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module mig_7series_v2_3_rank_common #
(
parameter TCQ = 100,
parameter DRAM_TYPE = "DDR3",
parameter MAINT_PRESCALER_DIV = 40,
parameter nBANK_MACHS = 4,
parameter nCKESR = 4,
parameter nCK_PER_CLK = 2,
parameter PERIODIC_RD_TIMER_DIV = 20,
parameter RANK_WIDTH = 2,
parameter RANKS = 4,
parameter REFRESH_TIMER_DIV = 39,
parameter ZQ_TIMER_DIV = 640000
)
(/*AUTOARG*/
// Outputs
maint_prescaler_tick_r, refresh_tick, maint_zq_r, maint_sre_r, maint_srx_r,
maint_req_r, maint_rank_r, clear_periodic_rd_request, periodic_rd_r,
periodic_rd_rank_r, app_ref_ack, app_zq_ack, app_sr_active, maint_ref_zq_wip,
// Inputs
clk, rst, init_calib_complete, app_ref_req, app_zq_req, app_sr_req,
insert_maint_r1, refresh_request, maint_wip_r, slot_0_present, slot_1_present,
periodic_rd_request, periodic_rd_ack_r
);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
input clk;
input rst;
// Maintenance and periodic read prescaler. Nominally 200 nS.
localparam ONE = 1;
localparam MAINT_PRESCALER_WIDTH = clogb2(MAINT_PRESCALER_DIV + 1);
input init_calib_complete;
reg maint_prescaler_tick_r_lcl;
generate
begin : maint_prescaler
reg [MAINT_PRESCALER_WIDTH-1:0] maint_prescaler_r;
reg [MAINT_PRESCALER_WIDTH-1:0] maint_prescaler_ns;
wire maint_prescaler_tick_ns =
(maint_prescaler_r == ONE[MAINT_PRESCALER_WIDTH-1:0]);
always @(/*AS*/init_calib_complete or maint_prescaler_r
or maint_prescaler_tick_ns) begin
maint_prescaler_ns = maint_prescaler_r;
if (~init_calib_complete || maint_prescaler_tick_ns)
maint_prescaler_ns = MAINT_PRESCALER_DIV[MAINT_PRESCALER_WIDTH-1:0];
else if (|maint_prescaler_r)
maint_prescaler_ns = maint_prescaler_r - ONE[MAINT_PRESCALER_WIDTH-1:0];
end
always @(posedge clk) maint_prescaler_r <= #TCQ maint_prescaler_ns;
always @(posedge clk) maint_prescaler_tick_r_lcl <=
#TCQ maint_prescaler_tick_ns;
end
endgenerate
output wire maint_prescaler_tick_r;
assign maint_prescaler_tick_r = maint_prescaler_tick_r_lcl;
// Refresh timebase. Nominically 7800 nS.
localparam REFRESH_TIMER_WIDTH = clogb2(REFRESH_TIMER_DIV + /*idle*/ 1);
wire refresh_tick_lcl;
generate
begin : refresh_timer
reg [REFRESH_TIMER_WIDTH-1:0] refresh_timer_r;
reg [REFRESH_TIMER_WIDTH-1:0] refresh_timer_ns;
always @(/*AS*/init_calib_complete or maint_prescaler_tick_r_lcl
or refresh_tick_lcl or refresh_timer_r) begin
refresh_timer_ns = refresh_timer_r;
if (~init_calib_complete || refresh_tick_lcl)
refresh_timer_ns = REFRESH_TIMER_DIV[REFRESH_TIMER_WIDTH-1:0];
else if (|refresh_timer_r && maint_prescaler_tick_r_lcl)
refresh_timer_ns =
refresh_timer_r - ONE[REFRESH_TIMER_WIDTH-1:0];
end
always @(posedge clk) refresh_timer_r <= #TCQ refresh_timer_ns;
assign refresh_tick_lcl = (refresh_timer_r ==
ONE[REFRESH_TIMER_WIDTH-1:0]) && maint_prescaler_tick_r_lcl;
end
endgenerate
output wire refresh_tick;
assign refresh_tick = refresh_tick_lcl;
// ZQ timebase. Nominally 128 mS
localparam ZQ_TIMER_WIDTH = clogb2(ZQ_TIMER_DIV + 1);
input app_zq_req;
input insert_maint_r1;
reg maint_zq_r_lcl;
reg zq_request = 1'b0;
generate
if (DRAM_TYPE == "DDR3") begin : zq_cntrl
reg zq_tick = 1'b0;
if (ZQ_TIMER_DIV !=0) begin : zq_timer
reg [ZQ_TIMER_WIDTH-1:0] zq_timer_r;
reg [ZQ_TIMER_WIDTH-1:0] zq_timer_ns;
always @(/*AS*/init_calib_complete or maint_prescaler_tick_r_lcl
or zq_tick or zq_timer_r) begin
zq_timer_ns = zq_timer_r;
if (~init_calib_complete || zq_tick)
zq_timer_ns = ZQ_TIMER_DIV[ZQ_TIMER_WIDTH-1:0];
else if (|zq_timer_r && maint_prescaler_tick_r_lcl)
zq_timer_ns = zq_timer_r - ONE[ZQ_TIMER_WIDTH-1:0];
end
always @(posedge clk) zq_timer_r <= #TCQ zq_timer_ns;
always @(/*AS*/maint_prescaler_tick_r_lcl or zq_timer_r)
zq_tick = (zq_timer_r ==
ONE[ZQ_TIMER_WIDTH-1:0] && maint_prescaler_tick_r_lcl);
end // zq_timer
// ZQ request. Set request with timer tick, and when exiting PHY init. Never
// request if ZQ_TIMER_DIV == 0.
begin : zq_request_logic
wire zq_clears_zq_request = insert_maint_r1 && maint_zq_r_lcl;
reg zq_request_r;
wire zq_request_ns = ~rst && (DRAM_TYPE == "DDR3") &&
((~init_calib_complete && (ZQ_TIMER_DIV != 0)) ||
(zq_request_r && ~zq_clears_zq_request) ||
zq_tick ||
(app_zq_req && init_calib_complete));
always @(posedge clk) zq_request_r <= #TCQ zq_request_ns;
always @(/*AS*/init_calib_complete or zq_request_r)
zq_request = init_calib_complete && zq_request_r;
end // zq_request_logic
end
endgenerate
// Self-refresh control
localparam nCKESR_CLKS = (nCKESR / nCK_PER_CLK) + (nCKESR % nCK_PER_CLK ? 1 : 0);
localparam CKESR_TIMER_WIDTH = clogb2(nCKESR_CLKS + 1);
input app_sr_req;
reg maint_sre_r_lcl;
reg maint_srx_r_lcl;
reg sre_request = 1'b0;
wire inhbt_srx;
generate begin : sr_cntrl
// SRE request. Set request with user request.
begin : sre_request_logic
reg sre_request_r;
wire sre_clears_sre_request = insert_maint_r1 && maint_sre_r_lcl;
wire sre_request_ns = ~rst && ((sre_request_r && ~sre_clears_sre_request)
|| (app_sr_req && init_calib_complete && ~maint_sre_r_lcl));
always @(posedge clk) sre_request_r <= #TCQ sre_request_ns;
always @(init_calib_complete or sre_request_r)
sre_request = init_calib_complete && sre_request_r;
end // sre_request_logic
// CKESR timer: Self-Refresh must be maintained for a minimum of tCKESR
begin : ckesr_timer
reg [CKESR_TIMER_WIDTH-1:0] ckesr_timer_r = {CKESR_TIMER_WIDTH{1'b0}};
reg [CKESR_TIMER_WIDTH-1:0] ckesr_timer_ns = {CKESR_TIMER_WIDTH{1'b0}};
always @(insert_maint_r1 or ckesr_timer_r or maint_sre_r_lcl) begin
ckesr_timer_ns = ckesr_timer_r;
if (insert_maint_r1 && maint_sre_r_lcl)
ckesr_timer_ns = nCKESR_CLKS[CKESR_TIMER_WIDTH-1:0];
else if(|ckesr_timer_r)
ckesr_timer_ns = ckesr_timer_r - ONE[CKESR_TIMER_WIDTH-1:0];
end
always @(posedge clk) ckesr_timer_r <= #TCQ ckesr_timer_ns;
assign inhbt_srx = |ckesr_timer_r;
end // ckesr_timer
end
endgenerate
// DRAM maintenance operations of refresh and ZQ calibration, and self-refresh
// DRAM maintenance operations and self-refresh have their own channel in the
// queue. There is also a single, very simple bank machine
// dedicated to these operations. Its assumed that the
// maintenance operations can be completed quickly enough
// to avoid any queuing.
//
// ZQ, refresh and self-refresh requests share a channel into controller.
// Self-refresh is appended to the uppermost bit of the request bus and ZQ is
// appended just below that.
input[RANKS-1:0] refresh_request;
input maint_wip_r;
reg maint_req_r_lcl;
reg [RANK_WIDTH-1:0] maint_rank_r_lcl;
input [7:0] slot_0_present;
input [7:0] slot_1_present;
generate
begin : maintenance_request
// Maintenance request pipeline.
reg upd_last_master_r;
reg new_maint_rank_r;
wire maint_busy = upd_last_master_r || new_maint_rank_r ||
maint_req_r_lcl || maint_wip_r;
wire [RANKS+1:0] maint_request = {sre_request, zq_request, refresh_request[RANKS-1:0]};
wire upd_last_master_ns = |maint_request && ~maint_busy;
always @(posedge clk) upd_last_master_r <= #TCQ upd_last_master_ns;
always @(posedge clk) new_maint_rank_r <= #TCQ upd_last_master_r;
always @(posedge clk) maint_req_r_lcl <= #TCQ new_maint_rank_r;
// Arbitrate maintenance requests.
wire [RANKS+1:0] maint_grant_ns;
wire [RANKS+1:0] maint_grant_r;
mig_7series_v2_3_round_robin_arb #
(.WIDTH (RANKS+2))
maint_arb0
(.grant_ns (maint_grant_ns),
.grant_r (maint_grant_r),
.upd_last_master (upd_last_master_r),
.current_master (maint_grant_r),
.req (maint_request),
.disable_grant (1'b0),
/*AUTOINST*/
// Inputs
.clk (clk),
.rst (rst));
// Look at arbitration results. Decide if ZQ, refresh or self-refresh.
// If refresh select the maintenance rank from the winning rank controller.
// If ZQ or self-refresh, generate a sequence of rank numbers corresponding to
// slots populated maint_rank_r is not used for comparisons in the queue for ZQ
// or self-refresh requests. The bank machine will enable CS for the number of
// states equal to the the number of occupied slots. This will produce a
// command to every occupied slot, but not in any particular order.
wire [7:0] present = slot_0_present | slot_1_present;
integer i;
reg [RANK_WIDTH-1:0] maint_rank_ns;
wire maint_zq_ns = ~rst && (upd_last_master_r
? maint_grant_r[RANKS]
: maint_zq_r_lcl);
wire maint_srx_ns = ~rst && (maint_sre_r_lcl
? ~app_sr_req & ~inhbt_srx
: maint_srx_r_lcl && upd_last_master_r
? maint_grant_r[RANKS+1]
: maint_srx_r_lcl);
wire maint_sre_ns = ~rst && (upd_last_master_r
? maint_grant_r[RANKS+1]
: maint_sre_r_lcl && ~maint_srx_ns);
always @(/*AS*/maint_grant_r or maint_rank_r_lcl or maint_zq_ns
or maint_sre_ns or maint_srx_ns or present or rst
or upd_last_master_r) begin
if (rst) maint_rank_ns = {RANK_WIDTH{1'b0}};
else begin
maint_rank_ns = maint_rank_r_lcl;
if (maint_zq_ns || maint_sre_ns || maint_srx_ns) begin
maint_rank_ns = maint_rank_r_lcl + ONE[RANK_WIDTH-1:0];
for (i=0; i<8; i=i+1)
if (~present[maint_rank_ns])
maint_rank_ns = maint_rank_ns + ONE[RANK_WIDTH-1:0];
end
else
if (upd_last_master_r)
for (i=0; i<RANKS; i=i+1)
if (maint_grant_r[i]) maint_rank_ns = i[RANK_WIDTH-1:0];
end
end
always @(posedge clk) maint_rank_r_lcl <= #TCQ maint_rank_ns;
always @(posedge clk) maint_zq_r_lcl <= #TCQ maint_zq_ns;
always @(posedge clk) maint_sre_r_lcl <= #TCQ maint_sre_ns;
always @(posedge clk) maint_srx_r_lcl <= #TCQ maint_srx_ns;
end // block: maintenance_request
endgenerate
output wire maint_zq_r;
assign maint_zq_r = maint_zq_r_lcl;
output wire maint_sre_r;
assign maint_sre_r = maint_sre_r_lcl;
output wire maint_srx_r;
assign maint_srx_r = maint_srx_r_lcl;
output wire maint_req_r;
assign maint_req_r = maint_req_r_lcl;
output wire [RANK_WIDTH-1:0] maint_rank_r;
assign maint_rank_r = maint_rank_r_lcl;
// Indicate whether self-refresh is active or not.
output app_sr_active;
reg app_sr_active_r;
wire app_sr_active_ns =
insert_maint_r1 ? maint_sre_r && ~maint_srx_r : app_sr_active_r;
always @(posedge clk) app_sr_active_r <= #TCQ app_sr_active_ns;
assign app_sr_active = app_sr_active_r;
// Acknowledge user REF and ZQ Requests
input app_ref_req;
output app_ref_ack;
wire app_ref_ack_ns;
wire app_ref_ns;
reg app_ref_ack_r = 1'b0;
reg app_ref_r = 1'b0;
assign app_ref_ns = init_calib_complete && (app_ref_req || app_ref_r && |refresh_request);
assign app_ref_ack_ns = app_ref_r && ~|refresh_request;
always @(posedge clk) app_ref_r <= #TCQ app_ref_ns;
always @(posedge clk) app_ref_ack_r <= #TCQ app_ref_ack_ns;
assign app_ref_ack = app_ref_ack_r;
output app_zq_ack;
wire app_zq_ack_ns;
wire app_zq_ns;
reg app_zq_ack_r = 1'b0;
reg app_zq_r = 1'b0;
assign app_zq_ns = init_calib_complete && (app_zq_req || app_zq_r && zq_request);
assign app_zq_ack_ns = app_zq_r && ~zq_request;
always @(posedge clk) app_zq_r <= #TCQ app_zq_ns;
always @(posedge clk) app_zq_ack_r <= #TCQ app_zq_ack_ns;
assign app_zq_ack = app_zq_ack_r;
// Periodic reads to maintain PHY alignment.
// Demand insertion of periodic read as soon as
// possible. Since the is a single rank, bank compare mechanism
// must be used, periodic reads must be forced in at the
// expense of not accepting a normal request.
input [RANKS-1:0] periodic_rd_request;
reg periodic_rd_r_lcl;
reg [RANK_WIDTH-1:0] periodic_rd_rank_r_lcl;
input periodic_rd_ack_r;
output wire [RANKS-1:0] clear_periodic_rd_request;
output wire periodic_rd_r;
output wire [RANK_WIDTH-1:0] periodic_rd_rank_r;
generate
// This is not needed in 7-Series and should remain disabled
if ( PERIODIC_RD_TIMER_DIV != 0 ) begin : periodic_read_request
// Maintenance request pipeline.
reg periodic_rd_r_cnt;
wire int_periodic_rd_ack_r = (periodic_rd_ack_r && periodic_rd_r_cnt);
reg upd_last_master_r;
wire periodic_rd_busy = upd_last_master_r || periodic_rd_r_lcl;
wire upd_last_master_ns =
init_calib_complete && (|periodic_rd_request && ~periodic_rd_busy);
always @(posedge clk) upd_last_master_r <= #TCQ upd_last_master_ns;
wire periodic_rd_ns = init_calib_complete &&
(upd_last_master_r || (periodic_rd_r_lcl && ~int_periodic_rd_ack_r));
always @(posedge clk) periodic_rd_r_lcl <= #TCQ periodic_rd_ns;
always @(posedge clk) begin
if (rst) periodic_rd_r_cnt <= #TCQ 1'b0;
else if (periodic_rd_r_lcl && periodic_rd_ack_r)
periodic_rd_r_cnt <= ~periodic_rd_r_cnt;
end
// Arbitrate periodic read requests.
wire [RANKS-1:0] periodic_rd_grant_ns;
reg [RANKS-1:0] periodic_rd_grant_r;
mig_7series_v2_3_round_robin_arb #
(.WIDTH (RANKS))
periodic_rd_arb0
(.grant_ns (periodic_rd_grant_ns[RANKS-1:0]),
.grant_r (),
.upd_last_master (upd_last_master_r),
.current_master (periodic_rd_grant_r[RANKS-1:0]),
.req (periodic_rd_request[RANKS-1:0]),
.disable_grant (1'b0),
/*AUTOINST*/
// Inputs
.clk (clk),
.rst (rst));
always @(posedge clk) periodic_rd_grant_r = upd_last_master_ns
? periodic_rd_grant_ns
: periodic_rd_grant_r;
// Encode and set periodic read rank into periodic_rd_rank_r.
integer i;
reg [RANK_WIDTH-1:0] periodic_rd_rank_ns;
always @(/*AS*/periodic_rd_grant_r or periodic_rd_rank_r_lcl
or upd_last_master_r) begin
periodic_rd_rank_ns = periodic_rd_rank_r_lcl;
if (upd_last_master_r)
for (i=0; i<RANKS; i=i+1)
if (periodic_rd_grant_r[i])
periodic_rd_rank_ns = i[RANK_WIDTH-1:0];
end
always @(posedge clk) periodic_rd_rank_r_lcl <=
#TCQ periodic_rd_rank_ns;
// Once the request is dropped in the queue, it might be a while before it
// emerges. Can't clear the request based on seeing the read issued.
// Need to clear the request as soon as its made it into the queue.
assign clear_periodic_rd_request =
periodic_rd_grant_r & {RANKS{periodic_rd_ack_r}};
assign periodic_rd_r = periodic_rd_r_lcl;
assign periodic_rd_rank_r = periodic_rd_rank_r_lcl;
end else begin
// Disable periodic reads
assign clear_periodic_rd_request = {RANKS{1'b0}};
assign periodic_rd_r = 1'b0;
assign periodic_rd_rank_r = {RANK_WIDTH{1'b0}};
end // block: periodic_read_request
endgenerate
// Indicate that a refresh is in progress. The PHY will use this to schedule
// tap adjustments during idle bus time
reg maint_ref_zq_wip_r = 1'b0;
output maint_ref_zq_wip;
always @(posedge clk)
if(rst)
maint_ref_zq_wip_r <= #TCQ 1'b0;
else if((zq_request || |refresh_request) && insert_maint_r1)
maint_ref_zq_wip_r <= #TCQ 1'b1;
else if(~maint_wip_r)
maint_ref_zq_wip_r <= #TCQ 1'b0;
assign maint_ref_zq_wip = maint_ref_zq_wip_r;
endmodule
|
module Comparators
//Module Parameter
//W_Exp = 9 ; Single Precision Format
//W_Exp = 11; Double Precision Format
# (parameter W_Exp = 9)
/* # (parameter W_Exp = 12)*/
(
input wire [W_Exp-1:0] exp, //exponent of the fifth phase
output wire overflow, //overflow flag
output wire underflow //underflow flag
);
wire [W_Exp-1:0] U_limit; //Max Normal value of the standar ieee 754
wire [W_Exp-1:0] L_limit; //Min Normal value of the standar ieee 754
//Compares the exponent with the Max Normal Value, if the exponent is
//larger than U_limit then exist overflow
Greater_Comparator #(.W(W_Exp)) GTComparator (
.Data_A(exp),
.Data_B(U_limit),
.gthan(overflow)
);
//Compares the exponent with the Min Normal Value, if the exponent is
//smaller than L_limit then exist underflow
Comparator_Less #(.W(W_Exp)) LTComparator (
.Data_A(exp),
.Data_B(L_limit),
.less(underflow)
);
//This generate sentence creates the limit values based on the
//precision format
generate
if(W_Exp == 9) begin
assign U_limit = 9'hfe;
assign L_limit = 9'h01;
end
else begin
assign U_limit = 12'b111111111110;
assign L_limit = 12'b000000000001;
end
endgenerate
endmodule
|
module mig_7series_v2_3_ddr_phy_prbs_rdlvl #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter nCK_PER_CLK = 2, // # of memory clocks per CLK
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter RANKS = 1, // # of DRAM ranks
parameter SIM_CAL_OPTION = "NONE", // Skip various calibration steps
parameter PRBS_WIDTH = 8, // PRBS generator output width
parameter FIXED_VICTIM = "TRUE", // No victim rotation when "TRUE"
parameter FINE_PER_BIT = "ON",
parameter CENTER_COMP_MODE = "ON",
parameter PI_VAL_ADJ = "ON"
)
(
input clk,
input rst,
// Calibration status, control signals
input prbs_rdlvl_start,
(* max_fanout = 100 *) output reg prbs_rdlvl_done,
output reg prbs_last_byte_done,
output reg prbs_rdlvl_prech_req,
input complex_sample_cnt_inc,
input prech_done,
input phy_if_empty,
// Captured data in fabric clock domain
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] rd_data,
//Expected data from PRBS generator
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] compare_data,
// Decrement initial Phaser_IN Fine tap delay
input [5:0] pi_counter_read_val,
// Stage 1 calibration outputs
output reg pi_en_stg2_f,
output reg pi_stg2_f_incdec,
output [255:0] dbg_prbs_rdlvl,
output [DQS_CNT_WIDTH:0] pi_stg2_prbs_rdlvl_cnt,
output reg [2:0] rd_victim_sel,
output reg complex_victim_inc,
output reg reset_rd_addr,
output reg read_pause,
output reg [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r,
output reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps,
output reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps,
output reg [DRAM_WIDTH-1:0] fine_delay_incdec_pb, //fine_delay decreament per bit
output reg fine_delay_sel //fine delay selection - actual update of fine delay
);
localparam [5:0] PRBS_IDLE = 6'h00;
localparam [5:0] PRBS_NEW_DQS_WAIT = 6'h01;
localparam [5:0] PRBS_PAT_COMPARE = 6'h02;
localparam [5:0] PRBS_DEC_DQS = 6'h03;
localparam [5:0] PRBS_DEC_DQS_WAIT = 6'h04;
localparam [5:0] PRBS_INC_DQS = 6'h05;
localparam [5:0] PRBS_INC_DQS_WAIT = 6'h06;
localparam [5:0] PRBS_CALC_TAPS = 6'h07;
localparam [5:0] PRBS_NEXT_DQS = 6'h08;
localparam [5:0] PRBS_NEW_DQS_PREWAIT = 6'h09;
localparam [5:0] PRBS_DONE = 6'h0A;
localparam [5:0] PRBS_CALC_TAPS_PRE = 6'h0B;
localparam [5:0] PRBS_CALC_TAPS_WAIT = 6'h0C;
localparam [5:0] FINE_PI_DEC = 6'h0D; //go back to all fail or back to center
localparam [5:0] FINE_PI_DEC_WAIT = 6'h0E; //wait for PI tap dec settle
localparam [5:0] FINE_PI_INC = 6'h0F; //increse up to 1 fail
localparam [5:0] FINE_PI_INC_WAIT = 6'h10; //wait for PI tap int settle
localparam [5:0] FINE_PAT_COMPARE_PER_BIT = 6'h11; //compare per bit error and check left/right/gain/loss
localparam [5:0] FINE_CALC_TAPS = 6'h12; //setup fine_delay_incdec_pb for better window size
localparam [5:0] FINE_CALC_TAPS_WAIT = 6'h13; //wait for ROM value for dec cnt
localparam [11:0] NUM_SAMPLES_CNT = (SIM_CAL_OPTION == "NONE") ? 'd50 : 12'h001;
localparam [11:0] NUM_SAMPLES_CNT1 = (SIM_CAL_OPTION == "NONE") ? 'd20 : 12'h001;
localparam [11:0] NUM_SAMPLES_CNT2 = (SIM_CAL_OPTION == "NONE") ? 'd10 : 12'h001;
wire [DQS_CNT_WIDTH+2:0]prbs_dqs_cnt_timing;
reg [DQS_CNT_WIDTH+2:0] prbs_dqs_cnt_timing_r;
reg [DQS_CNT_WIDTH:0] prbs_dqs_cnt_r;
reg prbs_prech_req_r;
reg [5:0] prbs_state_r;
reg [5:0] prbs_state_r1;
reg wait_state_cnt_en_r;
reg [3:0] wait_state_cnt_r;
reg cnt_wait_state;
reg err_chk_invalid;
// reg found_edge_r;
reg prbs_found_1st_edge_r;
reg prbs_found_2nd_edge_r;
reg [5:0] prbs_1st_edge_taps_r;
// reg found_stable_eye_r;
reg [5:0] prbs_dqs_tap_cnt_r;
reg [5:0] prbs_dec_tap_calc_plus_3;
reg [5:0] prbs_dec_tap_calc_minus_3;
reg prbs_dqs_tap_limit_r;
reg [5:0] prbs_inc_tap_cnt;
reg [5:0] prbs_dec_tap_cnt;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r4;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r4;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r4;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r4;
reg mux_rd_valid_r;
reg rd_valid_r1;
reg rd_valid_r2;
reg rd_valid_r3;
reg new_cnt_dqs_r;
reg prbs_tap_en_r;
reg prbs_tap_inc_r;
reg pi_en_stg2_f_timing;
reg pi_stg2_f_incdec_timing;
wire [DQ_WIDTH-1:0] rd_data_rise0;
wire [DQ_WIDTH-1:0] rd_data_fall0;
wire [DQ_WIDTH-1:0] rd_data_rise1;
wire [DQ_WIDTH-1:0] rd_data_fall1;
wire [DQ_WIDTH-1:0] rd_data_rise2;
wire [DQ_WIDTH-1:0] rd_data_fall2;
wire [DQ_WIDTH-1:0] rd_data_rise3;
wire [DQ_WIDTH-1:0] rd_data_fall3;
wire [DQ_WIDTH-1:0] compare_data_r0;
wire [DQ_WIDTH-1:0] compare_data_f0;
wire [DQ_WIDTH-1:0] compare_data_r1;
wire [DQ_WIDTH-1:0] compare_data_f1;
wire [DQ_WIDTH-1:0] compare_data_r2;
wire [DQ_WIDTH-1:0] compare_data_f2;
wire [DQ_WIDTH-1:0] compare_data_r3;
wire [DQ_WIDTH-1:0] compare_data_f3;
reg [DRAM_WIDTH-1:0] compare_data_rise0_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall0_r1;
reg [DRAM_WIDTH-1:0] compare_data_rise1_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall1_r1;
reg [DRAM_WIDTH-1:0] compare_data_rise2_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall2_r1;
reg [DRAM_WIDTH-1:0] compare_data_rise3_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall3_r1;
reg [DQS_CNT_WIDTH:0] rd_mux_sel_r;
reg [5:0] prbs_2nd_edge_taps_r;
// reg [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r;
reg [5:0] rdlvl_cpt_tap_cnt;
reg prbs_rdlvl_start_r;
reg compare_err;
reg compare_err_r0;
reg compare_err_f0;
reg compare_err_r1;
reg compare_err_f1;
reg compare_err_r2;
reg compare_err_f2;
reg compare_err_r3;
reg compare_err_f3;
reg samples_cnt1_en_r;
reg samples_cnt2_en_r;
reg [11:0] samples_cnt_r;
reg num_samples_done_r;
reg num_samples_done_ind; //indicate num_samples_done_r is set in FINE_PAT_COMPARE_PER_BIT to prevent victim_sel_rd out of sync
reg [DQS_WIDTH-1:0] prbs_tap_mod;
//reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps;
//reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps;
//**************************************************************************
// signals for per-bit algorithm of fine_delay calculations
//**************************************************************************
reg [6*DRAM_WIDTH-1:0] left_edge_pb; //left edge value per bit
reg [6*DRAM_WIDTH-1:0] right_edge_pb; //right edge value per bit
reg [5*DRAM_WIDTH-1:0] match_flag_pb; //5 consecutive match flag per bit
reg [4:0] match_flag_and; //5 consecute match flag of all bits (1: all bit fail)
reg [DRAM_WIDTH-1:0] left_edge_found_pb; //left_edge found per bit - use for loss calculation
reg [DRAM_WIDTH-1:0] left_edge_updated; //left edge was updated for this PI tap - used for largest left edge /ref bit update
reg [DRAM_WIDTH-1:0] right_edge_found_pb; //right_edge found per bit - use for gail calulation and smallest right edge update
reg right_edge_found; //smallest right_edge found
reg [DRAM_WIDTH*6-1:0] left_loss_pb; //left_edge loss per bit
reg [DRAM_WIDTH*6-1:0] right_gain_pb; //right_edge gain per bit
reg [DRAM_WIDTH-1:0] ref_bit; //bit number which has largest left edge (with smaller right edge)
reg [DRAM_WIDTH-1:0] bit_cnt; //bit number used to calculate ref bit
reg [DRAM_WIDTH-1:0] ref_bit_per_bit; //bit flags which have largest left edge
reg [5:0] ref_right_edge; //ref_bit right edge - keep the smallest edge of ref bits
reg [5:0] largest_left_edge; //biggest left edge of per bit - will be left edge of byte
reg [5:0] smallest_right_edge; //smallest right edge of per bit - will be right edge of byte
reg [5:0] fine_pi_dec_cnt; //Phase In tap decrement count (to go back to '0' or center)
reg [6:0] center_calc; //used for calculate the dec tap for centering
reg [5:0] right_edge_ref; //ref_bit right edge
reg [5:0] left_edge_ref; //ref_bit left edge
reg [DRAM_WIDTH-1:0] compare_err_pb; //compare error per bit
reg [DRAM_WIDTH-1:0] compare_err_pb_latch_r; //sticky compare error per bit used for left/right edge
reg compare_err_pb_and; //indicate all bit fail
reg fine_inc_stage; //fine_inc_stage (1: increment all except ref_bit, 0: only inc for gain bit)
reg [1:0] stage_cnt; //stage cnt (0,1: fine delay inc stage, 2: fine delay dec stage)
wire fine_calib; //turn on/off fine delay calibration
reg [5:0] mem_out_dec;
reg [5:0] dec_cnt;
reg fine_dly_error; //indicate it has wrong left/right edge
wire center_comp;
wire pi_adj;
//**************************************************************************
// DQS count to hard PHY during write calibration using Phaser_OUT Stage2
// coarse delay
//**************************************************************************
assign pi_stg2_prbs_rdlvl_cnt = prbs_dqs_cnt_r;
//fine delay turn on
assign fine_calib = (FINE_PER_BIT=="ON")? 1:0;
assign center_comp = (CENTER_COMP_MODE == "ON")? 1: 0;
assign pi_adj = (PI_VAL_ADJ == "ON")?1:0;
assign dbg_prbs_rdlvl[0+:6] = left_edge_pb[0+:6];
assign dbg_prbs_rdlvl[7:6] = left_loss_pb[0+:2];
assign dbg_prbs_rdlvl[8+:6] = left_edge_pb[6+:6];
assign dbg_prbs_rdlvl[15:14] = left_loss_pb[6+:2];
assign dbg_prbs_rdlvl[16+:6] = left_edge_pb[12+:6] ;
assign dbg_prbs_rdlvl[23:22] = left_loss_pb[12+:2];
assign dbg_prbs_rdlvl[24+:6] = left_edge_pb[18+:6] ;
assign dbg_prbs_rdlvl[31:30] = left_loss_pb[18+:2];
assign dbg_prbs_rdlvl[32+:6] = left_edge_pb[24+:6];
assign dbg_prbs_rdlvl[39:38] = left_loss_pb[24+:2];
assign dbg_prbs_rdlvl[40+:6] = left_edge_pb[30+:6];
assign dbg_prbs_rdlvl[47:46] = left_loss_pb[30+:2];
assign dbg_prbs_rdlvl[48+:6] = left_edge_pb[36+:6];
assign dbg_prbs_rdlvl[55:54] = left_loss_pb[36+:2];
assign dbg_prbs_rdlvl[56+:6] = left_edge_pb[42+:6];
assign dbg_prbs_rdlvl[63:62] = left_loss_pb[42+:2];
assign dbg_prbs_rdlvl[64+:6] = right_edge_pb[0+:6];
assign dbg_prbs_rdlvl[71:70] = right_gain_pb[0+:2];
assign dbg_prbs_rdlvl[72+:6] = right_edge_pb[6+:6] ;
assign dbg_prbs_rdlvl[79:78] = right_gain_pb[6+:2];
assign dbg_prbs_rdlvl[80+:6] = right_edge_pb[12+:6];
assign dbg_prbs_rdlvl[87:86] = right_gain_pb[12+:2];
assign dbg_prbs_rdlvl[88+:6] = right_edge_pb[18+:6];
assign dbg_prbs_rdlvl[95:94] = right_gain_pb[18+:2];
assign dbg_prbs_rdlvl[96+:6] = right_edge_pb[24+:6];
assign dbg_prbs_rdlvl[103:102] = right_gain_pb[24+:2];
assign dbg_prbs_rdlvl[104+:6] = right_edge_pb[30+:6];
assign dbg_prbs_rdlvl[111:110] = right_gain_pb[30+:2];
assign dbg_prbs_rdlvl[112+:6] = right_edge_pb[36+:6];
assign dbg_prbs_rdlvl[119:118] = right_gain_pb[36+:2];
assign dbg_prbs_rdlvl[120+:6] = right_edge_pb[42+:6];
assign dbg_prbs_rdlvl[127:126] = right_gain_pb[42+:2];
assign dbg_prbs_rdlvl[128+:6] = pi_counter_read_val;
assign dbg_prbs_rdlvl[134+:6] = prbs_dqs_tap_cnt_r;
assign dbg_prbs_rdlvl[140] = prbs_found_1st_edge_r;
assign dbg_prbs_rdlvl[141] = prbs_found_2nd_edge_r;
assign dbg_prbs_rdlvl[142] = compare_err;
assign dbg_prbs_rdlvl[143] = phy_if_empty;
assign dbg_prbs_rdlvl[144] = prbs_rdlvl_start;
assign dbg_prbs_rdlvl[145] = prbs_rdlvl_done;
assign dbg_prbs_rdlvl[146+:5] = prbs_dqs_cnt_r;
assign dbg_prbs_rdlvl[151+:6] = left_edge_pb[prbs_dqs_cnt_r*6+:6] ;
assign dbg_prbs_rdlvl[157+:6] = right_edge_pb[prbs_dqs_cnt_r*6+:6];
assign dbg_prbs_rdlvl[163+:6] = {2'h0,complex_victim_inc, rd_victim_sel[2:0]};
assign dbg_prbs_rdlvl[169+:6] =right_gain_pb[prbs_dqs_cnt_r*6+:6] ;
assign dbg_prbs_rdlvl[177:175] = ref_bit[2:0];
assign dbg_prbs_rdlvl[178+:6] = prbs_state_r1[5:0];
assign dbg_prbs_rdlvl[184] = rd_valid_r2;
assign dbg_prbs_rdlvl[185] = compare_err_r0;
assign dbg_prbs_rdlvl[186] = compare_err_f0;
assign dbg_prbs_rdlvl[187] = compare_err_r1;
assign dbg_prbs_rdlvl[188] = compare_err_f1;
assign dbg_prbs_rdlvl[189] = compare_err_r2;
assign dbg_prbs_rdlvl[190] = compare_err_f2;
assign dbg_prbs_rdlvl[191] = compare_err_r3;
assign dbg_prbs_rdlvl[192] = compare_err_f3;
assign dbg_prbs_rdlvl[193+:8] = left_edge_found_pb;
assign dbg_prbs_rdlvl[201+:8] = right_edge_found_pb;
assign dbg_prbs_rdlvl[209+:6] =largest_left_edge ;
assign dbg_prbs_rdlvl[215+:6] =smallest_right_edge ;
assign dbg_prbs_rdlvl[221+:8] = fine_delay_incdec_pb;
assign dbg_prbs_rdlvl[229] = fine_delay_sel;
assign dbg_prbs_rdlvl[230+:8] = compare_err_pb_latch_r;
assign dbg_prbs_rdlvl[238+:6] = fine_pi_dec_cnt;
assign dbg_prbs_rdlvl[244+:5] = match_flag_and ;
assign dbg_prbs_rdlvl[249+:2] =stage_cnt ;
assign dbg_prbs_rdlvl[251] = fine_inc_stage ;
assign dbg_prbs_rdlvl[252] = compare_err_pb_and ;
assign dbg_prbs_rdlvl[253] = right_edge_found ;
assign dbg_prbs_rdlvl[254] = fine_dly_error ;
assign dbg_prbs_rdlvl[255]= 'b0;//reserved
//**************************************************************************
// Record first and second edges found during calibration
//**************************************************************************
generate
always @(posedge clk)
if (rst) begin
dbg_prbs_first_edge_taps <= #TCQ 'b0;
dbg_prbs_second_edge_taps <= #TCQ 'b0;
end else if (prbs_state_r == PRBS_CALC_TAPS) begin
// Record tap counts of first and second edge edges during
// calibration for each DQS group. If neither edge has
// been found, then those taps will remain 0
if (prbs_found_1st_edge_r)
dbg_prbs_first_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ prbs_1st_edge_taps_r;
if (prbs_found_2nd_edge_r)
dbg_prbs_second_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ prbs_2nd_edge_taps_r;
end else if (prbs_state_r == FINE_CALC_TAPS) begin
if(stage_cnt == 'd2) begin
dbg_prbs_first_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ largest_left_edge;
dbg_prbs_second_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ smallest_right_edge;
end
end
endgenerate
//padded calculation
always @ (smallest_right_edge or largest_left_edge)
center_calc <= {1'b0, smallest_right_edge} + {1'b0,largest_left_edge};
//***************************************************************************
//***************************************************************************
// Data mux to route appropriate bit to calibration logic - i.e. calibration
// is done sequentially, one bit (or DQS group) at a time
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: rd_data_div4_logic_clk
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign rd_data_rise2 = rd_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign rd_data_fall2 = rd_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign rd_data_rise3 = rd_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign rd_data_fall3 = rd_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
assign compare_data_r0 = compare_data[DQ_WIDTH-1:0];
assign compare_data_f0 = compare_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign compare_data_r1 = compare_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign compare_data_f1 = compare_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign compare_data_r2 = compare_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign compare_data_f2 = compare_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign compare_data_r3 = compare_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign compare_data_f3 = compare_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
end else begin: rd_data_div2_logic_clk
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign compare_data_r0 = compare_data[DQ_WIDTH-1:0];
assign compare_data_f0 = compare_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign compare_data_r1 = compare_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign compare_data_f1 = compare_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign compare_data_r2 = 'h0;
assign compare_data_f2 = 'h0;
assign compare_data_r3 = 'h0;
assign compare_data_f3 = 'h0;
end
endgenerate
always @(posedge clk) begin
rd_mux_sel_r <= #TCQ prbs_dqs_cnt_r;
end
// Register outputs for improved timing.
// NOTE: Will need to change when per-bit DQ deskew is supported.
// Currenly all bits in DQS group are checked in aggregate
generate
genvar mux_i;
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r1[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r1[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r1[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r1[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise2_r1[mux_i] <= #TCQ rd_data_rise2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall2_r1[mux_i] <= #TCQ rd_data_fall2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise3_r1[mux_i] <= #TCQ rd_data_rise3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall3_r1[mux_i] <= #TCQ rd_data_fall3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
//Compare data
compare_data_rise0_r1[mux_i] <= #TCQ compare_data_r0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall0_r1[mux_i] <= #TCQ compare_data_f0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_rise1_r1[mux_i] <= #TCQ compare_data_r1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall1_r1[mux_i] <= #TCQ compare_data_f1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_rise2_r1[mux_i] <= #TCQ compare_data_r2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall2_r1[mux_i] <= #TCQ compare_data_f2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_rise3_r1[mux_i] <= #TCQ compare_data_r3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall3_r1[mux_i] <= #TCQ compare_data_f3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
endgenerate
generate
genvar muxr2_i;
if (nCK_PER_CLK == 4) begin: gen_mux_div4
for (muxr2_i = 0; muxr2_i < DRAM_WIDTH; muxr2_i = muxr2_i + 1) begin: gen_rd_4
always @(posedge clk) begin
if (mux_rd_valid_r) begin
mux_rd_rise0_r2[muxr2_i] <= #TCQ mux_rd_rise0_r1[muxr2_i];
mux_rd_fall0_r2[muxr2_i] <= #TCQ mux_rd_fall0_r1[muxr2_i];
mux_rd_rise1_r2[muxr2_i] <= #TCQ mux_rd_rise1_r1[muxr2_i];
mux_rd_fall1_r2[muxr2_i] <= #TCQ mux_rd_fall1_r1[muxr2_i];
mux_rd_rise2_r2[muxr2_i] <= #TCQ mux_rd_rise2_r1[muxr2_i];
mux_rd_fall2_r2[muxr2_i] <= #TCQ mux_rd_fall2_r1[muxr2_i];
mux_rd_rise3_r2[muxr2_i] <= #TCQ mux_rd_rise3_r1[muxr2_i];
mux_rd_fall3_r2[muxr2_i] <= #TCQ mux_rd_fall3_r1[muxr2_i];
end
//pipeline stage
mux_rd_rise0_r3[muxr2_i] <= #TCQ mux_rd_rise0_r2[muxr2_i];
mux_rd_fall0_r3[muxr2_i] <= #TCQ mux_rd_fall0_r2[muxr2_i];
mux_rd_rise1_r3[muxr2_i] <= #TCQ mux_rd_rise1_r2[muxr2_i];
mux_rd_fall1_r3[muxr2_i] <= #TCQ mux_rd_fall1_r2[muxr2_i];
mux_rd_rise2_r3[muxr2_i] <= #TCQ mux_rd_rise2_r2[muxr2_i];
mux_rd_fall2_r3[muxr2_i] <= #TCQ mux_rd_fall2_r2[muxr2_i];
mux_rd_rise3_r3[muxr2_i] <= #TCQ mux_rd_rise3_r2[muxr2_i];
mux_rd_fall3_r3[muxr2_i] <= #TCQ mux_rd_fall3_r2[muxr2_i];
//pipeline stage
mux_rd_rise0_r4[muxr2_i] <= #TCQ mux_rd_rise0_r3[muxr2_i];
mux_rd_fall0_r4[muxr2_i] <= #TCQ mux_rd_fall0_r3[muxr2_i];
mux_rd_rise1_r4[muxr2_i] <= #TCQ mux_rd_rise1_r3[muxr2_i];
mux_rd_fall1_r4[muxr2_i] <= #TCQ mux_rd_fall1_r3[muxr2_i];
mux_rd_rise2_r4[muxr2_i] <= #TCQ mux_rd_rise2_r3[muxr2_i];
mux_rd_fall2_r4[muxr2_i] <= #TCQ mux_rd_fall2_r3[muxr2_i];
mux_rd_rise3_r4[muxr2_i] <= #TCQ mux_rd_rise3_r3[muxr2_i];
mux_rd_fall3_r4[muxr2_i] <= #TCQ mux_rd_fall3_r3[muxr2_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_mux_div2
for (muxr2_i = 0; muxr2_i < DRAM_WIDTH; muxr2_i = muxr2_i + 1) begin: gen_rd_2
always @(posedge clk) begin
if (mux_rd_valid_r) begin
mux_rd_rise0_r2[muxr2_i] <= #TCQ mux_rd_rise0_r1[muxr2_i];
mux_rd_fall0_r2[muxr2_i] <= #TCQ mux_rd_fall0_r1[muxr2_i];
mux_rd_rise1_r2[muxr2_i] <= #TCQ mux_rd_rise1_r1[muxr2_i];
mux_rd_fall1_r2[muxr2_i] <= #TCQ mux_rd_fall1_r1[muxr2_i];
mux_rd_rise2_r2[muxr2_i] <= 'h0;
mux_rd_fall2_r2[muxr2_i] <= 'h0;
mux_rd_rise3_r2[muxr2_i] <= 'h0;
mux_rd_fall3_r2[muxr2_i] <= 'h0;
end
mux_rd_rise0_r3[muxr2_i] <= #TCQ mux_rd_rise0_r2[muxr2_i];
mux_rd_fall0_r3[muxr2_i] <= #TCQ mux_rd_fall0_r2[muxr2_i];
mux_rd_rise1_r3[muxr2_i] <= #TCQ mux_rd_rise1_r2[muxr2_i];
mux_rd_fall1_r3[muxr2_i] <= #TCQ mux_rd_fall1_r2[muxr2_i];
mux_rd_rise2_r3[muxr2_i] <= 'h0;
mux_rd_fall2_r3[muxr2_i] <= 'h0;
mux_rd_rise3_r3[muxr2_i] <= 'h0;
mux_rd_fall3_r3[muxr2_i] <= 'h0;
//pipeline stage
mux_rd_rise0_r4[muxr2_i] <= #TCQ mux_rd_rise0_r3[muxr2_i];
mux_rd_fall0_r4[muxr2_i] <= #TCQ mux_rd_fall0_r3[muxr2_i];
mux_rd_rise1_r4[muxr2_i] <= #TCQ mux_rd_rise1_r3[muxr2_i];
mux_rd_fall1_r4[muxr2_i] <= #TCQ mux_rd_fall1_r3[muxr2_i];
mux_rd_rise2_r4[muxr2_i] <= 'h0;
mux_rd_fall2_r4[muxr2_i] <= 'h0;
mux_rd_rise3_r4[muxr2_i] <= 'h0;
mux_rd_fall3_r4[muxr2_i] <= 'h0;
end
end
end
endgenerate
// Registered signal indicates when mux_rd_rise/fall_r is valid
always @(posedge clk) begin
mux_rd_valid_r <= #TCQ ~phy_if_empty && prbs_rdlvl_start;
rd_valid_r1 <= #TCQ mux_rd_valid_r;
rd_valid_r2 <= #TCQ rd_valid_r1;
rd_valid_r3 <= #TCQ rd_valid_r2;
end
// Counter counts # of samples compared
// Reset sample counter when not "sampling"
// Otherwise, count # of samples compared
// Same counter is shared for three samples checked
always @(posedge clk)
if (rst)
samples_cnt_r <= #TCQ 'b0;
else if (samples_cnt_r == NUM_SAMPLES_CNT) begin
samples_cnt_r <= #TCQ 'b0;
end else if (complex_sample_cnt_inc) begin
samples_cnt_r <= #TCQ samples_cnt_r + 1;
/*if (!rd_valid_r1 ||
(prbs_state_r == PRBS_DEC_DQS_WAIT) ||
(prbs_state_r == PRBS_INC_DQS_WAIT) ||
(prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS) ||
(samples_cnt_r == NUM_SAMPLES_CNT) ||
(samples_cnt_r == NUM_SAMPLES_CNT1))
samples_cnt_r <= #TCQ 'b0;
else if (rd_valid_r1 &&
(((samples_cnt_r < NUM_SAMPLES_CNT) && ~samples_cnt1_en_r) ||
((samples_cnt_r < NUM_SAMPLES_CNT1) && ~samples_cnt2_en_r) ||
((samples_cnt_r < NUM_SAMPLES_CNT2) && samples_cnt2_en_r)))
samples_cnt_r <= #TCQ samples_cnt_r + 1;*/
end
// Count #2 enable generation
// Assert when correct number of samples compared
always @(posedge clk)
if (rst)
samples_cnt1_en_r <= #TCQ 1'b0;
else begin
if ((prbs_state_r == PRBS_IDLE) ||
(prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS) ||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == PRBS_NEW_DQS_PREWAIT))
samples_cnt1_en_r <= #TCQ 1'b0;
else if ((samples_cnt_r == NUM_SAMPLES_CNT) && rd_valid_r1)
samples_cnt1_en_r <= #TCQ 1'b1;
end
// Counter #3 enable generation
// Assert when correct number of samples compared
always @(posedge clk)
if (rst)
samples_cnt2_en_r <= #TCQ 1'b0;
else begin
if ((prbs_state_r == PRBS_IDLE) ||
(prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS) ||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == PRBS_NEW_DQS_PREWAIT))
samples_cnt2_en_r <= #TCQ 1'b0;
else if ((samples_cnt_r == NUM_SAMPLES_CNT1) && rd_valid_r1 && samples_cnt1_en_r)
samples_cnt2_en_r <= #TCQ 1'b1;
end
// Victim selection logic
always @(posedge clk)
if (rst)
rd_victim_sel <= #TCQ 'd0;
else if (num_samples_done_r)
rd_victim_sel <= #TCQ 'd0;
else if (samples_cnt_r == NUM_SAMPLES_CNT) begin
if (rd_victim_sel < 'd7)
rd_victim_sel <= #TCQ rd_victim_sel + 1;
end
// Output row count increment pulse to phy_init
always @(posedge clk)
if (rst)
complex_victim_inc <= #TCQ 1'b0;
else if (samples_cnt_r == NUM_SAMPLES_CNT)
complex_victim_inc <= #TCQ 1'b1;
else
complex_victim_inc <= #TCQ 1'b0;
generate
if (FIXED_VICTIM == "TRUE") begin: victim_fixed
always @(posedge clk)
if (rst)
num_samples_done_r <= #TCQ 1'b0;
else if ((prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS)||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == FINE_PI_DEC))
num_samples_done_r <= #TCQ 'b0;
else if (samples_cnt_r == NUM_SAMPLES_CNT)
num_samples_done_r <= #TCQ 1'b1;
end else begin: victim_not_fixed
always @(posedge clk)
if (rst)
num_samples_done_r <= #TCQ 1'b0;
else if ((prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS)||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == FINE_PI_DEC))
num_samples_done_r <= #TCQ 'b0;
else if ((samples_cnt_r == NUM_SAMPLES_CNT) && (rd_victim_sel == 'd7))
num_samples_done_r <= #TCQ 1'b1;
end
endgenerate
//***************************************************************************
// Compare Read Data for the byte being Leveled with Expected data from PRBS
// generator. Resulting compare_err signal used to determine read data valid
// edge.
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: cmp_err_4to1
always @ (posedge clk) begin
if (rst || new_cnt_dqs_r) begin
compare_err <= #TCQ 1'b0;
compare_err_r0 <= #TCQ 1'b0;
compare_err_f0 <= #TCQ 1'b0;
compare_err_r1 <= #TCQ 1'b0;
compare_err_f1 <= #TCQ 1'b0;
compare_err_r2 <= #TCQ 1'b0;
compare_err_f2 <= #TCQ 1'b0;
compare_err_r3 <= #TCQ 1'b0;
compare_err_f3 <= #TCQ 1'b0;
end else if (rd_valid_r2) begin
compare_err_r0 <= #TCQ (mux_rd_rise0_r3 != compare_data_rise0_r1);
compare_err_f0 <= #TCQ (mux_rd_fall0_r3 != compare_data_fall0_r1);
compare_err_r1 <= #TCQ (mux_rd_rise1_r3 != compare_data_rise1_r1);
compare_err_f1 <= #TCQ (mux_rd_fall1_r3 != compare_data_fall1_r1);
compare_err_r2 <= #TCQ (mux_rd_rise2_r3 != compare_data_rise2_r1);
compare_err_f2 <= #TCQ (mux_rd_fall2_r3 != compare_data_fall2_r1);
compare_err_r3 <= #TCQ (mux_rd_rise3_r3 != compare_data_rise3_r1);
compare_err_f3 <= #TCQ (mux_rd_fall3_r3 != compare_data_fall3_r1);
compare_err <= #TCQ (compare_err_r0 | compare_err_f0 |
compare_err_r1 | compare_err_f1 |
compare_err_r2 | compare_err_f2 |
compare_err_r3 | compare_err_f3);
end
end
end else begin: cmp_err_2to1
always @ (posedge clk) begin
if (rst || new_cnt_dqs_r) begin
compare_err <= #TCQ 1'b0;
compare_err_r0 <= #TCQ 1'b0;
compare_err_f0 <= #TCQ 1'b0;
compare_err_r1 <= #TCQ 1'b0;
compare_err_f1 <= #TCQ 1'b0;
end else if (rd_valid_r2) begin
compare_err_r0 <= #TCQ (mux_rd_rise0_r3 != compare_data_rise0_r1);
compare_err_f0 <= #TCQ (mux_rd_fall0_r3 != compare_data_fall0_r1);
compare_err_r1 <= #TCQ (mux_rd_rise1_r3 != compare_data_rise1_r1);
compare_err_f1 <= #TCQ (mux_rd_fall1_r3 != compare_data_fall1_r1);
compare_err <= #TCQ (compare_err_r0 | compare_err_f0 |
compare_err_r1 | compare_err_f1);
end
end
end
endgenerate
//***************************************************************************
// Decrement initial Phaser_IN fine delay value before proceeding with
// read calibration
//***************************************************************************
//***************************************************************************
// Demultiplexor to control Phaser_IN delay values
//***************************************************************************
// Read DQS
always @(posedge clk) begin
if (rst) begin
pi_en_stg2_f_timing <= #TCQ 'b0;
pi_stg2_f_incdec_timing <= #TCQ 'b0;
end else if (prbs_tap_en_r) begin
// Change only specified DQS
pi_en_stg2_f_timing <= #TCQ 1'b1;
pi_stg2_f_incdec_timing <= #TCQ prbs_tap_inc_r;
end else begin
pi_en_stg2_f_timing <= #TCQ 'b0;
pi_stg2_f_incdec_timing <= #TCQ 'b0;
end
end
// registered for timing
always @(posedge clk) begin
pi_en_stg2_f <= #TCQ pi_en_stg2_f_timing;
pi_stg2_f_incdec <= #TCQ pi_stg2_f_incdec_timing;
end
//***************************************************************************
// generate request to PHY_INIT logic to issue precharged. Required when
// calibration can take a long time (during which there are only constant
// reads present on this bus). In this case need to issue perioidic
// precharges to avoid tRAS violation. This signal must meet the following
// requirements: (1) only transition from 0->1 when prech is first needed,
// (2) stay at 1 and only transition 1->0 when RDLVL_PRECH_DONE asserted
//***************************************************************************
always @(posedge clk)
if (rst)
prbs_rdlvl_prech_req <= #TCQ 1'b0;
else
prbs_rdlvl_prech_req <= #TCQ prbs_prech_req_r;
//*****************************************************************
// keep track of edge tap counts found, and current capture clock
// tap count
//*****************************************************************
always @(posedge clk)
if (rst) begin
prbs_dqs_tap_cnt_r <= #TCQ 'b0;
rdlvl_cpt_tap_cnt <= #TCQ 'b0;
end else if (new_cnt_dqs_r) begin
prbs_dqs_tap_cnt_r <= #TCQ pi_counter_read_val;
rdlvl_cpt_tap_cnt <= #TCQ pi_counter_read_val;
end else if (prbs_tap_en_r) begin
if (prbs_tap_inc_r)
prbs_dqs_tap_cnt_r <= #TCQ prbs_dqs_tap_cnt_r + 1;
else if (prbs_dqs_tap_cnt_r != 'd0)
prbs_dqs_tap_cnt_r <= #TCQ prbs_dqs_tap_cnt_r - 1;
end
always @(posedge clk)
if (rst) begin
prbs_dec_tap_calc_plus_3 <= #TCQ 'b0;
prbs_dec_tap_calc_minus_3 <= #TCQ 'b0;
end else if (new_cnt_dqs_r) begin
prbs_dec_tap_calc_plus_3 <= #TCQ 'b000011;
prbs_dec_tap_calc_minus_3 <= #TCQ 'b111100;
end else begin
prbs_dec_tap_calc_plus_3 <= #TCQ (prbs_dqs_tap_cnt_r - rdlvl_cpt_tap_cnt + 3);
prbs_dec_tap_calc_minus_3 <= #TCQ (prbs_dqs_tap_cnt_r - rdlvl_cpt_tap_cnt - 3);
end
always @(posedge clk)
if (rst || new_cnt_dqs_r)
prbs_dqs_tap_limit_r <= #TCQ 1'b0;
else if (prbs_dqs_tap_cnt_r == 6'd63)
prbs_dqs_tap_limit_r <= #TCQ 1'b1;
else
prbs_dqs_tap_limit_r <= #TCQ 1'b0;
// Temp wire for timing.
// The following in the always block below causes timing issues
// due to DSP block inference
// 6*prbs_dqs_cnt_r.
// replacing this with two left shifts + one left shift to avoid
// DSP multiplier.
assign prbs_dqs_cnt_timing = {2'd0, prbs_dqs_cnt_r};
always @(posedge clk)
prbs_dqs_cnt_timing_r <= #TCQ prbs_dqs_cnt_timing;
// Storing DQS tap values at the end of each DQS read leveling
always @(posedge clk) begin
if (rst) begin
prbs_final_dqs_tap_cnt_r <= #TCQ 'b0;
end else if ((prbs_state_r == PRBS_NEXT_DQS) && (prbs_state_r1 != PRBS_NEXT_DQS)) begin
prbs_final_dqs_tap_cnt_r[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ prbs_dqs_tap_cnt_r;
end
end
//*****************************************************************
always @(posedge clk) begin
prbs_state_r1 <= #TCQ prbs_state_r;
prbs_rdlvl_start_r <= #TCQ prbs_rdlvl_start;
end
// Wait counter for wait states
always @(posedge clk)
if ((prbs_state_r == PRBS_NEW_DQS_WAIT) ||
(prbs_state_r == PRBS_INC_DQS_WAIT) ||
(prbs_state_r == PRBS_DEC_DQS_WAIT) ||
(prbs_state_r == FINE_PI_DEC_WAIT) ||
(prbs_state_r == FINE_PI_INC_WAIT) ||
(prbs_state_r == PRBS_NEW_DQS_PREWAIT))
wait_state_cnt_en_r <= #TCQ 1'b1;
else
wait_state_cnt_en_r <= #TCQ 1'b0;
always @(posedge clk)
if (!wait_state_cnt_en_r) begin
wait_state_cnt_r <= #TCQ 'b0;
cnt_wait_state <= #TCQ 1'b0;
end else begin
if (wait_state_cnt_r < 'd15) begin
wait_state_cnt_r <= #TCQ wait_state_cnt_r + 1;
cnt_wait_state <= #TCQ 1'b0;
end else begin
// Need to reset to 0 to handle the case when there are two
// different WAIT states back-to-back
wait_state_cnt_r <= #TCQ 'b0;
cnt_wait_state <= #TCQ 1'b1;
end
end
always @ (posedge clk)
err_chk_invalid <= #TCQ (wait_state_cnt_r < 'd14);
//*****************************************************************
// compare error checking per-bit
//****************************************************************
generate
genvar pb_i;
if (nCK_PER_CLK == 4) begin: cmp_err_pb_4to1
for(pb_i=0 ; pb_i<DRAM_WIDTH; pb_i=pb_i+1) begin
always @ (posedge clk) begin
//prevent error check during PI inc/dec and wait
if (rst || new_cnt_dqs_r || (prbs_state_r == FINE_PI_INC) || (prbs_state_r == FINE_PI_DEC) ||
(err_chk_invalid && ((prbs_state_r == FINE_PI_DEC_WAIT)||(prbs_state_r == FINE_PI_INC_WAIT))))
compare_err_pb[pb_i] <= #TCQ 1'b0;
else if (rd_valid_r2)
compare_err_pb[pb_i] <= #TCQ (mux_rd_rise0_r3[pb_i] != compare_data_rise0_r1[pb_i]) |
(mux_rd_fall0_r3[pb_i] != compare_data_fall0_r1[pb_i]) |
(mux_rd_rise1_r3[pb_i] != compare_data_rise1_r1[pb_i]) |
(mux_rd_fall1_r3[pb_i] != compare_data_fall1_r1[pb_i]) |
(mux_rd_rise2_r3[pb_i] != compare_data_rise2_r1[pb_i]) |
(mux_rd_fall2_r3[pb_i] != compare_data_fall2_r1[pb_i]) |
(mux_rd_rise3_r3[pb_i] != compare_data_rise3_r1[pb_i]) |
(mux_rd_fall3_r3[pb_i] != compare_data_fall3_r1[pb_i]) ;
end //always
end //for
end else begin: cmp_err_pb_2to1
for(pb_i=0 ; pb_i<DRAM_WIDTH; pb_i=pb_i+1) begin
always @ (posedge clk) begin
if (rst || new_cnt_dqs_r || (prbs_state_r == FINE_PI_INC) || (prbs_state_r == FINE_PI_DEC) ||
(err_chk_invalid && ((prbs_state_r == FINE_PI_DEC_WAIT)||(prbs_state_r == FINE_PI_INC_WAIT))))
compare_err_pb[pb_i] <= #TCQ 1'b0;
else if (rd_valid_r2)
compare_err_pb[pb_i] <= #TCQ (mux_rd_rise0_r3[pb_i] != compare_data_rise0_r1[pb_i]) |
(mux_rd_fall0_r3[pb_i] != compare_data_fall0_r1[pb_i]) |
(mux_rd_rise1_r3[pb_i] != compare_data_rise1_r1[pb_i]) |
(mux_rd_fall1_r3[pb_i] != compare_data_fall1_r1[pb_i]) ;
end //always
end //for
end //if
endgenerate
//checking all bit has error
always @ (posedge clk) begin
if(rst || new_cnt_dqs_r) begin
compare_err_pb_and <= #TCQ 1'b0;
end else begin
compare_err_pb_and <= #TCQ &compare_err_pb;
end
end
//generate stick error bit - left/right edge
generate
genvar pb_r;
for(pb_r=0; pb_r<DRAM_WIDTH; pb_r=pb_r+1) begin
always @ (posedge clk) begin
if((prbs_state_r == FINE_PI_INC) | (prbs_state_r == FINE_PI_DEC) |
(~cnt_wait_state && ((prbs_state_r == FINE_PI_INC_WAIT)|(prbs_state_r == FINE_PI_DEC_WAIT))))
compare_err_pb_latch_r[pb_r] <= #TCQ 1'b0;
else
compare_err_pb_latch_r[pb_r] <= #TCQ compare_err_pb[pb_r]? 1'b1:compare_err_pb_latch_r[pb_r];
end
end
endgenerate
//in stage 0, if left edge found, update ref_bit (one hot)
always @ (posedge clk) begin
if (rst | (prbs_state_r == PRBS_NEW_DQS_WAIT)) begin
ref_bit_per_bit <= #TCQ 'd0;
end else if ((prbs_state_r == FINE_PI_INC) && (stage_cnt=='b0)) begin
if(|left_edge_updated) ref_bit_per_bit <= #TCQ left_edge_updated;
end
end
//ref bit with samllest right edge
//if bit 1 and 3 are set to ref_bit_per_bit but bit 1 has smaller right edge, bit is selected as ref_bit
always @ (posedge clk) begin
if(rst | (prbs_state_r == PRBS_NEW_DQS_WAIT)) begin
bit_cnt <= #TCQ 'd0;
ref_right_edge <= #TCQ 6'h3f;
ref_bit <= #TCQ 'd0;
end else if ((prbs_state_r == FINE_CALC_TAPS_WAIT) && (stage_cnt == 'b0) && (bit_cnt < DRAM_WIDTH)) begin
bit_cnt <= #TCQ bit_cnt +'b1;
if ((ref_bit_per_bit[bit_cnt]==1'b1) && (right_edge_pb[bit_cnt*6+:6]<= ref_right_edge)) begin
ref_bit <= #TCQ bit_cnt;
ref_right_edge <= #TCQ right_edge_pb[bit_cnt*6+:6];
end
end
end
//pipe lining for reference bit left/right edge
always @ (posedge clk) begin
left_edge_ref <= #TCQ left_edge_pb[ref_bit*6+:6];
right_edge_ref <= #TCQ right_edge_pb[ref_bit*6+:6];
end
//left_edge/right_edge/left_loss/right_gain update
generate
genvar eg;
for(eg=0; eg<DRAM_WIDTH; eg = eg+1) begin
always @ (posedge clk) begin
if(rst | (prbs_state_r == PRBS_NEW_DQS_WAIT)) begin
match_flag_pb[eg*5+:5] <= #TCQ 5'h1f;
left_edge_pb[eg*6+:6] <= #TCQ 'b0;
right_edge_pb[eg*6+:6] <= #TCQ 6'h3f;
left_edge_found_pb[eg] <= #TCQ 1'b0;
right_edge_found_pb[eg] <= #TCQ 1'b0;
left_loss_pb[eg*6+:6] <= #TCQ 'b0;
right_gain_pb[eg*6+:6] <= #TCQ 'b0;
left_edge_updated[eg] <= #TCQ 'b0;
end else begin
if((prbs_state_r == FINE_PAT_COMPARE_PER_BIT) && (num_samples_done_r || compare_err_pb_and)) begin
//left edge is updated when match flag becomes 100000 (1 fail , 5 success)
if(match_flag_pb[eg*5+:5]==5'b10000 && compare_err_pb_latch_r[eg]==0) begin
left_edge_pb[eg*6+:6] <= #TCQ prbs_dqs_tap_cnt_r-4;
left_edge_found_pb[eg] <= #TCQ 1'b1; //used for update largest_left_edge
left_edge_updated[eg] <= #TCQ 1'b1;
//check the loss of bit - update only for left edge found
if(~left_edge_found_pb[eg])
left_loss_pb[eg*6+:6] <= #TCQ (left_edge_ref > prbs_dqs_tap_cnt_r - 4)? 'd0
: prbs_dqs_tap_cnt_r-4-left_edge_ref;
//right edge is updated when match flag becomes 000001 (5 success, 1 fail)
end else if (match_flag_pb[eg*5+:5]==5'b00000 && compare_err_pb_latch_r[eg]) begin
right_edge_pb[eg*6+:6] <= #TCQ prbs_dqs_tap_cnt_r-1;
right_edge_found_pb[eg] <= #TCQ 1'b1;
//check the gain of bit - update only for right edge found
if(~right_edge_found_pb[eg])
right_gain_pb[eg*6+:6] <= #TCQ (right_edge_ref > prbs_dqs_tap_cnt_r-1)?
((right_edge_pb[eg*6 +:6] > prbs_dqs_tap_cnt_r-1)? 0: prbs_dqs_tap_cnt_r-1- right_edge_pb[eg*6+:6]):
((right_edge_pb[eg*6+:6] > right_edge_ref)? 0 : right_edge_ref - right_edge_pb[eg*6+:6]);
//no right edge found
end else if (prbs_dqs_tap_cnt_r == 6'h3f && ~right_edge_found_pb[eg]) begin
right_edge_pb[eg*6+:6] <= #TCQ 6'h3f;
right_edge_found_pb[eg] <= #TCQ 1'b1;
//right edge at 63. gain = max(0, ref_bit_right_tap - prev_right_edge)
right_gain_pb[eg*6+:6] <= #TCQ (right_edge_ref > right_edge_pb[eg*6+:6])?
(right_edge_ref - right_edge_pb[eg*6+:6]) : 0;
end
//update match flag - shift and update
match_flag_pb[eg*5+:5] <= #TCQ {match_flag_pb[(eg*5)+:4],compare_err_pb_latch_r[eg]};
end else if (prbs_state_r == FINE_PI_DEC) begin
left_edge_found_pb[eg] <= #TCQ 1'b0;
right_edge_found_pb[eg] <= #TCQ 1'b0;
left_loss_pb[eg*6+:6] <= #TCQ 'b0;
right_gain_pb[eg*6+:6] <= #TCQ 'b0;
match_flag_pb[eg*5+:5] <= #TCQ 5'h1f; //new fix
end else if (prbs_state_r == FINE_PI_INC) begin
left_edge_updated[eg] <= #TCQ 'b0; //used only for update largest ref_bit and largest_left_edge
end
end
end //always
end //for
endgenerate
//update fine_delay according to loss/gain value per bit
generate
genvar f_pb;
for(f_pb=0; f_pb<DRAM_WIDTH; f_pb=f_pb+1) begin
always @ (posedge clk) begin
if(rst | prbs_state_r == PRBS_NEW_DQS_WAIT ) begin
fine_delay_incdec_pb[f_pb] <= #TCQ 1'b0;
end else if((prbs_state_r == FINE_CALC_TAPS_WAIT) && (bit_cnt == DRAM_WIDTH)) begin
if(stage_cnt == 'd0) fine_delay_incdec_pb[f_pb] <= #TCQ (f_pb==ref_bit)? 1'b0:1'b1; //only for initial stage
else if(stage_cnt == 'd1) fine_delay_incdec_pb[f_pb] <= #TCQ (right_gain_pb[f_pb*6+:6]>left_loss_pb[f_pb*6+:6])?1'b1:1'b0;
end
end
end
endgenerate
//fine inc stage (stage cnt 0,1,2), fine dec stage (stage cnt 3)
always @ (posedge clk) begin
if (rst)
fine_inc_stage <= #TCQ 'b1;
else
fine_inc_stage <= #TCQ (stage_cnt!='d3);
end
//*****************************************************************
always @(posedge clk)
if (rst) begin
prbs_dqs_cnt_r <= #TCQ 'b0;
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
prbs_prech_req_r <= #TCQ 1'b0;
prbs_state_r <= #TCQ PRBS_IDLE;
prbs_found_1st_edge_r <= #TCQ 1'b0;
prbs_found_2nd_edge_r <= #TCQ 1'b0;
prbs_1st_edge_taps_r <= #TCQ 6'bxxxxxx;
prbs_inc_tap_cnt <= #TCQ 'b0;
prbs_dec_tap_cnt <= #TCQ 'b0;
new_cnt_dqs_r <= #TCQ 1'b0;
if (SIM_CAL_OPTION == "FAST_CAL")
prbs_rdlvl_done <= #TCQ 1'b1;
else
prbs_rdlvl_done <= #TCQ 1'b0;
prbs_2nd_edge_taps_r <= #TCQ 6'bxxxxxx;
prbs_last_byte_done <= #TCQ 1'b0;
prbs_tap_mod <= #TCQ 'd0;
reset_rd_addr <= #TCQ 'b0;
read_pause <= #TCQ 'b0;
fine_pi_dec_cnt <= #TCQ 'b0;
match_flag_and <= #TCQ 5'h1f;
stage_cnt <= #TCQ 2'b00;
right_edge_found <= #TCQ 1'b0;
largest_left_edge <= #TCQ 6'b000000;
smallest_right_edge <= #TCQ 6'b111111;
num_samples_done_ind <= #TCQ 'b0;
fine_delay_sel <= #TCQ 'b0;
fine_dly_error <= #TCQ 'b0;
end else begin
case (prbs_state_r)
PRBS_IDLE: begin
prbs_last_byte_done <= #TCQ 1'b0;
prbs_prech_req_r <= #TCQ 1'b0;
if (prbs_rdlvl_start && ~prbs_rdlvl_start_r) begin
if (SIM_CAL_OPTION == "SKIP_CAL" || SIM_CAL_OPTION == "FAST_CAL") begin
prbs_state_r <= #TCQ PRBS_DONE;
reset_rd_addr <= #TCQ 1'b1;
end else begin
new_cnt_dqs_r <= #TCQ 1'b1;
prbs_state_r <= #TCQ PRBS_NEW_DQS_WAIT;
fine_pi_dec_cnt <= #TCQ pi_counter_read_val;//.
end
end
end
// Wait for the new DQS group to change
// also gives time for the read data IN_FIFO to
// output the updated data for the new DQS group
PRBS_NEW_DQS_WAIT: begin
reset_rd_addr <= #TCQ 'b0;
prbs_last_byte_done <= #TCQ 1'b0;
prbs_prech_req_r <= #TCQ 1'b0;
//fine_inc_stage <= #TCQ 1'b1;
stage_cnt <= #TCQ 2'b0;
match_flag_and <= #TCQ 5'h1f;
if (cnt_wait_state) begin
new_cnt_dqs_r <= #TCQ 1'b0;
prbs_state_r <= #TCQ fine_calib? FINE_PI_DEC:PRBS_PAT_COMPARE;
end
end
// Check for presence of data eye edge. During this state, we
// sample the read data multiple times, and look for changes
// in the read data, specifically:
// 1. A change in the read data compared with the value of
// read data from the previous delay tap. This indicates
// that the most recent tap delay increment has moved us
// into either a new window, or moved/kept us in the
// transition/jitter region between windows. Note that this
// condition only needs to be checked for once, and for
// logistical purposes, we check this soon after entering
// this state (see comment in PRBS_PAT_COMPARE below for
// why this is done)
// 2. A change in the read data while we are in this state
// (i.e. in the absence of a tap delay increment). This
// indicates that we're close enough to a window edge that
// jitter will cause the read data to change even in the
// absence of a tap delay change
PRBS_PAT_COMPARE: begin
// Continue to sample read data and look for edges until the
// appropriate time interval (shorter for simulation-only,
// much, much longer for actual h/w) has elapsed
if (num_samples_done_r || compare_err) begin
if (prbs_dqs_tap_limit_r)
// Only one edge detected and ran out of taps since only one
// bit time worth of taps available for window detection. This
// can happen if at tap 0 DQS is in previous window which results
// in only left edge being detected. Or at tap 0 DQS is in the
// current window resulting in only right edge being detected.
// Depending on the frequency this case can also happen if at
// tap 0 DQS is in the left noise region resulting in only left
// edge being detected.
prbs_state_r <= #TCQ PRBS_CALC_TAPS_PRE;
else if (compare_err || (prbs_dqs_tap_cnt_r == 'd0)) begin
// Sticky bit - asserted after we encounter an edge, although
// the current edge may not be considered the "first edge" this
// just means we found at least one edge
prbs_found_1st_edge_r <= #TCQ 1'b1;
// Both edges of data valid window found:
// If we've found a second edge after a region of stability
// then we must have just passed the second ("right" edge of
// the window. Record this second_edge_taps = current tap-1,
// because we're one past the actual second edge tap, where
// the edge taps represent the extremes of the data valid
// window (i.e. smallest & largest taps where data still valid
if (prbs_found_1st_edge_r) begin
prbs_found_2nd_edge_r <= #TCQ 1'b1;
prbs_2nd_edge_taps_r <= #TCQ prbs_dqs_tap_cnt_r - 1;
prbs_state_r <= #TCQ PRBS_CALC_TAPS_PRE;
end else begin
// Otherwise, an edge was found (just not the "second" edge)
// Assuming DQS is in the correct window at tap 0 of Phaser IN
// fine tap. The first edge found is the right edge of the valid
// window and is the beginning of the jitter region hence done!
if (compare_err)
prbs_1st_edge_taps_r <= #TCQ prbs_dqs_tap_cnt_r + 1;
else
prbs_1st_edge_taps_r <= #TCQ 'd0;
prbs_inc_tap_cnt <= #TCQ rdlvl_cpt_tap_cnt - prbs_dqs_tap_cnt_r;
prbs_state_r <= #TCQ PRBS_INC_DQS;
end
end else begin
// Otherwise, if we haven't found an edge....
// If we still have taps left to use, then keep incrementing
if (prbs_found_1st_edge_r)
prbs_state_r <= #TCQ PRBS_INC_DQS;
else
prbs_state_r <= #TCQ PRBS_DEC_DQS;
end
end
end
// Increment Phaser_IN delay for DQS
PRBS_INC_DQS: begin
prbs_state_r <= #TCQ PRBS_INC_DQS_WAIT;
if (prbs_inc_tap_cnt > 'd0)
prbs_inc_tap_cnt <= #TCQ prbs_inc_tap_cnt - 1;
if (~prbs_dqs_tap_limit_r) begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b1;
end
end
// Wait for Phaser_In to settle, before checking again for an edge
PRBS_INC_DQS_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if (cnt_wait_state) begin
if (prbs_inc_tap_cnt > 'd0)
prbs_state_r <= #TCQ PRBS_INC_DQS;
else
prbs_state_r <= #TCQ PRBS_PAT_COMPARE;
end
end
// Calculate final value of Phaser_IN taps. At this point, one or both
// edges of data eye have been found, and/or all taps have been
// exhausted looking for the edges
// NOTE: The amount to be decrement by is calculated, not the
// absolute setting for DQS.
// CENTER compensation with shift by 1
PRBS_CALC_TAPS: begin
if (center_comp) begin
prbs_dec_tap_cnt <= #TCQ (dec_cnt[5] & dec_cnt[0])? 'd32: dec_cnt + pi_adj;
fine_dly_error <= #TCQ (dec_cnt[5] & dec_cnt[0])? 1'b1: fine_dly_error; //sticky bit
read_pause <= #TCQ 'b1;
prbs_state_r <= #TCQ PRBS_DEC_DQS;
end else begin //No center compensation
if (prbs_found_2nd_edge_r && prbs_found_1st_edge_r)
// Both edges detected
prbs_dec_tap_cnt
<= #TCQ ((prbs_2nd_edge_taps_r -
prbs_1st_edge_taps_r)>>1) + 1 + pi_adj;
else if (~prbs_found_2nd_edge_r && prbs_found_1st_edge_r)
// Only left edge detected
prbs_dec_tap_cnt
<= #TCQ ((prbs_dqs_tap_cnt_r - prbs_1st_edge_taps_r)>>1) + pi_adj;
else
// No edges detected
prbs_dec_tap_cnt
<= #TCQ (prbs_dqs_tap_cnt_r>>1) + pi_adj;
// Now use the value we just calculated to decrement CPT taps
// to the desired calibration point
read_pause <= #TCQ 'b1;
prbs_state_r <= #TCQ PRBS_DEC_DQS;
end
end
// decrement capture clock for final adjustment - center
// capture clock in middle of data eye. This adjustment will occur
// only when both the edges are found usign CPT taps. Must do this
// incrementally to avoid clock glitching (since CPT drives clock
// divider within each ISERDES)
PRBS_DEC_DQS: begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b0;
// once adjustment is complete, we're done with calibration for
// this DQS, repeat for next DQS
if (prbs_dec_tap_cnt > 'd0)
prbs_dec_tap_cnt <= #TCQ prbs_dec_tap_cnt - 1;
if (prbs_dec_tap_cnt == 6'b000001)
prbs_state_r <= #TCQ PRBS_NEXT_DQS;
else
prbs_state_r <= #TCQ PRBS_DEC_DQS_WAIT;
end
PRBS_DEC_DQS_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if (cnt_wait_state) begin
if (prbs_dec_tap_cnt > 'd0)
prbs_state_r <= #TCQ PRBS_DEC_DQS;
else
prbs_state_r <= #TCQ PRBS_PAT_COMPARE;
end
end
// Determine whether we're done, or have more DQS's to calibrate
// Also request precharge after every byte, as appropriate
PRBS_NEXT_DQS: begin
read_pause <= #TCQ 'b0;
reset_rd_addr <= #TCQ 'b1;
prbs_prech_req_r <= #TCQ 1'b1;
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
// Prepare for another iteration with next DQS group
prbs_found_1st_edge_r <= #TCQ 1'b0;
prbs_found_2nd_edge_r <= #TCQ 1'b0;
prbs_1st_edge_taps_r <= #TCQ 'd0;
prbs_2nd_edge_taps_r <= #TCQ 'd0;
largest_left_edge <= #TCQ 6'b000000;
smallest_right_edge <= #TCQ 6'b111111;
if (prbs_dqs_cnt_r >= DQS_WIDTH-1) begin
prbs_last_byte_done <= #TCQ 1'b1;
end
// Wait until precharge that occurs in between calibration of
// DQS groups is finished
if (prech_done) begin
prbs_prech_req_r <= #TCQ 1'b0;
if (prbs_dqs_cnt_r >= DQS_WIDTH-1) begin
// All DQS groups done
prbs_state_r <= #TCQ PRBS_DONE;
end else begin
// Process next DQS group
new_cnt_dqs_r <= #TCQ 1'b1;
//fine_pi_dec_cnt <= #TCQ pi_counter_read_val;//.
prbs_dqs_cnt_r <= #TCQ prbs_dqs_cnt_r + 1;
prbs_state_r <= #TCQ PRBS_NEW_DQS_PREWAIT;
end
end
end
PRBS_NEW_DQS_PREWAIT: begin
if (cnt_wait_state) begin
prbs_state_r <= #TCQ PRBS_NEW_DQS_WAIT;
fine_pi_dec_cnt <= #TCQ pi_counter_read_val;//.
end
end
PRBS_CALC_TAPS_PRE:
begin
if(num_samples_done_r) begin
prbs_state_r <= #TCQ fine_calib? PRBS_NEXT_DQS:PRBS_CALC_TAPS_WAIT;
if(center_comp && ~fine_calib) begin
if(prbs_found_1st_edge_r) largest_left_edge <= #TCQ prbs_1st_edge_taps_r;
else largest_left_edge <= #TCQ 6'd0;
if(prbs_found_2nd_edge_r) smallest_right_edge <= #TCQ prbs_2nd_edge_taps_r;
else smallest_right_edge <= #TCQ 6'd63;
end
end
end
//wait for center compensation
PRBS_CALC_TAPS_WAIT:
begin
prbs_state_r <= #TCQ PRBS_CALC_TAPS;
end
//if it is fine_inc stage (first/second stage): dec to 0
//if it is fine_dec stage (third stage): dec to center
FINE_PI_DEC: begin
fine_delay_sel <= #TCQ 'b0;
if(fine_pi_dec_cnt > 0) begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b0;
fine_pi_dec_cnt <= #TCQ fine_pi_dec_cnt - 'd1;
end
prbs_state_r <= #TCQ FINE_PI_DEC_WAIT;
end
//wait for phaser_in tap decrement.
//if first/second stage is done, goes to FINE_PI_INC
//if last stage is done, goes to NEXT_DQS
FINE_PI_DEC_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if(cnt_wait_state) begin
if(fine_pi_dec_cnt >0)
prbs_state_r <= #TCQ FINE_PI_DEC;
else
if(fine_inc_stage)
// prbs_state_r <= #TCQ FINE_PI_INC; //for temp change
prbs_state_r <= #TCQ FINE_PAT_COMPARE_PER_BIT; //start from pi tap "0"
else
prbs_state_r <= #TCQ PRBS_CALC_TAPS_PRE; //finish the process and go to the next DQS
end
end
FINE_PI_INC: begin
if(|left_edge_updated) largest_left_edge <= #TCQ prbs_dqs_tap_cnt_r-4;
if(|right_edge_found_pb && ~right_edge_found) begin
smallest_right_edge <= #TCQ prbs_dqs_tap_cnt_r -1 ;
right_edge_found <= #TCQ 'b1;
end
//left_edge_found_pb <= #TCQ {DRAM_WIDTH{1'b0}};
prbs_state_r <= #TCQ FINE_PI_INC_WAIT;
if(~prbs_dqs_tap_limit_r) begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b1;
end
end
//wait for phase_in tap increment
//need to do pattern compare for every bit
FINE_PI_INC_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if (cnt_wait_state) begin
prbs_state_r <= #TCQ FINE_PAT_COMPARE_PER_BIT;
end
end
//compare per bit data and update flags,left/right edge
FINE_PAT_COMPARE_PER_BIT: begin
if(num_samples_done_r || compare_err_pb_and) begin
//update and_flag - shift and add
match_flag_and <= #TCQ {match_flag_and[3:0],compare_err_pb_and};
//if it is consecutive 5 passing taps followed by fail or tap limit (finish the search)
//don't go to fine_FINE_CALC_TAPS to prevent to skip whole stage
//Or if all right edge are found
if((match_flag_and == 5'b00000 && compare_err_pb_and && (prbs_dqs_tap_cnt_r > 5)) || prbs_dqs_tap_limit_r || (&right_edge_found_pb)) begin
prbs_state_r <= #TCQ FINE_CALC_TAPS;
//if all right edge are alined (all right edge found at the same time), update smallest right edge in here
//doesnt need to set right_edge_found to 1 since it is not used after this stage
if(!right_edge_found) smallest_right_edge <= #TCQ prbs_dqs_tap_cnt_r-1;
end else begin
prbs_state_r <= #TCQ FINE_PI_INC; //keep increase until all fail
end
num_samples_done_ind <= num_samples_done_r;
end
end
//for fine_inc stage, inc all fine delay
//for fine_dec stage, apply dec fine delay for specific bits (by calculating the loss/gain)
// put phaser_in taps to the center
FINE_CALC_TAPS: begin
if(num_samples_done_ind || num_samples_done_r) begin
num_samples_done_ind <= #TCQ 'b0; //indicate num_samples_done_r is set
right_edge_found <= #TCQ 1'b0; //reset right edge found
match_flag_and <= #TCQ 5'h1f; //reset match flag for all bits
prbs_state_r <= #TCQ FINE_CALC_TAPS_WAIT;
end
end
FINE_CALC_TAPS_WAIT: begin //wait for ROM read out
if(stage_cnt == 'd2) begin //last stage : back to center
if(center_comp) begin
fine_pi_dec_cnt <= #TCQ (dec_cnt[5]&dec_cnt[0])? 'd32: prbs_dqs_tap_cnt_r - smallest_right_edge + dec_cnt - 1 + pi_adj ; //going to the center value & shift by 1
fine_dly_error <= #TCQ (dec_cnt[5]&dec_cnt[0]) ? 1'b1: fine_dly_error;
end else begin
fine_pi_dec_cnt <= #TCQ prbs_dqs_tap_cnt_r - center_calc[6:1] - center_calc[0] + pi_adj; //going to the center value & shift left by 1
fine_dly_error <= #TCQ 1'b0;
end
end else begin
fine_pi_dec_cnt <= #TCQ prbs_dqs_tap_cnt_r;
end
if (bit_cnt == DRAM_WIDTH) begin
fine_delay_sel <= #TCQ 'b1;
stage_cnt <= #TCQ stage_cnt + 1;
prbs_state_r <= #TCQ FINE_PI_DEC;
end
end
// Done with this stage of calibration
PRBS_DONE: begin
prbs_prech_req_r <= #TCQ 1'b0;
prbs_last_byte_done <= #TCQ 1'b0;
prbs_rdlvl_done <= #TCQ 1'b1;
reset_rd_addr <= #TCQ 1'b0;
end
endcase
end
//ROM generation for dec counter
always @ (largest_left_edge or smallest_right_edge) begin
case ({largest_left_edge, smallest_right_edge})
12'd0 : mem_out_dec = 6'b111111;
12'd1 : mem_out_dec = 6'b111111;
12'd2 : mem_out_dec = 6'b111111;
12'd3 : mem_out_dec = 6'b111111;
12'd4 : mem_out_dec = 6'b111111;
12'd5 : mem_out_dec = 6'b111111;
12'd6 : mem_out_dec = 6'b000100;
12'd7 : mem_out_dec = 6'b000101;
12'd8 : mem_out_dec = 6'b000101;
12'd9 : mem_out_dec = 6'b000110;
12'd10 : mem_out_dec = 6'b000110;
12'd11 : mem_out_dec = 6'b000111;
12'd12 : mem_out_dec = 6'b001000;
12'd13 : mem_out_dec = 6'b001000;
12'd14 : mem_out_dec = 6'b001001;
12'd15 : mem_out_dec = 6'b001010;
12'd16 : mem_out_dec = 6'b001010;
12'd17 : mem_out_dec = 6'b001011;
12'd18 : mem_out_dec = 6'b001011;
12'd19 : mem_out_dec = 6'b001100;
12'd20 : mem_out_dec = 6'b001100;
12'd21 : mem_out_dec = 6'b001100;
12'd22 : mem_out_dec = 6'b001100;
12'd23 : mem_out_dec = 6'b001101;
12'd24 : mem_out_dec = 6'b001100;
12'd25 : mem_out_dec = 6'b001100;
12'd26 : mem_out_dec = 6'b001101;
12'd27 : mem_out_dec = 6'b001110;
12'd28 : mem_out_dec = 6'b001110;
12'd29 : mem_out_dec = 6'b001111;
12'd30 : mem_out_dec = 6'b010000;
12'd31 : mem_out_dec = 6'b010001;
12'd32 : mem_out_dec = 6'b010001;
12'd33 : mem_out_dec = 6'b010010;
12'd34 : mem_out_dec = 6'b010010;
12'd35 : mem_out_dec = 6'b010010;
12'd36 : mem_out_dec = 6'b010011;
12'd37 : mem_out_dec = 6'b010100;
12'd38 : mem_out_dec = 6'b010100;
12'd39 : mem_out_dec = 6'b010101;
12'd40 : mem_out_dec = 6'b010101;
12'd41 : mem_out_dec = 6'b010110;
12'd42 : mem_out_dec = 6'b010110;
12'd43 : mem_out_dec = 6'b010111;
12'd44 : mem_out_dec = 6'b011000;
12'd45 : mem_out_dec = 6'b011001;
12'd46 : mem_out_dec = 6'b011001;
12'd47 : mem_out_dec = 6'b011010;
12'd48 : mem_out_dec = 6'b011010;
12'd49 : mem_out_dec = 6'b011011;
12'd50 : mem_out_dec = 6'b011011;
12'd51 : mem_out_dec = 6'b011100;
12'd52 : mem_out_dec = 6'b011100;
12'd53 : mem_out_dec = 6'b011100;
12'd54 : mem_out_dec = 6'b011100;
12'd55 : mem_out_dec = 6'b011100;
12'd56 : mem_out_dec = 6'b011100;
12'd57 : mem_out_dec = 6'b011100;
12'd58 : mem_out_dec = 6'b011100;
12'd59 : mem_out_dec = 6'b011101;
12'd60 : mem_out_dec = 6'b011110;
12'd61 : mem_out_dec = 6'b011111;
12'd62 : mem_out_dec = 6'b100000;
12'd63 : mem_out_dec = 6'b100000;
12'd64 : mem_out_dec = 6'b111111;
12'd65 : mem_out_dec = 6'b111111;
12'd66 : mem_out_dec = 6'b111111;
12'd67 : mem_out_dec = 6'b111111;
12'd68 : mem_out_dec = 6'b111111;
12'd69 : mem_out_dec = 6'b111111;
12'd70 : mem_out_dec = 6'b111111;
12'd71 : mem_out_dec = 6'b000100;
12'd72 : mem_out_dec = 6'b000100;
12'd73 : mem_out_dec = 6'b000101;
12'd74 : mem_out_dec = 6'b000110;
12'd75 : mem_out_dec = 6'b000111;
12'd76 : mem_out_dec = 6'b000111;
12'd77 : mem_out_dec = 6'b001000;
12'd78 : mem_out_dec = 6'b001001;
12'd79 : mem_out_dec = 6'b001001;
12'd80 : mem_out_dec = 6'b001010;
12'd81 : mem_out_dec = 6'b001010;
12'd82 : mem_out_dec = 6'b001011;
12'd83 : mem_out_dec = 6'b001011;
12'd84 : mem_out_dec = 6'b001011;
12'd85 : mem_out_dec = 6'b001011;
12'd86 : mem_out_dec = 6'b001011;
12'd87 : mem_out_dec = 6'b001100;
12'd88 : mem_out_dec = 6'b001011;
12'd89 : mem_out_dec = 6'b001100;
12'd90 : mem_out_dec = 6'b001100;
12'd91 : mem_out_dec = 6'b001101;
12'd92 : mem_out_dec = 6'b001110;
12'd93 : mem_out_dec = 6'b001111;
12'd94 : mem_out_dec = 6'b001111;
12'd95 : mem_out_dec = 6'b010000;
12'd96 : mem_out_dec = 6'b010001;
12'd97 : mem_out_dec = 6'b010001;
12'd98 : mem_out_dec = 6'b010010;
12'd99 : mem_out_dec = 6'b010010;
12'd100 : mem_out_dec = 6'b010011;
12'd101 : mem_out_dec = 6'b010011;
12'd102 : mem_out_dec = 6'b010100;
12'd103 : mem_out_dec = 6'b010100;
12'd104 : mem_out_dec = 6'b010100;
12'd105 : mem_out_dec = 6'b010101;
12'd106 : mem_out_dec = 6'b010110;
12'd107 : mem_out_dec = 6'b010111;
12'd108 : mem_out_dec = 6'b010111;
12'd109 : mem_out_dec = 6'b011000;
12'd110 : mem_out_dec = 6'b011001;
12'd111 : mem_out_dec = 6'b011001;
12'd112 : mem_out_dec = 6'b011010;
12'd113 : mem_out_dec = 6'b011010;
12'd114 : mem_out_dec = 6'b011011;
12'd115 : mem_out_dec = 6'b011011;
12'd116 : mem_out_dec = 6'b011011;
12'd117 : mem_out_dec = 6'b011011;
12'd118 : mem_out_dec = 6'b011011;
12'd119 : mem_out_dec = 6'b011011;
12'd120 : mem_out_dec = 6'b011011;
12'd121 : mem_out_dec = 6'b011011;
12'd122 : mem_out_dec = 6'b011100;
12'd123 : mem_out_dec = 6'b011101;
12'd124 : mem_out_dec = 6'b011110;
12'd125 : mem_out_dec = 6'b011110;
12'd126 : mem_out_dec = 6'b011111;
12'd127 : mem_out_dec = 6'b100000;
12'd128 : mem_out_dec = 6'b111111;
12'd129 : mem_out_dec = 6'b111111;
12'd130 : mem_out_dec = 6'b111111;
12'd131 : mem_out_dec = 6'b111111;
12'd132 : mem_out_dec = 6'b111111;
12'd133 : mem_out_dec = 6'b111111;
12'd134 : mem_out_dec = 6'b111111;
12'd135 : mem_out_dec = 6'b111111;
12'd136 : mem_out_dec = 6'b000100;
12'd137 : mem_out_dec = 6'b000101;
12'd138 : mem_out_dec = 6'b000101;
12'd139 : mem_out_dec = 6'b000110;
12'd140 : mem_out_dec = 6'b000110;
12'd141 : mem_out_dec = 6'b000111;
12'd142 : mem_out_dec = 6'b001000;
12'd143 : mem_out_dec = 6'b001001;
12'd144 : mem_out_dec = 6'b001001;
12'd145 : mem_out_dec = 6'b001010;
12'd146 : mem_out_dec = 6'b001010;
12'd147 : mem_out_dec = 6'b001010;
12'd148 : mem_out_dec = 6'b001010;
12'd149 : mem_out_dec = 6'b001010;
12'd150 : mem_out_dec = 6'b001010;
12'd151 : mem_out_dec = 6'b001011;
12'd152 : mem_out_dec = 6'b001010;
12'd153 : mem_out_dec = 6'b001011;
12'd154 : mem_out_dec = 6'b001100;
12'd155 : mem_out_dec = 6'b001101;
12'd156 : mem_out_dec = 6'b001101;
12'd157 : mem_out_dec = 6'b001110;
12'd158 : mem_out_dec = 6'b001111;
12'd159 : mem_out_dec = 6'b010000;
12'd160 : mem_out_dec = 6'b010000;
12'd161 : mem_out_dec = 6'b010001;
12'd162 : mem_out_dec = 6'b010001;
12'd163 : mem_out_dec = 6'b010010;
12'd164 : mem_out_dec = 6'b010010;
12'd165 : mem_out_dec = 6'b010011;
12'd166 : mem_out_dec = 6'b010011;
12'd167 : mem_out_dec = 6'b010100;
12'd168 : mem_out_dec = 6'b010100;
12'd169 : mem_out_dec = 6'b010101;
12'd170 : mem_out_dec = 6'b010101;
12'd171 : mem_out_dec = 6'b010110;
12'd172 : mem_out_dec = 6'b010111;
12'd173 : mem_out_dec = 6'b010111;
12'd174 : mem_out_dec = 6'b011000;
12'd175 : mem_out_dec = 6'b011001;
12'd176 : mem_out_dec = 6'b011001;
12'd177 : mem_out_dec = 6'b011010;
12'd178 : mem_out_dec = 6'b011010;
12'd179 : mem_out_dec = 6'b011010;
12'd180 : mem_out_dec = 6'b011010;
12'd181 : mem_out_dec = 6'b011010;
12'd182 : mem_out_dec = 6'b011010;
12'd183 : mem_out_dec = 6'b011010;
12'd184 : mem_out_dec = 6'b011010;
12'd185 : mem_out_dec = 6'b011011;
12'd186 : mem_out_dec = 6'b011100;
12'd187 : mem_out_dec = 6'b011100;
12'd188 : mem_out_dec = 6'b011101;
12'd189 : mem_out_dec = 6'b011110;
12'd190 : mem_out_dec = 6'b011111;
12'd191 : mem_out_dec = 6'b100000;
12'd192 : mem_out_dec = 6'b111111;
12'd193 : mem_out_dec = 6'b111111;
12'd194 : mem_out_dec = 6'b111111;
12'd195 : mem_out_dec = 6'b111111;
12'd196 : mem_out_dec = 6'b111111;
12'd197 : mem_out_dec = 6'b111111;
12'd198 : mem_out_dec = 6'b111111;
12'd199 : mem_out_dec = 6'b111111;
12'd200 : mem_out_dec = 6'b111111;
12'd201 : mem_out_dec = 6'b000100;
12'd202 : mem_out_dec = 6'b000100;
12'd203 : mem_out_dec = 6'b000101;
12'd204 : mem_out_dec = 6'b000110;
12'd205 : mem_out_dec = 6'b000111;
12'd206 : mem_out_dec = 6'b001000;
12'd207 : mem_out_dec = 6'b001000;
12'd208 : mem_out_dec = 6'b001001;
12'd209 : mem_out_dec = 6'b001001;
12'd210 : mem_out_dec = 6'b001001;
12'd211 : mem_out_dec = 6'b001001;
12'd212 : mem_out_dec = 6'b001001;
12'd213 : mem_out_dec = 6'b001001;
12'd214 : mem_out_dec = 6'b001001;
12'd215 : mem_out_dec = 6'b001010;
12'd216 : mem_out_dec = 6'b001010;
12'd217 : mem_out_dec = 6'b001011;
12'd218 : mem_out_dec = 6'b001011;
12'd219 : mem_out_dec = 6'b001100;
12'd220 : mem_out_dec = 6'b001101;
12'd221 : mem_out_dec = 6'b001110;
12'd222 : mem_out_dec = 6'b001111;
12'd223 : mem_out_dec = 6'b001111;
12'd224 : mem_out_dec = 6'b010000;
12'd225 : mem_out_dec = 6'b010000;
12'd226 : mem_out_dec = 6'b010001;
12'd227 : mem_out_dec = 6'b010001;
12'd228 : mem_out_dec = 6'b010010;
12'd229 : mem_out_dec = 6'b010010;
12'd230 : mem_out_dec = 6'b010011;
12'd231 : mem_out_dec = 6'b010011;
12'd232 : mem_out_dec = 6'b010011;
12'd233 : mem_out_dec = 6'b010100;
12'd234 : mem_out_dec = 6'b010100;
12'd235 : mem_out_dec = 6'b010101;
12'd236 : mem_out_dec = 6'b010110;
12'd237 : mem_out_dec = 6'b010111;
12'd238 : mem_out_dec = 6'b011000;
12'd239 : mem_out_dec = 6'b011000;
12'd240 : mem_out_dec = 6'b011001;
12'd241 : mem_out_dec = 6'b011001;
12'd242 : mem_out_dec = 6'b011001;
12'd243 : mem_out_dec = 6'b011001;
12'd244 : mem_out_dec = 6'b011001;
12'd245 : mem_out_dec = 6'b011001;
12'd246 : mem_out_dec = 6'b011001;
12'd247 : mem_out_dec = 6'b011001;
12'd248 : mem_out_dec = 6'b011010;
12'd249 : mem_out_dec = 6'b011010;
12'd250 : mem_out_dec = 6'b011011;
12'd251 : mem_out_dec = 6'b011100;
12'd252 : mem_out_dec = 6'b011101;
12'd253 : mem_out_dec = 6'b011110;
12'd254 : mem_out_dec = 6'b011110;
12'd255 : mem_out_dec = 6'b011111;
12'd256 : mem_out_dec = 6'b111111;
12'd257 : mem_out_dec = 6'b111111;
12'd258 : mem_out_dec = 6'b111111;
12'd259 : mem_out_dec = 6'b111111;
12'd260 : mem_out_dec = 6'b111111;
12'd261 : mem_out_dec = 6'b111111;
12'd262 : mem_out_dec = 6'b111111;
12'd263 : mem_out_dec = 6'b111111;
12'd264 : mem_out_dec = 6'b111111;
12'd265 : mem_out_dec = 6'b111111;
12'd266 : mem_out_dec = 6'b000100;
12'd267 : mem_out_dec = 6'b000101;
12'd268 : mem_out_dec = 6'b000110;
12'd269 : mem_out_dec = 6'b000110;
12'd270 : mem_out_dec = 6'b000111;
12'd271 : mem_out_dec = 6'b001000;
12'd272 : mem_out_dec = 6'b001000;
12'd273 : mem_out_dec = 6'b001000;
12'd274 : mem_out_dec = 6'b001000;
12'd275 : mem_out_dec = 6'b001000;
12'd276 : mem_out_dec = 6'b001000;
12'd277 : mem_out_dec = 6'b001000;
12'd278 : mem_out_dec = 6'b001000;
12'd279 : mem_out_dec = 6'b001001;
12'd280 : mem_out_dec = 6'b001001;
12'd281 : mem_out_dec = 6'b001010;
12'd282 : mem_out_dec = 6'b001011;
12'd283 : mem_out_dec = 6'b001100;
12'd284 : mem_out_dec = 6'b001101;
12'd285 : mem_out_dec = 6'b001101;
12'd286 : mem_out_dec = 6'b001110;
12'd287 : mem_out_dec = 6'b001111;
12'd288 : mem_out_dec = 6'b001111;
12'd289 : mem_out_dec = 6'b010000;
12'd290 : mem_out_dec = 6'b010000;
12'd291 : mem_out_dec = 6'b010001;
12'd292 : mem_out_dec = 6'b010001;
12'd293 : mem_out_dec = 6'b010010;
12'd294 : mem_out_dec = 6'b010010;
12'd295 : mem_out_dec = 6'b010011;
12'd296 : mem_out_dec = 6'b010010;
12'd297 : mem_out_dec = 6'b010011;
12'd298 : mem_out_dec = 6'b010100;
12'd299 : mem_out_dec = 6'b010101;
12'd300 : mem_out_dec = 6'b010110;
12'd301 : mem_out_dec = 6'b010110;
12'd302 : mem_out_dec = 6'b010111;
12'd303 : mem_out_dec = 6'b011000;
12'd304 : mem_out_dec = 6'b011000;
12'd305 : mem_out_dec = 6'b011000;
12'd306 : mem_out_dec = 6'b011000;
12'd307 : mem_out_dec = 6'b011000;
12'd308 : mem_out_dec = 6'b011000;
12'd309 : mem_out_dec = 6'b011000;
12'd310 : mem_out_dec = 6'b011000;
12'd311 : mem_out_dec = 6'b011001;
12'd312 : mem_out_dec = 6'b011001;
12'd313 : mem_out_dec = 6'b011010;
12'd314 : mem_out_dec = 6'b011011;
12'd315 : mem_out_dec = 6'b011100;
12'd316 : mem_out_dec = 6'b011100;
12'd317 : mem_out_dec = 6'b011101;
12'd318 : mem_out_dec = 6'b011110;
12'd319 : mem_out_dec = 6'b011111;
12'd320 : mem_out_dec = 6'b111111;
12'd321 : mem_out_dec = 6'b111111;
12'd322 : mem_out_dec = 6'b111111;
12'd323 : mem_out_dec = 6'b111111;
12'd324 : mem_out_dec = 6'b111111;
12'd325 : mem_out_dec = 6'b111111;
12'd326 : mem_out_dec = 6'b111111;
12'd327 : mem_out_dec = 6'b111111;
12'd328 : mem_out_dec = 6'b111111;
12'd329 : mem_out_dec = 6'b111111;
12'd330 : mem_out_dec = 6'b111111;
12'd331 : mem_out_dec = 6'b000100;
12'd332 : mem_out_dec = 6'b000101;
12'd333 : mem_out_dec = 6'b000110;
12'd334 : mem_out_dec = 6'b000111;
12'd335 : mem_out_dec = 6'b001000;
12'd336 : mem_out_dec = 6'b000111;
12'd337 : mem_out_dec = 6'b000111;
12'd338 : mem_out_dec = 6'b000111;
12'd339 : mem_out_dec = 6'b000111;
12'd340 : mem_out_dec = 6'b000111;
12'd341 : mem_out_dec = 6'b000111;
12'd342 : mem_out_dec = 6'b001000;
12'd343 : mem_out_dec = 6'b001001;
12'd344 : mem_out_dec = 6'b001001;
12'd345 : mem_out_dec = 6'b001010;
12'd346 : mem_out_dec = 6'b001011;
12'd347 : mem_out_dec = 6'b001011;
12'd348 : mem_out_dec = 6'b001100;
12'd349 : mem_out_dec = 6'b001101;
12'd350 : mem_out_dec = 6'b001110;
12'd351 : mem_out_dec = 6'b001110;
12'd352 : mem_out_dec = 6'b001111;
12'd353 : mem_out_dec = 6'b001111;
12'd354 : mem_out_dec = 6'b010000;
12'd355 : mem_out_dec = 6'b010000;
12'd356 : mem_out_dec = 6'b010001;
12'd357 : mem_out_dec = 6'b010001;
12'd358 : mem_out_dec = 6'b010001;
12'd359 : mem_out_dec = 6'b010010;
12'd360 : mem_out_dec = 6'b010010;
12'd361 : mem_out_dec = 6'b010011;
12'd362 : mem_out_dec = 6'b010100;
12'd363 : mem_out_dec = 6'b010100;
12'd364 : mem_out_dec = 6'b010101;
12'd365 : mem_out_dec = 6'b010110;
12'd366 : mem_out_dec = 6'b010111;
12'd367 : mem_out_dec = 6'b011000;
12'd368 : mem_out_dec = 6'b010111;
12'd369 : mem_out_dec = 6'b010111;
12'd370 : mem_out_dec = 6'b010111;
12'd371 : mem_out_dec = 6'b010111;
12'd372 : mem_out_dec = 6'b010111;
12'd373 : mem_out_dec = 6'b010111;
12'd374 : mem_out_dec = 6'b011000;
12'd375 : mem_out_dec = 6'b011001;
12'd376 : mem_out_dec = 6'b011001;
12'd377 : mem_out_dec = 6'b011010;
12'd378 : mem_out_dec = 6'b011010;
12'd379 : mem_out_dec = 6'b011011;
12'd380 : mem_out_dec = 6'b011100;
12'd381 : mem_out_dec = 6'b011101;
12'd382 : mem_out_dec = 6'b011101;
12'd383 : mem_out_dec = 6'b011110;
12'd384 : mem_out_dec = 6'b111111;
12'd385 : mem_out_dec = 6'b111111;
12'd386 : mem_out_dec = 6'b111111;
12'd387 : mem_out_dec = 6'b111111;
12'd388 : mem_out_dec = 6'b111111;
12'd389 : mem_out_dec = 6'b111111;
12'd390 : mem_out_dec = 6'b111111;
12'd391 : mem_out_dec = 6'b111111;
12'd392 : mem_out_dec = 6'b111111;
12'd393 : mem_out_dec = 6'b111111;
12'd394 : mem_out_dec = 6'b111111;
12'd395 : mem_out_dec = 6'b111111;
12'd396 : mem_out_dec = 6'b000101;
12'd397 : mem_out_dec = 6'b000110;
12'd398 : mem_out_dec = 6'b000110;
12'd399 : mem_out_dec = 6'b000111;
12'd400 : mem_out_dec = 6'b000110;
12'd401 : mem_out_dec = 6'b000110;
12'd402 : mem_out_dec = 6'b000110;
12'd403 : mem_out_dec = 6'b000110;
12'd404 : mem_out_dec = 6'b000110;
12'd405 : mem_out_dec = 6'b000111;
12'd406 : mem_out_dec = 6'b001000;
12'd407 : mem_out_dec = 6'b001000;
12'd408 : mem_out_dec = 6'b001001;
12'd409 : mem_out_dec = 6'b001001;
12'd410 : mem_out_dec = 6'b001010;
12'd411 : mem_out_dec = 6'b001011;
12'd412 : mem_out_dec = 6'b001100;
12'd413 : mem_out_dec = 6'b001100;
12'd414 : mem_out_dec = 6'b001101;
12'd415 : mem_out_dec = 6'b001110;
12'd416 : mem_out_dec = 6'b001110;
12'd417 : mem_out_dec = 6'b001111;
12'd418 : mem_out_dec = 6'b001111;
12'd419 : mem_out_dec = 6'b010000;
12'd420 : mem_out_dec = 6'b010000;
12'd421 : mem_out_dec = 6'b010000;
12'd422 : mem_out_dec = 6'b010001;
12'd423 : mem_out_dec = 6'b010001;
12'd424 : mem_out_dec = 6'b010010;
12'd425 : mem_out_dec = 6'b010011;
12'd426 : mem_out_dec = 6'b010011;
12'd427 : mem_out_dec = 6'b010100;
12'd428 : mem_out_dec = 6'b010101;
12'd429 : mem_out_dec = 6'b010110;
12'd430 : mem_out_dec = 6'b010111;
12'd431 : mem_out_dec = 6'b010111;
12'd432 : mem_out_dec = 6'b010110;
12'd433 : mem_out_dec = 6'b010110;
12'd434 : mem_out_dec = 6'b010110;
12'd435 : mem_out_dec = 6'b010110;
12'd436 : mem_out_dec = 6'b010110;
12'd437 : mem_out_dec = 6'b010111;
12'd438 : mem_out_dec = 6'b010111;
12'd439 : mem_out_dec = 6'b011000;
12'd440 : mem_out_dec = 6'b011001;
12'd441 : mem_out_dec = 6'b011001;
12'd442 : mem_out_dec = 6'b011010;
12'd443 : mem_out_dec = 6'b011011;
12'd444 : mem_out_dec = 6'b011011;
12'd445 : mem_out_dec = 6'b011100;
12'd446 : mem_out_dec = 6'b011101;
12'd447 : mem_out_dec = 6'b011110;
12'd448 : mem_out_dec = 6'b111111;
12'd449 : mem_out_dec = 6'b111111;
12'd450 : mem_out_dec = 6'b111111;
12'd451 : mem_out_dec = 6'b111111;
12'd452 : mem_out_dec = 6'b111111;
12'd453 : mem_out_dec = 6'b111111;
12'd454 : mem_out_dec = 6'b111111;
12'd455 : mem_out_dec = 6'b111111;
12'd456 : mem_out_dec = 6'b111111;
12'd457 : mem_out_dec = 6'b111111;
12'd458 : mem_out_dec = 6'b111111;
12'd459 : mem_out_dec = 6'b111111;
12'd460 : mem_out_dec = 6'b111111;
12'd461 : mem_out_dec = 6'b000101;
12'd462 : mem_out_dec = 6'b000110;
12'd463 : mem_out_dec = 6'b000110;
12'd464 : mem_out_dec = 6'b000110;
12'd465 : mem_out_dec = 6'b000110;
12'd466 : mem_out_dec = 6'b000110;
12'd467 : mem_out_dec = 6'b000110;
12'd468 : mem_out_dec = 6'b000110;
12'd469 : mem_out_dec = 6'b000111;
12'd470 : mem_out_dec = 6'b000111;
12'd471 : mem_out_dec = 6'b001000;
12'd472 : mem_out_dec = 6'b001000;
12'd473 : mem_out_dec = 6'b001001;
12'd474 : mem_out_dec = 6'b001010;
12'd475 : mem_out_dec = 6'b001011;
12'd476 : mem_out_dec = 6'b001011;
12'd477 : mem_out_dec = 6'b001100;
12'd478 : mem_out_dec = 6'b001101;
12'd479 : mem_out_dec = 6'b001110;
12'd480 : mem_out_dec = 6'b001110;
12'd481 : mem_out_dec = 6'b001110;
12'd482 : mem_out_dec = 6'b001111;
12'd483 : mem_out_dec = 6'b001111;
12'd484 : mem_out_dec = 6'b010000;
12'd485 : mem_out_dec = 6'b010000;
12'd486 : mem_out_dec = 6'b010000;
12'd487 : mem_out_dec = 6'b010001;
12'd488 : mem_out_dec = 6'b010001;
12'd489 : mem_out_dec = 6'b010010;
12'd490 : mem_out_dec = 6'b010011;
12'd491 : mem_out_dec = 6'b010100;
12'd492 : mem_out_dec = 6'b010101;
12'd493 : mem_out_dec = 6'b010101;
12'd494 : mem_out_dec = 6'b010110;
12'd495 : mem_out_dec = 6'b010110;
12'd496 : mem_out_dec = 6'b010110;
12'd497 : mem_out_dec = 6'b010110;
12'd498 : mem_out_dec = 6'b010101;
12'd499 : mem_out_dec = 6'b010101;
12'd500 : mem_out_dec = 6'b010110;
12'd501 : mem_out_dec = 6'b010111;
12'd502 : mem_out_dec = 6'b010111;
12'd503 : mem_out_dec = 6'b011000;
12'd504 : mem_out_dec = 6'b011000;
12'd505 : mem_out_dec = 6'b011001;
12'd506 : mem_out_dec = 6'b011010;
12'd507 : mem_out_dec = 6'b011010;
12'd508 : mem_out_dec = 6'b011011;
12'd509 : mem_out_dec = 6'b011100;
12'd510 : mem_out_dec = 6'b011101;
12'd511 : mem_out_dec = 6'b011101;
12'd512 : mem_out_dec = 6'b111111;
12'd513 : mem_out_dec = 6'b111111;
12'd514 : mem_out_dec = 6'b111111;
12'd515 : mem_out_dec = 6'b111111;
12'd516 : mem_out_dec = 6'b111111;
12'd517 : mem_out_dec = 6'b111111;
12'd518 : mem_out_dec = 6'b111111;
12'd519 : mem_out_dec = 6'b111111;
12'd520 : mem_out_dec = 6'b111111;
12'd521 : mem_out_dec = 6'b111111;
12'd522 : mem_out_dec = 6'b111111;
12'd523 : mem_out_dec = 6'b111111;
12'd524 : mem_out_dec = 6'b111111;
12'd525 : mem_out_dec = 6'b111111;
12'd526 : mem_out_dec = 6'b000100;
12'd527 : mem_out_dec = 6'b000101;
12'd528 : mem_out_dec = 6'b000100;
12'd529 : mem_out_dec = 6'b000100;
12'd530 : mem_out_dec = 6'b000100;
12'd531 : mem_out_dec = 6'b000101;
12'd532 : mem_out_dec = 6'b000101;
12'd533 : mem_out_dec = 6'b000110;
12'd534 : mem_out_dec = 6'b000111;
12'd535 : mem_out_dec = 6'b000111;
12'd536 : mem_out_dec = 6'b000111;
12'd537 : mem_out_dec = 6'b001000;
12'd538 : mem_out_dec = 6'b001001;
12'd539 : mem_out_dec = 6'b001010;
12'd540 : mem_out_dec = 6'b001011;
12'd541 : mem_out_dec = 6'b001011;
12'd542 : mem_out_dec = 6'b001100;
12'd543 : mem_out_dec = 6'b001101;
12'd544 : mem_out_dec = 6'b001101;
12'd545 : mem_out_dec = 6'b001101;
12'd546 : mem_out_dec = 6'b001110;
12'd547 : mem_out_dec = 6'b001110;
12'd548 : mem_out_dec = 6'b001110;
12'd549 : mem_out_dec = 6'b001111;
12'd550 : mem_out_dec = 6'b010000;
12'd551 : mem_out_dec = 6'b010000;
12'd552 : mem_out_dec = 6'b010001;
12'd553 : mem_out_dec = 6'b010001;
12'd554 : mem_out_dec = 6'b010010;
12'd555 : mem_out_dec = 6'b010010;
12'd556 : mem_out_dec = 6'b010011;
12'd557 : mem_out_dec = 6'b010100;
12'd558 : mem_out_dec = 6'b010100;
12'd559 : mem_out_dec = 6'b010100;
12'd560 : mem_out_dec = 6'b010100;
12'd561 : mem_out_dec = 6'b010100;
12'd562 : mem_out_dec = 6'b010100;
12'd563 : mem_out_dec = 6'b010101;
12'd564 : mem_out_dec = 6'b010101;
12'd565 : mem_out_dec = 6'b010110;
12'd566 : mem_out_dec = 6'b010111;
12'd567 : mem_out_dec = 6'b010111;
12'd568 : mem_out_dec = 6'b010111;
12'd569 : mem_out_dec = 6'b011000;
12'd570 : mem_out_dec = 6'b011001;
12'd571 : mem_out_dec = 6'b011010;
12'd572 : mem_out_dec = 6'b011010;
12'd573 : mem_out_dec = 6'b011011;
12'd574 : mem_out_dec = 6'b011100;
12'd575 : mem_out_dec = 6'b011101;
12'd576 : mem_out_dec = 6'b111111;
12'd577 : mem_out_dec = 6'b111111;
12'd578 : mem_out_dec = 6'b111111;
12'd579 : mem_out_dec = 6'b111111;
12'd580 : mem_out_dec = 6'b111111;
12'd581 : mem_out_dec = 6'b111111;
12'd582 : mem_out_dec = 6'b111111;
12'd583 : mem_out_dec = 6'b111111;
12'd584 : mem_out_dec = 6'b111111;
12'd585 : mem_out_dec = 6'b111111;
12'd586 : mem_out_dec = 6'b111111;
12'd587 : mem_out_dec = 6'b111111;
12'd588 : mem_out_dec = 6'b111111;
12'd589 : mem_out_dec = 6'b111111;
12'd590 : mem_out_dec = 6'b111111;
12'd591 : mem_out_dec = 6'b000100;
12'd592 : mem_out_dec = 6'b000011;
12'd593 : mem_out_dec = 6'b000011;
12'd594 : mem_out_dec = 6'b000100;
12'd595 : mem_out_dec = 6'b000101;
12'd596 : mem_out_dec = 6'b000101;
12'd597 : mem_out_dec = 6'b000110;
12'd598 : mem_out_dec = 6'b000110;
12'd599 : mem_out_dec = 6'b000111;
12'd600 : mem_out_dec = 6'b000111;
12'd601 : mem_out_dec = 6'b001000;
12'd602 : mem_out_dec = 6'b001001;
12'd603 : mem_out_dec = 6'b001010;
12'd604 : mem_out_dec = 6'b001010;
12'd605 : mem_out_dec = 6'b001011;
12'd606 : mem_out_dec = 6'b001100;
12'd607 : mem_out_dec = 6'b001101;
12'd608 : mem_out_dec = 6'b001101;
12'd609 : mem_out_dec = 6'b001101;
12'd610 : mem_out_dec = 6'b001110;
12'd611 : mem_out_dec = 6'b001110;
12'd612 : mem_out_dec = 6'b001110;
12'd613 : mem_out_dec = 6'b001111;
12'd614 : mem_out_dec = 6'b010000;
12'd615 : mem_out_dec = 6'b010000;
12'd616 : mem_out_dec = 6'b010000;
12'd617 : mem_out_dec = 6'b010001;
12'd618 : mem_out_dec = 6'b010001;
12'd619 : mem_out_dec = 6'b010010;
12'd620 : mem_out_dec = 6'b010010;
12'd621 : mem_out_dec = 6'b010011;
12'd622 : mem_out_dec = 6'b010011;
12'd623 : mem_out_dec = 6'b010100;
12'd624 : mem_out_dec = 6'b010011;
12'd625 : mem_out_dec = 6'b010011;
12'd626 : mem_out_dec = 6'b010100;
12'd627 : mem_out_dec = 6'b010100;
12'd628 : mem_out_dec = 6'b010101;
12'd629 : mem_out_dec = 6'b010110;
12'd630 : mem_out_dec = 6'b010110;
12'd631 : mem_out_dec = 6'b010111;
12'd632 : mem_out_dec = 6'b010111;
12'd633 : mem_out_dec = 6'b011000;
12'd634 : mem_out_dec = 6'b011001;
12'd635 : mem_out_dec = 6'b011001;
12'd636 : mem_out_dec = 6'b011010;
12'd637 : mem_out_dec = 6'b011011;
12'd638 : mem_out_dec = 6'b011100;
12'd639 : mem_out_dec = 6'b011100;
12'd640 : mem_out_dec = 6'b111111;
12'd641 : mem_out_dec = 6'b111111;
12'd642 : mem_out_dec = 6'b111111;
12'd643 : mem_out_dec = 6'b111111;
12'd644 : mem_out_dec = 6'b111111;
12'd645 : mem_out_dec = 6'b111111;
12'd646 : mem_out_dec = 6'b111111;
12'd647 : mem_out_dec = 6'b111111;
12'd648 : mem_out_dec = 6'b111111;
12'd649 : mem_out_dec = 6'b111111;
12'd650 : mem_out_dec = 6'b111111;
12'd651 : mem_out_dec = 6'b111111;
12'd652 : mem_out_dec = 6'b111111;
12'd653 : mem_out_dec = 6'b111111;
12'd654 : mem_out_dec = 6'b111111;
12'd655 : mem_out_dec = 6'b111111;
12'd656 : mem_out_dec = 6'b000011;
12'd657 : mem_out_dec = 6'b000011;
12'd658 : mem_out_dec = 6'b000100;
12'd659 : mem_out_dec = 6'b000100;
12'd660 : mem_out_dec = 6'b000101;
12'd661 : mem_out_dec = 6'b000110;
12'd662 : mem_out_dec = 6'b000110;
12'd663 : mem_out_dec = 6'b000111;
12'd664 : mem_out_dec = 6'b000111;
12'd665 : mem_out_dec = 6'b001000;
12'd666 : mem_out_dec = 6'b001001;
12'd667 : mem_out_dec = 6'b001001;
12'd668 : mem_out_dec = 6'b001010;
12'd669 : mem_out_dec = 6'b001011;
12'd670 : mem_out_dec = 6'b001100;
12'd671 : mem_out_dec = 6'b001100;
12'd672 : mem_out_dec = 6'b001100;
12'd673 : mem_out_dec = 6'b001101;
12'd674 : mem_out_dec = 6'b001101;
12'd675 : mem_out_dec = 6'b001101;
12'd676 : mem_out_dec = 6'b001110;
12'd677 : mem_out_dec = 6'b001111;
12'd678 : mem_out_dec = 6'b001111;
12'd679 : mem_out_dec = 6'b010000;
12'd680 : mem_out_dec = 6'b010000;
12'd681 : mem_out_dec = 6'b010000;
12'd682 : mem_out_dec = 6'b010001;
12'd683 : mem_out_dec = 6'b010001;
12'd684 : mem_out_dec = 6'b010010;
12'd685 : mem_out_dec = 6'b010010;
12'd686 : mem_out_dec = 6'b010011;
12'd687 : mem_out_dec = 6'b010011;
12'd688 : mem_out_dec = 6'b010011;
12'd689 : mem_out_dec = 6'b010011;
12'd690 : mem_out_dec = 6'b010100;
12'd691 : mem_out_dec = 6'b010100;
12'd692 : mem_out_dec = 6'b010101;
12'd693 : mem_out_dec = 6'b010101;
12'd694 : mem_out_dec = 6'b010110;
12'd695 : mem_out_dec = 6'b010111;
12'd696 : mem_out_dec = 6'b010111;
12'd697 : mem_out_dec = 6'b011000;
12'd698 : mem_out_dec = 6'b011000;
12'd699 : mem_out_dec = 6'b011001;
12'd700 : mem_out_dec = 6'b011010;
12'd701 : mem_out_dec = 6'b011011;
12'd702 : mem_out_dec = 6'b011011;
12'd703 : mem_out_dec = 6'b011100;
12'd704 : mem_out_dec = 6'b111111;
12'd705 : mem_out_dec = 6'b111111;
12'd706 : mem_out_dec = 6'b111111;
12'd707 : mem_out_dec = 6'b111111;
12'd708 : mem_out_dec = 6'b111111;
12'd709 : mem_out_dec = 6'b111111;
12'd710 : mem_out_dec = 6'b111111;
12'd711 : mem_out_dec = 6'b111111;
12'd712 : mem_out_dec = 6'b111111;
12'd713 : mem_out_dec = 6'b111111;
12'd714 : mem_out_dec = 6'b111111;
12'd715 : mem_out_dec = 6'b111111;
12'd716 : mem_out_dec = 6'b111111;
12'd717 : mem_out_dec = 6'b111111;
12'd718 : mem_out_dec = 6'b111111;
12'd719 : mem_out_dec = 6'b111111;
12'd720 : mem_out_dec = 6'b111111;
12'd721 : mem_out_dec = 6'b000011;
12'd722 : mem_out_dec = 6'b000100;
12'd723 : mem_out_dec = 6'b000100;
12'd724 : mem_out_dec = 6'b000101;
12'd725 : mem_out_dec = 6'b000101;
12'd726 : mem_out_dec = 6'b000110;
12'd727 : mem_out_dec = 6'b000111;
12'd728 : mem_out_dec = 6'b000111;
12'd729 : mem_out_dec = 6'b000111;
12'd730 : mem_out_dec = 6'b001000;
12'd731 : mem_out_dec = 6'b001001;
12'd732 : mem_out_dec = 6'b001010;
12'd733 : mem_out_dec = 6'b001011;
12'd734 : mem_out_dec = 6'b001011;
12'd735 : mem_out_dec = 6'b001100;
12'd736 : mem_out_dec = 6'b001100;
12'd737 : mem_out_dec = 6'b001101;
12'd738 : mem_out_dec = 6'b001101;
12'd739 : mem_out_dec = 6'b001101;
12'd740 : mem_out_dec = 6'b001110;
12'd741 : mem_out_dec = 6'b001110;
12'd742 : mem_out_dec = 6'b001111;
12'd743 : mem_out_dec = 6'b010000;
12'd744 : mem_out_dec = 6'b001111;
12'd745 : mem_out_dec = 6'b010000;
12'd746 : mem_out_dec = 6'b010000;
12'd747 : mem_out_dec = 6'b010001;
12'd748 : mem_out_dec = 6'b010001;
12'd749 : mem_out_dec = 6'b010010;
12'd750 : mem_out_dec = 6'b010010;
12'd751 : mem_out_dec = 6'b010011;
12'd752 : mem_out_dec = 6'b010010;
12'd753 : mem_out_dec = 6'b010011;
12'd754 : mem_out_dec = 6'b010011;
12'd755 : mem_out_dec = 6'b010100;
12'd756 : mem_out_dec = 6'b010101;
12'd757 : mem_out_dec = 6'b010101;
12'd758 : mem_out_dec = 6'b010110;
12'd759 : mem_out_dec = 6'b010110;
12'd760 : mem_out_dec = 6'b010111;
12'd761 : mem_out_dec = 6'b010111;
12'd762 : mem_out_dec = 6'b011000;
12'd763 : mem_out_dec = 6'b011001;
12'd764 : mem_out_dec = 6'b011010;
12'd765 : mem_out_dec = 6'b011010;
12'd766 : mem_out_dec = 6'b011011;
12'd767 : mem_out_dec = 6'b011100;
12'd768 : mem_out_dec = 6'b111111;
12'd769 : mem_out_dec = 6'b111111;
12'd770 : mem_out_dec = 6'b111111;
12'd771 : mem_out_dec = 6'b111111;
12'd772 : mem_out_dec = 6'b111111;
12'd773 : mem_out_dec = 6'b111111;
12'd774 : mem_out_dec = 6'b111111;
12'd775 : mem_out_dec = 6'b111111;
12'd776 : mem_out_dec = 6'b111111;
12'd777 : mem_out_dec = 6'b111111;
12'd778 : mem_out_dec = 6'b111111;
12'd779 : mem_out_dec = 6'b111111;
12'd780 : mem_out_dec = 6'b111111;
12'd781 : mem_out_dec = 6'b111111;
12'd782 : mem_out_dec = 6'b111111;
12'd783 : mem_out_dec = 6'b111111;
12'd784 : mem_out_dec = 6'b111111;
12'd785 : mem_out_dec = 6'b111111;
12'd786 : mem_out_dec = 6'b000011;
12'd787 : mem_out_dec = 6'b000100;
12'd788 : mem_out_dec = 6'b000101;
12'd789 : mem_out_dec = 6'b000101;
12'd790 : mem_out_dec = 6'b000110;
12'd791 : mem_out_dec = 6'b000110;
12'd792 : mem_out_dec = 6'b000110;
12'd793 : mem_out_dec = 6'b000111;
12'd794 : mem_out_dec = 6'b001000;
12'd795 : mem_out_dec = 6'b001001;
12'd796 : mem_out_dec = 6'b001010;
12'd797 : mem_out_dec = 6'b001010;
12'd798 : mem_out_dec = 6'b001011;
12'd799 : mem_out_dec = 6'b001100;
12'd800 : mem_out_dec = 6'b001100;
12'd801 : mem_out_dec = 6'b001100;
12'd802 : mem_out_dec = 6'b001101;
12'd803 : mem_out_dec = 6'b001101;
12'd804 : mem_out_dec = 6'b001110;
12'd805 : mem_out_dec = 6'b001110;
12'd806 : mem_out_dec = 6'b001111;
12'd807 : mem_out_dec = 6'b010000;
12'd808 : mem_out_dec = 6'b001111;
12'd809 : mem_out_dec = 6'b001111;
12'd810 : mem_out_dec = 6'b010000;
12'd811 : mem_out_dec = 6'b010000;
12'd812 : mem_out_dec = 6'b010001;
12'd813 : mem_out_dec = 6'b010001;
12'd814 : mem_out_dec = 6'b010010;
12'd815 : mem_out_dec = 6'b010010;
12'd816 : mem_out_dec = 6'b010010;
12'd817 : mem_out_dec = 6'b010011;
12'd818 : mem_out_dec = 6'b010011;
12'd819 : mem_out_dec = 6'b010100;
12'd820 : mem_out_dec = 6'b010100;
12'd821 : mem_out_dec = 6'b010101;
12'd822 : mem_out_dec = 6'b010110;
12'd823 : mem_out_dec = 6'b010110;
12'd824 : mem_out_dec = 6'b010110;
12'd825 : mem_out_dec = 6'b010111;
12'd826 : mem_out_dec = 6'b011000;
12'd827 : mem_out_dec = 6'b011001;
12'd828 : mem_out_dec = 6'b011001;
12'd829 : mem_out_dec = 6'b011010;
12'd830 : mem_out_dec = 6'b011011;
12'd831 : mem_out_dec = 6'b011100;
12'd832 : mem_out_dec = 6'b111111;
12'd833 : mem_out_dec = 6'b111111;
12'd834 : mem_out_dec = 6'b111111;
12'd835 : mem_out_dec = 6'b111111;
12'd836 : mem_out_dec = 6'b111111;
12'd837 : mem_out_dec = 6'b111111;
12'd838 : mem_out_dec = 6'b111111;
12'd839 : mem_out_dec = 6'b111111;
12'd840 : mem_out_dec = 6'b111111;
12'd841 : mem_out_dec = 6'b111111;
12'd842 : mem_out_dec = 6'b111111;
12'd843 : mem_out_dec = 6'b111111;
12'd844 : mem_out_dec = 6'b111111;
12'd845 : mem_out_dec = 6'b111111;
12'd846 : mem_out_dec = 6'b111111;
12'd847 : mem_out_dec = 6'b111111;
12'd848 : mem_out_dec = 6'b111111;
12'd849 : mem_out_dec = 6'b111111;
12'd850 : mem_out_dec = 6'b111111;
12'd851 : mem_out_dec = 6'b000100;
12'd852 : mem_out_dec = 6'b000100;
12'd853 : mem_out_dec = 6'b000101;
12'd854 : mem_out_dec = 6'b000101;
12'd855 : mem_out_dec = 6'b000110;
12'd856 : mem_out_dec = 6'b000110;
12'd857 : mem_out_dec = 6'b000111;
12'd858 : mem_out_dec = 6'b001000;
12'd859 : mem_out_dec = 6'b001001;
12'd860 : mem_out_dec = 6'b001001;
12'd861 : mem_out_dec = 6'b001010;
12'd862 : mem_out_dec = 6'b001011;
12'd863 : mem_out_dec = 6'b001100;
12'd864 : mem_out_dec = 6'b001100;
12'd865 : mem_out_dec = 6'b001100;
12'd866 : mem_out_dec = 6'b001100;
12'd867 : mem_out_dec = 6'b001101;
12'd868 : mem_out_dec = 6'b001101;
12'd869 : mem_out_dec = 6'b001110;
12'd870 : mem_out_dec = 6'b001111;
12'd871 : mem_out_dec = 6'b001111;
12'd872 : mem_out_dec = 6'b001110;
12'd873 : mem_out_dec = 6'b001111;
12'd874 : mem_out_dec = 6'b001111;
12'd875 : mem_out_dec = 6'b010000;
12'd876 : mem_out_dec = 6'b010000;
12'd877 : mem_out_dec = 6'b010001;
12'd878 : mem_out_dec = 6'b010001;
12'd879 : mem_out_dec = 6'b010010;
12'd880 : mem_out_dec = 6'b010010;
12'd881 : mem_out_dec = 6'b010010;
12'd882 : mem_out_dec = 6'b010011;
12'd883 : mem_out_dec = 6'b010100;
12'd884 : mem_out_dec = 6'b010100;
12'd885 : mem_out_dec = 6'b010101;
12'd886 : mem_out_dec = 6'b010101;
12'd887 : mem_out_dec = 6'b010110;
12'd888 : mem_out_dec = 6'b010110;
12'd889 : mem_out_dec = 6'b010111;
12'd890 : mem_out_dec = 6'b011000;
12'd891 : mem_out_dec = 6'b011000;
12'd892 : mem_out_dec = 6'b011001;
12'd893 : mem_out_dec = 6'b011010;
12'd894 : mem_out_dec = 6'b011011;
12'd895 : mem_out_dec = 6'b011011;
12'd896 : mem_out_dec = 6'b111111;
12'd897 : mem_out_dec = 6'b111111;
12'd898 : mem_out_dec = 6'b111111;
12'd899 : mem_out_dec = 6'b111111;
12'd900 : mem_out_dec = 6'b111111;
12'd901 : mem_out_dec = 6'b111111;
12'd902 : mem_out_dec = 6'b111111;
12'd903 : mem_out_dec = 6'b111111;
12'd904 : mem_out_dec = 6'b111111;
12'd905 : mem_out_dec = 6'b111111;
12'd906 : mem_out_dec = 6'b111111;
12'd907 : mem_out_dec = 6'b111111;
12'd908 : mem_out_dec = 6'b111111;
12'd909 : mem_out_dec = 6'b111111;
12'd910 : mem_out_dec = 6'b111111;
12'd911 : mem_out_dec = 6'b111111;
12'd912 : mem_out_dec = 6'b111111;
12'd913 : mem_out_dec = 6'b111111;
12'd914 : mem_out_dec = 6'b111111;
12'd915 : mem_out_dec = 6'b111111;
12'd916 : mem_out_dec = 6'b000100;
12'd917 : mem_out_dec = 6'b000101;
12'd918 : mem_out_dec = 6'b000101;
12'd919 : mem_out_dec = 6'b000110;
12'd920 : mem_out_dec = 6'b000110;
12'd921 : mem_out_dec = 6'b000111;
12'd922 : mem_out_dec = 6'b001000;
12'd923 : mem_out_dec = 6'b001000;
12'd924 : mem_out_dec = 6'b001001;
12'd925 : mem_out_dec = 6'b001010;
12'd926 : mem_out_dec = 6'b001011;
12'd927 : mem_out_dec = 6'b001011;
12'd928 : mem_out_dec = 6'b001011;
12'd929 : mem_out_dec = 6'b001100;
12'd930 : mem_out_dec = 6'b001100;
12'd931 : mem_out_dec = 6'b001101;
12'd932 : mem_out_dec = 6'b001101;
12'd933 : mem_out_dec = 6'b001110;
12'd934 : mem_out_dec = 6'b001110;
12'd935 : mem_out_dec = 6'b001111;
12'd936 : mem_out_dec = 6'b001110;
12'd937 : mem_out_dec = 6'b001110;
12'd938 : mem_out_dec = 6'b001111;
12'd939 : mem_out_dec = 6'b001111;
12'd940 : mem_out_dec = 6'b010000;
12'd941 : mem_out_dec = 6'b010000;
12'd942 : mem_out_dec = 6'b010001;
12'd943 : mem_out_dec = 6'b010001;
12'd944 : mem_out_dec = 6'b010010;
12'd945 : mem_out_dec = 6'b010010;
12'd946 : mem_out_dec = 6'b010011;
12'd947 : mem_out_dec = 6'b010011;
12'd948 : mem_out_dec = 6'b010100;
12'd949 : mem_out_dec = 6'b010100;
12'd950 : mem_out_dec = 6'b010101;
12'd951 : mem_out_dec = 6'b010110;
12'd952 : mem_out_dec = 6'b010110;
12'd953 : mem_out_dec = 6'b010111;
12'd954 : mem_out_dec = 6'b010111;
12'd955 : mem_out_dec = 6'b011000;
12'd956 : mem_out_dec = 6'b011001;
12'd957 : mem_out_dec = 6'b011010;
12'd958 : mem_out_dec = 6'b011010;
12'd959 : mem_out_dec = 6'b011011;
12'd960 : mem_out_dec = 6'b111111;
12'd961 : mem_out_dec = 6'b111111;
12'd962 : mem_out_dec = 6'b111111;
12'd963 : mem_out_dec = 6'b111111;
12'd964 : mem_out_dec = 6'b111111;
12'd965 : mem_out_dec = 6'b111111;
12'd966 : mem_out_dec = 6'b111111;
12'd967 : mem_out_dec = 6'b111111;
12'd968 : mem_out_dec = 6'b111111;
12'd969 : mem_out_dec = 6'b111111;
12'd970 : mem_out_dec = 6'b111111;
12'd971 : mem_out_dec = 6'b111111;
12'd972 : mem_out_dec = 6'b111111;
12'd973 : mem_out_dec = 6'b111111;
12'd974 : mem_out_dec = 6'b111111;
12'd975 : mem_out_dec = 6'b111111;
12'd976 : mem_out_dec = 6'b111111;
12'd977 : mem_out_dec = 6'b111111;
12'd978 : mem_out_dec = 6'b111111;
12'd979 : mem_out_dec = 6'b111111;
12'd980 : mem_out_dec = 6'b111111;
12'd981 : mem_out_dec = 6'b000100;
12'd982 : mem_out_dec = 6'b000101;
12'd983 : mem_out_dec = 6'b000110;
12'd984 : mem_out_dec = 6'b000110;
12'd985 : mem_out_dec = 6'b000111;
12'd986 : mem_out_dec = 6'b000111;
12'd987 : mem_out_dec = 6'b001000;
12'd988 : mem_out_dec = 6'b001001;
12'd989 : mem_out_dec = 6'b001010;
12'd990 : mem_out_dec = 6'b001010;
12'd991 : mem_out_dec = 6'b001011;
12'd992 : mem_out_dec = 6'b001011;
12'd993 : mem_out_dec = 6'b001011;
12'd994 : mem_out_dec = 6'b001100;
12'd995 : mem_out_dec = 6'b001100;
12'd996 : mem_out_dec = 6'b001101;
12'd997 : mem_out_dec = 6'b001110;
12'd998 : mem_out_dec = 6'b001110;
12'd999 : mem_out_dec = 6'b001110;
12'd1000 : mem_out_dec = 6'b001101;
12'd1001 : mem_out_dec = 6'b001110;
12'd1002 : mem_out_dec = 6'b001110;
12'd1003 : mem_out_dec = 6'b001111;
12'd1004 : mem_out_dec = 6'b001111;
12'd1005 : mem_out_dec = 6'b010000;
12'd1006 : mem_out_dec = 6'b010000;
12'd1007 : mem_out_dec = 6'b010001;
12'd1008 : mem_out_dec = 6'b010001;
12'd1009 : mem_out_dec = 6'b010010;
12'd1010 : mem_out_dec = 6'b010011;
12'd1011 : mem_out_dec = 6'b010011;
12'd1012 : mem_out_dec = 6'b010100;
12'd1013 : mem_out_dec = 6'b010100;
12'd1014 : mem_out_dec = 6'b010101;
12'd1015 : mem_out_dec = 6'b010110;
12'd1016 : mem_out_dec = 6'b010110;
12'd1017 : mem_out_dec = 6'b010110;
12'd1018 : mem_out_dec = 6'b010111;
12'd1019 : mem_out_dec = 6'b011000;
12'd1020 : mem_out_dec = 6'b011001;
12'd1021 : mem_out_dec = 6'b011001;
12'd1022 : mem_out_dec = 6'b011010;
12'd1023 : mem_out_dec = 6'b011011;
12'd1024 : mem_out_dec = 6'b111111;
12'd1025 : mem_out_dec = 6'b111111;
12'd1026 : mem_out_dec = 6'b111111;
12'd1027 : mem_out_dec = 6'b111111;
12'd1028 : mem_out_dec = 6'b111111;
12'd1029 : mem_out_dec = 6'b111111;
12'd1030 : mem_out_dec = 6'b111111;
12'd1031 : mem_out_dec = 6'b111111;
12'd1032 : mem_out_dec = 6'b111111;
12'd1033 : mem_out_dec = 6'b111111;
12'd1034 : mem_out_dec = 6'b111111;
12'd1035 : mem_out_dec = 6'b111111;
12'd1036 : mem_out_dec = 6'b111111;
12'd1037 : mem_out_dec = 6'b111111;
12'd1038 : mem_out_dec = 6'b111111;
12'd1039 : mem_out_dec = 6'b111111;
12'd1040 : mem_out_dec = 6'b111111;
12'd1041 : mem_out_dec = 6'b111111;
12'd1042 : mem_out_dec = 6'b111111;
12'd1043 : mem_out_dec = 6'b111111;
12'd1044 : mem_out_dec = 6'b111111;
12'd1045 : mem_out_dec = 6'b111111;
12'd1046 : mem_out_dec = 6'b000100;
12'd1047 : mem_out_dec = 6'b000101;
12'd1048 : mem_out_dec = 6'b000101;
12'd1049 : mem_out_dec = 6'b000110;
12'd1050 : mem_out_dec = 6'b000110;
12'd1051 : mem_out_dec = 6'b000111;
12'd1052 : mem_out_dec = 6'b001000;
12'd1053 : mem_out_dec = 6'b001001;
12'd1054 : mem_out_dec = 6'b001001;
12'd1055 : mem_out_dec = 6'b001010;
12'd1056 : mem_out_dec = 6'b001010;
12'd1057 : mem_out_dec = 6'b001011;
12'd1058 : mem_out_dec = 6'b001011;
12'd1059 : mem_out_dec = 6'b001100;
12'd1060 : mem_out_dec = 6'b001100;
12'd1061 : mem_out_dec = 6'b001100;
12'd1062 : mem_out_dec = 6'b001100;
12'd1063 : mem_out_dec = 6'b001100;
12'd1064 : mem_out_dec = 6'b001100;
12'd1065 : mem_out_dec = 6'b001100;
12'd1066 : mem_out_dec = 6'b001101;
12'd1067 : mem_out_dec = 6'b001101;
12'd1068 : mem_out_dec = 6'b001110;
12'd1069 : mem_out_dec = 6'b001111;
12'd1070 : mem_out_dec = 6'b010000;
12'd1071 : mem_out_dec = 6'b010000;
12'd1072 : mem_out_dec = 6'b010001;
12'd1073 : mem_out_dec = 6'b010001;
12'd1074 : mem_out_dec = 6'b010010;
12'd1075 : mem_out_dec = 6'b010010;
12'd1076 : mem_out_dec = 6'b010011;
12'd1077 : mem_out_dec = 6'b010011;
12'd1078 : mem_out_dec = 6'b010100;
12'd1079 : mem_out_dec = 6'b010101;
12'd1080 : mem_out_dec = 6'b010101;
12'd1081 : mem_out_dec = 6'b010110;
12'd1082 : mem_out_dec = 6'b010110;
12'd1083 : mem_out_dec = 6'b010111;
12'd1084 : mem_out_dec = 6'b011000;
12'd1085 : mem_out_dec = 6'b011000;
12'd1086 : mem_out_dec = 6'b011001;
12'd1087 : mem_out_dec = 6'b011010;
12'd1088 : mem_out_dec = 6'b111111;
12'd1089 : mem_out_dec = 6'b111111;
12'd1090 : mem_out_dec = 6'b111111;
12'd1091 : mem_out_dec = 6'b111111;
12'd1092 : mem_out_dec = 6'b111111;
12'd1093 : mem_out_dec = 6'b111111;
12'd1094 : mem_out_dec = 6'b111111;
12'd1095 : mem_out_dec = 6'b111111;
12'd1096 : mem_out_dec = 6'b111111;
12'd1097 : mem_out_dec = 6'b111111;
12'd1098 : mem_out_dec = 6'b111111;
12'd1099 : mem_out_dec = 6'b111111;
12'd1100 : mem_out_dec = 6'b111111;
12'd1101 : mem_out_dec = 6'b111111;
12'd1102 : mem_out_dec = 6'b111111;
12'd1103 : mem_out_dec = 6'b111111;
12'd1104 : mem_out_dec = 6'b111111;
12'd1105 : mem_out_dec = 6'b111111;
12'd1106 : mem_out_dec = 6'b111111;
12'd1107 : mem_out_dec = 6'b111111;
12'd1108 : mem_out_dec = 6'b111111;
12'd1109 : mem_out_dec = 6'b111111;
12'd1110 : mem_out_dec = 6'b111111;
12'd1111 : mem_out_dec = 6'b000100;
12'd1112 : mem_out_dec = 6'b000100;
12'd1113 : mem_out_dec = 6'b000101;
12'd1114 : mem_out_dec = 6'b000110;
12'd1115 : mem_out_dec = 6'b000111;
12'd1116 : mem_out_dec = 6'b000111;
12'd1117 : mem_out_dec = 6'b001000;
12'd1118 : mem_out_dec = 6'b001001;
12'd1119 : mem_out_dec = 6'b001001;
12'd1120 : mem_out_dec = 6'b001010;
12'd1121 : mem_out_dec = 6'b001010;
12'd1122 : mem_out_dec = 6'b001011;
12'd1123 : mem_out_dec = 6'b001011;
12'd1124 : mem_out_dec = 6'b001011;
12'd1125 : mem_out_dec = 6'b001011;
12'd1126 : mem_out_dec = 6'b001011;
12'd1127 : mem_out_dec = 6'b001011;
12'd1128 : mem_out_dec = 6'b001011;
12'd1129 : mem_out_dec = 6'b001011;
12'd1130 : mem_out_dec = 6'b001100;
12'd1131 : mem_out_dec = 6'b001101;
12'd1132 : mem_out_dec = 6'b001110;
12'd1133 : mem_out_dec = 6'b001110;
12'd1134 : mem_out_dec = 6'b001111;
12'd1135 : mem_out_dec = 6'b010000;
12'd1136 : mem_out_dec = 6'b010000;
12'd1137 : mem_out_dec = 6'b010001;
12'd1138 : mem_out_dec = 6'b010001;
12'd1139 : mem_out_dec = 6'b010010;
12'd1140 : mem_out_dec = 6'b010010;
12'd1141 : mem_out_dec = 6'b010011;
12'd1142 : mem_out_dec = 6'b010100;
12'd1143 : mem_out_dec = 6'b010100;
12'd1144 : mem_out_dec = 6'b010100;
12'd1145 : mem_out_dec = 6'b010101;
12'd1146 : mem_out_dec = 6'b010110;
12'd1147 : mem_out_dec = 6'b010110;
12'd1148 : mem_out_dec = 6'b010111;
12'd1149 : mem_out_dec = 6'b011000;
12'd1150 : mem_out_dec = 6'b011000;
12'd1151 : mem_out_dec = 6'b011001;
12'd1152 : mem_out_dec = 6'b111111;
12'd1153 : mem_out_dec = 6'b111111;
12'd1154 : mem_out_dec = 6'b111111;
12'd1155 : mem_out_dec = 6'b111111;
12'd1156 : mem_out_dec = 6'b111111;
12'd1157 : mem_out_dec = 6'b111111;
12'd1158 : mem_out_dec = 6'b111111;
12'd1159 : mem_out_dec = 6'b111111;
12'd1160 : mem_out_dec = 6'b111111;
12'd1161 : mem_out_dec = 6'b111111;
12'd1162 : mem_out_dec = 6'b111111;
12'd1163 : mem_out_dec = 6'b111111;
12'd1164 : mem_out_dec = 6'b111111;
12'd1165 : mem_out_dec = 6'b111111;
12'd1166 : mem_out_dec = 6'b111111;
12'd1167 : mem_out_dec = 6'b111111;
12'd1168 : mem_out_dec = 6'b111111;
12'd1169 : mem_out_dec = 6'b111111;
12'd1170 : mem_out_dec = 6'b111111;
12'd1171 : mem_out_dec = 6'b111111;
12'd1172 : mem_out_dec = 6'b111111;
12'd1173 : mem_out_dec = 6'b111111;
12'd1174 : mem_out_dec = 6'b111111;
12'd1175 : mem_out_dec = 6'b111111;
12'd1176 : mem_out_dec = 6'b000100;
12'd1177 : mem_out_dec = 6'b000101;
12'd1178 : mem_out_dec = 6'b000101;
12'd1179 : mem_out_dec = 6'b000110;
12'd1180 : mem_out_dec = 6'b000111;
12'd1181 : mem_out_dec = 6'b000111;
12'd1182 : mem_out_dec = 6'b001000;
12'd1183 : mem_out_dec = 6'b001001;
12'd1184 : mem_out_dec = 6'b001001;
12'd1185 : mem_out_dec = 6'b001010;
12'd1186 : mem_out_dec = 6'b001010;
12'd1187 : mem_out_dec = 6'b001010;
12'd1188 : mem_out_dec = 6'b001010;
12'd1189 : mem_out_dec = 6'b001010;
12'd1190 : mem_out_dec = 6'b001010;
12'd1191 : mem_out_dec = 6'b001010;
12'd1192 : mem_out_dec = 6'b001010;
12'd1193 : mem_out_dec = 6'b001011;
12'd1194 : mem_out_dec = 6'b001100;
12'd1195 : mem_out_dec = 6'b001100;
12'd1196 : mem_out_dec = 6'b001101;
12'd1197 : mem_out_dec = 6'b001110;
12'd1198 : mem_out_dec = 6'b001111;
12'd1199 : mem_out_dec = 6'b010000;
12'd1200 : mem_out_dec = 6'b010000;
12'd1201 : mem_out_dec = 6'b010000;
12'd1202 : mem_out_dec = 6'b010001;
12'd1203 : mem_out_dec = 6'b010001;
12'd1204 : mem_out_dec = 6'b010010;
12'd1205 : mem_out_dec = 6'b010011;
12'd1206 : mem_out_dec = 6'b010011;
12'd1207 : mem_out_dec = 6'b010100;
12'd1208 : mem_out_dec = 6'b010100;
12'd1209 : mem_out_dec = 6'b010100;
12'd1210 : mem_out_dec = 6'b010101;
12'd1211 : mem_out_dec = 6'b010110;
12'd1212 : mem_out_dec = 6'b010110;
12'd1213 : mem_out_dec = 6'b010111;
12'd1214 : mem_out_dec = 6'b011000;
12'd1215 : mem_out_dec = 6'b011001;
12'd1216 : mem_out_dec = 6'b111111;
12'd1217 : mem_out_dec = 6'b111111;
12'd1218 : mem_out_dec = 6'b111111;
12'd1219 : mem_out_dec = 6'b111111;
12'd1220 : mem_out_dec = 6'b111111;
12'd1221 : mem_out_dec = 6'b111111;
12'd1222 : mem_out_dec = 6'b111111;
12'd1223 : mem_out_dec = 6'b111111;
12'd1224 : mem_out_dec = 6'b111111;
12'd1225 : mem_out_dec = 6'b111111;
12'd1226 : mem_out_dec = 6'b111111;
12'd1227 : mem_out_dec = 6'b111111;
12'd1228 : mem_out_dec = 6'b111111;
12'd1229 : mem_out_dec = 6'b111111;
12'd1230 : mem_out_dec = 6'b111111;
12'd1231 : mem_out_dec = 6'b111111;
12'd1232 : mem_out_dec = 6'b111111;
12'd1233 : mem_out_dec = 6'b111111;
12'd1234 : mem_out_dec = 6'b111111;
12'd1235 : mem_out_dec = 6'b111111;
12'd1236 : mem_out_dec = 6'b111111;
12'd1237 : mem_out_dec = 6'b111111;
12'd1238 : mem_out_dec = 6'b111111;
12'd1239 : mem_out_dec = 6'b111111;
12'd1240 : mem_out_dec = 6'b111111;
12'd1241 : mem_out_dec = 6'b000100;
12'd1242 : mem_out_dec = 6'b000100;
12'd1243 : mem_out_dec = 6'b000101;
12'd1244 : mem_out_dec = 6'b000110;
12'd1245 : mem_out_dec = 6'b000111;
12'd1246 : mem_out_dec = 6'b001000;
12'd1247 : mem_out_dec = 6'b001000;
12'd1248 : mem_out_dec = 6'b001001;
12'd1249 : mem_out_dec = 6'b001001;
12'd1250 : mem_out_dec = 6'b001001;
12'd1251 : mem_out_dec = 6'b001001;
12'd1252 : mem_out_dec = 6'b001001;
12'd1253 : mem_out_dec = 6'b001001;
12'd1254 : mem_out_dec = 6'b001001;
12'd1255 : mem_out_dec = 6'b001001;
12'd1256 : mem_out_dec = 6'b001010;
12'd1257 : mem_out_dec = 6'b001010;
12'd1258 : mem_out_dec = 6'b001011;
12'd1259 : mem_out_dec = 6'b001100;
12'd1260 : mem_out_dec = 6'b001101;
12'd1261 : mem_out_dec = 6'b001110;
12'd1262 : mem_out_dec = 6'b001110;
12'd1263 : mem_out_dec = 6'b001111;
12'd1264 : mem_out_dec = 6'b001111;
12'd1265 : mem_out_dec = 6'b010000;
12'd1266 : mem_out_dec = 6'b010000;
12'd1267 : mem_out_dec = 6'b010001;
12'd1268 : mem_out_dec = 6'b010001;
12'd1269 : mem_out_dec = 6'b010010;
12'd1270 : mem_out_dec = 6'b010011;
12'd1271 : mem_out_dec = 6'b010011;
12'd1272 : mem_out_dec = 6'b010011;
12'd1273 : mem_out_dec = 6'b010100;
12'd1274 : mem_out_dec = 6'b010100;
12'd1275 : mem_out_dec = 6'b010101;
12'd1276 : mem_out_dec = 6'b010110;
12'd1277 : mem_out_dec = 6'b010111;
12'd1278 : mem_out_dec = 6'b011000;
12'd1279 : mem_out_dec = 6'b011000;
12'd1280 : mem_out_dec = 6'b111111;
12'd1281 : mem_out_dec = 6'b111111;
12'd1282 : mem_out_dec = 6'b111111;
12'd1283 : mem_out_dec = 6'b111111;
12'd1284 : mem_out_dec = 6'b111111;
12'd1285 : mem_out_dec = 6'b111111;
12'd1286 : mem_out_dec = 6'b111111;
12'd1287 : mem_out_dec = 6'b111111;
12'd1288 : mem_out_dec = 6'b111111;
12'd1289 : mem_out_dec = 6'b111111;
12'd1290 : mem_out_dec = 6'b111111;
12'd1291 : mem_out_dec = 6'b111111;
12'd1292 : mem_out_dec = 6'b111111;
12'd1293 : mem_out_dec = 6'b111111;
12'd1294 : mem_out_dec = 6'b111111;
12'd1295 : mem_out_dec = 6'b111111;
12'd1296 : mem_out_dec = 6'b111111;
12'd1297 : mem_out_dec = 6'b111111;
12'd1298 : mem_out_dec = 6'b111111;
12'd1299 : mem_out_dec = 6'b111111;
12'd1300 : mem_out_dec = 6'b111111;
12'd1301 : mem_out_dec = 6'b111111;
12'd1302 : mem_out_dec = 6'b111111;
12'd1303 : mem_out_dec = 6'b111111;
12'd1304 : mem_out_dec = 6'b111111;
12'd1305 : mem_out_dec = 6'b111111;
12'd1306 : mem_out_dec = 6'b000100;
12'd1307 : mem_out_dec = 6'b000101;
12'd1308 : mem_out_dec = 6'b000110;
12'd1309 : mem_out_dec = 6'b000110;
12'd1310 : mem_out_dec = 6'b000111;
12'd1311 : mem_out_dec = 6'b001000;
12'd1312 : mem_out_dec = 6'b001000;
12'd1313 : mem_out_dec = 6'b001000;
12'd1314 : mem_out_dec = 6'b001000;
12'd1315 : mem_out_dec = 6'b001000;
12'd1316 : mem_out_dec = 6'b001000;
12'd1317 : mem_out_dec = 6'b001000;
12'd1318 : mem_out_dec = 6'b001000;
12'd1319 : mem_out_dec = 6'b001001;
12'd1320 : mem_out_dec = 6'b001001;
12'd1321 : mem_out_dec = 6'b001010;
12'd1322 : mem_out_dec = 6'b001011;
12'd1323 : mem_out_dec = 6'b001100;
12'd1324 : mem_out_dec = 6'b001100;
12'd1325 : mem_out_dec = 6'b001101;
12'd1326 : mem_out_dec = 6'b001110;
12'd1327 : mem_out_dec = 6'b001111;
12'd1328 : mem_out_dec = 6'b001111;
12'd1329 : mem_out_dec = 6'b001111;
12'd1330 : mem_out_dec = 6'b010000;
12'd1331 : mem_out_dec = 6'b010000;
12'd1332 : mem_out_dec = 6'b010001;
12'd1333 : mem_out_dec = 6'b010001;
12'd1334 : mem_out_dec = 6'b010010;
12'd1335 : mem_out_dec = 6'b010011;
12'd1336 : mem_out_dec = 6'b010010;
12'd1337 : mem_out_dec = 6'b010011;
12'd1338 : mem_out_dec = 6'b010100;
12'd1339 : mem_out_dec = 6'b010101;
12'd1340 : mem_out_dec = 6'b010110;
12'd1341 : mem_out_dec = 6'b010110;
12'd1342 : mem_out_dec = 6'b010111;
12'd1343 : mem_out_dec = 6'b011000;
12'd1344 : mem_out_dec = 6'b111111;
12'd1345 : mem_out_dec = 6'b111111;
12'd1346 : mem_out_dec = 6'b111111;
12'd1347 : mem_out_dec = 6'b111111;
12'd1348 : mem_out_dec = 6'b111111;
12'd1349 : mem_out_dec = 6'b111111;
12'd1350 : mem_out_dec = 6'b111111;
12'd1351 : mem_out_dec = 6'b111111;
12'd1352 : mem_out_dec = 6'b111111;
12'd1353 : mem_out_dec = 6'b111111;
12'd1354 : mem_out_dec = 6'b111111;
12'd1355 : mem_out_dec = 6'b111111;
12'd1356 : mem_out_dec = 6'b111111;
12'd1357 : mem_out_dec = 6'b111111;
12'd1358 : mem_out_dec = 6'b111111;
12'd1359 : mem_out_dec = 6'b111111;
12'd1360 : mem_out_dec = 6'b111111;
12'd1361 : mem_out_dec = 6'b111111;
12'd1362 : mem_out_dec = 6'b111111;
12'd1363 : mem_out_dec = 6'b111111;
12'd1364 : mem_out_dec = 6'b111111;
12'd1365 : mem_out_dec = 6'b111111;
12'd1366 : mem_out_dec = 6'b111111;
12'd1367 : mem_out_dec = 6'b111111;
12'd1368 : mem_out_dec = 6'b111111;
12'd1369 : mem_out_dec = 6'b111111;
12'd1370 : mem_out_dec = 6'b111111;
12'd1371 : mem_out_dec = 6'b000101;
12'd1372 : mem_out_dec = 6'b000101;
12'd1373 : mem_out_dec = 6'b000110;
12'd1374 : mem_out_dec = 6'b000111;
12'd1375 : mem_out_dec = 6'b001000;
12'd1376 : mem_out_dec = 6'b000111;
12'd1377 : mem_out_dec = 6'b000111;
12'd1378 : mem_out_dec = 6'b000111;
12'd1379 : mem_out_dec = 6'b000111;
12'd1380 : mem_out_dec = 6'b000111;
12'd1381 : mem_out_dec = 6'b000111;
12'd1382 : mem_out_dec = 6'b001000;
12'd1383 : mem_out_dec = 6'b001001;
12'd1384 : mem_out_dec = 6'b001001;
12'd1385 : mem_out_dec = 6'b001010;
12'd1386 : mem_out_dec = 6'b001010;
12'd1387 : mem_out_dec = 6'b001011;
12'd1388 : mem_out_dec = 6'b001100;
12'd1389 : mem_out_dec = 6'b001101;
12'd1390 : mem_out_dec = 6'b001110;
12'd1391 : mem_out_dec = 6'b001110;
12'd1392 : mem_out_dec = 6'b001111;
12'd1393 : mem_out_dec = 6'b001111;
12'd1394 : mem_out_dec = 6'b010000;
12'd1395 : mem_out_dec = 6'b010000;
12'd1396 : mem_out_dec = 6'b010001;
12'd1397 : mem_out_dec = 6'b010001;
12'd1398 : mem_out_dec = 6'b010010;
12'd1399 : mem_out_dec = 6'b010010;
12'd1400 : mem_out_dec = 6'b010010;
12'd1401 : mem_out_dec = 6'b010011;
12'd1402 : mem_out_dec = 6'b010100;
12'd1403 : mem_out_dec = 6'b010100;
12'd1404 : mem_out_dec = 6'b010101;
12'd1405 : mem_out_dec = 6'b010110;
12'd1406 : mem_out_dec = 6'b010111;
12'd1407 : mem_out_dec = 6'b010111;
12'd1408 : mem_out_dec = 6'b111111;
12'd1409 : mem_out_dec = 6'b111111;
12'd1410 : mem_out_dec = 6'b111111;
12'd1411 : mem_out_dec = 6'b111111;
12'd1412 : mem_out_dec = 6'b111111;
12'd1413 : mem_out_dec = 6'b111111;
12'd1414 : mem_out_dec = 6'b111111;
12'd1415 : mem_out_dec = 6'b111111;
12'd1416 : mem_out_dec = 6'b111111;
12'd1417 : mem_out_dec = 6'b111111;
12'd1418 : mem_out_dec = 6'b111111;
12'd1419 : mem_out_dec = 6'b111111;
12'd1420 : mem_out_dec = 6'b111111;
12'd1421 : mem_out_dec = 6'b111111;
12'd1422 : mem_out_dec = 6'b111111;
12'd1423 : mem_out_dec = 6'b111111;
12'd1424 : mem_out_dec = 6'b111111;
12'd1425 : mem_out_dec = 6'b111111;
12'd1426 : mem_out_dec = 6'b111111;
12'd1427 : mem_out_dec = 6'b111111;
12'd1428 : mem_out_dec = 6'b111111;
12'd1429 : mem_out_dec = 6'b111111;
12'd1430 : mem_out_dec = 6'b111111;
12'd1431 : mem_out_dec = 6'b111111;
12'd1432 : mem_out_dec = 6'b111111;
12'd1433 : mem_out_dec = 6'b111111;
12'd1434 : mem_out_dec = 6'b111111;
12'd1435 : mem_out_dec = 6'b111111;
12'd1436 : mem_out_dec = 6'b000101;
12'd1437 : mem_out_dec = 6'b000110;
12'd1438 : mem_out_dec = 6'b000111;
12'd1439 : mem_out_dec = 6'b000111;
12'd1440 : mem_out_dec = 6'b000110;
12'd1441 : mem_out_dec = 6'b000110;
12'd1442 : mem_out_dec = 6'b000110;
12'd1443 : mem_out_dec = 6'b000110;
12'd1444 : mem_out_dec = 6'b000110;
12'd1445 : mem_out_dec = 6'b000111;
12'd1446 : mem_out_dec = 6'b000111;
12'd1447 : mem_out_dec = 6'b001000;
12'd1448 : mem_out_dec = 6'b001001;
12'd1449 : mem_out_dec = 6'b001001;
12'd1450 : mem_out_dec = 6'b001010;
12'd1451 : mem_out_dec = 6'b001011;
12'd1452 : mem_out_dec = 6'b001100;
12'd1453 : mem_out_dec = 6'b001100;
12'd1454 : mem_out_dec = 6'b001101;
12'd1455 : mem_out_dec = 6'b001110;
12'd1456 : mem_out_dec = 6'b001110;
12'd1457 : mem_out_dec = 6'b001111;
12'd1458 : mem_out_dec = 6'b001111;
12'd1459 : mem_out_dec = 6'b010000;
12'd1460 : mem_out_dec = 6'b010000;
12'd1461 : mem_out_dec = 6'b010001;
12'd1462 : mem_out_dec = 6'b010001;
12'd1463 : mem_out_dec = 6'b010010;
12'd1464 : mem_out_dec = 6'b010010;
12'd1465 : mem_out_dec = 6'b010011;
12'd1466 : mem_out_dec = 6'b010011;
12'd1467 : mem_out_dec = 6'b010100;
12'd1468 : mem_out_dec = 6'b010101;
12'd1469 : mem_out_dec = 6'b010110;
12'd1470 : mem_out_dec = 6'b010110;
12'd1471 : mem_out_dec = 6'b010111;
12'd1472 : mem_out_dec = 6'b111111;
12'd1473 : mem_out_dec = 6'b111111;
12'd1474 : mem_out_dec = 6'b111111;
12'd1475 : mem_out_dec = 6'b111111;
12'd1476 : mem_out_dec = 6'b111111;
12'd1477 : mem_out_dec = 6'b111111;
12'd1478 : mem_out_dec = 6'b111111;
12'd1479 : mem_out_dec = 6'b111111;
12'd1480 : mem_out_dec = 6'b111111;
12'd1481 : mem_out_dec = 6'b111111;
12'd1482 : mem_out_dec = 6'b111111;
12'd1483 : mem_out_dec = 6'b111111;
12'd1484 : mem_out_dec = 6'b111111;
12'd1485 : mem_out_dec = 6'b111111;
12'd1486 : mem_out_dec = 6'b111111;
12'd1487 : mem_out_dec = 6'b111111;
12'd1488 : mem_out_dec = 6'b111111;
12'd1489 : mem_out_dec = 6'b111111;
12'd1490 : mem_out_dec = 6'b111111;
12'd1491 : mem_out_dec = 6'b111111;
12'd1492 : mem_out_dec = 6'b111111;
12'd1493 : mem_out_dec = 6'b111111;
12'd1494 : mem_out_dec = 6'b111111;
12'd1495 : mem_out_dec = 6'b111111;
12'd1496 : mem_out_dec = 6'b111111;
12'd1497 : mem_out_dec = 6'b111111;
12'd1498 : mem_out_dec = 6'b111111;
12'd1499 : mem_out_dec = 6'b111111;
12'd1500 : mem_out_dec = 6'b111111;
12'd1501 : mem_out_dec = 6'b000101;
12'd1502 : mem_out_dec = 6'b000110;
12'd1503 : mem_out_dec = 6'b000110;
12'd1504 : mem_out_dec = 6'b000110;
12'd1505 : mem_out_dec = 6'b000110;
12'd1506 : mem_out_dec = 6'b000101;
12'd1507 : mem_out_dec = 6'b000101;
12'd1508 : mem_out_dec = 6'b000110;
12'd1509 : mem_out_dec = 6'b000111;
12'd1510 : mem_out_dec = 6'b000111;
12'd1511 : mem_out_dec = 6'b001000;
12'd1512 : mem_out_dec = 6'b001000;
12'd1513 : mem_out_dec = 6'b001001;
12'd1514 : mem_out_dec = 6'b001010;
12'd1515 : mem_out_dec = 6'b001011;
12'd1516 : mem_out_dec = 6'b001011;
12'd1517 : mem_out_dec = 6'b001100;
12'd1518 : mem_out_dec = 6'b001101;
12'd1519 : mem_out_dec = 6'b001110;
12'd1520 : mem_out_dec = 6'b001110;
12'd1521 : mem_out_dec = 6'b001110;
12'd1522 : mem_out_dec = 6'b001111;
12'd1523 : mem_out_dec = 6'b001111;
12'd1524 : mem_out_dec = 6'b010000;
12'd1525 : mem_out_dec = 6'b010000;
12'd1526 : mem_out_dec = 6'b010001;
12'd1527 : mem_out_dec = 6'b010001;
12'd1528 : mem_out_dec = 6'b010001;
12'd1529 : mem_out_dec = 6'b010010;
12'd1530 : mem_out_dec = 6'b010011;
12'd1531 : mem_out_dec = 6'b010100;
12'd1532 : mem_out_dec = 6'b010101;
12'd1533 : mem_out_dec = 6'b010101;
12'd1534 : mem_out_dec = 6'b010110;
12'd1535 : mem_out_dec = 6'b010110;
12'd1536 : mem_out_dec = 6'b111111;
12'd1537 : mem_out_dec = 6'b111111;
12'd1538 : mem_out_dec = 6'b111111;
12'd1539 : mem_out_dec = 6'b111111;
12'd1540 : mem_out_dec = 6'b111111;
12'd1541 : mem_out_dec = 6'b111111;
12'd1542 : mem_out_dec = 6'b111111;
12'd1543 : mem_out_dec = 6'b111111;
12'd1544 : mem_out_dec = 6'b111111;
12'd1545 : mem_out_dec = 6'b111111;
12'd1546 : mem_out_dec = 6'b111111;
12'd1547 : mem_out_dec = 6'b111111;
12'd1548 : mem_out_dec = 6'b111111;
12'd1549 : mem_out_dec = 6'b111111;
12'd1550 : mem_out_dec = 6'b111111;
12'd1551 : mem_out_dec = 6'b111111;
12'd1552 : mem_out_dec = 6'b111111;
12'd1553 : mem_out_dec = 6'b111111;
12'd1554 : mem_out_dec = 6'b111111;
12'd1555 : mem_out_dec = 6'b111111;
12'd1556 : mem_out_dec = 6'b111111;
12'd1557 : mem_out_dec = 6'b111111;
12'd1558 : mem_out_dec = 6'b111111;
12'd1559 : mem_out_dec = 6'b111111;
12'd1560 : mem_out_dec = 6'b111111;
12'd1561 : mem_out_dec = 6'b111111;
12'd1562 : mem_out_dec = 6'b111111;
12'd1563 : mem_out_dec = 6'b111111;
12'd1564 : mem_out_dec = 6'b111111;
12'd1565 : mem_out_dec = 6'b111111;
12'd1566 : mem_out_dec = 6'b000100;
12'd1567 : mem_out_dec = 6'b000100;
12'd1568 : mem_out_dec = 6'b000100;
12'd1569 : mem_out_dec = 6'b000100;
12'd1570 : mem_out_dec = 6'b000100;
12'd1571 : mem_out_dec = 6'b000101;
12'd1572 : mem_out_dec = 6'b000101;
12'd1573 : mem_out_dec = 6'b000110;
12'd1574 : mem_out_dec = 6'b000111;
12'd1575 : mem_out_dec = 6'b000111;
12'd1576 : mem_out_dec = 6'b000111;
12'd1577 : mem_out_dec = 6'b001000;
12'd1578 : mem_out_dec = 6'b001001;
12'd1579 : mem_out_dec = 6'b001010;
12'd1580 : mem_out_dec = 6'b001010;
12'd1581 : mem_out_dec = 6'b001011;
12'd1582 : mem_out_dec = 6'b001100;
12'd1583 : mem_out_dec = 6'b001101;
12'd1584 : mem_out_dec = 6'b001101;
12'd1585 : mem_out_dec = 6'b001101;
12'd1586 : mem_out_dec = 6'b001110;
12'd1587 : mem_out_dec = 6'b001110;
12'd1588 : mem_out_dec = 6'b001111;
12'd1589 : mem_out_dec = 6'b001111;
12'd1590 : mem_out_dec = 6'b010000;
12'd1591 : mem_out_dec = 6'b010001;
12'd1592 : mem_out_dec = 6'b010001;
12'd1593 : mem_out_dec = 6'b010001;
12'd1594 : mem_out_dec = 6'b010010;
12'd1595 : mem_out_dec = 6'b010010;
12'd1596 : mem_out_dec = 6'b010011;
12'd1597 : mem_out_dec = 6'b010011;
12'd1598 : mem_out_dec = 6'b010100;
12'd1599 : mem_out_dec = 6'b010100;
12'd1600 : mem_out_dec = 6'b111111;
12'd1601 : mem_out_dec = 6'b111111;
12'd1602 : mem_out_dec = 6'b111111;
12'd1603 : mem_out_dec = 6'b111111;
12'd1604 : mem_out_dec = 6'b111111;
12'd1605 : mem_out_dec = 6'b111111;
12'd1606 : mem_out_dec = 6'b111111;
12'd1607 : mem_out_dec = 6'b111111;
12'd1608 : mem_out_dec = 6'b111111;
12'd1609 : mem_out_dec = 6'b111111;
12'd1610 : mem_out_dec = 6'b111111;
12'd1611 : mem_out_dec = 6'b111111;
12'd1612 : mem_out_dec = 6'b111111;
12'd1613 : mem_out_dec = 6'b111111;
12'd1614 : mem_out_dec = 6'b111111;
12'd1615 : mem_out_dec = 6'b111111;
12'd1616 : mem_out_dec = 6'b111111;
12'd1617 : mem_out_dec = 6'b111111;
12'd1618 : mem_out_dec = 6'b111111;
12'd1619 : mem_out_dec = 6'b111111;
12'd1620 : mem_out_dec = 6'b111111;
12'd1621 : mem_out_dec = 6'b111111;
12'd1622 : mem_out_dec = 6'b111111;
12'd1623 : mem_out_dec = 6'b111111;
12'd1624 : mem_out_dec = 6'b111111;
12'd1625 : mem_out_dec = 6'b111111;
12'd1626 : mem_out_dec = 6'b111111;
12'd1627 : mem_out_dec = 6'b111111;
12'd1628 : mem_out_dec = 6'b111111;
12'd1629 : mem_out_dec = 6'b111111;
12'd1630 : mem_out_dec = 6'b111111;
12'd1631 : mem_out_dec = 6'b000100;
12'd1632 : mem_out_dec = 6'b000011;
12'd1633 : mem_out_dec = 6'b000011;
12'd1634 : mem_out_dec = 6'b000100;
12'd1635 : mem_out_dec = 6'b000100;
12'd1636 : mem_out_dec = 6'b000101;
12'd1637 : mem_out_dec = 6'b000110;
12'd1638 : mem_out_dec = 6'b000110;
12'd1639 : mem_out_dec = 6'b000111;
12'd1640 : mem_out_dec = 6'b000111;
12'd1641 : mem_out_dec = 6'b001000;
12'd1642 : mem_out_dec = 6'b001001;
12'd1643 : mem_out_dec = 6'b001001;
12'd1644 : mem_out_dec = 6'b001010;
12'd1645 : mem_out_dec = 6'b001011;
12'd1646 : mem_out_dec = 6'b001100;
12'd1647 : mem_out_dec = 6'b001101;
12'd1648 : mem_out_dec = 6'b001101;
12'd1649 : mem_out_dec = 6'b001101;
12'd1650 : mem_out_dec = 6'b001110;
12'd1651 : mem_out_dec = 6'b001110;
12'd1652 : mem_out_dec = 6'b001110;
12'd1653 : mem_out_dec = 6'b001111;
12'd1654 : mem_out_dec = 6'b010000;
12'd1655 : mem_out_dec = 6'b010000;
12'd1656 : mem_out_dec = 6'b010001;
12'd1657 : mem_out_dec = 6'b010001;
12'd1658 : mem_out_dec = 6'b010001;
12'd1659 : mem_out_dec = 6'b010010;
12'd1660 : mem_out_dec = 6'b010010;
12'd1661 : mem_out_dec = 6'b010011;
12'd1662 : mem_out_dec = 6'b010011;
12'd1663 : mem_out_dec = 6'b010100;
12'd1664 : mem_out_dec = 6'b111111;
12'd1665 : mem_out_dec = 6'b111111;
12'd1666 : mem_out_dec = 6'b111111;
12'd1667 : mem_out_dec = 6'b111111;
12'd1668 : mem_out_dec = 6'b111111;
12'd1669 : mem_out_dec = 6'b111111;
12'd1670 : mem_out_dec = 6'b111111;
12'd1671 : mem_out_dec = 6'b111111;
12'd1672 : mem_out_dec = 6'b111111;
12'd1673 : mem_out_dec = 6'b111111;
12'd1674 : mem_out_dec = 6'b111111;
12'd1675 : mem_out_dec = 6'b111111;
12'd1676 : mem_out_dec = 6'b111111;
12'd1677 : mem_out_dec = 6'b111111;
12'd1678 : mem_out_dec = 6'b111111;
12'd1679 : mem_out_dec = 6'b111111;
12'd1680 : mem_out_dec = 6'b111111;
12'd1681 : mem_out_dec = 6'b111111;
12'd1682 : mem_out_dec = 6'b111111;
12'd1683 : mem_out_dec = 6'b111111;
12'd1684 : mem_out_dec = 6'b111111;
12'd1685 : mem_out_dec = 6'b111111;
12'd1686 : mem_out_dec = 6'b111111;
12'd1687 : mem_out_dec = 6'b111111;
12'd1688 : mem_out_dec = 6'b111111;
12'd1689 : mem_out_dec = 6'b111111;
12'd1690 : mem_out_dec = 6'b111111;
12'd1691 : mem_out_dec = 6'b111111;
12'd1692 : mem_out_dec = 6'b111111;
12'd1693 : mem_out_dec = 6'b111111;
12'd1694 : mem_out_dec = 6'b111111;
12'd1695 : mem_out_dec = 6'b111111;
12'd1696 : mem_out_dec = 6'b000011;
12'd1697 : mem_out_dec = 6'b000011;
12'd1698 : mem_out_dec = 6'b000100;
12'd1699 : mem_out_dec = 6'b000100;
12'd1700 : mem_out_dec = 6'b000101;
12'd1701 : mem_out_dec = 6'b000101;
12'd1702 : mem_out_dec = 6'b000110;
12'd1703 : mem_out_dec = 6'b000111;
12'd1704 : mem_out_dec = 6'b000111;
12'd1705 : mem_out_dec = 6'b001000;
12'd1706 : mem_out_dec = 6'b001000;
12'd1707 : mem_out_dec = 6'b001001;
12'd1708 : mem_out_dec = 6'b001010;
12'd1709 : mem_out_dec = 6'b001011;
12'd1710 : mem_out_dec = 6'b001100;
12'd1711 : mem_out_dec = 6'b001100;
12'd1712 : mem_out_dec = 6'b001100;
12'd1713 : mem_out_dec = 6'b001101;
12'd1714 : mem_out_dec = 6'b001101;
12'd1715 : mem_out_dec = 6'b001110;
12'd1716 : mem_out_dec = 6'b001110;
12'd1717 : mem_out_dec = 6'b001111;
12'd1718 : mem_out_dec = 6'b001111;
12'd1719 : mem_out_dec = 6'b010000;
12'd1720 : mem_out_dec = 6'b010000;
12'd1721 : mem_out_dec = 6'b010000;
12'd1722 : mem_out_dec = 6'b010001;
12'd1723 : mem_out_dec = 6'b010001;
12'd1724 : mem_out_dec = 6'b010010;
12'd1725 : mem_out_dec = 6'b010010;
12'd1726 : mem_out_dec = 6'b010011;
12'd1727 : mem_out_dec = 6'b010011;
12'd1728 : mem_out_dec = 6'b111111;
12'd1729 : mem_out_dec = 6'b111111;
12'd1730 : mem_out_dec = 6'b111111;
12'd1731 : mem_out_dec = 6'b111111;
12'd1732 : mem_out_dec = 6'b111111;
12'd1733 : mem_out_dec = 6'b111111;
12'd1734 : mem_out_dec = 6'b111111;
12'd1735 : mem_out_dec = 6'b111111;
12'd1736 : mem_out_dec = 6'b111111;
12'd1737 : mem_out_dec = 6'b111111;
12'd1738 : mem_out_dec = 6'b111111;
12'd1739 : mem_out_dec = 6'b111111;
12'd1740 : mem_out_dec = 6'b111111;
12'd1741 : mem_out_dec = 6'b111111;
12'd1742 : mem_out_dec = 6'b111111;
12'd1743 : mem_out_dec = 6'b111111;
12'd1744 : mem_out_dec = 6'b111111;
12'd1745 : mem_out_dec = 6'b111111;
12'd1746 : mem_out_dec = 6'b111111;
12'd1747 : mem_out_dec = 6'b111111;
12'd1748 : mem_out_dec = 6'b111111;
12'd1749 : mem_out_dec = 6'b111111;
12'd1750 : mem_out_dec = 6'b111111;
12'd1751 : mem_out_dec = 6'b111111;
12'd1752 : mem_out_dec = 6'b111111;
12'd1753 : mem_out_dec = 6'b111111;
12'd1754 : mem_out_dec = 6'b111111;
12'd1755 : mem_out_dec = 6'b111111;
12'd1756 : mem_out_dec = 6'b111111;
12'd1757 : mem_out_dec = 6'b111111;
12'd1758 : mem_out_dec = 6'b111111;
12'd1759 : mem_out_dec = 6'b111111;
12'd1760 : mem_out_dec = 6'b111111;
12'd1761 : mem_out_dec = 6'b000011;
12'd1762 : mem_out_dec = 6'b000011;
12'd1763 : mem_out_dec = 6'b000100;
12'd1764 : mem_out_dec = 6'b000101;
12'd1765 : mem_out_dec = 6'b000101;
12'd1766 : mem_out_dec = 6'b000110;
12'd1767 : mem_out_dec = 6'b000111;
12'd1768 : mem_out_dec = 6'b000111;
12'd1769 : mem_out_dec = 6'b000111;
12'd1770 : mem_out_dec = 6'b001000;
12'd1771 : mem_out_dec = 6'b001001;
12'd1772 : mem_out_dec = 6'b001010;
12'd1773 : mem_out_dec = 6'b001011;
12'd1774 : mem_out_dec = 6'b001011;
12'd1775 : mem_out_dec = 6'b001100;
12'd1776 : mem_out_dec = 6'b001100;
12'd1777 : mem_out_dec = 6'b001101;
12'd1778 : mem_out_dec = 6'b001101;
12'd1779 : mem_out_dec = 6'b001101;
12'd1780 : mem_out_dec = 6'b001110;
12'd1781 : mem_out_dec = 6'b001111;
12'd1782 : mem_out_dec = 6'b001111;
12'd1783 : mem_out_dec = 6'b010000;
12'd1784 : mem_out_dec = 6'b010000;
12'd1785 : mem_out_dec = 6'b010000;
12'd1786 : mem_out_dec = 6'b010000;
12'd1787 : mem_out_dec = 6'b010001;
12'd1788 : mem_out_dec = 6'b010001;
12'd1789 : mem_out_dec = 6'b010010;
12'd1790 : mem_out_dec = 6'b010010;
12'd1791 : mem_out_dec = 6'b010011;
12'd1792 : mem_out_dec = 6'b111111;
12'd1793 : mem_out_dec = 6'b111111;
12'd1794 : mem_out_dec = 6'b111111;
12'd1795 : mem_out_dec = 6'b111111;
12'd1796 : mem_out_dec = 6'b111111;
12'd1797 : mem_out_dec = 6'b111111;
12'd1798 : mem_out_dec = 6'b111111;
12'd1799 : mem_out_dec = 6'b111111;
12'd1800 : mem_out_dec = 6'b111111;
12'd1801 : mem_out_dec = 6'b111111;
12'd1802 : mem_out_dec = 6'b111111;
12'd1803 : mem_out_dec = 6'b111111;
12'd1804 : mem_out_dec = 6'b111111;
12'd1805 : mem_out_dec = 6'b111111;
12'd1806 : mem_out_dec = 6'b111111;
12'd1807 : mem_out_dec = 6'b111111;
12'd1808 : mem_out_dec = 6'b111111;
12'd1809 : mem_out_dec = 6'b111111;
12'd1810 : mem_out_dec = 6'b111111;
12'd1811 : mem_out_dec = 6'b111111;
12'd1812 : mem_out_dec = 6'b111111;
12'd1813 : mem_out_dec = 6'b111111;
12'd1814 : mem_out_dec = 6'b111111;
12'd1815 : mem_out_dec = 6'b111111;
12'd1816 : mem_out_dec = 6'b111111;
12'd1817 : mem_out_dec = 6'b111111;
12'd1818 : mem_out_dec = 6'b111111;
12'd1819 : mem_out_dec = 6'b111111;
12'd1820 : mem_out_dec = 6'b111111;
12'd1821 : mem_out_dec = 6'b111111;
12'd1822 : mem_out_dec = 6'b111111;
12'd1823 : mem_out_dec = 6'b111111;
12'd1824 : mem_out_dec = 6'b111111;
12'd1825 : mem_out_dec = 6'b111111;
12'd1826 : mem_out_dec = 6'b000011;
12'd1827 : mem_out_dec = 6'b000100;
12'd1828 : mem_out_dec = 6'b000100;
12'd1829 : mem_out_dec = 6'b000101;
12'd1830 : mem_out_dec = 6'b000110;
12'd1831 : mem_out_dec = 6'b000110;
12'd1832 : mem_out_dec = 6'b000110;
12'd1833 : mem_out_dec = 6'b000111;
12'd1834 : mem_out_dec = 6'b001000;
12'd1835 : mem_out_dec = 6'b001001;
12'd1836 : mem_out_dec = 6'b001010;
12'd1837 : mem_out_dec = 6'b001010;
12'd1838 : mem_out_dec = 6'b001011;
12'd1839 : mem_out_dec = 6'b001100;
12'd1840 : mem_out_dec = 6'b001100;
12'd1841 : mem_out_dec = 6'b001100;
12'd1842 : mem_out_dec = 6'b001101;
12'd1843 : mem_out_dec = 6'b001101;
12'd1844 : mem_out_dec = 6'b001110;
12'd1845 : mem_out_dec = 6'b001110;
12'd1846 : mem_out_dec = 6'b001111;
12'd1847 : mem_out_dec = 6'b010000;
12'd1848 : mem_out_dec = 6'b001111;
12'd1849 : mem_out_dec = 6'b001111;
12'd1850 : mem_out_dec = 6'b010000;
12'd1851 : mem_out_dec = 6'b010000;
12'd1852 : mem_out_dec = 6'b010001;
12'd1853 : mem_out_dec = 6'b010001;
12'd1854 : mem_out_dec = 6'b010010;
12'd1855 : mem_out_dec = 6'b010010;
12'd1856 : mem_out_dec = 6'b111111;
12'd1857 : mem_out_dec = 6'b111111;
12'd1858 : mem_out_dec = 6'b111111;
12'd1859 : mem_out_dec = 6'b111111;
12'd1860 : mem_out_dec = 6'b111111;
12'd1861 : mem_out_dec = 6'b111111;
12'd1862 : mem_out_dec = 6'b111111;
12'd1863 : mem_out_dec = 6'b111111;
12'd1864 : mem_out_dec = 6'b111111;
12'd1865 : mem_out_dec = 6'b111111;
12'd1866 : mem_out_dec = 6'b111111;
12'd1867 : mem_out_dec = 6'b111111;
12'd1868 : mem_out_dec = 6'b111111;
12'd1869 : mem_out_dec = 6'b111111;
12'd1870 : mem_out_dec = 6'b111111;
12'd1871 : mem_out_dec = 6'b111111;
12'd1872 : mem_out_dec = 6'b111111;
12'd1873 : mem_out_dec = 6'b111111;
12'd1874 : mem_out_dec = 6'b111111;
12'd1875 : mem_out_dec = 6'b111111;
12'd1876 : mem_out_dec = 6'b111111;
12'd1877 : mem_out_dec = 6'b111111;
12'd1878 : mem_out_dec = 6'b111111;
12'd1879 : mem_out_dec = 6'b111111;
12'd1880 : mem_out_dec = 6'b111111;
12'd1881 : mem_out_dec = 6'b111111;
12'd1882 : mem_out_dec = 6'b111111;
12'd1883 : mem_out_dec = 6'b111111;
12'd1884 : mem_out_dec = 6'b111111;
12'd1885 : mem_out_dec = 6'b111111;
12'd1886 : mem_out_dec = 6'b111111;
12'd1887 : mem_out_dec = 6'b111111;
12'd1888 : mem_out_dec = 6'b111111;
12'd1889 : mem_out_dec = 6'b111111;
12'd1890 : mem_out_dec = 6'b111111;
12'd1891 : mem_out_dec = 6'b000100;
12'd1892 : mem_out_dec = 6'b000100;
12'd1893 : mem_out_dec = 6'b000101;
12'd1894 : mem_out_dec = 6'b000101;
12'd1895 : mem_out_dec = 6'b000110;
12'd1896 : mem_out_dec = 6'b000110;
12'd1897 : mem_out_dec = 6'b000111;
12'd1898 : mem_out_dec = 6'b001000;
12'd1899 : mem_out_dec = 6'b001001;
12'd1900 : mem_out_dec = 6'b001001;
12'd1901 : mem_out_dec = 6'b001010;
12'd1902 : mem_out_dec = 6'b001011;
12'd1903 : mem_out_dec = 6'b001100;
12'd1904 : mem_out_dec = 6'b001100;
12'd1905 : mem_out_dec = 6'b001100;
12'd1906 : mem_out_dec = 6'b001100;
12'd1907 : mem_out_dec = 6'b001101;
12'd1908 : mem_out_dec = 6'b001110;
12'd1909 : mem_out_dec = 6'b001110;
12'd1910 : mem_out_dec = 6'b001111;
12'd1911 : mem_out_dec = 6'b001111;
12'd1912 : mem_out_dec = 6'b001111;
12'd1913 : mem_out_dec = 6'b001111;
12'd1914 : mem_out_dec = 6'b001111;
12'd1915 : mem_out_dec = 6'b010000;
12'd1916 : mem_out_dec = 6'b010000;
12'd1917 : mem_out_dec = 6'b010001;
12'd1918 : mem_out_dec = 6'b010001;
12'd1919 : mem_out_dec = 6'b010010;
12'd1920 : mem_out_dec = 6'b111111;
12'd1921 : mem_out_dec = 6'b111111;
12'd1922 : mem_out_dec = 6'b111111;
12'd1923 : mem_out_dec = 6'b111111;
12'd1924 : mem_out_dec = 6'b111111;
12'd1925 : mem_out_dec = 6'b111111;
12'd1926 : mem_out_dec = 6'b111111;
12'd1927 : mem_out_dec = 6'b111111;
12'd1928 : mem_out_dec = 6'b111111;
12'd1929 : mem_out_dec = 6'b111111;
12'd1930 : mem_out_dec = 6'b111111;
12'd1931 : mem_out_dec = 6'b111111;
12'd1932 : mem_out_dec = 6'b111111;
12'd1933 : mem_out_dec = 6'b111111;
12'd1934 : mem_out_dec = 6'b111111;
12'd1935 : mem_out_dec = 6'b111111;
12'd1936 : mem_out_dec = 6'b111111;
12'd1937 : mem_out_dec = 6'b111111;
12'd1938 : mem_out_dec = 6'b111111;
12'd1939 : mem_out_dec = 6'b111111;
12'd1940 : mem_out_dec = 6'b111111;
12'd1941 : mem_out_dec = 6'b111111;
12'd1942 : mem_out_dec = 6'b111111;
12'd1943 : mem_out_dec = 6'b111111;
12'd1944 : mem_out_dec = 6'b111111;
12'd1945 : mem_out_dec = 6'b111111;
12'd1946 : mem_out_dec = 6'b111111;
12'd1947 : mem_out_dec = 6'b111111;
12'd1948 : mem_out_dec = 6'b111111;
12'd1949 : mem_out_dec = 6'b111111;
12'd1950 : mem_out_dec = 6'b111111;
12'd1951 : mem_out_dec = 6'b111111;
12'd1952 : mem_out_dec = 6'b111111;
12'd1953 : mem_out_dec = 6'b111111;
12'd1954 : mem_out_dec = 6'b111111;
12'd1955 : mem_out_dec = 6'b111111;
12'd1956 : mem_out_dec = 6'b000100;
12'd1957 : mem_out_dec = 6'b000101;
12'd1958 : mem_out_dec = 6'b000101;
12'd1959 : mem_out_dec = 6'b000110;
12'd1960 : mem_out_dec = 6'b000110;
12'd1961 : mem_out_dec = 6'b000111;
12'd1962 : mem_out_dec = 6'b001000;
12'd1963 : mem_out_dec = 6'b001000;
12'd1964 : mem_out_dec = 6'b001001;
12'd1965 : mem_out_dec = 6'b001010;
12'd1966 : mem_out_dec = 6'b001011;
12'd1967 : mem_out_dec = 6'b001011;
12'd1968 : mem_out_dec = 6'b001011;
12'd1969 : mem_out_dec = 6'b001100;
12'd1970 : mem_out_dec = 6'b001100;
12'd1971 : mem_out_dec = 6'b001101;
12'd1972 : mem_out_dec = 6'b001101;
12'd1973 : mem_out_dec = 6'b001110;
12'd1974 : mem_out_dec = 6'b001111;
12'd1975 : mem_out_dec = 6'b001111;
12'd1976 : mem_out_dec = 6'b001110;
12'd1977 : mem_out_dec = 6'b001110;
12'd1978 : mem_out_dec = 6'b001111;
12'd1979 : mem_out_dec = 6'b001111;
12'd1980 : mem_out_dec = 6'b010000;
12'd1981 : mem_out_dec = 6'b010000;
12'd1982 : mem_out_dec = 6'b010001;
12'd1983 : mem_out_dec = 6'b010001;
12'd1984 : mem_out_dec = 6'b111111;
12'd1985 : mem_out_dec = 6'b111111;
12'd1986 : mem_out_dec = 6'b111111;
12'd1987 : mem_out_dec = 6'b111111;
12'd1988 : mem_out_dec = 6'b111111;
12'd1989 : mem_out_dec = 6'b111111;
12'd1990 : mem_out_dec = 6'b111111;
12'd1991 : mem_out_dec = 6'b111111;
12'd1992 : mem_out_dec = 6'b111111;
12'd1993 : mem_out_dec = 6'b111111;
12'd1994 : mem_out_dec = 6'b111111;
12'd1995 : mem_out_dec = 6'b111111;
12'd1996 : mem_out_dec = 6'b111111;
12'd1997 : mem_out_dec = 6'b111111;
12'd1998 : mem_out_dec = 6'b111111;
12'd1999 : mem_out_dec = 6'b111111;
12'd2000 : mem_out_dec = 6'b111111;
12'd2001 : mem_out_dec = 6'b111111;
12'd2002 : mem_out_dec = 6'b111111;
12'd2003 : mem_out_dec = 6'b111111;
12'd2004 : mem_out_dec = 6'b111111;
12'd2005 : mem_out_dec = 6'b111111;
12'd2006 : mem_out_dec = 6'b111111;
12'd2007 : mem_out_dec = 6'b111111;
12'd2008 : mem_out_dec = 6'b111111;
12'd2009 : mem_out_dec = 6'b111111;
12'd2010 : mem_out_dec = 6'b111111;
12'd2011 : mem_out_dec = 6'b111111;
12'd2012 : mem_out_dec = 6'b111111;
12'd2013 : mem_out_dec = 6'b111111;
12'd2014 : mem_out_dec = 6'b111111;
12'd2015 : mem_out_dec = 6'b111111;
12'd2016 : mem_out_dec = 6'b111111;
12'd2017 : mem_out_dec = 6'b111111;
12'd2018 : mem_out_dec = 6'b111111;
12'd2019 : mem_out_dec = 6'b111111;
12'd2020 : mem_out_dec = 6'b111111;
12'd2021 : mem_out_dec = 6'b000100;
12'd2022 : mem_out_dec = 6'b000101;
12'd2023 : mem_out_dec = 6'b000110;
12'd2024 : mem_out_dec = 6'b000110;
12'd2025 : mem_out_dec = 6'b000111;
12'd2026 : mem_out_dec = 6'b000111;
12'd2027 : mem_out_dec = 6'b001000;
12'd2028 : mem_out_dec = 6'b001001;
12'd2029 : mem_out_dec = 6'b001010;
12'd2030 : mem_out_dec = 6'b001010;
12'd2031 : mem_out_dec = 6'b001011;
12'd2032 : mem_out_dec = 6'b001011;
12'd2033 : mem_out_dec = 6'b001011;
12'd2034 : mem_out_dec = 6'b001100;
12'd2035 : mem_out_dec = 6'b001101;
12'd2036 : mem_out_dec = 6'b001101;
12'd2037 : mem_out_dec = 6'b001110;
12'd2038 : mem_out_dec = 6'b001110;
12'd2039 : mem_out_dec = 6'b001110;
12'd2040 : mem_out_dec = 6'b001101;
12'd2041 : mem_out_dec = 6'b001110;
12'd2042 : mem_out_dec = 6'b001110;
12'd2043 : mem_out_dec = 6'b001111;
12'd2044 : mem_out_dec = 6'b001111;
12'd2045 : mem_out_dec = 6'b010000;
12'd2046 : mem_out_dec = 6'b010000;
12'd2047 : mem_out_dec = 6'b010001;
12'd2048 : mem_out_dec = 6'b111111;
12'd2049 : mem_out_dec = 6'b111111;
12'd2050 : mem_out_dec = 6'b111111;
12'd2051 : mem_out_dec = 6'b111111;
12'd2052 : mem_out_dec = 6'b111111;
12'd2053 : mem_out_dec = 6'b111111;
12'd2054 : mem_out_dec = 6'b111111;
12'd2055 : mem_out_dec = 6'b111111;
12'd2056 : mem_out_dec = 6'b111111;
12'd2057 : mem_out_dec = 6'b111111;
12'd2058 : mem_out_dec = 6'b111111;
12'd2059 : mem_out_dec = 6'b111111;
12'd2060 : mem_out_dec = 6'b111111;
12'd2061 : mem_out_dec = 6'b111111;
12'd2062 : mem_out_dec = 6'b111111;
12'd2063 : mem_out_dec = 6'b111111;
12'd2064 : mem_out_dec = 6'b111111;
12'd2065 : mem_out_dec = 6'b111111;
12'd2066 : mem_out_dec = 6'b111111;
12'd2067 : mem_out_dec = 6'b111111;
12'd2068 : mem_out_dec = 6'b111111;
12'd2069 : mem_out_dec = 6'b111111;
12'd2070 : mem_out_dec = 6'b111111;
12'd2071 : mem_out_dec = 6'b111111;
12'd2072 : mem_out_dec = 6'b111111;
12'd2073 : mem_out_dec = 6'b111111;
12'd2074 : mem_out_dec = 6'b111111;
12'd2075 : mem_out_dec = 6'b111111;
12'd2076 : mem_out_dec = 6'b111111;
12'd2077 : mem_out_dec = 6'b111111;
12'd2078 : mem_out_dec = 6'b111111;
12'd2079 : mem_out_dec = 6'b111111;
12'd2080 : mem_out_dec = 6'b111111;
12'd2081 : mem_out_dec = 6'b111111;
12'd2082 : mem_out_dec = 6'b111111;
12'd2083 : mem_out_dec = 6'b111111;
12'd2084 : mem_out_dec = 6'b111111;
12'd2085 : mem_out_dec = 6'b111111;
12'd2086 : mem_out_dec = 6'b000100;
12'd2087 : mem_out_dec = 6'b000101;
12'd2088 : mem_out_dec = 6'b000101;
12'd2089 : mem_out_dec = 6'b000110;
12'd2090 : mem_out_dec = 6'b000110;
12'd2091 : mem_out_dec = 6'b000111;
12'd2092 : mem_out_dec = 6'b001000;
12'd2093 : mem_out_dec = 6'b001001;
12'd2094 : mem_out_dec = 6'b001001;
12'd2095 : mem_out_dec = 6'b001010;
12'd2096 : mem_out_dec = 6'b001010;
12'd2097 : mem_out_dec = 6'b001011;
12'd2098 : mem_out_dec = 6'b001011;
12'd2099 : mem_out_dec = 6'b001100;
12'd2100 : mem_out_dec = 6'b001100;
12'd2101 : mem_out_dec = 6'b001100;
12'd2102 : mem_out_dec = 6'b001100;
12'd2103 : mem_out_dec = 6'b001101;
12'd2104 : mem_out_dec = 6'b001100;
12'd2105 : mem_out_dec = 6'b001100;
12'd2106 : mem_out_dec = 6'b001101;
12'd2107 : mem_out_dec = 6'b001101;
12'd2108 : mem_out_dec = 6'b001110;
12'd2109 : mem_out_dec = 6'b001111;
12'd2110 : mem_out_dec = 6'b010000;
12'd2111 : mem_out_dec = 6'b010000;
12'd2112 : mem_out_dec = 6'b111111;
12'd2113 : mem_out_dec = 6'b111111;
12'd2114 : mem_out_dec = 6'b111111;
12'd2115 : mem_out_dec = 6'b111111;
12'd2116 : mem_out_dec = 6'b111111;
12'd2117 : mem_out_dec = 6'b111111;
12'd2118 : mem_out_dec = 6'b111111;
12'd2119 : mem_out_dec = 6'b111111;
12'd2120 : mem_out_dec = 6'b111111;
12'd2121 : mem_out_dec = 6'b111111;
12'd2122 : mem_out_dec = 6'b111111;
12'd2123 : mem_out_dec = 6'b111111;
12'd2124 : mem_out_dec = 6'b111111;
12'd2125 : mem_out_dec = 6'b111111;
12'd2126 : mem_out_dec = 6'b111111;
12'd2127 : mem_out_dec = 6'b111111;
12'd2128 : mem_out_dec = 6'b111111;
12'd2129 : mem_out_dec = 6'b111111;
12'd2130 : mem_out_dec = 6'b111111;
12'd2131 : mem_out_dec = 6'b111111;
12'd2132 : mem_out_dec = 6'b111111;
12'd2133 : mem_out_dec = 6'b111111;
12'd2134 : mem_out_dec = 6'b111111;
12'd2135 : mem_out_dec = 6'b111111;
12'd2136 : mem_out_dec = 6'b111111;
12'd2137 : mem_out_dec = 6'b111111;
12'd2138 : mem_out_dec = 6'b111111;
12'd2139 : mem_out_dec = 6'b111111;
12'd2140 : mem_out_dec = 6'b111111;
12'd2141 : mem_out_dec = 6'b111111;
12'd2142 : mem_out_dec = 6'b111111;
12'd2143 : mem_out_dec = 6'b111111;
12'd2144 : mem_out_dec = 6'b111111;
12'd2145 : mem_out_dec = 6'b111111;
12'd2146 : mem_out_dec = 6'b111111;
12'd2147 : mem_out_dec = 6'b111111;
12'd2148 : mem_out_dec = 6'b111111;
12'd2149 : mem_out_dec = 6'b111111;
12'd2150 : mem_out_dec = 6'b111111;
12'd2151 : mem_out_dec = 6'b000100;
12'd2152 : mem_out_dec = 6'b000100;
12'd2153 : mem_out_dec = 6'b000101;
12'd2154 : mem_out_dec = 6'b000110;
12'd2155 : mem_out_dec = 6'b000111;
12'd2156 : mem_out_dec = 6'b000111;
12'd2157 : mem_out_dec = 6'b001000;
12'd2158 : mem_out_dec = 6'b001001;
12'd2159 : mem_out_dec = 6'b001001;
12'd2160 : mem_out_dec = 6'b001010;
12'd2161 : mem_out_dec = 6'b001010;
12'd2162 : mem_out_dec = 6'b001011;
12'd2163 : mem_out_dec = 6'b001011;
12'd2164 : mem_out_dec = 6'b001011;
12'd2165 : mem_out_dec = 6'b001011;
12'd2166 : mem_out_dec = 6'b001011;
12'd2167 : mem_out_dec = 6'b001100;
12'd2168 : mem_out_dec = 6'b001011;
12'd2169 : mem_out_dec = 6'b001011;
12'd2170 : mem_out_dec = 6'b001100;
12'd2171 : mem_out_dec = 6'b001101;
12'd2172 : mem_out_dec = 6'b001110;
12'd2173 : mem_out_dec = 6'b001110;
12'd2174 : mem_out_dec = 6'b001111;
12'd2175 : mem_out_dec = 6'b010000;
12'd2176 : mem_out_dec = 6'b111111;
12'd2177 : mem_out_dec = 6'b111111;
12'd2178 : mem_out_dec = 6'b111111;
12'd2179 : mem_out_dec = 6'b111111;
12'd2180 : mem_out_dec = 6'b111111;
12'd2181 : mem_out_dec = 6'b111111;
12'd2182 : mem_out_dec = 6'b111111;
12'd2183 : mem_out_dec = 6'b111111;
12'd2184 : mem_out_dec = 6'b111111;
12'd2185 : mem_out_dec = 6'b111111;
12'd2186 : mem_out_dec = 6'b111111;
12'd2187 : mem_out_dec = 6'b111111;
12'd2188 : mem_out_dec = 6'b111111;
12'd2189 : mem_out_dec = 6'b111111;
12'd2190 : mem_out_dec = 6'b111111;
12'd2191 : mem_out_dec = 6'b111111;
12'd2192 : mem_out_dec = 6'b111111;
12'd2193 : mem_out_dec = 6'b111111;
12'd2194 : mem_out_dec = 6'b111111;
12'd2195 : mem_out_dec = 6'b111111;
12'd2196 : mem_out_dec = 6'b111111;
12'd2197 : mem_out_dec = 6'b111111;
12'd2198 : mem_out_dec = 6'b111111;
12'd2199 : mem_out_dec = 6'b111111;
12'd2200 : mem_out_dec = 6'b111111;
12'd2201 : mem_out_dec = 6'b111111;
12'd2202 : mem_out_dec = 6'b111111;
12'd2203 : mem_out_dec = 6'b111111;
12'd2204 : mem_out_dec = 6'b111111;
12'd2205 : mem_out_dec = 6'b111111;
12'd2206 : mem_out_dec = 6'b111111;
12'd2207 : mem_out_dec = 6'b111111;
12'd2208 : mem_out_dec = 6'b111111;
12'd2209 : mem_out_dec = 6'b111111;
12'd2210 : mem_out_dec = 6'b111111;
12'd2211 : mem_out_dec = 6'b111111;
12'd2212 : mem_out_dec = 6'b111111;
12'd2213 : mem_out_dec = 6'b111111;
12'd2214 : mem_out_dec = 6'b111111;
12'd2215 : mem_out_dec = 6'b111111;
12'd2216 : mem_out_dec = 6'b000100;
12'd2217 : mem_out_dec = 6'b000101;
12'd2218 : mem_out_dec = 6'b000101;
12'd2219 : mem_out_dec = 6'b000110;
12'd2220 : mem_out_dec = 6'b000111;
12'd2221 : mem_out_dec = 6'b000111;
12'd2222 : mem_out_dec = 6'b001000;
12'd2223 : mem_out_dec = 6'b001001;
12'd2224 : mem_out_dec = 6'b001001;
12'd2225 : mem_out_dec = 6'b001010;
12'd2226 : mem_out_dec = 6'b001010;
12'd2227 : mem_out_dec = 6'b001010;
12'd2228 : mem_out_dec = 6'b001010;
12'd2229 : mem_out_dec = 6'b001010;
12'd2230 : mem_out_dec = 6'b001010;
12'd2231 : mem_out_dec = 6'b001010;
12'd2232 : mem_out_dec = 6'b001010;
12'd2233 : mem_out_dec = 6'b001011;
12'd2234 : mem_out_dec = 6'b001100;
12'd2235 : mem_out_dec = 6'b001100;
12'd2236 : mem_out_dec = 6'b001101;
12'd2237 : mem_out_dec = 6'b001110;
12'd2238 : mem_out_dec = 6'b001111;
12'd2239 : mem_out_dec = 6'b010000;
12'd2240 : mem_out_dec = 6'b111111;
12'd2241 : mem_out_dec = 6'b111111;
12'd2242 : mem_out_dec = 6'b111111;
12'd2243 : mem_out_dec = 6'b111111;
12'd2244 : mem_out_dec = 6'b111111;
12'd2245 : mem_out_dec = 6'b111111;
12'd2246 : mem_out_dec = 6'b111111;
12'd2247 : mem_out_dec = 6'b111111;
12'd2248 : mem_out_dec = 6'b111111;
12'd2249 : mem_out_dec = 6'b111111;
12'd2250 : mem_out_dec = 6'b111111;
12'd2251 : mem_out_dec = 6'b111111;
12'd2252 : mem_out_dec = 6'b111111;
12'd2253 : mem_out_dec = 6'b111111;
12'd2254 : mem_out_dec = 6'b111111;
12'd2255 : mem_out_dec = 6'b111111;
12'd2256 : mem_out_dec = 6'b111111;
12'd2257 : mem_out_dec = 6'b111111;
12'd2258 : mem_out_dec = 6'b111111;
12'd2259 : mem_out_dec = 6'b111111;
12'd2260 : mem_out_dec = 6'b111111;
12'd2261 : mem_out_dec = 6'b111111;
12'd2262 : mem_out_dec = 6'b111111;
12'd2263 : mem_out_dec = 6'b111111;
12'd2264 : mem_out_dec = 6'b111111;
12'd2265 : mem_out_dec = 6'b111111;
12'd2266 : mem_out_dec = 6'b111111;
12'd2267 : mem_out_dec = 6'b111111;
12'd2268 : mem_out_dec = 6'b111111;
12'd2269 : mem_out_dec = 6'b111111;
12'd2270 : mem_out_dec = 6'b111111;
12'd2271 : mem_out_dec = 6'b111111;
12'd2272 : mem_out_dec = 6'b111111;
12'd2273 : mem_out_dec = 6'b111111;
12'd2274 : mem_out_dec = 6'b111111;
12'd2275 : mem_out_dec = 6'b111111;
12'd2276 : mem_out_dec = 6'b111111;
12'd2277 : mem_out_dec = 6'b111111;
12'd2278 : mem_out_dec = 6'b111111;
12'd2279 : mem_out_dec = 6'b111111;
12'd2280 : mem_out_dec = 6'b111111;
12'd2281 : mem_out_dec = 6'b000100;
12'd2282 : mem_out_dec = 6'b000101;
12'd2283 : mem_out_dec = 6'b000101;
12'd2284 : mem_out_dec = 6'b000110;
12'd2285 : mem_out_dec = 6'b000111;
12'd2286 : mem_out_dec = 6'b001000;
12'd2287 : mem_out_dec = 6'b001001;
12'd2288 : mem_out_dec = 6'b001001;
12'd2289 : mem_out_dec = 6'b001001;
12'd2290 : mem_out_dec = 6'b001001;
12'd2291 : mem_out_dec = 6'b001001;
12'd2292 : mem_out_dec = 6'b001001;
12'd2293 : mem_out_dec = 6'b001001;
12'd2294 : mem_out_dec = 6'b001001;
12'd2295 : mem_out_dec = 6'b001001;
12'd2296 : mem_out_dec = 6'b001010;
12'd2297 : mem_out_dec = 6'b001010;
12'd2298 : mem_out_dec = 6'b001011;
12'd2299 : mem_out_dec = 6'b001100;
12'd2300 : mem_out_dec = 6'b001101;
12'd2301 : mem_out_dec = 6'b001110;
12'd2302 : mem_out_dec = 6'b001110;
12'd2303 : mem_out_dec = 6'b001111;
12'd2304 : mem_out_dec = 6'b111111;
12'd2305 : mem_out_dec = 6'b111111;
12'd2306 : mem_out_dec = 6'b111111;
12'd2307 : mem_out_dec = 6'b111111;
12'd2308 : mem_out_dec = 6'b111111;
12'd2309 : mem_out_dec = 6'b111111;
12'd2310 : mem_out_dec = 6'b111111;
12'd2311 : mem_out_dec = 6'b111111;
12'd2312 : mem_out_dec = 6'b111111;
12'd2313 : mem_out_dec = 6'b111111;
12'd2314 : mem_out_dec = 6'b111111;
12'd2315 : mem_out_dec = 6'b111111;
12'd2316 : mem_out_dec = 6'b111111;
12'd2317 : mem_out_dec = 6'b111111;
12'd2318 : mem_out_dec = 6'b111111;
12'd2319 : mem_out_dec = 6'b111111;
12'd2320 : mem_out_dec = 6'b111111;
12'd2321 : mem_out_dec = 6'b111111;
12'd2322 : mem_out_dec = 6'b111111;
12'd2323 : mem_out_dec = 6'b111111;
12'd2324 : mem_out_dec = 6'b111111;
12'd2325 : mem_out_dec = 6'b111111;
12'd2326 : mem_out_dec = 6'b111111;
12'd2327 : mem_out_dec = 6'b111111;
12'd2328 : mem_out_dec = 6'b111111;
12'd2329 : mem_out_dec = 6'b111111;
12'd2330 : mem_out_dec = 6'b111111;
12'd2331 : mem_out_dec = 6'b111111;
12'd2332 : mem_out_dec = 6'b111111;
12'd2333 : mem_out_dec = 6'b111111;
12'd2334 : mem_out_dec = 6'b111111;
12'd2335 : mem_out_dec = 6'b111111;
12'd2336 : mem_out_dec = 6'b111111;
12'd2337 : mem_out_dec = 6'b111111;
12'd2338 : mem_out_dec = 6'b111111;
12'd2339 : mem_out_dec = 6'b111111;
12'd2340 : mem_out_dec = 6'b111111;
12'd2341 : mem_out_dec = 6'b111111;
12'd2342 : mem_out_dec = 6'b111111;
12'd2343 : mem_out_dec = 6'b111111;
12'd2344 : mem_out_dec = 6'b111111;
12'd2345 : mem_out_dec = 6'b111111;
12'd2346 : mem_out_dec = 6'b000100;
12'd2347 : mem_out_dec = 6'b000101;
12'd2348 : mem_out_dec = 6'b000110;
12'd2349 : mem_out_dec = 6'b000111;
12'd2350 : mem_out_dec = 6'b000111;
12'd2351 : mem_out_dec = 6'b001000;
12'd2352 : mem_out_dec = 6'b001000;
12'd2353 : mem_out_dec = 6'b001000;
12'd2354 : mem_out_dec = 6'b001000;
12'd2355 : mem_out_dec = 6'b001000;
12'd2356 : mem_out_dec = 6'b001000;
12'd2357 : mem_out_dec = 6'b001000;
12'd2358 : mem_out_dec = 6'b001000;
12'd2359 : mem_out_dec = 6'b001001;
12'd2360 : mem_out_dec = 6'b001001;
12'd2361 : mem_out_dec = 6'b001010;
12'd2362 : mem_out_dec = 6'b001011;
12'd2363 : mem_out_dec = 6'b001100;
12'd2364 : mem_out_dec = 6'b001100;
12'd2365 : mem_out_dec = 6'b001101;
12'd2366 : mem_out_dec = 6'b001110;
12'd2367 : mem_out_dec = 6'b001111;
12'd2368 : mem_out_dec = 6'b111111;
12'd2369 : mem_out_dec = 6'b111111;
12'd2370 : mem_out_dec = 6'b111111;
12'd2371 : mem_out_dec = 6'b111111;
12'd2372 : mem_out_dec = 6'b111111;
12'd2373 : mem_out_dec = 6'b111111;
12'd2374 : mem_out_dec = 6'b111111;
12'd2375 : mem_out_dec = 6'b111111;
12'd2376 : mem_out_dec = 6'b111111;
12'd2377 : mem_out_dec = 6'b111111;
12'd2378 : mem_out_dec = 6'b111111;
12'd2379 : mem_out_dec = 6'b111111;
12'd2380 : mem_out_dec = 6'b111111;
12'd2381 : mem_out_dec = 6'b111111;
12'd2382 : mem_out_dec = 6'b111111;
12'd2383 : mem_out_dec = 6'b111111;
12'd2384 : mem_out_dec = 6'b111111;
12'd2385 : mem_out_dec = 6'b111111;
12'd2386 : mem_out_dec = 6'b111111;
12'd2387 : mem_out_dec = 6'b111111;
12'd2388 : mem_out_dec = 6'b111111;
12'd2389 : mem_out_dec = 6'b111111;
12'd2390 : mem_out_dec = 6'b111111;
12'd2391 : mem_out_dec = 6'b111111;
12'd2392 : mem_out_dec = 6'b111111;
12'd2393 : mem_out_dec = 6'b111111;
12'd2394 : mem_out_dec = 6'b111111;
12'd2395 : mem_out_dec = 6'b111111;
12'd2396 : mem_out_dec = 6'b111111;
12'd2397 : mem_out_dec = 6'b111111;
12'd2398 : mem_out_dec = 6'b111111;
12'd2399 : mem_out_dec = 6'b111111;
12'd2400 : mem_out_dec = 6'b111111;
12'd2401 : mem_out_dec = 6'b111111;
12'd2402 : mem_out_dec = 6'b111111;
12'd2403 : mem_out_dec = 6'b111111;
12'd2404 : mem_out_dec = 6'b111111;
12'd2405 : mem_out_dec = 6'b111111;
12'd2406 : mem_out_dec = 6'b111111;
12'd2407 : mem_out_dec = 6'b111111;
12'd2408 : mem_out_dec = 6'b111111;
12'd2409 : mem_out_dec = 6'b111111;
12'd2410 : mem_out_dec = 6'b111111;
12'd2411 : mem_out_dec = 6'b000101;
12'd2412 : mem_out_dec = 6'b000101;
12'd2413 : mem_out_dec = 6'b000110;
12'd2414 : mem_out_dec = 6'b000111;
12'd2415 : mem_out_dec = 6'b001000;
12'd2416 : mem_out_dec = 6'b000111;
12'd2417 : mem_out_dec = 6'b000111;
12'd2418 : mem_out_dec = 6'b000111;
12'd2419 : mem_out_dec = 6'b000111;
12'd2420 : mem_out_dec = 6'b000111;
12'd2421 : mem_out_dec = 6'b000111;
12'd2422 : mem_out_dec = 6'b001000;
12'd2423 : mem_out_dec = 6'b001001;
12'd2424 : mem_out_dec = 6'b001001;
12'd2425 : mem_out_dec = 6'b001010;
12'd2426 : mem_out_dec = 6'b001010;
12'd2427 : mem_out_dec = 6'b001011;
12'd2428 : mem_out_dec = 6'b001100;
12'd2429 : mem_out_dec = 6'b001101;
12'd2430 : mem_out_dec = 6'b001101;
12'd2431 : mem_out_dec = 6'b001110;
12'd2432 : mem_out_dec = 6'b111111;
12'd2433 : mem_out_dec = 6'b111111;
12'd2434 : mem_out_dec = 6'b111111;
12'd2435 : mem_out_dec = 6'b111111;
12'd2436 : mem_out_dec = 6'b111111;
12'd2437 : mem_out_dec = 6'b111111;
12'd2438 : mem_out_dec = 6'b111111;
12'd2439 : mem_out_dec = 6'b111111;
12'd2440 : mem_out_dec = 6'b111111;
12'd2441 : mem_out_dec = 6'b111111;
12'd2442 : mem_out_dec = 6'b111111;
12'd2443 : mem_out_dec = 6'b111111;
12'd2444 : mem_out_dec = 6'b111111;
12'd2445 : mem_out_dec = 6'b111111;
12'd2446 : mem_out_dec = 6'b111111;
12'd2447 : mem_out_dec = 6'b111111;
12'd2448 : mem_out_dec = 6'b111111;
12'd2449 : mem_out_dec = 6'b111111;
12'd2450 : mem_out_dec = 6'b111111;
12'd2451 : mem_out_dec = 6'b111111;
12'd2452 : mem_out_dec = 6'b111111;
12'd2453 : mem_out_dec = 6'b111111;
12'd2454 : mem_out_dec = 6'b111111;
12'd2455 : mem_out_dec = 6'b111111;
12'd2456 : mem_out_dec = 6'b111111;
12'd2457 : mem_out_dec = 6'b111111;
12'd2458 : mem_out_dec = 6'b111111;
12'd2459 : mem_out_dec = 6'b111111;
12'd2460 : mem_out_dec = 6'b111111;
12'd2461 : mem_out_dec = 6'b111111;
12'd2462 : mem_out_dec = 6'b111111;
12'd2463 : mem_out_dec = 6'b111111;
12'd2464 : mem_out_dec = 6'b111111;
12'd2465 : mem_out_dec = 6'b111111;
12'd2466 : mem_out_dec = 6'b111111;
12'd2467 : mem_out_dec = 6'b111111;
12'd2468 : mem_out_dec = 6'b111111;
12'd2469 : mem_out_dec = 6'b111111;
12'd2470 : mem_out_dec = 6'b111111;
12'd2471 : mem_out_dec = 6'b111111;
12'd2472 : mem_out_dec = 6'b111111;
12'd2473 : mem_out_dec = 6'b111111;
12'd2474 : mem_out_dec = 6'b111111;
12'd2475 : mem_out_dec = 6'b111111;
12'd2476 : mem_out_dec = 6'b000101;
12'd2477 : mem_out_dec = 6'b000110;
12'd2478 : mem_out_dec = 6'b000111;
12'd2479 : mem_out_dec = 6'b000111;
12'd2480 : mem_out_dec = 6'b000110;
12'd2481 : mem_out_dec = 6'b000110;
12'd2482 : mem_out_dec = 6'b000110;
12'd2483 : mem_out_dec = 6'b000110;
12'd2484 : mem_out_dec = 6'b000110;
12'd2485 : mem_out_dec = 6'b000111;
12'd2486 : mem_out_dec = 6'b000111;
12'd2487 : mem_out_dec = 6'b001000;
12'd2488 : mem_out_dec = 6'b001001;
12'd2489 : mem_out_dec = 6'b001001;
12'd2490 : mem_out_dec = 6'b001010;
12'd2491 : mem_out_dec = 6'b001011;
12'd2492 : mem_out_dec = 6'b001011;
12'd2493 : mem_out_dec = 6'b001100;
12'd2494 : mem_out_dec = 6'b001101;
12'd2495 : mem_out_dec = 6'b001110;
12'd2496 : mem_out_dec = 6'b111111;
12'd2497 : mem_out_dec = 6'b111111;
12'd2498 : mem_out_dec = 6'b111111;
12'd2499 : mem_out_dec = 6'b111111;
12'd2500 : mem_out_dec = 6'b111111;
12'd2501 : mem_out_dec = 6'b111111;
12'd2502 : mem_out_dec = 6'b111111;
12'd2503 : mem_out_dec = 6'b111111;
12'd2504 : mem_out_dec = 6'b111111;
12'd2505 : mem_out_dec = 6'b111111;
12'd2506 : mem_out_dec = 6'b111111;
12'd2507 : mem_out_dec = 6'b111111;
12'd2508 : mem_out_dec = 6'b111111;
12'd2509 : mem_out_dec = 6'b111111;
12'd2510 : mem_out_dec = 6'b111111;
12'd2511 : mem_out_dec = 6'b111111;
12'd2512 : mem_out_dec = 6'b111111;
12'd2513 : mem_out_dec = 6'b111111;
12'd2514 : mem_out_dec = 6'b111111;
12'd2515 : mem_out_dec = 6'b111111;
12'd2516 : mem_out_dec = 6'b111111;
12'd2517 : mem_out_dec = 6'b111111;
12'd2518 : mem_out_dec = 6'b111111;
12'd2519 : mem_out_dec = 6'b111111;
12'd2520 : mem_out_dec = 6'b111111;
12'd2521 : mem_out_dec = 6'b111111;
12'd2522 : mem_out_dec = 6'b111111;
12'd2523 : mem_out_dec = 6'b111111;
12'd2524 : mem_out_dec = 6'b111111;
12'd2525 : mem_out_dec = 6'b111111;
12'd2526 : mem_out_dec = 6'b111111;
12'd2527 : mem_out_dec = 6'b111111;
12'd2528 : mem_out_dec = 6'b111111;
12'd2529 : mem_out_dec = 6'b111111;
12'd2530 : mem_out_dec = 6'b111111;
12'd2531 : mem_out_dec = 6'b111111;
12'd2532 : mem_out_dec = 6'b111111;
12'd2533 : mem_out_dec = 6'b111111;
12'd2534 : mem_out_dec = 6'b111111;
12'd2535 : mem_out_dec = 6'b111111;
12'd2536 : mem_out_dec = 6'b111111;
12'd2537 : mem_out_dec = 6'b111111;
12'd2538 : mem_out_dec = 6'b111111;
12'd2539 : mem_out_dec = 6'b111111;
12'd2540 : mem_out_dec = 6'b111111;
12'd2541 : mem_out_dec = 6'b000101;
12'd2542 : mem_out_dec = 6'b000110;
12'd2543 : mem_out_dec = 6'b000110;
12'd2544 : mem_out_dec = 6'b000110;
12'd2545 : mem_out_dec = 6'b000110;
12'd2546 : mem_out_dec = 6'b000101;
12'd2547 : mem_out_dec = 6'b000101;
12'd2548 : mem_out_dec = 6'b000110;
12'd2549 : mem_out_dec = 6'b000111;
12'd2550 : mem_out_dec = 6'b000111;
12'd2551 : mem_out_dec = 6'b001000;
12'd2552 : mem_out_dec = 6'b001000;
12'd2553 : mem_out_dec = 6'b001001;
12'd2554 : mem_out_dec = 6'b001010;
12'd2555 : mem_out_dec = 6'b001010;
12'd2556 : mem_out_dec = 6'b001011;
12'd2557 : mem_out_dec = 6'b001100;
12'd2558 : mem_out_dec = 6'b001101;
12'd2559 : mem_out_dec = 6'b001101;
12'd2560 : mem_out_dec = 6'b111111;
12'd2561 : mem_out_dec = 6'b111111;
12'd2562 : mem_out_dec = 6'b111111;
12'd2563 : mem_out_dec = 6'b111111;
12'd2564 : mem_out_dec = 6'b111111;
12'd2565 : mem_out_dec = 6'b111111;
12'd2566 : mem_out_dec = 6'b111111;
12'd2567 : mem_out_dec = 6'b111111;
12'd2568 : mem_out_dec = 6'b111111;
12'd2569 : mem_out_dec = 6'b111111;
12'd2570 : mem_out_dec = 6'b111111;
12'd2571 : mem_out_dec = 6'b111111;
12'd2572 : mem_out_dec = 6'b111111;
12'd2573 : mem_out_dec = 6'b111111;
12'd2574 : mem_out_dec = 6'b111111;
12'd2575 : mem_out_dec = 6'b111111;
12'd2576 : mem_out_dec = 6'b111111;
12'd2577 : mem_out_dec = 6'b111111;
12'd2578 : mem_out_dec = 6'b111111;
12'd2579 : mem_out_dec = 6'b111111;
12'd2580 : mem_out_dec = 6'b111111;
12'd2581 : mem_out_dec = 6'b111111;
12'd2582 : mem_out_dec = 6'b111111;
12'd2583 : mem_out_dec = 6'b111111;
12'd2584 : mem_out_dec = 6'b111111;
12'd2585 : mem_out_dec = 6'b111111;
12'd2586 : mem_out_dec = 6'b111111;
12'd2587 : mem_out_dec = 6'b111111;
12'd2588 : mem_out_dec = 6'b111111;
12'd2589 : mem_out_dec = 6'b111111;
12'd2590 : mem_out_dec = 6'b111111;
12'd2591 : mem_out_dec = 6'b111111;
12'd2592 : mem_out_dec = 6'b111111;
12'd2593 : mem_out_dec = 6'b111111;
12'd2594 : mem_out_dec = 6'b111111;
12'd2595 : mem_out_dec = 6'b111111;
12'd2596 : mem_out_dec = 6'b111111;
12'd2597 : mem_out_dec = 6'b111111;
12'd2598 : mem_out_dec = 6'b111111;
12'd2599 : mem_out_dec = 6'b111111;
12'd2600 : mem_out_dec = 6'b111111;
12'd2601 : mem_out_dec = 6'b111111;
12'd2602 : mem_out_dec = 6'b111111;
12'd2603 : mem_out_dec = 6'b111111;
12'd2604 : mem_out_dec = 6'b111111;
12'd2605 : mem_out_dec = 6'b111111;
12'd2606 : mem_out_dec = 6'b000100;
12'd2607 : mem_out_dec = 6'b000101;
12'd2608 : mem_out_dec = 6'b000100;
12'd2609 : mem_out_dec = 6'b000100;
12'd2610 : mem_out_dec = 6'b000100;
12'd2611 : mem_out_dec = 6'b000101;
12'd2612 : mem_out_dec = 6'b000101;
12'd2613 : mem_out_dec = 6'b000110;
12'd2614 : mem_out_dec = 6'b000111;
12'd2615 : mem_out_dec = 6'b000111;
12'd2616 : mem_out_dec = 6'b000111;
12'd2617 : mem_out_dec = 6'b001000;
12'd2618 : mem_out_dec = 6'b001001;
12'd2619 : mem_out_dec = 6'b001010;
12'd2620 : mem_out_dec = 6'b001010;
12'd2621 : mem_out_dec = 6'b001011;
12'd2622 : mem_out_dec = 6'b001100;
12'd2623 : mem_out_dec = 6'b001101;
12'd2624 : mem_out_dec = 6'b111111;
12'd2625 : mem_out_dec = 6'b111111;
12'd2626 : mem_out_dec = 6'b111111;
12'd2627 : mem_out_dec = 6'b111111;
12'd2628 : mem_out_dec = 6'b111111;
12'd2629 : mem_out_dec = 6'b111111;
12'd2630 : mem_out_dec = 6'b111111;
12'd2631 : mem_out_dec = 6'b111111;
12'd2632 : mem_out_dec = 6'b111111;
12'd2633 : mem_out_dec = 6'b111111;
12'd2634 : mem_out_dec = 6'b111111;
12'd2635 : mem_out_dec = 6'b111111;
12'd2636 : mem_out_dec = 6'b111111;
12'd2637 : mem_out_dec = 6'b111111;
12'd2638 : mem_out_dec = 6'b111111;
12'd2639 : mem_out_dec = 6'b111111;
12'd2640 : mem_out_dec = 6'b111111;
12'd2641 : mem_out_dec = 6'b111111;
12'd2642 : mem_out_dec = 6'b111111;
12'd2643 : mem_out_dec = 6'b111111;
12'd2644 : mem_out_dec = 6'b111111;
12'd2645 : mem_out_dec = 6'b111111;
12'd2646 : mem_out_dec = 6'b111111;
12'd2647 : mem_out_dec = 6'b111111;
12'd2648 : mem_out_dec = 6'b111111;
12'd2649 : mem_out_dec = 6'b111111;
12'd2650 : mem_out_dec = 6'b111111;
12'd2651 : mem_out_dec = 6'b111111;
12'd2652 : mem_out_dec = 6'b111111;
12'd2653 : mem_out_dec = 6'b111111;
12'd2654 : mem_out_dec = 6'b111111;
12'd2655 : mem_out_dec = 6'b111111;
12'd2656 : mem_out_dec = 6'b111111;
12'd2657 : mem_out_dec = 6'b111111;
12'd2658 : mem_out_dec = 6'b111111;
12'd2659 : mem_out_dec = 6'b111111;
12'd2660 : mem_out_dec = 6'b111111;
12'd2661 : mem_out_dec = 6'b111111;
12'd2662 : mem_out_dec = 6'b111111;
12'd2663 : mem_out_dec = 6'b111111;
12'd2664 : mem_out_dec = 6'b111111;
12'd2665 : mem_out_dec = 6'b111111;
12'd2666 : mem_out_dec = 6'b111111;
12'd2667 : mem_out_dec = 6'b111111;
12'd2668 : mem_out_dec = 6'b111111;
12'd2669 : mem_out_dec = 6'b111111;
12'd2670 : mem_out_dec = 6'b111111;
12'd2671 : mem_out_dec = 6'b000100;
12'd2672 : mem_out_dec = 6'b000011;
12'd2673 : mem_out_dec = 6'b000011;
12'd2674 : mem_out_dec = 6'b000100;
12'd2675 : mem_out_dec = 6'b000100;
12'd2676 : mem_out_dec = 6'b000101;
12'd2677 : mem_out_dec = 6'b000110;
12'd2678 : mem_out_dec = 6'b000110;
12'd2679 : mem_out_dec = 6'b000111;
12'd2680 : mem_out_dec = 6'b000111;
12'd2681 : mem_out_dec = 6'b001000;
12'd2682 : mem_out_dec = 6'b001001;
12'd2683 : mem_out_dec = 6'b001001;
12'd2684 : mem_out_dec = 6'b001010;
12'd2685 : mem_out_dec = 6'b001011;
12'd2686 : mem_out_dec = 6'b001100;
12'd2687 : mem_out_dec = 6'b001100;
12'd2688 : mem_out_dec = 6'b111111;
12'd2689 : mem_out_dec = 6'b111111;
12'd2690 : mem_out_dec = 6'b111111;
12'd2691 : mem_out_dec = 6'b111111;
12'd2692 : mem_out_dec = 6'b111111;
12'd2693 : mem_out_dec = 6'b111111;
12'd2694 : mem_out_dec = 6'b111111;
12'd2695 : mem_out_dec = 6'b111111;
12'd2696 : mem_out_dec = 6'b111111;
12'd2697 : mem_out_dec = 6'b111111;
12'd2698 : mem_out_dec = 6'b111111;
12'd2699 : mem_out_dec = 6'b111111;
12'd2700 : mem_out_dec = 6'b111111;
12'd2701 : mem_out_dec = 6'b111111;
12'd2702 : mem_out_dec = 6'b111111;
12'd2703 : mem_out_dec = 6'b111111;
12'd2704 : mem_out_dec = 6'b111111;
12'd2705 : mem_out_dec = 6'b111111;
12'd2706 : mem_out_dec = 6'b111111;
12'd2707 : mem_out_dec = 6'b111111;
12'd2708 : mem_out_dec = 6'b111111;
12'd2709 : mem_out_dec = 6'b111111;
12'd2710 : mem_out_dec = 6'b111111;
12'd2711 : mem_out_dec = 6'b111111;
12'd2712 : mem_out_dec = 6'b111111;
12'd2713 : mem_out_dec = 6'b111111;
12'd2714 : mem_out_dec = 6'b111111;
12'd2715 : mem_out_dec = 6'b111111;
12'd2716 : mem_out_dec = 6'b111111;
12'd2717 : mem_out_dec = 6'b111111;
12'd2718 : mem_out_dec = 6'b111111;
12'd2719 : mem_out_dec = 6'b111111;
12'd2720 : mem_out_dec = 6'b111111;
12'd2721 : mem_out_dec = 6'b111111;
12'd2722 : mem_out_dec = 6'b111111;
12'd2723 : mem_out_dec = 6'b111111;
12'd2724 : mem_out_dec = 6'b111111;
12'd2725 : mem_out_dec = 6'b111111;
12'd2726 : mem_out_dec = 6'b111111;
12'd2727 : mem_out_dec = 6'b111111;
12'd2728 : mem_out_dec = 6'b111111;
12'd2729 : mem_out_dec = 6'b111111;
12'd2730 : mem_out_dec = 6'b111111;
12'd2731 : mem_out_dec = 6'b111111;
12'd2732 : mem_out_dec = 6'b111111;
12'd2733 : mem_out_dec = 6'b111111;
12'd2734 : mem_out_dec = 6'b111111;
12'd2735 : mem_out_dec = 6'b111111;
12'd2736 : mem_out_dec = 6'b000011;
12'd2737 : mem_out_dec = 6'b000011;
12'd2738 : mem_out_dec = 6'b000100;
12'd2739 : mem_out_dec = 6'b000100;
12'd2740 : mem_out_dec = 6'b000101;
12'd2741 : mem_out_dec = 6'b000101;
12'd2742 : mem_out_dec = 6'b000110;
12'd2743 : mem_out_dec = 6'b000111;
12'd2744 : mem_out_dec = 6'b000111;
12'd2745 : mem_out_dec = 6'b001000;
12'd2746 : mem_out_dec = 6'b001000;
12'd2747 : mem_out_dec = 6'b001001;
12'd2748 : mem_out_dec = 6'b001010;
12'd2749 : mem_out_dec = 6'b001011;
12'd2750 : mem_out_dec = 6'b001011;
12'd2751 : mem_out_dec = 6'b001100;
12'd2752 : mem_out_dec = 6'b111111;
12'd2753 : mem_out_dec = 6'b111111;
12'd2754 : mem_out_dec = 6'b111111;
12'd2755 : mem_out_dec = 6'b111111;
12'd2756 : mem_out_dec = 6'b111111;
12'd2757 : mem_out_dec = 6'b111111;
12'd2758 : mem_out_dec = 6'b111111;
12'd2759 : mem_out_dec = 6'b111111;
12'd2760 : mem_out_dec = 6'b111111;
12'd2761 : mem_out_dec = 6'b111111;
12'd2762 : mem_out_dec = 6'b111111;
12'd2763 : mem_out_dec = 6'b111111;
12'd2764 : mem_out_dec = 6'b111111;
12'd2765 : mem_out_dec = 6'b111111;
12'd2766 : mem_out_dec = 6'b111111;
12'd2767 : mem_out_dec = 6'b111111;
12'd2768 : mem_out_dec = 6'b111111;
12'd2769 : mem_out_dec = 6'b111111;
12'd2770 : mem_out_dec = 6'b111111;
12'd2771 : mem_out_dec = 6'b111111;
12'd2772 : mem_out_dec = 6'b111111;
12'd2773 : mem_out_dec = 6'b111111;
12'd2774 : mem_out_dec = 6'b111111;
12'd2775 : mem_out_dec = 6'b111111;
12'd2776 : mem_out_dec = 6'b111111;
12'd2777 : mem_out_dec = 6'b111111;
12'd2778 : mem_out_dec = 6'b111111;
12'd2779 : mem_out_dec = 6'b111111;
12'd2780 : mem_out_dec = 6'b111111;
12'd2781 : mem_out_dec = 6'b111111;
12'd2782 : mem_out_dec = 6'b111111;
12'd2783 : mem_out_dec = 6'b111111;
12'd2784 : mem_out_dec = 6'b111111;
12'd2785 : mem_out_dec = 6'b111111;
12'd2786 : mem_out_dec = 6'b111111;
12'd2787 : mem_out_dec = 6'b111111;
12'd2788 : mem_out_dec = 6'b111111;
12'd2789 : mem_out_dec = 6'b111111;
12'd2790 : mem_out_dec = 6'b111111;
12'd2791 : mem_out_dec = 6'b111111;
12'd2792 : mem_out_dec = 6'b111111;
12'd2793 : mem_out_dec = 6'b111111;
12'd2794 : mem_out_dec = 6'b111111;
12'd2795 : mem_out_dec = 6'b111111;
12'd2796 : mem_out_dec = 6'b111111;
12'd2797 : mem_out_dec = 6'b111111;
12'd2798 : mem_out_dec = 6'b111111;
12'd2799 : mem_out_dec = 6'b111111;
12'd2800 : mem_out_dec = 6'b111111;
12'd2801 : mem_out_dec = 6'b000011;
12'd2802 : mem_out_dec = 6'b000011;
12'd2803 : mem_out_dec = 6'b000100;
12'd2804 : mem_out_dec = 6'b000101;
12'd2805 : mem_out_dec = 6'b000101;
12'd2806 : mem_out_dec = 6'b000110;
12'd2807 : mem_out_dec = 6'b000111;
12'd2808 : mem_out_dec = 6'b000111;
12'd2809 : mem_out_dec = 6'b000111;
12'd2810 : mem_out_dec = 6'b001000;
12'd2811 : mem_out_dec = 6'b001001;
12'd2812 : mem_out_dec = 6'b001010;
12'd2813 : mem_out_dec = 6'b001010;
12'd2814 : mem_out_dec = 6'b001011;
12'd2815 : mem_out_dec = 6'b001100;
12'd2816 : mem_out_dec = 6'b111111;
12'd2817 : mem_out_dec = 6'b111111;
12'd2818 : mem_out_dec = 6'b111111;
12'd2819 : mem_out_dec = 6'b111111;
12'd2820 : mem_out_dec = 6'b111111;
12'd2821 : mem_out_dec = 6'b111111;
12'd2822 : mem_out_dec = 6'b111111;
12'd2823 : mem_out_dec = 6'b111111;
12'd2824 : mem_out_dec = 6'b111111;
12'd2825 : mem_out_dec = 6'b111111;
12'd2826 : mem_out_dec = 6'b111111;
12'd2827 : mem_out_dec = 6'b111111;
12'd2828 : mem_out_dec = 6'b111111;
12'd2829 : mem_out_dec = 6'b111111;
12'd2830 : mem_out_dec = 6'b111111;
12'd2831 : mem_out_dec = 6'b111111;
12'd2832 : mem_out_dec = 6'b111111;
12'd2833 : mem_out_dec = 6'b111111;
12'd2834 : mem_out_dec = 6'b111111;
12'd2835 : mem_out_dec = 6'b111111;
12'd2836 : mem_out_dec = 6'b111111;
12'd2837 : mem_out_dec = 6'b111111;
12'd2838 : mem_out_dec = 6'b111111;
12'd2839 : mem_out_dec = 6'b111111;
12'd2840 : mem_out_dec = 6'b111111;
12'd2841 : mem_out_dec = 6'b111111;
12'd2842 : mem_out_dec = 6'b111111;
12'd2843 : mem_out_dec = 6'b111111;
12'd2844 : mem_out_dec = 6'b111111;
12'd2845 : mem_out_dec = 6'b111111;
12'd2846 : mem_out_dec = 6'b111111;
12'd2847 : mem_out_dec = 6'b111111;
12'd2848 : mem_out_dec = 6'b111111;
12'd2849 : mem_out_dec = 6'b111111;
12'd2850 : mem_out_dec = 6'b111111;
12'd2851 : mem_out_dec = 6'b111111;
12'd2852 : mem_out_dec = 6'b111111;
12'd2853 : mem_out_dec = 6'b111111;
12'd2854 : mem_out_dec = 6'b111111;
12'd2855 : mem_out_dec = 6'b111111;
12'd2856 : mem_out_dec = 6'b111111;
12'd2857 : mem_out_dec = 6'b111111;
12'd2858 : mem_out_dec = 6'b111111;
12'd2859 : mem_out_dec = 6'b111111;
12'd2860 : mem_out_dec = 6'b111111;
12'd2861 : mem_out_dec = 6'b111111;
12'd2862 : mem_out_dec = 6'b111111;
12'd2863 : mem_out_dec = 6'b111111;
12'd2864 : mem_out_dec = 6'b111111;
12'd2865 : mem_out_dec = 6'b111111;
12'd2866 : mem_out_dec = 6'b000011;
12'd2867 : mem_out_dec = 6'b000100;
12'd2868 : mem_out_dec = 6'b000100;
12'd2869 : mem_out_dec = 6'b000101;
12'd2870 : mem_out_dec = 6'b000110;
12'd2871 : mem_out_dec = 6'b000110;
12'd2872 : mem_out_dec = 6'b000110;
12'd2873 : mem_out_dec = 6'b000111;
12'd2874 : mem_out_dec = 6'b001000;
12'd2875 : mem_out_dec = 6'b001001;
12'd2876 : mem_out_dec = 6'b001001;
12'd2877 : mem_out_dec = 6'b001010;
12'd2878 : mem_out_dec = 6'b001011;
12'd2879 : mem_out_dec = 6'b001100;
12'd2880 : mem_out_dec = 6'b111111;
12'd2881 : mem_out_dec = 6'b111111;
12'd2882 : mem_out_dec = 6'b111111;
12'd2883 : mem_out_dec = 6'b111111;
12'd2884 : mem_out_dec = 6'b111111;
12'd2885 : mem_out_dec = 6'b111111;
12'd2886 : mem_out_dec = 6'b111111;
12'd2887 : mem_out_dec = 6'b111111;
12'd2888 : mem_out_dec = 6'b111111;
12'd2889 : mem_out_dec = 6'b111111;
12'd2890 : mem_out_dec = 6'b111111;
12'd2891 : mem_out_dec = 6'b111111;
12'd2892 : mem_out_dec = 6'b111111;
12'd2893 : mem_out_dec = 6'b111111;
12'd2894 : mem_out_dec = 6'b111111;
12'd2895 : mem_out_dec = 6'b111111;
12'd2896 : mem_out_dec = 6'b111111;
12'd2897 : mem_out_dec = 6'b111111;
12'd2898 : mem_out_dec = 6'b111111;
12'd2899 : mem_out_dec = 6'b111111;
12'd2900 : mem_out_dec = 6'b111111;
12'd2901 : mem_out_dec = 6'b111111;
12'd2902 : mem_out_dec = 6'b111111;
12'd2903 : mem_out_dec = 6'b111111;
12'd2904 : mem_out_dec = 6'b111111;
12'd2905 : mem_out_dec = 6'b111111;
12'd2906 : mem_out_dec = 6'b111111;
12'd2907 : mem_out_dec = 6'b111111;
12'd2908 : mem_out_dec = 6'b111111;
12'd2909 : mem_out_dec = 6'b111111;
12'd2910 : mem_out_dec = 6'b111111;
12'd2911 : mem_out_dec = 6'b111111;
12'd2912 : mem_out_dec = 6'b111111;
12'd2913 : mem_out_dec = 6'b111111;
12'd2914 : mem_out_dec = 6'b111111;
12'd2915 : mem_out_dec = 6'b111111;
12'd2916 : mem_out_dec = 6'b111111;
12'd2917 : mem_out_dec = 6'b111111;
12'd2918 : mem_out_dec = 6'b111111;
12'd2919 : mem_out_dec = 6'b111111;
12'd2920 : mem_out_dec = 6'b111111;
12'd2921 : mem_out_dec = 6'b111111;
12'd2922 : mem_out_dec = 6'b111111;
12'd2923 : mem_out_dec = 6'b111111;
12'd2924 : mem_out_dec = 6'b111111;
12'd2925 : mem_out_dec = 6'b111111;
12'd2926 : mem_out_dec = 6'b111111;
12'd2927 : mem_out_dec = 6'b111111;
12'd2928 : mem_out_dec = 6'b111111;
12'd2929 : mem_out_dec = 6'b111111;
12'd2930 : mem_out_dec = 6'b111111;
12'd2931 : mem_out_dec = 6'b000100;
12'd2932 : mem_out_dec = 6'b000100;
12'd2933 : mem_out_dec = 6'b000101;
12'd2934 : mem_out_dec = 6'b000101;
12'd2935 : mem_out_dec = 6'b000110;
12'd2936 : mem_out_dec = 6'b000110;
12'd2937 : mem_out_dec = 6'b000111;
12'd2938 : mem_out_dec = 6'b001000;
12'd2939 : mem_out_dec = 6'b001000;
12'd2940 : mem_out_dec = 6'b001001;
12'd2941 : mem_out_dec = 6'b001010;
12'd2942 : mem_out_dec = 6'b001011;
12'd2943 : mem_out_dec = 6'b001011;
12'd2944 : mem_out_dec = 6'b111111;
12'd2945 : mem_out_dec = 6'b111111;
12'd2946 : mem_out_dec = 6'b111111;
12'd2947 : mem_out_dec = 6'b111111;
12'd2948 : mem_out_dec = 6'b111111;
12'd2949 : mem_out_dec = 6'b111111;
12'd2950 : mem_out_dec = 6'b111111;
12'd2951 : mem_out_dec = 6'b111111;
12'd2952 : mem_out_dec = 6'b111111;
12'd2953 : mem_out_dec = 6'b111111;
12'd2954 : mem_out_dec = 6'b111111;
12'd2955 : mem_out_dec = 6'b111111;
12'd2956 : mem_out_dec = 6'b111111;
12'd2957 : mem_out_dec = 6'b111111;
12'd2958 : mem_out_dec = 6'b111111;
12'd2959 : mem_out_dec = 6'b111111;
12'd2960 : mem_out_dec = 6'b111111;
12'd2961 : mem_out_dec = 6'b111111;
12'd2962 : mem_out_dec = 6'b111111;
12'd2963 : mem_out_dec = 6'b111111;
12'd2964 : mem_out_dec = 6'b111111;
12'd2965 : mem_out_dec = 6'b111111;
12'd2966 : mem_out_dec = 6'b111111;
12'd2967 : mem_out_dec = 6'b111111;
12'd2968 : mem_out_dec = 6'b111111;
12'd2969 : mem_out_dec = 6'b111111;
12'd2970 : mem_out_dec = 6'b111111;
12'd2971 : mem_out_dec = 6'b111111;
12'd2972 : mem_out_dec = 6'b111111;
12'd2973 : mem_out_dec = 6'b111111;
12'd2974 : mem_out_dec = 6'b111111;
12'd2975 : mem_out_dec = 6'b111111;
12'd2976 : mem_out_dec = 6'b111111;
12'd2977 : mem_out_dec = 6'b111111;
12'd2978 : mem_out_dec = 6'b111111;
12'd2979 : mem_out_dec = 6'b111111;
12'd2980 : mem_out_dec = 6'b111111;
12'd2981 : mem_out_dec = 6'b111111;
12'd2982 : mem_out_dec = 6'b111111;
12'd2983 : mem_out_dec = 6'b111111;
12'd2984 : mem_out_dec = 6'b111111;
12'd2985 : mem_out_dec = 6'b111111;
12'd2986 : mem_out_dec = 6'b111111;
12'd2987 : mem_out_dec = 6'b111111;
12'd2988 : mem_out_dec = 6'b111111;
12'd2989 : mem_out_dec = 6'b111111;
12'd2990 : mem_out_dec = 6'b111111;
12'd2991 : mem_out_dec = 6'b111111;
12'd2992 : mem_out_dec = 6'b111111;
12'd2993 : mem_out_dec = 6'b111111;
12'd2994 : mem_out_dec = 6'b111111;
12'd2995 : mem_out_dec = 6'b111111;
12'd2996 : mem_out_dec = 6'b000100;
12'd2997 : mem_out_dec = 6'b000101;
12'd2998 : mem_out_dec = 6'b000101;
12'd2999 : mem_out_dec = 6'b000110;
12'd3000 : mem_out_dec = 6'b000110;
12'd3001 : mem_out_dec = 6'b000111;
12'd3002 : mem_out_dec = 6'b000111;
12'd3003 : mem_out_dec = 6'b001000;
12'd3004 : mem_out_dec = 6'b001001;
12'd3005 : mem_out_dec = 6'b001010;
12'd3006 : mem_out_dec = 6'b001010;
12'd3007 : mem_out_dec = 6'b001011;
12'd3008 : mem_out_dec = 6'b111111;
12'd3009 : mem_out_dec = 6'b111111;
12'd3010 : mem_out_dec = 6'b111111;
12'd3011 : mem_out_dec = 6'b111111;
12'd3012 : mem_out_dec = 6'b111111;
12'd3013 : mem_out_dec = 6'b111111;
12'd3014 : mem_out_dec = 6'b111111;
12'd3015 : mem_out_dec = 6'b111111;
12'd3016 : mem_out_dec = 6'b111111;
12'd3017 : mem_out_dec = 6'b111111;
12'd3018 : mem_out_dec = 6'b111111;
12'd3019 : mem_out_dec = 6'b111111;
12'd3020 : mem_out_dec = 6'b111111;
12'd3021 : mem_out_dec = 6'b111111;
12'd3022 : mem_out_dec = 6'b111111;
12'd3023 : mem_out_dec = 6'b111111;
12'd3024 : mem_out_dec = 6'b111111;
12'd3025 : mem_out_dec = 6'b111111;
12'd3026 : mem_out_dec = 6'b111111;
12'd3027 : mem_out_dec = 6'b111111;
12'd3028 : mem_out_dec = 6'b111111;
12'd3029 : mem_out_dec = 6'b111111;
12'd3030 : mem_out_dec = 6'b111111;
12'd3031 : mem_out_dec = 6'b111111;
12'd3032 : mem_out_dec = 6'b111111;
12'd3033 : mem_out_dec = 6'b111111;
12'd3034 : mem_out_dec = 6'b111111;
12'd3035 : mem_out_dec = 6'b111111;
12'd3036 : mem_out_dec = 6'b111111;
12'd3037 : mem_out_dec = 6'b111111;
12'd3038 : mem_out_dec = 6'b111111;
12'd3039 : mem_out_dec = 6'b111111;
12'd3040 : mem_out_dec = 6'b111111;
12'd3041 : mem_out_dec = 6'b111111;
12'd3042 : mem_out_dec = 6'b111111;
12'd3043 : mem_out_dec = 6'b111111;
12'd3044 : mem_out_dec = 6'b111111;
12'd3045 : mem_out_dec = 6'b111111;
12'd3046 : mem_out_dec = 6'b111111;
12'd3047 : mem_out_dec = 6'b111111;
12'd3048 : mem_out_dec = 6'b111111;
12'd3049 : mem_out_dec = 6'b111111;
12'd3050 : mem_out_dec = 6'b111111;
12'd3051 : mem_out_dec = 6'b111111;
12'd3052 : mem_out_dec = 6'b111111;
12'd3053 : mem_out_dec = 6'b111111;
12'd3054 : mem_out_dec = 6'b111111;
12'd3055 : mem_out_dec = 6'b111111;
12'd3056 : mem_out_dec = 6'b111111;
12'd3057 : mem_out_dec = 6'b111111;
12'd3058 : mem_out_dec = 6'b111111;
12'd3059 : mem_out_dec = 6'b111111;
12'd3060 : mem_out_dec = 6'b111111;
12'd3061 : mem_out_dec = 6'b000100;
12'd3062 : mem_out_dec = 6'b000101;
12'd3063 : mem_out_dec = 6'b000110;
12'd3064 : mem_out_dec = 6'b000110;
12'd3065 : mem_out_dec = 6'b000111;
12'd3066 : mem_out_dec = 6'b000111;
12'd3067 : mem_out_dec = 6'b001000;
12'd3068 : mem_out_dec = 6'b001001;
12'd3069 : mem_out_dec = 6'b001001;
12'd3070 : mem_out_dec = 6'b001010;
12'd3071 : mem_out_dec = 6'b001011;
12'd3072 : mem_out_dec = 6'b111111;
12'd3073 : mem_out_dec = 6'b111111;
12'd3074 : mem_out_dec = 6'b111111;
12'd3075 : mem_out_dec = 6'b111111;
12'd3076 : mem_out_dec = 6'b111111;
12'd3077 : mem_out_dec = 6'b111111;
12'd3078 : mem_out_dec = 6'b111111;
12'd3079 : mem_out_dec = 6'b111111;
12'd3080 : mem_out_dec = 6'b111111;
12'd3081 : mem_out_dec = 6'b111111;
12'd3082 : mem_out_dec = 6'b111111;
12'd3083 : mem_out_dec = 6'b111111;
12'd3084 : mem_out_dec = 6'b111111;
12'd3085 : mem_out_dec = 6'b111111;
12'd3086 : mem_out_dec = 6'b111111;
12'd3087 : mem_out_dec = 6'b111111;
12'd3088 : mem_out_dec = 6'b111111;
12'd3089 : mem_out_dec = 6'b111111;
12'd3090 : mem_out_dec = 6'b111111;
12'd3091 : mem_out_dec = 6'b111111;
12'd3092 : mem_out_dec = 6'b111111;
12'd3093 : mem_out_dec = 6'b111111;
12'd3094 : mem_out_dec = 6'b111111;
12'd3095 : mem_out_dec = 6'b111111;
12'd3096 : mem_out_dec = 6'b111111;
12'd3097 : mem_out_dec = 6'b111111;
12'd3098 : mem_out_dec = 6'b111111;
12'd3099 : mem_out_dec = 6'b111111;
12'd3100 : mem_out_dec = 6'b111111;
12'd3101 : mem_out_dec = 6'b111111;
12'd3102 : mem_out_dec = 6'b111111;
12'd3103 : mem_out_dec = 6'b111111;
12'd3104 : mem_out_dec = 6'b111111;
12'd3105 : mem_out_dec = 6'b111111;
12'd3106 : mem_out_dec = 6'b111111;
12'd3107 : mem_out_dec = 6'b111111;
12'd3108 : mem_out_dec = 6'b111111;
12'd3109 : mem_out_dec = 6'b111111;
12'd3110 : mem_out_dec = 6'b111111;
12'd3111 : mem_out_dec = 6'b111111;
12'd3112 : mem_out_dec = 6'b111111;
12'd3113 : mem_out_dec = 6'b111111;
12'd3114 : mem_out_dec = 6'b111111;
12'd3115 : mem_out_dec = 6'b111111;
12'd3116 : mem_out_dec = 6'b111111;
12'd3117 : mem_out_dec = 6'b111111;
12'd3118 : mem_out_dec = 6'b111111;
12'd3119 : mem_out_dec = 6'b111111;
12'd3120 : mem_out_dec = 6'b111111;
12'd3121 : mem_out_dec = 6'b111111;
12'd3122 : mem_out_dec = 6'b111111;
12'd3123 : mem_out_dec = 6'b111111;
12'd3124 : mem_out_dec = 6'b111111;
12'd3125 : mem_out_dec = 6'b111111;
12'd3126 : mem_out_dec = 6'b000100;
12'd3127 : mem_out_dec = 6'b000101;
12'd3128 : mem_out_dec = 6'b000101;
12'd3129 : mem_out_dec = 6'b000110;
12'd3130 : mem_out_dec = 6'b000110;
12'd3131 : mem_out_dec = 6'b000111;
12'd3132 : mem_out_dec = 6'b001000;
12'd3133 : mem_out_dec = 6'b001000;
12'd3134 : mem_out_dec = 6'b001001;
12'd3135 : mem_out_dec = 6'b001010;
12'd3136 : mem_out_dec = 6'b111111;
12'd3137 : mem_out_dec = 6'b111111;
12'd3138 : mem_out_dec = 6'b111111;
12'd3139 : mem_out_dec = 6'b111111;
12'd3140 : mem_out_dec = 6'b111111;
12'd3141 : mem_out_dec = 6'b111111;
12'd3142 : mem_out_dec = 6'b111111;
12'd3143 : mem_out_dec = 6'b111111;
12'd3144 : mem_out_dec = 6'b111111;
12'd3145 : mem_out_dec = 6'b111111;
12'd3146 : mem_out_dec = 6'b111111;
12'd3147 : mem_out_dec = 6'b111111;
12'd3148 : mem_out_dec = 6'b111111;
12'd3149 : mem_out_dec = 6'b111111;
12'd3150 : mem_out_dec = 6'b111111;
12'd3151 : mem_out_dec = 6'b111111;
12'd3152 : mem_out_dec = 6'b111111;
12'd3153 : mem_out_dec = 6'b111111;
12'd3154 : mem_out_dec = 6'b111111;
12'd3155 : mem_out_dec = 6'b111111;
12'd3156 : mem_out_dec = 6'b111111;
12'd3157 : mem_out_dec = 6'b111111;
12'd3158 : mem_out_dec = 6'b111111;
12'd3159 : mem_out_dec = 6'b111111;
12'd3160 : mem_out_dec = 6'b111111;
12'd3161 : mem_out_dec = 6'b111111;
12'd3162 : mem_out_dec = 6'b111111;
12'd3163 : mem_out_dec = 6'b111111;
12'd3164 : mem_out_dec = 6'b111111;
12'd3165 : mem_out_dec = 6'b111111;
12'd3166 : mem_out_dec = 6'b111111;
12'd3167 : mem_out_dec = 6'b111111;
12'd3168 : mem_out_dec = 6'b111111;
12'd3169 : mem_out_dec = 6'b111111;
12'd3170 : mem_out_dec = 6'b111111;
12'd3171 : mem_out_dec = 6'b111111;
12'd3172 : mem_out_dec = 6'b111111;
12'd3173 : mem_out_dec = 6'b111111;
12'd3174 : mem_out_dec = 6'b111111;
12'd3175 : mem_out_dec = 6'b111111;
12'd3176 : mem_out_dec = 6'b111111;
12'd3177 : mem_out_dec = 6'b111111;
12'd3178 : mem_out_dec = 6'b111111;
12'd3179 : mem_out_dec = 6'b111111;
12'd3180 : mem_out_dec = 6'b111111;
12'd3181 : mem_out_dec = 6'b111111;
12'd3182 : mem_out_dec = 6'b111111;
12'd3183 : mem_out_dec = 6'b111111;
12'd3184 : mem_out_dec = 6'b111111;
12'd3185 : mem_out_dec = 6'b111111;
12'd3186 : mem_out_dec = 6'b111111;
12'd3187 : mem_out_dec = 6'b111111;
12'd3188 : mem_out_dec = 6'b111111;
12'd3189 : mem_out_dec = 6'b111111;
12'd3190 : mem_out_dec = 6'b111111;
12'd3191 : mem_out_dec = 6'b000100;
12'd3192 : mem_out_dec = 6'b000100;
12'd3193 : mem_out_dec = 6'b000101;
12'd3194 : mem_out_dec = 6'b000110;
12'd3195 : mem_out_dec = 6'b000110;
12'd3196 : mem_out_dec = 6'b000111;
12'd3197 : mem_out_dec = 6'b001000;
12'd3198 : mem_out_dec = 6'b001000;
12'd3199 : mem_out_dec = 6'b001001;
12'd3200 : mem_out_dec = 6'b111111;
12'd3201 : mem_out_dec = 6'b111111;
12'd3202 : mem_out_dec = 6'b111111;
12'd3203 : mem_out_dec = 6'b111111;
12'd3204 : mem_out_dec = 6'b111111;
12'd3205 : mem_out_dec = 6'b111111;
12'd3206 : mem_out_dec = 6'b111111;
12'd3207 : mem_out_dec = 6'b111111;
12'd3208 : mem_out_dec = 6'b111111;
12'd3209 : mem_out_dec = 6'b111111;
12'd3210 : mem_out_dec = 6'b111111;
12'd3211 : mem_out_dec = 6'b111111;
12'd3212 : mem_out_dec = 6'b111111;
12'd3213 : mem_out_dec = 6'b111111;
12'd3214 : mem_out_dec = 6'b111111;
12'd3215 : mem_out_dec = 6'b111111;
12'd3216 : mem_out_dec = 6'b111111;
12'd3217 : mem_out_dec = 6'b111111;
12'd3218 : mem_out_dec = 6'b111111;
12'd3219 : mem_out_dec = 6'b111111;
12'd3220 : mem_out_dec = 6'b111111;
12'd3221 : mem_out_dec = 6'b111111;
12'd3222 : mem_out_dec = 6'b111111;
12'd3223 : mem_out_dec = 6'b111111;
12'd3224 : mem_out_dec = 6'b111111;
12'd3225 : mem_out_dec = 6'b111111;
12'd3226 : mem_out_dec = 6'b111111;
12'd3227 : mem_out_dec = 6'b111111;
12'd3228 : mem_out_dec = 6'b111111;
12'd3229 : mem_out_dec = 6'b111111;
12'd3230 : mem_out_dec = 6'b111111;
12'd3231 : mem_out_dec = 6'b111111;
12'd3232 : mem_out_dec = 6'b111111;
12'd3233 : mem_out_dec = 6'b111111;
12'd3234 : mem_out_dec = 6'b111111;
12'd3235 : mem_out_dec = 6'b111111;
12'd3236 : mem_out_dec = 6'b111111;
12'd3237 : mem_out_dec = 6'b111111;
12'd3238 : mem_out_dec = 6'b111111;
12'd3239 : mem_out_dec = 6'b111111;
12'd3240 : mem_out_dec = 6'b111111;
12'd3241 : mem_out_dec = 6'b111111;
12'd3242 : mem_out_dec = 6'b111111;
12'd3243 : mem_out_dec = 6'b111111;
12'd3244 : mem_out_dec = 6'b111111;
12'd3245 : mem_out_dec = 6'b111111;
12'd3246 : mem_out_dec = 6'b111111;
12'd3247 : mem_out_dec = 6'b111111;
12'd3248 : mem_out_dec = 6'b111111;
12'd3249 : mem_out_dec = 6'b111111;
12'd3250 : mem_out_dec = 6'b111111;
12'd3251 : mem_out_dec = 6'b111111;
12'd3252 : mem_out_dec = 6'b111111;
12'd3253 : mem_out_dec = 6'b111111;
12'd3254 : mem_out_dec = 6'b111111;
12'd3255 : mem_out_dec = 6'b111111;
12'd3256 : mem_out_dec = 6'b000100;
12'd3257 : mem_out_dec = 6'b000100;
12'd3258 : mem_out_dec = 6'b000101;
12'd3259 : mem_out_dec = 6'b000110;
12'd3260 : mem_out_dec = 6'b000110;
12'd3261 : mem_out_dec = 6'b000111;
12'd3262 : mem_out_dec = 6'b001000;
12'd3263 : mem_out_dec = 6'b001001;
12'd3264 : mem_out_dec = 6'b111111;
12'd3265 : mem_out_dec = 6'b111111;
12'd3266 : mem_out_dec = 6'b111111;
12'd3267 : mem_out_dec = 6'b111111;
12'd3268 : mem_out_dec = 6'b111111;
12'd3269 : mem_out_dec = 6'b111111;
12'd3270 : mem_out_dec = 6'b111111;
12'd3271 : mem_out_dec = 6'b111111;
12'd3272 : mem_out_dec = 6'b111111;
12'd3273 : mem_out_dec = 6'b111111;
12'd3274 : mem_out_dec = 6'b111111;
12'd3275 : mem_out_dec = 6'b111111;
12'd3276 : mem_out_dec = 6'b111111;
12'd3277 : mem_out_dec = 6'b111111;
12'd3278 : mem_out_dec = 6'b111111;
12'd3279 : mem_out_dec = 6'b111111;
12'd3280 : mem_out_dec = 6'b111111;
12'd3281 : mem_out_dec = 6'b111111;
12'd3282 : mem_out_dec = 6'b111111;
12'd3283 : mem_out_dec = 6'b111111;
12'd3284 : mem_out_dec = 6'b111111;
12'd3285 : mem_out_dec = 6'b111111;
12'd3286 : mem_out_dec = 6'b111111;
12'd3287 : mem_out_dec = 6'b111111;
12'd3288 : mem_out_dec = 6'b111111;
12'd3289 : mem_out_dec = 6'b111111;
12'd3290 : mem_out_dec = 6'b111111;
12'd3291 : mem_out_dec = 6'b111111;
12'd3292 : mem_out_dec = 6'b111111;
12'd3293 : mem_out_dec = 6'b111111;
12'd3294 : mem_out_dec = 6'b111111;
12'd3295 : mem_out_dec = 6'b111111;
12'd3296 : mem_out_dec = 6'b111111;
12'd3297 : mem_out_dec = 6'b111111;
12'd3298 : mem_out_dec = 6'b111111;
12'd3299 : mem_out_dec = 6'b111111;
12'd3300 : mem_out_dec = 6'b111111;
12'd3301 : mem_out_dec = 6'b111111;
12'd3302 : mem_out_dec = 6'b111111;
12'd3303 : mem_out_dec = 6'b111111;
12'd3304 : mem_out_dec = 6'b111111;
12'd3305 : mem_out_dec = 6'b111111;
12'd3306 : mem_out_dec = 6'b111111;
12'd3307 : mem_out_dec = 6'b111111;
12'd3308 : mem_out_dec = 6'b111111;
12'd3309 : mem_out_dec = 6'b111111;
12'd3310 : mem_out_dec = 6'b111111;
12'd3311 : mem_out_dec = 6'b111111;
12'd3312 : mem_out_dec = 6'b111111;
12'd3313 : mem_out_dec = 6'b111111;
12'd3314 : mem_out_dec = 6'b111111;
12'd3315 : mem_out_dec = 6'b111111;
12'd3316 : mem_out_dec = 6'b111111;
12'd3317 : mem_out_dec = 6'b111111;
12'd3318 : mem_out_dec = 6'b111111;
12'd3319 : mem_out_dec = 6'b111111;
12'd3320 : mem_out_dec = 6'b111111;
12'd3321 : mem_out_dec = 6'b000100;
12'd3322 : mem_out_dec = 6'b000100;
12'd3323 : mem_out_dec = 6'b000101;
12'd3324 : mem_out_dec = 6'b000110;
12'd3325 : mem_out_dec = 6'b000111;
12'd3326 : mem_out_dec = 6'b001000;
12'd3327 : mem_out_dec = 6'b001000;
12'd3328 : mem_out_dec = 6'b111111;
12'd3329 : mem_out_dec = 6'b111111;
12'd3330 : mem_out_dec = 6'b111111;
12'd3331 : mem_out_dec = 6'b111111;
12'd3332 : mem_out_dec = 6'b111111;
12'd3333 : mem_out_dec = 6'b111111;
12'd3334 : mem_out_dec = 6'b111111;
12'd3335 : mem_out_dec = 6'b111111;
12'd3336 : mem_out_dec = 6'b111111;
12'd3337 : mem_out_dec = 6'b111111;
12'd3338 : mem_out_dec = 6'b111111;
12'd3339 : mem_out_dec = 6'b111111;
12'd3340 : mem_out_dec = 6'b111111;
12'd3341 : mem_out_dec = 6'b111111;
12'd3342 : mem_out_dec = 6'b111111;
12'd3343 : mem_out_dec = 6'b111111;
12'd3344 : mem_out_dec = 6'b111111;
12'd3345 : mem_out_dec = 6'b111111;
12'd3346 : mem_out_dec = 6'b111111;
12'd3347 : mem_out_dec = 6'b111111;
12'd3348 : mem_out_dec = 6'b111111;
12'd3349 : mem_out_dec = 6'b111111;
12'd3350 : mem_out_dec = 6'b111111;
12'd3351 : mem_out_dec = 6'b111111;
12'd3352 : mem_out_dec = 6'b111111;
12'd3353 : mem_out_dec = 6'b111111;
12'd3354 : mem_out_dec = 6'b111111;
12'd3355 : mem_out_dec = 6'b111111;
12'd3356 : mem_out_dec = 6'b111111;
12'd3357 : mem_out_dec = 6'b111111;
12'd3358 : mem_out_dec = 6'b111111;
12'd3359 : mem_out_dec = 6'b111111;
12'd3360 : mem_out_dec = 6'b111111;
12'd3361 : mem_out_dec = 6'b111111;
12'd3362 : mem_out_dec = 6'b111111;
12'd3363 : mem_out_dec = 6'b111111;
12'd3364 : mem_out_dec = 6'b111111;
12'd3365 : mem_out_dec = 6'b111111;
12'd3366 : mem_out_dec = 6'b111111;
12'd3367 : mem_out_dec = 6'b111111;
12'd3368 : mem_out_dec = 6'b111111;
12'd3369 : mem_out_dec = 6'b111111;
12'd3370 : mem_out_dec = 6'b111111;
12'd3371 : mem_out_dec = 6'b111111;
12'd3372 : mem_out_dec = 6'b111111;
12'd3373 : mem_out_dec = 6'b111111;
12'd3374 : mem_out_dec = 6'b111111;
12'd3375 : mem_out_dec = 6'b111111;
12'd3376 : mem_out_dec = 6'b111111;
12'd3377 : mem_out_dec = 6'b111111;
12'd3378 : mem_out_dec = 6'b111111;
12'd3379 : mem_out_dec = 6'b111111;
12'd3380 : mem_out_dec = 6'b111111;
12'd3381 : mem_out_dec = 6'b111111;
12'd3382 : mem_out_dec = 6'b111111;
12'd3383 : mem_out_dec = 6'b111111;
12'd3384 : mem_out_dec = 6'b111111;
12'd3385 : mem_out_dec = 6'b111111;
12'd3386 : mem_out_dec = 6'b000100;
12'd3387 : mem_out_dec = 6'b000101;
12'd3388 : mem_out_dec = 6'b000110;
12'd3389 : mem_out_dec = 6'b000110;
12'd3390 : mem_out_dec = 6'b000111;
12'd3391 : mem_out_dec = 6'b001000;
12'd3392 : mem_out_dec = 6'b111111;
12'd3393 : mem_out_dec = 6'b111111;
12'd3394 : mem_out_dec = 6'b111111;
12'd3395 : mem_out_dec = 6'b111111;
12'd3396 : mem_out_dec = 6'b111111;
12'd3397 : mem_out_dec = 6'b111111;
12'd3398 : mem_out_dec = 6'b111111;
12'd3399 : mem_out_dec = 6'b111111;
12'd3400 : mem_out_dec = 6'b111111;
12'd3401 : mem_out_dec = 6'b111111;
12'd3402 : mem_out_dec = 6'b111111;
12'd3403 : mem_out_dec = 6'b111111;
12'd3404 : mem_out_dec = 6'b111111;
12'd3405 : mem_out_dec = 6'b111111;
12'd3406 : mem_out_dec = 6'b111111;
12'd3407 : mem_out_dec = 6'b111111;
12'd3408 : mem_out_dec = 6'b111111;
12'd3409 : mem_out_dec = 6'b111111;
12'd3410 : mem_out_dec = 6'b111111;
12'd3411 : mem_out_dec = 6'b111111;
12'd3412 : mem_out_dec = 6'b111111;
12'd3413 : mem_out_dec = 6'b111111;
12'd3414 : mem_out_dec = 6'b111111;
12'd3415 : mem_out_dec = 6'b111111;
12'd3416 : mem_out_dec = 6'b111111;
12'd3417 : mem_out_dec = 6'b111111;
12'd3418 : mem_out_dec = 6'b111111;
12'd3419 : mem_out_dec = 6'b111111;
12'd3420 : mem_out_dec = 6'b111111;
12'd3421 : mem_out_dec = 6'b111111;
12'd3422 : mem_out_dec = 6'b111111;
12'd3423 : mem_out_dec = 6'b111111;
12'd3424 : mem_out_dec = 6'b111111;
12'd3425 : mem_out_dec = 6'b111111;
12'd3426 : mem_out_dec = 6'b111111;
12'd3427 : mem_out_dec = 6'b111111;
12'd3428 : mem_out_dec = 6'b111111;
12'd3429 : mem_out_dec = 6'b111111;
12'd3430 : mem_out_dec = 6'b111111;
12'd3431 : mem_out_dec = 6'b111111;
12'd3432 : mem_out_dec = 6'b111111;
12'd3433 : mem_out_dec = 6'b111111;
12'd3434 : mem_out_dec = 6'b111111;
12'd3435 : mem_out_dec = 6'b111111;
12'd3436 : mem_out_dec = 6'b111111;
12'd3437 : mem_out_dec = 6'b111111;
12'd3438 : mem_out_dec = 6'b111111;
12'd3439 : mem_out_dec = 6'b111111;
12'd3440 : mem_out_dec = 6'b111111;
12'd3441 : mem_out_dec = 6'b111111;
12'd3442 : mem_out_dec = 6'b111111;
12'd3443 : mem_out_dec = 6'b111111;
12'd3444 : mem_out_dec = 6'b111111;
12'd3445 : mem_out_dec = 6'b111111;
12'd3446 : mem_out_dec = 6'b111111;
12'd3447 : mem_out_dec = 6'b111111;
12'd3448 : mem_out_dec = 6'b111111;
12'd3449 : mem_out_dec = 6'b111111;
12'd3450 : mem_out_dec = 6'b111111;
12'd3451 : mem_out_dec = 6'b000100;
12'd3452 : mem_out_dec = 6'b000101;
12'd3453 : mem_out_dec = 6'b000110;
12'd3454 : mem_out_dec = 6'b000111;
12'd3455 : mem_out_dec = 6'b001000;
12'd3456 : mem_out_dec = 6'b111111;
12'd3457 : mem_out_dec = 6'b111111;
12'd3458 : mem_out_dec = 6'b111111;
12'd3459 : mem_out_dec = 6'b111111;
12'd3460 : mem_out_dec = 6'b111111;
12'd3461 : mem_out_dec = 6'b111111;
12'd3462 : mem_out_dec = 6'b111111;
12'd3463 : mem_out_dec = 6'b111111;
12'd3464 : mem_out_dec = 6'b111111;
12'd3465 : mem_out_dec = 6'b111111;
12'd3466 : mem_out_dec = 6'b111111;
12'd3467 : mem_out_dec = 6'b111111;
12'd3468 : mem_out_dec = 6'b111111;
12'd3469 : mem_out_dec = 6'b111111;
12'd3470 : mem_out_dec = 6'b111111;
12'd3471 : mem_out_dec = 6'b111111;
12'd3472 : mem_out_dec = 6'b111111;
12'd3473 : mem_out_dec = 6'b111111;
12'd3474 : mem_out_dec = 6'b111111;
12'd3475 : mem_out_dec = 6'b111111;
12'd3476 : mem_out_dec = 6'b111111;
12'd3477 : mem_out_dec = 6'b111111;
12'd3478 : mem_out_dec = 6'b111111;
12'd3479 : mem_out_dec = 6'b111111;
12'd3480 : mem_out_dec = 6'b111111;
12'd3481 : mem_out_dec = 6'b111111;
12'd3482 : mem_out_dec = 6'b111111;
12'd3483 : mem_out_dec = 6'b111111;
12'd3484 : mem_out_dec = 6'b111111;
12'd3485 : mem_out_dec = 6'b111111;
12'd3486 : mem_out_dec = 6'b111111;
12'd3487 : mem_out_dec = 6'b111111;
12'd3488 : mem_out_dec = 6'b111111;
12'd3489 : mem_out_dec = 6'b111111;
12'd3490 : mem_out_dec = 6'b111111;
12'd3491 : mem_out_dec = 6'b111111;
12'd3492 : mem_out_dec = 6'b111111;
12'd3493 : mem_out_dec = 6'b111111;
12'd3494 : mem_out_dec = 6'b111111;
12'd3495 : mem_out_dec = 6'b111111;
12'd3496 : mem_out_dec = 6'b111111;
12'd3497 : mem_out_dec = 6'b111111;
12'd3498 : mem_out_dec = 6'b111111;
12'd3499 : mem_out_dec = 6'b111111;
12'd3500 : mem_out_dec = 6'b111111;
12'd3501 : mem_out_dec = 6'b111111;
12'd3502 : mem_out_dec = 6'b111111;
12'd3503 : mem_out_dec = 6'b111111;
12'd3504 : mem_out_dec = 6'b111111;
12'd3505 : mem_out_dec = 6'b111111;
12'd3506 : mem_out_dec = 6'b111111;
12'd3507 : mem_out_dec = 6'b111111;
12'd3508 : mem_out_dec = 6'b111111;
12'd3509 : mem_out_dec = 6'b111111;
12'd3510 : mem_out_dec = 6'b111111;
12'd3511 : mem_out_dec = 6'b111111;
12'd3512 : mem_out_dec = 6'b111111;
12'd3513 : mem_out_dec = 6'b111111;
12'd3514 : mem_out_dec = 6'b111111;
12'd3515 : mem_out_dec = 6'b111111;
12'd3516 : mem_out_dec = 6'b000101;
12'd3517 : mem_out_dec = 6'b000110;
12'd3518 : mem_out_dec = 6'b000110;
12'd3519 : mem_out_dec = 6'b000111;
12'd3520 : mem_out_dec = 6'b111111;
12'd3521 : mem_out_dec = 6'b111111;
12'd3522 : mem_out_dec = 6'b111111;
12'd3523 : mem_out_dec = 6'b111111;
12'd3524 : mem_out_dec = 6'b111111;
12'd3525 : mem_out_dec = 6'b111111;
12'd3526 : mem_out_dec = 6'b111111;
12'd3527 : mem_out_dec = 6'b111111;
12'd3528 : mem_out_dec = 6'b111111;
12'd3529 : mem_out_dec = 6'b111111;
12'd3530 : mem_out_dec = 6'b111111;
12'd3531 : mem_out_dec = 6'b111111;
12'd3532 : mem_out_dec = 6'b111111;
12'd3533 : mem_out_dec = 6'b111111;
12'd3534 : mem_out_dec = 6'b111111;
12'd3535 : mem_out_dec = 6'b111111;
12'd3536 : mem_out_dec = 6'b111111;
12'd3537 : mem_out_dec = 6'b111111;
12'd3538 : mem_out_dec = 6'b111111;
12'd3539 : mem_out_dec = 6'b111111;
12'd3540 : mem_out_dec = 6'b111111;
12'd3541 : mem_out_dec = 6'b111111;
12'd3542 : mem_out_dec = 6'b111111;
12'd3543 : mem_out_dec = 6'b111111;
12'd3544 : mem_out_dec = 6'b111111;
12'd3545 : mem_out_dec = 6'b111111;
12'd3546 : mem_out_dec = 6'b111111;
12'd3547 : mem_out_dec = 6'b111111;
12'd3548 : mem_out_dec = 6'b111111;
12'd3549 : mem_out_dec = 6'b111111;
12'd3550 : mem_out_dec = 6'b111111;
12'd3551 : mem_out_dec = 6'b111111;
12'd3552 : mem_out_dec = 6'b111111;
12'd3553 : mem_out_dec = 6'b111111;
12'd3554 : mem_out_dec = 6'b111111;
12'd3555 : mem_out_dec = 6'b111111;
12'd3556 : mem_out_dec = 6'b111111;
12'd3557 : mem_out_dec = 6'b111111;
12'd3558 : mem_out_dec = 6'b111111;
12'd3559 : mem_out_dec = 6'b111111;
12'd3560 : mem_out_dec = 6'b111111;
12'd3561 : mem_out_dec = 6'b111111;
12'd3562 : mem_out_dec = 6'b111111;
12'd3563 : mem_out_dec = 6'b111111;
12'd3564 : mem_out_dec = 6'b111111;
12'd3565 : mem_out_dec = 6'b111111;
12'd3566 : mem_out_dec = 6'b111111;
12'd3567 : mem_out_dec = 6'b111111;
12'd3568 : mem_out_dec = 6'b111111;
12'd3569 : mem_out_dec = 6'b111111;
12'd3570 : mem_out_dec = 6'b111111;
12'd3571 : mem_out_dec = 6'b111111;
12'd3572 : mem_out_dec = 6'b111111;
12'd3573 : mem_out_dec = 6'b111111;
12'd3574 : mem_out_dec = 6'b111111;
12'd3575 : mem_out_dec = 6'b111111;
12'd3576 : mem_out_dec = 6'b111111;
12'd3577 : mem_out_dec = 6'b111111;
12'd3578 : mem_out_dec = 6'b111111;
12'd3579 : mem_out_dec = 6'b111111;
12'd3580 : mem_out_dec = 6'b111111;
12'd3581 : mem_out_dec = 6'b000101;
12'd3582 : mem_out_dec = 6'b000110;
12'd3583 : mem_out_dec = 6'b000110;
12'd3584 : mem_out_dec = 6'b111111;
12'd3585 : mem_out_dec = 6'b111111;
12'd3586 : mem_out_dec = 6'b111111;
12'd3587 : mem_out_dec = 6'b111111;
12'd3588 : mem_out_dec = 6'b111111;
12'd3589 : mem_out_dec = 6'b111111;
12'd3590 : mem_out_dec = 6'b111111;
12'd3591 : mem_out_dec = 6'b111111;
12'd3592 : mem_out_dec = 6'b111111;
12'd3593 : mem_out_dec = 6'b111111;
12'd3594 : mem_out_dec = 6'b111111;
12'd3595 : mem_out_dec = 6'b111111;
12'd3596 : mem_out_dec = 6'b111111;
12'd3597 : mem_out_dec = 6'b111111;
12'd3598 : mem_out_dec = 6'b111111;
12'd3599 : mem_out_dec = 6'b111111;
12'd3600 : mem_out_dec = 6'b111111;
12'd3601 : mem_out_dec = 6'b111111;
12'd3602 : mem_out_dec = 6'b111111;
12'd3603 : mem_out_dec = 6'b111111;
12'd3604 : mem_out_dec = 6'b111111;
12'd3605 : mem_out_dec = 6'b111111;
12'd3606 : mem_out_dec = 6'b111111;
12'd3607 : mem_out_dec = 6'b111111;
12'd3608 : mem_out_dec = 6'b111111;
12'd3609 : mem_out_dec = 6'b111111;
12'd3610 : mem_out_dec = 6'b111111;
12'd3611 : mem_out_dec = 6'b111111;
12'd3612 : mem_out_dec = 6'b111111;
12'd3613 : mem_out_dec = 6'b111111;
12'd3614 : mem_out_dec = 6'b111111;
12'd3615 : mem_out_dec = 6'b111111;
12'd3616 : mem_out_dec = 6'b111111;
12'd3617 : mem_out_dec = 6'b111111;
12'd3618 : mem_out_dec = 6'b111111;
12'd3619 : mem_out_dec = 6'b111111;
12'd3620 : mem_out_dec = 6'b111111;
12'd3621 : mem_out_dec = 6'b111111;
12'd3622 : mem_out_dec = 6'b111111;
12'd3623 : mem_out_dec = 6'b111111;
12'd3624 : mem_out_dec = 6'b111111;
12'd3625 : mem_out_dec = 6'b111111;
12'd3626 : mem_out_dec = 6'b111111;
12'd3627 : mem_out_dec = 6'b111111;
12'd3628 : mem_out_dec = 6'b111111;
12'd3629 : mem_out_dec = 6'b111111;
12'd3630 : mem_out_dec = 6'b111111;
12'd3631 : mem_out_dec = 6'b111111;
12'd3632 : mem_out_dec = 6'b111111;
12'd3633 : mem_out_dec = 6'b111111;
12'd3634 : mem_out_dec = 6'b111111;
12'd3635 : mem_out_dec = 6'b111111;
12'd3636 : mem_out_dec = 6'b111111;
12'd3637 : mem_out_dec = 6'b111111;
12'd3638 : mem_out_dec = 6'b111111;
12'd3639 : mem_out_dec = 6'b111111;
12'd3640 : mem_out_dec = 6'b111111;
12'd3641 : mem_out_dec = 6'b111111;
12'd3642 : mem_out_dec = 6'b111111;
12'd3643 : mem_out_dec = 6'b111111;
12'd3644 : mem_out_dec = 6'b111111;
12'd3645 : mem_out_dec = 6'b111111;
12'd3646 : mem_out_dec = 6'b000100;
12'd3647 : mem_out_dec = 6'b000101;
12'd3648 : mem_out_dec = 6'b111111;
12'd3649 : mem_out_dec = 6'b111111;
12'd3650 : mem_out_dec = 6'b111111;
12'd3651 : mem_out_dec = 6'b111111;
12'd3652 : mem_out_dec = 6'b111111;
12'd3653 : mem_out_dec = 6'b111111;
12'd3654 : mem_out_dec = 6'b111111;
12'd3655 : mem_out_dec = 6'b111111;
12'd3656 : mem_out_dec = 6'b111111;
12'd3657 : mem_out_dec = 6'b111111;
12'd3658 : mem_out_dec = 6'b111111;
12'd3659 : mem_out_dec = 6'b111111;
12'd3660 : mem_out_dec = 6'b111111;
12'd3661 : mem_out_dec = 6'b111111;
12'd3662 : mem_out_dec = 6'b111111;
12'd3663 : mem_out_dec = 6'b111111;
12'd3664 : mem_out_dec = 6'b111111;
12'd3665 : mem_out_dec = 6'b111111;
12'd3666 : mem_out_dec = 6'b111111;
12'd3667 : mem_out_dec = 6'b111111;
12'd3668 : mem_out_dec = 6'b111111;
12'd3669 : mem_out_dec = 6'b111111;
12'd3670 : mem_out_dec = 6'b111111;
12'd3671 : mem_out_dec = 6'b111111;
12'd3672 : mem_out_dec = 6'b111111;
12'd3673 : mem_out_dec = 6'b111111;
12'd3674 : mem_out_dec = 6'b111111;
12'd3675 : mem_out_dec = 6'b111111;
12'd3676 : mem_out_dec = 6'b111111;
12'd3677 : mem_out_dec = 6'b111111;
12'd3678 : mem_out_dec = 6'b111111;
12'd3679 : mem_out_dec = 6'b111111;
12'd3680 : mem_out_dec = 6'b111111;
12'd3681 : mem_out_dec = 6'b111111;
12'd3682 : mem_out_dec = 6'b111111;
12'd3683 : mem_out_dec = 6'b111111;
12'd3684 : mem_out_dec = 6'b111111;
12'd3685 : mem_out_dec = 6'b111111;
12'd3686 : mem_out_dec = 6'b111111;
12'd3687 : mem_out_dec = 6'b111111;
12'd3688 : mem_out_dec = 6'b111111;
12'd3689 : mem_out_dec = 6'b111111;
12'd3690 : mem_out_dec = 6'b111111;
12'd3691 : mem_out_dec = 6'b111111;
12'd3692 : mem_out_dec = 6'b111111;
12'd3693 : mem_out_dec = 6'b111111;
12'd3694 : mem_out_dec = 6'b111111;
12'd3695 : mem_out_dec = 6'b111111;
12'd3696 : mem_out_dec = 6'b111111;
12'd3697 : mem_out_dec = 6'b111111;
12'd3698 : mem_out_dec = 6'b111111;
12'd3699 : mem_out_dec = 6'b111111;
12'd3700 : mem_out_dec = 6'b111111;
12'd3701 : mem_out_dec = 6'b111111;
12'd3702 : mem_out_dec = 6'b111111;
12'd3703 : mem_out_dec = 6'b111111;
12'd3704 : mem_out_dec = 6'b111111;
12'd3705 : mem_out_dec = 6'b111111;
12'd3706 : mem_out_dec = 6'b111111;
12'd3707 : mem_out_dec = 6'b111111;
12'd3708 : mem_out_dec = 6'b111111;
12'd3709 : mem_out_dec = 6'b111111;
12'd3710 : mem_out_dec = 6'b111111;
12'd3711 : mem_out_dec = 6'b000100;
12'd3712 : mem_out_dec = 6'b111111;
12'd3713 : mem_out_dec = 6'b111111;
12'd3714 : mem_out_dec = 6'b111111;
12'd3715 : mem_out_dec = 6'b111111;
12'd3716 : mem_out_dec = 6'b111111;
12'd3717 : mem_out_dec = 6'b111111;
12'd3718 : mem_out_dec = 6'b111111;
12'd3719 : mem_out_dec = 6'b111111;
12'd3720 : mem_out_dec = 6'b111111;
12'd3721 : mem_out_dec = 6'b111111;
12'd3722 : mem_out_dec = 6'b111111;
12'd3723 : mem_out_dec = 6'b111111;
12'd3724 : mem_out_dec = 6'b111111;
12'd3725 : mem_out_dec = 6'b111111;
12'd3726 : mem_out_dec = 6'b111111;
12'd3727 : mem_out_dec = 6'b111111;
12'd3728 : mem_out_dec = 6'b111111;
12'd3729 : mem_out_dec = 6'b111111;
12'd3730 : mem_out_dec = 6'b111111;
12'd3731 : mem_out_dec = 6'b111111;
12'd3732 : mem_out_dec = 6'b111111;
12'd3733 : mem_out_dec = 6'b111111;
12'd3734 : mem_out_dec = 6'b111111;
12'd3735 : mem_out_dec = 6'b111111;
12'd3736 : mem_out_dec = 6'b111111;
12'd3737 : mem_out_dec = 6'b111111;
12'd3738 : mem_out_dec = 6'b111111;
12'd3739 : mem_out_dec = 6'b111111;
12'd3740 : mem_out_dec = 6'b111111;
12'd3741 : mem_out_dec = 6'b111111;
12'd3742 : mem_out_dec = 6'b111111;
12'd3743 : mem_out_dec = 6'b111111;
12'd3744 : mem_out_dec = 6'b111111;
12'd3745 : mem_out_dec = 6'b111111;
12'd3746 : mem_out_dec = 6'b111111;
12'd3747 : mem_out_dec = 6'b111111;
12'd3748 : mem_out_dec = 6'b111111;
12'd3749 : mem_out_dec = 6'b111111;
12'd3750 : mem_out_dec = 6'b111111;
12'd3751 : mem_out_dec = 6'b111111;
12'd3752 : mem_out_dec = 6'b111111;
12'd3753 : mem_out_dec = 6'b111111;
12'd3754 : mem_out_dec = 6'b111111;
12'd3755 : mem_out_dec = 6'b111111;
12'd3756 : mem_out_dec = 6'b111111;
12'd3757 : mem_out_dec = 6'b111111;
12'd3758 : mem_out_dec = 6'b111111;
12'd3759 : mem_out_dec = 6'b111111;
12'd3760 : mem_out_dec = 6'b111111;
12'd3761 : mem_out_dec = 6'b111111;
12'd3762 : mem_out_dec = 6'b111111;
12'd3763 : mem_out_dec = 6'b111111;
12'd3764 : mem_out_dec = 6'b111111;
12'd3765 : mem_out_dec = 6'b111111;
12'd3766 : mem_out_dec = 6'b111111;
12'd3767 : mem_out_dec = 6'b111111;
12'd3768 : mem_out_dec = 6'b111111;
12'd3769 : mem_out_dec = 6'b111111;
12'd3770 : mem_out_dec = 6'b111111;
12'd3771 : mem_out_dec = 6'b111111;
12'd3772 : mem_out_dec = 6'b111111;
12'd3773 : mem_out_dec = 6'b111111;
12'd3774 : mem_out_dec = 6'b111111;
12'd3775 : mem_out_dec = 6'b111111;
12'd3776 : mem_out_dec = 6'b111111;
12'd3777 : mem_out_dec = 6'b111111;
12'd3778 : mem_out_dec = 6'b111111;
12'd3779 : mem_out_dec = 6'b111111;
12'd3780 : mem_out_dec = 6'b111111;
12'd3781 : mem_out_dec = 6'b111111;
12'd3782 : mem_out_dec = 6'b111111;
12'd3783 : mem_out_dec = 6'b111111;
12'd3784 : mem_out_dec = 6'b111111;
12'd3785 : mem_out_dec = 6'b111111;
12'd3786 : mem_out_dec = 6'b111111;
12'd3787 : mem_out_dec = 6'b111111;
12'd3788 : mem_out_dec = 6'b111111;
12'd3789 : mem_out_dec = 6'b111111;
12'd3790 : mem_out_dec = 6'b111111;
12'd3791 : mem_out_dec = 6'b111111;
12'd3792 : mem_out_dec = 6'b111111;
12'd3793 : mem_out_dec = 6'b111111;
12'd3794 : mem_out_dec = 6'b111111;
12'd3795 : mem_out_dec = 6'b111111;
12'd3796 : mem_out_dec = 6'b111111;
12'd3797 : mem_out_dec = 6'b111111;
12'd3798 : mem_out_dec = 6'b111111;
12'd3799 : mem_out_dec = 6'b111111;
12'd3800 : mem_out_dec = 6'b111111;
12'd3801 : mem_out_dec = 6'b111111;
12'd3802 : mem_out_dec = 6'b111111;
12'd3803 : mem_out_dec = 6'b111111;
12'd3804 : mem_out_dec = 6'b111111;
12'd3805 : mem_out_dec = 6'b111111;
12'd3806 : mem_out_dec = 6'b111111;
12'd3807 : mem_out_dec = 6'b111111;
12'd3808 : mem_out_dec = 6'b111111;
12'd3809 : mem_out_dec = 6'b111111;
12'd3810 : mem_out_dec = 6'b111111;
12'd3811 : mem_out_dec = 6'b111111;
12'd3812 : mem_out_dec = 6'b111111;
12'd3813 : mem_out_dec = 6'b111111;
12'd3814 : mem_out_dec = 6'b111111;
12'd3815 : mem_out_dec = 6'b111111;
12'd3816 : mem_out_dec = 6'b111111;
12'd3817 : mem_out_dec = 6'b111111;
12'd3818 : mem_out_dec = 6'b111111;
12'd3819 : mem_out_dec = 6'b111111;
12'd3820 : mem_out_dec = 6'b111111;
12'd3821 : mem_out_dec = 6'b111111;
12'd3822 : mem_out_dec = 6'b111111;
12'd3823 : mem_out_dec = 6'b111111;
12'd3824 : mem_out_dec = 6'b111111;
12'd3825 : mem_out_dec = 6'b111111;
12'd3826 : mem_out_dec = 6'b111111;
12'd3827 : mem_out_dec = 6'b111111;
12'd3828 : mem_out_dec = 6'b111111;
12'd3829 : mem_out_dec = 6'b111111;
12'd3830 : mem_out_dec = 6'b111111;
12'd3831 : mem_out_dec = 6'b111111;
12'd3832 : mem_out_dec = 6'b111111;
12'd3833 : mem_out_dec = 6'b111111;
12'd3834 : mem_out_dec = 6'b111111;
12'd3835 : mem_out_dec = 6'b111111;
12'd3836 : mem_out_dec = 6'b111111;
12'd3837 : mem_out_dec = 6'b111111;
12'd3838 : mem_out_dec = 6'b111111;
12'd3839 : mem_out_dec = 6'b111111;
12'd3840 : mem_out_dec = 6'b111111;
12'd3841 : mem_out_dec = 6'b111111;
12'd3842 : mem_out_dec = 6'b111111;
12'd3843 : mem_out_dec = 6'b111111;
12'd3844 : mem_out_dec = 6'b111111;
12'd3845 : mem_out_dec = 6'b111111;
12'd3846 : mem_out_dec = 6'b111111;
12'd3847 : mem_out_dec = 6'b111111;
12'd3848 : mem_out_dec = 6'b111111;
12'd3849 : mem_out_dec = 6'b111111;
12'd3850 : mem_out_dec = 6'b111111;
12'd3851 : mem_out_dec = 6'b111111;
12'd3852 : mem_out_dec = 6'b111111;
12'd3853 : mem_out_dec = 6'b111111;
12'd3854 : mem_out_dec = 6'b111111;
12'd3855 : mem_out_dec = 6'b111111;
12'd3856 : mem_out_dec = 6'b111111;
12'd3857 : mem_out_dec = 6'b111111;
12'd3858 : mem_out_dec = 6'b111111;
12'd3859 : mem_out_dec = 6'b111111;
12'd3860 : mem_out_dec = 6'b111111;
12'd3861 : mem_out_dec = 6'b111111;
12'd3862 : mem_out_dec = 6'b111111;
12'd3863 : mem_out_dec = 6'b111111;
12'd3864 : mem_out_dec = 6'b111111;
12'd3865 : mem_out_dec = 6'b111111;
12'd3866 : mem_out_dec = 6'b111111;
12'd3867 : mem_out_dec = 6'b111111;
12'd3868 : mem_out_dec = 6'b111111;
12'd3869 : mem_out_dec = 6'b111111;
12'd3870 : mem_out_dec = 6'b111111;
12'd3871 : mem_out_dec = 6'b111111;
12'd3872 : mem_out_dec = 6'b111111;
12'd3873 : mem_out_dec = 6'b111111;
12'd3874 : mem_out_dec = 6'b111111;
12'd3875 : mem_out_dec = 6'b111111;
12'd3876 : mem_out_dec = 6'b111111;
12'd3877 : mem_out_dec = 6'b111111;
12'd3878 : mem_out_dec = 6'b111111;
12'd3879 : mem_out_dec = 6'b111111;
12'd3880 : mem_out_dec = 6'b111111;
12'd3881 : mem_out_dec = 6'b111111;
12'd3882 : mem_out_dec = 6'b111111;
12'd3883 : mem_out_dec = 6'b111111;
12'd3884 : mem_out_dec = 6'b111111;
12'd3885 : mem_out_dec = 6'b111111;
12'd3886 : mem_out_dec = 6'b111111;
12'd3887 : mem_out_dec = 6'b111111;
12'd3888 : mem_out_dec = 6'b111111;
12'd3889 : mem_out_dec = 6'b111111;
12'd3890 : mem_out_dec = 6'b111111;
12'd3891 : mem_out_dec = 6'b111111;
12'd3892 : mem_out_dec = 6'b111111;
12'd3893 : mem_out_dec = 6'b111111;
12'd3894 : mem_out_dec = 6'b111111;
12'd3895 : mem_out_dec = 6'b111111;
12'd3896 : mem_out_dec = 6'b111111;
12'd3897 : mem_out_dec = 6'b111111;
12'd3898 : mem_out_dec = 6'b111111;
12'd3899 : mem_out_dec = 6'b111111;
12'd3900 : mem_out_dec = 6'b111111;
12'd3901 : mem_out_dec = 6'b111111;
12'd3902 : mem_out_dec = 6'b111111;
12'd3903 : mem_out_dec = 6'b111111;
12'd3904 : mem_out_dec = 6'b111111;
12'd3905 : mem_out_dec = 6'b111111;
12'd3906 : mem_out_dec = 6'b111111;
12'd3907 : mem_out_dec = 6'b111111;
12'd3908 : mem_out_dec = 6'b111111;
12'd3909 : mem_out_dec = 6'b111111;
12'd3910 : mem_out_dec = 6'b111111;
12'd3911 : mem_out_dec = 6'b111111;
12'd3912 : mem_out_dec = 6'b111111;
12'd3913 : mem_out_dec = 6'b111111;
12'd3914 : mem_out_dec = 6'b111111;
12'd3915 : mem_out_dec = 6'b111111;
12'd3916 : mem_out_dec = 6'b111111;
12'd3917 : mem_out_dec = 6'b111111;
12'd3918 : mem_out_dec = 6'b111111;
12'd3919 : mem_out_dec = 6'b111111;
12'd3920 : mem_out_dec = 6'b111111;
12'd3921 : mem_out_dec = 6'b111111;
12'd3922 : mem_out_dec = 6'b111111;
12'd3923 : mem_out_dec = 6'b111111;
12'd3924 : mem_out_dec = 6'b111111;
12'd3925 : mem_out_dec = 6'b111111;
12'd3926 : mem_out_dec = 6'b111111;
12'd3927 : mem_out_dec = 6'b111111;
12'd3928 : mem_out_dec = 6'b111111;
12'd3929 : mem_out_dec = 6'b111111;
12'd3930 : mem_out_dec = 6'b111111;
12'd3931 : mem_out_dec = 6'b111111;
12'd3932 : mem_out_dec = 6'b111111;
12'd3933 : mem_out_dec = 6'b111111;
12'd3934 : mem_out_dec = 6'b111111;
12'd3935 : mem_out_dec = 6'b111111;
12'd3936 : mem_out_dec = 6'b111111;
12'd3937 : mem_out_dec = 6'b111111;
12'd3938 : mem_out_dec = 6'b111111;
12'd3939 : mem_out_dec = 6'b111111;
12'd3940 : mem_out_dec = 6'b111111;
12'd3941 : mem_out_dec = 6'b111111;
12'd3942 : mem_out_dec = 6'b111111;
12'd3943 : mem_out_dec = 6'b111111;
12'd3944 : mem_out_dec = 6'b111111;
12'd3945 : mem_out_dec = 6'b111111;
12'd3946 : mem_out_dec = 6'b111111;
12'd3947 : mem_out_dec = 6'b111111;
12'd3948 : mem_out_dec = 6'b111111;
12'd3949 : mem_out_dec = 6'b111111;
12'd3950 : mem_out_dec = 6'b111111;
12'd3951 : mem_out_dec = 6'b111111;
12'd3952 : mem_out_dec = 6'b111111;
12'd3953 : mem_out_dec = 6'b111111;
12'd3954 : mem_out_dec = 6'b111111;
12'd3955 : mem_out_dec = 6'b111111;
12'd3956 : mem_out_dec = 6'b111111;
12'd3957 : mem_out_dec = 6'b111111;
12'd3958 : mem_out_dec = 6'b111111;
12'd3959 : mem_out_dec = 6'b111111;
12'd3960 : mem_out_dec = 6'b111111;
12'd3961 : mem_out_dec = 6'b111111;
12'd3962 : mem_out_dec = 6'b111111;
12'd3963 : mem_out_dec = 6'b111111;
12'd3964 : mem_out_dec = 6'b111111;
12'd3965 : mem_out_dec = 6'b111111;
12'd3966 : mem_out_dec = 6'b111111;
12'd3967 : mem_out_dec = 6'b111111;
12'd3968 : mem_out_dec = 6'b111111;
12'd3969 : mem_out_dec = 6'b111111;
12'd3970 : mem_out_dec = 6'b111111;
12'd3971 : mem_out_dec = 6'b111111;
12'd3972 : mem_out_dec = 6'b111111;
12'd3973 : mem_out_dec = 6'b111111;
12'd3974 : mem_out_dec = 6'b111111;
12'd3975 : mem_out_dec = 6'b111111;
12'd3976 : mem_out_dec = 6'b111111;
12'd3977 : mem_out_dec = 6'b111111;
12'd3978 : mem_out_dec = 6'b111111;
12'd3979 : mem_out_dec = 6'b111111;
12'd3980 : mem_out_dec = 6'b111111;
12'd3981 : mem_out_dec = 6'b111111;
12'd3982 : mem_out_dec = 6'b111111;
12'd3983 : mem_out_dec = 6'b111111;
12'd3984 : mem_out_dec = 6'b111111;
12'd3985 : mem_out_dec = 6'b111111;
12'd3986 : mem_out_dec = 6'b111111;
12'd3987 : mem_out_dec = 6'b111111;
12'd3988 : mem_out_dec = 6'b111111;
12'd3989 : mem_out_dec = 6'b111111;
12'd3990 : mem_out_dec = 6'b111111;
12'd3991 : mem_out_dec = 6'b111111;
12'd3992 : mem_out_dec = 6'b111111;
12'd3993 : mem_out_dec = 6'b111111;
12'd3994 : mem_out_dec = 6'b111111;
12'd3995 : mem_out_dec = 6'b111111;
12'd3996 : mem_out_dec = 6'b111111;
12'd3997 : mem_out_dec = 6'b111111;
12'd3998 : mem_out_dec = 6'b111111;
12'd3999 : mem_out_dec = 6'b111111;
12'd4000 : mem_out_dec = 6'b111111;
12'd4001 : mem_out_dec = 6'b111111;
12'd4002 : mem_out_dec = 6'b111111;
12'd4003 : mem_out_dec = 6'b111111;
12'd4004 : mem_out_dec = 6'b111111;
12'd4005 : mem_out_dec = 6'b111111;
12'd4006 : mem_out_dec = 6'b111111;
12'd4007 : mem_out_dec = 6'b111111;
12'd4008 : mem_out_dec = 6'b111111;
12'd4009 : mem_out_dec = 6'b111111;
12'd4010 : mem_out_dec = 6'b111111;
12'd4011 : mem_out_dec = 6'b111111;
12'd4012 : mem_out_dec = 6'b111111;
12'd4013 : mem_out_dec = 6'b111111;
12'd4014 : mem_out_dec = 6'b111111;
12'd4015 : mem_out_dec = 6'b111111;
12'd4016 : mem_out_dec = 6'b111111;
12'd4017 : mem_out_dec = 6'b111111;
12'd4018 : mem_out_dec = 6'b111111;
12'd4019 : mem_out_dec = 6'b111111;
12'd4020 : mem_out_dec = 6'b111111;
12'd4021 : mem_out_dec = 6'b111111;
12'd4022 : mem_out_dec = 6'b111111;
12'd4023 : mem_out_dec = 6'b111111;
12'd4024 : mem_out_dec = 6'b111111;
12'd4025 : mem_out_dec = 6'b111111;
12'd4026 : mem_out_dec = 6'b111111;
12'd4027 : mem_out_dec = 6'b111111;
12'd4028 : mem_out_dec = 6'b111111;
12'd4029 : mem_out_dec = 6'b111111;
12'd4030 : mem_out_dec = 6'b111111;
12'd4031 : mem_out_dec = 6'b111111;
12'd4032 : mem_out_dec = 6'b111111;
12'd4033 : mem_out_dec = 6'b111111;
12'd4034 : mem_out_dec = 6'b111111;
12'd4035 : mem_out_dec = 6'b111111;
12'd4036 : mem_out_dec = 6'b111111;
12'd4037 : mem_out_dec = 6'b111111;
12'd4038 : mem_out_dec = 6'b111111;
12'd4039 : mem_out_dec = 6'b111111;
12'd4040 : mem_out_dec = 6'b111111;
12'd4041 : mem_out_dec = 6'b111111;
12'd4042 : mem_out_dec = 6'b111111;
12'd4043 : mem_out_dec = 6'b111111;
12'd4044 : mem_out_dec = 6'b111111;
12'd4045 : mem_out_dec = 6'b111111;
12'd4046 : mem_out_dec = 6'b111111;
12'd4047 : mem_out_dec = 6'b111111;
12'd4048 : mem_out_dec = 6'b111111;
12'd4049 : mem_out_dec = 6'b111111;
12'd4050 : mem_out_dec = 6'b111111;
12'd4051 : mem_out_dec = 6'b111111;
12'd4052 : mem_out_dec = 6'b111111;
12'd4053 : mem_out_dec = 6'b111111;
12'd4054 : mem_out_dec = 6'b111111;
12'd4055 : mem_out_dec = 6'b111111;
12'd4056 : mem_out_dec = 6'b111111;
12'd4057 : mem_out_dec = 6'b111111;
12'd4058 : mem_out_dec = 6'b111111;
12'd4059 : mem_out_dec = 6'b111111;
12'd4060 : mem_out_dec = 6'b111111;
12'd4061 : mem_out_dec = 6'b111111;
12'd4062 : mem_out_dec = 6'b111111;
12'd4063 : mem_out_dec = 6'b111111;
12'd4064 : mem_out_dec = 6'b111111;
12'd4065 : mem_out_dec = 6'b111111;
12'd4066 : mem_out_dec = 6'b111111;
12'd4067 : mem_out_dec = 6'b111111;
12'd4068 : mem_out_dec = 6'b111111;
12'd4069 : mem_out_dec = 6'b111111;
12'd4070 : mem_out_dec = 6'b111111;
12'd4071 : mem_out_dec = 6'b111111;
12'd4072 : mem_out_dec = 6'b111111;
12'd4073 : mem_out_dec = 6'b111111;
12'd4074 : mem_out_dec = 6'b111111;
12'd4075 : mem_out_dec = 6'b111111;
12'd4076 : mem_out_dec = 6'b111111;
12'd4077 : mem_out_dec = 6'b111111;
12'd4078 : mem_out_dec = 6'b111111;
12'd4079 : mem_out_dec = 6'b111111;
12'd4080 : mem_out_dec = 6'b111111;
12'd4081 : mem_out_dec = 6'b111111;
12'd4082 : mem_out_dec = 6'b111111;
12'd4083 : mem_out_dec = 6'b111111;
12'd4084 : mem_out_dec = 6'b111111;
12'd4085 : mem_out_dec = 6'b111111;
12'd4086 : mem_out_dec = 6'b111111;
12'd4087 : mem_out_dec = 6'b111111;
12'd4088 : mem_out_dec = 6'b111111;
12'd4089 : mem_out_dec = 6'b111111;
12'd4090 : mem_out_dec = 6'b111111;
12'd4091 : mem_out_dec = 6'b111111;
12'd4092 : mem_out_dec = 6'b111111;
12'd4093 : mem_out_dec = 6'b111111;
12'd4094 : mem_out_dec = 6'b111111;
12'd4095 : mem_out_dec = 6'b111111;
endcase
end
always @ (posedge clk) begin
dec_cnt <= #TCQ mem_out_dec;
end
endmodule
|
module mig_7series_v2_3_ddr_phy_prbs_rdlvl #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter nCK_PER_CLK = 2, // # of memory clocks per CLK
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter RANKS = 1, // # of DRAM ranks
parameter SIM_CAL_OPTION = "NONE", // Skip various calibration steps
parameter PRBS_WIDTH = 8, // PRBS generator output width
parameter FIXED_VICTIM = "TRUE", // No victim rotation when "TRUE"
parameter FINE_PER_BIT = "ON",
parameter CENTER_COMP_MODE = "ON",
parameter PI_VAL_ADJ = "ON"
)
(
input clk,
input rst,
// Calibration status, control signals
input prbs_rdlvl_start,
(* max_fanout = 100 *) output reg prbs_rdlvl_done,
output reg prbs_last_byte_done,
output reg prbs_rdlvl_prech_req,
input complex_sample_cnt_inc,
input prech_done,
input phy_if_empty,
// Captured data in fabric clock domain
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] rd_data,
//Expected data from PRBS generator
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] compare_data,
// Decrement initial Phaser_IN Fine tap delay
input [5:0] pi_counter_read_val,
// Stage 1 calibration outputs
output reg pi_en_stg2_f,
output reg pi_stg2_f_incdec,
output [255:0] dbg_prbs_rdlvl,
output [DQS_CNT_WIDTH:0] pi_stg2_prbs_rdlvl_cnt,
output reg [2:0] rd_victim_sel,
output reg complex_victim_inc,
output reg reset_rd_addr,
output reg read_pause,
output reg [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r,
output reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps,
output reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps,
output reg [DRAM_WIDTH-1:0] fine_delay_incdec_pb, //fine_delay decreament per bit
output reg fine_delay_sel //fine delay selection - actual update of fine delay
);
localparam [5:0] PRBS_IDLE = 6'h00;
localparam [5:0] PRBS_NEW_DQS_WAIT = 6'h01;
localparam [5:0] PRBS_PAT_COMPARE = 6'h02;
localparam [5:0] PRBS_DEC_DQS = 6'h03;
localparam [5:0] PRBS_DEC_DQS_WAIT = 6'h04;
localparam [5:0] PRBS_INC_DQS = 6'h05;
localparam [5:0] PRBS_INC_DQS_WAIT = 6'h06;
localparam [5:0] PRBS_CALC_TAPS = 6'h07;
localparam [5:0] PRBS_NEXT_DQS = 6'h08;
localparam [5:0] PRBS_NEW_DQS_PREWAIT = 6'h09;
localparam [5:0] PRBS_DONE = 6'h0A;
localparam [5:0] PRBS_CALC_TAPS_PRE = 6'h0B;
localparam [5:0] PRBS_CALC_TAPS_WAIT = 6'h0C;
localparam [5:0] FINE_PI_DEC = 6'h0D; //go back to all fail or back to center
localparam [5:0] FINE_PI_DEC_WAIT = 6'h0E; //wait for PI tap dec settle
localparam [5:0] FINE_PI_INC = 6'h0F; //increse up to 1 fail
localparam [5:0] FINE_PI_INC_WAIT = 6'h10; //wait for PI tap int settle
localparam [5:0] FINE_PAT_COMPARE_PER_BIT = 6'h11; //compare per bit error and check left/right/gain/loss
localparam [5:0] FINE_CALC_TAPS = 6'h12; //setup fine_delay_incdec_pb for better window size
localparam [5:0] FINE_CALC_TAPS_WAIT = 6'h13; //wait for ROM value for dec cnt
localparam [11:0] NUM_SAMPLES_CNT = (SIM_CAL_OPTION == "NONE") ? 'd50 : 12'h001;
localparam [11:0] NUM_SAMPLES_CNT1 = (SIM_CAL_OPTION == "NONE") ? 'd20 : 12'h001;
localparam [11:0] NUM_SAMPLES_CNT2 = (SIM_CAL_OPTION == "NONE") ? 'd10 : 12'h001;
wire [DQS_CNT_WIDTH+2:0]prbs_dqs_cnt_timing;
reg [DQS_CNT_WIDTH+2:0] prbs_dqs_cnt_timing_r;
reg [DQS_CNT_WIDTH:0] prbs_dqs_cnt_r;
reg prbs_prech_req_r;
reg [5:0] prbs_state_r;
reg [5:0] prbs_state_r1;
reg wait_state_cnt_en_r;
reg [3:0] wait_state_cnt_r;
reg cnt_wait_state;
reg err_chk_invalid;
// reg found_edge_r;
reg prbs_found_1st_edge_r;
reg prbs_found_2nd_edge_r;
reg [5:0] prbs_1st_edge_taps_r;
// reg found_stable_eye_r;
reg [5:0] prbs_dqs_tap_cnt_r;
reg [5:0] prbs_dec_tap_calc_plus_3;
reg [5:0] prbs_dec_tap_calc_minus_3;
reg prbs_dqs_tap_limit_r;
reg [5:0] prbs_inc_tap_cnt;
reg [5:0] prbs_dec_tap_cnt;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r4;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r4;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r4;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r4;
reg mux_rd_valid_r;
reg rd_valid_r1;
reg rd_valid_r2;
reg rd_valid_r3;
reg new_cnt_dqs_r;
reg prbs_tap_en_r;
reg prbs_tap_inc_r;
reg pi_en_stg2_f_timing;
reg pi_stg2_f_incdec_timing;
wire [DQ_WIDTH-1:0] rd_data_rise0;
wire [DQ_WIDTH-1:0] rd_data_fall0;
wire [DQ_WIDTH-1:0] rd_data_rise1;
wire [DQ_WIDTH-1:0] rd_data_fall1;
wire [DQ_WIDTH-1:0] rd_data_rise2;
wire [DQ_WIDTH-1:0] rd_data_fall2;
wire [DQ_WIDTH-1:0] rd_data_rise3;
wire [DQ_WIDTH-1:0] rd_data_fall3;
wire [DQ_WIDTH-1:0] compare_data_r0;
wire [DQ_WIDTH-1:0] compare_data_f0;
wire [DQ_WIDTH-1:0] compare_data_r1;
wire [DQ_WIDTH-1:0] compare_data_f1;
wire [DQ_WIDTH-1:0] compare_data_r2;
wire [DQ_WIDTH-1:0] compare_data_f2;
wire [DQ_WIDTH-1:0] compare_data_r3;
wire [DQ_WIDTH-1:0] compare_data_f3;
reg [DRAM_WIDTH-1:0] compare_data_rise0_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall0_r1;
reg [DRAM_WIDTH-1:0] compare_data_rise1_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall1_r1;
reg [DRAM_WIDTH-1:0] compare_data_rise2_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall2_r1;
reg [DRAM_WIDTH-1:0] compare_data_rise3_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall3_r1;
reg [DQS_CNT_WIDTH:0] rd_mux_sel_r;
reg [5:0] prbs_2nd_edge_taps_r;
// reg [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r;
reg [5:0] rdlvl_cpt_tap_cnt;
reg prbs_rdlvl_start_r;
reg compare_err;
reg compare_err_r0;
reg compare_err_f0;
reg compare_err_r1;
reg compare_err_f1;
reg compare_err_r2;
reg compare_err_f2;
reg compare_err_r3;
reg compare_err_f3;
reg samples_cnt1_en_r;
reg samples_cnt2_en_r;
reg [11:0] samples_cnt_r;
reg num_samples_done_r;
reg num_samples_done_ind; //indicate num_samples_done_r is set in FINE_PAT_COMPARE_PER_BIT to prevent victim_sel_rd out of sync
reg [DQS_WIDTH-1:0] prbs_tap_mod;
//reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps;
//reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps;
//**************************************************************************
// signals for per-bit algorithm of fine_delay calculations
//**************************************************************************
reg [6*DRAM_WIDTH-1:0] left_edge_pb; //left edge value per bit
reg [6*DRAM_WIDTH-1:0] right_edge_pb; //right edge value per bit
reg [5*DRAM_WIDTH-1:0] match_flag_pb; //5 consecutive match flag per bit
reg [4:0] match_flag_and; //5 consecute match flag of all bits (1: all bit fail)
reg [DRAM_WIDTH-1:0] left_edge_found_pb; //left_edge found per bit - use for loss calculation
reg [DRAM_WIDTH-1:0] left_edge_updated; //left edge was updated for this PI tap - used for largest left edge /ref bit update
reg [DRAM_WIDTH-1:0] right_edge_found_pb; //right_edge found per bit - use for gail calulation and smallest right edge update
reg right_edge_found; //smallest right_edge found
reg [DRAM_WIDTH*6-1:0] left_loss_pb; //left_edge loss per bit
reg [DRAM_WIDTH*6-1:0] right_gain_pb; //right_edge gain per bit
reg [DRAM_WIDTH-1:0] ref_bit; //bit number which has largest left edge (with smaller right edge)
reg [DRAM_WIDTH-1:0] bit_cnt; //bit number used to calculate ref bit
reg [DRAM_WIDTH-1:0] ref_bit_per_bit; //bit flags which have largest left edge
reg [5:0] ref_right_edge; //ref_bit right edge - keep the smallest edge of ref bits
reg [5:0] largest_left_edge; //biggest left edge of per bit - will be left edge of byte
reg [5:0] smallest_right_edge; //smallest right edge of per bit - will be right edge of byte
reg [5:0] fine_pi_dec_cnt; //Phase In tap decrement count (to go back to '0' or center)
reg [6:0] center_calc; //used for calculate the dec tap for centering
reg [5:0] right_edge_ref; //ref_bit right edge
reg [5:0] left_edge_ref; //ref_bit left edge
reg [DRAM_WIDTH-1:0] compare_err_pb; //compare error per bit
reg [DRAM_WIDTH-1:0] compare_err_pb_latch_r; //sticky compare error per bit used for left/right edge
reg compare_err_pb_and; //indicate all bit fail
reg fine_inc_stage; //fine_inc_stage (1: increment all except ref_bit, 0: only inc for gain bit)
reg [1:0] stage_cnt; //stage cnt (0,1: fine delay inc stage, 2: fine delay dec stage)
wire fine_calib; //turn on/off fine delay calibration
reg [5:0] mem_out_dec;
reg [5:0] dec_cnt;
reg fine_dly_error; //indicate it has wrong left/right edge
wire center_comp;
wire pi_adj;
//**************************************************************************
// DQS count to hard PHY during write calibration using Phaser_OUT Stage2
// coarse delay
//**************************************************************************
assign pi_stg2_prbs_rdlvl_cnt = prbs_dqs_cnt_r;
//fine delay turn on
assign fine_calib = (FINE_PER_BIT=="ON")? 1:0;
assign center_comp = (CENTER_COMP_MODE == "ON")? 1: 0;
assign pi_adj = (PI_VAL_ADJ == "ON")?1:0;
assign dbg_prbs_rdlvl[0+:6] = left_edge_pb[0+:6];
assign dbg_prbs_rdlvl[7:6] = left_loss_pb[0+:2];
assign dbg_prbs_rdlvl[8+:6] = left_edge_pb[6+:6];
assign dbg_prbs_rdlvl[15:14] = left_loss_pb[6+:2];
assign dbg_prbs_rdlvl[16+:6] = left_edge_pb[12+:6] ;
assign dbg_prbs_rdlvl[23:22] = left_loss_pb[12+:2];
assign dbg_prbs_rdlvl[24+:6] = left_edge_pb[18+:6] ;
assign dbg_prbs_rdlvl[31:30] = left_loss_pb[18+:2];
assign dbg_prbs_rdlvl[32+:6] = left_edge_pb[24+:6];
assign dbg_prbs_rdlvl[39:38] = left_loss_pb[24+:2];
assign dbg_prbs_rdlvl[40+:6] = left_edge_pb[30+:6];
assign dbg_prbs_rdlvl[47:46] = left_loss_pb[30+:2];
assign dbg_prbs_rdlvl[48+:6] = left_edge_pb[36+:6];
assign dbg_prbs_rdlvl[55:54] = left_loss_pb[36+:2];
assign dbg_prbs_rdlvl[56+:6] = left_edge_pb[42+:6];
assign dbg_prbs_rdlvl[63:62] = left_loss_pb[42+:2];
assign dbg_prbs_rdlvl[64+:6] = right_edge_pb[0+:6];
assign dbg_prbs_rdlvl[71:70] = right_gain_pb[0+:2];
assign dbg_prbs_rdlvl[72+:6] = right_edge_pb[6+:6] ;
assign dbg_prbs_rdlvl[79:78] = right_gain_pb[6+:2];
assign dbg_prbs_rdlvl[80+:6] = right_edge_pb[12+:6];
assign dbg_prbs_rdlvl[87:86] = right_gain_pb[12+:2];
assign dbg_prbs_rdlvl[88+:6] = right_edge_pb[18+:6];
assign dbg_prbs_rdlvl[95:94] = right_gain_pb[18+:2];
assign dbg_prbs_rdlvl[96+:6] = right_edge_pb[24+:6];
assign dbg_prbs_rdlvl[103:102] = right_gain_pb[24+:2];
assign dbg_prbs_rdlvl[104+:6] = right_edge_pb[30+:6];
assign dbg_prbs_rdlvl[111:110] = right_gain_pb[30+:2];
assign dbg_prbs_rdlvl[112+:6] = right_edge_pb[36+:6];
assign dbg_prbs_rdlvl[119:118] = right_gain_pb[36+:2];
assign dbg_prbs_rdlvl[120+:6] = right_edge_pb[42+:6];
assign dbg_prbs_rdlvl[127:126] = right_gain_pb[42+:2];
assign dbg_prbs_rdlvl[128+:6] = pi_counter_read_val;
assign dbg_prbs_rdlvl[134+:6] = prbs_dqs_tap_cnt_r;
assign dbg_prbs_rdlvl[140] = prbs_found_1st_edge_r;
assign dbg_prbs_rdlvl[141] = prbs_found_2nd_edge_r;
assign dbg_prbs_rdlvl[142] = compare_err;
assign dbg_prbs_rdlvl[143] = phy_if_empty;
assign dbg_prbs_rdlvl[144] = prbs_rdlvl_start;
assign dbg_prbs_rdlvl[145] = prbs_rdlvl_done;
assign dbg_prbs_rdlvl[146+:5] = prbs_dqs_cnt_r;
assign dbg_prbs_rdlvl[151+:6] = left_edge_pb[prbs_dqs_cnt_r*6+:6] ;
assign dbg_prbs_rdlvl[157+:6] = right_edge_pb[prbs_dqs_cnt_r*6+:6];
assign dbg_prbs_rdlvl[163+:6] = {2'h0,complex_victim_inc, rd_victim_sel[2:0]};
assign dbg_prbs_rdlvl[169+:6] =right_gain_pb[prbs_dqs_cnt_r*6+:6] ;
assign dbg_prbs_rdlvl[177:175] = ref_bit[2:0];
assign dbg_prbs_rdlvl[178+:6] = prbs_state_r1[5:0];
assign dbg_prbs_rdlvl[184] = rd_valid_r2;
assign dbg_prbs_rdlvl[185] = compare_err_r0;
assign dbg_prbs_rdlvl[186] = compare_err_f0;
assign dbg_prbs_rdlvl[187] = compare_err_r1;
assign dbg_prbs_rdlvl[188] = compare_err_f1;
assign dbg_prbs_rdlvl[189] = compare_err_r2;
assign dbg_prbs_rdlvl[190] = compare_err_f2;
assign dbg_prbs_rdlvl[191] = compare_err_r3;
assign dbg_prbs_rdlvl[192] = compare_err_f3;
assign dbg_prbs_rdlvl[193+:8] = left_edge_found_pb;
assign dbg_prbs_rdlvl[201+:8] = right_edge_found_pb;
assign dbg_prbs_rdlvl[209+:6] =largest_left_edge ;
assign dbg_prbs_rdlvl[215+:6] =smallest_right_edge ;
assign dbg_prbs_rdlvl[221+:8] = fine_delay_incdec_pb;
assign dbg_prbs_rdlvl[229] = fine_delay_sel;
assign dbg_prbs_rdlvl[230+:8] = compare_err_pb_latch_r;
assign dbg_prbs_rdlvl[238+:6] = fine_pi_dec_cnt;
assign dbg_prbs_rdlvl[244+:5] = match_flag_and ;
assign dbg_prbs_rdlvl[249+:2] =stage_cnt ;
assign dbg_prbs_rdlvl[251] = fine_inc_stage ;
assign dbg_prbs_rdlvl[252] = compare_err_pb_and ;
assign dbg_prbs_rdlvl[253] = right_edge_found ;
assign dbg_prbs_rdlvl[254] = fine_dly_error ;
assign dbg_prbs_rdlvl[255]= 'b0;//reserved
//**************************************************************************
// Record first and second edges found during calibration
//**************************************************************************
generate
always @(posedge clk)
if (rst) begin
dbg_prbs_first_edge_taps <= #TCQ 'b0;
dbg_prbs_second_edge_taps <= #TCQ 'b0;
end else if (prbs_state_r == PRBS_CALC_TAPS) begin
// Record tap counts of first and second edge edges during
// calibration for each DQS group. If neither edge has
// been found, then those taps will remain 0
if (prbs_found_1st_edge_r)
dbg_prbs_first_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ prbs_1st_edge_taps_r;
if (prbs_found_2nd_edge_r)
dbg_prbs_second_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ prbs_2nd_edge_taps_r;
end else if (prbs_state_r == FINE_CALC_TAPS) begin
if(stage_cnt == 'd2) begin
dbg_prbs_first_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ largest_left_edge;
dbg_prbs_second_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ smallest_right_edge;
end
end
endgenerate
//padded calculation
always @ (smallest_right_edge or largest_left_edge)
center_calc <= {1'b0, smallest_right_edge} + {1'b0,largest_left_edge};
//***************************************************************************
//***************************************************************************
// Data mux to route appropriate bit to calibration logic - i.e. calibration
// is done sequentially, one bit (or DQS group) at a time
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: rd_data_div4_logic_clk
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign rd_data_rise2 = rd_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign rd_data_fall2 = rd_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign rd_data_rise3 = rd_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign rd_data_fall3 = rd_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
assign compare_data_r0 = compare_data[DQ_WIDTH-1:0];
assign compare_data_f0 = compare_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign compare_data_r1 = compare_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign compare_data_f1 = compare_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign compare_data_r2 = compare_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign compare_data_f2 = compare_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign compare_data_r3 = compare_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign compare_data_f3 = compare_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
end else begin: rd_data_div2_logic_clk
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign compare_data_r0 = compare_data[DQ_WIDTH-1:0];
assign compare_data_f0 = compare_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign compare_data_r1 = compare_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign compare_data_f1 = compare_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign compare_data_r2 = 'h0;
assign compare_data_f2 = 'h0;
assign compare_data_r3 = 'h0;
assign compare_data_f3 = 'h0;
end
endgenerate
always @(posedge clk) begin
rd_mux_sel_r <= #TCQ prbs_dqs_cnt_r;
end
// Register outputs for improved timing.
// NOTE: Will need to change when per-bit DQ deskew is supported.
// Currenly all bits in DQS group are checked in aggregate
generate
genvar mux_i;
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r1[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r1[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r1[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r1[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise2_r1[mux_i] <= #TCQ rd_data_rise2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall2_r1[mux_i] <= #TCQ rd_data_fall2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise3_r1[mux_i] <= #TCQ rd_data_rise3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall3_r1[mux_i] <= #TCQ rd_data_fall3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
//Compare data
compare_data_rise0_r1[mux_i] <= #TCQ compare_data_r0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall0_r1[mux_i] <= #TCQ compare_data_f0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_rise1_r1[mux_i] <= #TCQ compare_data_r1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall1_r1[mux_i] <= #TCQ compare_data_f1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_rise2_r1[mux_i] <= #TCQ compare_data_r2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall2_r1[mux_i] <= #TCQ compare_data_f2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_rise3_r1[mux_i] <= #TCQ compare_data_r3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall3_r1[mux_i] <= #TCQ compare_data_f3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
endgenerate
generate
genvar muxr2_i;
if (nCK_PER_CLK == 4) begin: gen_mux_div4
for (muxr2_i = 0; muxr2_i < DRAM_WIDTH; muxr2_i = muxr2_i + 1) begin: gen_rd_4
always @(posedge clk) begin
if (mux_rd_valid_r) begin
mux_rd_rise0_r2[muxr2_i] <= #TCQ mux_rd_rise0_r1[muxr2_i];
mux_rd_fall0_r2[muxr2_i] <= #TCQ mux_rd_fall0_r1[muxr2_i];
mux_rd_rise1_r2[muxr2_i] <= #TCQ mux_rd_rise1_r1[muxr2_i];
mux_rd_fall1_r2[muxr2_i] <= #TCQ mux_rd_fall1_r1[muxr2_i];
mux_rd_rise2_r2[muxr2_i] <= #TCQ mux_rd_rise2_r1[muxr2_i];
mux_rd_fall2_r2[muxr2_i] <= #TCQ mux_rd_fall2_r1[muxr2_i];
mux_rd_rise3_r2[muxr2_i] <= #TCQ mux_rd_rise3_r1[muxr2_i];
mux_rd_fall3_r2[muxr2_i] <= #TCQ mux_rd_fall3_r1[muxr2_i];
end
//pipeline stage
mux_rd_rise0_r3[muxr2_i] <= #TCQ mux_rd_rise0_r2[muxr2_i];
mux_rd_fall0_r3[muxr2_i] <= #TCQ mux_rd_fall0_r2[muxr2_i];
mux_rd_rise1_r3[muxr2_i] <= #TCQ mux_rd_rise1_r2[muxr2_i];
mux_rd_fall1_r3[muxr2_i] <= #TCQ mux_rd_fall1_r2[muxr2_i];
mux_rd_rise2_r3[muxr2_i] <= #TCQ mux_rd_rise2_r2[muxr2_i];
mux_rd_fall2_r3[muxr2_i] <= #TCQ mux_rd_fall2_r2[muxr2_i];
mux_rd_rise3_r3[muxr2_i] <= #TCQ mux_rd_rise3_r2[muxr2_i];
mux_rd_fall3_r3[muxr2_i] <= #TCQ mux_rd_fall3_r2[muxr2_i];
//pipeline stage
mux_rd_rise0_r4[muxr2_i] <= #TCQ mux_rd_rise0_r3[muxr2_i];
mux_rd_fall0_r4[muxr2_i] <= #TCQ mux_rd_fall0_r3[muxr2_i];
mux_rd_rise1_r4[muxr2_i] <= #TCQ mux_rd_rise1_r3[muxr2_i];
mux_rd_fall1_r4[muxr2_i] <= #TCQ mux_rd_fall1_r3[muxr2_i];
mux_rd_rise2_r4[muxr2_i] <= #TCQ mux_rd_rise2_r3[muxr2_i];
mux_rd_fall2_r4[muxr2_i] <= #TCQ mux_rd_fall2_r3[muxr2_i];
mux_rd_rise3_r4[muxr2_i] <= #TCQ mux_rd_rise3_r3[muxr2_i];
mux_rd_fall3_r4[muxr2_i] <= #TCQ mux_rd_fall3_r3[muxr2_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_mux_div2
for (muxr2_i = 0; muxr2_i < DRAM_WIDTH; muxr2_i = muxr2_i + 1) begin: gen_rd_2
always @(posedge clk) begin
if (mux_rd_valid_r) begin
mux_rd_rise0_r2[muxr2_i] <= #TCQ mux_rd_rise0_r1[muxr2_i];
mux_rd_fall0_r2[muxr2_i] <= #TCQ mux_rd_fall0_r1[muxr2_i];
mux_rd_rise1_r2[muxr2_i] <= #TCQ mux_rd_rise1_r1[muxr2_i];
mux_rd_fall1_r2[muxr2_i] <= #TCQ mux_rd_fall1_r1[muxr2_i];
mux_rd_rise2_r2[muxr2_i] <= 'h0;
mux_rd_fall2_r2[muxr2_i] <= 'h0;
mux_rd_rise3_r2[muxr2_i] <= 'h0;
mux_rd_fall3_r2[muxr2_i] <= 'h0;
end
mux_rd_rise0_r3[muxr2_i] <= #TCQ mux_rd_rise0_r2[muxr2_i];
mux_rd_fall0_r3[muxr2_i] <= #TCQ mux_rd_fall0_r2[muxr2_i];
mux_rd_rise1_r3[muxr2_i] <= #TCQ mux_rd_rise1_r2[muxr2_i];
mux_rd_fall1_r3[muxr2_i] <= #TCQ mux_rd_fall1_r2[muxr2_i];
mux_rd_rise2_r3[muxr2_i] <= 'h0;
mux_rd_fall2_r3[muxr2_i] <= 'h0;
mux_rd_rise3_r3[muxr2_i] <= 'h0;
mux_rd_fall3_r3[muxr2_i] <= 'h0;
//pipeline stage
mux_rd_rise0_r4[muxr2_i] <= #TCQ mux_rd_rise0_r3[muxr2_i];
mux_rd_fall0_r4[muxr2_i] <= #TCQ mux_rd_fall0_r3[muxr2_i];
mux_rd_rise1_r4[muxr2_i] <= #TCQ mux_rd_rise1_r3[muxr2_i];
mux_rd_fall1_r4[muxr2_i] <= #TCQ mux_rd_fall1_r3[muxr2_i];
mux_rd_rise2_r4[muxr2_i] <= 'h0;
mux_rd_fall2_r4[muxr2_i] <= 'h0;
mux_rd_rise3_r4[muxr2_i] <= 'h0;
mux_rd_fall3_r4[muxr2_i] <= 'h0;
end
end
end
endgenerate
// Registered signal indicates when mux_rd_rise/fall_r is valid
always @(posedge clk) begin
mux_rd_valid_r <= #TCQ ~phy_if_empty && prbs_rdlvl_start;
rd_valid_r1 <= #TCQ mux_rd_valid_r;
rd_valid_r2 <= #TCQ rd_valid_r1;
rd_valid_r3 <= #TCQ rd_valid_r2;
end
// Counter counts # of samples compared
// Reset sample counter when not "sampling"
// Otherwise, count # of samples compared
// Same counter is shared for three samples checked
always @(posedge clk)
if (rst)
samples_cnt_r <= #TCQ 'b0;
else if (samples_cnt_r == NUM_SAMPLES_CNT) begin
samples_cnt_r <= #TCQ 'b0;
end else if (complex_sample_cnt_inc) begin
samples_cnt_r <= #TCQ samples_cnt_r + 1;
/*if (!rd_valid_r1 ||
(prbs_state_r == PRBS_DEC_DQS_WAIT) ||
(prbs_state_r == PRBS_INC_DQS_WAIT) ||
(prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS) ||
(samples_cnt_r == NUM_SAMPLES_CNT) ||
(samples_cnt_r == NUM_SAMPLES_CNT1))
samples_cnt_r <= #TCQ 'b0;
else if (rd_valid_r1 &&
(((samples_cnt_r < NUM_SAMPLES_CNT) && ~samples_cnt1_en_r) ||
((samples_cnt_r < NUM_SAMPLES_CNT1) && ~samples_cnt2_en_r) ||
((samples_cnt_r < NUM_SAMPLES_CNT2) && samples_cnt2_en_r)))
samples_cnt_r <= #TCQ samples_cnt_r + 1;*/
end
// Count #2 enable generation
// Assert when correct number of samples compared
always @(posedge clk)
if (rst)
samples_cnt1_en_r <= #TCQ 1'b0;
else begin
if ((prbs_state_r == PRBS_IDLE) ||
(prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS) ||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == PRBS_NEW_DQS_PREWAIT))
samples_cnt1_en_r <= #TCQ 1'b0;
else if ((samples_cnt_r == NUM_SAMPLES_CNT) && rd_valid_r1)
samples_cnt1_en_r <= #TCQ 1'b1;
end
// Counter #3 enable generation
// Assert when correct number of samples compared
always @(posedge clk)
if (rst)
samples_cnt2_en_r <= #TCQ 1'b0;
else begin
if ((prbs_state_r == PRBS_IDLE) ||
(prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS) ||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == PRBS_NEW_DQS_PREWAIT))
samples_cnt2_en_r <= #TCQ 1'b0;
else if ((samples_cnt_r == NUM_SAMPLES_CNT1) && rd_valid_r1 && samples_cnt1_en_r)
samples_cnt2_en_r <= #TCQ 1'b1;
end
// Victim selection logic
always @(posedge clk)
if (rst)
rd_victim_sel <= #TCQ 'd0;
else if (num_samples_done_r)
rd_victim_sel <= #TCQ 'd0;
else if (samples_cnt_r == NUM_SAMPLES_CNT) begin
if (rd_victim_sel < 'd7)
rd_victim_sel <= #TCQ rd_victim_sel + 1;
end
// Output row count increment pulse to phy_init
always @(posedge clk)
if (rst)
complex_victim_inc <= #TCQ 1'b0;
else if (samples_cnt_r == NUM_SAMPLES_CNT)
complex_victim_inc <= #TCQ 1'b1;
else
complex_victim_inc <= #TCQ 1'b0;
generate
if (FIXED_VICTIM == "TRUE") begin: victim_fixed
always @(posedge clk)
if (rst)
num_samples_done_r <= #TCQ 1'b0;
else if ((prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS)||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == FINE_PI_DEC))
num_samples_done_r <= #TCQ 'b0;
else if (samples_cnt_r == NUM_SAMPLES_CNT)
num_samples_done_r <= #TCQ 1'b1;
end else begin: victim_not_fixed
always @(posedge clk)
if (rst)
num_samples_done_r <= #TCQ 1'b0;
else if ((prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS)||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == FINE_PI_DEC))
num_samples_done_r <= #TCQ 'b0;
else if ((samples_cnt_r == NUM_SAMPLES_CNT) && (rd_victim_sel == 'd7))
num_samples_done_r <= #TCQ 1'b1;
end
endgenerate
//***************************************************************************
// Compare Read Data for the byte being Leveled with Expected data from PRBS
// generator. Resulting compare_err signal used to determine read data valid
// edge.
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: cmp_err_4to1
always @ (posedge clk) begin
if (rst || new_cnt_dqs_r) begin
compare_err <= #TCQ 1'b0;
compare_err_r0 <= #TCQ 1'b0;
compare_err_f0 <= #TCQ 1'b0;
compare_err_r1 <= #TCQ 1'b0;
compare_err_f1 <= #TCQ 1'b0;
compare_err_r2 <= #TCQ 1'b0;
compare_err_f2 <= #TCQ 1'b0;
compare_err_r3 <= #TCQ 1'b0;
compare_err_f3 <= #TCQ 1'b0;
end else if (rd_valid_r2) begin
compare_err_r0 <= #TCQ (mux_rd_rise0_r3 != compare_data_rise0_r1);
compare_err_f0 <= #TCQ (mux_rd_fall0_r3 != compare_data_fall0_r1);
compare_err_r1 <= #TCQ (mux_rd_rise1_r3 != compare_data_rise1_r1);
compare_err_f1 <= #TCQ (mux_rd_fall1_r3 != compare_data_fall1_r1);
compare_err_r2 <= #TCQ (mux_rd_rise2_r3 != compare_data_rise2_r1);
compare_err_f2 <= #TCQ (mux_rd_fall2_r3 != compare_data_fall2_r1);
compare_err_r3 <= #TCQ (mux_rd_rise3_r3 != compare_data_rise3_r1);
compare_err_f3 <= #TCQ (mux_rd_fall3_r3 != compare_data_fall3_r1);
compare_err <= #TCQ (compare_err_r0 | compare_err_f0 |
compare_err_r1 | compare_err_f1 |
compare_err_r2 | compare_err_f2 |
compare_err_r3 | compare_err_f3);
end
end
end else begin: cmp_err_2to1
always @ (posedge clk) begin
if (rst || new_cnt_dqs_r) begin
compare_err <= #TCQ 1'b0;
compare_err_r0 <= #TCQ 1'b0;
compare_err_f0 <= #TCQ 1'b0;
compare_err_r1 <= #TCQ 1'b0;
compare_err_f1 <= #TCQ 1'b0;
end else if (rd_valid_r2) begin
compare_err_r0 <= #TCQ (mux_rd_rise0_r3 != compare_data_rise0_r1);
compare_err_f0 <= #TCQ (mux_rd_fall0_r3 != compare_data_fall0_r1);
compare_err_r1 <= #TCQ (mux_rd_rise1_r3 != compare_data_rise1_r1);
compare_err_f1 <= #TCQ (mux_rd_fall1_r3 != compare_data_fall1_r1);
compare_err <= #TCQ (compare_err_r0 | compare_err_f0 |
compare_err_r1 | compare_err_f1);
end
end
end
endgenerate
//***************************************************************************
// Decrement initial Phaser_IN fine delay value before proceeding with
// read calibration
//***************************************************************************
//***************************************************************************
// Demultiplexor to control Phaser_IN delay values
//***************************************************************************
// Read DQS
always @(posedge clk) begin
if (rst) begin
pi_en_stg2_f_timing <= #TCQ 'b0;
pi_stg2_f_incdec_timing <= #TCQ 'b0;
end else if (prbs_tap_en_r) begin
// Change only specified DQS
pi_en_stg2_f_timing <= #TCQ 1'b1;
pi_stg2_f_incdec_timing <= #TCQ prbs_tap_inc_r;
end else begin
pi_en_stg2_f_timing <= #TCQ 'b0;
pi_stg2_f_incdec_timing <= #TCQ 'b0;
end
end
// registered for timing
always @(posedge clk) begin
pi_en_stg2_f <= #TCQ pi_en_stg2_f_timing;
pi_stg2_f_incdec <= #TCQ pi_stg2_f_incdec_timing;
end
//***************************************************************************
// generate request to PHY_INIT logic to issue precharged. Required when
// calibration can take a long time (during which there are only constant
// reads present on this bus). In this case need to issue perioidic
// precharges to avoid tRAS violation. This signal must meet the following
// requirements: (1) only transition from 0->1 when prech is first needed,
// (2) stay at 1 and only transition 1->0 when RDLVL_PRECH_DONE asserted
//***************************************************************************
always @(posedge clk)
if (rst)
prbs_rdlvl_prech_req <= #TCQ 1'b0;
else
prbs_rdlvl_prech_req <= #TCQ prbs_prech_req_r;
//*****************************************************************
// keep track of edge tap counts found, and current capture clock
// tap count
//*****************************************************************
always @(posedge clk)
if (rst) begin
prbs_dqs_tap_cnt_r <= #TCQ 'b0;
rdlvl_cpt_tap_cnt <= #TCQ 'b0;
end else if (new_cnt_dqs_r) begin
prbs_dqs_tap_cnt_r <= #TCQ pi_counter_read_val;
rdlvl_cpt_tap_cnt <= #TCQ pi_counter_read_val;
end else if (prbs_tap_en_r) begin
if (prbs_tap_inc_r)
prbs_dqs_tap_cnt_r <= #TCQ prbs_dqs_tap_cnt_r + 1;
else if (prbs_dqs_tap_cnt_r != 'd0)
prbs_dqs_tap_cnt_r <= #TCQ prbs_dqs_tap_cnt_r - 1;
end
always @(posedge clk)
if (rst) begin
prbs_dec_tap_calc_plus_3 <= #TCQ 'b0;
prbs_dec_tap_calc_minus_3 <= #TCQ 'b0;
end else if (new_cnt_dqs_r) begin
prbs_dec_tap_calc_plus_3 <= #TCQ 'b000011;
prbs_dec_tap_calc_minus_3 <= #TCQ 'b111100;
end else begin
prbs_dec_tap_calc_plus_3 <= #TCQ (prbs_dqs_tap_cnt_r - rdlvl_cpt_tap_cnt + 3);
prbs_dec_tap_calc_minus_3 <= #TCQ (prbs_dqs_tap_cnt_r - rdlvl_cpt_tap_cnt - 3);
end
always @(posedge clk)
if (rst || new_cnt_dqs_r)
prbs_dqs_tap_limit_r <= #TCQ 1'b0;
else if (prbs_dqs_tap_cnt_r == 6'd63)
prbs_dqs_tap_limit_r <= #TCQ 1'b1;
else
prbs_dqs_tap_limit_r <= #TCQ 1'b0;
// Temp wire for timing.
// The following in the always block below causes timing issues
// due to DSP block inference
// 6*prbs_dqs_cnt_r.
// replacing this with two left shifts + one left shift to avoid
// DSP multiplier.
assign prbs_dqs_cnt_timing = {2'd0, prbs_dqs_cnt_r};
always @(posedge clk)
prbs_dqs_cnt_timing_r <= #TCQ prbs_dqs_cnt_timing;
// Storing DQS tap values at the end of each DQS read leveling
always @(posedge clk) begin
if (rst) begin
prbs_final_dqs_tap_cnt_r <= #TCQ 'b0;
end else if ((prbs_state_r == PRBS_NEXT_DQS) && (prbs_state_r1 != PRBS_NEXT_DQS)) begin
prbs_final_dqs_tap_cnt_r[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ prbs_dqs_tap_cnt_r;
end
end
//*****************************************************************
always @(posedge clk) begin
prbs_state_r1 <= #TCQ prbs_state_r;
prbs_rdlvl_start_r <= #TCQ prbs_rdlvl_start;
end
// Wait counter for wait states
always @(posedge clk)
if ((prbs_state_r == PRBS_NEW_DQS_WAIT) ||
(prbs_state_r == PRBS_INC_DQS_WAIT) ||
(prbs_state_r == PRBS_DEC_DQS_WAIT) ||
(prbs_state_r == FINE_PI_DEC_WAIT) ||
(prbs_state_r == FINE_PI_INC_WAIT) ||
(prbs_state_r == PRBS_NEW_DQS_PREWAIT))
wait_state_cnt_en_r <= #TCQ 1'b1;
else
wait_state_cnt_en_r <= #TCQ 1'b0;
always @(posedge clk)
if (!wait_state_cnt_en_r) begin
wait_state_cnt_r <= #TCQ 'b0;
cnt_wait_state <= #TCQ 1'b0;
end else begin
if (wait_state_cnt_r < 'd15) begin
wait_state_cnt_r <= #TCQ wait_state_cnt_r + 1;
cnt_wait_state <= #TCQ 1'b0;
end else begin
// Need to reset to 0 to handle the case when there are two
// different WAIT states back-to-back
wait_state_cnt_r <= #TCQ 'b0;
cnt_wait_state <= #TCQ 1'b1;
end
end
always @ (posedge clk)
err_chk_invalid <= #TCQ (wait_state_cnt_r < 'd14);
//*****************************************************************
// compare error checking per-bit
//****************************************************************
generate
genvar pb_i;
if (nCK_PER_CLK == 4) begin: cmp_err_pb_4to1
for(pb_i=0 ; pb_i<DRAM_WIDTH; pb_i=pb_i+1) begin
always @ (posedge clk) begin
//prevent error check during PI inc/dec and wait
if (rst || new_cnt_dqs_r || (prbs_state_r == FINE_PI_INC) || (prbs_state_r == FINE_PI_DEC) ||
(err_chk_invalid && ((prbs_state_r == FINE_PI_DEC_WAIT)||(prbs_state_r == FINE_PI_INC_WAIT))))
compare_err_pb[pb_i] <= #TCQ 1'b0;
else if (rd_valid_r2)
compare_err_pb[pb_i] <= #TCQ (mux_rd_rise0_r3[pb_i] != compare_data_rise0_r1[pb_i]) |
(mux_rd_fall0_r3[pb_i] != compare_data_fall0_r1[pb_i]) |
(mux_rd_rise1_r3[pb_i] != compare_data_rise1_r1[pb_i]) |
(mux_rd_fall1_r3[pb_i] != compare_data_fall1_r1[pb_i]) |
(mux_rd_rise2_r3[pb_i] != compare_data_rise2_r1[pb_i]) |
(mux_rd_fall2_r3[pb_i] != compare_data_fall2_r1[pb_i]) |
(mux_rd_rise3_r3[pb_i] != compare_data_rise3_r1[pb_i]) |
(mux_rd_fall3_r3[pb_i] != compare_data_fall3_r1[pb_i]) ;
end //always
end //for
end else begin: cmp_err_pb_2to1
for(pb_i=0 ; pb_i<DRAM_WIDTH; pb_i=pb_i+1) begin
always @ (posedge clk) begin
if (rst || new_cnt_dqs_r || (prbs_state_r == FINE_PI_INC) || (prbs_state_r == FINE_PI_DEC) ||
(err_chk_invalid && ((prbs_state_r == FINE_PI_DEC_WAIT)||(prbs_state_r == FINE_PI_INC_WAIT))))
compare_err_pb[pb_i] <= #TCQ 1'b0;
else if (rd_valid_r2)
compare_err_pb[pb_i] <= #TCQ (mux_rd_rise0_r3[pb_i] != compare_data_rise0_r1[pb_i]) |
(mux_rd_fall0_r3[pb_i] != compare_data_fall0_r1[pb_i]) |
(mux_rd_rise1_r3[pb_i] != compare_data_rise1_r1[pb_i]) |
(mux_rd_fall1_r3[pb_i] != compare_data_fall1_r1[pb_i]) ;
end //always
end //for
end //if
endgenerate
//checking all bit has error
always @ (posedge clk) begin
if(rst || new_cnt_dqs_r) begin
compare_err_pb_and <= #TCQ 1'b0;
end else begin
compare_err_pb_and <= #TCQ &compare_err_pb;
end
end
//generate stick error bit - left/right edge
generate
genvar pb_r;
for(pb_r=0; pb_r<DRAM_WIDTH; pb_r=pb_r+1) begin
always @ (posedge clk) begin
if((prbs_state_r == FINE_PI_INC) | (prbs_state_r == FINE_PI_DEC) |
(~cnt_wait_state && ((prbs_state_r == FINE_PI_INC_WAIT)|(prbs_state_r == FINE_PI_DEC_WAIT))))
compare_err_pb_latch_r[pb_r] <= #TCQ 1'b0;
else
compare_err_pb_latch_r[pb_r] <= #TCQ compare_err_pb[pb_r]? 1'b1:compare_err_pb_latch_r[pb_r];
end
end
endgenerate
//in stage 0, if left edge found, update ref_bit (one hot)
always @ (posedge clk) begin
if (rst | (prbs_state_r == PRBS_NEW_DQS_WAIT)) begin
ref_bit_per_bit <= #TCQ 'd0;
end else if ((prbs_state_r == FINE_PI_INC) && (stage_cnt=='b0)) begin
if(|left_edge_updated) ref_bit_per_bit <= #TCQ left_edge_updated;
end
end
//ref bit with samllest right edge
//if bit 1 and 3 are set to ref_bit_per_bit but bit 1 has smaller right edge, bit is selected as ref_bit
always @ (posedge clk) begin
if(rst | (prbs_state_r == PRBS_NEW_DQS_WAIT)) begin
bit_cnt <= #TCQ 'd0;
ref_right_edge <= #TCQ 6'h3f;
ref_bit <= #TCQ 'd0;
end else if ((prbs_state_r == FINE_CALC_TAPS_WAIT) && (stage_cnt == 'b0) && (bit_cnt < DRAM_WIDTH)) begin
bit_cnt <= #TCQ bit_cnt +'b1;
if ((ref_bit_per_bit[bit_cnt]==1'b1) && (right_edge_pb[bit_cnt*6+:6]<= ref_right_edge)) begin
ref_bit <= #TCQ bit_cnt;
ref_right_edge <= #TCQ right_edge_pb[bit_cnt*6+:6];
end
end
end
//pipe lining for reference bit left/right edge
always @ (posedge clk) begin
left_edge_ref <= #TCQ left_edge_pb[ref_bit*6+:6];
right_edge_ref <= #TCQ right_edge_pb[ref_bit*6+:6];
end
//left_edge/right_edge/left_loss/right_gain update
generate
genvar eg;
for(eg=0; eg<DRAM_WIDTH; eg = eg+1) begin
always @ (posedge clk) begin
if(rst | (prbs_state_r == PRBS_NEW_DQS_WAIT)) begin
match_flag_pb[eg*5+:5] <= #TCQ 5'h1f;
left_edge_pb[eg*6+:6] <= #TCQ 'b0;
right_edge_pb[eg*6+:6] <= #TCQ 6'h3f;
left_edge_found_pb[eg] <= #TCQ 1'b0;
right_edge_found_pb[eg] <= #TCQ 1'b0;
left_loss_pb[eg*6+:6] <= #TCQ 'b0;
right_gain_pb[eg*6+:6] <= #TCQ 'b0;
left_edge_updated[eg] <= #TCQ 'b0;
end else begin
if((prbs_state_r == FINE_PAT_COMPARE_PER_BIT) && (num_samples_done_r || compare_err_pb_and)) begin
//left edge is updated when match flag becomes 100000 (1 fail , 5 success)
if(match_flag_pb[eg*5+:5]==5'b10000 && compare_err_pb_latch_r[eg]==0) begin
left_edge_pb[eg*6+:6] <= #TCQ prbs_dqs_tap_cnt_r-4;
left_edge_found_pb[eg] <= #TCQ 1'b1; //used for update largest_left_edge
left_edge_updated[eg] <= #TCQ 1'b1;
//check the loss of bit - update only for left edge found
if(~left_edge_found_pb[eg])
left_loss_pb[eg*6+:6] <= #TCQ (left_edge_ref > prbs_dqs_tap_cnt_r - 4)? 'd0
: prbs_dqs_tap_cnt_r-4-left_edge_ref;
//right edge is updated when match flag becomes 000001 (5 success, 1 fail)
end else if (match_flag_pb[eg*5+:5]==5'b00000 && compare_err_pb_latch_r[eg]) begin
right_edge_pb[eg*6+:6] <= #TCQ prbs_dqs_tap_cnt_r-1;
right_edge_found_pb[eg] <= #TCQ 1'b1;
//check the gain of bit - update only for right edge found
if(~right_edge_found_pb[eg])
right_gain_pb[eg*6+:6] <= #TCQ (right_edge_ref > prbs_dqs_tap_cnt_r-1)?
((right_edge_pb[eg*6 +:6] > prbs_dqs_tap_cnt_r-1)? 0: prbs_dqs_tap_cnt_r-1- right_edge_pb[eg*6+:6]):
((right_edge_pb[eg*6+:6] > right_edge_ref)? 0 : right_edge_ref - right_edge_pb[eg*6+:6]);
//no right edge found
end else if (prbs_dqs_tap_cnt_r == 6'h3f && ~right_edge_found_pb[eg]) begin
right_edge_pb[eg*6+:6] <= #TCQ 6'h3f;
right_edge_found_pb[eg] <= #TCQ 1'b1;
//right edge at 63. gain = max(0, ref_bit_right_tap - prev_right_edge)
right_gain_pb[eg*6+:6] <= #TCQ (right_edge_ref > right_edge_pb[eg*6+:6])?
(right_edge_ref - right_edge_pb[eg*6+:6]) : 0;
end
//update match flag - shift and update
match_flag_pb[eg*5+:5] <= #TCQ {match_flag_pb[(eg*5)+:4],compare_err_pb_latch_r[eg]};
end else if (prbs_state_r == FINE_PI_DEC) begin
left_edge_found_pb[eg] <= #TCQ 1'b0;
right_edge_found_pb[eg] <= #TCQ 1'b0;
left_loss_pb[eg*6+:6] <= #TCQ 'b0;
right_gain_pb[eg*6+:6] <= #TCQ 'b0;
match_flag_pb[eg*5+:5] <= #TCQ 5'h1f; //new fix
end else if (prbs_state_r == FINE_PI_INC) begin
left_edge_updated[eg] <= #TCQ 'b0; //used only for update largest ref_bit and largest_left_edge
end
end
end //always
end //for
endgenerate
//update fine_delay according to loss/gain value per bit
generate
genvar f_pb;
for(f_pb=0; f_pb<DRAM_WIDTH; f_pb=f_pb+1) begin
always @ (posedge clk) begin
if(rst | prbs_state_r == PRBS_NEW_DQS_WAIT ) begin
fine_delay_incdec_pb[f_pb] <= #TCQ 1'b0;
end else if((prbs_state_r == FINE_CALC_TAPS_WAIT) && (bit_cnt == DRAM_WIDTH)) begin
if(stage_cnt == 'd0) fine_delay_incdec_pb[f_pb] <= #TCQ (f_pb==ref_bit)? 1'b0:1'b1; //only for initial stage
else if(stage_cnt == 'd1) fine_delay_incdec_pb[f_pb] <= #TCQ (right_gain_pb[f_pb*6+:6]>left_loss_pb[f_pb*6+:6])?1'b1:1'b0;
end
end
end
endgenerate
//fine inc stage (stage cnt 0,1,2), fine dec stage (stage cnt 3)
always @ (posedge clk) begin
if (rst)
fine_inc_stage <= #TCQ 'b1;
else
fine_inc_stage <= #TCQ (stage_cnt!='d3);
end
//*****************************************************************
always @(posedge clk)
if (rst) begin
prbs_dqs_cnt_r <= #TCQ 'b0;
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
prbs_prech_req_r <= #TCQ 1'b0;
prbs_state_r <= #TCQ PRBS_IDLE;
prbs_found_1st_edge_r <= #TCQ 1'b0;
prbs_found_2nd_edge_r <= #TCQ 1'b0;
prbs_1st_edge_taps_r <= #TCQ 6'bxxxxxx;
prbs_inc_tap_cnt <= #TCQ 'b0;
prbs_dec_tap_cnt <= #TCQ 'b0;
new_cnt_dqs_r <= #TCQ 1'b0;
if (SIM_CAL_OPTION == "FAST_CAL")
prbs_rdlvl_done <= #TCQ 1'b1;
else
prbs_rdlvl_done <= #TCQ 1'b0;
prbs_2nd_edge_taps_r <= #TCQ 6'bxxxxxx;
prbs_last_byte_done <= #TCQ 1'b0;
prbs_tap_mod <= #TCQ 'd0;
reset_rd_addr <= #TCQ 'b0;
read_pause <= #TCQ 'b0;
fine_pi_dec_cnt <= #TCQ 'b0;
match_flag_and <= #TCQ 5'h1f;
stage_cnt <= #TCQ 2'b00;
right_edge_found <= #TCQ 1'b0;
largest_left_edge <= #TCQ 6'b000000;
smallest_right_edge <= #TCQ 6'b111111;
num_samples_done_ind <= #TCQ 'b0;
fine_delay_sel <= #TCQ 'b0;
fine_dly_error <= #TCQ 'b0;
end else begin
case (prbs_state_r)
PRBS_IDLE: begin
prbs_last_byte_done <= #TCQ 1'b0;
prbs_prech_req_r <= #TCQ 1'b0;
if (prbs_rdlvl_start && ~prbs_rdlvl_start_r) begin
if (SIM_CAL_OPTION == "SKIP_CAL" || SIM_CAL_OPTION == "FAST_CAL") begin
prbs_state_r <= #TCQ PRBS_DONE;
reset_rd_addr <= #TCQ 1'b1;
end else begin
new_cnt_dqs_r <= #TCQ 1'b1;
prbs_state_r <= #TCQ PRBS_NEW_DQS_WAIT;
fine_pi_dec_cnt <= #TCQ pi_counter_read_val;//.
end
end
end
// Wait for the new DQS group to change
// also gives time for the read data IN_FIFO to
// output the updated data for the new DQS group
PRBS_NEW_DQS_WAIT: begin
reset_rd_addr <= #TCQ 'b0;
prbs_last_byte_done <= #TCQ 1'b0;
prbs_prech_req_r <= #TCQ 1'b0;
//fine_inc_stage <= #TCQ 1'b1;
stage_cnt <= #TCQ 2'b0;
match_flag_and <= #TCQ 5'h1f;
if (cnt_wait_state) begin
new_cnt_dqs_r <= #TCQ 1'b0;
prbs_state_r <= #TCQ fine_calib? FINE_PI_DEC:PRBS_PAT_COMPARE;
end
end
// Check for presence of data eye edge. During this state, we
// sample the read data multiple times, and look for changes
// in the read data, specifically:
// 1. A change in the read data compared with the value of
// read data from the previous delay tap. This indicates
// that the most recent tap delay increment has moved us
// into either a new window, or moved/kept us in the
// transition/jitter region between windows. Note that this
// condition only needs to be checked for once, and for
// logistical purposes, we check this soon after entering
// this state (see comment in PRBS_PAT_COMPARE below for
// why this is done)
// 2. A change in the read data while we are in this state
// (i.e. in the absence of a tap delay increment). This
// indicates that we're close enough to a window edge that
// jitter will cause the read data to change even in the
// absence of a tap delay change
PRBS_PAT_COMPARE: begin
// Continue to sample read data and look for edges until the
// appropriate time interval (shorter for simulation-only,
// much, much longer for actual h/w) has elapsed
if (num_samples_done_r || compare_err) begin
if (prbs_dqs_tap_limit_r)
// Only one edge detected and ran out of taps since only one
// bit time worth of taps available for window detection. This
// can happen if at tap 0 DQS is in previous window which results
// in only left edge being detected. Or at tap 0 DQS is in the
// current window resulting in only right edge being detected.
// Depending on the frequency this case can also happen if at
// tap 0 DQS is in the left noise region resulting in only left
// edge being detected.
prbs_state_r <= #TCQ PRBS_CALC_TAPS_PRE;
else if (compare_err || (prbs_dqs_tap_cnt_r == 'd0)) begin
// Sticky bit - asserted after we encounter an edge, although
// the current edge may not be considered the "first edge" this
// just means we found at least one edge
prbs_found_1st_edge_r <= #TCQ 1'b1;
// Both edges of data valid window found:
// If we've found a second edge after a region of stability
// then we must have just passed the second ("right" edge of
// the window. Record this second_edge_taps = current tap-1,
// because we're one past the actual second edge tap, where
// the edge taps represent the extremes of the data valid
// window (i.e. smallest & largest taps where data still valid
if (prbs_found_1st_edge_r) begin
prbs_found_2nd_edge_r <= #TCQ 1'b1;
prbs_2nd_edge_taps_r <= #TCQ prbs_dqs_tap_cnt_r - 1;
prbs_state_r <= #TCQ PRBS_CALC_TAPS_PRE;
end else begin
// Otherwise, an edge was found (just not the "second" edge)
// Assuming DQS is in the correct window at tap 0 of Phaser IN
// fine tap. The first edge found is the right edge of the valid
// window and is the beginning of the jitter region hence done!
if (compare_err)
prbs_1st_edge_taps_r <= #TCQ prbs_dqs_tap_cnt_r + 1;
else
prbs_1st_edge_taps_r <= #TCQ 'd0;
prbs_inc_tap_cnt <= #TCQ rdlvl_cpt_tap_cnt - prbs_dqs_tap_cnt_r;
prbs_state_r <= #TCQ PRBS_INC_DQS;
end
end else begin
// Otherwise, if we haven't found an edge....
// If we still have taps left to use, then keep incrementing
if (prbs_found_1st_edge_r)
prbs_state_r <= #TCQ PRBS_INC_DQS;
else
prbs_state_r <= #TCQ PRBS_DEC_DQS;
end
end
end
// Increment Phaser_IN delay for DQS
PRBS_INC_DQS: begin
prbs_state_r <= #TCQ PRBS_INC_DQS_WAIT;
if (prbs_inc_tap_cnt > 'd0)
prbs_inc_tap_cnt <= #TCQ prbs_inc_tap_cnt - 1;
if (~prbs_dqs_tap_limit_r) begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b1;
end
end
// Wait for Phaser_In to settle, before checking again for an edge
PRBS_INC_DQS_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if (cnt_wait_state) begin
if (prbs_inc_tap_cnt > 'd0)
prbs_state_r <= #TCQ PRBS_INC_DQS;
else
prbs_state_r <= #TCQ PRBS_PAT_COMPARE;
end
end
// Calculate final value of Phaser_IN taps. At this point, one or both
// edges of data eye have been found, and/or all taps have been
// exhausted looking for the edges
// NOTE: The amount to be decrement by is calculated, not the
// absolute setting for DQS.
// CENTER compensation with shift by 1
PRBS_CALC_TAPS: begin
if (center_comp) begin
prbs_dec_tap_cnt <= #TCQ (dec_cnt[5] & dec_cnt[0])? 'd32: dec_cnt + pi_adj;
fine_dly_error <= #TCQ (dec_cnt[5] & dec_cnt[0])? 1'b1: fine_dly_error; //sticky bit
read_pause <= #TCQ 'b1;
prbs_state_r <= #TCQ PRBS_DEC_DQS;
end else begin //No center compensation
if (prbs_found_2nd_edge_r && prbs_found_1st_edge_r)
// Both edges detected
prbs_dec_tap_cnt
<= #TCQ ((prbs_2nd_edge_taps_r -
prbs_1st_edge_taps_r)>>1) + 1 + pi_adj;
else if (~prbs_found_2nd_edge_r && prbs_found_1st_edge_r)
// Only left edge detected
prbs_dec_tap_cnt
<= #TCQ ((prbs_dqs_tap_cnt_r - prbs_1st_edge_taps_r)>>1) + pi_adj;
else
// No edges detected
prbs_dec_tap_cnt
<= #TCQ (prbs_dqs_tap_cnt_r>>1) + pi_adj;
// Now use the value we just calculated to decrement CPT taps
// to the desired calibration point
read_pause <= #TCQ 'b1;
prbs_state_r <= #TCQ PRBS_DEC_DQS;
end
end
// decrement capture clock for final adjustment - center
// capture clock in middle of data eye. This adjustment will occur
// only when both the edges are found usign CPT taps. Must do this
// incrementally to avoid clock glitching (since CPT drives clock
// divider within each ISERDES)
PRBS_DEC_DQS: begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b0;
// once adjustment is complete, we're done with calibration for
// this DQS, repeat for next DQS
if (prbs_dec_tap_cnt > 'd0)
prbs_dec_tap_cnt <= #TCQ prbs_dec_tap_cnt - 1;
if (prbs_dec_tap_cnt == 6'b000001)
prbs_state_r <= #TCQ PRBS_NEXT_DQS;
else
prbs_state_r <= #TCQ PRBS_DEC_DQS_WAIT;
end
PRBS_DEC_DQS_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if (cnt_wait_state) begin
if (prbs_dec_tap_cnt > 'd0)
prbs_state_r <= #TCQ PRBS_DEC_DQS;
else
prbs_state_r <= #TCQ PRBS_PAT_COMPARE;
end
end
// Determine whether we're done, or have more DQS's to calibrate
// Also request precharge after every byte, as appropriate
PRBS_NEXT_DQS: begin
read_pause <= #TCQ 'b0;
reset_rd_addr <= #TCQ 'b1;
prbs_prech_req_r <= #TCQ 1'b1;
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
// Prepare for another iteration with next DQS group
prbs_found_1st_edge_r <= #TCQ 1'b0;
prbs_found_2nd_edge_r <= #TCQ 1'b0;
prbs_1st_edge_taps_r <= #TCQ 'd0;
prbs_2nd_edge_taps_r <= #TCQ 'd0;
largest_left_edge <= #TCQ 6'b000000;
smallest_right_edge <= #TCQ 6'b111111;
if (prbs_dqs_cnt_r >= DQS_WIDTH-1) begin
prbs_last_byte_done <= #TCQ 1'b1;
end
// Wait until precharge that occurs in between calibration of
// DQS groups is finished
if (prech_done) begin
prbs_prech_req_r <= #TCQ 1'b0;
if (prbs_dqs_cnt_r >= DQS_WIDTH-1) begin
// All DQS groups done
prbs_state_r <= #TCQ PRBS_DONE;
end else begin
// Process next DQS group
new_cnt_dqs_r <= #TCQ 1'b1;
//fine_pi_dec_cnt <= #TCQ pi_counter_read_val;//.
prbs_dqs_cnt_r <= #TCQ prbs_dqs_cnt_r + 1;
prbs_state_r <= #TCQ PRBS_NEW_DQS_PREWAIT;
end
end
end
PRBS_NEW_DQS_PREWAIT: begin
if (cnt_wait_state) begin
prbs_state_r <= #TCQ PRBS_NEW_DQS_WAIT;
fine_pi_dec_cnt <= #TCQ pi_counter_read_val;//.
end
end
PRBS_CALC_TAPS_PRE:
begin
if(num_samples_done_r) begin
prbs_state_r <= #TCQ fine_calib? PRBS_NEXT_DQS:PRBS_CALC_TAPS_WAIT;
if(center_comp && ~fine_calib) begin
if(prbs_found_1st_edge_r) largest_left_edge <= #TCQ prbs_1st_edge_taps_r;
else largest_left_edge <= #TCQ 6'd0;
if(prbs_found_2nd_edge_r) smallest_right_edge <= #TCQ prbs_2nd_edge_taps_r;
else smallest_right_edge <= #TCQ 6'd63;
end
end
end
//wait for center compensation
PRBS_CALC_TAPS_WAIT:
begin
prbs_state_r <= #TCQ PRBS_CALC_TAPS;
end
//if it is fine_inc stage (first/second stage): dec to 0
//if it is fine_dec stage (third stage): dec to center
FINE_PI_DEC: begin
fine_delay_sel <= #TCQ 'b0;
if(fine_pi_dec_cnt > 0) begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b0;
fine_pi_dec_cnt <= #TCQ fine_pi_dec_cnt - 'd1;
end
prbs_state_r <= #TCQ FINE_PI_DEC_WAIT;
end
//wait for phaser_in tap decrement.
//if first/second stage is done, goes to FINE_PI_INC
//if last stage is done, goes to NEXT_DQS
FINE_PI_DEC_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if(cnt_wait_state) begin
if(fine_pi_dec_cnt >0)
prbs_state_r <= #TCQ FINE_PI_DEC;
else
if(fine_inc_stage)
// prbs_state_r <= #TCQ FINE_PI_INC; //for temp change
prbs_state_r <= #TCQ FINE_PAT_COMPARE_PER_BIT; //start from pi tap "0"
else
prbs_state_r <= #TCQ PRBS_CALC_TAPS_PRE; //finish the process and go to the next DQS
end
end
FINE_PI_INC: begin
if(|left_edge_updated) largest_left_edge <= #TCQ prbs_dqs_tap_cnt_r-4;
if(|right_edge_found_pb && ~right_edge_found) begin
smallest_right_edge <= #TCQ prbs_dqs_tap_cnt_r -1 ;
right_edge_found <= #TCQ 'b1;
end
//left_edge_found_pb <= #TCQ {DRAM_WIDTH{1'b0}};
prbs_state_r <= #TCQ FINE_PI_INC_WAIT;
if(~prbs_dqs_tap_limit_r) begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b1;
end
end
//wait for phase_in tap increment
//need to do pattern compare for every bit
FINE_PI_INC_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if (cnt_wait_state) begin
prbs_state_r <= #TCQ FINE_PAT_COMPARE_PER_BIT;
end
end
//compare per bit data and update flags,left/right edge
FINE_PAT_COMPARE_PER_BIT: begin
if(num_samples_done_r || compare_err_pb_and) begin
//update and_flag - shift and add
match_flag_and <= #TCQ {match_flag_and[3:0],compare_err_pb_and};
//if it is consecutive 5 passing taps followed by fail or tap limit (finish the search)
//don't go to fine_FINE_CALC_TAPS to prevent to skip whole stage
//Or if all right edge are found
if((match_flag_and == 5'b00000 && compare_err_pb_and && (prbs_dqs_tap_cnt_r > 5)) || prbs_dqs_tap_limit_r || (&right_edge_found_pb)) begin
prbs_state_r <= #TCQ FINE_CALC_TAPS;
//if all right edge are alined (all right edge found at the same time), update smallest right edge in here
//doesnt need to set right_edge_found to 1 since it is not used after this stage
if(!right_edge_found) smallest_right_edge <= #TCQ prbs_dqs_tap_cnt_r-1;
end else begin
prbs_state_r <= #TCQ FINE_PI_INC; //keep increase until all fail
end
num_samples_done_ind <= num_samples_done_r;
end
end
//for fine_inc stage, inc all fine delay
//for fine_dec stage, apply dec fine delay for specific bits (by calculating the loss/gain)
// put phaser_in taps to the center
FINE_CALC_TAPS: begin
if(num_samples_done_ind || num_samples_done_r) begin
num_samples_done_ind <= #TCQ 'b0; //indicate num_samples_done_r is set
right_edge_found <= #TCQ 1'b0; //reset right edge found
match_flag_and <= #TCQ 5'h1f; //reset match flag for all bits
prbs_state_r <= #TCQ FINE_CALC_TAPS_WAIT;
end
end
FINE_CALC_TAPS_WAIT: begin //wait for ROM read out
if(stage_cnt == 'd2) begin //last stage : back to center
if(center_comp) begin
fine_pi_dec_cnt <= #TCQ (dec_cnt[5]&dec_cnt[0])? 'd32: prbs_dqs_tap_cnt_r - smallest_right_edge + dec_cnt - 1 + pi_adj ; //going to the center value & shift by 1
fine_dly_error <= #TCQ (dec_cnt[5]&dec_cnt[0]) ? 1'b1: fine_dly_error;
end else begin
fine_pi_dec_cnt <= #TCQ prbs_dqs_tap_cnt_r - center_calc[6:1] - center_calc[0] + pi_adj; //going to the center value & shift left by 1
fine_dly_error <= #TCQ 1'b0;
end
end else begin
fine_pi_dec_cnt <= #TCQ prbs_dqs_tap_cnt_r;
end
if (bit_cnt == DRAM_WIDTH) begin
fine_delay_sel <= #TCQ 'b1;
stage_cnt <= #TCQ stage_cnt + 1;
prbs_state_r <= #TCQ FINE_PI_DEC;
end
end
// Done with this stage of calibration
PRBS_DONE: begin
prbs_prech_req_r <= #TCQ 1'b0;
prbs_last_byte_done <= #TCQ 1'b0;
prbs_rdlvl_done <= #TCQ 1'b1;
reset_rd_addr <= #TCQ 1'b0;
end
endcase
end
//ROM generation for dec counter
always @ (largest_left_edge or smallest_right_edge) begin
case ({largest_left_edge, smallest_right_edge})
12'd0 : mem_out_dec = 6'b111111;
12'd1 : mem_out_dec = 6'b111111;
12'd2 : mem_out_dec = 6'b111111;
12'd3 : mem_out_dec = 6'b111111;
12'd4 : mem_out_dec = 6'b111111;
12'd5 : mem_out_dec = 6'b111111;
12'd6 : mem_out_dec = 6'b000100;
12'd7 : mem_out_dec = 6'b000101;
12'd8 : mem_out_dec = 6'b000101;
12'd9 : mem_out_dec = 6'b000110;
12'd10 : mem_out_dec = 6'b000110;
12'd11 : mem_out_dec = 6'b000111;
12'd12 : mem_out_dec = 6'b001000;
12'd13 : mem_out_dec = 6'b001000;
12'd14 : mem_out_dec = 6'b001001;
12'd15 : mem_out_dec = 6'b001010;
12'd16 : mem_out_dec = 6'b001010;
12'd17 : mem_out_dec = 6'b001011;
12'd18 : mem_out_dec = 6'b001011;
12'd19 : mem_out_dec = 6'b001100;
12'd20 : mem_out_dec = 6'b001100;
12'd21 : mem_out_dec = 6'b001100;
12'd22 : mem_out_dec = 6'b001100;
12'd23 : mem_out_dec = 6'b001101;
12'd24 : mem_out_dec = 6'b001100;
12'd25 : mem_out_dec = 6'b001100;
12'd26 : mem_out_dec = 6'b001101;
12'd27 : mem_out_dec = 6'b001110;
12'd28 : mem_out_dec = 6'b001110;
12'd29 : mem_out_dec = 6'b001111;
12'd30 : mem_out_dec = 6'b010000;
12'd31 : mem_out_dec = 6'b010001;
12'd32 : mem_out_dec = 6'b010001;
12'd33 : mem_out_dec = 6'b010010;
12'd34 : mem_out_dec = 6'b010010;
12'd35 : mem_out_dec = 6'b010010;
12'd36 : mem_out_dec = 6'b010011;
12'd37 : mem_out_dec = 6'b010100;
12'd38 : mem_out_dec = 6'b010100;
12'd39 : mem_out_dec = 6'b010101;
12'd40 : mem_out_dec = 6'b010101;
12'd41 : mem_out_dec = 6'b010110;
12'd42 : mem_out_dec = 6'b010110;
12'd43 : mem_out_dec = 6'b010111;
12'd44 : mem_out_dec = 6'b011000;
12'd45 : mem_out_dec = 6'b011001;
12'd46 : mem_out_dec = 6'b011001;
12'd47 : mem_out_dec = 6'b011010;
12'd48 : mem_out_dec = 6'b011010;
12'd49 : mem_out_dec = 6'b011011;
12'd50 : mem_out_dec = 6'b011011;
12'd51 : mem_out_dec = 6'b011100;
12'd52 : mem_out_dec = 6'b011100;
12'd53 : mem_out_dec = 6'b011100;
12'd54 : mem_out_dec = 6'b011100;
12'd55 : mem_out_dec = 6'b011100;
12'd56 : mem_out_dec = 6'b011100;
12'd57 : mem_out_dec = 6'b011100;
12'd58 : mem_out_dec = 6'b011100;
12'd59 : mem_out_dec = 6'b011101;
12'd60 : mem_out_dec = 6'b011110;
12'd61 : mem_out_dec = 6'b011111;
12'd62 : mem_out_dec = 6'b100000;
12'd63 : mem_out_dec = 6'b100000;
12'd64 : mem_out_dec = 6'b111111;
12'd65 : mem_out_dec = 6'b111111;
12'd66 : mem_out_dec = 6'b111111;
12'd67 : mem_out_dec = 6'b111111;
12'd68 : mem_out_dec = 6'b111111;
12'd69 : mem_out_dec = 6'b111111;
12'd70 : mem_out_dec = 6'b111111;
12'd71 : mem_out_dec = 6'b000100;
12'd72 : mem_out_dec = 6'b000100;
12'd73 : mem_out_dec = 6'b000101;
12'd74 : mem_out_dec = 6'b000110;
12'd75 : mem_out_dec = 6'b000111;
12'd76 : mem_out_dec = 6'b000111;
12'd77 : mem_out_dec = 6'b001000;
12'd78 : mem_out_dec = 6'b001001;
12'd79 : mem_out_dec = 6'b001001;
12'd80 : mem_out_dec = 6'b001010;
12'd81 : mem_out_dec = 6'b001010;
12'd82 : mem_out_dec = 6'b001011;
12'd83 : mem_out_dec = 6'b001011;
12'd84 : mem_out_dec = 6'b001011;
12'd85 : mem_out_dec = 6'b001011;
12'd86 : mem_out_dec = 6'b001011;
12'd87 : mem_out_dec = 6'b001100;
12'd88 : mem_out_dec = 6'b001011;
12'd89 : mem_out_dec = 6'b001100;
12'd90 : mem_out_dec = 6'b001100;
12'd91 : mem_out_dec = 6'b001101;
12'd92 : mem_out_dec = 6'b001110;
12'd93 : mem_out_dec = 6'b001111;
12'd94 : mem_out_dec = 6'b001111;
12'd95 : mem_out_dec = 6'b010000;
12'd96 : mem_out_dec = 6'b010001;
12'd97 : mem_out_dec = 6'b010001;
12'd98 : mem_out_dec = 6'b010010;
12'd99 : mem_out_dec = 6'b010010;
12'd100 : mem_out_dec = 6'b010011;
12'd101 : mem_out_dec = 6'b010011;
12'd102 : mem_out_dec = 6'b010100;
12'd103 : mem_out_dec = 6'b010100;
12'd104 : mem_out_dec = 6'b010100;
12'd105 : mem_out_dec = 6'b010101;
12'd106 : mem_out_dec = 6'b010110;
12'd107 : mem_out_dec = 6'b010111;
12'd108 : mem_out_dec = 6'b010111;
12'd109 : mem_out_dec = 6'b011000;
12'd110 : mem_out_dec = 6'b011001;
12'd111 : mem_out_dec = 6'b011001;
12'd112 : mem_out_dec = 6'b011010;
12'd113 : mem_out_dec = 6'b011010;
12'd114 : mem_out_dec = 6'b011011;
12'd115 : mem_out_dec = 6'b011011;
12'd116 : mem_out_dec = 6'b011011;
12'd117 : mem_out_dec = 6'b011011;
12'd118 : mem_out_dec = 6'b011011;
12'd119 : mem_out_dec = 6'b011011;
12'd120 : mem_out_dec = 6'b011011;
12'd121 : mem_out_dec = 6'b011011;
12'd122 : mem_out_dec = 6'b011100;
12'd123 : mem_out_dec = 6'b011101;
12'd124 : mem_out_dec = 6'b011110;
12'd125 : mem_out_dec = 6'b011110;
12'd126 : mem_out_dec = 6'b011111;
12'd127 : mem_out_dec = 6'b100000;
12'd128 : mem_out_dec = 6'b111111;
12'd129 : mem_out_dec = 6'b111111;
12'd130 : mem_out_dec = 6'b111111;
12'd131 : mem_out_dec = 6'b111111;
12'd132 : mem_out_dec = 6'b111111;
12'd133 : mem_out_dec = 6'b111111;
12'd134 : mem_out_dec = 6'b111111;
12'd135 : mem_out_dec = 6'b111111;
12'd136 : mem_out_dec = 6'b000100;
12'd137 : mem_out_dec = 6'b000101;
12'd138 : mem_out_dec = 6'b000101;
12'd139 : mem_out_dec = 6'b000110;
12'd140 : mem_out_dec = 6'b000110;
12'd141 : mem_out_dec = 6'b000111;
12'd142 : mem_out_dec = 6'b001000;
12'd143 : mem_out_dec = 6'b001001;
12'd144 : mem_out_dec = 6'b001001;
12'd145 : mem_out_dec = 6'b001010;
12'd146 : mem_out_dec = 6'b001010;
12'd147 : mem_out_dec = 6'b001010;
12'd148 : mem_out_dec = 6'b001010;
12'd149 : mem_out_dec = 6'b001010;
12'd150 : mem_out_dec = 6'b001010;
12'd151 : mem_out_dec = 6'b001011;
12'd152 : mem_out_dec = 6'b001010;
12'd153 : mem_out_dec = 6'b001011;
12'd154 : mem_out_dec = 6'b001100;
12'd155 : mem_out_dec = 6'b001101;
12'd156 : mem_out_dec = 6'b001101;
12'd157 : mem_out_dec = 6'b001110;
12'd158 : mem_out_dec = 6'b001111;
12'd159 : mem_out_dec = 6'b010000;
12'd160 : mem_out_dec = 6'b010000;
12'd161 : mem_out_dec = 6'b010001;
12'd162 : mem_out_dec = 6'b010001;
12'd163 : mem_out_dec = 6'b010010;
12'd164 : mem_out_dec = 6'b010010;
12'd165 : mem_out_dec = 6'b010011;
12'd166 : mem_out_dec = 6'b010011;
12'd167 : mem_out_dec = 6'b010100;
12'd168 : mem_out_dec = 6'b010100;
12'd169 : mem_out_dec = 6'b010101;
12'd170 : mem_out_dec = 6'b010101;
12'd171 : mem_out_dec = 6'b010110;
12'd172 : mem_out_dec = 6'b010111;
12'd173 : mem_out_dec = 6'b010111;
12'd174 : mem_out_dec = 6'b011000;
12'd175 : mem_out_dec = 6'b011001;
12'd176 : mem_out_dec = 6'b011001;
12'd177 : mem_out_dec = 6'b011010;
12'd178 : mem_out_dec = 6'b011010;
12'd179 : mem_out_dec = 6'b011010;
12'd180 : mem_out_dec = 6'b011010;
12'd181 : mem_out_dec = 6'b011010;
12'd182 : mem_out_dec = 6'b011010;
12'd183 : mem_out_dec = 6'b011010;
12'd184 : mem_out_dec = 6'b011010;
12'd185 : mem_out_dec = 6'b011011;
12'd186 : mem_out_dec = 6'b011100;
12'd187 : mem_out_dec = 6'b011100;
12'd188 : mem_out_dec = 6'b011101;
12'd189 : mem_out_dec = 6'b011110;
12'd190 : mem_out_dec = 6'b011111;
12'd191 : mem_out_dec = 6'b100000;
12'd192 : mem_out_dec = 6'b111111;
12'd193 : mem_out_dec = 6'b111111;
12'd194 : mem_out_dec = 6'b111111;
12'd195 : mem_out_dec = 6'b111111;
12'd196 : mem_out_dec = 6'b111111;
12'd197 : mem_out_dec = 6'b111111;
12'd198 : mem_out_dec = 6'b111111;
12'd199 : mem_out_dec = 6'b111111;
12'd200 : mem_out_dec = 6'b111111;
12'd201 : mem_out_dec = 6'b000100;
12'd202 : mem_out_dec = 6'b000100;
12'd203 : mem_out_dec = 6'b000101;
12'd204 : mem_out_dec = 6'b000110;
12'd205 : mem_out_dec = 6'b000111;
12'd206 : mem_out_dec = 6'b001000;
12'd207 : mem_out_dec = 6'b001000;
12'd208 : mem_out_dec = 6'b001001;
12'd209 : mem_out_dec = 6'b001001;
12'd210 : mem_out_dec = 6'b001001;
12'd211 : mem_out_dec = 6'b001001;
12'd212 : mem_out_dec = 6'b001001;
12'd213 : mem_out_dec = 6'b001001;
12'd214 : mem_out_dec = 6'b001001;
12'd215 : mem_out_dec = 6'b001010;
12'd216 : mem_out_dec = 6'b001010;
12'd217 : mem_out_dec = 6'b001011;
12'd218 : mem_out_dec = 6'b001011;
12'd219 : mem_out_dec = 6'b001100;
12'd220 : mem_out_dec = 6'b001101;
12'd221 : mem_out_dec = 6'b001110;
12'd222 : mem_out_dec = 6'b001111;
12'd223 : mem_out_dec = 6'b001111;
12'd224 : mem_out_dec = 6'b010000;
12'd225 : mem_out_dec = 6'b010000;
12'd226 : mem_out_dec = 6'b010001;
12'd227 : mem_out_dec = 6'b010001;
12'd228 : mem_out_dec = 6'b010010;
12'd229 : mem_out_dec = 6'b010010;
12'd230 : mem_out_dec = 6'b010011;
12'd231 : mem_out_dec = 6'b010011;
12'd232 : mem_out_dec = 6'b010011;
12'd233 : mem_out_dec = 6'b010100;
12'd234 : mem_out_dec = 6'b010100;
12'd235 : mem_out_dec = 6'b010101;
12'd236 : mem_out_dec = 6'b010110;
12'd237 : mem_out_dec = 6'b010111;
12'd238 : mem_out_dec = 6'b011000;
12'd239 : mem_out_dec = 6'b011000;
12'd240 : mem_out_dec = 6'b011001;
12'd241 : mem_out_dec = 6'b011001;
12'd242 : mem_out_dec = 6'b011001;
12'd243 : mem_out_dec = 6'b011001;
12'd244 : mem_out_dec = 6'b011001;
12'd245 : mem_out_dec = 6'b011001;
12'd246 : mem_out_dec = 6'b011001;
12'd247 : mem_out_dec = 6'b011001;
12'd248 : mem_out_dec = 6'b011010;
12'd249 : mem_out_dec = 6'b011010;
12'd250 : mem_out_dec = 6'b011011;
12'd251 : mem_out_dec = 6'b011100;
12'd252 : mem_out_dec = 6'b011101;
12'd253 : mem_out_dec = 6'b011110;
12'd254 : mem_out_dec = 6'b011110;
12'd255 : mem_out_dec = 6'b011111;
12'd256 : mem_out_dec = 6'b111111;
12'd257 : mem_out_dec = 6'b111111;
12'd258 : mem_out_dec = 6'b111111;
12'd259 : mem_out_dec = 6'b111111;
12'd260 : mem_out_dec = 6'b111111;
12'd261 : mem_out_dec = 6'b111111;
12'd262 : mem_out_dec = 6'b111111;
12'd263 : mem_out_dec = 6'b111111;
12'd264 : mem_out_dec = 6'b111111;
12'd265 : mem_out_dec = 6'b111111;
12'd266 : mem_out_dec = 6'b000100;
12'd267 : mem_out_dec = 6'b000101;
12'd268 : mem_out_dec = 6'b000110;
12'd269 : mem_out_dec = 6'b000110;
12'd270 : mem_out_dec = 6'b000111;
12'd271 : mem_out_dec = 6'b001000;
12'd272 : mem_out_dec = 6'b001000;
12'd273 : mem_out_dec = 6'b001000;
12'd274 : mem_out_dec = 6'b001000;
12'd275 : mem_out_dec = 6'b001000;
12'd276 : mem_out_dec = 6'b001000;
12'd277 : mem_out_dec = 6'b001000;
12'd278 : mem_out_dec = 6'b001000;
12'd279 : mem_out_dec = 6'b001001;
12'd280 : mem_out_dec = 6'b001001;
12'd281 : mem_out_dec = 6'b001010;
12'd282 : mem_out_dec = 6'b001011;
12'd283 : mem_out_dec = 6'b001100;
12'd284 : mem_out_dec = 6'b001101;
12'd285 : mem_out_dec = 6'b001101;
12'd286 : mem_out_dec = 6'b001110;
12'd287 : mem_out_dec = 6'b001111;
12'd288 : mem_out_dec = 6'b001111;
12'd289 : mem_out_dec = 6'b010000;
12'd290 : mem_out_dec = 6'b010000;
12'd291 : mem_out_dec = 6'b010001;
12'd292 : mem_out_dec = 6'b010001;
12'd293 : mem_out_dec = 6'b010010;
12'd294 : mem_out_dec = 6'b010010;
12'd295 : mem_out_dec = 6'b010011;
12'd296 : mem_out_dec = 6'b010010;
12'd297 : mem_out_dec = 6'b010011;
12'd298 : mem_out_dec = 6'b010100;
12'd299 : mem_out_dec = 6'b010101;
12'd300 : mem_out_dec = 6'b010110;
12'd301 : mem_out_dec = 6'b010110;
12'd302 : mem_out_dec = 6'b010111;
12'd303 : mem_out_dec = 6'b011000;
12'd304 : mem_out_dec = 6'b011000;
12'd305 : mem_out_dec = 6'b011000;
12'd306 : mem_out_dec = 6'b011000;
12'd307 : mem_out_dec = 6'b011000;
12'd308 : mem_out_dec = 6'b011000;
12'd309 : mem_out_dec = 6'b011000;
12'd310 : mem_out_dec = 6'b011000;
12'd311 : mem_out_dec = 6'b011001;
12'd312 : mem_out_dec = 6'b011001;
12'd313 : mem_out_dec = 6'b011010;
12'd314 : mem_out_dec = 6'b011011;
12'd315 : mem_out_dec = 6'b011100;
12'd316 : mem_out_dec = 6'b011100;
12'd317 : mem_out_dec = 6'b011101;
12'd318 : mem_out_dec = 6'b011110;
12'd319 : mem_out_dec = 6'b011111;
12'd320 : mem_out_dec = 6'b111111;
12'd321 : mem_out_dec = 6'b111111;
12'd322 : mem_out_dec = 6'b111111;
12'd323 : mem_out_dec = 6'b111111;
12'd324 : mem_out_dec = 6'b111111;
12'd325 : mem_out_dec = 6'b111111;
12'd326 : mem_out_dec = 6'b111111;
12'd327 : mem_out_dec = 6'b111111;
12'd328 : mem_out_dec = 6'b111111;
12'd329 : mem_out_dec = 6'b111111;
12'd330 : mem_out_dec = 6'b111111;
12'd331 : mem_out_dec = 6'b000100;
12'd332 : mem_out_dec = 6'b000101;
12'd333 : mem_out_dec = 6'b000110;
12'd334 : mem_out_dec = 6'b000111;
12'd335 : mem_out_dec = 6'b001000;
12'd336 : mem_out_dec = 6'b000111;
12'd337 : mem_out_dec = 6'b000111;
12'd338 : mem_out_dec = 6'b000111;
12'd339 : mem_out_dec = 6'b000111;
12'd340 : mem_out_dec = 6'b000111;
12'd341 : mem_out_dec = 6'b000111;
12'd342 : mem_out_dec = 6'b001000;
12'd343 : mem_out_dec = 6'b001001;
12'd344 : mem_out_dec = 6'b001001;
12'd345 : mem_out_dec = 6'b001010;
12'd346 : mem_out_dec = 6'b001011;
12'd347 : mem_out_dec = 6'b001011;
12'd348 : mem_out_dec = 6'b001100;
12'd349 : mem_out_dec = 6'b001101;
12'd350 : mem_out_dec = 6'b001110;
12'd351 : mem_out_dec = 6'b001110;
12'd352 : mem_out_dec = 6'b001111;
12'd353 : mem_out_dec = 6'b001111;
12'd354 : mem_out_dec = 6'b010000;
12'd355 : mem_out_dec = 6'b010000;
12'd356 : mem_out_dec = 6'b010001;
12'd357 : mem_out_dec = 6'b010001;
12'd358 : mem_out_dec = 6'b010001;
12'd359 : mem_out_dec = 6'b010010;
12'd360 : mem_out_dec = 6'b010010;
12'd361 : mem_out_dec = 6'b010011;
12'd362 : mem_out_dec = 6'b010100;
12'd363 : mem_out_dec = 6'b010100;
12'd364 : mem_out_dec = 6'b010101;
12'd365 : mem_out_dec = 6'b010110;
12'd366 : mem_out_dec = 6'b010111;
12'd367 : mem_out_dec = 6'b011000;
12'd368 : mem_out_dec = 6'b010111;
12'd369 : mem_out_dec = 6'b010111;
12'd370 : mem_out_dec = 6'b010111;
12'd371 : mem_out_dec = 6'b010111;
12'd372 : mem_out_dec = 6'b010111;
12'd373 : mem_out_dec = 6'b010111;
12'd374 : mem_out_dec = 6'b011000;
12'd375 : mem_out_dec = 6'b011001;
12'd376 : mem_out_dec = 6'b011001;
12'd377 : mem_out_dec = 6'b011010;
12'd378 : mem_out_dec = 6'b011010;
12'd379 : mem_out_dec = 6'b011011;
12'd380 : mem_out_dec = 6'b011100;
12'd381 : mem_out_dec = 6'b011101;
12'd382 : mem_out_dec = 6'b011101;
12'd383 : mem_out_dec = 6'b011110;
12'd384 : mem_out_dec = 6'b111111;
12'd385 : mem_out_dec = 6'b111111;
12'd386 : mem_out_dec = 6'b111111;
12'd387 : mem_out_dec = 6'b111111;
12'd388 : mem_out_dec = 6'b111111;
12'd389 : mem_out_dec = 6'b111111;
12'd390 : mem_out_dec = 6'b111111;
12'd391 : mem_out_dec = 6'b111111;
12'd392 : mem_out_dec = 6'b111111;
12'd393 : mem_out_dec = 6'b111111;
12'd394 : mem_out_dec = 6'b111111;
12'd395 : mem_out_dec = 6'b111111;
12'd396 : mem_out_dec = 6'b000101;
12'd397 : mem_out_dec = 6'b000110;
12'd398 : mem_out_dec = 6'b000110;
12'd399 : mem_out_dec = 6'b000111;
12'd400 : mem_out_dec = 6'b000110;
12'd401 : mem_out_dec = 6'b000110;
12'd402 : mem_out_dec = 6'b000110;
12'd403 : mem_out_dec = 6'b000110;
12'd404 : mem_out_dec = 6'b000110;
12'd405 : mem_out_dec = 6'b000111;
12'd406 : mem_out_dec = 6'b001000;
12'd407 : mem_out_dec = 6'b001000;
12'd408 : mem_out_dec = 6'b001001;
12'd409 : mem_out_dec = 6'b001001;
12'd410 : mem_out_dec = 6'b001010;
12'd411 : mem_out_dec = 6'b001011;
12'd412 : mem_out_dec = 6'b001100;
12'd413 : mem_out_dec = 6'b001100;
12'd414 : mem_out_dec = 6'b001101;
12'd415 : mem_out_dec = 6'b001110;
12'd416 : mem_out_dec = 6'b001110;
12'd417 : mem_out_dec = 6'b001111;
12'd418 : mem_out_dec = 6'b001111;
12'd419 : mem_out_dec = 6'b010000;
12'd420 : mem_out_dec = 6'b010000;
12'd421 : mem_out_dec = 6'b010000;
12'd422 : mem_out_dec = 6'b010001;
12'd423 : mem_out_dec = 6'b010001;
12'd424 : mem_out_dec = 6'b010010;
12'd425 : mem_out_dec = 6'b010011;
12'd426 : mem_out_dec = 6'b010011;
12'd427 : mem_out_dec = 6'b010100;
12'd428 : mem_out_dec = 6'b010101;
12'd429 : mem_out_dec = 6'b010110;
12'd430 : mem_out_dec = 6'b010111;
12'd431 : mem_out_dec = 6'b010111;
12'd432 : mem_out_dec = 6'b010110;
12'd433 : mem_out_dec = 6'b010110;
12'd434 : mem_out_dec = 6'b010110;
12'd435 : mem_out_dec = 6'b010110;
12'd436 : mem_out_dec = 6'b010110;
12'd437 : mem_out_dec = 6'b010111;
12'd438 : mem_out_dec = 6'b010111;
12'd439 : mem_out_dec = 6'b011000;
12'd440 : mem_out_dec = 6'b011001;
12'd441 : mem_out_dec = 6'b011001;
12'd442 : mem_out_dec = 6'b011010;
12'd443 : mem_out_dec = 6'b011011;
12'd444 : mem_out_dec = 6'b011011;
12'd445 : mem_out_dec = 6'b011100;
12'd446 : mem_out_dec = 6'b011101;
12'd447 : mem_out_dec = 6'b011110;
12'd448 : mem_out_dec = 6'b111111;
12'd449 : mem_out_dec = 6'b111111;
12'd450 : mem_out_dec = 6'b111111;
12'd451 : mem_out_dec = 6'b111111;
12'd452 : mem_out_dec = 6'b111111;
12'd453 : mem_out_dec = 6'b111111;
12'd454 : mem_out_dec = 6'b111111;
12'd455 : mem_out_dec = 6'b111111;
12'd456 : mem_out_dec = 6'b111111;
12'd457 : mem_out_dec = 6'b111111;
12'd458 : mem_out_dec = 6'b111111;
12'd459 : mem_out_dec = 6'b111111;
12'd460 : mem_out_dec = 6'b111111;
12'd461 : mem_out_dec = 6'b000101;
12'd462 : mem_out_dec = 6'b000110;
12'd463 : mem_out_dec = 6'b000110;
12'd464 : mem_out_dec = 6'b000110;
12'd465 : mem_out_dec = 6'b000110;
12'd466 : mem_out_dec = 6'b000110;
12'd467 : mem_out_dec = 6'b000110;
12'd468 : mem_out_dec = 6'b000110;
12'd469 : mem_out_dec = 6'b000111;
12'd470 : mem_out_dec = 6'b000111;
12'd471 : mem_out_dec = 6'b001000;
12'd472 : mem_out_dec = 6'b001000;
12'd473 : mem_out_dec = 6'b001001;
12'd474 : mem_out_dec = 6'b001010;
12'd475 : mem_out_dec = 6'b001011;
12'd476 : mem_out_dec = 6'b001011;
12'd477 : mem_out_dec = 6'b001100;
12'd478 : mem_out_dec = 6'b001101;
12'd479 : mem_out_dec = 6'b001110;
12'd480 : mem_out_dec = 6'b001110;
12'd481 : mem_out_dec = 6'b001110;
12'd482 : mem_out_dec = 6'b001111;
12'd483 : mem_out_dec = 6'b001111;
12'd484 : mem_out_dec = 6'b010000;
12'd485 : mem_out_dec = 6'b010000;
12'd486 : mem_out_dec = 6'b010000;
12'd487 : mem_out_dec = 6'b010001;
12'd488 : mem_out_dec = 6'b010001;
12'd489 : mem_out_dec = 6'b010010;
12'd490 : mem_out_dec = 6'b010011;
12'd491 : mem_out_dec = 6'b010100;
12'd492 : mem_out_dec = 6'b010101;
12'd493 : mem_out_dec = 6'b010101;
12'd494 : mem_out_dec = 6'b010110;
12'd495 : mem_out_dec = 6'b010110;
12'd496 : mem_out_dec = 6'b010110;
12'd497 : mem_out_dec = 6'b010110;
12'd498 : mem_out_dec = 6'b010101;
12'd499 : mem_out_dec = 6'b010101;
12'd500 : mem_out_dec = 6'b010110;
12'd501 : mem_out_dec = 6'b010111;
12'd502 : mem_out_dec = 6'b010111;
12'd503 : mem_out_dec = 6'b011000;
12'd504 : mem_out_dec = 6'b011000;
12'd505 : mem_out_dec = 6'b011001;
12'd506 : mem_out_dec = 6'b011010;
12'd507 : mem_out_dec = 6'b011010;
12'd508 : mem_out_dec = 6'b011011;
12'd509 : mem_out_dec = 6'b011100;
12'd510 : mem_out_dec = 6'b011101;
12'd511 : mem_out_dec = 6'b011101;
12'd512 : mem_out_dec = 6'b111111;
12'd513 : mem_out_dec = 6'b111111;
12'd514 : mem_out_dec = 6'b111111;
12'd515 : mem_out_dec = 6'b111111;
12'd516 : mem_out_dec = 6'b111111;
12'd517 : mem_out_dec = 6'b111111;
12'd518 : mem_out_dec = 6'b111111;
12'd519 : mem_out_dec = 6'b111111;
12'd520 : mem_out_dec = 6'b111111;
12'd521 : mem_out_dec = 6'b111111;
12'd522 : mem_out_dec = 6'b111111;
12'd523 : mem_out_dec = 6'b111111;
12'd524 : mem_out_dec = 6'b111111;
12'd525 : mem_out_dec = 6'b111111;
12'd526 : mem_out_dec = 6'b000100;
12'd527 : mem_out_dec = 6'b000101;
12'd528 : mem_out_dec = 6'b000100;
12'd529 : mem_out_dec = 6'b000100;
12'd530 : mem_out_dec = 6'b000100;
12'd531 : mem_out_dec = 6'b000101;
12'd532 : mem_out_dec = 6'b000101;
12'd533 : mem_out_dec = 6'b000110;
12'd534 : mem_out_dec = 6'b000111;
12'd535 : mem_out_dec = 6'b000111;
12'd536 : mem_out_dec = 6'b000111;
12'd537 : mem_out_dec = 6'b001000;
12'd538 : mem_out_dec = 6'b001001;
12'd539 : mem_out_dec = 6'b001010;
12'd540 : mem_out_dec = 6'b001011;
12'd541 : mem_out_dec = 6'b001011;
12'd542 : mem_out_dec = 6'b001100;
12'd543 : mem_out_dec = 6'b001101;
12'd544 : mem_out_dec = 6'b001101;
12'd545 : mem_out_dec = 6'b001101;
12'd546 : mem_out_dec = 6'b001110;
12'd547 : mem_out_dec = 6'b001110;
12'd548 : mem_out_dec = 6'b001110;
12'd549 : mem_out_dec = 6'b001111;
12'd550 : mem_out_dec = 6'b010000;
12'd551 : mem_out_dec = 6'b010000;
12'd552 : mem_out_dec = 6'b010001;
12'd553 : mem_out_dec = 6'b010001;
12'd554 : mem_out_dec = 6'b010010;
12'd555 : mem_out_dec = 6'b010010;
12'd556 : mem_out_dec = 6'b010011;
12'd557 : mem_out_dec = 6'b010100;
12'd558 : mem_out_dec = 6'b010100;
12'd559 : mem_out_dec = 6'b010100;
12'd560 : mem_out_dec = 6'b010100;
12'd561 : mem_out_dec = 6'b010100;
12'd562 : mem_out_dec = 6'b010100;
12'd563 : mem_out_dec = 6'b010101;
12'd564 : mem_out_dec = 6'b010101;
12'd565 : mem_out_dec = 6'b010110;
12'd566 : mem_out_dec = 6'b010111;
12'd567 : mem_out_dec = 6'b010111;
12'd568 : mem_out_dec = 6'b010111;
12'd569 : mem_out_dec = 6'b011000;
12'd570 : mem_out_dec = 6'b011001;
12'd571 : mem_out_dec = 6'b011010;
12'd572 : mem_out_dec = 6'b011010;
12'd573 : mem_out_dec = 6'b011011;
12'd574 : mem_out_dec = 6'b011100;
12'd575 : mem_out_dec = 6'b011101;
12'd576 : mem_out_dec = 6'b111111;
12'd577 : mem_out_dec = 6'b111111;
12'd578 : mem_out_dec = 6'b111111;
12'd579 : mem_out_dec = 6'b111111;
12'd580 : mem_out_dec = 6'b111111;
12'd581 : mem_out_dec = 6'b111111;
12'd582 : mem_out_dec = 6'b111111;
12'd583 : mem_out_dec = 6'b111111;
12'd584 : mem_out_dec = 6'b111111;
12'd585 : mem_out_dec = 6'b111111;
12'd586 : mem_out_dec = 6'b111111;
12'd587 : mem_out_dec = 6'b111111;
12'd588 : mem_out_dec = 6'b111111;
12'd589 : mem_out_dec = 6'b111111;
12'd590 : mem_out_dec = 6'b111111;
12'd591 : mem_out_dec = 6'b000100;
12'd592 : mem_out_dec = 6'b000011;
12'd593 : mem_out_dec = 6'b000011;
12'd594 : mem_out_dec = 6'b000100;
12'd595 : mem_out_dec = 6'b000101;
12'd596 : mem_out_dec = 6'b000101;
12'd597 : mem_out_dec = 6'b000110;
12'd598 : mem_out_dec = 6'b000110;
12'd599 : mem_out_dec = 6'b000111;
12'd600 : mem_out_dec = 6'b000111;
12'd601 : mem_out_dec = 6'b001000;
12'd602 : mem_out_dec = 6'b001001;
12'd603 : mem_out_dec = 6'b001010;
12'd604 : mem_out_dec = 6'b001010;
12'd605 : mem_out_dec = 6'b001011;
12'd606 : mem_out_dec = 6'b001100;
12'd607 : mem_out_dec = 6'b001101;
12'd608 : mem_out_dec = 6'b001101;
12'd609 : mem_out_dec = 6'b001101;
12'd610 : mem_out_dec = 6'b001110;
12'd611 : mem_out_dec = 6'b001110;
12'd612 : mem_out_dec = 6'b001110;
12'd613 : mem_out_dec = 6'b001111;
12'd614 : mem_out_dec = 6'b010000;
12'd615 : mem_out_dec = 6'b010000;
12'd616 : mem_out_dec = 6'b010000;
12'd617 : mem_out_dec = 6'b010001;
12'd618 : mem_out_dec = 6'b010001;
12'd619 : mem_out_dec = 6'b010010;
12'd620 : mem_out_dec = 6'b010010;
12'd621 : mem_out_dec = 6'b010011;
12'd622 : mem_out_dec = 6'b010011;
12'd623 : mem_out_dec = 6'b010100;
12'd624 : mem_out_dec = 6'b010011;
12'd625 : mem_out_dec = 6'b010011;
12'd626 : mem_out_dec = 6'b010100;
12'd627 : mem_out_dec = 6'b010100;
12'd628 : mem_out_dec = 6'b010101;
12'd629 : mem_out_dec = 6'b010110;
12'd630 : mem_out_dec = 6'b010110;
12'd631 : mem_out_dec = 6'b010111;
12'd632 : mem_out_dec = 6'b010111;
12'd633 : mem_out_dec = 6'b011000;
12'd634 : mem_out_dec = 6'b011001;
12'd635 : mem_out_dec = 6'b011001;
12'd636 : mem_out_dec = 6'b011010;
12'd637 : mem_out_dec = 6'b011011;
12'd638 : mem_out_dec = 6'b011100;
12'd639 : mem_out_dec = 6'b011100;
12'd640 : mem_out_dec = 6'b111111;
12'd641 : mem_out_dec = 6'b111111;
12'd642 : mem_out_dec = 6'b111111;
12'd643 : mem_out_dec = 6'b111111;
12'd644 : mem_out_dec = 6'b111111;
12'd645 : mem_out_dec = 6'b111111;
12'd646 : mem_out_dec = 6'b111111;
12'd647 : mem_out_dec = 6'b111111;
12'd648 : mem_out_dec = 6'b111111;
12'd649 : mem_out_dec = 6'b111111;
12'd650 : mem_out_dec = 6'b111111;
12'd651 : mem_out_dec = 6'b111111;
12'd652 : mem_out_dec = 6'b111111;
12'd653 : mem_out_dec = 6'b111111;
12'd654 : mem_out_dec = 6'b111111;
12'd655 : mem_out_dec = 6'b111111;
12'd656 : mem_out_dec = 6'b000011;
12'd657 : mem_out_dec = 6'b000011;
12'd658 : mem_out_dec = 6'b000100;
12'd659 : mem_out_dec = 6'b000100;
12'd660 : mem_out_dec = 6'b000101;
12'd661 : mem_out_dec = 6'b000110;
12'd662 : mem_out_dec = 6'b000110;
12'd663 : mem_out_dec = 6'b000111;
12'd664 : mem_out_dec = 6'b000111;
12'd665 : mem_out_dec = 6'b001000;
12'd666 : mem_out_dec = 6'b001001;
12'd667 : mem_out_dec = 6'b001001;
12'd668 : mem_out_dec = 6'b001010;
12'd669 : mem_out_dec = 6'b001011;
12'd670 : mem_out_dec = 6'b001100;
12'd671 : mem_out_dec = 6'b001100;
12'd672 : mem_out_dec = 6'b001100;
12'd673 : mem_out_dec = 6'b001101;
12'd674 : mem_out_dec = 6'b001101;
12'd675 : mem_out_dec = 6'b001101;
12'd676 : mem_out_dec = 6'b001110;
12'd677 : mem_out_dec = 6'b001111;
12'd678 : mem_out_dec = 6'b001111;
12'd679 : mem_out_dec = 6'b010000;
12'd680 : mem_out_dec = 6'b010000;
12'd681 : mem_out_dec = 6'b010000;
12'd682 : mem_out_dec = 6'b010001;
12'd683 : mem_out_dec = 6'b010001;
12'd684 : mem_out_dec = 6'b010010;
12'd685 : mem_out_dec = 6'b010010;
12'd686 : mem_out_dec = 6'b010011;
12'd687 : mem_out_dec = 6'b010011;
12'd688 : mem_out_dec = 6'b010011;
12'd689 : mem_out_dec = 6'b010011;
12'd690 : mem_out_dec = 6'b010100;
12'd691 : mem_out_dec = 6'b010100;
12'd692 : mem_out_dec = 6'b010101;
12'd693 : mem_out_dec = 6'b010101;
12'd694 : mem_out_dec = 6'b010110;
12'd695 : mem_out_dec = 6'b010111;
12'd696 : mem_out_dec = 6'b010111;
12'd697 : mem_out_dec = 6'b011000;
12'd698 : mem_out_dec = 6'b011000;
12'd699 : mem_out_dec = 6'b011001;
12'd700 : mem_out_dec = 6'b011010;
12'd701 : mem_out_dec = 6'b011011;
12'd702 : mem_out_dec = 6'b011011;
12'd703 : mem_out_dec = 6'b011100;
12'd704 : mem_out_dec = 6'b111111;
12'd705 : mem_out_dec = 6'b111111;
12'd706 : mem_out_dec = 6'b111111;
12'd707 : mem_out_dec = 6'b111111;
12'd708 : mem_out_dec = 6'b111111;
12'd709 : mem_out_dec = 6'b111111;
12'd710 : mem_out_dec = 6'b111111;
12'd711 : mem_out_dec = 6'b111111;
12'd712 : mem_out_dec = 6'b111111;
12'd713 : mem_out_dec = 6'b111111;
12'd714 : mem_out_dec = 6'b111111;
12'd715 : mem_out_dec = 6'b111111;
12'd716 : mem_out_dec = 6'b111111;
12'd717 : mem_out_dec = 6'b111111;
12'd718 : mem_out_dec = 6'b111111;
12'd719 : mem_out_dec = 6'b111111;
12'd720 : mem_out_dec = 6'b111111;
12'd721 : mem_out_dec = 6'b000011;
12'd722 : mem_out_dec = 6'b000100;
12'd723 : mem_out_dec = 6'b000100;
12'd724 : mem_out_dec = 6'b000101;
12'd725 : mem_out_dec = 6'b000101;
12'd726 : mem_out_dec = 6'b000110;
12'd727 : mem_out_dec = 6'b000111;
12'd728 : mem_out_dec = 6'b000111;
12'd729 : mem_out_dec = 6'b000111;
12'd730 : mem_out_dec = 6'b001000;
12'd731 : mem_out_dec = 6'b001001;
12'd732 : mem_out_dec = 6'b001010;
12'd733 : mem_out_dec = 6'b001011;
12'd734 : mem_out_dec = 6'b001011;
12'd735 : mem_out_dec = 6'b001100;
12'd736 : mem_out_dec = 6'b001100;
12'd737 : mem_out_dec = 6'b001101;
12'd738 : mem_out_dec = 6'b001101;
12'd739 : mem_out_dec = 6'b001101;
12'd740 : mem_out_dec = 6'b001110;
12'd741 : mem_out_dec = 6'b001110;
12'd742 : mem_out_dec = 6'b001111;
12'd743 : mem_out_dec = 6'b010000;
12'd744 : mem_out_dec = 6'b001111;
12'd745 : mem_out_dec = 6'b010000;
12'd746 : mem_out_dec = 6'b010000;
12'd747 : mem_out_dec = 6'b010001;
12'd748 : mem_out_dec = 6'b010001;
12'd749 : mem_out_dec = 6'b010010;
12'd750 : mem_out_dec = 6'b010010;
12'd751 : mem_out_dec = 6'b010011;
12'd752 : mem_out_dec = 6'b010010;
12'd753 : mem_out_dec = 6'b010011;
12'd754 : mem_out_dec = 6'b010011;
12'd755 : mem_out_dec = 6'b010100;
12'd756 : mem_out_dec = 6'b010101;
12'd757 : mem_out_dec = 6'b010101;
12'd758 : mem_out_dec = 6'b010110;
12'd759 : mem_out_dec = 6'b010110;
12'd760 : mem_out_dec = 6'b010111;
12'd761 : mem_out_dec = 6'b010111;
12'd762 : mem_out_dec = 6'b011000;
12'd763 : mem_out_dec = 6'b011001;
12'd764 : mem_out_dec = 6'b011010;
12'd765 : mem_out_dec = 6'b011010;
12'd766 : mem_out_dec = 6'b011011;
12'd767 : mem_out_dec = 6'b011100;
12'd768 : mem_out_dec = 6'b111111;
12'd769 : mem_out_dec = 6'b111111;
12'd770 : mem_out_dec = 6'b111111;
12'd771 : mem_out_dec = 6'b111111;
12'd772 : mem_out_dec = 6'b111111;
12'd773 : mem_out_dec = 6'b111111;
12'd774 : mem_out_dec = 6'b111111;
12'd775 : mem_out_dec = 6'b111111;
12'd776 : mem_out_dec = 6'b111111;
12'd777 : mem_out_dec = 6'b111111;
12'd778 : mem_out_dec = 6'b111111;
12'd779 : mem_out_dec = 6'b111111;
12'd780 : mem_out_dec = 6'b111111;
12'd781 : mem_out_dec = 6'b111111;
12'd782 : mem_out_dec = 6'b111111;
12'd783 : mem_out_dec = 6'b111111;
12'd784 : mem_out_dec = 6'b111111;
12'd785 : mem_out_dec = 6'b111111;
12'd786 : mem_out_dec = 6'b000011;
12'd787 : mem_out_dec = 6'b000100;
12'd788 : mem_out_dec = 6'b000101;
12'd789 : mem_out_dec = 6'b000101;
12'd790 : mem_out_dec = 6'b000110;
12'd791 : mem_out_dec = 6'b000110;
12'd792 : mem_out_dec = 6'b000110;
12'd793 : mem_out_dec = 6'b000111;
12'd794 : mem_out_dec = 6'b001000;
12'd795 : mem_out_dec = 6'b001001;
12'd796 : mem_out_dec = 6'b001010;
12'd797 : mem_out_dec = 6'b001010;
12'd798 : mem_out_dec = 6'b001011;
12'd799 : mem_out_dec = 6'b001100;
12'd800 : mem_out_dec = 6'b001100;
12'd801 : mem_out_dec = 6'b001100;
12'd802 : mem_out_dec = 6'b001101;
12'd803 : mem_out_dec = 6'b001101;
12'd804 : mem_out_dec = 6'b001110;
12'd805 : mem_out_dec = 6'b001110;
12'd806 : mem_out_dec = 6'b001111;
12'd807 : mem_out_dec = 6'b010000;
12'd808 : mem_out_dec = 6'b001111;
12'd809 : mem_out_dec = 6'b001111;
12'd810 : mem_out_dec = 6'b010000;
12'd811 : mem_out_dec = 6'b010000;
12'd812 : mem_out_dec = 6'b010001;
12'd813 : mem_out_dec = 6'b010001;
12'd814 : mem_out_dec = 6'b010010;
12'd815 : mem_out_dec = 6'b010010;
12'd816 : mem_out_dec = 6'b010010;
12'd817 : mem_out_dec = 6'b010011;
12'd818 : mem_out_dec = 6'b010011;
12'd819 : mem_out_dec = 6'b010100;
12'd820 : mem_out_dec = 6'b010100;
12'd821 : mem_out_dec = 6'b010101;
12'd822 : mem_out_dec = 6'b010110;
12'd823 : mem_out_dec = 6'b010110;
12'd824 : mem_out_dec = 6'b010110;
12'd825 : mem_out_dec = 6'b010111;
12'd826 : mem_out_dec = 6'b011000;
12'd827 : mem_out_dec = 6'b011001;
12'd828 : mem_out_dec = 6'b011001;
12'd829 : mem_out_dec = 6'b011010;
12'd830 : mem_out_dec = 6'b011011;
12'd831 : mem_out_dec = 6'b011100;
12'd832 : mem_out_dec = 6'b111111;
12'd833 : mem_out_dec = 6'b111111;
12'd834 : mem_out_dec = 6'b111111;
12'd835 : mem_out_dec = 6'b111111;
12'd836 : mem_out_dec = 6'b111111;
12'd837 : mem_out_dec = 6'b111111;
12'd838 : mem_out_dec = 6'b111111;
12'd839 : mem_out_dec = 6'b111111;
12'd840 : mem_out_dec = 6'b111111;
12'd841 : mem_out_dec = 6'b111111;
12'd842 : mem_out_dec = 6'b111111;
12'd843 : mem_out_dec = 6'b111111;
12'd844 : mem_out_dec = 6'b111111;
12'd845 : mem_out_dec = 6'b111111;
12'd846 : mem_out_dec = 6'b111111;
12'd847 : mem_out_dec = 6'b111111;
12'd848 : mem_out_dec = 6'b111111;
12'd849 : mem_out_dec = 6'b111111;
12'd850 : mem_out_dec = 6'b111111;
12'd851 : mem_out_dec = 6'b000100;
12'd852 : mem_out_dec = 6'b000100;
12'd853 : mem_out_dec = 6'b000101;
12'd854 : mem_out_dec = 6'b000101;
12'd855 : mem_out_dec = 6'b000110;
12'd856 : mem_out_dec = 6'b000110;
12'd857 : mem_out_dec = 6'b000111;
12'd858 : mem_out_dec = 6'b001000;
12'd859 : mem_out_dec = 6'b001001;
12'd860 : mem_out_dec = 6'b001001;
12'd861 : mem_out_dec = 6'b001010;
12'd862 : mem_out_dec = 6'b001011;
12'd863 : mem_out_dec = 6'b001100;
12'd864 : mem_out_dec = 6'b001100;
12'd865 : mem_out_dec = 6'b001100;
12'd866 : mem_out_dec = 6'b001100;
12'd867 : mem_out_dec = 6'b001101;
12'd868 : mem_out_dec = 6'b001101;
12'd869 : mem_out_dec = 6'b001110;
12'd870 : mem_out_dec = 6'b001111;
12'd871 : mem_out_dec = 6'b001111;
12'd872 : mem_out_dec = 6'b001110;
12'd873 : mem_out_dec = 6'b001111;
12'd874 : mem_out_dec = 6'b001111;
12'd875 : mem_out_dec = 6'b010000;
12'd876 : mem_out_dec = 6'b010000;
12'd877 : mem_out_dec = 6'b010001;
12'd878 : mem_out_dec = 6'b010001;
12'd879 : mem_out_dec = 6'b010010;
12'd880 : mem_out_dec = 6'b010010;
12'd881 : mem_out_dec = 6'b010010;
12'd882 : mem_out_dec = 6'b010011;
12'd883 : mem_out_dec = 6'b010100;
12'd884 : mem_out_dec = 6'b010100;
12'd885 : mem_out_dec = 6'b010101;
12'd886 : mem_out_dec = 6'b010101;
12'd887 : mem_out_dec = 6'b010110;
12'd888 : mem_out_dec = 6'b010110;
12'd889 : mem_out_dec = 6'b010111;
12'd890 : mem_out_dec = 6'b011000;
12'd891 : mem_out_dec = 6'b011000;
12'd892 : mem_out_dec = 6'b011001;
12'd893 : mem_out_dec = 6'b011010;
12'd894 : mem_out_dec = 6'b011011;
12'd895 : mem_out_dec = 6'b011011;
12'd896 : mem_out_dec = 6'b111111;
12'd897 : mem_out_dec = 6'b111111;
12'd898 : mem_out_dec = 6'b111111;
12'd899 : mem_out_dec = 6'b111111;
12'd900 : mem_out_dec = 6'b111111;
12'd901 : mem_out_dec = 6'b111111;
12'd902 : mem_out_dec = 6'b111111;
12'd903 : mem_out_dec = 6'b111111;
12'd904 : mem_out_dec = 6'b111111;
12'd905 : mem_out_dec = 6'b111111;
12'd906 : mem_out_dec = 6'b111111;
12'd907 : mem_out_dec = 6'b111111;
12'd908 : mem_out_dec = 6'b111111;
12'd909 : mem_out_dec = 6'b111111;
12'd910 : mem_out_dec = 6'b111111;
12'd911 : mem_out_dec = 6'b111111;
12'd912 : mem_out_dec = 6'b111111;
12'd913 : mem_out_dec = 6'b111111;
12'd914 : mem_out_dec = 6'b111111;
12'd915 : mem_out_dec = 6'b111111;
12'd916 : mem_out_dec = 6'b000100;
12'd917 : mem_out_dec = 6'b000101;
12'd918 : mem_out_dec = 6'b000101;
12'd919 : mem_out_dec = 6'b000110;
12'd920 : mem_out_dec = 6'b000110;
12'd921 : mem_out_dec = 6'b000111;
12'd922 : mem_out_dec = 6'b001000;
12'd923 : mem_out_dec = 6'b001000;
12'd924 : mem_out_dec = 6'b001001;
12'd925 : mem_out_dec = 6'b001010;
12'd926 : mem_out_dec = 6'b001011;
12'd927 : mem_out_dec = 6'b001011;
12'd928 : mem_out_dec = 6'b001011;
12'd929 : mem_out_dec = 6'b001100;
12'd930 : mem_out_dec = 6'b001100;
12'd931 : mem_out_dec = 6'b001101;
12'd932 : mem_out_dec = 6'b001101;
12'd933 : mem_out_dec = 6'b001110;
12'd934 : mem_out_dec = 6'b001110;
12'd935 : mem_out_dec = 6'b001111;
12'd936 : mem_out_dec = 6'b001110;
12'd937 : mem_out_dec = 6'b001110;
12'd938 : mem_out_dec = 6'b001111;
12'd939 : mem_out_dec = 6'b001111;
12'd940 : mem_out_dec = 6'b010000;
12'd941 : mem_out_dec = 6'b010000;
12'd942 : mem_out_dec = 6'b010001;
12'd943 : mem_out_dec = 6'b010001;
12'd944 : mem_out_dec = 6'b010010;
12'd945 : mem_out_dec = 6'b010010;
12'd946 : mem_out_dec = 6'b010011;
12'd947 : mem_out_dec = 6'b010011;
12'd948 : mem_out_dec = 6'b010100;
12'd949 : mem_out_dec = 6'b010100;
12'd950 : mem_out_dec = 6'b010101;
12'd951 : mem_out_dec = 6'b010110;
12'd952 : mem_out_dec = 6'b010110;
12'd953 : mem_out_dec = 6'b010111;
12'd954 : mem_out_dec = 6'b010111;
12'd955 : mem_out_dec = 6'b011000;
12'd956 : mem_out_dec = 6'b011001;
12'd957 : mem_out_dec = 6'b011010;
12'd958 : mem_out_dec = 6'b011010;
12'd959 : mem_out_dec = 6'b011011;
12'd960 : mem_out_dec = 6'b111111;
12'd961 : mem_out_dec = 6'b111111;
12'd962 : mem_out_dec = 6'b111111;
12'd963 : mem_out_dec = 6'b111111;
12'd964 : mem_out_dec = 6'b111111;
12'd965 : mem_out_dec = 6'b111111;
12'd966 : mem_out_dec = 6'b111111;
12'd967 : mem_out_dec = 6'b111111;
12'd968 : mem_out_dec = 6'b111111;
12'd969 : mem_out_dec = 6'b111111;
12'd970 : mem_out_dec = 6'b111111;
12'd971 : mem_out_dec = 6'b111111;
12'd972 : mem_out_dec = 6'b111111;
12'd973 : mem_out_dec = 6'b111111;
12'd974 : mem_out_dec = 6'b111111;
12'd975 : mem_out_dec = 6'b111111;
12'd976 : mem_out_dec = 6'b111111;
12'd977 : mem_out_dec = 6'b111111;
12'd978 : mem_out_dec = 6'b111111;
12'd979 : mem_out_dec = 6'b111111;
12'd980 : mem_out_dec = 6'b111111;
12'd981 : mem_out_dec = 6'b000100;
12'd982 : mem_out_dec = 6'b000101;
12'd983 : mem_out_dec = 6'b000110;
12'd984 : mem_out_dec = 6'b000110;
12'd985 : mem_out_dec = 6'b000111;
12'd986 : mem_out_dec = 6'b000111;
12'd987 : mem_out_dec = 6'b001000;
12'd988 : mem_out_dec = 6'b001001;
12'd989 : mem_out_dec = 6'b001010;
12'd990 : mem_out_dec = 6'b001010;
12'd991 : mem_out_dec = 6'b001011;
12'd992 : mem_out_dec = 6'b001011;
12'd993 : mem_out_dec = 6'b001011;
12'd994 : mem_out_dec = 6'b001100;
12'd995 : mem_out_dec = 6'b001100;
12'd996 : mem_out_dec = 6'b001101;
12'd997 : mem_out_dec = 6'b001110;
12'd998 : mem_out_dec = 6'b001110;
12'd999 : mem_out_dec = 6'b001110;
12'd1000 : mem_out_dec = 6'b001101;
12'd1001 : mem_out_dec = 6'b001110;
12'd1002 : mem_out_dec = 6'b001110;
12'd1003 : mem_out_dec = 6'b001111;
12'd1004 : mem_out_dec = 6'b001111;
12'd1005 : mem_out_dec = 6'b010000;
12'd1006 : mem_out_dec = 6'b010000;
12'd1007 : mem_out_dec = 6'b010001;
12'd1008 : mem_out_dec = 6'b010001;
12'd1009 : mem_out_dec = 6'b010010;
12'd1010 : mem_out_dec = 6'b010011;
12'd1011 : mem_out_dec = 6'b010011;
12'd1012 : mem_out_dec = 6'b010100;
12'd1013 : mem_out_dec = 6'b010100;
12'd1014 : mem_out_dec = 6'b010101;
12'd1015 : mem_out_dec = 6'b010110;
12'd1016 : mem_out_dec = 6'b010110;
12'd1017 : mem_out_dec = 6'b010110;
12'd1018 : mem_out_dec = 6'b010111;
12'd1019 : mem_out_dec = 6'b011000;
12'd1020 : mem_out_dec = 6'b011001;
12'd1021 : mem_out_dec = 6'b011001;
12'd1022 : mem_out_dec = 6'b011010;
12'd1023 : mem_out_dec = 6'b011011;
12'd1024 : mem_out_dec = 6'b111111;
12'd1025 : mem_out_dec = 6'b111111;
12'd1026 : mem_out_dec = 6'b111111;
12'd1027 : mem_out_dec = 6'b111111;
12'd1028 : mem_out_dec = 6'b111111;
12'd1029 : mem_out_dec = 6'b111111;
12'd1030 : mem_out_dec = 6'b111111;
12'd1031 : mem_out_dec = 6'b111111;
12'd1032 : mem_out_dec = 6'b111111;
12'd1033 : mem_out_dec = 6'b111111;
12'd1034 : mem_out_dec = 6'b111111;
12'd1035 : mem_out_dec = 6'b111111;
12'd1036 : mem_out_dec = 6'b111111;
12'd1037 : mem_out_dec = 6'b111111;
12'd1038 : mem_out_dec = 6'b111111;
12'd1039 : mem_out_dec = 6'b111111;
12'd1040 : mem_out_dec = 6'b111111;
12'd1041 : mem_out_dec = 6'b111111;
12'd1042 : mem_out_dec = 6'b111111;
12'd1043 : mem_out_dec = 6'b111111;
12'd1044 : mem_out_dec = 6'b111111;
12'd1045 : mem_out_dec = 6'b111111;
12'd1046 : mem_out_dec = 6'b000100;
12'd1047 : mem_out_dec = 6'b000101;
12'd1048 : mem_out_dec = 6'b000101;
12'd1049 : mem_out_dec = 6'b000110;
12'd1050 : mem_out_dec = 6'b000110;
12'd1051 : mem_out_dec = 6'b000111;
12'd1052 : mem_out_dec = 6'b001000;
12'd1053 : mem_out_dec = 6'b001001;
12'd1054 : mem_out_dec = 6'b001001;
12'd1055 : mem_out_dec = 6'b001010;
12'd1056 : mem_out_dec = 6'b001010;
12'd1057 : mem_out_dec = 6'b001011;
12'd1058 : mem_out_dec = 6'b001011;
12'd1059 : mem_out_dec = 6'b001100;
12'd1060 : mem_out_dec = 6'b001100;
12'd1061 : mem_out_dec = 6'b001100;
12'd1062 : mem_out_dec = 6'b001100;
12'd1063 : mem_out_dec = 6'b001100;
12'd1064 : mem_out_dec = 6'b001100;
12'd1065 : mem_out_dec = 6'b001100;
12'd1066 : mem_out_dec = 6'b001101;
12'd1067 : mem_out_dec = 6'b001101;
12'd1068 : mem_out_dec = 6'b001110;
12'd1069 : mem_out_dec = 6'b001111;
12'd1070 : mem_out_dec = 6'b010000;
12'd1071 : mem_out_dec = 6'b010000;
12'd1072 : mem_out_dec = 6'b010001;
12'd1073 : mem_out_dec = 6'b010001;
12'd1074 : mem_out_dec = 6'b010010;
12'd1075 : mem_out_dec = 6'b010010;
12'd1076 : mem_out_dec = 6'b010011;
12'd1077 : mem_out_dec = 6'b010011;
12'd1078 : mem_out_dec = 6'b010100;
12'd1079 : mem_out_dec = 6'b010101;
12'd1080 : mem_out_dec = 6'b010101;
12'd1081 : mem_out_dec = 6'b010110;
12'd1082 : mem_out_dec = 6'b010110;
12'd1083 : mem_out_dec = 6'b010111;
12'd1084 : mem_out_dec = 6'b011000;
12'd1085 : mem_out_dec = 6'b011000;
12'd1086 : mem_out_dec = 6'b011001;
12'd1087 : mem_out_dec = 6'b011010;
12'd1088 : mem_out_dec = 6'b111111;
12'd1089 : mem_out_dec = 6'b111111;
12'd1090 : mem_out_dec = 6'b111111;
12'd1091 : mem_out_dec = 6'b111111;
12'd1092 : mem_out_dec = 6'b111111;
12'd1093 : mem_out_dec = 6'b111111;
12'd1094 : mem_out_dec = 6'b111111;
12'd1095 : mem_out_dec = 6'b111111;
12'd1096 : mem_out_dec = 6'b111111;
12'd1097 : mem_out_dec = 6'b111111;
12'd1098 : mem_out_dec = 6'b111111;
12'd1099 : mem_out_dec = 6'b111111;
12'd1100 : mem_out_dec = 6'b111111;
12'd1101 : mem_out_dec = 6'b111111;
12'd1102 : mem_out_dec = 6'b111111;
12'd1103 : mem_out_dec = 6'b111111;
12'd1104 : mem_out_dec = 6'b111111;
12'd1105 : mem_out_dec = 6'b111111;
12'd1106 : mem_out_dec = 6'b111111;
12'd1107 : mem_out_dec = 6'b111111;
12'd1108 : mem_out_dec = 6'b111111;
12'd1109 : mem_out_dec = 6'b111111;
12'd1110 : mem_out_dec = 6'b111111;
12'd1111 : mem_out_dec = 6'b000100;
12'd1112 : mem_out_dec = 6'b000100;
12'd1113 : mem_out_dec = 6'b000101;
12'd1114 : mem_out_dec = 6'b000110;
12'd1115 : mem_out_dec = 6'b000111;
12'd1116 : mem_out_dec = 6'b000111;
12'd1117 : mem_out_dec = 6'b001000;
12'd1118 : mem_out_dec = 6'b001001;
12'd1119 : mem_out_dec = 6'b001001;
12'd1120 : mem_out_dec = 6'b001010;
12'd1121 : mem_out_dec = 6'b001010;
12'd1122 : mem_out_dec = 6'b001011;
12'd1123 : mem_out_dec = 6'b001011;
12'd1124 : mem_out_dec = 6'b001011;
12'd1125 : mem_out_dec = 6'b001011;
12'd1126 : mem_out_dec = 6'b001011;
12'd1127 : mem_out_dec = 6'b001011;
12'd1128 : mem_out_dec = 6'b001011;
12'd1129 : mem_out_dec = 6'b001011;
12'd1130 : mem_out_dec = 6'b001100;
12'd1131 : mem_out_dec = 6'b001101;
12'd1132 : mem_out_dec = 6'b001110;
12'd1133 : mem_out_dec = 6'b001110;
12'd1134 : mem_out_dec = 6'b001111;
12'd1135 : mem_out_dec = 6'b010000;
12'd1136 : mem_out_dec = 6'b010000;
12'd1137 : mem_out_dec = 6'b010001;
12'd1138 : mem_out_dec = 6'b010001;
12'd1139 : mem_out_dec = 6'b010010;
12'd1140 : mem_out_dec = 6'b010010;
12'd1141 : mem_out_dec = 6'b010011;
12'd1142 : mem_out_dec = 6'b010100;
12'd1143 : mem_out_dec = 6'b010100;
12'd1144 : mem_out_dec = 6'b010100;
12'd1145 : mem_out_dec = 6'b010101;
12'd1146 : mem_out_dec = 6'b010110;
12'd1147 : mem_out_dec = 6'b010110;
12'd1148 : mem_out_dec = 6'b010111;
12'd1149 : mem_out_dec = 6'b011000;
12'd1150 : mem_out_dec = 6'b011000;
12'd1151 : mem_out_dec = 6'b011001;
12'd1152 : mem_out_dec = 6'b111111;
12'd1153 : mem_out_dec = 6'b111111;
12'd1154 : mem_out_dec = 6'b111111;
12'd1155 : mem_out_dec = 6'b111111;
12'd1156 : mem_out_dec = 6'b111111;
12'd1157 : mem_out_dec = 6'b111111;
12'd1158 : mem_out_dec = 6'b111111;
12'd1159 : mem_out_dec = 6'b111111;
12'd1160 : mem_out_dec = 6'b111111;
12'd1161 : mem_out_dec = 6'b111111;
12'd1162 : mem_out_dec = 6'b111111;
12'd1163 : mem_out_dec = 6'b111111;
12'd1164 : mem_out_dec = 6'b111111;
12'd1165 : mem_out_dec = 6'b111111;
12'd1166 : mem_out_dec = 6'b111111;
12'd1167 : mem_out_dec = 6'b111111;
12'd1168 : mem_out_dec = 6'b111111;
12'd1169 : mem_out_dec = 6'b111111;
12'd1170 : mem_out_dec = 6'b111111;
12'd1171 : mem_out_dec = 6'b111111;
12'd1172 : mem_out_dec = 6'b111111;
12'd1173 : mem_out_dec = 6'b111111;
12'd1174 : mem_out_dec = 6'b111111;
12'd1175 : mem_out_dec = 6'b111111;
12'd1176 : mem_out_dec = 6'b000100;
12'd1177 : mem_out_dec = 6'b000101;
12'd1178 : mem_out_dec = 6'b000101;
12'd1179 : mem_out_dec = 6'b000110;
12'd1180 : mem_out_dec = 6'b000111;
12'd1181 : mem_out_dec = 6'b000111;
12'd1182 : mem_out_dec = 6'b001000;
12'd1183 : mem_out_dec = 6'b001001;
12'd1184 : mem_out_dec = 6'b001001;
12'd1185 : mem_out_dec = 6'b001010;
12'd1186 : mem_out_dec = 6'b001010;
12'd1187 : mem_out_dec = 6'b001010;
12'd1188 : mem_out_dec = 6'b001010;
12'd1189 : mem_out_dec = 6'b001010;
12'd1190 : mem_out_dec = 6'b001010;
12'd1191 : mem_out_dec = 6'b001010;
12'd1192 : mem_out_dec = 6'b001010;
12'd1193 : mem_out_dec = 6'b001011;
12'd1194 : mem_out_dec = 6'b001100;
12'd1195 : mem_out_dec = 6'b001100;
12'd1196 : mem_out_dec = 6'b001101;
12'd1197 : mem_out_dec = 6'b001110;
12'd1198 : mem_out_dec = 6'b001111;
12'd1199 : mem_out_dec = 6'b010000;
12'd1200 : mem_out_dec = 6'b010000;
12'd1201 : mem_out_dec = 6'b010000;
12'd1202 : mem_out_dec = 6'b010001;
12'd1203 : mem_out_dec = 6'b010001;
12'd1204 : mem_out_dec = 6'b010010;
12'd1205 : mem_out_dec = 6'b010011;
12'd1206 : mem_out_dec = 6'b010011;
12'd1207 : mem_out_dec = 6'b010100;
12'd1208 : mem_out_dec = 6'b010100;
12'd1209 : mem_out_dec = 6'b010100;
12'd1210 : mem_out_dec = 6'b010101;
12'd1211 : mem_out_dec = 6'b010110;
12'd1212 : mem_out_dec = 6'b010110;
12'd1213 : mem_out_dec = 6'b010111;
12'd1214 : mem_out_dec = 6'b011000;
12'd1215 : mem_out_dec = 6'b011001;
12'd1216 : mem_out_dec = 6'b111111;
12'd1217 : mem_out_dec = 6'b111111;
12'd1218 : mem_out_dec = 6'b111111;
12'd1219 : mem_out_dec = 6'b111111;
12'd1220 : mem_out_dec = 6'b111111;
12'd1221 : mem_out_dec = 6'b111111;
12'd1222 : mem_out_dec = 6'b111111;
12'd1223 : mem_out_dec = 6'b111111;
12'd1224 : mem_out_dec = 6'b111111;
12'd1225 : mem_out_dec = 6'b111111;
12'd1226 : mem_out_dec = 6'b111111;
12'd1227 : mem_out_dec = 6'b111111;
12'd1228 : mem_out_dec = 6'b111111;
12'd1229 : mem_out_dec = 6'b111111;
12'd1230 : mem_out_dec = 6'b111111;
12'd1231 : mem_out_dec = 6'b111111;
12'd1232 : mem_out_dec = 6'b111111;
12'd1233 : mem_out_dec = 6'b111111;
12'd1234 : mem_out_dec = 6'b111111;
12'd1235 : mem_out_dec = 6'b111111;
12'd1236 : mem_out_dec = 6'b111111;
12'd1237 : mem_out_dec = 6'b111111;
12'd1238 : mem_out_dec = 6'b111111;
12'd1239 : mem_out_dec = 6'b111111;
12'd1240 : mem_out_dec = 6'b111111;
12'd1241 : mem_out_dec = 6'b000100;
12'd1242 : mem_out_dec = 6'b000100;
12'd1243 : mem_out_dec = 6'b000101;
12'd1244 : mem_out_dec = 6'b000110;
12'd1245 : mem_out_dec = 6'b000111;
12'd1246 : mem_out_dec = 6'b001000;
12'd1247 : mem_out_dec = 6'b001000;
12'd1248 : mem_out_dec = 6'b001001;
12'd1249 : mem_out_dec = 6'b001001;
12'd1250 : mem_out_dec = 6'b001001;
12'd1251 : mem_out_dec = 6'b001001;
12'd1252 : mem_out_dec = 6'b001001;
12'd1253 : mem_out_dec = 6'b001001;
12'd1254 : mem_out_dec = 6'b001001;
12'd1255 : mem_out_dec = 6'b001001;
12'd1256 : mem_out_dec = 6'b001010;
12'd1257 : mem_out_dec = 6'b001010;
12'd1258 : mem_out_dec = 6'b001011;
12'd1259 : mem_out_dec = 6'b001100;
12'd1260 : mem_out_dec = 6'b001101;
12'd1261 : mem_out_dec = 6'b001110;
12'd1262 : mem_out_dec = 6'b001110;
12'd1263 : mem_out_dec = 6'b001111;
12'd1264 : mem_out_dec = 6'b001111;
12'd1265 : mem_out_dec = 6'b010000;
12'd1266 : mem_out_dec = 6'b010000;
12'd1267 : mem_out_dec = 6'b010001;
12'd1268 : mem_out_dec = 6'b010001;
12'd1269 : mem_out_dec = 6'b010010;
12'd1270 : mem_out_dec = 6'b010011;
12'd1271 : mem_out_dec = 6'b010011;
12'd1272 : mem_out_dec = 6'b010011;
12'd1273 : mem_out_dec = 6'b010100;
12'd1274 : mem_out_dec = 6'b010100;
12'd1275 : mem_out_dec = 6'b010101;
12'd1276 : mem_out_dec = 6'b010110;
12'd1277 : mem_out_dec = 6'b010111;
12'd1278 : mem_out_dec = 6'b011000;
12'd1279 : mem_out_dec = 6'b011000;
12'd1280 : mem_out_dec = 6'b111111;
12'd1281 : mem_out_dec = 6'b111111;
12'd1282 : mem_out_dec = 6'b111111;
12'd1283 : mem_out_dec = 6'b111111;
12'd1284 : mem_out_dec = 6'b111111;
12'd1285 : mem_out_dec = 6'b111111;
12'd1286 : mem_out_dec = 6'b111111;
12'd1287 : mem_out_dec = 6'b111111;
12'd1288 : mem_out_dec = 6'b111111;
12'd1289 : mem_out_dec = 6'b111111;
12'd1290 : mem_out_dec = 6'b111111;
12'd1291 : mem_out_dec = 6'b111111;
12'd1292 : mem_out_dec = 6'b111111;
12'd1293 : mem_out_dec = 6'b111111;
12'd1294 : mem_out_dec = 6'b111111;
12'd1295 : mem_out_dec = 6'b111111;
12'd1296 : mem_out_dec = 6'b111111;
12'd1297 : mem_out_dec = 6'b111111;
12'd1298 : mem_out_dec = 6'b111111;
12'd1299 : mem_out_dec = 6'b111111;
12'd1300 : mem_out_dec = 6'b111111;
12'd1301 : mem_out_dec = 6'b111111;
12'd1302 : mem_out_dec = 6'b111111;
12'd1303 : mem_out_dec = 6'b111111;
12'd1304 : mem_out_dec = 6'b111111;
12'd1305 : mem_out_dec = 6'b111111;
12'd1306 : mem_out_dec = 6'b000100;
12'd1307 : mem_out_dec = 6'b000101;
12'd1308 : mem_out_dec = 6'b000110;
12'd1309 : mem_out_dec = 6'b000110;
12'd1310 : mem_out_dec = 6'b000111;
12'd1311 : mem_out_dec = 6'b001000;
12'd1312 : mem_out_dec = 6'b001000;
12'd1313 : mem_out_dec = 6'b001000;
12'd1314 : mem_out_dec = 6'b001000;
12'd1315 : mem_out_dec = 6'b001000;
12'd1316 : mem_out_dec = 6'b001000;
12'd1317 : mem_out_dec = 6'b001000;
12'd1318 : mem_out_dec = 6'b001000;
12'd1319 : mem_out_dec = 6'b001001;
12'd1320 : mem_out_dec = 6'b001001;
12'd1321 : mem_out_dec = 6'b001010;
12'd1322 : mem_out_dec = 6'b001011;
12'd1323 : mem_out_dec = 6'b001100;
12'd1324 : mem_out_dec = 6'b001100;
12'd1325 : mem_out_dec = 6'b001101;
12'd1326 : mem_out_dec = 6'b001110;
12'd1327 : mem_out_dec = 6'b001111;
12'd1328 : mem_out_dec = 6'b001111;
12'd1329 : mem_out_dec = 6'b001111;
12'd1330 : mem_out_dec = 6'b010000;
12'd1331 : mem_out_dec = 6'b010000;
12'd1332 : mem_out_dec = 6'b010001;
12'd1333 : mem_out_dec = 6'b010001;
12'd1334 : mem_out_dec = 6'b010010;
12'd1335 : mem_out_dec = 6'b010011;
12'd1336 : mem_out_dec = 6'b010010;
12'd1337 : mem_out_dec = 6'b010011;
12'd1338 : mem_out_dec = 6'b010100;
12'd1339 : mem_out_dec = 6'b010101;
12'd1340 : mem_out_dec = 6'b010110;
12'd1341 : mem_out_dec = 6'b010110;
12'd1342 : mem_out_dec = 6'b010111;
12'd1343 : mem_out_dec = 6'b011000;
12'd1344 : mem_out_dec = 6'b111111;
12'd1345 : mem_out_dec = 6'b111111;
12'd1346 : mem_out_dec = 6'b111111;
12'd1347 : mem_out_dec = 6'b111111;
12'd1348 : mem_out_dec = 6'b111111;
12'd1349 : mem_out_dec = 6'b111111;
12'd1350 : mem_out_dec = 6'b111111;
12'd1351 : mem_out_dec = 6'b111111;
12'd1352 : mem_out_dec = 6'b111111;
12'd1353 : mem_out_dec = 6'b111111;
12'd1354 : mem_out_dec = 6'b111111;
12'd1355 : mem_out_dec = 6'b111111;
12'd1356 : mem_out_dec = 6'b111111;
12'd1357 : mem_out_dec = 6'b111111;
12'd1358 : mem_out_dec = 6'b111111;
12'd1359 : mem_out_dec = 6'b111111;
12'd1360 : mem_out_dec = 6'b111111;
12'd1361 : mem_out_dec = 6'b111111;
12'd1362 : mem_out_dec = 6'b111111;
12'd1363 : mem_out_dec = 6'b111111;
12'd1364 : mem_out_dec = 6'b111111;
12'd1365 : mem_out_dec = 6'b111111;
12'd1366 : mem_out_dec = 6'b111111;
12'd1367 : mem_out_dec = 6'b111111;
12'd1368 : mem_out_dec = 6'b111111;
12'd1369 : mem_out_dec = 6'b111111;
12'd1370 : mem_out_dec = 6'b111111;
12'd1371 : mem_out_dec = 6'b000101;
12'd1372 : mem_out_dec = 6'b000101;
12'd1373 : mem_out_dec = 6'b000110;
12'd1374 : mem_out_dec = 6'b000111;
12'd1375 : mem_out_dec = 6'b001000;
12'd1376 : mem_out_dec = 6'b000111;
12'd1377 : mem_out_dec = 6'b000111;
12'd1378 : mem_out_dec = 6'b000111;
12'd1379 : mem_out_dec = 6'b000111;
12'd1380 : mem_out_dec = 6'b000111;
12'd1381 : mem_out_dec = 6'b000111;
12'd1382 : mem_out_dec = 6'b001000;
12'd1383 : mem_out_dec = 6'b001001;
12'd1384 : mem_out_dec = 6'b001001;
12'd1385 : mem_out_dec = 6'b001010;
12'd1386 : mem_out_dec = 6'b001010;
12'd1387 : mem_out_dec = 6'b001011;
12'd1388 : mem_out_dec = 6'b001100;
12'd1389 : mem_out_dec = 6'b001101;
12'd1390 : mem_out_dec = 6'b001110;
12'd1391 : mem_out_dec = 6'b001110;
12'd1392 : mem_out_dec = 6'b001111;
12'd1393 : mem_out_dec = 6'b001111;
12'd1394 : mem_out_dec = 6'b010000;
12'd1395 : mem_out_dec = 6'b010000;
12'd1396 : mem_out_dec = 6'b010001;
12'd1397 : mem_out_dec = 6'b010001;
12'd1398 : mem_out_dec = 6'b010010;
12'd1399 : mem_out_dec = 6'b010010;
12'd1400 : mem_out_dec = 6'b010010;
12'd1401 : mem_out_dec = 6'b010011;
12'd1402 : mem_out_dec = 6'b010100;
12'd1403 : mem_out_dec = 6'b010100;
12'd1404 : mem_out_dec = 6'b010101;
12'd1405 : mem_out_dec = 6'b010110;
12'd1406 : mem_out_dec = 6'b010111;
12'd1407 : mem_out_dec = 6'b010111;
12'd1408 : mem_out_dec = 6'b111111;
12'd1409 : mem_out_dec = 6'b111111;
12'd1410 : mem_out_dec = 6'b111111;
12'd1411 : mem_out_dec = 6'b111111;
12'd1412 : mem_out_dec = 6'b111111;
12'd1413 : mem_out_dec = 6'b111111;
12'd1414 : mem_out_dec = 6'b111111;
12'd1415 : mem_out_dec = 6'b111111;
12'd1416 : mem_out_dec = 6'b111111;
12'd1417 : mem_out_dec = 6'b111111;
12'd1418 : mem_out_dec = 6'b111111;
12'd1419 : mem_out_dec = 6'b111111;
12'd1420 : mem_out_dec = 6'b111111;
12'd1421 : mem_out_dec = 6'b111111;
12'd1422 : mem_out_dec = 6'b111111;
12'd1423 : mem_out_dec = 6'b111111;
12'd1424 : mem_out_dec = 6'b111111;
12'd1425 : mem_out_dec = 6'b111111;
12'd1426 : mem_out_dec = 6'b111111;
12'd1427 : mem_out_dec = 6'b111111;
12'd1428 : mem_out_dec = 6'b111111;
12'd1429 : mem_out_dec = 6'b111111;
12'd1430 : mem_out_dec = 6'b111111;
12'd1431 : mem_out_dec = 6'b111111;
12'd1432 : mem_out_dec = 6'b111111;
12'd1433 : mem_out_dec = 6'b111111;
12'd1434 : mem_out_dec = 6'b111111;
12'd1435 : mem_out_dec = 6'b111111;
12'd1436 : mem_out_dec = 6'b000101;
12'd1437 : mem_out_dec = 6'b000110;
12'd1438 : mem_out_dec = 6'b000111;
12'd1439 : mem_out_dec = 6'b000111;
12'd1440 : mem_out_dec = 6'b000110;
12'd1441 : mem_out_dec = 6'b000110;
12'd1442 : mem_out_dec = 6'b000110;
12'd1443 : mem_out_dec = 6'b000110;
12'd1444 : mem_out_dec = 6'b000110;
12'd1445 : mem_out_dec = 6'b000111;
12'd1446 : mem_out_dec = 6'b000111;
12'd1447 : mem_out_dec = 6'b001000;
12'd1448 : mem_out_dec = 6'b001001;
12'd1449 : mem_out_dec = 6'b001001;
12'd1450 : mem_out_dec = 6'b001010;
12'd1451 : mem_out_dec = 6'b001011;
12'd1452 : mem_out_dec = 6'b001100;
12'd1453 : mem_out_dec = 6'b001100;
12'd1454 : mem_out_dec = 6'b001101;
12'd1455 : mem_out_dec = 6'b001110;
12'd1456 : mem_out_dec = 6'b001110;
12'd1457 : mem_out_dec = 6'b001111;
12'd1458 : mem_out_dec = 6'b001111;
12'd1459 : mem_out_dec = 6'b010000;
12'd1460 : mem_out_dec = 6'b010000;
12'd1461 : mem_out_dec = 6'b010001;
12'd1462 : mem_out_dec = 6'b010001;
12'd1463 : mem_out_dec = 6'b010010;
12'd1464 : mem_out_dec = 6'b010010;
12'd1465 : mem_out_dec = 6'b010011;
12'd1466 : mem_out_dec = 6'b010011;
12'd1467 : mem_out_dec = 6'b010100;
12'd1468 : mem_out_dec = 6'b010101;
12'd1469 : mem_out_dec = 6'b010110;
12'd1470 : mem_out_dec = 6'b010110;
12'd1471 : mem_out_dec = 6'b010111;
12'd1472 : mem_out_dec = 6'b111111;
12'd1473 : mem_out_dec = 6'b111111;
12'd1474 : mem_out_dec = 6'b111111;
12'd1475 : mem_out_dec = 6'b111111;
12'd1476 : mem_out_dec = 6'b111111;
12'd1477 : mem_out_dec = 6'b111111;
12'd1478 : mem_out_dec = 6'b111111;
12'd1479 : mem_out_dec = 6'b111111;
12'd1480 : mem_out_dec = 6'b111111;
12'd1481 : mem_out_dec = 6'b111111;
12'd1482 : mem_out_dec = 6'b111111;
12'd1483 : mem_out_dec = 6'b111111;
12'd1484 : mem_out_dec = 6'b111111;
12'd1485 : mem_out_dec = 6'b111111;
12'd1486 : mem_out_dec = 6'b111111;
12'd1487 : mem_out_dec = 6'b111111;
12'd1488 : mem_out_dec = 6'b111111;
12'd1489 : mem_out_dec = 6'b111111;
12'd1490 : mem_out_dec = 6'b111111;
12'd1491 : mem_out_dec = 6'b111111;
12'd1492 : mem_out_dec = 6'b111111;
12'd1493 : mem_out_dec = 6'b111111;
12'd1494 : mem_out_dec = 6'b111111;
12'd1495 : mem_out_dec = 6'b111111;
12'd1496 : mem_out_dec = 6'b111111;
12'd1497 : mem_out_dec = 6'b111111;
12'd1498 : mem_out_dec = 6'b111111;
12'd1499 : mem_out_dec = 6'b111111;
12'd1500 : mem_out_dec = 6'b111111;
12'd1501 : mem_out_dec = 6'b000101;
12'd1502 : mem_out_dec = 6'b000110;
12'd1503 : mem_out_dec = 6'b000110;
12'd1504 : mem_out_dec = 6'b000110;
12'd1505 : mem_out_dec = 6'b000110;
12'd1506 : mem_out_dec = 6'b000101;
12'd1507 : mem_out_dec = 6'b000101;
12'd1508 : mem_out_dec = 6'b000110;
12'd1509 : mem_out_dec = 6'b000111;
12'd1510 : mem_out_dec = 6'b000111;
12'd1511 : mem_out_dec = 6'b001000;
12'd1512 : mem_out_dec = 6'b001000;
12'd1513 : mem_out_dec = 6'b001001;
12'd1514 : mem_out_dec = 6'b001010;
12'd1515 : mem_out_dec = 6'b001011;
12'd1516 : mem_out_dec = 6'b001011;
12'd1517 : mem_out_dec = 6'b001100;
12'd1518 : mem_out_dec = 6'b001101;
12'd1519 : mem_out_dec = 6'b001110;
12'd1520 : mem_out_dec = 6'b001110;
12'd1521 : mem_out_dec = 6'b001110;
12'd1522 : mem_out_dec = 6'b001111;
12'd1523 : mem_out_dec = 6'b001111;
12'd1524 : mem_out_dec = 6'b010000;
12'd1525 : mem_out_dec = 6'b010000;
12'd1526 : mem_out_dec = 6'b010001;
12'd1527 : mem_out_dec = 6'b010001;
12'd1528 : mem_out_dec = 6'b010001;
12'd1529 : mem_out_dec = 6'b010010;
12'd1530 : mem_out_dec = 6'b010011;
12'd1531 : mem_out_dec = 6'b010100;
12'd1532 : mem_out_dec = 6'b010101;
12'd1533 : mem_out_dec = 6'b010101;
12'd1534 : mem_out_dec = 6'b010110;
12'd1535 : mem_out_dec = 6'b010110;
12'd1536 : mem_out_dec = 6'b111111;
12'd1537 : mem_out_dec = 6'b111111;
12'd1538 : mem_out_dec = 6'b111111;
12'd1539 : mem_out_dec = 6'b111111;
12'd1540 : mem_out_dec = 6'b111111;
12'd1541 : mem_out_dec = 6'b111111;
12'd1542 : mem_out_dec = 6'b111111;
12'd1543 : mem_out_dec = 6'b111111;
12'd1544 : mem_out_dec = 6'b111111;
12'd1545 : mem_out_dec = 6'b111111;
12'd1546 : mem_out_dec = 6'b111111;
12'd1547 : mem_out_dec = 6'b111111;
12'd1548 : mem_out_dec = 6'b111111;
12'd1549 : mem_out_dec = 6'b111111;
12'd1550 : mem_out_dec = 6'b111111;
12'd1551 : mem_out_dec = 6'b111111;
12'd1552 : mem_out_dec = 6'b111111;
12'd1553 : mem_out_dec = 6'b111111;
12'd1554 : mem_out_dec = 6'b111111;
12'd1555 : mem_out_dec = 6'b111111;
12'd1556 : mem_out_dec = 6'b111111;
12'd1557 : mem_out_dec = 6'b111111;
12'd1558 : mem_out_dec = 6'b111111;
12'd1559 : mem_out_dec = 6'b111111;
12'd1560 : mem_out_dec = 6'b111111;
12'd1561 : mem_out_dec = 6'b111111;
12'd1562 : mem_out_dec = 6'b111111;
12'd1563 : mem_out_dec = 6'b111111;
12'd1564 : mem_out_dec = 6'b111111;
12'd1565 : mem_out_dec = 6'b111111;
12'd1566 : mem_out_dec = 6'b000100;
12'd1567 : mem_out_dec = 6'b000100;
12'd1568 : mem_out_dec = 6'b000100;
12'd1569 : mem_out_dec = 6'b000100;
12'd1570 : mem_out_dec = 6'b000100;
12'd1571 : mem_out_dec = 6'b000101;
12'd1572 : mem_out_dec = 6'b000101;
12'd1573 : mem_out_dec = 6'b000110;
12'd1574 : mem_out_dec = 6'b000111;
12'd1575 : mem_out_dec = 6'b000111;
12'd1576 : mem_out_dec = 6'b000111;
12'd1577 : mem_out_dec = 6'b001000;
12'd1578 : mem_out_dec = 6'b001001;
12'd1579 : mem_out_dec = 6'b001010;
12'd1580 : mem_out_dec = 6'b001010;
12'd1581 : mem_out_dec = 6'b001011;
12'd1582 : mem_out_dec = 6'b001100;
12'd1583 : mem_out_dec = 6'b001101;
12'd1584 : mem_out_dec = 6'b001101;
12'd1585 : mem_out_dec = 6'b001101;
12'd1586 : mem_out_dec = 6'b001110;
12'd1587 : mem_out_dec = 6'b001110;
12'd1588 : mem_out_dec = 6'b001111;
12'd1589 : mem_out_dec = 6'b001111;
12'd1590 : mem_out_dec = 6'b010000;
12'd1591 : mem_out_dec = 6'b010001;
12'd1592 : mem_out_dec = 6'b010001;
12'd1593 : mem_out_dec = 6'b010001;
12'd1594 : mem_out_dec = 6'b010010;
12'd1595 : mem_out_dec = 6'b010010;
12'd1596 : mem_out_dec = 6'b010011;
12'd1597 : mem_out_dec = 6'b010011;
12'd1598 : mem_out_dec = 6'b010100;
12'd1599 : mem_out_dec = 6'b010100;
12'd1600 : mem_out_dec = 6'b111111;
12'd1601 : mem_out_dec = 6'b111111;
12'd1602 : mem_out_dec = 6'b111111;
12'd1603 : mem_out_dec = 6'b111111;
12'd1604 : mem_out_dec = 6'b111111;
12'd1605 : mem_out_dec = 6'b111111;
12'd1606 : mem_out_dec = 6'b111111;
12'd1607 : mem_out_dec = 6'b111111;
12'd1608 : mem_out_dec = 6'b111111;
12'd1609 : mem_out_dec = 6'b111111;
12'd1610 : mem_out_dec = 6'b111111;
12'd1611 : mem_out_dec = 6'b111111;
12'd1612 : mem_out_dec = 6'b111111;
12'd1613 : mem_out_dec = 6'b111111;
12'd1614 : mem_out_dec = 6'b111111;
12'd1615 : mem_out_dec = 6'b111111;
12'd1616 : mem_out_dec = 6'b111111;
12'd1617 : mem_out_dec = 6'b111111;
12'd1618 : mem_out_dec = 6'b111111;
12'd1619 : mem_out_dec = 6'b111111;
12'd1620 : mem_out_dec = 6'b111111;
12'd1621 : mem_out_dec = 6'b111111;
12'd1622 : mem_out_dec = 6'b111111;
12'd1623 : mem_out_dec = 6'b111111;
12'd1624 : mem_out_dec = 6'b111111;
12'd1625 : mem_out_dec = 6'b111111;
12'd1626 : mem_out_dec = 6'b111111;
12'd1627 : mem_out_dec = 6'b111111;
12'd1628 : mem_out_dec = 6'b111111;
12'd1629 : mem_out_dec = 6'b111111;
12'd1630 : mem_out_dec = 6'b111111;
12'd1631 : mem_out_dec = 6'b000100;
12'd1632 : mem_out_dec = 6'b000011;
12'd1633 : mem_out_dec = 6'b000011;
12'd1634 : mem_out_dec = 6'b000100;
12'd1635 : mem_out_dec = 6'b000100;
12'd1636 : mem_out_dec = 6'b000101;
12'd1637 : mem_out_dec = 6'b000110;
12'd1638 : mem_out_dec = 6'b000110;
12'd1639 : mem_out_dec = 6'b000111;
12'd1640 : mem_out_dec = 6'b000111;
12'd1641 : mem_out_dec = 6'b001000;
12'd1642 : mem_out_dec = 6'b001001;
12'd1643 : mem_out_dec = 6'b001001;
12'd1644 : mem_out_dec = 6'b001010;
12'd1645 : mem_out_dec = 6'b001011;
12'd1646 : mem_out_dec = 6'b001100;
12'd1647 : mem_out_dec = 6'b001101;
12'd1648 : mem_out_dec = 6'b001101;
12'd1649 : mem_out_dec = 6'b001101;
12'd1650 : mem_out_dec = 6'b001110;
12'd1651 : mem_out_dec = 6'b001110;
12'd1652 : mem_out_dec = 6'b001110;
12'd1653 : mem_out_dec = 6'b001111;
12'd1654 : mem_out_dec = 6'b010000;
12'd1655 : mem_out_dec = 6'b010000;
12'd1656 : mem_out_dec = 6'b010001;
12'd1657 : mem_out_dec = 6'b010001;
12'd1658 : mem_out_dec = 6'b010001;
12'd1659 : mem_out_dec = 6'b010010;
12'd1660 : mem_out_dec = 6'b010010;
12'd1661 : mem_out_dec = 6'b010011;
12'd1662 : mem_out_dec = 6'b010011;
12'd1663 : mem_out_dec = 6'b010100;
12'd1664 : mem_out_dec = 6'b111111;
12'd1665 : mem_out_dec = 6'b111111;
12'd1666 : mem_out_dec = 6'b111111;
12'd1667 : mem_out_dec = 6'b111111;
12'd1668 : mem_out_dec = 6'b111111;
12'd1669 : mem_out_dec = 6'b111111;
12'd1670 : mem_out_dec = 6'b111111;
12'd1671 : mem_out_dec = 6'b111111;
12'd1672 : mem_out_dec = 6'b111111;
12'd1673 : mem_out_dec = 6'b111111;
12'd1674 : mem_out_dec = 6'b111111;
12'd1675 : mem_out_dec = 6'b111111;
12'd1676 : mem_out_dec = 6'b111111;
12'd1677 : mem_out_dec = 6'b111111;
12'd1678 : mem_out_dec = 6'b111111;
12'd1679 : mem_out_dec = 6'b111111;
12'd1680 : mem_out_dec = 6'b111111;
12'd1681 : mem_out_dec = 6'b111111;
12'd1682 : mem_out_dec = 6'b111111;
12'd1683 : mem_out_dec = 6'b111111;
12'd1684 : mem_out_dec = 6'b111111;
12'd1685 : mem_out_dec = 6'b111111;
12'd1686 : mem_out_dec = 6'b111111;
12'd1687 : mem_out_dec = 6'b111111;
12'd1688 : mem_out_dec = 6'b111111;
12'd1689 : mem_out_dec = 6'b111111;
12'd1690 : mem_out_dec = 6'b111111;
12'd1691 : mem_out_dec = 6'b111111;
12'd1692 : mem_out_dec = 6'b111111;
12'd1693 : mem_out_dec = 6'b111111;
12'd1694 : mem_out_dec = 6'b111111;
12'd1695 : mem_out_dec = 6'b111111;
12'd1696 : mem_out_dec = 6'b000011;
12'd1697 : mem_out_dec = 6'b000011;
12'd1698 : mem_out_dec = 6'b000100;
12'd1699 : mem_out_dec = 6'b000100;
12'd1700 : mem_out_dec = 6'b000101;
12'd1701 : mem_out_dec = 6'b000101;
12'd1702 : mem_out_dec = 6'b000110;
12'd1703 : mem_out_dec = 6'b000111;
12'd1704 : mem_out_dec = 6'b000111;
12'd1705 : mem_out_dec = 6'b001000;
12'd1706 : mem_out_dec = 6'b001000;
12'd1707 : mem_out_dec = 6'b001001;
12'd1708 : mem_out_dec = 6'b001010;
12'd1709 : mem_out_dec = 6'b001011;
12'd1710 : mem_out_dec = 6'b001100;
12'd1711 : mem_out_dec = 6'b001100;
12'd1712 : mem_out_dec = 6'b001100;
12'd1713 : mem_out_dec = 6'b001101;
12'd1714 : mem_out_dec = 6'b001101;
12'd1715 : mem_out_dec = 6'b001110;
12'd1716 : mem_out_dec = 6'b001110;
12'd1717 : mem_out_dec = 6'b001111;
12'd1718 : mem_out_dec = 6'b001111;
12'd1719 : mem_out_dec = 6'b010000;
12'd1720 : mem_out_dec = 6'b010000;
12'd1721 : mem_out_dec = 6'b010000;
12'd1722 : mem_out_dec = 6'b010001;
12'd1723 : mem_out_dec = 6'b010001;
12'd1724 : mem_out_dec = 6'b010010;
12'd1725 : mem_out_dec = 6'b010010;
12'd1726 : mem_out_dec = 6'b010011;
12'd1727 : mem_out_dec = 6'b010011;
12'd1728 : mem_out_dec = 6'b111111;
12'd1729 : mem_out_dec = 6'b111111;
12'd1730 : mem_out_dec = 6'b111111;
12'd1731 : mem_out_dec = 6'b111111;
12'd1732 : mem_out_dec = 6'b111111;
12'd1733 : mem_out_dec = 6'b111111;
12'd1734 : mem_out_dec = 6'b111111;
12'd1735 : mem_out_dec = 6'b111111;
12'd1736 : mem_out_dec = 6'b111111;
12'd1737 : mem_out_dec = 6'b111111;
12'd1738 : mem_out_dec = 6'b111111;
12'd1739 : mem_out_dec = 6'b111111;
12'd1740 : mem_out_dec = 6'b111111;
12'd1741 : mem_out_dec = 6'b111111;
12'd1742 : mem_out_dec = 6'b111111;
12'd1743 : mem_out_dec = 6'b111111;
12'd1744 : mem_out_dec = 6'b111111;
12'd1745 : mem_out_dec = 6'b111111;
12'd1746 : mem_out_dec = 6'b111111;
12'd1747 : mem_out_dec = 6'b111111;
12'd1748 : mem_out_dec = 6'b111111;
12'd1749 : mem_out_dec = 6'b111111;
12'd1750 : mem_out_dec = 6'b111111;
12'd1751 : mem_out_dec = 6'b111111;
12'd1752 : mem_out_dec = 6'b111111;
12'd1753 : mem_out_dec = 6'b111111;
12'd1754 : mem_out_dec = 6'b111111;
12'd1755 : mem_out_dec = 6'b111111;
12'd1756 : mem_out_dec = 6'b111111;
12'd1757 : mem_out_dec = 6'b111111;
12'd1758 : mem_out_dec = 6'b111111;
12'd1759 : mem_out_dec = 6'b111111;
12'd1760 : mem_out_dec = 6'b111111;
12'd1761 : mem_out_dec = 6'b000011;
12'd1762 : mem_out_dec = 6'b000011;
12'd1763 : mem_out_dec = 6'b000100;
12'd1764 : mem_out_dec = 6'b000101;
12'd1765 : mem_out_dec = 6'b000101;
12'd1766 : mem_out_dec = 6'b000110;
12'd1767 : mem_out_dec = 6'b000111;
12'd1768 : mem_out_dec = 6'b000111;
12'd1769 : mem_out_dec = 6'b000111;
12'd1770 : mem_out_dec = 6'b001000;
12'd1771 : mem_out_dec = 6'b001001;
12'd1772 : mem_out_dec = 6'b001010;
12'd1773 : mem_out_dec = 6'b001011;
12'd1774 : mem_out_dec = 6'b001011;
12'd1775 : mem_out_dec = 6'b001100;
12'd1776 : mem_out_dec = 6'b001100;
12'd1777 : mem_out_dec = 6'b001101;
12'd1778 : mem_out_dec = 6'b001101;
12'd1779 : mem_out_dec = 6'b001101;
12'd1780 : mem_out_dec = 6'b001110;
12'd1781 : mem_out_dec = 6'b001111;
12'd1782 : mem_out_dec = 6'b001111;
12'd1783 : mem_out_dec = 6'b010000;
12'd1784 : mem_out_dec = 6'b010000;
12'd1785 : mem_out_dec = 6'b010000;
12'd1786 : mem_out_dec = 6'b010000;
12'd1787 : mem_out_dec = 6'b010001;
12'd1788 : mem_out_dec = 6'b010001;
12'd1789 : mem_out_dec = 6'b010010;
12'd1790 : mem_out_dec = 6'b010010;
12'd1791 : mem_out_dec = 6'b010011;
12'd1792 : mem_out_dec = 6'b111111;
12'd1793 : mem_out_dec = 6'b111111;
12'd1794 : mem_out_dec = 6'b111111;
12'd1795 : mem_out_dec = 6'b111111;
12'd1796 : mem_out_dec = 6'b111111;
12'd1797 : mem_out_dec = 6'b111111;
12'd1798 : mem_out_dec = 6'b111111;
12'd1799 : mem_out_dec = 6'b111111;
12'd1800 : mem_out_dec = 6'b111111;
12'd1801 : mem_out_dec = 6'b111111;
12'd1802 : mem_out_dec = 6'b111111;
12'd1803 : mem_out_dec = 6'b111111;
12'd1804 : mem_out_dec = 6'b111111;
12'd1805 : mem_out_dec = 6'b111111;
12'd1806 : mem_out_dec = 6'b111111;
12'd1807 : mem_out_dec = 6'b111111;
12'd1808 : mem_out_dec = 6'b111111;
12'd1809 : mem_out_dec = 6'b111111;
12'd1810 : mem_out_dec = 6'b111111;
12'd1811 : mem_out_dec = 6'b111111;
12'd1812 : mem_out_dec = 6'b111111;
12'd1813 : mem_out_dec = 6'b111111;
12'd1814 : mem_out_dec = 6'b111111;
12'd1815 : mem_out_dec = 6'b111111;
12'd1816 : mem_out_dec = 6'b111111;
12'd1817 : mem_out_dec = 6'b111111;
12'd1818 : mem_out_dec = 6'b111111;
12'd1819 : mem_out_dec = 6'b111111;
12'd1820 : mem_out_dec = 6'b111111;
12'd1821 : mem_out_dec = 6'b111111;
12'd1822 : mem_out_dec = 6'b111111;
12'd1823 : mem_out_dec = 6'b111111;
12'd1824 : mem_out_dec = 6'b111111;
12'd1825 : mem_out_dec = 6'b111111;
12'd1826 : mem_out_dec = 6'b000011;
12'd1827 : mem_out_dec = 6'b000100;
12'd1828 : mem_out_dec = 6'b000100;
12'd1829 : mem_out_dec = 6'b000101;
12'd1830 : mem_out_dec = 6'b000110;
12'd1831 : mem_out_dec = 6'b000110;
12'd1832 : mem_out_dec = 6'b000110;
12'd1833 : mem_out_dec = 6'b000111;
12'd1834 : mem_out_dec = 6'b001000;
12'd1835 : mem_out_dec = 6'b001001;
12'd1836 : mem_out_dec = 6'b001010;
12'd1837 : mem_out_dec = 6'b001010;
12'd1838 : mem_out_dec = 6'b001011;
12'd1839 : mem_out_dec = 6'b001100;
12'd1840 : mem_out_dec = 6'b001100;
12'd1841 : mem_out_dec = 6'b001100;
12'd1842 : mem_out_dec = 6'b001101;
12'd1843 : mem_out_dec = 6'b001101;
12'd1844 : mem_out_dec = 6'b001110;
12'd1845 : mem_out_dec = 6'b001110;
12'd1846 : mem_out_dec = 6'b001111;
12'd1847 : mem_out_dec = 6'b010000;
12'd1848 : mem_out_dec = 6'b001111;
12'd1849 : mem_out_dec = 6'b001111;
12'd1850 : mem_out_dec = 6'b010000;
12'd1851 : mem_out_dec = 6'b010000;
12'd1852 : mem_out_dec = 6'b010001;
12'd1853 : mem_out_dec = 6'b010001;
12'd1854 : mem_out_dec = 6'b010010;
12'd1855 : mem_out_dec = 6'b010010;
12'd1856 : mem_out_dec = 6'b111111;
12'd1857 : mem_out_dec = 6'b111111;
12'd1858 : mem_out_dec = 6'b111111;
12'd1859 : mem_out_dec = 6'b111111;
12'd1860 : mem_out_dec = 6'b111111;
12'd1861 : mem_out_dec = 6'b111111;
12'd1862 : mem_out_dec = 6'b111111;
12'd1863 : mem_out_dec = 6'b111111;
12'd1864 : mem_out_dec = 6'b111111;
12'd1865 : mem_out_dec = 6'b111111;
12'd1866 : mem_out_dec = 6'b111111;
12'd1867 : mem_out_dec = 6'b111111;
12'd1868 : mem_out_dec = 6'b111111;
12'd1869 : mem_out_dec = 6'b111111;
12'd1870 : mem_out_dec = 6'b111111;
12'd1871 : mem_out_dec = 6'b111111;
12'd1872 : mem_out_dec = 6'b111111;
12'd1873 : mem_out_dec = 6'b111111;
12'd1874 : mem_out_dec = 6'b111111;
12'd1875 : mem_out_dec = 6'b111111;
12'd1876 : mem_out_dec = 6'b111111;
12'd1877 : mem_out_dec = 6'b111111;
12'd1878 : mem_out_dec = 6'b111111;
12'd1879 : mem_out_dec = 6'b111111;
12'd1880 : mem_out_dec = 6'b111111;
12'd1881 : mem_out_dec = 6'b111111;
12'd1882 : mem_out_dec = 6'b111111;
12'd1883 : mem_out_dec = 6'b111111;
12'd1884 : mem_out_dec = 6'b111111;
12'd1885 : mem_out_dec = 6'b111111;
12'd1886 : mem_out_dec = 6'b111111;
12'd1887 : mem_out_dec = 6'b111111;
12'd1888 : mem_out_dec = 6'b111111;
12'd1889 : mem_out_dec = 6'b111111;
12'd1890 : mem_out_dec = 6'b111111;
12'd1891 : mem_out_dec = 6'b000100;
12'd1892 : mem_out_dec = 6'b000100;
12'd1893 : mem_out_dec = 6'b000101;
12'd1894 : mem_out_dec = 6'b000101;
12'd1895 : mem_out_dec = 6'b000110;
12'd1896 : mem_out_dec = 6'b000110;
12'd1897 : mem_out_dec = 6'b000111;
12'd1898 : mem_out_dec = 6'b001000;
12'd1899 : mem_out_dec = 6'b001001;
12'd1900 : mem_out_dec = 6'b001001;
12'd1901 : mem_out_dec = 6'b001010;
12'd1902 : mem_out_dec = 6'b001011;
12'd1903 : mem_out_dec = 6'b001100;
12'd1904 : mem_out_dec = 6'b001100;
12'd1905 : mem_out_dec = 6'b001100;
12'd1906 : mem_out_dec = 6'b001100;
12'd1907 : mem_out_dec = 6'b001101;
12'd1908 : mem_out_dec = 6'b001110;
12'd1909 : mem_out_dec = 6'b001110;
12'd1910 : mem_out_dec = 6'b001111;
12'd1911 : mem_out_dec = 6'b001111;
12'd1912 : mem_out_dec = 6'b001111;
12'd1913 : mem_out_dec = 6'b001111;
12'd1914 : mem_out_dec = 6'b001111;
12'd1915 : mem_out_dec = 6'b010000;
12'd1916 : mem_out_dec = 6'b010000;
12'd1917 : mem_out_dec = 6'b010001;
12'd1918 : mem_out_dec = 6'b010001;
12'd1919 : mem_out_dec = 6'b010010;
12'd1920 : mem_out_dec = 6'b111111;
12'd1921 : mem_out_dec = 6'b111111;
12'd1922 : mem_out_dec = 6'b111111;
12'd1923 : mem_out_dec = 6'b111111;
12'd1924 : mem_out_dec = 6'b111111;
12'd1925 : mem_out_dec = 6'b111111;
12'd1926 : mem_out_dec = 6'b111111;
12'd1927 : mem_out_dec = 6'b111111;
12'd1928 : mem_out_dec = 6'b111111;
12'd1929 : mem_out_dec = 6'b111111;
12'd1930 : mem_out_dec = 6'b111111;
12'd1931 : mem_out_dec = 6'b111111;
12'd1932 : mem_out_dec = 6'b111111;
12'd1933 : mem_out_dec = 6'b111111;
12'd1934 : mem_out_dec = 6'b111111;
12'd1935 : mem_out_dec = 6'b111111;
12'd1936 : mem_out_dec = 6'b111111;
12'd1937 : mem_out_dec = 6'b111111;
12'd1938 : mem_out_dec = 6'b111111;
12'd1939 : mem_out_dec = 6'b111111;
12'd1940 : mem_out_dec = 6'b111111;
12'd1941 : mem_out_dec = 6'b111111;
12'd1942 : mem_out_dec = 6'b111111;
12'd1943 : mem_out_dec = 6'b111111;
12'd1944 : mem_out_dec = 6'b111111;
12'd1945 : mem_out_dec = 6'b111111;
12'd1946 : mem_out_dec = 6'b111111;
12'd1947 : mem_out_dec = 6'b111111;
12'd1948 : mem_out_dec = 6'b111111;
12'd1949 : mem_out_dec = 6'b111111;
12'd1950 : mem_out_dec = 6'b111111;
12'd1951 : mem_out_dec = 6'b111111;
12'd1952 : mem_out_dec = 6'b111111;
12'd1953 : mem_out_dec = 6'b111111;
12'd1954 : mem_out_dec = 6'b111111;
12'd1955 : mem_out_dec = 6'b111111;
12'd1956 : mem_out_dec = 6'b000100;
12'd1957 : mem_out_dec = 6'b000101;
12'd1958 : mem_out_dec = 6'b000101;
12'd1959 : mem_out_dec = 6'b000110;
12'd1960 : mem_out_dec = 6'b000110;
12'd1961 : mem_out_dec = 6'b000111;
12'd1962 : mem_out_dec = 6'b001000;
12'd1963 : mem_out_dec = 6'b001000;
12'd1964 : mem_out_dec = 6'b001001;
12'd1965 : mem_out_dec = 6'b001010;
12'd1966 : mem_out_dec = 6'b001011;
12'd1967 : mem_out_dec = 6'b001011;
12'd1968 : mem_out_dec = 6'b001011;
12'd1969 : mem_out_dec = 6'b001100;
12'd1970 : mem_out_dec = 6'b001100;
12'd1971 : mem_out_dec = 6'b001101;
12'd1972 : mem_out_dec = 6'b001101;
12'd1973 : mem_out_dec = 6'b001110;
12'd1974 : mem_out_dec = 6'b001111;
12'd1975 : mem_out_dec = 6'b001111;
12'd1976 : mem_out_dec = 6'b001110;
12'd1977 : mem_out_dec = 6'b001110;
12'd1978 : mem_out_dec = 6'b001111;
12'd1979 : mem_out_dec = 6'b001111;
12'd1980 : mem_out_dec = 6'b010000;
12'd1981 : mem_out_dec = 6'b010000;
12'd1982 : mem_out_dec = 6'b010001;
12'd1983 : mem_out_dec = 6'b010001;
12'd1984 : mem_out_dec = 6'b111111;
12'd1985 : mem_out_dec = 6'b111111;
12'd1986 : mem_out_dec = 6'b111111;
12'd1987 : mem_out_dec = 6'b111111;
12'd1988 : mem_out_dec = 6'b111111;
12'd1989 : mem_out_dec = 6'b111111;
12'd1990 : mem_out_dec = 6'b111111;
12'd1991 : mem_out_dec = 6'b111111;
12'd1992 : mem_out_dec = 6'b111111;
12'd1993 : mem_out_dec = 6'b111111;
12'd1994 : mem_out_dec = 6'b111111;
12'd1995 : mem_out_dec = 6'b111111;
12'd1996 : mem_out_dec = 6'b111111;
12'd1997 : mem_out_dec = 6'b111111;
12'd1998 : mem_out_dec = 6'b111111;
12'd1999 : mem_out_dec = 6'b111111;
12'd2000 : mem_out_dec = 6'b111111;
12'd2001 : mem_out_dec = 6'b111111;
12'd2002 : mem_out_dec = 6'b111111;
12'd2003 : mem_out_dec = 6'b111111;
12'd2004 : mem_out_dec = 6'b111111;
12'd2005 : mem_out_dec = 6'b111111;
12'd2006 : mem_out_dec = 6'b111111;
12'd2007 : mem_out_dec = 6'b111111;
12'd2008 : mem_out_dec = 6'b111111;
12'd2009 : mem_out_dec = 6'b111111;
12'd2010 : mem_out_dec = 6'b111111;
12'd2011 : mem_out_dec = 6'b111111;
12'd2012 : mem_out_dec = 6'b111111;
12'd2013 : mem_out_dec = 6'b111111;
12'd2014 : mem_out_dec = 6'b111111;
12'd2015 : mem_out_dec = 6'b111111;
12'd2016 : mem_out_dec = 6'b111111;
12'd2017 : mem_out_dec = 6'b111111;
12'd2018 : mem_out_dec = 6'b111111;
12'd2019 : mem_out_dec = 6'b111111;
12'd2020 : mem_out_dec = 6'b111111;
12'd2021 : mem_out_dec = 6'b000100;
12'd2022 : mem_out_dec = 6'b000101;
12'd2023 : mem_out_dec = 6'b000110;
12'd2024 : mem_out_dec = 6'b000110;
12'd2025 : mem_out_dec = 6'b000111;
12'd2026 : mem_out_dec = 6'b000111;
12'd2027 : mem_out_dec = 6'b001000;
12'd2028 : mem_out_dec = 6'b001001;
12'd2029 : mem_out_dec = 6'b001010;
12'd2030 : mem_out_dec = 6'b001010;
12'd2031 : mem_out_dec = 6'b001011;
12'd2032 : mem_out_dec = 6'b001011;
12'd2033 : mem_out_dec = 6'b001011;
12'd2034 : mem_out_dec = 6'b001100;
12'd2035 : mem_out_dec = 6'b001101;
12'd2036 : mem_out_dec = 6'b001101;
12'd2037 : mem_out_dec = 6'b001110;
12'd2038 : mem_out_dec = 6'b001110;
12'd2039 : mem_out_dec = 6'b001110;
12'd2040 : mem_out_dec = 6'b001101;
12'd2041 : mem_out_dec = 6'b001110;
12'd2042 : mem_out_dec = 6'b001110;
12'd2043 : mem_out_dec = 6'b001111;
12'd2044 : mem_out_dec = 6'b001111;
12'd2045 : mem_out_dec = 6'b010000;
12'd2046 : mem_out_dec = 6'b010000;
12'd2047 : mem_out_dec = 6'b010001;
12'd2048 : mem_out_dec = 6'b111111;
12'd2049 : mem_out_dec = 6'b111111;
12'd2050 : mem_out_dec = 6'b111111;
12'd2051 : mem_out_dec = 6'b111111;
12'd2052 : mem_out_dec = 6'b111111;
12'd2053 : mem_out_dec = 6'b111111;
12'd2054 : mem_out_dec = 6'b111111;
12'd2055 : mem_out_dec = 6'b111111;
12'd2056 : mem_out_dec = 6'b111111;
12'd2057 : mem_out_dec = 6'b111111;
12'd2058 : mem_out_dec = 6'b111111;
12'd2059 : mem_out_dec = 6'b111111;
12'd2060 : mem_out_dec = 6'b111111;
12'd2061 : mem_out_dec = 6'b111111;
12'd2062 : mem_out_dec = 6'b111111;
12'd2063 : mem_out_dec = 6'b111111;
12'd2064 : mem_out_dec = 6'b111111;
12'd2065 : mem_out_dec = 6'b111111;
12'd2066 : mem_out_dec = 6'b111111;
12'd2067 : mem_out_dec = 6'b111111;
12'd2068 : mem_out_dec = 6'b111111;
12'd2069 : mem_out_dec = 6'b111111;
12'd2070 : mem_out_dec = 6'b111111;
12'd2071 : mem_out_dec = 6'b111111;
12'd2072 : mem_out_dec = 6'b111111;
12'd2073 : mem_out_dec = 6'b111111;
12'd2074 : mem_out_dec = 6'b111111;
12'd2075 : mem_out_dec = 6'b111111;
12'd2076 : mem_out_dec = 6'b111111;
12'd2077 : mem_out_dec = 6'b111111;
12'd2078 : mem_out_dec = 6'b111111;
12'd2079 : mem_out_dec = 6'b111111;
12'd2080 : mem_out_dec = 6'b111111;
12'd2081 : mem_out_dec = 6'b111111;
12'd2082 : mem_out_dec = 6'b111111;
12'd2083 : mem_out_dec = 6'b111111;
12'd2084 : mem_out_dec = 6'b111111;
12'd2085 : mem_out_dec = 6'b111111;
12'd2086 : mem_out_dec = 6'b000100;
12'd2087 : mem_out_dec = 6'b000101;
12'd2088 : mem_out_dec = 6'b000101;
12'd2089 : mem_out_dec = 6'b000110;
12'd2090 : mem_out_dec = 6'b000110;
12'd2091 : mem_out_dec = 6'b000111;
12'd2092 : mem_out_dec = 6'b001000;
12'd2093 : mem_out_dec = 6'b001001;
12'd2094 : mem_out_dec = 6'b001001;
12'd2095 : mem_out_dec = 6'b001010;
12'd2096 : mem_out_dec = 6'b001010;
12'd2097 : mem_out_dec = 6'b001011;
12'd2098 : mem_out_dec = 6'b001011;
12'd2099 : mem_out_dec = 6'b001100;
12'd2100 : mem_out_dec = 6'b001100;
12'd2101 : mem_out_dec = 6'b001100;
12'd2102 : mem_out_dec = 6'b001100;
12'd2103 : mem_out_dec = 6'b001101;
12'd2104 : mem_out_dec = 6'b001100;
12'd2105 : mem_out_dec = 6'b001100;
12'd2106 : mem_out_dec = 6'b001101;
12'd2107 : mem_out_dec = 6'b001101;
12'd2108 : mem_out_dec = 6'b001110;
12'd2109 : mem_out_dec = 6'b001111;
12'd2110 : mem_out_dec = 6'b010000;
12'd2111 : mem_out_dec = 6'b010000;
12'd2112 : mem_out_dec = 6'b111111;
12'd2113 : mem_out_dec = 6'b111111;
12'd2114 : mem_out_dec = 6'b111111;
12'd2115 : mem_out_dec = 6'b111111;
12'd2116 : mem_out_dec = 6'b111111;
12'd2117 : mem_out_dec = 6'b111111;
12'd2118 : mem_out_dec = 6'b111111;
12'd2119 : mem_out_dec = 6'b111111;
12'd2120 : mem_out_dec = 6'b111111;
12'd2121 : mem_out_dec = 6'b111111;
12'd2122 : mem_out_dec = 6'b111111;
12'd2123 : mem_out_dec = 6'b111111;
12'd2124 : mem_out_dec = 6'b111111;
12'd2125 : mem_out_dec = 6'b111111;
12'd2126 : mem_out_dec = 6'b111111;
12'd2127 : mem_out_dec = 6'b111111;
12'd2128 : mem_out_dec = 6'b111111;
12'd2129 : mem_out_dec = 6'b111111;
12'd2130 : mem_out_dec = 6'b111111;
12'd2131 : mem_out_dec = 6'b111111;
12'd2132 : mem_out_dec = 6'b111111;
12'd2133 : mem_out_dec = 6'b111111;
12'd2134 : mem_out_dec = 6'b111111;
12'd2135 : mem_out_dec = 6'b111111;
12'd2136 : mem_out_dec = 6'b111111;
12'd2137 : mem_out_dec = 6'b111111;
12'd2138 : mem_out_dec = 6'b111111;
12'd2139 : mem_out_dec = 6'b111111;
12'd2140 : mem_out_dec = 6'b111111;
12'd2141 : mem_out_dec = 6'b111111;
12'd2142 : mem_out_dec = 6'b111111;
12'd2143 : mem_out_dec = 6'b111111;
12'd2144 : mem_out_dec = 6'b111111;
12'd2145 : mem_out_dec = 6'b111111;
12'd2146 : mem_out_dec = 6'b111111;
12'd2147 : mem_out_dec = 6'b111111;
12'd2148 : mem_out_dec = 6'b111111;
12'd2149 : mem_out_dec = 6'b111111;
12'd2150 : mem_out_dec = 6'b111111;
12'd2151 : mem_out_dec = 6'b000100;
12'd2152 : mem_out_dec = 6'b000100;
12'd2153 : mem_out_dec = 6'b000101;
12'd2154 : mem_out_dec = 6'b000110;
12'd2155 : mem_out_dec = 6'b000111;
12'd2156 : mem_out_dec = 6'b000111;
12'd2157 : mem_out_dec = 6'b001000;
12'd2158 : mem_out_dec = 6'b001001;
12'd2159 : mem_out_dec = 6'b001001;
12'd2160 : mem_out_dec = 6'b001010;
12'd2161 : mem_out_dec = 6'b001010;
12'd2162 : mem_out_dec = 6'b001011;
12'd2163 : mem_out_dec = 6'b001011;
12'd2164 : mem_out_dec = 6'b001011;
12'd2165 : mem_out_dec = 6'b001011;
12'd2166 : mem_out_dec = 6'b001011;
12'd2167 : mem_out_dec = 6'b001100;
12'd2168 : mem_out_dec = 6'b001011;
12'd2169 : mem_out_dec = 6'b001011;
12'd2170 : mem_out_dec = 6'b001100;
12'd2171 : mem_out_dec = 6'b001101;
12'd2172 : mem_out_dec = 6'b001110;
12'd2173 : mem_out_dec = 6'b001110;
12'd2174 : mem_out_dec = 6'b001111;
12'd2175 : mem_out_dec = 6'b010000;
12'd2176 : mem_out_dec = 6'b111111;
12'd2177 : mem_out_dec = 6'b111111;
12'd2178 : mem_out_dec = 6'b111111;
12'd2179 : mem_out_dec = 6'b111111;
12'd2180 : mem_out_dec = 6'b111111;
12'd2181 : mem_out_dec = 6'b111111;
12'd2182 : mem_out_dec = 6'b111111;
12'd2183 : mem_out_dec = 6'b111111;
12'd2184 : mem_out_dec = 6'b111111;
12'd2185 : mem_out_dec = 6'b111111;
12'd2186 : mem_out_dec = 6'b111111;
12'd2187 : mem_out_dec = 6'b111111;
12'd2188 : mem_out_dec = 6'b111111;
12'd2189 : mem_out_dec = 6'b111111;
12'd2190 : mem_out_dec = 6'b111111;
12'd2191 : mem_out_dec = 6'b111111;
12'd2192 : mem_out_dec = 6'b111111;
12'd2193 : mem_out_dec = 6'b111111;
12'd2194 : mem_out_dec = 6'b111111;
12'd2195 : mem_out_dec = 6'b111111;
12'd2196 : mem_out_dec = 6'b111111;
12'd2197 : mem_out_dec = 6'b111111;
12'd2198 : mem_out_dec = 6'b111111;
12'd2199 : mem_out_dec = 6'b111111;
12'd2200 : mem_out_dec = 6'b111111;
12'd2201 : mem_out_dec = 6'b111111;
12'd2202 : mem_out_dec = 6'b111111;
12'd2203 : mem_out_dec = 6'b111111;
12'd2204 : mem_out_dec = 6'b111111;
12'd2205 : mem_out_dec = 6'b111111;
12'd2206 : mem_out_dec = 6'b111111;
12'd2207 : mem_out_dec = 6'b111111;
12'd2208 : mem_out_dec = 6'b111111;
12'd2209 : mem_out_dec = 6'b111111;
12'd2210 : mem_out_dec = 6'b111111;
12'd2211 : mem_out_dec = 6'b111111;
12'd2212 : mem_out_dec = 6'b111111;
12'd2213 : mem_out_dec = 6'b111111;
12'd2214 : mem_out_dec = 6'b111111;
12'd2215 : mem_out_dec = 6'b111111;
12'd2216 : mem_out_dec = 6'b000100;
12'd2217 : mem_out_dec = 6'b000101;
12'd2218 : mem_out_dec = 6'b000101;
12'd2219 : mem_out_dec = 6'b000110;
12'd2220 : mem_out_dec = 6'b000111;
12'd2221 : mem_out_dec = 6'b000111;
12'd2222 : mem_out_dec = 6'b001000;
12'd2223 : mem_out_dec = 6'b001001;
12'd2224 : mem_out_dec = 6'b001001;
12'd2225 : mem_out_dec = 6'b001010;
12'd2226 : mem_out_dec = 6'b001010;
12'd2227 : mem_out_dec = 6'b001010;
12'd2228 : mem_out_dec = 6'b001010;
12'd2229 : mem_out_dec = 6'b001010;
12'd2230 : mem_out_dec = 6'b001010;
12'd2231 : mem_out_dec = 6'b001010;
12'd2232 : mem_out_dec = 6'b001010;
12'd2233 : mem_out_dec = 6'b001011;
12'd2234 : mem_out_dec = 6'b001100;
12'd2235 : mem_out_dec = 6'b001100;
12'd2236 : mem_out_dec = 6'b001101;
12'd2237 : mem_out_dec = 6'b001110;
12'd2238 : mem_out_dec = 6'b001111;
12'd2239 : mem_out_dec = 6'b010000;
12'd2240 : mem_out_dec = 6'b111111;
12'd2241 : mem_out_dec = 6'b111111;
12'd2242 : mem_out_dec = 6'b111111;
12'd2243 : mem_out_dec = 6'b111111;
12'd2244 : mem_out_dec = 6'b111111;
12'd2245 : mem_out_dec = 6'b111111;
12'd2246 : mem_out_dec = 6'b111111;
12'd2247 : mem_out_dec = 6'b111111;
12'd2248 : mem_out_dec = 6'b111111;
12'd2249 : mem_out_dec = 6'b111111;
12'd2250 : mem_out_dec = 6'b111111;
12'd2251 : mem_out_dec = 6'b111111;
12'd2252 : mem_out_dec = 6'b111111;
12'd2253 : mem_out_dec = 6'b111111;
12'd2254 : mem_out_dec = 6'b111111;
12'd2255 : mem_out_dec = 6'b111111;
12'd2256 : mem_out_dec = 6'b111111;
12'd2257 : mem_out_dec = 6'b111111;
12'd2258 : mem_out_dec = 6'b111111;
12'd2259 : mem_out_dec = 6'b111111;
12'd2260 : mem_out_dec = 6'b111111;
12'd2261 : mem_out_dec = 6'b111111;
12'd2262 : mem_out_dec = 6'b111111;
12'd2263 : mem_out_dec = 6'b111111;
12'd2264 : mem_out_dec = 6'b111111;
12'd2265 : mem_out_dec = 6'b111111;
12'd2266 : mem_out_dec = 6'b111111;
12'd2267 : mem_out_dec = 6'b111111;
12'd2268 : mem_out_dec = 6'b111111;
12'd2269 : mem_out_dec = 6'b111111;
12'd2270 : mem_out_dec = 6'b111111;
12'd2271 : mem_out_dec = 6'b111111;
12'd2272 : mem_out_dec = 6'b111111;
12'd2273 : mem_out_dec = 6'b111111;
12'd2274 : mem_out_dec = 6'b111111;
12'd2275 : mem_out_dec = 6'b111111;
12'd2276 : mem_out_dec = 6'b111111;
12'd2277 : mem_out_dec = 6'b111111;
12'd2278 : mem_out_dec = 6'b111111;
12'd2279 : mem_out_dec = 6'b111111;
12'd2280 : mem_out_dec = 6'b111111;
12'd2281 : mem_out_dec = 6'b000100;
12'd2282 : mem_out_dec = 6'b000101;
12'd2283 : mem_out_dec = 6'b000101;
12'd2284 : mem_out_dec = 6'b000110;
12'd2285 : mem_out_dec = 6'b000111;
12'd2286 : mem_out_dec = 6'b001000;
12'd2287 : mem_out_dec = 6'b001001;
12'd2288 : mem_out_dec = 6'b001001;
12'd2289 : mem_out_dec = 6'b001001;
12'd2290 : mem_out_dec = 6'b001001;
12'd2291 : mem_out_dec = 6'b001001;
12'd2292 : mem_out_dec = 6'b001001;
12'd2293 : mem_out_dec = 6'b001001;
12'd2294 : mem_out_dec = 6'b001001;
12'd2295 : mem_out_dec = 6'b001001;
12'd2296 : mem_out_dec = 6'b001010;
12'd2297 : mem_out_dec = 6'b001010;
12'd2298 : mem_out_dec = 6'b001011;
12'd2299 : mem_out_dec = 6'b001100;
12'd2300 : mem_out_dec = 6'b001101;
12'd2301 : mem_out_dec = 6'b001110;
12'd2302 : mem_out_dec = 6'b001110;
12'd2303 : mem_out_dec = 6'b001111;
12'd2304 : mem_out_dec = 6'b111111;
12'd2305 : mem_out_dec = 6'b111111;
12'd2306 : mem_out_dec = 6'b111111;
12'd2307 : mem_out_dec = 6'b111111;
12'd2308 : mem_out_dec = 6'b111111;
12'd2309 : mem_out_dec = 6'b111111;
12'd2310 : mem_out_dec = 6'b111111;
12'd2311 : mem_out_dec = 6'b111111;
12'd2312 : mem_out_dec = 6'b111111;
12'd2313 : mem_out_dec = 6'b111111;
12'd2314 : mem_out_dec = 6'b111111;
12'd2315 : mem_out_dec = 6'b111111;
12'd2316 : mem_out_dec = 6'b111111;
12'd2317 : mem_out_dec = 6'b111111;
12'd2318 : mem_out_dec = 6'b111111;
12'd2319 : mem_out_dec = 6'b111111;
12'd2320 : mem_out_dec = 6'b111111;
12'd2321 : mem_out_dec = 6'b111111;
12'd2322 : mem_out_dec = 6'b111111;
12'd2323 : mem_out_dec = 6'b111111;
12'd2324 : mem_out_dec = 6'b111111;
12'd2325 : mem_out_dec = 6'b111111;
12'd2326 : mem_out_dec = 6'b111111;
12'd2327 : mem_out_dec = 6'b111111;
12'd2328 : mem_out_dec = 6'b111111;
12'd2329 : mem_out_dec = 6'b111111;
12'd2330 : mem_out_dec = 6'b111111;
12'd2331 : mem_out_dec = 6'b111111;
12'd2332 : mem_out_dec = 6'b111111;
12'd2333 : mem_out_dec = 6'b111111;
12'd2334 : mem_out_dec = 6'b111111;
12'd2335 : mem_out_dec = 6'b111111;
12'd2336 : mem_out_dec = 6'b111111;
12'd2337 : mem_out_dec = 6'b111111;
12'd2338 : mem_out_dec = 6'b111111;
12'd2339 : mem_out_dec = 6'b111111;
12'd2340 : mem_out_dec = 6'b111111;
12'd2341 : mem_out_dec = 6'b111111;
12'd2342 : mem_out_dec = 6'b111111;
12'd2343 : mem_out_dec = 6'b111111;
12'd2344 : mem_out_dec = 6'b111111;
12'd2345 : mem_out_dec = 6'b111111;
12'd2346 : mem_out_dec = 6'b000100;
12'd2347 : mem_out_dec = 6'b000101;
12'd2348 : mem_out_dec = 6'b000110;
12'd2349 : mem_out_dec = 6'b000111;
12'd2350 : mem_out_dec = 6'b000111;
12'd2351 : mem_out_dec = 6'b001000;
12'd2352 : mem_out_dec = 6'b001000;
12'd2353 : mem_out_dec = 6'b001000;
12'd2354 : mem_out_dec = 6'b001000;
12'd2355 : mem_out_dec = 6'b001000;
12'd2356 : mem_out_dec = 6'b001000;
12'd2357 : mem_out_dec = 6'b001000;
12'd2358 : mem_out_dec = 6'b001000;
12'd2359 : mem_out_dec = 6'b001001;
12'd2360 : mem_out_dec = 6'b001001;
12'd2361 : mem_out_dec = 6'b001010;
12'd2362 : mem_out_dec = 6'b001011;
12'd2363 : mem_out_dec = 6'b001100;
12'd2364 : mem_out_dec = 6'b001100;
12'd2365 : mem_out_dec = 6'b001101;
12'd2366 : mem_out_dec = 6'b001110;
12'd2367 : mem_out_dec = 6'b001111;
12'd2368 : mem_out_dec = 6'b111111;
12'd2369 : mem_out_dec = 6'b111111;
12'd2370 : mem_out_dec = 6'b111111;
12'd2371 : mem_out_dec = 6'b111111;
12'd2372 : mem_out_dec = 6'b111111;
12'd2373 : mem_out_dec = 6'b111111;
12'd2374 : mem_out_dec = 6'b111111;
12'd2375 : mem_out_dec = 6'b111111;
12'd2376 : mem_out_dec = 6'b111111;
12'd2377 : mem_out_dec = 6'b111111;
12'd2378 : mem_out_dec = 6'b111111;
12'd2379 : mem_out_dec = 6'b111111;
12'd2380 : mem_out_dec = 6'b111111;
12'd2381 : mem_out_dec = 6'b111111;
12'd2382 : mem_out_dec = 6'b111111;
12'd2383 : mem_out_dec = 6'b111111;
12'd2384 : mem_out_dec = 6'b111111;
12'd2385 : mem_out_dec = 6'b111111;
12'd2386 : mem_out_dec = 6'b111111;
12'd2387 : mem_out_dec = 6'b111111;
12'd2388 : mem_out_dec = 6'b111111;
12'd2389 : mem_out_dec = 6'b111111;
12'd2390 : mem_out_dec = 6'b111111;
12'd2391 : mem_out_dec = 6'b111111;
12'd2392 : mem_out_dec = 6'b111111;
12'd2393 : mem_out_dec = 6'b111111;
12'd2394 : mem_out_dec = 6'b111111;
12'd2395 : mem_out_dec = 6'b111111;
12'd2396 : mem_out_dec = 6'b111111;
12'd2397 : mem_out_dec = 6'b111111;
12'd2398 : mem_out_dec = 6'b111111;
12'd2399 : mem_out_dec = 6'b111111;
12'd2400 : mem_out_dec = 6'b111111;
12'd2401 : mem_out_dec = 6'b111111;
12'd2402 : mem_out_dec = 6'b111111;
12'd2403 : mem_out_dec = 6'b111111;
12'd2404 : mem_out_dec = 6'b111111;
12'd2405 : mem_out_dec = 6'b111111;
12'd2406 : mem_out_dec = 6'b111111;
12'd2407 : mem_out_dec = 6'b111111;
12'd2408 : mem_out_dec = 6'b111111;
12'd2409 : mem_out_dec = 6'b111111;
12'd2410 : mem_out_dec = 6'b111111;
12'd2411 : mem_out_dec = 6'b000101;
12'd2412 : mem_out_dec = 6'b000101;
12'd2413 : mem_out_dec = 6'b000110;
12'd2414 : mem_out_dec = 6'b000111;
12'd2415 : mem_out_dec = 6'b001000;
12'd2416 : mem_out_dec = 6'b000111;
12'd2417 : mem_out_dec = 6'b000111;
12'd2418 : mem_out_dec = 6'b000111;
12'd2419 : mem_out_dec = 6'b000111;
12'd2420 : mem_out_dec = 6'b000111;
12'd2421 : mem_out_dec = 6'b000111;
12'd2422 : mem_out_dec = 6'b001000;
12'd2423 : mem_out_dec = 6'b001001;
12'd2424 : mem_out_dec = 6'b001001;
12'd2425 : mem_out_dec = 6'b001010;
12'd2426 : mem_out_dec = 6'b001010;
12'd2427 : mem_out_dec = 6'b001011;
12'd2428 : mem_out_dec = 6'b001100;
12'd2429 : mem_out_dec = 6'b001101;
12'd2430 : mem_out_dec = 6'b001101;
12'd2431 : mem_out_dec = 6'b001110;
12'd2432 : mem_out_dec = 6'b111111;
12'd2433 : mem_out_dec = 6'b111111;
12'd2434 : mem_out_dec = 6'b111111;
12'd2435 : mem_out_dec = 6'b111111;
12'd2436 : mem_out_dec = 6'b111111;
12'd2437 : mem_out_dec = 6'b111111;
12'd2438 : mem_out_dec = 6'b111111;
12'd2439 : mem_out_dec = 6'b111111;
12'd2440 : mem_out_dec = 6'b111111;
12'd2441 : mem_out_dec = 6'b111111;
12'd2442 : mem_out_dec = 6'b111111;
12'd2443 : mem_out_dec = 6'b111111;
12'd2444 : mem_out_dec = 6'b111111;
12'd2445 : mem_out_dec = 6'b111111;
12'd2446 : mem_out_dec = 6'b111111;
12'd2447 : mem_out_dec = 6'b111111;
12'd2448 : mem_out_dec = 6'b111111;
12'd2449 : mem_out_dec = 6'b111111;
12'd2450 : mem_out_dec = 6'b111111;
12'd2451 : mem_out_dec = 6'b111111;
12'd2452 : mem_out_dec = 6'b111111;
12'd2453 : mem_out_dec = 6'b111111;
12'd2454 : mem_out_dec = 6'b111111;
12'd2455 : mem_out_dec = 6'b111111;
12'd2456 : mem_out_dec = 6'b111111;
12'd2457 : mem_out_dec = 6'b111111;
12'd2458 : mem_out_dec = 6'b111111;
12'd2459 : mem_out_dec = 6'b111111;
12'd2460 : mem_out_dec = 6'b111111;
12'd2461 : mem_out_dec = 6'b111111;
12'd2462 : mem_out_dec = 6'b111111;
12'd2463 : mem_out_dec = 6'b111111;
12'd2464 : mem_out_dec = 6'b111111;
12'd2465 : mem_out_dec = 6'b111111;
12'd2466 : mem_out_dec = 6'b111111;
12'd2467 : mem_out_dec = 6'b111111;
12'd2468 : mem_out_dec = 6'b111111;
12'd2469 : mem_out_dec = 6'b111111;
12'd2470 : mem_out_dec = 6'b111111;
12'd2471 : mem_out_dec = 6'b111111;
12'd2472 : mem_out_dec = 6'b111111;
12'd2473 : mem_out_dec = 6'b111111;
12'd2474 : mem_out_dec = 6'b111111;
12'd2475 : mem_out_dec = 6'b111111;
12'd2476 : mem_out_dec = 6'b000101;
12'd2477 : mem_out_dec = 6'b000110;
12'd2478 : mem_out_dec = 6'b000111;
12'd2479 : mem_out_dec = 6'b000111;
12'd2480 : mem_out_dec = 6'b000110;
12'd2481 : mem_out_dec = 6'b000110;
12'd2482 : mem_out_dec = 6'b000110;
12'd2483 : mem_out_dec = 6'b000110;
12'd2484 : mem_out_dec = 6'b000110;
12'd2485 : mem_out_dec = 6'b000111;
12'd2486 : mem_out_dec = 6'b000111;
12'd2487 : mem_out_dec = 6'b001000;
12'd2488 : mem_out_dec = 6'b001001;
12'd2489 : mem_out_dec = 6'b001001;
12'd2490 : mem_out_dec = 6'b001010;
12'd2491 : mem_out_dec = 6'b001011;
12'd2492 : mem_out_dec = 6'b001011;
12'd2493 : mem_out_dec = 6'b001100;
12'd2494 : mem_out_dec = 6'b001101;
12'd2495 : mem_out_dec = 6'b001110;
12'd2496 : mem_out_dec = 6'b111111;
12'd2497 : mem_out_dec = 6'b111111;
12'd2498 : mem_out_dec = 6'b111111;
12'd2499 : mem_out_dec = 6'b111111;
12'd2500 : mem_out_dec = 6'b111111;
12'd2501 : mem_out_dec = 6'b111111;
12'd2502 : mem_out_dec = 6'b111111;
12'd2503 : mem_out_dec = 6'b111111;
12'd2504 : mem_out_dec = 6'b111111;
12'd2505 : mem_out_dec = 6'b111111;
12'd2506 : mem_out_dec = 6'b111111;
12'd2507 : mem_out_dec = 6'b111111;
12'd2508 : mem_out_dec = 6'b111111;
12'd2509 : mem_out_dec = 6'b111111;
12'd2510 : mem_out_dec = 6'b111111;
12'd2511 : mem_out_dec = 6'b111111;
12'd2512 : mem_out_dec = 6'b111111;
12'd2513 : mem_out_dec = 6'b111111;
12'd2514 : mem_out_dec = 6'b111111;
12'd2515 : mem_out_dec = 6'b111111;
12'd2516 : mem_out_dec = 6'b111111;
12'd2517 : mem_out_dec = 6'b111111;
12'd2518 : mem_out_dec = 6'b111111;
12'd2519 : mem_out_dec = 6'b111111;
12'd2520 : mem_out_dec = 6'b111111;
12'd2521 : mem_out_dec = 6'b111111;
12'd2522 : mem_out_dec = 6'b111111;
12'd2523 : mem_out_dec = 6'b111111;
12'd2524 : mem_out_dec = 6'b111111;
12'd2525 : mem_out_dec = 6'b111111;
12'd2526 : mem_out_dec = 6'b111111;
12'd2527 : mem_out_dec = 6'b111111;
12'd2528 : mem_out_dec = 6'b111111;
12'd2529 : mem_out_dec = 6'b111111;
12'd2530 : mem_out_dec = 6'b111111;
12'd2531 : mem_out_dec = 6'b111111;
12'd2532 : mem_out_dec = 6'b111111;
12'd2533 : mem_out_dec = 6'b111111;
12'd2534 : mem_out_dec = 6'b111111;
12'd2535 : mem_out_dec = 6'b111111;
12'd2536 : mem_out_dec = 6'b111111;
12'd2537 : mem_out_dec = 6'b111111;
12'd2538 : mem_out_dec = 6'b111111;
12'd2539 : mem_out_dec = 6'b111111;
12'd2540 : mem_out_dec = 6'b111111;
12'd2541 : mem_out_dec = 6'b000101;
12'd2542 : mem_out_dec = 6'b000110;
12'd2543 : mem_out_dec = 6'b000110;
12'd2544 : mem_out_dec = 6'b000110;
12'd2545 : mem_out_dec = 6'b000110;
12'd2546 : mem_out_dec = 6'b000101;
12'd2547 : mem_out_dec = 6'b000101;
12'd2548 : mem_out_dec = 6'b000110;
12'd2549 : mem_out_dec = 6'b000111;
12'd2550 : mem_out_dec = 6'b000111;
12'd2551 : mem_out_dec = 6'b001000;
12'd2552 : mem_out_dec = 6'b001000;
12'd2553 : mem_out_dec = 6'b001001;
12'd2554 : mem_out_dec = 6'b001010;
12'd2555 : mem_out_dec = 6'b001010;
12'd2556 : mem_out_dec = 6'b001011;
12'd2557 : mem_out_dec = 6'b001100;
12'd2558 : mem_out_dec = 6'b001101;
12'd2559 : mem_out_dec = 6'b001101;
12'd2560 : mem_out_dec = 6'b111111;
12'd2561 : mem_out_dec = 6'b111111;
12'd2562 : mem_out_dec = 6'b111111;
12'd2563 : mem_out_dec = 6'b111111;
12'd2564 : mem_out_dec = 6'b111111;
12'd2565 : mem_out_dec = 6'b111111;
12'd2566 : mem_out_dec = 6'b111111;
12'd2567 : mem_out_dec = 6'b111111;
12'd2568 : mem_out_dec = 6'b111111;
12'd2569 : mem_out_dec = 6'b111111;
12'd2570 : mem_out_dec = 6'b111111;
12'd2571 : mem_out_dec = 6'b111111;
12'd2572 : mem_out_dec = 6'b111111;
12'd2573 : mem_out_dec = 6'b111111;
12'd2574 : mem_out_dec = 6'b111111;
12'd2575 : mem_out_dec = 6'b111111;
12'd2576 : mem_out_dec = 6'b111111;
12'd2577 : mem_out_dec = 6'b111111;
12'd2578 : mem_out_dec = 6'b111111;
12'd2579 : mem_out_dec = 6'b111111;
12'd2580 : mem_out_dec = 6'b111111;
12'd2581 : mem_out_dec = 6'b111111;
12'd2582 : mem_out_dec = 6'b111111;
12'd2583 : mem_out_dec = 6'b111111;
12'd2584 : mem_out_dec = 6'b111111;
12'd2585 : mem_out_dec = 6'b111111;
12'd2586 : mem_out_dec = 6'b111111;
12'd2587 : mem_out_dec = 6'b111111;
12'd2588 : mem_out_dec = 6'b111111;
12'd2589 : mem_out_dec = 6'b111111;
12'd2590 : mem_out_dec = 6'b111111;
12'd2591 : mem_out_dec = 6'b111111;
12'd2592 : mem_out_dec = 6'b111111;
12'd2593 : mem_out_dec = 6'b111111;
12'd2594 : mem_out_dec = 6'b111111;
12'd2595 : mem_out_dec = 6'b111111;
12'd2596 : mem_out_dec = 6'b111111;
12'd2597 : mem_out_dec = 6'b111111;
12'd2598 : mem_out_dec = 6'b111111;
12'd2599 : mem_out_dec = 6'b111111;
12'd2600 : mem_out_dec = 6'b111111;
12'd2601 : mem_out_dec = 6'b111111;
12'd2602 : mem_out_dec = 6'b111111;
12'd2603 : mem_out_dec = 6'b111111;
12'd2604 : mem_out_dec = 6'b111111;
12'd2605 : mem_out_dec = 6'b111111;
12'd2606 : mem_out_dec = 6'b000100;
12'd2607 : mem_out_dec = 6'b000101;
12'd2608 : mem_out_dec = 6'b000100;
12'd2609 : mem_out_dec = 6'b000100;
12'd2610 : mem_out_dec = 6'b000100;
12'd2611 : mem_out_dec = 6'b000101;
12'd2612 : mem_out_dec = 6'b000101;
12'd2613 : mem_out_dec = 6'b000110;
12'd2614 : mem_out_dec = 6'b000111;
12'd2615 : mem_out_dec = 6'b000111;
12'd2616 : mem_out_dec = 6'b000111;
12'd2617 : mem_out_dec = 6'b001000;
12'd2618 : mem_out_dec = 6'b001001;
12'd2619 : mem_out_dec = 6'b001010;
12'd2620 : mem_out_dec = 6'b001010;
12'd2621 : mem_out_dec = 6'b001011;
12'd2622 : mem_out_dec = 6'b001100;
12'd2623 : mem_out_dec = 6'b001101;
12'd2624 : mem_out_dec = 6'b111111;
12'd2625 : mem_out_dec = 6'b111111;
12'd2626 : mem_out_dec = 6'b111111;
12'd2627 : mem_out_dec = 6'b111111;
12'd2628 : mem_out_dec = 6'b111111;
12'd2629 : mem_out_dec = 6'b111111;
12'd2630 : mem_out_dec = 6'b111111;
12'd2631 : mem_out_dec = 6'b111111;
12'd2632 : mem_out_dec = 6'b111111;
12'd2633 : mem_out_dec = 6'b111111;
12'd2634 : mem_out_dec = 6'b111111;
12'd2635 : mem_out_dec = 6'b111111;
12'd2636 : mem_out_dec = 6'b111111;
12'd2637 : mem_out_dec = 6'b111111;
12'd2638 : mem_out_dec = 6'b111111;
12'd2639 : mem_out_dec = 6'b111111;
12'd2640 : mem_out_dec = 6'b111111;
12'd2641 : mem_out_dec = 6'b111111;
12'd2642 : mem_out_dec = 6'b111111;
12'd2643 : mem_out_dec = 6'b111111;
12'd2644 : mem_out_dec = 6'b111111;
12'd2645 : mem_out_dec = 6'b111111;
12'd2646 : mem_out_dec = 6'b111111;
12'd2647 : mem_out_dec = 6'b111111;
12'd2648 : mem_out_dec = 6'b111111;
12'd2649 : mem_out_dec = 6'b111111;
12'd2650 : mem_out_dec = 6'b111111;
12'd2651 : mem_out_dec = 6'b111111;
12'd2652 : mem_out_dec = 6'b111111;
12'd2653 : mem_out_dec = 6'b111111;
12'd2654 : mem_out_dec = 6'b111111;
12'd2655 : mem_out_dec = 6'b111111;
12'd2656 : mem_out_dec = 6'b111111;
12'd2657 : mem_out_dec = 6'b111111;
12'd2658 : mem_out_dec = 6'b111111;
12'd2659 : mem_out_dec = 6'b111111;
12'd2660 : mem_out_dec = 6'b111111;
12'd2661 : mem_out_dec = 6'b111111;
12'd2662 : mem_out_dec = 6'b111111;
12'd2663 : mem_out_dec = 6'b111111;
12'd2664 : mem_out_dec = 6'b111111;
12'd2665 : mem_out_dec = 6'b111111;
12'd2666 : mem_out_dec = 6'b111111;
12'd2667 : mem_out_dec = 6'b111111;
12'd2668 : mem_out_dec = 6'b111111;
12'd2669 : mem_out_dec = 6'b111111;
12'd2670 : mem_out_dec = 6'b111111;
12'd2671 : mem_out_dec = 6'b000100;
12'd2672 : mem_out_dec = 6'b000011;
12'd2673 : mem_out_dec = 6'b000011;
12'd2674 : mem_out_dec = 6'b000100;
12'd2675 : mem_out_dec = 6'b000100;
12'd2676 : mem_out_dec = 6'b000101;
12'd2677 : mem_out_dec = 6'b000110;
12'd2678 : mem_out_dec = 6'b000110;
12'd2679 : mem_out_dec = 6'b000111;
12'd2680 : mem_out_dec = 6'b000111;
12'd2681 : mem_out_dec = 6'b001000;
12'd2682 : mem_out_dec = 6'b001001;
12'd2683 : mem_out_dec = 6'b001001;
12'd2684 : mem_out_dec = 6'b001010;
12'd2685 : mem_out_dec = 6'b001011;
12'd2686 : mem_out_dec = 6'b001100;
12'd2687 : mem_out_dec = 6'b001100;
12'd2688 : mem_out_dec = 6'b111111;
12'd2689 : mem_out_dec = 6'b111111;
12'd2690 : mem_out_dec = 6'b111111;
12'd2691 : mem_out_dec = 6'b111111;
12'd2692 : mem_out_dec = 6'b111111;
12'd2693 : mem_out_dec = 6'b111111;
12'd2694 : mem_out_dec = 6'b111111;
12'd2695 : mem_out_dec = 6'b111111;
12'd2696 : mem_out_dec = 6'b111111;
12'd2697 : mem_out_dec = 6'b111111;
12'd2698 : mem_out_dec = 6'b111111;
12'd2699 : mem_out_dec = 6'b111111;
12'd2700 : mem_out_dec = 6'b111111;
12'd2701 : mem_out_dec = 6'b111111;
12'd2702 : mem_out_dec = 6'b111111;
12'd2703 : mem_out_dec = 6'b111111;
12'd2704 : mem_out_dec = 6'b111111;
12'd2705 : mem_out_dec = 6'b111111;
12'd2706 : mem_out_dec = 6'b111111;
12'd2707 : mem_out_dec = 6'b111111;
12'd2708 : mem_out_dec = 6'b111111;
12'd2709 : mem_out_dec = 6'b111111;
12'd2710 : mem_out_dec = 6'b111111;
12'd2711 : mem_out_dec = 6'b111111;
12'd2712 : mem_out_dec = 6'b111111;
12'd2713 : mem_out_dec = 6'b111111;
12'd2714 : mem_out_dec = 6'b111111;
12'd2715 : mem_out_dec = 6'b111111;
12'd2716 : mem_out_dec = 6'b111111;
12'd2717 : mem_out_dec = 6'b111111;
12'd2718 : mem_out_dec = 6'b111111;
12'd2719 : mem_out_dec = 6'b111111;
12'd2720 : mem_out_dec = 6'b111111;
12'd2721 : mem_out_dec = 6'b111111;
12'd2722 : mem_out_dec = 6'b111111;
12'd2723 : mem_out_dec = 6'b111111;
12'd2724 : mem_out_dec = 6'b111111;
12'd2725 : mem_out_dec = 6'b111111;
12'd2726 : mem_out_dec = 6'b111111;
12'd2727 : mem_out_dec = 6'b111111;
12'd2728 : mem_out_dec = 6'b111111;
12'd2729 : mem_out_dec = 6'b111111;
12'd2730 : mem_out_dec = 6'b111111;
12'd2731 : mem_out_dec = 6'b111111;
12'd2732 : mem_out_dec = 6'b111111;
12'd2733 : mem_out_dec = 6'b111111;
12'd2734 : mem_out_dec = 6'b111111;
12'd2735 : mem_out_dec = 6'b111111;
12'd2736 : mem_out_dec = 6'b000011;
12'd2737 : mem_out_dec = 6'b000011;
12'd2738 : mem_out_dec = 6'b000100;
12'd2739 : mem_out_dec = 6'b000100;
12'd2740 : mem_out_dec = 6'b000101;
12'd2741 : mem_out_dec = 6'b000101;
12'd2742 : mem_out_dec = 6'b000110;
12'd2743 : mem_out_dec = 6'b000111;
12'd2744 : mem_out_dec = 6'b000111;
12'd2745 : mem_out_dec = 6'b001000;
12'd2746 : mem_out_dec = 6'b001000;
12'd2747 : mem_out_dec = 6'b001001;
12'd2748 : mem_out_dec = 6'b001010;
12'd2749 : mem_out_dec = 6'b001011;
12'd2750 : mem_out_dec = 6'b001011;
12'd2751 : mem_out_dec = 6'b001100;
12'd2752 : mem_out_dec = 6'b111111;
12'd2753 : mem_out_dec = 6'b111111;
12'd2754 : mem_out_dec = 6'b111111;
12'd2755 : mem_out_dec = 6'b111111;
12'd2756 : mem_out_dec = 6'b111111;
12'd2757 : mem_out_dec = 6'b111111;
12'd2758 : mem_out_dec = 6'b111111;
12'd2759 : mem_out_dec = 6'b111111;
12'd2760 : mem_out_dec = 6'b111111;
12'd2761 : mem_out_dec = 6'b111111;
12'd2762 : mem_out_dec = 6'b111111;
12'd2763 : mem_out_dec = 6'b111111;
12'd2764 : mem_out_dec = 6'b111111;
12'd2765 : mem_out_dec = 6'b111111;
12'd2766 : mem_out_dec = 6'b111111;
12'd2767 : mem_out_dec = 6'b111111;
12'd2768 : mem_out_dec = 6'b111111;
12'd2769 : mem_out_dec = 6'b111111;
12'd2770 : mem_out_dec = 6'b111111;
12'd2771 : mem_out_dec = 6'b111111;
12'd2772 : mem_out_dec = 6'b111111;
12'd2773 : mem_out_dec = 6'b111111;
12'd2774 : mem_out_dec = 6'b111111;
12'd2775 : mem_out_dec = 6'b111111;
12'd2776 : mem_out_dec = 6'b111111;
12'd2777 : mem_out_dec = 6'b111111;
12'd2778 : mem_out_dec = 6'b111111;
12'd2779 : mem_out_dec = 6'b111111;
12'd2780 : mem_out_dec = 6'b111111;
12'd2781 : mem_out_dec = 6'b111111;
12'd2782 : mem_out_dec = 6'b111111;
12'd2783 : mem_out_dec = 6'b111111;
12'd2784 : mem_out_dec = 6'b111111;
12'd2785 : mem_out_dec = 6'b111111;
12'd2786 : mem_out_dec = 6'b111111;
12'd2787 : mem_out_dec = 6'b111111;
12'd2788 : mem_out_dec = 6'b111111;
12'd2789 : mem_out_dec = 6'b111111;
12'd2790 : mem_out_dec = 6'b111111;
12'd2791 : mem_out_dec = 6'b111111;
12'd2792 : mem_out_dec = 6'b111111;
12'd2793 : mem_out_dec = 6'b111111;
12'd2794 : mem_out_dec = 6'b111111;
12'd2795 : mem_out_dec = 6'b111111;
12'd2796 : mem_out_dec = 6'b111111;
12'd2797 : mem_out_dec = 6'b111111;
12'd2798 : mem_out_dec = 6'b111111;
12'd2799 : mem_out_dec = 6'b111111;
12'd2800 : mem_out_dec = 6'b111111;
12'd2801 : mem_out_dec = 6'b000011;
12'd2802 : mem_out_dec = 6'b000011;
12'd2803 : mem_out_dec = 6'b000100;
12'd2804 : mem_out_dec = 6'b000101;
12'd2805 : mem_out_dec = 6'b000101;
12'd2806 : mem_out_dec = 6'b000110;
12'd2807 : mem_out_dec = 6'b000111;
12'd2808 : mem_out_dec = 6'b000111;
12'd2809 : mem_out_dec = 6'b000111;
12'd2810 : mem_out_dec = 6'b001000;
12'd2811 : mem_out_dec = 6'b001001;
12'd2812 : mem_out_dec = 6'b001010;
12'd2813 : mem_out_dec = 6'b001010;
12'd2814 : mem_out_dec = 6'b001011;
12'd2815 : mem_out_dec = 6'b001100;
12'd2816 : mem_out_dec = 6'b111111;
12'd2817 : mem_out_dec = 6'b111111;
12'd2818 : mem_out_dec = 6'b111111;
12'd2819 : mem_out_dec = 6'b111111;
12'd2820 : mem_out_dec = 6'b111111;
12'd2821 : mem_out_dec = 6'b111111;
12'd2822 : mem_out_dec = 6'b111111;
12'd2823 : mem_out_dec = 6'b111111;
12'd2824 : mem_out_dec = 6'b111111;
12'd2825 : mem_out_dec = 6'b111111;
12'd2826 : mem_out_dec = 6'b111111;
12'd2827 : mem_out_dec = 6'b111111;
12'd2828 : mem_out_dec = 6'b111111;
12'd2829 : mem_out_dec = 6'b111111;
12'd2830 : mem_out_dec = 6'b111111;
12'd2831 : mem_out_dec = 6'b111111;
12'd2832 : mem_out_dec = 6'b111111;
12'd2833 : mem_out_dec = 6'b111111;
12'd2834 : mem_out_dec = 6'b111111;
12'd2835 : mem_out_dec = 6'b111111;
12'd2836 : mem_out_dec = 6'b111111;
12'd2837 : mem_out_dec = 6'b111111;
12'd2838 : mem_out_dec = 6'b111111;
12'd2839 : mem_out_dec = 6'b111111;
12'd2840 : mem_out_dec = 6'b111111;
12'd2841 : mem_out_dec = 6'b111111;
12'd2842 : mem_out_dec = 6'b111111;
12'd2843 : mem_out_dec = 6'b111111;
12'd2844 : mem_out_dec = 6'b111111;
12'd2845 : mem_out_dec = 6'b111111;
12'd2846 : mem_out_dec = 6'b111111;
12'd2847 : mem_out_dec = 6'b111111;
12'd2848 : mem_out_dec = 6'b111111;
12'd2849 : mem_out_dec = 6'b111111;
12'd2850 : mem_out_dec = 6'b111111;
12'd2851 : mem_out_dec = 6'b111111;
12'd2852 : mem_out_dec = 6'b111111;
12'd2853 : mem_out_dec = 6'b111111;
12'd2854 : mem_out_dec = 6'b111111;
12'd2855 : mem_out_dec = 6'b111111;
12'd2856 : mem_out_dec = 6'b111111;
12'd2857 : mem_out_dec = 6'b111111;
12'd2858 : mem_out_dec = 6'b111111;
12'd2859 : mem_out_dec = 6'b111111;
12'd2860 : mem_out_dec = 6'b111111;
12'd2861 : mem_out_dec = 6'b111111;
12'd2862 : mem_out_dec = 6'b111111;
12'd2863 : mem_out_dec = 6'b111111;
12'd2864 : mem_out_dec = 6'b111111;
12'd2865 : mem_out_dec = 6'b111111;
12'd2866 : mem_out_dec = 6'b000011;
12'd2867 : mem_out_dec = 6'b000100;
12'd2868 : mem_out_dec = 6'b000100;
12'd2869 : mem_out_dec = 6'b000101;
12'd2870 : mem_out_dec = 6'b000110;
12'd2871 : mem_out_dec = 6'b000110;
12'd2872 : mem_out_dec = 6'b000110;
12'd2873 : mem_out_dec = 6'b000111;
12'd2874 : mem_out_dec = 6'b001000;
12'd2875 : mem_out_dec = 6'b001001;
12'd2876 : mem_out_dec = 6'b001001;
12'd2877 : mem_out_dec = 6'b001010;
12'd2878 : mem_out_dec = 6'b001011;
12'd2879 : mem_out_dec = 6'b001100;
12'd2880 : mem_out_dec = 6'b111111;
12'd2881 : mem_out_dec = 6'b111111;
12'd2882 : mem_out_dec = 6'b111111;
12'd2883 : mem_out_dec = 6'b111111;
12'd2884 : mem_out_dec = 6'b111111;
12'd2885 : mem_out_dec = 6'b111111;
12'd2886 : mem_out_dec = 6'b111111;
12'd2887 : mem_out_dec = 6'b111111;
12'd2888 : mem_out_dec = 6'b111111;
12'd2889 : mem_out_dec = 6'b111111;
12'd2890 : mem_out_dec = 6'b111111;
12'd2891 : mem_out_dec = 6'b111111;
12'd2892 : mem_out_dec = 6'b111111;
12'd2893 : mem_out_dec = 6'b111111;
12'd2894 : mem_out_dec = 6'b111111;
12'd2895 : mem_out_dec = 6'b111111;
12'd2896 : mem_out_dec = 6'b111111;
12'd2897 : mem_out_dec = 6'b111111;
12'd2898 : mem_out_dec = 6'b111111;
12'd2899 : mem_out_dec = 6'b111111;
12'd2900 : mem_out_dec = 6'b111111;
12'd2901 : mem_out_dec = 6'b111111;
12'd2902 : mem_out_dec = 6'b111111;
12'd2903 : mem_out_dec = 6'b111111;
12'd2904 : mem_out_dec = 6'b111111;
12'd2905 : mem_out_dec = 6'b111111;
12'd2906 : mem_out_dec = 6'b111111;
12'd2907 : mem_out_dec = 6'b111111;
12'd2908 : mem_out_dec = 6'b111111;
12'd2909 : mem_out_dec = 6'b111111;
12'd2910 : mem_out_dec = 6'b111111;
12'd2911 : mem_out_dec = 6'b111111;
12'd2912 : mem_out_dec = 6'b111111;
12'd2913 : mem_out_dec = 6'b111111;
12'd2914 : mem_out_dec = 6'b111111;
12'd2915 : mem_out_dec = 6'b111111;
12'd2916 : mem_out_dec = 6'b111111;
12'd2917 : mem_out_dec = 6'b111111;
12'd2918 : mem_out_dec = 6'b111111;
12'd2919 : mem_out_dec = 6'b111111;
12'd2920 : mem_out_dec = 6'b111111;
12'd2921 : mem_out_dec = 6'b111111;
12'd2922 : mem_out_dec = 6'b111111;
12'd2923 : mem_out_dec = 6'b111111;
12'd2924 : mem_out_dec = 6'b111111;
12'd2925 : mem_out_dec = 6'b111111;
12'd2926 : mem_out_dec = 6'b111111;
12'd2927 : mem_out_dec = 6'b111111;
12'd2928 : mem_out_dec = 6'b111111;
12'd2929 : mem_out_dec = 6'b111111;
12'd2930 : mem_out_dec = 6'b111111;
12'd2931 : mem_out_dec = 6'b000100;
12'd2932 : mem_out_dec = 6'b000100;
12'd2933 : mem_out_dec = 6'b000101;
12'd2934 : mem_out_dec = 6'b000101;
12'd2935 : mem_out_dec = 6'b000110;
12'd2936 : mem_out_dec = 6'b000110;
12'd2937 : mem_out_dec = 6'b000111;
12'd2938 : mem_out_dec = 6'b001000;
12'd2939 : mem_out_dec = 6'b001000;
12'd2940 : mem_out_dec = 6'b001001;
12'd2941 : mem_out_dec = 6'b001010;
12'd2942 : mem_out_dec = 6'b001011;
12'd2943 : mem_out_dec = 6'b001011;
12'd2944 : mem_out_dec = 6'b111111;
12'd2945 : mem_out_dec = 6'b111111;
12'd2946 : mem_out_dec = 6'b111111;
12'd2947 : mem_out_dec = 6'b111111;
12'd2948 : mem_out_dec = 6'b111111;
12'd2949 : mem_out_dec = 6'b111111;
12'd2950 : mem_out_dec = 6'b111111;
12'd2951 : mem_out_dec = 6'b111111;
12'd2952 : mem_out_dec = 6'b111111;
12'd2953 : mem_out_dec = 6'b111111;
12'd2954 : mem_out_dec = 6'b111111;
12'd2955 : mem_out_dec = 6'b111111;
12'd2956 : mem_out_dec = 6'b111111;
12'd2957 : mem_out_dec = 6'b111111;
12'd2958 : mem_out_dec = 6'b111111;
12'd2959 : mem_out_dec = 6'b111111;
12'd2960 : mem_out_dec = 6'b111111;
12'd2961 : mem_out_dec = 6'b111111;
12'd2962 : mem_out_dec = 6'b111111;
12'd2963 : mem_out_dec = 6'b111111;
12'd2964 : mem_out_dec = 6'b111111;
12'd2965 : mem_out_dec = 6'b111111;
12'd2966 : mem_out_dec = 6'b111111;
12'd2967 : mem_out_dec = 6'b111111;
12'd2968 : mem_out_dec = 6'b111111;
12'd2969 : mem_out_dec = 6'b111111;
12'd2970 : mem_out_dec = 6'b111111;
12'd2971 : mem_out_dec = 6'b111111;
12'd2972 : mem_out_dec = 6'b111111;
12'd2973 : mem_out_dec = 6'b111111;
12'd2974 : mem_out_dec = 6'b111111;
12'd2975 : mem_out_dec = 6'b111111;
12'd2976 : mem_out_dec = 6'b111111;
12'd2977 : mem_out_dec = 6'b111111;
12'd2978 : mem_out_dec = 6'b111111;
12'd2979 : mem_out_dec = 6'b111111;
12'd2980 : mem_out_dec = 6'b111111;
12'd2981 : mem_out_dec = 6'b111111;
12'd2982 : mem_out_dec = 6'b111111;
12'd2983 : mem_out_dec = 6'b111111;
12'd2984 : mem_out_dec = 6'b111111;
12'd2985 : mem_out_dec = 6'b111111;
12'd2986 : mem_out_dec = 6'b111111;
12'd2987 : mem_out_dec = 6'b111111;
12'd2988 : mem_out_dec = 6'b111111;
12'd2989 : mem_out_dec = 6'b111111;
12'd2990 : mem_out_dec = 6'b111111;
12'd2991 : mem_out_dec = 6'b111111;
12'd2992 : mem_out_dec = 6'b111111;
12'd2993 : mem_out_dec = 6'b111111;
12'd2994 : mem_out_dec = 6'b111111;
12'd2995 : mem_out_dec = 6'b111111;
12'd2996 : mem_out_dec = 6'b000100;
12'd2997 : mem_out_dec = 6'b000101;
12'd2998 : mem_out_dec = 6'b000101;
12'd2999 : mem_out_dec = 6'b000110;
12'd3000 : mem_out_dec = 6'b000110;
12'd3001 : mem_out_dec = 6'b000111;
12'd3002 : mem_out_dec = 6'b000111;
12'd3003 : mem_out_dec = 6'b001000;
12'd3004 : mem_out_dec = 6'b001001;
12'd3005 : mem_out_dec = 6'b001010;
12'd3006 : mem_out_dec = 6'b001010;
12'd3007 : mem_out_dec = 6'b001011;
12'd3008 : mem_out_dec = 6'b111111;
12'd3009 : mem_out_dec = 6'b111111;
12'd3010 : mem_out_dec = 6'b111111;
12'd3011 : mem_out_dec = 6'b111111;
12'd3012 : mem_out_dec = 6'b111111;
12'd3013 : mem_out_dec = 6'b111111;
12'd3014 : mem_out_dec = 6'b111111;
12'd3015 : mem_out_dec = 6'b111111;
12'd3016 : mem_out_dec = 6'b111111;
12'd3017 : mem_out_dec = 6'b111111;
12'd3018 : mem_out_dec = 6'b111111;
12'd3019 : mem_out_dec = 6'b111111;
12'd3020 : mem_out_dec = 6'b111111;
12'd3021 : mem_out_dec = 6'b111111;
12'd3022 : mem_out_dec = 6'b111111;
12'd3023 : mem_out_dec = 6'b111111;
12'd3024 : mem_out_dec = 6'b111111;
12'd3025 : mem_out_dec = 6'b111111;
12'd3026 : mem_out_dec = 6'b111111;
12'd3027 : mem_out_dec = 6'b111111;
12'd3028 : mem_out_dec = 6'b111111;
12'd3029 : mem_out_dec = 6'b111111;
12'd3030 : mem_out_dec = 6'b111111;
12'd3031 : mem_out_dec = 6'b111111;
12'd3032 : mem_out_dec = 6'b111111;
12'd3033 : mem_out_dec = 6'b111111;
12'd3034 : mem_out_dec = 6'b111111;
12'd3035 : mem_out_dec = 6'b111111;
12'd3036 : mem_out_dec = 6'b111111;
12'd3037 : mem_out_dec = 6'b111111;
12'd3038 : mem_out_dec = 6'b111111;
12'd3039 : mem_out_dec = 6'b111111;
12'd3040 : mem_out_dec = 6'b111111;
12'd3041 : mem_out_dec = 6'b111111;
12'd3042 : mem_out_dec = 6'b111111;
12'd3043 : mem_out_dec = 6'b111111;
12'd3044 : mem_out_dec = 6'b111111;
12'd3045 : mem_out_dec = 6'b111111;
12'd3046 : mem_out_dec = 6'b111111;
12'd3047 : mem_out_dec = 6'b111111;
12'd3048 : mem_out_dec = 6'b111111;
12'd3049 : mem_out_dec = 6'b111111;
12'd3050 : mem_out_dec = 6'b111111;
12'd3051 : mem_out_dec = 6'b111111;
12'd3052 : mem_out_dec = 6'b111111;
12'd3053 : mem_out_dec = 6'b111111;
12'd3054 : mem_out_dec = 6'b111111;
12'd3055 : mem_out_dec = 6'b111111;
12'd3056 : mem_out_dec = 6'b111111;
12'd3057 : mem_out_dec = 6'b111111;
12'd3058 : mem_out_dec = 6'b111111;
12'd3059 : mem_out_dec = 6'b111111;
12'd3060 : mem_out_dec = 6'b111111;
12'd3061 : mem_out_dec = 6'b000100;
12'd3062 : mem_out_dec = 6'b000101;
12'd3063 : mem_out_dec = 6'b000110;
12'd3064 : mem_out_dec = 6'b000110;
12'd3065 : mem_out_dec = 6'b000111;
12'd3066 : mem_out_dec = 6'b000111;
12'd3067 : mem_out_dec = 6'b001000;
12'd3068 : mem_out_dec = 6'b001001;
12'd3069 : mem_out_dec = 6'b001001;
12'd3070 : mem_out_dec = 6'b001010;
12'd3071 : mem_out_dec = 6'b001011;
12'd3072 : mem_out_dec = 6'b111111;
12'd3073 : mem_out_dec = 6'b111111;
12'd3074 : mem_out_dec = 6'b111111;
12'd3075 : mem_out_dec = 6'b111111;
12'd3076 : mem_out_dec = 6'b111111;
12'd3077 : mem_out_dec = 6'b111111;
12'd3078 : mem_out_dec = 6'b111111;
12'd3079 : mem_out_dec = 6'b111111;
12'd3080 : mem_out_dec = 6'b111111;
12'd3081 : mem_out_dec = 6'b111111;
12'd3082 : mem_out_dec = 6'b111111;
12'd3083 : mem_out_dec = 6'b111111;
12'd3084 : mem_out_dec = 6'b111111;
12'd3085 : mem_out_dec = 6'b111111;
12'd3086 : mem_out_dec = 6'b111111;
12'd3087 : mem_out_dec = 6'b111111;
12'd3088 : mem_out_dec = 6'b111111;
12'd3089 : mem_out_dec = 6'b111111;
12'd3090 : mem_out_dec = 6'b111111;
12'd3091 : mem_out_dec = 6'b111111;
12'd3092 : mem_out_dec = 6'b111111;
12'd3093 : mem_out_dec = 6'b111111;
12'd3094 : mem_out_dec = 6'b111111;
12'd3095 : mem_out_dec = 6'b111111;
12'd3096 : mem_out_dec = 6'b111111;
12'd3097 : mem_out_dec = 6'b111111;
12'd3098 : mem_out_dec = 6'b111111;
12'd3099 : mem_out_dec = 6'b111111;
12'd3100 : mem_out_dec = 6'b111111;
12'd3101 : mem_out_dec = 6'b111111;
12'd3102 : mem_out_dec = 6'b111111;
12'd3103 : mem_out_dec = 6'b111111;
12'd3104 : mem_out_dec = 6'b111111;
12'd3105 : mem_out_dec = 6'b111111;
12'd3106 : mem_out_dec = 6'b111111;
12'd3107 : mem_out_dec = 6'b111111;
12'd3108 : mem_out_dec = 6'b111111;
12'd3109 : mem_out_dec = 6'b111111;
12'd3110 : mem_out_dec = 6'b111111;
12'd3111 : mem_out_dec = 6'b111111;
12'd3112 : mem_out_dec = 6'b111111;
12'd3113 : mem_out_dec = 6'b111111;
12'd3114 : mem_out_dec = 6'b111111;
12'd3115 : mem_out_dec = 6'b111111;
12'd3116 : mem_out_dec = 6'b111111;
12'd3117 : mem_out_dec = 6'b111111;
12'd3118 : mem_out_dec = 6'b111111;
12'd3119 : mem_out_dec = 6'b111111;
12'd3120 : mem_out_dec = 6'b111111;
12'd3121 : mem_out_dec = 6'b111111;
12'd3122 : mem_out_dec = 6'b111111;
12'd3123 : mem_out_dec = 6'b111111;
12'd3124 : mem_out_dec = 6'b111111;
12'd3125 : mem_out_dec = 6'b111111;
12'd3126 : mem_out_dec = 6'b000100;
12'd3127 : mem_out_dec = 6'b000101;
12'd3128 : mem_out_dec = 6'b000101;
12'd3129 : mem_out_dec = 6'b000110;
12'd3130 : mem_out_dec = 6'b000110;
12'd3131 : mem_out_dec = 6'b000111;
12'd3132 : mem_out_dec = 6'b001000;
12'd3133 : mem_out_dec = 6'b001000;
12'd3134 : mem_out_dec = 6'b001001;
12'd3135 : mem_out_dec = 6'b001010;
12'd3136 : mem_out_dec = 6'b111111;
12'd3137 : mem_out_dec = 6'b111111;
12'd3138 : mem_out_dec = 6'b111111;
12'd3139 : mem_out_dec = 6'b111111;
12'd3140 : mem_out_dec = 6'b111111;
12'd3141 : mem_out_dec = 6'b111111;
12'd3142 : mem_out_dec = 6'b111111;
12'd3143 : mem_out_dec = 6'b111111;
12'd3144 : mem_out_dec = 6'b111111;
12'd3145 : mem_out_dec = 6'b111111;
12'd3146 : mem_out_dec = 6'b111111;
12'd3147 : mem_out_dec = 6'b111111;
12'd3148 : mem_out_dec = 6'b111111;
12'd3149 : mem_out_dec = 6'b111111;
12'd3150 : mem_out_dec = 6'b111111;
12'd3151 : mem_out_dec = 6'b111111;
12'd3152 : mem_out_dec = 6'b111111;
12'd3153 : mem_out_dec = 6'b111111;
12'd3154 : mem_out_dec = 6'b111111;
12'd3155 : mem_out_dec = 6'b111111;
12'd3156 : mem_out_dec = 6'b111111;
12'd3157 : mem_out_dec = 6'b111111;
12'd3158 : mem_out_dec = 6'b111111;
12'd3159 : mem_out_dec = 6'b111111;
12'd3160 : mem_out_dec = 6'b111111;
12'd3161 : mem_out_dec = 6'b111111;
12'd3162 : mem_out_dec = 6'b111111;
12'd3163 : mem_out_dec = 6'b111111;
12'd3164 : mem_out_dec = 6'b111111;
12'd3165 : mem_out_dec = 6'b111111;
12'd3166 : mem_out_dec = 6'b111111;
12'd3167 : mem_out_dec = 6'b111111;
12'd3168 : mem_out_dec = 6'b111111;
12'd3169 : mem_out_dec = 6'b111111;
12'd3170 : mem_out_dec = 6'b111111;
12'd3171 : mem_out_dec = 6'b111111;
12'd3172 : mem_out_dec = 6'b111111;
12'd3173 : mem_out_dec = 6'b111111;
12'd3174 : mem_out_dec = 6'b111111;
12'd3175 : mem_out_dec = 6'b111111;
12'd3176 : mem_out_dec = 6'b111111;
12'd3177 : mem_out_dec = 6'b111111;
12'd3178 : mem_out_dec = 6'b111111;
12'd3179 : mem_out_dec = 6'b111111;
12'd3180 : mem_out_dec = 6'b111111;
12'd3181 : mem_out_dec = 6'b111111;
12'd3182 : mem_out_dec = 6'b111111;
12'd3183 : mem_out_dec = 6'b111111;
12'd3184 : mem_out_dec = 6'b111111;
12'd3185 : mem_out_dec = 6'b111111;
12'd3186 : mem_out_dec = 6'b111111;
12'd3187 : mem_out_dec = 6'b111111;
12'd3188 : mem_out_dec = 6'b111111;
12'd3189 : mem_out_dec = 6'b111111;
12'd3190 : mem_out_dec = 6'b111111;
12'd3191 : mem_out_dec = 6'b000100;
12'd3192 : mem_out_dec = 6'b000100;
12'd3193 : mem_out_dec = 6'b000101;
12'd3194 : mem_out_dec = 6'b000110;
12'd3195 : mem_out_dec = 6'b000110;
12'd3196 : mem_out_dec = 6'b000111;
12'd3197 : mem_out_dec = 6'b001000;
12'd3198 : mem_out_dec = 6'b001000;
12'd3199 : mem_out_dec = 6'b001001;
12'd3200 : mem_out_dec = 6'b111111;
12'd3201 : mem_out_dec = 6'b111111;
12'd3202 : mem_out_dec = 6'b111111;
12'd3203 : mem_out_dec = 6'b111111;
12'd3204 : mem_out_dec = 6'b111111;
12'd3205 : mem_out_dec = 6'b111111;
12'd3206 : mem_out_dec = 6'b111111;
12'd3207 : mem_out_dec = 6'b111111;
12'd3208 : mem_out_dec = 6'b111111;
12'd3209 : mem_out_dec = 6'b111111;
12'd3210 : mem_out_dec = 6'b111111;
12'd3211 : mem_out_dec = 6'b111111;
12'd3212 : mem_out_dec = 6'b111111;
12'd3213 : mem_out_dec = 6'b111111;
12'd3214 : mem_out_dec = 6'b111111;
12'd3215 : mem_out_dec = 6'b111111;
12'd3216 : mem_out_dec = 6'b111111;
12'd3217 : mem_out_dec = 6'b111111;
12'd3218 : mem_out_dec = 6'b111111;
12'd3219 : mem_out_dec = 6'b111111;
12'd3220 : mem_out_dec = 6'b111111;
12'd3221 : mem_out_dec = 6'b111111;
12'd3222 : mem_out_dec = 6'b111111;
12'd3223 : mem_out_dec = 6'b111111;
12'd3224 : mem_out_dec = 6'b111111;
12'd3225 : mem_out_dec = 6'b111111;
12'd3226 : mem_out_dec = 6'b111111;
12'd3227 : mem_out_dec = 6'b111111;
12'd3228 : mem_out_dec = 6'b111111;
12'd3229 : mem_out_dec = 6'b111111;
12'd3230 : mem_out_dec = 6'b111111;
12'd3231 : mem_out_dec = 6'b111111;
12'd3232 : mem_out_dec = 6'b111111;
12'd3233 : mem_out_dec = 6'b111111;
12'd3234 : mem_out_dec = 6'b111111;
12'd3235 : mem_out_dec = 6'b111111;
12'd3236 : mem_out_dec = 6'b111111;
12'd3237 : mem_out_dec = 6'b111111;
12'd3238 : mem_out_dec = 6'b111111;
12'd3239 : mem_out_dec = 6'b111111;
12'd3240 : mem_out_dec = 6'b111111;
12'd3241 : mem_out_dec = 6'b111111;
12'd3242 : mem_out_dec = 6'b111111;
12'd3243 : mem_out_dec = 6'b111111;
12'd3244 : mem_out_dec = 6'b111111;
12'd3245 : mem_out_dec = 6'b111111;
12'd3246 : mem_out_dec = 6'b111111;
12'd3247 : mem_out_dec = 6'b111111;
12'd3248 : mem_out_dec = 6'b111111;
12'd3249 : mem_out_dec = 6'b111111;
12'd3250 : mem_out_dec = 6'b111111;
12'd3251 : mem_out_dec = 6'b111111;
12'd3252 : mem_out_dec = 6'b111111;
12'd3253 : mem_out_dec = 6'b111111;
12'd3254 : mem_out_dec = 6'b111111;
12'd3255 : mem_out_dec = 6'b111111;
12'd3256 : mem_out_dec = 6'b000100;
12'd3257 : mem_out_dec = 6'b000100;
12'd3258 : mem_out_dec = 6'b000101;
12'd3259 : mem_out_dec = 6'b000110;
12'd3260 : mem_out_dec = 6'b000110;
12'd3261 : mem_out_dec = 6'b000111;
12'd3262 : mem_out_dec = 6'b001000;
12'd3263 : mem_out_dec = 6'b001001;
12'd3264 : mem_out_dec = 6'b111111;
12'd3265 : mem_out_dec = 6'b111111;
12'd3266 : mem_out_dec = 6'b111111;
12'd3267 : mem_out_dec = 6'b111111;
12'd3268 : mem_out_dec = 6'b111111;
12'd3269 : mem_out_dec = 6'b111111;
12'd3270 : mem_out_dec = 6'b111111;
12'd3271 : mem_out_dec = 6'b111111;
12'd3272 : mem_out_dec = 6'b111111;
12'd3273 : mem_out_dec = 6'b111111;
12'd3274 : mem_out_dec = 6'b111111;
12'd3275 : mem_out_dec = 6'b111111;
12'd3276 : mem_out_dec = 6'b111111;
12'd3277 : mem_out_dec = 6'b111111;
12'd3278 : mem_out_dec = 6'b111111;
12'd3279 : mem_out_dec = 6'b111111;
12'd3280 : mem_out_dec = 6'b111111;
12'd3281 : mem_out_dec = 6'b111111;
12'd3282 : mem_out_dec = 6'b111111;
12'd3283 : mem_out_dec = 6'b111111;
12'd3284 : mem_out_dec = 6'b111111;
12'd3285 : mem_out_dec = 6'b111111;
12'd3286 : mem_out_dec = 6'b111111;
12'd3287 : mem_out_dec = 6'b111111;
12'd3288 : mem_out_dec = 6'b111111;
12'd3289 : mem_out_dec = 6'b111111;
12'd3290 : mem_out_dec = 6'b111111;
12'd3291 : mem_out_dec = 6'b111111;
12'd3292 : mem_out_dec = 6'b111111;
12'd3293 : mem_out_dec = 6'b111111;
12'd3294 : mem_out_dec = 6'b111111;
12'd3295 : mem_out_dec = 6'b111111;
12'd3296 : mem_out_dec = 6'b111111;
12'd3297 : mem_out_dec = 6'b111111;
12'd3298 : mem_out_dec = 6'b111111;
12'd3299 : mem_out_dec = 6'b111111;
12'd3300 : mem_out_dec = 6'b111111;
12'd3301 : mem_out_dec = 6'b111111;
12'd3302 : mem_out_dec = 6'b111111;
12'd3303 : mem_out_dec = 6'b111111;
12'd3304 : mem_out_dec = 6'b111111;
12'd3305 : mem_out_dec = 6'b111111;
12'd3306 : mem_out_dec = 6'b111111;
12'd3307 : mem_out_dec = 6'b111111;
12'd3308 : mem_out_dec = 6'b111111;
12'd3309 : mem_out_dec = 6'b111111;
12'd3310 : mem_out_dec = 6'b111111;
12'd3311 : mem_out_dec = 6'b111111;
12'd3312 : mem_out_dec = 6'b111111;
12'd3313 : mem_out_dec = 6'b111111;
12'd3314 : mem_out_dec = 6'b111111;
12'd3315 : mem_out_dec = 6'b111111;
12'd3316 : mem_out_dec = 6'b111111;
12'd3317 : mem_out_dec = 6'b111111;
12'd3318 : mem_out_dec = 6'b111111;
12'd3319 : mem_out_dec = 6'b111111;
12'd3320 : mem_out_dec = 6'b111111;
12'd3321 : mem_out_dec = 6'b000100;
12'd3322 : mem_out_dec = 6'b000100;
12'd3323 : mem_out_dec = 6'b000101;
12'd3324 : mem_out_dec = 6'b000110;
12'd3325 : mem_out_dec = 6'b000111;
12'd3326 : mem_out_dec = 6'b001000;
12'd3327 : mem_out_dec = 6'b001000;
12'd3328 : mem_out_dec = 6'b111111;
12'd3329 : mem_out_dec = 6'b111111;
12'd3330 : mem_out_dec = 6'b111111;
12'd3331 : mem_out_dec = 6'b111111;
12'd3332 : mem_out_dec = 6'b111111;
12'd3333 : mem_out_dec = 6'b111111;
12'd3334 : mem_out_dec = 6'b111111;
12'd3335 : mem_out_dec = 6'b111111;
12'd3336 : mem_out_dec = 6'b111111;
12'd3337 : mem_out_dec = 6'b111111;
12'd3338 : mem_out_dec = 6'b111111;
12'd3339 : mem_out_dec = 6'b111111;
12'd3340 : mem_out_dec = 6'b111111;
12'd3341 : mem_out_dec = 6'b111111;
12'd3342 : mem_out_dec = 6'b111111;
12'd3343 : mem_out_dec = 6'b111111;
12'd3344 : mem_out_dec = 6'b111111;
12'd3345 : mem_out_dec = 6'b111111;
12'd3346 : mem_out_dec = 6'b111111;
12'd3347 : mem_out_dec = 6'b111111;
12'd3348 : mem_out_dec = 6'b111111;
12'd3349 : mem_out_dec = 6'b111111;
12'd3350 : mem_out_dec = 6'b111111;
12'd3351 : mem_out_dec = 6'b111111;
12'd3352 : mem_out_dec = 6'b111111;
12'd3353 : mem_out_dec = 6'b111111;
12'd3354 : mem_out_dec = 6'b111111;
12'd3355 : mem_out_dec = 6'b111111;
12'd3356 : mem_out_dec = 6'b111111;
12'd3357 : mem_out_dec = 6'b111111;
12'd3358 : mem_out_dec = 6'b111111;
12'd3359 : mem_out_dec = 6'b111111;
12'd3360 : mem_out_dec = 6'b111111;
12'd3361 : mem_out_dec = 6'b111111;
12'd3362 : mem_out_dec = 6'b111111;
12'd3363 : mem_out_dec = 6'b111111;
12'd3364 : mem_out_dec = 6'b111111;
12'd3365 : mem_out_dec = 6'b111111;
12'd3366 : mem_out_dec = 6'b111111;
12'd3367 : mem_out_dec = 6'b111111;
12'd3368 : mem_out_dec = 6'b111111;
12'd3369 : mem_out_dec = 6'b111111;
12'd3370 : mem_out_dec = 6'b111111;
12'd3371 : mem_out_dec = 6'b111111;
12'd3372 : mem_out_dec = 6'b111111;
12'd3373 : mem_out_dec = 6'b111111;
12'd3374 : mem_out_dec = 6'b111111;
12'd3375 : mem_out_dec = 6'b111111;
12'd3376 : mem_out_dec = 6'b111111;
12'd3377 : mem_out_dec = 6'b111111;
12'd3378 : mem_out_dec = 6'b111111;
12'd3379 : mem_out_dec = 6'b111111;
12'd3380 : mem_out_dec = 6'b111111;
12'd3381 : mem_out_dec = 6'b111111;
12'd3382 : mem_out_dec = 6'b111111;
12'd3383 : mem_out_dec = 6'b111111;
12'd3384 : mem_out_dec = 6'b111111;
12'd3385 : mem_out_dec = 6'b111111;
12'd3386 : mem_out_dec = 6'b000100;
12'd3387 : mem_out_dec = 6'b000101;
12'd3388 : mem_out_dec = 6'b000110;
12'd3389 : mem_out_dec = 6'b000110;
12'd3390 : mem_out_dec = 6'b000111;
12'd3391 : mem_out_dec = 6'b001000;
12'd3392 : mem_out_dec = 6'b111111;
12'd3393 : mem_out_dec = 6'b111111;
12'd3394 : mem_out_dec = 6'b111111;
12'd3395 : mem_out_dec = 6'b111111;
12'd3396 : mem_out_dec = 6'b111111;
12'd3397 : mem_out_dec = 6'b111111;
12'd3398 : mem_out_dec = 6'b111111;
12'd3399 : mem_out_dec = 6'b111111;
12'd3400 : mem_out_dec = 6'b111111;
12'd3401 : mem_out_dec = 6'b111111;
12'd3402 : mem_out_dec = 6'b111111;
12'd3403 : mem_out_dec = 6'b111111;
12'd3404 : mem_out_dec = 6'b111111;
12'd3405 : mem_out_dec = 6'b111111;
12'd3406 : mem_out_dec = 6'b111111;
12'd3407 : mem_out_dec = 6'b111111;
12'd3408 : mem_out_dec = 6'b111111;
12'd3409 : mem_out_dec = 6'b111111;
12'd3410 : mem_out_dec = 6'b111111;
12'd3411 : mem_out_dec = 6'b111111;
12'd3412 : mem_out_dec = 6'b111111;
12'd3413 : mem_out_dec = 6'b111111;
12'd3414 : mem_out_dec = 6'b111111;
12'd3415 : mem_out_dec = 6'b111111;
12'd3416 : mem_out_dec = 6'b111111;
12'd3417 : mem_out_dec = 6'b111111;
12'd3418 : mem_out_dec = 6'b111111;
12'd3419 : mem_out_dec = 6'b111111;
12'd3420 : mem_out_dec = 6'b111111;
12'd3421 : mem_out_dec = 6'b111111;
12'd3422 : mem_out_dec = 6'b111111;
12'd3423 : mem_out_dec = 6'b111111;
12'd3424 : mem_out_dec = 6'b111111;
12'd3425 : mem_out_dec = 6'b111111;
12'd3426 : mem_out_dec = 6'b111111;
12'd3427 : mem_out_dec = 6'b111111;
12'd3428 : mem_out_dec = 6'b111111;
12'd3429 : mem_out_dec = 6'b111111;
12'd3430 : mem_out_dec = 6'b111111;
12'd3431 : mem_out_dec = 6'b111111;
12'd3432 : mem_out_dec = 6'b111111;
12'd3433 : mem_out_dec = 6'b111111;
12'd3434 : mem_out_dec = 6'b111111;
12'd3435 : mem_out_dec = 6'b111111;
12'd3436 : mem_out_dec = 6'b111111;
12'd3437 : mem_out_dec = 6'b111111;
12'd3438 : mem_out_dec = 6'b111111;
12'd3439 : mem_out_dec = 6'b111111;
12'd3440 : mem_out_dec = 6'b111111;
12'd3441 : mem_out_dec = 6'b111111;
12'd3442 : mem_out_dec = 6'b111111;
12'd3443 : mem_out_dec = 6'b111111;
12'd3444 : mem_out_dec = 6'b111111;
12'd3445 : mem_out_dec = 6'b111111;
12'd3446 : mem_out_dec = 6'b111111;
12'd3447 : mem_out_dec = 6'b111111;
12'd3448 : mem_out_dec = 6'b111111;
12'd3449 : mem_out_dec = 6'b111111;
12'd3450 : mem_out_dec = 6'b111111;
12'd3451 : mem_out_dec = 6'b000100;
12'd3452 : mem_out_dec = 6'b000101;
12'd3453 : mem_out_dec = 6'b000110;
12'd3454 : mem_out_dec = 6'b000111;
12'd3455 : mem_out_dec = 6'b001000;
12'd3456 : mem_out_dec = 6'b111111;
12'd3457 : mem_out_dec = 6'b111111;
12'd3458 : mem_out_dec = 6'b111111;
12'd3459 : mem_out_dec = 6'b111111;
12'd3460 : mem_out_dec = 6'b111111;
12'd3461 : mem_out_dec = 6'b111111;
12'd3462 : mem_out_dec = 6'b111111;
12'd3463 : mem_out_dec = 6'b111111;
12'd3464 : mem_out_dec = 6'b111111;
12'd3465 : mem_out_dec = 6'b111111;
12'd3466 : mem_out_dec = 6'b111111;
12'd3467 : mem_out_dec = 6'b111111;
12'd3468 : mem_out_dec = 6'b111111;
12'd3469 : mem_out_dec = 6'b111111;
12'd3470 : mem_out_dec = 6'b111111;
12'd3471 : mem_out_dec = 6'b111111;
12'd3472 : mem_out_dec = 6'b111111;
12'd3473 : mem_out_dec = 6'b111111;
12'd3474 : mem_out_dec = 6'b111111;
12'd3475 : mem_out_dec = 6'b111111;
12'd3476 : mem_out_dec = 6'b111111;
12'd3477 : mem_out_dec = 6'b111111;
12'd3478 : mem_out_dec = 6'b111111;
12'd3479 : mem_out_dec = 6'b111111;
12'd3480 : mem_out_dec = 6'b111111;
12'd3481 : mem_out_dec = 6'b111111;
12'd3482 : mem_out_dec = 6'b111111;
12'd3483 : mem_out_dec = 6'b111111;
12'd3484 : mem_out_dec = 6'b111111;
12'd3485 : mem_out_dec = 6'b111111;
12'd3486 : mem_out_dec = 6'b111111;
12'd3487 : mem_out_dec = 6'b111111;
12'd3488 : mem_out_dec = 6'b111111;
12'd3489 : mem_out_dec = 6'b111111;
12'd3490 : mem_out_dec = 6'b111111;
12'd3491 : mem_out_dec = 6'b111111;
12'd3492 : mem_out_dec = 6'b111111;
12'd3493 : mem_out_dec = 6'b111111;
12'd3494 : mem_out_dec = 6'b111111;
12'd3495 : mem_out_dec = 6'b111111;
12'd3496 : mem_out_dec = 6'b111111;
12'd3497 : mem_out_dec = 6'b111111;
12'd3498 : mem_out_dec = 6'b111111;
12'd3499 : mem_out_dec = 6'b111111;
12'd3500 : mem_out_dec = 6'b111111;
12'd3501 : mem_out_dec = 6'b111111;
12'd3502 : mem_out_dec = 6'b111111;
12'd3503 : mem_out_dec = 6'b111111;
12'd3504 : mem_out_dec = 6'b111111;
12'd3505 : mem_out_dec = 6'b111111;
12'd3506 : mem_out_dec = 6'b111111;
12'd3507 : mem_out_dec = 6'b111111;
12'd3508 : mem_out_dec = 6'b111111;
12'd3509 : mem_out_dec = 6'b111111;
12'd3510 : mem_out_dec = 6'b111111;
12'd3511 : mem_out_dec = 6'b111111;
12'd3512 : mem_out_dec = 6'b111111;
12'd3513 : mem_out_dec = 6'b111111;
12'd3514 : mem_out_dec = 6'b111111;
12'd3515 : mem_out_dec = 6'b111111;
12'd3516 : mem_out_dec = 6'b000101;
12'd3517 : mem_out_dec = 6'b000110;
12'd3518 : mem_out_dec = 6'b000110;
12'd3519 : mem_out_dec = 6'b000111;
12'd3520 : mem_out_dec = 6'b111111;
12'd3521 : mem_out_dec = 6'b111111;
12'd3522 : mem_out_dec = 6'b111111;
12'd3523 : mem_out_dec = 6'b111111;
12'd3524 : mem_out_dec = 6'b111111;
12'd3525 : mem_out_dec = 6'b111111;
12'd3526 : mem_out_dec = 6'b111111;
12'd3527 : mem_out_dec = 6'b111111;
12'd3528 : mem_out_dec = 6'b111111;
12'd3529 : mem_out_dec = 6'b111111;
12'd3530 : mem_out_dec = 6'b111111;
12'd3531 : mem_out_dec = 6'b111111;
12'd3532 : mem_out_dec = 6'b111111;
12'd3533 : mem_out_dec = 6'b111111;
12'd3534 : mem_out_dec = 6'b111111;
12'd3535 : mem_out_dec = 6'b111111;
12'd3536 : mem_out_dec = 6'b111111;
12'd3537 : mem_out_dec = 6'b111111;
12'd3538 : mem_out_dec = 6'b111111;
12'd3539 : mem_out_dec = 6'b111111;
12'd3540 : mem_out_dec = 6'b111111;
12'd3541 : mem_out_dec = 6'b111111;
12'd3542 : mem_out_dec = 6'b111111;
12'd3543 : mem_out_dec = 6'b111111;
12'd3544 : mem_out_dec = 6'b111111;
12'd3545 : mem_out_dec = 6'b111111;
12'd3546 : mem_out_dec = 6'b111111;
12'd3547 : mem_out_dec = 6'b111111;
12'd3548 : mem_out_dec = 6'b111111;
12'd3549 : mem_out_dec = 6'b111111;
12'd3550 : mem_out_dec = 6'b111111;
12'd3551 : mem_out_dec = 6'b111111;
12'd3552 : mem_out_dec = 6'b111111;
12'd3553 : mem_out_dec = 6'b111111;
12'd3554 : mem_out_dec = 6'b111111;
12'd3555 : mem_out_dec = 6'b111111;
12'd3556 : mem_out_dec = 6'b111111;
12'd3557 : mem_out_dec = 6'b111111;
12'd3558 : mem_out_dec = 6'b111111;
12'd3559 : mem_out_dec = 6'b111111;
12'd3560 : mem_out_dec = 6'b111111;
12'd3561 : mem_out_dec = 6'b111111;
12'd3562 : mem_out_dec = 6'b111111;
12'd3563 : mem_out_dec = 6'b111111;
12'd3564 : mem_out_dec = 6'b111111;
12'd3565 : mem_out_dec = 6'b111111;
12'd3566 : mem_out_dec = 6'b111111;
12'd3567 : mem_out_dec = 6'b111111;
12'd3568 : mem_out_dec = 6'b111111;
12'd3569 : mem_out_dec = 6'b111111;
12'd3570 : mem_out_dec = 6'b111111;
12'd3571 : mem_out_dec = 6'b111111;
12'd3572 : mem_out_dec = 6'b111111;
12'd3573 : mem_out_dec = 6'b111111;
12'd3574 : mem_out_dec = 6'b111111;
12'd3575 : mem_out_dec = 6'b111111;
12'd3576 : mem_out_dec = 6'b111111;
12'd3577 : mem_out_dec = 6'b111111;
12'd3578 : mem_out_dec = 6'b111111;
12'd3579 : mem_out_dec = 6'b111111;
12'd3580 : mem_out_dec = 6'b111111;
12'd3581 : mem_out_dec = 6'b000101;
12'd3582 : mem_out_dec = 6'b000110;
12'd3583 : mem_out_dec = 6'b000110;
12'd3584 : mem_out_dec = 6'b111111;
12'd3585 : mem_out_dec = 6'b111111;
12'd3586 : mem_out_dec = 6'b111111;
12'd3587 : mem_out_dec = 6'b111111;
12'd3588 : mem_out_dec = 6'b111111;
12'd3589 : mem_out_dec = 6'b111111;
12'd3590 : mem_out_dec = 6'b111111;
12'd3591 : mem_out_dec = 6'b111111;
12'd3592 : mem_out_dec = 6'b111111;
12'd3593 : mem_out_dec = 6'b111111;
12'd3594 : mem_out_dec = 6'b111111;
12'd3595 : mem_out_dec = 6'b111111;
12'd3596 : mem_out_dec = 6'b111111;
12'd3597 : mem_out_dec = 6'b111111;
12'd3598 : mem_out_dec = 6'b111111;
12'd3599 : mem_out_dec = 6'b111111;
12'd3600 : mem_out_dec = 6'b111111;
12'd3601 : mem_out_dec = 6'b111111;
12'd3602 : mem_out_dec = 6'b111111;
12'd3603 : mem_out_dec = 6'b111111;
12'd3604 : mem_out_dec = 6'b111111;
12'd3605 : mem_out_dec = 6'b111111;
12'd3606 : mem_out_dec = 6'b111111;
12'd3607 : mem_out_dec = 6'b111111;
12'd3608 : mem_out_dec = 6'b111111;
12'd3609 : mem_out_dec = 6'b111111;
12'd3610 : mem_out_dec = 6'b111111;
12'd3611 : mem_out_dec = 6'b111111;
12'd3612 : mem_out_dec = 6'b111111;
12'd3613 : mem_out_dec = 6'b111111;
12'd3614 : mem_out_dec = 6'b111111;
12'd3615 : mem_out_dec = 6'b111111;
12'd3616 : mem_out_dec = 6'b111111;
12'd3617 : mem_out_dec = 6'b111111;
12'd3618 : mem_out_dec = 6'b111111;
12'd3619 : mem_out_dec = 6'b111111;
12'd3620 : mem_out_dec = 6'b111111;
12'd3621 : mem_out_dec = 6'b111111;
12'd3622 : mem_out_dec = 6'b111111;
12'd3623 : mem_out_dec = 6'b111111;
12'd3624 : mem_out_dec = 6'b111111;
12'd3625 : mem_out_dec = 6'b111111;
12'd3626 : mem_out_dec = 6'b111111;
12'd3627 : mem_out_dec = 6'b111111;
12'd3628 : mem_out_dec = 6'b111111;
12'd3629 : mem_out_dec = 6'b111111;
12'd3630 : mem_out_dec = 6'b111111;
12'd3631 : mem_out_dec = 6'b111111;
12'd3632 : mem_out_dec = 6'b111111;
12'd3633 : mem_out_dec = 6'b111111;
12'd3634 : mem_out_dec = 6'b111111;
12'd3635 : mem_out_dec = 6'b111111;
12'd3636 : mem_out_dec = 6'b111111;
12'd3637 : mem_out_dec = 6'b111111;
12'd3638 : mem_out_dec = 6'b111111;
12'd3639 : mem_out_dec = 6'b111111;
12'd3640 : mem_out_dec = 6'b111111;
12'd3641 : mem_out_dec = 6'b111111;
12'd3642 : mem_out_dec = 6'b111111;
12'd3643 : mem_out_dec = 6'b111111;
12'd3644 : mem_out_dec = 6'b111111;
12'd3645 : mem_out_dec = 6'b111111;
12'd3646 : mem_out_dec = 6'b000100;
12'd3647 : mem_out_dec = 6'b000101;
12'd3648 : mem_out_dec = 6'b111111;
12'd3649 : mem_out_dec = 6'b111111;
12'd3650 : mem_out_dec = 6'b111111;
12'd3651 : mem_out_dec = 6'b111111;
12'd3652 : mem_out_dec = 6'b111111;
12'd3653 : mem_out_dec = 6'b111111;
12'd3654 : mem_out_dec = 6'b111111;
12'd3655 : mem_out_dec = 6'b111111;
12'd3656 : mem_out_dec = 6'b111111;
12'd3657 : mem_out_dec = 6'b111111;
12'd3658 : mem_out_dec = 6'b111111;
12'd3659 : mem_out_dec = 6'b111111;
12'd3660 : mem_out_dec = 6'b111111;
12'd3661 : mem_out_dec = 6'b111111;
12'd3662 : mem_out_dec = 6'b111111;
12'd3663 : mem_out_dec = 6'b111111;
12'd3664 : mem_out_dec = 6'b111111;
12'd3665 : mem_out_dec = 6'b111111;
12'd3666 : mem_out_dec = 6'b111111;
12'd3667 : mem_out_dec = 6'b111111;
12'd3668 : mem_out_dec = 6'b111111;
12'd3669 : mem_out_dec = 6'b111111;
12'd3670 : mem_out_dec = 6'b111111;
12'd3671 : mem_out_dec = 6'b111111;
12'd3672 : mem_out_dec = 6'b111111;
12'd3673 : mem_out_dec = 6'b111111;
12'd3674 : mem_out_dec = 6'b111111;
12'd3675 : mem_out_dec = 6'b111111;
12'd3676 : mem_out_dec = 6'b111111;
12'd3677 : mem_out_dec = 6'b111111;
12'd3678 : mem_out_dec = 6'b111111;
12'd3679 : mem_out_dec = 6'b111111;
12'd3680 : mem_out_dec = 6'b111111;
12'd3681 : mem_out_dec = 6'b111111;
12'd3682 : mem_out_dec = 6'b111111;
12'd3683 : mem_out_dec = 6'b111111;
12'd3684 : mem_out_dec = 6'b111111;
12'd3685 : mem_out_dec = 6'b111111;
12'd3686 : mem_out_dec = 6'b111111;
12'd3687 : mem_out_dec = 6'b111111;
12'd3688 : mem_out_dec = 6'b111111;
12'd3689 : mem_out_dec = 6'b111111;
12'd3690 : mem_out_dec = 6'b111111;
12'd3691 : mem_out_dec = 6'b111111;
12'd3692 : mem_out_dec = 6'b111111;
12'd3693 : mem_out_dec = 6'b111111;
12'd3694 : mem_out_dec = 6'b111111;
12'd3695 : mem_out_dec = 6'b111111;
12'd3696 : mem_out_dec = 6'b111111;
12'd3697 : mem_out_dec = 6'b111111;
12'd3698 : mem_out_dec = 6'b111111;
12'd3699 : mem_out_dec = 6'b111111;
12'd3700 : mem_out_dec = 6'b111111;
12'd3701 : mem_out_dec = 6'b111111;
12'd3702 : mem_out_dec = 6'b111111;
12'd3703 : mem_out_dec = 6'b111111;
12'd3704 : mem_out_dec = 6'b111111;
12'd3705 : mem_out_dec = 6'b111111;
12'd3706 : mem_out_dec = 6'b111111;
12'd3707 : mem_out_dec = 6'b111111;
12'd3708 : mem_out_dec = 6'b111111;
12'd3709 : mem_out_dec = 6'b111111;
12'd3710 : mem_out_dec = 6'b111111;
12'd3711 : mem_out_dec = 6'b000100;
12'd3712 : mem_out_dec = 6'b111111;
12'd3713 : mem_out_dec = 6'b111111;
12'd3714 : mem_out_dec = 6'b111111;
12'd3715 : mem_out_dec = 6'b111111;
12'd3716 : mem_out_dec = 6'b111111;
12'd3717 : mem_out_dec = 6'b111111;
12'd3718 : mem_out_dec = 6'b111111;
12'd3719 : mem_out_dec = 6'b111111;
12'd3720 : mem_out_dec = 6'b111111;
12'd3721 : mem_out_dec = 6'b111111;
12'd3722 : mem_out_dec = 6'b111111;
12'd3723 : mem_out_dec = 6'b111111;
12'd3724 : mem_out_dec = 6'b111111;
12'd3725 : mem_out_dec = 6'b111111;
12'd3726 : mem_out_dec = 6'b111111;
12'd3727 : mem_out_dec = 6'b111111;
12'd3728 : mem_out_dec = 6'b111111;
12'd3729 : mem_out_dec = 6'b111111;
12'd3730 : mem_out_dec = 6'b111111;
12'd3731 : mem_out_dec = 6'b111111;
12'd3732 : mem_out_dec = 6'b111111;
12'd3733 : mem_out_dec = 6'b111111;
12'd3734 : mem_out_dec = 6'b111111;
12'd3735 : mem_out_dec = 6'b111111;
12'd3736 : mem_out_dec = 6'b111111;
12'd3737 : mem_out_dec = 6'b111111;
12'd3738 : mem_out_dec = 6'b111111;
12'd3739 : mem_out_dec = 6'b111111;
12'd3740 : mem_out_dec = 6'b111111;
12'd3741 : mem_out_dec = 6'b111111;
12'd3742 : mem_out_dec = 6'b111111;
12'd3743 : mem_out_dec = 6'b111111;
12'd3744 : mem_out_dec = 6'b111111;
12'd3745 : mem_out_dec = 6'b111111;
12'd3746 : mem_out_dec = 6'b111111;
12'd3747 : mem_out_dec = 6'b111111;
12'd3748 : mem_out_dec = 6'b111111;
12'd3749 : mem_out_dec = 6'b111111;
12'd3750 : mem_out_dec = 6'b111111;
12'd3751 : mem_out_dec = 6'b111111;
12'd3752 : mem_out_dec = 6'b111111;
12'd3753 : mem_out_dec = 6'b111111;
12'd3754 : mem_out_dec = 6'b111111;
12'd3755 : mem_out_dec = 6'b111111;
12'd3756 : mem_out_dec = 6'b111111;
12'd3757 : mem_out_dec = 6'b111111;
12'd3758 : mem_out_dec = 6'b111111;
12'd3759 : mem_out_dec = 6'b111111;
12'd3760 : mem_out_dec = 6'b111111;
12'd3761 : mem_out_dec = 6'b111111;
12'd3762 : mem_out_dec = 6'b111111;
12'd3763 : mem_out_dec = 6'b111111;
12'd3764 : mem_out_dec = 6'b111111;
12'd3765 : mem_out_dec = 6'b111111;
12'd3766 : mem_out_dec = 6'b111111;
12'd3767 : mem_out_dec = 6'b111111;
12'd3768 : mem_out_dec = 6'b111111;
12'd3769 : mem_out_dec = 6'b111111;
12'd3770 : mem_out_dec = 6'b111111;
12'd3771 : mem_out_dec = 6'b111111;
12'd3772 : mem_out_dec = 6'b111111;
12'd3773 : mem_out_dec = 6'b111111;
12'd3774 : mem_out_dec = 6'b111111;
12'd3775 : mem_out_dec = 6'b111111;
12'd3776 : mem_out_dec = 6'b111111;
12'd3777 : mem_out_dec = 6'b111111;
12'd3778 : mem_out_dec = 6'b111111;
12'd3779 : mem_out_dec = 6'b111111;
12'd3780 : mem_out_dec = 6'b111111;
12'd3781 : mem_out_dec = 6'b111111;
12'd3782 : mem_out_dec = 6'b111111;
12'd3783 : mem_out_dec = 6'b111111;
12'd3784 : mem_out_dec = 6'b111111;
12'd3785 : mem_out_dec = 6'b111111;
12'd3786 : mem_out_dec = 6'b111111;
12'd3787 : mem_out_dec = 6'b111111;
12'd3788 : mem_out_dec = 6'b111111;
12'd3789 : mem_out_dec = 6'b111111;
12'd3790 : mem_out_dec = 6'b111111;
12'd3791 : mem_out_dec = 6'b111111;
12'd3792 : mem_out_dec = 6'b111111;
12'd3793 : mem_out_dec = 6'b111111;
12'd3794 : mem_out_dec = 6'b111111;
12'd3795 : mem_out_dec = 6'b111111;
12'd3796 : mem_out_dec = 6'b111111;
12'd3797 : mem_out_dec = 6'b111111;
12'd3798 : mem_out_dec = 6'b111111;
12'd3799 : mem_out_dec = 6'b111111;
12'd3800 : mem_out_dec = 6'b111111;
12'd3801 : mem_out_dec = 6'b111111;
12'd3802 : mem_out_dec = 6'b111111;
12'd3803 : mem_out_dec = 6'b111111;
12'd3804 : mem_out_dec = 6'b111111;
12'd3805 : mem_out_dec = 6'b111111;
12'd3806 : mem_out_dec = 6'b111111;
12'd3807 : mem_out_dec = 6'b111111;
12'd3808 : mem_out_dec = 6'b111111;
12'd3809 : mem_out_dec = 6'b111111;
12'd3810 : mem_out_dec = 6'b111111;
12'd3811 : mem_out_dec = 6'b111111;
12'd3812 : mem_out_dec = 6'b111111;
12'd3813 : mem_out_dec = 6'b111111;
12'd3814 : mem_out_dec = 6'b111111;
12'd3815 : mem_out_dec = 6'b111111;
12'd3816 : mem_out_dec = 6'b111111;
12'd3817 : mem_out_dec = 6'b111111;
12'd3818 : mem_out_dec = 6'b111111;
12'd3819 : mem_out_dec = 6'b111111;
12'd3820 : mem_out_dec = 6'b111111;
12'd3821 : mem_out_dec = 6'b111111;
12'd3822 : mem_out_dec = 6'b111111;
12'd3823 : mem_out_dec = 6'b111111;
12'd3824 : mem_out_dec = 6'b111111;
12'd3825 : mem_out_dec = 6'b111111;
12'd3826 : mem_out_dec = 6'b111111;
12'd3827 : mem_out_dec = 6'b111111;
12'd3828 : mem_out_dec = 6'b111111;
12'd3829 : mem_out_dec = 6'b111111;
12'd3830 : mem_out_dec = 6'b111111;
12'd3831 : mem_out_dec = 6'b111111;
12'd3832 : mem_out_dec = 6'b111111;
12'd3833 : mem_out_dec = 6'b111111;
12'd3834 : mem_out_dec = 6'b111111;
12'd3835 : mem_out_dec = 6'b111111;
12'd3836 : mem_out_dec = 6'b111111;
12'd3837 : mem_out_dec = 6'b111111;
12'd3838 : mem_out_dec = 6'b111111;
12'd3839 : mem_out_dec = 6'b111111;
12'd3840 : mem_out_dec = 6'b111111;
12'd3841 : mem_out_dec = 6'b111111;
12'd3842 : mem_out_dec = 6'b111111;
12'd3843 : mem_out_dec = 6'b111111;
12'd3844 : mem_out_dec = 6'b111111;
12'd3845 : mem_out_dec = 6'b111111;
12'd3846 : mem_out_dec = 6'b111111;
12'd3847 : mem_out_dec = 6'b111111;
12'd3848 : mem_out_dec = 6'b111111;
12'd3849 : mem_out_dec = 6'b111111;
12'd3850 : mem_out_dec = 6'b111111;
12'd3851 : mem_out_dec = 6'b111111;
12'd3852 : mem_out_dec = 6'b111111;
12'd3853 : mem_out_dec = 6'b111111;
12'd3854 : mem_out_dec = 6'b111111;
12'd3855 : mem_out_dec = 6'b111111;
12'd3856 : mem_out_dec = 6'b111111;
12'd3857 : mem_out_dec = 6'b111111;
12'd3858 : mem_out_dec = 6'b111111;
12'd3859 : mem_out_dec = 6'b111111;
12'd3860 : mem_out_dec = 6'b111111;
12'd3861 : mem_out_dec = 6'b111111;
12'd3862 : mem_out_dec = 6'b111111;
12'd3863 : mem_out_dec = 6'b111111;
12'd3864 : mem_out_dec = 6'b111111;
12'd3865 : mem_out_dec = 6'b111111;
12'd3866 : mem_out_dec = 6'b111111;
12'd3867 : mem_out_dec = 6'b111111;
12'd3868 : mem_out_dec = 6'b111111;
12'd3869 : mem_out_dec = 6'b111111;
12'd3870 : mem_out_dec = 6'b111111;
12'd3871 : mem_out_dec = 6'b111111;
12'd3872 : mem_out_dec = 6'b111111;
12'd3873 : mem_out_dec = 6'b111111;
12'd3874 : mem_out_dec = 6'b111111;
12'd3875 : mem_out_dec = 6'b111111;
12'd3876 : mem_out_dec = 6'b111111;
12'd3877 : mem_out_dec = 6'b111111;
12'd3878 : mem_out_dec = 6'b111111;
12'd3879 : mem_out_dec = 6'b111111;
12'd3880 : mem_out_dec = 6'b111111;
12'd3881 : mem_out_dec = 6'b111111;
12'd3882 : mem_out_dec = 6'b111111;
12'd3883 : mem_out_dec = 6'b111111;
12'd3884 : mem_out_dec = 6'b111111;
12'd3885 : mem_out_dec = 6'b111111;
12'd3886 : mem_out_dec = 6'b111111;
12'd3887 : mem_out_dec = 6'b111111;
12'd3888 : mem_out_dec = 6'b111111;
12'd3889 : mem_out_dec = 6'b111111;
12'd3890 : mem_out_dec = 6'b111111;
12'd3891 : mem_out_dec = 6'b111111;
12'd3892 : mem_out_dec = 6'b111111;
12'd3893 : mem_out_dec = 6'b111111;
12'd3894 : mem_out_dec = 6'b111111;
12'd3895 : mem_out_dec = 6'b111111;
12'd3896 : mem_out_dec = 6'b111111;
12'd3897 : mem_out_dec = 6'b111111;
12'd3898 : mem_out_dec = 6'b111111;
12'd3899 : mem_out_dec = 6'b111111;
12'd3900 : mem_out_dec = 6'b111111;
12'd3901 : mem_out_dec = 6'b111111;
12'd3902 : mem_out_dec = 6'b111111;
12'd3903 : mem_out_dec = 6'b111111;
12'd3904 : mem_out_dec = 6'b111111;
12'd3905 : mem_out_dec = 6'b111111;
12'd3906 : mem_out_dec = 6'b111111;
12'd3907 : mem_out_dec = 6'b111111;
12'd3908 : mem_out_dec = 6'b111111;
12'd3909 : mem_out_dec = 6'b111111;
12'd3910 : mem_out_dec = 6'b111111;
12'd3911 : mem_out_dec = 6'b111111;
12'd3912 : mem_out_dec = 6'b111111;
12'd3913 : mem_out_dec = 6'b111111;
12'd3914 : mem_out_dec = 6'b111111;
12'd3915 : mem_out_dec = 6'b111111;
12'd3916 : mem_out_dec = 6'b111111;
12'd3917 : mem_out_dec = 6'b111111;
12'd3918 : mem_out_dec = 6'b111111;
12'd3919 : mem_out_dec = 6'b111111;
12'd3920 : mem_out_dec = 6'b111111;
12'd3921 : mem_out_dec = 6'b111111;
12'd3922 : mem_out_dec = 6'b111111;
12'd3923 : mem_out_dec = 6'b111111;
12'd3924 : mem_out_dec = 6'b111111;
12'd3925 : mem_out_dec = 6'b111111;
12'd3926 : mem_out_dec = 6'b111111;
12'd3927 : mem_out_dec = 6'b111111;
12'd3928 : mem_out_dec = 6'b111111;
12'd3929 : mem_out_dec = 6'b111111;
12'd3930 : mem_out_dec = 6'b111111;
12'd3931 : mem_out_dec = 6'b111111;
12'd3932 : mem_out_dec = 6'b111111;
12'd3933 : mem_out_dec = 6'b111111;
12'd3934 : mem_out_dec = 6'b111111;
12'd3935 : mem_out_dec = 6'b111111;
12'd3936 : mem_out_dec = 6'b111111;
12'd3937 : mem_out_dec = 6'b111111;
12'd3938 : mem_out_dec = 6'b111111;
12'd3939 : mem_out_dec = 6'b111111;
12'd3940 : mem_out_dec = 6'b111111;
12'd3941 : mem_out_dec = 6'b111111;
12'd3942 : mem_out_dec = 6'b111111;
12'd3943 : mem_out_dec = 6'b111111;
12'd3944 : mem_out_dec = 6'b111111;
12'd3945 : mem_out_dec = 6'b111111;
12'd3946 : mem_out_dec = 6'b111111;
12'd3947 : mem_out_dec = 6'b111111;
12'd3948 : mem_out_dec = 6'b111111;
12'd3949 : mem_out_dec = 6'b111111;
12'd3950 : mem_out_dec = 6'b111111;
12'd3951 : mem_out_dec = 6'b111111;
12'd3952 : mem_out_dec = 6'b111111;
12'd3953 : mem_out_dec = 6'b111111;
12'd3954 : mem_out_dec = 6'b111111;
12'd3955 : mem_out_dec = 6'b111111;
12'd3956 : mem_out_dec = 6'b111111;
12'd3957 : mem_out_dec = 6'b111111;
12'd3958 : mem_out_dec = 6'b111111;
12'd3959 : mem_out_dec = 6'b111111;
12'd3960 : mem_out_dec = 6'b111111;
12'd3961 : mem_out_dec = 6'b111111;
12'd3962 : mem_out_dec = 6'b111111;
12'd3963 : mem_out_dec = 6'b111111;
12'd3964 : mem_out_dec = 6'b111111;
12'd3965 : mem_out_dec = 6'b111111;
12'd3966 : mem_out_dec = 6'b111111;
12'd3967 : mem_out_dec = 6'b111111;
12'd3968 : mem_out_dec = 6'b111111;
12'd3969 : mem_out_dec = 6'b111111;
12'd3970 : mem_out_dec = 6'b111111;
12'd3971 : mem_out_dec = 6'b111111;
12'd3972 : mem_out_dec = 6'b111111;
12'd3973 : mem_out_dec = 6'b111111;
12'd3974 : mem_out_dec = 6'b111111;
12'd3975 : mem_out_dec = 6'b111111;
12'd3976 : mem_out_dec = 6'b111111;
12'd3977 : mem_out_dec = 6'b111111;
12'd3978 : mem_out_dec = 6'b111111;
12'd3979 : mem_out_dec = 6'b111111;
12'd3980 : mem_out_dec = 6'b111111;
12'd3981 : mem_out_dec = 6'b111111;
12'd3982 : mem_out_dec = 6'b111111;
12'd3983 : mem_out_dec = 6'b111111;
12'd3984 : mem_out_dec = 6'b111111;
12'd3985 : mem_out_dec = 6'b111111;
12'd3986 : mem_out_dec = 6'b111111;
12'd3987 : mem_out_dec = 6'b111111;
12'd3988 : mem_out_dec = 6'b111111;
12'd3989 : mem_out_dec = 6'b111111;
12'd3990 : mem_out_dec = 6'b111111;
12'd3991 : mem_out_dec = 6'b111111;
12'd3992 : mem_out_dec = 6'b111111;
12'd3993 : mem_out_dec = 6'b111111;
12'd3994 : mem_out_dec = 6'b111111;
12'd3995 : mem_out_dec = 6'b111111;
12'd3996 : mem_out_dec = 6'b111111;
12'd3997 : mem_out_dec = 6'b111111;
12'd3998 : mem_out_dec = 6'b111111;
12'd3999 : mem_out_dec = 6'b111111;
12'd4000 : mem_out_dec = 6'b111111;
12'd4001 : mem_out_dec = 6'b111111;
12'd4002 : mem_out_dec = 6'b111111;
12'd4003 : mem_out_dec = 6'b111111;
12'd4004 : mem_out_dec = 6'b111111;
12'd4005 : mem_out_dec = 6'b111111;
12'd4006 : mem_out_dec = 6'b111111;
12'd4007 : mem_out_dec = 6'b111111;
12'd4008 : mem_out_dec = 6'b111111;
12'd4009 : mem_out_dec = 6'b111111;
12'd4010 : mem_out_dec = 6'b111111;
12'd4011 : mem_out_dec = 6'b111111;
12'd4012 : mem_out_dec = 6'b111111;
12'd4013 : mem_out_dec = 6'b111111;
12'd4014 : mem_out_dec = 6'b111111;
12'd4015 : mem_out_dec = 6'b111111;
12'd4016 : mem_out_dec = 6'b111111;
12'd4017 : mem_out_dec = 6'b111111;
12'd4018 : mem_out_dec = 6'b111111;
12'd4019 : mem_out_dec = 6'b111111;
12'd4020 : mem_out_dec = 6'b111111;
12'd4021 : mem_out_dec = 6'b111111;
12'd4022 : mem_out_dec = 6'b111111;
12'd4023 : mem_out_dec = 6'b111111;
12'd4024 : mem_out_dec = 6'b111111;
12'd4025 : mem_out_dec = 6'b111111;
12'd4026 : mem_out_dec = 6'b111111;
12'd4027 : mem_out_dec = 6'b111111;
12'd4028 : mem_out_dec = 6'b111111;
12'd4029 : mem_out_dec = 6'b111111;
12'd4030 : mem_out_dec = 6'b111111;
12'd4031 : mem_out_dec = 6'b111111;
12'd4032 : mem_out_dec = 6'b111111;
12'd4033 : mem_out_dec = 6'b111111;
12'd4034 : mem_out_dec = 6'b111111;
12'd4035 : mem_out_dec = 6'b111111;
12'd4036 : mem_out_dec = 6'b111111;
12'd4037 : mem_out_dec = 6'b111111;
12'd4038 : mem_out_dec = 6'b111111;
12'd4039 : mem_out_dec = 6'b111111;
12'd4040 : mem_out_dec = 6'b111111;
12'd4041 : mem_out_dec = 6'b111111;
12'd4042 : mem_out_dec = 6'b111111;
12'd4043 : mem_out_dec = 6'b111111;
12'd4044 : mem_out_dec = 6'b111111;
12'd4045 : mem_out_dec = 6'b111111;
12'd4046 : mem_out_dec = 6'b111111;
12'd4047 : mem_out_dec = 6'b111111;
12'd4048 : mem_out_dec = 6'b111111;
12'd4049 : mem_out_dec = 6'b111111;
12'd4050 : mem_out_dec = 6'b111111;
12'd4051 : mem_out_dec = 6'b111111;
12'd4052 : mem_out_dec = 6'b111111;
12'd4053 : mem_out_dec = 6'b111111;
12'd4054 : mem_out_dec = 6'b111111;
12'd4055 : mem_out_dec = 6'b111111;
12'd4056 : mem_out_dec = 6'b111111;
12'd4057 : mem_out_dec = 6'b111111;
12'd4058 : mem_out_dec = 6'b111111;
12'd4059 : mem_out_dec = 6'b111111;
12'd4060 : mem_out_dec = 6'b111111;
12'd4061 : mem_out_dec = 6'b111111;
12'd4062 : mem_out_dec = 6'b111111;
12'd4063 : mem_out_dec = 6'b111111;
12'd4064 : mem_out_dec = 6'b111111;
12'd4065 : mem_out_dec = 6'b111111;
12'd4066 : mem_out_dec = 6'b111111;
12'd4067 : mem_out_dec = 6'b111111;
12'd4068 : mem_out_dec = 6'b111111;
12'd4069 : mem_out_dec = 6'b111111;
12'd4070 : mem_out_dec = 6'b111111;
12'd4071 : mem_out_dec = 6'b111111;
12'd4072 : mem_out_dec = 6'b111111;
12'd4073 : mem_out_dec = 6'b111111;
12'd4074 : mem_out_dec = 6'b111111;
12'd4075 : mem_out_dec = 6'b111111;
12'd4076 : mem_out_dec = 6'b111111;
12'd4077 : mem_out_dec = 6'b111111;
12'd4078 : mem_out_dec = 6'b111111;
12'd4079 : mem_out_dec = 6'b111111;
12'd4080 : mem_out_dec = 6'b111111;
12'd4081 : mem_out_dec = 6'b111111;
12'd4082 : mem_out_dec = 6'b111111;
12'd4083 : mem_out_dec = 6'b111111;
12'd4084 : mem_out_dec = 6'b111111;
12'd4085 : mem_out_dec = 6'b111111;
12'd4086 : mem_out_dec = 6'b111111;
12'd4087 : mem_out_dec = 6'b111111;
12'd4088 : mem_out_dec = 6'b111111;
12'd4089 : mem_out_dec = 6'b111111;
12'd4090 : mem_out_dec = 6'b111111;
12'd4091 : mem_out_dec = 6'b111111;
12'd4092 : mem_out_dec = 6'b111111;
12'd4093 : mem_out_dec = 6'b111111;
12'd4094 : mem_out_dec = 6'b111111;
12'd4095 : mem_out_dec = 6'b111111;
endcase
end
always @ (posedge clk) begin
dec_cnt <= #TCQ mem_out_dec;
end
endmodule
|
module mig_7series_v2_3_ddr_phy_prbs_rdlvl #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter nCK_PER_CLK = 2, // # of memory clocks per CLK
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter RANKS = 1, // # of DRAM ranks
parameter SIM_CAL_OPTION = "NONE", // Skip various calibration steps
parameter PRBS_WIDTH = 8, // PRBS generator output width
parameter FIXED_VICTIM = "TRUE", // No victim rotation when "TRUE"
parameter FINE_PER_BIT = "ON",
parameter CENTER_COMP_MODE = "ON",
parameter PI_VAL_ADJ = "ON"
)
(
input clk,
input rst,
// Calibration status, control signals
input prbs_rdlvl_start,
(* max_fanout = 100 *) output reg prbs_rdlvl_done,
output reg prbs_last_byte_done,
output reg prbs_rdlvl_prech_req,
input complex_sample_cnt_inc,
input prech_done,
input phy_if_empty,
// Captured data in fabric clock domain
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] rd_data,
//Expected data from PRBS generator
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] compare_data,
// Decrement initial Phaser_IN Fine tap delay
input [5:0] pi_counter_read_val,
// Stage 1 calibration outputs
output reg pi_en_stg2_f,
output reg pi_stg2_f_incdec,
output [255:0] dbg_prbs_rdlvl,
output [DQS_CNT_WIDTH:0] pi_stg2_prbs_rdlvl_cnt,
output reg [2:0] rd_victim_sel,
output reg complex_victim_inc,
output reg reset_rd_addr,
output reg read_pause,
output reg [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r,
output reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps,
output reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps,
output reg [DRAM_WIDTH-1:0] fine_delay_incdec_pb, //fine_delay decreament per bit
output reg fine_delay_sel //fine delay selection - actual update of fine delay
);
localparam [5:0] PRBS_IDLE = 6'h00;
localparam [5:0] PRBS_NEW_DQS_WAIT = 6'h01;
localparam [5:0] PRBS_PAT_COMPARE = 6'h02;
localparam [5:0] PRBS_DEC_DQS = 6'h03;
localparam [5:0] PRBS_DEC_DQS_WAIT = 6'h04;
localparam [5:0] PRBS_INC_DQS = 6'h05;
localparam [5:0] PRBS_INC_DQS_WAIT = 6'h06;
localparam [5:0] PRBS_CALC_TAPS = 6'h07;
localparam [5:0] PRBS_NEXT_DQS = 6'h08;
localparam [5:0] PRBS_NEW_DQS_PREWAIT = 6'h09;
localparam [5:0] PRBS_DONE = 6'h0A;
localparam [5:0] PRBS_CALC_TAPS_PRE = 6'h0B;
localparam [5:0] PRBS_CALC_TAPS_WAIT = 6'h0C;
localparam [5:0] FINE_PI_DEC = 6'h0D; //go back to all fail or back to center
localparam [5:0] FINE_PI_DEC_WAIT = 6'h0E; //wait for PI tap dec settle
localparam [5:0] FINE_PI_INC = 6'h0F; //increse up to 1 fail
localparam [5:0] FINE_PI_INC_WAIT = 6'h10; //wait for PI tap int settle
localparam [5:0] FINE_PAT_COMPARE_PER_BIT = 6'h11; //compare per bit error and check left/right/gain/loss
localparam [5:0] FINE_CALC_TAPS = 6'h12; //setup fine_delay_incdec_pb for better window size
localparam [5:0] FINE_CALC_TAPS_WAIT = 6'h13; //wait for ROM value for dec cnt
localparam [11:0] NUM_SAMPLES_CNT = (SIM_CAL_OPTION == "NONE") ? 'd50 : 12'h001;
localparam [11:0] NUM_SAMPLES_CNT1 = (SIM_CAL_OPTION == "NONE") ? 'd20 : 12'h001;
localparam [11:0] NUM_SAMPLES_CNT2 = (SIM_CAL_OPTION == "NONE") ? 'd10 : 12'h001;
wire [DQS_CNT_WIDTH+2:0]prbs_dqs_cnt_timing;
reg [DQS_CNT_WIDTH+2:0] prbs_dqs_cnt_timing_r;
reg [DQS_CNT_WIDTH:0] prbs_dqs_cnt_r;
reg prbs_prech_req_r;
reg [5:0] prbs_state_r;
reg [5:0] prbs_state_r1;
reg wait_state_cnt_en_r;
reg [3:0] wait_state_cnt_r;
reg cnt_wait_state;
reg err_chk_invalid;
// reg found_edge_r;
reg prbs_found_1st_edge_r;
reg prbs_found_2nd_edge_r;
reg [5:0] prbs_1st_edge_taps_r;
// reg found_stable_eye_r;
reg [5:0] prbs_dqs_tap_cnt_r;
reg [5:0] prbs_dec_tap_calc_plus_3;
reg [5:0] prbs_dec_tap_calc_minus_3;
reg prbs_dqs_tap_limit_r;
reg [5:0] prbs_inc_tap_cnt;
reg [5:0] prbs_dec_tap_cnt;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r1;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r1;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r2;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r2;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r3;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r4;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r4;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r4;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r4;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r4;
reg mux_rd_valid_r;
reg rd_valid_r1;
reg rd_valid_r2;
reg rd_valid_r3;
reg new_cnt_dqs_r;
reg prbs_tap_en_r;
reg prbs_tap_inc_r;
reg pi_en_stg2_f_timing;
reg pi_stg2_f_incdec_timing;
wire [DQ_WIDTH-1:0] rd_data_rise0;
wire [DQ_WIDTH-1:0] rd_data_fall0;
wire [DQ_WIDTH-1:0] rd_data_rise1;
wire [DQ_WIDTH-1:0] rd_data_fall1;
wire [DQ_WIDTH-1:0] rd_data_rise2;
wire [DQ_WIDTH-1:0] rd_data_fall2;
wire [DQ_WIDTH-1:0] rd_data_rise3;
wire [DQ_WIDTH-1:0] rd_data_fall3;
wire [DQ_WIDTH-1:0] compare_data_r0;
wire [DQ_WIDTH-1:0] compare_data_f0;
wire [DQ_WIDTH-1:0] compare_data_r1;
wire [DQ_WIDTH-1:0] compare_data_f1;
wire [DQ_WIDTH-1:0] compare_data_r2;
wire [DQ_WIDTH-1:0] compare_data_f2;
wire [DQ_WIDTH-1:0] compare_data_r3;
wire [DQ_WIDTH-1:0] compare_data_f3;
reg [DRAM_WIDTH-1:0] compare_data_rise0_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall0_r1;
reg [DRAM_WIDTH-1:0] compare_data_rise1_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall1_r1;
reg [DRAM_WIDTH-1:0] compare_data_rise2_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall2_r1;
reg [DRAM_WIDTH-1:0] compare_data_rise3_r1;
reg [DRAM_WIDTH-1:0] compare_data_fall3_r1;
reg [DQS_CNT_WIDTH:0] rd_mux_sel_r;
reg [5:0] prbs_2nd_edge_taps_r;
// reg [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r;
reg [5:0] rdlvl_cpt_tap_cnt;
reg prbs_rdlvl_start_r;
reg compare_err;
reg compare_err_r0;
reg compare_err_f0;
reg compare_err_r1;
reg compare_err_f1;
reg compare_err_r2;
reg compare_err_f2;
reg compare_err_r3;
reg compare_err_f3;
reg samples_cnt1_en_r;
reg samples_cnt2_en_r;
reg [11:0] samples_cnt_r;
reg num_samples_done_r;
reg num_samples_done_ind; //indicate num_samples_done_r is set in FINE_PAT_COMPARE_PER_BIT to prevent victim_sel_rd out of sync
reg [DQS_WIDTH-1:0] prbs_tap_mod;
//reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps;
//reg [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps;
//**************************************************************************
// signals for per-bit algorithm of fine_delay calculations
//**************************************************************************
reg [6*DRAM_WIDTH-1:0] left_edge_pb; //left edge value per bit
reg [6*DRAM_WIDTH-1:0] right_edge_pb; //right edge value per bit
reg [5*DRAM_WIDTH-1:0] match_flag_pb; //5 consecutive match flag per bit
reg [4:0] match_flag_and; //5 consecute match flag of all bits (1: all bit fail)
reg [DRAM_WIDTH-1:0] left_edge_found_pb; //left_edge found per bit - use for loss calculation
reg [DRAM_WIDTH-1:0] left_edge_updated; //left edge was updated for this PI tap - used for largest left edge /ref bit update
reg [DRAM_WIDTH-1:0] right_edge_found_pb; //right_edge found per bit - use for gail calulation and smallest right edge update
reg right_edge_found; //smallest right_edge found
reg [DRAM_WIDTH*6-1:0] left_loss_pb; //left_edge loss per bit
reg [DRAM_WIDTH*6-1:0] right_gain_pb; //right_edge gain per bit
reg [DRAM_WIDTH-1:0] ref_bit; //bit number which has largest left edge (with smaller right edge)
reg [DRAM_WIDTH-1:0] bit_cnt; //bit number used to calculate ref bit
reg [DRAM_WIDTH-1:0] ref_bit_per_bit; //bit flags which have largest left edge
reg [5:0] ref_right_edge; //ref_bit right edge - keep the smallest edge of ref bits
reg [5:0] largest_left_edge; //biggest left edge of per bit - will be left edge of byte
reg [5:0] smallest_right_edge; //smallest right edge of per bit - will be right edge of byte
reg [5:0] fine_pi_dec_cnt; //Phase In tap decrement count (to go back to '0' or center)
reg [6:0] center_calc; //used for calculate the dec tap for centering
reg [5:0] right_edge_ref; //ref_bit right edge
reg [5:0] left_edge_ref; //ref_bit left edge
reg [DRAM_WIDTH-1:0] compare_err_pb; //compare error per bit
reg [DRAM_WIDTH-1:0] compare_err_pb_latch_r; //sticky compare error per bit used for left/right edge
reg compare_err_pb_and; //indicate all bit fail
reg fine_inc_stage; //fine_inc_stage (1: increment all except ref_bit, 0: only inc for gain bit)
reg [1:0] stage_cnt; //stage cnt (0,1: fine delay inc stage, 2: fine delay dec stage)
wire fine_calib; //turn on/off fine delay calibration
reg [5:0] mem_out_dec;
reg [5:0] dec_cnt;
reg fine_dly_error; //indicate it has wrong left/right edge
wire center_comp;
wire pi_adj;
//**************************************************************************
// DQS count to hard PHY during write calibration using Phaser_OUT Stage2
// coarse delay
//**************************************************************************
assign pi_stg2_prbs_rdlvl_cnt = prbs_dqs_cnt_r;
//fine delay turn on
assign fine_calib = (FINE_PER_BIT=="ON")? 1:0;
assign center_comp = (CENTER_COMP_MODE == "ON")? 1: 0;
assign pi_adj = (PI_VAL_ADJ == "ON")?1:0;
assign dbg_prbs_rdlvl[0+:6] = left_edge_pb[0+:6];
assign dbg_prbs_rdlvl[7:6] = left_loss_pb[0+:2];
assign dbg_prbs_rdlvl[8+:6] = left_edge_pb[6+:6];
assign dbg_prbs_rdlvl[15:14] = left_loss_pb[6+:2];
assign dbg_prbs_rdlvl[16+:6] = left_edge_pb[12+:6] ;
assign dbg_prbs_rdlvl[23:22] = left_loss_pb[12+:2];
assign dbg_prbs_rdlvl[24+:6] = left_edge_pb[18+:6] ;
assign dbg_prbs_rdlvl[31:30] = left_loss_pb[18+:2];
assign dbg_prbs_rdlvl[32+:6] = left_edge_pb[24+:6];
assign dbg_prbs_rdlvl[39:38] = left_loss_pb[24+:2];
assign dbg_prbs_rdlvl[40+:6] = left_edge_pb[30+:6];
assign dbg_prbs_rdlvl[47:46] = left_loss_pb[30+:2];
assign dbg_prbs_rdlvl[48+:6] = left_edge_pb[36+:6];
assign dbg_prbs_rdlvl[55:54] = left_loss_pb[36+:2];
assign dbg_prbs_rdlvl[56+:6] = left_edge_pb[42+:6];
assign dbg_prbs_rdlvl[63:62] = left_loss_pb[42+:2];
assign dbg_prbs_rdlvl[64+:6] = right_edge_pb[0+:6];
assign dbg_prbs_rdlvl[71:70] = right_gain_pb[0+:2];
assign dbg_prbs_rdlvl[72+:6] = right_edge_pb[6+:6] ;
assign dbg_prbs_rdlvl[79:78] = right_gain_pb[6+:2];
assign dbg_prbs_rdlvl[80+:6] = right_edge_pb[12+:6];
assign dbg_prbs_rdlvl[87:86] = right_gain_pb[12+:2];
assign dbg_prbs_rdlvl[88+:6] = right_edge_pb[18+:6];
assign dbg_prbs_rdlvl[95:94] = right_gain_pb[18+:2];
assign dbg_prbs_rdlvl[96+:6] = right_edge_pb[24+:6];
assign dbg_prbs_rdlvl[103:102] = right_gain_pb[24+:2];
assign dbg_prbs_rdlvl[104+:6] = right_edge_pb[30+:6];
assign dbg_prbs_rdlvl[111:110] = right_gain_pb[30+:2];
assign dbg_prbs_rdlvl[112+:6] = right_edge_pb[36+:6];
assign dbg_prbs_rdlvl[119:118] = right_gain_pb[36+:2];
assign dbg_prbs_rdlvl[120+:6] = right_edge_pb[42+:6];
assign dbg_prbs_rdlvl[127:126] = right_gain_pb[42+:2];
assign dbg_prbs_rdlvl[128+:6] = pi_counter_read_val;
assign dbg_prbs_rdlvl[134+:6] = prbs_dqs_tap_cnt_r;
assign dbg_prbs_rdlvl[140] = prbs_found_1st_edge_r;
assign dbg_prbs_rdlvl[141] = prbs_found_2nd_edge_r;
assign dbg_prbs_rdlvl[142] = compare_err;
assign dbg_prbs_rdlvl[143] = phy_if_empty;
assign dbg_prbs_rdlvl[144] = prbs_rdlvl_start;
assign dbg_prbs_rdlvl[145] = prbs_rdlvl_done;
assign dbg_prbs_rdlvl[146+:5] = prbs_dqs_cnt_r;
assign dbg_prbs_rdlvl[151+:6] = left_edge_pb[prbs_dqs_cnt_r*6+:6] ;
assign dbg_prbs_rdlvl[157+:6] = right_edge_pb[prbs_dqs_cnt_r*6+:6];
assign dbg_prbs_rdlvl[163+:6] = {2'h0,complex_victim_inc, rd_victim_sel[2:0]};
assign dbg_prbs_rdlvl[169+:6] =right_gain_pb[prbs_dqs_cnt_r*6+:6] ;
assign dbg_prbs_rdlvl[177:175] = ref_bit[2:0];
assign dbg_prbs_rdlvl[178+:6] = prbs_state_r1[5:0];
assign dbg_prbs_rdlvl[184] = rd_valid_r2;
assign dbg_prbs_rdlvl[185] = compare_err_r0;
assign dbg_prbs_rdlvl[186] = compare_err_f0;
assign dbg_prbs_rdlvl[187] = compare_err_r1;
assign dbg_prbs_rdlvl[188] = compare_err_f1;
assign dbg_prbs_rdlvl[189] = compare_err_r2;
assign dbg_prbs_rdlvl[190] = compare_err_f2;
assign dbg_prbs_rdlvl[191] = compare_err_r3;
assign dbg_prbs_rdlvl[192] = compare_err_f3;
assign dbg_prbs_rdlvl[193+:8] = left_edge_found_pb;
assign dbg_prbs_rdlvl[201+:8] = right_edge_found_pb;
assign dbg_prbs_rdlvl[209+:6] =largest_left_edge ;
assign dbg_prbs_rdlvl[215+:6] =smallest_right_edge ;
assign dbg_prbs_rdlvl[221+:8] = fine_delay_incdec_pb;
assign dbg_prbs_rdlvl[229] = fine_delay_sel;
assign dbg_prbs_rdlvl[230+:8] = compare_err_pb_latch_r;
assign dbg_prbs_rdlvl[238+:6] = fine_pi_dec_cnt;
assign dbg_prbs_rdlvl[244+:5] = match_flag_and ;
assign dbg_prbs_rdlvl[249+:2] =stage_cnt ;
assign dbg_prbs_rdlvl[251] = fine_inc_stage ;
assign dbg_prbs_rdlvl[252] = compare_err_pb_and ;
assign dbg_prbs_rdlvl[253] = right_edge_found ;
assign dbg_prbs_rdlvl[254] = fine_dly_error ;
assign dbg_prbs_rdlvl[255]= 'b0;//reserved
//**************************************************************************
// Record first and second edges found during calibration
//**************************************************************************
generate
always @(posedge clk)
if (rst) begin
dbg_prbs_first_edge_taps <= #TCQ 'b0;
dbg_prbs_second_edge_taps <= #TCQ 'b0;
end else if (prbs_state_r == PRBS_CALC_TAPS) begin
// Record tap counts of first and second edge edges during
// calibration for each DQS group. If neither edge has
// been found, then those taps will remain 0
if (prbs_found_1st_edge_r)
dbg_prbs_first_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ prbs_1st_edge_taps_r;
if (prbs_found_2nd_edge_r)
dbg_prbs_second_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ prbs_2nd_edge_taps_r;
end else if (prbs_state_r == FINE_CALC_TAPS) begin
if(stage_cnt == 'd2) begin
dbg_prbs_first_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ largest_left_edge;
dbg_prbs_second_edge_taps[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ smallest_right_edge;
end
end
endgenerate
//padded calculation
always @ (smallest_right_edge or largest_left_edge)
center_calc <= {1'b0, smallest_right_edge} + {1'b0,largest_left_edge};
//***************************************************************************
//***************************************************************************
// Data mux to route appropriate bit to calibration logic - i.e. calibration
// is done sequentially, one bit (or DQS group) at a time
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: rd_data_div4_logic_clk
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign rd_data_rise2 = rd_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign rd_data_fall2 = rd_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign rd_data_rise3 = rd_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign rd_data_fall3 = rd_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
assign compare_data_r0 = compare_data[DQ_WIDTH-1:0];
assign compare_data_f0 = compare_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign compare_data_r1 = compare_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign compare_data_f1 = compare_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign compare_data_r2 = compare_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign compare_data_f2 = compare_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign compare_data_r3 = compare_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign compare_data_f3 = compare_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
end else begin: rd_data_div2_logic_clk
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign compare_data_r0 = compare_data[DQ_WIDTH-1:0];
assign compare_data_f0 = compare_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign compare_data_r1 = compare_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign compare_data_f1 = compare_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign compare_data_r2 = 'h0;
assign compare_data_f2 = 'h0;
assign compare_data_r3 = 'h0;
assign compare_data_f3 = 'h0;
end
endgenerate
always @(posedge clk) begin
rd_mux_sel_r <= #TCQ prbs_dqs_cnt_r;
end
// Register outputs for improved timing.
// NOTE: Will need to change when per-bit DQ deskew is supported.
// Currenly all bits in DQS group are checked in aggregate
generate
genvar mux_i;
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r1[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r1[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r1[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r1[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise2_r1[mux_i] <= #TCQ rd_data_rise2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall2_r1[mux_i] <= #TCQ rd_data_fall2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise3_r1[mux_i] <= #TCQ rd_data_rise3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall3_r1[mux_i] <= #TCQ rd_data_fall3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
//Compare data
compare_data_rise0_r1[mux_i] <= #TCQ compare_data_r0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall0_r1[mux_i] <= #TCQ compare_data_f0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_rise1_r1[mux_i] <= #TCQ compare_data_r1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall1_r1[mux_i] <= #TCQ compare_data_f1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_rise2_r1[mux_i] <= #TCQ compare_data_r2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall2_r1[mux_i] <= #TCQ compare_data_f2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_rise3_r1[mux_i] <= #TCQ compare_data_r3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
compare_data_fall3_r1[mux_i] <= #TCQ compare_data_f3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
endgenerate
generate
genvar muxr2_i;
if (nCK_PER_CLK == 4) begin: gen_mux_div4
for (muxr2_i = 0; muxr2_i < DRAM_WIDTH; muxr2_i = muxr2_i + 1) begin: gen_rd_4
always @(posedge clk) begin
if (mux_rd_valid_r) begin
mux_rd_rise0_r2[muxr2_i] <= #TCQ mux_rd_rise0_r1[muxr2_i];
mux_rd_fall0_r2[muxr2_i] <= #TCQ mux_rd_fall0_r1[muxr2_i];
mux_rd_rise1_r2[muxr2_i] <= #TCQ mux_rd_rise1_r1[muxr2_i];
mux_rd_fall1_r2[muxr2_i] <= #TCQ mux_rd_fall1_r1[muxr2_i];
mux_rd_rise2_r2[muxr2_i] <= #TCQ mux_rd_rise2_r1[muxr2_i];
mux_rd_fall2_r2[muxr2_i] <= #TCQ mux_rd_fall2_r1[muxr2_i];
mux_rd_rise3_r2[muxr2_i] <= #TCQ mux_rd_rise3_r1[muxr2_i];
mux_rd_fall3_r2[muxr2_i] <= #TCQ mux_rd_fall3_r1[muxr2_i];
end
//pipeline stage
mux_rd_rise0_r3[muxr2_i] <= #TCQ mux_rd_rise0_r2[muxr2_i];
mux_rd_fall0_r3[muxr2_i] <= #TCQ mux_rd_fall0_r2[muxr2_i];
mux_rd_rise1_r3[muxr2_i] <= #TCQ mux_rd_rise1_r2[muxr2_i];
mux_rd_fall1_r3[muxr2_i] <= #TCQ mux_rd_fall1_r2[muxr2_i];
mux_rd_rise2_r3[muxr2_i] <= #TCQ mux_rd_rise2_r2[muxr2_i];
mux_rd_fall2_r3[muxr2_i] <= #TCQ mux_rd_fall2_r2[muxr2_i];
mux_rd_rise3_r3[muxr2_i] <= #TCQ mux_rd_rise3_r2[muxr2_i];
mux_rd_fall3_r3[muxr2_i] <= #TCQ mux_rd_fall3_r2[muxr2_i];
//pipeline stage
mux_rd_rise0_r4[muxr2_i] <= #TCQ mux_rd_rise0_r3[muxr2_i];
mux_rd_fall0_r4[muxr2_i] <= #TCQ mux_rd_fall0_r3[muxr2_i];
mux_rd_rise1_r4[muxr2_i] <= #TCQ mux_rd_rise1_r3[muxr2_i];
mux_rd_fall1_r4[muxr2_i] <= #TCQ mux_rd_fall1_r3[muxr2_i];
mux_rd_rise2_r4[muxr2_i] <= #TCQ mux_rd_rise2_r3[muxr2_i];
mux_rd_fall2_r4[muxr2_i] <= #TCQ mux_rd_fall2_r3[muxr2_i];
mux_rd_rise3_r4[muxr2_i] <= #TCQ mux_rd_rise3_r3[muxr2_i];
mux_rd_fall3_r4[muxr2_i] <= #TCQ mux_rd_fall3_r3[muxr2_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_mux_div2
for (muxr2_i = 0; muxr2_i < DRAM_WIDTH; muxr2_i = muxr2_i + 1) begin: gen_rd_2
always @(posedge clk) begin
if (mux_rd_valid_r) begin
mux_rd_rise0_r2[muxr2_i] <= #TCQ mux_rd_rise0_r1[muxr2_i];
mux_rd_fall0_r2[muxr2_i] <= #TCQ mux_rd_fall0_r1[muxr2_i];
mux_rd_rise1_r2[muxr2_i] <= #TCQ mux_rd_rise1_r1[muxr2_i];
mux_rd_fall1_r2[muxr2_i] <= #TCQ mux_rd_fall1_r1[muxr2_i];
mux_rd_rise2_r2[muxr2_i] <= 'h0;
mux_rd_fall2_r2[muxr2_i] <= 'h0;
mux_rd_rise3_r2[muxr2_i] <= 'h0;
mux_rd_fall3_r2[muxr2_i] <= 'h0;
end
mux_rd_rise0_r3[muxr2_i] <= #TCQ mux_rd_rise0_r2[muxr2_i];
mux_rd_fall0_r3[muxr2_i] <= #TCQ mux_rd_fall0_r2[muxr2_i];
mux_rd_rise1_r3[muxr2_i] <= #TCQ mux_rd_rise1_r2[muxr2_i];
mux_rd_fall1_r3[muxr2_i] <= #TCQ mux_rd_fall1_r2[muxr2_i];
mux_rd_rise2_r3[muxr2_i] <= 'h0;
mux_rd_fall2_r3[muxr2_i] <= 'h0;
mux_rd_rise3_r3[muxr2_i] <= 'h0;
mux_rd_fall3_r3[muxr2_i] <= 'h0;
//pipeline stage
mux_rd_rise0_r4[muxr2_i] <= #TCQ mux_rd_rise0_r3[muxr2_i];
mux_rd_fall0_r4[muxr2_i] <= #TCQ mux_rd_fall0_r3[muxr2_i];
mux_rd_rise1_r4[muxr2_i] <= #TCQ mux_rd_rise1_r3[muxr2_i];
mux_rd_fall1_r4[muxr2_i] <= #TCQ mux_rd_fall1_r3[muxr2_i];
mux_rd_rise2_r4[muxr2_i] <= 'h0;
mux_rd_fall2_r4[muxr2_i] <= 'h0;
mux_rd_rise3_r4[muxr2_i] <= 'h0;
mux_rd_fall3_r4[muxr2_i] <= 'h0;
end
end
end
endgenerate
// Registered signal indicates when mux_rd_rise/fall_r is valid
always @(posedge clk) begin
mux_rd_valid_r <= #TCQ ~phy_if_empty && prbs_rdlvl_start;
rd_valid_r1 <= #TCQ mux_rd_valid_r;
rd_valid_r2 <= #TCQ rd_valid_r1;
rd_valid_r3 <= #TCQ rd_valid_r2;
end
// Counter counts # of samples compared
// Reset sample counter when not "sampling"
// Otherwise, count # of samples compared
// Same counter is shared for three samples checked
always @(posedge clk)
if (rst)
samples_cnt_r <= #TCQ 'b0;
else if (samples_cnt_r == NUM_SAMPLES_CNT) begin
samples_cnt_r <= #TCQ 'b0;
end else if (complex_sample_cnt_inc) begin
samples_cnt_r <= #TCQ samples_cnt_r + 1;
/*if (!rd_valid_r1 ||
(prbs_state_r == PRBS_DEC_DQS_WAIT) ||
(prbs_state_r == PRBS_INC_DQS_WAIT) ||
(prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS) ||
(samples_cnt_r == NUM_SAMPLES_CNT) ||
(samples_cnt_r == NUM_SAMPLES_CNT1))
samples_cnt_r <= #TCQ 'b0;
else if (rd_valid_r1 &&
(((samples_cnt_r < NUM_SAMPLES_CNT) && ~samples_cnt1_en_r) ||
((samples_cnt_r < NUM_SAMPLES_CNT1) && ~samples_cnt2_en_r) ||
((samples_cnt_r < NUM_SAMPLES_CNT2) && samples_cnt2_en_r)))
samples_cnt_r <= #TCQ samples_cnt_r + 1;*/
end
// Count #2 enable generation
// Assert when correct number of samples compared
always @(posedge clk)
if (rst)
samples_cnt1_en_r <= #TCQ 1'b0;
else begin
if ((prbs_state_r == PRBS_IDLE) ||
(prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS) ||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == PRBS_NEW_DQS_PREWAIT))
samples_cnt1_en_r <= #TCQ 1'b0;
else if ((samples_cnt_r == NUM_SAMPLES_CNT) && rd_valid_r1)
samples_cnt1_en_r <= #TCQ 1'b1;
end
// Counter #3 enable generation
// Assert when correct number of samples compared
always @(posedge clk)
if (rst)
samples_cnt2_en_r <= #TCQ 1'b0;
else begin
if ((prbs_state_r == PRBS_IDLE) ||
(prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS) ||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == PRBS_NEW_DQS_PREWAIT))
samples_cnt2_en_r <= #TCQ 1'b0;
else if ((samples_cnt_r == NUM_SAMPLES_CNT1) && rd_valid_r1 && samples_cnt1_en_r)
samples_cnt2_en_r <= #TCQ 1'b1;
end
// Victim selection logic
always @(posedge clk)
if (rst)
rd_victim_sel <= #TCQ 'd0;
else if (num_samples_done_r)
rd_victim_sel <= #TCQ 'd0;
else if (samples_cnt_r == NUM_SAMPLES_CNT) begin
if (rd_victim_sel < 'd7)
rd_victim_sel <= #TCQ rd_victim_sel + 1;
end
// Output row count increment pulse to phy_init
always @(posedge clk)
if (rst)
complex_victim_inc <= #TCQ 1'b0;
else if (samples_cnt_r == NUM_SAMPLES_CNT)
complex_victim_inc <= #TCQ 1'b1;
else
complex_victim_inc <= #TCQ 1'b0;
generate
if (FIXED_VICTIM == "TRUE") begin: victim_fixed
always @(posedge clk)
if (rst)
num_samples_done_r <= #TCQ 1'b0;
else if ((prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS)||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == FINE_PI_DEC))
num_samples_done_r <= #TCQ 'b0;
else if (samples_cnt_r == NUM_SAMPLES_CNT)
num_samples_done_r <= #TCQ 1'b1;
end else begin: victim_not_fixed
always @(posedge clk)
if (rst)
num_samples_done_r <= #TCQ 1'b0;
else if ((prbs_state_r == PRBS_DEC_DQS) ||
(prbs_state_r == PRBS_INC_DQS)||
(prbs_state_r == FINE_PI_INC) ||
(prbs_state_r == FINE_PI_DEC))
num_samples_done_r <= #TCQ 'b0;
else if ((samples_cnt_r == NUM_SAMPLES_CNT) && (rd_victim_sel == 'd7))
num_samples_done_r <= #TCQ 1'b1;
end
endgenerate
//***************************************************************************
// Compare Read Data for the byte being Leveled with Expected data from PRBS
// generator. Resulting compare_err signal used to determine read data valid
// edge.
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: cmp_err_4to1
always @ (posedge clk) begin
if (rst || new_cnt_dqs_r) begin
compare_err <= #TCQ 1'b0;
compare_err_r0 <= #TCQ 1'b0;
compare_err_f0 <= #TCQ 1'b0;
compare_err_r1 <= #TCQ 1'b0;
compare_err_f1 <= #TCQ 1'b0;
compare_err_r2 <= #TCQ 1'b0;
compare_err_f2 <= #TCQ 1'b0;
compare_err_r3 <= #TCQ 1'b0;
compare_err_f3 <= #TCQ 1'b0;
end else if (rd_valid_r2) begin
compare_err_r0 <= #TCQ (mux_rd_rise0_r3 != compare_data_rise0_r1);
compare_err_f0 <= #TCQ (mux_rd_fall0_r3 != compare_data_fall0_r1);
compare_err_r1 <= #TCQ (mux_rd_rise1_r3 != compare_data_rise1_r1);
compare_err_f1 <= #TCQ (mux_rd_fall1_r3 != compare_data_fall1_r1);
compare_err_r2 <= #TCQ (mux_rd_rise2_r3 != compare_data_rise2_r1);
compare_err_f2 <= #TCQ (mux_rd_fall2_r3 != compare_data_fall2_r1);
compare_err_r3 <= #TCQ (mux_rd_rise3_r3 != compare_data_rise3_r1);
compare_err_f3 <= #TCQ (mux_rd_fall3_r3 != compare_data_fall3_r1);
compare_err <= #TCQ (compare_err_r0 | compare_err_f0 |
compare_err_r1 | compare_err_f1 |
compare_err_r2 | compare_err_f2 |
compare_err_r3 | compare_err_f3);
end
end
end else begin: cmp_err_2to1
always @ (posedge clk) begin
if (rst || new_cnt_dqs_r) begin
compare_err <= #TCQ 1'b0;
compare_err_r0 <= #TCQ 1'b0;
compare_err_f0 <= #TCQ 1'b0;
compare_err_r1 <= #TCQ 1'b0;
compare_err_f1 <= #TCQ 1'b0;
end else if (rd_valid_r2) begin
compare_err_r0 <= #TCQ (mux_rd_rise0_r3 != compare_data_rise0_r1);
compare_err_f0 <= #TCQ (mux_rd_fall0_r3 != compare_data_fall0_r1);
compare_err_r1 <= #TCQ (mux_rd_rise1_r3 != compare_data_rise1_r1);
compare_err_f1 <= #TCQ (mux_rd_fall1_r3 != compare_data_fall1_r1);
compare_err <= #TCQ (compare_err_r0 | compare_err_f0 |
compare_err_r1 | compare_err_f1);
end
end
end
endgenerate
//***************************************************************************
// Decrement initial Phaser_IN fine delay value before proceeding with
// read calibration
//***************************************************************************
//***************************************************************************
// Demultiplexor to control Phaser_IN delay values
//***************************************************************************
// Read DQS
always @(posedge clk) begin
if (rst) begin
pi_en_stg2_f_timing <= #TCQ 'b0;
pi_stg2_f_incdec_timing <= #TCQ 'b0;
end else if (prbs_tap_en_r) begin
// Change only specified DQS
pi_en_stg2_f_timing <= #TCQ 1'b1;
pi_stg2_f_incdec_timing <= #TCQ prbs_tap_inc_r;
end else begin
pi_en_stg2_f_timing <= #TCQ 'b0;
pi_stg2_f_incdec_timing <= #TCQ 'b0;
end
end
// registered for timing
always @(posedge clk) begin
pi_en_stg2_f <= #TCQ pi_en_stg2_f_timing;
pi_stg2_f_incdec <= #TCQ pi_stg2_f_incdec_timing;
end
//***************************************************************************
// generate request to PHY_INIT logic to issue precharged. Required when
// calibration can take a long time (during which there are only constant
// reads present on this bus). In this case need to issue perioidic
// precharges to avoid tRAS violation. This signal must meet the following
// requirements: (1) only transition from 0->1 when prech is first needed,
// (2) stay at 1 and only transition 1->0 when RDLVL_PRECH_DONE asserted
//***************************************************************************
always @(posedge clk)
if (rst)
prbs_rdlvl_prech_req <= #TCQ 1'b0;
else
prbs_rdlvl_prech_req <= #TCQ prbs_prech_req_r;
//*****************************************************************
// keep track of edge tap counts found, and current capture clock
// tap count
//*****************************************************************
always @(posedge clk)
if (rst) begin
prbs_dqs_tap_cnt_r <= #TCQ 'b0;
rdlvl_cpt_tap_cnt <= #TCQ 'b0;
end else if (new_cnt_dqs_r) begin
prbs_dqs_tap_cnt_r <= #TCQ pi_counter_read_val;
rdlvl_cpt_tap_cnt <= #TCQ pi_counter_read_val;
end else if (prbs_tap_en_r) begin
if (prbs_tap_inc_r)
prbs_dqs_tap_cnt_r <= #TCQ prbs_dqs_tap_cnt_r + 1;
else if (prbs_dqs_tap_cnt_r != 'd0)
prbs_dqs_tap_cnt_r <= #TCQ prbs_dqs_tap_cnt_r - 1;
end
always @(posedge clk)
if (rst) begin
prbs_dec_tap_calc_plus_3 <= #TCQ 'b0;
prbs_dec_tap_calc_minus_3 <= #TCQ 'b0;
end else if (new_cnt_dqs_r) begin
prbs_dec_tap_calc_plus_3 <= #TCQ 'b000011;
prbs_dec_tap_calc_minus_3 <= #TCQ 'b111100;
end else begin
prbs_dec_tap_calc_plus_3 <= #TCQ (prbs_dqs_tap_cnt_r - rdlvl_cpt_tap_cnt + 3);
prbs_dec_tap_calc_minus_3 <= #TCQ (prbs_dqs_tap_cnt_r - rdlvl_cpt_tap_cnt - 3);
end
always @(posedge clk)
if (rst || new_cnt_dqs_r)
prbs_dqs_tap_limit_r <= #TCQ 1'b0;
else if (prbs_dqs_tap_cnt_r == 6'd63)
prbs_dqs_tap_limit_r <= #TCQ 1'b1;
else
prbs_dqs_tap_limit_r <= #TCQ 1'b0;
// Temp wire for timing.
// The following in the always block below causes timing issues
// due to DSP block inference
// 6*prbs_dqs_cnt_r.
// replacing this with two left shifts + one left shift to avoid
// DSP multiplier.
assign prbs_dqs_cnt_timing = {2'd0, prbs_dqs_cnt_r};
always @(posedge clk)
prbs_dqs_cnt_timing_r <= #TCQ prbs_dqs_cnt_timing;
// Storing DQS tap values at the end of each DQS read leveling
always @(posedge clk) begin
if (rst) begin
prbs_final_dqs_tap_cnt_r <= #TCQ 'b0;
end else if ((prbs_state_r == PRBS_NEXT_DQS) && (prbs_state_r1 != PRBS_NEXT_DQS)) begin
prbs_final_dqs_tap_cnt_r[(prbs_dqs_cnt_timing_r*6)+:6]
<= #TCQ prbs_dqs_tap_cnt_r;
end
end
//*****************************************************************
always @(posedge clk) begin
prbs_state_r1 <= #TCQ prbs_state_r;
prbs_rdlvl_start_r <= #TCQ prbs_rdlvl_start;
end
// Wait counter for wait states
always @(posedge clk)
if ((prbs_state_r == PRBS_NEW_DQS_WAIT) ||
(prbs_state_r == PRBS_INC_DQS_WAIT) ||
(prbs_state_r == PRBS_DEC_DQS_WAIT) ||
(prbs_state_r == FINE_PI_DEC_WAIT) ||
(prbs_state_r == FINE_PI_INC_WAIT) ||
(prbs_state_r == PRBS_NEW_DQS_PREWAIT))
wait_state_cnt_en_r <= #TCQ 1'b1;
else
wait_state_cnt_en_r <= #TCQ 1'b0;
always @(posedge clk)
if (!wait_state_cnt_en_r) begin
wait_state_cnt_r <= #TCQ 'b0;
cnt_wait_state <= #TCQ 1'b0;
end else begin
if (wait_state_cnt_r < 'd15) begin
wait_state_cnt_r <= #TCQ wait_state_cnt_r + 1;
cnt_wait_state <= #TCQ 1'b0;
end else begin
// Need to reset to 0 to handle the case when there are two
// different WAIT states back-to-back
wait_state_cnt_r <= #TCQ 'b0;
cnt_wait_state <= #TCQ 1'b1;
end
end
always @ (posedge clk)
err_chk_invalid <= #TCQ (wait_state_cnt_r < 'd14);
//*****************************************************************
// compare error checking per-bit
//****************************************************************
generate
genvar pb_i;
if (nCK_PER_CLK == 4) begin: cmp_err_pb_4to1
for(pb_i=0 ; pb_i<DRAM_WIDTH; pb_i=pb_i+1) begin
always @ (posedge clk) begin
//prevent error check during PI inc/dec and wait
if (rst || new_cnt_dqs_r || (prbs_state_r == FINE_PI_INC) || (prbs_state_r == FINE_PI_DEC) ||
(err_chk_invalid && ((prbs_state_r == FINE_PI_DEC_WAIT)||(prbs_state_r == FINE_PI_INC_WAIT))))
compare_err_pb[pb_i] <= #TCQ 1'b0;
else if (rd_valid_r2)
compare_err_pb[pb_i] <= #TCQ (mux_rd_rise0_r3[pb_i] != compare_data_rise0_r1[pb_i]) |
(mux_rd_fall0_r3[pb_i] != compare_data_fall0_r1[pb_i]) |
(mux_rd_rise1_r3[pb_i] != compare_data_rise1_r1[pb_i]) |
(mux_rd_fall1_r3[pb_i] != compare_data_fall1_r1[pb_i]) |
(mux_rd_rise2_r3[pb_i] != compare_data_rise2_r1[pb_i]) |
(mux_rd_fall2_r3[pb_i] != compare_data_fall2_r1[pb_i]) |
(mux_rd_rise3_r3[pb_i] != compare_data_rise3_r1[pb_i]) |
(mux_rd_fall3_r3[pb_i] != compare_data_fall3_r1[pb_i]) ;
end //always
end //for
end else begin: cmp_err_pb_2to1
for(pb_i=0 ; pb_i<DRAM_WIDTH; pb_i=pb_i+1) begin
always @ (posedge clk) begin
if (rst || new_cnt_dqs_r || (prbs_state_r == FINE_PI_INC) || (prbs_state_r == FINE_PI_DEC) ||
(err_chk_invalid && ((prbs_state_r == FINE_PI_DEC_WAIT)||(prbs_state_r == FINE_PI_INC_WAIT))))
compare_err_pb[pb_i] <= #TCQ 1'b0;
else if (rd_valid_r2)
compare_err_pb[pb_i] <= #TCQ (mux_rd_rise0_r3[pb_i] != compare_data_rise0_r1[pb_i]) |
(mux_rd_fall0_r3[pb_i] != compare_data_fall0_r1[pb_i]) |
(mux_rd_rise1_r3[pb_i] != compare_data_rise1_r1[pb_i]) |
(mux_rd_fall1_r3[pb_i] != compare_data_fall1_r1[pb_i]) ;
end //always
end //for
end //if
endgenerate
//checking all bit has error
always @ (posedge clk) begin
if(rst || new_cnt_dqs_r) begin
compare_err_pb_and <= #TCQ 1'b0;
end else begin
compare_err_pb_and <= #TCQ &compare_err_pb;
end
end
//generate stick error bit - left/right edge
generate
genvar pb_r;
for(pb_r=0; pb_r<DRAM_WIDTH; pb_r=pb_r+1) begin
always @ (posedge clk) begin
if((prbs_state_r == FINE_PI_INC) | (prbs_state_r == FINE_PI_DEC) |
(~cnt_wait_state && ((prbs_state_r == FINE_PI_INC_WAIT)|(prbs_state_r == FINE_PI_DEC_WAIT))))
compare_err_pb_latch_r[pb_r] <= #TCQ 1'b0;
else
compare_err_pb_latch_r[pb_r] <= #TCQ compare_err_pb[pb_r]? 1'b1:compare_err_pb_latch_r[pb_r];
end
end
endgenerate
//in stage 0, if left edge found, update ref_bit (one hot)
always @ (posedge clk) begin
if (rst | (prbs_state_r == PRBS_NEW_DQS_WAIT)) begin
ref_bit_per_bit <= #TCQ 'd0;
end else if ((prbs_state_r == FINE_PI_INC) && (stage_cnt=='b0)) begin
if(|left_edge_updated) ref_bit_per_bit <= #TCQ left_edge_updated;
end
end
//ref bit with samllest right edge
//if bit 1 and 3 are set to ref_bit_per_bit but bit 1 has smaller right edge, bit is selected as ref_bit
always @ (posedge clk) begin
if(rst | (prbs_state_r == PRBS_NEW_DQS_WAIT)) begin
bit_cnt <= #TCQ 'd0;
ref_right_edge <= #TCQ 6'h3f;
ref_bit <= #TCQ 'd0;
end else if ((prbs_state_r == FINE_CALC_TAPS_WAIT) && (stage_cnt == 'b0) && (bit_cnt < DRAM_WIDTH)) begin
bit_cnt <= #TCQ bit_cnt +'b1;
if ((ref_bit_per_bit[bit_cnt]==1'b1) && (right_edge_pb[bit_cnt*6+:6]<= ref_right_edge)) begin
ref_bit <= #TCQ bit_cnt;
ref_right_edge <= #TCQ right_edge_pb[bit_cnt*6+:6];
end
end
end
//pipe lining for reference bit left/right edge
always @ (posedge clk) begin
left_edge_ref <= #TCQ left_edge_pb[ref_bit*6+:6];
right_edge_ref <= #TCQ right_edge_pb[ref_bit*6+:6];
end
//left_edge/right_edge/left_loss/right_gain update
generate
genvar eg;
for(eg=0; eg<DRAM_WIDTH; eg = eg+1) begin
always @ (posedge clk) begin
if(rst | (prbs_state_r == PRBS_NEW_DQS_WAIT)) begin
match_flag_pb[eg*5+:5] <= #TCQ 5'h1f;
left_edge_pb[eg*6+:6] <= #TCQ 'b0;
right_edge_pb[eg*6+:6] <= #TCQ 6'h3f;
left_edge_found_pb[eg] <= #TCQ 1'b0;
right_edge_found_pb[eg] <= #TCQ 1'b0;
left_loss_pb[eg*6+:6] <= #TCQ 'b0;
right_gain_pb[eg*6+:6] <= #TCQ 'b0;
left_edge_updated[eg] <= #TCQ 'b0;
end else begin
if((prbs_state_r == FINE_PAT_COMPARE_PER_BIT) && (num_samples_done_r || compare_err_pb_and)) begin
//left edge is updated when match flag becomes 100000 (1 fail , 5 success)
if(match_flag_pb[eg*5+:5]==5'b10000 && compare_err_pb_latch_r[eg]==0) begin
left_edge_pb[eg*6+:6] <= #TCQ prbs_dqs_tap_cnt_r-4;
left_edge_found_pb[eg] <= #TCQ 1'b1; //used for update largest_left_edge
left_edge_updated[eg] <= #TCQ 1'b1;
//check the loss of bit - update only for left edge found
if(~left_edge_found_pb[eg])
left_loss_pb[eg*6+:6] <= #TCQ (left_edge_ref > prbs_dqs_tap_cnt_r - 4)? 'd0
: prbs_dqs_tap_cnt_r-4-left_edge_ref;
//right edge is updated when match flag becomes 000001 (5 success, 1 fail)
end else if (match_flag_pb[eg*5+:5]==5'b00000 && compare_err_pb_latch_r[eg]) begin
right_edge_pb[eg*6+:6] <= #TCQ prbs_dqs_tap_cnt_r-1;
right_edge_found_pb[eg] <= #TCQ 1'b1;
//check the gain of bit - update only for right edge found
if(~right_edge_found_pb[eg])
right_gain_pb[eg*6+:6] <= #TCQ (right_edge_ref > prbs_dqs_tap_cnt_r-1)?
((right_edge_pb[eg*6 +:6] > prbs_dqs_tap_cnt_r-1)? 0: prbs_dqs_tap_cnt_r-1- right_edge_pb[eg*6+:6]):
((right_edge_pb[eg*6+:6] > right_edge_ref)? 0 : right_edge_ref - right_edge_pb[eg*6+:6]);
//no right edge found
end else if (prbs_dqs_tap_cnt_r == 6'h3f && ~right_edge_found_pb[eg]) begin
right_edge_pb[eg*6+:6] <= #TCQ 6'h3f;
right_edge_found_pb[eg] <= #TCQ 1'b1;
//right edge at 63. gain = max(0, ref_bit_right_tap - prev_right_edge)
right_gain_pb[eg*6+:6] <= #TCQ (right_edge_ref > right_edge_pb[eg*6+:6])?
(right_edge_ref - right_edge_pb[eg*6+:6]) : 0;
end
//update match flag - shift and update
match_flag_pb[eg*5+:5] <= #TCQ {match_flag_pb[(eg*5)+:4],compare_err_pb_latch_r[eg]};
end else if (prbs_state_r == FINE_PI_DEC) begin
left_edge_found_pb[eg] <= #TCQ 1'b0;
right_edge_found_pb[eg] <= #TCQ 1'b0;
left_loss_pb[eg*6+:6] <= #TCQ 'b0;
right_gain_pb[eg*6+:6] <= #TCQ 'b0;
match_flag_pb[eg*5+:5] <= #TCQ 5'h1f; //new fix
end else if (prbs_state_r == FINE_PI_INC) begin
left_edge_updated[eg] <= #TCQ 'b0; //used only for update largest ref_bit and largest_left_edge
end
end
end //always
end //for
endgenerate
//update fine_delay according to loss/gain value per bit
generate
genvar f_pb;
for(f_pb=0; f_pb<DRAM_WIDTH; f_pb=f_pb+1) begin
always @ (posedge clk) begin
if(rst | prbs_state_r == PRBS_NEW_DQS_WAIT ) begin
fine_delay_incdec_pb[f_pb] <= #TCQ 1'b0;
end else if((prbs_state_r == FINE_CALC_TAPS_WAIT) && (bit_cnt == DRAM_WIDTH)) begin
if(stage_cnt == 'd0) fine_delay_incdec_pb[f_pb] <= #TCQ (f_pb==ref_bit)? 1'b0:1'b1; //only for initial stage
else if(stage_cnt == 'd1) fine_delay_incdec_pb[f_pb] <= #TCQ (right_gain_pb[f_pb*6+:6]>left_loss_pb[f_pb*6+:6])?1'b1:1'b0;
end
end
end
endgenerate
//fine inc stage (stage cnt 0,1,2), fine dec stage (stage cnt 3)
always @ (posedge clk) begin
if (rst)
fine_inc_stage <= #TCQ 'b1;
else
fine_inc_stage <= #TCQ (stage_cnt!='d3);
end
//*****************************************************************
always @(posedge clk)
if (rst) begin
prbs_dqs_cnt_r <= #TCQ 'b0;
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
prbs_prech_req_r <= #TCQ 1'b0;
prbs_state_r <= #TCQ PRBS_IDLE;
prbs_found_1st_edge_r <= #TCQ 1'b0;
prbs_found_2nd_edge_r <= #TCQ 1'b0;
prbs_1st_edge_taps_r <= #TCQ 6'bxxxxxx;
prbs_inc_tap_cnt <= #TCQ 'b0;
prbs_dec_tap_cnt <= #TCQ 'b0;
new_cnt_dqs_r <= #TCQ 1'b0;
if (SIM_CAL_OPTION == "FAST_CAL")
prbs_rdlvl_done <= #TCQ 1'b1;
else
prbs_rdlvl_done <= #TCQ 1'b0;
prbs_2nd_edge_taps_r <= #TCQ 6'bxxxxxx;
prbs_last_byte_done <= #TCQ 1'b0;
prbs_tap_mod <= #TCQ 'd0;
reset_rd_addr <= #TCQ 'b0;
read_pause <= #TCQ 'b0;
fine_pi_dec_cnt <= #TCQ 'b0;
match_flag_and <= #TCQ 5'h1f;
stage_cnt <= #TCQ 2'b00;
right_edge_found <= #TCQ 1'b0;
largest_left_edge <= #TCQ 6'b000000;
smallest_right_edge <= #TCQ 6'b111111;
num_samples_done_ind <= #TCQ 'b0;
fine_delay_sel <= #TCQ 'b0;
fine_dly_error <= #TCQ 'b0;
end else begin
case (prbs_state_r)
PRBS_IDLE: begin
prbs_last_byte_done <= #TCQ 1'b0;
prbs_prech_req_r <= #TCQ 1'b0;
if (prbs_rdlvl_start && ~prbs_rdlvl_start_r) begin
if (SIM_CAL_OPTION == "SKIP_CAL" || SIM_CAL_OPTION == "FAST_CAL") begin
prbs_state_r <= #TCQ PRBS_DONE;
reset_rd_addr <= #TCQ 1'b1;
end else begin
new_cnt_dqs_r <= #TCQ 1'b1;
prbs_state_r <= #TCQ PRBS_NEW_DQS_WAIT;
fine_pi_dec_cnt <= #TCQ pi_counter_read_val;//.
end
end
end
// Wait for the new DQS group to change
// also gives time for the read data IN_FIFO to
// output the updated data for the new DQS group
PRBS_NEW_DQS_WAIT: begin
reset_rd_addr <= #TCQ 'b0;
prbs_last_byte_done <= #TCQ 1'b0;
prbs_prech_req_r <= #TCQ 1'b0;
//fine_inc_stage <= #TCQ 1'b1;
stage_cnt <= #TCQ 2'b0;
match_flag_and <= #TCQ 5'h1f;
if (cnt_wait_state) begin
new_cnt_dqs_r <= #TCQ 1'b0;
prbs_state_r <= #TCQ fine_calib? FINE_PI_DEC:PRBS_PAT_COMPARE;
end
end
// Check for presence of data eye edge. During this state, we
// sample the read data multiple times, and look for changes
// in the read data, specifically:
// 1. A change in the read data compared with the value of
// read data from the previous delay tap. This indicates
// that the most recent tap delay increment has moved us
// into either a new window, or moved/kept us in the
// transition/jitter region between windows. Note that this
// condition only needs to be checked for once, and for
// logistical purposes, we check this soon after entering
// this state (see comment in PRBS_PAT_COMPARE below for
// why this is done)
// 2. A change in the read data while we are in this state
// (i.e. in the absence of a tap delay increment). This
// indicates that we're close enough to a window edge that
// jitter will cause the read data to change even in the
// absence of a tap delay change
PRBS_PAT_COMPARE: begin
// Continue to sample read data and look for edges until the
// appropriate time interval (shorter for simulation-only,
// much, much longer for actual h/w) has elapsed
if (num_samples_done_r || compare_err) begin
if (prbs_dqs_tap_limit_r)
// Only one edge detected and ran out of taps since only one
// bit time worth of taps available for window detection. This
// can happen if at tap 0 DQS is in previous window which results
// in only left edge being detected. Or at tap 0 DQS is in the
// current window resulting in only right edge being detected.
// Depending on the frequency this case can also happen if at
// tap 0 DQS is in the left noise region resulting in only left
// edge being detected.
prbs_state_r <= #TCQ PRBS_CALC_TAPS_PRE;
else if (compare_err || (prbs_dqs_tap_cnt_r == 'd0)) begin
// Sticky bit - asserted after we encounter an edge, although
// the current edge may not be considered the "first edge" this
// just means we found at least one edge
prbs_found_1st_edge_r <= #TCQ 1'b1;
// Both edges of data valid window found:
// If we've found a second edge after a region of stability
// then we must have just passed the second ("right" edge of
// the window. Record this second_edge_taps = current tap-1,
// because we're one past the actual second edge tap, where
// the edge taps represent the extremes of the data valid
// window (i.e. smallest & largest taps where data still valid
if (prbs_found_1st_edge_r) begin
prbs_found_2nd_edge_r <= #TCQ 1'b1;
prbs_2nd_edge_taps_r <= #TCQ prbs_dqs_tap_cnt_r - 1;
prbs_state_r <= #TCQ PRBS_CALC_TAPS_PRE;
end else begin
// Otherwise, an edge was found (just not the "second" edge)
// Assuming DQS is in the correct window at tap 0 of Phaser IN
// fine tap. The first edge found is the right edge of the valid
// window and is the beginning of the jitter region hence done!
if (compare_err)
prbs_1st_edge_taps_r <= #TCQ prbs_dqs_tap_cnt_r + 1;
else
prbs_1st_edge_taps_r <= #TCQ 'd0;
prbs_inc_tap_cnt <= #TCQ rdlvl_cpt_tap_cnt - prbs_dqs_tap_cnt_r;
prbs_state_r <= #TCQ PRBS_INC_DQS;
end
end else begin
// Otherwise, if we haven't found an edge....
// If we still have taps left to use, then keep incrementing
if (prbs_found_1st_edge_r)
prbs_state_r <= #TCQ PRBS_INC_DQS;
else
prbs_state_r <= #TCQ PRBS_DEC_DQS;
end
end
end
// Increment Phaser_IN delay for DQS
PRBS_INC_DQS: begin
prbs_state_r <= #TCQ PRBS_INC_DQS_WAIT;
if (prbs_inc_tap_cnt > 'd0)
prbs_inc_tap_cnt <= #TCQ prbs_inc_tap_cnt - 1;
if (~prbs_dqs_tap_limit_r) begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b1;
end
end
// Wait for Phaser_In to settle, before checking again for an edge
PRBS_INC_DQS_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if (cnt_wait_state) begin
if (prbs_inc_tap_cnt > 'd0)
prbs_state_r <= #TCQ PRBS_INC_DQS;
else
prbs_state_r <= #TCQ PRBS_PAT_COMPARE;
end
end
// Calculate final value of Phaser_IN taps. At this point, one or both
// edges of data eye have been found, and/or all taps have been
// exhausted looking for the edges
// NOTE: The amount to be decrement by is calculated, not the
// absolute setting for DQS.
// CENTER compensation with shift by 1
PRBS_CALC_TAPS: begin
if (center_comp) begin
prbs_dec_tap_cnt <= #TCQ (dec_cnt[5] & dec_cnt[0])? 'd32: dec_cnt + pi_adj;
fine_dly_error <= #TCQ (dec_cnt[5] & dec_cnt[0])? 1'b1: fine_dly_error; //sticky bit
read_pause <= #TCQ 'b1;
prbs_state_r <= #TCQ PRBS_DEC_DQS;
end else begin //No center compensation
if (prbs_found_2nd_edge_r && prbs_found_1st_edge_r)
// Both edges detected
prbs_dec_tap_cnt
<= #TCQ ((prbs_2nd_edge_taps_r -
prbs_1st_edge_taps_r)>>1) + 1 + pi_adj;
else if (~prbs_found_2nd_edge_r && prbs_found_1st_edge_r)
// Only left edge detected
prbs_dec_tap_cnt
<= #TCQ ((prbs_dqs_tap_cnt_r - prbs_1st_edge_taps_r)>>1) + pi_adj;
else
// No edges detected
prbs_dec_tap_cnt
<= #TCQ (prbs_dqs_tap_cnt_r>>1) + pi_adj;
// Now use the value we just calculated to decrement CPT taps
// to the desired calibration point
read_pause <= #TCQ 'b1;
prbs_state_r <= #TCQ PRBS_DEC_DQS;
end
end
// decrement capture clock for final adjustment - center
// capture clock in middle of data eye. This adjustment will occur
// only when both the edges are found usign CPT taps. Must do this
// incrementally to avoid clock glitching (since CPT drives clock
// divider within each ISERDES)
PRBS_DEC_DQS: begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b0;
// once adjustment is complete, we're done with calibration for
// this DQS, repeat for next DQS
if (prbs_dec_tap_cnt > 'd0)
prbs_dec_tap_cnt <= #TCQ prbs_dec_tap_cnt - 1;
if (prbs_dec_tap_cnt == 6'b000001)
prbs_state_r <= #TCQ PRBS_NEXT_DQS;
else
prbs_state_r <= #TCQ PRBS_DEC_DQS_WAIT;
end
PRBS_DEC_DQS_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if (cnt_wait_state) begin
if (prbs_dec_tap_cnt > 'd0)
prbs_state_r <= #TCQ PRBS_DEC_DQS;
else
prbs_state_r <= #TCQ PRBS_PAT_COMPARE;
end
end
// Determine whether we're done, or have more DQS's to calibrate
// Also request precharge after every byte, as appropriate
PRBS_NEXT_DQS: begin
read_pause <= #TCQ 'b0;
reset_rd_addr <= #TCQ 'b1;
prbs_prech_req_r <= #TCQ 1'b1;
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
// Prepare for another iteration with next DQS group
prbs_found_1st_edge_r <= #TCQ 1'b0;
prbs_found_2nd_edge_r <= #TCQ 1'b0;
prbs_1st_edge_taps_r <= #TCQ 'd0;
prbs_2nd_edge_taps_r <= #TCQ 'd0;
largest_left_edge <= #TCQ 6'b000000;
smallest_right_edge <= #TCQ 6'b111111;
if (prbs_dqs_cnt_r >= DQS_WIDTH-1) begin
prbs_last_byte_done <= #TCQ 1'b1;
end
// Wait until precharge that occurs in between calibration of
// DQS groups is finished
if (prech_done) begin
prbs_prech_req_r <= #TCQ 1'b0;
if (prbs_dqs_cnt_r >= DQS_WIDTH-1) begin
// All DQS groups done
prbs_state_r <= #TCQ PRBS_DONE;
end else begin
// Process next DQS group
new_cnt_dqs_r <= #TCQ 1'b1;
//fine_pi_dec_cnt <= #TCQ pi_counter_read_val;//.
prbs_dqs_cnt_r <= #TCQ prbs_dqs_cnt_r + 1;
prbs_state_r <= #TCQ PRBS_NEW_DQS_PREWAIT;
end
end
end
PRBS_NEW_DQS_PREWAIT: begin
if (cnt_wait_state) begin
prbs_state_r <= #TCQ PRBS_NEW_DQS_WAIT;
fine_pi_dec_cnt <= #TCQ pi_counter_read_val;//.
end
end
PRBS_CALC_TAPS_PRE:
begin
if(num_samples_done_r) begin
prbs_state_r <= #TCQ fine_calib? PRBS_NEXT_DQS:PRBS_CALC_TAPS_WAIT;
if(center_comp && ~fine_calib) begin
if(prbs_found_1st_edge_r) largest_left_edge <= #TCQ prbs_1st_edge_taps_r;
else largest_left_edge <= #TCQ 6'd0;
if(prbs_found_2nd_edge_r) smallest_right_edge <= #TCQ prbs_2nd_edge_taps_r;
else smallest_right_edge <= #TCQ 6'd63;
end
end
end
//wait for center compensation
PRBS_CALC_TAPS_WAIT:
begin
prbs_state_r <= #TCQ PRBS_CALC_TAPS;
end
//if it is fine_inc stage (first/second stage): dec to 0
//if it is fine_dec stage (third stage): dec to center
FINE_PI_DEC: begin
fine_delay_sel <= #TCQ 'b0;
if(fine_pi_dec_cnt > 0) begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b0;
fine_pi_dec_cnt <= #TCQ fine_pi_dec_cnt - 'd1;
end
prbs_state_r <= #TCQ FINE_PI_DEC_WAIT;
end
//wait for phaser_in tap decrement.
//if first/second stage is done, goes to FINE_PI_INC
//if last stage is done, goes to NEXT_DQS
FINE_PI_DEC_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if(cnt_wait_state) begin
if(fine_pi_dec_cnt >0)
prbs_state_r <= #TCQ FINE_PI_DEC;
else
if(fine_inc_stage)
// prbs_state_r <= #TCQ FINE_PI_INC; //for temp change
prbs_state_r <= #TCQ FINE_PAT_COMPARE_PER_BIT; //start from pi tap "0"
else
prbs_state_r <= #TCQ PRBS_CALC_TAPS_PRE; //finish the process and go to the next DQS
end
end
FINE_PI_INC: begin
if(|left_edge_updated) largest_left_edge <= #TCQ prbs_dqs_tap_cnt_r-4;
if(|right_edge_found_pb && ~right_edge_found) begin
smallest_right_edge <= #TCQ prbs_dqs_tap_cnt_r -1 ;
right_edge_found <= #TCQ 'b1;
end
//left_edge_found_pb <= #TCQ {DRAM_WIDTH{1'b0}};
prbs_state_r <= #TCQ FINE_PI_INC_WAIT;
if(~prbs_dqs_tap_limit_r) begin
prbs_tap_en_r <= #TCQ 1'b1;
prbs_tap_inc_r <= #TCQ 1'b1;
end
end
//wait for phase_in tap increment
//need to do pattern compare for every bit
FINE_PI_INC_WAIT: begin
prbs_tap_en_r <= #TCQ 1'b0;
prbs_tap_inc_r <= #TCQ 1'b0;
if (cnt_wait_state) begin
prbs_state_r <= #TCQ FINE_PAT_COMPARE_PER_BIT;
end
end
//compare per bit data and update flags,left/right edge
FINE_PAT_COMPARE_PER_BIT: begin
if(num_samples_done_r || compare_err_pb_and) begin
//update and_flag - shift and add
match_flag_and <= #TCQ {match_flag_and[3:0],compare_err_pb_and};
//if it is consecutive 5 passing taps followed by fail or tap limit (finish the search)
//don't go to fine_FINE_CALC_TAPS to prevent to skip whole stage
//Or if all right edge are found
if((match_flag_and == 5'b00000 && compare_err_pb_and && (prbs_dqs_tap_cnt_r > 5)) || prbs_dqs_tap_limit_r || (&right_edge_found_pb)) begin
prbs_state_r <= #TCQ FINE_CALC_TAPS;
//if all right edge are alined (all right edge found at the same time), update smallest right edge in here
//doesnt need to set right_edge_found to 1 since it is not used after this stage
if(!right_edge_found) smallest_right_edge <= #TCQ prbs_dqs_tap_cnt_r-1;
end else begin
prbs_state_r <= #TCQ FINE_PI_INC; //keep increase until all fail
end
num_samples_done_ind <= num_samples_done_r;
end
end
//for fine_inc stage, inc all fine delay
//for fine_dec stage, apply dec fine delay for specific bits (by calculating the loss/gain)
// put phaser_in taps to the center
FINE_CALC_TAPS: begin
if(num_samples_done_ind || num_samples_done_r) begin
num_samples_done_ind <= #TCQ 'b0; //indicate num_samples_done_r is set
right_edge_found <= #TCQ 1'b0; //reset right edge found
match_flag_and <= #TCQ 5'h1f; //reset match flag for all bits
prbs_state_r <= #TCQ FINE_CALC_TAPS_WAIT;
end
end
FINE_CALC_TAPS_WAIT: begin //wait for ROM read out
if(stage_cnt == 'd2) begin //last stage : back to center
if(center_comp) begin
fine_pi_dec_cnt <= #TCQ (dec_cnt[5]&dec_cnt[0])? 'd32: prbs_dqs_tap_cnt_r - smallest_right_edge + dec_cnt - 1 + pi_adj ; //going to the center value & shift by 1
fine_dly_error <= #TCQ (dec_cnt[5]&dec_cnt[0]) ? 1'b1: fine_dly_error;
end else begin
fine_pi_dec_cnt <= #TCQ prbs_dqs_tap_cnt_r - center_calc[6:1] - center_calc[0] + pi_adj; //going to the center value & shift left by 1
fine_dly_error <= #TCQ 1'b0;
end
end else begin
fine_pi_dec_cnt <= #TCQ prbs_dqs_tap_cnt_r;
end
if (bit_cnt == DRAM_WIDTH) begin
fine_delay_sel <= #TCQ 'b1;
stage_cnt <= #TCQ stage_cnt + 1;
prbs_state_r <= #TCQ FINE_PI_DEC;
end
end
// Done with this stage of calibration
PRBS_DONE: begin
prbs_prech_req_r <= #TCQ 1'b0;
prbs_last_byte_done <= #TCQ 1'b0;
prbs_rdlvl_done <= #TCQ 1'b1;
reset_rd_addr <= #TCQ 1'b0;
end
endcase
end
//ROM generation for dec counter
always @ (largest_left_edge or smallest_right_edge) begin
case ({largest_left_edge, smallest_right_edge})
12'd0 : mem_out_dec = 6'b111111;
12'd1 : mem_out_dec = 6'b111111;
12'd2 : mem_out_dec = 6'b111111;
12'd3 : mem_out_dec = 6'b111111;
12'd4 : mem_out_dec = 6'b111111;
12'd5 : mem_out_dec = 6'b111111;
12'd6 : mem_out_dec = 6'b000100;
12'd7 : mem_out_dec = 6'b000101;
12'd8 : mem_out_dec = 6'b000101;
12'd9 : mem_out_dec = 6'b000110;
12'd10 : mem_out_dec = 6'b000110;
12'd11 : mem_out_dec = 6'b000111;
12'd12 : mem_out_dec = 6'b001000;
12'd13 : mem_out_dec = 6'b001000;
12'd14 : mem_out_dec = 6'b001001;
12'd15 : mem_out_dec = 6'b001010;
12'd16 : mem_out_dec = 6'b001010;
12'd17 : mem_out_dec = 6'b001011;
12'd18 : mem_out_dec = 6'b001011;
12'd19 : mem_out_dec = 6'b001100;
12'd20 : mem_out_dec = 6'b001100;
12'd21 : mem_out_dec = 6'b001100;
12'd22 : mem_out_dec = 6'b001100;
12'd23 : mem_out_dec = 6'b001101;
12'd24 : mem_out_dec = 6'b001100;
12'd25 : mem_out_dec = 6'b001100;
12'd26 : mem_out_dec = 6'b001101;
12'd27 : mem_out_dec = 6'b001110;
12'd28 : mem_out_dec = 6'b001110;
12'd29 : mem_out_dec = 6'b001111;
12'd30 : mem_out_dec = 6'b010000;
12'd31 : mem_out_dec = 6'b010001;
12'd32 : mem_out_dec = 6'b010001;
12'd33 : mem_out_dec = 6'b010010;
12'd34 : mem_out_dec = 6'b010010;
12'd35 : mem_out_dec = 6'b010010;
12'd36 : mem_out_dec = 6'b010011;
12'd37 : mem_out_dec = 6'b010100;
12'd38 : mem_out_dec = 6'b010100;
12'd39 : mem_out_dec = 6'b010101;
12'd40 : mem_out_dec = 6'b010101;
12'd41 : mem_out_dec = 6'b010110;
12'd42 : mem_out_dec = 6'b010110;
12'd43 : mem_out_dec = 6'b010111;
12'd44 : mem_out_dec = 6'b011000;
12'd45 : mem_out_dec = 6'b011001;
12'd46 : mem_out_dec = 6'b011001;
12'd47 : mem_out_dec = 6'b011010;
12'd48 : mem_out_dec = 6'b011010;
12'd49 : mem_out_dec = 6'b011011;
12'd50 : mem_out_dec = 6'b011011;
12'd51 : mem_out_dec = 6'b011100;
12'd52 : mem_out_dec = 6'b011100;
12'd53 : mem_out_dec = 6'b011100;
12'd54 : mem_out_dec = 6'b011100;
12'd55 : mem_out_dec = 6'b011100;
12'd56 : mem_out_dec = 6'b011100;
12'd57 : mem_out_dec = 6'b011100;
12'd58 : mem_out_dec = 6'b011100;
12'd59 : mem_out_dec = 6'b011101;
12'd60 : mem_out_dec = 6'b011110;
12'd61 : mem_out_dec = 6'b011111;
12'd62 : mem_out_dec = 6'b100000;
12'd63 : mem_out_dec = 6'b100000;
12'd64 : mem_out_dec = 6'b111111;
12'd65 : mem_out_dec = 6'b111111;
12'd66 : mem_out_dec = 6'b111111;
12'd67 : mem_out_dec = 6'b111111;
12'd68 : mem_out_dec = 6'b111111;
12'd69 : mem_out_dec = 6'b111111;
12'd70 : mem_out_dec = 6'b111111;
12'd71 : mem_out_dec = 6'b000100;
12'd72 : mem_out_dec = 6'b000100;
12'd73 : mem_out_dec = 6'b000101;
12'd74 : mem_out_dec = 6'b000110;
12'd75 : mem_out_dec = 6'b000111;
12'd76 : mem_out_dec = 6'b000111;
12'd77 : mem_out_dec = 6'b001000;
12'd78 : mem_out_dec = 6'b001001;
12'd79 : mem_out_dec = 6'b001001;
12'd80 : mem_out_dec = 6'b001010;
12'd81 : mem_out_dec = 6'b001010;
12'd82 : mem_out_dec = 6'b001011;
12'd83 : mem_out_dec = 6'b001011;
12'd84 : mem_out_dec = 6'b001011;
12'd85 : mem_out_dec = 6'b001011;
12'd86 : mem_out_dec = 6'b001011;
12'd87 : mem_out_dec = 6'b001100;
12'd88 : mem_out_dec = 6'b001011;
12'd89 : mem_out_dec = 6'b001100;
12'd90 : mem_out_dec = 6'b001100;
12'd91 : mem_out_dec = 6'b001101;
12'd92 : mem_out_dec = 6'b001110;
12'd93 : mem_out_dec = 6'b001111;
12'd94 : mem_out_dec = 6'b001111;
12'd95 : mem_out_dec = 6'b010000;
12'd96 : mem_out_dec = 6'b010001;
12'd97 : mem_out_dec = 6'b010001;
12'd98 : mem_out_dec = 6'b010010;
12'd99 : mem_out_dec = 6'b010010;
12'd100 : mem_out_dec = 6'b010011;
12'd101 : mem_out_dec = 6'b010011;
12'd102 : mem_out_dec = 6'b010100;
12'd103 : mem_out_dec = 6'b010100;
12'd104 : mem_out_dec = 6'b010100;
12'd105 : mem_out_dec = 6'b010101;
12'd106 : mem_out_dec = 6'b010110;
12'd107 : mem_out_dec = 6'b010111;
12'd108 : mem_out_dec = 6'b010111;
12'd109 : mem_out_dec = 6'b011000;
12'd110 : mem_out_dec = 6'b011001;
12'd111 : mem_out_dec = 6'b011001;
12'd112 : mem_out_dec = 6'b011010;
12'd113 : mem_out_dec = 6'b011010;
12'd114 : mem_out_dec = 6'b011011;
12'd115 : mem_out_dec = 6'b011011;
12'd116 : mem_out_dec = 6'b011011;
12'd117 : mem_out_dec = 6'b011011;
12'd118 : mem_out_dec = 6'b011011;
12'd119 : mem_out_dec = 6'b011011;
12'd120 : mem_out_dec = 6'b011011;
12'd121 : mem_out_dec = 6'b011011;
12'd122 : mem_out_dec = 6'b011100;
12'd123 : mem_out_dec = 6'b011101;
12'd124 : mem_out_dec = 6'b011110;
12'd125 : mem_out_dec = 6'b011110;
12'd126 : mem_out_dec = 6'b011111;
12'd127 : mem_out_dec = 6'b100000;
12'd128 : mem_out_dec = 6'b111111;
12'd129 : mem_out_dec = 6'b111111;
12'd130 : mem_out_dec = 6'b111111;
12'd131 : mem_out_dec = 6'b111111;
12'd132 : mem_out_dec = 6'b111111;
12'd133 : mem_out_dec = 6'b111111;
12'd134 : mem_out_dec = 6'b111111;
12'd135 : mem_out_dec = 6'b111111;
12'd136 : mem_out_dec = 6'b000100;
12'd137 : mem_out_dec = 6'b000101;
12'd138 : mem_out_dec = 6'b000101;
12'd139 : mem_out_dec = 6'b000110;
12'd140 : mem_out_dec = 6'b000110;
12'd141 : mem_out_dec = 6'b000111;
12'd142 : mem_out_dec = 6'b001000;
12'd143 : mem_out_dec = 6'b001001;
12'd144 : mem_out_dec = 6'b001001;
12'd145 : mem_out_dec = 6'b001010;
12'd146 : mem_out_dec = 6'b001010;
12'd147 : mem_out_dec = 6'b001010;
12'd148 : mem_out_dec = 6'b001010;
12'd149 : mem_out_dec = 6'b001010;
12'd150 : mem_out_dec = 6'b001010;
12'd151 : mem_out_dec = 6'b001011;
12'd152 : mem_out_dec = 6'b001010;
12'd153 : mem_out_dec = 6'b001011;
12'd154 : mem_out_dec = 6'b001100;
12'd155 : mem_out_dec = 6'b001101;
12'd156 : mem_out_dec = 6'b001101;
12'd157 : mem_out_dec = 6'b001110;
12'd158 : mem_out_dec = 6'b001111;
12'd159 : mem_out_dec = 6'b010000;
12'd160 : mem_out_dec = 6'b010000;
12'd161 : mem_out_dec = 6'b010001;
12'd162 : mem_out_dec = 6'b010001;
12'd163 : mem_out_dec = 6'b010010;
12'd164 : mem_out_dec = 6'b010010;
12'd165 : mem_out_dec = 6'b010011;
12'd166 : mem_out_dec = 6'b010011;
12'd167 : mem_out_dec = 6'b010100;
12'd168 : mem_out_dec = 6'b010100;
12'd169 : mem_out_dec = 6'b010101;
12'd170 : mem_out_dec = 6'b010101;
12'd171 : mem_out_dec = 6'b010110;
12'd172 : mem_out_dec = 6'b010111;
12'd173 : mem_out_dec = 6'b010111;
12'd174 : mem_out_dec = 6'b011000;
12'd175 : mem_out_dec = 6'b011001;
12'd176 : mem_out_dec = 6'b011001;
12'd177 : mem_out_dec = 6'b011010;
12'd178 : mem_out_dec = 6'b011010;
12'd179 : mem_out_dec = 6'b011010;
12'd180 : mem_out_dec = 6'b011010;
12'd181 : mem_out_dec = 6'b011010;
12'd182 : mem_out_dec = 6'b011010;
12'd183 : mem_out_dec = 6'b011010;
12'd184 : mem_out_dec = 6'b011010;
12'd185 : mem_out_dec = 6'b011011;
12'd186 : mem_out_dec = 6'b011100;
12'd187 : mem_out_dec = 6'b011100;
12'd188 : mem_out_dec = 6'b011101;
12'd189 : mem_out_dec = 6'b011110;
12'd190 : mem_out_dec = 6'b011111;
12'd191 : mem_out_dec = 6'b100000;
12'd192 : mem_out_dec = 6'b111111;
12'd193 : mem_out_dec = 6'b111111;
12'd194 : mem_out_dec = 6'b111111;
12'd195 : mem_out_dec = 6'b111111;
12'd196 : mem_out_dec = 6'b111111;
12'd197 : mem_out_dec = 6'b111111;
12'd198 : mem_out_dec = 6'b111111;
12'd199 : mem_out_dec = 6'b111111;
12'd200 : mem_out_dec = 6'b111111;
12'd201 : mem_out_dec = 6'b000100;
12'd202 : mem_out_dec = 6'b000100;
12'd203 : mem_out_dec = 6'b000101;
12'd204 : mem_out_dec = 6'b000110;
12'd205 : mem_out_dec = 6'b000111;
12'd206 : mem_out_dec = 6'b001000;
12'd207 : mem_out_dec = 6'b001000;
12'd208 : mem_out_dec = 6'b001001;
12'd209 : mem_out_dec = 6'b001001;
12'd210 : mem_out_dec = 6'b001001;
12'd211 : mem_out_dec = 6'b001001;
12'd212 : mem_out_dec = 6'b001001;
12'd213 : mem_out_dec = 6'b001001;
12'd214 : mem_out_dec = 6'b001001;
12'd215 : mem_out_dec = 6'b001010;
12'd216 : mem_out_dec = 6'b001010;
12'd217 : mem_out_dec = 6'b001011;
12'd218 : mem_out_dec = 6'b001011;
12'd219 : mem_out_dec = 6'b001100;
12'd220 : mem_out_dec = 6'b001101;
12'd221 : mem_out_dec = 6'b001110;
12'd222 : mem_out_dec = 6'b001111;
12'd223 : mem_out_dec = 6'b001111;
12'd224 : mem_out_dec = 6'b010000;
12'd225 : mem_out_dec = 6'b010000;
12'd226 : mem_out_dec = 6'b010001;
12'd227 : mem_out_dec = 6'b010001;
12'd228 : mem_out_dec = 6'b010010;
12'd229 : mem_out_dec = 6'b010010;
12'd230 : mem_out_dec = 6'b010011;
12'd231 : mem_out_dec = 6'b010011;
12'd232 : mem_out_dec = 6'b010011;
12'd233 : mem_out_dec = 6'b010100;
12'd234 : mem_out_dec = 6'b010100;
12'd235 : mem_out_dec = 6'b010101;
12'd236 : mem_out_dec = 6'b010110;
12'd237 : mem_out_dec = 6'b010111;
12'd238 : mem_out_dec = 6'b011000;
12'd239 : mem_out_dec = 6'b011000;
12'd240 : mem_out_dec = 6'b011001;
12'd241 : mem_out_dec = 6'b011001;
12'd242 : mem_out_dec = 6'b011001;
12'd243 : mem_out_dec = 6'b011001;
12'd244 : mem_out_dec = 6'b011001;
12'd245 : mem_out_dec = 6'b011001;
12'd246 : mem_out_dec = 6'b011001;
12'd247 : mem_out_dec = 6'b011001;
12'd248 : mem_out_dec = 6'b011010;
12'd249 : mem_out_dec = 6'b011010;
12'd250 : mem_out_dec = 6'b011011;
12'd251 : mem_out_dec = 6'b011100;
12'd252 : mem_out_dec = 6'b011101;
12'd253 : mem_out_dec = 6'b011110;
12'd254 : mem_out_dec = 6'b011110;
12'd255 : mem_out_dec = 6'b011111;
12'd256 : mem_out_dec = 6'b111111;
12'd257 : mem_out_dec = 6'b111111;
12'd258 : mem_out_dec = 6'b111111;
12'd259 : mem_out_dec = 6'b111111;
12'd260 : mem_out_dec = 6'b111111;
12'd261 : mem_out_dec = 6'b111111;
12'd262 : mem_out_dec = 6'b111111;
12'd263 : mem_out_dec = 6'b111111;
12'd264 : mem_out_dec = 6'b111111;
12'd265 : mem_out_dec = 6'b111111;
12'd266 : mem_out_dec = 6'b000100;
12'd267 : mem_out_dec = 6'b000101;
12'd268 : mem_out_dec = 6'b000110;
12'd269 : mem_out_dec = 6'b000110;
12'd270 : mem_out_dec = 6'b000111;
12'd271 : mem_out_dec = 6'b001000;
12'd272 : mem_out_dec = 6'b001000;
12'd273 : mem_out_dec = 6'b001000;
12'd274 : mem_out_dec = 6'b001000;
12'd275 : mem_out_dec = 6'b001000;
12'd276 : mem_out_dec = 6'b001000;
12'd277 : mem_out_dec = 6'b001000;
12'd278 : mem_out_dec = 6'b001000;
12'd279 : mem_out_dec = 6'b001001;
12'd280 : mem_out_dec = 6'b001001;
12'd281 : mem_out_dec = 6'b001010;
12'd282 : mem_out_dec = 6'b001011;
12'd283 : mem_out_dec = 6'b001100;
12'd284 : mem_out_dec = 6'b001101;
12'd285 : mem_out_dec = 6'b001101;
12'd286 : mem_out_dec = 6'b001110;
12'd287 : mem_out_dec = 6'b001111;
12'd288 : mem_out_dec = 6'b001111;
12'd289 : mem_out_dec = 6'b010000;
12'd290 : mem_out_dec = 6'b010000;
12'd291 : mem_out_dec = 6'b010001;
12'd292 : mem_out_dec = 6'b010001;
12'd293 : mem_out_dec = 6'b010010;
12'd294 : mem_out_dec = 6'b010010;
12'd295 : mem_out_dec = 6'b010011;
12'd296 : mem_out_dec = 6'b010010;
12'd297 : mem_out_dec = 6'b010011;
12'd298 : mem_out_dec = 6'b010100;
12'd299 : mem_out_dec = 6'b010101;
12'd300 : mem_out_dec = 6'b010110;
12'd301 : mem_out_dec = 6'b010110;
12'd302 : mem_out_dec = 6'b010111;
12'd303 : mem_out_dec = 6'b011000;
12'd304 : mem_out_dec = 6'b011000;
12'd305 : mem_out_dec = 6'b011000;
12'd306 : mem_out_dec = 6'b011000;
12'd307 : mem_out_dec = 6'b011000;
12'd308 : mem_out_dec = 6'b011000;
12'd309 : mem_out_dec = 6'b011000;
12'd310 : mem_out_dec = 6'b011000;
12'd311 : mem_out_dec = 6'b011001;
12'd312 : mem_out_dec = 6'b011001;
12'd313 : mem_out_dec = 6'b011010;
12'd314 : mem_out_dec = 6'b011011;
12'd315 : mem_out_dec = 6'b011100;
12'd316 : mem_out_dec = 6'b011100;
12'd317 : mem_out_dec = 6'b011101;
12'd318 : mem_out_dec = 6'b011110;
12'd319 : mem_out_dec = 6'b011111;
12'd320 : mem_out_dec = 6'b111111;
12'd321 : mem_out_dec = 6'b111111;
12'd322 : mem_out_dec = 6'b111111;
12'd323 : mem_out_dec = 6'b111111;
12'd324 : mem_out_dec = 6'b111111;
12'd325 : mem_out_dec = 6'b111111;
12'd326 : mem_out_dec = 6'b111111;
12'd327 : mem_out_dec = 6'b111111;
12'd328 : mem_out_dec = 6'b111111;
12'd329 : mem_out_dec = 6'b111111;
12'd330 : mem_out_dec = 6'b111111;
12'd331 : mem_out_dec = 6'b000100;
12'd332 : mem_out_dec = 6'b000101;
12'd333 : mem_out_dec = 6'b000110;
12'd334 : mem_out_dec = 6'b000111;
12'd335 : mem_out_dec = 6'b001000;
12'd336 : mem_out_dec = 6'b000111;
12'd337 : mem_out_dec = 6'b000111;
12'd338 : mem_out_dec = 6'b000111;
12'd339 : mem_out_dec = 6'b000111;
12'd340 : mem_out_dec = 6'b000111;
12'd341 : mem_out_dec = 6'b000111;
12'd342 : mem_out_dec = 6'b001000;
12'd343 : mem_out_dec = 6'b001001;
12'd344 : mem_out_dec = 6'b001001;
12'd345 : mem_out_dec = 6'b001010;
12'd346 : mem_out_dec = 6'b001011;
12'd347 : mem_out_dec = 6'b001011;
12'd348 : mem_out_dec = 6'b001100;
12'd349 : mem_out_dec = 6'b001101;
12'd350 : mem_out_dec = 6'b001110;
12'd351 : mem_out_dec = 6'b001110;
12'd352 : mem_out_dec = 6'b001111;
12'd353 : mem_out_dec = 6'b001111;
12'd354 : mem_out_dec = 6'b010000;
12'd355 : mem_out_dec = 6'b010000;
12'd356 : mem_out_dec = 6'b010001;
12'd357 : mem_out_dec = 6'b010001;
12'd358 : mem_out_dec = 6'b010001;
12'd359 : mem_out_dec = 6'b010010;
12'd360 : mem_out_dec = 6'b010010;
12'd361 : mem_out_dec = 6'b010011;
12'd362 : mem_out_dec = 6'b010100;
12'd363 : mem_out_dec = 6'b010100;
12'd364 : mem_out_dec = 6'b010101;
12'd365 : mem_out_dec = 6'b010110;
12'd366 : mem_out_dec = 6'b010111;
12'd367 : mem_out_dec = 6'b011000;
12'd368 : mem_out_dec = 6'b010111;
12'd369 : mem_out_dec = 6'b010111;
12'd370 : mem_out_dec = 6'b010111;
12'd371 : mem_out_dec = 6'b010111;
12'd372 : mem_out_dec = 6'b010111;
12'd373 : mem_out_dec = 6'b010111;
12'd374 : mem_out_dec = 6'b011000;
12'd375 : mem_out_dec = 6'b011001;
12'd376 : mem_out_dec = 6'b011001;
12'd377 : mem_out_dec = 6'b011010;
12'd378 : mem_out_dec = 6'b011010;
12'd379 : mem_out_dec = 6'b011011;
12'd380 : mem_out_dec = 6'b011100;
12'd381 : mem_out_dec = 6'b011101;
12'd382 : mem_out_dec = 6'b011101;
12'd383 : mem_out_dec = 6'b011110;
12'd384 : mem_out_dec = 6'b111111;
12'd385 : mem_out_dec = 6'b111111;
12'd386 : mem_out_dec = 6'b111111;
12'd387 : mem_out_dec = 6'b111111;
12'd388 : mem_out_dec = 6'b111111;
12'd389 : mem_out_dec = 6'b111111;
12'd390 : mem_out_dec = 6'b111111;
12'd391 : mem_out_dec = 6'b111111;
12'd392 : mem_out_dec = 6'b111111;
12'd393 : mem_out_dec = 6'b111111;
12'd394 : mem_out_dec = 6'b111111;
12'd395 : mem_out_dec = 6'b111111;
12'd396 : mem_out_dec = 6'b000101;
12'd397 : mem_out_dec = 6'b000110;
12'd398 : mem_out_dec = 6'b000110;
12'd399 : mem_out_dec = 6'b000111;
12'd400 : mem_out_dec = 6'b000110;
12'd401 : mem_out_dec = 6'b000110;
12'd402 : mem_out_dec = 6'b000110;
12'd403 : mem_out_dec = 6'b000110;
12'd404 : mem_out_dec = 6'b000110;
12'd405 : mem_out_dec = 6'b000111;
12'd406 : mem_out_dec = 6'b001000;
12'd407 : mem_out_dec = 6'b001000;
12'd408 : mem_out_dec = 6'b001001;
12'd409 : mem_out_dec = 6'b001001;
12'd410 : mem_out_dec = 6'b001010;
12'd411 : mem_out_dec = 6'b001011;
12'd412 : mem_out_dec = 6'b001100;
12'd413 : mem_out_dec = 6'b001100;
12'd414 : mem_out_dec = 6'b001101;
12'd415 : mem_out_dec = 6'b001110;
12'd416 : mem_out_dec = 6'b001110;
12'd417 : mem_out_dec = 6'b001111;
12'd418 : mem_out_dec = 6'b001111;
12'd419 : mem_out_dec = 6'b010000;
12'd420 : mem_out_dec = 6'b010000;
12'd421 : mem_out_dec = 6'b010000;
12'd422 : mem_out_dec = 6'b010001;
12'd423 : mem_out_dec = 6'b010001;
12'd424 : mem_out_dec = 6'b010010;
12'd425 : mem_out_dec = 6'b010011;
12'd426 : mem_out_dec = 6'b010011;
12'd427 : mem_out_dec = 6'b010100;
12'd428 : mem_out_dec = 6'b010101;
12'd429 : mem_out_dec = 6'b010110;
12'd430 : mem_out_dec = 6'b010111;
12'd431 : mem_out_dec = 6'b010111;
12'd432 : mem_out_dec = 6'b010110;
12'd433 : mem_out_dec = 6'b010110;
12'd434 : mem_out_dec = 6'b010110;
12'd435 : mem_out_dec = 6'b010110;
12'd436 : mem_out_dec = 6'b010110;
12'd437 : mem_out_dec = 6'b010111;
12'd438 : mem_out_dec = 6'b010111;
12'd439 : mem_out_dec = 6'b011000;
12'd440 : mem_out_dec = 6'b011001;
12'd441 : mem_out_dec = 6'b011001;
12'd442 : mem_out_dec = 6'b011010;
12'd443 : mem_out_dec = 6'b011011;
12'd444 : mem_out_dec = 6'b011011;
12'd445 : mem_out_dec = 6'b011100;
12'd446 : mem_out_dec = 6'b011101;
12'd447 : mem_out_dec = 6'b011110;
12'd448 : mem_out_dec = 6'b111111;
12'd449 : mem_out_dec = 6'b111111;
12'd450 : mem_out_dec = 6'b111111;
12'd451 : mem_out_dec = 6'b111111;
12'd452 : mem_out_dec = 6'b111111;
12'd453 : mem_out_dec = 6'b111111;
12'd454 : mem_out_dec = 6'b111111;
12'd455 : mem_out_dec = 6'b111111;
12'd456 : mem_out_dec = 6'b111111;
12'd457 : mem_out_dec = 6'b111111;
12'd458 : mem_out_dec = 6'b111111;
12'd459 : mem_out_dec = 6'b111111;
12'd460 : mem_out_dec = 6'b111111;
12'd461 : mem_out_dec = 6'b000101;
12'd462 : mem_out_dec = 6'b000110;
12'd463 : mem_out_dec = 6'b000110;
12'd464 : mem_out_dec = 6'b000110;
12'd465 : mem_out_dec = 6'b000110;
12'd466 : mem_out_dec = 6'b000110;
12'd467 : mem_out_dec = 6'b000110;
12'd468 : mem_out_dec = 6'b000110;
12'd469 : mem_out_dec = 6'b000111;
12'd470 : mem_out_dec = 6'b000111;
12'd471 : mem_out_dec = 6'b001000;
12'd472 : mem_out_dec = 6'b001000;
12'd473 : mem_out_dec = 6'b001001;
12'd474 : mem_out_dec = 6'b001010;
12'd475 : mem_out_dec = 6'b001011;
12'd476 : mem_out_dec = 6'b001011;
12'd477 : mem_out_dec = 6'b001100;
12'd478 : mem_out_dec = 6'b001101;
12'd479 : mem_out_dec = 6'b001110;
12'd480 : mem_out_dec = 6'b001110;
12'd481 : mem_out_dec = 6'b001110;
12'd482 : mem_out_dec = 6'b001111;
12'd483 : mem_out_dec = 6'b001111;
12'd484 : mem_out_dec = 6'b010000;
12'd485 : mem_out_dec = 6'b010000;
12'd486 : mem_out_dec = 6'b010000;
12'd487 : mem_out_dec = 6'b010001;
12'd488 : mem_out_dec = 6'b010001;
12'd489 : mem_out_dec = 6'b010010;
12'd490 : mem_out_dec = 6'b010011;
12'd491 : mem_out_dec = 6'b010100;
12'd492 : mem_out_dec = 6'b010101;
12'd493 : mem_out_dec = 6'b010101;
12'd494 : mem_out_dec = 6'b010110;
12'd495 : mem_out_dec = 6'b010110;
12'd496 : mem_out_dec = 6'b010110;
12'd497 : mem_out_dec = 6'b010110;
12'd498 : mem_out_dec = 6'b010101;
12'd499 : mem_out_dec = 6'b010101;
12'd500 : mem_out_dec = 6'b010110;
12'd501 : mem_out_dec = 6'b010111;
12'd502 : mem_out_dec = 6'b010111;
12'd503 : mem_out_dec = 6'b011000;
12'd504 : mem_out_dec = 6'b011000;
12'd505 : mem_out_dec = 6'b011001;
12'd506 : mem_out_dec = 6'b011010;
12'd507 : mem_out_dec = 6'b011010;
12'd508 : mem_out_dec = 6'b011011;
12'd509 : mem_out_dec = 6'b011100;
12'd510 : mem_out_dec = 6'b011101;
12'd511 : mem_out_dec = 6'b011101;
12'd512 : mem_out_dec = 6'b111111;
12'd513 : mem_out_dec = 6'b111111;
12'd514 : mem_out_dec = 6'b111111;
12'd515 : mem_out_dec = 6'b111111;
12'd516 : mem_out_dec = 6'b111111;
12'd517 : mem_out_dec = 6'b111111;
12'd518 : mem_out_dec = 6'b111111;
12'd519 : mem_out_dec = 6'b111111;
12'd520 : mem_out_dec = 6'b111111;
12'd521 : mem_out_dec = 6'b111111;
12'd522 : mem_out_dec = 6'b111111;
12'd523 : mem_out_dec = 6'b111111;
12'd524 : mem_out_dec = 6'b111111;
12'd525 : mem_out_dec = 6'b111111;
12'd526 : mem_out_dec = 6'b000100;
12'd527 : mem_out_dec = 6'b000101;
12'd528 : mem_out_dec = 6'b000100;
12'd529 : mem_out_dec = 6'b000100;
12'd530 : mem_out_dec = 6'b000100;
12'd531 : mem_out_dec = 6'b000101;
12'd532 : mem_out_dec = 6'b000101;
12'd533 : mem_out_dec = 6'b000110;
12'd534 : mem_out_dec = 6'b000111;
12'd535 : mem_out_dec = 6'b000111;
12'd536 : mem_out_dec = 6'b000111;
12'd537 : mem_out_dec = 6'b001000;
12'd538 : mem_out_dec = 6'b001001;
12'd539 : mem_out_dec = 6'b001010;
12'd540 : mem_out_dec = 6'b001011;
12'd541 : mem_out_dec = 6'b001011;
12'd542 : mem_out_dec = 6'b001100;
12'd543 : mem_out_dec = 6'b001101;
12'd544 : mem_out_dec = 6'b001101;
12'd545 : mem_out_dec = 6'b001101;
12'd546 : mem_out_dec = 6'b001110;
12'd547 : mem_out_dec = 6'b001110;
12'd548 : mem_out_dec = 6'b001110;
12'd549 : mem_out_dec = 6'b001111;
12'd550 : mem_out_dec = 6'b010000;
12'd551 : mem_out_dec = 6'b010000;
12'd552 : mem_out_dec = 6'b010001;
12'd553 : mem_out_dec = 6'b010001;
12'd554 : mem_out_dec = 6'b010010;
12'd555 : mem_out_dec = 6'b010010;
12'd556 : mem_out_dec = 6'b010011;
12'd557 : mem_out_dec = 6'b010100;
12'd558 : mem_out_dec = 6'b010100;
12'd559 : mem_out_dec = 6'b010100;
12'd560 : mem_out_dec = 6'b010100;
12'd561 : mem_out_dec = 6'b010100;
12'd562 : mem_out_dec = 6'b010100;
12'd563 : mem_out_dec = 6'b010101;
12'd564 : mem_out_dec = 6'b010101;
12'd565 : mem_out_dec = 6'b010110;
12'd566 : mem_out_dec = 6'b010111;
12'd567 : mem_out_dec = 6'b010111;
12'd568 : mem_out_dec = 6'b010111;
12'd569 : mem_out_dec = 6'b011000;
12'd570 : mem_out_dec = 6'b011001;
12'd571 : mem_out_dec = 6'b011010;
12'd572 : mem_out_dec = 6'b011010;
12'd573 : mem_out_dec = 6'b011011;
12'd574 : mem_out_dec = 6'b011100;
12'd575 : mem_out_dec = 6'b011101;
12'd576 : mem_out_dec = 6'b111111;
12'd577 : mem_out_dec = 6'b111111;
12'd578 : mem_out_dec = 6'b111111;
12'd579 : mem_out_dec = 6'b111111;
12'd580 : mem_out_dec = 6'b111111;
12'd581 : mem_out_dec = 6'b111111;
12'd582 : mem_out_dec = 6'b111111;
12'd583 : mem_out_dec = 6'b111111;
12'd584 : mem_out_dec = 6'b111111;
12'd585 : mem_out_dec = 6'b111111;
12'd586 : mem_out_dec = 6'b111111;
12'd587 : mem_out_dec = 6'b111111;
12'd588 : mem_out_dec = 6'b111111;
12'd589 : mem_out_dec = 6'b111111;
12'd590 : mem_out_dec = 6'b111111;
12'd591 : mem_out_dec = 6'b000100;
12'd592 : mem_out_dec = 6'b000011;
12'd593 : mem_out_dec = 6'b000011;
12'd594 : mem_out_dec = 6'b000100;
12'd595 : mem_out_dec = 6'b000101;
12'd596 : mem_out_dec = 6'b000101;
12'd597 : mem_out_dec = 6'b000110;
12'd598 : mem_out_dec = 6'b000110;
12'd599 : mem_out_dec = 6'b000111;
12'd600 : mem_out_dec = 6'b000111;
12'd601 : mem_out_dec = 6'b001000;
12'd602 : mem_out_dec = 6'b001001;
12'd603 : mem_out_dec = 6'b001010;
12'd604 : mem_out_dec = 6'b001010;
12'd605 : mem_out_dec = 6'b001011;
12'd606 : mem_out_dec = 6'b001100;
12'd607 : mem_out_dec = 6'b001101;
12'd608 : mem_out_dec = 6'b001101;
12'd609 : mem_out_dec = 6'b001101;
12'd610 : mem_out_dec = 6'b001110;
12'd611 : mem_out_dec = 6'b001110;
12'd612 : mem_out_dec = 6'b001110;
12'd613 : mem_out_dec = 6'b001111;
12'd614 : mem_out_dec = 6'b010000;
12'd615 : mem_out_dec = 6'b010000;
12'd616 : mem_out_dec = 6'b010000;
12'd617 : mem_out_dec = 6'b010001;
12'd618 : mem_out_dec = 6'b010001;
12'd619 : mem_out_dec = 6'b010010;
12'd620 : mem_out_dec = 6'b010010;
12'd621 : mem_out_dec = 6'b010011;
12'd622 : mem_out_dec = 6'b010011;
12'd623 : mem_out_dec = 6'b010100;
12'd624 : mem_out_dec = 6'b010011;
12'd625 : mem_out_dec = 6'b010011;
12'd626 : mem_out_dec = 6'b010100;
12'd627 : mem_out_dec = 6'b010100;
12'd628 : mem_out_dec = 6'b010101;
12'd629 : mem_out_dec = 6'b010110;
12'd630 : mem_out_dec = 6'b010110;
12'd631 : mem_out_dec = 6'b010111;
12'd632 : mem_out_dec = 6'b010111;
12'd633 : mem_out_dec = 6'b011000;
12'd634 : mem_out_dec = 6'b011001;
12'd635 : mem_out_dec = 6'b011001;
12'd636 : mem_out_dec = 6'b011010;
12'd637 : mem_out_dec = 6'b011011;
12'd638 : mem_out_dec = 6'b011100;
12'd639 : mem_out_dec = 6'b011100;
12'd640 : mem_out_dec = 6'b111111;
12'd641 : mem_out_dec = 6'b111111;
12'd642 : mem_out_dec = 6'b111111;
12'd643 : mem_out_dec = 6'b111111;
12'd644 : mem_out_dec = 6'b111111;
12'd645 : mem_out_dec = 6'b111111;
12'd646 : mem_out_dec = 6'b111111;
12'd647 : mem_out_dec = 6'b111111;
12'd648 : mem_out_dec = 6'b111111;
12'd649 : mem_out_dec = 6'b111111;
12'd650 : mem_out_dec = 6'b111111;
12'd651 : mem_out_dec = 6'b111111;
12'd652 : mem_out_dec = 6'b111111;
12'd653 : mem_out_dec = 6'b111111;
12'd654 : mem_out_dec = 6'b111111;
12'd655 : mem_out_dec = 6'b111111;
12'd656 : mem_out_dec = 6'b000011;
12'd657 : mem_out_dec = 6'b000011;
12'd658 : mem_out_dec = 6'b000100;
12'd659 : mem_out_dec = 6'b000100;
12'd660 : mem_out_dec = 6'b000101;
12'd661 : mem_out_dec = 6'b000110;
12'd662 : mem_out_dec = 6'b000110;
12'd663 : mem_out_dec = 6'b000111;
12'd664 : mem_out_dec = 6'b000111;
12'd665 : mem_out_dec = 6'b001000;
12'd666 : mem_out_dec = 6'b001001;
12'd667 : mem_out_dec = 6'b001001;
12'd668 : mem_out_dec = 6'b001010;
12'd669 : mem_out_dec = 6'b001011;
12'd670 : mem_out_dec = 6'b001100;
12'd671 : mem_out_dec = 6'b001100;
12'd672 : mem_out_dec = 6'b001100;
12'd673 : mem_out_dec = 6'b001101;
12'd674 : mem_out_dec = 6'b001101;
12'd675 : mem_out_dec = 6'b001101;
12'd676 : mem_out_dec = 6'b001110;
12'd677 : mem_out_dec = 6'b001111;
12'd678 : mem_out_dec = 6'b001111;
12'd679 : mem_out_dec = 6'b010000;
12'd680 : mem_out_dec = 6'b010000;
12'd681 : mem_out_dec = 6'b010000;
12'd682 : mem_out_dec = 6'b010001;
12'd683 : mem_out_dec = 6'b010001;
12'd684 : mem_out_dec = 6'b010010;
12'd685 : mem_out_dec = 6'b010010;
12'd686 : mem_out_dec = 6'b010011;
12'd687 : mem_out_dec = 6'b010011;
12'd688 : mem_out_dec = 6'b010011;
12'd689 : mem_out_dec = 6'b010011;
12'd690 : mem_out_dec = 6'b010100;
12'd691 : mem_out_dec = 6'b010100;
12'd692 : mem_out_dec = 6'b010101;
12'd693 : mem_out_dec = 6'b010101;
12'd694 : mem_out_dec = 6'b010110;
12'd695 : mem_out_dec = 6'b010111;
12'd696 : mem_out_dec = 6'b010111;
12'd697 : mem_out_dec = 6'b011000;
12'd698 : mem_out_dec = 6'b011000;
12'd699 : mem_out_dec = 6'b011001;
12'd700 : mem_out_dec = 6'b011010;
12'd701 : mem_out_dec = 6'b011011;
12'd702 : mem_out_dec = 6'b011011;
12'd703 : mem_out_dec = 6'b011100;
12'd704 : mem_out_dec = 6'b111111;
12'd705 : mem_out_dec = 6'b111111;
12'd706 : mem_out_dec = 6'b111111;
12'd707 : mem_out_dec = 6'b111111;
12'd708 : mem_out_dec = 6'b111111;
12'd709 : mem_out_dec = 6'b111111;
12'd710 : mem_out_dec = 6'b111111;
12'd711 : mem_out_dec = 6'b111111;
12'd712 : mem_out_dec = 6'b111111;
12'd713 : mem_out_dec = 6'b111111;
12'd714 : mem_out_dec = 6'b111111;
12'd715 : mem_out_dec = 6'b111111;
12'd716 : mem_out_dec = 6'b111111;
12'd717 : mem_out_dec = 6'b111111;
12'd718 : mem_out_dec = 6'b111111;
12'd719 : mem_out_dec = 6'b111111;
12'd720 : mem_out_dec = 6'b111111;
12'd721 : mem_out_dec = 6'b000011;
12'd722 : mem_out_dec = 6'b000100;
12'd723 : mem_out_dec = 6'b000100;
12'd724 : mem_out_dec = 6'b000101;
12'd725 : mem_out_dec = 6'b000101;
12'd726 : mem_out_dec = 6'b000110;
12'd727 : mem_out_dec = 6'b000111;
12'd728 : mem_out_dec = 6'b000111;
12'd729 : mem_out_dec = 6'b000111;
12'd730 : mem_out_dec = 6'b001000;
12'd731 : mem_out_dec = 6'b001001;
12'd732 : mem_out_dec = 6'b001010;
12'd733 : mem_out_dec = 6'b001011;
12'd734 : mem_out_dec = 6'b001011;
12'd735 : mem_out_dec = 6'b001100;
12'd736 : mem_out_dec = 6'b001100;
12'd737 : mem_out_dec = 6'b001101;
12'd738 : mem_out_dec = 6'b001101;
12'd739 : mem_out_dec = 6'b001101;
12'd740 : mem_out_dec = 6'b001110;
12'd741 : mem_out_dec = 6'b001110;
12'd742 : mem_out_dec = 6'b001111;
12'd743 : mem_out_dec = 6'b010000;
12'd744 : mem_out_dec = 6'b001111;
12'd745 : mem_out_dec = 6'b010000;
12'd746 : mem_out_dec = 6'b010000;
12'd747 : mem_out_dec = 6'b010001;
12'd748 : mem_out_dec = 6'b010001;
12'd749 : mem_out_dec = 6'b010010;
12'd750 : mem_out_dec = 6'b010010;
12'd751 : mem_out_dec = 6'b010011;
12'd752 : mem_out_dec = 6'b010010;
12'd753 : mem_out_dec = 6'b010011;
12'd754 : mem_out_dec = 6'b010011;
12'd755 : mem_out_dec = 6'b010100;
12'd756 : mem_out_dec = 6'b010101;
12'd757 : mem_out_dec = 6'b010101;
12'd758 : mem_out_dec = 6'b010110;
12'd759 : mem_out_dec = 6'b010110;
12'd760 : mem_out_dec = 6'b010111;
12'd761 : mem_out_dec = 6'b010111;
12'd762 : mem_out_dec = 6'b011000;
12'd763 : mem_out_dec = 6'b011001;
12'd764 : mem_out_dec = 6'b011010;
12'd765 : mem_out_dec = 6'b011010;
12'd766 : mem_out_dec = 6'b011011;
12'd767 : mem_out_dec = 6'b011100;
12'd768 : mem_out_dec = 6'b111111;
12'd769 : mem_out_dec = 6'b111111;
12'd770 : mem_out_dec = 6'b111111;
12'd771 : mem_out_dec = 6'b111111;
12'd772 : mem_out_dec = 6'b111111;
12'd773 : mem_out_dec = 6'b111111;
12'd774 : mem_out_dec = 6'b111111;
12'd775 : mem_out_dec = 6'b111111;
12'd776 : mem_out_dec = 6'b111111;
12'd777 : mem_out_dec = 6'b111111;
12'd778 : mem_out_dec = 6'b111111;
12'd779 : mem_out_dec = 6'b111111;
12'd780 : mem_out_dec = 6'b111111;
12'd781 : mem_out_dec = 6'b111111;
12'd782 : mem_out_dec = 6'b111111;
12'd783 : mem_out_dec = 6'b111111;
12'd784 : mem_out_dec = 6'b111111;
12'd785 : mem_out_dec = 6'b111111;
12'd786 : mem_out_dec = 6'b000011;
12'd787 : mem_out_dec = 6'b000100;
12'd788 : mem_out_dec = 6'b000101;
12'd789 : mem_out_dec = 6'b000101;
12'd790 : mem_out_dec = 6'b000110;
12'd791 : mem_out_dec = 6'b000110;
12'd792 : mem_out_dec = 6'b000110;
12'd793 : mem_out_dec = 6'b000111;
12'd794 : mem_out_dec = 6'b001000;
12'd795 : mem_out_dec = 6'b001001;
12'd796 : mem_out_dec = 6'b001010;
12'd797 : mem_out_dec = 6'b001010;
12'd798 : mem_out_dec = 6'b001011;
12'd799 : mem_out_dec = 6'b001100;
12'd800 : mem_out_dec = 6'b001100;
12'd801 : mem_out_dec = 6'b001100;
12'd802 : mem_out_dec = 6'b001101;
12'd803 : mem_out_dec = 6'b001101;
12'd804 : mem_out_dec = 6'b001110;
12'd805 : mem_out_dec = 6'b001110;
12'd806 : mem_out_dec = 6'b001111;
12'd807 : mem_out_dec = 6'b010000;
12'd808 : mem_out_dec = 6'b001111;
12'd809 : mem_out_dec = 6'b001111;
12'd810 : mem_out_dec = 6'b010000;
12'd811 : mem_out_dec = 6'b010000;
12'd812 : mem_out_dec = 6'b010001;
12'd813 : mem_out_dec = 6'b010001;
12'd814 : mem_out_dec = 6'b010010;
12'd815 : mem_out_dec = 6'b010010;
12'd816 : mem_out_dec = 6'b010010;
12'd817 : mem_out_dec = 6'b010011;
12'd818 : mem_out_dec = 6'b010011;
12'd819 : mem_out_dec = 6'b010100;
12'd820 : mem_out_dec = 6'b010100;
12'd821 : mem_out_dec = 6'b010101;
12'd822 : mem_out_dec = 6'b010110;
12'd823 : mem_out_dec = 6'b010110;
12'd824 : mem_out_dec = 6'b010110;
12'd825 : mem_out_dec = 6'b010111;
12'd826 : mem_out_dec = 6'b011000;
12'd827 : mem_out_dec = 6'b011001;
12'd828 : mem_out_dec = 6'b011001;
12'd829 : mem_out_dec = 6'b011010;
12'd830 : mem_out_dec = 6'b011011;
12'd831 : mem_out_dec = 6'b011100;
12'd832 : mem_out_dec = 6'b111111;
12'd833 : mem_out_dec = 6'b111111;
12'd834 : mem_out_dec = 6'b111111;
12'd835 : mem_out_dec = 6'b111111;
12'd836 : mem_out_dec = 6'b111111;
12'd837 : mem_out_dec = 6'b111111;
12'd838 : mem_out_dec = 6'b111111;
12'd839 : mem_out_dec = 6'b111111;
12'd840 : mem_out_dec = 6'b111111;
12'd841 : mem_out_dec = 6'b111111;
12'd842 : mem_out_dec = 6'b111111;
12'd843 : mem_out_dec = 6'b111111;
12'd844 : mem_out_dec = 6'b111111;
12'd845 : mem_out_dec = 6'b111111;
12'd846 : mem_out_dec = 6'b111111;
12'd847 : mem_out_dec = 6'b111111;
12'd848 : mem_out_dec = 6'b111111;
12'd849 : mem_out_dec = 6'b111111;
12'd850 : mem_out_dec = 6'b111111;
12'd851 : mem_out_dec = 6'b000100;
12'd852 : mem_out_dec = 6'b000100;
12'd853 : mem_out_dec = 6'b000101;
12'd854 : mem_out_dec = 6'b000101;
12'd855 : mem_out_dec = 6'b000110;
12'd856 : mem_out_dec = 6'b000110;
12'd857 : mem_out_dec = 6'b000111;
12'd858 : mem_out_dec = 6'b001000;
12'd859 : mem_out_dec = 6'b001001;
12'd860 : mem_out_dec = 6'b001001;
12'd861 : mem_out_dec = 6'b001010;
12'd862 : mem_out_dec = 6'b001011;
12'd863 : mem_out_dec = 6'b001100;
12'd864 : mem_out_dec = 6'b001100;
12'd865 : mem_out_dec = 6'b001100;
12'd866 : mem_out_dec = 6'b001100;
12'd867 : mem_out_dec = 6'b001101;
12'd868 : mem_out_dec = 6'b001101;
12'd869 : mem_out_dec = 6'b001110;
12'd870 : mem_out_dec = 6'b001111;
12'd871 : mem_out_dec = 6'b001111;
12'd872 : mem_out_dec = 6'b001110;
12'd873 : mem_out_dec = 6'b001111;
12'd874 : mem_out_dec = 6'b001111;
12'd875 : mem_out_dec = 6'b010000;
12'd876 : mem_out_dec = 6'b010000;
12'd877 : mem_out_dec = 6'b010001;
12'd878 : mem_out_dec = 6'b010001;
12'd879 : mem_out_dec = 6'b010010;
12'd880 : mem_out_dec = 6'b010010;
12'd881 : mem_out_dec = 6'b010010;
12'd882 : mem_out_dec = 6'b010011;
12'd883 : mem_out_dec = 6'b010100;
12'd884 : mem_out_dec = 6'b010100;
12'd885 : mem_out_dec = 6'b010101;
12'd886 : mem_out_dec = 6'b010101;
12'd887 : mem_out_dec = 6'b010110;
12'd888 : mem_out_dec = 6'b010110;
12'd889 : mem_out_dec = 6'b010111;
12'd890 : mem_out_dec = 6'b011000;
12'd891 : mem_out_dec = 6'b011000;
12'd892 : mem_out_dec = 6'b011001;
12'd893 : mem_out_dec = 6'b011010;
12'd894 : mem_out_dec = 6'b011011;
12'd895 : mem_out_dec = 6'b011011;
12'd896 : mem_out_dec = 6'b111111;
12'd897 : mem_out_dec = 6'b111111;
12'd898 : mem_out_dec = 6'b111111;
12'd899 : mem_out_dec = 6'b111111;
12'd900 : mem_out_dec = 6'b111111;
12'd901 : mem_out_dec = 6'b111111;
12'd902 : mem_out_dec = 6'b111111;
12'd903 : mem_out_dec = 6'b111111;
12'd904 : mem_out_dec = 6'b111111;
12'd905 : mem_out_dec = 6'b111111;
12'd906 : mem_out_dec = 6'b111111;
12'd907 : mem_out_dec = 6'b111111;
12'd908 : mem_out_dec = 6'b111111;
12'd909 : mem_out_dec = 6'b111111;
12'd910 : mem_out_dec = 6'b111111;
12'd911 : mem_out_dec = 6'b111111;
12'd912 : mem_out_dec = 6'b111111;
12'd913 : mem_out_dec = 6'b111111;
12'd914 : mem_out_dec = 6'b111111;
12'd915 : mem_out_dec = 6'b111111;
12'd916 : mem_out_dec = 6'b000100;
12'd917 : mem_out_dec = 6'b000101;
12'd918 : mem_out_dec = 6'b000101;
12'd919 : mem_out_dec = 6'b000110;
12'd920 : mem_out_dec = 6'b000110;
12'd921 : mem_out_dec = 6'b000111;
12'd922 : mem_out_dec = 6'b001000;
12'd923 : mem_out_dec = 6'b001000;
12'd924 : mem_out_dec = 6'b001001;
12'd925 : mem_out_dec = 6'b001010;
12'd926 : mem_out_dec = 6'b001011;
12'd927 : mem_out_dec = 6'b001011;
12'd928 : mem_out_dec = 6'b001011;
12'd929 : mem_out_dec = 6'b001100;
12'd930 : mem_out_dec = 6'b001100;
12'd931 : mem_out_dec = 6'b001101;
12'd932 : mem_out_dec = 6'b001101;
12'd933 : mem_out_dec = 6'b001110;
12'd934 : mem_out_dec = 6'b001110;
12'd935 : mem_out_dec = 6'b001111;
12'd936 : mem_out_dec = 6'b001110;
12'd937 : mem_out_dec = 6'b001110;
12'd938 : mem_out_dec = 6'b001111;
12'd939 : mem_out_dec = 6'b001111;
12'd940 : mem_out_dec = 6'b010000;
12'd941 : mem_out_dec = 6'b010000;
12'd942 : mem_out_dec = 6'b010001;
12'd943 : mem_out_dec = 6'b010001;
12'd944 : mem_out_dec = 6'b010010;
12'd945 : mem_out_dec = 6'b010010;
12'd946 : mem_out_dec = 6'b010011;
12'd947 : mem_out_dec = 6'b010011;
12'd948 : mem_out_dec = 6'b010100;
12'd949 : mem_out_dec = 6'b010100;
12'd950 : mem_out_dec = 6'b010101;
12'd951 : mem_out_dec = 6'b010110;
12'd952 : mem_out_dec = 6'b010110;
12'd953 : mem_out_dec = 6'b010111;
12'd954 : mem_out_dec = 6'b010111;
12'd955 : mem_out_dec = 6'b011000;
12'd956 : mem_out_dec = 6'b011001;
12'd957 : mem_out_dec = 6'b011010;
12'd958 : mem_out_dec = 6'b011010;
12'd959 : mem_out_dec = 6'b011011;
12'd960 : mem_out_dec = 6'b111111;
12'd961 : mem_out_dec = 6'b111111;
12'd962 : mem_out_dec = 6'b111111;
12'd963 : mem_out_dec = 6'b111111;
12'd964 : mem_out_dec = 6'b111111;
12'd965 : mem_out_dec = 6'b111111;
12'd966 : mem_out_dec = 6'b111111;
12'd967 : mem_out_dec = 6'b111111;
12'd968 : mem_out_dec = 6'b111111;
12'd969 : mem_out_dec = 6'b111111;
12'd970 : mem_out_dec = 6'b111111;
12'd971 : mem_out_dec = 6'b111111;
12'd972 : mem_out_dec = 6'b111111;
12'd973 : mem_out_dec = 6'b111111;
12'd974 : mem_out_dec = 6'b111111;
12'd975 : mem_out_dec = 6'b111111;
12'd976 : mem_out_dec = 6'b111111;
12'd977 : mem_out_dec = 6'b111111;
12'd978 : mem_out_dec = 6'b111111;
12'd979 : mem_out_dec = 6'b111111;
12'd980 : mem_out_dec = 6'b111111;
12'd981 : mem_out_dec = 6'b000100;
12'd982 : mem_out_dec = 6'b000101;
12'd983 : mem_out_dec = 6'b000110;
12'd984 : mem_out_dec = 6'b000110;
12'd985 : mem_out_dec = 6'b000111;
12'd986 : mem_out_dec = 6'b000111;
12'd987 : mem_out_dec = 6'b001000;
12'd988 : mem_out_dec = 6'b001001;
12'd989 : mem_out_dec = 6'b001010;
12'd990 : mem_out_dec = 6'b001010;
12'd991 : mem_out_dec = 6'b001011;
12'd992 : mem_out_dec = 6'b001011;
12'd993 : mem_out_dec = 6'b001011;
12'd994 : mem_out_dec = 6'b001100;
12'd995 : mem_out_dec = 6'b001100;
12'd996 : mem_out_dec = 6'b001101;
12'd997 : mem_out_dec = 6'b001110;
12'd998 : mem_out_dec = 6'b001110;
12'd999 : mem_out_dec = 6'b001110;
12'd1000 : mem_out_dec = 6'b001101;
12'd1001 : mem_out_dec = 6'b001110;
12'd1002 : mem_out_dec = 6'b001110;
12'd1003 : mem_out_dec = 6'b001111;
12'd1004 : mem_out_dec = 6'b001111;
12'd1005 : mem_out_dec = 6'b010000;
12'd1006 : mem_out_dec = 6'b010000;
12'd1007 : mem_out_dec = 6'b010001;
12'd1008 : mem_out_dec = 6'b010001;
12'd1009 : mem_out_dec = 6'b010010;
12'd1010 : mem_out_dec = 6'b010011;
12'd1011 : mem_out_dec = 6'b010011;
12'd1012 : mem_out_dec = 6'b010100;
12'd1013 : mem_out_dec = 6'b010100;
12'd1014 : mem_out_dec = 6'b010101;
12'd1015 : mem_out_dec = 6'b010110;
12'd1016 : mem_out_dec = 6'b010110;
12'd1017 : mem_out_dec = 6'b010110;
12'd1018 : mem_out_dec = 6'b010111;
12'd1019 : mem_out_dec = 6'b011000;
12'd1020 : mem_out_dec = 6'b011001;
12'd1021 : mem_out_dec = 6'b011001;
12'd1022 : mem_out_dec = 6'b011010;
12'd1023 : mem_out_dec = 6'b011011;
12'd1024 : mem_out_dec = 6'b111111;
12'd1025 : mem_out_dec = 6'b111111;
12'd1026 : mem_out_dec = 6'b111111;
12'd1027 : mem_out_dec = 6'b111111;
12'd1028 : mem_out_dec = 6'b111111;
12'd1029 : mem_out_dec = 6'b111111;
12'd1030 : mem_out_dec = 6'b111111;
12'd1031 : mem_out_dec = 6'b111111;
12'd1032 : mem_out_dec = 6'b111111;
12'd1033 : mem_out_dec = 6'b111111;
12'd1034 : mem_out_dec = 6'b111111;
12'd1035 : mem_out_dec = 6'b111111;
12'd1036 : mem_out_dec = 6'b111111;
12'd1037 : mem_out_dec = 6'b111111;
12'd1038 : mem_out_dec = 6'b111111;
12'd1039 : mem_out_dec = 6'b111111;
12'd1040 : mem_out_dec = 6'b111111;
12'd1041 : mem_out_dec = 6'b111111;
12'd1042 : mem_out_dec = 6'b111111;
12'd1043 : mem_out_dec = 6'b111111;
12'd1044 : mem_out_dec = 6'b111111;
12'd1045 : mem_out_dec = 6'b111111;
12'd1046 : mem_out_dec = 6'b000100;
12'd1047 : mem_out_dec = 6'b000101;
12'd1048 : mem_out_dec = 6'b000101;
12'd1049 : mem_out_dec = 6'b000110;
12'd1050 : mem_out_dec = 6'b000110;
12'd1051 : mem_out_dec = 6'b000111;
12'd1052 : mem_out_dec = 6'b001000;
12'd1053 : mem_out_dec = 6'b001001;
12'd1054 : mem_out_dec = 6'b001001;
12'd1055 : mem_out_dec = 6'b001010;
12'd1056 : mem_out_dec = 6'b001010;
12'd1057 : mem_out_dec = 6'b001011;
12'd1058 : mem_out_dec = 6'b001011;
12'd1059 : mem_out_dec = 6'b001100;
12'd1060 : mem_out_dec = 6'b001100;
12'd1061 : mem_out_dec = 6'b001100;
12'd1062 : mem_out_dec = 6'b001100;
12'd1063 : mem_out_dec = 6'b001100;
12'd1064 : mem_out_dec = 6'b001100;
12'd1065 : mem_out_dec = 6'b001100;
12'd1066 : mem_out_dec = 6'b001101;
12'd1067 : mem_out_dec = 6'b001101;
12'd1068 : mem_out_dec = 6'b001110;
12'd1069 : mem_out_dec = 6'b001111;
12'd1070 : mem_out_dec = 6'b010000;
12'd1071 : mem_out_dec = 6'b010000;
12'd1072 : mem_out_dec = 6'b010001;
12'd1073 : mem_out_dec = 6'b010001;
12'd1074 : mem_out_dec = 6'b010010;
12'd1075 : mem_out_dec = 6'b010010;
12'd1076 : mem_out_dec = 6'b010011;
12'd1077 : mem_out_dec = 6'b010011;
12'd1078 : mem_out_dec = 6'b010100;
12'd1079 : mem_out_dec = 6'b010101;
12'd1080 : mem_out_dec = 6'b010101;
12'd1081 : mem_out_dec = 6'b010110;
12'd1082 : mem_out_dec = 6'b010110;
12'd1083 : mem_out_dec = 6'b010111;
12'd1084 : mem_out_dec = 6'b011000;
12'd1085 : mem_out_dec = 6'b011000;
12'd1086 : mem_out_dec = 6'b011001;
12'd1087 : mem_out_dec = 6'b011010;
12'd1088 : mem_out_dec = 6'b111111;
12'd1089 : mem_out_dec = 6'b111111;
12'd1090 : mem_out_dec = 6'b111111;
12'd1091 : mem_out_dec = 6'b111111;
12'd1092 : mem_out_dec = 6'b111111;
12'd1093 : mem_out_dec = 6'b111111;
12'd1094 : mem_out_dec = 6'b111111;
12'd1095 : mem_out_dec = 6'b111111;
12'd1096 : mem_out_dec = 6'b111111;
12'd1097 : mem_out_dec = 6'b111111;
12'd1098 : mem_out_dec = 6'b111111;
12'd1099 : mem_out_dec = 6'b111111;
12'd1100 : mem_out_dec = 6'b111111;
12'd1101 : mem_out_dec = 6'b111111;
12'd1102 : mem_out_dec = 6'b111111;
12'd1103 : mem_out_dec = 6'b111111;
12'd1104 : mem_out_dec = 6'b111111;
12'd1105 : mem_out_dec = 6'b111111;
12'd1106 : mem_out_dec = 6'b111111;
12'd1107 : mem_out_dec = 6'b111111;
12'd1108 : mem_out_dec = 6'b111111;
12'd1109 : mem_out_dec = 6'b111111;
12'd1110 : mem_out_dec = 6'b111111;
12'd1111 : mem_out_dec = 6'b000100;
12'd1112 : mem_out_dec = 6'b000100;
12'd1113 : mem_out_dec = 6'b000101;
12'd1114 : mem_out_dec = 6'b000110;
12'd1115 : mem_out_dec = 6'b000111;
12'd1116 : mem_out_dec = 6'b000111;
12'd1117 : mem_out_dec = 6'b001000;
12'd1118 : mem_out_dec = 6'b001001;
12'd1119 : mem_out_dec = 6'b001001;
12'd1120 : mem_out_dec = 6'b001010;
12'd1121 : mem_out_dec = 6'b001010;
12'd1122 : mem_out_dec = 6'b001011;
12'd1123 : mem_out_dec = 6'b001011;
12'd1124 : mem_out_dec = 6'b001011;
12'd1125 : mem_out_dec = 6'b001011;
12'd1126 : mem_out_dec = 6'b001011;
12'd1127 : mem_out_dec = 6'b001011;
12'd1128 : mem_out_dec = 6'b001011;
12'd1129 : mem_out_dec = 6'b001011;
12'd1130 : mem_out_dec = 6'b001100;
12'd1131 : mem_out_dec = 6'b001101;
12'd1132 : mem_out_dec = 6'b001110;
12'd1133 : mem_out_dec = 6'b001110;
12'd1134 : mem_out_dec = 6'b001111;
12'd1135 : mem_out_dec = 6'b010000;
12'd1136 : mem_out_dec = 6'b010000;
12'd1137 : mem_out_dec = 6'b010001;
12'd1138 : mem_out_dec = 6'b010001;
12'd1139 : mem_out_dec = 6'b010010;
12'd1140 : mem_out_dec = 6'b010010;
12'd1141 : mem_out_dec = 6'b010011;
12'd1142 : mem_out_dec = 6'b010100;
12'd1143 : mem_out_dec = 6'b010100;
12'd1144 : mem_out_dec = 6'b010100;
12'd1145 : mem_out_dec = 6'b010101;
12'd1146 : mem_out_dec = 6'b010110;
12'd1147 : mem_out_dec = 6'b010110;
12'd1148 : mem_out_dec = 6'b010111;
12'd1149 : mem_out_dec = 6'b011000;
12'd1150 : mem_out_dec = 6'b011000;
12'd1151 : mem_out_dec = 6'b011001;
12'd1152 : mem_out_dec = 6'b111111;
12'd1153 : mem_out_dec = 6'b111111;
12'd1154 : mem_out_dec = 6'b111111;
12'd1155 : mem_out_dec = 6'b111111;
12'd1156 : mem_out_dec = 6'b111111;
12'd1157 : mem_out_dec = 6'b111111;
12'd1158 : mem_out_dec = 6'b111111;
12'd1159 : mem_out_dec = 6'b111111;
12'd1160 : mem_out_dec = 6'b111111;
12'd1161 : mem_out_dec = 6'b111111;
12'd1162 : mem_out_dec = 6'b111111;
12'd1163 : mem_out_dec = 6'b111111;
12'd1164 : mem_out_dec = 6'b111111;
12'd1165 : mem_out_dec = 6'b111111;
12'd1166 : mem_out_dec = 6'b111111;
12'd1167 : mem_out_dec = 6'b111111;
12'd1168 : mem_out_dec = 6'b111111;
12'd1169 : mem_out_dec = 6'b111111;
12'd1170 : mem_out_dec = 6'b111111;
12'd1171 : mem_out_dec = 6'b111111;
12'd1172 : mem_out_dec = 6'b111111;
12'd1173 : mem_out_dec = 6'b111111;
12'd1174 : mem_out_dec = 6'b111111;
12'd1175 : mem_out_dec = 6'b111111;
12'd1176 : mem_out_dec = 6'b000100;
12'd1177 : mem_out_dec = 6'b000101;
12'd1178 : mem_out_dec = 6'b000101;
12'd1179 : mem_out_dec = 6'b000110;
12'd1180 : mem_out_dec = 6'b000111;
12'd1181 : mem_out_dec = 6'b000111;
12'd1182 : mem_out_dec = 6'b001000;
12'd1183 : mem_out_dec = 6'b001001;
12'd1184 : mem_out_dec = 6'b001001;
12'd1185 : mem_out_dec = 6'b001010;
12'd1186 : mem_out_dec = 6'b001010;
12'd1187 : mem_out_dec = 6'b001010;
12'd1188 : mem_out_dec = 6'b001010;
12'd1189 : mem_out_dec = 6'b001010;
12'd1190 : mem_out_dec = 6'b001010;
12'd1191 : mem_out_dec = 6'b001010;
12'd1192 : mem_out_dec = 6'b001010;
12'd1193 : mem_out_dec = 6'b001011;
12'd1194 : mem_out_dec = 6'b001100;
12'd1195 : mem_out_dec = 6'b001100;
12'd1196 : mem_out_dec = 6'b001101;
12'd1197 : mem_out_dec = 6'b001110;
12'd1198 : mem_out_dec = 6'b001111;
12'd1199 : mem_out_dec = 6'b010000;
12'd1200 : mem_out_dec = 6'b010000;
12'd1201 : mem_out_dec = 6'b010000;
12'd1202 : mem_out_dec = 6'b010001;
12'd1203 : mem_out_dec = 6'b010001;
12'd1204 : mem_out_dec = 6'b010010;
12'd1205 : mem_out_dec = 6'b010011;
12'd1206 : mem_out_dec = 6'b010011;
12'd1207 : mem_out_dec = 6'b010100;
12'd1208 : mem_out_dec = 6'b010100;
12'd1209 : mem_out_dec = 6'b010100;
12'd1210 : mem_out_dec = 6'b010101;
12'd1211 : mem_out_dec = 6'b010110;
12'd1212 : mem_out_dec = 6'b010110;
12'd1213 : mem_out_dec = 6'b010111;
12'd1214 : mem_out_dec = 6'b011000;
12'd1215 : mem_out_dec = 6'b011001;
12'd1216 : mem_out_dec = 6'b111111;
12'd1217 : mem_out_dec = 6'b111111;
12'd1218 : mem_out_dec = 6'b111111;
12'd1219 : mem_out_dec = 6'b111111;
12'd1220 : mem_out_dec = 6'b111111;
12'd1221 : mem_out_dec = 6'b111111;
12'd1222 : mem_out_dec = 6'b111111;
12'd1223 : mem_out_dec = 6'b111111;
12'd1224 : mem_out_dec = 6'b111111;
12'd1225 : mem_out_dec = 6'b111111;
12'd1226 : mem_out_dec = 6'b111111;
12'd1227 : mem_out_dec = 6'b111111;
12'd1228 : mem_out_dec = 6'b111111;
12'd1229 : mem_out_dec = 6'b111111;
12'd1230 : mem_out_dec = 6'b111111;
12'd1231 : mem_out_dec = 6'b111111;
12'd1232 : mem_out_dec = 6'b111111;
12'd1233 : mem_out_dec = 6'b111111;
12'd1234 : mem_out_dec = 6'b111111;
12'd1235 : mem_out_dec = 6'b111111;
12'd1236 : mem_out_dec = 6'b111111;
12'd1237 : mem_out_dec = 6'b111111;
12'd1238 : mem_out_dec = 6'b111111;
12'd1239 : mem_out_dec = 6'b111111;
12'd1240 : mem_out_dec = 6'b111111;
12'd1241 : mem_out_dec = 6'b000100;
12'd1242 : mem_out_dec = 6'b000100;
12'd1243 : mem_out_dec = 6'b000101;
12'd1244 : mem_out_dec = 6'b000110;
12'd1245 : mem_out_dec = 6'b000111;
12'd1246 : mem_out_dec = 6'b001000;
12'd1247 : mem_out_dec = 6'b001000;
12'd1248 : mem_out_dec = 6'b001001;
12'd1249 : mem_out_dec = 6'b001001;
12'd1250 : mem_out_dec = 6'b001001;
12'd1251 : mem_out_dec = 6'b001001;
12'd1252 : mem_out_dec = 6'b001001;
12'd1253 : mem_out_dec = 6'b001001;
12'd1254 : mem_out_dec = 6'b001001;
12'd1255 : mem_out_dec = 6'b001001;
12'd1256 : mem_out_dec = 6'b001010;
12'd1257 : mem_out_dec = 6'b001010;
12'd1258 : mem_out_dec = 6'b001011;
12'd1259 : mem_out_dec = 6'b001100;
12'd1260 : mem_out_dec = 6'b001101;
12'd1261 : mem_out_dec = 6'b001110;
12'd1262 : mem_out_dec = 6'b001110;
12'd1263 : mem_out_dec = 6'b001111;
12'd1264 : mem_out_dec = 6'b001111;
12'd1265 : mem_out_dec = 6'b010000;
12'd1266 : mem_out_dec = 6'b010000;
12'd1267 : mem_out_dec = 6'b010001;
12'd1268 : mem_out_dec = 6'b010001;
12'd1269 : mem_out_dec = 6'b010010;
12'd1270 : mem_out_dec = 6'b010011;
12'd1271 : mem_out_dec = 6'b010011;
12'd1272 : mem_out_dec = 6'b010011;
12'd1273 : mem_out_dec = 6'b010100;
12'd1274 : mem_out_dec = 6'b010100;
12'd1275 : mem_out_dec = 6'b010101;
12'd1276 : mem_out_dec = 6'b010110;
12'd1277 : mem_out_dec = 6'b010111;
12'd1278 : mem_out_dec = 6'b011000;
12'd1279 : mem_out_dec = 6'b011000;
12'd1280 : mem_out_dec = 6'b111111;
12'd1281 : mem_out_dec = 6'b111111;
12'd1282 : mem_out_dec = 6'b111111;
12'd1283 : mem_out_dec = 6'b111111;
12'd1284 : mem_out_dec = 6'b111111;
12'd1285 : mem_out_dec = 6'b111111;
12'd1286 : mem_out_dec = 6'b111111;
12'd1287 : mem_out_dec = 6'b111111;
12'd1288 : mem_out_dec = 6'b111111;
12'd1289 : mem_out_dec = 6'b111111;
12'd1290 : mem_out_dec = 6'b111111;
12'd1291 : mem_out_dec = 6'b111111;
12'd1292 : mem_out_dec = 6'b111111;
12'd1293 : mem_out_dec = 6'b111111;
12'd1294 : mem_out_dec = 6'b111111;
12'd1295 : mem_out_dec = 6'b111111;
12'd1296 : mem_out_dec = 6'b111111;
12'd1297 : mem_out_dec = 6'b111111;
12'd1298 : mem_out_dec = 6'b111111;
12'd1299 : mem_out_dec = 6'b111111;
12'd1300 : mem_out_dec = 6'b111111;
12'd1301 : mem_out_dec = 6'b111111;
12'd1302 : mem_out_dec = 6'b111111;
12'd1303 : mem_out_dec = 6'b111111;
12'd1304 : mem_out_dec = 6'b111111;
12'd1305 : mem_out_dec = 6'b111111;
12'd1306 : mem_out_dec = 6'b000100;
12'd1307 : mem_out_dec = 6'b000101;
12'd1308 : mem_out_dec = 6'b000110;
12'd1309 : mem_out_dec = 6'b000110;
12'd1310 : mem_out_dec = 6'b000111;
12'd1311 : mem_out_dec = 6'b001000;
12'd1312 : mem_out_dec = 6'b001000;
12'd1313 : mem_out_dec = 6'b001000;
12'd1314 : mem_out_dec = 6'b001000;
12'd1315 : mem_out_dec = 6'b001000;
12'd1316 : mem_out_dec = 6'b001000;
12'd1317 : mem_out_dec = 6'b001000;
12'd1318 : mem_out_dec = 6'b001000;
12'd1319 : mem_out_dec = 6'b001001;
12'd1320 : mem_out_dec = 6'b001001;
12'd1321 : mem_out_dec = 6'b001010;
12'd1322 : mem_out_dec = 6'b001011;
12'd1323 : mem_out_dec = 6'b001100;
12'd1324 : mem_out_dec = 6'b001100;
12'd1325 : mem_out_dec = 6'b001101;
12'd1326 : mem_out_dec = 6'b001110;
12'd1327 : mem_out_dec = 6'b001111;
12'd1328 : mem_out_dec = 6'b001111;
12'd1329 : mem_out_dec = 6'b001111;
12'd1330 : mem_out_dec = 6'b010000;
12'd1331 : mem_out_dec = 6'b010000;
12'd1332 : mem_out_dec = 6'b010001;
12'd1333 : mem_out_dec = 6'b010001;
12'd1334 : mem_out_dec = 6'b010010;
12'd1335 : mem_out_dec = 6'b010011;
12'd1336 : mem_out_dec = 6'b010010;
12'd1337 : mem_out_dec = 6'b010011;
12'd1338 : mem_out_dec = 6'b010100;
12'd1339 : mem_out_dec = 6'b010101;
12'd1340 : mem_out_dec = 6'b010110;
12'd1341 : mem_out_dec = 6'b010110;
12'd1342 : mem_out_dec = 6'b010111;
12'd1343 : mem_out_dec = 6'b011000;
12'd1344 : mem_out_dec = 6'b111111;
12'd1345 : mem_out_dec = 6'b111111;
12'd1346 : mem_out_dec = 6'b111111;
12'd1347 : mem_out_dec = 6'b111111;
12'd1348 : mem_out_dec = 6'b111111;
12'd1349 : mem_out_dec = 6'b111111;
12'd1350 : mem_out_dec = 6'b111111;
12'd1351 : mem_out_dec = 6'b111111;
12'd1352 : mem_out_dec = 6'b111111;
12'd1353 : mem_out_dec = 6'b111111;
12'd1354 : mem_out_dec = 6'b111111;
12'd1355 : mem_out_dec = 6'b111111;
12'd1356 : mem_out_dec = 6'b111111;
12'd1357 : mem_out_dec = 6'b111111;
12'd1358 : mem_out_dec = 6'b111111;
12'd1359 : mem_out_dec = 6'b111111;
12'd1360 : mem_out_dec = 6'b111111;
12'd1361 : mem_out_dec = 6'b111111;
12'd1362 : mem_out_dec = 6'b111111;
12'd1363 : mem_out_dec = 6'b111111;
12'd1364 : mem_out_dec = 6'b111111;
12'd1365 : mem_out_dec = 6'b111111;
12'd1366 : mem_out_dec = 6'b111111;
12'd1367 : mem_out_dec = 6'b111111;
12'd1368 : mem_out_dec = 6'b111111;
12'd1369 : mem_out_dec = 6'b111111;
12'd1370 : mem_out_dec = 6'b111111;
12'd1371 : mem_out_dec = 6'b000101;
12'd1372 : mem_out_dec = 6'b000101;
12'd1373 : mem_out_dec = 6'b000110;
12'd1374 : mem_out_dec = 6'b000111;
12'd1375 : mem_out_dec = 6'b001000;
12'd1376 : mem_out_dec = 6'b000111;
12'd1377 : mem_out_dec = 6'b000111;
12'd1378 : mem_out_dec = 6'b000111;
12'd1379 : mem_out_dec = 6'b000111;
12'd1380 : mem_out_dec = 6'b000111;
12'd1381 : mem_out_dec = 6'b000111;
12'd1382 : mem_out_dec = 6'b001000;
12'd1383 : mem_out_dec = 6'b001001;
12'd1384 : mem_out_dec = 6'b001001;
12'd1385 : mem_out_dec = 6'b001010;
12'd1386 : mem_out_dec = 6'b001010;
12'd1387 : mem_out_dec = 6'b001011;
12'd1388 : mem_out_dec = 6'b001100;
12'd1389 : mem_out_dec = 6'b001101;
12'd1390 : mem_out_dec = 6'b001110;
12'd1391 : mem_out_dec = 6'b001110;
12'd1392 : mem_out_dec = 6'b001111;
12'd1393 : mem_out_dec = 6'b001111;
12'd1394 : mem_out_dec = 6'b010000;
12'd1395 : mem_out_dec = 6'b010000;
12'd1396 : mem_out_dec = 6'b010001;
12'd1397 : mem_out_dec = 6'b010001;
12'd1398 : mem_out_dec = 6'b010010;
12'd1399 : mem_out_dec = 6'b010010;
12'd1400 : mem_out_dec = 6'b010010;
12'd1401 : mem_out_dec = 6'b010011;
12'd1402 : mem_out_dec = 6'b010100;
12'd1403 : mem_out_dec = 6'b010100;
12'd1404 : mem_out_dec = 6'b010101;
12'd1405 : mem_out_dec = 6'b010110;
12'd1406 : mem_out_dec = 6'b010111;
12'd1407 : mem_out_dec = 6'b010111;
12'd1408 : mem_out_dec = 6'b111111;
12'd1409 : mem_out_dec = 6'b111111;
12'd1410 : mem_out_dec = 6'b111111;
12'd1411 : mem_out_dec = 6'b111111;
12'd1412 : mem_out_dec = 6'b111111;
12'd1413 : mem_out_dec = 6'b111111;
12'd1414 : mem_out_dec = 6'b111111;
12'd1415 : mem_out_dec = 6'b111111;
12'd1416 : mem_out_dec = 6'b111111;
12'd1417 : mem_out_dec = 6'b111111;
12'd1418 : mem_out_dec = 6'b111111;
12'd1419 : mem_out_dec = 6'b111111;
12'd1420 : mem_out_dec = 6'b111111;
12'd1421 : mem_out_dec = 6'b111111;
12'd1422 : mem_out_dec = 6'b111111;
12'd1423 : mem_out_dec = 6'b111111;
12'd1424 : mem_out_dec = 6'b111111;
12'd1425 : mem_out_dec = 6'b111111;
12'd1426 : mem_out_dec = 6'b111111;
12'd1427 : mem_out_dec = 6'b111111;
12'd1428 : mem_out_dec = 6'b111111;
12'd1429 : mem_out_dec = 6'b111111;
12'd1430 : mem_out_dec = 6'b111111;
12'd1431 : mem_out_dec = 6'b111111;
12'd1432 : mem_out_dec = 6'b111111;
12'd1433 : mem_out_dec = 6'b111111;
12'd1434 : mem_out_dec = 6'b111111;
12'd1435 : mem_out_dec = 6'b111111;
12'd1436 : mem_out_dec = 6'b000101;
12'd1437 : mem_out_dec = 6'b000110;
12'd1438 : mem_out_dec = 6'b000111;
12'd1439 : mem_out_dec = 6'b000111;
12'd1440 : mem_out_dec = 6'b000110;
12'd1441 : mem_out_dec = 6'b000110;
12'd1442 : mem_out_dec = 6'b000110;
12'd1443 : mem_out_dec = 6'b000110;
12'd1444 : mem_out_dec = 6'b000110;
12'd1445 : mem_out_dec = 6'b000111;
12'd1446 : mem_out_dec = 6'b000111;
12'd1447 : mem_out_dec = 6'b001000;
12'd1448 : mem_out_dec = 6'b001001;
12'd1449 : mem_out_dec = 6'b001001;
12'd1450 : mem_out_dec = 6'b001010;
12'd1451 : mem_out_dec = 6'b001011;
12'd1452 : mem_out_dec = 6'b001100;
12'd1453 : mem_out_dec = 6'b001100;
12'd1454 : mem_out_dec = 6'b001101;
12'd1455 : mem_out_dec = 6'b001110;
12'd1456 : mem_out_dec = 6'b001110;
12'd1457 : mem_out_dec = 6'b001111;
12'd1458 : mem_out_dec = 6'b001111;
12'd1459 : mem_out_dec = 6'b010000;
12'd1460 : mem_out_dec = 6'b010000;
12'd1461 : mem_out_dec = 6'b010001;
12'd1462 : mem_out_dec = 6'b010001;
12'd1463 : mem_out_dec = 6'b010010;
12'd1464 : mem_out_dec = 6'b010010;
12'd1465 : mem_out_dec = 6'b010011;
12'd1466 : mem_out_dec = 6'b010011;
12'd1467 : mem_out_dec = 6'b010100;
12'd1468 : mem_out_dec = 6'b010101;
12'd1469 : mem_out_dec = 6'b010110;
12'd1470 : mem_out_dec = 6'b010110;
12'd1471 : mem_out_dec = 6'b010111;
12'd1472 : mem_out_dec = 6'b111111;
12'd1473 : mem_out_dec = 6'b111111;
12'd1474 : mem_out_dec = 6'b111111;
12'd1475 : mem_out_dec = 6'b111111;
12'd1476 : mem_out_dec = 6'b111111;
12'd1477 : mem_out_dec = 6'b111111;
12'd1478 : mem_out_dec = 6'b111111;
12'd1479 : mem_out_dec = 6'b111111;
12'd1480 : mem_out_dec = 6'b111111;
12'd1481 : mem_out_dec = 6'b111111;
12'd1482 : mem_out_dec = 6'b111111;
12'd1483 : mem_out_dec = 6'b111111;
12'd1484 : mem_out_dec = 6'b111111;
12'd1485 : mem_out_dec = 6'b111111;
12'd1486 : mem_out_dec = 6'b111111;
12'd1487 : mem_out_dec = 6'b111111;
12'd1488 : mem_out_dec = 6'b111111;
12'd1489 : mem_out_dec = 6'b111111;
12'd1490 : mem_out_dec = 6'b111111;
12'd1491 : mem_out_dec = 6'b111111;
12'd1492 : mem_out_dec = 6'b111111;
12'd1493 : mem_out_dec = 6'b111111;
12'd1494 : mem_out_dec = 6'b111111;
12'd1495 : mem_out_dec = 6'b111111;
12'd1496 : mem_out_dec = 6'b111111;
12'd1497 : mem_out_dec = 6'b111111;
12'd1498 : mem_out_dec = 6'b111111;
12'd1499 : mem_out_dec = 6'b111111;
12'd1500 : mem_out_dec = 6'b111111;
12'd1501 : mem_out_dec = 6'b000101;
12'd1502 : mem_out_dec = 6'b000110;
12'd1503 : mem_out_dec = 6'b000110;
12'd1504 : mem_out_dec = 6'b000110;
12'd1505 : mem_out_dec = 6'b000110;
12'd1506 : mem_out_dec = 6'b000101;
12'd1507 : mem_out_dec = 6'b000101;
12'd1508 : mem_out_dec = 6'b000110;
12'd1509 : mem_out_dec = 6'b000111;
12'd1510 : mem_out_dec = 6'b000111;
12'd1511 : mem_out_dec = 6'b001000;
12'd1512 : mem_out_dec = 6'b001000;
12'd1513 : mem_out_dec = 6'b001001;
12'd1514 : mem_out_dec = 6'b001010;
12'd1515 : mem_out_dec = 6'b001011;
12'd1516 : mem_out_dec = 6'b001011;
12'd1517 : mem_out_dec = 6'b001100;
12'd1518 : mem_out_dec = 6'b001101;
12'd1519 : mem_out_dec = 6'b001110;
12'd1520 : mem_out_dec = 6'b001110;
12'd1521 : mem_out_dec = 6'b001110;
12'd1522 : mem_out_dec = 6'b001111;
12'd1523 : mem_out_dec = 6'b001111;
12'd1524 : mem_out_dec = 6'b010000;
12'd1525 : mem_out_dec = 6'b010000;
12'd1526 : mem_out_dec = 6'b010001;
12'd1527 : mem_out_dec = 6'b010001;
12'd1528 : mem_out_dec = 6'b010001;
12'd1529 : mem_out_dec = 6'b010010;
12'd1530 : mem_out_dec = 6'b010011;
12'd1531 : mem_out_dec = 6'b010100;
12'd1532 : mem_out_dec = 6'b010101;
12'd1533 : mem_out_dec = 6'b010101;
12'd1534 : mem_out_dec = 6'b010110;
12'd1535 : mem_out_dec = 6'b010110;
12'd1536 : mem_out_dec = 6'b111111;
12'd1537 : mem_out_dec = 6'b111111;
12'd1538 : mem_out_dec = 6'b111111;
12'd1539 : mem_out_dec = 6'b111111;
12'd1540 : mem_out_dec = 6'b111111;
12'd1541 : mem_out_dec = 6'b111111;
12'd1542 : mem_out_dec = 6'b111111;
12'd1543 : mem_out_dec = 6'b111111;
12'd1544 : mem_out_dec = 6'b111111;
12'd1545 : mem_out_dec = 6'b111111;
12'd1546 : mem_out_dec = 6'b111111;
12'd1547 : mem_out_dec = 6'b111111;
12'd1548 : mem_out_dec = 6'b111111;
12'd1549 : mem_out_dec = 6'b111111;
12'd1550 : mem_out_dec = 6'b111111;
12'd1551 : mem_out_dec = 6'b111111;
12'd1552 : mem_out_dec = 6'b111111;
12'd1553 : mem_out_dec = 6'b111111;
12'd1554 : mem_out_dec = 6'b111111;
12'd1555 : mem_out_dec = 6'b111111;
12'd1556 : mem_out_dec = 6'b111111;
12'd1557 : mem_out_dec = 6'b111111;
12'd1558 : mem_out_dec = 6'b111111;
12'd1559 : mem_out_dec = 6'b111111;
12'd1560 : mem_out_dec = 6'b111111;
12'd1561 : mem_out_dec = 6'b111111;
12'd1562 : mem_out_dec = 6'b111111;
12'd1563 : mem_out_dec = 6'b111111;
12'd1564 : mem_out_dec = 6'b111111;
12'd1565 : mem_out_dec = 6'b111111;
12'd1566 : mem_out_dec = 6'b000100;
12'd1567 : mem_out_dec = 6'b000100;
12'd1568 : mem_out_dec = 6'b000100;
12'd1569 : mem_out_dec = 6'b000100;
12'd1570 : mem_out_dec = 6'b000100;
12'd1571 : mem_out_dec = 6'b000101;
12'd1572 : mem_out_dec = 6'b000101;
12'd1573 : mem_out_dec = 6'b000110;
12'd1574 : mem_out_dec = 6'b000111;
12'd1575 : mem_out_dec = 6'b000111;
12'd1576 : mem_out_dec = 6'b000111;
12'd1577 : mem_out_dec = 6'b001000;
12'd1578 : mem_out_dec = 6'b001001;
12'd1579 : mem_out_dec = 6'b001010;
12'd1580 : mem_out_dec = 6'b001010;
12'd1581 : mem_out_dec = 6'b001011;
12'd1582 : mem_out_dec = 6'b001100;
12'd1583 : mem_out_dec = 6'b001101;
12'd1584 : mem_out_dec = 6'b001101;
12'd1585 : mem_out_dec = 6'b001101;
12'd1586 : mem_out_dec = 6'b001110;
12'd1587 : mem_out_dec = 6'b001110;
12'd1588 : mem_out_dec = 6'b001111;
12'd1589 : mem_out_dec = 6'b001111;
12'd1590 : mem_out_dec = 6'b010000;
12'd1591 : mem_out_dec = 6'b010001;
12'd1592 : mem_out_dec = 6'b010001;
12'd1593 : mem_out_dec = 6'b010001;
12'd1594 : mem_out_dec = 6'b010010;
12'd1595 : mem_out_dec = 6'b010010;
12'd1596 : mem_out_dec = 6'b010011;
12'd1597 : mem_out_dec = 6'b010011;
12'd1598 : mem_out_dec = 6'b010100;
12'd1599 : mem_out_dec = 6'b010100;
12'd1600 : mem_out_dec = 6'b111111;
12'd1601 : mem_out_dec = 6'b111111;
12'd1602 : mem_out_dec = 6'b111111;
12'd1603 : mem_out_dec = 6'b111111;
12'd1604 : mem_out_dec = 6'b111111;
12'd1605 : mem_out_dec = 6'b111111;
12'd1606 : mem_out_dec = 6'b111111;
12'd1607 : mem_out_dec = 6'b111111;
12'd1608 : mem_out_dec = 6'b111111;
12'd1609 : mem_out_dec = 6'b111111;
12'd1610 : mem_out_dec = 6'b111111;
12'd1611 : mem_out_dec = 6'b111111;
12'd1612 : mem_out_dec = 6'b111111;
12'd1613 : mem_out_dec = 6'b111111;
12'd1614 : mem_out_dec = 6'b111111;
12'd1615 : mem_out_dec = 6'b111111;
12'd1616 : mem_out_dec = 6'b111111;
12'd1617 : mem_out_dec = 6'b111111;
12'd1618 : mem_out_dec = 6'b111111;
12'd1619 : mem_out_dec = 6'b111111;
12'd1620 : mem_out_dec = 6'b111111;
12'd1621 : mem_out_dec = 6'b111111;
12'd1622 : mem_out_dec = 6'b111111;
12'd1623 : mem_out_dec = 6'b111111;
12'd1624 : mem_out_dec = 6'b111111;
12'd1625 : mem_out_dec = 6'b111111;
12'd1626 : mem_out_dec = 6'b111111;
12'd1627 : mem_out_dec = 6'b111111;
12'd1628 : mem_out_dec = 6'b111111;
12'd1629 : mem_out_dec = 6'b111111;
12'd1630 : mem_out_dec = 6'b111111;
12'd1631 : mem_out_dec = 6'b000100;
12'd1632 : mem_out_dec = 6'b000011;
12'd1633 : mem_out_dec = 6'b000011;
12'd1634 : mem_out_dec = 6'b000100;
12'd1635 : mem_out_dec = 6'b000100;
12'd1636 : mem_out_dec = 6'b000101;
12'd1637 : mem_out_dec = 6'b000110;
12'd1638 : mem_out_dec = 6'b000110;
12'd1639 : mem_out_dec = 6'b000111;
12'd1640 : mem_out_dec = 6'b000111;
12'd1641 : mem_out_dec = 6'b001000;
12'd1642 : mem_out_dec = 6'b001001;
12'd1643 : mem_out_dec = 6'b001001;
12'd1644 : mem_out_dec = 6'b001010;
12'd1645 : mem_out_dec = 6'b001011;
12'd1646 : mem_out_dec = 6'b001100;
12'd1647 : mem_out_dec = 6'b001101;
12'd1648 : mem_out_dec = 6'b001101;
12'd1649 : mem_out_dec = 6'b001101;
12'd1650 : mem_out_dec = 6'b001110;
12'd1651 : mem_out_dec = 6'b001110;
12'd1652 : mem_out_dec = 6'b001110;
12'd1653 : mem_out_dec = 6'b001111;
12'd1654 : mem_out_dec = 6'b010000;
12'd1655 : mem_out_dec = 6'b010000;
12'd1656 : mem_out_dec = 6'b010001;
12'd1657 : mem_out_dec = 6'b010001;
12'd1658 : mem_out_dec = 6'b010001;
12'd1659 : mem_out_dec = 6'b010010;
12'd1660 : mem_out_dec = 6'b010010;
12'd1661 : mem_out_dec = 6'b010011;
12'd1662 : mem_out_dec = 6'b010011;
12'd1663 : mem_out_dec = 6'b010100;
12'd1664 : mem_out_dec = 6'b111111;
12'd1665 : mem_out_dec = 6'b111111;
12'd1666 : mem_out_dec = 6'b111111;
12'd1667 : mem_out_dec = 6'b111111;
12'd1668 : mem_out_dec = 6'b111111;
12'd1669 : mem_out_dec = 6'b111111;
12'd1670 : mem_out_dec = 6'b111111;
12'd1671 : mem_out_dec = 6'b111111;
12'd1672 : mem_out_dec = 6'b111111;
12'd1673 : mem_out_dec = 6'b111111;
12'd1674 : mem_out_dec = 6'b111111;
12'd1675 : mem_out_dec = 6'b111111;
12'd1676 : mem_out_dec = 6'b111111;
12'd1677 : mem_out_dec = 6'b111111;
12'd1678 : mem_out_dec = 6'b111111;
12'd1679 : mem_out_dec = 6'b111111;
12'd1680 : mem_out_dec = 6'b111111;
12'd1681 : mem_out_dec = 6'b111111;
12'd1682 : mem_out_dec = 6'b111111;
12'd1683 : mem_out_dec = 6'b111111;
12'd1684 : mem_out_dec = 6'b111111;
12'd1685 : mem_out_dec = 6'b111111;
12'd1686 : mem_out_dec = 6'b111111;
12'd1687 : mem_out_dec = 6'b111111;
12'd1688 : mem_out_dec = 6'b111111;
12'd1689 : mem_out_dec = 6'b111111;
12'd1690 : mem_out_dec = 6'b111111;
12'd1691 : mem_out_dec = 6'b111111;
12'd1692 : mem_out_dec = 6'b111111;
12'd1693 : mem_out_dec = 6'b111111;
12'd1694 : mem_out_dec = 6'b111111;
12'd1695 : mem_out_dec = 6'b111111;
12'd1696 : mem_out_dec = 6'b000011;
12'd1697 : mem_out_dec = 6'b000011;
12'd1698 : mem_out_dec = 6'b000100;
12'd1699 : mem_out_dec = 6'b000100;
12'd1700 : mem_out_dec = 6'b000101;
12'd1701 : mem_out_dec = 6'b000101;
12'd1702 : mem_out_dec = 6'b000110;
12'd1703 : mem_out_dec = 6'b000111;
12'd1704 : mem_out_dec = 6'b000111;
12'd1705 : mem_out_dec = 6'b001000;
12'd1706 : mem_out_dec = 6'b001000;
12'd1707 : mem_out_dec = 6'b001001;
12'd1708 : mem_out_dec = 6'b001010;
12'd1709 : mem_out_dec = 6'b001011;
12'd1710 : mem_out_dec = 6'b001100;
12'd1711 : mem_out_dec = 6'b001100;
12'd1712 : mem_out_dec = 6'b001100;
12'd1713 : mem_out_dec = 6'b001101;
12'd1714 : mem_out_dec = 6'b001101;
12'd1715 : mem_out_dec = 6'b001110;
12'd1716 : mem_out_dec = 6'b001110;
12'd1717 : mem_out_dec = 6'b001111;
12'd1718 : mem_out_dec = 6'b001111;
12'd1719 : mem_out_dec = 6'b010000;
12'd1720 : mem_out_dec = 6'b010000;
12'd1721 : mem_out_dec = 6'b010000;
12'd1722 : mem_out_dec = 6'b010001;
12'd1723 : mem_out_dec = 6'b010001;
12'd1724 : mem_out_dec = 6'b010010;
12'd1725 : mem_out_dec = 6'b010010;
12'd1726 : mem_out_dec = 6'b010011;
12'd1727 : mem_out_dec = 6'b010011;
12'd1728 : mem_out_dec = 6'b111111;
12'd1729 : mem_out_dec = 6'b111111;
12'd1730 : mem_out_dec = 6'b111111;
12'd1731 : mem_out_dec = 6'b111111;
12'd1732 : mem_out_dec = 6'b111111;
12'd1733 : mem_out_dec = 6'b111111;
12'd1734 : mem_out_dec = 6'b111111;
12'd1735 : mem_out_dec = 6'b111111;
12'd1736 : mem_out_dec = 6'b111111;
12'd1737 : mem_out_dec = 6'b111111;
12'd1738 : mem_out_dec = 6'b111111;
12'd1739 : mem_out_dec = 6'b111111;
12'd1740 : mem_out_dec = 6'b111111;
12'd1741 : mem_out_dec = 6'b111111;
12'd1742 : mem_out_dec = 6'b111111;
12'd1743 : mem_out_dec = 6'b111111;
12'd1744 : mem_out_dec = 6'b111111;
12'd1745 : mem_out_dec = 6'b111111;
12'd1746 : mem_out_dec = 6'b111111;
12'd1747 : mem_out_dec = 6'b111111;
12'd1748 : mem_out_dec = 6'b111111;
12'd1749 : mem_out_dec = 6'b111111;
12'd1750 : mem_out_dec = 6'b111111;
12'd1751 : mem_out_dec = 6'b111111;
12'd1752 : mem_out_dec = 6'b111111;
12'd1753 : mem_out_dec = 6'b111111;
12'd1754 : mem_out_dec = 6'b111111;
12'd1755 : mem_out_dec = 6'b111111;
12'd1756 : mem_out_dec = 6'b111111;
12'd1757 : mem_out_dec = 6'b111111;
12'd1758 : mem_out_dec = 6'b111111;
12'd1759 : mem_out_dec = 6'b111111;
12'd1760 : mem_out_dec = 6'b111111;
12'd1761 : mem_out_dec = 6'b000011;
12'd1762 : mem_out_dec = 6'b000011;
12'd1763 : mem_out_dec = 6'b000100;
12'd1764 : mem_out_dec = 6'b000101;
12'd1765 : mem_out_dec = 6'b000101;
12'd1766 : mem_out_dec = 6'b000110;
12'd1767 : mem_out_dec = 6'b000111;
12'd1768 : mem_out_dec = 6'b000111;
12'd1769 : mem_out_dec = 6'b000111;
12'd1770 : mem_out_dec = 6'b001000;
12'd1771 : mem_out_dec = 6'b001001;
12'd1772 : mem_out_dec = 6'b001010;
12'd1773 : mem_out_dec = 6'b001011;
12'd1774 : mem_out_dec = 6'b001011;
12'd1775 : mem_out_dec = 6'b001100;
12'd1776 : mem_out_dec = 6'b001100;
12'd1777 : mem_out_dec = 6'b001101;
12'd1778 : mem_out_dec = 6'b001101;
12'd1779 : mem_out_dec = 6'b001101;
12'd1780 : mem_out_dec = 6'b001110;
12'd1781 : mem_out_dec = 6'b001111;
12'd1782 : mem_out_dec = 6'b001111;
12'd1783 : mem_out_dec = 6'b010000;
12'd1784 : mem_out_dec = 6'b010000;
12'd1785 : mem_out_dec = 6'b010000;
12'd1786 : mem_out_dec = 6'b010000;
12'd1787 : mem_out_dec = 6'b010001;
12'd1788 : mem_out_dec = 6'b010001;
12'd1789 : mem_out_dec = 6'b010010;
12'd1790 : mem_out_dec = 6'b010010;
12'd1791 : mem_out_dec = 6'b010011;
12'd1792 : mem_out_dec = 6'b111111;
12'd1793 : mem_out_dec = 6'b111111;
12'd1794 : mem_out_dec = 6'b111111;
12'd1795 : mem_out_dec = 6'b111111;
12'd1796 : mem_out_dec = 6'b111111;
12'd1797 : mem_out_dec = 6'b111111;
12'd1798 : mem_out_dec = 6'b111111;
12'd1799 : mem_out_dec = 6'b111111;
12'd1800 : mem_out_dec = 6'b111111;
12'd1801 : mem_out_dec = 6'b111111;
12'd1802 : mem_out_dec = 6'b111111;
12'd1803 : mem_out_dec = 6'b111111;
12'd1804 : mem_out_dec = 6'b111111;
12'd1805 : mem_out_dec = 6'b111111;
12'd1806 : mem_out_dec = 6'b111111;
12'd1807 : mem_out_dec = 6'b111111;
12'd1808 : mem_out_dec = 6'b111111;
12'd1809 : mem_out_dec = 6'b111111;
12'd1810 : mem_out_dec = 6'b111111;
12'd1811 : mem_out_dec = 6'b111111;
12'd1812 : mem_out_dec = 6'b111111;
12'd1813 : mem_out_dec = 6'b111111;
12'd1814 : mem_out_dec = 6'b111111;
12'd1815 : mem_out_dec = 6'b111111;
12'd1816 : mem_out_dec = 6'b111111;
12'd1817 : mem_out_dec = 6'b111111;
12'd1818 : mem_out_dec = 6'b111111;
12'd1819 : mem_out_dec = 6'b111111;
12'd1820 : mem_out_dec = 6'b111111;
12'd1821 : mem_out_dec = 6'b111111;
12'd1822 : mem_out_dec = 6'b111111;
12'd1823 : mem_out_dec = 6'b111111;
12'd1824 : mem_out_dec = 6'b111111;
12'd1825 : mem_out_dec = 6'b111111;
12'd1826 : mem_out_dec = 6'b000011;
12'd1827 : mem_out_dec = 6'b000100;
12'd1828 : mem_out_dec = 6'b000100;
12'd1829 : mem_out_dec = 6'b000101;
12'd1830 : mem_out_dec = 6'b000110;
12'd1831 : mem_out_dec = 6'b000110;
12'd1832 : mem_out_dec = 6'b000110;
12'd1833 : mem_out_dec = 6'b000111;
12'd1834 : mem_out_dec = 6'b001000;
12'd1835 : mem_out_dec = 6'b001001;
12'd1836 : mem_out_dec = 6'b001010;
12'd1837 : mem_out_dec = 6'b001010;
12'd1838 : mem_out_dec = 6'b001011;
12'd1839 : mem_out_dec = 6'b001100;
12'd1840 : mem_out_dec = 6'b001100;
12'd1841 : mem_out_dec = 6'b001100;
12'd1842 : mem_out_dec = 6'b001101;
12'd1843 : mem_out_dec = 6'b001101;
12'd1844 : mem_out_dec = 6'b001110;
12'd1845 : mem_out_dec = 6'b001110;
12'd1846 : mem_out_dec = 6'b001111;
12'd1847 : mem_out_dec = 6'b010000;
12'd1848 : mem_out_dec = 6'b001111;
12'd1849 : mem_out_dec = 6'b001111;
12'd1850 : mem_out_dec = 6'b010000;
12'd1851 : mem_out_dec = 6'b010000;
12'd1852 : mem_out_dec = 6'b010001;
12'd1853 : mem_out_dec = 6'b010001;
12'd1854 : mem_out_dec = 6'b010010;
12'd1855 : mem_out_dec = 6'b010010;
12'd1856 : mem_out_dec = 6'b111111;
12'd1857 : mem_out_dec = 6'b111111;
12'd1858 : mem_out_dec = 6'b111111;
12'd1859 : mem_out_dec = 6'b111111;
12'd1860 : mem_out_dec = 6'b111111;
12'd1861 : mem_out_dec = 6'b111111;
12'd1862 : mem_out_dec = 6'b111111;
12'd1863 : mem_out_dec = 6'b111111;
12'd1864 : mem_out_dec = 6'b111111;
12'd1865 : mem_out_dec = 6'b111111;
12'd1866 : mem_out_dec = 6'b111111;
12'd1867 : mem_out_dec = 6'b111111;
12'd1868 : mem_out_dec = 6'b111111;
12'd1869 : mem_out_dec = 6'b111111;
12'd1870 : mem_out_dec = 6'b111111;
12'd1871 : mem_out_dec = 6'b111111;
12'd1872 : mem_out_dec = 6'b111111;
12'd1873 : mem_out_dec = 6'b111111;
12'd1874 : mem_out_dec = 6'b111111;
12'd1875 : mem_out_dec = 6'b111111;
12'd1876 : mem_out_dec = 6'b111111;
12'd1877 : mem_out_dec = 6'b111111;
12'd1878 : mem_out_dec = 6'b111111;
12'd1879 : mem_out_dec = 6'b111111;
12'd1880 : mem_out_dec = 6'b111111;
12'd1881 : mem_out_dec = 6'b111111;
12'd1882 : mem_out_dec = 6'b111111;
12'd1883 : mem_out_dec = 6'b111111;
12'd1884 : mem_out_dec = 6'b111111;
12'd1885 : mem_out_dec = 6'b111111;
12'd1886 : mem_out_dec = 6'b111111;
12'd1887 : mem_out_dec = 6'b111111;
12'd1888 : mem_out_dec = 6'b111111;
12'd1889 : mem_out_dec = 6'b111111;
12'd1890 : mem_out_dec = 6'b111111;
12'd1891 : mem_out_dec = 6'b000100;
12'd1892 : mem_out_dec = 6'b000100;
12'd1893 : mem_out_dec = 6'b000101;
12'd1894 : mem_out_dec = 6'b000101;
12'd1895 : mem_out_dec = 6'b000110;
12'd1896 : mem_out_dec = 6'b000110;
12'd1897 : mem_out_dec = 6'b000111;
12'd1898 : mem_out_dec = 6'b001000;
12'd1899 : mem_out_dec = 6'b001001;
12'd1900 : mem_out_dec = 6'b001001;
12'd1901 : mem_out_dec = 6'b001010;
12'd1902 : mem_out_dec = 6'b001011;
12'd1903 : mem_out_dec = 6'b001100;
12'd1904 : mem_out_dec = 6'b001100;
12'd1905 : mem_out_dec = 6'b001100;
12'd1906 : mem_out_dec = 6'b001100;
12'd1907 : mem_out_dec = 6'b001101;
12'd1908 : mem_out_dec = 6'b001110;
12'd1909 : mem_out_dec = 6'b001110;
12'd1910 : mem_out_dec = 6'b001111;
12'd1911 : mem_out_dec = 6'b001111;
12'd1912 : mem_out_dec = 6'b001111;
12'd1913 : mem_out_dec = 6'b001111;
12'd1914 : mem_out_dec = 6'b001111;
12'd1915 : mem_out_dec = 6'b010000;
12'd1916 : mem_out_dec = 6'b010000;
12'd1917 : mem_out_dec = 6'b010001;
12'd1918 : mem_out_dec = 6'b010001;
12'd1919 : mem_out_dec = 6'b010010;
12'd1920 : mem_out_dec = 6'b111111;
12'd1921 : mem_out_dec = 6'b111111;
12'd1922 : mem_out_dec = 6'b111111;
12'd1923 : mem_out_dec = 6'b111111;
12'd1924 : mem_out_dec = 6'b111111;
12'd1925 : mem_out_dec = 6'b111111;
12'd1926 : mem_out_dec = 6'b111111;
12'd1927 : mem_out_dec = 6'b111111;
12'd1928 : mem_out_dec = 6'b111111;
12'd1929 : mem_out_dec = 6'b111111;
12'd1930 : mem_out_dec = 6'b111111;
12'd1931 : mem_out_dec = 6'b111111;
12'd1932 : mem_out_dec = 6'b111111;
12'd1933 : mem_out_dec = 6'b111111;
12'd1934 : mem_out_dec = 6'b111111;
12'd1935 : mem_out_dec = 6'b111111;
12'd1936 : mem_out_dec = 6'b111111;
12'd1937 : mem_out_dec = 6'b111111;
12'd1938 : mem_out_dec = 6'b111111;
12'd1939 : mem_out_dec = 6'b111111;
12'd1940 : mem_out_dec = 6'b111111;
12'd1941 : mem_out_dec = 6'b111111;
12'd1942 : mem_out_dec = 6'b111111;
12'd1943 : mem_out_dec = 6'b111111;
12'd1944 : mem_out_dec = 6'b111111;
12'd1945 : mem_out_dec = 6'b111111;
12'd1946 : mem_out_dec = 6'b111111;
12'd1947 : mem_out_dec = 6'b111111;
12'd1948 : mem_out_dec = 6'b111111;
12'd1949 : mem_out_dec = 6'b111111;
12'd1950 : mem_out_dec = 6'b111111;
12'd1951 : mem_out_dec = 6'b111111;
12'd1952 : mem_out_dec = 6'b111111;
12'd1953 : mem_out_dec = 6'b111111;
12'd1954 : mem_out_dec = 6'b111111;
12'd1955 : mem_out_dec = 6'b111111;
12'd1956 : mem_out_dec = 6'b000100;
12'd1957 : mem_out_dec = 6'b000101;
12'd1958 : mem_out_dec = 6'b000101;
12'd1959 : mem_out_dec = 6'b000110;
12'd1960 : mem_out_dec = 6'b000110;
12'd1961 : mem_out_dec = 6'b000111;
12'd1962 : mem_out_dec = 6'b001000;
12'd1963 : mem_out_dec = 6'b001000;
12'd1964 : mem_out_dec = 6'b001001;
12'd1965 : mem_out_dec = 6'b001010;
12'd1966 : mem_out_dec = 6'b001011;
12'd1967 : mem_out_dec = 6'b001011;
12'd1968 : mem_out_dec = 6'b001011;
12'd1969 : mem_out_dec = 6'b001100;
12'd1970 : mem_out_dec = 6'b001100;
12'd1971 : mem_out_dec = 6'b001101;
12'd1972 : mem_out_dec = 6'b001101;
12'd1973 : mem_out_dec = 6'b001110;
12'd1974 : mem_out_dec = 6'b001111;
12'd1975 : mem_out_dec = 6'b001111;
12'd1976 : mem_out_dec = 6'b001110;
12'd1977 : mem_out_dec = 6'b001110;
12'd1978 : mem_out_dec = 6'b001111;
12'd1979 : mem_out_dec = 6'b001111;
12'd1980 : mem_out_dec = 6'b010000;
12'd1981 : mem_out_dec = 6'b010000;
12'd1982 : mem_out_dec = 6'b010001;
12'd1983 : mem_out_dec = 6'b010001;
12'd1984 : mem_out_dec = 6'b111111;
12'd1985 : mem_out_dec = 6'b111111;
12'd1986 : mem_out_dec = 6'b111111;
12'd1987 : mem_out_dec = 6'b111111;
12'd1988 : mem_out_dec = 6'b111111;
12'd1989 : mem_out_dec = 6'b111111;
12'd1990 : mem_out_dec = 6'b111111;
12'd1991 : mem_out_dec = 6'b111111;
12'd1992 : mem_out_dec = 6'b111111;
12'd1993 : mem_out_dec = 6'b111111;
12'd1994 : mem_out_dec = 6'b111111;
12'd1995 : mem_out_dec = 6'b111111;
12'd1996 : mem_out_dec = 6'b111111;
12'd1997 : mem_out_dec = 6'b111111;
12'd1998 : mem_out_dec = 6'b111111;
12'd1999 : mem_out_dec = 6'b111111;
12'd2000 : mem_out_dec = 6'b111111;
12'd2001 : mem_out_dec = 6'b111111;
12'd2002 : mem_out_dec = 6'b111111;
12'd2003 : mem_out_dec = 6'b111111;
12'd2004 : mem_out_dec = 6'b111111;
12'd2005 : mem_out_dec = 6'b111111;
12'd2006 : mem_out_dec = 6'b111111;
12'd2007 : mem_out_dec = 6'b111111;
12'd2008 : mem_out_dec = 6'b111111;
12'd2009 : mem_out_dec = 6'b111111;
12'd2010 : mem_out_dec = 6'b111111;
12'd2011 : mem_out_dec = 6'b111111;
12'd2012 : mem_out_dec = 6'b111111;
12'd2013 : mem_out_dec = 6'b111111;
12'd2014 : mem_out_dec = 6'b111111;
12'd2015 : mem_out_dec = 6'b111111;
12'd2016 : mem_out_dec = 6'b111111;
12'd2017 : mem_out_dec = 6'b111111;
12'd2018 : mem_out_dec = 6'b111111;
12'd2019 : mem_out_dec = 6'b111111;
12'd2020 : mem_out_dec = 6'b111111;
12'd2021 : mem_out_dec = 6'b000100;
12'd2022 : mem_out_dec = 6'b000101;
12'd2023 : mem_out_dec = 6'b000110;
12'd2024 : mem_out_dec = 6'b000110;
12'd2025 : mem_out_dec = 6'b000111;
12'd2026 : mem_out_dec = 6'b000111;
12'd2027 : mem_out_dec = 6'b001000;
12'd2028 : mem_out_dec = 6'b001001;
12'd2029 : mem_out_dec = 6'b001010;
12'd2030 : mem_out_dec = 6'b001010;
12'd2031 : mem_out_dec = 6'b001011;
12'd2032 : mem_out_dec = 6'b001011;
12'd2033 : mem_out_dec = 6'b001011;
12'd2034 : mem_out_dec = 6'b001100;
12'd2035 : mem_out_dec = 6'b001101;
12'd2036 : mem_out_dec = 6'b001101;
12'd2037 : mem_out_dec = 6'b001110;
12'd2038 : mem_out_dec = 6'b001110;
12'd2039 : mem_out_dec = 6'b001110;
12'd2040 : mem_out_dec = 6'b001101;
12'd2041 : mem_out_dec = 6'b001110;
12'd2042 : mem_out_dec = 6'b001110;
12'd2043 : mem_out_dec = 6'b001111;
12'd2044 : mem_out_dec = 6'b001111;
12'd2045 : mem_out_dec = 6'b010000;
12'd2046 : mem_out_dec = 6'b010000;
12'd2047 : mem_out_dec = 6'b010001;
12'd2048 : mem_out_dec = 6'b111111;
12'd2049 : mem_out_dec = 6'b111111;
12'd2050 : mem_out_dec = 6'b111111;
12'd2051 : mem_out_dec = 6'b111111;
12'd2052 : mem_out_dec = 6'b111111;
12'd2053 : mem_out_dec = 6'b111111;
12'd2054 : mem_out_dec = 6'b111111;
12'd2055 : mem_out_dec = 6'b111111;
12'd2056 : mem_out_dec = 6'b111111;
12'd2057 : mem_out_dec = 6'b111111;
12'd2058 : mem_out_dec = 6'b111111;
12'd2059 : mem_out_dec = 6'b111111;
12'd2060 : mem_out_dec = 6'b111111;
12'd2061 : mem_out_dec = 6'b111111;
12'd2062 : mem_out_dec = 6'b111111;
12'd2063 : mem_out_dec = 6'b111111;
12'd2064 : mem_out_dec = 6'b111111;
12'd2065 : mem_out_dec = 6'b111111;
12'd2066 : mem_out_dec = 6'b111111;
12'd2067 : mem_out_dec = 6'b111111;
12'd2068 : mem_out_dec = 6'b111111;
12'd2069 : mem_out_dec = 6'b111111;
12'd2070 : mem_out_dec = 6'b111111;
12'd2071 : mem_out_dec = 6'b111111;
12'd2072 : mem_out_dec = 6'b111111;
12'd2073 : mem_out_dec = 6'b111111;
12'd2074 : mem_out_dec = 6'b111111;
12'd2075 : mem_out_dec = 6'b111111;
12'd2076 : mem_out_dec = 6'b111111;
12'd2077 : mem_out_dec = 6'b111111;
12'd2078 : mem_out_dec = 6'b111111;
12'd2079 : mem_out_dec = 6'b111111;
12'd2080 : mem_out_dec = 6'b111111;
12'd2081 : mem_out_dec = 6'b111111;
12'd2082 : mem_out_dec = 6'b111111;
12'd2083 : mem_out_dec = 6'b111111;
12'd2084 : mem_out_dec = 6'b111111;
12'd2085 : mem_out_dec = 6'b111111;
12'd2086 : mem_out_dec = 6'b000100;
12'd2087 : mem_out_dec = 6'b000101;
12'd2088 : mem_out_dec = 6'b000101;
12'd2089 : mem_out_dec = 6'b000110;
12'd2090 : mem_out_dec = 6'b000110;
12'd2091 : mem_out_dec = 6'b000111;
12'd2092 : mem_out_dec = 6'b001000;
12'd2093 : mem_out_dec = 6'b001001;
12'd2094 : mem_out_dec = 6'b001001;
12'd2095 : mem_out_dec = 6'b001010;
12'd2096 : mem_out_dec = 6'b001010;
12'd2097 : mem_out_dec = 6'b001011;
12'd2098 : mem_out_dec = 6'b001011;
12'd2099 : mem_out_dec = 6'b001100;
12'd2100 : mem_out_dec = 6'b001100;
12'd2101 : mem_out_dec = 6'b001100;
12'd2102 : mem_out_dec = 6'b001100;
12'd2103 : mem_out_dec = 6'b001101;
12'd2104 : mem_out_dec = 6'b001100;
12'd2105 : mem_out_dec = 6'b001100;
12'd2106 : mem_out_dec = 6'b001101;
12'd2107 : mem_out_dec = 6'b001101;
12'd2108 : mem_out_dec = 6'b001110;
12'd2109 : mem_out_dec = 6'b001111;
12'd2110 : mem_out_dec = 6'b010000;
12'd2111 : mem_out_dec = 6'b010000;
12'd2112 : mem_out_dec = 6'b111111;
12'd2113 : mem_out_dec = 6'b111111;
12'd2114 : mem_out_dec = 6'b111111;
12'd2115 : mem_out_dec = 6'b111111;
12'd2116 : mem_out_dec = 6'b111111;
12'd2117 : mem_out_dec = 6'b111111;
12'd2118 : mem_out_dec = 6'b111111;
12'd2119 : mem_out_dec = 6'b111111;
12'd2120 : mem_out_dec = 6'b111111;
12'd2121 : mem_out_dec = 6'b111111;
12'd2122 : mem_out_dec = 6'b111111;
12'd2123 : mem_out_dec = 6'b111111;
12'd2124 : mem_out_dec = 6'b111111;
12'd2125 : mem_out_dec = 6'b111111;
12'd2126 : mem_out_dec = 6'b111111;
12'd2127 : mem_out_dec = 6'b111111;
12'd2128 : mem_out_dec = 6'b111111;
12'd2129 : mem_out_dec = 6'b111111;
12'd2130 : mem_out_dec = 6'b111111;
12'd2131 : mem_out_dec = 6'b111111;
12'd2132 : mem_out_dec = 6'b111111;
12'd2133 : mem_out_dec = 6'b111111;
12'd2134 : mem_out_dec = 6'b111111;
12'd2135 : mem_out_dec = 6'b111111;
12'd2136 : mem_out_dec = 6'b111111;
12'd2137 : mem_out_dec = 6'b111111;
12'd2138 : mem_out_dec = 6'b111111;
12'd2139 : mem_out_dec = 6'b111111;
12'd2140 : mem_out_dec = 6'b111111;
12'd2141 : mem_out_dec = 6'b111111;
12'd2142 : mem_out_dec = 6'b111111;
12'd2143 : mem_out_dec = 6'b111111;
12'd2144 : mem_out_dec = 6'b111111;
12'd2145 : mem_out_dec = 6'b111111;
12'd2146 : mem_out_dec = 6'b111111;
12'd2147 : mem_out_dec = 6'b111111;
12'd2148 : mem_out_dec = 6'b111111;
12'd2149 : mem_out_dec = 6'b111111;
12'd2150 : mem_out_dec = 6'b111111;
12'd2151 : mem_out_dec = 6'b000100;
12'd2152 : mem_out_dec = 6'b000100;
12'd2153 : mem_out_dec = 6'b000101;
12'd2154 : mem_out_dec = 6'b000110;
12'd2155 : mem_out_dec = 6'b000111;
12'd2156 : mem_out_dec = 6'b000111;
12'd2157 : mem_out_dec = 6'b001000;
12'd2158 : mem_out_dec = 6'b001001;
12'd2159 : mem_out_dec = 6'b001001;
12'd2160 : mem_out_dec = 6'b001010;
12'd2161 : mem_out_dec = 6'b001010;
12'd2162 : mem_out_dec = 6'b001011;
12'd2163 : mem_out_dec = 6'b001011;
12'd2164 : mem_out_dec = 6'b001011;
12'd2165 : mem_out_dec = 6'b001011;
12'd2166 : mem_out_dec = 6'b001011;
12'd2167 : mem_out_dec = 6'b001100;
12'd2168 : mem_out_dec = 6'b001011;
12'd2169 : mem_out_dec = 6'b001011;
12'd2170 : mem_out_dec = 6'b001100;
12'd2171 : mem_out_dec = 6'b001101;
12'd2172 : mem_out_dec = 6'b001110;
12'd2173 : mem_out_dec = 6'b001110;
12'd2174 : mem_out_dec = 6'b001111;
12'd2175 : mem_out_dec = 6'b010000;
12'd2176 : mem_out_dec = 6'b111111;
12'd2177 : mem_out_dec = 6'b111111;
12'd2178 : mem_out_dec = 6'b111111;
12'd2179 : mem_out_dec = 6'b111111;
12'd2180 : mem_out_dec = 6'b111111;
12'd2181 : mem_out_dec = 6'b111111;
12'd2182 : mem_out_dec = 6'b111111;
12'd2183 : mem_out_dec = 6'b111111;
12'd2184 : mem_out_dec = 6'b111111;
12'd2185 : mem_out_dec = 6'b111111;
12'd2186 : mem_out_dec = 6'b111111;
12'd2187 : mem_out_dec = 6'b111111;
12'd2188 : mem_out_dec = 6'b111111;
12'd2189 : mem_out_dec = 6'b111111;
12'd2190 : mem_out_dec = 6'b111111;
12'd2191 : mem_out_dec = 6'b111111;
12'd2192 : mem_out_dec = 6'b111111;
12'd2193 : mem_out_dec = 6'b111111;
12'd2194 : mem_out_dec = 6'b111111;
12'd2195 : mem_out_dec = 6'b111111;
12'd2196 : mem_out_dec = 6'b111111;
12'd2197 : mem_out_dec = 6'b111111;
12'd2198 : mem_out_dec = 6'b111111;
12'd2199 : mem_out_dec = 6'b111111;
12'd2200 : mem_out_dec = 6'b111111;
12'd2201 : mem_out_dec = 6'b111111;
12'd2202 : mem_out_dec = 6'b111111;
12'd2203 : mem_out_dec = 6'b111111;
12'd2204 : mem_out_dec = 6'b111111;
12'd2205 : mem_out_dec = 6'b111111;
12'd2206 : mem_out_dec = 6'b111111;
12'd2207 : mem_out_dec = 6'b111111;
12'd2208 : mem_out_dec = 6'b111111;
12'd2209 : mem_out_dec = 6'b111111;
12'd2210 : mem_out_dec = 6'b111111;
12'd2211 : mem_out_dec = 6'b111111;
12'd2212 : mem_out_dec = 6'b111111;
12'd2213 : mem_out_dec = 6'b111111;
12'd2214 : mem_out_dec = 6'b111111;
12'd2215 : mem_out_dec = 6'b111111;
12'd2216 : mem_out_dec = 6'b000100;
12'd2217 : mem_out_dec = 6'b000101;
12'd2218 : mem_out_dec = 6'b000101;
12'd2219 : mem_out_dec = 6'b000110;
12'd2220 : mem_out_dec = 6'b000111;
12'd2221 : mem_out_dec = 6'b000111;
12'd2222 : mem_out_dec = 6'b001000;
12'd2223 : mem_out_dec = 6'b001001;
12'd2224 : mem_out_dec = 6'b001001;
12'd2225 : mem_out_dec = 6'b001010;
12'd2226 : mem_out_dec = 6'b001010;
12'd2227 : mem_out_dec = 6'b001010;
12'd2228 : mem_out_dec = 6'b001010;
12'd2229 : mem_out_dec = 6'b001010;
12'd2230 : mem_out_dec = 6'b001010;
12'd2231 : mem_out_dec = 6'b001010;
12'd2232 : mem_out_dec = 6'b001010;
12'd2233 : mem_out_dec = 6'b001011;
12'd2234 : mem_out_dec = 6'b001100;
12'd2235 : mem_out_dec = 6'b001100;
12'd2236 : mem_out_dec = 6'b001101;
12'd2237 : mem_out_dec = 6'b001110;
12'd2238 : mem_out_dec = 6'b001111;
12'd2239 : mem_out_dec = 6'b010000;
12'd2240 : mem_out_dec = 6'b111111;
12'd2241 : mem_out_dec = 6'b111111;
12'd2242 : mem_out_dec = 6'b111111;
12'd2243 : mem_out_dec = 6'b111111;
12'd2244 : mem_out_dec = 6'b111111;
12'd2245 : mem_out_dec = 6'b111111;
12'd2246 : mem_out_dec = 6'b111111;
12'd2247 : mem_out_dec = 6'b111111;
12'd2248 : mem_out_dec = 6'b111111;
12'd2249 : mem_out_dec = 6'b111111;
12'd2250 : mem_out_dec = 6'b111111;
12'd2251 : mem_out_dec = 6'b111111;
12'd2252 : mem_out_dec = 6'b111111;
12'd2253 : mem_out_dec = 6'b111111;
12'd2254 : mem_out_dec = 6'b111111;
12'd2255 : mem_out_dec = 6'b111111;
12'd2256 : mem_out_dec = 6'b111111;
12'd2257 : mem_out_dec = 6'b111111;
12'd2258 : mem_out_dec = 6'b111111;
12'd2259 : mem_out_dec = 6'b111111;
12'd2260 : mem_out_dec = 6'b111111;
12'd2261 : mem_out_dec = 6'b111111;
12'd2262 : mem_out_dec = 6'b111111;
12'd2263 : mem_out_dec = 6'b111111;
12'd2264 : mem_out_dec = 6'b111111;
12'd2265 : mem_out_dec = 6'b111111;
12'd2266 : mem_out_dec = 6'b111111;
12'd2267 : mem_out_dec = 6'b111111;
12'd2268 : mem_out_dec = 6'b111111;
12'd2269 : mem_out_dec = 6'b111111;
12'd2270 : mem_out_dec = 6'b111111;
12'd2271 : mem_out_dec = 6'b111111;
12'd2272 : mem_out_dec = 6'b111111;
12'd2273 : mem_out_dec = 6'b111111;
12'd2274 : mem_out_dec = 6'b111111;
12'd2275 : mem_out_dec = 6'b111111;
12'd2276 : mem_out_dec = 6'b111111;
12'd2277 : mem_out_dec = 6'b111111;
12'd2278 : mem_out_dec = 6'b111111;
12'd2279 : mem_out_dec = 6'b111111;
12'd2280 : mem_out_dec = 6'b111111;
12'd2281 : mem_out_dec = 6'b000100;
12'd2282 : mem_out_dec = 6'b000101;
12'd2283 : mem_out_dec = 6'b000101;
12'd2284 : mem_out_dec = 6'b000110;
12'd2285 : mem_out_dec = 6'b000111;
12'd2286 : mem_out_dec = 6'b001000;
12'd2287 : mem_out_dec = 6'b001001;
12'd2288 : mem_out_dec = 6'b001001;
12'd2289 : mem_out_dec = 6'b001001;
12'd2290 : mem_out_dec = 6'b001001;
12'd2291 : mem_out_dec = 6'b001001;
12'd2292 : mem_out_dec = 6'b001001;
12'd2293 : mem_out_dec = 6'b001001;
12'd2294 : mem_out_dec = 6'b001001;
12'd2295 : mem_out_dec = 6'b001001;
12'd2296 : mem_out_dec = 6'b001010;
12'd2297 : mem_out_dec = 6'b001010;
12'd2298 : mem_out_dec = 6'b001011;
12'd2299 : mem_out_dec = 6'b001100;
12'd2300 : mem_out_dec = 6'b001101;
12'd2301 : mem_out_dec = 6'b001110;
12'd2302 : mem_out_dec = 6'b001110;
12'd2303 : mem_out_dec = 6'b001111;
12'd2304 : mem_out_dec = 6'b111111;
12'd2305 : mem_out_dec = 6'b111111;
12'd2306 : mem_out_dec = 6'b111111;
12'd2307 : mem_out_dec = 6'b111111;
12'd2308 : mem_out_dec = 6'b111111;
12'd2309 : mem_out_dec = 6'b111111;
12'd2310 : mem_out_dec = 6'b111111;
12'd2311 : mem_out_dec = 6'b111111;
12'd2312 : mem_out_dec = 6'b111111;
12'd2313 : mem_out_dec = 6'b111111;
12'd2314 : mem_out_dec = 6'b111111;
12'd2315 : mem_out_dec = 6'b111111;
12'd2316 : mem_out_dec = 6'b111111;
12'd2317 : mem_out_dec = 6'b111111;
12'd2318 : mem_out_dec = 6'b111111;
12'd2319 : mem_out_dec = 6'b111111;
12'd2320 : mem_out_dec = 6'b111111;
12'd2321 : mem_out_dec = 6'b111111;
12'd2322 : mem_out_dec = 6'b111111;
12'd2323 : mem_out_dec = 6'b111111;
12'd2324 : mem_out_dec = 6'b111111;
12'd2325 : mem_out_dec = 6'b111111;
12'd2326 : mem_out_dec = 6'b111111;
12'd2327 : mem_out_dec = 6'b111111;
12'd2328 : mem_out_dec = 6'b111111;
12'd2329 : mem_out_dec = 6'b111111;
12'd2330 : mem_out_dec = 6'b111111;
12'd2331 : mem_out_dec = 6'b111111;
12'd2332 : mem_out_dec = 6'b111111;
12'd2333 : mem_out_dec = 6'b111111;
12'd2334 : mem_out_dec = 6'b111111;
12'd2335 : mem_out_dec = 6'b111111;
12'd2336 : mem_out_dec = 6'b111111;
12'd2337 : mem_out_dec = 6'b111111;
12'd2338 : mem_out_dec = 6'b111111;
12'd2339 : mem_out_dec = 6'b111111;
12'd2340 : mem_out_dec = 6'b111111;
12'd2341 : mem_out_dec = 6'b111111;
12'd2342 : mem_out_dec = 6'b111111;
12'd2343 : mem_out_dec = 6'b111111;
12'd2344 : mem_out_dec = 6'b111111;
12'd2345 : mem_out_dec = 6'b111111;
12'd2346 : mem_out_dec = 6'b000100;
12'd2347 : mem_out_dec = 6'b000101;
12'd2348 : mem_out_dec = 6'b000110;
12'd2349 : mem_out_dec = 6'b000111;
12'd2350 : mem_out_dec = 6'b000111;
12'd2351 : mem_out_dec = 6'b001000;
12'd2352 : mem_out_dec = 6'b001000;
12'd2353 : mem_out_dec = 6'b001000;
12'd2354 : mem_out_dec = 6'b001000;
12'd2355 : mem_out_dec = 6'b001000;
12'd2356 : mem_out_dec = 6'b001000;
12'd2357 : mem_out_dec = 6'b001000;
12'd2358 : mem_out_dec = 6'b001000;
12'd2359 : mem_out_dec = 6'b001001;
12'd2360 : mem_out_dec = 6'b001001;
12'd2361 : mem_out_dec = 6'b001010;
12'd2362 : mem_out_dec = 6'b001011;
12'd2363 : mem_out_dec = 6'b001100;
12'd2364 : mem_out_dec = 6'b001100;
12'd2365 : mem_out_dec = 6'b001101;
12'd2366 : mem_out_dec = 6'b001110;
12'd2367 : mem_out_dec = 6'b001111;
12'd2368 : mem_out_dec = 6'b111111;
12'd2369 : mem_out_dec = 6'b111111;
12'd2370 : mem_out_dec = 6'b111111;
12'd2371 : mem_out_dec = 6'b111111;
12'd2372 : mem_out_dec = 6'b111111;
12'd2373 : mem_out_dec = 6'b111111;
12'd2374 : mem_out_dec = 6'b111111;
12'd2375 : mem_out_dec = 6'b111111;
12'd2376 : mem_out_dec = 6'b111111;
12'd2377 : mem_out_dec = 6'b111111;
12'd2378 : mem_out_dec = 6'b111111;
12'd2379 : mem_out_dec = 6'b111111;
12'd2380 : mem_out_dec = 6'b111111;
12'd2381 : mem_out_dec = 6'b111111;
12'd2382 : mem_out_dec = 6'b111111;
12'd2383 : mem_out_dec = 6'b111111;
12'd2384 : mem_out_dec = 6'b111111;
12'd2385 : mem_out_dec = 6'b111111;
12'd2386 : mem_out_dec = 6'b111111;
12'd2387 : mem_out_dec = 6'b111111;
12'd2388 : mem_out_dec = 6'b111111;
12'd2389 : mem_out_dec = 6'b111111;
12'd2390 : mem_out_dec = 6'b111111;
12'd2391 : mem_out_dec = 6'b111111;
12'd2392 : mem_out_dec = 6'b111111;
12'd2393 : mem_out_dec = 6'b111111;
12'd2394 : mem_out_dec = 6'b111111;
12'd2395 : mem_out_dec = 6'b111111;
12'd2396 : mem_out_dec = 6'b111111;
12'd2397 : mem_out_dec = 6'b111111;
12'd2398 : mem_out_dec = 6'b111111;
12'd2399 : mem_out_dec = 6'b111111;
12'd2400 : mem_out_dec = 6'b111111;
12'd2401 : mem_out_dec = 6'b111111;
12'd2402 : mem_out_dec = 6'b111111;
12'd2403 : mem_out_dec = 6'b111111;
12'd2404 : mem_out_dec = 6'b111111;
12'd2405 : mem_out_dec = 6'b111111;
12'd2406 : mem_out_dec = 6'b111111;
12'd2407 : mem_out_dec = 6'b111111;
12'd2408 : mem_out_dec = 6'b111111;
12'd2409 : mem_out_dec = 6'b111111;
12'd2410 : mem_out_dec = 6'b111111;
12'd2411 : mem_out_dec = 6'b000101;
12'd2412 : mem_out_dec = 6'b000101;
12'd2413 : mem_out_dec = 6'b000110;
12'd2414 : mem_out_dec = 6'b000111;
12'd2415 : mem_out_dec = 6'b001000;
12'd2416 : mem_out_dec = 6'b000111;
12'd2417 : mem_out_dec = 6'b000111;
12'd2418 : mem_out_dec = 6'b000111;
12'd2419 : mem_out_dec = 6'b000111;
12'd2420 : mem_out_dec = 6'b000111;
12'd2421 : mem_out_dec = 6'b000111;
12'd2422 : mem_out_dec = 6'b001000;
12'd2423 : mem_out_dec = 6'b001001;
12'd2424 : mem_out_dec = 6'b001001;
12'd2425 : mem_out_dec = 6'b001010;
12'd2426 : mem_out_dec = 6'b001010;
12'd2427 : mem_out_dec = 6'b001011;
12'd2428 : mem_out_dec = 6'b001100;
12'd2429 : mem_out_dec = 6'b001101;
12'd2430 : mem_out_dec = 6'b001101;
12'd2431 : mem_out_dec = 6'b001110;
12'd2432 : mem_out_dec = 6'b111111;
12'd2433 : mem_out_dec = 6'b111111;
12'd2434 : mem_out_dec = 6'b111111;
12'd2435 : mem_out_dec = 6'b111111;
12'd2436 : mem_out_dec = 6'b111111;
12'd2437 : mem_out_dec = 6'b111111;
12'd2438 : mem_out_dec = 6'b111111;
12'd2439 : mem_out_dec = 6'b111111;
12'd2440 : mem_out_dec = 6'b111111;
12'd2441 : mem_out_dec = 6'b111111;
12'd2442 : mem_out_dec = 6'b111111;
12'd2443 : mem_out_dec = 6'b111111;
12'd2444 : mem_out_dec = 6'b111111;
12'd2445 : mem_out_dec = 6'b111111;
12'd2446 : mem_out_dec = 6'b111111;
12'd2447 : mem_out_dec = 6'b111111;
12'd2448 : mem_out_dec = 6'b111111;
12'd2449 : mem_out_dec = 6'b111111;
12'd2450 : mem_out_dec = 6'b111111;
12'd2451 : mem_out_dec = 6'b111111;
12'd2452 : mem_out_dec = 6'b111111;
12'd2453 : mem_out_dec = 6'b111111;
12'd2454 : mem_out_dec = 6'b111111;
12'd2455 : mem_out_dec = 6'b111111;
12'd2456 : mem_out_dec = 6'b111111;
12'd2457 : mem_out_dec = 6'b111111;
12'd2458 : mem_out_dec = 6'b111111;
12'd2459 : mem_out_dec = 6'b111111;
12'd2460 : mem_out_dec = 6'b111111;
12'd2461 : mem_out_dec = 6'b111111;
12'd2462 : mem_out_dec = 6'b111111;
12'd2463 : mem_out_dec = 6'b111111;
12'd2464 : mem_out_dec = 6'b111111;
12'd2465 : mem_out_dec = 6'b111111;
12'd2466 : mem_out_dec = 6'b111111;
12'd2467 : mem_out_dec = 6'b111111;
12'd2468 : mem_out_dec = 6'b111111;
12'd2469 : mem_out_dec = 6'b111111;
12'd2470 : mem_out_dec = 6'b111111;
12'd2471 : mem_out_dec = 6'b111111;
12'd2472 : mem_out_dec = 6'b111111;
12'd2473 : mem_out_dec = 6'b111111;
12'd2474 : mem_out_dec = 6'b111111;
12'd2475 : mem_out_dec = 6'b111111;
12'd2476 : mem_out_dec = 6'b000101;
12'd2477 : mem_out_dec = 6'b000110;
12'd2478 : mem_out_dec = 6'b000111;
12'd2479 : mem_out_dec = 6'b000111;
12'd2480 : mem_out_dec = 6'b000110;
12'd2481 : mem_out_dec = 6'b000110;
12'd2482 : mem_out_dec = 6'b000110;
12'd2483 : mem_out_dec = 6'b000110;
12'd2484 : mem_out_dec = 6'b000110;
12'd2485 : mem_out_dec = 6'b000111;
12'd2486 : mem_out_dec = 6'b000111;
12'd2487 : mem_out_dec = 6'b001000;
12'd2488 : mem_out_dec = 6'b001001;
12'd2489 : mem_out_dec = 6'b001001;
12'd2490 : mem_out_dec = 6'b001010;
12'd2491 : mem_out_dec = 6'b001011;
12'd2492 : mem_out_dec = 6'b001011;
12'd2493 : mem_out_dec = 6'b001100;
12'd2494 : mem_out_dec = 6'b001101;
12'd2495 : mem_out_dec = 6'b001110;
12'd2496 : mem_out_dec = 6'b111111;
12'd2497 : mem_out_dec = 6'b111111;
12'd2498 : mem_out_dec = 6'b111111;
12'd2499 : mem_out_dec = 6'b111111;
12'd2500 : mem_out_dec = 6'b111111;
12'd2501 : mem_out_dec = 6'b111111;
12'd2502 : mem_out_dec = 6'b111111;
12'd2503 : mem_out_dec = 6'b111111;
12'd2504 : mem_out_dec = 6'b111111;
12'd2505 : mem_out_dec = 6'b111111;
12'd2506 : mem_out_dec = 6'b111111;
12'd2507 : mem_out_dec = 6'b111111;
12'd2508 : mem_out_dec = 6'b111111;
12'd2509 : mem_out_dec = 6'b111111;
12'd2510 : mem_out_dec = 6'b111111;
12'd2511 : mem_out_dec = 6'b111111;
12'd2512 : mem_out_dec = 6'b111111;
12'd2513 : mem_out_dec = 6'b111111;
12'd2514 : mem_out_dec = 6'b111111;
12'd2515 : mem_out_dec = 6'b111111;
12'd2516 : mem_out_dec = 6'b111111;
12'd2517 : mem_out_dec = 6'b111111;
12'd2518 : mem_out_dec = 6'b111111;
12'd2519 : mem_out_dec = 6'b111111;
12'd2520 : mem_out_dec = 6'b111111;
12'd2521 : mem_out_dec = 6'b111111;
12'd2522 : mem_out_dec = 6'b111111;
12'd2523 : mem_out_dec = 6'b111111;
12'd2524 : mem_out_dec = 6'b111111;
12'd2525 : mem_out_dec = 6'b111111;
12'd2526 : mem_out_dec = 6'b111111;
12'd2527 : mem_out_dec = 6'b111111;
12'd2528 : mem_out_dec = 6'b111111;
12'd2529 : mem_out_dec = 6'b111111;
12'd2530 : mem_out_dec = 6'b111111;
12'd2531 : mem_out_dec = 6'b111111;
12'd2532 : mem_out_dec = 6'b111111;
12'd2533 : mem_out_dec = 6'b111111;
12'd2534 : mem_out_dec = 6'b111111;
12'd2535 : mem_out_dec = 6'b111111;
12'd2536 : mem_out_dec = 6'b111111;
12'd2537 : mem_out_dec = 6'b111111;
12'd2538 : mem_out_dec = 6'b111111;
12'd2539 : mem_out_dec = 6'b111111;
12'd2540 : mem_out_dec = 6'b111111;
12'd2541 : mem_out_dec = 6'b000101;
12'd2542 : mem_out_dec = 6'b000110;
12'd2543 : mem_out_dec = 6'b000110;
12'd2544 : mem_out_dec = 6'b000110;
12'd2545 : mem_out_dec = 6'b000110;
12'd2546 : mem_out_dec = 6'b000101;
12'd2547 : mem_out_dec = 6'b000101;
12'd2548 : mem_out_dec = 6'b000110;
12'd2549 : mem_out_dec = 6'b000111;
12'd2550 : mem_out_dec = 6'b000111;
12'd2551 : mem_out_dec = 6'b001000;
12'd2552 : mem_out_dec = 6'b001000;
12'd2553 : mem_out_dec = 6'b001001;
12'd2554 : mem_out_dec = 6'b001010;
12'd2555 : mem_out_dec = 6'b001010;
12'd2556 : mem_out_dec = 6'b001011;
12'd2557 : mem_out_dec = 6'b001100;
12'd2558 : mem_out_dec = 6'b001101;
12'd2559 : mem_out_dec = 6'b001101;
12'd2560 : mem_out_dec = 6'b111111;
12'd2561 : mem_out_dec = 6'b111111;
12'd2562 : mem_out_dec = 6'b111111;
12'd2563 : mem_out_dec = 6'b111111;
12'd2564 : mem_out_dec = 6'b111111;
12'd2565 : mem_out_dec = 6'b111111;
12'd2566 : mem_out_dec = 6'b111111;
12'd2567 : mem_out_dec = 6'b111111;
12'd2568 : mem_out_dec = 6'b111111;
12'd2569 : mem_out_dec = 6'b111111;
12'd2570 : mem_out_dec = 6'b111111;
12'd2571 : mem_out_dec = 6'b111111;
12'd2572 : mem_out_dec = 6'b111111;
12'd2573 : mem_out_dec = 6'b111111;
12'd2574 : mem_out_dec = 6'b111111;
12'd2575 : mem_out_dec = 6'b111111;
12'd2576 : mem_out_dec = 6'b111111;
12'd2577 : mem_out_dec = 6'b111111;
12'd2578 : mem_out_dec = 6'b111111;
12'd2579 : mem_out_dec = 6'b111111;
12'd2580 : mem_out_dec = 6'b111111;
12'd2581 : mem_out_dec = 6'b111111;
12'd2582 : mem_out_dec = 6'b111111;
12'd2583 : mem_out_dec = 6'b111111;
12'd2584 : mem_out_dec = 6'b111111;
12'd2585 : mem_out_dec = 6'b111111;
12'd2586 : mem_out_dec = 6'b111111;
12'd2587 : mem_out_dec = 6'b111111;
12'd2588 : mem_out_dec = 6'b111111;
12'd2589 : mem_out_dec = 6'b111111;
12'd2590 : mem_out_dec = 6'b111111;
12'd2591 : mem_out_dec = 6'b111111;
12'd2592 : mem_out_dec = 6'b111111;
12'd2593 : mem_out_dec = 6'b111111;
12'd2594 : mem_out_dec = 6'b111111;
12'd2595 : mem_out_dec = 6'b111111;
12'd2596 : mem_out_dec = 6'b111111;
12'd2597 : mem_out_dec = 6'b111111;
12'd2598 : mem_out_dec = 6'b111111;
12'd2599 : mem_out_dec = 6'b111111;
12'd2600 : mem_out_dec = 6'b111111;
12'd2601 : mem_out_dec = 6'b111111;
12'd2602 : mem_out_dec = 6'b111111;
12'd2603 : mem_out_dec = 6'b111111;
12'd2604 : mem_out_dec = 6'b111111;
12'd2605 : mem_out_dec = 6'b111111;
12'd2606 : mem_out_dec = 6'b000100;
12'd2607 : mem_out_dec = 6'b000101;
12'd2608 : mem_out_dec = 6'b000100;
12'd2609 : mem_out_dec = 6'b000100;
12'd2610 : mem_out_dec = 6'b000100;
12'd2611 : mem_out_dec = 6'b000101;
12'd2612 : mem_out_dec = 6'b000101;
12'd2613 : mem_out_dec = 6'b000110;
12'd2614 : mem_out_dec = 6'b000111;
12'd2615 : mem_out_dec = 6'b000111;
12'd2616 : mem_out_dec = 6'b000111;
12'd2617 : mem_out_dec = 6'b001000;
12'd2618 : mem_out_dec = 6'b001001;
12'd2619 : mem_out_dec = 6'b001010;
12'd2620 : mem_out_dec = 6'b001010;
12'd2621 : mem_out_dec = 6'b001011;
12'd2622 : mem_out_dec = 6'b001100;
12'd2623 : mem_out_dec = 6'b001101;
12'd2624 : mem_out_dec = 6'b111111;
12'd2625 : mem_out_dec = 6'b111111;
12'd2626 : mem_out_dec = 6'b111111;
12'd2627 : mem_out_dec = 6'b111111;
12'd2628 : mem_out_dec = 6'b111111;
12'd2629 : mem_out_dec = 6'b111111;
12'd2630 : mem_out_dec = 6'b111111;
12'd2631 : mem_out_dec = 6'b111111;
12'd2632 : mem_out_dec = 6'b111111;
12'd2633 : mem_out_dec = 6'b111111;
12'd2634 : mem_out_dec = 6'b111111;
12'd2635 : mem_out_dec = 6'b111111;
12'd2636 : mem_out_dec = 6'b111111;
12'd2637 : mem_out_dec = 6'b111111;
12'd2638 : mem_out_dec = 6'b111111;
12'd2639 : mem_out_dec = 6'b111111;
12'd2640 : mem_out_dec = 6'b111111;
12'd2641 : mem_out_dec = 6'b111111;
12'd2642 : mem_out_dec = 6'b111111;
12'd2643 : mem_out_dec = 6'b111111;
12'd2644 : mem_out_dec = 6'b111111;
12'd2645 : mem_out_dec = 6'b111111;
12'd2646 : mem_out_dec = 6'b111111;
12'd2647 : mem_out_dec = 6'b111111;
12'd2648 : mem_out_dec = 6'b111111;
12'd2649 : mem_out_dec = 6'b111111;
12'd2650 : mem_out_dec = 6'b111111;
12'd2651 : mem_out_dec = 6'b111111;
12'd2652 : mem_out_dec = 6'b111111;
12'd2653 : mem_out_dec = 6'b111111;
12'd2654 : mem_out_dec = 6'b111111;
12'd2655 : mem_out_dec = 6'b111111;
12'd2656 : mem_out_dec = 6'b111111;
12'd2657 : mem_out_dec = 6'b111111;
12'd2658 : mem_out_dec = 6'b111111;
12'd2659 : mem_out_dec = 6'b111111;
12'd2660 : mem_out_dec = 6'b111111;
12'd2661 : mem_out_dec = 6'b111111;
12'd2662 : mem_out_dec = 6'b111111;
12'd2663 : mem_out_dec = 6'b111111;
12'd2664 : mem_out_dec = 6'b111111;
12'd2665 : mem_out_dec = 6'b111111;
12'd2666 : mem_out_dec = 6'b111111;
12'd2667 : mem_out_dec = 6'b111111;
12'd2668 : mem_out_dec = 6'b111111;
12'd2669 : mem_out_dec = 6'b111111;
12'd2670 : mem_out_dec = 6'b111111;
12'd2671 : mem_out_dec = 6'b000100;
12'd2672 : mem_out_dec = 6'b000011;
12'd2673 : mem_out_dec = 6'b000011;
12'd2674 : mem_out_dec = 6'b000100;
12'd2675 : mem_out_dec = 6'b000100;
12'd2676 : mem_out_dec = 6'b000101;
12'd2677 : mem_out_dec = 6'b000110;
12'd2678 : mem_out_dec = 6'b000110;
12'd2679 : mem_out_dec = 6'b000111;
12'd2680 : mem_out_dec = 6'b000111;
12'd2681 : mem_out_dec = 6'b001000;
12'd2682 : mem_out_dec = 6'b001001;
12'd2683 : mem_out_dec = 6'b001001;
12'd2684 : mem_out_dec = 6'b001010;
12'd2685 : mem_out_dec = 6'b001011;
12'd2686 : mem_out_dec = 6'b001100;
12'd2687 : mem_out_dec = 6'b001100;
12'd2688 : mem_out_dec = 6'b111111;
12'd2689 : mem_out_dec = 6'b111111;
12'd2690 : mem_out_dec = 6'b111111;
12'd2691 : mem_out_dec = 6'b111111;
12'd2692 : mem_out_dec = 6'b111111;
12'd2693 : mem_out_dec = 6'b111111;
12'd2694 : mem_out_dec = 6'b111111;
12'd2695 : mem_out_dec = 6'b111111;
12'd2696 : mem_out_dec = 6'b111111;
12'd2697 : mem_out_dec = 6'b111111;
12'd2698 : mem_out_dec = 6'b111111;
12'd2699 : mem_out_dec = 6'b111111;
12'd2700 : mem_out_dec = 6'b111111;
12'd2701 : mem_out_dec = 6'b111111;
12'd2702 : mem_out_dec = 6'b111111;
12'd2703 : mem_out_dec = 6'b111111;
12'd2704 : mem_out_dec = 6'b111111;
12'd2705 : mem_out_dec = 6'b111111;
12'd2706 : mem_out_dec = 6'b111111;
12'd2707 : mem_out_dec = 6'b111111;
12'd2708 : mem_out_dec = 6'b111111;
12'd2709 : mem_out_dec = 6'b111111;
12'd2710 : mem_out_dec = 6'b111111;
12'd2711 : mem_out_dec = 6'b111111;
12'd2712 : mem_out_dec = 6'b111111;
12'd2713 : mem_out_dec = 6'b111111;
12'd2714 : mem_out_dec = 6'b111111;
12'd2715 : mem_out_dec = 6'b111111;
12'd2716 : mem_out_dec = 6'b111111;
12'd2717 : mem_out_dec = 6'b111111;
12'd2718 : mem_out_dec = 6'b111111;
12'd2719 : mem_out_dec = 6'b111111;
12'd2720 : mem_out_dec = 6'b111111;
12'd2721 : mem_out_dec = 6'b111111;
12'd2722 : mem_out_dec = 6'b111111;
12'd2723 : mem_out_dec = 6'b111111;
12'd2724 : mem_out_dec = 6'b111111;
12'd2725 : mem_out_dec = 6'b111111;
12'd2726 : mem_out_dec = 6'b111111;
12'd2727 : mem_out_dec = 6'b111111;
12'd2728 : mem_out_dec = 6'b111111;
12'd2729 : mem_out_dec = 6'b111111;
12'd2730 : mem_out_dec = 6'b111111;
12'd2731 : mem_out_dec = 6'b111111;
12'd2732 : mem_out_dec = 6'b111111;
12'd2733 : mem_out_dec = 6'b111111;
12'd2734 : mem_out_dec = 6'b111111;
12'd2735 : mem_out_dec = 6'b111111;
12'd2736 : mem_out_dec = 6'b000011;
12'd2737 : mem_out_dec = 6'b000011;
12'd2738 : mem_out_dec = 6'b000100;
12'd2739 : mem_out_dec = 6'b000100;
12'd2740 : mem_out_dec = 6'b000101;
12'd2741 : mem_out_dec = 6'b000101;
12'd2742 : mem_out_dec = 6'b000110;
12'd2743 : mem_out_dec = 6'b000111;
12'd2744 : mem_out_dec = 6'b000111;
12'd2745 : mem_out_dec = 6'b001000;
12'd2746 : mem_out_dec = 6'b001000;
12'd2747 : mem_out_dec = 6'b001001;
12'd2748 : mem_out_dec = 6'b001010;
12'd2749 : mem_out_dec = 6'b001011;
12'd2750 : mem_out_dec = 6'b001011;
12'd2751 : mem_out_dec = 6'b001100;
12'd2752 : mem_out_dec = 6'b111111;
12'd2753 : mem_out_dec = 6'b111111;
12'd2754 : mem_out_dec = 6'b111111;
12'd2755 : mem_out_dec = 6'b111111;
12'd2756 : mem_out_dec = 6'b111111;
12'd2757 : mem_out_dec = 6'b111111;
12'd2758 : mem_out_dec = 6'b111111;
12'd2759 : mem_out_dec = 6'b111111;
12'd2760 : mem_out_dec = 6'b111111;
12'd2761 : mem_out_dec = 6'b111111;
12'd2762 : mem_out_dec = 6'b111111;
12'd2763 : mem_out_dec = 6'b111111;
12'd2764 : mem_out_dec = 6'b111111;
12'd2765 : mem_out_dec = 6'b111111;
12'd2766 : mem_out_dec = 6'b111111;
12'd2767 : mem_out_dec = 6'b111111;
12'd2768 : mem_out_dec = 6'b111111;
12'd2769 : mem_out_dec = 6'b111111;
12'd2770 : mem_out_dec = 6'b111111;
12'd2771 : mem_out_dec = 6'b111111;
12'd2772 : mem_out_dec = 6'b111111;
12'd2773 : mem_out_dec = 6'b111111;
12'd2774 : mem_out_dec = 6'b111111;
12'd2775 : mem_out_dec = 6'b111111;
12'd2776 : mem_out_dec = 6'b111111;
12'd2777 : mem_out_dec = 6'b111111;
12'd2778 : mem_out_dec = 6'b111111;
12'd2779 : mem_out_dec = 6'b111111;
12'd2780 : mem_out_dec = 6'b111111;
12'd2781 : mem_out_dec = 6'b111111;
12'd2782 : mem_out_dec = 6'b111111;
12'd2783 : mem_out_dec = 6'b111111;
12'd2784 : mem_out_dec = 6'b111111;
12'd2785 : mem_out_dec = 6'b111111;
12'd2786 : mem_out_dec = 6'b111111;
12'd2787 : mem_out_dec = 6'b111111;
12'd2788 : mem_out_dec = 6'b111111;
12'd2789 : mem_out_dec = 6'b111111;
12'd2790 : mem_out_dec = 6'b111111;
12'd2791 : mem_out_dec = 6'b111111;
12'd2792 : mem_out_dec = 6'b111111;
12'd2793 : mem_out_dec = 6'b111111;
12'd2794 : mem_out_dec = 6'b111111;
12'd2795 : mem_out_dec = 6'b111111;
12'd2796 : mem_out_dec = 6'b111111;
12'd2797 : mem_out_dec = 6'b111111;
12'd2798 : mem_out_dec = 6'b111111;
12'd2799 : mem_out_dec = 6'b111111;
12'd2800 : mem_out_dec = 6'b111111;
12'd2801 : mem_out_dec = 6'b000011;
12'd2802 : mem_out_dec = 6'b000011;
12'd2803 : mem_out_dec = 6'b000100;
12'd2804 : mem_out_dec = 6'b000101;
12'd2805 : mem_out_dec = 6'b000101;
12'd2806 : mem_out_dec = 6'b000110;
12'd2807 : mem_out_dec = 6'b000111;
12'd2808 : mem_out_dec = 6'b000111;
12'd2809 : mem_out_dec = 6'b000111;
12'd2810 : mem_out_dec = 6'b001000;
12'd2811 : mem_out_dec = 6'b001001;
12'd2812 : mem_out_dec = 6'b001010;
12'd2813 : mem_out_dec = 6'b001010;
12'd2814 : mem_out_dec = 6'b001011;
12'd2815 : mem_out_dec = 6'b001100;
12'd2816 : mem_out_dec = 6'b111111;
12'd2817 : mem_out_dec = 6'b111111;
12'd2818 : mem_out_dec = 6'b111111;
12'd2819 : mem_out_dec = 6'b111111;
12'd2820 : mem_out_dec = 6'b111111;
12'd2821 : mem_out_dec = 6'b111111;
12'd2822 : mem_out_dec = 6'b111111;
12'd2823 : mem_out_dec = 6'b111111;
12'd2824 : mem_out_dec = 6'b111111;
12'd2825 : mem_out_dec = 6'b111111;
12'd2826 : mem_out_dec = 6'b111111;
12'd2827 : mem_out_dec = 6'b111111;
12'd2828 : mem_out_dec = 6'b111111;
12'd2829 : mem_out_dec = 6'b111111;
12'd2830 : mem_out_dec = 6'b111111;
12'd2831 : mem_out_dec = 6'b111111;
12'd2832 : mem_out_dec = 6'b111111;
12'd2833 : mem_out_dec = 6'b111111;
12'd2834 : mem_out_dec = 6'b111111;
12'd2835 : mem_out_dec = 6'b111111;
12'd2836 : mem_out_dec = 6'b111111;
12'd2837 : mem_out_dec = 6'b111111;
12'd2838 : mem_out_dec = 6'b111111;
12'd2839 : mem_out_dec = 6'b111111;
12'd2840 : mem_out_dec = 6'b111111;
12'd2841 : mem_out_dec = 6'b111111;
12'd2842 : mem_out_dec = 6'b111111;
12'd2843 : mem_out_dec = 6'b111111;
12'd2844 : mem_out_dec = 6'b111111;
12'd2845 : mem_out_dec = 6'b111111;
12'd2846 : mem_out_dec = 6'b111111;
12'd2847 : mem_out_dec = 6'b111111;
12'd2848 : mem_out_dec = 6'b111111;
12'd2849 : mem_out_dec = 6'b111111;
12'd2850 : mem_out_dec = 6'b111111;
12'd2851 : mem_out_dec = 6'b111111;
12'd2852 : mem_out_dec = 6'b111111;
12'd2853 : mem_out_dec = 6'b111111;
12'd2854 : mem_out_dec = 6'b111111;
12'd2855 : mem_out_dec = 6'b111111;
12'd2856 : mem_out_dec = 6'b111111;
12'd2857 : mem_out_dec = 6'b111111;
12'd2858 : mem_out_dec = 6'b111111;
12'd2859 : mem_out_dec = 6'b111111;
12'd2860 : mem_out_dec = 6'b111111;
12'd2861 : mem_out_dec = 6'b111111;
12'd2862 : mem_out_dec = 6'b111111;
12'd2863 : mem_out_dec = 6'b111111;
12'd2864 : mem_out_dec = 6'b111111;
12'd2865 : mem_out_dec = 6'b111111;
12'd2866 : mem_out_dec = 6'b000011;
12'd2867 : mem_out_dec = 6'b000100;
12'd2868 : mem_out_dec = 6'b000100;
12'd2869 : mem_out_dec = 6'b000101;
12'd2870 : mem_out_dec = 6'b000110;
12'd2871 : mem_out_dec = 6'b000110;
12'd2872 : mem_out_dec = 6'b000110;
12'd2873 : mem_out_dec = 6'b000111;
12'd2874 : mem_out_dec = 6'b001000;
12'd2875 : mem_out_dec = 6'b001001;
12'd2876 : mem_out_dec = 6'b001001;
12'd2877 : mem_out_dec = 6'b001010;
12'd2878 : mem_out_dec = 6'b001011;
12'd2879 : mem_out_dec = 6'b001100;
12'd2880 : mem_out_dec = 6'b111111;
12'd2881 : mem_out_dec = 6'b111111;
12'd2882 : mem_out_dec = 6'b111111;
12'd2883 : mem_out_dec = 6'b111111;
12'd2884 : mem_out_dec = 6'b111111;
12'd2885 : mem_out_dec = 6'b111111;
12'd2886 : mem_out_dec = 6'b111111;
12'd2887 : mem_out_dec = 6'b111111;
12'd2888 : mem_out_dec = 6'b111111;
12'd2889 : mem_out_dec = 6'b111111;
12'd2890 : mem_out_dec = 6'b111111;
12'd2891 : mem_out_dec = 6'b111111;
12'd2892 : mem_out_dec = 6'b111111;
12'd2893 : mem_out_dec = 6'b111111;
12'd2894 : mem_out_dec = 6'b111111;
12'd2895 : mem_out_dec = 6'b111111;
12'd2896 : mem_out_dec = 6'b111111;
12'd2897 : mem_out_dec = 6'b111111;
12'd2898 : mem_out_dec = 6'b111111;
12'd2899 : mem_out_dec = 6'b111111;
12'd2900 : mem_out_dec = 6'b111111;
12'd2901 : mem_out_dec = 6'b111111;
12'd2902 : mem_out_dec = 6'b111111;
12'd2903 : mem_out_dec = 6'b111111;
12'd2904 : mem_out_dec = 6'b111111;
12'd2905 : mem_out_dec = 6'b111111;
12'd2906 : mem_out_dec = 6'b111111;
12'd2907 : mem_out_dec = 6'b111111;
12'd2908 : mem_out_dec = 6'b111111;
12'd2909 : mem_out_dec = 6'b111111;
12'd2910 : mem_out_dec = 6'b111111;
12'd2911 : mem_out_dec = 6'b111111;
12'd2912 : mem_out_dec = 6'b111111;
12'd2913 : mem_out_dec = 6'b111111;
12'd2914 : mem_out_dec = 6'b111111;
12'd2915 : mem_out_dec = 6'b111111;
12'd2916 : mem_out_dec = 6'b111111;
12'd2917 : mem_out_dec = 6'b111111;
12'd2918 : mem_out_dec = 6'b111111;
12'd2919 : mem_out_dec = 6'b111111;
12'd2920 : mem_out_dec = 6'b111111;
12'd2921 : mem_out_dec = 6'b111111;
12'd2922 : mem_out_dec = 6'b111111;
12'd2923 : mem_out_dec = 6'b111111;
12'd2924 : mem_out_dec = 6'b111111;
12'd2925 : mem_out_dec = 6'b111111;
12'd2926 : mem_out_dec = 6'b111111;
12'd2927 : mem_out_dec = 6'b111111;
12'd2928 : mem_out_dec = 6'b111111;
12'd2929 : mem_out_dec = 6'b111111;
12'd2930 : mem_out_dec = 6'b111111;
12'd2931 : mem_out_dec = 6'b000100;
12'd2932 : mem_out_dec = 6'b000100;
12'd2933 : mem_out_dec = 6'b000101;
12'd2934 : mem_out_dec = 6'b000101;
12'd2935 : mem_out_dec = 6'b000110;
12'd2936 : mem_out_dec = 6'b000110;
12'd2937 : mem_out_dec = 6'b000111;
12'd2938 : mem_out_dec = 6'b001000;
12'd2939 : mem_out_dec = 6'b001000;
12'd2940 : mem_out_dec = 6'b001001;
12'd2941 : mem_out_dec = 6'b001010;
12'd2942 : mem_out_dec = 6'b001011;
12'd2943 : mem_out_dec = 6'b001011;
12'd2944 : mem_out_dec = 6'b111111;
12'd2945 : mem_out_dec = 6'b111111;
12'd2946 : mem_out_dec = 6'b111111;
12'd2947 : mem_out_dec = 6'b111111;
12'd2948 : mem_out_dec = 6'b111111;
12'd2949 : mem_out_dec = 6'b111111;
12'd2950 : mem_out_dec = 6'b111111;
12'd2951 : mem_out_dec = 6'b111111;
12'd2952 : mem_out_dec = 6'b111111;
12'd2953 : mem_out_dec = 6'b111111;
12'd2954 : mem_out_dec = 6'b111111;
12'd2955 : mem_out_dec = 6'b111111;
12'd2956 : mem_out_dec = 6'b111111;
12'd2957 : mem_out_dec = 6'b111111;
12'd2958 : mem_out_dec = 6'b111111;
12'd2959 : mem_out_dec = 6'b111111;
12'd2960 : mem_out_dec = 6'b111111;
12'd2961 : mem_out_dec = 6'b111111;
12'd2962 : mem_out_dec = 6'b111111;
12'd2963 : mem_out_dec = 6'b111111;
12'd2964 : mem_out_dec = 6'b111111;
12'd2965 : mem_out_dec = 6'b111111;
12'd2966 : mem_out_dec = 6'b111111;
12'd2967 : mem_out_dec = 6'b111111;
12'd2968 : mem_out_dec = 6'b111111;
12'd2969 : mem_out_dec = 6'b111111;
12'd2970 : mem_out_dec = 6'b111111;
12'd2971 : mem_out_dec = 6'b111111;
12'd2972 : mem_out_dec = 6'b111111;
12'd2973 : mem_out_dec = 6'b111111;
12'd2974 : mem_out_dec = 6'b111111;
12'd2975 : mem_out_dec = 6'b111111;
12'd2976 : mem_out_dec = 6'b111111;
12'd2977 : mem_out_dec = 6'b111111;
12'd2978 : mem_out_dec = 6'b111111;
12'd2979 : mem_out_dec = 6'b111111;
12'd2980 : mem_out_dec = 6'b111111;
12'd2981 : mem_out_dec = 6'b111111;
12'd2982 : mem_out_dec = 6'b111111;
12'd2983 : mem_out_dec = 6'b111111;
12'd2984 : mem_out_dec = 6'b111111;
12'd2985 : mem_out_dec = 6'b111111;
12'd2986 : mem_out_dec = 6'b111111;
12'd2987 : mem_out_dec = 6'b111111;
12'd2988 : mem_out_dec = 6'b111111;
12'd2989 : mem_out_dec = 6'b111111;
12'd2990 : mem_out_dec = 6'b111111;
12'd2991 : mem_out_dec = 6'b111111;
12'd2992 : mem_out_dec = 6'b111111;
12'd2993 : mem_out_dec = 6'b111111;
12'd2994 : mem_out_dec = 6'b111111;
12'd2995 : mem_out_dec = 6'b111111;
12'd2996 : mem_out_dec = 6'b000100;
12'd2997 : mem_out_dec = 6'b000101;
12'd2998 : mem_out_dec = 6'b000101;
12'd2999 : mem_out_dec = 6'b000110;
12'd3000 : mem_out_dec = 6'b000110;
12'd3001 : mem_out_dec = 6'b000111;
12'd3002 : mem_out_dec = 6'b000111;
12'd3003 : mem_out_dec = 6'b001000;
12'd3004 : mem_out_dec = 6'b001001;
12'd3005 : mem_out_dec = 6'b001010;
12'd3006 : mem_out_dec = 6'b001010;
12'd3007 : mem_out_dec = 6'b001011;
12'd3008 : mem_out_dec = 6'b111111;
12'd3009 : mem_out_dec = 6'b111111;
12'd3010 : mem_out_dec = 6'b111111;
12'd3011 : mem_out_dec = 6'b111111;
12'd3012 : mem_out_dec = 6'b111111;
12'd3013 : mem_out_dec = 6'b111111;
12'd3014 : mem_out_dec = 6'b111111;
12'd3015 : mem_out_dec = 6'b111111;
12'd3016 : mem_out_dec = 6'b111111;
12'd3017 : mem_out_dec = 6'b111111;
12'd3018 : mem_out_dec = 6'b111111;
12'd3019 : mem_out_dec = 6'b111111;
12'd3020 : mem_out_dec = 6'b111111;
12'd3021 : mem_out_dec = 6'b111111;
12'd3022 : mem_out_dec = 6'b111111;
12'd3023 : mem_out_dec = 6'b111111;
12'd3024 : mem_out_dec = 6'b111111;
12'd3025 : mem_out_dec = 6'b111111;
12'd3026 : mem_out_dec = 6'b111111;
12'd3027 : mem_out_dec = 6'b111111;
12'd3028 : mem_out_dec = 6'b111111;
12'd3029 : mem_out_dec = 6'b111111;
12'd3030 : mem_out_dec = 6'b111111;
12'd3031 : mem_out_dec = 6'b111111;
12'd3032 : mem_out_dec = 6'b111111;
12'd3033 : mem_out_dec = 6'b111111;
12'd3034 : mem_out_dec = 6'b111111;
12'd3035 : mem_out_dec = 6'b111111;
12'd3036 : mem_out_dec = 6'b111111;
12'd3037 : mem_out_dec = 6'b111111;
12'd3038 : mem_out_dec = 6'b111111;
12'd3039 : mem_out_dec = 6'b111111;
12'd3040 : mem_out_dec = 6'b111111;
12'd3041 : mem_out_dec = 6'b111111;
12'd3042 : mem_out_dec = 6'b111111;
12'd3043 : mem_out_dec = 6'b111111;
12'd3044 : mem_out_dec = 6'b111111;
12'd3045 : mem_out_dec = 6'b111111;
12'd3046 : mem_out_dec = 6'b111111;
12'd3047 : mem_out_dec = 6'b111111;
12'd3048 : mem_out_dec = 6'b111111;
12'd3049 : mem_out_dec = 6'b111111;
12'd3050 : mem_out_dec = 6'b111111;
12'd3051 : mem_out_dec = 6'b111111;
12'd3052 : mem_out_dec = 6'b111111;
12'd3053 : mem_out_dec = 6'b111111;
12'd3054 : mem_out_dec = 6'b111111;
12'd3055 : mem_out_dec = 6'b111111;
12'd3056 : mem_out_dec = 6'b111111;
12'd3057 : mem_out_dec = 6'b111111;
12'd3058 : mem_out_dec = 6'b111111;
12'd3059 : mem_out_dec = 6'b111111;
12'd3060 : mem_out_dec = 6'b111111;
12'd3061 : mem_out_dec = 6'b000100;
12'd3062 : mem_out_dec = 6'b000101;
12'd3063 : mem_out_dec = 6'b000110;
12'd3064 : mem_out_dec = 6'b000110;
12'd3065 : mem_out_dec = 6'b000111;
12'd3066 : mem_out_dec = 6'b000111;
12'd3067 : mem_out_dec = 6'b001000;
12'd3068 : mem_out_dec = 6'b001001;
12'd3069 : mem_out_dec = 6'b001001;
12'd3070 : mem_out_dec = 6'b001010;
12'd3071 : mem_out_dec = 6'b001011;
12'd3072 : mem_out_dec = 6'b111111;
12'd3073 : mem_out_dec = 6'b111111;
12'd3074 : mem_out_dec = 6'b111111;
12'd3075 : mem_out_dec = 6'b111111;
12'd3076 : mem_out_dec = 6'b111111;
12'd3077 : mem_out_dec = 6'b111111;
12'd3078 : mem_out_dec = 6'b111111;
12'd3079 : mem_out_dec = 6'b111111;
12'd3080 : mem_out_dec = 6'b111111;
12'd3081 : mem_out_dec = 6'b111111;
12'd3082 : mem_out_dec = 6'b111111;
12'd3083 : mem_out_dec = 6'b111111;
12'd3084 : mem_out_dec = 6'b111111;
12'd3085 : mem_out_dec = 6'b111111;
12'd3086 : mem_out_dec = 6'b111111;
12'd3087 : mem_out_dec = 6'b111111;
12'd3088 : mem_out_dec = 6'b111111;
12'd3089 : mem_out_dec = 6'b111111;
12'd3090 : mem_out_dec = 6'b111111;
12'd3091 : mem_out_dec = 6'b111111;
12'd3092 : mem_out_dec = 6'b111111;
12'd3093 : mem_out_dec = 6'b111111;
12'd3094 : mem_out_dec = 6'b111111;
12'd3095 : mem_out_dec = 6'b111111;
12'd3096 : mem_out_dec = 6'b111111;
12'd3097 : mem_out_dec = 6'b111111;
12'd3098 : mem_out_dec = 6'b111111;
12'd3099 : mem_out_dec = 6'b111111;
12'd3100 : mem_out_dec = 6'b111111;
12'd3101 : mem_out_dec = 6'b111111;
12'd3102 : mem_out_dec = 6'b111111;
12'd3103 : mem_out_dec = 6'b111111;
12'd3104 : mem_out_dec = 6'b111111;
12'd3105 : mem_out_dec = 6'b111111;
12'd3106 : mem_out_dec = 6'b111111;
12'd3107 : mem_out_dec = 6'b111111;
12'd3108 : mem_out_dec = 6'b111111;
12'd3109 : mem_out_dec = 6'b111111;
12'd3110 : mem_out_dec = 6'b111111;
12'd3111 : mem_out_dec = 6'b111111;
12'd3112 : mem_out_dec = 6'b111111;
12'd3113 : mem_out_dec = 6'b111111;
12'd3114 : mem_out_dec = 6'b111111;
12'd3115 : mem_out_dec = 6'b111111;
12'd3116 : mem_out_dec = 6'b111111;
12'd3117 : mem_out_dec = 6'b111111;
12'd3118 : mem_out_dec = 6'b111111;
12'd3119 : mem_out_dec = 6'b111111;
12'd3120 : mem_out_dec = 6'b111111;
12'd3121 : mem_out_dec = 6'b111111;
12'd3122 : mem_out_dec = 6'b111111;
12'd3123 : mem_out_dec = 6'b111111;
12'd3124 : mem_out_dec = 6'b111111;
12'd3125 : mem_out_dec = 6'b111111;
12'd3126 : mem_out_dec = 6'b000100;
12'd3127 : mem_out_dec = 6'b000101;
12'd3128 : mem_out_dec = 6'b000101;
12'd3129 : mem_out_dec = 6'b000110;
12'd3130 : mem_out_dec = 6'b000110;
12'd3131 : mem_out_dec = 6'b000111;
12'd3132 : mem_out_dec = 6'b001000;
12'd3133 : mem_out_dec = 6'b001000;
12'd3134 : mem_out_dec = 6'b001001;
12'd3135 : mem_out_dec = 6'b001010;
12'd3136 : mem_out_dec = 6'b111111;
12'd3137 : mem_out_dec = 6'b111111;
12'd3138 : mem_out_dec = 6'b111111;
12'd3139 : mem_out_dec = 6'b111111;
12'd3140 : mem_out_dec = 6'b111111;
12'd3141 : mem_out_dec = 6'b111111;
12'd3142 : mem_out_dec = 6'b111111;
12'd3143 : mem_out_dec = 6'b111111;
12'd3144 : mem_out_dec = 6'b111111;
12'd3145 : mem_out_dec = 6'b111111;
12'd3146 : mem_out_dec = 6'b111111;
12'd3147 : mem_out_dec = 6'b111111;
12'd3148 : mem_out_dec = 6'b111111;
12'd3149 : mem_out_dec = 6'b111111;
12'd3150 : mem_out_dec = 6'b111111;
12'd3151 : mem_out_dec = 6'b111111;
12'd3152 : mem_out_dec = 6'b111111;
12'd3153 : mem_out_dec = 6'b111111;
12'd3154 : mem_out_dec = 6'b111111;
12'd3155 : mem_out_dec = 6'b111111;
12'd3156 : mem_out_dec = 6'b111111;
12'd3157 : mem_out_dec = 6'b111111;
12'd3158 : mem_out_dec = 6'b111111;
12'd3159 : mem_out_dec = 6'b111111;
12'd3160 : mem_out_dec = 6'b111111;
12'd3161 : mem_out_dec = 6'b111111;
12'd3162 : mem_out_dec = 6'b111111;
12'd3163 : mem_out_dec = 6'b111111;
12'd3164 : mem_out_dec = 6'b111111;
12'd3165 : mem_out_dec = 6'b111111;
12'd3166 : mem_out_dec = 6'b111111;
12'd3167 : mem_out_dec = 6'b111111;
12'd3168 : mem_out_dec = 6'b111111;
12'd3169 : mem_out_dec = 6'b111111;
12'd3170 : mem_out_dec = 6'b111111;
12'd3171 : mem_out_dec = 6'b111111;
12'd3172 : mem_out_dec = 6'b111111;
12'd3173 : mem_out_dec = 6'b111111;
12'd3174 : mem_out_dec = 6'b111111;
12'd3175 : mem_out_dec = 6'b111111;
12'd3176 : mem_out_dec = 6'b111111;
12'd3177 : mem_out_dec = 6'b111111;
12'd3178 : mem_out_dec = 6'b111111;
12'd3179 : mem_out_dec = 6'b111111;
12'd3180 : mem_out_dec = 6'b111111;
12'd3181 : mem_out_dec = 6'b111111;
12'd3182 : mem_out_dec = 6'b111111;
12'd3183 : mem_out_dec = 6'b111111;
12'd3184 : mem_out_dec = 6'b111111;
12'd3185 : mem_out_dec = 6'b111111;
12'd3186 : mem_out_dec = 6'b111111;
12'd3187 : mem_out_dec = 6'b111111;
12'd3188 : mem_out_dec = 6'b111111;
12'd3189 : mem_out_dec = 6'b111111;
12'd3190 : mem_out_dec = 6'b111111;
12'd3191 : mem_out_dec = 6'b000100;
12'd3192 : mem_out_dec = 6'b000100;
12'd3193 : mem_out_dec = 6'b000101;
12'd3194 : mem_out_dec = 6'b000110;
12'd3195 : mem_out_dec = 6'b000110;
12'd3196 : mem_out_dec = 6'b000111;
12'd3197 : mem_out_dec = 6'b001000;
12'd3198 : mem_out_dec = 6'b001000;
12'd3199 : mem_out_dec = 6'b001001;
12'd3200 : mem_out_dec = 6'b111111;
12'd3201 : mem_out_dec = 6'b111111;
12'd3202 : mem_out_dec = 6'b111111;
12'd3203 : mem_out_dec = 6'b111111;
12'd3204 : mem_out_dec = 6'b111111;
12'd3205 : mem_out_dec = 6'b111111;
12'd3206 : mem_out_dec = 6'b111111;
12'd3207 : mem_out_dec = 6'b111111;
12'd3208 : mem_out_dec = 6'b111111;
12'd3209 : mem_out_dec = 6'b111111;
12'd3210 : mem_out_dec = 6'b111111;
12'd3211 : mem_out_dec = 6'b111111;
12'd3212 : mem_out_dec = 6'b111111;
12'd3213 : mem_out_dec = 6'b111111;
12'd3214 : mem_out_dec = 6'b111111;
12'd3215 : mem_out_dec = 6'b111111;
12'd3216 : mem_out_dec = 6'b111111;
12'd3217 : mem_out_dec = 6'b111111;
12'd3218 : mem_out_dec = 6'b111111;
12'd3219 : mem_out_dec = 6'b111111;
12'd3220 : mem_out_dec = 6'b111111;
12'd3221 : mem_out_dec = 6'b111111;
12'd3222 : mem_out_dec = 6'b111111;
12'd3223 : mem_out_dec = 6'b111111;
12'd3224 : mem_out_dec = 6'b111111;
12'd3225 : mem_out_dec = 6'b111111;
12'd3226 : mem_out_dec = 6'b111111;
12'd3227 : mem_out_dec = 6'b111111;
12'd3228 : mem_out_dec = 6'b111111;
12'd3229 : mem_out_dec = 6'b111111;
12'd3230 : mem_out_dec = 6'b111111;
12'd3231 : mem_out_dec = 6'b111111;
12'd3232 : mem_out_dec = 6'b111111;
12'd3233 : mem_out_dec = 6'b111111;
12'd3234 : mem_out_dec = 6'b111111;
12'd3235 : mem_out_dec = 6'b111111;
12'd3236 : mem_out_dec = 6'b111111;
12'd3237 : mem_out_dec = 6'b111111;
12'd3238 : mem_out_dec = 6'b111111;
12'd3239 : mem_out_dec = 6'b111111;
12'd3240 : mem_out_dec = 6'b111111;
12'd3241 : mem_out_dec = 6'b111111;
12'd3242 : mem_out_dec = 6'b111111;
12'd3243 : mem_out_dec = 6'b111111;
12'd3244 : mem_out_dec = 6'b111111;
12'd3245 : mem_out_dec = 6'b111111;
12'd3246 : mem_out_dec = 6'b111111;
12'd3247 : mem_out_dec = 6'b111111;
12'd3248 : mem_out_dec = 6'b111111;
12'd3249 : mem_out_dec = 6'b111111;
12'd3250 : mem_out_dec = 6'b111111;
12'd3251 : mem_out_dec = 6'b111111;
12'd3252 : mem_out_dec = 6'b111111;
12'd3253 : mem_out_dec = 6'b111111;
12'd3254 : mem_out_dec = 6'b111111;
12'd3255 : mem_out_dec = 6'b111111;
12'd3256 : mem_out_dec = 6'b000100;
12'd3257 : mem_out_dec = 6'b000100;
12'd3258 : mem_out_dec = 6'b000101;
12'd3259 : mem_out_dec = 6'b000110;
12'd3260 : mem_out_dec = 6'b000110;
12'd3261 : mem_out_dec = 6'b000111;
12'd3262 : mem_out_dec = 6'b001000;
12'd3263 : mem_out_dec = 6'b001001;
12'd3264 : mem_out_dec = 6'b111111;
12'd3265 : mem_out_dec = 6'b111111;
12'd3266 : mem_out_dec = 6'b111111;
12'd3267 : mem_out_dec = 6'b111111;
12'd3268 : mem_out_dec = 6'b111111;
12'd3269 : mem_out_dec = 6'b111111;
12'd3270 : mem_out_dec = 6'b111111;
12'd3271 : mem_out_dec = 6'b111111;
12'd3272 : mem_out_dec = 6'b111111;
12'd3273 : mem_out_dec = 6'b111111;
12'd3274 : mem_out_dec = 6'b111111;
12'd3275 : mem_out_dec = 6'b111111;
12'd3276 : mem_out_dec = 6'b111111;
12'd3277 : mem_out_dec = 6'b111111;
12'd3278 : mem_out_dec = 6'b111111;
12'd3279 : mem_out_dec = 6'b111111;
12'd3280 : mem_out_dec = 6'b111111;
12'd3281 : mem_out_dec = 6'b111111;
12'd3282 : mem_out_dec = 6'b111111;
12'd3283 : mem_out_dec = 6'b111111;
12'd3284 : mem_out_dec = 6'b111111;
12'd3285 : mem_out_dec = 6'b111111;
12'd3286 : mem_out_dec = 6'b111111;
12'd3287 : mem_out_dec = 6'b111111;
12'd3288 : mem_out_dec = 6'b111111;
12'd3289 : mem_out_dec = 6'b111111;
12'd3290 : mem_out_dec = 6'b111111;
12'd3291 : mem_out_dec = 6'b111111;
12'd3292 : mem_out_dec = 6'b111111;
12'd3293 : mem_out_dec = 6'b111111;
12'd3294 : mem_out_dec = 6'b111111;
12'd3295 : mem_out_dec = 6'b111111;
12'd3296 : mem_out_dec = 6'b111111;
12'd3297 : mem_out_dec = 6'b111111;
12'd3298 : mem_out_dec = 6'b111111;
12'd3299 : mem_out_dec = 6'b111111;
12'd3300 : mem_out_dec = 6'b111111;
12'd3301 : mem_out_dec = 6'b111111;
12'd3302 : mem_out_dec = 6'b111111;
12'd3303 : mem_out_dec = 6'b111111;
12'd3304 : mem_out_dec = 6'b111111;
12'd3305 : mem_out_dec = 6'b111111;
12'd3306 : mem_out_dec = 6'b111111;
12'd3307 : mem_out_dec = 6'b111111;
12'd3308 : mem_out_dec = 6'b111111;
12'd3309 : mem_out_dec = 6'b111111;
12'd3310 : mem_out_dec = 6'b111111;
12'd3311 : mem_out_dec = 6'b111111;
12'd3312 : mem_out_dec = 6'b111111;
12'd3313 : mem_out_dec = 6'b111111;
12'd3314 : mem_out_dec = 6'b111111;
12'd3315 : mem_out_dec = 6'b111111;
12'd3316 : mem_out_dec = 6'b111111;
12'd3317 : mem_out_dec = 6'b111111;
12'd3318 : mem_out_dec = 6'b111111;
12'd3319 : mem_out_dec = 6'b111111;
12'd3320 : mem_out_dec = 6'b111111;
12'd3321 : mem_out_dec = 6'b000100;
12'd3322 : mem_out_dec = 6'b000100;
12'd3323 : mem_out_dec = 6'b000101;
12'd3324 : mem_out_dec = 6'b000110;
12'd3325 : mem_out_dec = 6'b000111;
12'd3326 : mem_out_dec = 6'b001000;
12'd3327 : mem_out_dec = 6'b001000;
12'd3328 : mem_out_dec = 6'b111111;
12'd3329 : mem_out_dec = 6'b111111;
12'd3330 : mem_out_dec = 6'b111111;
12'd3331 : mem_out_dec = 6'b111111;
12'd3332 : mem_out_dec = 6'b111111;
12'd3333 : mem_out_dec = 6'b111111;
12'd3334 : mem_out_dec = 6'b111111;
12'd3335 : mem_out_dec = 6'b111111;
12'd3336 : mem_out_dec = 6'b111111;
12'd3337 : mem_out_dec = 6'b111111;
12'd3338 : mem_out_dec = 6'b111111;
12'd3339 : mem_out_dec = 6'b111111;
12'd3340 : mem_out_dec = 6'b111111;
12'd3341 : mem_out_dec = 6'b111111;
12'd3342 : mem_out_dec = 6'b111111;
12'd3343 : mem_out_dec = 6'b111111;
12'd3344 : mem_out_dec = 6'b111111;
12'd3345 : mem_out_dec = 6'b111111;
12'd3346 : mem_out_dec = 6'b111111;
12'd3347 : mem_out_dec = 6'b111111;
12'd3348 : mem_out_dec = 6'b111111;
12'd3349 : mem_out_dec = 6'b111111;
12'd3350 : mem_out_dec = 6'b111111;
12'd3351 : mem_out_dec = 6'b111111;
12'd3352 : mem_out_dec = 6'b111111;
12'd3353 : mem_out_dec = 6'b111111;
12'd3354 : mem_out_dec = 6'b111111;
12'd3355 : mem_out_dec = 6'b111111;
12'd3356 : mem_out_dec = 6'b111111;
12'd3357 : mem_out_dec = 6'b111111;
12'd3358 : mem_out_dec = 6'b111111;
12'd3359 : mem_out_dec = 6'b111111;
12'd3360 : mem_out_dec = 6'b111111;
12'd3361 : mem_out_dec = 6'b111111;
12'd3362 : mem_out_dec = 6'b111111;
12'd3363 : mem_out_dec = 6'b111111;
12'd3364 : mem_out_dec = 6'b111111;
12'd3365 : mem_out_dec = 6'b111111;
12'd3366 : mem_out_dec = 6'b111111;
12'd3367 : mem_out_dec = 6'b111111;
12'd3368 : mem_out_dec = 6'b111111;
12'd3369 : mem_out_dec = 6'b111111;
12'd3370 : mem_out_dec = 6'b111111;
12'd3371 : mem_out_dec = 6'b111111;
12'd3372 : mem_out_dec = 6'b111111;
12'd3373 : mem_out_dec = 6'b111111;
12'd3374 : mem_out_dec = 6'b111111;
12'd3375 : mem_out_dec = 6'b111111;
12'd3376 : mem_out_dec = 6'b111111;
12'd3377 : mem_out_dec = 6'b111111;
12'd3378 : mem_out_dec = 6'b111111;
12'd3379 : mem_out_dec = 6'b111111;
12'd3380 : mem_out_dec = 6'b111111;
12'd3381 : mem_out_dec = 6'b111111;
12'd3382 : mem_out_dec = 6'b111111;
12'd3383 : mem_out_dec = 6'b111111;
12'd3384 : mem_out_dec = 6'b111111;
12'd3385 : mem_out_dec = 6'b111111;
12'd3386 : mem_out_dec = 6'b000100;
12'd3387 : mem_out_dec = 6'b000101;
12'd3388 : mem_out_dec = 6'b000110;
12'd3389 : mem_out_dec = 6'b000110;
12'd3390 : mem_out_dec = 6'b000111;
12'd3391 : mem_out_dec = 6'b001000;
12'd3392 : mem_out_dec = 6'b111111;
12'd3393 : mem_out_dec = 6'b111111;
12'd3394 : mem_out_dec = 6'b111111;
12'd3395 : mem_out_dec = 6'b111111;
12'd3396 : mem_out_dec = 6'b111111;
12'd3397 : mem_out_dec = 6'b111111;
12'd3398 : mem_out_dec = 6'b111111;
12'd3399 : mem_out_dec = 6'b111111;
12'd3400 : mem_out_dec = 6'b111111;
12'd3401 : mem_out_dec = 6'b111111;
12'd3402 : mem_out_dec = 6'b111111;
12'd3403 : mem_out_dec = 6'b111111;
12'd3404 : mem_out_dec = 6'b111111;
12'd3405 : mem_out_dec = 6'b111111;
12'd3406 : mem_out_dec = 6'b111111;
12'd3407 : mem_out_dec = 6'b111111;
12'd3408 : mem_out_dec = 6'b111111;
12'd3409 : mem_out_dec = 6'b111111;
12'd3410 : mem_out_dec = 6'b111111;
12'd3411 : mem_out_dec = 6'b111111;
12'd3412 : mem_out_dec = 6'b111111;
12'd3413 : mem_out_dec = 6'b111111;
12'd3414 : mem_out_dec = 6'b111111;
12'd3415 : mem_out_dec = 6'b111111;
12'd3416 : mem_out_dec = 6'b111111;
12'd3417 : mem_out_dec = 6'b111111;
12'd3418 : mem_out_dec = 6'b111111;
12'd3419 : mem_out_dec = 6'b111111;
12'd3420 : mem_out_dec = 6'b111111;
12'd3421 : mem_out_dec = 6'b111111;
12'd3422 : mem_out_dec = 6'b111111;
12'd3423 : mem_out_dec = 6'b111111;
12'd3424 : mem_out_dec = 6'b111111;
12'd3425 : mem_out_dec = 6'b111111;
12'd3426 : mem_out_dec = 6'b111111;
12'd3427 : mem_out_dec = 6'b111111;
12'd3428 : mem_out_dec = 6'b111111;
12'd3429 : mem_out_dec = 6'b111111;
12'd3430 : mem_out_dec = 6'b111111;
12'd3431 : mem_out_dec = 6'b111111;
12'd3432 : mem_out_dec = 6'b111111;
12'd3433 : mem_out_dec = 6'b111111;
12'd3434 : mem_out_dec = 6'b111111;
12'd3435 : mem_out_dec = 6'b111111;
12'd3436 : mem_out_dec = 6'b111111;
12'd3437 : mem_out_dec = 6'b111111;
12'd3438 : mem_out_dec = 6'b111111;
12'd3439 : mem_out_dec = 6'b111111;
12'd3440 : mem_out_dec = 6'b111111;
12'd3441 : mem_out_dec = 6'b111111;
12'd3442 : mem_out_dec = 6'b111111;
12'd3443 : mem_out_dec = 6'b111111;
12'd3444 : mem_out_dec = 6'b111111;
12'd3445 : mem_out_dec = 6'b111111;
12'd3446 : mem_out_dec = 6'b111111;
12'd3447 : mem_out_dec = 6'b111111;
12'd3448 : mem_out_dec = 6'b111111;
12'd3449 : mem_out_dec = 6'b111111;
12'd3450 : mem_out_dec = 6'b111111;
12'd3451 : mem_out_dec = 6'b000100;
12'd3452 : mem_out_dec = 6'b000101;
12'd3453 : mem_out_dec = 6'b000110;
12'd3454 : mem_out_dec = 6'b000111;
12'd3455 : mem_out_dec = 6'b001000;
12'd3456 : mem_out_dec = 6'b111111;
12'd3457 : mem_out_dec = 6'b111111;
12'd3458 : mem_out_dec = 6'b111111;
12'd3459 : mem_out_dec = 6'b111111;
12'd3460 : mem_out_dec = 6'b111111;
12'd3461 : mem_out_dec = 6'b111111;
12'd3462 : mem_out_dec = 6'b111111;
12'd3463 : mem_out_dec = 6'b111111;
12'd3464 : mem_out_dec = 6'b111111;
12'd3465 : mem_out_dec = 6'b111111;
12'd3466 : mem_out_dec = 6'b111111;
12'd3467 : mem_out_dec = 6'b111111;
12'd3468 : mem_out_dec = 6'b111111;
12'd3469 : mem_out_dec = 6'b111111;
12'd3470 : mem_out_dec = 6'b111111;
12'd3471 : mem_out_dec = 6'b111111;
12'd3472 : mem_out_dec = 6'b111111;
12'd3473 : mem_out_dec = 6'b111111;
12'd3474 : mem_out_dec = 6'b111111;
12'd3475 : mem_out_dec = 6'b111111;
12'd3476 : mem_out_dec = 6'b111111;
12'd3477 : mem_out_dec = 6'b111111;
12'd3478 : mem_out_dec = 6'b111111;
12'd3479 : mem_out_dec = 6'b111111;
12'd3480 : mem_out_dec = 6'b111111;
12'd3481 : mem_out_dec = 6'b111111;
12'd3482 : mem_out_dec = 6'b111111;
12'd3483 : mem_out_dec = 6'b111111;
12'd3484 : mem_out_dec = 6'b111111;
12'd3485 : mem_out_dec = 6'b111111;
12'd3486 : mem_out_dec = 6'b111111;
12'd3487 : mem_out_dec = 6'b111111;
12'd3488 : mem_out_dec = 6'b111111;
12'd3489 : mem_out_dec = 6'b111111;
12'd3490 : mem_out_dec = 6'b111111;
12'd3491 : mem_out_dec = 6'b111111;
12'd3492 : mem_out_dec = 6'b111111;
12'd3493 : mem_out_dec = 6'b111111;
12'd3494 : mem_out_dec = 6'b111111;
12'd3495 : mem_out_dec = 6'b111111;
12'd3496 : mem_out_dec = 6'b111111;
12'd3497 : mem_out_dec = 6'b111111;
12'd3498 : mem_out_dec = 6'b111111;
12'd3499 : mem_out_dec = 6'b111111;
12'd3500 : mem_out_dec = 6'b111111;
12'd3501 : mem_out_dec = 6'b111111;
12'd3502 : mem_out_dec = 6'b111111;
12'd3503 : mem_out_dec = 6'b111111;
12'd3504 : mem_out_dec = 6'b111111;
12'd3505 : mem_out_dec = 6'b111111;
12'd3506 : mem_out_dec = 6'b111111;
12'd3507 : mem_out_dec = 6'b111111;
12'd3508 : mem_out_dec = 6'b111111;
12'd3509 : mem_out_dec = 6'b111111;
12'd3510 : mem_out_dec = 6'b111111;
12'd3511 : mem_out_dec = 6'b111111;
12'd3512 : mem_out_dec = 6'b111111;
12'd3513 : mem_out_dec = 6'b111111;
12'd3514 : mem_out_dec = 6'b111111;
12'd3515 : mem_out_dec = 6'b111111;
12'd3516 : mem_out_dec = 6'b000101;
12'd3517 : mem_out_dec = 6'b000110;
12'd3518 : mem_out_dec = 6'b000110;
12'd3519 : mem_out_dec = 6'b000111;
12'd3520 : mem_out_dec = 6'b111111;
12'd3521 : mem_out_dec = 6'b111111;
12'd3522 : mem_out_dec = 6'b111111;
12'd3523 : mem_out_dec = 6'b111111;
12'd3524 : mem_out_dec = 6'b111111;
12'd3525 : mem_out_dec = 6'b111111;
12'd3526 : mem_out_dec = 6'b111111;
12'd3527 : mem_out_dec = 6'b111111;
12'd3528 : mem_out_dec = 6'b111111;
12'd3529 : mem_out_dec = 6'b111111;
12'd3530 : mem_out_dec = 6'b111111;
12'd3531 : mem_out_dec = 6'b111111;
12'd3532 : mem_out_dec = 6'b111111;
12'd3533 : mem_out_dec = 6'b111111;
12'd3534 : mem_out_dec = 6'b111111;
12'd3535 : mem_out_dec = 6'b111111;
12'd3536 : mem_out_dec = 6'b111111;
12'd3537 : mem_out_dec = 6'b111111;
12'd3538 : mem_out_dec = 6'b111111;
12'd3539 : mem_out_dec = 6'b111111;
12'd3540 : mem_out_dec = 6'b111111;
12'd3541 : mem_out_dec = 6'b111111;
12'd3542 : mem_out_dec = 6'b111111;
12'd3543 : mem_out_dec = 6'b111111;
12'd3544 : mem_out_dec = 6'b111111;
12'd3545 : mem_out_dec = 6'b111111;
12'd3546 : mem_out_dec = 6'b111111;
12'd3547 : mem_out_dec = 6'b111111;
12'd3548 : mem_out_dec = 6'b111111;
12'd3549 : mem_out_dec = 6'b111111;
12'd3550 : mem_out_dec = 6'b111111;
12'd3551 : mem_out_dec = 6'b111111;
12'd3552 : mem_out_dec = 6'b111111;
12'd3553 : mem_out_dec = 6'b111111;
12'd3554 : mem_out_dec = 6'b111111;
12'd3555 : mem_out_dec = 6'b111111;
12'd3556 : mem_out_dec = 6'b111111;
12'd3557 : mem_out_dec = 6'b111111;
12'd3558 : mem_out_dec = 6'b111111;
12'd3559 : mem_out_dec = 6'b111111;
12'd3560 : mem_out_dec = 6'b111111;
12'd3561 : mem_out_dec = 6'b111111;
12'd3562 : mem_out_dec = 6'b111111;
12'd3563 : mem_out_dec = 6'b111111;
12'd3564 : mem_out_dec = 6'b111111;
12'd3565 : mem_out_dec = 6'b111111;
12'd3566 : mem_out_dec = 6'b111111;
12'd3567 : mem_out_dec = 6'b111111;
12'd3568 : mem_out_dec = 6'b111111;
12'd3569 : mem_out_dec = 6'b111111;
12'd3570 : mem_out_dec = 6'b111111;
12'd3571 : mem_out_dec = 6'b111111;
12'd3572 : mem_out_dec = 6'b111111;
12'd3573 : mem_out_dec = 6'b111111;
12'd3574 : mem_out_dec = 6'b111111;
12'd3575 : mem_out_dec = 6'b111111;
12'd3576 : mem_out_dec = 6'b111111;
12'd3577 : mem_out_dec = 6'b111111;
12'd3578 : mem_out_dec = 6'b111111;
12'd3579 : mem_out_dec = 6'b111111;
12'd3580 : mem_out_dec = 6'b111111;
12'd3581 : mem_out_dec = 6'b000101;
12'd3582 : mem_out_dec = 6'b000110;
12'd3583 : mem_out_dec = 6'b000110;
12'd3584 : mem_out_dec = 6'b111111;
12'd3585 : mem_out_dec = 6'b111111;
12'd3586 : mem_out_dec = 6'b111111;
12'd3587 : mem_out_dec = 6'b111111;
12'd3588 : mem_out_dec = 6'b111111;
12'd3589 : mem_out_dec = 6'b111111;
12'd3590 : mem_out_dec = 6'b111111;
12'd3591 : mem_out_dec = 6'b111111;
12'd3592 : mem_out_dec = 6'b111111;
12'd3593 : mem_out_dec = 6'b111111;
12'd3594 : mem_out_dec = 6'b111111;
12'd3595 : mem_out_dec = 6'b111111;
12'd3596 : mem_out_dec = 6'b111111;
12'd3597 : mem_out_dec = 6'b111111;
12'd3598 : mem_out_dec = 6'b111111;
12'd3599 : mem_out_dec = 6'b111111;
12'd3600 : mem_out_dec = 6'b111111;
12'd3601 : mem_out_dec = 6'b111111;
12'd3602 : mem_out_dec = 6'b111111;
12'd3603 : mem_out_dec = 6'b111111;
12'd3604 : mem_out_dec = 6'b111111;
12'd3605 : mem_out_dec = 6'b111111;
12'd3606 : mem_out_dec = 6'b111111;
12'd3607 : mem_out_dec = 6'b111111;
12'd3608 : mem_out_dec = 6'b111111;
12'd3609 : mem_out_dec = 6'b111111;
12'd3610 : mem_out_dec = 6'b111111;
12'd3611 : mem_out_dec = 6'b111111;
12'd3612 : mem_out_dec = 6'b111111;
12'd3613 : mem_out_dec = 6'b111111;
12'd3614 : mem_out_dec = 6'b111111;
12'd3615 : mem_out_dec = 6'b111111;
12'd3616 : mem_out_dec = 6'b111111;
12'd3617 : mem_out_dec = 6'b111111;
12'd3618 : mem_out_dec = 6'b111111;
12'd3619 : mem_out_dec = 6'b111111;
12'd3620 : mem_out_dec = 6'b111111;
12'd3621 : mem_out_dec = 6'b111111;
12'd3622 : mem_out_dec = 6'b111111;
12'd3623 : mem_out_dec = 6'b111111;
12'd3624 : mem_out_dec = 6'b111111;
12'd3625 : mem_out_dec = 6'b111111;
12'd3626 : mem_out_dec = 6'b111111;
12'd3627 : mem_out_dec = 6'b111111;
12'd3628 : mem_out_dec = 6'b111111;
12'd3629 : mem_out_dec = 6'b111111;
12'd3630 : mem_out_dec = 6'b111111;
12'd3631 : mem_out_dec = 6'b111111;
12'd3632 : mem_out_dec = 6'b111111;
12'd3633 : mem_out_dec = 6'b111111;
12'd3634 : mem_out_dec = 6'b111111;
12'd3635 : mem_out_dec = 6'b111111;
12'd3636 : mem_out_dec = 6'b111111;
12'd3637 : mem_out_dec = 6'b111111;
12'd3638 : mem_out_dec = 6'b111111;
12'd3639 : mem_out_dec = 6'b111111;
12'd3640 : mem_out_dec = 6'b111111;
12'd3641 : mem_out_dec = 6'b111111;
12'd3642 : mem_out_dec = 6'b111111;
12'd3643 : mem_out_dec = 6'b111111;
12'd3644 : mem_out_dec = 6'b111111;
12'd3645 : mem_out_dec = 6'b111111;
12'd3646 : mem_out_dec = 6'b000100;
12'd3647 : mem_out_dec = 6'b000101;
12'd3648 : mem_out_dec = 6'b111111;
12'd3649 : mem_out_dec = 6'b111111;
12'd3650 : mem_out_dec = 6'b111111;
12'd3651 : mem_out_dec = 6'b111111;
12'd3652 : mem_out_dec = 6'b111111;
12'd3653 : mem_out_dec = 6'b111111;
12'd3654 : mem_out_dec = 6'b111111;
12'd3655 : mem_out_dec = 6'b111111;
12'd3656 : mem_out_dec = 6'b111111;
12'd3657 : mem_out_dec = 6'b111111;
12'd3658 : mem_out_dec = 6'b111111;
12'd3659 : mem_out_dec = 6'b111111;
12'd3660 : mem_out_dec = 6'b111111;
12'd3661 : mem_out_dec = 6'b111111;
12'd3662 : mem_out_dec = 6'b111111;
12'd3663 : mem_out_dec = 6'b111111;
12'd3664 : mem_out_dec = 6'b111111;
12'd3665 : mem_out_dec = 6'b111111;
12'd3666 : mem_out_dec = 6'b111111;
12'd3667 : mem_out_dec = 6'b111111;
12'd3668 : mem_out_dec = 6'b111111;
12'd3669 : mem_out_dec = 6'b111111;
12'd3670 : mem_out_dec = 6'b111111;
12'd3671 : mem_out_dec = 6'b111111;
12'd3672 : mem_out_dec = 6'b111111;
12'd3673 : mem_out_dec = 6'b111111;
12'd3674 : mem_out_dec = 6'b111111;
12'd3675 : mem_out_dec = 6'b111111;
12'd3676 : mem_out_dec = 6'b111111;
12'd3677 : mem_out_dec = 6'b111111;
12'd3678 : mem_out_dec = 6'b111111;
12'd3679 : mem_out_dec = 6'b111111;
12'd3680 : mem_out_dec = 6'b111111;
12'd3681 : mem_out_dec = 6'b111111;
12'd3682 : mem_out_dec = 6'b111111;
12'd3683 : mem_out_dec = 6'b111111;
12'd3684 : mem_out_dec = 6'b111111;
12'd3685 : mem_out_dec = 6'b111111;
12'd3686 : mem_out_dec = 6'b111111;
12'd3687 : mem_out_dec = 6'b111111;
12'd3688 : mem_out_dec = 6'b111111;
12'd3689 : mem_out_dec = 6'b111111;
12'd3690 : mem_out_dec = 6'b111111;
12'd3691 : mem_out_dec = 6'b111111;
12'd3692 : mem_out_dec = 6'b111111;
12'd3693 : mem_out_dec = 6'b111111;
12'd3694 : mem_out_dec = 6'b111111;
12'd3695 : mem_out_dec = 6'b111111;
12'd3696 : mem_out_dec = 6'b111111;
12'd3697 : mem_out_dec = 6'b111111;
12'd3698 : mem_out_dec = 6'b111111;
12'd3699 : mem_out_dec = 6'b111111;
12'd3700 : mem_out_dec = 6'b111111;
12'd3701 : mem_out_dec = 6'b111111;
12'd3702 : mem_out_dec = 6'b111111;
12'd3703 : mem_out_dec = 6'b111111;
12'd3704 : mem_out_dec = 6'b111111;
12'd3705 : mem_out_dec = 6'b111111;
12'd3706 : mem_out_dec = 6'b111111;
12'd3707 : mem_out_dec = 6'b111111;
12'd3708 : mem_out_dec = 6'b111111;
12'd3709 : mem_out_dec = 6'b111111;
12'd3710 : mem_out_dec = 6'b111111;
12'd3711 : mem_out_dec = 6'b000100;
12'd3712 : mem_out_dec = 6'b111111;
12'd3713 : mem_out_dec = 6'b111111;
12'd3714 : mem_out_dec = 6'b111111;
12'd3715 : mem_out_dec = 6'b111111;
12'd3716 : mem_out_dec = 6'b111111;
12'd3717 : mem_out_dec = 6'b111111;
12'd3718 : mem_out_dec = 6'b111111;
12'd3719 : mem_out_dec = 6'b111111;
12'd3720 : mem_out_dec = 6'b111111;
12'd3721 : mem_out_dec = 6'b111111;
12'd3722 : mem_out_dec = 6'b111111;
12'd3723 : mem_out_dec = 6'b111111;
12'd3724 : mem_out_dec = 6'b111111;
12'd3725 : mem_out_dec = 6'b111111;
12'd3726 : mem_out_dec = 6'b111111;
12'd3727 : mem_out_dec = 6'b111111;
12'd3728 : mem_out_dec = 6'b111111;
12'd3729 : mem_out_dec = 6'b111111;
12'd3730 : mem_out_dec = 6'b111111;
12'd3731 : mem_out_dec = 6'b111111;
12'd3732 : mem_out_dec = 6'b111111;
12'd3733 : mem_out_dec = 6'b111111;
12'd3734 : mem_out_dec = 6'b111111;
12'd3735 : mem_out_dec = 6'b111111;
12'd3736 : mem_out_dec = 6'b111111;
12'd3737 : mem_out_dec = 6'b111111;
12'd3738 : mem_out_dec = 6'b111111;
12'd3739 : mem_out_dec = 6'b111111;
12'd3740 : mem_out_dec = 6'b111111;
12'd3741 : mem_out_dec = 6'b111111;
12'd3742 : mem_out_dec = 6'b111111;
12'd3743 : mem_out_dec = 6'b111111;
12'd3744 : mem_out_dec = 6'b111111;
12'd3745 : mem_out_dec = 6'b111111;
12'd3746 : mem_out_dec = 6'b111111;
12'd3747 : mem_out_dec = 6'b111111;
12'd3748 : mem_out_dec = 6'b111111;
12'd3749 : mem_out_dec = 6'b111111;
12'd3750 : mem_out_dec = 6'b111111;
12'd3751 : mem_out_dec = 6'b111111;
12'd3752 : mem_out_dec = 6'b111111;
12'd3753 : mem_out_dec = 6'b111111;
12'd3754 : mem_out_dec = 6'b111111;
12'd3755 : mem_out_dec = 6'b111111;
12'd3756 : mem_out_dec = 6'b111111;
12'd3757 : mem_out_dec = 6'b111111;
12'd3758 : mem_out_dec = 6'b111111;
12'd3759 : mem_out_dec = 6'b111111;
12'd3760 : mem_out_dec = 6'b111111;
12'd3761 : mem_out_dec = 6'b111111;
12'd3762 : mem_out_dec = 6'b111111;
12'd3763 : mem_out_dec = 6'b111111;
12'd3764 : mem_out_dec = 6'b111111;
12'd3765 : mem_out_dec = 6'b111111;
12'd3766 : mem_out_dec = 6'b111111;
12'd3767 : mem_out_dec = 6'b111111;
12'd3768 : mem_out_dec = 6'b111111;
12'd3769 : mem_out_dec = 6'b111111;
12'd3770 : mem_out_dec = 6'b111111;
12'd3771 : mem_out_dec = 6'b111111;
12'd3772 : mem_out_dec = 6'b111111;
12'd3773 : mem_out_dec = 6'b111111;
12'd3774 : mem_out_dec = 6'b111111;
12'd3775 : mem_out_dec = 6'b111111;
12'd3776 : mem_out_dec = 6'b111111;
12'd3777 : mem_out_dec = 6'b111111;
12'd3778 : mem_out_dec = 6'b111111;
12'd3779 : mem_out_dec = 6'b111111;
12'd3780 : mem_out_dec = 6'b111111;
12'd3781 : mem_out_dec = 6'b111111;
12'd3782 : mem_out_dec = 6'b111111;
12'd3783 : mem_out_dec = 6'b111111;
12'd3784 : mem_out_dec = 6'b111111;
12'd3785 : mem_out_dec = 6'b111111;
12'd3786 : mem_out_dec = 6'b111111;
12'd3787 : mem_out_dec = 6'b111111;
12'd3788 : mem_out_dec = 6'b111111;
12'd3789 : mem_out_dec = 6'b111111;
12'd3790 : mem_out_dec = 6'b111111;
12'd3791 : mem_out_dec = 6'b111111;
12'd3792 : mem_out_dec = 6'b111111;
12'd3793 : mem_out_dec = 6'b111111;
12'd3794 : mem_out_dec = 6'b111111;
12'd3795 : mem_out_dec = 6'b111111;
12'd3796 : mem_out_dec = 6'b111111;
12'd3797 : mem_out_dec = 6'b111111;
12'd3798 : mem_out_dec = 6'b111111;
12'd3799 : mem_out_dec = 6'b111111;
12'd3800 : mem_out_dec = 6'b111111;
12'd3801 : mem_out_dec = 6'b111111;
12'd3802 : mem_out_dec = 6'b111111;
12'd3803 : mem_out_dec = 6'b111111;
12'd3804 : mem_out_dec = 6'b111111;
12'd3805 : mem_out_dec = 6'b111111;
12'd3806 : mem_out_dec = 6'b111111;
12'd3807 : mem_out_dec = 6'b111111;
12'd3808 : mem_out_dec = 6'b111111;
12'd3809 : mem_out_dec = 6'b111111;
12'd3810 : mem_out_dec = 6'b111111;
12'd3811 : mem_out_dec = 6'b111111;
12'd3812 : mem_out_dec = 6'b111111;
12'd3813 : mem_out_dec = 6'b111111;
12'd3814 : mem_out_dec = 6'b111111;
12'd3815 : mem_out_dec = 6'b111111;
12'd3816 : mem_out_dec = 6'b111111;
12'd3817 : mem_out_dec = 6'b111111;
12'd3818 : mem_out_dec = 6'b111111;
12'd3819 : mem_out_dec = 6'b111111;
12'd3820 : mem_out_dec = 6'b111111;
12'd3821 : mem_out_dec = 6'b111111;
12'd3822 : mem_out_dec = 6'b111111;
12'd3823 : mem_out_dec = 6'b111111;
12'd3824 : mem_out_dec = 6'b111111;
12'd3825 : mem_out_dec = 6'b111111;
12'd3826 : mem_out_dec = 6'b111111;
12'd3827 : mem_out_dec = 6'b111111;
12'd3828 : mem_out_dec = 6'b111111;
12'd3829 : mem_out_dec = 6'b111111;
12'd3830 : mem_out_dec = 6'b111111;
12'd3831 : mem_out_dec = 6'b111111;
12'd3832 : mem_out_dec = 6'b111111;
12'd3833 : mem_out_dec = 6'b111111;
12'd3834 : mem_out_dec = 6'b111111;
12'd3835 : mem_out_dec = 6'b111111;
12'd3836 : mem_out_dec = 6'b111111;
12'd3837 : mem_out_dec = 6'b111111;
12'd3838 : mem_out_dec = 6'b111111;
12'd3839 : mem_out_dec = 6'b111111;
12'd3840 : mem_out_dec = 6'b111111;
12'd3841 : mem_out_dec = 6'b111111;
12'd3842 : mem_out_dec = 6'b111111;
12'd3843 : mem_out_dec = 6'b111111;
12'd3844 : mem_out_dec = 6'b111111;
12'd3845 : mem_out_dec = 6'b111111;
12'd3846 : mem_out_dec = 6'b111111;
12'd3847 : mem_out_dec = 6'b111111;
12'd3848 : mem_out_dec = 6'b111111;
12'd3849 : mem_out_dec = 6'b111111;
12'd3850 : mem_out_dec = 6'b111111;
12'd3851 : mem_out_dec = 6'b111111;
12'd3852 : mem_out_dec = 6'b111111;
12'd3853 : mem_out_dec = 6'b111111;
12'd3854 : mem_out_dec = 6'b111111;
12'd3855 : mem_out_dec = 6'b111111;
12'd3856 : mem_out_dec = 6'b111111;
12'd3857 : mem_out_dec = 6'b111111;
12'd3858 : mem_out_dec = 6'b111111;
12'd3859 : mem_out_dec = 6'b111111;
12'd3860 : mem_out_dec = 6'b111111;
12'd3861 : mem_out_dec = 6'b111111;
12'd3862 : mem_out_dec = 6'b111111;
12'd3863 : mem_out_dec = 6'b111111;
12'd3864 : mem_out_dec = 6'b111111;
12'd3865 : mem_out_dec = 6'b111111;
12'd3866 : mem_out_dec = 6'b111111;
12'd3867 : mem_out_dec = 6'b111111;
12'd3868 : mem_out_dec = 6'b111111;
12'd3869 : mem_out_dec = 6'b111111;
12'd3870 : mem_out_dec = 6'b111111;
12'd3871 : mem_out_dec = 6'b111111;
12'd3872 : mem_out_dec = 6'b111111;
12'd3873 : mem_out_dec = 6'b111111;
12'd3874 : mem_out_dec = 6'b111111;
12'd3875 : mem_out_dec = 6'b111111;
12'd3876 : mem_out_dec = 6'b111111;
12'd3877 : mem_out_dec = 6'b111111;
12'd3878 : mem_out_dec = 6'b111111;
12'd3879 : mem_out_dec = 6'b111111;
12'd3880 : mem_out_dec = 6'b111111;
12'd3881 : mem_out_dec = 6'b111111;
12'd3882 : mem_out_dec = 6'b111111;
12'd3883 : mem_out_dec = 6'b111111;
12'd3884 : mem_out_dec = 6'b111111;
12'd3885 : mem_out_dec = 6'b111111;
12'd3886 : mem_out_dec = 6'b111111;
12'd3887 : mem_out_dec = 6'b111111;
12'd3888 : mem_out_dec = 6'b111111;
12'd3889 : mem_out_dec = 6'b111111;
12'd3890 : mem_out_dec = 6'b111111;
12'd3891 : mem_out_dec = 6'b111111;
12'd3892 : mem_out_dec = 6'b111111;
12'd3893 : mem_out_dec = 6'b111111;
12'd3894 : mem_out_dec = 6'b111111;
12'd3895 : mem_out_dec = 6'b111111;
12'd3896 : mem_out_dec = 6'b111111;
12'd3897 : mem_out_dec = 6'b111111;
12'd3898 : mem_out_dec = 6'b111111;
12'd3899 : mem_out_dec = 6'b111111;
12'd3900 : mem_out_dec = 6'b111111;
12'd3901 : mem_out_dec = 6'b111111;
12'd3902 : mem_out_dec = 6'b111111;
12'd3903 : mem_out_dec = 6'b111111;
12'd3904 : mem_out_dec = 6'b111111;
12'd3905 : mem_out_dec = 6'b111111;
12'd3906 : mem_out_dec = 6'b111111;
12'd3907 : mem_out_dec = 6'b111111;
12'd3908 : mem_out_dec = 6'b111111;
12'd3909 : mem_out_dec = 6'b111111;
12'd3910 : mem_out_dec = 6'b111111;
12'd3911 : mem_out_dec = 6'b111111;
12'd3912 : mem_out_dec = 6'b111111;
12'd3913 : mem_out_dec = 6'b111111;
12'd3914 : mem_out_dec = 6'b111111;
12'd3915 : mem_out_dec = 6'b111111;
12'd3916 : mem_out_dec = 6'b111111;
12'd3917 : mem_out_dec = 6'b111111;
12'd3918 : mem_out_dec = 6'b111111;
12'd3919 : mem_out_dec = 6'b111111;
12'd3920 : mem_out_dec = 6'b111111;
12'd3921 : mem_out_dec = 6'b111111;
12'd3922 : mem_out_dec = 6'b111111;
12'd3923 : mem_out_dec = 6'b111111;
12'd3924 : mem_out_dec = 6'b111111;
12'd3925 : mem_out_dec = 6'b111111;
12'd3926 : mem_out_dec = 6'b111111;
12'd3927 : mem_out_dec = 6'b111111;
12'd3928 : mem_out_dec = 6'b111111;
12'd3929 : mem_out_dec = 6'b111111;
12'd3930 : mem_out_dec = 6'b111111;
12'd3931 : mem_out_dec = 6'b111111;
12'd3932 : mem_out_dec = 6'b111111;
12'd3933 : mem_out_dec = 6'b111111;
12'd3934 : mem_out_dec = 6'b111111;
12'd3935 : mem_out_dec = 6'b111111;
12'd3936 : mem_out_dec = 6'b111111;
12'd3937 : mem_out_dec = 6'b111111;
12'd3938 : mem_out_dec = 6'b111111;
12'd3939 : mem_out_dec = 6'b111111;
12'd3940 : mem_out_dec = 6'b111111;
12'd3941 : mem_out_dec = 6'b111111;
12'd3942 : mem_out_dec = 6'b111111;
12'd3943 : mem_out_dec = 6'b111111;
12'd3944 : mem_out_dec = 6'b111111;
12'd3945 : mem_out_dec = 6'b111111;
12'd3946 : mem_out_dec = 6'b111111;
12'd3947 : mem_out_dec = 6'b111111;
12'd3948 : mem_out_dec = 6'b111111;
12'd3949 : mem_out_dec = 6'b111111;
12'd3950 : mem_out_dec = 6'b111111;
12'd3951 : mem_out_dec = 6'b111111;
12'd3952 : mem_out_dec = 6'b111111;
12'd3953 : mem_out_dec = 6'b111111;
12'd3954 : mem_out_dec = 6'b111111;
12'd3955 : mem_out_dec = 6'b111111;
12'd3956 : mem_out_dec = 6'b111111;
12'd3957 : mem_out_dec = 6'b111111;
12'd3958 : mem_out_dec = 6'b111111;
12'd3959 : mem_out_dec = 6'b111111;
12'd3960 : mem_out_dec = 6'b111111;
12'd3961 : mem_out_dec = 6'b111111;
12'd3962 : mem_out_dec = 6'b111111;
12'd3963 : mem_out_dec = 6'b111111;
12'd3964 : mem_out_dec = 6'b111111;
12'd3965 : mem_out_dec = 6'b111111;
12'd3966 : mem_out_dec = 6'b111111;
12'd3967 : mem_out_dec = 6'b111111;
12'd3968 : mem_out_dec = 6'b111111;
12'd3969 : mem_out_dec = 6'b111111;
12'd3970 : mem_out_dec = 6'b111111;
12'd3971 : mem_out_dec = 6'b111111;
12'd3972 : mem_out_dec = 6'b111111;
12'd3973 : mem_out_dec = 6'b111111;
12'd3974 : mem_out_dec = 6'b111111;
12'd3975 : mem_out_dec = 6'b111111;
12'd3976 : mem_out_dec = 6'b111111;
12'd3977 : mem_out_dec = 6'b111111;
12'd3978 : mem_out_dec = 6'b111111;
12'd3979 : mem_out_dec = 6'b111111;
12'd3980 : mem_out_dec = 6'b111111;
12'd3981 : mem_out_dec = 6'b111111;
12'd3982 : mem_out_dec = 6'b111111;
12'd3983 : mem_out_dec = 6'b111111;
12'd3984 : mem_out_dec = 6'b111111;
12'd3985 : mem_out_dec = 6'b111111;
12'd3986 : mem_out_dec = 6'b111111;
12'd3987 : mem_out_dec = 6'b111111;
12'd3988 : mem_out_dec = 6'b111111;
12'd3989 : mem_out_dec = 6'b111111;
12'd3990 : mem_out_dec = 6'b111111;
12'd3991 : mem_out_dec = 6'b111111;
12'd3992 : mem_out_dec = 6'b111111;
12'd3993 : mem_out_dec = 6'b111111;
12'd3994 : mem_out_dec = 6'b111111;
12'd3995 : mem_out_dec = 6'b111111;
12'd3996 : mem_out_dec = 6'b111111;
12'd3997 : mem_out_dec = 6'b111111;
12'd3998 : mem_out_dec = 6'b111111;
12'd3999 : mem_out_dec = 6'b111111;
12'd4000 : mem_out_dec = 6'b111111;
12'd4001 : mem_out_dec = 6'b111111;
12'd4002 : mem_out_dec = 6'b111111;
12'd4003 : mem_out_dec = 6'b111111;
12'd4004 : mem_out_dec = 6'b111111;
12'd4005 : mem_out_dec = 6'b111111;
12'd4006 : mem_out_dec = 6'b111111;
12'd4007 : mem_out_dec = 6'b111111;
12'd4008 : mem_out_dec = 6'b111111;
12'd4009 : mem_out_dec = 6'b111111;
12'd4010 : mem_out_dec = 6'b111111;
12'd4011 : mem_out_dec = 6'b111111;
12'd4012 : mem_out_dec = 6'b111111;
12'd4013 : mem_out_dec = 6'b111111;
12'd4014 : mem_out_dec = 6'b111111;
12'd4015 : mem_out_dec = 6'b111111;
12'd4016 : mem_out_dec = 6'b111111;
12'd4017 : mem_out_dec = 6'b111111;
12'd4018 : mem_out_dec = 6'b111111;
12'd4019 : mem_out_dec = 6'b111111;
12'd4020 : mem_out_dec = 6'b111111;
12'd4021 : mem_out_dec = 6'b111111;
12'd4022 : mem_out_dec = 6'b111111;
12'd4023 : mem_out_dec = 6'b111111;
12'd4024 : mem_out_dec = 6'b111111;
12'd4025 : mem_out_dec = 6'b111111;
12'd4026 : mem_out_dec = 6'b111111;
12'd4027 : mem_out_dec = 6'b111111;
12'd4028 : mem_out_dec = 6'b111111;
12'd4029 : mem_out_dec = 6'b111111;
12'd4030 : mem_out_dec = 6'b111111;
12'd4031 : mem_out_dec = 6'b111111;
12'd4032 : mem_out_dec = 6'b111111;
12'd4033 : mem_out_dec = 6'b111111;
12'd4034 : mem_out_dec = 6'b111111;
12'd4035 : mem_out_dec = 6'b111111;
12'd4036 : mem_out_dec = 6'b111111;
12'd4037 : mem_out_dec = 6'b111111;
12'd4038 : mem_out_dec = 6'b111111;
12'd4039 : mem_out_dec = 6'b111111;
12'd4040 : mem_out_dec = 6'b111111;
12'd4041 : mem_out_dec = 6'b111111;
12'd4042 : mem_out_dec = 6'b111111;
12'd4043 : mem_out_dec = 6'b111111;
12'd4044 : mem_out_dec = 6'b111111;
12'd4045 : mem_out_dec = 6'b111111;
12'd4046 : mem_out_dec = 6'b111111;
12'd4047 : mem_out_dec = 6'b111111;
12'd4048 : mem_out_dec = 6'b111111;
12'd4049 : mem_out_dec = 6'b111111;
12'd4050 : mem_out_dec = 6'b111111;
12'd4051 : mem_out_dec = 6'b111111;
12'd4052 : mem_out_dec = 6'b111111;
12'd4053 : mem_out_dec = 6'b111111;
12'd4054 : mem_out_dec = 6'b111111;
12'd4055 : mem_out_dec = 6'b111111;
12'd4056 : mem_out_dec = 6'b111111;
12'd4057 : mem_out_dec = 6'b111111;
12'd4058 : mem_out_dec = 6'b111111;
12'd4059 : mem_out_dec = 6'b111111;
12'd4060 : mem_out_dec = 6'b111111;
12'd4061 : mem_out_dec = 6'b111111;
12'd4062 : mem_out_dec = 6'b111111;
12'd4063 : mem_out_dec = 6'b111111;
12'd4064 : mem_out_dec = 6'b111111;
12'd4065 : mem_out_dec = 6'b111111;
12'd4066 : mem_out_dec = 6'b111111;
12'd4067 : mem_out_dec = 6'b111111;
12'd4068 : mem_out_dec = 6'b111111;
12'd4069 : mem_out_dec = 6'b111111;
12'd4070 : mem_out_dec = 6'b111111;
12'd4071 : mem_out_dec = 6'b111111;
12'd4072 : mem_out_dec = 6'b111111;
12'd4073 : mem_out_dec = 6'b111111;
12'd4074 : mem_out_dec = 6'b111111;
12'd4075 : mem_out_dec = 6'b111111;
12'd4076 : mem_out_dec = 6'b111111;
12'd4077 : mem_out_dec = 6'b111111;
12'd4078 : mem_out_dec = 6'b111111;
12'd4079 : mem_out_dec = 6'b111111;
12'd4080 : mem_out_dec = 6'b111111;
12'd4081 : mem_out_dec = 6'b111111;
12'd4082 : mem_out_dec = 6'b111111;
12'd4083 : mem_out_dec = 6'b111111;
12'd4084 : mem_out_dec = 6'b111111;
12'd4085 : mem_out_dec = 6'b111111;
12'd4086 : mem_out_dec = 6'b111111;
12'd4087 : mem_out_dec = 6'b111111;
12'd4088 : mem_out_dec = 6'b111111;
12'd4089 : mem_out_dec = 6'b111111;
12'd4090 : mem_out_dec = 6'b111111;
12'd4091 : mem_out_dec = 6'b111111;
12'd4092 : mem_out_dec = 6'b111111;
12'd4093 : mem_out_dec = 6'b111111;
12'd4094 : mem_out_dec = 6'b111111;
12'd4095 : mem_out_dec = 6'b111111;
endcase
end
always @ (posedge clk) begin
dec_cnt <= #TCQ mem_out_dec;
end
endmodule
|
module mig_7series_v2_3_poc_tap_base #
(parameter MMCM_SAMP_WAIT = 10,
parameter POC_USE_METASTABLE_SAMP = "FALSE",
parameter TCQ = 100,
parameter SAMPCNTRWIDTH = 8,
parameter TAPCNTRWIDTH = 7,
parameter TAPSPERKCLK = 112)
(/*AUTOARG*/
// Outputs
psincdec, psen, run, run_end, run_polarity, samps_hi_held, tap,
// Inputs
pd_out, clk, samples, samps_solid_thresh, psdone, rst,
poc_sample_pd
);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
input pd_out;
input clk;
input [SAMPCNTRWIDTH:0] samples, samps_solid_thresh;
input psdone;
input rst;
localparam ONE = 1;
localparam SAMP_WAIT_WIDTH = clogb2(MMCM_SAMP_WAIT);
reg [SAMP_WAIT_WIDTH-1:0] samp_wait_ns, samp_wait_r;
always @(posedge clk) samp_wait_r <= #TCQ samp_wait_ns;
reg pd_out_r;
always @(posedge clk) pd_out_r <= #TCQ pd_out;
wire pd_out_sel = POC_USE_METASTABLE_SAMP == "TRUE" ? pd_out_r : pd_out;
output psincdec;
assign psincdec = 1'b1;
output psen;
reg psen_int;
assign psen = psen_int;
reg [TAPCNTRWIDTH-1:0] run_r;
reg [TAPCNTRWIDTH-1:0] run_ns;
always @(posedge clk) run_r <= #TCQ run_ns;
output [TAPCNTRWIDTH-1:0] run;
assign run = run_r;
output run_end;
reg run_end_int;
assign run_end = run_end_int;
reg run_polarity_r;
reg run_polarity_ns;
always @(posedge clk) run_polarity_r <= #TCQ run_polarity_ns;
output run_polarity;
assign run_polarity = run_polarity_r;
reg [SAMPCNTRWIDTH-1:0] samp_cntr_r;
reg [SAMPCNTRWIDTH-1:0] samp_cntr_ns;
always @(posedge clk) samp_cntr_r <= #TCQ samp_cntr_ns;
reg [SAMPCNTRWIDTH:0] samps_hi_r;
reg [SAMPCNTRWIDTH:0] samps_hi_ns;
always @(posedge clk) samps_hi_r <= #TCQ samps_hi_ns;
reg [SAMPCNTRWIDTH:0] samps_hi_held_r;
reg [SAMPCNTRWIDTH:0] samps_hi_held_ns;
always @(posedge clk) samps_hi_held_r <= #TCQ samps_hi_held_ns;
output [SAMPCNTRWIDTH:0] samps_hi_held;
assign samps_hi_held = samps_hi_held_r;
reg [TAPCNTRWIDTH-1:0] tap_ns, tap_r;
always @(posedge clk) tap_r <= #TCQ tap_ns;
output [TAPCNTRWIDTH-1:0] tap;
assign tap = tap_r;
localparam SMWIDTH = 2;
reg [SMWIDTH-1:0] sm_ns;
reg [SMWIDTH-1:0] sm_r;
always @(posedge clk) sm_r <= #TCQ sm_ns;
reg samps_zero_ns, samps_zero_r, samps_one_ns, samps_one_r;
always @(posedge clk) samps_zero_r <= #TCQ samps_zero_ns;
always @(posedge clk)samps_one_r <= #TCQ samps_one_ns;
// Interesting corner case... what if both samps_zero and samps_one are
// hi? Could happen for small sample counts and reasonable values of
// PCT_SAMPS_SOLID. Doesn't affect samps_solid. run_polarity assignment
// consistently breaks tie with samps_one_r.
wire [SAMPCNTRWIDTH:0] samps_lo = samples + ONE[SAMPCNTRWIDTH:0] - samps_hi_r;
always @(*) begin
samps_zero_ns = samps_zero_r;
samps_one_ns = samps_one_r;
samps_zero_ns = samps_lo >= samps_solid_thresh;
samps_one_ns = samps_hi_r >= samps_solid_thresh;
end // always @ begin
wire new_polarity = run_polarity_ns ^ run_polarity_r;
input poc_sample_pd;
always @(*) begin
if (rst == 1'b1) begin
// RESET next states
psen_int = 1'b0;
sm_ns = /*AUTOLINK("SAMPLE")*/2'd0;
run_polarity_ns = 1'b0;
run_ns = {TAPCNTRWIDTH{1'b0}};
run_end_int = 1'b0;
samp_cntr_ns = {SAMPCNTRWIDTH{1'b0}};
samps_hi_ns = {SAMPCNTRWIDTH+1{1'b0}};
tap_ns = {TAPCNTRWIDTH{1'b0}};
samp_wait_ns = MMCM_SAMP_WAIT[SAMP_WAIT_WIDTH-1:0];
samps_hi_held_ns = {SAMPCNTRWIDTH+1{1'b0}};
end else begin
// Default next states;
psen_int = 1'b0;
sm_ns = sm_r;
run_polarity_ns = run_polarity_r;
run_ns = run_r;
run_end_int = 1'b0;
samp_cntr_ns = samp_cntr_r;
samps_hi_ns = samps_hi_r;
tap_ns = tap_r;
samp_wait_ns = samp_wait_r;
if (|samp_wait_r) samp_wait_ns = samp_wait_r - ONE[SAMP_WAIT_WIDTH-1:0];
samps_hi_held_ns = samps_hi_held_r;
// State based actions and next states.
case (sm_r)
/*AL("SAMPLE")*/2'd0: begin
if (~|samp_wait_r && poc_sample_pd | POC_USE_METASTABLE_SAMP == "TRUE") begin
if (POC_USE_METASTABLE_SAMP == "TRUE") samp_wait_ns = ONE[SAMP_WAIT_WIDTH-1:0];
if ({1'b0, samp_cntr_r} == samples) sm_ns = /*AK("COMPUTE")*/2'd1;
samps_hi_ns = samps_hi_r + {{SAMPCNTRWIDTH{1'b0}}, pd_out_sel};
samp_cntr_ns = samp_cntr_r + ONE[SAMPCNTRWIDTH-1:0];
end
end
/*AL("COMPUTE")*/2'd1:begin
sm_ns = /*AK("PSEN")*/2'd2;
end
/*AL("PSEN")*/2'd2:begin
sm_ns = /*AK("PSDONE_WAIT")*/2'd3;
psen_int = 1'b1;
samp_cntr_ns = {SAMPCNTRWIDTH{1'b0}};
samps_hi_ns = {SAMPCNTRWIDTH+1{1'b0}};
samps_hi_held_ns = samps_hi_r;
tap_ns = (tap_r < TAPSPERKCLK[TAPCNTRWIDTH-1:0] - ONE[TAPCNTRWIDTH-1:0])
? tap_r + ONE[TAPCNTRWIDTH-1:0]
: {TAPCNTRWIDTH{1'b0}};
if (run_polarity_r) begin
if (samps_zero_r) run_polarity_ns = 1'b0;
end else begin
if (samps_one_r) run_polarity_ns = 1'b1;
end
if (new_polarity) begin
run_ns ={TAPCNTRWIDTH{1'b0}};
run_end_int = 1'b1;
end else run_ns = run_r + ONE[TAPCNTRWIDTH-1:0];
end
/*AL("PSDONE_WAIT")*/2'd3:begin
samp_wait_ns = MMCM_SAMP_WAIT[SAMP_WAIT_WIDTH-1:0] - ONE[SAMP_WAIT_WIDTH-1:0];
if (psdone) sm_ns = /*AK("SAMPLE")*/2'd0;
end
endcase // case (sm_r)
end // else: !if(rst == 1'b1)
end // always @ (*)
endmodule
|
module mig_7series_v2_3_poc_tap_base #
(parameter MMCM_SAMP_WAIT = 10,
parameter POC_USE_METASTABLE_SAMP = "FALSE",
parameter TCQ = 100,
parameter SAMPCNTRWIDTH = 8,
parameter TAPCNTRWIDTH = 7,
parameter TAPSPERKCLK = 112)
(/*AUTOARG*/
// Outputs
psincdec, psen, run, run_end, run_polarity, samps_hi_held, tap,
// Inputs
pd_out, clk, samples, samps_solid_thresh, psdone, rst,
poc_sample_pd
);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
input pd_out;
input clk;
input [SAMPCNTRWIDTH:0] samples, samps_solid_thresh;
input psdone;
input rst;
localparam ONE = 1;
localparam SAMP_WAIT_WIDTH = clogb2(MMCM_SAMP_WAIT);
reg [SAMP_WAIT_WIDTH-1:0] samp_wait_ns, samp_wait_r;
always @(posedge clk) samp_wait_r <= #TCQ samp_wait_ns;
reg pd_out_r;
always @(posedge clk) pd_out_r <= #TCQ pd_out;
wire pd_out_sel = POC_USE_METASTABLE_SAMP == "TRUE" ? pd_out_r : pd_out;
output psincdec;
assign psincdec = 1'b1;
output psen;
reg psen_int;
assign psen = psen_int;
reg [TAPCNTRWIDTH-1:0] run_r;
reg [TAPCNTRWIDTH-1:0] run_ns;
always @(posedge clk) run_r <= #TCQ run_ns;
output [TAPCNTRWIDTH-1:0] run;
assign run = run_r;
output run_end;
reg run_end_int;
assign run_end = run_end_int;
reg run_polarity_r;
reg run_polarity_ns;
always @(posedge clk) run_polarity_r <= #TCQ run_polarity_ns;
output run_polarity;
assign run_polarity = run_polarity_r;
reg [SAMPCNTRWIDTH-1:0] samp_cntr_r;
reg [SAMPCNTRWIDTH-1:0] samp_cntr_ns;
always @(posedge clk) samp_cntr_r <= #TCQ samp_cntr_ns;
reg [SAMPCNTRWIDTH:0] samps_hi_r;
reg [SAMPCNTRWIDTH:0] samps_hi_ns;
always @(posedge clk) samps_hi_r <= #TCQ samps_hi_ns;
reg [SAMPCNTRWIDTH:0] samps_hi_held_r;
reg [SAMPCNTRWIDTH:0] samps_hi_held_ns;
always @(posedge clk) samps_hi_held_r <= #TCQ samps_hi_held_ns;
output [SAMPCNTRWIDTH:0] samps_hi_held;
assign samps_hi_held = samps_hi_held_r;
reg [TAPCNTRWIDTH-1:0] tap_ns, tap_r;
always @(posedge clk) tap_r <= #TCQ tap_ns;
output [TAPCNTRWIDTH-1:0] tap;
assign tap = tap_r;
localparam SMWIDTH = 2;
reg [SMWIDTH-1:0] sm_ns;
reg [SMWIDTH-1:0] sm_r;
always @(posedge clk) sm_r <= #TCQ sm_ns;
reg samps_zero_ns, samps_zero_r, samps_one_ns, samps_one_r;
always @(posedge clk) samps_zero_r <= #TCQ samps_zero_ns;
always @(posedge clk)samps_one_r <= #TCQ samps_one_ns;
// Interesting corner case... what if both samps_zero and samps_one are
// hi? Could happen for small sample counts and reasonable values of
// PCT_SAMPS_SOLID. Doesn't affect samps_solid. run_polarity assignment
// consistently breaks tie with samps_one_r.
wire [SAMPCNTRWIDTH:0] samps_lo = samples + ONE[SAMPCNTRWIDTH:0] - samps_hi_r;
always @(*) begin
samps_zero_ns = samps_zero_r;
samps_one_ns = samps_one_r;
samps_zero_ns = samps_lo >= samps_solid_thresh;
samps_one_ns = samps_hi_r >= samps_solid_thresh;
end // always @ begin
wire new_polarity = run_polarity_ns ^ run_polarity_r;
input poc_sample_pd;
always @(*) begin
if (rst == 1'b1) begin
// RESET next states
psen_int = 1'b0;
sm_ns = /*AUTOLINK("SAMPLE")*/2'd0;
run_polarity_ns = 1'b0;
run_ns = {TAPCNTRWIDTH{1'b0}};
run_end_int = 1'b0;
samp_cntr_ns = {SAMPCNTRWIDTH{1'b0}};
samps_hi_ns = {SAMPCNTRWIDTH+1{1'b0}};
tap_ns = {TAPCNTRWIDTH{1'b0}};
samp_wait_ns = MMCM_SAMP_WAIT[SAMP_WAIT_WIDTH-1:0];
samps_hi_held_ns = {SAMPCNTRWIDTH+1{1'b0}};
end else begin
// Default next states;
psen_int = 1'b0;
sm_ns = sm_r;
run_polarity_ns = run_polarity_r;
run_ns = run_r;
run_end_int = 1'b0;
samp_cntr_ns = samp_cntr_r;
samps_hi_ns = samps_hi_r;
tap_ns = tap_r;
samp_wait_ns = samp_wait_r;
if (|samp_wait_r) samp_wait_ns = samp_wait_r - ONE[SAMP_WAIT_WIDTH-1:0];
samps_hi_held_ns = samps_hi_held_r;
// State based actions and next states.
case (sm_r)
/*AL("SAMPLE")*/2'd0: begin
if (~|samp_wait_r && poc_sample_pd | POC_USE_METASTABLE_SAMP == "TRUE") begin
if (POC_USE_METASTABLE_SAMP == "TRUE") samp_wait_ns = ONE[SAMP_WAIT_WIDTH-1:0];
if ({1'b0, samp_cntr_r} == samples) sm_ns = /*AK("COMPUTE")*/2'd1;
samps_hi_ns = samps_hi_r + {{SAMPCNTRWIDTH{1'b0}}, pd_out_sel};
samp_cntr_ns = samp_cntr_r + ONE[SAMPCNTRWIDTH-1:0];
end
end
/*AL("COMPUTE")*/2'd1:begin
sm_ns = /*AK("PSEN")*/2'd2;
end
/*AL("PSEN")*/2'd2:begin
sm_ns = /*AK("PSDONE_WAIT")*/2'd3;
psen_int = 1'b1;
samp_cntr_ns = {SAMPCNTRWIDTH{1'b0}};
samps_hi_ns = {SAMPCNTRWIDTH+1{1'b0}};
samps_hi_held_ns = samps_hi_r;
tap_ns = (tap_r < TAPSPERKCLK[TAPCNTRWIDTH-1:0] - ONE[TAPCNTRWIDTH-1:0])
? tap_r + ONE[TAPCNTRWIDTH-1:0]
: {TAPCNTRWIDTH{1'b0}};
if (run_polarity_r) begin
if (samps_zero_r) run_polarity_ns = 1'b0;
end else begin
if (samps_one_r) run_polarity_ns = 1'b1;
end
if (new_polarity) begin
run_ns ={TAPCNTRWIDTH{1'b0}};
run_end_int = 1'b1;
end else run_ns = run_r + ONE[TAPCNTRWIDTH-1:0];
end
/*AL("PSDONE_WAIT")*/2'd3:begin
samp_wait_ns = MMCM_SAMP_WAIT[SAMP_WAIT_WIDTH-1:0] - ONE[SAMP_WAIT_WIDTH-1:0];
if (psdone) sm_ns = /*AK("SAMPLE")*/2'd0;
end
endcase // case (sm_r)
end // else: !if(rst == 1'b1)
end // always @ (*)
endmodule
|
module mig_7series_v2_3_poc_tap_base #
(parameter MMCM_SAMP_WAIT = 10,
parameter POC_USE_METASTABLE_SAMP = "FALSE",
parameter TCQ = 100,
parameter SAMPCNTRWIDTH = 8,
parameter TAPCNTRWIDTH = 7,
parameter TAPSPERKCLK = 112)
(/*AUTOARG*/
// Outputs
psincdec, psen, run, run_end, run_polarity, samps_hi_held, tap,
// Inputs
pd_out, clk, samples, samps_solid_thresh, psdone, rst,
poc_sample_pd
);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
input pd_out;
input clk;
input [SAMPCNTRWIDTH:0] samples, samps_solid_thresh;
input psdone;
input rst;
localparam ONE = 1;
localparam SAMP_WAIT_WIDTH = clogb2(MMCM_SAMP_WAIT);
reg [SAMP_WAIT_WIDTH-1:0] samp_wait_ns, samp_wait_r;
always @(posedge clk) samp_wait_r <= #TCQ samp_wait_ns;
reg pd_out_r;
always @(posedge clk) pd_out_r <= #TCQ pd_out;
wire pd_out_sel = POC_USE_METASTABLE_SAMP == "TRUE" ? pd_out_r : pd_out;
output psincdec;
assign psincdec = 1'b1;
output psen;
reg psen_int;
assign psen = psen_int;
reg [TAPCNTRWIDTH-1:0] run_r;
reg [TAPCNTRWIDTH-1:0] run_ns;
always @(posedge clk) run_r <= #TCQ run_ns;
output [TAPCNTRWIDTH-1:0] run;
assign run = run_r;
output run_end;
reg run_end_int;
assign run_end = run_end_int;
reg run_polarity_r;
reg run_polarity_ns;
always @(posedge clk) run_polarity_r <= #TCQ run_polarity_ns;
output run_polarity;
assign run_polarity = run_polarity_r;
reg [SAMPCNTRWIDTH-1:0] samp_cntr_r;
reg [SAMPCNTRWIDTH-1:0] samp_cntr_ns;
always @(posedge clk) samp_cntr_r <= #TCQ samp_cntr_ns;
reg [SAMPCNTRWIDTH:0] samps_hi_r;
reg [SAMPCNTRWIDTH:0] samps_hi_ns;
always @(posedge clk) samps_hi_r <= #TCQ samps_hi_ns;
reg [SAMPCNTRWIDTH:0] samps_hi_held_r;
reg [SAMPCNTRWIDTH:0] samps_hi_held_ns;
always @(posedge clk) samps_hi_held_r <= #TCQ samps_hi_held_ns;
output [SAMPCNTRWIDTH:0] samps_hi_held;
assign samps_hi_held = samps_hi_held_r;
reg [TAPCNTRWIDTH-1:0] tap_ns, tap_r;
always @(posedge clk) tap_r <= #TCQ tap_ns;
output [TAPCNTRWIDTH-1:0] tap;
assign tap = tap_r;
localparam SMWIDTH = 2;
reg [SMWIDTH-1:0] sm_ns;
reg [SMWIDTH-1:0] sm_r;
always @(posedge clk) sm_r <= #TCQ sm_ns;
reg samps_zero_ns, samps_zero_r, samps_one_ns, samps_one_r;
always @(posedge clk) samps_zero_r <= #TCQ samps_zero_ns;
always @(posedge clk)samps_one_r <= #TCQ samps_one_ns;
// Interesting corner case... what if both samps_zero and samps_one are
// hi? Could happen for small sample counts and reasonable values of
// PCT_SAMPS_SOLID. Doesn't affect samps_solid. run_polarity assignment
// consistently breaks tie with samps_one_r.
wire [SAMPCNTRWIDTH:0] samps_lo = samples + ONE[SAMPCNTRWIDTH:0] - samps_hi_r;
always @(*) begin
samps_zero_ns = samps_zero_r;
samps_one_ns = samps_one_r;
samps_zero_ns = samps_lo >= samps_solid_thresh;
samps_one_ns = samps_hi_r >= samps_solid_thresh;
end // always @ begin
wire new_polarity = run_polarity_ns ^ run_polarity_r;
input poc_sample_pd;
always @(*) begin
if (rst == 1'b1) begin
// RESET next states
psen_int = 1'b0;
sm_ns = /*AUTOLINK("SAMPLE")*/2'd0;
run_polarity_ns = 1'b0;
run_ns = {TAPCNTRWIDTH{1'b0}};
run_end_int = 1'b0;
samp_cntr_ns = {SAMPCNTRWIDTH{1'b0}};
samps_hi_ns = {SAMPCNTRWIDTH+1{1'b0}};
tap_ns = {TAPCNTRWIDTH{1'b0}};
samp_wait_ns = MMCM_SAMP_WAIT[SAMP_WAIT_WIDTH-1:0];
samps_hi_held_ns = {SAMPCNTRWIDTH+1{1'b0}};
end else begin
// Default next states;
psen_int = 1'b0;
sm_ns = sm_r;
run_polarity_ns = run_polarity_r;
run_ns = run_r;
run_end_int = 1'b0;
samp_cntr_ns = samp_cntr_r;
samps_hi_ns = samps_hi_r;
tap_ns = tap_r;
samp_wait_ns = samp_wait_r;
if (|samp_wait_r) samp_wait_ns = samp_wait_r - ONE[SAMP_WAIT_WIDTH-1:0];
samps_hi_held_ns = samps_hi_held_r;
// State based actions and next states.
case (sm_r)
/*AL("SAMPLE")*/2'd0: begin
if (~|samp_wait_r && poc_sample_pd | POC_USE_METASTABLE_SAMP == "TRUE") begin
if (POC_USE_METASTABLE_SAMP == "TRUE") samp_wait_ns = ONE[SAMP_WAIT_WIDTH-1:0];
if ({1'b0, samp_cntr_r} == samples) sm_ns = /*AK("COMPUTE")*/2'd1;
samps_hi_ns = samps_hi_r + {{SAMPCNTRWIDTH{1'b0}}, pd_out_sel};
samp_cntr_ns = samp_cntr_r + ONE[SAMPCNTRWIDTH-1:0];
end
end
/*AL("COMPUTE")*/2'd1:begin
sm_ns = /*AK("PSEN")*/2'd2;
end
/*AL("PSEN")*/2'd2:begin
sm_ns = /*AK("PSDONE_WAIT")*/2'd3;
psen_int = 1'b1;
samp_cntr_ns = {SAMPCNTRWIDTH{1'b0}};
samps_hi_ns = {SAMPCNTRWIDTH+1{1'b0}};
samps_hi_held_ns = samps_hi_r;
tap_ns = (tap_r < TAPSPERKCLK[TAPCNTRWIDTH-1:0] - ONE[TAPCNTRWIDTH-1:0])
? tap_r + ONE[TAPCNTRWIDTH-1:0]
: {TAPCNTRWIDTH{1'b0}};
if (run_polarity_r) begin
if (samps_zero_r) run_polarity_ns = 1'b0;
end else begin
if (samps_one_r) run_polarity_ns = 1'b1;
end
if (new_polarity) begin
run_ns ={TAPCNTRWIDTH{1'b0}};
run_end_int = 1'b1;
end else run_ns = run_r + ONE[TAPCNTRWIDTH-1:0];
end
/*AL("PSDONE_WAIT")*/2'd3:begin
samp_wait_ns = MMCM_SAMP_WAIT[SAMP_WAIT_WIDTH-1:0] - ONE[SAMP_WAIT_WIDTH-1:0];
if (psdone) sm_ns = /*AK("SAMPLE")*/2'd0;
end
endcase // case (sm_r)
end // else: !if(rst == 1'b1)
end // always @ (*)
endmodule
|
module outputs)
wire [3:0] ram_init_addr; // From ui_rd_data0 of ui_rd_data.v
wire ram_init_done_r; // From ui_rd_data0 of ui_rd_data.v
wire rd_accepted; // From ui_cmd0 of ui_cmd.v
wire rd_buf_full; // From ui_rd_data0 of ui_rd_data.v
wire [DATA_BUF_ADDR_WIDTH-1:0]rd_data_buf_addr_r;// From ui_rd_data0 of ui_rd_data.v
wire wr_accepted; // From ui_cmd0 of ui_cmd.v
wire [DATA_BUF_ADDR_WIDTH-1:0] wr_data_buf_addr;// From ui_wr_data0 of ui_wr_data.v
wire wr_req_16; // From ui_wr_data0 of ui_wr_data.v
// End of automatics
// In the UI, the read and write buffers are allowed to be asymmetric to
// to maximize read performance, but the MC's native interface requires
// symmetry, so we zero-fill the write pointer
generate
if(DATA_BUF_ADDR_WIDTH > 4) begin
assign wr_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:4] = 0;
end
endgenerate
mig_7series_v2_3_ui_cmd #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.ADDR_WIDTH (ADDR_WIDTH),
.BANK_WIDTH (BANK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.RANK_WIDTH (RANK_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.RANKS (RANKS),
.MEM_ADDR_ORDER (MEM_ADDR_ORDER))
ui_cmd0
(/*AUTOINST*/
// Outputs
.app_rdy (app_rdy),
.use_addr (use_addr),
.rank (rank[RANK_WIDTH-1:0]),
.bank (bank[BANK_WIDTH-1:0]),
.row (row[ROW_WIDTH-1:0]),
.col (col[COL_WIDTH-1:0]),
.size (size),
.cmd (cmd[2:0]),
.hi_priority (hi_priority),
.rd_accepted (rd_accepted),
.wr_accepted (wr_accepted),
.data_buf_addr (data_buf_addr),
// Inputs
.rst (rst),
.clk (clk),
.accept_ns (accept_ns),
.rd_buf_full (rd_buf_full),
.wr_req_16 (wr_req_16),
.app_addr (app_addr[ADDR_WIDTH-1:0]),
.app_cmd (app_cmd[2:0]),
.app_sz (app_sz),
.app_hi_pri (app_hi_pri),
.app_en (app_en),
.wr_data_buf_addr (wr_data_buf_addr),
.rd_data_buf_addr_r (rd_data_buf_addr_r));
mig_7series_v2_3_ui_wr_data #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.APP_DATA_WIDTH (APP_DATA_WIDTH),
.APP_MASK_WIDTH (APP_MASK_WIDTH),
.nCK_PER_CLK (nCK_PER_CLK),
.ECC (ECC),
.ECC_TEST (ECC_TEST),
.CWL (CWL_M))
ui_wr_data0
(/*AUTOINST*/
// Outputs
.app_wdf_rdy (app_wdf_rdy),
.wr_req_16 (wr_req_16),
.wr_data_buf_addr (wr_data_buf_addr[3:0]),
.wr_data (wr_data[APP_DATA_WIDTH-1:0]),
.wr_data_mask (wr_data_mask[APP_MASK_WIDTH-1:0]),
.raw_not_ecc (raw_not_ecc[2*nCK_PER_CLK-1:0]),
// Inputs
.rst (rst),
.clk (clk),
.app_wdf_data (app_wdf_data[APP_DATA_WIDTH-1:0]),
.app_wdf_mask (app_wdf_mask[APP_MASK_WIDTH-1:0]),
.app_raw_not_ecc (app_raw_not_ecc[2*nCK_PER_CLK-1:0]),
.app_wdf_wren (app_wdf_wren),
.app_wdf_end (app_wdf_end),
.wr_data_offset (wr_data_offset),
.wr_data_addr (wr_data_addr[3:0]),
.wr_data_en (wr_data_en),
.wr_accepted (wr_accepted),
.ram_init_done_r (ram_init_done_r),
.ram_init_addr (ram_init_addr));
mig_7series_v2_3_ui_rd_data #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.APP_DATA_WIDTH (APP_DATA_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.nCK_PER_CLK (nCK_PER_CLK),
.ECC (ECC),
.ORDERING (ORDERING))
ui_rd_data0
(/*AUTOINST*/
// Outputs
.ram_init_done_r (ram_init_done_r),
.ram_init_addr (ram_init_addr),
.app_rd_data_valid (app_rd_data_valid),
.app_rd_data_end (app_rd_data_end),
.app_rd_data (app_rd_data[APP_DATA_WIDTH-1:0]),
.app_ecc_multiple_err (app_ecc_multiple_err[2*nCK_PER_CLK-1:0]),
.rd_buf_full (rd_buf_full),
.rd_data_buf_addr_r (rd_data_buf_addr_r),
// Inputs
.rst (rst),
.clk (clk),
.rd_data_en (rd_data_en),
.rd_data_addr (rd_data_addr),
.rd_data_offset (rd_data_offset),
.rd_data_end (rd_data_end),
.rd_data (rd_data[APP_DATA_WIDTH-1:0]),
.ecc_multiple (ecc_multiple[3:0]),
.rd_accepted (rd_accepted));
endmodule
|
module outputs)
wire [3:0] ram_init_addr; // From ui_rd_data0 of ui_rd_data.v
wire ram_init_done_r; // From ui_rd_data0 of ui_rd_data.v
wire rd_accepted; // From ui_cmd0 of ui_cmd.v
wire rd_buf_full; // From ui_rd_data0 of ui_rd_data.v
wire [DATA_BUF_ADDR_WIDTH-1:0]rd_data_buf_addr_r;// From ui_rd_data0 of ui_rd_data.v
wire wr_accepted; // From ui_cmd0 of ui_cmd.v
wire [DATA_BUF_ADDR_WIDTH-1:0] wr_data_buf_addr;// From ui_wr_data0 of ui_wr_data.v
wire wr_req_16; // From ui_wr_data0 of ui_wr_data.v
// End of automatics
// In the UI, the read and write buffers are allowed to be asymmetric to
// to maximize read performance, but the MC's native interface requires
// symmetry, so we zero-fill the write pointer
generate
if(DATA_BUF_ADDR_WIDTH > 4) begin
assign wr_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:4] = 0;
end
endgenerate
mig_7series_v2_3_ui_cmd #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.ADDR_WIDTH (ADDR_WIDTH),
.BANK_WIDTH (BANK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.RANK_WIDTH (RANK_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.RANKS (RANKS),
.MEM_ADDR_ORDER (MEM_ADDR_ORDER))
ui_cmd0
(/*AUTOINST*/
// Outputs
.app_rdy (app_rdy),
.use_addr (use_addr),
.rank (rank[RANK_WIDTH-1:0]),
.bank (bank[BANK_WIDTH-1:0]),
.row (row[ROW_WIDTH-1:0]),
.col (col[COL_WIDTH-1:0]),
.size (size),
.cmd (cmd[2:0]),
.hi_priority (hi_priority),
.rd_accepted (rd_accepted),
.wr_accepted (wr_accepted),
.data_buf_addr (data_buf_addr),
// Inputs
.rst (rst),
.clk (clk),
.accept_ns (accept_ns),
.rd_buf_full (rd_buf_full),
.wr_req_16 (wr_req_16),
.app_addr (app_addr[ADDR_WIDTH-1:0]),
.app_cmd (app_cmd[2:0]),
.app_sz (app_sz),
.app_hi_pri (app_hi_pri),
.app_en (app_en),
.wr_data_buf_addr (wr_data_buf_addr),
.rd_data_buf_addr_r (rd_data_buf_addr_r));
mig_7series_v2_3_ui_wr_data #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.APP_DATA_WIDTH (APP_DATA_WIDTH),
.APP_MASK_WIDTH (APP_MASK_WIDTH),
.nCK_PER_CLK (nCK_PER_CLK),
.ECC (ECC),
.ECC_TEST (ECC_TEST),
.CWL (CWL_M))
ui_wr_data0
(/*AUTOINST*/
// Outputs
.app_wdf_rdy (app_wdf_rdy),
.wr_req_16 (wr_req_16),
.wr_data_buf_addr (wr_data_buf_addr[3:0]),
.wr_data (wr_data[APP_DATA_WIDTH-1:0]),
.wr_data_mask (wr_data_mask[APP_MASK_WIDTH-1:0]),
.raw_not_ecc (raw_not_ecc[2*nCK_PER_CLK-1:0]),
// Inputs
.rst (rst),
.clk (clk),
.app_wdf_data (app_wdf_data[APP_DATA_WIDTH-1:0]),
.app_wdf_mask (app_wdf_mask[APP_MASK_WIDTH-1:0]),
.app_raw_not_ecc (app_raw_not_ecc[2*nCK_PER_CLK-1:0]),
.app_wdf_wren (app_wdf_wren),
.app_wdf_end (app_wdf_end),
.wr_data_offset (wr_data_offset),
.wr_data_addr (wr_data_addr[3:0]),
.wr_data_en (wr_data_en),
.wr_accepted (wr_accepted),
.ram_init_done_r (ram_init_done_r),
.ram_init_addr (ram_init_addr));
mig_7series_v2_3_ui_rd_data #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.APP_DATA_WIDTH (APP_DATA_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.nCK_PER_CLK (nCK_PER_CLK),
.ECC (ECC),
.ORDERING (ORDERING))
ui_rd_data0
(/*AUTOINST*/
// Outputs
.ram_init_done_r (ram_init_done_r),
.ram_init_addr (ram_init_addr),
.app_rd_data_valid (app_rd_data_valid),
.app_rd_data_end (app_rd_data_end),
.app_rd_data (app_rd_data[APP_DATA_WIDTH-1:0]),
.app_ecc_multiple_err (app_ecc_multiple_err[2*nCK_PER_CLK-1:0]),
.rd_buf_full (rd_buf_full),
.rd_data_buf_addr_r (rd_data_buf_addr_r),
// Inputs
.rst (rst),
.clk (clk),
.rd_data_en (rd_data_en),
.rd_data_addr (rd_data_addr),
.rd_data_offset (rd_data_offset),
.rd_data_end (rd_data_end),
.rd_data (rd_data[APP_DATA_WIDTH-1:0]),
.ecc_multiple (ecc_multiple[3:0]),
.rd_accepted (rd_accepted));
endmodule
|
module mig_7series_v2_3_memc_ui_top_std #
(
parameter TCQ = 100,
parameter DDR3_VDD_OP_VOLT = "135", // Voltage mode used for DDR3
parameter PAYLOAD_WIDTH = 64,
parameter ADDR_CMD_MODE = "UNBUF",
parameter AL = "0", // Additive Latency option
parameter BANK_WIDTH = 3, // # of bank bits
parameter BM_CNT_WIDTH = 2, // Bank machine counter width
parameter BURST_MODE = "8", // Burst length
parameter BURST_TYPE = "SEQ", // Burst type
parameter CA_MIRROR = "OFF", // C/A mirror opt for DDR3 dual rank
parameter CK_WIDTH = 1, // # of CK/CK# outputs to memory
parameter CL = 5,
parameter COL_WIDTH = 12, // column address width
parameter CMD_PIPE_PLUS1 = "ON", // add pipeline stage between MC and PHY
parameter CS_WIDTH = 1, // # of unique CS outputs
parameter CKE_WIDTH = 1, // # of cke outputs
parameter CWL = 5,
parameter DATA_WIDTH = 64,
parameter DATA_BUF_ADDR_WIDTH = 5,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DDR2_DQSN_ENABLE = "YES", // Enable differential DQS for DDR2
parameter DM_WIDTH = 8, // # of DM (data mask)
parameter DQ_CNT_WIDTH = 6, // = ceil(log2(DQ_WIDTH))
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_TYPE = "DDR3",
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter ECC = "OFF",
parameter ECC_WIDTH = 8,
parameter ECC_TEST = "OFF",
parameter MC_ERR_ADDR_WIDTH = 31,
parameter MASTER_PHY_CTL = 0, // The bank number where master PHY_CONTROL resides
parameter nAL = 0, // Additive latency (in clk cyc)
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2, // # of memory CKs per fabric CLK
parameter nCS_PER_RANK = 1, // # of unique CS outputs per rank
parameter ORDERING = "NORM",
parameter IBUF_LPWR_MODE = "OFF",
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter DATA_IO_PRIM_TYPE = "DEFAULT", // # = "HP_LP", "HR_LP", "DEFAULT"
parameter DATA_IO_IDLE_PWRDWN = "ON", // "ON" or "OFF"
parameter IODELAY_GRP0 = "IODELAY_MIG0",
parameter IODELAY_GRP1 = "IODELAY_MIG1",
parameter FPGA_SPEED_GRADE = 1,
parameter OUTPUT_DRV = "HIGH",
parameter REG_CTRL = "OFF",
parameter RTT_NOM = "60",
parameter RTT_WR = "120",
parameter STARVE_LIMIT = 2,
parameter tCK = 2500, // pS
parameter tCKE = 10000, // pS
parameter tFAW = 40000, // pS
parameter tPRDI = 1_000_000, // pS
parameter tRAS = 37500, // pS
parameter tRCD = 12500, // pS
parameter tREFI = 7800000, // pS
parameter tRFC = 110000, // pS
parameter tRP = 12500, // pS
parameter tRRD = 10000, // pS
parameter tRTP = 7500, // pS
parameter tWTR = 7500, // pS
parameter tZQI = 128_000_000, // nS
parameter tZQCS = 64, // CKs
parameter USER_REFRESH = "OFF", // Whether user manages REF
parameter TEMP_MON_EN = "ON", // Enable/Disable tempmon
parameter WRLVL = "OFF",
parameter DEBUG_PORT = "OFF",
parameter CAL_WIDTH = "HALF",
parameter RANK_WIDTH = 1,
parameter RANKS = 4,
parameter ODT_WIDTH = 1,
parameter ROW_WIDTH = 16, // DRAM address bus width
parameter ADDR_WIDTH = 32,
parameter APP_MASK_WIDTH = 8,
parameter APP_DATA_WIDTH = 64,
parameter [3:0] BYTE_LANES_B0 = 4'b1111,
parameter [3:0] BYTE_LANES_B1 = 4'b1111,
parameter [3:0] BYTE_LANES_B2 = 4'b1111,
parameter [3:0] BYTE_LANES_B3 = 4'b1111,
parameter [3:0] BYTE_LANES_B4 = 4'b1111,
parameter [3:0] DATA_CTL_B0 = 4'hc,
parameter [3:0] DATA_CTL_B1 = 4'hf,
parameter [3:0] DATA_CTL_B2 = 4'hf,
parameter [3:0] DATA_CTL_B3 = 4'h0,
parameter [3:0] DATA_CTL_B4 = 4'h0,
parameter [47:0] PHY_0_BITLANES = 48'h0000_0000_0000,
parameter [47:0] PHY_1_BITLANES = 48'h0000_0000_0000,
parameter [47:0] PHY_2_BITLANES = 48'h0000_0000_0000,
// control/address/data pin mapping parameters
parameter [143:0] CK_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter [191:0] ADDR_MAP
= 192'h000_000_000_000_000_000_000_000_000_000_000_000_000_000_000_000,
parameter [35:0] BANK_MAP = 36'h000_000_000,
parameter [11:0] CAS_MAP = 12'h000,
parameter [7:0] CKE_ODT_BYTE_MAP = 8'h00,
parameter [95:0] CKE_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] ODT_MAP = 96'h000_000_000_000_000_000_000_000,
parameter CKE_ODT_AUX = "FALSE",
parameter [119:0] CS_MAP = 120'h000_000_000_000_000_000_000_000_000_000,
parameter [11:0] PARITY_MAP = 12'h000,
parameter [11:0] RAS_MAP = 12'h000,
parameter [11:0] WE_MAP = 12'h000,
parameter [143:0] DQS_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter [95:0] DATA0_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA1_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA2_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA3_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA4_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA5_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA6_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA7_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA8_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA9_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA10_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA11_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA12_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA13_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA14_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA15_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA16_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA17_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [107:0] MASK0_MAP = 108'h000_000_000_000_000_000_000_000_000,
parameter [107:0] MASK1_MAP = 108'h000_000_000_000_000_000_000_000_000,
parameter [7:0] SLOT_0_CONFIG = 8'b0000_0001,
parameter [7:0] SLOT_1_CONFIG = 8'b0000_0000,
parameter MEM_ADDR_ORDER = "BANK_ROW_COLUMN",
// calibration Address. The address given below will be used for calibration
// read and write operations.
parameter [15:0] CALIB_ROW_ADD = 16'h0000, // Calibration row address
parameter [11:0] CALIB_COL_ADD = 12'h000, // Calibration column address
parameter [2:0] CALIB_BA_ADD = 3'h0, // Calibration bank address
parameter SIM_BYPASS_INIT_CAL = "OFF",
parameter REFCLK_FREQ = 300.0,
parameter USE_CS_PORT = 1, // Support chip select output
parameter USE_DM_PORT = 1, // Support data mask output
parameter USE_ODT_PORT = 1, // Support ODT output
parameter IDELAY_ADJ = "ON", //ON : IDELAY-1, OFF: No change
parameter FINE_PER_BIT = "ON", //ON : Use per bit calib for complex rdlvl
parameter CENTER_COMP_MODE = "ON", //ON: use PI stg2 tap compensation
parameter PI_VAL_ADJ = "ON", //ON: PI stg2 tap -1 for centering
parameter TAPSPERKCLK = 56
)
(
// Clock and reset ports
input clk,
input [1:0] clk_ref,
input mem_refclk ,
input freq_refclk ,
input pll_lock,
input sync_pulse ,
input mmcm_ps_clk,
input poc_sample_pd,
input rst,
// memory interface ports
inout [DQ_WIDTH-1:0] ddr_dq,
inout [DQS_WIDTH-1:0] ddr_dqs_n,
inout [DQS_WIDTH-1:0] ddr_dqs,
output [ROW_WIDTH-1:0] ddr_addr,
output [BANK_WIDTH-1:0] ddr_ba,
output ddr_cas_n,
output [CK_WIDTH-1:0] ddr_ck_n,
output [CK_WIDTH-1:0] ddr_ck,
output [CKE_WIDTH-1:0] ddr_cke,
output [CS_WIDTH*nCS_PER_RANK-1:0] ddr_cs_n,
output [DM_WIDTH-1:0] ddr_dm,
output [ODT_WIDTH-1:0] ddr_odt,
output ddr_ras_n,
output ddr_reset_n,
output ddr_parity,
output ddr_we_n,
output [BM_CNT_WIDTH-1:0] bank_mach_next,
// user interface ports
input [ADDR_WIDTH-1:0] app_addr,
input [2:0] app_cmd,
input app_en,
input app_hi_pri,
input [APP_DATA_WIDTH-1:0] app_wdf_data,
input app_wdf_end,
input [APP_MASK_WIDTH-1:0] app_wdf_mask,
input app_wdf_wren,
input app_correct_en_i,
input [2*nCK_PER_CLK-1:0] app_raw_not_ecc,
output [2*nCK_PER_CLK-1:0] app_ecc_multiple_err,
output [APP_DATA_WIDTH-1:0] app_rd_data,
output app_rd_data_end,
output app_rd_data_valid,
output app_rdy,
output app_wdf_rdy,
input app_sr_req,
output app_sr_active,
input app_ref_req,
output app_ref_ack,
input app_zq_req,
output app_zq_ack,
// temperature monitor ports
input [11:0] device_temp,
//phase shift clock control
output psen,
output psincdec,
input psdone,
// debug logic ports
input dbg_idel_down_all,
input dbg_idel_down_cpt,
input dbg_idel_up_all,
input dbg_idel_up_cpt,
input dbg_sel_all_idel_cpt,
input [DQS_CNT_WIDTH-1:0] dbg_sel_idel_cpt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_first_edge_cnt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_second_edge_cnt,
output [DQS_WIDTH-1:0] dbg_rd_data_edge_detect,
output [2*nCK_PER_CLK*DQ_WIDTH-1:0] dbg_rddata,
output [1:0] dbg_rdlvl_done,
output [1:0] dbg_rdlvl_err,
output [1:0] dbg_rdlvl_start,
output [5:0] dbg_tap_cnt_during_wrlvl,
output dbg_wl_edge_detect_valid,
output dbg_wrlvl_done,
output dbg_wrlvl_err,
output dbg_wrlvl_start,
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output init_calib_complete,
input dbg_sel_pi_incdec,
input dbg_sel_po_incdec,
input [DQS_CNT_WIDTH:0] dbg_byte_sel,
input dbg_pi_f_inc,
input dbg_pi_f_dec,
input dbg_po_f_inc,
input dbg_po_f_stg23_sel,
input dbg_po_f_dec,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_tap_cnt,
output [5*DQS_WIDTH*RANKS-1:0] dbg_dq_idelay_tap_cnt,
output dbg_rddata_valid,
output [6*DQS_WIDTH-1:0] dbg_wrlvl_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_wrlvl_coarse_tap_cnt,
output ref_dll_lock,
input rst_phaser_ref,
input iddr_rst,
output [6*RANKS-1:0] dbg_rd_data_offset,
output [255:0] dbg_calib_top,
output [255:0] dbg_phy_wrlvl,
output [255:0] dbg_phy_rdlvl,
output [99:0] dbg_phy_wrcal,
output [255:0] dbg_phy_init,
output [255:0] dbg_prbs_rdlvl,
output [255:0] dbg_dqs_found_cal,
output [5:0] dbg_pi_counter_read_val,
output [8:0] dbg_po_counter_read_val,
output dbg_pi_phaselock_start,
output dbg_pi_phaselocked_done,
output dbg_pi_phaselock_err,
output dbg_pi_dqsfound_start,
output dbg_pi_dqsfound_done,
output dbg_pi_dqsfound_err,
output dbg_wrcal_start,
output dbg_wrcal_done,
output dbg_wrcal_err,
output [11:0] dbg_pi_dqs_found_lanes_phy4lanes,
output [11:0] dbg_pi_phase_locked_phy4lanes,
output [6*RANKS-1:0] dbg_calib_rd_data_offset_1,
output [6*RANKS-1:0] dbg_calib_rd_data_offset_2,
output [5:0] dbg_data_offset,
output [5:0] dbg_data_offset_1,
output [5:0] dbg_data_offset_2,
output dbg_oclkdelay_calib_start,
output dbg_oclkdelay_calib_done,
output [255:0] dbg_phy_oclkdelay_cal,
output [DRAM_WIDTH*16 -1:0] dbg_oclkdelay_rd_data,
output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_final_dqs_tap_cnt_r,
output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps,
output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps
);
localparam IODELAY_GRP = (tCK <= 1500)? IODELAY_GRP1 : IODELAY_GRP0;
// wire [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r;
// wire [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps;
// wire [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps;
wire correct_en;
wire [2*nCK_PER_CLK-1:0] raw_not_ecc;
wire [2*nCK_PER_CLK-1:0] ecc_single;
wire [2*nCK_PER_CLK-1:0] ecc_multiple;
wire [MC_ERR_ADDR_WIDTH-1:0] ecc_err_addr;
wire [DQ_WIDTH/8-1:0] fi_xor_we;
wire [DQ_WIDTH-1:0] fi_xor_wrdata;
wire [DATA_BUF_OFFSET_WIDTH-1:0] wr_data_offset;
wire wr_data_en;
wire [DATA_BUF_ADDR_WIDTH-1:0] wr_data_addr;
wire [DATA_BUF_OFFSET_WIDTH-1:0] rd_data_offset;
wire rd_data_en;
wire [DATA_BUF_ADDR_WIDTH-1:0] rd_data_addr;
wire accept;
wire accept_ns;
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] rd_data;
wire rd_data_end;
wire use_addr;
wire size;
wire [ROW_WIDTH-1:0] row;
wire [RANK_WIDTH-1:0] rank;
wire hi_priority;
wire [DATA_BUF_ADDR_WIDTH-1:0] data_buf_addr;
wire [COL_WIDTH-1:0] col;
wire [2:0] cmd;
wire [BANK_WIDTH-1:0] bank;
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data;
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH/8-1:0] wr_data_mask;
wire app_sr_req_i;
wire app_sr_active_i;
wire app_ref_req_i;
wire app_ref_ack_i;
wire app_zq_req_i;
wire app_zq_ack_i;
wire rst_tg_mc;
wire error;
wire init_wrcal_complete;
reg reset /* synthesis syn_maxfan = 10 */;
//***************************************************************************
always @(posedge clk)
reset <= #TCQ (rst | rst_tg_mc);
assign fi_xor_we = {DQ_WIDTH/8{1'b0}} ;
assign fi_xor_wrdata = {DQ_WIDTH{1'b0}} ;
mig_7series_v2_3_mem_intfc #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.PAYLOAD_WIDTH (PAYLOAD_WIDTH),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.AL (AL),
.BANK_WIDTH (BANK_WIDTH),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.CA_MIRROR (CA_MIRROR),
.CK_WIDTH (CK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.CMD_PIPE_PLUS1 (CMD_PIPE_PLUS1),
.CS_WIDTH (CS_WIDTH),
.nCS_PER_RANK (nCS_PER_RANK),
.CKE_WIDTH (CKE_WIDTH),
.DATA_WIDTH (DATA_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DATA_BUF_OFFSET_WIDTH (DATA_BUF_OFFSET_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.DM_WIDTH (DM_WIDTH),
.DQ_CNT_WIDTH (DQ_CNT_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.DRAM_WIDTH (DRAM_WIDTH),
.ECC (ECC),
.ECC_WIDTH (ECC_WIDTH),
.MC_ERR_ADDR_WIDTH (MC_ERR_ADDR_WIDTH),
.REFCLK_FREQ (REFCLK_FREQ),
.nAL (nAL),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.ORDERING (ORDERING),
.OUTPUT_DRV (OUTPUT_DRV),
.IBUF_LPWR_MODE (IBUF_LPWR_MODE),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN (DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.REG_CTRL (REG_CTRL),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.CL (CL),
.CWL (CWL),
.tCK (tCK),
.tCKE (tCKE),
.tFAW (tFAW),
.tPRDI (tPRDI),
.tRAS (tRAS),
.tRCD (tRCD),
.tREFI (tREFI),
.tRFC (tRFC),
.tRP (tRP),
.tRRD (tRRD),
.tRTP (tRTP),
.tWTR (tWTR),
.tZQI (tZQI),
.tZQCS (tZQCS),
.USER_REFRESH (USER_REFRESH),
.TEMP_MON_EN (TEMP_MON_EN),
.WRLVL (WRLVL),
.DEBUG_PORT (DEBUG_PORT),
.CAL_WIDTH (CAL_WIDTH),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.SIM_BYPASS_INIT_CAL (SIM_BYPASS_INIT_CAL),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.SLOT_0_CONFIG (SLOT_0_CONFIG),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.STARVE_LIMIT (STARVE_LIMIT),
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK)
)
mem_intfc0
(
.clk (clk),
.clk_ref (tCK <= 1500 ? clk_ref[1] : clk_ref[0]),
.mem_refclk (mem_refclk), //memory clock
.freq_refclk (freq_refclk),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
.mmcm_ps_clk (mmcm_ps_clk),
.poc_sample_pd (poc_sample_pd),
.rst (rst),
.error (error),
.reset (reset),
.rst_tg_mc (rst_tg_mc),
.ddr_dq (ddr_dq),
.ddr_dqs_n (ddr_dqs_n),
.ddr_dqs (ddr_dqs),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_cas_n (ddr_cas_n),
.ddr_ck_n (ddr_ck_n),
.ddr_ck (ddr_ck),
.ddr_cke (ddr_cke),
.ddr_cs_n (ddr_cs_n),
.ddr_dm (ddr_dm),
.ddr_odt (ddr_odt),
.ddr_ras_n (ddr_ras_n),
.ddr_reset_n (ddr_reset_n),
.ddr_parity (ddr_parity),
.ddr_we_n (ddr_we_n),
.slot_0_present (SLOT_0_CONFIG),
.slot_1_present (SLOT_1_CONFIG),
.correct_en (correct_en),
.bank (bank),
.cmd (cmd),
.col (col),
.data_buf_addr (data_buf_addr),
.wr_data (wr_data),
.wr_data_mask (wr_data_mask),
.rank (rank),
.raw_not_ecc (raw_not_ecc),
.row (row),
.hi_priority (hi_priority),
.size (size),
.use_addr (use_addr),
.accept (accept),
.accept_ns (accept_ns),
.ecc_single (ecc_single),
.ecc_multiple (ecc_multiple),
.ecc_err_addr (ecc_err_addr),
.rd_data (rd_data),
.rd_data_addr (rd_data_addr),
.rd_data_en (rd_data_en),
.rd_data_end (rd_data_end),
.rd_data_offset (rd_data_offset),
.wr_data_addr (wr_data_addr),
.wr_data_en (wr_data_en),
.wr_data_offset (wr_data_offset),
.bank_mach_next (bank_mach_next),
.init_calib_complete (init_calib_complete),
.init_wrcal_complete (init_wrcal_complete),
.app_sr_req (app_sr_req_i),
.app_sr_active (app_sr_active_i),
.app_ref_req (app_ref_req_i),
.app_ref_ack (app_ref_ack_i),
.app_zq_req (app_zq_req_i),
.app_zq_ack (app_zq_ack_i),
.device_temp (device_temp),
.psen (psen),
.psincdec (psincdec),
.psdone (psdone),
.fi_xor_we (fi_xor_we),
.fi_xor_wrdata (fi_xor_wrdata),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_calib_top (dbg_calib_top),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_rddata (dbg_rddata),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_sel_pi_incdec (dbg_sel_pi_incdec),
.dbg_sel_po_incdec (dbg_sel_po_incdec),
.dbg_byte_sel (dbg_byte_sel),
.dbg_pi_f_inc (dbg_pi_f_inc),
.dbg_pi_f_dec (dbg_pi_f_dec),
.dbg_po_f_inc (dbg_po_f_inc),
.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel),
.dbg_po_f_dec (dbg_po_f_dec),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_rddata_valid (dbg_rddata_valid),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl),
.dbg_pi_counter_read_val (dbg_pi_counter_read_val),
.dbg_po_counter_read_val (dbg_po_counter_read_val),
.ref_dll_lock (ref_dll_lock),
.rst_phaser_ref (rst_phaser_ref),
.iddr_rst (iddr_rst),
.dbg_rd_data_offset (dbg_rd_data_offset),
.dbg_phy_init (dbg_phy_init),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.dbg_dqs_found_cal (dbg_dqs_found_cal),
.dbg_pi_phaselock_start (dbg_pi_phaselock_start),
.dbg_pi_phaselocked_done (dbg_pi_phaselocked_done),
.dbg_pi_phaselock_err (dbg_pi_phaselock_err),
.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start),
.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done),
.dbg_pi_dqsfound_err (dbg_pi_dqsfound_err),
.dbg_wrcal_start (dbg_wrcal_start),
.dbg_wrcal_done (dbg_wrcal_done),
.dbg_wrcal_err (dbg_wrcal_err),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_calib_rd_data_offset_1 (dbg_calib_rd_data_offset_1),
.dbg_calib_rd_data_offset_2 (dbg_calib_rd_data_offset_2),
.dbg_data_offset (dbg_data_offset),
.dbg_data_offset_1 (dbg_data_offset_1),
.dbg_data_offset_2 (dbg_data_offset_2),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data),
.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start),
.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done),
.prbs_final_dqs_tap_cnt_r (dbg_prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps)
);
mig_7series_v2_3_ui_top #
(
.TCQ (TCQ),
.APP_DATA_WIDTH (APP_DATA_WIDTH),
.APP_MASK_WIDTH (APP_MASK_WIDTH),
.BANK_WIDTH (BANK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.CWL (CWL),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.ECC (ECC),
.ECC_TEST (ECC_TEST),
.nCK_PER_CLK (nCK_PER_CLK),
.ORDERING (ORDERING),
.RANKS (RANKS),
.RANK_WIDTH (RANK_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.MEM_ADDR_ORDER (MEM_ADDR_ORDER)
)
u_ui_top
(
.wr_data_mask (wr_data_mask[APP_MASK_WIDTH-1:0]),
.wr_data (wr_data[APP_DATA_WIDTH-1:0]),
.use_addr (use_addr),
.size (size),
.row (row),
.raw_not_ecc (raw_not_ecc),
.rank (rank),
.hi_priority (hi_priority),
.data_buf_addr (data_buf_addr),
.col (col),
.cmd (cmd),
.bank (bank),
.app_wdf_rdy (app_wdf_rdy),
.app_rdy (app_rdy),
.app_rd_data_valid (app_rd_data_valid),
.app_rd_data_end (app_rd_data_end),
.app_rd_data (app_rd_data),
.app_ecc_multiple_err (app_ecc_multiple_err),
.correct_en (correct_en),
.wr_data_offset (wr_data_offset),
.wr_data_en (wr_data_en),
.wr_data_addr (wr_data_addr),
.rst (reset),
.rd_data_offset (rd_data_offset),
.rd_data_end (rd_data_end),
.rd_data_en (rd_data_en),
.rd_data_addr (rd_data_addr),
.rd_data (rd_data[APP_DATA_WIDTH-1:0]),
.ecc_multiple (ecc_multiple),
.clk (clk),
.app_wdf_wren (app_wdf_wren),
.app_wdf_mask (app_wdf_mask),
.app_wdf_end (app_wdf_end),
.app_wdf_data (app_wdf_data),
.app_sz (1'b1),
.app_raw_not_ecc (app_raw_not_ecc),
.app_hi_pri (app_hi_pri),
.app_en (app_en),
.app_cmd (app_cmd),
.app_addr (app_addr),
.accept_ns (accept_ns),
.accept (accept),
.app_correct_en (app_correct_en_i),
.app_sr_req (app_sr_req),
.sr_req (app_sr_req_i),
.sr_active (app_sr_active_i),
.app_sr_active (app_sr_active),
.app_ref_req (app_ref_req),
.ref_req (app_ref_req_i),
.ref_ack (app_ref_ack_i),
.app_ref_ack (app_ref_ack),
.app_zq_req (app_zq_req),
.zq_req (app_zq_req_i),
.zq_ack (app_zq_ack_i),
.app_zq_ack (app_zq_ack)
);
endmodule
|
module mig_7series_v2_3_memc_ui_top_std #
(
parameter TCQ = 100,
parameter DDR3_VDD_OP_VOLT = "135", // Voltage mode used for DDR3
parameter PAYLOAD_WIDTH = 64,
parameter ADDR_CMD_MODE = "UNBUF",
parameter AL = "0", // Additive Latency option
parameter BANK_WIDTH = 3, // # of bank bits
parameter BM_CNT_WIDTH = 2, // Bank machine counter width
parameter BURST_MODE = "8", // Burst length
parameter BURST_TYPE = "SEQ", // Burst type
parameter CA_MIRROR = "OFF", // C/A mirror opt for DDR3 dual rank
parameter CK_WIDTH = 1, // # of CK/CK# outputs to memory
parameter CL = 5,
parameter COL_WIDTH = 12, // column address width
parameter CMD_PIPE_PLUS1 = "ON", // add pipeline stage between MC and PHY
parameter CS_WIDTH = 1, // # of unique CS outputs
parameter CKE_WIDTH = 1, // # of cke outputs
parameter CWL = 5,
parameter DATA_WIDTH = 64,
parameter DATA_BUF_ADDR_WIDTH = 5,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DDR2_DQSN_ENABLE = "YES", // Enable differential DQS for DDR2
parameter DM_WIDTH = 8, // # of DM (data mask)
parameter DQ_CNT_WIDTH = 6, // = ceil(log2(DQ_WIDTH))
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_TYPE = "DDR3",
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter ECC = "OFF",
parameter ECC_WIDTH = 8,
parameter ECC_TEST = "OFF",
parameter MC_ERR_ADDR_WIDTH = 31,
parameter MASTER_PHY_CTL = 0, // The bank number where master PHY_CONTROL resides
parameter nAL = 0, // Additive latency (in clk cyc)
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2, // # of memory CKs per fabric CLK
parameter nCS_PER_RANK = 1, // # of unique CS outputs per rank
parameter ORDERING = "NORM",
parameter IBUF_LPWR_MODE = "OFF",
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter DATA_IO_PRIM_TYPE = "DEFAULT", // # = "HP_LP", "HR_LP", "DEFAULT"
parameter DATA_IO_IDLE_PWRDWN = "ON", // "ON" or "OFF"
parameter IODELAY_GRP0 = "IODELAY_MIG0",
parameter IODELAY_GRP1 = "IODELAY_MIG1",
parameter FPGA_SPEED_GRADE = 1,
parameter OUTPUT_DRV = "HIGH",
parameter REG_CTRL = "OFF",
parameter RTT_NOM = "60",
parameter RTT_WR = "120",
parameter STARVE_LIMIT = 2,
parameter tCK = 2500, // pS
parameter tCKE = 10000, // pS
parameter tFAW = 40000, // pS
parameter tPRDI = 1_000_000, // pS
parameter tRAS = 37500, // pS
parameter tRCD = 12500, // pS
parameter tREFI = 7800000, // pS
parameter tRFC = 110000, // pS
parameter tRP = 12500, // pS
parameter tRRD = 10000, // pS
parameter tRTP = 7500, // pS
parameter tWTR = 7500, // pS
parameter tZQI = 128_000_000, // nS
parameter tZQCS = 64, // CKs
parameter USER_REFRESH = "OFF", // Whether user manages REF
parameter TEMP_MON_EN = "ON", // Enable/Disable tempmon
parameter WRLVL = "OFF",
parameter DEBUG_PORT = "OFF",
parameter CAL_WIDTH = "HALF",
parameter RANK_WIDTH = 1,
parameter RANKS = 4,
parameter ODT_WIDTH = 1,
parameter ROW_WIDTH = 16, // DRAM address bus width
parameter ADDR_WIDTH = 32,
parameter APP_MASK_WIDTH = 8,
parameter APP_DATA_WIDTH = 64,
parameter [3:0] BYTE_LANES_B0 = 4'b1111,
parameter [3:0] BYTE_LANES_B1 = 4'b1111,
parameter [3:0] BYTE_LANES_B2 = 4'b1111,
parameter [3:0] BYTE_LANES_B3 = 4'b1111,
parameter [3:0] BYTE_LANES_B4 = 4'b1111,
parameter [3:0] DATA_CTL_B0 = 4'hc,
parameter [3:0] DATA_CTL_B1 = 4'hf,
parameter [3:0] DATA_CTL_B2 = 4'hf,
parameter [3:0] DATA_CTL_B3 = 4'h0,
parameter [3:0] DATA_CTL_B4 = 4'h0,
parameter [47:0] PHY_0_BITLANES = 48'h0000_0000_0000,
parameter [47:0] PHY_1_BITLANES = 48'h0000_0000_0000,
parameter [47:0] PHY_2_BITLANES = 48'h0000_0000_0000,
// control/address/data pin mapping parameters
parameter [143:0] CK_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter [191:0] ADDR_MAP
= 192'h000_000_000_000_000_000_000_000_000_000_000_000_000_000_000_000,
parameter [35:0] BANK_MAP = 36'h000_000_000,
parameter [11:0] CAS_MAP = 12'h000,
parameter [7:0] CKE_ODT_BYTE_MAP = 8'h00,
parameter [95:0] CKE_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] ODT_MAP = 96'h000_000_000_000_000_000_000_000,
parameter CKE_ODT_AUX = "FALSE",
parameter [119:0] CS_MAP = 120'h000_000_000_000_000_000_000_000_000_000,
parameter [11:0] PARITY_MAP = 12'h000,
parameter [11:0] RAS_MAP = 12'h000,
parameter [11:0] WE_MAP = 12'h000,
parameter [143:0] DQS_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter [95:0] DATA0_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA1_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA2_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA3_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA4_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA5_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA6_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA7_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA8_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA9_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA10_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA11_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA12_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA13_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA14_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA15_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA16_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [95:0] DATA17_MAP = 96'h000_000_000_000_000_000_000_000,
parameter [107:0] MASK0_MAP = 108'h000_000_000_000_000_000_000_000_000,
parameter [107:0] MASK1_MAP = 108'h000_000_000_000_000_000_000_000_000,
parameter [7:0] SLOT_0_CONFIG = 8'b0000_0001,
parameter [7:0] SLOT_1_CONFIG = 8'b0000_0000,
parameter MEM_ADDR_ORDER = "BANK_ROW_COLUMN",
// calibration Address. The address given below will be used for calibration
// read and write operations.
parameter [15:0] CALIB_ROW_ADD = 16'h0000, // Calibration row address
parameter [11:0] CALIB_COL_ADD = 12'h000, // Calibration column address
parameter [2:0] CALIB_BA_ADD = 3'h0, // Calibration bank address
parameter SIM_BYPASS_INIT_CAL = "OFF",
parameter REFCLK_FREQ = 300.0,
parameter USE_CS_PORT = 1, // Support chip select output
parameter USE_DM_PORT = 1, // Support data mask output
parameter USE_ODT_PORT = 1, // Support ODT output
parameter IDELAY_ADJ = "ON", //ON : IDELAY-1, OFF: No change
parameter FINE_PER_BIT = "ON", //ON : Use per bit calib for complex rdlvl
parameter CENTER_COMP_MODE = "ON", //ON: use PI stg2 tap compensation
parameter PI_VAL_ADJ = "ON", //ON: PI stg2 tap -1 for centering
parameter TAPSPERKCLK = 56
)
(
// Clock and reset ports
input clk,
input [1:0] clk_ref,
input mem_refclk ,
input freq_refclk ,
input pll_lock,
input sync_pulse ,
input mmcm_ps_clk,
input poc_sample_pd,
input rst,
// memory interface ports
inout [DQ_WIDTH-1:0] ddr_dq,
inout [DQS_WIDTH-1:0] ddr_dqs_n,
inout [DQS_WIDTH-1:0] ddr_dqs,
output [ROW_WIDTH-1:0] ddr_addr,
output [BANK_WIDTH-1:0] ddr_ba,
output ddr_cas_n,
output [CK_WIDTH-1:0] ddr_ck_n,
output [CK_WIDTH-1:0] ddr_ck,
output [CKE_WIDTH-1:0] ddr_cke,
output [CS_WIDTH*nCS_PER_RANK-1:0] ddr_cs_n,
output [DM_WIDTH-1:0] ddr_dm,
output [ODT_WIDTH-1:0] ddr_odt,
output ddr_ras_n,
output ddr_reset_n,
output ddr_parity,
output ddr_we_n,
output [BM_CNT_WIDTH-1:0] bank_mach_next,
// user interface ports
input [ADDR_WIDTH-1:0] app_addr,
input [2:0] app_cmd,
input app_en,
input app_hi_pri,
input [APP_DATA_WIDTH-1:0] app_wdf_data,
input app_wdf_end,
input [APP_MASK_WIDTH-1:0] app_wdf_mask,
input app_wdf_wren,
input app_correct_en_i,
input [2*nCK_PER_CLK-1:0] app_raw_not_ecc,
output [2*nCK_PER_CLK-1:0] app_ecc_multiple_err,
output [APP_DATA_WIDTH-1:0] app_rd_data,
output app_rd_data_end,
output app_rd_data_valid,
output app_rdy,
output app_wdf_rdy,
input app_sr_req,
output app_sr_active,
input app_ref_req,
output app_ref_ack,
input app_zq_req,
output app_zq_ack,
// temperature monitor ports
input [11:0] device_temp,
//phase shift clock control
output psen,
output psincdec,
input psdone,
// debug logic ports
input dbg_idel_down_all,
input dbg_idel_down_cpt,
input dbg_idel_up_all,
input dbg_idel_up_cpt,
input dbg_sel_all_idel_cpt,
input [DQS_CNT_WIDTH-1:0] dbg_sel_idel_cpt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_first_edge_cnt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_second_edge_cnt,
output [DQS_WIDTH-1:0] dbg_rd_data_edge_detect,
output [2*nCK_PER_CLK*DQ_WIDTH-1:0] dbg_rddata,
output [1:0] dbg_rdlvl_done,
output [1:0] dbg_rdlvl_err,
output [1:0] dbg_rdlvl_start,
output [5:0] dbg_tap_cnt_during_wrlvl,
output dbg_wl_edge_detect_valid,
output dbg_wrlvl_done,
output dbg_wrlvl_err,
output dbg_wrlvl_start,
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output init_calib_complete,
input dbg_sel_pi_incdec,
input dbg_sel_po_incdec,
input [DQS_CNT_WIDTH:0] dbg_byte_sel,
input dbg_pi_f_inc,
input dbg_pi_f_dec,
input dbg_po_f_inc,
input dbg_po_f_stg23_sel,
input dbg_po_f_dec,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_tap_cnt,
output [5*DQS_WIDTH*RANKS-1:0] dbg_dq_idelay_tap_cnt,
output dbg_rddata_valid,
output [6*DQS_WIDTH-1:0] dbg_wrlvl_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_wrlvl_coarse_tap_cnt,
output ref_dll_lock,
input rst_phaser_ref,
input iddr_rst,
output [6*RANKS-1:0] dbg_rd_data_offset,
output [255:0] dbg_calib_top,
output [255:0] dbg_phy_wrlvl,
output [255:0] dbg_phy_rdlvl,
output [99:0] dbg_phy_wrcal,
output [255:0] dbg_phy_init,
output [255:0] dbg_prbs_rdlvl,
output [255:0] dbg_dqs_found_cal,
output [5:0] dbg_pi_counter_read_val,
output [8:0] dbg_po_counter_read_val,
output dbg_pi_phaselock_start,
output dbg_pi_phaselocked_done,
output dbg_pi_phaselock_err,
output dbg_pi_dqsfound_start,
output dbg_pi_dqsfound_done,
output dbg_pi_dqsfound_err,
output dbg_wrcal_start,
output dbg_wrcal_done,
output dbg_wrcal_err,
output [11:0] dbg_pi_dqs_found_lanes_phy4lanes,
output [11:0] dbg_pi_phase_locked_phy4lanes,
output [6*RANKS-1:0] dbg_calib_rd_data_offset_1,
output [6*RANKS-1:0] dbg_calib_rd_data_offset_2,
output [5:0] dbg_data_offset,
output [5:0] dbg_data_offset_1,
output [5:0] dbg_data_offset_2,
output dbg_oclkdelay_calib_start,
output dbg_oclkdelay_calib_done,
output [255:0] dbg_phy_oclkdelay_cal,
output [DRAM_WIDTH*16 -1:0] dbg_oclkdelay_rd_data,
output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_final_dqs_tap_cnt_r,
output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps,
output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps
);
localparam IODELAY_GRP = (tCK <= 1500)? IODELAY_GRP1 : IODELAY_GRP0;
// wire [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r;
// wire [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps;
// wire [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps;
wire correct_en;
wire [2*nCK_PER_CLK-1:0] raw_not_ecc;
wire [2*nCK_PER_CLK-1:0] ecc_single;
wire [2*nCK_PER_CLK-1:0] ecc_multiple;
wire [MC_ERR_ADDR_WIDTH-1:0] ecc_err_addr;
wire [DQ_WIDTH/8-1:0] fi_xor_we;
wire [DQ_WIDTH-1:0] fi_xor_wrdata;
wire [DATA_BUF_OFFSET_WIDTH-1:0] wr_data_offset;
wire wr_data_en;
wire [DATA_BUF_ADDR_WIDTH-1:0] wr_data_addr;
wire [DATA_BUF_OFFSET_WIDTH-1:0] rd_data_offset;
wire rd_data_en;
wire [DATA_BUF_ADDR_WIDTH-1:0] rd_data_addr;
wire accept;
wire accept_ns;
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] rd_data;
wire rd_data_end;
wire use_addr;
wire size;
wire [ROW_WIDTH-1:0] row;
wire [RANK_WIDTH-1:0] rank;
wire hi_priority;
wire [DATA_BUF_ADDR_WIDTH-1:0] data_buf_addr;
wire [COL_WIDTH-1:0] col;
wire [2:0] cmd;
wire [BANK_WIDTH-1:0] bank;
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data;
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH/8-1:0] wr_data_mask;
wire app_sr_req_i;
wire app_sr_active_i;
wire app_ref_req_i;
wire app_ref_ack_i;
wire app_zq_req_i;
wire app_zq_ack_i;
wire rst_tg_mc;
wire error;
wire init_wrcal_complete;
reg reset /* synthesis syn_maxfan = 10 */;
//***************************************************************************
always @(posedge clk)
reset <= #TCQ (rst | rst_tg_mc);
assign fi_xor_we = {DQ_WIDTH/8{1'b0}} ;
assign fi_xor_wrdata = {DQ_WIDTH{1'b0}} ;
mig_7series_v2_3_mem_intfc #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.PAYLOAD_WIDTH (PAYLOAD_WIDTH),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.AL (AL),
.BANK_WIDTH (BANK_WIDTH),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.CA_MIRROR (CA_MIRROR),
.CK_WIDTH (CK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.CMD_PIPE_PLUS1 (CMD_PIPE_PLUS1),
.CS_WIDTH (CS_WIDTH),
.nCS_PER_RANK (nCS_PER_RANK),
.CKE_WIDTH (CKE_WIDTH),
.DATA_WIDTH (DATA_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DATA_BUF_OFFSET_WIDTH (DATA_BUF_OFFSET_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.DM_WIDTH (DM_WIDTH),
.DQ_CNT_WIDTH (DQ_CNT_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.DRAM_WIDTH (DRAM_WIDTH),
.ECC (ECC),
.ECC_WIDTH (ECC_WIDTH),
.MC_ERR_ADDR_WIDTH (MC_ERR_ADDR_WIDTH),
.REFCLK_FREQ (REFCLK_FREQ),
.nAL (nAL),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.ORDERING (ORDERING),
.OUTPUT_DRV (OUTPUT_DRV),
.IBUF_LPWR_MODE (IBUF_LPWR_MODE),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN (DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.REG_CTRL (REG_CTRL),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.CL (CL),
.CWL (CWL),
.tCK (tCK),
.tCKE (tCKE),
.tFAW (tFAW),
.tPRDI (tPRDI),
.tRAS (tRAS),
.tRCD (tRCD),
.tREFI (tREFI),
.tRFC (tRFC),
.tRP (tRP),
.tRRD (tRRD),
.tRTP (tRTP),
.tWTR (tWTR),
.tZQI (tZQI),
.tZQCS (tZQCS),
.USER_REFRESH (USER_REFRESH),
.TEMP_MON_EN (TEMP_MON_EN),
.WRLVL (WRLVL),
.DEBUG_PORT (DEBUG_PORT),
.CAL_WIDTH (CAL_WIDTH),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.SIM_BYPASS_INIT_CAL (SIM_BYPASS_INIT_CAL),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.SLOT_0_CONFIG (SLOT_0_CONFIG),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.STARVE_LIMIT (STARVE_LIMIT),
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK)
)
mem_intfc0
(
.clk (clk),
.clk_ref (tCK <= 1500 ? clk_ref[1] : clk_ref[0]),
.mem_refclk (mem_refclk), //memory clock
.freq_refclk (freq_refclk),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
.mmcm_ps_clk (mmcm_ps_clk),
.poc_sample_pd (poc_sample_pd),
.rst (rst),
.error (error),
.reset (reset),
.rst_tg_mc (rst_tg_mc),
.ddr_dq (ddr_dq),
.ddr_dqs_n (ddr_dqs_n),
.ddr_dqs (ddr_dqs),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_cas_n (ddr_cas_n),
.ddr_ck_n (ddr_ck_n),
.ddr_ck (ddr_ck),
.ddr_cke (ddr_cke),
.ddr_cs_n (ddr_cs_n),
.ddr_dm (ddr_dm),
.ddr_odt (ddr_odt),
.ddr_ras_n (ddr_ras_n),
.ddr_reset_n (ddr_reset_n),
.ddr_parity (ddr_parity),
.ddr_we_n (ddr_we_n),
.slot_0_present (SLOT_0_CONFIG),
.slot_1_present (SLOT_1_CONFIG),
.correct_en (correct_en),
.bank (bank),
.cmd (cmd),
.col (col),
.data_buf_addr (data_buf_addr),
.wr_data (wr_data),
.wr_data_mask (wr_data_mask),
.rank (rank),
.raw_not_ecc (raw_not_ecc),
.row (row),
.hi_priority (hi_priority),
.size (size),
.use_addr (use_addr),
.accept (accept),
.accept_ns (accept_ns),
.ecc_single (ecc_single),
.ecc_multiple (ecc_multiple),
.ecc_err_addr (ecc_err_addr),
.rd_data (rd_data),
.rd_data_addr (rd_data_addr),
.rd_data_en (rd_data_en),
.rd_data_end (rd_data_end),
.rd_data_offset (rd_data_offset),
.wr_data_addr (wr_data_addr),
.wr_data_en (wr_data_en),
.wr_data_offset (wr_data_offset),
.bank_mach_next (bank_mach_next),
.init_calib_complete (init_calib_complete),
.init_wrcal_complete (init_wrcal_complete),
.app_sr_req (app_sr_req_i),
.app_sr_active (app_sr_active_i),
.app_ref_req (app_ref_req_i),
.app_ref_ack (app_ref_ack_i),
.app_zq_req (app_zq_req_i),
.app_zq_ack (app_zq_ack_i),
.device_temp (device_temp),
.psen (psen),
.psincdec (psincdec),
.psdone (psdone),
.fi_xor_we (fi_xor_we),
.fi_xor_wrdata (fi_xor_wrdata),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_calib_top (dbg_calib_top),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_rddata (dbg_rddata),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_sel_pi_incdec (dbg_sel_pi_incdec),
.dbg_sel_po_incdec (dbg_sel_po_incdec),
.dbg_byte_sel (dbg_byte_sel),
.dbg_pi_f_inc (dbg_pi_f_inc),
.dbg_pi_f_dec (dbg_pi_f_dec),
.dbg_po_f_inc (dbg_po_f_inc),
.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel),
.dbg_po_f_dec (dbg_po_f_dec),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_rddata_valid (dbg_rddata_valid),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl),
.dbg_pi_counter_read_val (dbg_pi_counter_read_val),
.dbg_po_counter_read_val (dbg_po_counter_read_val),
.ref_dll_lock (ref_dll_lock),
.rst_phaser_ref (rst_phaser_ref),
.iddr_rst (iddr_rst),
.dbg_rd_data_offset (dbg_rd_data_offset),
.dbg_phy_init (dbg_phy_init),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.dbg_dqs_found_cal (dbg_dqs_found_cal),
.dbg_pi_phaselock_start (dbg_pi_phaselock_start),
.dbg_pi_phaselocked_done (dbg_pi_phaselocked_done),
.dbg_pi_phaselock_err (dbg_pi_phaselock_err),
.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start),
.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done),
.dbg_pi_dqsfound_err (dbg_pi_dqsfound_err),
.dbg_wrcal_start (dbg_wrcal_start),
.dbg_wrcal_done (dbg_wrcal_done),
.dbg_wrcal_err (dbg_wrcal_err),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_calib_rd_data_offset_1 (dbg_calib_rd_data_offset_1),
.dbg_calib_rd_data_offset_2 (dbg_calib_rd_data_offset_2),
.dbg_data_offset (dbg_data_offset),
.dbg_data_offset_1 (dbg_data_offset_1),
.dbg_data_offset_2 (dbg_data_offset_2),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data),
.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start),
.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done),
.prbs_final_dqs_tap_cnt_r (dbg_prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps)
);
mig_7series_v2_3_ui_top #
(
.TCQ (TCQ),
.APP_DATA_WIDTH (APP_DATA_WIDTH),
.APP_MASK_WIDTH (APP_MASK_WIDTH),
.BANK_WIDTH (BANK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.CWL (CWL),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.ECC (ECC),
.ECC_TEST (ECC_TEST),
.nCK_PER_CLK (nCK_PER_CLK),
.ORDERING (ORDERING),
.RANKS (RANKS),
.RANK_WIDTH (RANK_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.MEM_ADDR_ORDER (MEM_ADDR_ORDER)
)
u_ui_top
(
.wr_data_mask (wr_data_mask[APP_MASK_WIDTH-1:0]),
.wr_data (wr_data[APP_DATA_WIDTH-1:0]),
.use_addr (use_addr),
.size (size),
.row (row),
.raw_not_ecc (raw_not_ecc),
.rank (rank),
.hi_priority (hi_priority),
.data_buf_addr (data_buf_addr),
.col (col),
.cmd (cmd),
.bank (bank),
.app_wdf_rdy (app_wdf_rdy),
.app_rdy (app_rdy),
.app_rd_data_valid (app_rd_data_valid),
.app_rd_data_end (app_rd_data_end),
.app_rd_data (app_rd_data),
.app_ecc_multiple_err (app_ecc_multiple_err),
.correct_en (correct_en),
.wr_data_offset (wr_data_offset),
.wr_data_en (wr_data_en),
.wr_data_addr (wr_data_addr),
.rst (reset),
.rd_data_offset (rd_data_offset),
.rd_data_end (rd_data_end),
.rd_data_en (rd_data_en),
.rd_data_addr (rd_data_addr),
.rd_data (rd_data[APP_DATA_WIDTH-1:0]),
.ecc_multiple (ecc_multiple),
.clk (clk),
.app_wdf_wren (app_wdf_wren),
.app_wdf_mask (app_wdf_mask),
.app_wdf_end (app_wdf_end),
.app_wdf_data (app_wdf_data),
.app_sz (1'b1),
.app_raw_not_ecc (app_raw_not_ecc),
.app_hi_pri (app_hi_pri),
.app_en (app_en),
.app_cmd (app_cmd),
.app_addr (app_addr),
.accept_ns (accept_ns),
.accept (accept),
.app_correct_en (app_correct_en_i),
.app_sr_req (app_sr_req),
.sr_req (app_sr_req_i),
.sr_active (app_sr_active_i),
.app_sr_active (app_sr_active),
.app_ref_req (app_ref_req),
.ref_req (app_ref_req_i),
.ref_ack (app_ref_ack_i),
.app_ref_ack (app_ref_ack),
.app_zq_req (app_zq_req),
.zq_req (app_zq_req_i),
.zq_ack (app_zq_ack_i),
.app_zq_ack (app_zq_ack)
);
endmodule
|
module mig_7series_v2_3_ddr_phy_init #
(
parameter tCK = 1500, // DDRx SDRAM clock period
parameter TCQ = 100,
parameter nCK_PER_CLK = 4, // # of memory clocks per CLK
parameter CLK_PERIOD = 3000, // Logic (internal) clk period (in ps)
parameter USE_ODT_PORT = 0, // 0 - No ODT output from FPGA
// 1 - ODT output from FPGA
parameter DDR3_VDD_OP_VOLT = "150", // Voltage mode used for DDR3
// 150 - 1.50 V
// 135 - 1.35 V
// 125 - 1.25 V
parameter VREF = "EXTERNAL", // Internal or external Vref
parameter PRBS_WIDTH = 8, // PRBS sequence = 2^PRBS_WIDTH
parameter BANK_WIDTH = 2,
parameter CA_MIRROR = "OFF", // C/A mirror opt for DDR3 dual rank
parameter COL_WIDTH = 10,
parameter nCS_PER_RANK = 1, // # of CS bits per rank e.g. for
// component I/F with CS_WIDTH=1,
// nCS_PER_RANK=# of components
parameter DQ_WIDTH = 64,
parameter DQS_WIDTH = 8,
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter ROW_WIDTH = 14,
parameter CS_WIDTH = 1,
parameter RANKS = 1, // # of memory ranks in the interface
parameter CKE_WIDTH = 1, // # of cke outputs
parameter DRAM_TYPE = "DDR3",
parameter REG_CTRL = "ON",
parameter ADDR_CMD_MODE= "1T",
// calibration Address
parameter CALIB_ROW_ADD = 16'h0000,// Calibration row address
parameter CALIB_COL_ADD = 12'h000, // Calibration column address
parameter CALIB_BA_ADD = 3'h0, // Calibration bank address
// DRAM mode settings
parameter AL = "0", // Additive Latency option
parameter BURST_MODE = "8", // Burst length
parameter BURST_TYPE = "SEQ", // Burst type
// parameter nAL = 0, // Additive latency (in clk cyc)
parameter nCL = 5, // Read CAS latency (in clk cyc)
parameter nCWL = 5, // Write CAS latency (in clk cyc)
parameter tRFC = 110000, // Refresh-to-command delay (in ps)
parameter REFRESH_TIMER = 1553, // Refresh interval in fabrci cycles between 8 posted refreshes
parameter REFRESH_TIMER_WIDTH = 8,
parameter OUTPUT_DRV = "HIGH", // DRAM reduced output drive option
parameter RTT_NOM = "60", // Nominal ODT termination value
parameter RTT_WR = "60", // Write ODT termination value
parameter WRLVL = "ON", // Enable write leveling
// parameter PHASE_DETECT = "ON", // Enable read phase detector
parameter DDR2_DQSN_ENABLE = "YES", // Enable differential DQS for DDR2
parameter nSLOTS = 1, // Number of DIMM SLOTs in the system
parameter SIM_INIT_OPTION = "NONE", // "NONE", "SKIP_PU_DLY", "SKIP_INIT"
parameter SIM_CAL_OPTION = "NONE", // "NONE", "FAST_CAL", "SKIP_CAL"
parameter CKE_ODT_AUX = "FALSE",
parameter PRE_REV3ES = "OFF", // Enable TG error detection during calibration
parameter TEST_AL = "0", // Internal use for ICM verification
parameter FIXED_VICTIM = "TRUE",
parameter BYPASS_COMPLEX_OCAL = "FALSE"
)
(
input clk,
input rst,
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] prbs_o,
input delay_incdec_done,
input ck_addr_cmd_delay_done,
input pi_phase_locked_all,
input pi_dqs_found_done,
input dqsfound_retry,
input dqs_found_prech_req,
output reg pi_phaselock_start,
output pi_phase_locked_err,
output pi_calib_done,
input phy_if_empty,
// Read/write calibration interface
input wrlvl_done,
input wrlvl_rank_done,
input wrlvl_byte_done,
input wrlvl_byte_redo,
input wrlvl_final,
output reg wrlvl_final_if_rst,
input oclkdelay_calib_done,
input oclk_prech_req,
input oclk_calib_resume,
input lim_done,
input lim_wr_req,
output reg oclkdelay_calib_start,
//complex oclkdelay calibration
input complex_oclkdelay_calib_done,
input complex_oclk_prech_req,
input complex_oclk_calib_resume,
output reg complex_oclkdelay_calib_start,
input [DQS_CNT_WIDTH:0] complex_oclkdelay_calib_cnt, // same as oclkdelay_calib_cnt
output reg complex_ocal_num_samples_inc,
input complex_ocal_num_samples_done_r,
input [2:0] complex_ocal_rd_victim_sel,
output reg complex_ocal_reset_rd_addr,
input complex_ocal_ref_req,
output reg complex_ocal_ref_done,
input done_dqs_tap_inc,
input [5:0] rd_data_offset_0,
input [5:0] rd_data_offset_1,
input [5:0] rd_data_offset_2,
input [6*RANKS-1:0] rd_data_offset_ranks_0,
input [6*RANKS-1:0] rd_data_offset_ranks_1,
input [6*RANKS-1:0] rd_data_offset_ranks_2,
input pi_dqs_found_rank_done,
input wrcal_done,
input wrcal_prech_req,
input wrcal_read_req,
input wrcal_act_req,
input temp_wrcal_done,
input [7:0] slot_0_present,
input [7:0] slot_1_present,
output reg wl_sm_start,
output reg wr_lvl_start,
output reg wrcal_start,
output reg wrcal_rd_wait,
output reg wrcal_sanity_chk,
output reg tg_timer_done,
output reg no_rst_tg_mc,
input rdlvl_stg1_done,
input rdlvl_stg1_rank_done,
output reg rdlvl_stg1_start,
output reg pi_dqs_found_start,
output reg detect_pi_found_dqs,
// rdlvl stage 1 precharge requested after each DQS
input rdlvl_prech_req,
input rdlvl_last_byte_done,
input wrcal_resume,
input wrcal_sanity_chk_done,
// MPR read leveling
input mpr_rdlvl_done,
input mpr_rnk_done,
input mpr_last_byte_done,
output reg mpr_rdlvl_start,
output reg mpr_end_if_reset,
// PRBS Read Leveling
input prbs_rdlvl_done,
input prbs_last_byte_done,
input prbs_rdlvl_prech_req,
input complex_victim_inc,
input [2:0] rd_victim_sel,
input [DQS_CNT_WIDTH:0] pi_stg2_prbs_rdlvl_cnt,
output reg [2:0] victim_sel,
output reg [DQS_CNT_WIDTH:0]victim_byte_cnt,
output reg prbs_rdlvl_start,
output reg prbs_gen_clk_en,
output reg prbs_gen_oclk_clk_en,
output reg complex_sample_cnt_inc,
output reg complex_sample_cnt_inc_ocal,
output reg complex_wr_done,
// Signals shared btw multiple calibration stages
output reg prech_done,
// Data select / status
output reg init_calib_complete,
// Signal to mask memory model error for Invalid latching edge
output reg calib_writes,
// PHY address/control
// 2 commands to PHY Control Block per div 2 clock in 2:1 mode
// 4 commands to PHY Control Block per div 4 clock in 4:1 mode
output reg [nCK_PER_CLK*ROW_WIDTH-1:0] phy_address,
output reg [nCK_PER_CLK*BANK_WIDTH-1:0]phy_bank,
output reg [nCK_PER_CLK-1:0] phy_ras_n,
output reg [nCK_PER_CLK-1:0] phy_cas_n,
output reg [nCK_PER_CLK-1:0] phy_we_n,
output reg phy_reset_n,
output [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] phy_cs_n,
// Hard PHY Interface signals
input phy_ctl_ready,
input phy_ctl_full,
input phy_cmd_full,
input phy_data_full,
output reg calib_ctl_wren,
output reg calib_cmd_wren,
output reg [1:0] calib_seq,
output reg write_calib,
output reg read_calib,
// PHY_Ctl_Wd
output reg [2:0] calib_cmd,
// calib_aux_out used for CKE and ODT
output reg [3:0] calib_aux_out,
output reg [1:0] calib_odt ,
output reg [nCK_PER_CLK-1:0] calib_cke ,
output [1:0] calib_rank_cnt,
output reg [1:0] calib_cas_slot,
output reg [5:0] calib_data_offset_0,
output reg [5:0] calib_data_offset_1,
output reg [5:0] calib_data_offset_2,
// PHY OUT_FIFO
output reg calib_wrdata_en,
output reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] phy_wrdata,
// PHY Read
output phy_rddata_en,
output phy_rddata_valid,
output [255:0] dbg_phy_init,
input read_pause,
input reset_rd_addr,
//OCAL centering calibration
input oclkdelay_center_calib_start,
input oclk_center_write_resume,
input oclkdelay_center_calib_done
);
//*****************************************************************************
// Assertions to be added
//*****************************************************************************
// The phy_ctl_full signal must never be asserted in synchronous mode of
// operation either 4:1 or 2:1
//
// The RANKS parameter must never be set to '0' by the user
// valid values: 1 to 4
//
//*****************************************************************************
//***************************************************************************
// Number of Read level stage 1 writes limited to a SDRAM row
// The address of Read Level stage 1 reads must also be limited
// to a single SDRAM row
// (2^COL_WIDTH)/BURST_MODE = (2^10)/8 = 128
localparam NUM_STG1_WR_RD = (BURST_MODE == "8") ? 4 :
(BURST_MODE == "4") ? 8 : 4;
localparam ADDR_INC = (BURST_MODE == "8") ? 8 :
(BURST_MODE == "4") ? 4 : 8;
// In a 2 slot dual rank per system RTT_NOM values
// for Rank2 and Rank3 default to 40 ohms
localparam RTT_NOM2 = "40";
localparam RTT_NOM3 = "40";
localparam RTT_NOM_int = (USE_ODT_PORT == 1) ? RTT_NOM : RTT_WR;
// Specifically for use with half-frequency controller (nCK_PER_CLK=2)
// = 1 if burst length = 4, = 0 if burst length = 8. Determines how
// often row command needs to be issued during read-leveling
// For DDR3 the burst length is fixed during calibration
localparam BURST4_FLAG = (DRAM_TYPE == "DDR3")? 1'b0 :
(BURST_MODE == "8") ? 1'b0 :
((BURST_MODE == "4") ? 1'b1 : 1'b0);
//***************************************************************************
// Counter values used to determine bus timing
// NOTE on all counter terminal counts - these can/should be one less than
// the actual delay to take into account extra clock cycle delay in
// generating the corresponding "done" signal
//***************************************************************************
localparam CLK_MEM_PERIOD = CLK_PERIOD / nCK_PER_CLK;
// Calculate initial delay required in number of CLK clock cycles
// to delay initially. The counter is clocked by [CLK/1024] - which
// is approximately division by 1000 - note that the formulas below will
// result in more than the minimum wait time because of this approximation.
// NOTE: For DDR3 JEDEC specifies to delay reset
// by 200us, and CKE by an additional 500us after power-up
// For DDR2 CKE is delayed by 200us after power up.
localparam DDR3_RESET_DELAY_NS = 200000;
localparam DDR3_CKE_DELAY_NS = 500000 + DDR3_RESET_DELAY_NS;
localparam DDR2_CKE_DELAY_NS = 200000;
localparam PWRON_RESET_DELAY_CNT =
((DDR3_RESET_DELAY_NS+CLK_PERIOD-1)/CLK_PERIOD);
localparam PWRON_CKE_DELAY_CNT = (DRAM_TYPE == "DDR3") ?
(((DDR3_CKE_DELAY_NS+CLK_PERIOD-1)/CLK_PERIOD)) :
(((DDR2_CKE_DELAY_NS+CLK_PERIOD-1)/CLK_PERIOD));
// FOR DDR2 -1 taken out. With -1 not getting 200us. The equation
// needs to be reworked.
localparam DDR2_INIT_PRE_DELAY_PS = 400000;
localparam DDR2_INIT_PRE_CNT =
((DDR2_INIT_PRE_DELAY_PS+CLK_PERIOD-1)/CLK_PERIOD)-1;
// Calculate tXPR time: reset from CKE HIGH to valid command after power-up
// tXPR = (max(5nCK, tRFC(min)+10ns). Add a few (blah, messy) more clock
// cycles because this counter actually starts up before CKE is asserted
// to memory.
localparam TXPR_DELAY_CNT =
(5*CLK_MEM_PERIOD > tRFC+10000) ?
(((5+nCK_PER_CLK-1)/nCK_PER_CLK)-1)+11 :
(((tRFC+10000+CLK_PERIOD-1)/CLK_PERIOD)-1)+11;
// tDLLK/tZQINIT time = 512*tCK = 256*tCLKDIV
localparam TDLLK_TZQINIT_DELAY_CNT = 255;
// TWR values in ns. Both DDR2 and DDR3 have the same value.
// 15000ns/tCK
localparam TWR_CYC = ((15000) % CLK_MEM_PERIOD) ?
(15000/CLK_MEM_PERIOD) + 1 : 15000/CLK_MEM_PERIOD;
// time to wait between consecutive commands in PHY_INIT - this is a
// generic number, and must be large enough to account for worst case
// timing parameter (tRFC - refresh-to-active) across all memory speed
// grades and operating frequencies. Expressed in clk
// (Divided by 4 or Divided by 2) clock cycles.
localparam CNTNEXT_CMD = 7'b1111111;
// Counter values to keep track of which MR register to load during init
// Set value of INIT_CNT_MR_DONE to equal value of counter for last mode
// register configured during initialization.
// NOTE: Reserve more bits for DDR2 - more MR accesses for DDR2 init
localparam INIT_CNT_MR2 = 2'b00;
localparam INIT_CNT_MR3 = 2'b01;
localparam INIT_CNT_MR1 = 2'b10;
localparam INIT_CNT_MR0 = 2'b11;
localparam INIT_CNT_MR_DONE = 2'b11;
// Register chip programmable values for DDR3
// The register chip for the registered DIMM needs to be programmed
// before the initialization of the registered DIMM.
// Address for the control word is in : DBA2, DA2, DA1, DA0
// Data for the control word is in: DBA1 DBA0, DA4, DA3
// The values will be stored in the local param in the following format
// {DBA[2:0], DA[4:0]}
// RC0 is global features control word. Address == 000
localparam REG_RC0 = 8'b00000000;
// RC1 Clock driver enable control word. Enables or disables the four
// output clocks in the register chip. For single rank and dual rank
// two clocks will be enabled and for quad rank all the four clocks
// will be enabled. Address == 000. Data = 0110 for single and dual rank.
// = 0000 for quad rank
localparam REG_RC1 = 8'b00000001;
// RC2 timing control word. Set in 1T timing mode
// Address = 010. Data = 0000
localparam REG_RC2 = 8'b00000010;
// RC3 timing control word. Setting the data based on number of RANKS (inturn the number of loads)
// This setting is specific to RDIMMs from Micron Technology
localparam REG_RC3 = (RANKS >= 2) ? 8'b00101011 : 8'b00000011;
// RC4 timing control work. Setting the data based on number of RANKS (inturn the number of loads)
// This setting is specific to RDIMMs from Micron Technology
localparam REG_RC4 = (RANKS >= 2) ? 8'b00101100 : 8'b00000100;
// RC5 timing control work. Setting the data based on number of RANKS (inturn the number of loads)
// This setting is specific to RDIMMs from Micron Technology
localparam REG_RC5 = (RANKS >= 2) ? 8'b00101101 : 8'b00000101;
// RC10 timing control work. Setting the data to 0000
localparam [3:0] FREQUENCY_ENCODING = (tCK >= 1072 && tCK < 1250) ? 4'b0100 :
(tCK >= 1250 && tCK < 1500) ? 4'b0011 :
(tCK >= 1500 && tCK < 1875) ? 4'b0010 :
(tCK >= 1875 && tCK < 2500) ? 4'b0001 : 4'b0000;
localparam REG_RC10 = {1'b1,FREQUENCY_ENCODING,3'b010};
localparam VREF_ENCODING = (VREF == "INTERNAL") ? 1'b1 : 1'b0;
localparam [3:0] DDR3_VOLTAGE_ENCODING = (DDR3_VDD_OP_VOLT == "125") ? {1'b0,VREF_ENCODING,2'b10} :
(DDR3_VDD_OP_VOLT == "135") ? {1'b0,VREF_ENCODING,2'b01} :
{1'b0,VREF_ENCODING,2'b00} ;
localparam REG_RC11 = {1'b1,DDR3_VOLTAGE_ENCODING,3'b011};
// For non-zero AL values
localparam nAL = (AL == "CL-1") ? nCL - 1 : 0;
// Adding the register dimm latency to write latency
localparam CWL_M = (REG_CTRL == "ON") ? nCWL + nAL + 1 : nCWL + nAL;
// Count value to generate pi_phase_locked_err signal
localparam PHASELOCKED_TIMEOUT = (SIM_CAL_OPTION == "NONE") ? 16383 : 1000;
// Timeout interval for detecting error with Traffic Generator
localparam [13:0] TG_TIMER_TIMEOUT
= (SIM_CAL_OPTION == "NONE") ? 14'h3FFF : 14'h0001;
//bit num per DQS
localparam DQ_PER_DQS = DQ_WIDTH/DQS_WIDTH;
//COMPLEX_ROW_CNT_BYTE
localparam COMPLEX_ROW_CNT_BYTE = (FIXED_VICTIM=="FALSE")? DQ_PER_DQS*2: 2;
localparam COMPLEX_RD = (FIXED_VICTIM=="FALSE")? DQ_PER_DQS : 1;
// Master state machine encoding
localparam INIT_IDLE = 7'b0000000; //0
localparam INIT_WAIT_CKE_EXIT = 7'b0000001; //1
localparam INIT_LOAD_MR = 7'b0000010; //2
localparam INIT_LOAD_MR_WAIT = 7'b0000011; //3
localparam INIT_ZQCL = 7'b0000100; //4
localparam INIT_WAIT_DLLK_ZQINIT = 7'b0000101; //5
localparam INIT_WRLVL_START = 7'b0000110; //6
localparam INIT_WRLVL_WAIT = 7'b0000111; //7
localparam INIT_WRLVL_LOAD_MR = 7'b0001000; //8
localparam INIT_WRLVL_LOAD_MR_WAIT = 7'b0001001; //9
localparam INIT_WRLVL_LOAD_MR2 = 7'b0001010; //A
localparam INIT_WRLVL_LOAD_MR2_WAIT = 7'b0001011; //B
localparam INIT_RDLVL_ACT = 7'b0001100; //C
localparam INIT_RDLVL_ACT_WAIT = 7'b0001101; //D
localparam INIT_RDLVL_STG1_WRITE = 7'b0001110; //E
localparam INIT_RDLVL_STG1_WRITE_READ = 7'b0001111; //F
localparam INIT_RDLVL_STG1_READ = 7'b0010000; //10
localparam INIT_RDLVL_STG2_READ = 7'b0010001; //11
localparam INIT_RDLVL_STG2_READ_WAIT = 7'b0010010; //12
localparam INIT_PRECHARGE_PREWAIT = 7'b0010011; //13
localparam INIT_PRECHARGE = 7'b0010100; //14
localparam INIT_PRECHARGE_WAIT = 7'b0010101; //15
localparam INIT_DONE = 7'b0010110; //16
localparam INIT_DDR2_PRECHARGE = 7'b0010111; //17
localparam INIT_DDR2_PRECHARGE_WAIT = 7'b0011000; //18
localparam INIT_REFRESH = 7'b0011001; //19
localparam INIT_REFRESH_WAIT = 7'b0011010; //1A
localparam INIT_REG_WRITE = 7'b0011011; //1B
localparam INIT_REG_WRITE_WAIT = 7'b0011100; //1C
localparam INIT_DDR2_MULTI_RANK = 7'b0011101; //1D
localparam INIT_DDR2_MULTI_RANK_WAIT = 7'b0011110; //1E
localparam INIT_WRCAL_ACT = 7'b0011111; //1F
localparam INIT_WRCAL_ACT_WAIT = 7'b0100000; //20
localparam INIT_WRCAL_WRITE = 7'b0100001; //21
localparam INIT_WRCAL_WRITE_READ = 7'b0100010; //22
localparam INIT_WRCAL_READ = 7'b0100011; //23
localparam INIT_WRCAL_READ_WAIT = 7'b0100100; //24
localparam INIT_WRCAL_MULT_READS = 7'b0100101; //25
localparam INIT_PI_PHASELOCK_READS = 7'b0100110; //26
localparam INIT_MPR_RDEN = 7'b0100111; //27
localparam INIT_MPR_WAIT = 7'b0101000; //28
localparam INIT_MPR_READ = 7'b0101001; //29
localparam INIT_MPR_DISABLE_PREWAIT = 7'b0101010; //2A
localparam INIT_MPR_DISABLE = 7'b0101011; //2B
localparam INIT_MPR_DISABLE_WAIT = 7'b0101100; //2C
localparam INIT_OCLKDELAY_ACT = 7'b0101101; //2D
localparam INIT_OCLKDELAY_ACT_WAIT = 7'b0101110; //2E
localparam INIT_OCLKDELAY_WRITE = 7'b0101111; //2F
localparam INIT_OCLKDELAY_WRITE_WAIT = 7'b0110000; //30
localparam INIT_OCLKDELAY_READ = 7'b0110001; //31
localparam INIT_OCLKDELAY_READ_WAIT = 7'b0110010; //32
localparam INIT_REFRESH_RNK2_WAIT = 7'b0110011; //33
localparam INIT_RDLVL_COMPLEX_PRECHARGE = 7'b0110100; //34
localparam INIT_RDLVL_COMPLEX_PRECHARGE_WAIT = 7'b0110101; //35
localparam INIT_RDLVL_COMPLEX_ACT = 7'b0110110; //36
localparam INIT_RDLVL_COMPLEX_ACT_WAIT = 7'b0110111; //37
localparam INIT_RDLVL_COMPLEX_READ = 7'b0111000; //38
localparam INIT_RDLVL_COMPLEX_READ_WAIT = 7'b0111001; //39
localparam INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT = 7'b0111010; //3A
localparam INIT_OCAL_COMPLEX_ACT = 7'b0111011; //3B
localparam INIT_OCAL_COMPLEX_ACT_WAIT = 7'b0111100; //3C
localparam INIT_OCAL_COMPLEX_WRITE_WAIT = 7'b0111101; //3D
localparam INIT_OCAL_COMPLEX_RESUME_WAIT = 7'b0111110; //3E
localparam INIT_OCAL_CENTER_ACT = 7'b0111111; //3F
localparam INIT_OCAL_CENTER_WRITE = 7'b1000000; //40
localparam INIT_OCAL_CENTER_WRITE_WAIT = 7'b1000001; //41
localparam INIT_OCAL_CENTER_ACT_WAIT = 7'b1000010; //42
integer i, j, k, l, m, n, p, q;
reg pi_dqs_found_all_r;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r1;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r2;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r3;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r4;
reg pi_calib_rank_done_r;
reg [13:0] pi_phaselock_timer;
reg stg1_wr_done;
reg rnk_ref_cnt;
reg pi_dqs_found_done_r1;
reg pi_dqs_found_rank_done_r;
reg read_calib_int;
reg read_calib_r;
reg pi_calib_done_r;
reg pi_calib_done_r1;
reg burst_addr_r;
reg [1:0] chip_cnt_r;
reg [6:0] cnt_cmd_r;
reg cnt_cmd_done_r;
reg cnt_cmd_done_m7_r;
reg [7:0] cnt_dllk_zqinit_r;
reg cnt_dllk_zqinit_done_r;
reg cnt_init_af_done_r;
reg [1:0] cnt_init_af_r;
reg [1:0] cnt_init_data_r;
reg [1:0] cnt_init_mr_r;
reg cnt_init_mr_done_r;
reg cnt_init_pre_wait_done_r;
reg [7:0] cnt_init_pre_wait_r;
reg [9:0] cnt_pwron_ce_r;
reg cnt_pwron_cke_done_r;
reg cnt_pwron_cke_done_r1;
reg [8:0] cnt_pwron_r;
reg cnt_pwron_reset_done_r;
reg cnt_txpr_done_r;
reg [7:0] cnt_txpr_r;
reg ddr2_pre_flag_r;
reg ddr2_refresh_flag_r;
reg ddr3_lm_done_r;
reg [4:0] enable_wrlvl_cnt;
reg init_complete_r;
reg init_complete_r1;
reg init_complete_r2;
(* keep = "true" *) reg init_complete_r_timing;
(* keep = "true" *) reg init_complete_r1_timing;
reg [6:0] init_next_state;
reg [6:0] init_state_r;
reg [6:0] init_state_r1;
wire [15:0] load_mr0;
wire [15:0] load_mr1;
wire [15:0] load_mr2;
wire [15:0] load_mr3;
reg mem_init_done_r;
reg [1:0] mr2_r [0:3];
reg [2:0] mr1_r [0:3];
reg new_burst_r;
reg [15:0] wrcal_start_dly_r;
wire wrcal_start_pre;
reg wrcal_resume_r;
// Only one ODT signal per rank in PHY Control Block
reg [nCK_PER_CLK-1:0] phy_tmp_odt_r;
reg [nCK_PER_CLK-1:0] phy_tmp_odt_r1;
reg [CS_WIDTH*nCS_PER_RANK-1:0] phy_tmp_cs1_r;
reg [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] phy_int_cs_n;
wire prech_done_pre;
reg [15:0] prech_done_dly_r;
reg prech_pending_r;
reg prech_req_posedge_r;
reg prech_req_r;
reg pwron_ce_r;
reg first_rdlvl_pat_r;
reg first_wrcal_pat_r;
reg phy_wrdata_en;
reg phy_wrdata_en_r1;
reg [1:0] wrdata_pat_cnt;
reg [1:0] wrcal_pat_cnt;
reg [ROW_WIDTH-1:0] address_w;
reg [BANK_WIDTH-1:0] bank_w;
reg rdlvl_stg1_done_r1;
reg rdlvl_stg1_start_int;
reg [15:0] rdlvl_start_dly0_r;
reg rdlvl_start_pre;
reg rdlvl_last_byte_done_r;
wire rdlvl_rd;
wire rdlvl_wr;
reg rdlvl_wr_r;
wire rdlvl_wr_rd;
reg [3:0] reg_ctrl_cnt_r;
reg [1:0] tmp_mr2_r [0:3];
reg [2:0] tmp_mr1_r [0:3];
reg wrlvl_done_r;
reg wrlvl_done_r1;
reg wrlvl_rank_done_r1;
reg wrlvl_rank_done_r2;
reg wrlvl_rank_done_r3;
reg wrlvl_rank_done_r4;
reg wrlvl_rank_done_r5;
reg wrlvl_rank_done_r6;
reg wrlvl_rank_done_r7;
reg [2:0] wrlvl_rank_cntr;
reg wrlvl_odt_ctl;
reg wrlvl_odt;
reg wrlvl_active;
reg wrlvl_active_r1;
reg [2:0] num_reads;
reg temp_wrcal_done_r;
reg temp_lmr_done;
reg extend_cal_pat;
reg [13:0] tg_timer;
reg tg_timer_go;
reg cnt_wrcal_rd;
reg [3:0] cnt_wait;
reg [7:0] wrcal_reads;
reg [8:0] stg1_wr_rd_cnt;
reg phy_data_full_r;
reg wr_level_dqs_asrt;
reg wr_level_dqs_asrt_r1;
reg [1:0] dqs_asrt_cnt;
reg [3:0] num_refresh;
wire oclkdelay_calib_start_pre;
reg [15:0] oclkdelay_start_dly_r;
reg [3:0] oclk_wr_cnt;
reg [3:0] wrcal_wr_cnt;
reg wrlvl_final_r;
reg prbs_rdlvl_done_r1;
reg prbs_rdlvl_done_r2;
reg prbs_rdlvl_done_r3;
reg prbs_last_byte_done_r;
reg phy_if_empty_r;
reg prbs_pat_resume_int;
reg complex_row0_wr_done;
reg complex_row1_wr_done;
reg complex_row0_rd_done;
reg complex_row1_rd_done;
reg complex_row0_rd_done_r1;
reg [3:0] complex_wait_cnt;
reg [3:0] complex_num_reads;
reg [3:0] complex_num_reads_dec;
reg [ROW_WIDTH-1:0] complex_address;
reg wr_victim_inc;
reg [2:0] wr_victim_sel;
reg [DQS_CNT_WIDTH:0] wr_byte_cnt;
reg [7:0] complex_row_cnt;
reg complex_sample_cnt_inc_r1;
reg complex_sample_cnt_inc_r2;
reg complex_odt_ext;
reg complex_ocal_odt_ext;
reg wrcal_final_chk;
wire prech_req;
reg read_pause_r1;
reg read_pause_r2;
wire read_pause_ext;
reg reset_rd_addr_r1;
reg complex_rdlvl_int_ref_req;
reg ext_int_ref_req;
//complex OCLK delay calibration
reg [7:0] complex_row_cnt_ocal;
reg [4:0] complex_num_writes;
reg [4:0] complex_num_writes_dec;
reg complex_oclkdelay_calib_start_int;
reg complex_oclkdelay_calib_start_r1;
reg complex_oclkdelay_calib_start_r2;
reg complex_oclkdelay_calib_done_r1;
// reg [DQS_CNT_WIDTH:0] wr_byte_cnt_ocal;
reg [2:0] wr_victim_sel_ocal;
reg complex_row1_rd_done_r1; //time for switch to write
reg [2:0] complex_row1_rd_cnt; //row1 read number for the byte (8 (16 rows) row1)
reg complex_byte_rd_done; //read for the byte is done
reg complex_byte_rd_done_r1;
// reg complex_row_change; //every 16 rows of read, it is set to "0" for write
reg ocal_num_samples_inc; //1 read/write is done
reg complex_ocal_wr_start; //indicate complex ocal write is started. used for prbs rd addr gen
reg prbs_rdlvl_done_pulse; //rising edge for prbs_rdlvl_done. used for pipelining
reg prech_done_r1, prech_done_r2, prech_done_r3;
reg mask_lim_done;
reg complex_mask_lim_done;
reg oclkdelay_calib_start_int;
reg [REFRESH_TIMER_WIDTH-1:0] oclkdelay_ref_cnt;
reg oclkdelay_int_ref_req;
reg [3:0] ocal_act_wait_cnt;
reg oclk_calib_resume_level;
reg ocal_last_byte_done;
wire mmcm_wr; //MMCM centering write. no CS will be set
wire exit_ocal_complex_resume_wait =
init_state_r == INIT_OCAL_COMPLEX_RESUME_WAIT && complex_oclk_calib_resume;
//***************************************************************************
// Debug
//***************************************************************************
//synthesis translate_off
always @(posedge mem_init_done_r) begin
if (!rst)
$display ("PHY_INIT: Memory Initialization completed at %t", $time);
end
always @(posedge wrlvl_done) begin
if (!rst && (WRLVL == "ON"))
$display ("PHY_INIT: Write Leveling completed at %t", $time);
end
always @(posedge rdlvl_stg1_done) begin
if (!rst)
$display ("PHY_INIT: Read Leveling Stage 1 completed at %t", $time);
end
always @(posedge mpr_rdlvl_done) begin
if (!rst)
$display ("PHY_INIT: MPR Read Leveling completed at %t", $time);
end
always @(posedge oclkdelay_calib_done) begin
if (!rst)
$display ("PHY_INIT: OCLKDELAY calibration completed at %t", $time);
end
always @(posedge pi_calib_done_r1) begin
if (!rst)
$display ("PHY_INIT: Phaser_In Phase Locked at %t", $time);
end
always @(posedge pi_dqs_found_done) begin
if (!rst)
$display ("PHY_INIT: Phaser_In DQSFOUND completed at %t", $time);
end
always @(posedge wrcal_done) begin
if (!rst && (WRLVL == "ON"))
$display ("PHY_INIT: Write Calibration completed at %t", $time);
end
always@(posedge prbs_rdlvl_done)begin
if(!rst)
$display("PHY_INIT : PRBS/PER_BIT calibration completed at %t",$time);
end
always@(posedge complex_oclkdelay_calib_done)begin
if(!rst)
$display("PHY_INIT : COMPLEX OCLKDELAY calibration completed at %t",$time);
end
always@(posedge oclkdelay_center_calib_done)begin
if(!rst)
$display("PHY_INIT : OCLKDELAY CENTER CALIB calibration completed at %t",$time);
end
//synthesis translate_on
assign dbg_phy_init[5:0] = init_state_r;
assign dbg_phy_init[6+:8] = complex_row_cnt;
assign dbg_phy_init[14+:3] = victim_sel;
assign dbg_phy_init[17+:4] = victim_byte_cnt;
assign dbg_phy_init[21+:9] = stg1_wr_rd_cnt[8:0];
assign dbg_phy_init[30+:15] = complex_address;
assign dbg_phy_init[(30+15)+:15] = phy_address[14:0];
assign dbg_phy_init[60] =prbs_rdlvl_prech_req ;
assign dbg_phy_init[61] =prech_req_posedge_r ;
//***************************************************************************
// DQS count to be sent to hard PHY during Phaser_IN Phase Locking stage
//***************************************************************************
// assign pi_phaselock_calib_cnt = dqs_cnt_r;
assign pi_calib_done = pi_calib_done_r1;
assign read_pause_ext = read_pause | read_pause_r2;
//detect rising edge of prbs_rdlvl_done to reset all control sighals
always @ (posedge clk) begin
prbs_rdlvl_done_pulse <= #TCQ prbs_rdlvl_done & ~prbs_rdlvl_done_r1;
end
always @ (posedge clk) begin
read_pause_r1 <= #TCQ read_pause;
read_pause_r2 <= #TCQ read_pause_r1;
end
always @(posedge clk) begin
if (rst)
wrcal_final_chk <= #TCQ 1'b0;
else if ((init_next_state == INIT_WRCAL_ACT) && wrcal_done &&
(DRAM_TYPE == "DDR3"))
wrcal_final_chk <= #TCQ 1'b1;
end
always @(posedge clk) begin
rdlvl_stg1_done_r1 <= #TCQ rdlvl_stg1_done;
prbs_rdlvl_done_r1 <= #TCQ prbs_rdlvl_done;
prbs_rdlvl_done_r2 <= #TCQ prbs_rdlvl_done_r1;
prbs_rdlvl_done_r3 <= #TCQ prbs_rdlvl_done_r2;
wrcal_resume_r <= #TCQ wrcal_resume;
wrcal_sanity_chk <= #TCQ wrcal_final_chk;
end
always @(posedge clk) begin
if (rst)
mpr_end_if_reset <= #TCQ 1'b0;
else if (mpr_last_byte_done && (num_refresh != 'd0))
mpr_end_if_reset <= #TCQ 1'b1;
else
mpr_end_if_reset <= #TCQ 1'b0;
end
// Siganl to mask memory model error for Invalid latching edge
always @(posedge clk)
if (rst)
calib_writes <= #TCQ 1'b0;
else if ((init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ))
calib_writes <= #TCQ 1'b1;
else
calib_writes <= #TCQ 1'b0;
always @(posedge clk)
if (rst)
wrcal_rd_wait <= #TCQ 1'b0;
else if (init_state_r == INIT_WRCAL_READ_WAIT)
wrcal_rd_wait <= #TCQ 1'b1;
else
wrcal_rd_wait <= #TCQ 1'b0;
//***************************************************************************
// Signal PHY completion when calibration is finished
// Signal assertion is delayed by four clock cycles to account for the
// multi cycle path constraint to (phy_init_data_sel) signal.
//***************************************************************************
always @(posedge clk)
if (rst) begin
init_complete_r <= #TCQ 1'b0;
init_complete_r_timing <= #TCQ 1'b0;
init_complete_r1 <= #TCQ 1'b0;
init_complete_r1_timing <= #TCQ 1'b0;
init_complete_r2 <= #TCQ 1'b0;
init_calib_complete <= #TCQ 1'b0;
end else begin
if (init_state_r == INIT_DONE) begin
init_complete_r <= #TCQ 1'b1;
init_complete_r_timing <= #TCQ 1'b1;
end
init_complete_r1 <= #TCQ init_complete_r;
init_complete_r1_timing <= #TCQ init_complete_r_timing;
init_complete_r2 <= #TCQ init_complete_r1;
init_calib_complete <= #TCQ init_complete_r2;
end
always @ (posedge clk)
if (rst)
complex_oclkdelay_calib_done_r1 <= #TCQ 1'b0;
else
complex_oclkdelay_calib_done_r1 <= #TCQ complex_oclkdelay_calib_done;
//reset read address for starting complex ocaldealy calib
always @ (posedge clk) begin
complex_ocal_reset_rd_addr <= #TCQ ((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && (complex_wait_cnt == 'd9)) || (prbs_last_byte_done && ~prbs_last_byte_done_r);
end
//first write for complex oclkdealy calib
always @ (posedge clk) begin
if (rst)
complex_ocal_wr_start <= #TCQ 'b0;
else
complex_ocal_wr_start <= #TCQ complex_ocal_reset_rd_addr? 1'b1 : complex_ocal_wr_start;
end
//ocal stg3 centering start
// always @ (posedge clk)
// if(rst) oclkdelay_center_calib_start <= #TCQ 1'b0;
// else
// oclkdelay_center_calib_start <= #TCQ ((init_state_r == INIT_OCAL_CENTER_ACT) && lim_done)? 1'b1: oclkdelay_center_calib_start;
//***************************************************************************
// Instantiate FF for the phy_init_data_sel signal. A multi cycle path
// constraint will be assigned to this signal. This signal will only be
// used within the PHY
//***************************************************************************
// FDRSE u_ff_phy_init_data_sel
// (
// .Q (phy_init_data_sel),
// .C (clk),
// .CE (1'b1),
// .D (init_complete_r),
// .R (1'b0),
// .S (1'b0)
// ) /* synthesis syn_preserve=1 */
// /* synthesis syn_replicate = 0 */;
//***************************************************************************
// Mode register programming
//***************************************************************************
//*****************************************************************
// DDR3 Load mode reg0
// Mode Register (MR0):
// [15:13] - unused - 000
// [12] - Precharge Power-down DLL usage - 0 (DLL frozen, slow-exit),
// 1 (DLL maintained)
// [11:9] - write recovery for Auto Precharge (tWR/tCK = 6)
// [8] - DLL reset - 0 or 1
// [7] - Test Mode - 0 (normal)
// [6:4],[2] - CAS latency - CAS_LAT
// [3] - Burst Type - BURST_TYPE
// [1:0] - Burst Length - BURST_LEN
// DDR2 Load mode register
// Mode Register (MR):
// [15:14] - unused - 00
// [13] - reserved - 0
// [12] - Power-down mode - 0 (normal)
// [11:9] - write recovery - write recovery for Auto Precharge
// (tWR/tCK = 6)
// [8] - DLL reset - 0 or 1
// [7] - Test Mode - 0 (normal)
// [6:4] - CAS latency - CAS_LAT
// [3] - Burst Type - BURST_TYPE
// [2:0] - Burst Length - BURST_LEN
//*****************************************************************
generate
if(DRAM_TYPE == "DDR3") begin: gen_load_mr0_DDR3
assign load_mr0[1:0] = (BURST_MODE == "8") ? 2'b00 :
(BURST_MODE == "OTF") ? 2'b01 :
(BURST_MODE == "4") ? 2'b10 : 2'b11;
assign load_mr0[2] = (nCL >= 12) ? 1'b1 : 1'b0; // LSb of CAS latency
assign load_mr0[3] = (BURST_TYPE == "SEQ") ? 1'b0 : 1'b1;
assign load_mr0[6:4] = ((nCL == 5) || (nCL == 13)) ? 3'b001 :
((nCL == 6) || (nCL == 14)) ? 3'b010 :
(nCL == 7) ? 3'b011 :
(nCL == 8) ? 3'b100 :
(nCL == 9) ? 3'b101 :
(nCL == 10) ? 3'b110 :
(nCL == 11) ? 3'b111 :
(nCL == 12) ? 3'b000 : 3'b111;
assign load_mr0[7] = 1'b0;
assign load_mr0[8] = 1'b1; // Reset DLL (init only)
assign load_mr0[11:9] = (TWR_CYC == 5) ? 3'b001 :
(TWR_CYC == 6) ? 3'b010 :
(TWR_CYC == 7) ? 3'b011 :
(TWR_CYC == 8) ? 3'b100 :
(TWR_CYC == 9) ? 3'b101 :
(TWR_CYC == 10) ? 3'b101 :
(TWR_CYC == 11) ? 3'b110 :
(TWR_CYC == 12) ? 3'b110 :
(TWR_CYC == 13) ? 3'b111 :
(TWR_CYC == 14) ? 3'b111 :
(TWR_CYC == 15) ? 3'b000 :
(TWR_CYC == 16) ? 3'b000 : 3'b010;
assign load_mr0[12] = 1'b0; // Precharge Power-Down DLL 'slow-exit'
assign load_mr0[15:13] = 3'b000;
end else if (DRAM_TYPE == "DDR2") begin: gen_load_mr0_DDR2 // block: gen
assign load_mr0[2:0] = (BURST_MODE == "8") ? 3'b011 :
(BURST_MODE == "4") ? 3'b010 : 3'b111;
assign load_mr0[3] = (BURST_TYPE == "SEQ") ? 1'b0 : 1'b1;
assign load_mr0[6:4] = (nCL == 3) ? 3'b011 :
(nCL == 4) ? 3'b100 :
(nCL == 5) ? 3'b101 :
(nCL == 6) ? 3'b110 : 3'b111;
assign load_mr0[7] = 1'b0;
assign load_mr0[8] = 1'b1; // Reset DLL (init only)
assign load_mr0[11:9] = (TWR_CYC == 2) ? 3'b001 :
(TWR_CYC == 3) ? 3'b010 :
(TWR_CYC == 4) ? 3'b011 :
(TWR_CYC == 5) ? 3'b100 :
(TWR_CYC == 6) ? 3'b101 : 3'b010;
assign load_mr0[15:12]= 4'b0000; // Reserved
end
endgenerate
//*****************************************************************
// DDR3 Load mode reg1
// Mode Register (MR1):
// [15:13] - unused - 00
// [12] - output enable - 0 (enabled for DQ, DQS, DQS#)
// [11] - TDQS enable - 0 (TDQS disabled and DM enabled)
// [10] - reserved - 0 (must be '0')
// [9] - RTT[2] - 0
// [8] - reserved - 0 (must be '0')
// [7] - write leveling - 0 (disabled), 1 (enabled)
// [6] - RTT[1] - RTT[1:0] = 0(no ODT), 1(75), 2(150), 3(50)
// [5] - Output driver impedance[1] - 0 (RZQ/6 and RZQ/7)
// [4:3] - Additive CAS - ADDITIVE_CAS
// [2] - RTT[0]
// [1] - Output driver impedance[0] - 0(RZQ/6), or 1 (RZQ/7)
// [0] - DLL enable - 0 (normal)
// DDR2 ext mode register
// Extended Mode Register (MR):
// [15:14] - unused - 00
// [13] - reserved - 0
// [12] - output enable - 0 (enabled)
// [11] - RDQS enable - 0 (disabled)
// [10] - DQS# enable - 0 (enabled)
// [9:7] - OCD Program - 111 or 000 (first 111, then 000 during init)
// [6] - RTT[1] - RTT[1:0] = 0(no ODT), 1(75), 2(150), 3(50)
// [5:3] - Additive CAS - ADDITIVE_CAS
// [2] - RTT[0]
// [1] - Output drive - REDUCE_DRV (= 0(full), = 1 (reduced)
// [0] - DLL enable - 0 (normal)
//*****************************************************************
generate
if(DRAM_TYPE == "DDR3") begin: gen_load_mr1_DDR3
assign load_mr1[0] = 1'b0; // DLL enabled during Imitialization
assign load_mr1[1] = (OUTPUT_DRV == "LOW") ? 1'b0 : 1'b1;
assign load_mr1[2] = ((RTT_NOM_int == "30") || (RTT_NOM_int == "40") ||
(RTT_NOM_int == "60")) ? 1'b1 : 1'b0;
assign load_mr1[4:3] = (AL == "0") ? 2'b00 :
(AL == "CL-1") ? 2'b01 :
(AL == "CL-2") ? 2'b10 : 2'b11;
assign load_mr1[5] = 1'b0;
assign load_mr1[6] = ((RTT_NOM_int == "40") || (RTT_NOM_int == "120")) ?
1'b1 : 1'b0;
assign load_mr1[7] = 1'b0; // Enable write lvl after init sequence
assign load_mr1[8] = 1'b0;
assign load_mr1[9] = ((RTT_NOM_int == "20") || (RTT_NOM_int == "30")) ?
1'b1 : 1'b0;
assign load_mr1[10] = 1'b0;
assign load_mr1[15:11] = 5'b00000;
end else if (DRAM_TYPE == "DDR2") begin: gen_load_mr1_DDR2
assign load_mr1[0] = 1'b0; // DLL enabled during Imitialization
assign load_mr1[1] = (OUTPUT_DRV == "LOW") ? 1'b1 : 1'b0;
assign load_mr1[2] = ((RTT_NOM_int == "75") || (RTT_NOM_int == "50")) ?
1'b1 : 1'b0;
assign load_mr1[5:3] = (AL == "0") ? 3'b000 :
(AL == "1") ? 3'b001 :
(AL == "2") ? 3'b010 :
(AL == "3") ? 3'b011 :
(AL == "4") ? 3'b100 : 3'b111;
assign load_mr1[6] = ((RTT_NOM_int == "50") ||
(RTT_NOM_int == "150")) ? 1'b1 : 1'b0;
assign load_mr1[9:7] = 3'b000;
assign load_mr1[10] = (DDR2_DQSN_ENABLE == "YES") ? 1'b0 : 1'b1;
assign load_mr1[15:11] = 5'b00000;
end
endgenerate
//*****************************************************************
// DDR3 Load mode reg2
// Mode Register (MR2):
// [15:11] - unused - 00
// [10:9] - RTT_WR - 00 (Dynamic ODT off)
// [8] - reserved - 0 (must be '0')
// [7] - self-refresh temperature range -
// 0 (normal), 1 (extended)
// [6] - Auto Self-Refresh - 0 (manual), 1(auto)
// [5:3] - CAS Write Latency (CWL) -
// 000 (5 for 400 MHz device),
// 001 (6 for 400 MHz to 533 MHz devices),
// 010 (7 for 533 MHz to 667 MHz devices),
// 011 (8 for 667 MHz to 800 MHz)
// [2:0] - Partial Array Self-Refresh (Optional) -
// 000 (full array)
// Not used for DDR2
//*****************************************************************
generate
if(DRAM_TYPE == "DDR3") begin: gen_load_mr2_DDR3
assign load_mr2[2:0] = 3'b000;
assign load_mr2[5:3] = (nCWL == 5) ? 3'b000 :
(nCWL == 6) ? 3'b001 :
(nCWL == 7) ? 3'b010 :
(nCWL == 8) ? 3'b011 :
(nCWL == 9) ? 3'b100 :
(nCWL == 10) ? 3'b101 :
(nCWL == 11) ? 3'b110 : 3'b111;
assign load_mr2[6] = 1'b0;
assign load_mr2[7] = 1'b0;
assign load_mr2[8] = 1'b0;
// Dynamic ODT disabled
assign load_mr2[10:9] = 2'b00;
assign load_mr2[15:11] = 5'b00000;
end else begin: gen_load_mr2_DDR2
assign load_mr2[15:0] = 16'd0;
end
endgenerate
//*****************************************************************
// DDR3 Load mode reg3
// Mode Register (MR3):
// [15:3] - unused - All zeros
// [2] - MPR Operation - 0(normal operation), 1(data flow from MPR)
// [1:0] - MPR location - 00 (Predefined pattern)
//*****************************************************************
assign load_mr3[1:0] = 2'b00;
assign load_mr3[2] = 1'b0;
assign load_mr3[15:3] = 13'b0000000000000;
// For multi-rank systems the rank being accessed during writes in
// Read Leveling must be sent to phy_write for the bitslip logic
assign calib_rank_cnt = chip_cnt_r;
//***************************************************************************
// Logic to begin initial calibration, and to handle precharge requests
// during read-leveling (to avoid tRAS violations if individual read
// levelling calibration stages take more than max{tRAS) to complete).
//***************************************************************************
// Assert when readback for each stage of read-leveling begins. However,
// note this indicates only when the read command is issued and when
// Phaser_IN has phase aligned FREQ_REF clock to read DQS. It does not
// indicate when the read data is present on the bus (when this happens
// after the read command is issued depends on CAS LATENCY) - there will
// need to be some delay before valid data is present on the bus.
// assign rdlvl_start_pre = (init_state_r == INIT_PI_PHASELOCK_READS);
// Assert when read back for oclkdelay calibration begins
assign oclkdelay_calib_start_pre = (init_state_r == INIT_OCAL_CENTER_ACT); //(init_state_r == INIT_OCLKDELAY_READ);
// Assert when read back for write calibration begins
assign wrcal_start_pre = (init_state_r == INIT_WRCAL_READ) || (init_state_r == INIT_WRCAL_MULT_READS);
// Common precharge signal done signal - pulses only when there has been
// a precharge issued as a result of a PRECH_REQ pulse. Note also a common
// PRECH_DONE signal is used for all blocks
assign prech_done_pre = (((init_state_r == INIT_RDLVL_STG1_READ) || (init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
((rdlvl_last_byte_done_r || prbs_last_byte_done_r) && (init_state_r == INIT_RDLVL_ACT_WAIT) && cnt_cmd_done_r) ||
(dqs_found_prech_req && (init_state_r == INIT_RDLVL_ACT_WAIT)) ||
(init_state_r == INIT_MPR_RDEN) ||
((init_state_r == INIT_WRCAL_ACT_WAIT) && cnt_cmd_done_r) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT) && complex_oclkdelay_calib_start_r1) ||
((init_state_r == INIT_OCLKDELAY_ACT_WAIT) && cnt_cmd_done_r) ||
((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) && prbs_last_byte_done_r) || //prbs_rdlvl_done
(wrlvl_final && (init_state_r == INIT_REFRESH_WAIT) && cnt_cmd_done_r && ~oclkdelay_calib_done)) &&
prech_pending_r &&
!prech_req_posedge_r);
always @(posedge clk)
if (rst)
pi_phaselock_start <= #TCQ 1'b0;
else if (init_state_r == INIT_PI_PHASELOCK_READS)
pi_phaselock_start <= #TCQ 1'b1;
// Delay start of each calibration by 16 clock cycles to ensure that when
// calibration logic begins, read data is already appearing on the bus.
// Each circuit should synthesize using an SRL16. Assume that reset is
// long enough to clear contents of SRL16.
always @(posedge clk) begin
rdlvl_last_byte_done_r <= #TCQ rdlvl_last_byte_done;
prbs_last_byte_done_r <= #TCQ prbs_last_byte_done;
rdlvl_start_dly0_r <= #TCQ {rdlvl_start_dly0_r[14:0],
rdlvl_start_pre};
wrcal_start_dly_r <= #TCQ {wrcal_start_dly_r[14:0],
wrcal_start_pre};
oclkdelay_start_dly_r <= #TCQ {oclkdelay_start_dly_r[14:0],
oclkdelay_calib_start_pre};
prech_done_dly_r <= #TCQ {prech_done_dly_r[14:0],
prech_done_pre};
end
always @(posedge clk)
if (rst)
oclkdelay_calib_start_int <= #TCQ 1'b0;
else if (oclkdelay_start_dly_r[5])
oclkdelay_calib_start_int <= #TCQ 1'b1;
always @(posedge clk) begin
if (rst)
ocal_last_byte_done <= #TCQ 1'b0;
else if ((complex_oclkdelay_calib_cnt == DQS_WIDTH-1) && oclkdelay_center_calib_done)
ocal_last_byte_done <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_REFRESH) || prbs_rdlvl_done || ocal_last_byte_done || oclkdelay_center_calib_done)
oclkdelay_ref_cnt <= #TCQ REFRESH_TIMER;
else if (oclkdelay_calib_start_int) begin
if (oclkdelay_ref_cnt > 'd0)
oclkdelay_ref_cnt <= #TCQ oclkdelay_ref_cnt - 1;
else
oclkdelay_ref_cnt <= #TCQ REFRESH_TIMER;
end
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_OCAL_CENTER_ACT) || oclkdelay_calib_done || ocal_last_byte_done || oclkdelay_center_calib_done)
oclkdelay_int_ref_req <= #TCQ 1'b0;
else if (oclkdelay_ref_cnt == 'd1)
oclkdelay_int_ref_req <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst)
ocal_act_wait_cnt <= #TCQ 'd0;
else if ((init_state_r == INIT_OCAL_CENTER_ACT_WAIT) && ocal_act_wait_cnt < 'd15)
ocal_act_wait_cnt <= #TCQ ocal_act_wait_cnt + 1;
else
ocal_act_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_OCLKDELAY_READ))
oclk_calib_resume_level <= #TCQ 1'b0;
else if (oclk_calib_resume)
oclk_calib_resume_level <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_RDLVL_ACT_WAIT) || prbs_rdlvl_done)
complex_rdlvl_int_ref_req <= #TCQ 1'b0;
else if (oclkdelay_ref_cnt == 'd1)
// complex_rdlvl_int_ref_req <= #TCQ 1'b1;
complex_rdlvl_int_ref_req <= #TCQ 1'b0; //temporary fix for read issue
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_RDLVL_COMPLEX_READ))
ext_int_ref_req <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_ACT_WAIT) && complex_rdlvl_int_ref_req)
ext_int_ref_req <= #TCQ 1'b1;
end
always @(posedge clk) begin
prech_done <= #TCQ prech_done_dly_r[15];
prech_done_r1 <= #TCQ prech_done_dly_r[15];
prech_done_r2 <= #TCQ prech_done_r1;
prech_done_r3 <= #TCQ prech_done_r2;
end
always @(posedge clk)
if (rst)
mpr_rdlvl_start <= #TCQ 1'b0;
else if (pi_dqs_found_done &&
(init_state_r == INIT_MPR_READ))
mpr_rdlvl_start <= #TCQ 1'b1;
always @(posedge clk)
phy_if_empty_r <= #TCQ phy_if_empty;
always @(posedge clk)
if (rst ||
((stg1_wr_rd_cnt == 'd2) && ~stg1_wr_done) || prbs_rdlvl_done)
prbs_gen_clk_en <= #TCQ 1'b0;
else if ((~phy_if_empty_r && rdlvl_stg1_done_r1 && ~prbs_rdlvl_done) ||
((init_state_r == INIT_RDLVL_ACT_WAIT) && rdlvl_stg1_done_r1 && (cnt_cmd_r == 'd127)) ||
((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && rdlvl_stg1_done_r1 && (complex_wait_cnt == 'd14))
|| (init_state_r == INIT_RDLVL_COMPLEX_READ) || ((init_state_r == INIT_PRECHARGE_PREWAIT) && prbs_rdlvl_start))
prbs_gen_clk_en <= #TCQ 1'b1;
//Enable for complex oclkdelay - used in prbs gen
always @(posedge clk)
if (rst ||
((stg1_wr_rd_cnt == 'd2) && ~stg1_wr_done) || complex_oclkdelay_calib_done ||
(complex_wait_cnt == 'd15 && complex_num_writes == 1 && complex_ocal_wr_start) ||
( init_state_r == INIT_RDLVL_STG1_WRITE && complex_num_writes_dec == 'd2) || ~complex_ocal_wr_start ||
(complex_byte_rd_done && init_state_r == INIT_RDLVL_COMPLEX_ACT ) ||
(init_state_r != INIT_OCAL_COMPLEX_RESUME_WAIT && init_state_r1 == INIT_OCAL_COMPLEX_RESUME_WAIT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT))
prbs_gen_oclk_clk_en <= #TCQ 1'b0;
else if ((~phy_if_empty_r && ~complex_oclkdelay_calib_done && prbs_rdlvl_done_r1) || // changed for new algo 3/26
((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && (complex_wait_cnt == 'd14)) ||
((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (complex_wait_cnt == 'd14)) ||
exit_ocal_complex_resume_wait ||
((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && ~stg1_wr_done && ~complex_row1_wr_done && ~complex_ocal_num_samples_done_r && (complex_wait_cnt == 'd14))
|| (init_state_r == INIT_RDLVL_COMPLEX_READ) )
prbs_gen_oclk_clk_en <= #TCQ 1'b1;
generate
if (RANKS < 2) begin
always @(posedge clk)
if (rst) begin
rdlvl_stg1_start <= #TCQ 1'b0;
rdlvl_stg1_start_int <= #TCQ 1'b0;
rdlvl_start_pre <= #TCQ 1'b0;
prbs_rdlvl_start <= #TCQ 1'b0;
end else begin
if (pi_dqs_found_done && cnt_cmd_done_r &&
(init_state_r == INIT_RDLVL_ACT_WAIT))
rdlvl_stg1_start_int <= #TCQ 1'b1;
if (pi_dqs_found_done &&
(init_state_r == INIT_RDLVL_STG1_READ))begin
rdlvl_start_pre <= #TCQ 1'b1;
rdlvl_stg1_start <= #TCQ rdlvl_start_dly0_r[14];
end
if (pi_dqs_found_done && rdlvl_stg1_done && ~prbs_rdlvl_done &&
(init_state_r == INIT_RDLVL_COMPLEX_READ) && (WRLVL == "ON")) begin
prbs_rdlvl_start <= #TCQ 1'b1;
end
end
end else begin
always @(posedge clk)
if (rst || rdlvl_stg1_rank_done) begin
rdlvl_stg1_start <= #TCQ 1'b0;
rdlvl_stg1_start_int <= #TCQ 1'b0;
rdlvl_start_pre <= #TCQ 1'b0;
prbs_rdlvl_start <= #TCQ 1'b0;
end else begin
if (pi_dqs_found_done && cnt_cmd_done_r &&
(init_state_r == INIT_RDLVL_ACT_WAIT))
rdlvl_stg1_start_int <= #TCQ 1'b1;
if (pi_dqs_found_done &&
(init_state_r == INIT_RDLVL_STG1_READ))begin
rdlvl_start_pre <= #TCQ 1'b1;
rdlvl_stg1_start <= #TCQ rdlvl_start_dly0_r[14];
end
if (pi_dqs_found_done && rdlvl_stg1_done && ~prbs_rdlvl_done &&
(init_state_r == INIT_RDLVL_COMPLEX_READ) && (WRLVL == "ON")) begin
prbs_rdlvl_start <= #TCQ 1'b1;
end
end
end
endgenerate
always @(posedge clk) begin
if (rst || dqsfound_retry || wrlvl_byte_redo) begin
pi_dqs_found_start <= #TCQ 1'b0;
wrcal_start <= #TCQ 1'b0;
end else begin
if (!pi_dqs_found_done && init_state_r == INIT_RDLVL_STG2_READ)
pi_dqs_found_start <= #TCQ 1'b1;
if (wrcal_start_dly_r[5])
wrcal_start <= #TCQ 1'b1;
end
end // else: !if(rst)
always @(posedge clk)
if (rst)
oclkdelay_calib_start <= #TCQ 1'b0;
else if (oclkdelay_start_dly_r[5])
oclkdelay_calib_start <= #TCQ 1'b1;
always @(posedge clk)
if (rst)
pi_dqs_found_done_r1 <= #TCQ 1'b0;
else
pi_dqs_found_done_r1 <= #TCQ pi_dqs_found_done;
always @(posedge clk)
wrlvl_final_r <= #TCQ wrlvl_final;
// Reset IN_FIFO after final write leveling to make sure the FIFO
// pointers are initialized
always @(posedge clk)
if (rst || (init_state_r == INIT_WRCAL_WRITE) || (init_state_r == INIT_REFRESH))
wrlvl_final_if_rst <= #TCQ 1'b0;
else if (wrlvl_done_r && //(wrlvl_final_r && wrlvl_done_r &&
(init_state_r == INIT_WRLVL_LOAD_MR2))
wrlvl_final_if_rst <= #TCQ 1'b1;
// Constantly enable DQS while write leveling is enabled in the memory
// This is more to get rid of warnings in simulation, can later change
// this code to only enable WRLVL_ACTIVE when WRLVL_START is asserted
always @(posedge clk)
if (rst ||
((init_state_r1 != INIT_WRLVL_START) &&
(init_state_r == INIT_WRLVL_START)))
wrlvl_odt_ctl <= #TCQ 1'b0;
else if (wrlvl_rank_done && ~wrlvl_rank_done_r1)
wrlvl_odt_ctl <= #TCQ 1'b1;
generate
if (nCK_PER_CLK == 4) begin: en_cnt_div4
always @ (posedge clk)
if (rst)
enable_wrlvl_cnt <= #TCQ 5'd0;
else if ((init_state_r == INIT_WRLVL_START) ||
(wrlvl_odt && (enable_wrlvl_cnt == 5'd0)))
enable_wrlvl_cnt <= #TCQ 5'd12;
else if ((enable_wrlvl_cnt > 5'd0) && ~(phy_ctl_full || phy_cmd_full))
enable_wrlvl_cnt <= #TCQ enable_wrlvl_cnt - 1;
// ODT stays asserted as long as write_calib
// signal is asserted
always @(posedge clk)
if (rst || wrlvl_odt_ctl)
wrlvl_odt <= #TCQ 1'b0;
else if (enable_wrlvl_cnt == 5'd1)
wrlvl_odt <= #TCQ 1'b1;
end else begin: en_cnt_div2
always @ (posedge clk)
if (rst)
enable_wrlvl_cnt <= #TCQ 5'd0;
else if ((init_state_r == INIT_WRLVL_START) ||
(wrlvl_odt && (enable_wrlvl_cnt == 5'd0)))
enable_wrlvl_cnt <= #TCQ 5'd21;
else if ((enable_wrlvl_cnt > 5'd0) && ~(phy_ctl_full || phy_cmd_full))
enable_wrlvl_cnt <= #TCQ enable_wrlvl_cnt - 1;
// ODT stays asserted as long as write_calib
// signal is asserted
always @(posedge clk)
if (rst || wrlvl_odt_ctl)
wrlvl_odt <= #TCQ 1'b0;
else if (enable_wrlvl_cnt == 5'd1)
wrlvl_odt <= #TCQ 1'b1;
end
endgenerate
always @(posedge clk)
if (rst || wrlvl_rank_done || done_dqs_tap_inc)
wrlvl_active <= #TCQ 1'b0;
else if ((enable_wrlvl_cnt == 5'd1) && wrlvl_odt && !wrlvl_active)
wrlvl_active <= #TCQ 1'b1;
// signal used to assert DQS for write leveling.
// the DQS will be asserted once every 16 clock cycles.
always @(posedge clk)begin
if(rst || (enable_wrlvl_cnt != 5'd1)) begin
wr_level_dqs_asrt <= #TCQ 1'd0;
end else if ((enable_wrlvl_cnt == 5'd1) && (wrlvl_active_r1)) begin
wr_level_dqs_asrt <= #TCQ 1'd1;
end
end
always @ (posedge clk) begin
if (rst || (wrlvl_done_r && ~wrlvl_done_r1))
dqs_asrt_cnt <= #TCQ 2'd0;
else if (wr_level_dqs_asrt && dqs_asrt_cnt != 2'd3)
dqs_asrt_cnt <= #TCQ (dqs_asrt_cnt + 1);
end
always @ (posedge clk) begin
if (rst || ~wrlvl_active)
wr_lvl_start <= #TCQ 1'd0;
else if (dqs_asrt_cnt == 2'd3)
wr_lvl_start <= #TCQ 1'd1;
end
always @(posedge clk) begin
if (rst)
wl_sm_start <= #TCQ 1'b0;
else
wl_sm_start <= #TCQ wr_level_dqs_asrt_r1;
end
always @(posedge clk) begin
wrlvl_active_r1 <= #TCQ wrlvl_active;
wr_level_dqs_asrt_r1 <= #TCQ wr_level_dqs_asrt;
wrlvl_done_r <= #TCQ wrlvl_done;
wrlvl_done_r1 <= #TCQ wrlvl_done_r;
wrlvl_rank_done_r1 <= #TCQ wrlvl_rank_done;
wrlvl_rank_done_r2 <= #TCQ wrlvl_rank_done_r1;
wrlvl_rank_done_r3 <= #TCQ wrlvl_rank_done_r2;
wrlvl_rank_done_r4 <= #TCQ wrlvl_rank_done_r3;
wrlvl_rank_done_r5 <= #TCQ wrlvl_rank_done_r4;
wrlvl_rank_done_r6 <= #TCQ wrlvl_rank_done_r5;
wrlvl_rank_done_r7 <= #TCQ wrlvl_rank_done_r6;
end
always @ (posedge clk) begin
//if (rst)
wrlvl_rank_cntr <= #TCQ 3'd0;
//else if (wrlvl_rank_done)
// wrlvl_rank_cntr <= #TCQ wrlvl_rank_cntr + 1'b1;
end
//*****************************************************************
// Precharge request logic - those calibration logic blocks
// that require greater than tRAS(max) to finish must break up
// their calibration into smaller units of time, with precharges
// issued in between. This is done using the XXX_PRECH_REQ and
// PRECH_DONE handshaking between PHY_INIT and those blocks
//*****************************************************************
// Shared request from multiple sources
assign prech_req = oclk_prech_req | rdlvl_prech_req | wrcal_prech_req | prbs_rdlvl_prech_req |
(dqs_found_prech_req & (init_state_r == INIT_RDLVL_STG2_READ_WAIT));
// Handshaking logic to force precharge during read leveling, and to
// notify read leveling logic when precharge has been initiated and
// it's okay to proceed with leveling again
always @(posedge clk)
if (rst) begin
prech_req_r <= #TCQ 1'b0;
prech_req_posedge_r <= #TCQ 1'b0;
prech_pending_r <= #TCQ 1'b0;
end else begin
prech_req_r <= #TCQ prech_req;
prech_req_posedge_r <= #TCQ prech_req & ~prech_req_r;
if (prech_req_posedge_r)
prech_pending_r <= #TCQ 1'b1;
// Clear after we've finished with the precharge and have
// returned to issuing read leveling calibration reads
else if (prech_done_pre)
prech_pending_r <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst || prech_done_r3)
mask_lim_done <= #TCQ 1'b0;
else if (prech_pending_r)
mask_lim_done <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst || prbs_rdlvl_done_r3)
complex_mask_lim_done <= #TCQ 1'b0;
else if (~prbs_rdlvl_done && complex_oclkdelay_calib_start_int)
complex_mask_lim_done <= #TCQ 1'b1;
end
//Complex oclkdelay calibrration
//***************************************************************************
// Various timing counters
//***************************************************************************
//*****************************************************************
// Generic delay for various states that require it (e.g. for turnaround
// between read and write). Make this a sufficiently large number of clock
// cycles to cover all possible frequencies and memory components)
// Requirements for this counter:
// 1. Greater than tMRD
// 2. tRFC (refresh-active) for DDR2
// 3. (list the other requirements, slacker...)
//*****************************************************************
always @(posedge clk) begin
case (init_state_r)
INIT_LOAD_MR_WAIT,
INIT_WRLVL_LOAD_MR_WAIT,
INIT_WRLVL_LOAD_MR2_WAIT,
INIT_MPR_WAIT,
INIT_MPR_DISABLE_PREWAIT,
INIT_MPR_DISABLE_WAIT,
INIT_OCLKDELAY_ACT_WAIT,
INIT_OCLKDELAY_WRITE_WAIT,
INIT_RDLVL_ACT_WAIT,
INIT_RDLVL_STG1_WRITE_READ,
INIT_RDLVL_STG2_READ_WAIT,
INIT_WRCAL_ACT_WAIT,
INIT_WRCAL_WRITE_READ,
INIT_WRCAL_READ_WAIT,
INIT_PRECHARGE_PREWAIT,
INIT_PRECHARGE_WAIT,
INIT_DDR2_PRECHARGE_WAIT,
INIT_REG_WRITE_WAIT,
INIT_REFRESH_WAIT,
INIT_REFRESH_RNK2_WAIT: begin
if (phy_ctl_full || phy_cmd_full)
cnt_cmd_r <= #TCQ cnt_cmd_r;
else
cnt_cmd_r <= #TCQ cnt_cmd_r + 1;
end
INIT_WRLVL_WAIT:
cnt_cmd_r <= #TCQ 'b0;
default:
cnt_cmd_r <= #TCQ 'b0;
endcase
end
// pulse when count reaches terminal count
always @(posedge clk)
cnt_cmd_done_r <= #TCQ (cnt_cmd_r == CNTNEXT_CMD);
// For ODT deassertion - hold throughout post read/write wait stage, but
// deassert before next command. The post read/write stage is very long, so
// we simply address the longest case here plus some margin.
always @(posedge clk)
cnt_cmd_done_m7_r <= #TCQ (cnt_cmd_r == (CNTNEXT_CMD - 7));
//************************************************************************
// Added to support PO fine delay inc when TG errors
always @(posedge clk) begin
case (init_state_r)
INIT_WRCAL_READ_WAIT: begin
if (phy_ctl_full || phy_cmd_full)
cnt_wait <= #TCQ cnt_wait;
else
cnt_wait <= #TCQ cnt_wait + 1;
end
default:
cnt_wait <= #TCQ 'b0;
endcase
end
always @(posedge clk)
cnt_wrcal_rd <= #TCQ (cnt_wait == 'd4);
always @(posedge clk) begin
if (rst || ~temp_wrcal_done)
temp_lmr_done <= #TCQ 1'b0;
else if (temp_wrcal_done && (init_state_r == INIT_LOAD_MR))
temp_lmr_done <= #TCQ 1'b1;
end
always @(posedge clk)
temp_wrcal_done_r <= #TCQ temp_wrcal_done;
always @(posedge clk)
if (rst) begin
tg_timer_go <= #TCQ 1'b0;
end else if ((PRE_REV3ES == "ON") && temp_wrcal_done && temp_lmr_done &&
(init_state_r == INIT_WRCAL_READ_WAIT)) begin
tg_timer_go <= #TCQ 1'b1;
end else begin
tg_timer_go <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst || (temp_wrcal_done && ~temp_wrcal_done_r) ||
(init_state_r == INIT_PRECHARGE_PREWAIT))
tg_timer <= #TCQ 'd0;
else if ((pi_phaselock_timer == PHASELOCKED_TIMEOUT) &&
tg_timer_go &&
(tg_timer != TG_TIMER_TIMEOUT))
tg_timer <= #TCQ tg_timer + 1;
end
always @(posedge clk) begin
if (rst)
tg_timer_done <= #TCQ 1'b0;
else if (tg_timer == TG_TIMER_TIMEOUT)
tg_timer_done <= #TCQ 1'b1;
else
tg_timer_done <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst)
no_rst_tg_mc <= #TCQ 1'b0;
else if ((init_state_r == INIT_WRCAL_ACT) && wrcal_read_req)
no_rst_tg_mc <= #TCQ 1'b1;
else
no_rst_tg_mc <= #TCQ 1'b0;
end
//************************************************************************
always @(posedge clk) begin
if (rst)
detect_pi_found_dqs <= #TCQ 1'b0;
else if ((cnt_cmd_r == 7'b0111111) &&
(init_state_r == INIT_RDLVL_STG2_READ_WAIT))
detect_pi_found_dqs <= #TCQ 1'b1;
else
detect_pi_found_dqs <= #TCQ 1'b0;
end
//*****************************************************************
// Initial delay after power-on for RESET, CKE
// NOTE: Could reduce power consumption by turning off these counters
// after initial power-up (at expense of more logic)
// NOTE: Likely can combine multiple counters into single counter
//*****************************************************************
// Create divided by 1024 version of clock
always @(posedge clk)
if (rst) begin
cnt_pwron_ce_r <= #TCQ 10'h000;
pwron_ce_r <= #TCQ 1'b0;
end else begin
cnt_pwron_ce_r <= #TCQ cnt_pwron_ce_r + 1;
pwron_ce_r <= #TCQ (cnt_pwron_ce_r == 10'h3FF);
end
// "Main" power-on counter - ticks every CLKDIV/1024 cycles
always @(posedge clk)
if (rst)
cnt_pwron_r <= #TCQ 'b0;
else if (pwron_ce_r)
cnt_pwron_r <= #TCQ cnt_pwron_r + 1;
always @(posedge clk)
if (rst || ~phy_ctl_ready) begin
cnt_pwron_reset_done_r <= #TCQ 1'b0;
cnt_pwron_cke_done_r <= #TCQ 1'b0;
end else begin
// skip power-up count for simulation purposes only
if ((SIM_INIT_OPTION == "SKIP_PU_DLY") ||
(SIM_INIT_OPTION == "SKIP_INIT")) begin
cnt_pwron_reset_done_r <= #TCQ 1'b1;
cnt_pwron_cke_done_r <= #TCQ 1'b1;
end else begin
// otherwise, create latched version of done signal for RESET, CKE
if (DRAM_TYPE == "DDR3") begin
if (!cnt_pwron_reset_done_r)
cnt_pwron_reset_done_r
<= #TCQ (cnt_pwron_r == PWRON_RESET_DELAY_CNT);
if (!cnt_pwron_cke_done_r)
cnt_pwron_cke_done_r
<= #TCQ (cnt_pwron_r == PWRON_CKE_DELAY_CNT);
end else begin // DDR2
cnt_pwron_reset_done_r <= #TCQ 1'b1; // not needed
if (!cnt_pwron_cke_done_r)
cnt_pwron_cke_done_r
<= #TCQ (cnt_pwron_r == PWRON_CKE_DELAY_CNT);
end
end
end // else: !if(rst || ~phy_ctl_ready)
always @(posedge clk)
cnt_pwron_cke_done_r1 <= #TCQ cnt_pwron_cke_done_r;
// Keep RESET asserted and CKE deasserted until after power-on delay
always @(posedge clk or posedge rst) begin
if (rst)
phy_reset_n <= #TCQ 1'b0;
else
phy_reset_n <= #TCQ cnt_pwron_reset_done_r;
// phy_cke <= #TCQ {CKE_WIDTH{cnt_pwron_cke_done_r}};
end
//*****************************************************************
// Counter for tXPR (pronouned "Tax-Payer") - wait time after
// CKE deassertion before first MRS command can be asserted
//*****************************************************************
always @(posedge clk)
if (!cnt_pwron_cke_done_r) begin
cnt_txpr_r <= #TCQ 'b0;
cnt_txpr_done_r <= #TCQ 1'b0;
end else begin
cnt_txpr_r <= #TCQ cnt_txpr_r + 1;
if (!cnt_txpr_done_r)
cnt_txpr_done_r <= #TCQ (cnt_txpr_r == TXPR_DELAY_CNT);
end
//*****************************************************************
// Counter for the initial 400ns wait for issuing precharge all
// command after CKE assertion. Only for DDR2.
//*****************************************************************
always @(posedge clk)
if (!cnt_pwron_cke_done_r) begin
cnt_init_pre_wait_r <= #TCQ 'b0;
cnt_init_pre_wait_done_r <= #TCQ 1'b0;
end else begin
cnt_init_pre_wait_r <= #TCQ cnt_init_pre_wait_r + 1;
if (!cnt_init_pre_wait_done_r)
cnt_init_pre_wait_done_r
<= #TCQ (cnt_init_pre_wait_r >= DDR2_INIT_PRE_CNT);
end
//*****************************************************************
// Wait for both DLL to lock (tDLLK) and ZQ calibration to finish
// (tZQINIT). Both take the same amount of time (512*tCK)
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_ZQCL) begin
cnt_dllk_zqinit_r <= #TCQ 'b0;
cnt_dllk_zqinit_done_r <= #TCQ 1'b0;
end else if (~(phy_ctl_full || phy_cmd_full)) begin
cnt_dllk_zqinit_r <= #TCQ cnt_dllk_zqinit_r + 1;
if (!cnt_dllk_zqinit_done_r)
cnt_dllk_zqinit_done_r
<= #TCQ (cnt_dllk_zqinit_r == TDLLK_TZQINIT_DELAY_CNT);
end
//*****************************************************************
// Keep track of which MRS counter needs to be programmed during
// memory initialization
// The counter and the done signal are reset an additional time
// for DDR2. The same signals are used for the additional DDR2
// initialization sequence.
//*****************************************************************
always @(posedge clk)
if ((init_state_r == INIT_IDLE)||
((init_state_r == INIT_REFRESH)
&& (~mem_init_done_r))) begin
cnt_init_mr_r <= #TCQ 'b0;
cnt_init_mr_done_r <= #TCQ 1'b0;
end else if (init_state_r == INIT_LOAD_MR) begin
cnt_init_mr_r <= #TCQ cnt_init_mr_r + 1;
cnt_init_mr_done_r <= #TCQ (cnt_init_mr_r == INIT_CNT_MR_DONE);
end
//*****************************************************************
// Flag to tell if the first precharge for DDR2 init sequence is
// done
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE)
ddr2_pre_flag_r<= #TCQ 'b0;
else if (init_state_r == INIT_LOAD_MR)
ddr2_pre_flag_r<= #TCQ 1'b1;
// reset the flag for multi rank case
else if ((ddr2_refresh_flag_r) &&
(init_state_r == INIT_LOAD_MR_WAIT)&&
(cnt_cmd_done_r) && (cnt_init_mr_done_r))
ddr2_pre_flag_r <= #TCQ 'b0;
//*****************************************************************
// Flag to tell if the refresh stat for DDR2 init sequence is
// reached
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE)
ddr2_refresh_flag_r<= #TCQ 'b0;
else if ((init_state_r == INIT_REFRESH) && (~mem_init_done_r))
// reset the flag for multi rank case
ddr2_refresh_flag_r<= #TCQ 1'b1;
else if ((ddr2_refresh_flag_r) &&
(init_state_r == INIT_LOAD_MR_WAIT)&&
(cnt_cmd_done_r) && (cnt_init_mr_done_r))
ddr2_refresh_flag_r <= #TCQ 'b0;
//*****************************************************************
// Keep track of the number of auto refreshes for DDR2
// initialization. The spec asks for a minimum of two refreshes.
// Four refreshes are performed here. The two extra refreshes is to
// account for the 200 clock cycle wait between step h and l.
// Without the two extra refreshes we would have to have a
// wait state.
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE) begin
cnt_init_af_r <= #TCQ 'b0;
cnt_init_af_done_r <= #TCQ 1'b0;
end else if ((init_state_r == INIT_REFRESH) && (~mem_init_done_r))begin
cnt_init_af_r <= #TCQ cnt_init_af_r + 1;
cnt_init_af_done_r <= #TCQ (cnt_init_af_r == 2'b11);
end
//*****************************************************************
// Keep track of the register control word programming for
// DDR3 RDIMM
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE)
reg_ctrl_cnt_r <= #TCQ 'b0;
else if (init_state_r == INIT_REG_WRITE)
reg_ctrl_cnt_r <= #TCQ reg_ctrl_cnt_r + 1;
generate
if (RANKS < 2) begin: one_rank
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done ||
(complex_byte_rd_done) || prbs_rdlvl_done_pulse )
stg1_wr_done <= #TCQ 1'b0;
else if (init_state_r == INIT_RDLVL_STG1_WRITE_READ)
stg1_wr_done <= #TCQ 1'b1;
end else begin: two_ranks
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done ||
(complex_byte_rd_done) || prbs_rdlvl_done_pulse ||
(rdlvl_stg1_rank_done ))
stg1_wr_done <= #TCQ 1'b0;
else if (init_state_r == INIT_RDLVL_STG1_WRITE_READ)
stg1_wr_done <= #TCQ 1'b1;
end
endgenerate
always @(posedge clk)
if (rst)
rnk_ref_cnt <= #TCQ 1'b0;
else if (stg1_wr_done &&
(init_state_r == INIT_REFRESH_WAIT) && cnt_cmd_done_r)
rnk_ref_cnt <= #TCQ ~rnk_ref_cnt;
always @(posedge clk)
if (rst || (init_state_r == INIT_MPR_RDEN) || (init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) || (init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) || (init_state_r ==INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT))
num_refresh <= #TCQ 'd0;
else if ((init_state_r == INIT_REFRESH) &&
(~pi_dqs_found_done || ((DRAM_TYPE == "DDR3") && ~oclkdelay_calib_done) ||
(rdlvl_stg1_done && ~prbs_rdlvl_done) ||
(prbs_rdlvl_done && ~complex_oclkdelay_calib_done) ||
((CLK_PERIOD/nCK_PER_CLK <= 2500) && wrcal_done && ~rdlvl_stg1_done) ||
((CLK_PERIOD/nCK_PER_CLK > 2500) && wrlvl_done_r1 && ~rdlvl_stg1_done)))
num_refresh <= #TCQ num_refresh + 1;
//***************************************************************************
// Initialization state machine
//***************************************************************************
//*****************************************************************
// Next-state logic
//*****************************************************************
always @(posedge clk)
if (rst)begin
init_state_r <= #TCQ INIT_IDLE;
init_state_r1 <= #TCQ INIT_IDLE;
end else begin
init_state_r <= #TCQ init_next_state;
init_state_r1 <= #TCQ init_state_r;
end
always @(*) begin
init_next_state = init_state_r;
(* full_case, parallel_case *) case (init_state_r)
//*******************************************************
// DRAM initialization
//*******************************************************
// Initial state - wait for:
// 1. Power-on delays to pass
// 2. PHY Control Block to assert phy_ctl_ready
// 3. PHY Control FIFO must not be FULL
// 4. Read path initialization to finish
INIT_IDLE:
if (cnt_pwron_cke_done_r && phy_ctl_ready && ck_addr_cmd_delay_done && delay_incdec_done
&& ~(phy_ctl_full || phy_cmd_full) ) begin
// If skipping memory initialization (simulation only)
if (SIM_INIT_OPTION == "SKIP_INIT")
//if (WRLVL == "ON")
// Proceed to write leveling
// init_next_state = INIT_WRLVL_START;
//else //if (SIM_CAL_OPTION != "SKIP_CAL")
// Proceed to Phaser_In phase lock
init_next_state = INIT_RDLVL_ACT;
// else
// Skip read leveling
//init_next_state = INIT_DONE;
else
init_next_state = INIT_WAIT_CKE_EXIT;
end
// Wait minimum of Reset CKE exit time (tXPR = max(tXS,
INIT_WAIT_CKE_EXIT:
if ((cnt_txpr_done_r) && (DRAM_TYPE == "DDR3")
&& ~(phy_ctl_full || phy_cmd_full)) begin
if((REG_CTRL == "ON") && ((nCS_PER_RANK > 1) ||
(RANKS > 1)))
//register write for reg dimm. Some register chips
// have the register chip in a pre-programmed state
// in that case the nCS_PER_RANK == 1 && RANKS == 1
init_next_state = INIT_REG_WRITE;
else
// Load mode register - this state is repeated multiple times
init_next_state = INIT_LOAD_MR;
end else if ((cnt_init_pre_wait_done_r) && (DRAM_TYPE == "DDR2")
&& ~(phy_ctl_full || phy_cmd_full))
// DDR2 start with a precharge all command
init_next_state = INIT_DDR2_PRECHARGE;
INIT_REG_WRITE:
init_next_state = INIT_REG_WRITE_WAIT;
INIT_REG_WRITE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if(reg_ctrl_cnt_r == 4'd8)
init_next_state = INIT_LOAD_MR;
else
init_next_state = INIT_REG_WRITE;
end
INIT_LOAD_MR:
init_next_state = INIT_LOAD_MR_WAIT;
// After loading MR, wait at least tMRD
INIT_LOAD_MR_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
// If finished loading all mode registers, proceed to next step
if (prbs_rdlvl_done && pi_dqs_found_done && rdlvl_stg1_done)
// for ddr3 when the correct burst length is writtern at end
init_next_state = INIT_PRECHARGE;
else if (~wrcal_done && temp_lmr_done)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (cnt_init_mr_done_r)begin
if(DRAM_TYPE == "DDR3")
init_next_state = INIT_ZQCL;
else begin //DDR2
if(ddr2_refresh_flag_r)begin
// memory initialization per rank for multi-rank case
if (!mem_init_done_r && (chip_cnt_r <= RANKS-1))
init_next_state = INIT_DDR2_MULTI_RANK;
else
init_next_state = INIT_RDLVL_ACT;
// ddr2 initialization done.load mode state after refresh
end else
init_next_state = INIT_DDR2_PRECHARGE;
end
end else
init_next_state = INIT_LOAD_MR;
end
// DDR2 multi rank transition state
INIT_DDR2_MULTI_RANK:
init_next_state = INIT_DDR2_MULTI_RANK_WAIT;
INIT_DDR2_MULTI_RANK_WAIT:
init_next_state = INIT_DDR2_PRECHARGE;
// Initial ZQ calibration
INIT_ZQCL:
init_next_state = INIT_WAIT_DLLK_ZQINIT;
// Wait until both DLL have locked, and ZQ calibration done
INIT_WAIT_DLLK_ZQINIT:
if (cnt_dllk_zqinit_done_r && ~(phy_ctl_full || phy_cmd_full))
// memory initialization per rank for multi-rank case
if (!mem_init_done_r && (chip_cnt_r <= RANKS-1))
init_next_state = INIT_LOAD_MR;
//else if (WRLVL == "ON")
// init_next_state = INIT_WRLVL_START;
else
// skip write-leveling (e.g. for DDR2 interface)
init_next_state = INIT_RDLVL_ACT;
// Initial precharge for DDR2
INIT_DDR2_PRECHARGE:
init_next_state = INIT_DDR2_PRECHARGE_WAIT;
INIT_DDR2_PRECHARGE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if (ddr2_pre_flag_r)
init_next_state = INIT_REFRESH;
else // from precharge state initially go to load mode
init_next_state = INIT_LOAD_MR;
end
INIT_REFRESH:
if ((RANKS == 2) && (chip_cnt_r == RANKS - 1))
init_next_state = INIT_REFRESH_RNK2_WAIT;
else
init_next_state = INIT_REFRESH_WAIT;
INIT_REFRESH_RNK2_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_PRECHARGE;
INIT_REFRESH_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))begin
if(cnt_init_af_done_r && (~mem_init_done_r))
// go to lm state as part of DDR2 init sequence
init_next_state = INIT_LOAD_MR;
// Go to state to issue back-to-back writes during limit check and centering
else if (~oclkdelay_calib_done && (mpr_last_byte_done || mpr_rdlvl_done) && (DRAM_TYPE == "DDR3")) begin
if (num_refresh == 'd8)
init_next_state = INIT_OCAL_CENTER_ACT;
else
init_next_state = INIT_REFRESH;
end else if(rdlvl_stg1_done && oclkdelay_center_calib_done &&
complex_oclkdelay_calib_done && ~wrlvl_done_r1 && (WRLVL == "ON"))
init_next_state = INIT_WRLVL_START;
else if (pi_dqs_found_done && ~wrlvl_done_r1 && ~wrlvl_final && ~wrlvl_byte_redo && (WRLVL == "ON"))
init_next_state = INIT_WRLVL_START;
else if ((((prbs_last_byte_done_r || prbs_rdlvl_done) && ~complex_oclkdelay_calib_done
&& pi_dqs_found_done) && (WRLVL == "ON")) //&& rdlvl_stg1_done // changed for new algo 3/26
&& mem_init_done_r) begin
if (num_refresh == 'd8) begin
if (BYPASS_COMPLEX_OCAL == "FALSE")
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else
init_next_state = INIT_WRCAL_ACT;
end else
init_next_state = INIT_REFRESH;
end else if (~pi_dqs_found_done ||
(rdlvl_stg1_done && ~prbs_rdlvl_done && ~complex_oclkdelay_calib_done) ||
((CLK_PERIOD/nCK_PER_CLK <= 2500) && wrcal_done && ~rdlvl_stg1_done) ||
((CLK_PERIOD/nCK_PER_CLK > 2500) && wrlvl_done_r1 && ~rdlvl_stg1_done)) begin
if (num_refresh == 'd8)
init_next_state = INIT_RDLVL_ACT;
else
init_next_state = INIT_REFRESH;
end else if ((~wrcal_done && wrlvl_byte_redo)&& (DRAM_TYPE == "DDR3")
&& (CLK_PERIOD/nCK_PER_CLK > 2500))
init_next_state = INIT_WRLVL_LOAD_MR2;
else if (((prbs_rdlvl_done && rdlvl_stg1_done && complex_oclkdelay_calib_done && pi_dqs_found_done) && (WRLVL == "ON"))
&& mem_init_done_r && (CLK_PERIOD/nCK_PER_CLK > 2500))
init_next_state = INIT_WRCAL_ACT;
else if (pi_dqs_found_done && (DRAM_TYPE == "DDR3") && ~(mpr_last_byte_done || mpr_rdlvl_done)) begin
if (num_refresh == 'd8)
init_next_state = INIT_MPR_RDEN;
else
init_next_state = INIT_REFRESH;
end else if (((oclkdelay_calib_done && wrlvl_final && ~wrlvl_done_r1) || // changed for new algo 3/25
(~wrcal_done && wrlvl_byte_redo)) && (DRAM_TYPE == "DDR3"))
init_next_state = INIT_WRLVL_LOAD_MR2;
else if ((~wrcal_done && (WRLVL == "ON") && (CLK_PERIOD/nCK_PER_CLK <= 2500))
&& pi_dqs_found_done)
init_next_state = INIT_WRCAL_ACT;
else if (mem_init_done_r) begin
if (RANKS < 2)
init_next_state = INIT_RDLVL_ACT;
else if (stg1_wr_done && ~rnk_ref_cnt && ~rdlvl_stg1_done)
init_next_state = INIT_PRECHARGE;
else
init_next_state = INIT_RDLVL_ACT;
end else // to DDR2 init state as part of DDR2 init sequence
init_next_state = INIT_REFRESH;
end
//******************************************************
// Write Leveling
//*******************************************************
// Enable write leveling in MR1 and start write leveling
// for current rank
INIT_WRLVL_START:
init_next_state = INIT_WRLVL_WAIT;
// Wait for both MR load and write leveling to complete
// (write leveling should take much longer than MR load..)
INIT_WRLVL_WAIT:
if (wrlvl_rank_done_r7 && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_WRLVL_LOAD_MR;
// Disable write leveling in MR1 for current rank
INIT_WRLVL_LOAD_MR:
init_next_state = INIT_WRLVL_LOAD_MR_WAIT;
INIT_WRLVL_LOAD_MR_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_WRLVL_LOAD_MR2;
// Load MR2 to set ODT: Dynamic ODT for single rank case
// And ODTs for multi-rank case as well
INIT_WRLVL_LOAD_MR2:
init_next_state = INIT_WRLVL_LOAD_MR2_WAIT;
// Wait tMRD before proceeding
INIT_WRLVL_LOAD_MR2_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
//if (wrlvl_byte_done)
// init_next_state = INIT_PRECHARGE_PREWAIT;
// else if ((RANKS == 2) && wrlvl_rank_done_r2)
// init_next_state = INIT_WRLVL_LOAD_MR2_WAIT;
if (~wrlvl_done_r1)
init_next_state = INIT_WRLVL_START;
else if (SIM_CAL_OPTION == "SKIP_CAL")
// If skip rdlvl, then we're done
init_next_state = INIT_DONE;
else
// Otherwise, proceed to read leveling
//init_next_state = INIT_RDLVL_ACT;
init_next_state = INIT_PRECHARGE_PREWAIT;
end
//*******************************************************
// Read Leveling
//*******************************************************
// single row activate. All subsequent read leveling writes and
// read will take place in this row
INIT_RDLVL_ACT:
init_next_state = INIT_RDLVL_ACT_WAIT;
// hang out for awhile before issuing subsequent column commands
// it's also possible to reach this state at various points
// during read leveling - determine what the current stage is
INIT_RDLVL_ACT_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
// Just finished an activate. Now either write, read, or precharge
// depending on where we are in the training sequence
if (!pi_calib_done_r1)
init_next_state = INIT_PI_PHASELOCK_READS;
else if (!pi_dqs_found_done)
// (!pi_dqs_found_start || pi_dqs_found_rank_done))
init_next_state = INIT_RDLVL_STG2_READ;
else if (~wrcal_done && (WRLVL == "ON") && (CLK_PERIOD/nCK_PER_CLK <= 2500))
init_next_state = INIT_WRCAL_ACT_WAIT;
else if ((!rdlvl_stg1_done && ~stg1_wr_done && ~rdlvl_last_byte_done) ||
(!prbs_rdlvl_done && ~stg1_wr_done && ~prbs_last_byte_done)) begin
// Added to avoid rdlvl_stg1 write data pattern at the start of PRBS rdlvl
if (!prbs_rdlvl_done && ~stg1_wr_done && rdlvl_last_byte_done)
init_next_state = INIT_RDLVL_ACT_WAIT;
else
init_next_state = INIT_RDLVL_STG1_WRITE;
end else if ((!rdlvl_stg1_done && rdlvl_stg1_start_int) || !prbs_rdlvl_done) begin
if (rdlvl_last_byte_done || prbs_last_byte_done)
// Added to avoid extra reads at the end of read leveling
init_next_state = INIT_RDLVL_ACT_WAIT;
else begin
// Case 2: If in stage 1, and just precharged after training
// previous byte, then continue reading
if (rdlvl_stg1_done)
init_next_state = INIT_RDLVL_STG1_WRITE_READ;
else
init_next_state = INIT_RDLVL_STG1_READ;
end
end else if ((prbs_rdlvl_done && rdlvl_stg1_done && (RANKS == 1)) && (WRLVL == "ON") &&
(CLK_PERIOD/nCK_PER_CLK > 2500))
init_next_state = INIT_WRCAL_ACT_WAIT;
else
// Otherwise, if we're finished with calibration, then precharge
// the row - silly, because we just opened it - possible to take
// this out by adding logic to avoid the ACT in first place. Make
// sure that cnt_cmd_done will handle tRAS(min)
init_next_state = INIT_PRECHARGE_PREWAIT;
end
//**************************************************
// Back-to-back reads for Phaser_IN Phase locking
// DQS to FREQ_REF clock
//**************************************************
INIT_PI_PHASELOCK_READS:
if (pi_phase_locked_all_r3 && ~pi_phase_locked_all_r4)
init_next_state = INIT_PRECHARGE_PREWAIT;
//*********************************************
// Stage 1 read-leveling (write and continuous read)
//*********************************************
// Write training pattern for stage 1
// PRBS pattern of TBD length
INIT_RDLVL_STG1_WRITE:
// 4:1 DDR3 BL8 will require all 8 words in 1 DIV4 clock cycle
// 2:1 DDR2/DDR3 BL8 will require 2 DIV2 clock cycles for 8 words
// 2:1 DDR2 BL4 will require 1 DIV2 clock cycle for 4 words
// An entire row worth of writes issued before proceeding to reads
// The number of write is (2^column width)/burst length to accomodate
// PRBS pattern for window detection.
//VCCO/VCCAUX write is not done
if ((complex_num_writes_dec == 1) && ~complex_row0_wr_done && prbs_rdlvl_done && rdlvl_stg1_done_r1)
init_next_state = INIT_OCAL_COMPLEX_WRITE_WAIT;
//back to back write from row1
else if (stg1_wr_rd_cnt == 9'd1) begin
if (rdlvl_stg1_done_r1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else
init_next_state = INIT_RDLVL_STG1_WRITE_READ;
end
INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT:
if(read_pause_ext) begin
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
end else begin
if (prech_req_posedge_r || complex_rdlvl_int_ref_req || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15)
//At the end of the byte, it goes to REFRESH
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE;
end
INIT_RDLVL_COMPLEX_PRECHARGE:
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_WAIT;
INIT_RDLVL_COMPLEX_PRECHARGE_WAIT:
if (prech_req_posedge_r || complex_rdlvl_int_ref_req || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15) begin
if (prbs_rdlvl_done || prbs_last_byte_done_r) begin // changed for new algo 3/26
// added condition to ensure that limit starts after rdlvl_stg1_done is asserted in the bypass complex rdlvl mode
if ((~prbs_rdlvl_done && complex_oclkdelay_calib_start_int) || ~lim_done)
init_next_state = INIT_OCAL_CENTER_ACT; //INIT_OCAL_COMPLEX_ACT; // changed for new algo 3/26
else if (lim_done && complex_oclkdelay_calib_start_r2)
init_next_state = INIT_RDLVL_COMPLEX_ACT;
else
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_WAIT;
end else
init_next_state = INIT_RDLVL_COMPLEX_ACT;
end
INIT_RDLVL_COMPLEX_ACT:
init_next_state = INIT_RDLVL_COMPLEX_ACT_WAIT;
INIT_RDLVL_COMPLEX_ACT_WAIT:
if (complex_rdlvl_int_ref_req)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15) begin
if (oclkdelay_center_calib_start)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
else if (stg1_wr_done)
init_next_state = INIT_RDLVL_COMPLEX_READ;
else if (~complex_row1_wr_done)
if (complex_oclkdelay_calib_start_int && complex_ocal_num_samples_done_r) //WAIT for resume signal for write
init_next_state = INIT_OCAL_COMPLEX_RESUME_WAIT;
else
init_next_state = INIT_RDLVL_STG1_WRITE;
else
init_next_state = INIT_RDLVL_STG1_WRITE_READ;
end
// Write-read turnaround
INIT_RDLVL_STG1_WRITE_READ:
if (reset_rd_addr_r1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))begin
if (rdlvl_stg1_done_r1)
init_next_state = INIT_RDLVL_COMPLEX_READ;
else
init_next_state = INIT_RDLVL_STG1_READ;
end
// Continuous read, where interruptible by precharge request from
// calibration logic. Also precharges when stage 1 is complete
// No precharges when reads provided to Phaser_IN for phase locking
// FREQ_REF to read DQS since data integrity is not important.
INIT_RDLVL_STG1_READ:
if (rdlvl_stg1_rank_done || (rdlvl_stg1_done && ~rdlvl_stg1_done_r1) ||
prech_req_posedge_r || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
INIT_RDLVL_COMPLEX_READ:
if (prech_req_posedge_r || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
//For non-back-to-back reads from row0 (VCCO and VCCAUX pattern)
else if (~prbs_rdlvl_done && (complex_num_reads_dec == 1) && ~complex_row0_rd_done)
init_next_state = INIT_RDLVL_COMPLEX_READ_WAIT;
//For back-to-back reads from row1 (ISI pattern)
else if (stg1_wr_rd_cnt == 'd1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
INIT_RDLVL_COMPLEX_READ_WAIT:
if (prech_req_posedge_r || complex_rdlvl_int_ref_req || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (stg1_wr_rd_cnt == 'd1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15)
init_next_state = INIT_RDLVL_COMPLEX_READ;
//*********************************************
// DQSFOUND calibration (set of 4 reads with gaps)
//*********************************************
// Read of training data. Note that Stage 2 is not a constant read,
// instead there is a large gap between each set of back-to-back reads
INIT_RDLVL_STG2_READ:
// 4 read commands issued back-to-back
if (num_reads == 'b1)
init_next_state = INIT_RDLVL_STG2_READ_WAIT;
// Wait before issuing the next set of reads. If a precharge request
// comes in then handle - this can occur after stage 2 calibration is
// completed for a DQS group
INIT_RDLVL_STG2_READ_WAIT:
if (~(phy_ctl_full || phy_cmd_full)) begin
if (pi_dqs_found_rank_done ||
pi_dqs_found_done || prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (cnt_cmd_done_r)
init_next_state = INIT_RDLVL_STG2_READ;
end
//******************************************************************
// MPR Read Leveling for DDR3 OCLK_DELAYED calibration
//******************************************************************
// Issue Load Mode Register 3 command with A[2]=1, A[1:0]=2'b00
// to enable Multi Purpose Register (MPR) Read
INIT_MPR_RDEN:
init_next_state = INIT_MPR_WAIT;
//Wait tMRD, tMOD
INIT_MPR_WAIT:
if (cnt_cmd_done_r) begin
init_next_state = INIT_MPR_READ;
end
// Issue back-to-back read commands to read from MPR with
// Address bus 0x0000 for BL=8. DQ[0] will output the pre-defined
// MPR pattern of 01010101 (Rise0 = 1'b0, Fall0 = 1'b1 ...)
INIT_MPR_READ:
if (mpr_rdlvl_done || mpr_rnk_done || rdlvl_prech_req)
init_next_state = INIT_MPR_DISABLE_PREWAIT;
INIT_MPR_DISABLE_PREWAIT:
if (cnt_cmd_done_r)
init_next_state = INIT_MPR_DISABLE;
// Issue Load Mode Register 3 command with A[2]=0 to disable
// MPR read
INIT_MPR_DISABLE:
init_next_state = INIT_MPR_DISABLE_WAIT;
INIT_MPR_DISABLE_WAIT:
init_next_state = INIT_PRECHARGE_PREWAIT;
//***********************************************************************
// OCLKDELAY Calibration
//***********************************************************************
// This calibration requires single write followed by single read to
// determine the Phaser_Out stage 3 delay required to center write DQS
// in write DQ valid window.
// Single Row Activate command before issuing Write command
INIT_OCLKDELAY_ACT:
init_next_state = INIT_OCLKDELAY_ACT_WAIT;
INIT_OCLKDELAY_ACT_WAIT:
if (cnt_cmd_done_r && ~oclk_prech_req)
init_next_state = INIT_OCLKDELAY_WRITE;
else if (oclkdelay_calib_done || prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
INIT_OCLKDELAY_WRITE:
if (oclk_wr_cnt == 4'd1)
init_next_state = INIT_OCLKDELAY_WRITE_WAIT;
INIT_OCLKDELAY_WRITE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if (oclkdelay_int_ref_req)
init_next_state = INIT_PRECHARGE_PREWAIT;
else
init_next_state = INIT_OCLKDELAY_READ;
end
INIT_OCLKDELAY_READ:
init_next_state = INIT_OCLKDELAY_READ_WAIT;
INIT_OCLKDELAY_READ_WAIT:
if (~(phy_ctl_full || phy_cmd_full)) begin
if ((oclk_calib_resume_level || oclk_calib_resume) && ~oclkdelay_int_ref_req)
init_next_state = INIT_OCLKDELAY_WRITE;
else if (oclkdelay_calib_done || prech_req_posedge_r ||
wrlvl_final || oclkdelay_int_ref_req)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (oclkdelay_center_calib_start)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
end
//*********************************************
// Write calibration
//*********************************************
// single row activate
INIT_WRCAL_ACT:
init_next_state = INIT_WRCAL_ACT_WAIT;
// hang out for awhile before issuing subsequent column command
INIT_WRCAL_ACT_WAIT:
if (cnt_cmd_done_r && ~wrcal_prech_req)
init_next_state = INIT_WRCAL_WRITE;
else if (wrcal_done || prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
// Write training pattern for write calibration
INIT_WRCAL_WRITE:
// Once we've issued enough commands for 8 words - proceed to reads
//if (burst_addr_r == 1'b1)
if (wrcal_wr_cnt == 4'd1)
init_next_state = INIT_WRCAL_WRITE_READ;
// Write-read turnaround
INIT_WRCAL_WRITE_READ:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_WRCAL_READ;
else if (dqsfound_retry)
init_next_state = INIT_RDLVL_STG2_READ_WAIT;
INIT_WRCAL_READ:
if (burst_addr_r == 1'b1)
init_next_state = INIT_WRCAL_READ_WAIT;
INIT_WRCAL_READ_WAIT:
if (~(phy_ctl_full || phy_cmd_full)) begin
if (wrcal_resume_r) begin
if (wrcal_final_chk)
init_next_state = INIT_WRCAL_READ;
else
init_next_state = INIT_WRCAL_WRITE;
end else if (wrcal_done || prech_req_posedge_r || wrcal_act_req ||
// Added to support PO fine delay inc when TG errors
wrlvl_byte_redo || (temp_wrcal_done && ~temp_lmr_done))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (dqsfound_retry)
init_next_state = INIT_RDLVL_STG2_READ_WAIT;
else if (wrcal_read_req && cnt_wrcal_rd)
init_next_state = INIT_WRCAL_MULT_READS;
end
INIT_WRCAL_MULT_READS:
// multiple read commands issued back-to-back
if (wrcal_reads == 'b1)
init_next_state = INIT_WRCAL_READ_WAIT;
//*********************************************
// Handling of precharge during and in between read-level stages
//*********************************************
// Make sure we aren't violating any timing specs by precharging
// immediately
INIT_PRECHARGE_PREWAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_PRECHARGE;
// Initiate precharge
INIT_PRECHARGE:
init_next_state = INIT_PRECHARGE_WAIT;
INIT_PRECHARGE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if ((wrcal_sanity_chk_done && (DRAM_TYPE == "DDR3")) ||
(rdlvl_stg1_done && prbs_rdlvl_done && pi_dqs_found_done &&
(DRAM_TYPE == "DDR2")))
init_next_state = INIT_DONE;
else if ((wrcal_done || (WRLVL == "OFF")) && rdlvl_stg1_done && prbs_rdlvl_done &&
pi_dqs_found_done && complex_oclkdelay_calib_done && wrlvl_done_r1 && ((ddr3_lm_done_r) || (DRAM_TYPE == "DDR2")))
init_next_state = INIT_WRCAL_ACT;
else if ((wrcal_done || (WRLVL == "OFF") || (~wrcal_done && temp_wrcal_done && ~temp_lmr_done))
&& (rdlvl_stg1_done || (~wrcal_done && temp_wrcal_done && ~temp_lmr_done))
&& prbs_rdlvl_done && complex_oclkdelay_calib_done && wrlvl_done_r1 &rdlvl_stg1_done && pi_dqs_found_done) begin
// after all calibration program the correct burst length
init_next_state = INIT_LOAD_MR;
// Added to support PO fine delay inc when TG errors
end else if (~wrcal_done && temp_wrcal_done && temp_lmr_done)
init_next_state = INIT_WRCAL_READ_WAIT;
else if (rdlvl_stg1_done && pi_dqs_found_done && (WRLVL == "ON"))
// If read leveling finished, proceed to write calibration
init_next_state = INIT_REFRESH;
else
// Otherwise, open row for read-leveling purposes
init_next_state = INIT_REFRESH;
end
//*******************************************************
// COMPLEX OCLK calibration - for fragmented write
//*******************************************************
INIT_OCAL_COMPLEX_ACT:
init_next_state = INIT_OCAL_COMPLEX_ACT_WAIT;
INIT_OCAL_COMPLEX_ACT_WAIT:
if (complex_wait_cnt =='d15)
init_next_state = INIT_RDLVL_STG1_WRITE;
INIT_OCAL_COMPLEX_WRITE_WAIT:
if (prech_req_posedge_r || (complex_oclkdelay_calib_done && ~complex_oclkdelay_calib_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (stg1_wr_rd_cnt == 'd1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15)
init_next_state = INIT_RDLVL_STG1_WRITE;
//wait for all srg2/stg3 tap movement is done and go back to write again
INIT_OCAL_COMPLEX_RESUME_WAIT:
if (complex_oclk_calib_resume)
init_next_state = INIT_RDLVL_STG1_WRITE;
else if (complex_oclkdelay_calib_done || complex_ocal_ref_req )
init_next_state = INIT_PRECHARGE_PREWAIT;
//*******************************************************
// OCAL STG3 Centering calibration
//*******************************************************
INIT_OCAL_CENTER_ACT:
init_next_state = INIT_OCAL_CENTER_ACT_WAIT;
INIT_OCAL_CENTER_ACT_WAIT:
if (ocal_act_wait_cnt == 'd15)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
INIT_OCAL_CENTER_WRITE:
if(!oclk_center_write_resume && !lim_wr_req)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
INIT_OCAL_CENTER_WRITE_WAIT:
//if (oclkdelay_center_calib_done || prech_req_posedge_r)
if (prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (lim_done && ~mask_lim_done && ~complex_mask_lim_done && oclkdelay_calib_done && ~oclkdelay_center_calib_start)
init_next_state = INIT_OCAL_COMPLEX_ACT_WAIT;
else if (lim_done && ~mask_lim_done && ~complex_mask_lim_done && ~oclkdelay_center_calib_start)
init_next_state = INIT_OCLKDELAY_READ_WAIT;
else if (oclk_center_write_resume || lim_wr_req)
init_next_state = INIT_OCAL_CENTER_WRITE;
//*******************************************************
// Initialization/Calibration done. Take a long rest, relax
//*******************************************************
INIT_DONE:
init_next_state = INIT_DONE;
endcase
end
//*****************************************************************
// Initialization done signal - asserted before leveling starts
//*****************************************************************
always @(posedge clk)
if (rst)
mem_init_done_r <= #TCQ 1'b0;
else if ((!cnt_dllk_zqinit_done_r &&
(cnt_dllk_zqinit_r == TDLLK_TZQINIT_DELAY_CNT) &&
(chip_cnt_r == RANKS-1) && (DRAM_TYPE == "DDR3"))
|| ( (init_state_r == INIT_LOAD_MR_WAIT) &&
(ddr2_refresh_flag_r) && (chip_cnt_r == RANKS-1)
&& (cnt_init_mr_done_r) && (DRAM_TYPE == "DDR2")))
mem_init_done_r <= #TCQ 1'b1;
//*****************************************************************
// Write Calibration signal to PHY Control Block - asserted before
// Write Leveling starts
//*****************************************************************
//generate
//if (RANKS < 2) begin: ranks_one
always @(posedge clk) begin
if (rst || (done_dqs_tap_inc &&
(init_state_r == INIT_WRLVL_LOAD_MR2)))
write_calib <= #TCQ 1'b0;
else if (wrlvl_active_r1)
write_calib <= #TCQ 1'b1;
end
//end else begin: ranks_two
// always @(posedge clk) begin
// if (rst ||
// ((init_state_r1 == INIT_WRLVL_LOAD_MR_WAIT) &&
// ((wrlvl_rank_done_r2 && (chip_cnt_r == RANKS-1)) ||
// (SIM_CAL_OPTION == "FAST_CAL"))))
// write_calib <= #TCQ 1'b0;
// else if (wrlvl_active_r1)
// write_calib <= #TCQ 1'b1;
// end
//end
//endgenerate
//*****************************************************************
// Read Calibration signal to PHY Control Block - asserted after
// Write Leveling during PHASER_IN phase locking stage.
// Must be de-asserted before Read Leveling
//*****************************************************************
always @(posedge clk) begin
if (rst || pi_calib_done_r1)
read_calib_int <= #TCQ 1'b0;
else if (~pi_calib_done_r1 && (init_state_r == INIT_RDLVL_ACT_WAIT) &&
(cnt_cmd_r == CNTNEXT_CMD))
read_calib_int <= #TCQ 1'b1;
end
always @(posedge clk)
read_calib_r <= #TCQ read_calib_int;
always @(posedge clk) begin
if (rst || pi_calib_done_r1)
read_calib <= #TCQ 1'b0;
else if (~pi_calib_done_r1 && (init_state_r == INIT_PI_PHASELOCK_READS))
read_calib <= #TCQ 1'b1;
end
always @(posedge clk)
if (rst)
pi_calib_done_r <= #TCQ 1'b0;
else if (pi_calib_rank_done_r)// && (chip_cnt_r == RANKS-1))
pi_calib_done_r <= #TCQ 1'b1;
always @(posedge clk)
if (rst)
pi_calib_rank_done_r <= #TCQ 1'b0;
else if (pi_phase_locked_all_r3 && ~pi_phase_locked_all_r4)
pi_calib_rank_done_r <= #TCQ 1'b1;
else
pi_calib_rank_done_r <= #TCQ 1'b0;
always @(posedge clk) begin
if (rst || ((PRE_REV3ES == "ON") && temp_wrcal_done && ~temp_wrcal_done_r))
pi_phaselock_timer <= #TCQ 'd0;
else if (((init_state_r == INIT_PI_PHASELOCK_READS) &&
(pi_phaselock_timer != PHASELOCKED_TIMEOUT)) ||
tg_timer_go)
pi_phaselock_timer <= #TCQ pi_phaselock_timer + 1;
else
pi_phaselock_timer <= #TCQ pi_phaselock_timer;
end
assign pi_phase_locked_err = (pi_phaselock_timer == PHASELOCKED_TIMEOUT) ? 1'b1 : 1'b0;
//*****************************************************************
// DDR3 final burst length programming done. For DDR3 during
// calibration the burst length is fixed to BL8. After calibration
// the correct burst length is programmed.
//*****************************************************************
always @(posedge clk)
if (rst)
ddr3_lm_done_r <= #TCQ 1'b0;
else if ((init_state_r == INIT_LOAD_MR_WAIT) &&
(chip_cnt_r == RANKS-1) && wrcal_done)
ddr3_lm_done_r <= #TCQ 1'b1;
always @(posedge clk) begin
pi_dqs_found_rank_done_r <= #TCQ pi_dqs_found_rank_done;
pi_phase_locked_all_r1 <= #TCQ pi_phase_locked_all;
pi_phase_locked_all_r2 <= #TCQ pi_phase_locked_all_r1;
pi_phase_locked_all_r3 <= #TCQ pi_phase_locked_all_r2;
pi_phase_locked_all_r4 <= #TCQ pi_phase_locked_all_r3;
pi_dqs_found_all_r <= #TCQ pi_dqs_found_done;
pi_calib_done_r1 <= #TCQ pi_calib_done_r;
end
//***************************************************************************
// Logic for deep memory (multi-rank) configurations
//***************************************************************************
// For DDR3 asserted when
generate
if (RANKS < 2) begin: single_rank
always @(posedge clk)
chip_cnt_r <= #TCQ 2'b00;
end else begin: dual_rank
always @(posedge clk)
if (rst ||
// Set chip_cnt_r to 2'b00 after both Ranks are read leveled
(rdlvl_stg1_done && prbs_rdlvl_done && ~wrcal_done) ||
// Set chip_cnt_r to 2'b00 after both Ranks are write leveled
(wrlvl_done_r &&
(init_state_r==INIT_WRLVL_LOAD_MR2_WAIT)))begin
chip_cnt_r <= #TCQ 2'b00;
end else if ((((init_state_r == INIT_WAIT_DLLK_ZQINIT) &&
(cnt_dllk_zqinit_r == TDLLK_TZQINIT_DELAY_CNT)) &&
(DRAM_TYPE == "DDR3")) ||
((init_state_r==INIT_REFRESH_RNK2_WAIT) &&
(cnt_cmd_r=='d36)) ||
//mpr_rnk_done ||
//(rdlvl_stg1_rank_done && ~rdlvl_last_byte_done) ||
//(stg1_wr_done && (init_state_r == INIT_REFRESH) &&
//~(rnk_ref_cnt && rdlvl_last_byte_done)) ||
// Increment chip_cnt_r to issue Refresh to second rank
(~pi_dqs_found_all_r &&
(init_state_r==INIT_PRECHARGE_PREWAIT) &&
(cnt_cmd_r=='d36)) ||
// Increment chip_cnt_r when DQSFOUND done for the Rank
(pi_dqs_found_rank_done && ~pi_dqs_found_rank_done_r) ||
((init_state_r == INIT_LOAD_MR_WAIT)&& cnt_cmd_done_r
&& wrcal_done) ||
((init_state_r == INIT_DDR2_MULTI_RANK)
&& (DRAM_TYPE == "DDR2"))) begin
if ((~mem_init_done_r || ~rdlvl_stg1_done || ~pi_dqs_found_done ||
// condition to increment chip_cnt during
// final burst length programming for DDR3
~pi_calib_done_r || wrcal_done) //~mpr_rdlvl_done ||
&& (chip_cnt_r != RANKS-1))
chip_cnt_r <= #TCQ chip_cnt_r + 1;
else
chip_cnt_r <= #TCQ 2'b00;
end
end
endgenerate
// verilint STARC-2.2.3.3 off
generate
if ((REG_CTRL == "ON") && (RANKS == 1)) begin: DDR3_RDIMM_1rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if (init_state_r == INIT_REG_WRITE) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if(!(CWL_M%2)) begin
phy_int_cs_n[0%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[1%nCK_PER_CLK] <= #TCQ 1'b0;
end else begin
phy_int_cs_n[2%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[3%nCK_PER_CLK] <= #TCQ 1'b0;
end
end else if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) //even CWL
phy_int_cs_n[0] <= #TCQ 1'b0;
else // odd CWL
phy_int_cs_n[1*nCS_PER_RANK] <= #TCQ 1'b0;
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end
end else if (RANKS == 1) begin: DDR3_1rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) begin //even CWL
for (n = 0; n < nCS_PER_RANK; n = n + 1) begin
phy_int_cs_n[n] <= #TCQ 1'b0;
end
end else begin //odd CWL
for (p = nCS_PER_RANK; p < 2*nCS_PER_RANK; p = p + 1) begin
phy_int_cs_n[p] <= #TCQ 1'b0;
end
end
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end
end else if ((REG_CTRL == "ON") && (RANKS == 2)) begin: DDR3_2rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if (init_state_r == INIT_REG_WRITE) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if(!(CWL_M%2)) begin
phy_int_cs_n[0%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[1%nCK_PER_CLK] <= #TCQ 1'b0;
end else begin
phy_int_cs_n[2%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[3%nCK_PER_CLK] <= #TCQ 1'b0;
end
end else begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
case (chip_cnt_r)
2'b00:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) //even CWL
phy_int_cs_n[0] <= #TCQ 1'b0;
else // odd CWL
phy_int_cs_n[1*CS_WIDTH*nCS_PER_RANK] <= #TCQ 1'b0;
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (n = 0; n < nCS_PER_RANK*nCK_PER_CLK*2; n = n + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[n+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
2'b01:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) //even CWL
phy_int_cs_n[1] <= #TCQ 1'b0;
else // odd CWL
phy_int_cs_n[1+1*CS_WIDTH*nCS_PER_RANK] <= #TCQ 1'b0;
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (p = nCS_PER_RANK; p < nCS_PER_RANK*nCK_PER_CLK*2; p = p + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[p+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
endcase
end
end
end else if (RANKS == 2) begin: DDR3_2rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if (init_state_r == INIT_REG_WRITE) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if(!(CWL_M%2)) begin
phy_int_cs_n[0%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[1%nCK_PER_CLK] <= #TCQ 1'b0;
end else begin
phy_int_cs_n[2%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[3%nCK_PER_CLK] <= #TCQ 1'b0;
end
end else begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
case (chip_cnt_r)
2'b00:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) begin //even CWL
for (n = 0; n < nCS_PER_RANK; n = n + 1) begin
phy_int_cs_n[n] <= #TCQ 1'b0;
end
end else begin // odd CWL
for (p = CS_WIDTH*nCS_PER_RANK; p < (CS_WIDTH*nCS_PER_RANK + nCS_PER_RANK); p = p + 1) begin
phy_int_cs_n[p] <= #TCQ 1'b0;
end
end
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (n = 0; n < nCS_PER_RANK*nCK_PER_CLK*2; n = n + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[n+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
2'b01:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) begin //even CWL
for (q = nCS_PER_RANK; q < (2 * nCS_PER_RANK); q = q + 1) begin
phy_int_cs_n[q] <= #TCQ 1'b0;
end
end else begin // odd CWL
for (m = (nCS_PER_RANK*CS_WIDTH + nCS_PER_RANK); m < (nCS_PER_RANK*CS_WIDTH + 2*nCS_PER_RANK); m = m + 1) begin
phy_int_cs_n[m] <= #TCQ 1'b0;
end
end
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (p = nCS_PER_RANK; p < nCS_PER_RANK*nCK_PER_CLK*2; p = p + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[p+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
endcase
end
end // always @ (posedge clk)
end
// verilint STARC-2.2.3.3 on
// commented out for now. Need it for DDR2 2T timing
/* end else begin: DDR2
always @(posedge clk)
if (rst) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end else begin
if (init_state_r == INIT_REG_WRITE) begin
// All ranks selected simultaneously
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b0}};
end else if ((wrlvl_odt) ||
(init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH)) begin
phy_int_cs_n[0] <= #TCQ 1'b0;
end
else phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end // else: !if(rst)
end // block: DDR2 */
endgenerate
assign phy_cs_n = phy_int_cs_n;
//***************************************************************************
// Write/read burst logic for calibration
//***************************************************************************
assign rdlvl_wr = (init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE);
assign rdlvl_rd = (init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_MPR_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS);
assign rdlvl_wr_rd = rdlvl_wr | rdlvl_rd;
assign mmcm_wr = (init_state_r == INIT_OCAL_CENTER_WRITE); //used to de-assert cs_n during centering
// assign mmcm_wr = 'b0; // (init_state_r == INIT_OCAL_CENTER_WRITE);
//***************************************************************************
// Address generation and logic to count # of writes/reads issued during
// certain stages of calibration
//***************************************************************************
// Column address generation logic:
// Keep track of the current column address - since all bursts are in
// increments of 8 only during calibration, we need to keep track of
// addresses [COL_WIDTH-1:3], lower order address bits will always = 0
always @(posedge clk)
if (rst || wrcal_done)
burst_addr_r <= #TCQ 1'b0;
else if ((init_state_r == INIT_WRCAL_ACT_WAIT) ||
(init_state_r == INIT_OCLKDELAY_ACT_WAIT) ||
(init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS) ||
(init_state_r == INIT_WRCAL_READ_WAIT))
burst_addr_r <= #TCQ 1'b1;
else if (rdlvl_wr_rd && new_burst_r)
burst_addr_r <= #TCQ ~burst_addr_r;
else
burst_addr_r <= #TCQ 1'b0;
// Read Level Stage 1 requires writes to the entire row since
// a PRBS pattern is being written. This counter keeps track
// of the number of writes which depends on the column width
// The (stg1_wr_rd_cnt==9'd0) condition was added so the col
// address wraps around during stage1 reads
always @(posedge clk)
if (rst || ((init_state_r == INIT_RDLVL_STG1_WRITE_READ) &&
~rdlvl_stg1_done))
stg1_wr_rd_cnt <= #TCQ NUM_STG1_WR_RD;
else if (rdlvl_last_byte_done || (stg1_wr_rd_cnt == 9'd1) ||
(prbs_rdlvl_prech_req && (init_state_r == INIT_RDLVL_ACT_WAIT)) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) ) begin
if (~complex_row0_wr_done || wr_victim_inc ||
(complex_row1_wr_done && (~complex_row0_rd_done || (complex_row0_rd_done && complex_row1_rd_done))))
stg1_wr_rd_cnt <= #TCQ 'd127;
else
stg1_wr_rd_cnt <= #TCQ prbs_rdlvl_done?'d30 :'d22;
end else if (((init_state_r == INIT_RDLVL_STG1_WRITE) && new_burst_r && ~phy_data_full)
||((init_state_r == INIT_RDLVL_COMPLEX_READ) && rdlvl_stg1_done))
stg1_wr_rd_cnt <= #TCQ stg1_wr_rd_cnt - 1;
always @(posedge clk)
if (rst)
wr_victim_inc <= #TCQ 1'b0;
else if (complex_row0_wr_done && (stg1_wr_rd_cnt == 9'd2) && ~stg1_wr_done)
wr_victim_inc <= #TCQ 1'b1;
else
wr_victim_inc <= #TCQ 1'b0;
always @(posedge clk)
reset_rd_addr_r1 <= #TCQ reset_rd_addr;
generate
if (FIXED_VICTIM == "FALSE") begin: row_cnt_victim_rotate
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt == DQ_WIDTH*2-1)) || ~rdlvl_stg1_done_r1 || prbs_rdlvl_done)
complex_row_cnt <= #TCQ 'd0;
else if ((((stg1_wr_rd_cnt == 'd22) && ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(complex_rdlvl_int_ref_req && (init_state_r == INIT_REFRESH_WAIT) && (cnt_cmd_r == 'd127)))) ||
complex_victim_inc || (complex_sample_cnt_inc_r2 && ~complex_victim_inc) || wr_victim_inc || reset_rd_addr_r1)) begin
// During writes row count is incremented with every wr_victim_in and stg1_wr_rd_cnt=='d22
if ((complex_row_cnt < DQ_WIDTH*2-1) && ~stg1_wr_done)
complex_row_cnt <= #TCQ complex_row_cnt + 1;
// During reads row count requires different conditions for increments
else if (stg1_wr_done) begin
if (reset_rd_addr_r1)
complex_row_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt*16;
// When looping multiple times in the same victim bit in a byte
else if (complex_sample_cnt_inc_r2 && ~complex_victim_inc)
complex_row_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt*16 + rd_victim_sel*2;
// When looping through victim bits within a byte
else if (complex_row_cnt < pi_stg2_prbs_rdlvl_cnt*16+15)
complex_row_cnt <= #TCQ complex_row_cnt + 1;
// When the number of samples is done and tap is incremented within a byte
else
complex_row_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt*16;
end
end
end else begin: row_cnt_victim_fixed
always @(posedge clk)
if (rst || ~rdlvl_stg1_done_r1 || prbs_rdlvl_done)
complex_row_cnt <= #TCQ 'd0;
else if ((stg1_wr_rd_cnt == 'd22) && (((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_WAIT) && (complex_wait_cnt == 'd15)) || complex_rdlvl_int_ref_req))
complex_row_cnt <= #TCQ 'd1;
else
complex_row_cnt <= #TCQ 'd0;
end
endgenerate
//row count
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt_ocal == COMPLEX_ROW_CNT_BYTE-1)) || ~rdlvl_stg1_done_r1 || prbs_rdlvl_done_pulse || complex_byte_rd_done)
complex_row_cnt_ocal <= #TCQ 'd0;
else if ( prbs_rdlvl_done && (((stg1_wr_rd_cnt == 'd30) && (init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE)) ||
(complex_sample_cnt_inc_r2) || wr_victim_inc)) begin
// During writes row count is incremented with every wr_victim_in and stg1_wr_rd_cnt=='d22
if (complex_row_cnt_ocal < COMPLEX_ROW_CNT_BYTE-1) begin
complex_row_cnt_ocal <= #TCQ complex_row_cnt_ocal + 1;
end
end
always @(posedge clk)
if (rst)
complex_odt_ext <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) || (init_state_r == INIT_PRECHARGE))
complex_odt_ext <= #TCQ 1'b0;
else if (rdlvl_stg1_done_r1 && (stg1_wr_rd_cnt == 9'd1) && (init_state_r == INIT_RDLVL_STG1_WRITE))
complex_odt_ext <= #TCQ 1'b1;
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt == DQ_WIDTH*2-1))) begin
wr_victim_sel <= #TCQ 'd0;
wr_byte_cnt <= #TCQ 'd0;
end else if (rdlvl_stg1_done_r1 && wr_victim_inc) begin
wr_victim_sel <= #TCQ wr_victim_sel + 1;
if (wr_victim_sel == 'd7)
wr_byte_cnt <= #TCQ wr_byte_cnt + 1;
end
always @(posedge clk)
if (rst) begin
wr_victim_sel_ocal <= #TCQ 'd0;
end else if (wr_victim_inc && (complex_row_cnt_ocal == COMPLEX_ROW_CNT_BYTE-1)) begin
wr_victim_sel_ocal <= #TCQ 'd0;
end else if (prbs_rdlvl_done && wr_victim_inc) begin
wr_victim_sel_ocal <= #TCQ wr_victim_sel_ocal + 1;
end
always @(posedge clk)
if (rst) begin
victim_sel <= #TCQ 'd0;
victim_byte_cnt <= #TCQ 'd0;
end else if ((~stg1_wr_done && ~prbs_rdlvl_done) || (prbs_rdlvl_done && ~complex_wr_done)) begin
victim_sel <= #TCQ prbs_rdlvl_done? wr_victim_sel_ocal: wr_victim_sel;
victim_byte_cnt <= #TCQ prbs_rdlvl_done? complex_oclkdelay_calib_cnt:wr_byte_cnt;
end else begin
if( (init_state_r == INIT_RDLVL_COMPLEX_ACT) || reset_rd_addr)
victim_sel <= #TCQ prbs_rdlvl_done? complex_ocal_rd_victim_sel:rd_victim_sel;
victim_byte_cnt <= #TCQ prbs_rdlvl_done? complex_oclkdelay_calib_cnt:pi_stg2_prbs_rdlvl_cnt;
end
generate
if (FIXED_VICTIM == "FALSE") begin: wr_done_victim_rotate
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt < DQ_WIDTH*2-1) && ~prbs_rdlvl_done) ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done || prbs_rdlvl_done_pulse) begin
complex_row0_wr_done <= #TCQ 1'b0;
end else if ( rdlvl_stg1_done_r1 && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row0_wr_done <= #TCQ 1'b1;
end
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt < DQ_WIDTH*2-1) && ~prbs_rdlvl_done) ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done || prbs_rdlvl_done_pulse) begin
complex_row1_wr_done <= #TCQ 1'b0;
end else if (complex_row0_wr_done && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row1_wr_done <= #TCQ 1'b1;
end
end else begin: wr_done_victim_fixed
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done ) begin
complex_row0_wr_done <= #TCQ 1'b0;
end else if (rdlvl_stg1_done_r1 && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row0_wr_done <= #TCQ 1'b1;
end
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done ) begin
complex_row1_wr_done <= #TCQ 1'b0;
end else if (complex_row0_wr_done && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row1_wr_done <= #TCQ 1'b1;
end
end
endgenerate
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse)
complex_row0_rd_done <= #TCQ 1'b0;
else if (complex_sample_cnt_inc)
complex_row0_rd_done <= #TCQ 1'b0;
else if ( (prbs_rdlvl_start || complex_oclkdelay_calib_start_int) && (stg1_wr_rd_cnt == 9'd2) && complex_row0_wr_done && complex_row1_wr_done)
complex_row0_rd_done <= #TCQ 1'b1;
always @(posedge clk)
complex_row0_rd_done_r1 <= #TCQ complex_row0_rd_done;
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse)
complex_row1_rd_done <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) || (init_state_r == INIT_PRECHARGE))
complex_row1_rd_done <= #TCQ 1'b0;
else if (complex_row0_rd_done && (stg1_wr_rd_cnt == 9'd2))
complex_row1_rd_done <= #TCQ 1'b1;
always @(posedge clk)
complex_row1_rd_done_r1 <= #TCQ complex_row1_rd_done;
//calculate row rd num for complex_oclkdelay_calib
//once it reached to 8
always @ (posedge clk)
if (rst || prbs_rdlvl_done_pulse) complex_row1_rd_cnt <= #TCQ 'd0;
else
complex_row1_rd_cnt <= #TCQ (complex_row1_rd_done & ~complex_row1_rd_done_r1) ?
((complex_row1_rd_cnt == (COMPLEX_RD-1))? 0:complex_row1_rd_cnt + 'd1)
: complex_row1_rd_cnt;
//For write, reset rd_done for the byte
always @ (posedge clk) begin
if (rst || (init_state_r == INIT_RDLVL_STG1_WRITE) || prbs_rdlvl_done_pulse)
complex_byte_rd_done <= #TCQ 'b0;
else if (prbs_rdlvl_done && (complex_row1_rd_cnt == (COMPLEX_RD-1)) && (complex_row1_rd_done & ~complex_row1_rd_done_r1))
complex_byte_rd_done <= #TCQ 'b1;
end
always @ (posedge clk) begin
complex_byte_rd_done_r1 <= #TCQ complex_byte_rd_done;
complex_ocal_num_samples_inc <= #TCQ (complex_byte_rd_done & ~complex_byte_rd_done_r1);
end
generate
if (RANKS < 2) begin: one_rank_complex
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done || ( complex_oclkdelay_calib_done && (init_state_r == INIT_RDLVL_STG1_WRITE )) ||
(complex_byte_rd_done && init_state_r == INIT_RDLVL_COMPLEX_ACT) || prbs_rdlvl_done_pulse )
complex_wr_done <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
else if ((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
end else begin: dual_rank_complex
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done || ( complex_oclkdelay_calib_done && (init_state_r == INIT_RDLVL_STG1_WRITE )) ||
(rdlvl_stg1_rank_done ) || (complex_byte_rd_done && init_state_r == INIT_RDLVL_COMPLEX_ACT) || prbs_rdlvl_done_pulse )
complex_wr_done <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
else if ((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
end
endgenerate
always @(posedge clk)
if (rst)
complex_wait_cnt <= #TCQ 'd0;
else if (((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_WAIT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)) && complex_wait_cnt < 'd15)
complex_wait_cnt <= #TCQ complex_wait_cnt + 1;
else
complex_wait_cnt <= #TCQ 'd0;
always @(posedge clk)
if (rst) begin
complex_num_reads <= #TCQ 'd1;
end else if ((((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) && (complex_wait_cnt == 'd14)) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) && ext_int_ref_req && (cnt_cmd_r == 'd127))) &&
~complex_row0_rd_done) begin
if (stg1_wr_rd_cnt > 'd85) begin
if (complex_num_reads < 'd6)
complex_num_reads <= #TCQ complex_num_reads + 1;
else
complex_num_reads <= #TCQ 'd1;
// Initila value for VCCAUX pattern is 3, 7, and 12
end else if (stg1_wr_rd_cnt > 'd73) begin
if (stg1_wr_rd_cnt == 'd85)
complex_num_reads <= #TCQ 'd3;
else if (complex_num_reads < 'd5)
complex_num_reads <= #TCQ complex_num_reads + 1;
end else if (stg1_wr_rd_cnt > 'd39) begin
if (stg1_wr_rd_cnt == 'd73)
complex_num_reads <= #TCQ 'd7;
else if (complex_num_reads < 'd10)
complex_num_reads <= #TCQ complex_num_reads + 1;
end else begin
if (stg1_wr_rd_cnt == 'd39)
complex_num_reads <= #TCQ 'd12;
else if (complex_num_reads < 'd14)
complex_num_reads <= #TCQ complex_num_reads + 1;
end
// Initialize to 1 at the start of reads or after precharge and activate
end else if ((((init_state_r == INIT_RDLVL_STG1_WRITE_READ) || (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)) && ~ext_int_ref_req) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) && (stg1_wr_rd_cnt == 'd22)))
complex_num_reads <= #TCQ 'd1;
always @(posedge clk)
if (rst)
complex_num_reads_dec <= #TCQ 'd1;
else if (((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) && (complex_wait_cnt == 'd15) && ~complex_row0_rd_done) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) || (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)))
complex_num_reads_dec <= #TCQ complex_num_reads;
else if ((init_state_r == INIT_RDLVL_COMPLEX_READ) && (complex_num_reads_dec > 'd0))
complex_num_reads_dec <= #TCQ complex_num_reads_dec - 1;
always @(posedge clk)
if (rst)
complex_address <= #TCQ 'd0;
else if (((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) && (init_state_r1 != INIT_RDLVL_COMPLEX_READ_WAIT)) ||
((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (init_state_r1 != INIT_OCAL_COMPLEX_WRITE_WAIT)))
complex_address <= #TCQ phy_address[COL_WIDTH-1:0];
always @ (posedge clk)
if (rst)
complex_oclkdelay_calib_start_int <= #TCQ 'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT) && prbs_last_byte_done_r) // changed for new algo 3/26
complex_oclkdelay_calib_start_int <= #TCQ 'b1;
always @(posedge clk) begin
complex_oclkdelay_calib_start_r1 <= #TCQ complex_oclkdelay_calib_start_int;
complex_oclkdelay_calib_start_r2 <= #TCQ complex_oclkdelay_calib_start_r1;
end
always @ (posedge clk)
if (rst)
complex_oclkdelay_calib_start <= #TCQ 'b0;
else if (complex_oclkdelay_calib_start_int && (init_state_r == INIT_OCAL_CENTER_WRITE_WAIT) && prbs_rdlvl_done) // changed for new algo 3/26
complex_oclkdelay_calib_start <= #TCQ 'b1;
//packet fragmentation for complex oclkdealy calib write
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse) begin
complex_num_writes <= #TCQ 'd1;
end else if ((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (complex_wait_cnt == 'd14) && ~complex_row0_wr_done) begin
if (stg1_wr_rd_cnt > 'd85) begin
if (complex_num_writes < 'd6)
complex_num_writes <= #TCQ complex_num_writes + 1;
else
complex_num_writes <= #TCQ 'd1;
// Initila value for VCCAUX pattern is 3, 7, and 12
end else if (stg1_wr_rd_cnt > 'd73) begin
if (stg1_wr_rd_cnt == 'd85)
complex_num_writes <= #TCQ 'd3;
else if (complex_num_writes < 'd5)
complex_num_writes <= #TCQ complex_num_writes + 1;
end else if (stg1_wr_rd_cnt > 'd39) begin
if (stg1_wr_rd_cnt == 'd73)
complex_num_writes <= #TCQ 'd7;
else if (complex_num_writes < 'd10)
complex_num_writes <= #TCQ complex_num_writes + 1;
end else begin
if (stg1_wr_rd_cnt == 'd39)
complex_num_writes <= #TCQ 'd12;
else if (complex_num_writes < 'd14)
complex_num_writes <= #TCQ complex_num_writes + 1;
end
// Initialize to 1 at the start of write or after precharge and activate
end else if ((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && complex_row0_wr_done)
complex_num_writes <= #TCQ 'd30;
else if (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)
complex_num_writes <= #TCQ 'd1;
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse)
complex_num_writes_dec <= #TCQ 'd1;
else if (((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (complex_wait_cnt == 'd15) && ~complex_row0_rd_done) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) || (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)))
complex_num_writes_dec <= #TCQ complex_num_writes;
else if ((init_state_r == INIT_RDLVL_STG1_WRITE) && (complex_num_writes_dec > 'd0))
complex_num_writes_dec <= #TCQ complex_num_writes_dec - 1;
always @(posedge clk)
if (rst)
complex_sample_cnt_inc_ocal <= #TCQ 1'b0;
else if ((stg1_wr_rd_cnt == 9'd1) && complex_byte_rd_done && prbs_rdlvl_done)
complex_sample_cnt_inc_ocal <= #TCQ 1'b1;
else
complex_sample_cnt_inc_ocal <= #TCQ 1'b0;
always @(posedge clk)
if (rst)
complex_sample_cnt_inc <= #TCQ 1'b0;
else if ((stg1_wr_rd_cnt == 9'd1) && complex_row1_rd_done)
complex_sample_cnt_inc <= #TCQ 1'b1;
else
complex_sample_cnt_inc <= #TCQ 1'b0;
always @(posedge clk) begin
complex_sample_cnt_inc_r1 <= #TCQ complex_sample_cnt_inc;
complex_sample_cnt_inc_r2 <= #TCQ complex_sample_cnt_inc_r1;
end
//complex refresh req
always @ (posedge clk) begin
if(rst || (init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(prbs_rdlvl_done && (init_state_r == INIT_RDLVL_COMPLEX_ACT)) )
complex_ocal_ref_done <= #TCQ 1'b1;
else if (init_state_r == INIT_RDLVL_STG1_WRITE)
complex_ocal_ref_done <= #TCQ 1'b0;
end
//complex ocal odt extention
always @(posedge clk)
if (rst)
complex_ocal_odt_ext <= #TCQ 1'b0;
else if (((init_state_r == INIT_PRECHARGE_PREWAIT) && cnt_cmd_done_m7_r) || (init_state_r == INIT_OCLKDELAY_READ_WAIT))
complex_ocal_odt_ext <= #TCQ 1'b0;
else if ((init_state_r == INIT_OCAL_CENTER_WRITE) || (init_state_r == INIT_OCAL_CENTER_WRITE_WAIT))
complex_ocal_odt_ext <= #TCQ 1'b1;
// OCLKDELAY calibration requires multiple writes because
// write can be up to 2 cycles early since OCLKDELAY tap
// can go down to 0
always @(posedge clk)
if (rst || (init_state_r == INIT_OCLKDELAY_WRITE_WAIT) ||
(oclk_wr_cnt == 4'd0))
oclk_wr_cnt <= #TCQ NUM_STG1_WR_RD;
else if ((init_state_r == INIT_OCLKDELAY_WRITE) &&
new_burst_r && ~phy_data_full)
oclk_wr_cnt <= #TCQ oclk_wr_cnt - 1;
// Write calibration requires multiple writes because
// write can be up to 2 cycles early due to new write
// leveling algorithm to avoid late writes
always @(posedge clk)
if (rst || (init_state_r == INIT_WRCAL_WRITE_READ) ||
(wrcal_wr_cnt == 4'd0))
wrcal_wr_cnt <= #TCQ NUM_STG1_WR_RD;
else if ((init_state_r == INIT_WRCAL_WRITE) &&
new_burst_r && ~phy_data_full)
wrcal_wr_cnt <= #TCQ wrcal_wr_cnt - 1;
generate
if(nCK_PER_CLK == 4) begin:back_to_back_reads_4_1
// 4 back-to-back reads with gaps for
// read data_offset calibration (rdlvl stage 2)
always @(posedge clk)
if (rst || (init_state_r == INIT_RDLVL_STG2_READ_WAIT))
num_reads <= #TCQ 3'b000;
else if ((num_reads > 3'b000) && ~(phy_ctl_full || phy_cmd_full))
num_reads <= #TCQ num_reads - 1;
else if ((init_state_r == INIT_RDLVL_STG2_READ) || phy_ctl_full ||
phy_cmd_full && new_burst_r)
num_reads <= #TCQ 3'b011;
end else if(nCK_PER_CLK == 2) begin: back_to_back_reads_2_1
// 4 back-to-back reads with gaps for
// read data_offset calibration (rdlvl stage 2)
always @(posedge clk)
if (rst || (init_state_r == INIT_RDLVL_STG2_READ_WAIT))
num_reads <= #TCQ 3'b000;
else if ((num_reads > 3'b000) && ~(phy_ctl_full || phy_cmd_full))
num_reads <= #TCQ num_reads - 1;
else if ((init_state_r == INIT_RDLVL_STG2_READ) || phy_ctl_full ||
phy_cmd_full && new_burst_r)
num_reads <= #TCQ 3'b111;
end
endgenerate
// back-to-back reads during write calibration
always @(posedge clk)
if (rst ||(init_state_r == INIT_WRCAL_READ_WAIT))
wrcal_reads <= #TCQ 2'b00;
else if ((wrcal_reads > 2'b00) && ~(phy_ctl_full || phy_cmd_full))
wrcal_reads <= #TCQ wrcal_reads - 1;
else if ((init_state_r == INIT_WRCAL_MULT_READS) || phy_ctl_full ||
phy_cmd_full && new_burst_r)
wrcal_reads <= #TCQ 'd255;
// determine how often to issue row command during read leveling writes
// and reads
always @(posedge clk)
if (rdlvl_wr_rd) begin
// 2:1 mode - every other command issued is a data command
// 4:1 mode - every command issued is a data command
if (nCK_PER_CLK == 2) begin
if (!phy_ctl_full)
new_burst_r <= #TCQ ~new_burst_r;
end else
new_burst_r <= #TCQ 1'b1;
end else
new_burst_r <= #TCQ 1'b1;
// indicate when a write is occurring. PHY_WRDATA_EN must be asserted
// simultaneous with the corresponding command/address for CWL = 5,6
always @(posedge clk) begin
rdlvl_wr_r <= #TCQ rdlvl_wr;
calib_wrdata_en <= #TCQ phy_wrdata_en;
end
always @(posedge clk) begin
if (rst || wrcal_done)
extend_cal_pat <= #TCQ 1'b0;
else if (temp_lmr_done && (PRE_REV3ES == "ON"))
extend_cal_pat <= #TCQ 1'b1;
end
generate
if ((nCK_PER_CLK == 4) || (BURST_MODE == "4")) begin: wrdqen_div4
// Write data enable asserted for one DIV4 clock cycle
// Only BL8 supported with DIV4. DDR2 BL4 will use DIV2.
always @(*) begin
if (~phy_data_full && ((init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE)))
phy_wrdata_en = 1'b1;
else
phy_wrdata_en = 1'b0;
end
end else begin: wrdqen_div2 // block: wrdqen_div4
always @(*)
if((rdlvl_wr & ~phy_ctl_full & new_burst_r & ~phy_data_full)
| phy_wrdata_en_r1)
phy_wrdata_en = 1'b1;
else
phy_wrdata_en = 1'b0;
always @(posedge clk)
phy_wrdata_en_r1 <= #TCQ rdlvl_wr & ~phy_ctl_full & new_burst_r
& ~phy_data_full;
always @(posedge clk) begin
if (!phy_wrdata_en & first_rdlvl_pat_r)
wrdata_pat_cnt <= #TCQ 2'b00;
else if (wrdata_pat_cnt == 2'b11)
wrdata_pat_cnt <= #TCQ 2'b10;
else
wrdata_pat_cnt <= #TCQ wrdata_pat_cnt + 1;
end
always @(posedge clk) begin
if (!phy_wrdata_en & first_wrcal_pat_r)
wrcal_pat_cnt <= #TCQ 2'b00;
else if (extend_cal_pat && (wrcal_pat_cnt == 2'b01))
wrcal_pat_cnt <= #TCQ 2'b00;
else if (wrcal_pat_cnt == 2'b11)
wrcal_pat_cnt <= #TCQ 2'b10;
else
wrcal_pat_cnt <= #TCQ wrcal_pat_cnt + 1;
end
end
endgenerate
// indicate when a write is occurring. PHY_RDDATA_EN must be asserted
// simultaneous with the corresponding command/address. PHY_RDDATA_EN
// is used during read-leveling to determine read latency
assign phy_rddata_en = ~phy_if_empty;
// Read data valid generation for MC and User Interface after calibration is
// complete
assign phy_rddata_valid = init_complete_r1_timing ? phy_rddata_en : 1'b0;
//***************************************************************************
// Generate training data written at start of each read-leveling stage
// For every stage of read leveling, 8 words are written into memory
// The format is as follows (shown as {rise,fall}):
// Stage 1: 0xF, 0x0, 0xF, 0x0, 0xF, 0x0, 0xF, 0x0
// Stage 2: 0xF, 0x0, 0xA, 0x5, 0x5, 0xA, 0x9, 0x6
//***************************************************************************
always @(posedge clk)
if ((init_state_r == INIT_IDLE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE))
cnt_init_data_r <= #TCQ 2'b00;
else if (phy_wrdata_en)
cnt_init_data_r <= #TCQ cnt_init_data_r + 1;
else if (init_state_r == INIT_WRCAL_WRITE)
cnt_init_data_r <= #TCQ 2'b10;
// write different sequence for very
// first write to memory only. Used to help us differentiate
// if the writes are "early" or "on-time" during read leveling
always @(posedge clk)
if (rst || rdlvl_stg1_rank_done)
first_rdlvl_pat_r <= #TCQ 1'b1;
else if (phy_wrdata_en && (init_state_r == INIT_RDLVL_STG1_WRITE))
first_rdlvl_pat_r <= #TCQ 1'b0;
always @(posedge clk)
if (rst || wrcal_resume ||
(init_state_r == INIT_WRCAL_ACT_WAIT))
first_wrcal_pat_r <= #TCQ 1'b1;
else if (phy_wrdata_en && (init_state_r == INIT_WRCAL_WRITE))
first_wrcal_pat_r <= #TCQ 1'b0;
generate
if ((CLK_PERIOD/nCK_PER_CLK > 2500) && (nCK_PER_CLK == 2)) begin: wrdq_div2_2to1_rdlvl_first
always @(posedge clk)
if (~oclkdelay_calib_done)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}}};
else if (!rdlvl_stg1_done) begin
// The 16 words for stage 1 write data in 2:1 mode is written
// over 4 consecutive controller clock cycles. Note that write
// data follows phy_wrdata_en by one clock cycle
case (wrdata_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},
{DQ_WIDTH/4{4'h9}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
endcase
end else if (!prbs_rdlvl_done && ~phy_data_full) begin
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},
{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},
{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
end else if (!wrcal_done) begin
case (wrcal_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h5}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},
{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h4}}};
end
endcase
end
end else if ((CLK_PERIOD/nCK_PER_CLK > 2500) && (nCK_PER_CLK == 4)) begin: wrdq_div2_4to1_rdlvl_first
always @(posedge clk)
if (~oclkdelay_calib_done)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}}};
else if (!rdlvl_stg1_done && ~phy_data_full)
// write different sequence for very
// first write to memory only. Used to help us differentiate
// if the writes are "early" or "on-time" during read leveling
if (first_rdlvl_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},{DQ_WIDTH/4{4'h9}}};
else
// For all others, change the first two words written in order
// to differentiate the "early write" and "on-time write"
// readback patterns during read leveling
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
else if (~(prbs_rdlvl_done || prbs_last_byte_done_r) && ~phy_data_full)
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[8*8-1:7*8]}},{DQ_WIDTH/8{prbs_o[7*8-1:6*8]}},
{DQ_WIDTH/8{prbs_o[6*8-1:5*8]}},{DQ_WIDTH/8{prbs_o[5*8-1:4*8]}},
{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
else if (!wrcal_done)
if (first_wrcal_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'h5}},{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},{DQ_WIDTH/4{4'hF}}};
else
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
end else if (nCK_PER_CLK == 4) begin: wrdq_div1_4to1_wrcal_first
always @(posedge clk)
if ((~oclkdelay_calib_done) && (DRAM_TYPE == "DDR3"))
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}}};
else if ((!wrcal_done)&& (DRAM_TYPE == "DDR3")) begin
if (extend_cal_pat)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'h5}},{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},{DQ_WIDTH/4{4'hF}}};
else if (first_wrcal_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'h5}},{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},{DQ_WIDTH/4{4'hF}}};
else
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
end else if (!rdlvl_stg1_done && ~phy_data_full) begin
// write different sequence for very
// first write to memory only. Used to help us differentiate
// if the writes are "early" or "on-time" during read leveling
if (first_rdlvl_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},{DQ_WIDTH/4{4'h9}}};
else
// For all others, change the first two words written in order
// to differentiate the "early write" and "on-time write"
// readback patterns during read leveling
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
end else if (!prbs_rdlvl_done && ~phy_data_full)
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[8*8-1:7*8]}},{DQ_WIDTH/8{prbs_o[7*8-1:6*8]}},
{DQ_WIDTH/8{prbs_o[6*8-1:5*8]}},{DQ_WIDTH/8{prbs_o[5*8-1:4*8]}},
{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
else if (!complex_oclkdelay_calib_done && ~phy_data_full)
phy_wrdata <= #TCQ prbs_o;
end else begin: wrdq_div1_2to1_wrcal_first
always @(posedge clk)
if ((~oclkdelay_calib_done)&& (DRAM_TYPE == "DDR3"))
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}}};
else if ((!wrcal_done) && (DRAM_TYPE == "DDR3"))begin
case (wrcal_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h5}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},
{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h4}}};
end
endcase
end else if (!rdlvl_stg1_done) begin
// The 16 words for stage 1 write data in 2:1 mode is written
// over 4 consecutive controller clock cycles. Note that write
// data follows phy_wrdata_en by one clock cycle
case (wrdata_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},
{DQ_WIDTH/4{4'h9}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
endcase
end else if (!prbs_rdlvl_done && ~phy_data_full) begin
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},
{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},
{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
end else if (!complex_oclkdelay_calib_done && ~phy_data_full) begin
phy_wrdata <= #TCQ prbs_o;
end
end
endgenerate
//***************************************************************************
// Memory control/address
//***************************************************************************
// Phases [2] and [3] are always deasserted for 4:1 mode
generate
if (nCK_PER_CLK == 4) begin: gen_div4_ca_tieoff
always @(posedge clk) begin
phy_ras_n[3:2] <= #TCQ 3'b11;
phy_cas_n[3:2] <= #TCQ 3'b11;
phy_we_n[3:2] <= #TCQ 3'b11;
end
end
endgenerate
// Assert RAS when: (1) Loading MRS, (2) Activating Row, (3) Precharging
// (4) auto refresh
// verilint STARC-2.7.3.3b off
generate
if (!(CWL_M % 2)) begin: even_cwl
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT))begin
phy_ras_n[0] <= #TCQ 1'b0;
phy_ras_n[1] <= #TCQ 1'b1;
end else begin
phy_ras_n[0] <= #TCQ 1'b1;
phy_ras_n[1] <= #TCQ 1'b1;
end
end
// Assert CAS when: (1) Loading MRS, (2) Issuing Read/Write command
// (3) auto refresh
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_REFRESH) ||
(rdlvl_wr_rd && new_burst_r))begin
phy_cas_n[0] <= #TCQ 1'b0;
phy_cas_n[1] <= #TCQ 1'b1;
end else begin
phy_cas_n[0] <= #TCQ 1'b1;
phy_cas_n[1] <= #TCQ 1'b1;
end
end
// Assert WE when: (1) Loading MRS, (2) Issuing Write command (only
// occur during read leveling), (3) Issuing ZQ Long Calib command,
// (4) Precharge
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE)||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(rdlvl_wr && new_burst_r))begin
phy_we_n[0] <= #TCQ 1'b0;
phy_we_n[1] <= #TCQ 1'b1;
end else begin
phy_we_n[0] <= #TCQ 1'b1;
phy_we_n[1] <= #TCQ 1'b1;
end
end
end else begin: odd_cwl
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(init_state_r == INIT_REFRESH))begin
phy_ras_n[0] <= #TCQ 1'b1;
phy_ras_n[1] <= #TCQ 1'b0;
end else begin
phy_ras_n[0] <= #TCQ 1'b1;
phy_ras_n[1] <= #TCQ 1'b1;
end
end
// Assert CAS when: (1) Loading MRS, (2) Issuing Read/Write command
// (3) auto refresh
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_REFRESH) ||
(rdlvl_wr_rd && new_burst_r))begin
phy_cas_n[0] <= #TCQ 1'b1;
phy_cas_n[1] <= #TCQ 1'b0;
end else begin
phy_cas_n[0] <= #TCQ 1'b1;
phy_cas_n[1] <= #TCQ 1'b1;
end
end
// Assert WE when: (1) Loading MRS, (2) Issuing Write command (only
// occur during read leveling), (3) Issuing ZQ Long Calib command,
// (4) Precharge
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE)||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(rdlvl_wr && new_burst_r))begin
phy_we_n[0] <= #TCQ 1'b1;
phy_we_n[1] <= #TCQ 1'b0;
end else begin
phy_we_n[0] <= #TCQ 1'b1;
phy_we_n[1] <= #TCQ 1'b1;
end
end
end
endgenerate
// verilint STARC-2.7.3.3b on
// Assign calib_cmd for the command field in PHY_Ctl_Word
always @(posedge clk) begin
if (wr_level_dqs_asrt) begin
// Request to toggle DQS during write leveling
calib_cmd <= #TCQ 3'b001;
if (CWL_M % 2) begin // odd write latency
calib_data_offset_0 <= #TCQ CWL_M + 3;
calib_data_offset_1 <= #TCQ CWL_M + 3;
calib_data_offset_2 <= #TCQ CWL_M + 3;
calib_cas_slot <= #TCQ 2'b01;
end else begin // even write latency
calib_data_offset_0 <= #TCQ CWL_M + 2;
calib_data_offset_1 <= #TCQ CWL_M + 2;
calib_data_offset_2 <= #TCQ CWL_M + 2;
calib_cas_slot <= #TCQ 2'b00;
end
end else if (rdlvl_wr && new_burst_r) begin
// Write Command
calib_cmd <= #TCQ 3'b001;
if (CWL_M % 2) begin // odd write latency
calib_data_offset_0 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 3 : CWL_M - 1;
calib_data_offset_1 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 3 : CWL_M - 1;
calib_data_offset_2 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 3 : CWL_M - 1;
calib_cas_slot <= #TCQ 2'b01;
end else begin // even write latency
calib_data_offset_0 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 2 : CWL_M - 2 ;
calib_data_offset_1 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 2 : CWL_M - 2 ;
calib_data_offset_2 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 2 : CWL_M - 2 ;
calib_cas_slot <= #TCQ 2'b00;
end
end else if (rdlvl_rd && new_burst_r) begin
// Read Command
calib_cmd <= #TCQ 3'b011;
if (CWL_M % 2)
calib_cas_slot <= #TCQ 2'b01;
else
calib_cas_slot <= #TCQ 2'b00;
if (~pi_calib_done_r1) begin
calib_data_offset_0 <= #TCQ 6'd0;
calib_data_offset_1 <= #TCQ 6'd0;
calib_data_offset_2 <= #TCQ 6'd0;
end else if (~pi_dqs_found_done_r1) begin
calib_data_offset_0 <= #TCQ rd_data_offset_0;
calib_data_offset_1 <= #TCQ rd_data_offset_1;
calib_data_offset_2 <= #TCQ rd_data_offset_2;
end else begin
calib_data_offset_0 <= #TCQ rd_data_offset_ranks_0[6*chip_cnt_r+:6];
calib_data_offset_1 <= #TCQ rd_data_offset_ranks_1[6*chip_cnt_r+:6];
calib_data_offset_2 <= #TCQ rd_data_offset_ranks_2[6*chip_cnt_r+:6];
end
end else begin
// Non-Data Commands like NOP, MRS, ZQ Long Cal, Precharge,
// Active, Refresh
calib_cmd <= #TCQ 3'b100;
calib_data_offset_0 <= #TCQ 6'd0;
calib_data_offset_1 <= #TCQ 6'd0;
calib_data_offset_2 <= #TCQ 6'd0;
if (CWL_M % 2)
calib_cas_slot <= #TCQ 2'b01;
else
calib_cas_slot <= #TCQ 2'b00;
end
end
// Write Enable to PHY_Control FIFO always asserted
// No danger of this FIFO being Full with 4:1 sync clock ratio
// This is also the write enable to the command OUT_FIFO
always @(posedge clk) begin
if (rst) begin
calib_ctl_wren <= #TCQ 1'b0;
calib_cmd_wren <= #TCQ 1'b0;
calib_seq <= #TCQ 2'b00;
end else if (cnt_pwron_cke_done_r && phy_ctl_ready
&& ~(phy_ctl_full || phy_cmd_full )) begin
calib_ctl_wren <= #TCQ 1'b1;
calib_cmd_wren <= #TCQ 1'b1;
calib_seq <= #TCQ calib_seq + 1;
end else begin
calib_ctl_wren <= #TCQ 1'b0;
calib_cmd_wren <= #TCQ 1'b0;
calib_seq <= #TCQ calib_seq;
end
end
generate
genvar rnk_i;
for (rnk_i = 0; rnk_i < 4; rnk_i = rnk_i + 1) begin: gen_rnk
always @(posedge clk) begin
if (rst) begin
mr2_r[rnk_i] <= #TCQ 2'b00;
mr1_r[rnk_i] <= #TCQ 3'b000;
end else begin
mr2_r[rnk_i] <= #TCQ tmp_mr2_r[rnk_i];
mr1_r[rnk_i] <= #TCQ tmp_mr1_r[rnk_i];
end
end
end
endgenerate
// ODT assignment based on slot config and slot present
// For single slot systems slot_1_present input will be ignored
// Assuming component interfaces to be single slot systems
generate
if (nSLOTS == 1) begin: gen_single_slot_odt
always @(posedge clk) begin
if (rst) begin
tmp_mr2_r[1] <= #TCQ 2'b00;
tmp_mr2_r[2] <= #TCQ 2'b00;
tmp_mr2_r[3] <= #TCQ 2'b00;
tmp_mr1_r[1] <= #TCQ 3'b000;
tmp_mr1_r[2] <= #TCQ 3'b000;
tmp_mr1_r[3] <= #TCQ 3'b000;
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b1}};
phy_tmp_odt_r <= #TCQ 4'b0000;
phy_tmp_odt_r1 <= #TCQ phy_tmp_odt_r;
end else begin
case ({slot_0_present[0],slot_0_present[1],
slot_0_present[2],slot_0_present[3]})
// Single slot configuration with quad rank
// Assuming same behavior as single slot dual rank for now
// DDR2 does not have quad rank parts
4'b1111: begin
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 RTT_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 RTT_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
phy_tmp_odt_r <= #TCQ 4'b0001;
// Chip Select assignments
phy_tmp_cs1_r[((chip_cnt_r*nCS_PER_RANK)
) +: nCS_PER_RANK] <= #TCQ 'b0;
end
// Single slot configuration with single rank
4'b1000: begin
phy_tmp_odt_r <= #TCQ 4'b0001;
if ((REG_CTRL == "ON") && (nCS_PER_RANK > 1)) begin
phy_tmp_cs1_r[chip_cnt_r] <= #TCQ 1'b0;
end else begin
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b0}};
end
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
((cnt_init_mr_r == 2'd0) || (USE_ODT_PORT == 1)))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 RTT_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 RTT_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
// Single slot configuration with dual rank
4'b1100: begin
phy_tmp_odt_r <= #TCQ 4'b0001;
// Chip Select assignments
phy_tmp_cs1_r[((chip_cnt_r*nCS_PER_RANK)
) +: nCS_PER_RANK] <= #TCQ 'b0;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
default: begin
phy_tmp_odt_r <= #TCQ 4'b0001;
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
endcase
end
end
end else if (nSLOTS == 2) begin: gen_dual_slot_odt
always @ (posedge clk) begin
if (rst) begin
tmp_mr2_r[1] <= #TCQ 2'b00;
tmp_mr2_r[2] <= #TCQ 2'b00;
tmp_mr2_r[3] <= #TCQ 2'b00;
tmp_mr1_r[1] <= #TCQ 3'b000;
tmp_mr1_r[2] <= #TCQ 3'b000;
tmp_mr1_r[3] <= #TCQ 3'b000;
phy_tmp_odt_r <= #TCQ 4'b0000;
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b1}};
phy_tmp_odt_r1 <= #TCQ phy_tmp_odt_r;
end else begin
case ({slot_0_present[0],slot_0_present[1],
slot_1_present[0],slot_1_present[1]})
// Two slot configuration, one slot present, single rank
4'b10_00: begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r <= #TCQ 4'b0001;
end
phy_tmp_cs1_r <= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
4'b00_10: begin
//Rank1 ODT enabled
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r <= #TCQ 4'b0001;
end
phy_tmp_cs1_r <= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank1 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank1 Rtt_NOM defaults to 120 ohms
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
// Two slot configuration, one slot present, dual rank
4'b00_11: begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r
<= #TCQ 4'b0001;
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
4'b11_00: begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r <= #TCQ 4'b0001;
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank1 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
// Two slot configuration, one rank per slot
4'b10_10: begin
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r == 2'b00)begin
phy_tmp_odt_r
<= #TCQ 4'b0010; //bit0 for rank0
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0001; //bit0 for rank0
end
end else begin
if((init_state_r == INIT_WRLVL_WAIT) ||
(init_next_state == INIT_RDLVL_STG1_WRITE) ||
(init_next_state == INIT_WRCAL_WRITE) ||
(init_next_state == INIT_OCAL_CENTER_WRITE) ||
(init_next_state == INIT_OCLKDELAY_WRITE))
phy_tmp_odt_r <= #TCQ 4'b0011; // bit0 for rank0/1 (write)
else if ((init_next_state == INIT_PI_PHASELOCK_READS) ||
(init_next_state == INIT_MPR_READ) ||
(init_next_state == INIT_RDLVL_STG1_READ) ||
(init_next_state == INIT_RDLVL_COMPLEX_READ) ||
(init_next_state == INIT_RDLVL_STG2_READ) ||
(init_next_state == INIT_OCLKDELAY_READ) ||
(init_next_state == INIT_WRCAL_READ) ||
(init_next_state == INIT_WRCAL_MULT_READS))
phy_tmp_odt_r <= #TCQ 4'b0010; // bit0 for rank1 (rank 0 rd)
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_WR == "60") ? 3'b001 :
(RTT_WR == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
end
end
// Two Slots - One slot with dual rank and other with single rank
4'b10_11: begin
//Rank3 Rtt_NOM
tmp_mr1_r[2] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
tmp_mr2_r[2] <= #TCQ 2'b00;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[1] <= #TCQ 3'b000;
end
//Slot1 Rank1 or Rank3 is being written
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r == 2'b00)begin
phy_tmp_odt_r
<= #TCQ 4'b0010;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0001;
end
end else begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
if (chip_cnt_r[0] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0011;
//Slot0 Rank0 is being written
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0101; // ODT for ranks 0 and 2 aserted
end
end else if ((init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS))begin
if (chip_cnt_r == 2'b00) begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0001;
end
end
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
end
// Two Slots - One slot with dual rank and other with single rank
4'b11_10: begin
//Rank2 Rtt_NOM
tmp_mr1_r[2] <= #TCQ (RTT_NOM2 == "60") ? 3'b001 :
(RTT_NOM2 == "120") ? 3'b010 :
(RTT_NOM2 == "20") ? 3'b100 :
(RTT_NOM2 == "30") ? 3'b101 :
(RTT_NOM2 == "40") ? 3'b011:
3'b000;
tmp_mr2_r[2] <= #TCQ 2'b00;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011:
3'b000;
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r[1] == 1'b1)begin
phy_tmp_odt_r <=
#TCQ 4'b0001;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0100; // rank 2 ODT asserted
end
end else begin
if (// wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
if (chip_cnt_r[1] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0110;
end else begin
phy_tmp_odt_r <=
#TCQ 4'b0101;
end
end else if ((init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS)) begin
if (chip_cnt_r[1] == 1'b1) begin
phy_tmp_odt_r[(1*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ 4'b0010;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
end
end
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
end
// Two Slots - two ranks per slot
4'b11_11: begin
//Rank2 Rtt_NOM
tmp_mr1_r[2] <= #TCQ (RTT_NOM2 == "60") ? 3'b001 :
(RTT_NOM2 == "120") ? 3'b010 :
(RTT_NOM2 == "20") ? 3'b100 :
(RTT_NOM2 == "30") ? 3'b101 :
(RTT_NOM2 == "40") ? 3'b011 :
3'b000;
//Rank3 Rtt_NOM
tmp_mr1_r[3] <= #TCQ (RTT_NOM3 == "60") ? 3'b001 :
(RTT_NOM3 == "120") ? 3'b010 :
(RTT_NOM3 == "20") ? 3'b100 :
(RTT_NOM3 == "30") ? 3'b101 :
(RTT_NOM3 == "40") ? 3'b011 :
3'b000;
tmp_mr2_r[2] <= #TCQ 2'b00;
tmp_mr2_r[3] <= #TCQ 2'b00;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[1] <= #TCQ 3'b000;
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r[1] == 1'b1)begin
phy_tmp_odt_r
<= #TCQ 4'b0001;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
end
end else begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
//Slot1 Rank1 or Rank3 is being written
if (chip_cnt_r[0] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0110;
//Slot0 Rank0 or Rank2 is being written
end else begin
phy_tmp_odt_r
<= #TCQ 4'b1001;
end
end else if ((init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS))begin
//Slot1 Rank1 or Rank3 is being read
if (chip_cnt_r[0] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
//Slot0 Rank0 or Rank2 is being read
end else begin
phy_tmp_odt_r
<= #TCQ 4'b1000;
end
end
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
end
default: begin
phy_tmp_odt_r <= #TCQ 4'b1111;
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "60") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
end
end
endcase
end
end
end
endgenerate
// PHY only supports two ranks.
// calib_aux_out[0] is CKE for rank 0 and calib_aux_out[1] is ODT for rank 0
// calib_aux_out[2] is CKE for rank 1 and calib_aux_out[3] is ODT for rank 1
generate
if(CKE_ODT_AUX == "FALSE") begin
if ((nSLOTS == 1) && (RANKS < 2)) begin
always @(posedge clk)
if (rst) begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}} ;
calib_odt <= 2'b00 ;
end else begin
if (cnt_pwron_cke_done_r /*&& ~cnt_pwron_cke_done_r1*/)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b1}};
end else begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}};
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF"))/* ||
wrlvl_rank_done || wrlvl_rank_done_r1 ||
(wrlvl_done && !wrlvl_done_r)*/) && (DRAM_TYPE == "DDR3")) begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt ) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
complex_odt_ext ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
complex_ocal_odt_ext ||
(init_state_r == INIT_OCLKDELAY_WRITE)||
(init_state_r == INIT_OCLKDELAY_WRITE_WAIT))) begin
// Quad rank in a single slot
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 1) && (RANKS <= 2)) begin
always @(posedge clk)
if (rst) begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}} ;
calib_odt <= 2'b00 ;
end else begin
if (cnt_pwron_cke_done_r /*&& ~cnt_pwron_cke_done_r1*/)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b1}};
end else begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}};
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF"))/* ||
wrlvl_rank_done_r2 ||
(wrlvl_done && !wrlvl_done_r)*/) && (DRAM_TYPE == "DDR3")) begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt)||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
complex_odt_ext ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
complex_ocal_odt_ext ||
(init_state_r == INIT_OCLKDELAY_WRITE)||
(init_state_r == INIT_OCLKDELAY_WRITE_WAIT))) begin
// Dual rank in a single slot
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 2) && (RANKS == 2)) begin
always @(posedge clk)
if (rst)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}} ;
calib_odt <= 2'b00 ;
end else begin
if (cnt_pwron_cke_done_r /*&& ~cnt_pwron_cke_done_r1*/)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b1}};
end else begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}};
end
if (((DRAM_TYPE == "DDR2") && (RTT_NOM == "DISABLED")) ||
((DRAM_TYPE == "DDR3") &&
(RTT_NOM == "DISABLED") && (RTT_WR == "OFF"))) begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end else if (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// Quad rank in a single slot
if (nCK_PER_CLK == 2) begin
calib_odt[0]
<= #TCQ (!calib_odt[0]) ? phy_tmp_odt_r[0] : 1'b0;
calib_odt[1]
<= #TCQ (!calib_odt[1]) ? phy_tmp_odt_r[1] : 1'b0;
end else begin
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end
// Turn on for idle rank during read if dynamic ODT is enabled in DDR3
end else if(((DRAM_TYPE == "DDR3") && (RTT_WR != "OFF")) &&
((init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_MPR_READ) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS))) begin
if (nCK_PER_CLK == 2) begin
calib_odt[0]
<= #TCQ (!calib_odt[0]) ? phy_tmp_odt_r[0] : 1'b0;
calib_odt[1]
<= #TCQ (!calib_odt[1]) ? phy_tmp_odt_r[1] : 1'b0;
end else begin
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end
// disable well before next command and before disabling write leveling
end else if(cnt_cmd_done_m7_r ||
(init_state_r == INIT_WRLVL_WAIT && ~wrlvl_odt))
calib_odt <= #TCQ 2'b00;
end
end
end else begin//USE AUX OUTPUT for routing CKE and ODT.
if ((nSLOTS == 1) && (RANKS < 2)) begin
always @(posedge clk)
if (rst) begin
calib_aux_out <= #TCQ 4'b0000;
end else begin
if (cnt_pwron_cke_done_r && ~cnt_pwron_cke_done_r1)begin
calib_aux_out[0] <= #TCQ 1'b1;
calib_aux_out[2] <= #TCQ 1'b1;
end else begin
calib_aux_out[0] <= #TCQ 1'b0;
calib_aux_out[2] <= #TCQ 1'b0;
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF")) ||
wrlvl_rank_done || wrlvl_rank_done_r1 ||
(wrlvl_done && !wrlvl_done_r)) && (DRAM_TYPE == "DDR3")) begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE))) begin
// Quad rank in a single slot
calib_aux_out[1] <= #TCQ phy_tmp_odt_r[0];
calib_aux_out[3] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 1) && (RANKS <= 2)) begin
always @(posedge clk)
if (rst) begin
calib_aux_out <= #TCQ 4'b0000;
end else begin
if (cnt_pwron_cke_done_r && ~cnt_pwron_cke_done_r1)begin
calib_aux_out[0] <= #TCQ 1'b1;
calib_aux_out[2] <= #TCQ 1'b1;
end else begin
calib_aux_out[0] <= #TCQ 1'b0;
calib_aux_out[2] <= #TCQ 1'b0;
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF")) ||
wrlvl_rank_done_r2 ||
(wrlvl_done && !wrlvl_done_r)) && (DRAM_TYPE == "DDR3")) begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE))) begin
// Dual rank in a single slot
calib_aux_out[1] <= #TCQ phy_tmp_odt_r[0];
calib_aux_out[3] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 2) && (RANKS == 2)) begin
always @(posedge clk)
if (rst)
calib_aux_out <= #TCQ 4'b0000;
else begin
if (cnt_pwron_cke_done_r && ~cnt_pwron_cke_done_r1)begin
calib_aux_out[0] <= #TCQ 1'b1;
calib_aux_out[2] <= #TCQ 1'b1;
end else begin
calib_aux_out[0] <= #TCQ 1'b0;
calib_aux_out[2] <= #TCQ 1'b0;
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF")) ||
wrlvl_rank_done_r2 ||
(wrlvl_done && !wrlvl_done_r)) && (DRAM_TYPE == "DDR3")) begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE))) begin
// Quad rank in a single slot
if (nCK_PER_CLK == 2) begin
calib_aux_out[1]
<= #TCQ (!calib_aux_out[1]) ? phy_tmp_odt_r[0] : 1'b0;
calib_aux_out[3]
<= #TCQ (!calib_aux_out[3]) ? phy_tmp_odt_r[1] : 1'b0;
end else begin
calib_aux_out[1] <= #TCQ phy_tmp_odt_r[0];
calib_aux_out[3] <= #TCQ phy_tmp_odt_r[1];
end
end else begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end
end
end
end
endgenerate
//*****************************************************************
// memory address during init
//*****************************************************************
always @(posedge clk)
phy_data_full_r <= #TCQ phy_data_full;
// verilint STARC-2.7.3.3b off
always @(*)begin
// Bus 0 for address/bank never used
address_w = 'b0;
bank_w = 'b0;
if ((init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_DDR2_PRECHARGE)) begin
// Set A10=1 for ZQ long calibration or Precharge All
address_w = 'b0;
address_w[10] = 1'b1;
bank_w = 'b0;
end else if (init_state_r == INIT_WRLVL_START) begin
// Enable wrlvl in MR1
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[2] = mr1_r[chip_cnt_r][0];
address_w[6] = mr1_r[chip_cnt_r][1];
address_w[9] = mr1_r[chip_cnt_r][2];
address_w[7] = 1'b1;
end else if (init_state_r == INIT_WRLVL_LOAD_MR) begin
// Finished with write leveling, disable wrlvl in MR1
// For single rank disable Rtt_Nom
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[2] = mr1_r[chip_cnt_r][0];
address_w[6] = mr1_r[chip_cnt_r][1];
address_w[9] = mr1_r[chip_cnt_r][2];
end else if (init_state_r == INIT_WRLVL_LOAD_MR2) begin
// Set RTT_WR in MR2 after write leveling disabled
bank_w[1:0] = 2'b10;
address_w = load_mr2[ROW_WIDTH-1:0];
address_w[10:9] = mr2_r[chip_cnt_r];
end else if (init_state_r == INIT_MPR_READ) begin
address_w = 'b0;
bank_w = 'b0;
end else if (init_state_r == INIT_MPR_RDEN) begin
// Enable MPR read with LMR3 and A2=1
bank_w[BANK_WIDTH-1:0] = 'd3;
address_w = {ROW_WIDTH{1'b0}};
address_w[2] = 1'b1;
end else if (init_state_r == INIT_MPR_DISABLE) begin
// Disable MPR read with LMR3 and A2=0
bank_w[BANK_WIDTH-1:0] = 'd3;
address_w = {ROW_WIDTH{1'b0}};
end else if ((init_state_r == INIT_REG_WRITE)&
(DRAM_TYPE == "DDR3"))begin
// bank_w is assigned a 3 bit value. In some
// DDR2 cases there will be only two bank bits.
//Qualifying the condition with DDR3
bank_w = 'b0;
address_w = 'b0;
case (reg_ctrl_cnt_r)
4'h1:begin
address_w[4:0] = REG_RC1[4:0];
bank_w = REG_RC1[7:5];
end
4'h2: address_w[4:0] = REG_RC2[4:0];
4'h3: begin
address_w[4:0] = REG_RC3[4:0];
bank_w = REG_RC3[7:5];
end
4'h4: begin
address_w[4:0] = REG_RC4[4:0];
bank_w = REG_RC4[7:5];
end
4'h5: begin
address_w[4:0] = REG_RC5[4:0];
bank_w = REG_RC5[7:5];
end
4'h6: begin
address_w[4:0] = REG_RC10[4:0];
bank_w = REG_RC10[7:5];
end
4'h7: begin
address_w[4:0] = REG_RC11[4:0];
bank_w = REG_RC11[7:5];
end
default: address_w[4:0] = REG_RC0[4:0];
endcase
end else if (init_state_r == INIT_LOAD_MR) begin
// If loading mode register, look at cnt_init_mr to determine
// which MR is currently being programmed
address_w = 'b0;
bank_w = 'b0;
if(DRAM_TYPE == "DDR3")begin
if(rdlvl_stg1_done && prbs_rdlvl_done && pi_dqs_found_done)begin
// end of the calibration programming correct
// burst length
if (TEST_AL == "0") begin
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
address_w[8]= 1'b0; //Don't reset DLL
end else begin
// programming correct AL value
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
if (TEST_AL == "CL-1")
address_w[4:3]= 2'b01; // AL="CL-1"
else
address_w[4:3]= 2'b10; // AL="CL-2"
end
end else begin
case (cnt_init_mr_r)
INIT_CNT_MR2: begin
bank_w[1:0] = 2'b10;
address_w = load_mr2[ROW_WIDTH-1:0];
address_w[10:9] = mr2_r[chip_cnt_r];
end
INIT_CNT_MR3: begin
bank_w[1:0] = 2'b11;
address_w = load_mr3[ROW_WIDTH-1:0];
end
INIT_CNT_MR1: begin
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[2] = mr1_r[chip_cnt_r][0];
address_w[6] = mr1_r[chip_cnt_r][1];
address_w[9] = mr1_r[chip_cnt_r][2];
end
INIT_CNT_MR0: begin
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
// fixing it to BL8 for calibration
address_w[1:0] = 2'b00;
end
default: begin
bank_w = {BANK_WIDTH{1'bx}};
address_w = {ROW_WIDTH{1'bx}};
end
endcase
end
end else begin // DDR2
case (cnt_init_mr_r)
INIT_CNT_MR2: begin
if(~ddr2_refresh_flag_r)begin
bank_w[1:0] = 2'b10;
address_w = load_mr2[ROW_WIDTH-1:0];
end else begin // second set of lm commands
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
address_w[8]= 1'b0;
//MRS command without resetting DLL
end
end
INIT_CNT_MR3: begin
if(~ddr2_refresh_flag_r)begin
bank_w[1:0] = 2'b11;
address_w = load_mr3[ROW_WIDTH-1:0];
end else begin // second set of lm commands
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
address_w[8]= 1'b0;
//MRS command without resetting DLL. Repeted again
// because there is an extra state.
end
end
INIT_CNT_MR1: begin
bank_w[1:0] = 2'b01;
if(~ddr2_refresh_flag_r)begin
address_w = load_mr1[ROW_WIDTH-1:0];
end else begin // second set of lm commands
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[9:7] = 3'b111;
//OCD default state
end
end
INIT_CNT_MR0: begin
if(~ddr2_refresh_flag_r)begin
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
end else begin // second set of lm commands
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
if((chip_cnt_r == 2'd1) || (chip_cnt_r == 2'd3))begin
// always disable odt for rank 1 and rank 3 as per SPEC
address_w[2] = 'b0;
address_w[6] = 'b0;
end
//OCD exit
end
end
default: begin
bank_w = {BANK_WIDTH{1'bx}};
address_w = {ROW_WIDTH{1'bx}};
end
endcase
end
end else if ( ~prbs_rdlvl_done && ((init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ))) begin
// Writing and reading PRBS pattern for read leveling stage 1
// Need to support burst length 4 or 8. PRBS pattern will be
// written to entire row and read back from the same row repeatedly
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if (((stg1_wr_rd_cnt == NUM_STG1_WR_RD) && ~rdlvl_stg1_done) || (stg1_wr_rd_cnt == 'd127) ||
((stg1_wr_rd_cnt == 'd22) && (((init_state_r1 != INIT_RDLVL_STG1_WRITE) && ~stg1_wr_done) || complex_row0_rd_done))) begin
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
end else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((stg1_wr_rd_cnt >= 9'd0) && new_burst_r && ~phy_data_full_r) begin
if ((init_state_r == INIT_RDLVL_COMPLEX_READ) && (init_state_r1 != INIT_RDLVL_COMPLEX_READ) )// ||
// ((init_state_r == INIT_RDLVL_STG1_WRITE) && prbs_rdlvl_done) )
address_w[COL_WIDTH-1:0] = complex_address[COL_WIDTH-1:0] + ADDR_INC;
else
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end
//need to add address for complex oclkdelay calib
end else if (prbs_rdlvl_done && ((init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ))) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if ((stg1_wr_rd_cnt == 'd127) || ((stg1_wr_rd_cnt == 'd30) && (((init_state_r1 != INIT_RDLVL_STG1_WRITE) && ~stg1_wr_done) || complex_row0_rd_done))) begin
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
end else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((stg1_wr_rd_cnt >= 9'd0) && new_burst_r && ~phy_data_full_r) begin
if ((init_state_r == INIT_RDLVL_STG1_WRITE) && (init_state_r1 != INIT_RDLVL_STG1_WRITE) )
// ((init_state_r == INIT_RDLVL_STG1_WRITE) && prbs_rdlvl_done) )
address_w[COL_WIDTH-1:0] = complex_address[COL_WIDTH-1:0] + ADDR_INC;
else
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end
end else if ((init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_READ)) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if (oclk_wr_cnt == NUM_STG1_WR_RD)
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((oclk_wr_cnt >= 4'd0) && new_burst_r && ~phy_data_full_r)
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end else if ((init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_READ)) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if (wrcal_wr_cnt == NUM_STG1_WR_RD)
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((wrcal_wr_cnt >= 4'd0) && new_burst_r && ~phy_data_full_r)
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end else if ((init_state_r == INIT_WRCAL_MULT_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ)) begin
// when writing or reading back training pattern for read leveling stage2
// need to support burst length of 4 or 8. This may mean issuing
// multiple commands to cover the entire range of addresses accessed
// during read leveling.
// Hard coding A[12] to 1 so that it will always be burst length of 8
// for DDR3. Does not have any effect on DDR2.
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
address_w[COL_WIDTH-1:0] =
{CALIB_COL_ADD[COL_WIDTH-1:3],burst_addr_r, 3'b000};
address_w[12] = 1'b1;
end else if ((init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT)) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
//if (stg1_wr_rd_cnt == 'd22)
// address_w = CALIB_ROW_ADD[ROW_WIDTH-1:0] + 1;
//else
address_w = prbs_rdlvl_done ? CALIB_ROW_ADD[ROW_WIDTH-1:0] + complex_row_cnt_ocal :
CALIB_ROW_ADD[ROW_WIDTH-1:0] + complex_row_cnt;
end else begin
bank_w = {BANK_WIDTH{1'bx}};
address_w = {ROW_WIDTH{1'bx}};
end
end
// verilint STARC-2.7.3.3b on
// registring before sending out
generate
genvar r,s;
if ((DRAM_TYPE != "DDR3") || (CA_MIRROR != "ON")) begin: gen_no_mirror
for (r = 0; r < nCK_PER_CLK; r = r + 1) begin: div_clk_loop
always @(posedge clk) begin
phy_address[(r*ROW_WIDTH) +: ROW_WIDTH] <= #TCQ address_w;
phy_bank[(r*BANK_WIDTH) +: BANK_WIDTH] <= #TCQ bank_w;
end
end
end else begin: gen_mirror
// Control/addressing mirroring (optional for DDR3 dual rank DIMMs)
// Mirror for the 2nd rank only. Logic needs to be enhanced to account
// for multiple slots, currently only supports one slot, 2-rank config
for (r = 0; r < nCK_PER_CLK; r = r + 1) begin: gen_ba_div_clk_loop
for (s = 0; s < BANK_WIDTH; s = s + 1) begin: gen_ba
always @(posedge clk)
if (chip_cnt_r == 2'b00) begin
phy_bank[(r*BANK_WIDTH) + s] <= #TCQ bank_w[s];
end else begin
phy_bank[(r*BANK_WIDTH) + s] <= #TCQ bank_w[(s == 0) ? 1 : ((s == 1) ? 0 : s)];
end
end
end
for (r = 0; r < nCK_PER_CLK; r = r + 1) begin: gen_addr_div_clk_loop
for (s = 0; s < ROW_WIDTH; s = s + 1) begin: gen_addr
always @(posedge clk)
if (chip_cnt_r == 2'b00) begin
phy_address[(r*ROW_WIDTH) + s] <= #TCQ address_w[s];
end else begin
phy_address[(r*ROW_WIDTH) + s] <= #TCQ address_w[
(s == 3) ? 4 :
((s == 4) ? 3 :
((s == 5) ? 6 :
((s == 6) ? 5 :
((s == 7) ? 8 :
((s == 8) ? 7 : s)))))];
end
end
end
end
endgenerate
endmodule
|
module mig_7series_v2_3_ddr_phy_init #
(
parameter tCK = 1500, // DDRx SDRAM clock period
parameter TCQ = 100,
parameter nCK_PER_CLK = 4, // # of memory clocks per CLK
parameter CLK_PERIOD = 3000, // Logic (internal) clk period (in ps)
parameter USE_ODT_PORT = 0, // 0 - No ODT output from FPGA
// 1 - ODT output from FPGA
parameter DDR3_VDD_OP_VOLT = "150", // Voltage mode used for DDR3
// 150 - 1.50 V
// 135 - 1.35 V
// 125 - 1.25 V
parameter VREF = "EXTERNAL", // Internal or external Vref
parameter PRBS_WIDTH = 8, // PRBS sequence = 2^PRBS_WIDTH
parameter BANK_WIDTH = 2,
parameter CA_MIRROR = "OFF", // C/A mirror opt for DDR3 dual rank
parameter COL_WIDTH = 10,
parameter nCS_PER_RANK = 1, // # of CS bits per rank e.g. for
// component I/F with CS_WIDTH=1,
// nCS_PER_RANK=# of components
parameter DQ_WIDTH = 64,
parameter DQS_WIDTH = 8,
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter ROW_WIDTH = 14,
parameter CS_WIDTH = 1,
parameter RANKS = 1, // # of memory ranks in the interface
parameter CKE_WIDTH = 1, // # of cke outputs
parameter DRAM_TYPE = "DDR3",
parameter REG_CTRL = "ON",
parameter ADDR_CMD_MODE= "1T",
// calibration Address
parameter CALIB_ROW_ADD = 16'h0000,// Calibration row address
parameter CALIB_COL_ADD = 12'h000, // Calibration column address
parameter CALIB_BA_ADD = 3'h0, // Calibration bank address
// DRAM mode settings
parameter AL = "0", // Additive Latency option
parameter BURST_MODE = "8", // Burst length
parameter BURST_TYPE = "SEQ", // Burst type
// parameter nAL = 0, // Additive latency (in clk cyc)
parameter nCL = 5, // Read CAS latency (in clk cyc)
parameter nCWL = 5, // Write CAS latency (in clk cyc)
parameter tRFC = 110000, // Refresh-to-command delay (in ps)
parameter REFRESH_TIMER = 1553, // Refresh interval in fabrci cycles between 8 posted refreshes
parameter REFRESH_TIMER_WIDTH = 8,
parameter OUTPUT_DRV = "HIGH", // DRAM reduced output drive option
parameter RTT_NOM = "60", // Nominal ODT termination value
parameter RTT_WR = "60", // Write ODT termination value
parameter WRLVL = "ON", // Enable write leveling
// parameter PHASE_DETECT = "ON", // Enable read phase detector
parameter DDR2_DQSN_ENABLE = "YES", // Enable differential DQS for DDR2
parameter nSLOTS = 1, // Number of DIMM SLOTs in the system
parameter SIM_INIT_OPTION = "NONE", // "NONE", "SKIP_PU_DLY", "SKIP_INIT"
parameter SIM_CAL_OPTION = "NONE", // "NONE", "FAST_CAL", "SKIP_CAL"
parameter CKE_ODT_AUX = "FALSE",
parameter PRE_REV3ES = "OFF", // Enable TG error detection during calibration
parameter TEST_AL = "0", // Internal use for ICM verification
parameter FIXED_VICTIM = "TRUE",
parameter BYPASS_COMPLEX_OCAL = "FALSE"
)
(
input clk,
input rst,
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] prbs_o,
input delay_incdec_done,
input ck_addr_cmd_delay_done,
input pi_phase_locked_all,
input pi_dqs_found_done,
input dqsfound_retry,
input dqs_found_prech_req,
output reg pi_phaselock_start,
output pi_phase_locked_err,
output pi_calib_done,
input phy_if_empty,
// Read/write calibration interface
input wrlvl_done,
input wrlvl_rank_done,
input wrlvl_byte_done,
input wrlvl_byte_redo,
input wrlvl_final,
output reg wrlvl_final_if_rst,
input oclkdelay_calib_done,
input oclk_prech_req,
input oclk_calib_resume,
input lim_done,
input lim_wr_req,
output reg oclkdelay_calib_start,
//complex oclkdelay calibration
input complex_oclkdelay_calib_done,
input complex_oclk_prech_req,
input complex_oclk_calib_resume,
output reg complex_oclkdelay_calib_start,
input [DQS_CNT_WIDTH:0] complex_oclkdelay_calib_cnt, // same as oclkdelay_calib_cnt
output reg complex_ocal_num_samples_inc,
input complex_ocal_num_samples_done_r,
input [2:0] complex_ocal_rd_victim_sel,
output reg complex_ocal_reset_rd_addr,
input complex_ocal_ref_req,
output reg complex_ocal_ref_done,
input done_dqs_tap_inc,
input [5:0] rd_data_offset_0,
input [5:0] rd_data_offset_1,
input [5:0] rd_data_offset_2,
input [6*RANKS-1:0] rd_data_offset_ranks_0,
input [6*RANKS-1:0] rd_data_offset_ranks_1,
input [6*RANKS-1:0] rd_data_offset_ranks_2,
input pi_dqs_found_rank_done,
input wrcal_done,
input wrcal_prech_req,
input wrcal_read_req,
input wrcal_act_req,
input temp_wrcal_done,
input [7:0] slot_0_present,
input [7:0] slot_1_present,
output reg wl_sm_start,
output reg wr_lvl_start,
output reg wrcal_start,
output reg wrcal_rd_wait,
output reg wrcal_sanity_chk,
output reg tg_timer_done,
output reg no_rst_tg_mc,
input rdlvl_stg1_done,
input rdlvl_stg1_rank_done,
output reg rdlvl_stg1_start,
output reg pi_dqs_found_start,
output reg detect_pi_found_dqs,
// rdlvl stage 1 precharge requested after each DQS
input rdlvl_prech_req,
input rdlvl_last_byte_done,
input wrcal_resume,
input wrcal_sanity_chk_done,
// MPR read leveling
input mpr_rdlvl_done,
input mpr_rnk_done,
input mpr_last_byte_done,
output reg mpr_rdlvl_start,
output reg mpr_end_if_reset,
// PRBS Read Leveling
input prbs_rdlvl_done,
input prbs_last_byte_done,
input prbs_rdlvl_prech_req,
input complex_victim_inc,
input [2:0] rd_victim_sel,
input [DQS_CNT_WIDTH:0] pi_stg2_prbs_rdlvl_cnt,
output reg [2:0] victim_sel,
output reg [DQS_CNT_WIDTH:0]victim_byte_cnt,
output reg prbs_rdlvl_start,
output reg prbs_gen_clk_en,
output reg prbs_gen_oclk_clk_en,
output reg complex_sample_cnt_inc,
output reg complex_sample_cnt_inc_ocal,
output reg complex_wr_done,
// Signals shared btw multiple calibration stages
output reg prech_done,
// Data select / status
output reg init_calib_complete,
// Signal to mask memory model error for Invalid latching edge
output reg calib_writes,
// PHY address/control
// 2 commands to PHY Control Block per div 2 clock in 2:1 mode
// 4 commands to PHY Control Block per div 4 clock in 4:1 mode
output reg [nCK_PER_CLK*ROW_WIDTH-1:0] phy_address,
output reg [nCK_PER_CLK*BANK_WIDTH-1:0]phy_bank,
output reg [nCK_PER_CLK-1:0] phy_ras_n,
output reg [nCK_PER_CLK-1:0] phy_cas_n,
output reg [nCK_PER_CLK-1:0] phy_we_n,
output reg phy_reset_n,
output [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] phy_cs_n,
// Hard PHY Interface signals
input phy_ctl_ready,
input phy_ctl_full,
input phy_cmd_full,
input phy_data_full,
output reg calib_ctl_wren,
output reg calib_cmd_wren,
output reg [1:0] calib_seq,
output reg write_calib,
output reg read_calib,
// PHY_Ctl_Wd
output reg [2:0] calib_cmd,
// calib_aux_out used for CKE and ODT
output reg [3:0] calib_aux_out,
output reg [1:0] calib_odt ,
output reg [nCK_PER_CLK-1:0] calib_cke ,
output [1:0] calib_rank_cnt,
output reg [1:0] calib_cas_slot,
output reg [5:0] calib_data_offset_0,
output reg [5:0] calib_data_offset_1,
output reg [5:0] calib_data_offset_2,
// PHY OUT_FIFO
output reg calib_wrdata_en,
output reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] phy_wrdata,
// PHY Read
output phy_rddata_en,
output phy_rddata_valid,
output [255:0] dbg_phy_init,
input read_pause,
input reset_rd_addr,
//OCAL centering calibration
input oclkdelay_center_calib_start,
input oclk_center_write_resume,
input oclkdelay_center_calib_done
);
//*****************************************************************************
// Assertions to be added
//*****************************************************************************
// The phy_ctl_full signal must never be asserted in synchronous mode of
// operation either 4:1 or 2:1
//
// The RANKS parameter must never be set to '0' by the user
// valid values: 1 to 4
//
//*****************************************************************************
//***************************************************************************
// Number of Read level stage 1 writes limited to a SDRAM row
// The address of Read Level stage 1 reads must also be limited
// to a single SDRAM row
// (2^COL_WIDTH)/BURST_MODE = (2^10)/8 = 128
localparam NUM_STG1_WR_RD = (BURST_MODE == "8") ? 4 :
(BURST_MODE == "4") ? 8 : 4;
localparam ADDR_INC = (BURST_MODE == "8") ? 8 :
(BURST_MODE == "4") ? 4 : 8;
// In a 2 slot dual rank per system RTT_NOM values
// for Rank2 and Rank3 default to 40 ohms
localparam RTT_NOM2 = "40";
localparam RTT_NOM3 = "40";
localparam RTT_NOM_int = (USE_ODT_PORT == 1) ? RTT_NOM : RTT_WR;
// Specifically for use with half-frequency controller (nCK_PER_CLK=2)
// = 1 if burst length = 4, = 0 if burst length = 8. Determines how
// often row command needs to be issued during read-leveling
// For DDR3 the burst length is fixed during calibration
localparam BURST4_FLAG = (DRAM_TYPE == "DDR3")? 1'b0 :
(BURST_MODE == "8") ? 1'b0 :
((BURST_MODE == "4") ? 1'b1 : 1'b0);
//***************************************************************************
// Counter values used to determine bus timing
// NOTE on all counter terminal counts - these can/should be one less than
// the actual delay to take into account extra clock cycle delay in
// generating the corresponding "done" signal
//***************************************************************************
localparam CLK_MEM_PERIOD = CLK_PERIOD / nCK_PER_CLK;
// Calculate initial delay required in number of CLK clock cycles
// to delay initially. The counter is clocked by [CLK/1024] - which
// is approximately division by 1000 - note that the formulas below will
// result in more than the minimum wait time because of this approximation.
// NOTE: For DDR3 JEDEC specifies to delay reset
// by 200us, and CKE by an additional 500us after power-up
// For DDR2 CKE is delayed by 200us after power up.
localparam DDR3_RESET_DELAY_NS = 200000;
localparam DDR3_CKE_DELAY_NS = 500000 + DDR3_RESET_DELAY_NS;
localparam DDR2_CKE_DELAY_NS = 200000;
localparam PWRON_RESET_DELAY_CNT =
((DDR3_RESET_DELAY_NS+CLK_PERIOD-1)/CLK_PERIOD);
localparam PWRON_CKE_DELAY_CNT = (DRAM_TYPE == "DDR3") ?
(((DDR3_CKE_DELAY_NS+CLK_PERIOD-1)/CLK_PERIOD)) :
(((DDR2_CKE_DELAY_NS+CLK_PERIOD-1)/CLK_PERIOD));
// FOR DDR2 -1 taken out. With -1 not getting 200us. The equation
// needs to be reworked.
localparam DDR2_INIT_PRE_DELAY_PS = 400000;
localparam DDR2_INIT_PRE_CNT =
((DDR2_INIT_PRE_DELAY_PS+CLK_PERIOD-1)/CLK_PERIOD)-1;
// Calculate tXPR time: reset from CKE HIGH to valid command after power-up
// tXPR = (max(5nCK, tRFC(min)+10ns). Add a few (blah, messy) more clock
// cycles because this counter actually starts up before CKE is asserted
// to memory.
localparam TXPR_DELAY_CNT =
(5*CLK_MEM_PERIOD > tRFC+10000) ?
(((5+nCK_PER_CLK-1)/nCK_PER_CLK)-1)+11 :
(((tRFC+10000+CLK_PERIOD-1)/CLK_PERIOD)-1)+11;
// tDLLK/tZQINIT time = 512*tCK = 256*tCLKDIV
localparam TDLLK_TZQINIT_DELAY_CNT = 255;
// TWR values in ns. Both DDR2 and DDR3 have the same value.
// 15000ns/tCK
localparam TWR_CYC = ((15000) % CLK_MEM_PERIOD) ?
(15000/CLK_MEM_PERIOD) + 1 : 15000/CLK_MEM_PERIOD;
// time to wait between consecutive commands in PHY_INIT - this is a
// generic number, and must be large enough to account for worst case
// timing parameter (tRFC - refresh-to-active) across all memory speed
// grades and operating frequencies. Expressed in clk
// (Divided by 4 or Divided by 2) clock cycles.
localparam CNTNEXT_CMD = 7'b1111111;
// Counter values to keep track of which MR register to load during init
// Set value of INIT_CNT_MR_DONE to equal value of counter for last mode
// register configured during initialization.
// NOTE: Reserve more bits for DDR2 - more MR accesses for DDR2 init
localparam INIT_CNT_MR2 = 2'b00;
localparam INIT_CNT_MR3 = 2'b01;
localparam INIT_CNT_MR1 = 2'b10;
localparam INIT_CNT_MR0 = 2'b11;
localparam INIT_CNT_MR_DONE = 2'b11;
// Register chip programmable values for DDR3
// The register chip for the registered DIMM needs to be programmed
// before the initialization of the registered DIMM.
// Address for the control word is in : DBA2, DA2, DA1, DA0
// Data for the control word is in: DBA1 DBA0, DA4, DA3
// The values will be stored in the local param in the following format
// {DBA[2:0], DA[4:0]}
// RC0 is global features control word. Address == 000
localparam REG_RC0 = 8'b00000000;
// RC1 Clock driver enable control word. Enables or disables the four
// output clocks in the register chip. For single rank and dual rank
// two clocks will be enabled and for quad rank all the four clocks
// will be enabled. Address == 000. Data = 0110 for single and dual rank.
// = 0000 for quad rank
localparam REG_RC1 = 8'b00000001;
// RC2 timing control word. Set in 1T timing mode
// Address = 010. Data = 0000
localparam REG_RC2 = 8'b00000010;
// RC3 timing control word. Setting the data based on number of RANKS (inturn the number of loads)
// This setting is specific to RDIMMs from Micron Technology
localparam REG_RC3 = (RANKS >= 2) ? 8'b00101011 : 8'b00000011;
// RC4 timing control work. Setting the data based on number of RANKS (inturn the number of loads)
// This setting is specific to RDIMMs from Micron Technology
localparam REG_RC4 = (RANKS >= 2) ? 8'b00101100 : 8'b00000100;
// RC5 timing control work. Setting the data based on number of RANKS (inturn the number of loads)
// This setting is specific to RDIMMs from Micron Technology
localparam REG_RC5 = (RANKS >= 2) ? 8'b00101101 : 8'b00000101;
// RC10 timing control work. Setting the data to 0000
localparam [3:0] FREQUENCY_ENCODING = (tCK >= 1072 && tCK < 1250) ? 4'b0100 :
(tCK >= 1250 && tCK < 1500) ? 4'b0011 :
(tCK >= 1500 && tCK < 1875) ? 4'b0010 :
(tCK >= 1875 && tCK < 2500) ? 4'b0001 : 4'b0000;
localparam REG_RC10 = {1'b1,FREQUENCY_ENCODING,3'b010};
localparam VREF_ENCODING = (VREF == "INTERNAL") ? 1'b1 : 1'b0;
localparam [3:0] DDR3_VOLTAGE_ENCODING = (DDR3_VDD_OP_VOLT == "125") ? {1'b0,VREF_ENCODING,2'b10} :
(DDR3_VDD_OP_VOLT == "135") ? {1'b0,VREF_ENCODING,2'b01} :
{1'b0,VREF_ENCODING,2'b00} ;
localparam REG_RC11 = {1'b1,DDR3_VOLTAGE_ENCODING,3'b011};
// For non-zero AL values
localparam nAL = (AL == "CL-1") ? nCL - 1 : 0;
// Adding the register dimm latency to write latency
localparam CWL_M = (REG_CTRL == "ON") ? nCWL + nAL + 1 : nCWL + nAL;
// Count value to generate pi_phase_locked_err signal
localparam PHASELOCKED_TIMEOUT = (SIM_CAL_OPTION == "NONE") ? 16383 : 1000;
// Timeout interval for detecting error with Traffic Generator
localparam [13:0] TG_TIMER_TIMEOUT
= (SIM_CAL_OPTION == "NONE") ? 14'h3FFF : 14'h0001;
//bit num per DQS
localparam DQ_PER_DQS = DQ_WIDTH/DQS_WIDTH;
//COMPLEX_ROW_CNT_BYTE
localparam COMPLEX_ROW_CNT_BYTE = (FIXED_VICTIM=="FALSE")? DQ_PER_DQS*2: 2;
localparam COMPLEX_RD = (FIXED_VICTIM=="FALSE")? DQ_PER_DQS : 1;
// Master state machine encoding
localparam INIT_IDLE = 7'b0000000; //0
localparam INIT_WAIT_CKE_EXIT = 7'b0000001; //1
localparam INIT_LOAD_MR = 7'b0000010; //2
localparam INIT_LOAD_MR_WAIT = 7'b0000011; //3
localparam INIT_ZQCL = 7'b0000100; //4
localparam INIT_WAIT_DLLK_ZQINIT = 7'b0000101; //5
localparam INIT_WRLVL_START = 7'b0000110; //6
localparam INIT_WRLVL_WAIT = 7'b0000111; //7
localparam INIT_WRLVL_LOAD_MR = 7'b0001000; //8
localparam INIT_WRLVL_LOAD_MR_WAIT = 7'b0001001; //9
localparam INIT_WRLVL_LOAD_MR2 = 7'b0001010; //A
localparam INIT_WRLVL_LOAD_MR2_WAIT = 7'b0001011; //B
localparam INIT_RDLVL_ACT = 7'b0001100; //C
localparam INIT_RDLVL_ACT_WAIT = 7'b0001101; //D
localparam INIT_RDLVL_STG1_WRITE = 7'b0001110; //E
localparam INIT_RDLVL_STG1_WRITE_READ = 7'b0001111; //F
localparam INIT_RDLVL_STG1_READ = 7'b0010000; //10
localparam INIT_RDLVL_STG2_READ = 7'b0010001; //11
localparam INIT_RDLVL_STG2_READ_WAIT = 7'b0010010; //12
localparam INIT_PRECHARGE_PREWAIT = 7'b0010011; //13
localparam INIT_PRECHARGE = 7'b0010100; //14
localparam INIT_PRECHARGE_WAIT = 7'b0010101; //15
localparam INIT_DONE = 7'b0010110; //16
localparam INIT_DDR2_PRECHARGE = 7'b0010111; //17
localparam INIT_DDR2_PRECHARGE_WAIT = 7'b0011000; //18
localparam INIT_REFRESH = 7'b0011001; //19
localparam INIT_REFRESH_WAIT = 7'b0011010; //1A
localparam INIT_REG_WRITE = 7'b0011011; //1B
localparam INIT_REG_WRITE_WAIT = 7'b0011100; //1C
localparam INIT_DDR2_MULTI_RANK = 7'b0011101; //1D
localparam INIT_DDR2_MULTI_RANK_WAIT = 7'b0011110; //1E
localparam INIT_WRCAL_ACT = 7'b0011111; //1F
localparam INIT_WRCAL_ACT_WAIT = 7'b0100000; //20
localparam INIT_WRCAL_WRITE = 7'b0100001; //21
localparam INIT_WRCAL_WRITE_READ = 7'b0100010; //22
localparam INIT_WRCAL_READ = 7'b0100011; //23
localparam INIT_WRCAL_READ_WAIT = 7'b0100100; //24
localparam INIT_WRCAL_MULT_READS = 7'b0100101; //25
localparam INIT_PI_PHASELOCK_READS = 7'b0100110; //26
localparam INIT_MPR_RDEN = 7'b0100111; //27
localparam INIT_MPR_WAIT = 7'b0101000; //28
localparam INIT_MPR_READ = 7'b0101001; //29
localparam INIT_MPR_DISABLE_PREWAIT = 7'b0101010; //2A
localparam INIT_MPR_DISABLE = 7'b0101011; //2B
localparam INIT_MPR_DISABLE_WAIT = 7'b0101100; //2C
localparam INIT_OCLKDELAY_ACT = 7'b0101101; //2D
localparam INIT_OCLKDELAY_ACT_WAIT = 7'b0101110; //2E
localparam INIT_OCLKDELAY_WRITE = 7'b0101111; //2F
localparam INIT_OCLKDELAY_WRITE_WAIT = 7'b0110000; //30
localparam INIT_OCLKDELAY_READ = 7'b0110001; //31
localparam INIT_OCLKDELAY_READ_WAIT = 7'b0110010; //32
localparam INIT_REFRESH_RNK2_WAIT = 7'b0110011; //33
localparam INIT_RDLVL_COMPLEX_PRECHARGE = 7'b0110100; //34
localparam INIT_RDLVL_COMPLEX_PRECHARGE_WAIT = 7'b0110101; //35
localparam INIT_RDLVL_COMPLEX_ACT = 7'b0110110; //36
localparam INIT_RDLVL_COMPLEX_ACT_WAIT = 7'b0110111; //37
localparam INIT_RDLVL_COMPLEX_READ = 7'b0111000; //38
localparam INIT_RDLVL_COMPLEX_READ_WAIT = 7'b0111001; //39
localparam INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT = 7'b0111010; //3A
localparam INIT_OCAL_COMPLEX_ACT = 7'b0111011; //3B
localparam INIT_OCAL_COMPLEX_ACT_WAIT = 7'b0111100; //3C
localparam INIT_OCAL_COMPLEX_WRITE_WAIT = 7'b0111101; //3D
localparam INIT_OCAL_COMPLEX_RESUME_WAIT = 7'b0111110; //3E
localparam INIT_OCAL_CENTER_ACT = 7'b0111111; //3F
localparam INIT_OCAL_CENTER_WRITE = 7'b1000000; //40
localparam INIT_OCAL_CENTER_WRITE_WAIT = 7'b1000001; //41
localparam INIT_OCAL_CENTER_ACT_WAIT = 7'b1000010; //42
integer i, j, k, l, m, n, p, q;
reg pi_dqs_found_all_r;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r1;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r2;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r3;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r4;
reg pi_calib_rank_done_r;
reg [13:0] pi_phaselock_timer;
reg stg1_wr_done;
reg rnk_ref_cnt;
reg pi_dqs_found_done_r1;
reg pi_dqs_found_rank_done_r;
reg read_calib_int;
reg read_calib_r;
reg pi_calib_done_r;
reg pi_calib_done_r1;
reg burst_addr_r;
reg [1:0] chip_cnt_r;
reg [6:0] cnt_cmd_r;
reg cnt_cmd_done_r;
reg cnt_cmd_done_m7_r;
reg [7:0] cnt_dllk_zqinit_r;
reg cnt_dllk_zqinit_done_r;
reg cnt_init_af_done_r;
reg [1:0] cnt_init_af_r;
reg [1:0] cnt_init_data_r;
reg [1:0] cnt_init_mr_r;
reg cnt_init_mr_done_r;
reg cnt_init_pre_wait_done_r;
reg [7:0] cnt_init_pre_wait_r;
reg [9:0] cnt_pwron_ce_r;
reg cnt_pwron_cke_done_r;
reg cnt_pwron_cke_done_r1;
reg [8:0] cnt_pwron_r;
reg cnt_pwron_reset_done_r;
reg cnt_txpr_done_r;
reg [7:0] cnt_txpr_r;
reg ddr2_pre_flag_r;
reg ddr2_refresh_flag_r;
reg ddr3_lm_done_r;
reg [4:0] enable_wrlvl_cnt;
reg init_complete_r;
reg init_complete_r1;
reg init_complete_r2;
(* keep = "true" *) reg init_complete_r_timing;
(* keep = "true" *) reg init_complete_r1_timing;
reg [6:0] init_next_state;
reg [6:0] init_state_r;
reg [6:0] init_state_r1;
wire [15:0] load_mr0;
wire [15:0] load_mr1;
wire [15:0] load_mr2;
wire [15:0] load_mr3;
reg mem_init_done_r;
reg [1:0] mr2_r [0:3];
reg [2:0] mr1_r [0:3];
reg new_burst_r;
reg [15:0] wrcal_start_dly_r;
wire wrcal_start_pre;
reg wrcal_resume_r;
// Only one ODT signal per rank in PHY Control Block
reg [nCK_PER_CLK-1:0] phy_tmp_odt_r;
reg [nCK_PER_CLK-1:0] phy_tmp_odt_r1;
reg [CS_WIDTH*nCS_PER_RANK-1:0] phy_tmp_cs1_r;
reg [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] phy_int_cs_n;
wire prech_done_pre;
reg [15:0] prech_done_dly_r;
reg prech_pending_r;
reg prech_req_posedge_r;
reg prech_req_r;
reg pwron_ce_r;
reg first_rdlvl_pat_r;
reg first_wrcal_pat_r;
reg phy_wrdata_en;
reg phy_wrdata_en_r1;
reg [1:0] wrdata_pat_cnt;
reg [1:0] wrcal_pat_cnt;
reg [ROW_WIDTH-1:0] address_w;
reg [BANK_WIDTH-1:0] bank_w;
reg rdlvl_stg1_done_r1;
reg rdlvl_stg1_start_int;
reg [15:0] rdlvl_start_dly0_r;
reg rdlvl_start_pre;
reg rdlvl_last_byte_done_r;
wire rdlvl_rd;
wire rdlvl_wr;
reg rdlvl_wr_r;
wire rdlvl_wr_rd;
reg [3:0] reg_ctrl_cnt_r;
reg [1:0] tmp_mr2_r [0:3];
reg [2:0] tmp_mr1_r [0:3];
reg wrlvl_done_r;
reg wrlvl_done_r1;
reg wrlvl_rank_done_r1;
reg wrlvl_rank_done_r2;
reg wrlvl_rank_done_r3;
reg wrlvl_rank_done_r4;
reg wrlvl_rank_done_r5;
reg wrlvl_rank_done_r6;
reg wrlvl_rank_done_r7;
reg [2:0] wrlvl_rank_cntr;
reg wrlvl_odt_ctl;
reg wrlvl_odt;
reg wrlvl_active;
reg wrlvl_active_r1;
reg [2:0] num_reads;
reg temp_wrcal_done_r;
reg temp_lmr_done;
reg extend_cal_pat;
reg [13:0] tg_timer;
reg tg_timer_go;
reg cnt_wrcal_rd;
reg [3:0] cnt_wait;
reg [7:0] wrcal_reads;
reg [8:0] stg1_wr_rd_cnt;
reg phy_data_full_r;
reg wr_level_dqs_asrt;
reg wr_level_dqs_asrt_r1;
reg [1:0] dqs_asrt_cnt;
reg [3:0] num_refresh;
wire oclkdelay_calib_start_pre;
reg [15:0] oclkdelay_start_dly_r;
reg [3:0] oclk_wr_cnt;
reg [3:0] wrcal_wr_cnt;
reg wrlvl_final_r;
reg prbs_rdlvl_done_r1;
reg prbs_rdlvl_done_r2;
reg prbs_rdlvl_done_r3;
reg prbs_last_byte_done_r;
reg phy_if_empty_r;
reg prbs_pat_resume_int;
reg complex_row0_wr_done;
reg complex_row1_wr_done;
reg complex_row0_rd_done;
reg complex_row1_rd_done;
reg complex_row0_rd_done_r1;
reg [3:0] complex_wait_cnt;
reg [3:0] complex_num_reads;
reg [3:0] complex_num_reads_dec;
reg [ROW_WIDTH-1:0] complex_address;
reg wr_victim_inc;
reg [2:0] wr_victim_sel;
reg [DQS_CNT_WIDTH:0] wr_byte_cnt;
reg [7:0] complex_row_cnt;
reg complex_sample_cnt_inc_r1;
reg complex_sample_cnt_inc_r2;
reg complex_odt_ext;
reg complex_ocal_odt_ext;
reg wrcal_final_chk;
wire prech_req;
reg read_pause_r1;
reg read_pause_r2;
wire read_pause_ext;
reg reset_rd_addr_r1;
reg complex_rdlvl_int_ref_req;
reg ext_int_ref_req;
//complex OCLK delay calibration
reg [7:0] complex_row_cnt_ocal;
reg [4:0] complex_num_writes;
reg [4:0] complex_num_writes_dec;
reg complex_oclkdelay_calib_start_int;
reg complex_oclkdelay_calib_start_r1;
reg complex_oclkdelay_calib_start_r2;
reg complex_oclkdelay_calib_done_r1;
// reg [DQS_CNT_WIDTH:0] wr_byte_cnt_ocal;
reg [2:0] wr_victim_sel_ocal;
reg complex_row1_rd_done_r1; //time for switch to write
reg [2:0] complex_row1_rd_cnt; //row1 read number for the byte (8 (16 rows) row1)
reg complex_byte_rd_done; //read for the byte is done
reg complex_byte_rd_done_r1;
// reg complex_row_change; //every 16 rows of read, it is set to "0" for write
reg ocal_num_samples_inc; //1 read/write is done
reg complex_ocal_wr_start; //indicate complex ocal write is started. used for prbs rd addr gen
reg prbs_rdlvl_done_pulse; //rising edge for prbs_rdlvl_done. used for pipelining
reg prech_done_r1, prech_done_r2, prech_done_r3;
reg mask_lim_done;
reg complex_mask_lim_done;
reg oclkdelay_calib_start_int;
reg [REFRESH_TIMER_WIDTH-1:0] oclkdelay_ref_cnt;
reg oclkdelay_int_ref_req;
reg [3:0] ocal_act_wait_cnt;
reg oclk_calib_resume_level;
reg ocal_last_byte_done;
wire mmcm_wr; //MMCM centering write. no CS will be set
wire exit_ocal_complex_resume_wait =
init_state_r == INIT_OCAL_COMPLEX_RESUME_WAIT && complex_oclk_calib_resume;
//***************************************************************************
// Debug
//***************************************************************************
//synthesis translate_off
always @(posedge mem_init_done_r) begin
if (!rst)
$display ("PHY_INIT: Memory Initialization completed at %t", $time);
end
always @(posedge wrlvl_done) begin
if (!rst && (WRLVL == "ON"))
$display ("PHY_INIT: Write Leveling completed at %t", $time);
end
always @(posedge rdlvl_stg1_done) begin
if (!rst)
$display ("PHY_INIT: Read Leveling Stage 1 completed at %t", $time);
end
always @(posedge mpr_rdlvl_done) begin
if (!rst)
$display ("PHY_INIT: MPR Read Leveling completed at %t", $time);
end
always @(posedge oclkdelay_calib_done) begin
if (!rst)
$display ("PHY_INIT: OCLKDELAY calibration completed at %t", $time);
end
always @(posedge pi_calib_done_r1) begin
if (!rst)
$display ("PHY_INIT: Phaser_In Phase Locked at %t", $time);
end
always @(posedge pi_dqs_found_done) begin
if (!rst)
$display ("PHY_INIT: Phaser_In DQSFOUND completed at %t", $time);
end
always @(posedge wrcal_done) begin
if (!rst && (WRLVL == "ON"))
$display ("PHY_INIT: Write Calibration completed at %t", $time);
end
always@(posedge prbs_rdlvl_done)begin
if(!rst)
$display("PHY_INIT : PRBS/PER_BIT calibration completed at %t",$time);
end
always@(posedge complex_oclkdelay_calib_done)begin
if(!rst)
$display("PHY_INIT : COMPLEX OCLKDELAY calibration completed at %t",$time);
end
always@(posedge oclkdelay_center_calib_done)begin
if(!rst)
$display("PHY_INIT : OCLKDELAY CENTER CALIB calibration completed at %t",$time);
end
//synthesis translate_on
assign dbg_phy_init[5:0] = init_state_r;
assign dbg_phy_init[6+:8] = complex_row_cnt;
assign dbg_phy_init[14+:3] = victim_sel;
assign dbg_phy_init[17+:4] = victim_byte_cnt;
assign dbg_phy_init[21+:9] = stg1_wr_rd_cnt[8:0];
assign dbg_phy_init[30+:15] = complex_address;
assign dbg_phy_init[(30+15)+:15] = phy_address[14:0];
assign dbg_phy_init[60] =prbs_rdlvl_prech_req ;
assign dbg_phy_init[61] =prech_req_posedge_r ;
//***************************************************************************
// DQS count to be sent to hard PHY during Phaser_IN Phase Locking stage
//***************************************************************************
// assign pi_phaselock_calib_cnt = dqs_cnt_r;
assign pi_calib_done = pi_calib_done_r1;
assign read_pause_ext = read_pause | read_pause_r2;
//detect rising edge of prbs_rdlvl_done to reset all control sighals
always @ (posedge clk) begin
prbs_rdlvl_done_pulse <= #TCQ prbs_rdlvl_done & ~prbs_rdlvl_done_r1;
end
always @ (posedge clk) begin
read_pause_r1 <= #TCQ read_pause;
read_pause_r2 <= #TCQ read_pause_r1;
end
always @(posedge clk) begin
if (rst)
wrcal_final_chk <= #TCQ 1'b0;
else if ((init_next_state == INIT_WRCAL_ACT) && wrcal_done &&
(DRAM_TYPE == "DDR3"))
wrcal_final_chk <= #TCQ 1'b1;
end
always @(posedge clk) begin
rdlvl_stg1_done_r1 <= #TCQ rdlvl_stg1_done;
prbs_rdlvl_done_r1 <= #TCQ prbs_rdlvl_done;
prbs_rdlvl_done_r2 <= #TCQ prbs_rdlvl_done_r1;
prbs_rdlvl_done_r3 <= #TCQ prbs_rdlvl_done_r2;
wrcal_resume_r <= #TCQ wrcal_resume;
wrcal_sanity_chk <= #TCQ wrcal_final_chk;
end
always @(posedge clk) begin
if (rst)
mpr_end_if_reset <= #TCQ 1'b0;
else if (mpr_last_byte_done && (num_refresh != 'd0))
mpr_end_if_reset <= #TCQ 1'b1;
else
mpr_end_if_reset <= #TCQ 1'b0;
end
// Siganl to mask memory model error for Invalid latching edge
always @(posedge clk)
if (rst)
calib_writes <= #TCQ 1'b0;
else if ((init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ))
calib_writes <= #TCQ 1'b1;
else
calib_writes <= #TCQ 1'b0;
always @(posedge clk)
if (rst)
wrcal_rd_wait <= #TCQ 1'b0;
else if (init_state_r == INIT_WRCAL_READ_WAIT)
wrcal_rd_wait <= #TCQ 1'b1;
else
wrcal_rd_wait <= #TCQ 1'b0;
//***************************************************************************
// Signal PHY completion when calibration is finished
// Signal assertion is delayed by four clock cycles to account for the
// multi cycle path constraint to (phy_init_data_sel) signal.
//***************************************************************************
always @(posedge clk)
if (rst) begin
init_complete_r <= #TCQ 1'b0;
init_complete_r_timing <= #TCQ 1'b0;
init_complete_r1 <= #TCQ 1'b0;
init_complete_r1_timing <= #TCQ 1'b0;
init_complete_r2 <= #TCQ 1'b0;
init_calib_complete <= #TCQ 1'b0;
end else begin
if (init_state_r == INIT_DONE) begin
init_complete_r <= #TCQ 1'b1;
init_complete_r_timing <= #TCQ 1'b1;
end
init_complete_r1 <= #TCQ init_complete_r;
init_complete_r1_timing <= #TCQ init_complete_r_timing;
init_complete_r2 <= #TCQ init_complete_r1;
init_calib_complete <= #TCQ init_complete_r2;
end
always @ (posedge clk)
if (rst)
complex_oclkdelay_calib_done_r1 <= #TCQ 1'b0;
else
complex_oclkdelay_calib_done_r1 <= #TCQ complex_oclkdelay_calib_done;
//reset read address for starting complex ocaldealy calib
always @ (posedge clk) begin
complex_ocal_reset_rd_addr <= #TCQ ((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && (complex_wait_cnt == 'd9)) || (prbs_last_byte_done && ~prbs_last_byte_done_r);
end
//first write for complex oclkdealy calib
always @ (posedge clk) begin
if (rst)
complex_ocal_wr_start <= #TCQ 'b0;
else
complex_ocal_wr_start <= #TCQ complex_ocal_reset_rd_addr? 1'b1 : complex_ocal_wr_start;
end
//ocal stg3 centering start
// always @ (posedge clk)
// if(rst) oclkdelay_center_calib_start <= #TCQ 1'b0;
// else
// oclkdelay_center_calib_start <= #TCQ ((init_state_r == INIT_OCAL_CENTER_ACT) && lim_done)? 1'b1: oclkdelay_center_calib_start;
//***************************************************************************
// Instantiate FF for the phy_init_data_sel signal. A multi cycle path
// constraint will be assigned to this signal. This signal will only be
// used within the PHY
//***************************************************************************
// FDRSE u_ff_phy_init_data_sel
// (
// .Q (phy_init_data_sel),
// .C (clk),
// .CE (1'b1),
// .D (init_complete_r),
// .R (1'b0),
// .S (1'b0)
// ) /* synthesis syn_preserve=1 */
// /* synthesis syn_replicate = 0 */;
//***************************************************************************
// Mode register programming
//***************************************************************************
//*****************************************************************
// DDR3 Load mode reg0
// Mode Register (MR0):
// [15:13] - unused - 000
// [12] - Precharge Power-down DLL usage - 0 (DLL frozen, slow-exit),
// 1 (DLL maintained)
// [11:9] - write recovery for Auto Precharge (tWR/tCK = 6)
// [8] - DLL reset - 0 or 1
// [7] - Test Mode - 0 (normal)
// [6:4],[2] - CAS latency - CAS_LAT
// [3] - Burst Type - BURST_TYPE
// [1:0] - Burst Length - BURST_LEN
// DDR2 Load mode register
// Mode Register (MR):
// [15:14] - unused - 00
// [13] - reserved - 0
// [12] - Power-down mode - 0 (normal)
// [11:9] - write recovery - write recovery for Auto Precharge
// (tWR/tCK = 6)
// [8] - DLL reset - 0 or 1
// [7] - Test Mode - 0 (normal)
// [6:4] - CAS latency - CAS_LAT
// [3] - Burst Type - BURST_TYPE
// [2:0] - Burst Length - BURST_LEN
//*****************************************************************
generate
if(DRAM_TYPE == "DDR3") begin: gen_load_mr0_DDR3
assign load_mr0[1:0] = (BURST_MODE == "8") ? 2'b00 :
(BURST_MODE == "OTF") ? 2'b01 :
(BURST_MODE == "4") ? 2'b10 : 2'b11;
assign load_mr0[2] = (nCL >= 12) ? 1'b1 : 1'b0; // LSb of CAS latency
assign load_mr0[3] = (BURST_TYPE == "SEQ") ? 1'b0 : 1'b1;
assign load_mr0[6:4] = ((nCL == 5) || (nCL == 13)) ? 3'b001 :
((nCL == 6) || (nCL == 14)) ? 3'b010 :
(nCL == 7) ? 3'b011 :
(nCL == 8) ? 3'b100 :
(nCL == 9) ? 3'b101 :
(nCL == 10) ? 3'b110 :
(nCL == 11) ? 3'b111 :
(nCL == 12) ? 3'b000 : 3'b111;
assign load_mr0[7] = 1'b0;
assign load_mr0[8] = 1'b1; // Reset DLL (init only)
assign load_mr0[11:9] = (TWR_CYC == 5) ? 3'b001 :
(TWR_CYC == 6) ? 3'b010 :
(TWR_CYC == 7) ? 3'b011 :
(TWR_CYC == 8) ? 3'b100 :
(TWR_CYC == 9) ? 3'b101 :
(TWR_CYC == 10) ? 3'b101 :
(TWR_CYC == 11) ? 3'b110 :
(TWR_CYC == 12) ? 3'b110 :
(TWR_CYC == 13) ? 3'b111 :
(TWR_CYC == 14) ? 3'b111 :
(TWR_CYC == 15) ? 3'b000 :
(TWR_CYC == 16) ? 3'b000 : 3'b010;
assign load_mr0[12] = 1'b0; // Precharge Power-Down DLL 'slow-exit'
assign load_mr0[15:13] = 3'b000;
end else if (DRAM_TYPE == "DDR2") begin: gen_load_mr0_DDR2 // block: gen
assign load_mr0[2:0] = (BURST_MODE == "8") ? 3'b011 :
(BURST_MODE == "4") ? 3'b010 : 3'b111;
assign load_mr0[3] = (BURST_TYPE == "SEQ") ? 1'b0 : 1'b1;
assign load_mr0[6:4] = (nCL == 3) ? 3'b011 :
(nCL == 4) ? 3'b100 :
(nCL == 5) ? 3'b101 :
(nCL == 6) ? 3'b110 : 3'b111;
assign load_mr0[7] = 1'b0;
assign load_mr0[8] = 1'b1; // Reset DLL (init only)
assign load_mr0[11:9] = (TWR_CYC == 2) ? 3'b001 :
(TWR_CYC == 3) ? 3'b010 :
(TWR_CYC == 4) ? 3'b011 :
(TWR_CYC == 5) ? 3'b100 :
(TWR_CYC == 6) ? 3'b101 : 3'b010;
assign load_mr0[15:12]= 4'b0000; // Reserved
end
endgenerate
//*****************************************************************
// DDR3 Load mode reg1
// Mode Register (MR1):
// [15:13] - unused - 00
// [12] - output enable - 0 (enabled for DQ, DQS, DQS#)
// [11] - TDQS enable - 0 (TDQS disabled and DM enabled)
// [10] - reserved - 0 (must be '0')
// [9] - RTT[2] - 0
// [8] - reserved - 0 (must be '0')
// [7] - write leveling - 0 (disabled), 1 (enabled)
// [6] - RTT[1] - RTT[1:0] = 0(no ODT), 1(75), 2(150), 3(50)
// [5] - Output driver impedance[1] - 0 (RZQ/6 and RZQ/7)
// [4:3] - Additive CAS - ADDITIVE_CAS
// [2] - RTT[0]
// [1] - Output driver impedance[0] - 0(RZQ/6), or 1 (RZQ/7)
// [0] - DLL enable - 0 (normal)
// DDR2 ext mode register
// Extended Mode Register (MR):
// [15:14] - unused - 00
// [13] - reserved - 0
// [12] - output enable - 0 (enabled)
// [11] - RDQS enable - 0 (disabled)
// [10] - DQS# enable - 0 (enabled)
// [9:7] - OCD Program - 111 or 000 (first 111, then 000 during init)
// [6] - RTT[1] - RTT[1:0] = 0(no ODT), 1(75), 2(150), 3(50)
// [5:3] - Additive CAS - ADDITIVE_CAS
// [2] - RTT[0]
// [1] - Output drive - REDUCE_DRV (= 0(full), = 1 (reduced)
// [0] - DLL enable - 0 (normal)
//*****************************************************************
generate
if(DRAM_TYPE == "DDR3") begin: gen_load_mr1_DDR3
assign load_mr1[0] = 1'b0; // DLL enabled during Imitialization
assign load_mr1[1] = (OUTPUT_DRV == "LOW") ? 1'b0 : 1'b1;
assign load_mr1[2] = ((RTT_NOM_int == "30") || (RTT_NOM_int == "40") ||
(RTT_NOM_int == "60")) ? 1'b1 : 1'b0;
assign load_mr1[4:3] = (AL == "0") ? 2'b00 :
(AL == "CL-1") ? 2'b01 :
(AL == "CL-2") ? 2'b10 : 2'b11;
assign load_mr1[5] = 1'b0;
assign load_mr1[6] = ((RTT_NOM_int == "40") || (RTT_NOM_int == "120")) ?
1'b1 : 1'b0;
assign load_mr1[7] = 1'b0; // Enable write lvl after init sequence
assign load_mr1[8] = 1'b0;
assign load_mr1[9] = ((RTT_NOM_int == "20") || (RTT_NOM_int == "30")) ?
1'b1 : 1'b0;
assign load_mr1[10] = 1'b0;
assign load_mr1[15:11] = 5'b00000;
end else if (DRAM_TYPE == "DDR2") begin: gen_load_mr1_DDR2
assign load_mr1[0] = 1'b0; // DLL enabled during Imitialization
assign load_mr1[1] = (OUTPUT_DRV == "LOW") ? 1'b1 : 1'b0;
assign load_mr1[2] = ((RTT_NOM_int == "75") || (RTT_NOM_int == "50")) ?
1'b1 : 1'b0;
assign load_mr1[5:3] = (AL == "0") ? 3'b000 :
(AL == "1") ? 3'b001 :
(AL == "2") ? 3'b010 :
(AL == "3") ? 3'b011 :
(AL == "4") ? 3'b100 : 3'b111;
assign load_mr1[6] = ((RTT_NOM_int == "50") ||
(RTT_NOM_int == "150")) ? 1'b1 : 1'b0;
assign load_mr1[9:7] = 3'b000;
assign load_mr1[10] = (DDR2_DQSN_ENABLE == "YES") ? 1'b0 : 1'b1;
assign load_mr1[15:11] = 5'b00000;
end
endgenerate
//*****************************************************************
// DDR3 Load mode reg2
// Mode Register (MR2):
// [15:11] - unused - 00
// [10:9] - RTT_WR - 00 (Dynamic ODT off)
// [8] - reserved - 0 (must be '0')
// [7] - self-refresh temperature range -
// 0 (normal), 1 (extended)
// [6] - Auto Self-Refresh - 0 (manual), 1(auto)
// [5:3] - CAS Write Latency (CWL) -
// 000 (5 for 400 MHz device),
// 001 (6 for 400 MHz to 533 MHz devices),
// 010 (7 for 533 MHz to 667 MHz devices),
// 011 (8 for 667 MHz to 800 MHz)
// [2:0] - Partial Array Self-Refresh (Optional) -
// 000 (full array)
// Not used for DDR2
//*****************************************************************
generate
if(DRAM_TYPE == "DDR3") begin: gen_load_mr2_DDR3
assign load_mr2[2:0] = 3'b000;
assign load_mr2[5:3] = (nCWL == 5) ? 3'b000 :
(nCWL == 6) ? 3'b001 :
(nCWL == 7) ? 3'b010 :
(nCWL == 8) ? 3'b011 :
(nCWL == 9) ? 3'b100 :
(nCWL == 10) ? 3'b101 :
(nCWL == 11) ? 3'b110 : 3'b111;
assign load_mr2[6] = 1'b0;
assign load_mr2[7] = 1'b0;
assign load_mr2[8] = 1'b0;
// Dynamic ODT disabled
assign load_mr2[10:9] = 2'b00;
assign load_mr2[15:11] = 5'b00000;
end else begin: gen_load_mr2_DDR2
assign load_mr2[15:0] = 16'd0;
end
endgenerate
//*****************************************************************
// DDR3 Load mode reg3
// Mode Register (MR3):
// [15:3] - unused - All zeros
// [2] - MPR Operation - 0(normal operation), 1(data flow from MPR)
// [1:0] - MPR location - 00 (Predefined pattern)
//*****************************************************************
assign load_mr3[1:0] = 2'b00;
assign load_mr3[2] = 1'b0;
assign load_mr3[15:3] = 13'b0000000000000;
// For multi-rank systems the rank being accessed during writes in
// Read Leveling must be sent to phy_write for the bitslip logic
assign calib_rank_cnt = chip_cnt_r;
//***************************************************************************
// Logic to begin initial calibration, and to handle precharge requests
// during read-leveling (to avoid tRAS violations if individual read
// levelling calibration stages take more than max{tRAS) to complete).
//***************************************************************************
// Assert when readback for each stage of read-leveling begins. However,
// note this indicates only when the read command is issued and when
// Phaser_IN has phase aligned FREQ_REF clock to read DQS. It does not
// indicate when the read data is present on the bus (when this happens
// after the read command is issued depends on CAS LATENCY) - there will
// need to be some delay before valid data is present on the bus.
// assign rdlvl_start_pre = (init_state_r == INIT_PI_PHASELOCK_READS);
// Assert when read back for oclkdelay calibration begins
assign oclkdelay_calib_start_pre = (init_state_r == INIT_OCAL_CENTER_ACT); //(init_state_r == INIT_OCLKDELAY_READ);
// Assert when read back for write calibration begins
assign wrcal_start_pre = (init_state_r == INIT_WRCAL_READ) || (init_state_r == INIT_WRCAL_MULT_READS);
// Common precharge signal done signal - pulses only when there has been
// a precharge issued as a result of a PRECH_REQ pulse. Note also a common
// PRECH_DONE signal is used for all blocks
assign prech_done_pre = (((init_state_r == INIT_RDLVL_STG1_READ) || (init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
((rdlvl_last_byte_done_r || prbs_last_byte_done_r) && (init_state_r == INIT_RDLVL_ACT_WAIT) && cnt_cmd_done_r) ||
(dqs_found_prech_req && (init_state_r == INIT_RDLVL_ACT_WAIT)) ||
(init_state_r == INIT_MPR_RDEN) ||
((init_state_r == INIT_WRCAL_ACT_WAIT) && cnt_cmd_done_r) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT) && complex_oclkdelay_calib_start_r1) ||
((init_state_r == INIT_OCLKDELAY_ACT_WAIT) && cnt_cmd_done_r) ||
((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) && prbs_last_byte_done_r) || //prbs_rdlvl_done
(wrlvl_final && (init_state_r == INIT_REFRESH_WAIT) && cnt_cmd_done_r && ~oclkdelay_calib_done)) &&
prech_pending_r &&
!prech_req_posedge_r);
always @(posedge clk)
if (rst)
pi_phaselock_start <= #TCQ 1'b0;
else if (init_state_r == INIT_PI_PHASELOCK_READS)
pi_phaselock_start <= #TCQ 1'b1;
// Delay start of each calibration by 16 clock cycles to ensure that when
// calibration logic begins, read data is already appearing on the bus.
// Each circuit should synthesize using an SRL16. Assume that reset is
// long enough to clear contents of SRL16.
always @(posedge clk) begin
rdlvl_last_byte_done_r <= #TCQ rdlvl_last_byte_done;
prbs_last_byte_done_r <= #TCQ prbs_last_byte_done;
rdlvl_start_dly0_r <= #TCQ {rdlvl_start_dly0_r[14:0],
rdlvl_start_pre};
wrcal_start_dly_r <= #TCQ {wrcal_start_dly_r[14:0],
wrcal_start_pre};
oclkdelay_start_dly_r <= #TCQ {oclkdelay_start_dly_r[14:0],
oclkdelay_calib_start_pre};
prech_done_dly_r <= #TCQ {prech_done_dly_r[14:0],
prech_done_pre};
end
always @(posedge clk)
if (rst)
oclkdelay_calib_start_int <= #TCQ 1'b0;
else if (oclkdelay_start_dly_r[5])
oclkdelay_calib_start_int <= #TCQ 1'b1;
always @(posedge clk) begin
if (rst)
ocal_last_byte_done <= #TCQ 1'b0;
else if ((complex_oclkdelay_calib_cnt == DQS_WIDTH-1) && oclkdelay_center_calib_done)
ocal_last_byte_done <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_REFRESH) || prbs_rdlvl_done || ocal_last_byte_done || oclkdelay_center_calib_done)
oclkdelay_ref_cnt <= #TCQ REFRESH_TIMER;
else if (oclkdelay_calib_start_int) begin
if (oclkdelay_ref_cnt > 'd0)
oclkdelay_ref_cnt <= #TCQ oclkdelay_ref_cnt - 1;
else
oclkdelay_ref_cnt <= #TCQ REFRESH_TIMER;
end
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_OCAL_CENTER_ACT) || oclkdelay_calib_done || ocal_last_byte_done || oclkdelay_center_calib_done)
oclkdelay_int_ref_req <= #TCQ 1'b0;
else if (oclkdelay_ref_cnt == 'd1)
oclkdelay_int_ref_req <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst)
ocal_act_wait_cnt <= #TCQ 'd0;
else if ((init_state_r == INIT_OCAL_CENTER_ACT_WAIT) && ocal_act_wait_cnt < 'd15)
ocal_act_wait_cnt <= #TCQ ocal_act_wait_cnt + 1;
else
ocal_act_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_OCLKDELAY_READ))
oclk_calib_resume_level <= #TCQ 1'b0;
else if (oclk_calib_resume)
oclk_calib_resume_level <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_RDLVL_ACT_WAIT) || prbs_rdlvl_done)
complex_rdlvl_int_ref_req <= #TCQ 1'b0;
else if (oclkdelay_ref_cnt == 'd1)
// complex_rdlvl_int_ref_req <= #TCQ 1'b1;
complex_rdlvl_int_ref_req <= #TCQ 1'b0; //temporary fix for read issue
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_RDLVL_COMPLEX_READ))
ext_int_ref_req <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_ACT_WAIT) && complex_rdlvl_int_ref_req)
ext_int_ref_req <= #TCQ 1'b1;
end
always @(posedge clk) begin
prech_done <= #TCQ prech_done_dly_r[15];
prech_done_r1 <= #TCQ prech_done_dly_r[15];
prech_done_r2 <= #TCQ prech_done_r1;
prech_done_r3 <= #TCQ prech_done_r2;
end
always @(posedge clk)
if (rst)
mpr_rdlvl_start <= #TCQ 1'b0;
else if (pi_dqs_found_done &&
(init_state_r == INIT_MPR_READ))
mpr_rdlvl_start <= #TCQ 1'b1;
always @(posedge clk)
phy_if_empty_r <= #TCQ phy_if_empty;
always @(posedge clk)
if (rst ||
((stg1_wr_rd_cnt == 'd2) && ~stg1_wr_done) || prbs_rdlvl_done)
prbs_gen_clk_en <= #TCQ 1'b0;
else if ((~phy_if_empty_r && rdlvl_stg1_done_r1 && ~prbs_rdlvl_done) ||
((init_state_r == INIT_RDLVL_ACT_WAIT) && rdlvl_stg1_done_r1 && (cnt_cmd_r == 'd127)) ||
((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && rdlvl_stg1_done_r1 && (complex_wait_cnt == 'd14))
|| (init_state_r == INIT_RDLVL_COMPLEX_READ) || ((init_state_r == INIT_PRECHARGE_PREWAIT) && prbs_rdlvl_start))
prbs_gen_clk_en <= #TCQ 1'b1;
//Enable for complex oclkdelay - used in prbs gen
always @(posedge clk)
if (rst ||
((stg1_wr_rd_cnt == 'd2) && ~stg1_wr_done) || complex_oclkdelay_calib_done ||
(complex_wait_cnt == 'd15 && complex_num_writes == 1 && complex_ocal_wr_start) ||
( init_state_r == INIT_RDLVL_STG1_WRITE && complex_num_writes_dec == 'd2) || ~complex_ocal_wr_start ||
(complex_byte_rd_done && init_state_r == INIT_RDLVL_COMPLEX_ACT ) ||
(init_state_r != INIT_OCAL_COMPLEX_RESUME_WAIT && init_state_r1 == INIT_OCAL_COMPLEX_RESUME_WAIT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT))
prbs_gen_oclk_clk_en <= #TCQ 1'b0;
else if ((~phy_if_empty_r && ~complex_oclkdelay_calib_done && prbs_rdlvl_done_r1) || // changed for new algo 3/26
((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && (complex_wait_cnt == 'd14)) ||
((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (complex_wait_cnt == 'd14)) ||
exit_ocal_complex_resume_wait ||
((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && ~stg1_wr_done && ~complex_row1_wr_done && ~complex_ocal_num_samples_done_r && (complex_wait_cnt == 'd14))
|| (init_state_r == INIT_RDLVL_COMPLEX_READ) )
prbs_gen_oclk_clk_en <= #TCQ 1'b1;
generate
if (RANKS < 2) begin
always @(posedge clk)
if (rst) begin
rdlvl_stg1_start <= #TCQ 1'b0;
rdlvl_stg1_start_int <= #TCQ 1'b0;
rdlvl_start_pre <= #TCQ 1'b0;
prbs_rdlvl_start <= #TCQ 1'b0;
end else begin
if (pi_dqs_found_done && cnt_cmd_done_r &&
(init_state_r == INIT_RDLVL_ACT_WAIT))
rdlvl_stg1_start_int <= #TCQ 1'b1;
if (pi_dqs_found_done &&
(init_state_r == INIT_RDLVL_STG1_READ))begin
rdlvl_start_pre <= #TCQ 1'b1;
rdlvl_stg1_start <= #TCQ rdlvl_start_dly0_r[14];
end
if (pi_dqs_found_done && rdlvl_stg1_done && ~prbs_rdlvl_done &&
(init_state_r == INIT_RDLVL_COMPLEX_READ) && (WRLVL == "ON")) begin
prbs_rdlvl_start <= #TCQ 1'b1;
end
end
end else begin
always @(posedge clk)
if (rst || rdlvl_stg1_rank_done) begin
rdlvl_stg1_start <= #TCQ 1'b0;
rdlvl_stg1_start_int <= #TCQ 1'b0;
rdlvl_start_pre <= #TCQ 1'b0;
prbs_rdlvl_start <= #TCQ 1'b0;
end else begin
if (pi_dqs_found_done && cnt_cmd_done_r &&
(init_state_r == INIT_RDLVL_ACT_WAIT))
rdlvl_stg1_start_int <= #TCQ 1'b1;
if (pi_dqs_found_done &&
(init_state_r == INIT_RDLVL_STG1_READ))begin
rdlvl_start_pre <= #TCQ 1'b1;
rdlvl_stg1_start <= #TCQ rdlvl_start_dly0_r[14];
end
if (pi_dqs_found_done && rdlvl_stg1_done && ~prbs_rdlvl_done &&
(init_state_r == INIT_RDLVL_COMPLEX_READ) && (WRLVL == "ON")) begin
prbs_rdlvl_start <= #TCQ 1'b1;
end
end
end
endgenerate
always @(posedge clk) begin
if (rst || dqsfound_retry || wrlvl_byte_redo) begin
pi_dqs_found_start <= #TCQ 1'b0;
wrcal_start <= #TCQ 1'b0;
end else begin
if (!pi_dqs_found_done && init_state_r == INIT_RDLVL_STG2_READ)
pi_dqs_found_start <= #TCQ 1'b1;
if (wrcal_start_dly_r[5])
wrcal_start <= #TCQ 1'b1;
end
end // else: !if(rst)
always @(posedge clk)
if (rst)
oclkdelay_calib_start <= #TCQ 1'b0;
else if (oclkdelay_start_dly_r[5])
oclkdelay_calib_start <= #TCQ 1'b1;
always @(posedge clk)
if (rst)
pi_dqs_found_done_r1 <= #TCQ 1'b0;
else
pi_dqs_found_done_r1 <= #TCQ pi_dqs_found_done;
always @(posedge clk)
wrlvl_final_r <= #TCQ wrlvl_final;
// Reset IN_FIFO after final write leveling to make sure the FIFO
// pointers are initialized
always @(posedge clk)
if (rst || (init_state_r == INIT_WRCAL_WRITE) || (init_state_r == INIT_REFRESH))
wrlvl_final_if_rst <= #TCQ 1'b0;
else if (wrlvl_done_r && //(wrlvl_final_r && wrlvl_done_r &&
(init_state_r == INIT_WRLVL_LOAD_MR2))
wrlvl_final_if_rst <= #TCQ 1'b1;
// Constantly enable DQS while write leveling is enabled in the memory
// This is more to get rid of warnings in simulation, can later change
// this code to only enable WRLVL_ACTIVE when WRLVL_START is asserted
always @(posedge clk)
if (rst ||
((init_state_r1 != INIT_WRLVL_START) &&
(init_state_r == INIT_WRLVL_START)))
wrlvl_odt_ctl <= #TCQ 1'b0;
else if (wrlvl_rank_done && ~wrlvl_rank_done_r1)
wrlvl_odt_ctl <= #TCQ 1'b1;
generate
if (nCK_PER_CLK == 4) begin: en_cnt_div4
always @ (posedge clk)
if (rst)
enable_wrlvl_cnt <= #TCQ 5'd0;
else if ((init_state_r == INIT_WRLVL_START) ||
(wrlvl_odt && (enable_wrlvl_cnt == 5'd0)))
enable_wrlvl_cnt <= #TCQ 5'd12;
else if ((enable_wrlvl_cnt > 5'd0) && ~(phy_ctl_full || phy_cmd_full))
enable_wrlvl_cnt <= #TCQ enable_wrlvl_cnt - 1;
// ODT stays asserted as long as write_calib
// signal is asserted
always @(posedge clk)
if (rst || wrlvl_odt_ctl)
wrlvl_odt <= #TCQ 1'b0;
else if (enable_wrlvl_cnt == 5'd1)
wrlvl_odt <= #TCQ 1'b1;
end else begin: en_cnt_div2
always @ (posedge clk)
if (rst)
enable_wrlvl_cnt <= #TCQ 5'd0;
else if ((init_state_r == INIT_WRLVL_START) ||
(wrlvl_odt && (enable_wrlvl_cnt == 5'd0)))
enable_wrlvl_cnt <= #TCQ 5'd21;
else if ((enable_wrlvl_cnt > 5'd0) && ~(phy_ctl_full || phy_cmd_full))
enable_wrlvl_cnt <= #TCQ enable_wrlvl_cnt - 1;
// ODT stays asserted as long as write_calib
// signal is asserted
always @(posedge clk)
if (rst || wrlvl_odt_ctl)
wrlvl_odt <= #TCQ 1'b0;
else if (enable_wrlvl_cnt == 5'd1)
wrlvl_odt <= #TCQ 1'b1;
end
endgenerate
always @(posedge clk)
if (rst || wrlvl_rank_done || done_dqs_tap_inc)
wrlvl_active <= #TCQ 1'b0;
else if ((enable_wrlvl_cnt == 5'd1) && wrlvl_odt && !wrlvl_active)
wrlvl_active <= #TCQ 1'b1;
// signal used to assert DQS for write leveling.
// the DQS will be asserted once every 16 clock cycles.
always @(posedge clk)begin
if(rst || (enable_wrlvl_cnt != 5'd1)) begin
wr_level_dqs_asrt <= #TCQ 1'd0;
end else if ((enable_wrlvl_cnt == 5'd1) && (wrlvl_active_r1)) begin
wr_level_dqs_asrt <= #TCQ 1'd1;
end
end
always @ (posedge clk) begin
if (rst || (wrlvl_done_r && ~wrlvl_done_r1))
dqs_asrt_cnt <= #TCQ 2'd0;
else if (wr_level_dqs_asrt && dqs_asrt_cnt != 2'd3)
dqs_asrt_cnt <= #TCQ (dqs_asrt_cnt + 1);
end
always @ (posedge clk) begin
if (rst || ~wrlvl_active)
wr_lvl_start <= #TCQ 1'd0;
else if (dqs_asrt_cnt == 2'd3)
wr_lvl_start <= #TCQ 1'd1;
end
always @(posedge clk) begin
if (rst)
wl_sm_start <= #TCQ 1'b0;
else
wl_sm_start <= #TCQ wr_level_dqs_asrt_r1;
end
always @(posedge clk) begin
wrlvl_active_r1 <= #TCQ wrlvl_active;
wr_level_dqs_asrt_r1 <= #TCQ wr_level_dqs_asrt;
wrlvl_done_r <= #TCQ wrlvl_done;
wrlvl_done_r1 <= #TCQ wrlvl_done_r;
wrlvl_rank_done_r1 <= #TCQ wrlvl_rank_done;
wrlvl_rank_done_r2 <= #TCQ wrlvl_rank_done_r1;
wrlvl_rank_done_r3 <= #TCQ wrlvl_rank_done_r2;
wrlvl_rank_done_r4 <= #TCQ wrlvl_rank_done_r3;
wrlvl_rank_done_r5 <= #TCQ wrlvl_rank_done_r4;
wrlvl_rank_done_r6 <= #TCQ wrlvl_rank_done_r5;
wrlvl_rank_done_r7 <= #TCQ wrlvl_rank_done_r6;
end
always @ (posedge clk) begin
//if (rst)
wrlvl_rank_cntr <= #TCQ 3'd0;
//else if (wrlvl_rank_done)
// wrlvl_rank_cntr <= #TCQ wrlvl_rank_cntr + 1'b1;
end
//*****************************************************************
// Precharge request logic - those calibration logic blocks
// that require greater than tRAS(max) to finish must break up
// their calibration into smaller units of time, with precharges
// issued in between. This is done using the XXX_PRECH_REQ and
// PRECH_DONE handshaking between PHY_INIT and those blocks
//*****************************************************************
// Shared request from multiple sources
assign prech_req = oclk_prech_req | rdlvl_prech_req | wrcal_prech_req | prbs_rdlvl_prech_req |
(dqs_found_prech_req & (init_state_r == INIT_RDLVL_STG2_READ_WAIT));
// Handshaking logic to force precharge during read leveling, and to
// notify read leveling logic when precharge has been initiated and
// it's okay to proceed with leveling again
always @(posedge clk)
if (rst) begin
prech_req_r <= #TCQ 1'b0;
prech_req_posedge_r <= #TCQ 1'b0;
prech_pending_r <= #TCQ 1'b0;
end else begin
prech_req_r <= #TCQ prech_req;
prech_req_posedge_r <= #TCQ prech_req & ~prech_req_r;
if (prech_req_posedge_r)
prech_pending_r <= #TCQ 1'b1;
// Clear after we've finished with the precharge and have
// returned to issuing read leveling calibration reads
else if (prech_done_pre)
prech_pending_r <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst || prech_done_r3)
mask_lim_done <= #TCQ 1'b0;
else if (prech_pending_r)
mask_lim_done <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst || prbs_rdlvl_done_r3)
complex_mask_lim_done <= #TCQ 1'b0;
else if (~prbs_rdlvl_done && complex_oclkdelay_calib_start_int)
complex_mask_lim_done <= #TCQ 1'b1;
end
//Complex oclkdelay calibrration
//***************************************************************************
// Various timing counters
//***************************************************************************
//*****************************************************************
// Generic delay for various states that require it (e.g. for turnaround
// between read and write). Make this a sufficiently large number of clock
// cycles to cover all possible frequencies and memory components)
// Requirements for this counter:
// 1. Greater than tMRD
// 2. tRFC (refresh-active) for DDR2
// 3. (list the other requirements, slacker...)
//*****************************************************************
always @(posedge clk) begin
case (init_state_r)
INIT_LOAD_MR_WAIT,
INIT_WRLVL_LOAD_MR_WAIT,
INIT_WRLVL_LOAD_MR2_WAIT,
INIT_MPR_WAIT,
INIT_MPR_DISABLE_PREWAIT,
INIT_MPR_DISABLE_WAIT,
INIT_OCLKDELAY_ACT_WAIT,
INIT_OCLKDELAY_WRITE_WAIT,
INIT_RDLVL_ACT_WAIT,
INIT_RDLVL_STG1_WRITE_READ,
INIT_RDLVL_STG2_READ_WAIT,
INIT_WRCAL_ACT_WAIT,
INIT_WRCAL_WRITE_READ,
INIT_WRCAL_READ_WAIT,
INIT_PRECHARGE_PREWAIT,
INIT_PRECHARGE_WAIT,
INIT_DDR2_PRECHARGE_WAIT,
INIT_REG_WRITE_WAIT,
INIT_REFRESH_WAIT,
INIT_REFRESH_RNK2_WAIT: begin
if (phy_ctl_full || phy_cmd_full)
cnt_cmd_r <= #TCQ cnt_cmd_r;
else
cnt_cmd_r <= #TCQ cnt_cmd_r + 1;
end
INIT_WRLVL_WAIT:
cnt_cmd_r <= #TCQ 'b0;
default:
cnt_cmd_r <= #TCQ 'b0;
endcase
end
// pulse when count reaches terminal count
always @(posedge clk)
cnt_cmd_done_r <= #TCQ (cnt_cmd_r == CNTNEXT_CMD);
// For ODT deassertion - hold throughout post read/write wait stage, but
// deassert before next command. The post read/write stage is very long, so
// we simply address the longest case here plus some margin.
always @(posedge clk)
cnt_cmd_done_m7_r <= #TCQ (cnt_cmd_r == (CNTNEXT_CMD - 7));
//************************************************************************
// Added to support PO fine delay inc when TG errors
always @(posedge clk) begin
case (init_state_r)
INIT_WRCAL_READ_WAIT: begin
if (phy_ctl_full || phy_cmd_full)
cnt_wait <= #TCQ cnt_wait;
else
cnt_wait <= #TCQ cnt_wait + 1;
end
default:
cnt_wait <= #TCQ 'b0;
endcase
end
always @(posedge clk)
cnt_wrcal_rd <= #TCQ (cnt_wait == 'd4);
always @(posedge clk) begin
if (rst || ~temp_wrcal_done)
temp_lmr_done <= #TCQ 1'b0;
else if (temp_wrcal_done && (init_state_r == INIT_LOAD_MR))
temp_lmr_done <= #TCQ 1'b1;
end
always @(posedge clk)
temp_wrcal_done_r <= #TCQ temp_wrcal_done;
always @(posedge clk)
if (rst) begin
tg_timer_go <= #TCQ 1'b0;
end else if ((PRE_REV3ES == "ON") && temp_wrcal_done && temp_lmr_done &&
(init_state_r == INIT_WRCAL_READ_WAIT)) begin
tg_timer_go <= #TCQ 1'b1;
end else begin
tg_timer_go <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst || (temp_wrcal_done && ~temp_wrcal_done_r) ||
(init_state_r == INIT_PRECHARGE_PREWAIT))
tg_timer <= #TCQ 'd0;
else if ((pi_phaselock_timer == PHASELOCKED_TIMEOUT) &&
tg_timer_go &&
(tg_timer != TG_TIMER_TIMEOUT))
tg_timer <= #TCQ tg_timer + 1;
end
always @(posedge clk) begin
if (rst)
tg_timer_done <= #TCQ 1'b0;
else if (tg_timer == TG_TIMER_TIMEOUT)
tg_timer_done <= #TCQ 1'b1;
else
tg_timer_done <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst)
no_rst_tg_mc <= #TCQ 1'b0;
else if ((init_state_r == INIT_WRCAL_ACT) && wrcal_read_req)
no_rst_tg_mc <= #TCQ 1'b1;
else
no_rst_tg_mc <= #TCQ 1'b0;
end
//************************************************************************
always @(posedge clk) begin
if (rst)
detect_pi_found_dqs <= #TCQ 1'b0;
else if ((cnt_cmd_r == 7'b0111111) &&
(init_state_r == INIT_RDLVL_STG2_READ_WAIT))
detect_pi_found_dqs <= #TCQ 1'b1;
else
detect_pi_found_dqs <= #TCQ 1'b0;
end
//*****************************************************************
// Initial delay after power-on for RESET, CKE
// NOTE: Could reduce power consumption by turning off these counters
// after initial power-up (at expense of more logic)
// NOTE: Likely can combine multiple counters into single counter
//*****************************************************************
// Create divided by 1024 version of clock
always @(posedge clk)
if (rst) begin
cnt_pwron_ce_r <= #TCQ 10'h000;
pwron_ce_r <= #TCQ 1'b0;
end else begin
cnt_pwron_ce_r <= #TCQ cnt_pwron_ce_r + 1;
pwron_ce_r <= #TCQ (cnt_pwron_ce_r == 10'h3FF);
end
// "Main" power-on counter - ticks every CLKDIV/1024 cycles
always @(posedge clk)
if (rst)
cnt_pwron_r <= #TCQ 'b0;
else if (pwron_ce_r)
cnt_pwron_r <= #TCQ cnt_pwron_r + 1;
always @(posedge clk)
if (rst || ~phy_ctl_ready) begin
cnt_pwron_reset_done_r <= #TCQ 1'b0;
cnt_pwron_cke_done_r <= #TCQ 1'b0;
end else begin
// skip power-up count for simulation purposes only
if ((SIM_INIT_OPTION == "SKIP_PU_DLY") ||
(SIM_INIT_OPTION == "SKIP_INIT")) begin
cnt_pwron_reset_done_r <= #TCQ 1'b1;
cnt_pwron_cke_done_r <= #TCQ 1'b1;
end else begin
// otherwise, create latched version of done signal for RESET, CKE
if (DRAM_TYPE == "DDR3") begin
if (!cnt_pwron_reset_done_r)
cnt_pwron_reset_done_r
<= #TCQ (cnt_pwron_r == PWRON_RESET_DELAY_CNT);
if (!cnt_pwron_cke_done_r)
cnt_pwron_cke_done_r
<= #TCQ (cnt_pwron_r == PWRON_CKE_DELAY_CNT);
end else begin // DDR2
cnt_pwron_reset_done_r <= #TCQ 1'b1; // not needed
if (!cnt_pwron_cke_done_r)
cnt_pwron_cke_done_r
<= #TCQ (cnt_pwron_r == PWRON_CKE_DELAY_CNT);
end
end
end // else: !if(rst || ~phy_ctl_ready)
always @(posedge clk)
cnt_pwron_cke_done_r1 <= #TCQ cnt_pwron_cke_done_r;
// Keep RESET asserted and CKE deasserted until after power-on delay
always @(posedge clk or posedge rst) begin
if (rst)
phy_reset_n <= #TCQ 1'b0;
else
phy_reset_n <= #TCQ cnt_pwron_reset_done_r;
// phy_cke <= #TCQ {CKE_WIDTH{cnt_pwron_cke_done_r}};
end
//*****************************************************************
// Counter for tXPR (pronouned "Tax-Payer") - wait time after
// CKE deassertion before first MRS command can be asserted
//*****************************************************************
always @(posedge clk)
if (!cnt_pwron_cke_done_r) begin
cnt_txpr_r <= #TCQ 'b0;
cnt_txpr_done_r <= #TCQ 1'b0;
end else begin
cnt_txpr_r <= #TCQ cnt_txpr_r + 1;
if (!cnt_txpr_done_r)
cnt_txpr_done_r <= #TCQ (cnt_txpr_r == TXPR_DELAY_CNT);
end
//*****************************************************************
// Counter for the initial 400ns wait for issuing precharge all
// command after CKE assertion. Only for DDR2.
//*****************************************************************
always @(posedge clk)
if (!cnt_pwron_cke_done_r) begin
cnt_init_pre_wait_r <= #TCQ 'b0;
cnt_init_pre_wait_done_r <= #TCQ 1'b0;
end else begin
cnt_init_pre_wait_r <= #TCQ cnt_init_pre_wait_r + 1;
if (!cnt_init_pre_wait_done_r)
cnt_init_pre_wait_done_r
<= #TCQ (cnt_init_pre_wait_r >= DDR2_INIT_PRE_CNT);
end
//*****************************************************************
// Wait for both DLL to lock (tDLLK) and ZQ calibration to finish
// (tZQINIT). Both take the same amount of time (512*tCK)
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_ZQCL) begin
cnt_dllk_zqinit_r <= #TCQ 'b0;
cnt_dllk_zqinit_done_r <= #TCQ 1'b0;
end else if (~(phy_ctl_full || phy_cmd_full)) begin
cnt_dllk_zqinit_r <= #TCQ cnt_dllk_zqinit_r + 1;
if (!cnt_dllk_zqinit_done_r)
cnt_dllk_zqinit_done_r
<= #TCQ (cnt_dllk_zqinit_r == TDLLK_TZQINIT_DELAY_CNT);
end
//*****************************************************************
// Keep track of which MRS counter needs to be programmed during
// memory initialization
// The counter and the done signal are reset an additional time
// for DDR2. The same signals are used for the additional DDR2
// initialization sequence.
//*****************************************************************
always @(posedge clk)
if ((init_state_r == INIT_IDLE)||
((init_state_r == INIT_REFRESH)
&& (~mem_init_done_r))) begin
cnt_init_mr_r <= #TCQ 'b0;
cnt_init_mr_done_r <= #TCQ 1'b0;
end else if (init_state_r == INIT_LOAD_MR) begin
cnt_init_mr_r <= #TCQ cnt_init_mr_r + 1;
cnt_init_mr_done_r <= #TCQ (cnt_init_mr_r == INIT_CNT_MR_DONE);
end
//*****************************************************************
// Flag to tell if the first precharge for DDR2 init sequence is
// done
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE)
ddr2_pre_flag_r<= #TCQ 'b0;
else if (init_state_r == INIT_LOAD_MR)
ddr2_pre_flag_r<= #TCQ 1'b1;
// reset the flag for multi rank case
else if ((ddr2_refresh_flag_r) &&
(init_state_r == INIT_LOAD_MR_WAIT)&&
(cnt_cmd_done_r) && (cnt_init_mr_done_r))
ddr2_pre_flag_r <= #TCQ 'b0;
//*****************************************************************
// Flag to tell if the refresh stat for DDR2 init sequence is
// reached
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE)
ddr2_refresh_flag_r<= #TCQ 'b0;
else if ((init_state_r == INIT_REFRESH) && (~mem_init_done_r))
// reset the flag for multi rank case
ddr2_refresh_flag_r<= #TCQ 1'b1;
else if ((ddr2_refresh_flag_r) &&
(init_state_r == INIT_LOAD_MR_WAIT)&&
(cnt_cmd_done_r) && (cnt_init_mr_done_r))
ddr2_refresh_flag_r <= #TCQ 'b0;
//*****************************************************************
// Keep track of the number of auto refreshes for DDR2
// initialization. The spec asks for a minimum of two refreshes.
// Four refreshes are performed here. The two extra refreshes is to
// account for the 200 clock cycle wait between step h and l.
// Without the two extra refreshes we would have to have a
// wait state.
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE) begin
cnt_init_af_r <= #TCQ 'b0;
cnt_init_af_done_r <= #TCQ 1'b0;
end else if ((init_state_r == INIT_REFRESH) && (~mem_init_done_r))begin
cnt_init_af_r <= #TCQ cnt_init_af_r + 1;
cnt_init_af_done_r <= #TCQ (cnt_init_af_r == 2'b11);
end
//*****************************************************************
// Keep track of the register control word programming for
// DDR3 RDIMM
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE)
reg_ctrl_cnt_r <= #TCQ 'b0;
else if (init_state_r == INIT_REG_WRITE)
reg_ctrl_cnt_r <= #TCQ reg_ctrl_cnt_r + 1;
generate
if (RANKS < 2) begin: one_rank
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done ||
(complex_byte_rd_done) || prbs_rdlvl_done_pulse )
stg1_wr_done <= #TCQ 1'b0;
else if (init_state_r == INIT_RDLVL_STG1_WRITE_READ)
stg1_wr_done <= #TCQ 1'b1;
end else begin: two_ranks
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done ||
(complex_byte_rd_done) || prbs_rdlvl_done_pulse ||
(rdlvl_stg1_rank_done ))
stg1_wr_done <= #TCQ 1'b0;
else if (init_state_r == INIT_RDLVL_STG1_WRITE_READ)
stg1_wr_done <= #TCQ 1'b1;
end
endgenerate
always @(posedge clk)
if (rst)
rnk_ref_cnt <= #TCQ 1'b0;
else if (stg1_wr_done &&
(init_state_r == INIT_REFRESH_WAIT) && cnt_cmd_done_r)
rnk_ref_cnt <= #TCQ ~rnk_ref_cnt;
always @(posedge clk)
if (rst || (init_state_r == INIT_MPR_RDEN) || (init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) || (init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) || (init_state_r ==INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT))
num_refresh <= #TCQ 'd0;
else if ((init_state_r == INIT_REFRESH) &&
(~pi_dqs_found_done || ((DRAM_TYPE == "DDR3") && ~oclkdelay_calib_done) ||
(rdlvl_stg1_done && ~prbs_rdlvl_done) ||
(prbs_rdlvl_done && ~complex_oclkdelay_calib_done) ||
((CLK_PERIOD/nCK_PER_CLK <= 2500) && wrcal_done && ~rdlvl_stg1_done) ||
((CLK_PERIOD/nCK_PER_CLK > 2500) && wrlvl_done_r1 && ~rdlvl_stg1_done)))
num_refresh <= #TCQ num_refresh + 1;
//***************************************************************************
// Initialization state machine
//***************************************************************************
//*****************************************************************
// Next-state logic
//*****************************************************************
always @(posedge clk)
if (rst)begin
init_state_r <= #TCQ INIT_IDLE;
init_state_r1 <= #TCQ INIT_IDLE;
end else begin
init_state_r <= #TCQ init_next_state;
init_state_r1 <= #TCQ init_state_r;
end
always @(*) begin
init_next_state = init_state_r;
(* full_case, parallel_case *) case (init_state_r)
//*******************************************************
// DRAM initialization
//*******************************************************
// Initial state - wait for:
// 1. Power-on delays to pass
// 2. PHY Control Block to assert phy_ctl_ready
// 3. PHY Control FIFO must not be FULL
// 4. Read path initialization to finish
INIT_IDLE:
if (cnt_pwron_cke_done_r && phy_ctl_ready && ck_addr_cmd_delay_done && delay_incdec_done
&& ~(phy_ctl_full || phy_cmd_full) ) begin
// If skipping memory initialization (simulation only)
if (SIM_INIT_OPTION == "SKIP_INIT")
//if (WRLVL == "ON")
// Proceed to write leveling
// init_next_state = INIT_WRLVL_START;
//else //if (SIM_CAL_OPTION != "SKIP_CAL")
// Proceed to Phaser_In phase lock
init_next_state = INIT_RDLVL_ACT;
// else
// Skip read leveling
//init_next_state = INIT_DONE;
else
init_next_state = INIT_WAIT_CKE_EXIT;
end
// Wait minimum of Reset CKE exit time (tXPR = max(tXS,
INIT_WAIT_CKE_EXIT:
if ((cnt_txpr_done_r) && (DRAM_TYPE == "DDR3")
&& ~(phy_ctl_full || phy_cmd_full)) begin
if((REG_CTRL == "ON") && ((nCS_PER_RANK > 1) ||
(RANKS > 1)))
//register write for reg dimm. Some register chips
// have the register chip in a pre-programmed state
// in that case the nCS_PER_RANK == 1 && RANKS == 1
init_next_state = INIT_REG_WRITE;
else
// Load mode register - this state is repeated multiple times
init_next_state = INIT_LOAD_MR;
end else if ((cnt_init_pre_wait_done_r) && (DRAM_TYPE == "DDR2")
&& ~(phy_ctl_full || phy_cmd_full))
// DDR2 start with a precharge all command
init_next_state = INIT_DDR2_PRECHARGE;
INIT_REG_WRITE:
init_next_state = INIT_REG_WRITE_WAIT;
INIT_REG_WRITE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if(reg_ctrl_cnt_r == 4'd8)
init_next_state = INIT_LOAD_MR;
else
init_next_state = INIT_REG_WRITE;
end
INIT_LOAD_MR:
init_next_state = INIT_LOAD_MR_WAIT;
// After loading MR, wait at least tMRD
INIT_LOAD_MR_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
// If finished loading all mode registers, proceed to next step
if (prbs_rdlvl_done && pi_dqs_found_done && rdlvl_stg1_done)
// for ddr3 when the correct burst length is writtern at end
init_next_state = INIT_PRECHARGE;
else if (~wrcal_done && temp_lmr_done)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (cnt_init_mr_done_r)begin
if(DRAM_TYPE == "DDR3")
init_next_state = INIT_ZQCL;
else begin //DDR2
if(ddr2_refresh_flag_r)begin
// memory initialization per rank for multi-rank case
if (!mem_init_done_r && (chip_cnt_r <= RANKS-1))
init_next_state = INIT_DDR2_MULTI_RANK;
else
init_next_state = INIT_RDLVL_ACT;
// ddr2 initialization done.load mode state after refresh
end else
init_next_state = INIT_DDR2_PRECHARGE;
end
end else
init_next_state = INIT_LOAD_MR;
end
// DDR2 multi rank transition state
INIT_DDR2_MULTI_RANK:
init_next_state = INIT_DDR2_MULTI_RANK_WAIT;
INIT_DDR2_MULTI_RANK_WAIT:
init_next_state = INIT_DDR2_PRECHARGE;
// Initial ZQ calibration
INIT_ZQCL:
init_next_state = INIT_WAIT_DLLK_ZQINIT;
// Wait until both DLL have locked, and ZQ calibration done
INIT_WAIT_DLLK_ZQINIT:
if (cnt_dllk_zqinit_done_r && ~(phy_ctl_full || phy_cmd_full))
// memory initialization per rank for multi-rank case
if (!mem_init_done_r && (chip_cnt_r <= RANKS-1))
init_next_state = INIT_LOAD_MR;
//else if (WRLVL == "ON")
// init_next_state = INIT_WRLVL_START;
else
// skip write-leveling (e.g. for DDR2 interface)
init_next_state = INIT_RDLVL_ACT;
// Initial precharge for DDR2
INIT_DDR2_PRECHARGE:
init_next_state = INIT_DDR2_PRECHARGE_WAIT;
INIT_DDR2_PRECHARGE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if (ddr2_pre_flag_r)
init_next_state = INIT_REFRESH;
else // from precharge state initially go to load mode
init_next_state = INIT_LOAD_MR;
end
INIT_REFRESH:
if ((RANKS == 2) && (chip_cnt_r == RANKS - 1))
init_next_state = INIT_REFRESH_RNK2_WAIT;
else
init_next_state = INIT_REFRESH_WAIT;
INIT_REFRESH_RNK2_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_PRECHARGE;
INIT_REFRESH_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))begin
if(cnt_init_af_done_r && (~mem_init_done_r))
// go to lm state as part of DDR2 init sequence
init_next_state = INIT_LOAD_MR;
// Go to state to issue back-to-back writes during limit check and centering
else if (~oclkdelay_calib_done && (mpr_last_byte_done || mpr_rdlvl_done) && (DRAM_TYPE == "DDR3")) begin
if (num_refresh == 'd8)
init_next_state = INIT_OCAL_CENTER_ACT;
else
init_next_state = INIT_REFRESH;
end else if(rdlvl_stg1_done && oclkdelay_center_calib_done &&
complex_oclkdelay_calib_done && ~wrlvl_done_r1 && (WRLVL == "ON"))
init_next_state = INIT_WRLVL_START;
else if (pi_dqs_found_done && ~wrlvl_done_r1 && ~wrlvl_final && ~wrlvl_byte_redo && (WRLVL == "ON"))
init_next_state = INIT_WRLVL_START;
else if ((((prbs_last_byte_done_r || prbs_rdlvl_done) && ~complex_oclkdelay_calib_done
&& pi_dqs_found_done) && (WRLVL == "ON")) //&& rdlvl_stg1_done // changed for new algo 3/26
&& mem_init_done_r) begin
if (num_refresh == 'd8) begin
if (BYPASS_COMPLEX_OCAL == "FALSE")
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else
init_next_state = INIT_WRCAL_ACT;
end else
init_next_state = INIT_REFRESH;
end else if (~pi_dqs_found_done ||
(rdlvl_stg1_done && ~prbs_rdlvl_done && ~complex_oclkdelay_calib_done) ||
((CLK_PERIOD/nCK_PER_CLK <= 2500) && wrcal_done && ~rdlvl_stg1_done) ||
((CLK_PERIOD/nCK_PER_CLK > 2500) && wrlvl_done_r1 && ~rdlvl_stg1_done)) begin
if (num_refresh == 'd8)
init_next_state = INIT_RDLVL_ACT;
else
init_next_state = INIT_REFRESH;
end else if ((~wrcal_done && wrlvl_byte_redo)&& (DRAM_TYPE == "DDR3")
&& (CLK_PERIOD/nCK_PER_CLK > 2500))
init_next_state = INIT_WRLVL_LOAD_MR2;
else if (((prbs_rdlvl_done && rdlvl_stg1_done && complex_oclkdelay_calib_done && pi_dqs_found_done) && (WRLVL == "ON"))
&& mem_init_done_r && (CLK_PERIOD/nCK_PER_CLK > 2500))
init_next_state = INIT_WRCAL_ACT;
else if (pi_dqs_found_done && (DRAM_TYPE == "DDR3") && ~(mpr_last_byte_done || mpr_rdlvl_done)) begin
if (num_refresh == 'd8)
init_next_state = INIT_MPR_RDEN;
else
init_next_state = INIT_REFRESH;
end else if (((oclkdelay_calib_done && wrlvl_final && ~wrlvl_done_r1) || // changed for new algo 3/25
(~wrcal_done && wrlvl_byte_redo)) && (DRAM_TYPE == "DDR3"))
init_next_state = INIT_WRLVL_LOAD_MR2;
else if ((~wrcal_done && (WRLVL == "ON") && (CLK_PERIOD/nCK_PER_CLK <= 2500))
&& pi_dqs_found_done)
init_next_state = INIT_WRCAL_ACT;
else if (mem_init_done_r) begin
if (RANKS < 2)
init_next_state = INIT_RDLVL_ACT;
else if (stg1_wr_done && ~rnk_ref_cnt && ~rdlvl_stg1_done)
init_next_state = INIT_PRECHARGE;
else
init_next_state = INIT_RDLVL_ACT;
end else // to DDR2 init state as part of DDR2 init sequence
init_next_state = INIT_REFRESH;
end
//******************************************************
// Write Leveling
//*******************************************************
// Enable write leveling in MR1 and start write leveling
// for current rank
INIT_WRLVL_START:
init_next_state = INIT_WRLVL_WAIT;
// Wait for both MR load and write leveling to complete
// (write leveling should take much longer than MR load..)
INIT_WRLVL_WAIT:
if (wrlvl_rank_done_r7 && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_WRLVL_LOAD_MR;
// Disable write leveling in MR1 for current rank
INIT_WRLVL_LOAD_MR:
init_next_state = INIT_WRLVL_LOAD_MR_WAIT;
INIT_WRLVL_LOAD_MR_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_WRLVL_LOAD_MR2;
// Load MR2 to set ODT: Dynamic ODT for single rank case
// And ODTs for multi-rank case as well
INIT_WRLVL_LOAD_MR2:
init_next_state = INIT_WRLVL_LOAD_MR2_WAIT;
// Wait tMRD before proceeding
INIT_WRLVL_LOAD_MR2_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
//if (wrlvl_byte_done)
// init_next_state = INIT_PRECHARGE_PREWAIT;
// else if ((RANKS == 2) && wrlvl_rank_done_r2)
// init_next_state = INIT_WRLVL_LOAD_MR2_WAIT;
if (~wrlvl_done_r1)
init_next_state = INIT_WRLVL_START;
else if (SIM_CAL_OPTION == "SKIP_CAL")
// If skip rdlvl, then we're done
init_next_state = INIT_DONE;
else
// Otherwise, proceed to read leveling
//init_next_state = INIT_RDLVL_ACT;
init_next_state = INIT_PRECHARGE_PREWAIT;
end
//*******************************************************
// Read Leveling
//*******************************************************
// single row activate. All subsequent read leveling writes and
// read will take place in this row
INIT_RDLVL_ACT:
init_next_state = INIT_RDLVL_ACT_WAIT;
// hang out for awhile before issuing subsequent column commands
// it's also possible to reach this state at various points
// during read leveling - determine what the current stage is
INIT_RDLVL_ACT_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
// Just finished an activate. Now either write, read, or precharge
// depending on where we are in the training sequence
if (!pi_calib_done_r1)
init_next_state = INIT_PI_PHASELOCK_READS;
else if (!pi_dqs_found_done)
// (!pi_dqs_found_start || pi_dqs_found_rank_done))
init_next_state = INIT_RDLVL_STG2_READ;
else if (~wrcal_done && (WRLVL == "ON") && (CLK_PERIOD/nCK_PER_CLK <= 2500))
init_next_state = INIT_WRCAL_ACT_WAIT;
else if ((!rdlvl_stg1_done && ~stg1_wr_done && ~rdlvl_last_byte_done) ||
(!prbs_rdlvl_done && ~stg1_wr_done && ~prbs_last_byte_done)) begin
// Added to avoid rdlvl_stg1 write data pattern at the start of PRBS rdlvl
if (!prbs_rdlvl_done && ~stg1_wr_done && rdlvl_last_byte_done)
init_next_state = INIT_RDLVL_ACT_WAIT;
else
init_next_state = INIT_RDLVL_STG1_WRITE;
end else if ((!rdlvl_stg1_done && rdlvl_stg1_start_int) || !prbs_rdlvl_done) begin
if (rdlvl_last_byte_done || prbs_last_byte_done)
// Added to avoid extra reads at the end of read leveling
init_next_state = INIT_RDLVL_ACT_WAIT;
else begin
// Case 2: If in stage 1, and just precharged after training
// previous byte, then continue reading
if (rdlvl_stg1_done)
init_next_state = INIT_RDLVL_STG1_WRITE_READ;
else
init_next_state = INIT_RDLVL_STG1_READ;
end
end else if ((prbs_rdlvl_done && rdlvl_stg1_done && (RANKS == 1)) && (WRLVL == "ON") &&
(CLK_PERIOD/nCK_PER_CLK > 2500))
init_next_state = INIT_WRCAL_ACT_WAIT;
else
// Otherwise, if we're finished with calibration, then precharge
// the row - silly, because we just opened it - possible to take
// this out by adding logic to avoid the ACT in first place. Make
// sure that cnt_cmd_done will handle tRAS(min)
init_next_state = INIT_PRECHARGE_PREWAIT;
end
//**************************************************
// Back-to-back reads for Phaser_IN Phase locking
// DQS to FREQ_REF clock
//**************************************************
INIT_PI_PHASELOCK_READS:
if (pi_phase_locked_all_r3 && ~pi_phase_locked_all_r4)
init_next_state = INIT_PRECHARGE_PREWAIT;
//*********************************************
// Stage 1 read-leveling (write and continuous read)
//*********************************************
// Write training pattern for stage 1
// PRBS pattern of TBD length
INIT_RDLVL_STG1_WRITE:
// 4:1 DDR3 BL8 will require all 8 words in 1 DIV4 clock cycle
// 2:1 DDR2/DDR3 BL8 will require 2 DIV2 clock cycles for 8 words
// 2:1 DDR2 BL4 will require 1 DIV2 clock cycle for 4 words
// An entire row worth of writes issued before proceeding to reads
// The number of write is (2^column width)/burst length to accomodate
// PRBS pattern for window detection.
//VCCO/VCCAUX write is not done
if ((complex_num_writes_dec == 1) && ~complex_row0_wr_done && prbs_rdlvl_done && rdlvl_stg1_done_r1)
init_next_state = INIT_OCAL_COMPLEX_WRITE_WAIT;
//back to back write from row1
else if (stg1_wr_rd_cnt == 9'd1) begin
if (rdlvl_stg1_done_r1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else
init_next_state = INIT_RDLVL_STG1_WRITE_READ;
end
INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT:
if(read_pause_ext) begin
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
end else begin
if (prech_req_posedge_r || complex_rdlvl_int_ref_req || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15)
//At the end of the byte, it goes to REFRESH
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE;
end
INIT_RDLVL_COMPLEX_PRECHARGE:
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_WAIT;
INIT_RDLVL_COMPLEX_PRECHARGE_WAIT:
if (prech_req_posedge_r || complex_rdlvl_int_ref_req || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15) begin
if (prbs_rdlvl_done || prbs_last_byte_done_r) begin // changed for new algo 3/26
// added condition to ensure that limit starts after rdlvl_stg1_done is asserted in the bypass complex rdlvl mode
if ((~prbs_rdlvl_done && complex_oclkdelay_calib_start_int) || ~lim_done)
init_next_state = INIT_OCAL_CENTER_ACT; //INIT_OCAL_COMPLEX_ACT; // changed for new algo 3/26
else if (lim_done && complex_oclkdelay_calib_start_r2)
init_next_state = INIT_RDLVL_COMPLEX_ACT;
else
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_WAIT;
end else
init_next_state = INIT_RDLVL_COMPLEX_ACT;
end
INIT_RDLVL_COMPLEX_ACT:
init_next_state = INIT_RDLVL_COMPLEX_ACT_WAIT;
INIT_RDLVL_COMPLEX_ACT_WAIT:
if (complex_rdlvl_int_ref_req)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15) begin
if (oclkdelay_center_calib_start)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
else if (stg1_wr_done)
init_next_state = INIT_RDLVL_COMPLEX_READ;
else if (~complex_row1_wr_done)
if (complex_oclkdelay_calib_start_int && complex_ocal_num_samples_done_r) //WAIT for resume signal for write
init_next_state = INIT_OCAL_COMPLEX_RESUME_WAIT;
else
init_next_state = INIT_RDLVL_STG1_WRITE;
else
init_next_state = INIT_RDLVL_STG1_WRITE_READ;
end
// Write-read turnaround
INIT_RDLVL_STG1_WRITE_READ:
if (reset_rd_addr_r1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))begin
if (rdlvl_stg1_done_r1)
init_next_state = INIT_RDLVL_COMPLEX_READ;
else
init_next_state = INIT_RDLVL_STG1_READ;
end
// Continuous read, where interruptible by precharge request from
// calibration logic. Also precharges when stage 1 is complete
// No precharges when reads provided to Phaser_IN for phase locking
// FREQ_REF to read DQS since data integrity is not important.
INIT_RDLVL_STG1_READ:
if (rdlvl_stg1_rank_done || (rdlvl_stg1_done && ~rdlvl_stg1_done_r1) ||
prech_req_posedge_r || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
INIT_RDLVL_COMPLEX_READ:
if (prech_req_posedge_r || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
//For non-back-to-back reads from row0 (VCCO and VCCAUX pattern)
else if (~prbs_rdlvl_done && (complex_num_reads_dec == 1) && ~complex_row0_rd_done)
init_next_state = INIT_RDLVL_COMPLEX_READ_WAIT;
//For back-to-back reads from row1 (ISI pattern)
else if (stg1_wr_rd_cnt == 'd1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
INIT_RDLVL_COMPLEX_READ_WAIT:
if (prech_req_posedge_r || complex_rdlvl_int_ref_req || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (stg1_wr_rd_cnt == 'd1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15)
init_next_state = INIT_RDLVL_COMPLEX_READ;
//*********************************************
// DQSFOUND calibration (set of 4 reads with gaps)
//*********************************************
// Read of training data. Note that Stage 2 is not a constant read,
// instead there is a large gap between each set of back-to-back reads
INIT_RDLVL_STG2_READ:
// 4 read commands issued back-to-back
if (num_reads == 'b1)
init_next_state = INIT_RDLVL_STG2_READ_WAIT;
// Wait before issuing the next set of reads. If a precharge request
// comes in then handle - this can occur after stage 2 calibration is
// completed for a DQS group
INIT_RDLVL_STG2_READ_WAIT:
if (~(phy_ctl_full || phy_cmd_full)) begin
if (pi_dqs_found_rank_done ||
pi_dqs_found_done || prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (cnt_cmd_done_r)
init_next_state = INIT_RDLVL_STG2_READ;
end
//******************************************************************
// MPR Read Leveling for DDR3 OCLK_DELAYED calibration
//******************************************************************
// Issue Load Mode Register 3 command with A[2]=1, A[1:0]=2'b00
// to enable Multi Purpose Register (MPR) Read
INIT_MPR_RDEN:
init_next_state = INIT_MPR_WAIT;
//Wait tMRD, tMOD
INIT_MPR_WAIT:
if (cnt_cmd_done_r) begin
init_next_state = INIT_MPR_READ;
end
// Issue back-to-back read commands to read from MPR with
// Address bus 0x0000 for BL=8. DQ[0] will output the pre-defined
// MPR pattern of 01010101 (Rise0 = 1'b0, Fall0 = 1'b1 ...)
INIT_MPR_READ:
if (mpr_rdlvl_done || mpr_rnk_done || rdlvl_prech_req)
init_next_state = INIT_MPR_DISABLE_PREWAIT;
INIT_MPR_DISABLE_PREWAIT:
if (cnt_cmd_done_r)
init_next_state = INIT_MPR_DISABLE;
// Issue Load Mode Register 3 command with A[2]=0 to disable
// MPR read
INIT_MPR_DISABLE:
init_next_state = INIT_MPR_DISABLE_WAIT;
INIT_MPR_DISABLE_WAIT:
init_next_state = INIT_PRECHARGE_PREWAIT;
//***********************************************************************
// OCLKDELAY Calibration
//***********************************************************************
// This calibration requires single write followed by single read to
// determine the Phaser_Out stage 3 delay required to center write DQS
// in write DQ valid window.
// Single Row Activate command before issuing Write command
INIT_OCLKDELAY_ACT:
init_next_state = INIT_OCLKDELAY_ACT_WAIT;
INIT_OCLKDELAY_ACT_WAIT:
if (cnt_cmd_done_r && ~oclk_prech_req)
init_next_state = INIT_OCLKDELAY_WRITE;
else if (oclkdelay_calib_done || prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
INIT_OCLKDELAY_WRITE:
if (oclk_wr_cnt == 4'd1)
init_next_state = INIT_OCLKDELAY_WRITE_WAIT;
INIT_OCLKDELAY_WRITE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if (oclkdelay_int_ref_req)
init_next_state = INIT_PRECHARGE_PREWAIT;
else
init_next_state = INIT_OCLKDELAY_READ;
end
INIT_OCLKDELAY_READ:
init_next_state = INIT_OCLKDELAY_READ_WAIT;
INIT_OCLKDELAY_READ_WAIT:
if (~(phy_ctl_full || phy_cmd_full)) begin
if ((oclk_calib_resume_level || oclk_calib_resume) && ~oclkdelay_int_ref_req)
init_next_state = INIT_OCLKDELAY_WRITE;
else if (oclkdelay_calib_done || prech_req_posedge_r ||
wrlvl_final || oclkdelay_int_ref_req)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (oclkdelay_center_calib_start)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
end
//*********************************************
// Write calibration
//*********************************************
// single row activate
INIT_WRCAL_ACT:
init_next_state = INIT_WRCAL_ACT_WAIT;
// hang out for awhile before issuing subsequent column command
INIT_WRCAL_ACT_WAIT:
if (cnt_cmd_done_r && ~wrcal_prech_req)
init_next_state = INIT_WRCAL_WRITE;
else if (wrcal_done || prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
// Write training pattern for write calibration
INIT_WRCAL_WRITE:
// Once we've issued enough commands for 8 words - proceed to reads
//if (burst_addr_r == 1'b1)
if (wrcal_wr_cnt == 4'd1)
init_next_state = INIT_WRCAL_WRITE_READ;
// Write-read turnaround
INIT_WRCAL_WRITE_READ:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_WRCAL_READ;
else if (dqsfound_retry)
init_next_state = INIT_RDLVL_STG2_READ_WAIT;
INIT_WRCAL_READ:
if (burst_addr_r == 1'b1)
init_next_state = INIT_WRCAL_READ_WAIT;
INIT_WRCAL_READ_WAIT:
if (~(phy_ctl_full || phy_cmd_full)) begin
if (wrcal_resume_r) begin
if (wrcal_final_chk)
init_next_state = INIT_WRCAL_READ;
else
init_next_state = INIT_WRCAL_WRITE;
end else if (wrcal_done || prech_req_posedge_r || wrcal_act_req ||
// Added to support PO fine delay inc when TG errors
wrlvl_byte_redo || (temp_wrcal_done && ~temp_lmr_done))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (dqsfound_retry)
init_next_state = INIT_RDLVL_STG2_READ_WAIT;
else if (wrcal_read_req && cnt_wrcal_rd)
init_next_state = INIT_WRCAL_MULT_READS;
end
INIT_WRCAL_MULT_READS:
// multiple read commands issued back-to-back
if (wrcal_reads == 'b1)
init_next_state = INIT_WRCAL_READ_WAIT;
//*********************************************
// Handling of precharge during and in between read-level stages
//*********************************************
// Make sure we aren't violating any timing specs by precharging
// immediately
INIT_PRECHARGE_PREWAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_PRECHARGE;
// Initiate precharge
INIT_PRECHARGE:
init_next_state = INIT_PRECHARGE_WAIT;
INIT_PRECHARGE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if ((wrcal_sanity_chk_done && (DRAM_TYPE == "DDR3")) ||
(rdlvl_stg1_done && prbs_rdlvl_done && pi_dqs_found_done &&
(DRAM_TYPE == "DDR2")))
init_next_state = INIT_DONE;
else if ((wrcal_done || (WRLVL == "OFF")) && rdlvl_stg1_done && prbs_rdlvl_done &&
pi_dqs_found_done && complex_oclkdelay_calib_done && wrlvl_done_r1 && ((ddr3_lm_done_r) || (DRAM_TYPE == "DDR2")))
init_next_state = INIT_WRCAL_ACT;
else if ((wrcal_done || (WRLVL == "OFF") || (~wrcal_done && temp_wrcal_done && ~temp_lmr_done))
&& (rdlvl_stg1_done || (~wrcal_done && temp_wrcal_done && ~temp_lmr_done))
&& prbs_rdlvl_done && complex_oclkdelay_calib_done && wrlvl_done_r1 &rdlvl_stg1_done && pi_dqs_found_done) begin
// after all calibration program the correct burst length
init_next_state = INIT_LOAD_MR;
// Added to support PO fine delay inc when TG errors
end else if (~wrcal_done && temp_wrcal_done && temp_lmr_done)
init_next_state = INIT_WRCAL_READ_WAIT;
else if (rdlvl_stg1_done && pi_dqs_found_done && (WRLVL == "ON"))
// If read leveling finished, proceed to write calibration
init_next_state = INIT_REFRESH;
else
// Otherwise, open row for read-leveling purposes
init_next_state = INIT_REFRESH;
end
//*******************************************************
// COMPLEX OCLK calibration - for fragmented write
//*******************************************************
INIT_OCAL_COMPLEX_ACT:
init_next_state = INIT_OCAL_COMPLEX_ACT_WAIT;
INIT_OCAL_COMPLEX_ACT_WAIT:
if (complex_wait_cnt =='d15)
init_next_state = INIT_RDLVL_STG1_WRITE;
INIT_OCAL_COMPLEX_WRITE_WAIT:
if (prech_req_posedge_r || (complex_oclkdelay_calib_done && ~complex_oclkdelay_calib_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (stg1_wr_rd_cnt == 'd1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15)
init_next_state = INIT_RDLVL_STG1_WRITE;
//wait for all srg2/stg3 tap movement is done and go back to write again
INIT_OCAL_COMPLEX_RESUME_WAIT:
if (complex_oclk_calib_resume)
init_next_state = INIT_RDLVL_STG1_WRITE;
else if (complex_oclkdelay_calib_done || complex_ocal_ref_req )
init_next_state = INIT_PRECHARGE_PREWAIT;
//*******************************************************
// OCAL STG3 Centering calibration
//*******************************************************
INIT_OCAL_CENTER_ACT:
init_next_state = INIT_OCAL_CENTER_ACT_WAIT;
INIT_OCAL_CENTER_ACT_WAIT:
if (ocal_act_wait_cnt == 'd15)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
INIT_OCAL_CENTER_WRITE:
if(!oclk_center_write_resume && !lim_wr_req)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
INIT_OCAL_CENTER_WRITE_WAIT:
//if (oclkdelay_center_calib_done || prech_req_posedge_r)
if (prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (lim_done && ~mask_lim_done && ~complex_mask_lim_done && oclkdelay_calib_done && ~oclkdelay_center_calib_start)
init_next_state = INIT_OCAL_COMPLEX_ACT_WAIT;
else if (lim_done && ~mask_lim_done && ~complex_mask_lim_done && ~oclkdelay_center_calib_start)
init_next_state = INIT_OCLKDELAY_READ_WAIT;
else if (oclk_center_write_resume || lim_wr_req)
init_next_state = INIT_OCAL_CENTER_WRITE;
//*******************************************************
// Initialization/Calibration done. Take a long rest, relax
//*******************************************************
INIT_DONE:
init_next_state = INIT_DONE;
endcase
end
//*****************************************************************
// Initialization done signal - asserted before leveling starts
//*****************************************************************
always @(posedge clk)
if (rst)
mem_init_done_r <= #TCQ 1'b0;
else if ((!cnt_dllk_zqinit_done_r &&
(cnt_dllk_zqinit_r == TDLLK_TZQINIT_DELAY_CNT) &&
(chip_cnt_r == RANKS-1) && (DRAM_TYPE == "DDR3"))
|| ( (init_state_r == INIT_LOAD_MR_WAIT) &&
(ddr2_refresh_flag_r) && (chip_cnt_r == RANKS-1)
&& (cnt_init_mr_done_r) && (DRAM_TYPE == "DDR2")))
mem_init_done_r <= #TCQ 1'b1;
//*****************************************************************
// Write Calibration signal to PHY Control Block - asserted before
// Write Leveling starts
//*****************************************************************
//generate
//if (RANKS < 2) begin: ranks_one
always @(posedge clk) begin
if (rst || (done_dqs_tap_inc &&
(init_state_r == INIT_WRLVL_LOAD_MR2)))
write_calib <= #TCQ 1'b0;
else if (wrlvl_active_r1)
write_calib <= #TCQ 1'b1;
end
//end else begin: ranks_two
// always @(posedge clk) begin
// if (rst ||
// ((init_state_r1 == INIT_WRLVL_LOAD_MR_WAIT) &&
// ((wrlvl_rank_done_r2 && (chip_cnt_r == RANKS-1)) ||
// (SIM_CAL_OPTION == "FAST_CAL"))))
// write_calib <= #TCQ 1'b0;
// else if (wrlvl_active_r1)
// write_calib <= #TCQ 1'b1;
// end
//end
//endgenerate
//*****************************************************************
// Read Calibration signal to PHY Control Block - asserted after
// Write Leveling during PHASER_IN phase locking stage.
// Must be de-asserted before Read Leveling
//*****************************************************************
always @(posedge clk) begin
if (rst || pi_calib_done_r1)
read_calib_int <= #TCQ 1'b0;
else if (~pi_calib_done_r1 && (init_state_r == INIT_RDLVL_ACT_WAIT) &&
(cnt_cmd_r == CNTNEXT_CMD))
read_calib_int <= #TCQ 1'b1;
end
always @(posedge clk)
read_calib_r <= #TCQ read_calib_int;
always @(posedge clk) begin
if (rst || pi_calib_done_r1)
read_calib <= #TCQ 1'b0;
else if (~pi_calib_done_r1 && (init_state_r == INIT_PI_PHASELOCK_READS))
read_calib <= #TCQ 1'b1;
end
always @(posedge clk)
if (rst)
pi_calib_done_r <= #TCQ 1'b0;
else if (pi_calib_rank_done_r)// && (chip_cnt_r == RANKS-1))
pi_calib_done_r <= #TCQ 1'b1;
always @(posedge clk)
if (rst)
pi_calib_rank_done_r <= #TCQ 1'b0;
else if (pi_phase_locked_all_r3 && ~pi_phase_locked_all_r4)
pi_calib_rank_done_r <= #TCQ 1'b1;
else
pi_calib_rank_done_r <= #TCQ 1'b0;
always @(posedge clk) begin
if (rst || ((PRE_REV3ES == "ON") && temp_wrcal_done && ~temp_wrcal_done_r))
pi_phaselock_timer <= #TCQ 'd0;
else if (((init_state_r == INIT_PI_PHASELOCK_READS) &&
(pi_phaselock_timer != PHASELOCKED_TIMEOUT)) ||
tg_timer_go)
pi_phaselock_timer <= #TCQ pi_phaselock_timer + 1;
else
pi_phaselock_timer <= #TCQ pi_phaselock_timer;
end
assign pi_phase_locked_err = (pi_phaselock_timer == PHASELOCKED_TIMEOUT) ? 1'b1 : 1'b0;
//*****************************************************************
// DDR3 final burst length programming done. For DDR3 during
// calibration the burst length is fixed to BL8. After calibration
// the correct burst length is programmed.
//*****************************************************************
always @(posedge clk)
if (rst)
ddr3_lm_done_r <= #TCQ 1'b0;
else if ((init_state_r == INIT_LOAD_MR_WAIT) &&
(chip_cnt_r == RANKS-1) && wrcal_done)
ddr3_lm_done_r <= #TCQ 1'b1;
always @(posedge clk) begin
pi_dqs_found_rank_done_r <= #TCQ pi_dqs_found_rank_done;
pi_phase_locked_all_r1 <= #TCQ pi_phase_locked_all;
pi_phase_locked_all_r2 <= #TCQ pi_phase_locked_all_r1;
pi_phase_locked_all_r3 <= #TCQ pi_phase_locked_all_r2;
pi_phase_locked_all_r4 <= #TCQ pi_phase_locked_all_r3;
pi_dqs_found_all_r <= #TCQ pi_dqs_found_done;
pi_calib_done_r1 <= #TCQ pi_calib_done_r;
end
//***************************************************************************
// Logic for deep memory (multi-rank) configurations
//***************************************************************************
// For DDR3 asserted when
generate
if (RANKS < 2) begin: single_rank
always @(posedge clk)
chip_cnt_r <= #TCQ 2'b00;
end else begin: dual_rank
always @(posedge clk)
if (rst ||
// Set chip_cnt_r to 2'b00 after both Ranks are read leveled
(rdlvl_stg1_done && prbs_rdlvl_done && ~wrcal_done) ||
// Set chip_cnt_r to 2'b00 after both Ranks are write leveled
(wrlvl_done_r &&
(init_state_r==INIT_WRLVL_LOAD_MR2_WAIT)))begin
chip_cnt_r <= #TCQ 2'b00;
end else if ((((init_state_r == INIT_WAIT_DLLK_ZQINIT) &&
(cnt_dllk_zqinit_r == TDLLK_TZQINIT_DELAY_CNT)) &&
(DRAM_TYPE == "DDR3")) ||
((init_state_r==INIT_REFRESH_RNK2_WAIT) &&
(cnt_cmd_r=='d36)) ||
//mpr_rnk_done ||
//(rdlvl_stg1_rank_done && ~rdlvl_last_byte_done) ||
//(stg1_wr_done && (init_state_r == INIT_REFRESH) &&
//~(rnk_ref_cnt && rdlvl_last_byte_done)) ||
// Increment chip_cnt_r to issue Refresh to second rank
(~pi_dqs_found_all_r &&
(init_state_r==INIT_PRECHARGE_PREWAIT) &&
(cnt_cmd_r=='d36)) ||
// Increment chip_cnt_r when DQSFOUND done for the Rank
(pi_dqs_found_rank_done && ~pi_dqs_found_rank_done_r) ||
((init_state_r == INIT_LOAD_MR_WAIT)&& cnt_cmd_done_r
&& wrcal_done) ||
((init_state_r == INIT_DDR2_MULTI_RANK)
&& (DRAM_TYPE == "DDR2"))) begin
if ((~mem_init_done_r || ~rdlvl_stg1_done || ~pi_dqs_found_done ||
// condition to increment chip_cnt during
// final burst length programming for DDR3
~pi_calib_done_r || wrcal_done) //~mpr_rdlvl_done ||
&& (chip_cnt_r != RANKS-1))
chip_cnt_r <= #TCQ chip_cnt_r + 1;
else
chip_cnt_r <= #TCQ 2'b00;
end
end
endgenerate
// verilint STARC-2.2.3.3 off
generate
if ((REG_CTRL == "ON") && (RANKS == 1)) begin: DDR3_RDIMM_1rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if (init_state_r == INIT_REG_WRITE) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if(!(CWL_M%2)) begin
phy_int_cs_n[0%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[1%nCK_PER_CLK] <= #TCQ 1'b0;
end else begin
phy_int_cs_n[2%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[3%nCK_PER_CLK] <= #TCQ 1'b0;
end
end else if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) //even CWL
phy_int_cs_n[0] <= #TCQ 1'b0;
else // odd CWL
phy_int_cs_n[1*nCS_PER_RANK] <= #TCQ 1'b0;
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end
end else if (RANKS == 1) begin: DDR3_1rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) begin //even CWL
for (n = 0; n < nCS_PER_RANK; n = n + 1) begin
phy_int_cs_n[n] <= #TCQ 1'b0;
end
end else begin //odd CWL
for (p = nCS_PER_RANK; p < 2*nCS_PER_RANK; p = p + 1) begin
phy_int_cs_n[p] <= #TCQ 1'b0;
end
end
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end
end else if ((REG_CTRL == "ON") && (RANKS == 2)) begin: DDR3_2rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if (init_state_r == INIT_REG_WRITE) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if(!(CWL_M%2)) begin
phy_int_cs_n[0%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[1%nCK_PER_CLK] <= #TCQ 1'b0;
end else begin
phy_int_cs_n[2%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[3%nCK_PER_CLK] <= #TCQ 1'b0;
end
end else begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
case (chip_cnt_r)
2'b00:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) //even CWL
phy_int_cs_n[0] <= #TCQ 1'b0;
else // odd CWL
phy_int_cs_n[1*CS_WIDTH*nCS_PER_RANK] <= #TCQ 1'b0;
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (n = 0; n < nCS_PER_RANK*nCK_PER_CLK*2; n = n + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[n+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
2'b01:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) //even CWL
phy_int_cs_n[1] <= #TCQ 1'b0;
else // odd CWL
phy_int_cs_n[1+1*CS_WIDTH*nCS_PER_RANK] <= #TCQ 1'b0;
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (p = nCS_PER_RANK; p < nCS_PER_RANK*nCK_PER_CLK*2; p = p + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[p+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
endcase
end
end
end else if (RANKS == 2) begin: DDR3_2rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if (init_state_r == INIT_REG_WRITE) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if(!(CWL_M%2)) begin
phy_int_cs_n[0%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[1%nCK_PER_CLK] <= #TCQ 1'b0;
end else begin
phy_int_cs_n[2%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[3%nCK_PER_CLK] <= #TCQ 1'b0;
end
end else begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
case (chip_cnt_r)
2'b00:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) begin //even CWL
for (n = 0; n < nCS_PER_RANK; n = n + 1) begin
phy_int_cs_n[n] <= #TCQ 1'b0;
end
end else begin // odd CWL
for (p = CS_WIDTH*nCS_PER_RANK; p < (CS_WIDTH*nCS_PER_RANK + nCS_PER_RANK); p = p + 1) begin
phy_int_cs_n[p] <= #TCQ 1'b0;
end
end
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (n = 0; n < nCS_PER_RANK*nCK_PER_CLK*2; n = n + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[n+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
2'b01:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) begin //even CWL
for (q = nCS_PER_RANK; q < (2 * nCS_PER_RANK); q = q + 1) begin
phy_int_cs_n[q] <= #TCQ 1'b0;
end
end else begin // odd CWL
for (m = (nCS_PER_RANK*CS_WIDTH + nCS_PER_RANK); m < (nCS_PER_RANK*CS_WIDTH + 2*nCS_PER_RANK); m = m + 1) begin
phy_int_cs_n[m] <= #TCQ 1'b0;
end
end
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (p = nCS_PER_RANK; p < nCS_PER_RANK*nCK_PER_CLK*2; p = p + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[p+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
endcase
end
end // always @ (posedge clk)
end
// verilint STARC-2.2.3.3 on
// commented out for now. Need it for DDR2 2T timing
/* end else begin: DDR2
always @(posedge clk)
if (rst) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end else begin
if (init_state_r == INIT_REG_WRITE) begin
// All ranks selected simultaneously
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b0}};
end else if ((wrlvl_odt) ||
(init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH)) begin
phy_int_cs_n[0] <= #TCQ 1'b0;
end
else phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end // else: !if(rst)
end // block: DDR2 */
endgenerate
assign phy_cs_n = phy_int_cs_n;
//***************************************************************************
// Write/read burst logic for calibration
//***************************************************************************
assign rdlvl_wr = (init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE);
assign rdlvl_rd = (init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_MPR_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS);
assign rdlvl_wr_rd = rdlvl_wr | rdlvl_rd;
assign mmcm_wr = (init_state_r == INIT_OCAL_CENTER_WRITE); //used to de-assert cs_n during centering
// assign mmcm_wr = 'b0; // (init_state_r == INIT_OCAL_CENTER_WRITE);
//***************************************************************************
// Address generation and logic to count # of writes/reads issued during
// certain stages of calibration
//***************************************************************************
// Column address generation logic:
// Keep track of the current column address - since all bursts are in
// increments of 8 only during calibration, we need to keep track of
// addresses [COL_WIDTH-1:3], lower order address bits will always = 0
always @(posedge clk)
if (rst || wrcal_done)
burst_addr_r <= #TCQ 1'b0;
else if ((init_state_r == INIT_WRCAL_ACT_WAIT) ||
(init_state_r == INIT_OCLKDELAY_ACT_WAIT) ||
(init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS) ||
(init_state_r == INIT_WRCAL_READ_WAIT))
burst_addr_r <= #TCQ 1'b1;
else if (rdlvl_wr_rd && new_burst_r)
burst_addr_r <= #TCQ ~burst_addr_r;
else
burst_addr_r <= #TCQ 1'b0;
// Read Level Stage 1 requires writes to the entire row since
// a PRBS pattern is being written. This counter keeps track
// of the number of writes which depends on the column width
// The (stg1_wr_rd_cnt==9'd0) condition was added so the col
// address wraps around during stage1 reads
always @(posedge clk)
if (rst || ((init_state_r == INIT_RDLVL_STG1_WRITE_READ) &&
~rdlvl_stg1_done))
stg1_wr_rd_cnt <= #TCQ NUM_STG1_WR_RD;
else if (rdlvl_last_byte_done || (stg1_wr_rd_cnt == 9'd1) ||
(prbs_rdlvl_prech_req && (init_state_r == INIT_RDLVL_ACT_WAIT)) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) ) begin
if (~complex_row0_wr_done || wr_victim_inc ||
(complex_row1_wr_done && (~complex_row0_rd_done || (complex_row0_rd_done && complex_row1_rd_done))))
stg1_wr_rd_cnt <= #TCQ 'd127;
else
stg1_wr_rd_cnt <= #TCQ prbs_rdlvl_done?'d30 :'d22;
end else if (((init_state_r == INIT_RDLVL_STG1_WRITE) && new_burst_r && ~phy_data_full)
||((init_state_r == INIT_RDLVL_COMPLEX_READ) && rdlvl_stg1_done))
stg1_wr_rd_cnt <= #TCQ stg1_wr_rd_cnt - 1;
always @(posedge clk)
if (rst)
wr_victim_inc <= #TCQ 1'b0;
else if (complex_row0_wr_done && (stg1_wr_rd_cnt == 9'd2) && ~stg1_wr_done)
wr_victim_inc <= #TCQ 1'b1;
else
wr_victim_inc <= #TCQ 1'b0;
always @(posedge clk)
reset_rd_addr_r1 <= #TCQ reset_rd_addr;
generate
if (FIXED_VICTIM == "FALSE") begin: row_cnt_victim_rotate
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt == DQ_WIDTH*2-1)) || ~rdlvl_stg1_done_r1 || prbs_rdlvl_done)
complex_row_cnt <= #TCQ 'd0;
else if ((((stg1_wr_rd_cnt == 'd22) && ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(complex_rdlvl_int_ref_req && (init_state_r == INIT_REFRESH_WAIT) && (cnt_cmd_r == 'd127)))) ||
complex_victim_inc || (complex_sample_cnt_inc_r2 && ~complex_victim_inc) || wr_victim_inc || reset_rd_addr_r1)) begin
// During writes row count is incremented with every wr_victim_in and stg1_wr_rd_cnt=='d22
if ((complex_row_cnt < DQ_WIDTH*2-1) && ~stg1_wr_done)
complex_row_cnt <= #TCQ complex_row_cnt + 1;
// During reads row count requires different conditions for increments
else if (stg1_wr_done) begin
if (reset_rd_addr_r1)
complex_row_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt*16;
// When looping multiple times in the same victim bit in a byte
else if (complex_sample_cnt_inc_r2 && ~complex_victim_inc)
complex_row_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt*16 + rd_victim_sel*2;
// When looping through victim bits within a byte
else if (complex_row_cnt < pi_stg2_prbs_rdlvl_cnt*16+15)
complex_row_cnt <= #TCQ complex_row_cnt + 1;
// When the number of samples is done and tap is incremented within a byte
else
complex_row_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt*16;
end
end
end else begin: row_cnt_victim_fixed
always @(posedge clk)
if (rst || ~rdlvl_stg1_done_r1 || prbs_rdlvl_done)
complex_row_cnt <= #TCQ 'd0;
else if ((stg1_wr_rd_cnt == 'd22) && (((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_WAIT) && (complex_wait_cnt == 'd15)) || complex_rdlvl_int_ref_req))
complex_row_cnt <= #TCQ 'd1;
else
complex_row_cnt <= #TCQ 'd0;
end
endgenerate
//row count
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt_ocal == COMPLEX_ROW_CNT_BYTE-1)) || ~rdlvl_stg1_done_r1 || prbs_rdlvl_done_pulse || complex_byte_rd_done)
complex_row_cnt_ocal <= #TCQ 'd0;
else if ( prbs_rdlvl_done && (((stg1_wr_rd_cnt == 'd30) && (init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE)) ||
(complex_sample_cnt_inc_r2) || wr_victim_inc)) begin
// During writes row count is incremented with every wr_victim_in and stg1_wr_rd_cnt=='d22
if (complex_row_cnt_ocal < COMPLEX_ROW_CNT_BYTE-1) begin
complex_row_cnt_ocal <= #TCQ complex_row_cnt_ocal + 1;
end
end
always @(posedge clk)
if (rst)
complex_odt_ext <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) || (init_state_r == INIT_PRECHARGE))
complex_odt_ext <= #TCQ 1'b0;
else if (rdlvl_stg1_done_r1 && (stg1_wr_rd_cnt == 9'd1) && (init_state_r == INIT_RDLVL_STG1_WRITE))
complex_odt_ext <= #TCQ 1'b1;
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt == DQ_WIDTH*2-1))) begin
wr_victim_sel <= #TCQ 'd0;
wr_byte_cnt <= #TCQ 'd0;
end else if (rdlvl_stg1_done_r1 && wr_victim_inc) begin
wr_victim_sel <= #TCQ wr_victim_sel + 1;
if (wr_victim_sel == 'd7)
wr_byte_cnt <= #TCQ wr_byte_cnt + 1;
end
always @(posedge clk)
if (rst) begin
wr_victim_sel_ocal <= #TCQ 'd0;
end else if (wr_victim_inc && (complex_row_cnt_ocal == COMPLEX_ROW_CNT_BYTE-1)) begin
wr_victim_sel_ocal <= #TCQ 'd0;
end else if (prbs_rdlvl_done && wr_victim_inc) begin
wr_victim_sel_ocal <= #TCQ wr_victim_sel_ocal + 1;
end
always @(posedge clk)
if (rst) begin
victim_sel <= #TCQ 'd0;
victim_byte_cnt <= #TCQ 'd0;
end else if ((~stg1_wr_done && ~prbs_rdlvl_done) || (prbs_rdlvl_done && ~complex_wr_done)) begin
victim_sel <= #TCQ prbs_rdlvl_done? wr_victim_sel_ocal: wr_victim_sel;
victim_byte_cnt <= #TCQ prbs_rdlvl_done? complex_oclkdelay_calib_cnt:wr_byte_cnt;
end else begin
if( (init_state_r == INIT_RDLVL_COMPLEX_ACT) || reset_rd_addr)
victim_sel <= #TCQ prbs_rdlvl_done? complex_ocal_rd_victim_sel:rd_victim_sel;
victim_byte_cnt <= #TCQ prbs_rdlvl_done? complex_oclkdelay_calib_cnt:pi_stg2_prbs_rdlvl_cnt;
end
generate
if (FIXED_VICTIM == "FALSE") begin: wr_done_victim_rotate
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt < DQ_WIDTH*2-1) && ~prbs_rdlvl_done) ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done || prbs_rdlvl_done_pulse) begin
complex_row0_wr_done <= #TCQ 1'b0;
end else if ( rdlvl_stg1_done_r1 && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row0_wr_done <= #TCQ 1'b1;
end
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt < DQ_WIDTH*2-1) && ~prbs_rdlvl_done) ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done || prbs_rdlvl_done_pulse) begin
complex_row1_wr_done <= #TCQ 1'b0;
end else if (complex_row0_wr_done && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row1_wr_done <= #TCQ 1'b1;
end
end else begin: wr_done_victim_fixed
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done ) begin
complex_row0_wr_done <= #TCQ 1'b0;
end else if (rdlvl_stg1_done_r1 && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row0_wr_done <= #TCQ 1'b1;
end
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done ) begin
complex_row1_wr_done <= #TCQ 1'b0;
end else if (complex_row0_wr_done && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row1_wr_done <= #TCQ 1'b1;
end
end
endgenerate
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse)
complex_row0_rd_done <= #TCQ 1'b0;
else if (complex_sample_cnt_inc)
complex_row0_rd_done <= #TCQ 1'b0;
else if ( (prbs_rdlvl_start || complex_oclkdelay_calib_start_int) && (stg1_wr_rd_cnt == 9'd2) && complex_row0_wr_done && complex_row1_wr_done)
complex_row0_rd_done <= #TCQ 1'b1;
always @(posedge clk)
complex_row0_rd_done_r1 <= #TCQ complex_row0_rd_done;
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse)
complex_row1_rd_done <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) || (init_state_r == INIT_PRECHARGE))
complex_row1_rd_done <= #TCQ 1'b0;
else if (complex_row0_rd_done && (stg1_wr_rd_cnt == 9'd2))
complex_row1_rd_done <= #TCQ 1'b1;
always @(posedge clk)
complex_row1_rd_done_r1 <= #TCQ complex_row1_rd_done;
//calculate row rd num for complex_oclkdelay_calib
//once it reached to 8
always @ (posedge clk)
if (rst || prbs_rdlvl_done_pulse) complex_row1_rd_cnt <= #TCQ 'd0;
else
complex_row1_rd_cnt <= #TCQ (complex_row1_rd_done & ~complex_row1_rd_done_r1) ?
((complex_row1_rd_cnt == (COMPLEX_RD-1))? 0:complex_row1_rd_cnt + 'd1)
: complex_row1_rd_cnt;
//For write, reset rd_done for the byte
always @ (posedge clk) begin
if (rst || (init_state_r == INIT_RDLVL_STG1_WRITE) || prbs_rdlvl_done_pulse)
complex_byte_rd_done <= #TCQ 'b0;
else if (prbs_rdlvl_done && (complex_row1_rd_cnt == (COMPLEX_RD-1)) && (complex_row1_rd_done & ~complex_row1_rd_done_r1))
complex_byte_rd_done <= #TCQ 'b1;
end
always @ (posedge clk) begin
complex_byte_rd_done_r1 <= #TCQ complex_byte_rd_done;
complex_ocal_num_samples_inc <= #TCQ (complex_byte_rd_done & ~complex_byte_rd_done_r1);
end
generate
if (RANKS < 2) begin: one_rank_complex
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done || ( complex_oclkdelay_calib_done && (init_state_r == INIT_RDLVL_STG1_WRITE )) ||
(complex_byte_rd_done && init_state_r == INIT_RDLVL_COMPLEX_ACT) || prbs_rdlvl_done_pulse )
complex_wr_done <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
else if ((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
end else begin: dual_rank_complex
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done || ( complex_oclkdelay_calib_done && (init_state_r == INIT_RDLVL_STG1_WRITE )) ||
(rdlvl_stg1_rank_done ) || (complex_byte_rd_done && init_state_r == INIT_RDLVL_COMPLEX_ACT) || prbs_rdlvl_done_pulse )
complex_wr_done <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
else if ((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
end
endgenerate
always @(posedge clk)
if (rst)
complex_wait_cnt <= #TCQ 'd0;
else if (((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_WAIT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)) && complex_wait_cnt < 'd15)
complex_wait_cnt <= #TCQ complex_wait_cnt + 1;
else
complex_wait_cnt <= #TCQ 'd0;
always @(posedge clk)
if (rst) begin
complex_num_reads <= #TCQ 'd1;
end else if ((((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) && (complex_wait_cnt == 'd14)) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) && ext_int_ref_req && (cnt_cmd_r == 'd127))) &&
~complex_row0_rd_done) begin
if (stg1_wr_rd_cnt > 'd85) begin
if (complex_num_reads < 'd6)
complex_num_reads <= #TCQ complex_num_reads + 1;
else
complex_num_reads <= #TCQ 'd1;
// Initila value for VCCAUX pattern is 3, 7, and 12
end else if (stg1_wr_rd_cnt > 'd73) begin
if (stg1_wr_rd_cnt == 'd85)
complex_num_reads <= #TCQ 'd3;
else if (complex_num_reads < 'd5)
complex_num_reads <= #TCQ complex_num_reads + 1;
end else if (stg1_wr_rd_cnt > 'd39) begin
if (stg1_wr_rd_cnt == 'd73)
complex_num_reads <= #TCQ 'd7;
else if (complex_num_reads < 'd10)
complex_num_reads <= #TCQ complex_num_reads + 1;
end else begin
if (stg1_wr_rd_cnt == 'd39)
complex_num_reads <= #TCQ 'd12;
else if (complex_num_reads < 'd14)
complex_num_reads <= #TCQ complex_num_reads + 1;
end
// Initialize to 1 at the start of reads or after precharge and activate
end else if ((((init_state_r == INIT_RDLVL_STG1_WRITE_READ) || (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)) && ~ext_int_ref_req) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) && (stg1_wr_rd_cnt == 'd22)))
complex_num_reads <= #TCQ 'd1;
always @(posedge clk)
if (rst)
complex_num_reads_dec <= #TCQ 'd1;
else if (((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) && (complex_wait_cnt == 'd15) && ~complex_row0_rd_done) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) || (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)))
complex_num_reads_dec <= #TCQ complex_num_reads;
else if ((init_state_r == INIT_RDLVL_COMPLEX_READ) && (complex_num_reads_dec > 'd0))
complex_num_reads_dec <= #TCQ complex_num_reads_dec - 1;
always @(posedge clk)
if (rst)
complex_address <= #TCQ 'd0;
else if (((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) && (init_state_r1 != INIT_RDLVL_COMPLEX_READ_WAIT)) ||
((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (init_state_r1 != INIT_OCAL_COMPLEX_WRITE_WAIT)))
complex_address <= #TCQ phy_address[COL_WIDTH-1:0];
always @ (posedge clk)
if (rst)
complex_oclkdelay_calib_start_int <= #TCQ 'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT) && prbs_last_byte_done_r) // changed for new algo 3/26
complex_oclkdelay_calib_start_int <= #TCQ 'b1;
always @(posedge clk) begin
complex_oclkdelay_calib_start_r1 <= #TCQ complex_oclkdelay_calib_start_int;
complex_oclkdelay_calib_start_r2 <= #TCQ complex_oclkdelay_calib_start_r1;
end
always @ (posedge clk)
if (rst)
complex_oclkdelay_calib_start <= #TCQ 'b0;
else if (complex_oclkdelay_calib_start_int && (init_state_r == INIT_OCAL_CENTER_WRITE_WAIT) && prbs_rdlvl_done) // changed for new algo 3/26
complex_oclkdelay_calib_start <= #TCQ 'b1;
//packet fragmentation for complex oclkdealy calib write
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse) begin
complex_num_writes <= #TCQ 'd1;
end else if ((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (complex_wait_cnt == 'd14) && ~complex_row0_wr_done) begin
if (stg1_wr_rd_cnt > 'd85) begin
if (complex_num_writes < 'd6)
complex_num_writes <= #TCQ complex_num_writes + 1;
else
complex_num_writes <= #TCQ 'd1;
// Initila value for VCCAUX pattern is 3, 7, and 12
end else if (stg1_wr_rd_cnt > 'd73) begin
if (stg1_wr_rd_cnt == 'd85)
complex_num_writes <= #TCQ 'd3;
else if (complex_num_writes < 'd5)
complex_num_writes <= #TCQ complex_num_writes + 1;
end else if (stg1_wr_rd_cnt > 'd39) begin
if (stg1_wr_rd_cnt == 'd73)
complex_num_writes <= #TCQ 'd7;
else if (complex_num_writes < 'd10)
complex_num_writes <= #TCQ complex_num_writes + 1;
end else begin
if (stg1_wr_rd_cnt == 'd39)
complex_num_writes <= #TCQ 'd12;
else if (complex_num_writes < 'd14)
complex_num_writes <= #TCQ complex_num_writes + 1;
end
// Initialize to 1 at the start of write or after precharge and activate
end else if ((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && complex_row0_wr_done)
complex_num_writes <= #TCQ 'd30;
else if (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)
complex_num_writes <= #TCQ 'd1;
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse)
complex_num_writes_dec <= #TCQ 'd1;
else if (((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (complex_wait_cnt == 'd15) && ~complex_row0_rd_done) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) || (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)))
complex_num_writes_dec <= #TCQ complex_num_writes;
else if ((init_state_r == INIT_RDLVL_STG1_WRITE) && (complex_num_writes_dec > 'd0))
complex_num_writes_dec <= #TCQ complex_num_writes_dec - 1;
always @(posedge clk)
if (rst)
complex_sample_cnt_inc_ocal <= #TCQ 1'b0;
else if ((stg1_wr_rd_cnt == 9'd1) && complex_byte_rd_done && prbs_rdlvl_done)
complex_sample_cnt_inc_ocal <= #TCQ 1'b1;
else
complex_sample_cnt_inc_ocal <= #TCQ 1'b0;
always @(posedge clk)
if (rst)
complex_sample_cnt_inc <= #TCQ 1'b0;
else if ((stg1_wr_rd_cnt == 9'd1) && complex_row1_rd_done)
complex_sample_cnt_inc <= #TCQ 1'b1;
else
complex_sample_cnt_inc <= #TCQ 1'b0;
always @(posedge clk) begin
complex_sample_cnt_inc_r1 <= #TCQ complex_sample_cnt_inc;
complex_sample_cnt_inc_r2 <= #TCQ complex_sample_cnt_inc_r1;
end
//complex refresh req
always @ (posedge clk) begin
if(rst || (init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(prbs_rdlvl_done && (init_state_r == INIT_RDLVL_COMPLEX_ACT)) )
complex_ocal_ref_done <= #TCQ 1'b1;
else if (init_state_r == INIT_RDLVL_STG1_WRITE)
complex_ocal_ref_done <= #TCQ 1'b0;
end
//complex ocal odt extention
always @(posedge clk)
if (rst)
complex_ocal_odt_ext <= #TCQ 1'b0;
else if (((init_state_r == INIT_PRECHARGE_PREWAIT) && cnt_cmd_done_m7_r) || (init_state_r == INIT_OCLKDELAY_READ_WAIT))
complex_ocal_odt_ext <= #TCQ 1'b0;
else if ((init_state_r == INIT_OCAL_CENTER_WRITE) || (init_state_r == INIT_OCAL_CENTER_WRITE_WAIT))
complex_ocal_odt_ext <= #TCQ 1'b1;
// OCLKDELAY calibration requires multiple writes because
// write can be up to 2 cycles early since OCLKDELAY tap
// can go down to 0
always @(posedge clk)
if (rst || (init_state_r == INIT_OCLKDELAY_WRITE_WAIT) ||
(oclk_wr_cnt == 4'd0))
oclk_wr_cnt <= #TCQ NUM_STG1_WR_RD;
else if ((init_state_r == INIT_OCLKDELAY_WRITE) &&
new_burst_r && ~phy_data_full)
oclk_wr_cnt <= #TCQ oclk_wr_cnt - 1;
// Write calibration requires multiple writes because
// write can be up to 2 cycles early due to new write
// leveling algorithm to avoid late writes
always @(posedge clk)
if (rst || (init_state_r == INIT_WRCAL_WRITE_READ) ||
(wrcal_wr_cnt == 4'd0))
wrcal_wr_cnt <= #TCQ NUM_STG1_WR_RD;
else if ((init_state_r == INIT_WRCAL_WRITE) &&
new_burst_r && ~phy_data_full)
wrcal_wr_cnt <= #TCQ wrcal_wr_cnt - 1;
generate
if(nCK_PER_CLK == 4) begin:back_to_back_reads_4_1
// 4 back-to-back reads with gaps for
// read data_offset calibration (rdlvl stage 2)
always @(posedge clk)
if (rst || (init_state_r == INIT_RDLVL_STG2_READ_WAIT))
num_reads <= #TCQ 3'b000;
else if ((num_reads > 3'b000) && ~(phy_ctl_full || phy_cmd_full))
num_reads <= #TCQ num_reads - 1;
else if ((init_state_r == INIT_RDLVL_STG2_READ) || phy_ctl_full ||
phy_cmd_full && new_burst_r)
num_reads <= #TCQ 3'b011;
end else if(nCK_PER_CLK == 2) begin: back_to_back_reads_2_1
// 4 back-to-back reads with gaps for
// read data_offset calibration (rdlvl stage 2)
always @(posedge clk)
if (rst || (init_state_r == INIT_RDLVL_STG2_READ_WAIT))
num_reads <= #TCQ 3'b000;
else if ((num_reads > 3'b000) && ~(phy_ctl_full || phy_cmd_full))
num_reads <= #TCQ num_reads - 1;
else if ((init_state_r == INIT_RDLVL_STG2_READ) || phy_ctl_full ||
phy_cmd_full && new_burst_r)
num_reads <= #TCQ 3'b111;
end
endgenerate
// back-to-back reads during write calibration
always @(posedge clk)
if (rst ||(init_state_r == INIT_WRCAL_READ_WAIT))
wrcal_reads <= #TCQ 2'b00;
else if ((wrcal_reads > 2'b00) && ~(phy_ctl_full || phy_cmd_full))
wrcal_reads <= #TCQ wrcal_reads - 1;
else if ((init_state_r == INIT_WRCAL_MULT_READS) || phy_ctl_full ||
phy_cmd_full && new_burst_r)
wrcal_reads <= #TCQ 'd255;
// determine how often to issue row command during read leveling writes
// and reads
always @(posedge clk)
if (rdlvl_wr_rd) begin
// 2:1 mode - every other command issued is a data command
// 4:1 mode - every command issued is a data command
if (nCK_PER_CLK == 2) begin
if (!phy_ctl_full)
new_burst_r <= #TCQ ~new_burst_r;
end else
new_burst_r <= #TCQ 1'b1;
end else
new_burst_r <= #TCQ 1'b1;
// indicate when a write is occurring. PHY_WRDATA_EN must be asserted
// simultaneous with the corresponding command/address for CWL = 5,6
always @(posedge clk) begin
rdlvl_wr_r <= #TCQ rdlvl_wr;
calib_wrdata_en <= #TCQ phy_wrdata_en;
end
always @(posedge clk) begin
if (rst || wrcal_done)
extend_cal_pat <= #TCQ 1'b0;
else if (temp_lmr_done && (PRE_REV3ES == "ON"))
extend_cal_pat <= #TCQ 1'b1;
end
generate
if ((nCK_PER_CLK == 4) || (BURST_MODE == "4")) begin: wrdqen_div4
// Write data enable asserted for one DIV4 clock cycle
// Only BL8 supported with DIV4. DDR2 BL4 will use DIV2.
always @(*) begin
if (~phy_data_full && ((init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE)))
phy_wrdata_en = 1'b1;
else
phy_wrdata_en = 1'b0;
end
end else begin: wrdqen_div2 // block: wrdqen_div4
always @(*)
if((rdlvl_wr & ~phy_ctl_full & new_burst_r & ~phy_data_full)
| phy_wrdata_en_r1)
phy_wrdata_en = 1'b1;
else
phy_wrdata_en = 1'b0;
always @(posedge clk)
phy_wrdata_en_r1 <= #TCQ rdlvl_wr & ~phy_ctl_full & new_burst_r
& ~phy_data_full;
always @(posedge clk) begin
if (!phy_wrdata_en & first_rdlvl_pat_r)
wrdata_pat_cnt <= #TCQ 2'b00;
else if (wrdata_pat_cnt == 2'b11)
wrdata_pat_cnt <= #TCQ 2'b10;
else
wrdata_pat_cnt <= #TCQ wrdata_pat_cnt + 1;
end
always @(posedge clk) begin
if (!phy_wrdata_en & first_wrcal_pat_r)
wrcal_pat_cnt <= #TCQ 2'b00;
else if (extend_cal_pat && (wrcal_pat_cnt == 2'b01))
wrcal_pat_cnt <= #TCQ 2'b00;
else if (wrcal_pat_cnt == 2'b11)
wrcal_pat_cnt <= #TCQ 2'b10;
else
wrcal_pat_cnt <= #TCQ wrcal_pat_cnt + 1;
end
end
endgenerate
// indicate when a write is occurring. PHY_RDDATA_EN must be asserted
// simultaneous with the corresponding command/address. PHY_RDDATA_EN
// is used during read-leveling to determine read latency
assign phy_rddata_en = ~phy_if_empty;
// Read data valid generation for MC and User Interface after calibration is
// complete
assign phy_rddata_valid = init_complete_r1_timing ? phy_rddata_en : 1'b0;
//***************************************************************************
// Generate training data written at start of each read-leveling stage
// For every stage of read leveling, 8 words are written into memory
// The format is as follows (shown as {rise,fall}):
// Stage 1: 0xF, 0x0, 0xF, 0x0, 0xF, 0x0, 0xF, 0x0
// Stage 2: 0xF, 0x0, 0xA, 0x5, 0x5, 0xA, 0x9, 0x6
//***************************************************************************
always @(posedge clk)
if ((init_state_r == INIT_IDLE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE))
cnt_init_data_r <= #TCQ 2'b00;
else if (phy_wrdata_en)
cnt_init_data_r <= #TCQ cnt_init_data_r + 1;
else if (init_state_r == INIT_WRCAL_WRITE)
cnt_init_data_r <= #TCQ 2'b10;
// write different sequence for very
// first write to memory only. Used to help us differentiate
// if the writes are "early" or "on-time" during read leveling
always @(posedge clk)
if (rst || rdlvl_stg1_rank_done)
first_rdlvl_pat_r <= #TCQ 1'b1;
else if (phy_wrdata_en && (init_state_r == INIT_RDLVL_STG1_WRITE))
first_rdlvl_pat_r <= #TCQ 1'b0;
always @(posedge clk)
if (rst || wrcal_resume ||
(init_state_r == INIT_WRCAL_ACT_WAIT))
first_wrcal_pat_r <= #TCQ 1'b1;
else if (phy_wrdata_en && (init_state_r == INIT_WRCAL_WRITE))
first_wrcal_pat_r <= #TCQ 1'b0;
generate
if ((CLK_PERIOD/nCK_PER_CLK > 2500) && (nCK_PER_CLK == 2)) begin: wrdq_div2_2to1_rdlvl_first
always @(posedge clk)
if (~oclkdelay_calib_done)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}}};
else if (!rdlvl_stg1_done) begin
// The 16 words for stage 1 write data in 2:1 mode is written
// over 4 consecutive controller clock cycles. Note that write
// data follows phy_wrdata_en by one clock cycle
case (wrdata_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},
{DQ_WIDTH/4{4'h9}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
endcase
end else if (!prbs_rdlvl_done && ~phy_data_full) begin
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},
{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},
{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
end else if (!wrcal_done) begin
case (wrcal_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h5}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},
{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h4}}};
end
endcase
end
end else if ((CLK_PERIOD/nCK_PER_CLK > 2500) && (nCK_PER_CLK == 4)) begin: wrdq_div2_4to1_rdlvl_first
always @(posedge clk)
if (~oclkdelay_calib_done)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}}};
else if (!rdlvl_stg1_done && ~phy_data_full)
// write different sequence for very
// first write to memory only. Used to help us differentiate
// if the writes are "early" or "on-time" during read leveling
if (first_rdlvl_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},{DQ_WIDTH/4{4'h9}}};
else
// For all others, change the first two words written in order
// to differentiate the "early write" and "on-time write"
// readback patterns during read leveling
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
else if (~(prbs_rdlvl_done || prbs_last_byte_done_r) && ~phy_data_full)
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[8*8-1:7*8]}},{DQ_WIDTH/8{prbs_o[7*8-1:6*8]}},
{DQ_WIDTH/8{prbs_o[6*8-1:5*8]}},{DQ_WIDTH/8{prbs_o[5*8-1:4*8]}},
{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
else if (!wrcal_done)
if (first_wrcal_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'h5}},{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},{DQ_WIDTH/4{4'hF}}};
else
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
end else if (nCK_PER_CLK == 4) begin: wrdq_div1_4to1_wrcal_first
always @(posedge clk)
if ((~oclkdelay_calib_done) && (DRAM_TYPE == "DDR3"))
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}}};
else if ((!wrcal_done)&& (DRAM_TYPE == "DDR3")) begin
if (extend_cal_pat)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'h5}},{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},{DQ_WIDTH/4{4'hF}}};
else if (first_wrcal_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'h5}},{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},{DQ_WIDTH/4{4'hF}}};
else
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
end else if (!rdlvl_stg1_done && ~phy_data_full) begin
// write different sequence for very
// first write to memory only. Used to help us differentiate
// if the writes are "early" or "on-time" during read leveling
if (first_rdlvl_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},{DQ_WIDTH/4{4'h9}}};
else
// For all others, change the first two words written in order
// to differentiate the "early write" and "on-time write"
// readback patterns during read leveling
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
end else if (!prbs_rdlvl_done && ~phy_data_full)
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[8*8-1:7*8]}},{DQ_WIDTH/8{prbs_o[7*8-1:6*8]}},
{DQ_WIDTH/8{prbs_o[6*8-1:5*8]}},{DQ_WIDTH/8{prbs_o[5*8-1:4*8]}},
{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
else if (!complex_oclkdelay_calib_done && ~phy_data_full)
phy_wrdata <= #TCQ prbs_o;
end else begin: wrdq_div1_2to1_wrcal_first
always @(posedge clk)
if ((~oclkdelay_calib_done)&& (DRAM_TYPE == "DDR3"))
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}}};
else if ((!wrcal_done) && (DRAM_TYPE == "DDR3"))begin
case (wrcal_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h5}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},
{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h4}}};
end
endcase
end else if (!rdlvl_stg1_done) begin
// The 16 words for stage 1 write data in 2:1 mode is written
// over 4 consecutive controller clock cycles. Note that write
// data follows phy_wrdata_en by one clock cycle
case (wrdata_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},
{DQ_WIDTH/4{4'h9}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
endcase
end else if (!prbs_rdlvl_done && ~phy_data_full) begin
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},
{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},
{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
end else if (!complex_oclkdelay_calib_done && ~phy_data_full) begin
phy_wrdata <= #TCQ prbs_o;
end
end
endgenerate
//***************************************************************************
// Memory control/address
//***************************************************************************
// Phases [2] and [3] are always deasserted for 4:1 mode
generate
if (nCK_PER_CLK == 4) begin: gen_div4_ca_tieoff
always @(posedge clk) begin
phy_ras_n[3:2] <= #TCQ 3'b11;
phy_cas_n[3:2] <= #TCQ 3'b11;
phy_we_n[3:2] <= #TCQ 3'b11;
end
end
endgenerate
// Assert RAS when: (1) Loading MRS, (2) Activating Row, (3) Precharging
// (4) auto refresh
// verilint STARC-2.7.3.3b off
generate
if (!(CWL_M % 2)) begin: even_cwl
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT))begin
phy_ras_n[0] <= #TCQ 1'b0;
phy_ras_n[1] <= #TCQ 1'b1;
end else begin
phy_ras_n[0] <= #TCQ 1'b1;
phy_ras_n[1] <= #TCQ 1'b1;
end
end
// Assert CAS when: (1) Loading MRS, (2) Issuing Read/Write command
// (3) auto refresh
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_REFRESH) ||
(rdlvl_wr_rd && new_burst_r))begin
phy_cas_n[0] <= #TCQ 1'b0;
phy_cas_n[1] <= #TCQ 1'b1;
end else begin
phy_cas_n[0] <= #TCQ 1'b1;
phy_cas_n[1] <= #TCQ 1'b1;
end
end
// Assert WE when: (1) Loading MRS, (2) Issuing Write command (only
// occur during read leveling), (3) Issuing ZQ Long Calib command,
// (4) Precharge
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE)||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(rdlvl_wr && new_burst_r))begin
phy_we_n[0] <= #TCQ 1'b0;
phy_we_n[1] <= #TCQ 1'b1;
end else begin
phy_we_n[0] <= #TCQ 1'b1;
phy_we_n[1] <= #TCQ 1'b1;
end
end
end else begin: odd_cwl
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(init_state_r == INIT_REFRESH))begin
phy_ras_n[0] <= #TCQ 1'b1;
phy_ras_n[1] <= #TCQ 1'b0;
end else begin
phy_ras_n[0] <= #TCQ 1'b1;
phy_ras_n[1] <= #TCQ 1'b1;
end
end
// Assert CAS when: (1) Loading MRS, (2) Issuing Read/Write command
// (3) auto refresh
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_REFRESH) ||
(rdlvl_wr_rd && new_burst_r))begin
phy_cas_n[0] <= #TCQ 1'b1;
phy_cas_n[1] <= #TCQ 1'b0;
end else begin
phy_cas_n[0] <= #TCQ 1'b1;
phy_cas_n[1] <= #TCQ 1'b1;
end
end
// Assert WE when: (1) Loading MRS, (2) Issuing Write command (only
// occur during read leveling), (3) Issuing ZQ Long Calib command,
// (4) Precharge
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE)||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(rdlvl_wr && new_burst_r))begin
phy_we_n[0] <= #TCQ 1'b1;
phy_we_n[1] <= #TCQ 1'b0;
end else begin
phy_we_n[0] <= #TCQ 1'b1;
phy_we_n[1] <= #TCQ 1'b1;
end
end
end
endgenerate
// verilint STARC-2.7.3.3b on
// Assign calib_cmd for the command field in PHY_Ctl_Word
always @(posedge clk) begin
if (wr_level_dqs_asrt) begin
// Request to toggle DQS during write leveling
calib_cmd <= #TCQ 3'b001;
if (CWL_M % 2) begin // odd write latency
calib_data_offset_0 <= #TCQ CWL_M + 3;
calib_data_offset_1 <= #TCQ CWL_M + 3;
calib_data_offset_2 <= #TCQ CWL_M + 3;
calib_cas_slot <= #TCQ 2'b01;
end else begin // even write latency
calib_data_offset_0 <= #TCQ CWL_M + 2;
calib_data_offset_1 <= #TCQ CWL_M + 2;
calib_data_offset_2 <= #TCQ CWL_M + 2;
calib_cas_slot <= #TCQ 2'b00;
end
end else if (rdlvl_wr && new_burst_r) begin
// Write Command
calib_cmd <= #TCQ 3'b001;
if (CWL_M % 2) begin // odd write latency
calib_data_offset_0 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 3 : CWL_M - 1;
calib_data_offset_1 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 3 : CWL_M - 1;
calib_data_offset_2 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 3 : CWL_M - 1;
calib_cas_slot <= #TCQ 2'b01;
end else begin // even write latency
calib_data_offset_0 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 2 : CWL_M - 2 ;
calib_data_offset_1 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 2 : CWL_M - 2 ;
calib_data_offset_2 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 2 : CWL_M - 2 ;
calib_cas_slot <= #TCQ 2'b00;
end
end else if (rdlvl_rd && new_burst_r) begin
// Read Command
calib_cmd <= #TCQ 3'b011;
if (CWL_M % 2)
calib_cas_slot <= #TCQ 2'b01;
else
calib_cas_slot <= #TCQ 2'b00;
if (~pi_calib_done_r1) begin
calib_data_offset_0 <= #TCQ 6'd0;
calib_data_offset_1 <= #TCQ 6'd0;
calib_data_offset_2 <= #TCQ 6'd0;
end else if (~pi_dqs_found_done_r1) begin
calib_data_offset_0 <= #TCQ rd_data_offset_0;
calib_data_offset_1 <= #TCQ rd_data_offset_1;
calib_data_offset_2 <= #TCQ rd_data_offset_2;
end else begin
calib_data_offset_0 <= #TCQ rd_data_offset_ranks_0[6*chip_cnt_r+:6];
calib_data_offset_1 <= #TCQ rd_data_offset_ranks_1[6*chip_cnt_r+:6];
calib_data_offset_2 <= #TCQ rd_data_offset_ranks_2[6*chip_cnt_r+:6];
end
end else begin
// Non-Data Commands like NOP, MRS, ZQ Long Cal, Precharge,
// Active, Refresh
calib_cmd <= #TCQ 3'b100;
calib_data_offset_0 <= #TCQ 6'd0;
calib_data_offset_1 <= #TCQ 6'd0;
calib_data_offset_2 <= #TCQ 6'd0;
if (CWL_M % 2)
calib_cas_slot <= #TCQ 2'b01;
else
calib_cas_slot <= #TCQ 2'b00;
end
end
// Write Enable to PHY_Control FIFO always asserted
// No danger of this FIFO being Full with 4:1 sync clock ratio
// This is also the write enable to the command OUT_FIFO
always @(posedge clk) begin
if (rst) begin
calib_ctl_wren <= #TCQ 1'b0;
calib_cmd_wren <= #TCQ 1'b0;
calib_seq <= #TCQ 2'b00;
end else if (cnt_pwron_cke_done_r && phy_ctl_ready
&& ~(phy_ctl_full || phy_cmd_full )) begin
calib_ctl_wren <= #TCQ 1'b1;
calib_cmd_wren <= #TCQ 1'b1;
calib_seq <= #TCQ calib_seq + 1;
end else begin
calib_ctl_wren <= #TCQ 1'b0;
calib_cmd_wren <= #TCQ 1'b0;
calib_seq <= #TCQ calib_seq;
end
end
generate
genvar rnk_i;
for (rnk_i = 0; rnk_i < 4; rnk_i = rnk_i + 1) begin: gen_rnk
always @(posedge clk) begin
if (rst) begin
mr2_r[rnk_i] <= #TCQ 2'b00;
mr1_r[rnk_i] <= #TCQ 3'b000;
end else begin
mr2_r[rnk_i] <= #TCQ tmp_mr2_r[rnk_i];
mr1_r[rnk_i] <= #TCQ tmp_mr1_r[rnk_i];
end
end
end
endgenerate
// ODT assignment based on slot config and slot present
// For single slot systems slot_1_present input will be ignored
// Assuming component interfaces to be single slot systems
generate
if (nSLOTS == 1) begin: gen_single_slot_odt
always @(posedge clk) begin
if (rst) begin
tmp_mr2_r[1] <= #TCQ 2'b00;
tmp_mr2_r[2] <= #TCQ 2'b00;
tmp_mr2_r[3] <= #TCQ 2'b00;
tmp_mr1_r[1] <= #TCQ 3'b000;
tmp_mr1_r[2] <= #TCQ 3'b000;
tmp_mr1_r[3] <= #TCQ 3'b000;
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b1}};
phy_tmp_odt_r <= #TCQ 4'b0000;
phy_tmp_odt_r1 <= #TCQ phy_tmp_odt_r;
end else begin
case ({slot_0_present[0],slot_0_present[1],
slot_0_present[2],slot_0_present[3]})
// Single slot configuration with quad rank
// Assuming same behavior as single slot dual rank for now
// DDR2 does not have quad rank parts
4'b1111: begin
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 RTT_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 RTT_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
phy_tmp_odt_r <= #TCQ 4'b0001;
// Chip Select assignments
phy_tmp_cs1_r[((chip_cnt_r*nCS_PER_RANK)
) +: nCS_PER_RANK] <= #TCQ 'b0;
end
// Single slot configuration with single rank
4'b1000: begin
phy_tmp_odt_r <= #TCQ 4'b0001;
if ((REG_CTRL == "ON") && (nCS_PER_RANK > 1)) begin
phy_tmp_cs1_r[chip_cnt_r] <= #TCQ 1'b0;
end else begin
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b0}};
end
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
((cnt_init_mr_r == 2'd0) || (USE_ODT_PORT == 1)))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 RTT_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 RTT_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
// Single slot configuration with dual rank
4'b1100: begin
phy_tmp_odt_r <= #TCQ 4'b0001;
// Chip Select assignments
phy_tmp_cs1_r[((chip_cnt_r*nCS_PER_RANK)
) +: nCS_PER_RANK] <= #TCQ 'b0;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
default: begin
phy_tmp_odt_r <= #TCQ 4'b0001;
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
endcase
end
end
end else if (nSLOTS == 2) begin: gen_dual_slot_odt
always @ (posedge clk) begin
if (rst) begin
tmp_mr2_r[1] <= #TCQ 2'b00;
tmp_mr2_r[2] <= #TCQ 2'b00;
tmp_mr2_r[3] <= #TCQ 2'b00;
tmp_mr1_r[1] <= #TCQ 3'b000;
tmp_mr1_r[2] <= #TCQ 3'b000;
tmp_mr1_r[3] <= #TCQ 3'b000;
phy_tmp_odt_r <= #TCQ 4'b0000;
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b1}};
phy_tmp_odt_r1 <= #TCQ phy_tmp_odt_r;
end else begin
case ({slot_0_present[0],slot_0_present[1],
slot_1_present[0],slot_1_present[1]})
// Two slot configuration, one slot present, single rank
4'b10_00: begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r <= #TCQ 4'b0001;
end
phy_tmp_cs1_r <= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
4'b00_10: begin
//Rank1 ODT enabled
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r <= #TCQ 4'b0001;
end
phy_tmp_cs1_r <= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank1 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank1 Rtt_NOM defaults to 120 ohms
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
// Two slot configuration, one slot present, dual rank
4'b00_11: begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r
<= #TCQ 4'b0001;
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
4'b11_00: begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r <= #TCQ 4'b0001;
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank1 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
// Two slot configuration, one rank per slot
4'b10_10: begin
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r == 2'b00)begin
phy_tmp_odt_r
<= #TCQ 4'b0010; //bit0 for rank0
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0001; //bit0 for rank0
end
end else begin
if((init_state_r == INIT_WRLVL_WAIT) ||
(init_next_state == INIT_RDLVL_STG1_WRITE) ||
(init_next_state == INIT_WRCAL_WRITE) ||
(init_next_state == INIT_OCAL_CENTER_WRITE) ||
(init_next_state == INIT_OCLKDELAY_WRITE))
phy_tmp_odt_r <= #TCQ 4'b0011; // bit0 for rank0/1 (write)
else if ((init_next_state == INIT_PI_PHASELOCK_READS) ||
(init_next_state == INIT_MPR_READ) ||
(init_next_state == INIT_RDLVL_STG1_READ) ||
(init_next_state == INIT_RDLVL_COMPLEX_READ) ||
(init_next_state == INIT_RDLVL_STG2_READ) ||
(init_next_state == INIT_OCLKDELAY_READ) ||
(init_next_state == INIT_WRCAL_READ) ||
(init_next_state == INIT_WRCAL_MULT_READS))
phy_tmp_odt_r <= #TCQ 4'b0010; // bit0 for rank1 (rank 0 rd)
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_WR == "60") ? 3'b001 :
(RTT_WR == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
end
end
// Two Slots - One slot with dual rank and other with single rank
4'b10_11: begin
//Rank3 Rtt_NOM
tmp_mr1_r[2] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
tmp_mr2_r[2] <= #TCQ 2'b00;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[1] <= #TCQ 3'b000;
end
//Slot1 Rank1 or Rank3 is being written
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r == 2'b00)begin
phy_tmp_odt_r
<= #TCQ 4'b0010;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0001;
end
end else begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
if (chip_cnt_r[0] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0011;
//Slot0 Rank0 is being written
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0101; // ODT for ranks 0 and 2 aserted
end
end else if ((init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS))begin
if (chip_cnt_r == 2'b00) begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0001;
end
end
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
end
// Two Slots - One slot with dual rank and other with single rank
4'b11_10: begin
//Rank2 Rtt_NOM
tmp_mr1_r[2] <= #TCQ (RTT_NOM2 == "60") ? 3'b001 :
(RTT_NOM2 == "120") ? 3'b010 :
(RTT_NOM2 == "20") ? 3'b100 :
(RTT_NOM2 == "30") ? 3'b101 :
(RTT_NOM2 == "40") ? 3'b011:
3'b000;
tmp_mr2_r[2] <= #TCQ 2'b00;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011:
3'b000;
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r[1] == 1'b1)begin
phy_tmp_odt_r <=
#TCQ 4'b0001;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0100; // rank 2 ODT asserted
end
end else begin
if (// wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
if (chip_cnt_r[1] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0110;
end else begin
phy_tmp_odt_r <=
#TCQ 4'b0101;
end
end else if ((init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS)) begin
if (chip_cnt_r[1] == 1'b1) begin
phy_tmp_odt_r[(1*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ 4'b0010;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
end
end
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
end
// Two Slots - two ranks per slot
4'b11_11: begin
//Rank2 Rtt_NOM
tmp_mr1_r[2] <= #TCQ (RTT_NOM2 == "60") ? 3'b001 :
(RTT_NOM2 == "120") ? 3'b010 :
(RTT_NOM2 == "20") ? 3'b100 :
(RTT_NOM2 == "30") ? 3'b101 :
(RTT_NOM2 == "40") ? 3'b011 :
3'b000;
//Rank3 Rtt_NOM
tmp_mr1_r[3] <= #TCQ (RTT_NOM3 == "60") ? 3'b001 :
(RTT_NOM3 == "120") ? 3'b010 :
(RTT_NOM3 == "20") ? 3'b100 :
(RTT_NOM3 == "30") ? 3'b101 :
(RTT_NOM3 == "40") ? 3'b011 :
3'b000;
tmp_mr2_r[2] <= #TCQ 2'b00;
tmp_mr2_r[3] <= #TCQ 2'b00;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[1] <= #TCQ 3'b000;
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r[1] == 1'b1)begin
phy_tmp_odt_r
<= #TCQ 4'b0001;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
end
end else begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
//Slot1 Rank1 or Rank3 is being written
if (chip_cnt_r[0] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0110;
//Slot0 Rank0 or Rank2 is being written
end else begin
phy_tmp_odt_r
<= #TCQ 4'b1001;
end
end else if ((init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS))begin
//Slot1 Rank1 or Rank3 is being read
if (chip_cnt_r[0] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
//Slot0 Rank0 or Rank2 is being read
end else begin
phy_tmp_odt_r
<= #TCQ 4'b1000;
end
end
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
end
default: begin
phy_tmp_odt_r <= #TCQ 4'b1111;
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "60") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
end
end
endcase
end
end
end
endgenerate
// PHY only supports two ranks.
// calib_aux_out[0] is CKE for rank 0 and calib_aux_out[1] is ODT for rank 0
// calib_aux_out[2] is CKE for rank 1 and calib_aux_out[3] is ODT for rank 1
generate
if(CKE_ODT_AUX == "FALSE") begin
if ((nSLOTS == 1) && (RANKS < 2)) begin
always @(posedge clk)
if (rst) begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}} ;
calib_odt <= 2'b00 ;
end else begin
if (cnt_pwron_cke_done_r /*&& ~cnt_pwron_cke_done_r1*/)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b1}};
end else begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}};
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF"))/* ||
wrlvl_rank_done || wrlvl_rank_done_r1 ||
(wrlvl_done && !wrlvl_done_r)*/) && (DRAM_TYPE == "DDR3")) begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt ) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
complex_odt_ext ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
complex_ocal_odt_ext ||
(init_state_r == INIT_OCLKDELAY_WRITE)||
(init_state_r == INIT_OCLKDELAY_WRITE_WAIT))) begin
// Quad rank in a single slot
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 1) && (RANKS <= 2)) begin
always @(posedge clk)
if (rst) begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}} ;
calib_odt <= 2'b00 ;
end else begin
if (cnt_pwron_cke_done_r /*&& ~cnt_pwron_cke_done_r1*/)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b1}};
end else begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}};
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF"))/* ||
wrlvl_rank_done_r2 ||
(wrlvl_done && !wrlvl_done_r)*/) && (DRAM_TYPE == "DDR3")) begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt)||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
complex_odt_ext ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
complex_ocal_odt_ext ||
(init_state_r == INIT_OCLKDELAY_WRITE)||
(init_state_r == INIT_OCLKDELAY_WRITE_WAIT))) begin
// Dual rank in a single slot
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 2) && (RANKS == 2)) begin
always @(posedge clk)
if (rst)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}} ;
calib_odt <= 2'b00 ;
end else begin
if (cnt_pwron_cke_done_r /*&& ~cnt_pwron_cke_done_r1*/)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b1}};
end else begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}};
end
if (((DRAM_TYPE == "DDR2") && (RTT_NOM == "DISABLED")) ||
((DRAM_TYPE == "DDR3") &&
(RTT_NOM == "DISABLED") && (RTT_WR == "OFF"))) begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end else if (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// Quad rank in a single slot
if (nCK_PER_CLK == 2) begin
calib_odt[0]
<= #TCQ (!calib_odt[0]) ? phy_tmp_odt_r[0] : 1'b0;
calib_odt[1]
<= #TCQ (!calib_odt[1]) ? phy_tmp_odt_r[1] : 1'b0;
end else begin
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end
// Turn on for idle rank during read if dynamic ODT is enabled in DDR3
end else if(((DRAM_TYPE == "DDR3") && (RTT_WR != "OFF")) &&
((init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_MPR_READ) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS))) begin
if (nCK_PER_CLK == 2) begin
calib_odt[0]
<= #TCQ (!calib_odt[0]) ? phy_tmp_odt_r[0] : 1'b0;
calib_odt[1]
<= #TCQ (!calib_odt[1]) ? phy_tmp_odt_r[1] : 1'b0;
end else begin
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end
// disable well before next command and before disabling write leveling
end else if(cnt_cmd_done_m7_r ||
(init_state_r == INIT_WRLVL_WAIT && ~wrlvl_odt))
calib_odt <= #TCQ 2'b00;
end
end
end else begin//USE AUX OUTPUT for routing CKE and ODT.
if ((nSLOTS == 1) && (RANKS < 2)) begin
always @(posedge clk)
if (rst) begin
calib_aux_out <= #TCQ 4'b0000;
end else begin
if (cnt_pwron_cke_done_r && ~cnt_pwron_cke_done_r1)begin
calib_aux_out[0] <= #TCQ 1'b1;
calib_aux_out[2] <= #TCQ 1'b1;
end else begin
calib_aux_out[0] <= #TCQ 1'b0;
calib_aux_out[2] <= #TCQ 1'b0;
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF")) ||
wrlvl_rank_done || wrlvl_rank_done_r1 ||
(wrlvl_done && !wrlvl_done_r)) && (DRAM_TYPE == "DDR3")) begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE))) begin
// Quad rank in a single slot
calib_aux_out[1] <= #TCQ phy_tmp_odt_r[0];
calib_aux_out[3] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 1) && (RANKS <= 2)) begin
always @(posedge clk)
if (rst) begin
calib_aux_out <= #TCQ 4'b0000;
end else begin
if (cnt_pwron_cke_done_r && ~cnt_pwron_cke_done_r1)begin
calib_aux_out[0] <= #TCQ 1'b1;
calib_aux_out[2] <= #TCQ 1'b1;
end else begin
calib_aux_out[0] <= #TCQ 1'b0;
calib_aux_out[2] <= #TCQ 1'b0;
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF")) ||
wrlvl_rank_done_r2 ||
(wrlvl_done && !wrlvl_done_r)) && (DRAM_TYPE == "DDR3")) begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE))) begin
// Dual rank in a single slot
calib_aux_out[1] <= #TCQ phy_tmp_odt_r[0];
calib_aux_out[3] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 2) && (RANKS == 2)) begin
always @(posedge clk)
if (rst)
calib_aux_out <= #TCQ 4'b0000;
else begin
if (cnt_pwron_cke_done_r && ~cnt_pwron_cke_done_r1)begin
calib_aux_out[0] <= #TCQ 1'b1;
calib_aux_out[2] <= #TCQ 1'b1;
end else begin
calib_aux_out[0] <= #TCQ 1'b0;
calib_aux_out[2] <= #TCQ 1'b0;
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF")) ||
wrlvl_rank_done_r2 ||
(wrlvl_done && !wrlvl_done_r)) && (DRAM_TYPE == "DDR3")) begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE))) begin
// Quad rank in a single slot
if (nCK_PER_CLK == 2) begin
calib_aux_out[1]
<= #TCQ (!calib_aux_out[1]) ? phy_tmp_odt_r[0] : 1'b0;
calib_aux_out[3]
<= #TCQ (!calib_aux_out[3]) ? phy_tmp_odt_r[1] : 1'b0;
end else begin
calib_aux_out[1] <= #TCQ phy_tmp_odt_r[0];
calib_aux_out[3] <= #TCQ phy_tmp_odt_r[1];
end
end else begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end
end
end
end
endgenerate
//*****************************************************************
// memory address during init
//*****************************************************************
always @(posedge clk)
phy_data_full_r <= #TCQ phy_data_full;
// verilint STARC-2.7.3.3b off
always @(*)begin
// Bus 0 for address/bank never used
address_w = 'b0;
bank_w = 'b0;
if ((init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_DDR2_PRECHARGE)) begin
// Set A10=1 for ZQ long calibration or Precharge All
address_w = 'b0;
address_w[10] = 1'b1;
bank_w = 'b0;
end else if (init_state_r == INIT_WRLVL_START) begin
// Enable wrlvl in MR1
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[2] = mr1_r[chip_cnt_r][0];
address_w[6] = mr1_r[chip_cnt_r][1];
address_w[9] = mr1_r[chip_cnt_r][2];
address_w[7] = 1'b1;
end else if (init_state_r == INIT_WRLVL_LOAD_MR) begin
// Finished with write leveling, disable wrlvl in MR1
// For single rank disable Rtt_Nom
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[2] = mr1_r[chip_cnt_r][0];
address_w[6] = mr1_r[chip_cnt_r][1];
address_w[9] = mr1_r[chip_cnt_r][2];
end else if (init_state_r == INIT_WRLVL_LOAD_MR2) begin
// Set RTT_WR in MR2 after write leveling disabled
bank_w[1:0] = 2'b10;
address_w = load_mr2[ROW_WIDTH-1:0];
address_w[10:9] = mr2_r[chip_cnt_r];
end else if (init_state_r == INIT_MPR_READ) begin
address_w = 'b0;
bank_w = 'b0;
end else if (init_state_r == INIT_MPR_RDEN) begin
// Enable MPR read with LMR3 and A2=1
bank_w[BANK_WIDTH-1:0] = 'd3;
address_w = {ROW_WIDTH{1'b0}};
address_w[2] = 1'b1;
end else if (init_state_r == INIT_MPR_DISABLE) begin
// Disable MPR read with LMR3 and A2=0
bank_w[BANK_WIDTH-1:0] = 'd3;
address_w = {ROW_WIDTH{1'b0}};
end else if ((init_state_r == INIT_REG_WRITE)&
(DRAM_TYPE == "DDR3"))begin
// bank_w is assigned a 3 bit value. In some
// DDR2 cases there will be only two bank bits.
//Qualifying the condition with DDR3
bank_w = 'b0;
address_w = 'b0;
case (reg_ctrl_cnt_r)
4'h1:begin
address_w[4:0] = REG_RC1[4:0];
bank_w = REG_RC1[7:5];
end
4'h2: address_w[4:0] = REG_RC2[4:0];
4'h3: begin
address_w[4:0] = REG_RC3[4:0];
bank_w = REG_RC3[7:5];
end
4'h4: begin
address_w[4:0] = REG_RC4[4:0];
bank_w = REG_RC4[7:5];
end
4'h5: begin
address_w[4:0] = REG_RC5[4:0];
bank_w = REG_RC5[7:5];
end
4'h6: begin
address_w[4:0] = REG_RC10[4:0];
bank_w = REG_RC10[7:5];
end
4'h7: begin
address_w[4:0] = REG_RC11[4:0];
bank_w = REG_RC11[7:5];
end
default: address_w[4:0] = REG_RC0[4:0];
endcase
end else if (init_state_r == INIT_LOAD_MR) begin
// If loading mode register, look at cnt_init_mr to determine
// which MR is currently being programmed
address_w = 'b0;
bank_w = 'b0;
if(DRAM_TYPE == "DDR3")begin
if(rdlvl_stg1_done && prbs_rdlvl_done && pi_dqs_found_done)begin
// end of the calibration programming correct
// burst length
if (TEST_AL == "0") begin
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
address_w[8]= 1'b0; //Don't reset DLL
end else begin
// programming correct AL value
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
if (TEST_AL == "CL-1")
address_w[4:3]= 2'b01; // AL="CL-1"
else
address_w[4:3]= 2'b10; // AL="CL-2"
end
end else begin
case (cnt_init_mr_r)
INIT_CNT_MR2: begin
bank_w[1:0] = 2'b10;
address_w = load_mr2[ROW_WIDTH-1:0];
address_w[10:9] = mr2_r[chip_cnt_r];
end
INIT_CNT_MR3: begin
bank_w[1:0] = 2'b11;
address_w = load_mr3[ROW_WIDTH-1:0];
end
INIT_CNT_MR1: begin
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[2] = mr1_r[chip_cnt_r][0];
address_w[6] = mr1_r[chip_cnt_r][1];
address_w[9] = mr1_r[chip_cnt_r][2];
end
INIT_CNT_MR0: begin
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
// fixing it to BL8 for calibration
address_w[1:0] = 2'b00;
end
default: begin
bank_w = {BANK_WIDTH{1'bx}};
address_w = {ROW_WIDTH{1'bx}};
end
endcase
end
end else begin // DDR2
case (cnt_init_mr_r)
INIT_CNT_MR2: begin
if(~ddr2_refresh_flag_r)begin
bank_w[1:0] = 2'b10;
address_w = load_mr2[ROW_WIDTH-1:0];
end else begin // second set of lm commands
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
address_w[8]= 1'b0;
//MRS command without resetting DLL
end
end
INIT_CNT_MR3: begin
if(~ddr2_refresh_flag_r)begin
bank_w[1:0] = 2'b11;
address_w = load_mr3[ROW_WIDTH-1:0];
end else begin // second set of lm commands
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
address_w[8]= 1'b0;
//MRS command without resetting DLL. Repeted again
// because there is an extra state.
end
end
INIT_CNT_MR1: begin
bank_w[1:0] = 2'b01;
if(~ddr2_refresh_flag_r)begin
address_w = load_mr1[ROW_WIDTH-1:0];
end else begin // second set of lm commands
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[9:7] = 3'b111;
//OCD default state
end
end
INIT_CNT_MR0: begin
if(~ddr2_refresh_flag_r)begin
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
end else begin // second set of lm commands
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
if((chip_cnt_r == 2'd1) || (chip_cnt_r == 2'd3))begin
// always disable odt for rank 1 and rank 3 as per SPEC
address_w[2] = 'b0;
address_w[6] = 'b0;
end
//OCD exit
end
end
default: begin
bank_w = {BANK_WIDTH{1'bx}};
address_w = {ROW_WIDTH{1'bx}};
end
endcase
end
end else if ( ~prbs_rdlvl_done && ((init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ))) begin
// Writing and reading PRBS pattern for read leveling stage 1
// Need to support burst length 4 or 8. PRBS pattern will be
// written to entire row and read back from the same row repeatedly
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if (((stg1_wr_rd_cnt == NUM_STG1_WR_RD) && ~rdlvl_stg1_done) || (stg1_wr_rd_cnt == 'd127) ||
((stg1_wr_rd_cnt == 'd22) && (((init_state_r1 != INIT_RDLVL_STG1_WRITE) && ~stg1_wr_done) || complex_row0_rd_done))) begin
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
end else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((stg1_wr_rd_cnt >= 9'd0) && new_burst_r && ~phy_data_full_r) begin
if ((init_state_r == INIT_RDLVL_COMPLEX_READ) && (init_state_r1 != INIT_RDLVL_COMPLEX_READ) )// ||
// ((init_state_r == INIT_RDLVL_STG1_WRITE) && prbs_rdlvl_done) )
address_w[COL_WIDTH-1:0] = complex_address[COL_WIDTH-1:0] + ADDR_INC;
else
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end
//need to add address for complex oclkdelay calib
end else if (prbs_rdlvl_done && ((init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ))) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if ((stg1_wr_rd_cnt == 'd127) || ((stg1_wr_rd_cnt == 'd30) && (((init_state_r1 != INIT_RDLVL_STG1_WRITE) && ~stg1_wr_done) || complex_row0_rd_done))) begin
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
end else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((stg1_wr_rd_cnt >= 9'd0) && new_burst_r && ~phy_data_full_r) begin
if ((init_state_r == INIT_RDLVL_STG1_WRITE) && (init_state_r1 != INIT_RDLVL_STG1_WRITE) )
// ((init_state_r == INIT_RDLVL_STG1_WRITE) && prbs_rdlvl_done) )
address_w[COL_WIDTH-1:0] = complex_address[COL_WIDTH-1:0] + ADDR_INC;
else
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end
end else if ((init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_READ)) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if (oclk_wr_cnt == NUM_STG1_WR_RD)
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((oclk_wr_cnt >= 4'd0) && new_burst_r && ~phy_data_full_r)
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end else if ((init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_READ)) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if (wrcal_wr_cnt == NUM_STG1_WR_RD)
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((wrcal_wr_cnt >= 4'd0) && new_burst_r && ~phy_data_full_r)
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end else if ((init_state_r == INIT_WRCAL_MULT_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ)) begin
// when writing or reading back training pattern for read leveling stage2
// need to support burst length of 4 or 8. This may mean issuing
// multiple commands to cover the entire range of addresses accessed
// during read leveling.
// Hard coding A[12] to 1 so that it will always be burst length of 8
// for DDR3. Does not have any effect on DDR2.
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
address_w[COL_WIDTH-1:0] =
{CALIB_COL_ADD[COL_WIDTH-1:3],burst_addr_r, 3'b000};
address_w[12] = 1'b1;
end else if ((init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT)) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
//if (stg1_wr_rd_cnt == 'd22)
// address_w = CALIB_ROW_ADD[ROW_WIDTH-1:0] + 1;
//else
address_w = prbs_rdlvl_done ? CALIB_ROW_ADD[ROW_WIDTH-1:0] + complex_row_cnt_ocal :
CALIB_ROW_ADD[ROW_WIDTH-1:0] + complex_row_cnt;
end else begin
bank_w = {BANK_WIDTH{1'bx}};
address_w = {ROW_WIDTH{1'bx}};
end
end
// verilint STARC-2.7.3.3b on
// registring before sending out
generate
genvar r,s;
if ((DRAM_TYPE != "DDR3") || (CA_MIRROR != "ON")) begin: gen_no_mirror
for (r = 0; r < nCK_PER_CLK; r = r + 1) begin: div_clk_loop
always @(posedge clk) begin
phy_address[(r*ROW_WIDTH) +: ROW_WIDTH] <= #TCQ address_w;
phy_bank[(r*BANK_WIDTH) +: BANK_WIDTH] <= #TCQ bank_w;
end
end
end else begin: gen_mirror
// Control/addressing mirroring (optional for DDR3 dual rank DIMMs)
// Mirror for the 2nd rank only. Logic needs to be enhanced to account
// for multiple slots, currently only supports one slot, 2-rank config
for (r = 0; r < nCK_PER_CLK; r = r + 1) begin: gen_ba_div_clk_loop
for (s = 0; s < BANK_WIDTH; s = s + 1) begin: gen_ba
always @(posedge clk)
if (chip_cnt_r == 2'b00) begin
phy_bank[(r*BANK_WIDTH) + s] <= #TCQ bank_w[s];
end else begin
phy_bank[(r*BANK_WIDTH) + s] <= #TCQ bank_w[(s == 0) ? 1 : ((s == 1) ? 0 : s)];
end
end
end
for (r = 0; r < nCK_PER_CLK; r = r + 1) begin: gen_addr_div_clk_loop
for (s = 0; s < ROW_WIDTH; s = s + 1) begin: gen_addr
always @(posedge clk)
if (chip_cnt_r == 2'b00) begin
phy_address[(r*ROW_WIDTH) + s] <= #TCQ address_w[s];
end else begin
phy_address[(r*ROW_WIDTH) + s] <= #TCQ address_w[
(s == 3) ? 4 :
((s == 4) ? 3 :
((s == 5) ? 6 :
((s == 6) ? 5 :
((s == 7) ? 8 :
((s == 8) ? 7 : s)))))];
end
end
end
end
endgenerate
endmodule
|
module mig_7series_v2_3_ddr_phy_init #
(
parameter tCK = 1500, // DDRx SDRAM clock period
parameter TCQ = 100,
parameter nCK_PER_CLK = 4, // # of memory clocks per CLK
parameter CLK_PERIOD = 3000, // Logic (internal) clk period (in ps)
parameter USE_ODT_PORT = 0, // 0 - No ODT output from FPGA
// 1 - ODT output from FPGA
parameter DDR3_VDD_OP_VOLT = "150", // Voltage mode used for DDR3
// 150 - 1.50 V
// 135 - 1.35 V
// 125 - 1.25 V
parameter VREF = "EXTERNAL", // Internal or external Vref
parameter PRBS_WIDTH = 8, // PRBS sequence = 2^PRBS_WIDTH
parameter BANK_WIDTH = 2,
parameter CA_MIRROR = "OFF", // C/A mirror opt for DDR3 dual rank
parameter COL_WIDTH = 10,
parameter nCS_PER_RANK = 1, // # of CS bits per rank e.g. for
// component I/F with CS_WIDTH=1,
// nCS_PER_RANK=# of components
parameter DQ_WIDTH = 64,
parameter DQS_WIDTH = 8,
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter ROW_WIDTH = 14,
parameter CS_WIDTH = 1,
parameter RANKS = 1, // # of memory ranks in the interface
parameter CKE_WIDTH = 1, // # of cke outputs
parameter DRAM_TYPE = "DDR3",
parameter REG_CTRL = "ON",
parameter ADDR_CMD_MODE= "1T",
// calibration Address
parameter CALIB_ROW_ADD = 16'h0000,// Calibration row address
parameter CALIB_COL_ADD = 12'h000, // Calibration column address
parameter CALIB_BA_ADD = 3'h0, // Calibration bank address
// DRAM mode settings
parameter AL = "0", // Additive Latency option
parameter BURST_MODE = "8", // Burst length
parameter BURST_TYPE = "SEQ", // Burst type
// parameter nAL = 0, // Additive latency (in clk cyc)
parameter nCL = 5, // Read CAS latency (in clk cyc)
parameter nCWL = 5, // Write CAS latency (in clk cyc)
parameter tRFC = 110000, // Refresh-to-command delay (in ps)
parameter REFRESH_TIMER = 1553, // Refresh interval in fabrci cycles between 8 posted refreshes
parameter REFRESH_TIMER_WIDTH = 8,
parameter OUTPUT_DRV = "HIGH", // DRAM reduced output drive option
parameter RTT_NOM = "60", // Nominal ODT termination value
parameter RTT_WR = "60", // Write ODT termination value
parameter WRLVL = "ON", // Enable write leveling
// parameter PHASE_DETECT = "ON", // Enable read phase detector
parameter DDR2_DQSN_ENABLE = "YES", // Enable differential DQS for DDR2
parameter nSLOTS = 1, // Number of DIMM SLOTs in the system
parameter SIM_INIT_OPTION = "NONE", // "NONE", "SKIP_PU_DLY", "SKIP_INIT"
parameter SIM_CAL_OPTION = "NONE", // "NONE", "FAST_CAL", "SKIP_CAL"
parameter CKE_ODT_AUX = "FALSE",
parameter PRE_REV3ES = "OFF", // Enable TG error detection during calibration
parameter TEST_AL = "0", // Internal use for ICM verification
parameter FIXED_VICTIM = "TRUE",
parameter BYPASS_COMPLEX_OCAL = "FALSE"
)
(
input clk,
input rst,
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] prbs_o,
input delay_incdec_done,
input ck_addr_cmd_delay_done,
input pi_phase_locked_all,
input pi_dqs_found_done,
input dqsfound_retry,
input dqs_found_prech_req,
output reg pi_phaselock_start,
output pi_phase_locked_err,
output pi_calib_done,
input phy_if_empty,
// Read/write calibration interface
input wrlvl_done,
input wrlvl_rank_done,
input wrlvl_byte_done,
input wrlvl_byte_redo,
input wrlvl_final,
output reg wrlvl_final_if_rst,
input oclkdelay_calib_done,
input oclk_prech_req,
input oclk_calib_resume,
input lim_done,
input lim_wr_req,
output reg oclkdelay_calib_start,
//complex oclkdelay calibration
input complex_oclkdelay_calib_done,
input complex_oclk_prech_req,
input complex_oclk_calib_resume,
output reg complex_oclkdelay_calib_start,
input [DQS_CNT_WIDTH:0] complex_oclkdelay_calib_cnt, // same as oclkdelay_calib_cnt
output reg complex_ocal_num_samples_inc,
input complex_ocal_num_samples_done_r,
input [2:0] complex_ocal_rd_victim_sel,
output reg complex_ocal_reset_rd_addr,
input complex_ocal_ref_req,
output reg complex_ocal_ref_done,
input done_dqs_tap_inc,
input [5:0] rd_data_offset_0,
input [5:0] rd_data_offset_1,
input [5:0] rd_data_offset_2,
input [6*RANKS-1:0] rd_data_offset_ranks_0,
input [6*RANKS-1:0] rd_data_offset_ranks_1,
input [6*RANKS-1:0] rd_data_offset_ranks_2,
input pi_dqs_found_rank_done,
input wrcal_done,
input wrcal_prech_req,
input wrcal_read_req,
input wrcal_act_req,
input temp_wrcal_done,
input [7:0] slot_0_present,
input [7:0] slot_1_present,
output reg wl_sm_start,
output reg wr_lvl_start,
output reg wrcal_start,
output reg wrcal_rd_wait,
output reg wrcal_sanity_chk,
output reg tg_timer_done,
output reg no_rst_tg_mc,
input rdlvl_stg1_done,
input rdlvl_stg1_rank_done,
output reg rdlvl_stg1_start,
output reg pi_dqs_found_start,
output reg detect_pi_found_dqs,
// rdlvl stage 1 precharge requested after each DQS
input rdlvl_prech_req,
input rdlvl_last_byte_done,
input wrcal_resume,
input wrcal_sanity_chk_done,
// MPR read leveling
input mpr_rdlvl_done,
input mpr_rnk_done,
input mpr_last_byte_done,
output reg mpr_rdlvl_start,
output reg mpr_end_if_reset,
// PRBS Read Leveling
input prbs_rdlvl_done,
input prbs_last_byte_done,
input prbs_rdlvl_prech_req,
input complex_victim_inc,
input [2:0] rd_victim_sel,
input [DQS_CNT_WIDTH:0] pi_stg2_prbs_rdlvl_cnt,
output reg [2:0] victim_sel,
output reg [DQS_CNT_WIDTH:0]victim_byte_cnt,
output reg prbs_rdlvl_start,
output reg prbs_gen_clk_en,
output reg prbs_gen_oclk_clk_en,
output reg complex_sample_cnt_inc,
output reg complex_sample_cnt_inc_ocal,
output reg complex_wr_done,
// Signals shared btw multiple calibration stages
output reg prech_done,
// Data select / status
output reg init_calib_complete,
// Signal to mask memory model error for Invalid latching edge
output reg calib_writes,
// PHY address/control
// 2 commands to PHY Control Block per div 2 clock in 2:1 mode
// 4 commands to PHY Control Block per div 4 clock in 4:1 mode
output reg [nCK_PER_CLK*ROW_WIDTH-1:0] phy_address,
output reg [nCK_PER_CLK*BANK_WIDTH-1:0]phy_bank,
output reg [nCK_PER_CLK-1:0] phy_ras_n,
output reg [nCK_PER_CLK-1:0] phy_cas_n,
output reg [nCK_PER_CLK-1:0] phy_we_n,
output reg phy_reset_n,
output [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] phy_cs_n,
// Hard PHY Interface signals
input phy_ctl_ready,
input phy_ctl_full,
input phy_cmd_full,
input phy_data_full,
output reg calib_ctl_wren,
output reg calib_cmd_wren,
output reg [1:0] calib_seq,
output reg write_calib,
output reg read_calib,
// PHY_Ctl_Wd
output reg [2:0] calib_cmd,
// calib_aux_out used for CKE and ODT
output reg [3:0] calib_aux_out,
output reg [1:0] calib_odt ,
output reg [nCK_PER_CLK-1:0] calib_cke ,
output [1:0] calib_rank_cnt,
output reg [1:0] calib_cas_slot,
output reg [5:0] calib_data_offset_0,
output reg [5:0] calib_data_offset_1,
output reg [5:0] calib_data_offset_2,
// PHY OUT_FIFO
output reg calib_wrdata_en,
output reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] phy_wrdata,
// PHY Read
output phy_rddata_en,
output phy_rddata_valid,
output [255:0] dbg_phy_init,
input read_pause,
input reset_rd_addr,
//OCAL centering calibration
input oclkdelay_center_calib_start,
input oclk_center_write_resume,
input oclkdelay_center_calib_done
);
//*****************************************************************************
// Assertions to be added
//*****************************************************************************
// The phy_ctl_full signal must never be asserted in synchronous mode of
// operation either 4:1 or 2:1
//
// The RANKS parameter must never be set to '0' by the user
// valid values: 1 to 4
//
//*****************************************************************************
//***************************************************************************
// Number of Read level stage 1 writes limited to a SDRAM row
// The address of Read Level stage 1 reads must also be limited
// to a single SDRAM row
// (2^COL_WIDTH)/BURST_MODE = (2^10)/8 = 128
localparam NUM_STG1_WR_RD = (BURST_MODE == "8") ? 4 :
(BURST_MODE == "4") ? 8 : 4;
localparam ADDR_INC = (BURST_MODE == "8") ? 8 :
(BURST_MODE == "4") ? 4 : 8;
// In a 2 slot dual rank per system RTT_NOM values
// for Rank2 and Rank3 default to 40 ohms
localparam RTT_NOM2 = "40";
localparam RTT_NOM3 = "40";
localparam RTT_NOM_int = (USE_ODT_PORT == 1) ? RTT_NOM : RTT_WR;
// Specifically for use with half-frequency controller (nCK_PER_CLK=2)
// = 1 if burst length = 4, = 0 if burst length = 8. Determines how
// often row command needs to be issued during read-leveling
// For DDR3 the burst length is fixed during calibration
localparam BURST4_FLAG = (DRAM_TYPE == "DDR3")? 1'b0 :
(BURST_MODE == "8") ? 1'b0 :
((BURST_MODE == "4") ? 1'b1 : 1'b0);
//***************************************************************************
// Counter values used to determine bus timing
// NOTE on all counter terminal counts - these can/should be one less than
// the actual delay to take into account extra clock cycle delay in
// generating the corresponding "done" signal
//***************************************************************************
localparam CLK_MEM_PERIOD = CLK_PERIOD / nCK_PER_CLK;
// Calculate initial delay required in number of CLK clock cycles
// to delay initially. The counter is clocked by [CLK/1024] - which
// is approximately division by 1000 - note that the formulas below will
// result in more than the minimum wait time because of this approximation.
// NOTE: For DDR3 JEDEC specifies to delay reset
// by 200us, and CKE by an additional 500us after power-up
// For DDR2 CKE is delayed by 200us after power up.
localparam DDR3_RESET_DELAY_NS = 200000;
localparam DDR3_CKE_DELAY_NS = 500000 + DDR3_RESET_DELAY_NS;
localparam DDR2_CKE_DELAY_NS = 200000;
localparam PWRON_RESET_DELAY_CNT =
((DDR3_RESET_DELAY_NS+CLK_PERIOD-1)/CLK_PERIOD);
localparam PWRON_CKE_DELAY_CNT = (DRAM_TYPE == "DDR3") ?
(((DDR3_CKE_DELAY_NS+CLK_PERIOD-1)/CLK_PERIOD)) :
(((DDR2_CKE_DELAY_NS+CLK_PERIOD-1)/CLK_PERIOD));
// FOR DDR2 -1 taken out. With -1 not getting 200us. The equation
// needs to be reworked.
localparam DDR2_INIT_PRE_DELAY_PS = 400000;
localparam DDR2_INIT_PRE_CNT =
((DDR2_INIT_PRE_DELAY_PS+CLK_PERIOD-1)/CLK_PERIOD)-1;
// Calculate tXPR time: reset from CKE HIGH to valid command after power-up
// tXPR = (max(5nCK, tRFC(min)+10ns). Add a few (blah, messy) more clock
// cycles because this counter actually starts up before CKE is asserted
// to memory.
localparam TXPR_DELAY_CNT =
(5*CLK_MEM_PERIOD > tRFC+10000) ?
(((5+nCK_PER_CLK-1)/nCK_PER_CLK)-1)+11 :
(((tRFC+10000+CLK_PERIOD-1)/CLK_PERIOD)-1)+11;
// tDLLK/tZQINIT time = 512*tCK = 256*tCLKDIV
localparam TDLLK_TZQINIT_DELAY_CNT = 255;
// TWR values in ns. Both DDR2 and DDR3 have the same value.
// 15000ns/tCK
localparam TWR_CYC = ((15000) % CLK_MEM_PERIOD) ?
(15000/CLK_MEM_PERIOD) + 1 : 15000/CLK_MEM_PERIOD;
// time to wait between consecutive commands in PHY_INIT - this is a
// generic number, and must be large enough to account for worst case
// timing parameter (tRFC - refresh-to-active) across all memory speed
// grades and operating frequencies. Expressed in clk
// (Divided by 4 or Divided by 2) clock cycles.
localparam CNTNEXT_CMD = 7'b1111111;
// Counter values to keep track of which MR register to load during init
// Set value of INIT_CNT_MR_DONE to equal value of counter for last mode
// register configured during initialization.
// NOTE: Reserve more bits for DDR2 - more MR accesses for DDR2 init
localparam INIT_CNT_MR2 = 2'b00;
localparam INIT_CNT_MR3 = 2'b01;
localparam INIT_CNT_MR1 = 2'b10;
localparam INIT_CNT_MR0 = 2'b11;
localparam INIT_CNT_MR_DONE = 2'b11;
// Register chip programmable values for DDR3
// The register chip for the registered DIMM needs to be programmed
// before the initialization of the registered DIMM.
// Address for the control word is in : DBA2, DA2, DA1, DA0
// Data for the control word is in: DBA1 DBA0, DA4, DA3
// The values will be stored in the local param in the following format
// {DBA[2:0], DA[4:0]}
// RC0 is global features control word. Address == 000
localparam REG_RC0 = 8'b00000000;
// RC1 Clock driver enable control word. Enables or disables the four
// output clocks in the register chip. For single rank and dual rank
// two clocks will be enabled and for quad rank all the four clocks
// will be enabled. Address == 000. Data = 0110 for single and dual rank.
// = 0000 for quad rank
localparam REG_RC1 = 8'b00000001;
// RC2 timing control word. Set in 1T timing mode
// Address = 010. Data = 0000
localparam REG_RC2 = 8'b00000010;
// RC3 timing control word. Setting the data based on number of RANKS (inturn the number of loads)
// This setting is specific to RDIMMs from Micron Technology
localparam REG_RC3 = (RANKS >= 2) ? 8'b00101011 : 8'b00000011;
// RC4 timing control work. Setting the data based on number of RANKS (inturn the number of loads)
// This setting is specific to RDIMMs from Micron Technology
localparam REG_RC4 = (RANKS >= 2) ? 8'b00101100 : 8'b00000100;
// RC5 timing control work. Setting the data based on number of RANKS (inturn the number of loads)
// This setting is specific to RDIMMs from Micron Technology
localparam REG_RC5 = (RANKS >= 2) ? 8'b00101101 : 8'b00000101;
// RC10 timing control work. Setting the data to 0000
localparam [3:0] FREQUENCY_ENCODING = (tCK >= 1072 && tCK < 1250) ? 4'b0100 :
(tCK >= 1250 && tCK < 1500) ? 4'b0011 :
(tCK >= 1500 && tCK < 1875) ? 4'b0010 :
(tCK >= 1875 && tCK < 2500) ? 4'b0001 : 4'b0000;
localparam REG_RC10 = {1'b1,FREQUENCY_ENCODING,3'b010};
localparam VREF_ENCODING = (VREF == "INTERNAL") ? 1'b1 : 1'b0;
localparam [3:0] DDR3_VOLTAGE_ENCODING = (DDR3_VDD_OP_VOLT == "125") ? {1'b0,VREF_ENCODING,2'b10} :
(DDR3_VDD_OP_VOLT == "135") ? {1'b0,VREF_ENCODING,2'b01} :
{1'b0,VREF_ENCODING,2'b00} ;
localparam REG_RC11 = {1'b1,DDR3_VOLTAGE_ENCODING,3'b011};
// For non-zero AL values
localparam nAL = (AL == "CL-1") ? nCL - 1 : 0;
// Adding the register dimm latency to write latency
localparam CWL_M = (REG_CTRL == "ON") ? nCWL + nAL + 1 : nCWL + nAL;
// Count value to generate pi_phase_locked_err signal
localparam PHASELOCKED_TIMEOUT = (SIM_CAL_OPTION == "NONE") ? 16383 : 1000;
// Timeout interval for detecting error with Traffic Generator
localparam [13:0] TG_TIMER_TIMEOUT
= (SIM_CAL_OPTION == "NONE") ? 14'h3FFF : 14'h0001;
//bit num per DQS
localparam DQ_PER_DQS = DQ_WIDTH/DQS_WIDTH;
//COMPLEX_ROW_CNT_BYTE
localparam COMPLEX_ROW_CNT_BYTE = (FIXED_VICTIM=="FALSE")? DQ_PER_DQS*2: 2;
localparam COMPLEX_RD = (FIXED_VICTIM=="FALSE")? DQ_PER_DQS : 1;
// Master state machine encoding
localparam INIT_IDLE = 7'b0000000; //0
localparam INIT_WAIT_CKE_EXIT = 7'b0000001; //1
localparam INIT_LOAD_MR = 7'b0000010; //2
localparam INIT_LOAD_MR_WAIT = 7'b0000011; //3
localparam INIT_ZQCL = 7'b0000100; //4
localparam INIT_WAIT_DLLK_ZQINIT = 7'b0000101; //5
localparam INIT_WRLVL_START = 7'b0000110; //6
localparam INIT_WRLVL_WAIT = 7'b0000111; //7
localparam INIT_WRLVL_LOAD_MR = 7'b0001000; //8
localparam INIT_WRLVL_LOAD_MR_WAIT = 7'b0001001; //9
localparam INIT_WRLVL_LOAD_MR2 = 7'b0001010; //A
localparam INIT_WRLVL_LOAD_MR2_WAIT = 7'b0001011; //B
localparam INIT_RDLVL_ACT = 7'b0001100; //C
localparam INIT_RDLVL_ACT_WAIT = 7'b0001101; //D
localparam INIT_RDLVL_STG1_WRITE = 7'b0001110; //E
localparam INIT_RDLVL_STG1_WRITE_READ = 7'b0001111; //F
localparam INIT_RDLVL_STG1_READ = 7'b0010000; //10
localparam INIT_RDLVL_STG2_READ = 7'b0010001; //11
localparam INIT_RDLVL_STG2_READ_WAIT = 7'b0010010; //12
localparam INIT_PRECHARGE_PREWAIT = 7'b0010011; //13
localparam INIT_PRECHARGE = 7'b0010100; //14
localparam INIT_PRECHARGE_WAIT = 7'b0010101; //15
localparam INIT_DONE = 7'b0010110; //16
localparam INIT_DDR2_PRECHARGE = 7'b0010111; //17
localparam INIT_DDR2_PRECHARGE_WAIT = 7'b0011000; //18
localparam INIT_REFRESH = 7'b0011001; //19
localparam INIT_REFRESH_WAIT = 7'b0011010; //1A
localparam INIT_REG_WRITE = 7'b0011011; //1B
localparam INIT_REG_WRITE_WAIT = 7'b0011100; //1C
localparam INIT_DDR2_MULTI_RANK = 7'b0011101; //1D
localparam INIT_DDR2_MULTI_RANK_WAIT = 7'b0011110; //1E
localparam INIT_WRCAL_ACT = 7'b0011111; //1F
localparam INIT_WRCAL_ACT_WAIT = 7'b0100000; //20
localparam INIT_WRCAL_WRITE = 7'b0100001; //21
localparam INIT_WRCAL_WRITE_READ = 7'b0100010; //22
localparam INIT_WRCAL_READ = 7'b0100011; //23
localparam INIT_WRCAL_READ_WAIT = 7'b0100100; //24
localparam INIT_WRCAL_MULT_READS = 7'b0100101; //25
localparam INIT_PI_PHASELOCK_READS = 7'b0100110; //26
localparam INIT_MPR_RDEN = 7'b0100111; //27
localparam INIT_MPR_WAIT = 7'b0101000; //28
localparam INIT_MPR_READ = 7'b0101001; //29
localparam INIT_MPR_DISABLE_PREWAIT = 7'b0101010; //2A
localparam INIT_MPR_DISABLE = 7'b0101011; //2B
localparam INIT_MPR_DISABLE_WAIT = 7'b0101100; //2C
localparam INIT_OCLKDELAY_ACT = 7'b0101101; //2D
localparam INIT_OCLKDELAY_ACT_WAIT = 7'b0101110; //2E
localparam INIT_OCLKDELAY_WRITE = 7'b0101111; //2F
localparam INIT_OCLKDELAY_WRITE_WAIT = 7'b0110000; //30
localparam INIT_OCLKDELAY_READ = 7'b0110001; //31
localparam INIT_OCLKDELAY_READ_WAIT = 7'b0110010; //32
localparam INIT_REFRESH_RNK2_WAIT = 7'b0110011; //33
localparam INIT_RDLVL_COMPLEX_PRECHARGE = 7'b0110100; //34
localparam INIT_RDLVL_COMPLEX_PRECHARGE_WAIT = 7'b0110101; //35
localparam INIT_RDLVL_COMPLEX_ACT = 7'b0110110; //36
localparam INIT_RDLVL_COMPLEX_ACT_WAIT = 7'b0110111; //37
localparam INIT_RDLVL_COMPLEX_READ = 7'b0111000; //38
localparam INIT_RDLVL_COMPLEX_READ_WAIT = 7'b0111001; //39
localparam INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT = 7'b0111010; //3A
localparam INIT_OCAL_COMPLEX_ACT = 7'b0111011; //3B
localparam INIT_OCAL_COMPLEX_ACT_WAIT = 7'b0111100; //3C
localparam INIT_OCAL_COMPLEX_WRITE_WAIT = 7'b0111101; //3D
localparam INIT_OCAL_COMPLEX_RESUME_WAIT = 7'b0111110; //3E
localparam INIT_OCAL_CENTER_ACT = 7'b0111111; //3F
localparam INIT_OCAL_CENTER_WRITE = 7'b1000000; //40
localparam INIT_OCAL_CENTER_WRITE_WAIT = 7'b1000001; //41
localparam INIT_OCAL_CENTER_ACT_WAIT = 7'b1000010; //42
integer i, j, k, l, m, n, p, q;
reg pi_dqs_found_all_r;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r1;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r2;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r3;
(* ASYNC_REG = "TRUE" *) reg pi_phase_locked_all_r4;
reg pi_calib_rank_done_r;
reg [13:0] pi_phaselock_timer;
reg stg1_wr_done;
reg rnk_ref_cnt;
reg pi_dqs_found_done_r1;
reg pi_dqs_found_rank_done_r;
reg read_calib_int;
reg read_calib_r;
reg pi_calib_done_r;
reg pi_calib_done_r1;
reg burst_addr_r;
reg [1:0] chip_cnt_r;
reg [6:0] cnt_cmd_r;
reg cnt_cmd_done_r;
reg cnt_cmd_done_m7_r;
reg [7:0] cnt_dllk_zqinit_r;
reg cnt_dllk_zqinit_done_r;
reg cnt_init_af_done_r;
reg [1:0] cnt_init_af_r;
reg [1:0] cnt_init_data_r;
reg [1:0] cnt_init_mr_r;
reg cnt_init_mr_done_r;
reg cnt_init_pre_wait_done_r;
reg [7:0] cnt_init_pre_wait_r;
reg [9:0] cnt_pwron_ce_r;
reg cnt_pwron_cke_done_r;
reg cnt_pwron_cke_done_r1;
reg [8:0] cnt_pwron_r;
reg cnt_pwron_reset_done_r;
reg cnt_txpr_done_r;
reg [7:0] cnt_txpr_r;
reg ddr2_pre_flag_r;
reg ddr2_refresh_flag_r;
reg ddr3_lm_done_r;
reg [4:0] enable_wrlvl_cnt;
reg init_complete_r;
reg init_complete_r1;
reg init_complete_r2;
(* keep = "true" *) reg init_complete_r_timing;
(* keep = "true" *) reg init_complete_r1_timing;
reg [6:0] init_next_state;
reg [6:0] init_state_r;
reg [6:0] init_state_r1;
wire [15:0] load_mr0;
wire [15:0] load_mr1;
wire [15:0] load_mr2;
wire [15:0] load_mr3;
reg mem_init_done_r;
reg [1:0] mr2_r [0:3];
reg [2:0] mr1_r [0:3];
reg new_burst_r;
reg [15:0] wrcal_start_dly_r;
wire wrcal_start_pre;
reg wrcal_resume_r;
// Only one ODT signal per rank in PHY Control Block
reg [nCK_PER_CLK-1:0] phy_tmp_odt_r;
reg [nCK_PER_CLK-1:0] phy_tmp_odt_r1;
reg [CS_WIDTH*nCS_PER_RANK-1:0] phy_tmp_cs1_r;
reg [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] phy_int_cs_n;
wire prech_done_pre;
reg [15:0] prech_done_dly_r;
reg prech_pending_r;
reg prech_req_posedge_r;
reg prech_req_r;
reg pwron_ce_r;
reg first_rdlvl_pat_r;
reg first_wrcal_pat_r;
reg phy_wrdata_en;
reg phy_wrdata_en_r1;
reg [1:0] wrdata_pat_cnt;
reg [1:0] wrcal_pat_cnt;
reg [ROW_WIDTH-1:0] address_w;
reg [BANK_WIDTH-1:0] bank_w;
reg rdlvl_stg1_done_r1;
reg rdlvl_stg1_start_int;
reg [15:0] rdlvl_start_dly0_r;
reg rdlvl_start_pre;
reg rdlvl_last_byte_done_r;
wire rdlvl_rd;
wire rdlvl_wr;
reg rdlvl_wr_r;
wire rdlvl_wr_rd;
reg [3:0] reg_ctrl_cnt_r;
reg [1:0] tmp_mr2_r [0:3];
reg [2:0] tmp_mr1_r [0:3];
reg wrlvl_done_r;
reg wrlvl_done_r1;
reg wrlvl_rank_done_r1;
reg wrlvl_rank_done_r2;
reg wrlvl_rank_done_r3;
reg wrlvl_rank_done_r4;
reg wrlvl_rank_done_r5;
reg wrlvl_rank_done_r6;
reg wrlvl_rank_done_r7;
reg [2:0] wrlvl_rank_cntr;
reg wrlvl_odt_ctl;
reg wrlvl_odt;
reg wrlvl_active;
reg wrlvl_active_r1;
reg [2:0] num_reads;
reg temp_wrcal_done_r;
reg temp_lmr_done;
reg extend_cal_pat;
reg [13:0] tg_timer;
reg tg_timer_go;
reg cnt_wrcal_rd;
reg [3:0] cnt_wait;
reg [7:0] wrcal_reads;
reg [8:0] stg1_wr_rd_cnt;
reg phy_data_full_r;
reg wr_level_dqs_asrt;
reg wr_level_dqs_asrt_r1;
reg [1:0] dqs_asrt_cnt;
reg [3:0] num_refresh;
wire oclkdelay_calib_start_pre;
reg [15:0] oclkdelay_start_dly_r;
reg [3:0] oclk_wr_cnt;
reg [3:0] wrcal_wr_cnt;
reg wrlvl_final_r;
reg prbs_rdlvl_done_r1;
reg prbs_rdlvl_done_r2;
reg prbs_rdlvl_done_r3;
reg prbs_last_byte_done_r;
reg phy_if_empty_r;
reg prbs_pat_resume_int;
reg complex_row0_wr_done;
reg complex_row1_wr_done;
reg complex_row0_rd_done;
reg complex_row1_rd_done;
reg complex_row0_rd_done_r1;
reg [3:0] complex_wait_cnt;
reg [3:0] complex_num_reads;
reg [3:0] complex_num_reads_dec;
reg [ROW_WIDTH-1:0] complex_address;
reg wr_victim_inc;
reg [2:0] wr_victim_sel;
reg [DQS_CNT_WIDTH:0] wr_byte_cnt;
reg [7:0] complex_row_cnt;
reg complex_sample_cnt_inc_r1;
reg complex_sample_cnt_inc_r2;
reg complex_odt_ext;
reg complex_ocal_odt_ext;
reg wrcal_final_chk;
wire prech_req;
reg read_pause_r1;
reg read_pause_r2;
wire read_pause_ext;
reg reset_rd_addr_r1;
reg complex_rdlvl_int_ref_req;
reg ext_int_ref_req;
//complex OCLK delay calibration
reg [7:0] complex_row_cnt_ocal;
reg [4:0] complex_num_writes;
reg [4:0] complex_num_writes_dec;
reg complex_oclkdelay_calib_start_int;
reg complex_oclkdelay_calib_start_r1;
reg complex_oclkdelay_calib_start_r2;
reg complex_oclkdelay_calib_done_r1;
// reg [DQS_CNT_WIDTH:0] wr_byte_cnt_ocal;
reg [2:0] wr_victim_sel_ocal;
reg complex_row1_rd_done_r1; //time for switch to write
reg [2:0] complex_row1_rd_cnt; //row1 read number for the byte (8 (16 rows) row1)
reg complex_byte_rd_done; //read for the byte is done
reg complex_byte_rd_done_r1;
// reg complex_row_change; //every 16 rows of read, it is set to "0" for write
reg ocal_num_samples_inc; //1 read/write is done
reg complex_ocal_wr_start; //indicate complex ocal write is started. used for prbs rd addr gen
reg prbs_rdlvl_done_pulse; //rising edge for prbs_rdlvl_done. used for pipelining
reg prech_done_r1, prech_done_r2, prech_done_r3;
reg mask_lim_done;
reg complex_mask_lim_done;
reg oclkdelay_calib_start_int;
reg [REFRESH_TIMER_WIDTH-1:0] oclkdelay_ref_cnt;
reg oclkdelay_int_ref_req;
reg [3:0] ocal_act_wait_cnt;
reg oclk_calib_resume_level;
reg ocal_last_byte_done;
wire mmcm_wr; //MMCM centering write. no CS will be set
wire exit_ocal_complex_resume_wait =
init_state_r == INIT_OCAL_COMPLEX_RESUME_WAIT && complex_oclk_calib_resume;
//***************************************************************************
// Debug
//***************************************************************************
//synthesis translate_off
always @(posedge mem_init_done_r) begin
if (!rst)
$display ("PHY_INIT: Memory Initialization completed at %t", $time);
end
always @(posedge wrlvl_done) begin
if (!rst && (WRLVL == "ON"))
$display ("PHY_INIT: Write Leveling completed at %t", $time);
end
always @(posedge rdlvl_stg1_done) begin
if (!rst)
$display ("PHY_INIT: Read Leveling Stage 1 completed at %t", $time);
end
always @(posedge mpr_rdlvl_done) begin
if (!rst)
$display ("PHY_INIT: MPR Read Leveling completed at %t", $time);
end
always @(posedge oclkdelay_calib_done) begin
if (!rst)
$display ("PHY_INIT: OCLKDELAY calibration completed at %t", $time);
end
always @(posedge pi_calib_done_r1) begin
if (!rst)
$display ("PHY_INIT: Phaser_In Phase Locked at %t", $time);
end
always @(posedge pi_dqs_found_done) begin
if (!rst)
$display ("PHY_INIT: Phaser_In DQSFOUND completed at %t", $time);
end
always @(posedge wrcal_done) begin
if (!rst && (WRLVL == "ON"))
$display ("PHY_INIT: Write Calibration completed at %t", $time);
end
always@(posedge prbs_rdlvl_done)begin
if(!rst)
$display("PHY_INIT : PRBS/PER_BIT calibration completed at %t",$time);
end
always@(posedge complex_oclkdelay_calib_done)begin
if(!rst)
$display("PHY_INIT : COMPLEX OCLKDELAY calibration completed at %t",$time);
end
always@(posedge oclkdelay_center_calib_done)begin
if(!rst)
$display("PHY_INIT : OCLKDELAY CENTER CALIB calibration completed at %t",$time);
end
//synthesis translate_on
assign dbg_phy_init[5:0] = init_state_r;
assign dbg_phy_init[6+:8] = complex_row_cnt;
assign dbg_phy_init[14+:3] = victim_sel;
assign dbg_phy_init[17+:4] = victim_byte_cnt;
assign dbg_phy_init[21+:9] = stg1_wr_rd_cnt[8:0];
assign dbg_phy_init[30+:15] = complex_address;
assign dbg_phy_init[(30+15)+:15] = phy_address[14:0];
assign dbg_phy_init[60] =prbs_rdlvl_prech_req ;
assign dbg_phy_init[61] =prech_req_posedge_r ;
//***************************************************************************
// DQS count to be sent to hard PHY during Phaser_IN Phase Locking stage
//***************************************************************************
// assign pi_phaselock_calib_cnt = dqs_cnt_r;
assign pi_calib_done = pi_calib_done_r1;
assign read_pause_ext = read_pause | read_pause_r2;
//detect rising edge of prbs_rdlvl_done to reset all control sighals
always @ (posedge clk) begin
prbs_rdlvl_done_pulse <= #TCQ prbs_rdlvl_done & ~prbs_rdlvl_done_r1;
end
always @ (posedge clk) begin
read_pause_r1 <= #TCQ read_pause;
read_pause_r2 <= #TCQ read_pause_r1;
end
always @(posedge clk) begin
if (rst)
wrcal_final_chk <= #TCQ 1'b0;
else if ((init_next_state == INIT_WRCAL_ACT) && wrcal_done &&
(DRAM_TYPE == "DDR3"))
wrcal_final_chk <= #TCQ 1'b1;
end
always @(posedge clk) begin
rdlvl_stg1_done_r1 <= #TCQ rdlvl_stg1_done;
prbs_rdlvl_done_r1 <= #TCQ prbs_rdlvl_done;
prbs_rdlvl_done_r2 <= #TCQ prbs_rdlvl_done_r1;
prbs_rdlvl_done_r3 <= #TCQ prbs_rdlvl_done_r2;
wrcal_resume_r <= #TCQ wrcal_resume;
wrcal_sanity_chk <= #TCQ wrcal_final_chk;
end
always @(posedge clk) begin
if (rst)
mpr_end_if_reset <= #TCQ 1'b0;
else if (mpr_last_byte_done && (num_refresh != 'd0))
mpr_end_if_reset <= #TCQ 1'b1;
else
mpr_end_if_reset <= #TCQ 1'b0;
end
// Siganl to mask memory model error for Invalid latching edge
always @(posedge clk)
if (rst)
calib_writes <= #TCQ 1'b0;
else if ((init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ))
calib_writes <= #TCQ 1'b1;
else
calib_writes <= #TCQ 1'b0;
always @(posedge clk)
if (rst)
wrcal_rd_wait <= #TCQ 1'b0;
else if (init_state_r == INIT_WRCAL_READ_WAIT)
wrcal_rd_wait <= #TCQ 1'b1;
else
wrcal_rd_wait <= #TCQ 1'b0;
//***************************************************************************
// Signal PHY completion when calibration is finished
// Signal assertion is delayed by four clock cycles to account for the
// multi cycle path constraint to (phy_init_data_sel) signal.
//***************************************************************************
always @(posedge clk)
if (rst) begin
init_complete_r <= #TCQ 1'b0;
init_complete_r_timing <= #TCQ 1'b0;
init_complete_r1 <= #TCQ 1'b0;
init_complete_r1_timing <= #TCQ 1'b0;
init_complete_r2 <= #TCQ 1'b0;
init_calib_complete <= #TCQ 1'b0;
end else begin
if (init_state_r == INIT_DONE) begin
init_complete_r <= #TCQ 1'b1;
init_complete_r_timing <= #TCQ 1'b1;
end
init_complete_r1 <= #TCQ init_complete_r;
init_complete_r1_timing <= #TCQ init_complete_r_timing;
init_complete_r2 <= #TCQ init_complete_r1;
init_calib_complete <= #TCQ init_complete_r2;
end
always @ (posedge clk)
if (rst)
complex_oclkdelay_calib_done_r1 <= #TCQ 1'b0;
else
complex_oclkdelay_calib_done_r1 <= #TCQ complex_oclkdelay_calib_done;
//reset read address for starting complex ocaldealy calib
always @ (posedge clk) begin
complex_ocal_reset_rd_addr <= #TCQ ((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && (complex_wait_cnt == 'd9)) || (prbs_last_byte_done && ~prbs_last_byte_done_r);
end
//first write for complex oclkdealy calib
always @ (posedge clk) begin
if (rst)
complex_ocal_wr_start <= #TCQ 'b0;
else
complex_ocal_wr_start <= #TCQ complex_ocal_reset_rd_addr? 1'b1 : complex_ocal_wr_start;
end
//ocal stg3 centering start
// always @ (posedge clk)
// if(rst) oclkdelay_center_calib_start <= #TCQ 1'b0;
// else
// oclkdelay_center_calib_start <= #TCQ ((init_state_r == INIT_OCAL_CENTER_ACT) && lim_done)? 1'b1: oclkdelay_center_calib_start;
//***************************************************************************
// Instantiate FF for the phy_init_data_sel signal. A multi cycle path
// constraint will be assigned to this signal. This signal will only be
// used within the PHY
//***************************************************************************
// FDRSE u_ff_phy_init_data_sel
// (
// .Q (phy_init_data_sel),
// .C (clk),
// .CE (1'b1),
// .D (init_complete_r),
// .R (1'b0),
// .S (1'b0)
// ) /* synthesis syn_preserve=1 */
// /* synthesis syn_replicate = 0 */;
//***************************************************************************
// Mode register programming
//***************************************************************************
//*****************************************************************
// DDR3 Load mode reg0
// Mode Register (MR0):
// [15:13] - unused - 000
// [12] - Precharge Power-down DLL usage - 0 (DLL frozen, slow-exit),
// 1 (DLL maintained)
// [11:9] - write recovery for Auto Precharge (tWR/tCK = 6)
// [8] - DLL reset - 0 or 1
// [7] - Test Mode - 0 (normal)
// [6:4],[2] - CAS latency - CAS_LAT
// [3] - Burst Type - BURST_TYPE
// [1:0] - Burst Length - BURST_LEN
// DDR2 Load mode register
// Mode Register (MR):
// [15:14] - unused - 00
// [13] - reserved - 0
// [12] - Power-down mode - 0 (normal)
// [11:9] - write recovery - write recovery for Auto Precharge
// (tWR/tCK = 6)
// [8] - DLL reset - 0 or 1
// [7] - Test Mode - 0 (normal)
// [6:4] - CAS latency - CAS_LAT
// [3] - Burst Type - BURST_TYPE
// [2:0] - Burst Length - BURST_LEN
//*****************************************************************
generate
if(DRAM_TYPE == "DDR3") begin: gen_load_mr0_DDR3
assign load_mr0[1:0] = (BURST_MODE == "8") ? 2'b00 :
(BURST_MODE == "OTF") ? 2'b01 :
(BURST_MODE == "4") ? 2'b10 : 2'b11;
assign load_mr0[2] = (nCL >= 12) ? 1'b1 : 1'b0; // LSb of CAS latency
assign load_mr0[3] = (BURST_TYPE == "SEQ") ? 1'b0 : 1'b1;
assign load_mr0[6:4] = ((nCL == 5) || (nCL == 13)) ? 3'b001 :
((nCL == 6) || (nCL == 14)) ? 3'b010 :
(nCL == 7) ? 3'b011 :
(nCL == 8) ? 3'b100 :
(nCL == 9) ? 3'b101 :
(nCL == 10) ? 3'b110 :
(nCL == 11) ? 3'b111 :
(nCL == 12) ? 3'b000 : 3'b111;
assign load_mr0[7] = 1'b0;
assign load_mr0[8] = 1'b1; // Reset DLL (init only)
assign load_mr0[11:9] = (TWR_CYC == 5) ? 3'b001 :
(TWR_CYC == 6) ? 3'b010 :
(TWR_CYC == 7) ? 3'b011 :
(TWR_CYC == 8) ? 3'b100 :
(TWR_CYC == 9) ? 3'b101 :
(TWR_CYC == 10) ? 3'b101 :
(TWR_CYC == 11) ? 3'b110 :
(TWR_CYC == 12) ? 3'b110 :
(TWR_CYC == 13) ? 3'b111 :
(TWR_CYC == 14) ? 3'b111 :
(TWR_CYC == 15) ? 3'b000 :
(TWR_CYC == 16) ? 3'b000 : 3'b010;
assign load_mr0[12] = 1'b0; // Precharge Power-Down DLL 'slow-exit'
assign load_mr0[15:13] = 3'b000;
end else if (DRAM_TYPE == "DDR2") begin: gen_load_mr0_DDR2 // block: gen
assign load_mr0[2:0] = (BURST_MODE == "8") ? 3'b011 :
(BURST_MODE == "4") ? 3'b010 : 3'b111;
assign load_mr0[3] = (BURST_TYPE == "SEQ") ? 1'b0 : 1'b1;
assign load_mr0[6:4] = (nCL == 3) ? 3'b011 :
(nCL == 4) ? 3'b100 :
(nCL == 5) ? 3'b101 :
(nCL == 6) ? 3'b110 : 3'b111;
assign load_mr0[7] = 1'b0;
assign load_mr0[8] = 1'b1; // Reset DLL (init only)
assign load_mr0[11:9] = (TWR_CYC == 2) ? 3'b001 :
(TWR_CYC == 3) ? 3'b010 :
(TWR_CYC == 4) ? 3'b011 :
(TWR_CYC == 5) ? 3'b100 :
(TWR_CYC == 6) ? 3'b101 : 3'b010;
assign load_mr0[15:12]= 4'b0000; // Reserved
end
endgenerate
//*****************************************************************
// DDR3 Load mode reg1
// Mode Register (MR1):
// [15:13] - unused - 00
// [12] - output enable - 0 (enabled for DQ, DQS, DQS#)
// [11] - TDQS enable - 0 (TDQS disabled and DM enabled)
// [10] - reserved - 0 (must be '0')
// [9] - RTT[2] - 0
// [8] - reserved - 0 (must be '0')
// [7] - write leveling - 0 (disabled), 1 (enabled)
// [6] - RTT[1] - RTT[1:0] = 0(no ODT), 1(75), 2(150), 3(50)
// [5] - Output driver impedance[1] - 0 (RZQ/6 and RZQ/7)
// [4:3] - Additive CAS - ADDITIVE_CAS
// [2] - RTT[0]
// [1] - Output driver impedance[0] - 0(RZQ/6), or 1 (RZQ/7)
// [0] - DLL enable - 0 (normal)
// DDR2 ext mode register
// Extended Mode Register (MR):
// [15:14] - unused - 00
// [13] - reserved - 0
// [12] - output enable - 0 (enabled)
// [11] - RDQS enable - 0 (disabled)
// [10] - DQS# enable - 0 (enabled)
// [9:7] - OCD Program - 111 or 000 (first 111, then 000 during init)
// [6] - RTT[1] - RTT[1:0] = 0(no ODT), 1(75), 2(150), 3(50)
// [5:3] - Additive CAS - ADDITIVE_CAS
// [2] - RTT[0]
// [1] - Output drive - REDUCE_DRV (= 0(full), = 1 (reduced)
// [0] - DLL enable - 0 (normal)
//*****************************************************************
generate
if(DRAM_TYPE == "DDR3") begin: gen_load_mr1_DDR3
assign load_mr1[0] = 1'b0; // DLL enabled during Imitialization
assign load_mr1[1] = (OUTPUT_DRV == "LOW") ? 1'b0 : 1'b1;
assign load_mr1[2] = ((RTT_NOM_int == "30") || (RTT_NOM_int == "40") ||
(RTT_NOM_int == "60")) ? 1'b1 : 1'b0;
assign load_mr1[4:3] = (AL == "0") ? 2'b00 :
(AL == "CL-1") ? 2'b01 :
(AL == "CL-2") ? 2'b10 : 2'b11;
assign load_mr1[5] = 1'b0;
assign load_mr1[6] = ((RTT_NOM_int == "40") || (RTT_NOM_int == "120")) ?
1'b1 : 1'b0;
assign load_mr1[7] = 1'b0; // Enable write lvl after init sequence
assign load_mr1[8] = 1'b0;
assign load_mr1[9] = ((RTT_NOM_int == "20") || (RTT_NOM_int == "30")) ?
1'b1 : 1'b0;
assign load_mr1[10] = 1'b0;
assign load_mr1[15:11] = 5'b00000;
end else if (DRAM_TYPE == "DDR2") begin: gen_load_mr1_DDR2
assign load_mr1[0] = 1'b0; // DLL enabled during Imitialization
assign load_mr1[1] = (OUTPUT_DRV == "LOW") ? 1'b1 : 1'b0;
assign load_mr1[2] = ((RTT_NOM_int == "75") || (RTT_NOM_int == "50")) ?
1'b1 : 1'b0;
assign load_mr1[5:3] = (AL == "0") ? 3'b000 :
(AL == "1") ? 3'b001 :
(AL == "2") ? 3'b010 :
(AL == "3") ? 3'b011 :
(AL == "4") ? 3'b100 : 3'b111;
assign load_mr1[6] = ((RTT_NOM_int == "50") ||
(RTT_NOM_int == "150")) ? 1'b1 : 1'b0;
assign load_mr1[9:7] = 3'b000;
assign load_mr1[10] = (DDR2_DQSN_ENABLE == "YES") ? 1'b0 : 1'b1;
assign load_mr1[15:11] = 5'b00000;
end
endgenerate
//*****************************************************************
// DDR3 Load mode reg2
// Mode Register (MR2):
// [15:11] - unused - 00
// [10:9] - RTT_WR - 00 (Dynamic ODT off)
// [8] - reserved - 0 (must be '0')
// [7] - self-refresh temperature range -
// 0 (normal), 1 (extended)
// [6] - Auto Self-Refresh - 0 (manual), 1(auto)
// [5:3] - CAS Write Latency (CWL) -
// 000 (5 for 400 MHz device),
// 001 (6 for 400 MHz to 533 MHz devices),
// 010 (7 for 533 MHz to 667 MHz devices),
// 011 (8 for 667 MHz to 800 MHz)
// [2:0] - Partial Array Self-Refresh (Optional) -
// 000 (full array)
// Not used for DDR2
//*****************************************************************
generate
if(DRAM_TYPE == "DDR3") begin: gen_load_mr2_DDR3
assign load_mr2[2:0] = 3'b000;
assign load_mr2[5:3] = (nCWL == 5) ? 3'b000 :
(nCWL == 6) ? 3'b001 :
(nCWL == 7) ? 3'b010 :
(nCWL == 8) ? 3'b011 :
(nCWL == 9) ? 3'b100 :
(nCWL == 10) ? 3'b101 :
(nCWL == 11) ? 3'b110 : 3'b111;
assign load_mr2[6] = 1'b0;
assign load_mr2[7] = 1'b0;
assign load_mr2[8] = 1'b0;
// Dynamic ODT disabled
assign load_mr2[10:9] = 2'b00;
assign load_mr2[15:11] = 5'b00000;
end else begin: gen_load_mr2_DDR2
assign load_mr2[15:0] = 16'd0;
end
endgenerate
//*****************************************************************
// DDR3 Load mode reg3
// Mode Register (MR3):
// [15:3] - unused - All zeros
// [2] - MPR Operation - 0(normal operation), 1(data flow from MPR)
// [1:0] - MPR location - 00 (Predefined pattern)
//*****************************************************************
assign load_mr3[1:0] = 2'b00;
assign load_mr3[2] = 1'b0;
assign load_mr3[15:3] = 13'b0000000000000;
// For multi-rank systems the rank being accessed during writes in
// Read Leveling must be sent to phy_write for the bitslip logic
assign calib_rank_cnt = chip_cnt_r;
//***************************************************************************
// Logic to begin initial calibration, and to handle precharge requests
// during read-leveling (to avoid tRAS violations if individual read
// levelling calibration stages take more than max{tRAS) to complete).
//***************************************************************************
// Assert when readback for each stage of read-leveling begins. However,
// note this indicates only when the read command is issued and when
// Phaser_IN has phase aligned FREQ_REF clock to read DQS. It does not
// indicate when the read data is present on the bus (when this happens
// after the read command is issued depends on CAS LATENCY) - there will
// need to be some delay before valid data is present on the bus.
// assign rdlvl_start_pre = (init_state_r == INIT_PI_PHASELOCK_READS);
// Assert when read back for oclkdelay calibration begins
assign oclkdelay_calib_start_pre = (init_state_r == INIT_OCAL_CENTER_ACT); //(init_state_r == INIT_OCLKDELAY_READ);
// Assert when read back for write calibration begins
assign wrcal_start_pre = (init_state_r == INIT_WRCAL_READ) || (init_state_r == INIT_WRCAL_MULT_READS);
// Common precharge signal done signal - pulses only when there has been
// a precharge issued as a result of a PRECH_REQ pulse. Note also a common
// PRECH_DONE signal is used for all blocks
assign prech_done_pre = (((init_state_r == INIT_RDLVL_STG1_READ) || (init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
((rdlvl_last_byte_done_r || prbs_last_byte_done_r) && (init_state_r == INIT_RDLVL_ACT_WAIT) && cnt_cmd_done_r) ||
(dqs_found_prech_req && (init_state_r == INIT_RDLVL_ACT_WAIT)) ||
(init_state_r == INIT_MPR_RDEN) ||
((init_state_r == INIT_WRCAL_ACT_WAIT) && cnt_cmd_done_r) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT) && complex_oclkdelay_calib_start_r1) ||
((init_state_r == INIT_OCLKDELAY_ACT_WAIT) && cnt_cmd_done_r) ||
((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) && prbs_last_byte_done_r) || //prbs_rdlvl_done
(wrlvl_final && (init_state_r == INIT_REFRESH_WAIT) && cnt_cmd_done_r && ~oclkdelay_calib_done)) &&
prech_pending_r &&
!prech_req_posedge_r);
always @(posedge clk)
if (rst)
pi_phaselock_start <= #TCQ 1'b0;
else if (init_state_r == INIT_PI_PHASELOCK_READS)
pi_phaselock_start <= #TCQ 1'b1;
// Delay start of each calibration by 16 clock cycles to ensure that when
// calibration logic begins, read data is already appearing on the bus.
// Each circuit should synthesize using an SRL16. Assume that reset is
// long enough to clear contents of SRL16.
always @(posedge clk) begin
rdlvl_last_byte_done_r <= #TCQ rdlvl_last_byte_done;
prbs_last_byte_done_r <= #TCQ prbs_last_byte_done;
rdlvl_start_dly0_r <= #TCQ {rdlvl_start_dly0_r[14:0],
rdlvl_start_pre};
wrcal_start_dly_r <= #TCQ {wrcal_start_dly_r[14:0],
wrcal_start_pre};
oclkdelay_start_dly_r <= #TCQ {oclkdelay_start_dly_r[14:0],
oclkdelay_calib_start_pre};
prech_done_dly_r <= #TCQ {prech_done_dly_r[14:0],
prech_done_pre};
end
always @(posedge clk)
if (rst)
oclkdelay_calib_start_int <= #TCQ 1'b0;
else if (oclkdelay_start_dly_r[5])
oclkdelay_calib_start_int <= #TCQ 1'b1;
always @(posedge clk) begin
if (rst)
ocal_last_byte_done <= #TCQ 1'b0;
else if ((complex_oclkdelay_calib_cnt == DQS_WIDTH-1) && oclkdelay_center_calib_done)
ocal_last_byte_done <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_REFRESH) || prbs_rdlvl_done || ocal_last_byte_done || oclkdelay_center_calib_done)
oclkdelay_ref_cnt <= #TCQ REFRESH_TIMER;
else if (oclkdelay_calib_start_int) begin
if (oclkdelay_ref_cnt > 'd0)
oclkdelay_ref_cnt <= #TCQ oclkdelay_ref_cnt - 1;
else
oclkdelay_ref_cnt <= #TCQ REFRESH_TIMER;
end
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_OCAL_CENTER_ACT) || oclkdelay_calib_done || ocal_last_byte_done || oclkdelay_center_calib_done)
oclkdelay_int_ref_req <= #TCQ 1'b0;
else if (oclkdelay_ref_cnt == 'd1)
oclkdelay_int_ref_req <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst)
ocal_act_wait_cnt <= #TCQ 'd0;
else if ((init_state_r == INIT_OCAL_CENTER_ACT_WAIT) && ocal_act_wait_cnt < 'd15)
ocal_act_wait_cnt <= #TCQ ocal_act_wait_cnt + 1;
else
ocal_act_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_OCLKDELAY_READ))
oclk_calib_resume_level <= #TCQ 1'b0;
else if (oclk_calib_resume)
oclk_calib_resume_level <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_RDLVL_ACT_WAIT) || prbs_rdlvl_done)
complex_rdlvl_int_ref_req <= #TCQ 1'b0;
else if (oclkdelay_ref_cnt == 'd1)
// complex_rdlvl_int_ref_req <= #TCQ 1'b1;
complex_rdlvl_int_ref_req <= #TCQ 1'b0; //temporary fix for read issue
end
always @(posedge clk) begin
if (rst || (init_state_r == INIT_RDLVL_COMPLEX_READ))
ext_int_ref_req <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_ACT_WAIT) && complex_rdlvl_int_ref_req)
ext_int_ref_req <= #TCQ 1'b1;
end
always @(posedge clk) begin
prech_done <= #TCQ prech_done_dly_r[15];
prech_done_r1 <= #TCQ prech_done_dly_r[15];
prech_done_r2 <= #TCQ prech_done_r1;
prech_done_r3 <= #TCQ prech_done_r2;
end
always @(posedge clk)
if (rst)
mpr_rdlvl_start <= #TCQ 1'b0;
else if (pi_dqs_found_done &&
(init_state_r == INIT_MPR_READ))
mpr_rdlvl_start <= #TCQ 1'b1;
always @(posedge clk)
phy_if_empty_r <= #TCQ phy_if_empty;
always @(posedge clk)
if (rst ||
((stg1_wr_rd_cnt == 'd2) && ~stg1_wr_done) || prbs_rdlvl_done)
prbs_gen_clk_en <= #TCQ 1'b0;
else if ((~phy_if_empty_r && rdlvl_stg1_done_r1 && ~prbs_rdlvl_done) ||
((init_state_r == INIT_RDLVL_ACT_WAIT) && rdlvl_stg1_done_r1 && (cnt_cmd_r == 'd127)) ||
((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && rdlvl_stg1_done_r1 && (complex_wait_cnt == 'd14))
|| (init_state_r == INIT_RDLVL_COMPLEX_READ) || ((init_state_r == INIT_PRECHARGE_PREWAIT) && prbs_rdlvl_start))
prbs_gen_clk_en <= #TCQ 1'b1;
//Enable for complex oclkdelay - used in prbs gen
always @(posedge clk)
if (rst ||
((stg1_wr_rd_cnt == 'd2) && ~stg1_wr_done) || complex_oclkdelay_calib_done ||
(complex_wait_cnt == 'd15 && complex_num_writes == 1 && complex_ocal_wr_start) ||
( init_state_r == INIT_RDLVL_STG1_WRITE && complex_num_writes_dec == 'd2) || ~complex_ocal_wr_start ||
(complex_byte_rd_done && init_state_r == INIT_RDLVL_COMPLEX_ACT ) ||
(init_state_r != INIT_OCAL_COMPLEX_RESUME_WAIT && init_state_r1 == INIT_OCAL_COMPLEX_RESUME_WAIT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT))
prbs_gen_oclk_clk_en <= #TCQ 1'b0;
else if ((~phy_if_empty_r && ~complex_oclkdelay_calib_done && prbs_rdlvl_done_r1) || // changed for new algo 3/26
((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && (complex_wait_cnt == 'd14)) ||
((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (complex_wait_cnt == 'd14)) ||
exit_ocal_complex_resume_wait ||
((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && ~stg1_wr_done && ~complex_row1_wr_done && ~complex_ocal_num_samples_done_r && (complex_wait_cnt == 'd14))
|| (init_state_r == INIT_RDLVL_COMPLEX_READ) )
prbs_gen_oclk_clk_en <= #TCQ 1'b1;
generate
if (RANKS < 2) begin
always @(posedge clk)
if (rst) begin
rdlvl_stg1_start <= #TCQ 1'b0;
rdlvl_stg1_start_int <= #TCQ 1'b0;
rdlvl_start_pre <= #TCQ 1'b0;
prbs_rdlvl_start <= #TCQ 1'b0;
end else begin
if (pi_dqs_found_done && cnt_cmd_done_r &&
(init_state_r == INIT_RDLVL_ACT_WAIT))
rdlvl_stg1_start_int <= #TCQ 1'b1;
if (pi_dqs_found_done &&
(init_state_r == INIT_RDLVL_STG1_READ))begin
rdlvl_start_pre <= #TCQ 1'b1;
rdlvl_stg1_start <= #TCQ rdlvl_start_dly0_r[14];
end
if (pi_dqs_found_done && rdlvl_stg1_done && ~prbs_rdlvl_done &&
(init_state_r == INIT_RDLVL_COMPLEX_READ) && (WRLVL == "ON")) begin
prbs_rdlvl_start <= #TCQ 1'b1;
end
end
end else begin
always @(posedge clk)
if (rst || rdlvl_stg1_rank_done) begin
rdlvl_stg1_start <= #TCQ 1'b0;
rdlvl_stg1_start_int <= #TCQ 1'b0;
rdlvl_start_pre <= #TCQ 1'b0;
prbs_rdlvl_start <= #TCQ 1'b0;
end else begin
if (pi_dqs_found_done && cnt_cmd_done_r &&
(init_state_r == INIT_RDLVL_ACT_WAIT))
rdlvl_stg1_start_int <= #TCQ 1'b1;
if (pi_dqs_found_done &&
(init_state_r == INIT_RDLVL_STG1_READ))begin
rdlvl_start_pre <= #TCQ 1'b1;
rdlvl_stg1_start <= #TCQ rdlvl_start_dly0_r[14];
end
if (pi_dqs_found_done && rdlvl_stg1_done && ~prbs_rdlvl_done &&
(init_state_r == INIT_RDLVL_COMPLEX_READ) && (WRLVL == "ON")) begin
prbs_rdlvl_start <= #TCQ 1'b1;
end
end
end
endgenerate
always @(posedge clk) begin
if (rst || dqsfound_retry || wrlvl_byte_redo) begin
pi_dqs_found_start <= #TCQ 1'b0;
wrcal_start <= #TCQ 1'b0;
end else begin
if (!pi_dqs_found_done && init_state_r == INIT_RDLVL_STG2_READ)
pi_dqs_found_start <= #TCQ 1'b1;
if (wrcal_start_dly_r[5])
wrcal_start <= #TCQ 1'b1;
end
end // else: !if(rst)
always @(posedge clk)
if (rst)
oclkdelay_calib_start <= #TCQ 1'b0;
else if (oclkdelay_start_dly_r[5])
oclkdelay_calib_start <= #TCQ 1'b1;
always @(posedge clk)
if (rst)
pi_dqs_found_done_r1 <= #TCQ 1'b0;
else
pi_dqs_found_done_r1 <= #TCQ pi_dqs_found_done;
always @(posedge clk)
wrlvl_final_r <= #TCQ wrlvl_final;
// Reset IN_FIFO after final write leveling to make sure the FIFO
// pointers are initialized
always @(posedge clk)
if (rst || (init_state_r == INIT_WRCAL_WRITE) || (init_state_r == INIT_REFRESH))
wrlvl_final_if_rst <= #TCQ 1'b0;
else if (wrlvl_done_r && //(wrlvl_final_r && wrlvl_done_r &&
(init_state_r == INIT_WRLVL_LOAD_MR2))
wrlvl_final_if_rst <= #TCQ 1'b1;
// Constantly enable DQS while write leveling is enabled in the memory
// This is more to get rid of warnings in simulation, can later change
// this code to only enable WRLVL_ACTIVE when WRLVL_START is asserted
always @(posedge clk)
if (rst ||
((init_state_r1 != INIT_WRLVL_START) &&
(init_state_r == INIT_WRLVL_START)))
wrlvl_odt_ctl <= #TCQ 1'b0;
else if (wrlvl_rank_done && ~wrlvl_rank_done_r1)
wrlvl_odt_ctl <= #TCQ 1'b1;
generate
if (nCK_PER_CLK == 4) begin: en_cnt_div4
always @ (posedge clk)
if (rst)
enable_wrlvl_cnt <= #TCQ 5'd0;
else if ((init_state_r == INIT_WRLVL_START) ||
(wrlvl_odt && (enable_wrlvl_cnt == 5'd0)))
enable_wrlvl_cnt <= #TCQ 5'd12;
else if ((enable_wrlvl_cnt > 5'd0) && ~(phy_ctl_full || phy_cmd_full))
enable_wrlvl_cnt <= #TCQ enable_wrlvl_cnt - 1;
// ODT stays asserted as long as write_calib
// signal is asserted
always @(posedge clk)
if (rst || wrlvl_odt_ctl)
wrlvl_odt <= #TCQ 1'b0;
else if (enable_wrlvl_cnt == 5'd1)
wrlvl_odt <= #TCQ 1'b1;
end else begin: en_cnt_div2
always @ (posedge clk)
if (rst)
enable_wrlvl_cnt <= #TCQ 5'd0;
else if ((init_state_r == INIT_WRLVL_START) ||
(wrlvl_odt && (enable_wrlvl_cnt == 5'd0)))
enable_wrlvl_cnt <= #TCQ 5'd21;
else if ((enable_wrlvl_cnt > 5'd0) && ~(phy_ctl_full || phy_cmd_full))
enable_wrlvl_cnt <= #TCQ enable_wrlvl_cnt - 1;
// ODT stays asserted as long as write_calib
// signal is asserted
always @(posedge clk)
if (rst || wrlvl_odt_ctl)
wrlvl_odt <= #TCQ 1'b0;
else if (enable_wrlvl_cnt == 5'd1)
wrlvl_odt <= #TCQ 1'b1;
end
endgenerate
always @(posedge clk)
if (rst || wrlvl_rank_done || done_dqs_tap_inc)
wrlvl_active <= #TCQ 1'b0;
else if ((enable_wrlvl_cnt == 5'd1) && wrlvl_odt && !wrlvl_active)
wrlvl_active <= #TCQ 1'b1;
// signal used to assert DQS for write leveling.
// the DQS will be asserted once every 16 clock cycles.
always @(posedge clk)begin
if(rst || (enable_wrlvl_cnt != 5'd1)) begin
wr_level_dqs_asrt <= #TCQ 1'd0;
end else if ((enable_wrlvl_cnt == 5'd1) && (wrlvl_active_r1)) begin
wr_level_dqs_asrt <= #TCQ 1'd1;
end
end
always @ (posedge clk) begin
if (rst || (wrlvl_done_r && ~wrlvl_done_r1))
dqs_asrt_cnt <= #TCQ 2'd0;
else if (wr_level_dqs_asrt && dqs_asrt_cnt != 2'd3)
dqs_asrt_cnt <= #TCQ (dqs_asrt_cnt + 1);
end
always @ (posedge clk) begin
if (rst || ~wrlvl_active)
wr_lvl_start <= #TCQ 1'd0;
else if (dqs_asrt_cnt == 2'd3)
wr_lvl_start <= #TCQ 1'd1;
end
always @(posedge clk) begin
if (rst)
wl_sm_start <= #TCQ 1'b0;
else
wl_sm_start <= #TCQ wr_level_dqs_asrt_r1;
end
always @(posedge clk) begin
wrlvl_active_r1 <= #TCQ wrlvl_active;
wr_level_dqs_asrt_r1 <= #TCQ wr_level_dqs_asrt;
wrlvl_done_r <= #TCQ wrlvl_done;
wrlvl_done_r1 <= #TCQ wrlvl_done_r;
wrlvl_rank_done_r1 <= #TCQ wrlvl_rank_done;
wrlvl_rank_done_r2 <= #TCQ wrlvl_rank_done_r1;
wrlvl_rank_done_r3 <= #TCQ wrlvl_rank_done_r2;
wrlvl_rank_done_r4 <= #TCQ wrlvl_rank_done_r3;
wrlvl_rank_done_r5 <= #TCQ wrlvl_rank_done_r4;
wrlvl_rank_done_r6 <= #TCQ wrlvl_rank_done_r5;
wrlvl_rank_done_r7 <= #TCQ wrlvl_rank_done_r6;
end
always @ (posedge clk) begin
//if (rst)
wrlvl_rank_cntr <= #TCQ 3'd0;
//else if (wrlvl_rank_done)
// wrlvl_rank_cntr <= #TCQ wrlvl_rank_cntr + 1'b1;
end
//*****************************************************************
// Precharge request logic - those calibration logic blocks
// that require greater than tRAS(max) to finish must break up
// their calibration into smaller units of time, with precharges
// issued in between. This is done using the XXX_PRECH_REQ and
// PRECH_DONE handshaking between PHY_INIT and those blocks
//*****************************************************************
// Shared request from multiple sources
assign prech_req = oclk_prech_req | rdlvl_prech_req | wrcal_prech_req | prbs_rdlvl_prech_req |
(dqs_found_prech_req & (init_state_r == INIT_RDLVL_STG2_READ_WAIT));
// Handshaking logic to force precharge during read leveling, and to
// notify read leveling logic when precharge has been initiated and
// it's okay to proceed with leveling again
always @(posedge clk)
if (rst) begin
prech_req_r <= #TCQ 1'b0;
prech_req_posedge_r <= #TCQ 1'b0;
prech_pending_r <= #TCQ 1'b0;
end else begin
prech_req_r <= #TCQ prech_req;
prech_req_posedge_r <= #TCQ prech_req & ~prech_req_r;
if (prech_req_posedge_r)
prech_pending_r <= #TCQ 1'b1;
// Clear after we've finished with the precharge and have
// returned to issuing read leveling calibration reads
else if (prech_done_pre)
prech_pending_r <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst || prech_done_r3)
mask_lim_done <= #TCQ 1'b0;
else if (prech_pending_r)
mask_lim_done <= #TCQ 1'b1;
end
always @(posedge clk) begin
if (rst || prbs_rdlvl_done_r3)
complex_mask_lim_done <= #TCQ 1'b0;
else if (~prbs_rdlvl_done && complex_oclkdelay_calib_start_int)
complex_mask_lim_done <= #TCQ 1'b1;
end
//Complex oclkdelay calibrration
//***************************************************************************
// Various timing counters
//***************************************************************************
//*****************************************************************
// Generic delay for various states that require it (e.g. for turnaround
// between read and write). Make this a sufficiently large number of clock
// cycles to cover all possible frequencies and memory components)
// Requirements for this counter:
// 1. Greater than tMRD
// 2. tRFC (refresh-active) for DDR2
// 3. (list the other requirements, slacker...)
//*****************************************************************
always @(posedge clk) begin
case (init_state_r)
INIT_LOAD_MR_WAIT,
INIT_WRLVL_LOAD_MR_WAIT,
INIT_WRLVL_LOAD_MR2_WAIT,
INIT_MPR_WAIT,
INIT_MPR_DISABLE_PREWAIT,
INIT_MPR_DISABLE_WAIT,
INIT_OCLKDELAY_ACT_WAIT,
INIT_OCLKDELAY_WRITE_WAIT,
INIT_RDLVL_ACT_WAIT,
INIT_RDLVL_STG1_WRITE_READ,
INIT_RDLVL_STG2_READ_WAIT,
INIT_WRCAL_ACT_WAIT,
INIT_WRCAL_WRITE_READ,
INIT_WRCAL_READ_WAIT,
INIT_PRECHARGE_PREWAIT,
INIT_PRECHARGE_WAIT,
INIT_DDR2_PRECHARGE_WAIT,
INIT_REG_WRITE_WAIT,
INIT_REFRESH_WAIT,
INIT_REFRESH_RNK2_WAIT: begin
if (phy_ctl_full || phy_cmd_full)
cnt_cmd_r <= #TCQ cnt_cmd_r;
else
cnt_cmd_r <= #TCQ cnt_cmd_r + 1;
end
INIT_WRLVL_WAIT:
cnt_cmd_r <= #TCQ 'b0;
default:
cnt_cmd_r <= #TCQ 'b0;
endcase
end
// pulse when count reaches terminal count
always @(posedge clk)
cnt_cmd_done_r <= #TCQ (cnt_cmd_r == CNTNEXT_CMD);
// For ODT deassertion - hold throughout post read/write wait stage, but
// deassert before next command. The post read/write stage is very long, so
// we simply address the longest case here plus some margin.
always @(posedge clk)
cnt_cmd_done_m7_r <= #TCQ (cnt_cmd_r == (CNTNEXT_CMD - 7));
//************************************************************************
// Added to support PO fine delay inc when TG errors
always @(posedge clk) begin
case (init_state_r)
INIT_WRCAL_READ_WAIT: begin
if (phy_ctl_full || phy_cmd_full)
cnt_wait <= #TCQ cnt_wait;
else
cnt_wait <= #TCQ cnt_wait + 1;
end
default:
cnt_wait <= #TCQ 'b0;
endcase
end
always @(posedge clk)
cnt_wrcal_rd <= #TCQ (cnt_wait == 'd4);
always @(posedge clk) begin
if (rst || ~temp_wrcal_done)
temp_lmr_done <= #TCQ 1'b0;
else if (temp_wrcal_done && (init_state_r == INIT_LOAD_MR))
temp_lmr_done <= #TCQ 1'b1;
end
always @(posedge clk)
temp_wrcal_done_r <= #TCQ temp_wrcal_done;
always @(posedge clk)
if (rst) begin
tg_timer_go <= #TCQ 1'b0;
end else if ((PRE_REV3ES == "ON") && temp_wrcal_done && temp_lmr_done &&
(init_state_r == INIT_WRCAL_READ_WAIT)) begin
tg_timer_go <= #TCQ 1'b1;
end else begin
tg_timer_go <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst || (temp_wrcal_done && ~temp_wrcal_done_r) ||
(init_state_r == INIT_PRECHARGE_PREWAIT))
tg_timer <= #TCQ 'd0;
else if ((pi_phaselock_timer == PHASELOCKED_TIMEOUT) &&
tg_timer_go &&
(tg_timer != TG_TIMER_TIMEOUT))
tg_timer <= #TCQ tg_timer + 1;
end
always @(posedge clk) begin
if (rst)
tg_timer_done <= #TCQ 1'b0;
else if (tg_timer == TG_TIMER_TIMEOUT)
tg_timer_done <= #TCQ 1'b1;
else
tg_timer_done <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst)
no_rst_tg_mc <= #TCQ 1'b0;
else if ((init_state_r == INIT_WRCAL_ACT) && wrcal_read_req)
no_rst_tg_mc <= #TCQ 1'b1;
else
no_rst_tg_mc <= #TCQ 1'b0;
end
//************************************************************************
always @(posedge clk) begin
if (rst)
detect_pi_found_dqs <= #TCQ 1'b0;
else if ((cnt_cmd_r == 7'b0111111) &&
(init_state_r == INIT_RDLVL_STG2_READ_WAIT))
detect_pi_found_dqs <= #TCQ 1'b1;
else
detect_pi_found_dqs <= #TCQ 1'b0;
end
//*****************************************************************
// Initial delay after power-on for RESET, CKE
// NOTE: Could reduce power consumption by turning off these counters
// after initial power-up (at expense of more logic)
// NOTE: Likely can combine multiple counters into single counter
//*****************************************************************
// Create divided by 1024 version of clock
always @(posedge clk)
if (rst) begin
cnt_pwron_ce_r <= #TCQ 10'h000;
pwron_ce_r <= #TCQ 1'b0;
end else begin
cnt_pwron_ce_r <= #TCQ cnt_pwron_ce_r + 1;
pwron_ce_r <= #TCQ (cnt_pwron_ce_r == 10'h3FF);
end
// "Main" power-on counter - ticks every CLKDIV/1024 cycles
always @(posedge clk)
if (rst)
cnt_pwron_r <= #TCQ 'b0;
else if (pwron_ce_r)
cnt_pwron_r <= #TCQ cnt_pwron_r + 1;
always @(posedge clk)
if (rst || ~phy_ctl_ready) begin
cnt_pwron_reset_done_r <= #TCQ 1'b0;
cnt_pwron_cke_done_r <= #TCQ 1'b0;
end else begin
// skip power-up count for simulation purposes only
if ((SIM_INIT_OPTION == "SKIP_PU_DLY") ||
(SIM_INIT_OPTION == "SKIP_INIT")) begin
cnt_pwron_reset_done_r <= #TCQ 1'b1;
cnt_pwron_cke_done_r <= #TCQ 1'b1;
end else begin
// otherwise, create latched version of done signal for RESET, CKE
if (DRAM_TYPE == "DDR3") begin
if (!cnt_pwron_reset_done_r)
cnt_pwron_reset_done_r
<= #TCQ (cnt_pwron_r == PWRON_RESET_DELAY_CNT);
if (!cnt_pwron_cke_done_r)
cnt_pwron_cke_done_r
<= #TCQ (cnt_pwron_r == PWRON_CKE_DELAY_CNT);
end else begin // DDR2
cnt_pwron_reset_done_r <= #TCQ 1'b1; // not needed
if (!cnt_pwron_cke_done_r)
cnt_pwron_cke_done_r
<= #TCQ (cnt_pwron_r == PWRON_CKE_DELAY_CNT);
end
end
end // else: !if(rst || ~phy_ctl_ready)
always @(posedge clk)
cnt_pwron_cke_done_r1 <= #TCQ cnt_pwron_cke_done_r;
// Keep RESET asserted and CKE deasserted until after power-on delay
always @(posedge clk or posedge rst) begin
if (rst)
phy_reset_n <= #TCQ 1'b0;
else
phy_reset_n <= #TCQ cnt_pwron_reset_done_r;
// phy_cke <= #TCQ {CKE_WIDTH{cnt_pwron_cke_done_r}};
end
//*****************************************************************
// Counter for tXPR (pronouned "Tax-Payer") - wait time after
// CKE deassertion before first MRS command can be asserted
//*****************************************************************
always @(posedge clk)
if (!cnt_pwron_cke_done_r) begin
cnt_txpr_r <= #TCQ 'b0;
cnt_txpr_done_r <= #TCQ 1'b0;
end else begin
cnt_txpr_r <= #TCQ cnt_txpr_r + 1;
if (!cnt_txpr_done_r)
cnt_txpr_done_r <= #TCQ (cnt_txpr_r == TXPR_DELAY_CNT);
end
//*****************************************************************
// Counter for the initial 400ns wait for issuing precharge all
// command after CKE assertion. Only for DDR2.
//*****************************************************************
always @(posedge clk)
if (!cnt_pwron_cke_done_r) begin
cnt_init_pre_wait_r <= #TCQ 'b0;
cnt_init_pre_wait_done_r <= #TCQ 1'b0;
end else begin
cnt_init_pre_wait_r <= #TCQ cnt_init_pre_wait_r + 1;
if (!cnt_init_pre_wait_done_r)
cnt_init_pre_wait_done_r
<= #TCQ (cnt_init_pre_wait_r >= DDR2_INIT_PRE_CNT);
end
//*****************************************************************
// Wait for both DLL to lock (tDLLK) and ZQ calibration to finish
// (tZQINIT). Both take the same amount of time (512*tCK)
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_ZQCL) begin
cnt_dllk_zqinit_r <= #TCQ 'b0;
cnt_dllk_zqinit_done_r <= #TCQ 1'b0;
end else if (~(phy_ctl_full || phy_cmd_full)) begin
cnt_dllk_zqinit_r <= #TCQ cnt_dllk_zqinit_r + 1;
if (!cnt_dllk_zqinit_done_r)
cnt_dllk_zqinit_done_r
<= #TCQ (cnt_dllk_zqinit_r == TDLLK_TZQINIT_DELAY_CNT);
end
//*****************************************************************
// Keep track of which MRS counter needs to be programmed during
// memory initialization
// The counter and the done signal are reset an additional time
// for DDR2. The same signals are used for the additional DDR2
// initialization sequence.
//*****************************************************************
always @(posedge clk)
if ((init_state_r == INIT_IDLE)||
((init_state_r == INIT_REFRESH)
&& (~mem_init_done_r))) begin
cnt_init_mr_r <= #TCQ 'b0;
cnt_init_mr_done_r <= #TCQ 1'b0;
end else if (init_state_r == INIT_LOAD_MR) begin
cnt_init_mr_r <= #TCQ cnt_init_mr_r + 1;
cnt_init_mr_done_r <= #TCQ (cnt_init_mr_r == INIT_CNT_MR_DONE);
end
//*****************************************************************
// Flag to tell if the first precharge for DDR2 init sequence is
// done
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE)
ddr2_pre_flag_r<= #TCQ 'b0;
else if (init_state_r == INIT_LOAD_MR)
ddr2_pre_flag_r<= #TCQ 1'b1;
// reset the flag for multi rank case
else if ((ddr2_refresh_flag_r) &&
(init_state_r == INIT_LOAD_MR_WAIT)&&
(cnt_cmd_done_r) && (cnt_init_mr_done_r))
ddr2_pre_flag_r <= #TCQ 'b0;
//*****************************************************************
// Flag to tell if the refresh stat for DDR2 init sequence is
// reached
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE)
ddr2_refresh_flag_r<= #TCQ 'b0;
else if ((init_state_r == INIT_REFRESH) && (~mem_init_done_r))
// reset the flag for multi rank case
ddr2_refresh_flag_r<= #TCQ 1'b1;
else if ((ddr2_refresh_flag_r) &&
(init_state_r == INIT_LOAD_MR_WAIT)&&
(cnt_cmd_done_r) && (cnt_init_mr_done_r))
ddr2_refresh_flag_r <= #TCQ 'b0;
//*****************************************************************
// Keep track of the number of auto refreshes for DDR2
// initialization. The spec asks for a minimum of two refreshes.
// Four refreshes are performed here. The two extra refreshes is to
// account for the 200 clock cycle wait between step h and l.
// Without the two extra refreshes we would have to have a
// wait state.
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE) begin
cnt_init_af_r <= #TCQ 'b0;
cnt_init_af_done_r <= #TCQ 1'b0;
end else if ((init_state_r == INIT_REFRESH) && (~mem_init_done_r))begin
cnt_init_af_r <= #TCQ cnt_init_af_r + 1;
cnt_init_af_done_r <= #TCQ (cnt_init_af_r == 2'b11);
end
//*****************************************************************
// Keep track of the register control word programming for
// DDR3 RDIMM
//*****************************************************************
always @(posedge clk)
if (init_state_r == INIT_IDLE)
reg_ctrl_cnt_r <= #TCQ 'b0;
else if (init_state_r == INIT_REG_WRITE)
reg_ctrl_cnt_r <= #TCQ reg_ctrl_cnt_r + 1;
generate
if (RANKS < 2) begin: one_rank
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done ||
(complex_byte_rd_done) || prbs_rdlvl_done_pulse )
stg1_wr_done <= #TCQ 1'b0;
else if (init_state_r == INIT_RDLVL_STG1_WRITE_READ)
stg1_wr_done <= #TCQ 1'b1;
end else begin: two_ranks
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done ||
(complex_byte_rd_done) || prbs_rdlvl_done_pulse ||
(rdlvl_stg1_rank_done ))
stg1_wr_done <= #TCQ 1'b0;
else if (init_state_r == INIT_RDLVL_STG1_WRITE_READ)
stg1_wr_done <= #TCQ 1'b1;
end
endgenerate
always @(posedge clk)
if (rst)
rnk_ref_cnt <= #TCQ 1'b0;
else if (stg1_wr_done &&
(init_state_r == INIT_REFRESH_WAIT) && cnt_cmd_done_r)
rnk_ref_cnt <= #TCQ ~rnk_ref_cnt;
always @(posedge clk)
if (rst || (init_state_r == INIT_MPR_RDEN) || (init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) || (init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) || (init_state_r ==INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT))
num_refresh <= #TCQ 'd0;
else if ((init_state_r == INIT_REFRESH) &&
(~pi_dqs_found_done || ((DRAM_TYPE == "DDR3") && ~oclkdelay_calib_done) ||
(rdlvl_stg1_done && ~prbs_rdlvl_done) ||
(prbs_rdlvl_done && ~complex_oclkdelay_calib_done) ||
((CLK_PERIOD/nCK_PER_CLK <= 2500) && wrcal_done && ~rdlvl_stg1_done) ||
((CLK_PERIOD/nCK_PER_CLK > 2500) && wrlvl_done_r1 && ~rdlvl_stg1_done)))
num_refresh <= #TCQ num_refresh + 1;
//***************************************************************************
// Initialization state machine
//***************************************************************************
//*****************************************************************
// Next-state logic
//*****************************************************************
always @(posedge clk)
if (rst)begin
init_state_r <= #TCQ INIT_IDLE;
init_state_r1 <= #TCQ INIT_IDLE;
end else begin
init_state_r <= #TCQ init_next_state;
init_state_r1 <= #TCQ init_state_r;
end
always @(*) begin
init_next_state = init_state_r;
(* full_case, parallel_case *) case (init_state_r)
//*******************************************************
// DRAM initialization
//*******************************************************
// Initial state - wait for:
// 1. Power-on delays to pass
// 2. PHY Control Block to assert phy_ctl_ready
// 3. PHY Control FIFO must not be FULL
// 4. Read path initialization to finish
INIT_IDLE:
if (cnt_pwron_cke_done_r && phy_ctl_ready && ck_addr_cmd_delay_done && delay_incdec_done
&& ~(phy_ctl_full || phy_cmd_full) ) begin
// If skipping memory initialization (simulation only)
if (SIM_INIT_OPTION == "SKIP_INIT")
//if (WRLVL == "ON")
// Proceed to write leveling
// init_next_state = INIT_WRLVL_START;
//else //if (SIM_CAL_OPTION != "SKIP_CAL")
// Proceed to Phaser_In phase lock
init_next_state = INIT_RDLVL_ACT;
// else
// Skip read leveling
//init_next_state = INIT_DONE;
else
init_next_state = INIT_WAIT_CKE_EXIT;
end
// Wait minimum of Reset CKE exit time (tXPR = max(tXS,
INIT_WAIT_CKE_EXIT:
if ((cnt_txpr_done_r) && (DRAM_TYPE == "DDR3")
&& ~(phy_ctl_full || phy_cmd_full)) begin
if((REG_CTRL == "ON") && ((nCS_PER_RANK > 1) ||
(RANKS > 1)))
//register write for reg dimm. Some register chips
// have the register chip in a pre-programmed state
// in that case the nCS_PER_RANK == 1 && RANKS == 1
init_next_state = INIT_REG_WRITE;
else
// Load mode register - this state is repeated multiple times
init_next_state = INIT_LOAD_MR;
end else if ((cnt_init_pre_wait_done_r) && (DRAM_TYPE == "DDR2")
&& ~(phy_ctl_full || phy_cmd_full))
// DDR2 start with a precharge all command
init_next_state = INIT_DDR2_PRECHARGE;
INIT_REG_WRITE:
init_next_state = INIT_REG_WRITE_WAIT;
INIT_REG_WRITE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if(reg_ctrl_cnt_r == 4'd8)
init_next_state = INIT_LOAD_MR;
else
init_next_state = INIT_REG_WRITE;
end
INIT_LOAD_MR:
init_next_state = INIT_LOAD_MR_WAIT;
// After loading MR, wait at least tMRD
INIT_LOAD_MR_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
// If finished loading all mode registers, proceed to next step
if (prbs_rdlvl_done && pi_dqs_found_done && rdlvl_stg1_done)
// for ddr3 when the correct burst length is writtern at end
init_next_state = INIT_PRECHARGE;
else if (~wrcal_done && temp_lmr_done)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (cnt_init_mr_done_r)begin
if(DRAM_TYPE == "DDR3")
init_next_state = INIT_ZQCL;
else begin //DDR2
if(ddr2_refresh_flag_r)begin
// memory initialization per rank for multi-rank case
if (!mem_init_done_r && (chip_cnt_r <= RANKS-1))
init_next_state = INIT_DDR2_MULTI_RANK;
else
init_next_state = INIT_RDLVL_ACT;
// ddr2 initialization done.load mode state after refresh
end else
init_next_state = INIT_DDR2_PRECHARGE;
end
end else
init_next_state = INIT_LOAD_MR;
end
// DDR2 multi rank transition state
INIT_DDR2_MULTI_RANK:
init_next_state = INIT_DDR2_MULTI_RANK_WAIT;
INIT_DDR2_MULTI_RANK_WAIT:
init_next_state = INIT_DDR2_PRECHARGE;
// Initial ZQ calibration
INIT_ZQCL:
init_next_state = INIT_WAIT_DLLK_ZQINIT;
// Wait until both DLL have locked, and ZQ calibration done
INIT_WAIT_DLLK_ZQINIT:
if (cnt_dllk_zqinit_done_r && ~(phy_ctl_full || phy_cmd_full))
// memory initialization per rank for multi-rank case
if (!mem_init_done_r && (chip_cnt_r <= RANKS-1))
init_next_state = INIT_LOAD_MR;
//else if (WRLVL == "ON")
// init_next_state = INIT_WRLVL_START;
else
// skip write-leveling (e.g. for DDR2 interface)
init_next_state = INIT_RDLVL_ACT;
// Initial precharge for DDR2
INIT_DDR2_PRECHARGE:
init_next_state = INIT_DDR2_PRECHARGE_WAIT;
INIT_DDR2_PRECHARGE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if (ddr2_pre_flag_r)
init_next_state = INIT_REFRESH;
else // from precharge state initially go to load mode
init_next_state = INIT_LOAD_MR;
end
INIT_REFRESH:
if ((RANKS == 2) && (chip_cnt_r == RANKS - 1))
init_next_state = INIT_REFRESH_RNK2_WAIT;
else
init_next_state = INIT_REFRESH_WAIT;
INIT_REFRESH_RNK2_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_PRECHARGE;
INIT_REFRESH_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))begin
if(cnt_init_af_done_r && (~mem_init_done_r))
// go to lm state as part of DDR2 init sequence
init_next_state = INIT_LOAD_MR;
// Go to state to issue back-to-back writes during limit check and centering
else if (~oclkdelay_calib_done && (mpr_last_byte_done || mpr_rdlvl_done) && (DRAM_TYPE == "DDR3")) begin
if (num_refresh == 'd8)
init_next_state = INIT_OCAL_CENTER_ACT;
else
init_next_state = INIT_REFRESH;
end else if(rdlvl_stg1_done && oclkdelay_center_calib_done &&
complex_oclkdelay_calib_done && ~wrlvl_done_r1 && (WRLVL == "ON"))
init_next_state = INIT_WRLVL_START;
else if (pi_dqs_found_done && ~wrlvl_done_r1 && ~wrlvl_final && ~wrlvl_byte_redo && (WRLVL == "ON"))
init_next_state = INIT_WRLVL_START;
else if ((((prbs_last_byte_done_r || prbs_rdlvl_done) && ~complex_oclkdelay_calib_done
&& pi_dqs_found_done) && (WRLVL == "ON")) //&& rdlvl_stg1_done // changed for new algo 3/26
&& mem_init_done_r) begin
if (num_refresh == 'd8) begin
if (BYPASS_COMPLEX_OCAL == "FALSE")
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else
init_next_state = INIT_WRCAL_ACT;
end else
init_next_state = INIT_REFRESH;
end else if (~pi_dqs_found_done ||
(rdlvl_stg1_done && ~prbs_rdlvl_done && ~complex_oclkdelay_calib_done) ||
((CLK_PERIOD/nCK_PER_CLK <= 2500) && wrcal_done && ~rdlvl_stg1_done) ||
((CLK_PERIOD/nCK_PER_CLK > 2500) && wrlvl_done_r1 && ~rdlvl_stg1_done)) begin
if (num_refresh == 'd8)
init_next_state = INIT_RDLVL_ACT;
else
init_next_state = INIT_REFRESH;
end else if ((~wrcal_done && wrlvl_byte_redo)&& (DRAM_TYPE == "DDR3")
&& (CLK_PERIOD/nCK_PER_CLK > 2500))
init_next_state = INIT_WRLVL_LOAD_MR2;
else if (((prbs_rdlvl_done && rdlvl_stg1_done && complex_oclkdelay_calib_done && pi_dqs_found_done) && (WRLVL == "ON"))
&& mem_init_done_r && (CLK_PERIOD/nCK_PER_CLK > 2500))
init_next_state = INIT_WRCAL_ACT;
else if (pi_dqs_found_done && (DRAM_TYPE == "DDR3") && ~(mpr_last_byte_done || mpr_rdlvl_done)) begin
if (num_refresh == 'd8)
init_next_state = INIT_MPR_RDEN;
else
init_next_state = INIT_REFRESH;
end else if (((oclkdelay_calib_done && wrlvl_final && ~wrlvl_done_r1) || // changed for new algo 3/25
(~wrcal_done && wrlvl_byte_redo)) && (DRAM_TYPE == "DDR3"))
init_next_state = INIT_WRLVL_LOAD_MR2;
else if ((~wrcal_done && (WRLVL == "ON") && (CLK_PERIOD/nCK_PER_CLK <= 2500))
&& pi_dqs_found_done)
init_next_state = INIT_WRCAL_ACT;
else if (mem_init_done_r) begin
if (RANKS < 2)
init_next_state = INIT_RDLVL_ACT;
else if (stg1_wr_done && ~rnk_ref_cnt && ~rdlvl_stg1_done)
init_next_state = INIT_PRECHARGE;
else
init_next_state = INIT_RDLVL_ACT;
end else // to DDR2 init state as part of DDR2 init sequence
init_next_state = INIT_REFRESH;
end
//******************************************************
// Write Leveling
//*******************************************************
// Enable write leveling in MR1 and start write leveling
// for current rank
INIT_WRLVL_START:
init_next_state = INIT_WRLVL_WAIT;
// Wait for both MR load and write leveling to complete
// (write leveling should take much longer than MR load..)
INIT_WRLVL_WAIT:
if (wrlvl_rank_done_r7 && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_WRLVL_LOAD_MR;
// Disable write leveling in MR1 for current rank
INIT_WRLVL_LOAD_MR:
init_next_state = INIT_WRLVL_LOAD_MR_WAIT;
INIT_WRLVL_LOAD_MR_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_WRLVL_LOAD_MR2;
// Load MR2 to set ODT: Dynamic ODT for single rank case
// And ODTs for multi-rank case as well
INIT_WRLVL_LOAD_MR2:
init_next_state = INIT_WRLVL_LOAD_MR2_WAIT;
// Wait tMRD before proceeding
INIT_WRLVL_LOAD_MR2_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
//if (wrlvl_byte_done)
// init_next_state = INIT_PRECHARGE_PREWAIT;
// else if ((RANKS == 2) && wrlvl_rank_done_r2)
// init_next_state = INIT_WRLVL_LOAD_MR2_WAIT;
if (~wrlvl_done_r1)
init_next_state = INIT_WRLVL_START;
else if (SIM_CAL_OPTION == "SKIP_CAL")
// If skip rdlvl, then we're done
init_next_state = INIT_DONE;
else
// Otherwise, proceed to read leveling
//init_next_state = INIT_RDLVL_ACT;
init_next_state = INIT_PRECHARGE_PREWAIT;
end
//*******************************************************
// Read Leveling
//*******************************************************
// single row activate. All subsequent read leveling writes and
// read will take place in this row
INIT_RDLVL_ACT:
init_next_state = INIT_RDLVL_ACT_WAIT;
// hang out for awhile before issuing subsequent column commands
// it's also possible to reach this state at various points
// during read leveling - determine what the current stage is
INIT_RDLVL_ACT_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
// Just finished an activate. Now either write, read, or precharge
// depending on where we are in the training sequence
if (!pi_calib_done_r1)
init_next_state = INIT_PI_PHASELOCK_READS;
else if (!pi_dqs_found_done)
// (!pi_dqs_found_start || pi_dqs_found_rank_done))
init_next_state = INIT_RDLVL_STG2_READ;
else if (~wrcal_done && (WRLVL == "ON") && (CLK_PERIOD/nCK_PER_CLK <= 2500))
init_next_state = INIT_WRCAL_ACT_WAIT;
else if ((!rdlvl_stg1_done && ~stg1_wr_done && ~rdlvl_last_byte_done) ||
(!prbs_rdlvl_done && ~stg1_wr_done && ~prbs_last_byte_done)) begin
// Added to avoid rdlvl_stg1 write data pattern at the start of PRBS rdlvl
if (!prbs_rdlvl_done && ~stg1_wr_done && rdlvl_last_byte_done)
init_next_state = INIT_RDLVL_ACT_WAIT;
else
init_next_state = INIT_RDLVL_STG1_WRITE;
end else if ((!rdlvl_stg1_done && rdlvl_stg1_start_int) || !prbs_rdlvl_done) begin
if (rdlvl_last_byte_done || prbs_last_byte_done)
// Added to avoid extra reads at the end of read leveling
init_next_state = INIT_RDLVL_ACT_WAIT;
else begin
// Case 2: If in stage 1, and just precharged after training
// previous byte, then continue reading
if (rdlvl_stg1_done)
init_next_state = INIT_RDLVL_STG1_WRITE_READ;
else
init_next_state = INIT_RDLVL_STG1_READ;
end
end else if ((prbs_rdlvl_done && rdlvl_stg1_done && (RANKS == 1)) && (WRLVL == "ON") &&
(CLK_PERIOD/nCK_PER_CLK > 2500))
init_next_state = INIT_WRCAL_ACT_WAIT;
else
// Otherwise, if we're finished with calibration, then precharge
// the row - silly, because we just opened it - possible to take
// this out by adding logic to avoid the ACT in first place. Make
// sure that cnt_cmd_done will handle tRAS(min)
init_next_state = INIT_PRECHARGE_PREWAIT;
end
//**************************************************
// Back-to-back reads for Phaser_IN Phase locking
// DQS to FREQ_REF clock
//**************************************************
INIT_PI_PHASELOCK_READS:
if (pi_phase_locked_all_r3 && ~pi_phase_locked_all_r4)
init_next_state = INIT_PRECHARGE_PREWAIT;
//*********************************************
// Stage 1 read-leveling (write and continuous read)
//*********************************************
// Write training pattern for stage 1
// PRBS pattern of TBD length
INIT_RDLVL_STG1_WRITE:
// 4:1 DDR3 BL8 will require all 8 words in 1 DIV4 clock cycle
// 2:1 DDR2/DDR3 BL8 will require 2 DIV2 clock cycles for 8 words
// 2:1 DDR2 BL4 will require 1 DIV2 clock cycle for 4 words
// An entire row worth of writes issued before proceeding to reads
// The number of write is (2^column width)/burst length to accomodate
// PRBS pattern for window detection.
//VCCO/VCCAUX write is not done
if ((complex_num_writes_dec == 1) && ~complex_row0_wr_done && prbs_rdlvl_done && rdlvl_stg1_done_r1)
init_next_state = INIT_OCAL_COMPLEX_WRITE_WAIT;
//back to back write from row1
else if (stg1_wr_rd_cnt == 9'd1) begin
if (rdlvl_stg1_done_r1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else
init_next_state = INIT_RDLVL_STG1_WRITE_READ;
end
INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT:
if(read_pause_ext) begin
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
end else begin
if (prech_req_posedge_r || complex_rdlvl_int_ref_req || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15)
//At the end of the byte, it goes to REFRESH
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE;
end
INIT_RDLVL_COMPLEX_PRECHARGE:
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_WAIT;
INIT_RDLVL_COMPLEX_PRECHARGE_WAIT:
if (prech_req_posedge_r || complex_rdlvl_int_ref_req || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15) begin
if (prbs_rdlvl_done || prbs_last_byte_done_r) begin // changed for new algo 3/26
// added condition to ensure that limit starts after rdlvl_stg1_done is asserted in the bypass complex rdlvl mode
if ((~prbs_rdlvl_done && complex_oclkdelay_calib_start_int) || ~lim_done)
init_next_state = INIT_OCAL_CENTER_ACT; //INIT_OCAL_COMPLEX_ACT; // changed for new algo 3/26
else if (lim_done && complex_oclkdelay_calib_start_r2)
init_next_state = INIT_RDLVL_COMPLEX_ACT;
else
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_WAIT;
end else
init_next_state = INIT_RDLVL_COMPLEX_ACT;
end
INIT_RDLVL_COMPLEX_ACT:
init_next_state = INIT_RDLVL_COMPLEX_ACT_WAIT;
INIT_RDLVL_COMPLEX_ACT_WAIT:
if (complex_rdlvl_int_ref_req)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15) begin
if (oclkdelay_center_calib_start)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
else if (stg1_wr_done)
init_next_state = INIT_RDLVL_COMPLEX_READ;
else if (~complex_row1_wr_done)
if (complex_oclkdelay_calib_start_int && complex_ocal_num_samples_done_r) //WAIT for resume signal for write
init_next_state = INIT_OCAL_COMPLEX_RESUME_WAIT;
else
init_next_state = INIT_RDLVL_STG1_WRITE;
else
init_next_state = INIT_RDLVL_STG1_WRITE_READ;
end
// Write-read turnaround
INIT_RDLVL_STG1_WRITE_READ:
if (reset_rd_addr_r1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))begin
if (rdlvl_stg1_done_r1)
init_next_state = INIT_RDLVL_COMPLEX_READ;
else
init_next_state = INIT_RDLVL_STG1_READ;
end
// Continuous read, where interruptible by precharge request from
// calibration logic. Also precharges when stage 1 is complete
// No precharges when reads provided to Phaser_IN for phase locking
// FREQ_REF to read DQS since data integrity is not important.
INIT_RDLVL_STG1_READ:
if (rdlvl_stg1_rank_done || (rdlvl_stg1_done && ~rdlvl_stg1_done_r1) ||
prech_req_posedge_r || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
INIT_RDLVL_COMPLEX_READ:
if (prech_req_posedge_r || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
//For non-back-to-back reads from row0 (VCCO and VCCAUX pattern)
else if (~prbs_rdlvl_done && (complex_num_reads_dec == 1) && ~complex_row0_rd_done)
init_next_state = INIT_RDLVL_COMPLEX_READ_WAIT;
//For back-to-back reads from row1 (ISI pattern)
else if (stg1_wr_rd_cnt == 'd1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
INIT_RDLVL_COMPLEX_READ_WAIT:
if (prech_req_posedge_r || complex_rdlvl_int_ref_req || (prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (stg1_wr_rd_cnt == 'd1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15)
init_next_state = INIT_RDLVL_COMPLEX_READ;
//*********************************************
// DQSFOUND calibration (set of 4 reads with gaps)
//*********************************************
// Read of training data. Note that Stage 2 is not a constant read,
// instead there is a large gap between each set of back-to-back reads
INIT_RDLVL_STG2_READ:
// 4 read commands issued back-to-back
if (num_reads == 'b1)
init_next_state = INIT_RDLVL_STG2_READ_WAIT;
// Wait before issuing the next set of reads. If a precharge request
// comes in then handle - this can occur after stage 2 calibration is
// completed for a DQS group
INIT_RDLVL_STG2_READ_WAIT:
if (~(phy_ctl_full || phy_cmd_full)) begin
if (pi_dqs_found_rank_done ||
pi_dqs_found_done || prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (cnt_cmd_done_r)
init_next_state = INIT_RDLVL_STG2_READ;
end
//******************************************************************
// MPR Read Leveling for DDR3 OCLK_DELAYED calibration
//******************************************************************
// Issue Load Mode Register 3 command with A[2]=1, A[1:0]=2'b00
// to enable Multi Purpose Register (MPR) Read
INIT_MPR_RDEN:
init_next_state = INIT_MPR_WAIT;
//Wait tMRD, tMOD
INIT_MPR_WAIT:
if (cnt_cmd_done_r) begin
init_next_state = INIT_MPR_READ;
end
// Issue back-to-back read commands to read from MPR with
// Address bus 0x0000 for BL=8. DQ[0] will output the pre-defined
// MPR pattern of 01010101 (Rise0 = 1'b0, Fall0 = 1'b1 ...)
INIT_MPR_READ:
if (mpr_rdlvl_done || mpr_rnk_done || rdlvl_prech_req)
init_next_state = INIT_MPR_DISABLE_PREWAIT;
INIT_MPR_DISABLE_PREWAIT:
if (cnt_cmd_done_r)
init_next_state = INIT_MPR_DISABLE;
// Issue Load Mode Register 3 command with A[2]=0 to disable
// MPR read
INIT_MPR_DISABLE:
init_next_state = INIT_MPR_DISABLE_WAIT;
INIT_MPR_DISABLE_WAIT:
init_next_state = INIT_PRECHARGE_PREWAIT;
//***********************************************************************
// OCLKDELAY Calibration
//***********************************************************************
// This calibration requires single write followed by single read to
// determine the Phaser_Out stage 3 delay required to center write DQS
// in write DQ valid window.
// Single Row Activate command before issuing Write command
INIT_OCLKDELAY_ACT:
init_next_state = INIT_OCLKDELAY_ACT_WAIT;
INIT_OCLKDELAY_ACT_WAIT:
if (cnt_cmd_done_r && ~oclk_prech_req)
init_next_state = INIT_OCLKDELAY_WRITE;
else if (oclkdelay_calib_done || prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
INIT_OCLKDELAY_WRITE:
if (oclk_wr_cnt == 4'd1)
init_next_state = INIT_OCLKDELAY_WRITE_WAIT;
INIT_OCLKDELAY_WRITE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if (oclkdelay_int_ref_req)
init_next_state = INIT_PRECHARGE_PREWAIT;
else
init_next_state = INIT_OCLKDELAY_READ;
end
INIT_OCLKDELAY_READ:
init_next_state = INIT_OCLKDELAY_READ_WAIT;
INIT_OCLKDELAY_READ_WAIT:
if (~(phy_ctl_full || phy_cmd_full)) begin
if ((oclk_calib_resume_level || oclk_calib_resume) && ~oclkdelay_int_ref_req)
init_next_state = INIT_OCLKDELAY_WRITE;
else if (oclkdelay_calib_done || prech_req_posedge_r ||
wrlvl_final || oclkdelay_int_ref_req)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (oclkdelay_center_calib_start)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
end
//*********************************************
// Write calibration
//*********************************************
// single row activate
INIT_WRCAL_ACT:
init_next_state = INIT_WRCAL_ACT_WAIT;
// hang out for awhile before issuing subsequent column command
INIT_WRCAL_ACT_WAIT:
if (cnt_cmd_done_r && ~wrcal_prech_req)
init_next_state = INIT_WRCAL_WRITE;
else if (wrcal_done || prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
// Write training pattern for write calibration
INIT_WRCAL_WRITE:
// Once we've issued enough commands for 8 words - proceed to reads
//if (burst_addr_r == 1'b1)
if (wrcal_wr_cnt == 4'd1)
init_next_state = INIT_WRCAL_WRITE_READ;
// Write-read turnaround
INIT_WRCAL_WRITE_READ:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_WRCAL_READ;
else if (dqsfound_retry)
init_next_state = INIT_RDLVL_STG2_READ_WAIT;
INIT_WRCAL_READ:
if (burst_addr_r == 1'b1)
init_next_state = INIT_WRCAL_READ_WAIT;
INIT_WRCAL_READ_WAIT:
if (~(phy_ctl_full || phy_cmd_full)) begin
if (wrcal_resume_r) begin
if (wrcal_final_chk)
init_next_state = INIT_WRCAL_READ;
else
init_next_state = INIT_WRCAL_WRITE;
end else if (wrcal_done || prech_req_posedge_r || wrcal_act_req ||
// Added to support PO fine delay inc when TG errors
wrlvl_byte_redo || (temp_wrcal_done && ~temp_lmr_done))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (dqsfound_retry)
init_next_state = INIT_RDLVL_STG2_READ_WAIT;
else if (wrcal_read_req && cnt_wrcal_rd)
init_next_state = INIT_WRCAL_MULT_READS;
end
INIT_WRCAL_MULT_READS:
// multiple read commands issued back-to-back
if (wrcal_reads == 'b1)
init_next_state = INIT_WRCAL_READ_WAIT;
//*********************************************
// Handling of precharge during and in between read-level stages
//*********************************************
// Make sure we aren't violating any timing specs by precharging
// immediately
INIT_PRECHARGE_PREWAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full))
init_next_state = INIT_PRECHARGE;
// Initiate precharge
INIT_PRECHARGE:
init_next_state = INIT_PRECHARGE_WAIT;
INIT_PRECHARGE_WAIT:
if (cnt_cmd_done_r && ~(phy_ctl_full || phy_cmd_full)) begin
if ((wrcal_sanity_chk_done && (DRAM_TYPE == "DDR3")) ||
(rdlvl_stg1_done && prbs_rdlvl_done && pi_dqs_found_done &&
(DRAM_TYPE == "DDR2")))
init_next_state = INIT_DONE;
else if ((wrcal_done || (WRLVL == "OFF")) && rdlvl_stg1_done && prbs_rdlvl_done &&
pi_dqs_found_done && complex_oclkdelay_calib_done && wrlvl_done_r1 && ((ddr3_lm_done_r) || (DRAM_TYPE == "DDR2")))
init_next_state = INIT_WRCAL_ACT;
else if ((wrcal_done || (WRLVL == "OFF") || (~wrcal_done && temp_wrcal_done && ~temp_lmr_done))
&& (rdlvl_stg1_done || (~wrcal_done && temp_wrcal_done && ~temp_lmr_done))
&& prbs_rdlvl_done && complex_oclkdelay_calib_done && wrlvl_done_r1 &rdlvl_stg1_done && pi_dqs_found_done) begin
// after all calibration program the correct burst length
init_next_state = INIT_LOAD_MR;
// Added to support PO fine delay inc when TG errors
end else if (~wrcal_done && temp_wrcal_done && temp_lmr_done)
init_next_state = INIT_WRCAL_READ_WAIT;
else if (rdlvl_stg1_done && pi_dqs_found_done && (WRLVL == "ON"))
// If read leveling finished, proceed to write calibration
init_next_state = INIT_REFRESH;
else
// Otherwise, open row for read-leveling purposes
init_next_state = INIT_REFRESH;
end
//*******************************************************
// COMPLEX OCLK calibration - for fragmented write
//*******************************************************
INIT_OCAL_COMPLEX_ACT:
init_next_state = INIT_OCAL_COMPLEX_ACT_WAIT;
INIT_OCAL_COMPLEX_ACT_WAIT:
if (complex_wait_cnt =='d15)
init_next_state = INIT_RDLVL_STG1_WRITE;
INIT_OCAL_COMPLEX_WRITE_WAIT:
if (prech_req_posedge_r || (complex_oclkdelay_calib_done && ~complex_oclkdelay_calib_done_r1))
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (stg1_wr_rd_cnt == 'd1)
init_next_state = INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT;
else if (complex_wait_cnt == 'd15)
init_next_state = INIT_RDLVL_STG1_WRITE;
//wait for all srg2/stg3 tap movement is done and go back to write again
INIT_OCAL_COMPLEX_RESUME_WAIT:
if (complex_oclk_calib_resume)
init_next_state = INIT_RDLVL_STG1_WRITE;
else if (complex_oclkdelay_calib_done || complex_ocal_ref_req )
init_next_state = INIT_PRECHARGE_PREWAIT;
//*******************************************************
// OCAL STG3 Centering calibration
//*******************************************************
INIT_OCAL_CENTER_ACT:
init_next_state = INIT_OCAL_CENTER_ACT_WAIT;
INIT_OCAL_CENTER_ACT_WAIT:
if (ocal_act_wait_cnt == 'd15)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
INIT_OCAL_CENTER_WRITE:
if(!oclk_center_write_resume && !lim_wr_req)
init_next_state = INIT_OCAL_CENTER_WRITE_WAIT;
INIT_OCAL_CENTER_WRITE_WAIT:
//if (oclkdelay_center_calib_done || prech_req_posedge_r)
if (prech_req_posedge_r)
init_next_state = INIT_PRECHARGE_PREWAIT;
else if (lim_done && ~mask_lim_done && ~complex_mask_lim_done && oclkdelay_calib_done && ~oclkdelay_center_calib_start)
init_next_state = INIT_OCAL_COMPLEX_ACT_WAIT;
else if (lim_done && ~mask_lim_done && ~complex_mask_lim_done && ~oclkdelay_center_calib_start)
init_next_state = INIT_OCLKDELAY_READ_WAIT;
else if (oclk_center_write_resume || lim_wr_req)
init_next_state = INIT_OCAL_CENTER_WRITE;
//*******************************************************
// Initialization/Calibration done. Take a long rest, relax
//*******************************************************
INIT_DONE:
init_next_state = INIT_DONE;
endcase
end
//*****************************************************************
// Initialization done signal - asserted before leveling starts
//*****************************************************************
always @(posedge clk)
if (rst)
mem_init_done_r <= #TCQ 1'b0;
else if ((!cnt_dllk_zqinit_done_r &&
(cnt_dllk_zqinit_r == TDLLK_TZQINIT_DELAY_CNT) &&
(chip_cnt_r == RANKS-1) && (DRAM_TYPE == "DDR3"))
|| ( (init_state_r == INIT_LOAD_MR_WAIT) &&
(ddr2_refresh_flag_r) && (chip_cnt_r == RANKS-1)
&& (cnt_init_mr_done_r) && (DRAM_TYPE == "DDR2")))
mem_init_done_r <= #TCQ 1'b1;
//*****************************************************************
// Write Calibration signal to PHY Control Block - asserted before
// Write Leveling starts
//*****************************************************************
//generate
//if (RANKS < 2) begin: ranks_one
always @(posedge clk) begin
if (rst || (done_dqs_tap_inc &&
(init_state_r == INIT_WRLVL_LOAD_MR2)))
write_calib <= #TCQ 1'b0;
else if (wrlvl_active_r1)
write_calib <= #TCQ 1'b1;
end
//end else begin: ranks_two
// always @(posedge clk) begin
// if (rst ||
// ((init_state_r1 == INIT_WRLVL_LOAD_MR_WAIT) &&
// ((wrlvl_rank_done_r2 && (chip_cnt_r == RANKS-1)) ||
// (SIM_CAL_OPTION == "FAST_CAL"))))
// write_calib <= #TCQ 1'b0;
// else if (wrlvl_active_r1)
// write_calib <= #TCQ 1'b1;
// end
//end
//endgenerate
//*****************************************************************
// Read Calibration signal to PHY Control Block - asserted after
// Write Leveling during PHASER_IN phase locking stage.
// Must be de-asserted before Read Leveling
//*****************************************************************
always @(posedge clk) begin
if (rst || pi_calib_done_r1)
read_calib_int <= #TCQ 1'b0;
else if (~pi_calib_done_r1 && (init_state_r == INIT_RDLVL_ACT_WAIT) &&
(cnt_cmd_r == CNTNEXT_CMD))
read_calib_int <= #TCQ 1'b1;
end
always @(posedge clk)
read_calib_r <= #TCQ read_calib_int;
always @(posedge clk) begin
if (rst || pi_calib_done_r1)
read_calib <= #TCQ 1'b0;
else if (~pi_calib_done_r1 && (init_state_r == INIT_PI_PHASELOCK_READS))
read_calib <= #TCQ 1'b1;
end
always @(posedge clk)
if (rst)
pi_calib_done_r <= #TCQ 1'b0;
else if (pi_calib_rank_done_r)// && (chip_cnt_r == RANKS-1))
pi_calib_done_r <= #TCQ 1'b1;
always @(posedge clk)
if (rst)
pi_calib_rank_done_r <= #TCQ 1'b0;
else if (pi_phase_locked_all_r3 && ~pi_phase_locked_all_r4)
pi_calib_rank_done_r <= #TCQ 1'b1;
else
pi_calib_rank_done_r <= #TCQ 1'b0;
always @(posedge clk) begin
if (rst || ((PRE_REV3ES == "ON") && temp_wrcal_done && ~temp_wrcal_done_r))
pi_phaselock_timer <= #TCQ 'd0;
else if (((init_state_r == INIT_PI_PHASELOCK_READS) &&
(pi_phaselock_timer != PHASELOCKED_TIMEOUT)) ||
tg_timer_go)
pi_phaselock_timer <= #TCQ pi_phaselock_timer + 1;
else
pi_phaselock_timer <= #TCQ pi_phaselock_timer;
end
assign pi_phase_locked_err = (pi_phaselock_timer == PHASELOCKED_TIMEOUT) ? 1'b1 : 1'b0;
//*****************************************************************
// DDR3 final burst length programming done. For DDR3 during
// calibration the burst length is fixed to BL8. After calibration
// the correct burst length is programmed.
//*****************************************************************
always @(posedge clk)
if (rst)
ddr3_lm_done_r <= #TCQ 1'b0;
else if ((init_state_r == INIT_LOAD_MR_WAIT) &&
(chip_cnt_r == RANKS-1) && wrcal_done)
ddr3_lm_done_r <= #TCQ 1'b1;
always @(posedge clk) begin
pi_dqs_found_rank_done_r <= #TCQ pi_dqs_found_rank_done;
pi_phase_locked_all_r1 <= #TCQ pi_phase_locked_all;
pi_phase_locked_all_r2 <= #TCQ pi_phase_locked_all_r1;
pi_phase_locked_all_r3 <= #TCQ pi_phase_locked_all_r2;
pi_phase_locked_all_r4 <= #TCQ pi_phase_locked_all_r3;
pi_dqs_found_all_r <= #TCQ pi_dqs_found_done;
pi_calib_done_r1 <= #TCQ pi_calib_done_r;
end
//***************************************************************************
// Logic for deep memory (multi-rank) configurations
//***************************************************************************
// For DDR3 asserted when
generate
if (RANKS < 2) begin: single_rank
always @(posedge clk)
chip_cnt_r <= #TCQ 2'b00;
end else begin: dual_rank
always @(posedge clk)
if (rst ||
// Set chip_cnt_r to 2'b00 after both Ranks are read leveled
(rdlvl_stg1_done && prbs_rdlvl_done && ~wrcal_done) ||
// Set chip_cnt_r to 2'b00 after both Ranks are write leveled
(wrlvl_done_r &&
(init_state_r==INIT_WRLVL_LOAD_MR2_WAIT)))begin
chip_cnt_r <= #TCQ 2'b00;
end else if ((((init_state_r == INIT_WAIT_DLLK_ZQINIT) &&
(cnt_dllk_zqinit_r == TDLLK_TZQINIT_DELAY_CNT)) &&
(DRAM_TYPE == "DDR3")) ||
((init_state_r==INIT_REFRESH_RNK2_WAIT) &&
(cnt_cmd_r=='d36)) ||
//mpr_rnk_done ||
//(rdlvl_stg1_rank_done && ~rdlvl_last_byte_done) ||
//(stg1_wr_done && (init_state_r == INIT_REFRESH) &&
//~(rnk_ref_cnt && rdlvl_last_byte_done)) ||
// Increment chip_cnt_r to issue Refresh to second rank
(~pi_dqs_found_all_r &&
(init_state_r==INIT_PRECHARGE_PREWAIT) &&
(cnt_cmd_r=='d36)) ||
// Increment chip_cnt_r when DQSFOUND done for the Rank
(pi_dqs_found_rank_done && ~pi_dqs_found_rank_done_r) ||
((init_state_r == INIT_LOAD_MR_WAIT)&& cnt_cmd_done_r
&& wrcal_done) ||
((init_state_r == INIT_DDR2_MULTI_RANK)
&& (DRAM_TYPE == "DDR2"))) begin
if ((~mem_init_done_r || ~rdlvl_stg1_done || ~pi_dqs_found_done ||
// condition to increment chip_cnt during
// final burst length programming for DDR3
~pi_calib_done_r || wrcal_done) //~mpr_rdlvl_done ||
&& (chip_cnt_r != RANKS-1))
chip_cnt_r <= #TCQ chip_cnt_r + 1;
else
chip_cnt_r <= #TCQ 2'b00;
end
end
endgenerate
// verilint STARC-2.2.3.3 off
generate
if ((REG_CTRL == "ON") && (RANKS == 1)) begin: DDR3_RDIMM_1rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if (init_state_r == INIT_REG_WRITE) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if(!(CWL_M%2)) begin
phy_int_cs_n[0%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[1%nCK_PER_CLK] <= #TCQ 1'b0;
end else begin
phy_int_cs_n[2%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[3%nCK_PER_CLK] <= #TCQ 1'b0;
end
end else if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) //even CWL
phy_int_cs_n[0] <= #TCQ 1'b0;
else // odd CWL
phy_int_cs_n[1*nCS_PER_RANK] <= #TCQ 1'b0;
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end
end else if (RANKS == 1) begin: DDR3_1rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) begin //even CWL
for (n = 0; n < nCS_PER_RANK; n = n + 1) begin
phy_int_cs_n[n] <= #TCQ 1'b0;
end
end else begin //odd CWL
for (p = nCS_PER_RANK; p < 2*nCS_PER_RANK; p = p + 1) begin
phy_int_cs_n[p] <= #TCQ 1'b0;
end
end
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end
end else if ((REG_CTRL == "ON") && (RANKS == 2)) begin: DDR3_2rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if (init_state_r == INIT_REG_WRITE) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if(!(CWL_M%2)) begin
phy_int_cs_n[0%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[1%nCK_PER_CLK] <= #TCQ 1'b0;
end else begin
phy_int_cs_n[2%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[3%nCK_PER_CLK] <= #TCQ 1'b0;
end
end else begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
case (chip_cnt_r)
2'b00:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) //even CWL
phy_int_cs_n[0] <= #TCQ 1'b0;
else // odd CWL
phy_int_cs_n[1*CS_WIDTH*nCS_PER_RANK] <= #TCQ 1'b0;
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (n = 0; n < nCS_PER_RANK*nCK_PER_CLK*2; n = n + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[n+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
2'b01:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) //even CWL
phy_int_cs_n[1] <= #TCQ 1'b0;
else // odd CWL
phy_int_cs_n[1+1*CS_WIDTH*nCS_PER_RANK] <= #TCQ 1'b0;
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (p = nCS_PER_RANK; p < nCS_PER_RANK*nCK_PER_CLK*2; p = p + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[p+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
endcase
end
end
end else if (RANKS == 2) begin: DDR3_2rank
always @(posedge clk) begin
if (rst)
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
else if (init_state_r == INIT_REG_WRITE) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if(!(CWL_M%2)) begin
phy_int_cs_n[0%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[1%nCK_PER_CLK] <= #TCQ 1'b0;
end else begin
phy_int_cs_n[2%nCK_PER_CLK] <= #TCQ 1'b0;
phy_int_cs_n[3%nCK_PER_CLK] <= #TCQ 1'b0;
end
end else begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
case (chip_cnt_r)
2'b00:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) begin //even CWL
for (n = 0; n < nCS_PER_RANK; n = n + 1) begin
phy_int_cs_n[n] <= #TCQ 1'b0;
end
end else begin // odd CWL
for (p = CS_WIDTH*nCS_PER_RANK; p < (CS_WIDTH*nCS_PER_RANK + nCS_PER_RANK); p = p + 1) begin
phy_int_cs_n[p] <= #TCQ 1'b0;
end
end
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (n = 0; n < nCS_PER_RANK*nCK_PER_CLK*2; n = n + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[n+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
2'b01:begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(rdlvl_wr_rd && new_burst_r && ~mmcm_wr)) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
if (!(CWL_M % 2)) begin //even CWL
for (q = nCS_PER_RANK; q < (2 * nCS_PER_RANK); q = q + 1) begin
phy_int_cs_n[q] <= #TCQ 1'b0;
end
end else begin // odd CWL
for (m = (nCS_PER_RANK*CS_WIDTH + nCS_PER_RANK); m < (nCS_PER_RANK*CS_WIDTH + 2*nCS_PER_RANK); m = m + 1) begin
phy_int_cs_n[m] <= #TCQ 1'b0;
end
end
end else
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
//for (p = nCS_PER_RANK; p < nCS_PER_RANK*nCK_PER_CLK*2; p = p + (nCS_PER_RANK*2)) begin
//
// phy_int_cs_n[p+:nCS_PER_RANK] <= #TCQ {nCS_PER_RANK{1'b0}};
//end
end
endcase
end
end // always @ (posedge clk)
end
// verilint STARC-2.2.3.3 on
// commented out for now. Need it for DDR2 2T timing
/* end else begin: DDR2
always @(posedge clk)
if (rst) begin
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end else begin
if (init_state_r == INIT_REG_WRITE) begin
// All ranks selected simultaneously
phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b0}};
end else if ((wrlvl_odt) ||
(init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH)) begin
phy_int_cs_n[0] <= #TCQ 1'b0;
end
else phy_int_cs_n <= #TCQ {CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK{1'b1}};
end // else: !if(rst)
end // block: DDR2 */
endgenerate
assign phy_cs_n = phy_int_cs_n;
//***************************************************************************
// Write/read burst logic for calibration
//***************************************************************************
assign rdlvl_wr = (init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE);
assign rdlvl_rd = (init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_MPR_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS);
assign rdlvl_wr_rd = rdlvl_wr | rdlvl_rd;
assign mmcm_wr = (init_state_r == INIT_OCAL_CENTER_WRITE); //used to de-assert cs_n during centering
// assign mmcm_wr = 'b0; // (init_state_r == INIT_OCAL_CENTER_WRITE);
//***************************************************************************
// Address generation and logic to count # of writes/reads issued during
// certain stages of calibration
//***************************************************************************
// Column address generation logic:
// Keep track of the current column address - since all bursts are in
// increments of 8 only during calibration, we need to keep track of
// addresses [COL_WIDTH-1:3], lower order address bits will always = 0
always @(posedge clk)
if (rst || wrcal_done)
burst_addr_r <= #TCQ 1'b0;
else if ((init_state_r == INIT_WRCAL_ACT_WAIT) ||
(init_state_r == INIT_OCLKDELAY_ACT_WAIT) ||
(init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS) ||
(init_state_r == INIT_WRCAL_READ_WAIT))
burst_addr_r <= #TCQ 1'b1;
else if (rdlvl_wr_rd && new_burst_r)
burst_addr_r <= #TCQ ~burst_addr_r;
else
burst_addr_r <= #TCQ 1'b0;
// Read Level Stage 1 requires writes to the entire row since
// a PRBS pattern is being written. This counter keeps track
// of the number of writes which depends on the column width
// The (stg1_wr_rd_cnt==9'd0) condition was added so the col
// address wraps around during stage1 reads
always @(posedge clk)
if (rst || ((init_state_r == INIT_RDLVL_STG1_WRITE_READ) &&
~rdlvl_stg1_done))
stg1_wr_rd_cnt <= #TCQ NUM_STG1_WR_RD;
else if (rdlvl_last_byte_done || (stg1_wr_rd_cnt == 9'd1) ||
(prbs_rdlvl_prech_req && (init_state_r == INIT_RDLVL_ACT_WAIT)) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) ) begin
if (~complex_row0_wr_done || wr_victim_inc ||
(complex_row1_wr_done && (~complex_row0_rd_done || (complex_row0_rd_done && complex_row1_rd_done))))
stg1_wr_rd_cnt <= #TCQ 'd127;
else
stg1_wr_rd_cnt <= #TCQ prbs_rdlvl_done?'d30 :'d22;
end else if (((init_state_r == INIT_RDLVL_STG1_WRITE) && new_burst_r && ~phy_data_full)
||((init_state_r == INIT_RDLVL_COMPLEX_READ) && rdlvl_stg1_done))
stg1_wr_rd_cnt <= #TCQ stg1_wr_rd_cnt - 1;
always @(posedge clk)
if (rst)
wr_victim_inc <= #TCQ 1'b0;
else if (complex_row0_wr_done && (stg1_wr_rd_cnt == 9'd2) && ~stg1_wr_done)
wr_victim_inc <= #TCQ 1'b1;
else
wr_victim_inc <= #TCQ 1'b0;
always @(posedge clk)
reset_rd_addr_r1 <= #TCQ reset_rd_addr;
generate
if (FIXED_VICTIM == "FALSE") begin: row_cnt_victim_rotate
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt == DQ_WIDTH*2-1)) || ~rdlvl_stg1_done_r1 || prbs_rdlvl_done)
complex_row_cnt <= #TCQ 'd0;
else if ((((stg1_wr_rd_cnt == 'd22) && ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(complex_rdlvl_int_ref_req && (init_state_r == INIT_REFRESH_WAIT) && (cnt_cmd_r == 'd127)))) ||
complex_victim_inc || (complex_sample_cnt_inc_r2 && ~complex_victim_inc) || wr_victim_inc || reset_rd_addr_r1)) begin
// During writes row count is incremented with every wr_victim_in and stg1_wr_rd_cnt=='d22
if ((complex_row_cnt < DQ_WIDTH*2-1) && ~stg1_wr_done)
complex_row_cnt <= #TCQ complex_row_cnt + 1;
// During reads row count requires different conditions for increments
else if (stg1_wr_done) begin
if (reset_rd_addr_r1)
complex_row_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt*16;
// When looping multiple times in the same victim bit in a byte
else if (complex_sample_cnt_inc_r2 && ~complex_victim_inc)
complex_row_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt*16 + rd_victim_sel*2;
// When looping through victim bits within a byte
else if (complex_row_cnt < pi_stg2_prbs_rdlvl_cnt*16+15)
complex_row_cnt <= #TCQ complex_row_cnt + 1;
// When the number of samples is done and tap is incremented within a byte
else
complex_row_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt*16;
end
end
end else begin: row_cnt_victim_fixed
always @(posedge clk)
if (rst || ~rdlvl_stg1_done_r1 || prbs_rdlvl_done)
complex_row_cnt <= #TCQ 'd0;
else if ((stg1_wr_rd_cnt == 'd22) && (((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_WAIT) && (complex_wait_cnt == 'd15)) || complex_rdlvl_int_ref_req))
complex_row_cnt <= #TCQ 'd1;
else
complex_row_cnt <= #TCQ 'd0;
end
endgenerate
//row count
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt_ocal == COMPLEX_ROW_CNT_BYTE-1)) || ~rdlvl_stg1_done_r1 || prbs_rdlvl_done_pulse || complex_byte_rd_done)
complex_row_cnt_ocal <= #TCQ 'd0;
else if ( prbs_rdlvl_done && (((stg1_wr_rd_cnt == 'd30) && (init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE)) ||
(complex_sample_cnt_inc_r2) || wr_victim_inc)) begin
// During writes row count is incremented with every wr_victim_in and stg1_wr_rd_cnt=='d22
if (complex_row_cnt_ocal < COMPLEX_ROW_CNT_BYTE-1) begin
complex_row_cnt_ocal <= #TCQ complex_row_cnt_ocal + 1;
end
end
always @(posedge clk)
if (rst)
complex_odt_ext <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) || (init_state_r == INIT_PRECHARGE))
complex_odt_ext <= #TCQ 1'b0;
else if (rdlvl_stg1_done_r1 && (stg1_wr_rd_cnt == 9'd1) && (init_state_r == INIT_RDLVL_STG1_WRITE))
complex_odt_ext <= #TCQ 1'b1;
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt == DQ_WIDTH*2-1))) begin
wr_victim_sel <= #TCQ 'd0;
wr_byte_cnt <= #TCQ 'd0;
end else if (rdlvl_stg1_done_r1 && wr_victim_inc) begin
wr_victim_sel <= #TCQ wr_victim_sel + 1;
if (wr_victim_sel == 'd7)
wr_byte_cnt <= #TCQ wr_byte_cnt + 1;
end
always @(posedge clk)
if (rst) begin
wr_victim_sel_ocal <= #TCQ 'd0;
end else if (wr_victim_inc && (complex_row_cnt_ocal == COMPLEX_ROW_CNT_BYTE-1)) begin
wr_victim_sel_ocal <= #TCQ 'd0;
end else if (prbs_rdlvl_done && wr_victim_inc) begin
wr_victim_sel_ocal <= #TCQ wr_victim_sel_ocal + 1;
end
always @(posedge clk)
if (rst) begin
victim_sel <= #TCQ 'd0;
victim_byte_cnt <= #TCQ 'd0;
end else if ((~stg1_wr_done && ~prbs_rdlvl_done) || (prbs_rdlvl_done && ~complex_wr_done)) begin
victim_sel <= #TCQ prbs_rdlvl_done? wr_victim_sel_ocal: wr_victim_sel;
victim_byte_cnt <= #TCQ prbs_rdlvl_done? complex_oclkdelay_calib_cnt:wr_byte_cnt;
end else begin
if( (init_state_r == INIT_RDLVL_COMPLEX_ACT) || reset_rd_addr)
victim_sel <= #TCQ prbs_rdlvl_done? complex_ocal_rd_victim_sel:rd_victim_sel;
victim_byte_cnt <= #TCQ prbs_rdlvl_done? complex_oclkdelay_calib_cnt:pi_stg2_prbs_rdlvl_cnt;
end
generate
if (FIXED_VICTIM == "FALSE") begin: wr_done_victim_rotate
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt < DQ_WIDTH*2-1) && ~prbs_rdlvl_done) ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done || prbs_rdlvl_done_pulse) begin
complex_row0_wr_done <= #TCQ 1'b0;
end else if ( rdlvl_stg1_done_r1 && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row0_wr_done <= #TCQ 1'b1;
end
always @(posedge clk)
if (rst || (wr_victim_inc && (complex_row_cnt < DQ_WIDTH*2-1) && ~prbs_rdlvl_done) ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done || prbs_rdlvl_done_pulse) begin
complex_row1_wr_done <= #TCQ 1'b0;
end else if (complex_row0_wr_done && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row1_wr_done <= #TCQ 1'b1;
end
end else begin: wr_done_victim_fixed
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done ) begin
complex_row0_wr_done <= #TCQ 1'b0;
end else if (rdlvl_stg1_done_r1 && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row0_wr_done <= #TCQ 1'b1;
end
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse ||
(wr_victim_inc && prbs_rdlvl_done && complex_row_cnt_ocal <COMPLEX_ROW_CNT_BYTE-1) ||
complex_byte_rd_done ) begin
complex_row1_wr_done <= #TCQ 1'b0;
end else if (complex_row0_wr_done && (stg1_wr_rd_cnt == 9'd2)) begin
complex_row1_wr_done <= #TCQ 1'b1;
end
end
endgenerate
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse)
complex_row0_rd_done <= #TCQ 1'b0;
else if (complex_sample_cnt_inc)
complex_row0_rd_done <= #TCQ 1'b0;
else if ( (prbs_rdlvl_start || complex_oclkdelay_calib_start_int) && (stg1_wr_rd_cnt == 9'd2) && complex_row0_wr_done && complex_row1_wr_done)
complex_row0_rd_done <= #TCQ 1'b1;
always @(posedge clk)
complex_row0_rd_done_r1 <= #TCQ complex_row0_rd_done;
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse)
complex_row1_rd_done <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) || (init_state_r == INIT_PRECHARGE))
complex_row1_rd_done <= #TCQ 1'b0;
else if (complex_row0_rd_done && (stg1_wr_rd_cnt == 9'd2))
complex_row1_rd_done <= #TCQ 1'b1;
always @(posedge clk)
complex_row1_rd_done_r1 <= #TCQ complex_row1_rd_done;
//calculate row rd num for complex_oclkdelay_calib
//once it reached to 8
always @ (posedge clk)
if (rst || prbs_rdlvl_done_pulse) complex_row1_rd_cnt <= #TCQ 'd0;
else
complex_row1_rd_cnt <= #TCQ (complex_row1_rd_done & ~complex_row1_rd_done_r1) ?
((complex_row1_rd_cnt == (COMPLEX_RD-1))? 0:complex_row1_rd_cnt + 'd1)
: complex_row1_rd_cnt;
//For write, reset rd_done for the byte
always @ (posedge clk) begin
if (rst || (init_state_r == INIT_RDLVL_STG1_WRITE) || prbs_rdlvl_done_pulse)
complex_byte_rd_done <= #TCQ 'b0;
else if (prbs_rdlvl_done && (complex_row1_rd_cnt == (COMPLEX_RD-1)) && (complex_row1_rd_done & ~complex_row1_rd_done_r1))
complex_byte_rd_done <= #TCQ 'b1;
end
always @ (posedge clk) begin
complex_byte_rd_done_r1 <= #TCQ complex_byte_rd_done;
complex_ocal_num_samples_inc <= #TCQ (complex_byte_rd_done & ~complex_byte_rd_done_r1);
end
generate
if (RANKS < 2) begin: one_rank_complex
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done || ( complex_oclkdelay_calib_done && (init_state_r == INIT_RDLVL_STG1_WRITE )) ||
(complex_byte_rd_done && init_state_r == INIT_RDLVL_COMPLEX_ACT) || prbs_rdlvl_done_pulse )
complex_wr_done <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
else if ((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
end else begin: dual_rank_complex
always @(posedge clk)
if ((init_state_r == INIT_IDLE) || rdlvl_last_byte_done || ( complex_oclkdelay_calib_done && (init_state_r == INIT_RDLVL_STG1_WRITE )) ||
(rdlvl_stg1_rank_done ) || (complex_byte_rd_done && init_state_r == INIT_RDLVL_COMPLEX_ACT) || prbs_rdlvl_done_pulse )
complex_wr_done <= #TCQ 1'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
else if ((init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) && complex_row1_wr_done && (complex_wait_cnt == 'd13))
complex_wr_done <= #TCQ 1'b1;
end
endgenerate
always @(posedge clk)
if (rst)
complex_wait_cnt <= #TCQ 'd0;
else if (((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_WAIT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT_WAIT) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)) && complex_wait_cnt < 'd15)
complex_wait_cnt <= #TCQ complex_wait_cnt + 1;
else
complex_wait_cnt <= #TCQ 'd0;
always @(posedge clk)
if (rst) begin
complex_num_reads <= #TCQ 'd1;
end else if ((((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) && (complex_wait_cnt == 'd14)) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) && ext_int_ref_req && (cnt_cmd_r == 'd127))) &&
~complex_row0_rd_done) begin
if (stg1_wr_rd_cnt > 'd85) begin
if (complex_num_reads < 'd6)
complex_num_reads <= #TCQ complex_num_reads + 1;
else
complex_num_reads <= #TCQ 'd1;
// Initila value for VCCAUX pattern is 3, 7, and 12
end else if (stg1_wr_rd_cnt > 'd73) begin
if (stg1_wr_rd_cnt == 'd85)
complex_num_reads <= #TCQ 'd3;
else if (complex_num_reads < 'd5)
complex_num_reads <= #TCQ complex_num_reads + 1;
end else if (stg1_wr_rd_cnt > 'd39) begin
if (stg1_wr_rd_cnt == 'd73)
complex_num_reads <= #TCQ 'd7;
else if (complex_num_reads < 'd10)
complex_num_reads <= #TCQ complex_num_reads + 1;
end else begin
if (stg1_wr_rd_cnt == 'd39)
complex_num_reads <= #TCQ 'd12;
else if (complex_num_reads < 'd14)
complex_num_reads <= #TCQ complex_num_reads + 1;
end
// Initialize to 1 at the start of reads or after precharge and activate
end else if ((((init_state_r == INIT_RDLVL_STG1_WRITE_READ) || (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)) && ~ext_int_ref_req) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) && (stg1_wr_rd_cnt == 'd22)))
complex_num_reads <= #TCQ 'd1;
always @(posedge clk)
if (rst)
complex_num_reads_dec <= #TCQ 'd1;
else if (((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) && (complex_wait_cnt == 'd15) && ~complex_row0_rd_done) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) || (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)))
complex_num_reads_dec <= #TCQ complex_num_reads;
else if ((init_state_r == INIT_RDLVL_COMPLEX_READ) && (complex_num_reads_dec > 'd0))
complex_num_reads_dec <= #TCQ complex_num_reads_dec - 1;
always @(posedge clk)
if (rst)
complex_address <= #TCQ 'd0;
else if (((init_state_r == INIT_RDLVL_COMPLEX_READ_WAIT) && (init_state_r1 != INIT_RDLVL_COMPLEX_READ_WAIT)) ||
((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (init_state_r1 != INIT_OCAL_COMPLEX_WRITE_WAIT)))
complex_address <= #TCQ phy_address[COL_WIDTH-1:0];
always @ (posedge clk)
if (rst)
complex_oclkdelay_calib_start_int <= #TCQ 'b0;
else if ((init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE_PREWAIT) && prbs_last_byte_done_r) // changed for new algo 3/26
complex_oclkdelay_calib_start_int <= #TCQ 'b1;
always @(posedge clk) begin
complex_oclkdelay_calib_start_r1 <= #TCQ complex_oclkdelay_calib_start_int;
complex_oclkdelay_calib_start_r2 <= #TCQ complex_oclkdelay_calib_start_r1;
end
always @ (posedge clk)
if (rst)
complex_oclkdelay_calib_start <= #TCQ 'b0;
else if (complex_oclkdelay_calib_start_int && (init_state_r == INIT_OCAL_CENTER_WRITE_WAIT) && prbs_rdlvl_done) // changed for new algo 3/26
complex_oclkdelay_calib_start <= #TCQ 'b1;
//packet fragmentation for complex oclkdealy calib write
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse) begin
complex_num_writes <= #TCQ 'd1;
end else if ((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (complex_wait_cnt == 'd14) && ~complex_row0_wr_done) begin
if (stg1_wr_rd_cnt > 'd85) begin
if (complex_num_writes < 'd6)
complex_num_writes <= #TCQ complex_num_writes + 1;
else
complex_num_writes <= #TCQ 'd1;
// Initila value for VCCAUX pattern is 3, 7, and 12
end else if (stg1_wr_rd_cnt > 'd73) begin
if (stg1_wr_rd_cnt == 'd85)
complex_num_writes <= #TCQ 'd3;
else if (complex_num_writes < 'd5)
complex_num_writes <= #TCQ complex_num_writes + 1;
end else if (stg1_wr_rd_cnt > 'd39) begin
if (stg1_wr_rd_cnt == 'd73)
complex_num_writes <= #TCQ 'd7;
else if (complex_num_writes < 'd10)
complex_num_writes <= #TCQ complex_num_writes + 1;
end else begin
if (stg1_wr_rd_cnt == 'd39)
complex_num_writes <= #TCQ 'd12;
else if (complex_num_writes < 'd14)
complex_num_writes <= #TCQ complex_num_writes + 1;
end
// Initialize to 1 at the start of write or after precharge and activate
end else if ((init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT) && complex_row0_wr_done)
complex_num_writes <= #TCQ 'd30;
else if (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)
complex_num_writes <= #TCQ 'd1;
always @(posedge clk)
if (rst || prbs_rdlvl_done_pulse)
complex_num_writes_dec <= #TCQ 'd1;
else if (((init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) && (complex_wait_cnt == 'd15) && ~complex_row0_rd_done) ||
((init_state_r == INIT_RDLVL_STG1_WRITE_READ) || (init_state_r == INIT_RDLVL_COMPLEX_ACT_WAIT)))
complex_num_writes_dec <= #TCQ complex_num_writes;
else if ((init_state_r == INIT_RDLVL_STG1_WRITE) && (complex_num_writes_dec > 'd0))
complex_num_writes_dec <= #TCQ complex_num_writes_dec - 1;
always @(posedge clk)
if (rst)
complex_sample_cnt_inc_ocal <= #TCQ 1'b0;
else if ((stg1_wr_rd_cnt == 9'd1) && complex_byte_rd_done && prbs_rdlvl_done)
complex_sample_cnt_inc_ocal <= #TCQ 1'b1;
else
complex_sample_cnt_inc_ocal <= #TCQ 1'b0;
always @(posedge clk)
if (rst)
complex_sample_cnt_inc <= #TCQ 1'b0;
else if ((stg1_wr_rd_cnt == 9'd1) && complex_row1_rd_done)
complex_sample_cnt_inc <= #TCQ 1'b1;
else
complex_sample_cnt_inc <= #TCQ 1'b0;
always @(posedge clk) begin
complex_sample_cnt_inc_r1 <= #TCQ complex_sample_cnt_inc;
complex_sample_cnt_inc_r2 <= #TCQ complex_sample_cnt_inc_r1;
end
//complex refresh req
always @ (posedge clk) begin
if(rst || (init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(prbs_rdlvl_done && (init_state_r == INIT_RDLVL_COMPLEX_ACT)) )
complex_ocal_ref_done <= #TCQ 1'b1;
else if (init_state_r == INIT_RDLVL_STG1_WRITE)
complex_ocal_ref_done <= #TCQ 1'b0;
end
//complex ocal odt extention
always @(posedge clk)
if (rst)
complex_ocal_odt_ext <= #TCQ 1'b0;
else if (((init_state_r == INIT_PRECHARGE_PREWAIT) && cnt_cmd_done_m7_r) || (init_state_r == INIT_OCLKDELAY_READ_WAIT))
complex_ocal_odt_ext <= #TCQ 1'b0;
else if ((init_state_r == INIT_OCAL_CENTER_WRITE) || (init_state_r == INIT_OCAL_CENTER_WRITE_WAIT))
complex_ocal_odt_ext <= #TCQ 1'b1;
// OCLKDELAY calibration requires multiple writes because
// write can be up to 2 cycles early since OCLKDELAY tap
// can go down to 0
always @(posedge clk)
if (rst || (init_state_r == INIT_OCLKDELAY_WRITE_WAIT) ||
(oclk_wr_cnt == 4'd0))
oclk_wr_cnt <= #TCQ NUM_STG1_WR_RD;
else if ((init_state_r == INIT_OCLKDELAY_WRITE) &&
new_burst_r && ~phy_data_full)
oclk_wr_cnt <= #TCQ oclk_wr_cnt - 1;
// Write calibration requires multiple writes because
// write can be up to 2 cycles early due to new write
// leveling algorithm to avoid late writes
always @(posedge clk)
if (rst || (init_state_r == INIT_WRCAL_WRITE_READ) ||
(wrcal_wr_cnt == 4'd0))
wrcal_wr_cnt <= #TCQ NUM_STG1_WR_RD;
else if ((init_state_r == INIT_WRCAL_WRITE) &&
new_burst_r && ~phy_data_full)
wrcal_wr_cnt <= #TCQ wrcal_wr_cnt - 1;
generate
if(nCK_PER_CLK == 4) begin:back_to_back_reads_4_1
// 4 back-to-back reads with gaps for
// read data_offset calibration (rdlvl stage 2)
always @(posedge clk)
if (rst || (init_state_r == INIT_RDLVL_STG2_READ_WAIT))
num_reads <= #TCQ 3'b000;
else if ((num_reads > 3'b000) && ~(phy_ctl_full || phy_cmd_full))
num_reads <= #TCQ num_reads - 1;
else if ((init_state_r == INIT_RDLVL_STG2_READ) || phy_ctl_full ||
phy_cmd_full && new_burst_r)
num_reads <= #TCQ 3'b011;
end else if(nCK_PER_CLK == 2) begin: back_to_back_reads_2_1
// 4 back-to-back reads with gaps for
// read data_offset calibration (rdlvl stage 2)
always @(posedge clk)
if (rst || (init_state_r == INIT_RDLVL_STG2_READ_WAIT))
num_reads <= #TCQ 3'b000;
else if ((num_reads > 3'b000) && ~(phy_ctl_full || phy_cmd_full))
num_reads <= #TCQ num_reads - 1;
else if ((init_state_r == INIT_RDLVL_STG2_READ) || phy_ctl_full ||
phy_cmd_full && new_burst_r)
num_reads <= #TCQ 3'b111;
end
endgenerate
// back-to-back reads during write calibration
always @(posedge clk)
if (rst ||(init_state_r == INIT_WRCAL_READ_WAIT))
wrcal_reads <= #TCQ 2'b00;
else if ((wrcal_reads > 2'b00) && ~(phy_ctl_full || phy_cmd_full))
wrcal_reads <= #TCQ wrcal_reads - 1;
else if ((init_state_r == INIT_WRCAL_MULT_READS) || phy_ctl_full ||
phy_cmd_full && new_burst_r)
wrcal_reads <= #TCQ 'd255;
// determine how often to issue row command during read leveling writes
// and reads
always @(posedge clk)
if (rdlvl_wr_rd) begin
// 2:1 mode - every other command issued is a data command
// 4:1 mode - every command issued is a data command
if (nCK_PER_CLK == 2) begin
if (!phy_ctl_full)
new_burst_r <= #TCQ ~new_burst_r;
end else
new_burst_r <= #TCQ 1'b1;
end else
new_burst_r <= #TCQ 1'b1;
// indicate when a write is occurring. PHY_WRDATA_EN must be asserted
// simultaneous with the corresponding command/address for CWL = 5,6
always @(posedge clk) begin
rdlvl_wr_r <= #TCQ rdlvl_wr;
calib_wrdata_en <= #TCQ phy_wrdata_en;
end
always @(posedge clk) begin
if (rst || wrcal_done)
extend_cal_pat <= #TCQ 1'b0;
else if (temp_lmr_done && (PRE_REV3ES == "ON"))
extend_cal_pat <= #TCQ 1'b1;
end
generate
if ((nCK_PER_CLK == 4) || (BURST_MODE == "4")) begin: wrdqen_div4
// Write data enable asserted for one DIV4 clock cycle
// Only BL8 supported with DIV4. DDR2 BL4 will use DIV2.
always @(*) begin
if (~phy_data_full && ((init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE)))
phy_wrdata_en = 1'b1;
else
phy_wrdata_en = 1'b0;
end
end else begin: wrdqen_div2 // block: wrdqen_div4
always @(*)
if((rdlvl_wr & ~phy_ctl_full & new_burst_r & ~phy_data_full)
| phy_wrdata_en_r1)
phy_wrdata_en = 1'b1;
else
phy_wrdata_en = 1'b0;
always @(posedge clk)
phy_wrdata_en_r1 <= #TCQ rdlvl_wr & ~phy_ctl_full & new_burst_r
& ~phy_data_full;
always @(posedge clk) begin
if (!phy_wrdata_en & first_rdlvl_pat_r)
wrdata_pat_cnt <= #TCQ 2'b00;
else if (wrdata_pat_cnt == 2'b11)
wrdata_pat_cnt <= #TCQ 2'b10;
else
wrdata_pat_cnt <= #TCQ wrdata_pat_cnt + 1;
end
always @(posedge clk) begin
if (!phy_wrdata_en & first_wrcal_pat_r)
wrcal_pat_cnt <= #TCQ 2'b00;
else if (extend_cal_pat && (wrcal_pat_cnt == 2'b01))
wrcal_pat_cnt <= #TCQ 2'b00;
else if (wrcal_pat_cnt == 2'b11)
wrcal_pat_cnt <= #TCQ 2'b10;
else
wrcal_pat_cnt <= #TCQ wrcal_pat_cnt + 1;
end
end
endgenerate
// indicate when a write is occurring. PHY_RDDATA_EN must be asserted
// simultaneous with the corresponding command/address. PHY_RDDATA_EN
// is used during read-leveling to determine read latency
assign phy_rddata_en = ~phy_if_empty;
// Read data valid generation for MC and User Interface after calibration is
// complete
assign phy_rddata_valid = init_complete_r1_timing ? phy_rddata_en : 1'b0;
//***************************************************************************
// Generate training data written at start of each read-leveling stage
// For every stage of read leveling, 8 words are written into memory
// The format is as follows (shown as {rise,fall}):
// Stage 1: 0xF, 0x0, 0xF, 0x0, 0xF, 0x0, 0xF, 0x0
// Stage 2: 0xF, 0x0, 0xA, 0x5, 0x5, 0xA, 0x9, 0x6
//***************************************************************************
always @(posedge clk)
if ((init_state_r == INIT_IDLE) ||
(init_state_r == INIT_RDLVL_STG1_WRITE))
cnt_init_data_r <= #TCQ 2'b00;
else if (phy_wrdata_en)
cnt_init_data_r <= #TCQ cnt_init_data_r + 1;
else if (init_state_r == INIT_WRCAL_WRITE)
cnt_init_data_r <= #TCQ 2'b10;
// write different sequence for very
// first write to memory only. Used to help us differentiate
// if the writes are "early" or "on-time" during read leveling
always @(posedge clk)
if (rst || rdlvl_stg1_rank_done)
first_rdlvl_pat_r <= #TCQ 1'b1;
else if (phy_wrdata_en && (init_state_r == INIT_RDLVL_STG1_WRITE))
first_rdlvl_pat_r <= #TCQ 1'b0;
always @(posedge clk)
if (rst || wrcal_resume ||
(init_state_r == INIT_WRCAL_ACT_WAIT))
first_wrcal_pat_r <= #TCQ 1'b1;
else if (phy_wrdata_en && (init_state_r == INIT_WRCAL_WRITE))
first_wrcal_pat_r <= #TCQ 1'b0;
generate
if ((CLK_PERIOD/nCK_PER_CLK > 2500) && (nCK_PER_CLK == 2)) begin: wrdq_div2_2to1_rdlvl_first
always @(posedge clk)
if (~oclkdelay_calib_done)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}}};
else if (!rdlvl_stg1_done) begin
// The 16 words for stage 1 write data in 2:1 mode is written
// over 4 consecutive controller clock cycles. Note that write
// data follows phy_wrdata_en by one clock cycle
case (wrdata_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},
{DQ_WIDTH/4{4'h9}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
endcase
end else if (!prbs_rdlvl_done && ~phy_data_full) begin
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},
{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},
{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
end else if (!wrcal_done) begin
case (wrcal_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h5}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},
{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h4}}};
end
endcase
end
end else if ((CLK_PERIOD/nCK_PER_CLK > 2500) && (nCK_PER_CLK == 4)) begin: wrdq_div2_4to1_rdlvl_first
always @(posedge clk)
if (~oclkdelay_calib_done)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}}};
else if (!rdlvl_stg1_done && ~phy_data_full)
// write different sequence for very
// first write to memory only. Used to help us differentiate
// if the writes are "early" or "on-time" during read leveling
if (first_rdlvl_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},{DQ_WIDTH/4{4'h9}}};
else
// For all others, change the first two words written in order
// to differentiate the "early write" and "on-time write"
// readback patterns during read leveling
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
else if (~(prbs_rdlvl_done || prbs_last_byte_done_r) && ~phy_data_full)
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[8*8-1:7*8]}},{DQ_WIDTH/8{prbs_o[7*8-1:6*8]}},
{DQ_WIDTH/8{prbs_o[6*8-1:5*8]}},{DQ_WIDTH/8{prbs_o[5*8-1:4*8]}},
{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
else if (!wrcal_done)
if (first_wrcal_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'h5}},{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},{DQ_WIDTH/4{4'hF}}};
else
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
end else if (nCK_PER_CLK == 4) begin: wrdq_div1_4to1_wrcal_first
always @(posedge clk)
if ((~oclkdelay_calib_done) && (DRAM_TYPE == "DDR3"))
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},{DQ_WIDTH/4{4'h0}}};
else if ((!wrcal_done)&& (DRAM_TYPE == "DDR3")) begin
if (extend_cal_pat)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'h5}},{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},{DQ_WIDTH/4{4'hF}}};
else if (first_wrcal_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'h5}},{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},{DQ_WIDTH/4{4'hF}}};
else
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
end else if (!rdlvl_stg1_done && ~phy_data_full) begin
// write different sequence for very
// first write to memory only. Used to help us differentiate
// if the writes are "early" or "on-time" during read leveling
if (first_rdlvl_pat_r)
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},{DQ_WIDTH/4{4'h9}}};
else
// For all others, change the first two words written in order
// to differentiate the "early write" and "on-time write"
// readback patterns during read leveling
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},{DQ_WIDTH/4{4'hC}},
{DQ_WIDTH/4{4'hE}},{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},{DQ_WIDTH/4{4'hB}}};
end else if (!prbs_rdlvl_done && ~phy_data_full)
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[8*8-1:7*8]}},{DQ_WIDTH/8{prbs_o[7*8-1:6*8]}},
{DQ_WIDTH/8{prbs_o[6*8-1:5*8]}},{DQ_WIDTH/8{prbs_o[5*8-1:4*8]}},
{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
else if (!complex_oclkdelay_calib_done && ~phy_data_full)
phy_wrdata <= #TCQ prbs_o;
end else begin: wrdq_div1_2to1_wrcal_first
always @(posedge clk)
if ((~oclkdelay_calib_done)&& (DRAM_TYPE == "DDR3"))
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}},
{DQ_WIDTH/4{4'h0}}};
else if ((!wrcal_done) && (DRAM_TYPE == "DDR3"))begin
case (wrcal_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h5}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h0}},
{DQ_WIDTH/4{4'hF}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h6}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hA}},
{DQ_WIDTH/4{4'h5}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h8}},
{DQ_WIDTH/4{4'hD}},
{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h4}}};
end
endcase
end else if (!rdlvl_stg1_done) begin
// The 16 words for stage 1 write data in 2:1 mode is written
// over 4 consecutive controller clock cycles. Note that write
// data follows phy_wrdata_en by one clock cycle
case (wrdata_pat_cnt)
2'b00: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h3}},
{DQ_WIDTH/4{4'h9}}};
end
2'b01: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
2'b10: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'hE}},
{DQ_WIDTH/4{4'h7}},
{DQ_WIDTH/4{4'h1}},
{DQ_WIDTH/4{4'hB}}};
end
2'b11: begin
phy_wrdata <= #TCQ {{DQ_WIDTH/4{4'h4}},
{DQ_WIDTH/4{4'h2}},
{DQ_WIDTH/4{4'h9}},
{DQ_WIDTH/4{4'hC}}};
end
endcase
end else if (!prbs_rdlvl_done && ~phy_data_full) begin
phy_wrdata <= #TCQ prbs_o;
// prbs_o is 8-bits wide hence {DQ_WIDTH/8{prbs_o}} results in
// prbs_o being concatenated 8 times resulting in DQ_WIDTH
/*phy_wrdata <= #TCQ {{DQ_WIDTH/8{prbs_o[4*8-1:3*8]}},
{DQ_WIDTH/8{prbs_o[3*8-1:2*8]}},
{DQ_WIDTH/8{prbs_o[2*8-1:8]}},
{DQ_WIDTH/8{prbs_o[8-1:0]}}};*/
end else if (!complex_oclkdelay_calib_done && ~phy_data_full) begin
phy_wrdata <= #TCQ prbs_o;
end
end
endgenerate
//***************************************************************************
// Memory control/address
//***************************************************************************
// Phases [2] and [3] are always deasserted for 4:1 mode
generate
if (nCK_PER_CLK == 4) begin: gen_div4_ca_tieoff
always @(posedge clk) begin
phy_ras_n[3:2] <= #TCQ 3'b11;
phy_cas_n[3:2] <= #TCQ 3'b11;
phy_we_n[3:2] <= #TCQ 3'b11;
end
end
endgenerate
// Assert RAS when: (1) Loading MRS, (2) Activating Row, (3) Precharging
// (4) auto refresh
// verilint STARC-2.7.3.3b off
generate
if (!(CWL_M % 2)) begin: even_cwl
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_REFRESH) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT))begin
phy_ras_n[0] <= #TCQ 1'b0;
phy_ras_n[1] <= #TCQ 1'b1;
end else begin
phy_ras_n[0] <= #TCQ 1'b1;
phy_ras_n[1] <= #TCQ 1'b1;
end
end
// Assert CAS when: (1) Loading MRS, (2) Issuing Read/Write command
// (3) auto refresh
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_REFRESH) ||
(rdlvl_wr_rd && new_burst_r))begin
phy_cas_n[0] <= #TCQ 1'b0;
phy_cas_n[1] <= #TCQ 1'b1;
end else begin
phy_cas_n[0] <= #TCQ 1'b1;
phy_cas_n[1] <= #TCQ 1'b1;
end
end
// Assert WE when: (1) Loading MRS, (2) Issuing Write command (only
// occur during read leveling), (3) Issuing ZQ Long Calib command,
// (4) Precharge
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE)||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(rdlvl_wr && new_burst_r))begin
phy_we_n[0] <= #TCQ 1'b0;
phy_we_n[1] <= #TCQ 1'b1;
end else begin
phy_we_n[0] <= #TCQ 1'b1;
phy_we_n[1] <= #TCQ 1'b1;
end
end
end else begin: odd_cwl
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(init_state_r == INIT_REFRESH))begin
phy_ras_n[0] <= #TCQ 1'b1;
phy_ras_n[1] <= #TCQ 1'b0;
end else begin
phy_ras_n[0] <= #TCQ 1'b1;
phy_ras_n[1] <= #TCQ 1'b1;
end
end
// Assert CAS when: (1) Loading MRS, (2) Issuing Read/Write command
// (3) auto refresh
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_REFRESH) ||
(rdlvl_wr_rd && new_burst_r))begin
phy_cas_n[0] <= #TCQ 1'b1;
phy_cas_n[1] <= #TCQ 1'b0;
end else begin
phy_cas_n[0] <= #TCQ 1'b1;
phy_cas_n[1] <= #TCQ 1'b1;
end
end
// Assert WE when: (1) Loading MRS, (2) Issuing Write command (only
// occur during read leveling), (3) Issuing ZQ Long Calib command,
// (4) Precharge
always @(posedge clk) begin
if ((init_state_r == INIT_LOAD_MR) ||
(init_state_r == INIT_MPR_RDEN) ||
(init_state_r == INIT_MPR_DISABLE) ||
(init_state_r == INIT_REG_WRITE) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_WRLVL_START) ||
(init_state_r == INIT_WRLVL_LOAD_MR) ||
(init_state_r == INIT_WRLVL_LOAD_MR2) ||
(init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_DDR2_PRECHARGE)||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(rdlvl_wr && new_burst_r))begin
phy_we_n[0] <= #TCQ 1'b1;
phy_we_n[1] <= #TCQ 1'b0;
end else begin
phy_we_n[0] <= #TCQ 1'b1;
phy_we_n[1] <= #TCQ 1'b1;
end
end
end
endgenerate
// verilint STARC-2.7.3.3b on
// Assign calib_cmd for the command field in PHY_Ctl_Word
always @(posedge clk) begin
if (wr_level_dqs_asrt) begin
// Request to toggle DQS during write leveling
calib_cmd <= #TCQ 3'b001;
if (CWL_M % 2) begin // odd write latency
calib_data_offset_0 <= #TCQ CWL_M + 3;
calib_data_offset_1 <= #TCQ CWL_M + 3;
calib_data_offset_2 <= #TCQ CWL_M + 3;
calib_cas_slot <= #TCQ 2'b01;
end else begin // even write latency
calib_data_offset_0 <= #TCQ CWL_M + 2;
calib_data_offset_1 <= #TCQ CWL_M + 2;
calib_data_offset_2 <= #TCQ CWL_M + 2;
calib_cas_slot <= #TCQ 2'b00;
end
end else if (rdlvl_wr && new_burst_r) begin
// Write Command
calib_cmd <= #TCQ 3'b001;
if (CWL_M % 2) begin // odd write latency
calib_data_offset_0 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 3 : CWL_M - 1;
calib_data_offset_1 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 3 : CWL_M - 1;
calib_data_offset_2 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 3 : CWL_M - 1;
calib_cas_slot <= #TCQ 2'b01;
end else begin // even write latency
calib_data_offset_0 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 2 : CWL_M - 2 ;
calib_data_offset_1 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 2 : CWL_M - 2 ;
calib_data_offset_2 <= #TCQ (nCK_PER_CLK == 4) ? CWL_M + 2 : CWL_M - 2 ;
calib_cas_slot <= #TCQ 2'b00;
end
end else if (rdlvl_rd && new_burst_r) begin
// Read Command
calib_cmd <= #TCQ 3'b011;
if (CWL_M % 2)
calib_cas_slot <= #TCQ 2'b01;
else
calib_cas_slot <= #TCQ 2'b00;
if (~pi_calib_done_r1) begin
calib_data_offset_0 <= #TCQ 6'd0;
calib_data_offset_1 <= #TCQ 6'd0;
calib_data_offset_2 <= #TCQ 6'd0;
end else if (~pi_dqs_found_done_r1) begin
calib_data_offset_0 <= #TCQ rd_data_offset_0;
calib_data_offset_1 <= #TCQ rd_data_offset_1;
calib_data_offset_2 <= #TCQ rd_data_offset_2;
end else begin
calib_data_offset_0 <= #TCQ rd_data_offset_ranks_0[6*chip_cnt_r+:6];
calib_data_offset_1 <= #TCQ rd_data_offset_ranks_1[6*chip_cnt_r+:6];
calib_data_offset_2 <= #TCQ rd_data_offset_ranks_2[6*chip_cnt_r+:6];
end
end else begin
// Non-Data Commands like NOP, MRS, ZQ Long Cal, Precharge,
// Active, Refresh
calib_cmd <= #TCQ 3'b100;
calib_data_offset_0 <= #TCQ 6'd0;
calib_data_offset_1 <= #TCQ 6'd0;
calib_data_offset_2 <= #TCQ 6'd0;
if (CWL_M % 2)
calib_cas_slot <= #TCQ 2'b01;
else
calib_cas_slot <= #TCQ 2'b00;
end
end
// Write Enable to PHY_Control FIFO always asserted
// No danger of this FIFO being Full with 4:1 sync clock ratio
// This is also the write enable to the command OUT_FIFO
always @(posedge clk) begin
if (rst) begin
calib_ctl_wren <= #TCQ 1'b0;
calib_cmd_wren <= #TCQ 1'b0;
calib_seq <= #TCQ 2'b00;
end else if (cnt_pwron_cke_done_r && phy_ctl_ready
&& ~(phy_ctl_full || phy_cmd_full )) begin
calib_ctl_wren <= #TCQ 1'b1;
calib_cmd_wren <= #TCQ 1'b1;
calib_seq <= #TCQ calib_seq + 1;
end else begin
calib_ctl_wren <= #TCQ 1'b0;
calib_cmd_wren <= #TCQ 1'b0;
calib_seq <= #TCQ calib_seq;
end
end
generate
genvar rnk_i;
for (rnk_i = 0; rnk_i < 4; rnk_i = rnk_i + 1) begin: gen_rnk
always @(posedge clk) begin
if (rst) begin
mr2_r[rnk_i] <= #TCQ 2'b00;
mr1_r[rnk_i] <= #TCQ 3'b000;
end else begin
mr2_r[rnk_i] <= #TCQ tmp_mr2_r[rnk_i];
mr1_r[rnk_i] <= #TCQ tmp_mr1_r[rnk_i];
end
end
end
endgenerate
// ODT assignment based on slot config and slot present
// For single slot systems slot_1_present input will be ignored
// Assuming component interfaces to be single slot systems
generate
if (nSLOTS == 1) begin: gen_single_slot_odt
always @(posedge clk) begin
if (rst) begin
tmp_mr2_r[1] <= #TCQ 2'b00;
tmp_mr2_r[2] <= #TCQ 2'b00;
tmp_mr2_r[3] <= #TCQ 2'b00;
tmp_mr1_r[1] <= #TCQ 3'b000;
tmp_mr1_r[2] <= #TCQ 3'b000;
tmp_mr1_r[3] <= #TCQ 3'b000;
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b1}};
phy_tmp_odt_r <= #TCQ 4'b0000;
phy_tmp_odt_r1 <= #TCQ phy_tmp_odt_r;
end else begin
case ({slot_0_present[0],slot_0_present[1],
slot_0_present[2],slot_0_present[3]})
// Single slot configuration with quad rank
// Assuming same behavior as single slot dual rank for now
// DDR2 does not have quad rank parts
4'b1111: begin
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 RTT_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 RTT_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
phy_tmp_odt_r <= #TCQ 4'b0001;
// Chip Select assignments
phy_tmp_cs1_r[((chip_cnt_r*nCS_PER_RANK)
) +: nCS_PER_RANK] <= #TCQ 'b0;
end
// Single slot configuration with single rank
4'b1000: begin
phy_tmp_odt_r <= #TCQ 4'b0001;
if ((REG_CTRL == "ON") && (nCS_PER_RANK > 1)) begin
phy_tmp_cs1_r[chip_cnt_r] <= #TCQ 1'b0;
end else begin
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b0}};
end
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
((cnt_init_mr_r == 2'd0) || (USE_ODT_PORT == 1)))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 RTT_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 RTT_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
// Single slot configuration with dual rank
4'b1100: begin
phy_tmp_odt_r <= #TCQ 4'b0001;
// Chip Select assignments
phy_tmp_cs1_r[((chip_cnt_r*nCS_PER_RANK)
) +: nCS_PER_RANK] <= #TCQ 'b0;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
default: begin
phy_tmp_odt_r <= #TCQ 4'b0001;
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
endcase
end
end
end else if (nSLOTS == 2) begin: gen_dual_slot_odt
always @ (posedge clk) begin
if (rst) begin
tmp_mr2_r[1] <= #TCQ 2'b00;
tmp_mr2_r[2] <= #TCQ 2'b00;
tmp_mr2_r[3] <= #TCQ 2'b00;
tmp_mr1_r[1] <= #TCQ 3'b000;
tmp_mr1_r[2] <= #TCQ 3'b000;
tmp_mr1_r[3] <= #TCQ 3'b000;
phy_tmp_odt_r <= #TCQ 4'b0000;
phy_tmp_cs1_r <= #TCQ {CS_WIDTH*nCS_PER_RANK{1'b1}};
phy_tmp_odt_r1 <= #TCQ phy_tmp_odt_r;
end else begin
case ({slot_0_present[0],slot_0_present[1],
slot_1_present[0],slot_1_present[1]})
// Two slot configuration, one slot present, single rank
4'b10_00: begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r <= #TCQ 4'b0001;
end
phy_tmp_cs1_r <= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
4'b00_10: begin
//Rank1 ODT enabled
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r <= #TCQ 4'b0001;
end
phy_tmp_cs1_r <= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank1 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank1 Rtt_NOM defaults to 120 ohms
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
// Two slot configuration, one slot present, dual rank
4'b00_11: begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r
<= #TCQ 4'b0001;
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
4'b11_00: begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// odt turned on only during write
phy_tmp_odt_r <= #TCQ 4'b0001;
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank1 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
end
// Two slot configuration, one rank per slot
4'b10_10: begin
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r == 2'b00)begin
phy_tmp_odt_r
<= #TCQ 4'b0010; //bit0 for rank0
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0001; //bit0 for rank0
end
end else begin
if((init_state_r == INIT_WRLVL_WAIT) ||
(init_next_state == INIT_RDLVL_STG1_WRITE) ||
(init_next_state == INIT_WRCAL_WRITE) ||
(init_next_state == INIT_OCAL_CENTER_WRITE) ||
(init_next_state == INIT_OCLKDELAY_WRITE))
phy_tmp_odt_r <= #TCQ 4'b0011; // bit0 for rank0/1 (write)
else if ((init_next_state == INIT_PI_PHASELOCK_READS) ||
(init_next_state == INIT_MPR_READ) ||
(init_next_state == INIT_RDLVL_STG1_READ) ||
(init_next_state == INIT_RDLVL_COMPLEX_READ) ||
(init_next_state == INIT_RDLVL_STG2_READ) ||
(init_next_state == INIT_OCLKDELAY_READ) ||
(init_next_state == INIT_WRCAL_READ) ||
(init_next_state == INIT_WRCAL_MULT_READS))
phy_tmp_odt_r <= #TCQ 4'b0010; // bit0 for rank1 (rank 0 rd)
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_WR == "60") ? 3'b001 :
(RTT_WR == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
end
end
// Two Slots - One slot with dual rank and other with single rank
4'b10_11: begin
//Rank3 Rtt_NOM
tmp_mr1_r[2] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
tmp_mr2_r[2] <= #TCQ 2'b00;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[1] <= #TCQ 3'b000;
end
//Slot1 Rank1 or Rank3 is being written
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r == 2'b00)begin
phy_tmp_odt_r
<= #TCQ 4'b0010;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0001;
end
end else begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
if (chip_cnt_r[0] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0011;
//Slot0 Rank0 is being written
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0101; // ODT for ranks 0 and 2 aserted
end
end else if ((init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS))begin
if (chip_cnt_r == 2'b00) begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0001;
end
end
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
end
// Two Slots - One slot with dual rank and other with single rank
4'b11_10: begin
//Rank2 Rtt_NOM
tmp_mr1_r[2] <= #TCQ (RTT_NOM2 == "60") ? 3'b001 :
(RTT_NOM2 == "120") ? 3'b010 :
(RTT_NOM2 == "20") ? 3'b100 :
(RTT_NOM2 == "30") ? 3'b101 :
(RTT_NOM2 == "40") ? 3'b011:
3'b000;
tmp_mr2_r[2] <= #TCQ 2'b00;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011:
3'b000;
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r[1] == 1'b1)begin
phy_tmp_odt_r <=
#TCQ 4'b0001;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0100; // rank 2 ODT asserted
end
end else begin
if (// wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
if (chip_cnt_r[1] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0110;
end else begin
phy_tmp_odt_r <=
#TCQ 4'b0101;
end
end else if ((init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS)) begin
if (chip_cnt_r[1] == 1'b1) begin
phy_tmp_odt_r[(1*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ 4'b0010;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
end
end
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
end
// Two Slots - two ranks per slot
4'b11_11: begin
//Rank2 Rtt_NOM
tmp_mr1_r[2] <= #TCQ (RTT_NOM2 == "60") ? 3'b001 :
(RTT_NOM2 == "120") ? 3'b010 :
(RTT_NOM2 == "20") ? 3'b100 :
(RTT_NOM2 == "30") ? 3'b101 :
(RTT_NOM2 == "40") ? 3'b011 :
3'b000;
//Rank3 Rtt_NOM
tmp_mr1_r[3] <= #TCQ (RTT_NOM3 == "60") ? 3'b001 :
(RTT_NOM3 == "120") ? 3'b010 :
(RTT_NOM3 == "20") ? 3'b100 :
(RTT_NOM3 == "30") ? 3'b101 :
(RTT_NOM3 == "40") ? 3'b011 :
3'b000;
tmp_mr2_r[2] <= #TCQ 2'b00;
tmp_mr2_r[3] <= #TCQ 2'b00;
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done &&
(wrlvl_rank_cntr==3'd0))) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
end else begin
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM after write leveling completes
tmp_mr1_r[1] <= #TCQ 3'b000;
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM after write leveling completes
tmp_mr1_r[0] <= #TCQ 3'b000;
end
if(DRAM_TYPE == "DDR2")begin
if(chip_cnt_r[1] == 1'b1)begin
phy_tmp_odt_r
<= #TCQ 4'b0001;
end else begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
end
end else begin
if (//wrlvl_odt ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
//Slot1 Rank1 or Rank3 is being written
if (chip_cnt_r[0] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0110;
//Slot0 Rank0 or Rank2 is being written
end else begin
phy_tmp_odt_r
<= #TCQ 4'b1001;
end
end else if ((init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS))begin
//Slot1 Rank1 or Rank3 is being read
if (chip_cnt_r[0] == 1'b1) begin
phy_tmp_odt_r
<= #TCQ 4'b0100;
//Slot0 Rank0 or Rank2 is being read
end else begin
phy_tmp_odt_r
<= #TCQ 4'b1000;
end
end
end
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
end
default: begin
phy_tmp_odt_r <= #TCQ 4'b1111;
// Chip Select assignments
phy_tmp_cs1_r[(chip_cnt_r*nCS_PER_RANK) +: nCS_PER_RANK]
<= #TCQ {nCS_PER_RANK{1'b0}};
if ((RTT_WR == "OFF") ||
((WRLVL=="ON") && ~wrlvl_done)) begin
//Rank0 Dynamic ODT disabled
tmp_mr2_r[0] <= #TCQ 2'b00;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
3'b000;
//Rank1 Dynamic ODT disabled
tmp_mr2_r[1] <= #TCQ 2'b00;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "40") ? 3'b011 :
(RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "60") ? 3'b010 :
3'b000;
end else begin
//Rank0 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[0] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank0 Rtt_NOM
tmp_mr1_r[0] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
//Rank1 Dynamic ODT defaults to 120 ohms
tmp_mr2_r[1] <= #TCQ (RTT_WR == "60") ? 2'b01 :
2'b10;
//Rank1 Rtt_NOM
tmp_mr1_r[1] <= #TCQ (RTT_NOM_int == "60") ? 3'b001 :
(RTT_NOM_int == "120") ? 3'b010 :
(RTT_NOM_int == "20") ? 3'b100 :
(RTT_NOM_int == "30") ? 3'b101 :
(RTT_NOM_int == "40") ? 3'b011 :
3'b000;
end
end
endcase
end
end
end
endgenerate
// PHY only supports two ranks.
// calib_aux_out[0] is CKE for rank 0 and calib_aux_out[1] is ODT for rank 0
// calib_aux_out[2] is CKE for rank 1 and calib_aux_out[3] is ODT for rank 1
generate
if(CKE_ODT_AUX == "FALSE") begin
if ((nSLOTS == 1) && (RANKS < 2)) begin
always @(posedge clk)
if (rst) begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}} ;
calib_odt <= 2'b00 ;
end else begin
if (cnt_pwron_cke_done_r /*&& ~cnt_pwron_cke_done_r1*/)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b1}};
end else begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}};
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF"))/* ||
wrlvl_rank_done || wrlvl_rank_done_r1 ||
(wrlvl_done && !wrlvl_done_r)*/) && (DRAM_TYPE == "DDR3")) begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt ) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
complex_odt_ext ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
complex_ocal_odt_ext ||
(init_state_r == INIT_OCLKDELAY_WRITE)||
(init_state_r == INIT_OCLKDELAY_WRITE_WAIT))) begin
// Quad rank in a single slot
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 1) && (RANKS <= 2)) begin
always @(posedge clk)
if (rst) begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}} ;
calib_odt <= 2'b00 ;
end else begin
if (cnt_pwron_cke_done_r /*&& ~cnt_pwron_cke_done_r1*/)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b1}};
end else begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}};
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF"))/* ||
wrlvl_rank_done_r2 ||
(wrlvl_done && !wrlvl_done_r)*/) && (DRAM_TYPE == "DDR3")) begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt)||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_RDLVL_STG1_WRITE_READ) ||
complex_odt_ext ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_WRITE_READ) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
complex_ocal_odt_ext ||
(init_state_r == INIT_OCLKDELAY_WRITE)||
(init_state_r == INIT_OCLKDELAY_WRITE_WAIT))) begin
// Dual rank in a single slot
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 2) && (RANKS == 2)) begin
always @(posedge clk)
if (rst)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}} ;
calib_odt <= 2'b00 ;
end else begin
if (cnt_pwron_cke_done_r /*&& ~cnt_pwron_cke_done_r1*/)begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b1}};
end else begin
calib_cke <= #TCQ {nCK_PER_CLK{1'b0}};
end
if (((DRAM_TYPE == "DDR2") && (RTT_NOM == "DISABLED")) ||
((DRAM_TYPE == "DDR3") &&
(RTT_NOM == "DISABLED") && (RTT_WR == "OFF"))) begin
calib_odt[0] <= #TCQ 1'b0;
calib_odt[1] <= #TCQ 1'b0;
end else if (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE)) begin
// Quad rank in a single slot
if (nCK_PER_CLK == 2) begin
calib_odt[0]
<= #TCQ (!calib_odt[0]) ? phy_tmp_odt_r[0] : 1'b0;
calib_odt[1]
<= #TCQ (!calib_odt[1]) ? phy_tmp_odt_r[1] : 1'b0;
end else begin
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end
// Turn on for idle rank during read if dynamic ODT is enabled in DDR3
end else if(((DRAM_TYPE == "DDR3") && (RTT_WR != "OFF")) &&
((init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_MPR_READ) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ) ||
(init_state_r == INIT_RDLVL_STG2_READ) ||
(init_state_r == INIT_OCLKDELAY_READ) ||
(init_state_r == INIT_WRCAL_READ) ||
(init_state_r == INIT_WRCAL_MULT_READS))) begin
if (nCK_PER_CLK == 2) begin
calib_odt[0]
<= #TCQ (!calib_odt[0]) ? phy_tmp_odt_r[0] : 1'b0;
calib_odt[1]
<= #TCQ (!calib_odt[1]) ? phy_tmp_odt_r[1] : 1'b0;
end else begin
calib_odt[0] <= #TCQ phy_tmp_odt_r[0];
calib_odt[1] <= #TCQ phy_tmp_odt_r[1];
end
// disable well before next command and before disabling write leveling
end else if(cnt_cmd_done_m7_r ||
(init_state_r == INIT_WRLVL_WAIT && ~wrlvl_odt))
calib_odt <= #TCQ 2'b00;
end
end
end else begin//USE AUX OUTPUT for routing CKE and ODT.
if ((nSLOTS == 1) && (RANKS < 2)) begin
always @(posedge clk)
if (rst) begin
calib_aux_out <= #TCQ 4'b0000;
end else begin
if (cnt_pwron_cke_done_r && ~cnt_pwron_cke_done_r1)begin
calib_aux_out[0] <= #TCQ 1'b1;
calib_aux_out[2] <= #TCQ 1'b1;
end else begin
calib_aux_out[0] <= #TCQ 1'b0;
calib_aux_out[2] <= #TCQ 1'b0;
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF")) ||
wrlvl_rank_done || wrlvl_rank_done_r1 ||
(wrlvl_done && !wrlvl_done_r)) && (DRAM_TYPE == "DDR3")) begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE))) begin
// Quad rank in a single slot
calib_aux_out[1] <= #TCQ phy_tmp_odt_r[0];
calib_aux_out[3] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 1) && (RANKS <= 2)) begin
always @(posedge clk)
if (rst) begin
calib_aux_out <= #TCQ 4'b0000;
end else begin
if (cnt_pwron_cke_done_r && ~cnt_pwron_cke_done_r1)begin
calib_aux_out[0] <= #TCQ 1'b1;
calib_aux_out[2] <= #TCQ 1'b1;
end else begin
calib_aux_out[0] <= #TCQ 1'b0;
calib_aux_out[2] <= #TCQ 1'b0;
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF")) ||
wrlvl_rank_done_r2 ||
(wrlvl_done && !wrlvl_done_r)) && (DRAM_TYPE == "DDR3")) begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE))) begin
// Dual rank in a single slot
calib_aux_out[1] <= #TCQ phy_tmp_odt_r[0];
calib_aux_out[3] <= #TCQ phy_tmp_odt_r[1];
end else begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end
end
end else if ((nSLOTS == 2) && (RANKS == 2)) begin
always @(posedge clk)
if (rst)
calib_aux_out <= #TCQ 4'b0000;
else begin
if (cnt_pwron_cke_done_r && ~cnt_pwron_cke_done_r1)begin
calib_aux_out[0] <= #TCQ 1'b1;
calib_aux_out[2] <= #TCQ 1'b1;
end else begin
calib_aux_out[0] <= #TCQ 1'b0;
calib_aux_out[2] <= #TCQ 1'b0;
end
if ((((RTT_NOM == "DISABLED") && (RTT_WR == "OFF")) ||
wrlvl_rank_done_r2 ||
(wrlvl_done && !wrlvl_done_r)) && (DRAM_TYPE == "DDR3")) begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end else if (((DRAM_TYPE == "DDR3")
||((RTT_NOM != "DISABLED") && (DRAM_TYPE == "DDR2")))
&& (((init_state_r == INIT_WRLVL_WAIT) && wrlvl_odt) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_OCAL_COMPLEX_WRITE_WAIT) ||
(init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_WRITE))) begin
// Quad rank in a single slot
if (nCK_PER_CLK == 2) begin
calib_aux_out[1]
<= #TCQ (!calib_aux_out[1]) ? phy_tmp_odt_r[0] : 1'b0;
calib_aux_out[3]
<= #TCQ (!calib_aux_out[3]) ? phy_tmp_odt_r[1] : 1'b0;
end else begin
calib_aux_out[1] <= #TCQ phy_tmp_odt_r[0];
calib_aux_out[3] <= #TCQ phy_tmp_odt_r[1];
end
end else begin
calib_aux_out[1] <= #TCQ 1'b0;
calib_aux_out[3] <= #TCQ 1'b0;
end
end
end
end
endgenerate
//*****************************************************************
// memory address during init
//*****************************************************************
always @(posedge clk)
phy_data_full_r <= #TCQ phy_data_full;
// verilint STARC-2.7.3.3b off
always @(*)begin
// Bus 0 for address/bank never used
address_w = 'b0;
bank_w = 'b0;
if ((init_state_r == INIT_PRECHARGE) ||
(init_state_r == INIT_RDLVL_COMPLEX_PRECHARGE) ||
(init_state_r == INIT_ZQCL) ||
(init_state_r == INIT_DDR2_PRECHARGE)) begin
// Set A10=1 for ZQ long calibration or Precharge All
address_w = 'b0;
address_w[10] = 1'b1;
bank_w = 'b0;
end else if (init_state_r == INIT_WRLVL_START) begin
// Enable wrlvl in MR1
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[2] = mr1_r[chip_cnt_r][0];
address_w[6] = mr1_r[chip_cnt_r][1];
address_w[9] = mr1_r[chip_cnt_r][2];
address_w[7] = 1'b1;
end else if (init_state_r == INIT_WRLVL_LOAD_MR) begin
// Finished with write leveling, disable wrlvl in MR1
// For single rank disable Rtt_Nom
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[2] = mr1_r[chip_cnt_r][0];
address_w[6] = mr1_r[chip_cnt_r][1];
address_w[9] = mr1_r[chip_cnt_r][2];
end else if (init_state_r == INIT_WRLVL_LOAD_MR2) begin
// Set RTT_WR in MR2 after write leveling disabled
bank_w[1:0] = 2'b10;
address_w = load_mr2[ROW_WIDTH-1:0];
address_w[10:9] = mr2_r[chip_cnt_r];
end else if (init_state_r == INIT_MPR_READ) begin
address_w = 'b0;
bank_w = 'b0;
end else if (init_state_r == INIT_MPR_RDEN) begin
// Enable MPR read with LMR3 and A2=1
bank_w[BANK_WIDTH-1:0] = 'd3;
address_w = {ROW_WIDTH{1'b0}};
address_w[2] = 1'b1;
end else if (init_state_r == INIT_MPR_DISABLE) begin
// Disable MPR read with LMR3 and A2=0
bank_w[BANK_WIDTH-1:0] = 'd3;
address_w = {ROW_WIDTH{1'b0}};
end else if ((init_state_r == INIT_REG_WRITE)&
(DRAM_TYPE == "DDR3"))begin
// bank_w is assigned a 3 bit value. In some
// DDR2 cases there will be only two bank bits.
//Qualifying the condition with DDR3
bank_w = 'b0;
address_w = 'b0;
case (reg_ctrl_cnt_r)
4'h1:begin
address_w[4:0] = REG_RC1[4:0];
bank_w = REG_RC1[7:5];
end
4'h2: address_w[4:0] = REG_RC2[4:0];
4'h3: begin
address_w[4:0] = REG_RC3[4:0];
bank_w = REG_RC3[7:5];
end
4'h4: begin
address_w[4:0] = REG_RC4[4:0];
bank_w = REG_RC4[7:5];
end
4'h5: begin
address_w[4:0] = REG_RC5[4:0];
bank_w = REG_RC5[7:5];
end
4'h6: begin
address_w[4:0] = REG_RC10[4:0];
bank_w = REG_RC10[7:5];
end
4'h7: begin
address_w[4:0] = REG_RC11[4:0];
bank_w = REG_RC11[7:5];
end
default: address_w[4:0] = REG_RC0[4:0];
endcase
end else if (init_state_r == INIT_LOAD_MR) begin
// If loading mode register, look at cnt_init_mr to determine
// which MR is currently being programmed
address_w = 'b0;
bank_w = 'b0;
if(DRAM_TYPE == "DDR3")begin
if(rdlvl_stg1_done && prbs_rdlvl_done && pi_dqs_found_done)begin
// end of the calibration programming correct
// burst length
if (TEST_AL == "0") begin
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
address_w[8]= 1'b0; //Don't reset DLL
end else begin
// programming correct AL value
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
if (TEST_AL == "CL-1")
address_w[4:3]= 2'b01; // AL="CL-1"
else
address_w[4:3]= 2'b10; // AL="CL-2"
end
end else begin
case (cnt_init_mr_r)
INIT_CNT_MR2: begin
bank_w[1:0] = 2'b10;
address_w = load_mr2[ROW_WIDTH-1:0];
address_w[10:9] = mr2_r[chip_cnt_r];
end
INIT_CNT_MR3: begin
bank_w[1:0] = 2'b11;
address_w = load_mr3[ROW_WIDTH-1:0];
end
INIT_CNT_MR1: begin
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[2] = mr1_r[chip_cnt_r][0];
address_w[6] = mr1_r[chip_cnt_r][1];
address_w[9] = mr1_r[chip_cnt_r][2];
end
INIT_CNT_MR0: begin
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
// fixing it to BL8 for calibration
address_w[1:0] = 2'b00;
end
default: begin
bank_w = {BANK_WIDTH{1'bx}};
address_w = {ROW_WIDTH{1'bx}};
end
endcase
end
end else begin // DDR2
case (cnt_init_mr_r)
INIT_CNT_MR2: begin
if(~ddr2_refresh_flag_r)begin
bank_w[1:0] = 2'b10;
address_w = load_mr2[ROW_WIDTH-1:0];
end else begin // second set of lm commands
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
address_w[8]= 1'b0;
//MRS command without resetting DLL
end
end
INIT_CNT_MR3: begin
if(~ddr2_refresh_flag_r)begin
bank_w[1:0] = 2'b11;
address_w = load_mr3[ROW_WIDTH-1:0];
end else begin // second set of lm commands
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
address_w[8]= 1'b0;
//MRS command without resetting DLL. Repeted again
// because there is an extra state.
end
end
INIT_CNT_MR1: begin
bank_w[1:0] = 2'b01;
if(~ddr2_refresh_flag_r)begin
address_w = load_mr1[ROW_WIDTH-1:0];
end else begin // second set of lm commands
address_w = load_mr1[ROW_WIDTH-1:0];
address_w[9:7] = 3'b111;
//OCD default state
end
end
INIT_CNT_MR0: begin
if(~ddr2_refresh_flag_r)begin
bank_w[1:0] = 2'b00;
address_w = load_mr0[ROW_WIDTH-1:0];
end else begin // second set of lm commands
bank_w[1:0] = 2'b01;
address_w = load_mr1[ROW_WIDTH-1:0];
if((chip_cnt_r == 2'd1) || (chip_cnt_r == 2'd3))begin
// always disable odt for rank 1 and rank 3 as per SPEC
address_w[2] = 'b0;
address_w[6] = 'b0;
end
//OCD exit
end
end
default: begin
bank_w = {BANK_WIDTH{1'bx}};
address_w = {ROW_WIDTH{1'bx}};
end
endcase
end
end else if ( ~prbs_rdlvl_done && ((init_state_r == INIT_PI_PHASELOCK_READS) ||
(init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_STG1_READ) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ))) begin
// Writing and reading PRBS pattern for read leveling stage 1
// Need to support burst length 4 or 8. PRBS pattern will be
// written to entire row and read back from the same row repeatedly
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if (((stg1_wr_rd_cnt == NUM_STG1_WR_RD) && ~rdlvl_stg1_done) || (stg1_wr_rd_cnt == 'd127) ||
((stg1_wr_rd_cnt == 'd22) && (((init_state_r1 != INIT_RDLVL_STG1_WRITE) && ~stg1_wr_done) || complex_row0_rd_done))) begin
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
end else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((stg1_wr_rd_cnt >= 9'd0) && new_burst_r && ~phy_data_full_r) begin
if ((init_state_r == INIT_RDLVL_COMPLEX_READ) && (init_state_r1 != INIT_RDLVL_COMPLEX_READ) )// ||
// ((init_state_r == INIT_RDLVL_STG1_WRITE) && prbs_rdlvl_done) )
address_w[COL_WIDTH-1:0] = complex_address[COL_WIDTH-1:0] + ADDR_INC;
else
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end
//need to add address for complex oclkdelay calib
end else if (prbs_rdlvl_done && ((init_state_r == INIT_RDLVL_STG1_WRITE) ||
(init_state_r == INIT_RDLVL_COMPLEX_READ))) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if ((stg1_wr_rd_cnt == 'd127) || ((stg1_wr_rd_cnt == 'd30) && (((init_state_r1 != INIT_RDLVL_STG1_WRITE) && ~stg1_wr_done) || complex_row0_rd_done))) begin
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
end else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((stg1_wr_rd_cnt >= 9'd0) && new_burst_r && ~phy_data_full_r) begin
if ((init_state_r == INIT_RDLVL_STG1_WRITE) && (init_state_r1 != INIT_RDLVL_STG1_WRITE) )
// ((init_state_r == INIT_RDLVL_STG1_WRITE) && prbs_rdlvl_done) )
address_w[COL_WIDTH-1:0] = complex_address[COL_WIDTH-1:0] + ADDR_INC;
else
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end
end else if ((init_state_r == INIT_OCLKDELAY_WRITE) ||
(init_state_r == INIT_OCAL_CENTER_WRITE) ||
(init_state_r == INIT_OCLKDELAY_READ)) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if (oclk_wr_cnt == NUM_STG1_WR_RD)
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((oclk_wr_cnt >= 4'd0) && new_burst_r && ~phy_data_full_r)
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end else if ((init_state_r == INIT_WRCAL_WRITE) ||
(init_state_r == INIT_WRCAL_READ)) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
if (wrcal_wr_cnt == NUM_STG1_WR_RD)
address_w[COL_WIDTH-1:0] = {COL_WIDTH{1'b0}};
else if (phy_data_full_r || (!new_burst_r))
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0];
else if ((wrcal_wr_cnt >= 4'd0) && new_burst_r && ~phy_data_full_r)
address_w[COL_WIDTH-1:0] = phy_address[COL_WIDTH-1:0] + ADDR_INC;
end else if ((init_state_r == INIT_WRCAL_MULT_READS) ||
(init_state_r == INIT_RDLVL_STG2_READ)) begin
// when writing or reading back training pattern for read leveling stage2
// need to support burst length of 4 or 8. This may mean issuing
// multiple commands to cover the entire range of addresses accessed
// during read leveling.
// Hard coding A[12] to 1 so that it will always be burst length of 8
// for DDR3. Does not have any effect on DDR2.
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
address_w[ROW_WIDTH-1:COL_WIDTH] = {ROW_WIDTH-COL_WIDTH{1'b0}};
address_w[COL_WIDTH-1:0] =
{CALIB_COL_ADD[COL_WIDTH-1:3],burst_addr_r, 3'b000};
address_w[12] = 1'b1;
end else if ((init_state_r == INIT_RDLVL_ACT) ||
(init_state_r == INIT_RDLVL_COMPLEX_ACT) ||
(init_state_r == INIT_WRCAL_ACT) ||
(init_state_r == INIT_OCAL_COMPLEX_ACT) ||
(init_state_r == INIT_OCAL_CENTER_ACT) ||
(init_state_r == INIT_OCLKDELAY_ACT)) begin
bank_w = CALIB_BA_ADD[BANK_WIDTH-1:0];
//if (stg1_wr_rd_cnt == 'd22)
// address_w = CALIB_ROW_ADD[ROW_WIDTH-1:0] + 1;
//else
address_w = prbs_rdlvl_done ? CALIB_ROW_ADD[ROW_WIDTH-1:0] + complex_row_cnt_ocal :
CALIB_ROW_ADD[ROW_WIDTH-1:0] + complex_row_cnt;
end else begin
bank_w = {BANK_WIDTH{1'bx}};
address_w = {ROW_WIDTH{1'bx}};
end
end
// verilint STARC-2.7.3.3b on
// registring before sending out
generate
genvar r,s;
if ((DRAM_TYPE != "DDR3") || (CA_MIRROR != "ON")) begin: gen_no_mirror
for (r = 0; r < nCK_PER_CLK; r = r + 1) begin: div_clk_loop
always @(posedge clk) begin
phy_address[(r*ROW_WIDTH) +: ROW_WIDTH] <= #TCQ address_w;
phy_bank[(r*BANK_WIDTH) +: BANK_WIDTH] <= #TCQ bank_w;
end
end
end else begin: gen_mirror
// Control/addressing mirroring (optional for DDR3 dual rank DIMMs)
// Mirror for the 2nd rank only. Logic needs to be enhanced to account
// for multiple slots, currently only supports one slot, 2-rank config
for (r = 0; r < nCK_PER_CLK; r = r + 1) begin: gen_ba_div_clk_loop
for (s = 0; s < BANK_WIDTH; s = s + 1) begin: gen_ba
always @(posedge clk)
if (chip_cnt_r == 2'b00) begin
phy_bank[(r*BANK_WIDTH) + s] <= #TCQ bank_w[s];
end else begin
phy_bank[(r*BANK_WIDTH) + s] <= #TCQ bank_w[(s == 0) ? 1 : ((s == 1) ? 0 : s)];
end
end
end
for (r = 0; r < nCK_PER_CLK; r = r + 1) begin: gen_addr_div_clk_loop
for (s = 0; s < ROW_WIDTH; s = s + 1) begin: gen_addr
always @(posedge clk)
if (chip_cnt_r == 2'b00) begin
phy_address[(r*ROW_WIDTH) + s] <= #TCQ address_w[s];
end else begin
phy_address[(r*ROW_WIDTH) + s] <= #TCQ address_w[
(s == 3) ? 4 :
((s == 4) ? 3 :
((s == 5) ? 6 :
((s == 6) ? 5 :
((s == 7) ? 8 :
((s == 8) ? 7 : s)))))];
end
end
end
end
endgenerate
endmodule
|
module outputs)
wire accept_internal_r; // From bank_common0 of bank_common.v
wire accept_req; // From bank_common0 of bank_common.v
wire adv_order_q; // From bank_common0 of bank_common.v
wire [BM_CNT_WIDTH-1:0] idle_cnt; // From bank_common0 of bank_common.v
wire insert_maint_r; // From bank_common0 of bank_common.v
wire low_idle_cnt_r; // From bank_common0 of bank_common.v
wire maint_idle; // From bank_common0 of bank_common.v
wire [BM_CNT_WIDTH-1:0] order_cnt; // From bank_common0 of bank_common.v
wire periodic_rd_insert; // From bank_common0 of bank_common.v
wire [BM_CNT_WIDTH-1:0] rb_hit_busy_cnt; // From bank_common0 of bank_common.v
wire sent_row; // From arb_mux0 of arb_mux.v
wire was_priority; // From bank_common0 of bank_common.v
wire was_wr; // From bank_common0 of bank_common.v
// End of automatics
wire [RANK_WIDTH-1:0] rnk_config;
wire rnk_config_strobe;
wire rnk_config_kill_rts_col;
wire rnk_config_valid_r;
wire [nBANK_MACHS-1:0] rts_row;
wire [nBANK_MACHS-1:0] rts_col;
wire [nBANK_MACHS-1:0] rts_pre;
wire [nBANK_MACHS-1:0] col_rdy_wr;
wire [nBANK_MACHS-1:0] rtc;
wire [nBANK_MACHS-1:0] sending_pre;
wire [DATA_BUF_ADDR_VECT_INDX:0] req_data_buf_addr_r;
wire [nBANK_MACHS-1:0] req_size_r;
wire [RANK_VECT_INDX:0] req_rank_r;
wire [BANK_VECT_INDX:0] req_bank_r;
wire [ROW_VECT_INDX:0] req_row_r;
wire [ROW_VECT_INDX:0] col_addr;
wire [nBANK_MACHS-1:0] req_periodic_rd_r;
wire [nBANK_MACHS-1:0] req_wr_r;
wire [nBANK_MACHS-1:0] rd_wr_r;
wire [nBANK_MACHS-1:0] req_ras;
wire [nBANK_MACHS-1:0] req_cas;
wire [ROW_VECT_INDX:0] row_addr;
wire [nBANK_MACHS-1:0] row_cmd_wr;
wire [nBANK_MACHS-1:0] demand_priority;
wire [nBANK_MACHS-1:0] demand_act_priority;
wire [nBANK_MACHS-1:0] idle_ns;
wire [nBANK_MACHS-1:0] rb_hit_busy_r;
wire [nBANK_MACHS-1:0] bm_end;
wire [nBANK_MACHS-1:0] passing_open_bank;
wire [nBANK_MACHS-1:0] ordered_r;
wire [nBANK_MACHS-1:0] ordered_issued;
wire [nBANK_MACHS-1:0] rb_hit_busy_ns;
wire [nBANK_MACHS-1:0] maint_hit;
wire [nBANK_MACHS-1:0] idle_r;
wire [nBANK_MACHS-1:0] head_r;
wire [nBANK_MACHS-1:0] start_rcd;
wire [nBANK_MACHS-1:0] end_rtp;
wire [nBANK_MACHS-1:0] op_exit_req;
wire [nBANK_MACHS-1:0] op_exit_grant;
wire [nBANK_MACHS-1:0] start_pre_wait;
wire [(RAS_TIMER_WIDTH*nBANK_MACHS)-1:0] ras_timer_ns;
genvar ID;
generate for (ID=0; ID<nBANK_MACHS; ID=ID+1) begin:bank_cntrl
mig_7series_v2_3_bank_cntrl #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_WIDTH (BANK_WIDTH),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.BURST_MODE (BURST_MODE),
.COL_WIDTH (COL_WIDTH),
.CWL (CWL),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.ECC (ECC),
.ID (ID),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nOP_WAIT (nOP_WAIT),
.nRAS_CLKS (nRAS_CLKS),
.nRCD (nRCD),
.nRTP (nRTP),
.nRP (nRP),
.nWTP_CLKS (nWTP_CLKS),
.ORDERING (ORDERING),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.RAS_TIMER_WIDTH (RAS_TIMER_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.STARVE_LIMIT (STARVE_LIMIT))
bank0
(.demand_priority (demand_priority[ID]),
.demand_priority_in ({2{demand_priority}}),
.demand_act_priority (demand_act_priority[ID]),
.demand_act_priority_in ({2{demand_act_priority}}),
.rts_row (rts_row[ID]),
.rts_col (rts_col[ID]),
.rts_pre (rts_pre[ID]),
.col_rdy_wr (col_rdy_wr[ID]),
.rtc (rtc[ID]),
.sending_row (sending_row[ID]),
.sending_pre (sending_pre[ID]),
.sending_col (sending_col[ID]),
.req_data_buf_addr_r (req_data_buf_addr_r[(ID*DATA_BUF_ADDR_WIDTH)+:DATA_BUF_ADDR_WIDTH]),
.req_size_r (req_size_r[ID]),
.req_rank_r (req_rank_r[(ID*RANK_WIDTH)+:RANK_WIDTH]),
.req_bank_r (req_bank_r[(ID*BANK_WIDTH)+:BANK_WIDTH]),
.req_row_r (req_row_r[(ID*ROW_WIDTH)+:ROW_WIDTH]),
.col_addr (col_addr[(ID*ROW_WIDTH)+:ROW_WIDTH]),
.req_wr_r (req_wr_r[ID]),
.rd_wr_r (rd_wr_r[ID]),
.req_periodic_rd_r (req_periodic_rd_r[ID]),
.req_ras (req_ras[ID]),
.req_cas (req_cas[ID]),
.row_addr (row_addr[(ID*ROW_WIDTH)+:ROW_WIDTH]),
.row_cmd_wr (row_cmd_wr[ID]),
.act_this_rank_r (act_this_rank_r[(ID*RANKS)+:RANKS]),
.wr_this_rank_r (wr_this_rank_r[(ID*RANKS)+:RANKS]),
.rd_this_rank_r (rd_this_rank_r[(ID*RANKS)+:RANKS]),
.idle_ns (idle_ns[ID]),
.rb_hit_busy_r (rb_hit_busy_r[ID]),
.bm_end (bm_end[ID]),
.bm_end_in ({2{bm_end}}),
.passing_open_bank (passing_open_bank[ID]),
.passing_open_bank_in ({2{passing_open_bank}}),
.ordered_r (ordered_r[ID]),
.ordered_issued (ordered_issued[ID]),
.rb_hit_busy_ns (rb_hit_busy_ns[ID]),
.rb_hit_busy_ns_in ({2{rb_hit_busy_ns}}),
.maint_hit (maint_hit[ID]),
.req_rank_r_in ({2{req_rank_r}}),
.idle_r (idle_r[ID]),
.head_r (head_r[ID]),
.start_rcd (start_rcd[ID]),
.start_rcd_in ({2{start_rcd}}),
.end_rtp (end_rtp[ID]),
.op_exit_req (op_exit_req[ID]),
.op_exit_grant (op_exit_grant[ID]),
.start_pre_wait (start_pre_wait[ID]),
.ras_timer_ns (ras_timer_ns[(ID*RAS_TIMER_WIDTH)+:RAS_TIMER_WIDTH]),
.ras_timer_ns_in ({2{ras_timer_ns}}),
.rank_busy_r (rank_busy_r[ID*RANKS+:RANKS]),
/*AUTOINST*/
// Inputs
.accept_internal_r (accept_internal_r),
.accept_req (accept_req),
.adv_order_q (adv_order_q),
.bank (bank[BANK_WIDTH-1:0]),
.clk (clk),
.cmd (cmd[2:0]),
.col (col[COL_WIDTH-1:0]),
.data_buf_addr (data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.phy_rddata_valid (phy_rddata_valid),
.dq_busy_data (dq_busy_data),
.hi_priority (hi_priority),
.idle_cnt (idle_cnt[BM_CNT_WIDTH-1:0]),
.inhbt_act_faw_r (inhbt_act_faw_r[RANKS-1:0]),
.inhbt_rd (inhbt_rd[RANKS-1:0]),
.inhbt_wr (inhbt_wr[RANKS-1:0]),
.rnk_config (rnk_config[RANK_WIDTH-1:0]),
.rnk_config_strobe (rnk_config_strobe),
.rnk_config_kill_rts_col (rnk_config_kill_rts_col),
.rnk_config_valid_r (rnk_config_valid_r),
.low_idle_cnt_r (low_idle_cnt_r),
.maint_idle (maint_idle),
.maint_rank_r (maint_rank_r[RANK_WIDTH-1:0]),
.maint_req_r (maint_req_r),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.order_cnt (order_cnt[BM_CNT_WIDTH-1:0]),
.periodic_rd_ack_r (periodic_rd_ack_r),
.periodic_rd_insert (periodic_rd_insert),
.periodic_rd_rank_r (periodic_rd_rank_r[RANK_WIDTH-1:0]),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_data_full (phy_mc_data_full),
.rank (rank[RANK_WIDTH-1:0]),
.rb_hit_busy_cnt (rb_hit_busy_cnt[BM_CNT_WIDTH-1:0]),
.rd_data_addr (rd_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.rd_rmw (rd_rmw),
.row (row[ROW_WIDTH-1:0]),
.rst (rst),
.sent_col (sent_col),
.sent_row (sent_row),
.size (size),
.use_addr (use_addr),
.was_priority (was_priority),
.was_wr (was_wr));
end
endgenerate
mig_7series_v2_3_bank_common #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.LOW_IDLE_CNT (LOW_IDLE_CNT),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nOP_WAIT (nOP_WAIT),
.nRFC (nRFC),
.nXSDLL (nXSDLL),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.CWL (CWL),
.tZQCS (tZQCS))
bank_common0
(.op_exit_grant (op_exit_grant[nBANK_MACHS-1:0]),
/*AUTOINST*/
// Outputs
.accept_internal_r (accept_internal_r),
.accept_ns (accept_ns),
.accept (accept),
.periodic_rd_insert (periodic_rd_insert),
.periodic_rd_ack_r (periodic_rd_ack_r),
.accept_req (accept_req),
.rb_hit_busy_cnt (rb_hit_busy_cnt[BM_CNT_WIDTH-1:0]),
.idle_cnt (idle_cnt[BM_CNT_WIDTH-1:0]),
.idle (idle),
.order_cnt (order_cnt[BM_CNT_WIDTH-1:0]),
.adv_order_q (adv_order_q),
.bank_mach_next (bank_mach_next[BM_CNT_WIDTH-1:0]),
.low_idle_cnt_r (low_idle_cnt_r),
.was_wr (was_wr),
.was_priority (was_priority),
.maint_wip_r (maint_wip_r),
.maint_idle (maint_idle),
.insert_maint_r (insert_maint_r),
// Inputs
.clk (clk),
.rst (rst),
.idle_ns (idle_ns[nBANK_MACHS-1:0]),
.init_calib_complete (init_calib_complete),
.periodic_rd_r (periodic_rd_r),
.use_addr (use_addr),
.rb_hit_busy_r (rb_hit_busy_r[nBANK_MACHS-1:0]),
.idle_r (idle_r[nBANK_MACHS-1:0]),
.ordered_r (ordered_r[nBANK_MACHS-1:0]),
.ordered_issued (ordered_issued[nBANK_MACHS-1:0]),
.head_r (head_r[nBANK_MACHS-1:0]),
.end_rtp (end_rtp[nBANK_MACHS-1:0]),
.passing_open_bank (passing_open_bank[nBANK_MACHS-1:0]),
.op_exit_req (op_exit_req[nBANK_MACHS-1:0]),
.start_pre_wait (start_pre_wait[nBANK_MACHS-1:0]),
.cmd (cmd[2:0]),
.hi_priority (hi_priority),
.maint_req_r (maint_req_r),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.maint_srx_r (maint_srx_r),
.maint_hit (maint_hit[nBANK_MACHS-1:0]),
.bm_end (bm_end[nBANK_MACHS-1:0]),
.slot_0_present (slot_0_present[7:0]),
.slot_1_present (slot_1_present[7:0]));
mig_7series_v2_3_arb_mux #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.EVEN_CWL_2T_MODE (EVEN_CWL_2T_MODE),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_VECT_INDX (BANK_VECT_INDX),
.BANK_WIDTH (BANK_WIDTH),
.BURST_MODE (BURST_MODE),
.CS_WIDTH (CS_WIDTH),
.CL (CL),
.CWL (CWL),
.DATA_BUF_ADDR_VECT_INDX (DATA_BUF_ADDR_VECT_INDX),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.EARLY_WR_DATA_ADDR (EARLY_WR_DATA_ADDR),
.ECC (ECC),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.nRAS (nRAS),
.nRCD (nRCD),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nSLOTS (nSLOTS),
.nWR (nWR),
.RANKS (RANKS),
.RANK_VECT_INDX (RANK_VECT_INDX),
.RANK_WIDTH (RANK_WIDTH),
.ROW_VECT_INDX (ROW_VECT_INDX),
.ROW_WIDTH (ROW_WIDTH),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.SLOT_0_CONFIG (SLOT_0_CONFIG),
.SLOT_1_CONFIG (SLOT_1_CONFIG))
arb_mux0
(.rts_col (rts_col[nBANK_MACHS-1:0]), // AUTOs wants to make this an input.
/*AUTOINST*/
// Outputs
.col_a (col_a[ROW_WIDTH-1:0]),
.col_ba (col_ba[BANK_WIDTH-1:0]),
.col_data_buf_addr (col_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.col_periodic_rd (col_periodic_rd),
.col_ra (col_ra[RANK_WIDTH-1:0]),
.col_rmw (col_rmw),
.col_rd_wr (col_rd_wr),
.col_row (col_row[ROW_WIDTH-1:0]),
.col_size (col_size),
.col_wr_data_buf_addr (col_wr_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.mc_bank (mc_bank),
.mc_address (mc_address),
.mc_ras_n (mc_ras_n),
.mc_cas_n (mc_cas_n),
.mc_we_n (mc_we_n),
.mc_cs_n (mc_cs_n),
.mc_odt (mc_odt),
.mc_cke (mc_cke),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_cmd (mc_cmd),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.rnk_config (rnk_config[RANK_WIDTH-1:0]),
.rnk_config_valid_r (rnk_config_valid_r),
.mc_cas_slot (mc_cas_slot),
.sending_row (sending_row[nBANK_MACHS-1:0]),
.sending_pre (sending_pre[nBANK_MACHS-1:0]),
.sent_col (sent_col),
.sent_col_r (sent_col_r),
.sent_row (sent_row),
.sending_col (sending_col[nBANK_MACHS-1:0]),
.rnk_config_strobe (rnk_config_strobe),
.rnk_config_kill_rts_col (rnk_config_kill_rts_col),
.insert_maint_r1 (insert_maint_r1),
// Inputs
.init_calib_complete (init_calib_complete),
.calib_rddata_offset (calib_rddata_offset),
.calib_rddata_offset_1 (calib_rddata_offset_1),
.calib_rddata_offset_2 (calib_rddata_offset_2),
.col_addr (col_addr[ROW_VECT_INDX:0]),
.col_rdy_wr (col_rdy_wr[nBANK_MACHS-1:0]),
.insert_maint_r (insert_maint_r),
.maint_rank_r (maint_rank_r[RANK_WIDTH-1:0]),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.maint_srx_r (maint_srx_r),
.rd_wr_r (rd_wr_r[nBANK_MACHS-1:0]),
.req_bank_r (req_bank_r[BANK_VECT_INDX:0]),
.req_cas (req_cas[nBANK_MACHS-1:0]),
.req_data_buf_addr_r (req_data_buf_addr_r[DATA_BUF_ADDR_VECT_INDX:0]),
.req_periodic_rd_r (req_periodic_rd_r[nBANK_MACHS-1:0]),
.req_rank_r (req_rank_r[RANK_VECT_INDX:0]),
.req_ras (req_ras[nBANK_MACHS-1:0]),
.req_row_r (req_row_r[ROW_VECT_INDX:0]),
.req_size_r (req_size_r[nBANK_MACHS-1:0]),
.req_wr_r (req_wr_r[nBANK_MACHS-1:0]),
.row_addr (row_addr[ROW_VECT_INDX:0]),
.row_cmd_wr (row_cmd_wr[nBANK_MACHS-1:0]),
.rts_row (rts_row[nBANK_MACHS-1:0]),
.rtc (rtc[nBANK_MACHS-1:0]),
.rts_pre (rts_pre[nBANK_MACHS-1:0]),
.slot_0_present (slot_0_present[7:0]),
.slot_1_present (slot_1_present[7:0]),
.clk (clk),
.rst (rst));
endmodule
|
module outputs)
wire accept_internal_r; // From bank_common0 of bank_common.v
wire accept_req; // From bank_common0 of bank_common.v
wire adv_order_q; // From bank_common0 of bank_common.v
wire [BM_CNT_WIDTH-1:0] idle_cnt; // From bank_common0 of bank_common.v
wire insert_maint_r; // From bank_common0 of bank_common.v
wire low_idle_cnt_r; // From bank_common0 of bank_common.v
wire maint_idle; // From bank_common0 of bank_common.v
wire [BM_CNT_WIDTH-1:0] order_cnt; // From bank_common0 of bank_common.v
wire periodic_rd_insert; // From bank_common0 of bank_common.v
wire [BM_CNT_WIDTH-1:0] rb_hit_busy_cnt; // From bank_common0 of bank_common.v
wire sent_row; // From arb_mux0 of arb_mux.v
wire was_priority; // From bank_common0 of bank_common.v
wire was_wr; // From bank_common0 of bank_common.v
// End of automatics
wire [RANK_WIDTH-1:0] rnk_config;
wire rnk_config_strobe;
wire rnk_config_kill_rts_col;
wire rnk_config_valid_r;
wire [nBANK_MACHS-1:0] rts_row;
wire [nBANK_MACHS-1:0] rts_col;
wire [nBANK_MACHS-1:0] rts_pre;
wire [nBANK_MACHS-1:0] col_rdy_wr;
wire [nBANK_MACHS-1:0] rtc;
wire [nBANK_MACHS-1:0] sending_pre;
wire [DATA_BUF_ADDR_VECT_INDX:0] req_data_buf_addr_r;
wire [nBANK_MACHS-1:0] req_size_r;
wire [RANK_VECT_INDX:0] req_rank_r;
wire [BANK_VECT_INDX:0] req_bank_r;
wire [ROW_VECT_INDX:0] req_row_r;
wire [ROW_VECT_INDX:0] col_addr;
wire [nBANK_MACHS-1:0] req_periodic_rd_r;
wire [nBANK_MACHS-1:0] req_wr_r;
wire [nBANK_MACHS-1:0] rd_wr_r;
wire [nBANK_MACHS-1:0] req_ras;
wire [nBANK_MACHS-1:0] req_cas;
wire [ROW_VECT_INDX:0] row_addr;
wire [nBANK_MACHS-1:0] row_cmd_wr;
wire [nBANK_MACHS-1:0] demand_priority;
wire [nBANK_MACHS-1:0] demand_act_priority;
wire [nBANK_MACHS-1:0] idle_ns;
wire [nBANK_MACHS-1:0] rb_hit_busy_r;
wire [nBANK_MACHS-1:0] bm_end;
wire [nBANK_MACHS-1:0] passing_open_bank;
wire [nBANK_MACHS-1:0] ordered_r;
wire [nBANK_MACHS-1:0] ordered_issued;
wire [nBANK_MACHS-1:0] rb_hit_busy_ns;
wire [nBANK_MACHS-1:0] maint_hit;
wire [nBANK_MACHS-1:0] idle_r;
wire [nBANK_MACHS-1:0] head_r;
wire [nBANK_MACHS-1:0] start_rcd;
wire [nBANK_MACHS-1:0] end_rtp;
wire [nBANK_MACHS-1:0] op_exit_req;
wire [nBANK_MACHS-1:0] op_exit_grant;
wire [nBANK_MACHS-1:0] start_pre_wait;
wire [(RAS_TIMER_WIDTH*nBANK_MACHS)-1:0] ras_timer_ns;
genvar ID;
generate for (ID=0; ID<nBANK_MACHS; ID=ID+1) begin:bank_cntrl
mig_7series_v2_3_bank_cntrl #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_WIDTH (BANK_WIDTH),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.BURST_MODE (BURST_MODE),
.COL_WIDTH (COL_WIDTH),
.CWL (CWL),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.ECC (ECC),
.ID (ID),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nOP_WAIT (nOP_WAIT),
.nRAS_CLKS (nRAS_CLKS),
.nRCD (nRCD),
.nRTP (nRTP),
.nRP (nRP),
.nWTP_CLKS (nWTP_CLKS),
.ORDERING (ORDERING),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.RAS_TIMER_WIDTH (RAS_TIMER_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.STARVE_LIMIT (STARVE_LIMIT))
bank0
(.demand_priority (demand_priority[ID]),
.demand_priority_in ({2{demand_priority}}),
.demand_act_priority (demand_act_priority[ID]),
.demand_act_priority_in ({2{demand_act_priority}}),
.rts_row (rts_row[ID]),
.rts_col (rts_col[ID]),
.rts_pre (rts_pre[ID]),
.col_rdy_wr (col_rdy_wr[ID]),
.rtc (rtc[ID]),
.sending_row (sending_row[ID]),
.sending_pre (sending_pre[ID]),
.sending_col (sending_col[ID]),
.req_data_buf_addr_r (req_data_buf_addr_r[(ID*DATA_BUF_ADDR_WIDTH)+:DATA_BUF_ADDR_WIDTH]),
.req_size_r (req_size_r[ID]),
.req_rank_r (req_rank_r[(ID*RANK_WIDTH)+:RANK_WIDTH]),
.req_bank_r (req_bank_r[(ID*BANK_WIDTH)+:BANK_WIDTH]),
.req_row_r (req_row_r[(ID*ROW_WIDTH)+:ROW_WIDTH]),
.col_addr (col_addr[(ID*ROW_WIDTH)+:ROW_WIDTH]),
.req_wr_r (req_wr_r[ID]),
.rd_wr_r (rd_wr_r[ID]),
.req_periodic_rd_r (req_periodic_rd_r[ID]),
.req_ras (req_ras[ID]),
.req_cas (req_cas[ID]),
.row_addr (row_addr[(ID*ROW_WIDTH)+:ROW_WIDTH]),
.row_cmd_wr (row_cmd_wr[ID]),
.act_this_rank_r (act_this_rank_r[(ID*RANKS)+:RANKS]),
.wr_this_rank_r (wr_this_rank_r[(ID*RANKS)+:RANKS]),
.rd_this_rank_r (rd_this_rank_r[(ID*RANKS)+:RANKS]),
.idle_ns (idle_ns[ID]),
.rb_hit_busy_r (rb_hit_busy_r[ID]),
.bm_end (bm_end[ID]),
.bm_end_in ({2{bm_end}}),
.passing_open_bank (passing_open_bank[ID]),
.passing_open_bank_in ({2{passing_open_bank}}),
.ordered_r (ordered_r[ID]),
.ordered_issued (ordered_issued[ID]),
.rb_hit_busy_ns (rb_hit_busy_ns[ID]),
.rb_hit_busy_ns_in ({2{rb_hit_busy_ns}}),
.maint_hit (maint_hit[ID]),
.req_rank_r_in ({2{req_rank_r}}),
.idle_r (idle_r[ID]),
.head_r (head_r[ID]),
.start_rcd (start_rcd[ID]),
.start_rcd_in ({2{start_rcd}}),
.end_rtp (end_rtp[ID]),
.op_exit_req (op_exit_req[ID]),
.op_exit_grant (op_exit_grant[ID]),
.start_pre_wait (start_pre_wait[ID]),
.ras_timer_ns (ras_timer_ns[(ID*RAS_TIMER_WIDTH)+:RAS_TIMER_WIDTH]),
.ras_timer_ns_in ({2{ras_timer_ns}}),
.rank_busy_r (rank_busy_r[ID*RANKS+:RANKS]),
/*AUTOINST*/
// Inputs
.accept_internal_r (accept_internal_r),
.accept_req (accept_req),
.adv_order_q (adv_order_q),
.bank (bank[BANK_WIDTH-1:0]),
.clk (clk),
.cmd (cmd[2:0]),
.col (col[COL_WIDTH-1:0]),
.data_buf_addr (data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.phy_rddata_valid (phy_rddata_valid),
.dq_busy_data (dq_busy_data),
.hi_priority (hi_priority),
.idle_cnt (idle_cnt[BM_CNT_WIDTH-1:0]),
.inhbt_act_faw_r (inhbt_act_faw_r[RANKS-1:0]),
.inhbt_rd (inhbt_rd[RANKS-1:0]),
.inhbt_wr (inhbt_wr[RANKS-1:0]),
.rnk_config (rnk_config[RANK_WIDTH-1:0]),
.rnk_config_strobe (rnk_config_strobe),
.rnk_config_kill_rts_col (rnk_config_kill_rts_col),
.rnk_config_valid_r (rnk_config_valid_r),
.low_idle_cnt_r (low_idle_cnt_r),
.maint_idle (maint_idle),
.maint_rank_r (maint_rank_r[RANK_WIDTH-1:0]),
.maint_req_r (maint_req_r),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.order_cnt (order_cnt[BM_CNT_WIDTH-1:0]),
.periodic_rd_ack_r (periodic_rd_ack_r),
.periodic_rd_insert (periodic_rd_insert),
.periodic_rd_rank_r (periodic_rd_rank_r[RANK_WIDTH-1:0]),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_data_full (phy_mc_data_full),
.rank (rank[RANK_WIDTH-1:0]),
.rb_hit_busy_cnt (rb_hit_busy_cnt[BM_CNT_WIDTH-1:0]),
.rd_data_addr (rd_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.rd_rmw (rd_rmw),
.row (row[ROW_WIDTH-1:0]),
.rst (rst),
.sent_col (sent_col),
.sent_row (sent_row),
.size (size),
.use_addr (use_addr),
.was_priority (was_priority),
.was_wr (was_wr));
end
endgenerate
mig_7series_v2_3_bank_common #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.LOW_IDLE_CNT (LOW_IDLE_CNT),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nOP_WAIT (nOP_WAIT),
.nRFC (nRFC),
.nXSDLL (nXSDLL),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.CWL (CWL),
.tZQCS (tZQCS))
bank_common0
(.op_exit_grant (op_exit_grant[nBANK_MACHS-1:0]),
/*AUTOINST*/
// Outputs
.accept_internal_r (accept_internal_r),
.accept_ns (accept_ns),
.accept (accept),
.periodic_rd_insert (periodic_rd_insert),
.periodic_rd_ack_r (periodic_rd_ack_r),
.accept_req (accept_req),
.rb_hit_busy_cnt (rb_hit_busy_cnt[BM_CNT_WIDTH-1:0]),
.idle_cnt (idle_cnt[BM_CNT_WIDTH-1:0]),
.idle (idle),
.order_cnt (order_cnt[BM_CNT_WIDTH-1:0]),
.adv_order_q (adv_order_q),
.bank_mach_next (bank_mach_next[BM_CNT_WIDTH-1:0]),
.low_idle_cnt_r (low_idle_cnt_r),
.was_wr (was_wr),
.was_priority (was_priority),
.maint_wip_r (maint_wip_r),
.maint_idle (maint_idle),
.insert_maint_r (insert_maint_r),
// Inputs
.clk (clk),
.rst (rst),
.idle_ns (idle_ns[nBANK_MACHS-1:0]),
.init_calib_complete (init_calib_complete),
.periodic_rd_r (periodic_rd_r),
.use_addr (use_addr),
.rb_hit_busy_r (rb_hit_busy_r[nBANK_MACHS-1:0]),
.idle_r (idle_r[nBANK_MACHS-1:0]),
.ordered_r (ordered_r[nBANK_MACHS-1:0]),
.ordered_issued (ordered_issued[nBANK_MACHS-1:0]),
.head_r (head_r[nBANK_MACHS-1:0]),
.end_rtp (end_rtp[nBANK_MACHS-1:0]),
.passing_open_bank (passing_open_bank[nBANK_MACHS-1:0]),
.op_exit_req (op_exit_req[nBANK_MACHS-1:0]),
.start_pre_wait (start_pre_wait[nBANK_MACHS-1:0]),
.cmd (cmd[2:0]),
.hi_priority (hi_priority),
.maint_req_r (maint_req_r),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.maint_srx_r (maint_srx_r),
.maint_hit (maint_hit[nBANK_MACHS-1:0]),
.bm_end (bm_end[nBANK_MACHS-1:0]),
.slot_0_present (slot_0_present[7:0]),
.slot_1_present (slot_1_present[7:0]));
mig_7series_v2_3_arb_mux #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.EVEN_CWL_2T_MODE (EVEN_CWL_2T_MODE),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_VECT_INDX (BANK_VECT_INDX),
.BANK_WIDTH (BANK_WIDTH),
.BURST_MODE (BURST_MODE),
.CS_WIDTH (CS_WIDTH),
.CL (CL),
.CWL (CWL),
.DATA_BUF_ADDR_VECT_INDX (DATA_BUF_ADDR_VECT_INDX),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.EARLY_WR_DATA_ADDR (EARLY_WR_DATA_ADDR),
.ECC (ECC),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.nRAS (nRAS),
.nRCD (nRCD),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nSLOTS (nSLOTS),
.nWR (nWR),
.RANKS (RANKS),
.RANK_VECT_INDX (RANK_VECT_INDX),
.RANK_WIDTH (RANK_WIDTH),
.ROW_VECT_INDX (ROW_VECT_INDX),
.ROW_WIDTH (ROW_WIDTH),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.SLOT_0_CONFIG (SLOT_0_CONFIG),
.SLOT_1_CONFIG (SLOT_1_CONFIG))
arb_mux0
(.rts_col (rts_col[nBANK_MACHS-1:0]), // AUTOs wants to make this an input.
/*AUTOINST*/
// Outputs
.col_a (col_a[ROW_WIDTH-1:0]),
.col_ba (col_ba[BANK_WIDTH-1:0]),
.col_data_buf_addr (col_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.col_periodic_rd (col_periodic_rd),
.col_ra (col_ra[RANK_WIDTH-1:0]),
.col_rmw (col_rmw),
.col_rd_wr (col_rd_wr),
.col_row (col_row[ROW_WIDTH-1:0]),
.col_size (col_size),
.col_wr_data_buf_addr (col_wr_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.mc_bank (mc_bank),
.mc_address (mc_address),
.mc_ras_n (mc_ras_n),
.mc_cas_n (mc_cas_n),
.mc_we_n (mc_we_n),
.mc_cs_n (mc_cs_n),
.mc_odt (mc_odt),
.mc_cke (mc_cke),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_cmd (mc_cmd),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.rnk_config (rnk_config[RANK_WIDTH-1:0]),
.rnk_config_valid_r (rnk_config_valid_r),
.mc_cas_slot (mc_cas_slot),
.sending_row (sending_row[nBANK_MACHS-1:0]),
.sending_pre (sending_pre[nBANK_MACHS-1:0]),
.sent_col (sent_col),
.sent_col_r (sent_col_r),
.sent_row (sent_row),
.sending_col (sending_col[nBANK_MACHS-1:0]),
.rnk_config_strobe (rnk_config_strobe),
.rnk_config_kill_rts_col (rnk_config_kill_rts_col),
.insert_maint_r1 (insert_maint_r1),
// Inputs
.init_calib_complete (init_calib_complete),
.calib_rddata_offset (calib_rddata_offset),
.calib_rddata_offset_1 (calib_rddata_offset_1),
.calib_rddata_offset_2 (calib_rddata_offset_2),
.col_addr (col_addr[ROW_VECT_INDX:0]),
.col_rdy_wr (col_rdy_wr[nBANK_MACHS-1:0]),
.insert_maint_r (insert_maint_r),
.maint_rank_r (maint_rank_r[RANK_WIDTH-1:0]),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.maint_srx_r (maint_srx_r),
.rd_wr_r (rd_wr_r[nBANK_MACHS-1:0]),
.req_bank_r (req_bank_r[BANK_VECT_INDX:0]),
.req_cas (req_cas[nBANK_MACHS-1:0]),
.req_data_buf_addr_r (req_data_buf_addr_r[DATA_BUF_ADDR_VECT_INDX:0]),
.req_periodic_rd_r (req_periodic_rd_r[nBANK_MACHS-1:0]),
.req_rank_r (req_rank_r[RANK_VECT_INDX:0]),
.req_ras (req_ras[nBANK_MACHS-1:0]),
.req_row_r (req_row_r[ROW_VECT_INDX:0]),
.req_size_r (req_size_r[nBANK_MACHS-1:0]),
.req_wr_r (req_wr_r[nBANK_MACHS-1:0]),
.row_addr (row_addr[ROW_VECT_INDX:0]),
.row_cmd_wr (row_cmd_wr[nBANK_MACHS-1:0]),
.rts_row (rts_row[nBANK_MACHS-1:0]),
.rtc (rtc[nBANK_MACHS-1:0]),
.rts_pre (rts_pre[nBANK_MACHS-1:0]),
.slot_0_present (slot_0_present[7:0]),
.slot_1_present (slot_1_present[7:0]),
.clk (clk),
.rst (rst));
endmodule
|
module mig_7series_v2_3_arb_row_col #
(
parameter TCQ = 100,
parameter ADDR_CMD_MODE = "1T",
parameter CWL = 5,
parameter EARLY_WR_DATA_ADDR = "OFF",
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2,
parameter nRAS = 37500, // ACT->PRE cmd period (CKs)
parameter nRCD = 12500, // ACT->R/W delay (CKs)
parameter nWR = 6 // Write recovery (CKs)
)
(/*AUTOARG*/
// Outputs
grant_row_r, grant_pre_r, sent_row, sending_row, sending_pre, grant_config_r,
rnk_config_strobe, rnk_config_valid_r, grant_col_r,
sending_col, sent_col, sent_col_r, grant_col_wr, send_cmd0_row, send_cmd0_col,
send_cmd1_row, send_cmd1_col, send_cmd2_row, send_cmd2_col, send_cmd2_pre,
send_cmd3_col, col_channel_offset, cs_en0, cs_en1, cs_en2, cs_en3,
insert_maint_r1, rnk_config_kill_rts_col,
// Inputs
clk, rst, rts_row, rts_pre, insert_maint_r, rts_col, rtc, col_rdy_wr
);
// Create a delay when switching ranks
localparam RNK2RNK_DLY = 12;
localparam RNK2RNK_DLY_CLKS =
(RNK2RNK_DLY / nCK_PER_CLK) + (RNK2RNK_DLY % nCK_PER_CLK ? 1 : 0);
input clk;
input rst;
input [nBANK_MACHS-1:0] rts_row;
input insert_maint_r;
input [nBANK_MACHS-1:0] rts_col;
reg [RNK2RNK_DLY_CLKS-1:0] rnk_config_strobe_r;
wire block_grant_row;
wire block_grant_col;
wire rnk_config_kill_rts_col_lcl =
RNK2RNK_DLY_CLKS > 0 ? |rnk_config_strobe_r : 1'b0;
output rnk_config_kill_rts_col;
assign rnk_config_kill_rts_col = rnk_config_kill_rts_col_lcl;
wire [nBANK_MACHS-1:0] col_request;
wire granted_col_ns = |col_request;
wire [nBANK_MACHS-1:0] row_request =
rts_row & {nBANK_MACHS{~insert_maint_r}};
wire granted_row_ns = |row_request;
generate
if (ADDR_CMD_MODE == "2T" && nCK_PER_CLK != 4) begin : row_col_2T_arb
assign col_request =
rts_col & {nBANK_MACHS{~(rnk_config_kill_rts_col_lcl || insert_maint_r)}};
// Give column command priority whenever previous state has no row request.
wire [1:0] row_col_grant;
wire [1:0] current_master = ~granted_row_ns ? 2'b10 : row_col_grant;
wire upd_last_master = ~granted_row_ns || |row_col_grant;
mig_7series_v2_3_round_robin_arb #
(.WIDTH (2))
row_col_arb0
(.grant_ns (),
.grant_r (row_col_grant),
.upd_last_master (upd_last_master),
.current_master (current_master),
.clk (clk),
.rst (rst),
.req ({granted_row_ns, granted_col_ns}),
.disable_grant (1'b0));
assign {block_grant_col, block_grant_row} = row_col_grant;
end
else begin : row_col_1T_arb
assign col_request = rts_col & {nBANK_MACHS{~rnk_config_kill_rts_col_lcl}};
assign block_grant_row = 1'b0;
assign block_grant_col = 1'b0;
end
endgenerate
// Row address/command arbitration.
wire[nBANK_MACHS-1:0] grant_row_r_lcl;
output wire[nBANK_MACHS-1:0] grant_row_r;
assign grant_row_r = grant_row_r_lcl;
reg granted_row_r;
always @(posedge clk) granted_row_r <= #TCQ granted_row_ns;
wire sent_row_lcl = granted_row_r && ~block_grant_row;
output wire sent_row;
assign sent_row = sent_row_lcl;
mig_7series_v2_3_round_robin_arb #
(.WIDTH (nBANK_MACHS))
row_arb0
(.grant_ns (),
.grant_r (grant_row_r_lcl[nBANK_MACHS-1:0]),
.upd_last_master (sent_row_lcl),
.current_master (grant_row_r_lcl[nBANK_MACHS-1:0]),
.clk (clk),
.rst (rst),
.req (row_request),
.disable_grant (1'b0));
output wire [nBANK_MACHS-1:0] sending_row;
assign sending_row = grant_row_r_lcl & {nBANK_MACHS{~block_grant_row}};
// Precharge arbitration for 4:1 mode
input [nBANK_MACHS-1:0] rts_pre;
output wire[nBANK_MACHS-1:0] grant_pre_r;
output wire [nBANK_MACHS-1:0] sending_pre;
wire sent_pre_lcl;
generate
if((nCK_PER_CLK == 4) && (ADDR_CMD_MODE != "2T")) begin : pre_4_1_1T_arb
reg granted_pre_r;
wire[nBANK_MACHS-1:0] grant_pre_r_lcl;
wire granted_pre_ns = |rts_pre;
assign grant_pre_r = grant_pre_r_lcl;
always @(posedge clk) granted_pre_r <= #TCQ granted_pre_ns;
assign sent_pre_lcl = granted_pre_r;
assign sending_pre = grant_pre_r_lcl;
mig_7series_v2_3_round_robin_arb #
(.WIDTH (nBANK_MACHS))
pre_arb0
(.grant_ns (),
.grant_r (grant_pre_r_lcl[nBANK_MACHS-1:0]),
.upd_last_master (sent_pre_lcl),
.current_master (grant_pre_r_lcl[nBANK_MACHS-1:0]),
.clk (clk),
.rst (rst),
.req (rts_pre),
.disable_grant (1'b0));
end
endgenerate
`ifdef MC_SVA
all_bank_machines_row_arb:
cover property (@(posedge clk) (~rst && &rts_row));
`endif
// Rank config arbitration.
input [nBANK_MACHS-1:0] rtc;
wire [nBANK_MACHS-1:0] grant_config_r_lcl;
output wire [nBANK_MACHS-1:0] grant_config_r;
assign grant_config_r = grant_config_r_lcl;
wire upd_rnk_config_last_master;
mig_7series_v2_3_round_robin_arb #
(.WIDTH (nBANK_MACHS))
config_arb0
(.grant_ns (),
.grant_r (grant_config_r_lcl[nBANK_MACHS-1:0]),
.upd_last_master (upd_rnk_config_last_master),
.current_master (grant_config_r_lcl[nBANK_MACHS-1:0]),
.clk (clk),
.rst (rst),
.req (rtc[nBANK_MACHS-1:0]),
.disable_grant (1'b0));
`ifdef MC_SVA
all_bank_machines_config_arb: cover property (@(posedge clk) (~rst && &rtc));
`endif
wire rnk_config_strobe_ns = ~rnk_config_strobe_r[0] && |rtc && ~granted_col_ns;
always @(posedge clk) rnk_config_strobe_r[0] <= #TCQ rnk_config_strobe_ns;
genvar i;
generate
for(i = 1; i < RNK2RNK_DLY_CLKS; i = i + 1)
always @(posedge clk)
rnk_config_strobe_r[i] <= #TCQ rnk_config_strobe_r[i-1];
endgenerate
output wire rnk_config_strobe;
assign rnk_config_strobe = rnk_config_strobe_r[0];
assign upd_rnk_config_last_master = rnk_config_strobe_r[0];
// Generate rnk_config_valid.
reg rnk_config_valid_r_lcl;
wire rnk_config_valid_ns;
assign rnk_config_valid_ns =
~rst && (rnk_config_valid_r_lcl || rnk_config_strobe_ns);
always @(posedge clk) rnk_config_valid_r_lcl <= #TCQ rnk_config_valid_ns;
output wire rnk_config_valid_r;
assign rnk_config_valid_r = rnk_config_valid_r_lcl;
// Column address/command arbitration.
wire [nBANK_MACHS-1:0] grant_col_r_lcl;
output wire [nBANK_MACHS-1:0] grant_col_r;
assign grant_col_r = grant_col_r_lcl;
reg granted_col_r;
always @(posedge clk) granted_col_r <= #TCQ granted_col_ns;
wire sent_col_lcl;
mig_7series_v2_3_round_robin_arb #
(.WIDTH (nBANK_MACHS))
col_arb0
(.grant_ns (),
.grant_r (grant_col_r_lcl[nBANK_MACHS-1:0]),
.upd_last_master (sent_col_lcl),
.current_master (grant_col_r_lcl[nBANK_MACHS-1:0]),
.clk (clk),
.rst (rst),
.req (col_request),
.disable_grant (1'b0));
`ifdef MC_SVA
all_bank_machines_col_arb:
cover property (@(posedge clk) (~rst && &rts_col));
`endif
output wire [nBANK_MACHS-1:0] sending_col;
assign sending_col = grant_col_r_lcl & {nBANK_MACHS{~block_grant_col}};
assign sent_col_lcl = granted_col_r && ~block_grant_col;
reg sent_col_lcl_r = 1'b0;
always @(posedge clk) sent_col_lcl_r <= #TCQ sent_col_lcl;
output wire sent_col;
assign sent_col = sent_col_lcl;
output wire sent_col_r;
assign sent_col_r = sent_col_lcl_r;
// If we need early wr_data_addr because ECC is on, arbitrate
// to see which bank machine might sent the next wr_data_addr;
input [nBANK_MACHS-1:0] col_rdy_wr;
output wire [nBANK_MACHS-1:0] grant_col_wr;
generate
if (EARLY_WR_DATA_ADDR == "OFF") begin : early_wr_addr_arb_off
assign grant_col_wr = {nBANK_MACHS{1'b0}};
end
else begin : early_wr_addr_arb_on
wire [nBANK_MACHS-1:0] grant_col_wr_raw;
mig_7series_v2_3_round_robin_arb #
(.WIDTH (nBANK_MACHS))
col_arb0
(.grant_ns (grant_col_wr_raw),
.grant_r (),
.upd_last_master (sent_col_lcl),
.current_master (grant_col_r_lcl[nBANK_MACHS-1:0]),
.clk (clk),
.rst (rst),
.req (col_rdy_wr),
.disable_grant (1'b0));
reg [nBANK_MACHS-1:0] grant_col_wr_r;
wire [nBANK_MACHS-1:0] grant_col_wr_ns = granted_col_ns
? grant_col_wr_raw
: grant_col_wr_r;
always @(posedge clk) grant_col_wr_r <= #TCQ grant_col_wr_ns;
assign grant_col_wr = grant_col_wr_ns;
end // block: early_wr_addr_arb_on
endgenerate
output reg send_cmd0_row = 1'b0;
output reg send_cmd0_col = 1'b0;
output reg send_cmd1_row = 1'b0;
output reg send_cmd1_col = 1'b0;
output reg send_cmd2_row = 1'b0;
output reg send_cmd2_col = 1'b0;
output reg send_cmd2_pre = 1'b0;
output reg send_cmd3_col = 1'b0;
output reg cs_en0 = 1'b0;
output reg cs_en1 = 1'b0;
output reg cs_en2 = 1'b0;
output reg cs_en3 = 1'b0;
output wire [5:0] col_channel_offset;
reg insert_maint_r1_lcl;
always @(posedge clk) insert_maint_r1_lcl <= #TCQ insert_maint_r;
output wire insert_maint_r1;
assign insert_maint_r1 = insert_maint_r1_lcl;
wire sent_row_or_maint = sent_row_lcl || insert_maint_r1_lcl;
reg sent_row_or_maint_r = 1'b0;
always @(posedge clk) sent_row_or_maint_r <= #TCQ sent_row_or_maint;
generate
case ({(nCK_PER_CLK == 4), (nCK_PER_CLK == 2), (ADDR_CMD_MODE == "2T")})
3'b000 : begin : one_one_not2T
end
3'b001 : begin : one_one_2T
end
3'b010 : begin : two_one_not2T
if(!(CWL % 2)) begin // Place column commands on slot 0 for even CWL
always @(sent_col_lcl) begin
cs_en0 = sent_col_lcl;
send_cmd0_col = sent_col_lcl;
end
always @(sent_row_or_maint) begin
cs_en1 = sent_row_or_maint;
send_cmd1_row = sent_row_or_maint;
end
assign col_channel_offset = 0;
end
else begin // Place column commands on slot 1 for odd CWL
always @(sent_row_or_maint) begin
cs_en0 = sent_row_or_maint;
send_cmd0_row = sent_row_or_maint;
end
always @(sent_col_lcl) begin
cs_en1 = sent_col_lcl;
send_cmd1_col = sent_col_lcl;
end
assign col_channel_offset = 1;
end
end
3'b011 : begin : two_one_2T
if(!(CWL % 2)) begin // Place column commands on slot 1->0 for even CWL
always @(sent_row_or_maint_r or sent_col_lcl_r)
cs_en0 = sent_row_or_maint_r || sent_col_lcl_r;
always @(sent_row_or_maint or sent_row_or_maint_r) begin
send_cmd0_row = sent_row_or_maint_r;
send_cmd1_row = sent_row_or_maint;
end
always @(sent_col_lcl or sent_col_lcl_r) begin
send_cmd0_col = sent_col_lcl_r;
send_cmd1_col = sent_col_lcl;
end
assign col_channel_offset = 0;
end
else begin // Place column commands on slot 0->1 for odd CWL
always @(sent_col_lcl or sent_row_or_maint)
cs_en1 = sent_row_or_maint || sent_col_lcl;
always @(sent_row_or_maint) begin
send_cmd0_row = sent_row_or_maint;
send_cmd1_row = sent_row_or_maint;
end
always @(sent_col_lcl) begin
send_cmd0_col = sent_col_lcl;
send_cmd1_col = sent_col_lcl;
end
assign col_channel_offset = 1;
end
end
3'b100 : begin : four_one_not2T
if(!(CWL % 2)) begin // Place column commands on slot 0 for even CWL
always @(sent_col_lcl) begin
cs_en0 = sent_col_lcl;
send_cmd0_col = sent_col_lcl;
end
always @(sent_row_or_maint) begin
cs_en1 = sent_row_or_maint;
send_cmd1_row = sent_row_or_maint;
end
assign col_channel_offset = 0;
end
else begin // Place column commands on slot 1 for odd CWL
always @(sent_row_or_maint) begin
cs_en0 = sent_row_or_maint;
send_cmd0_row = sent_row_or_maint;
end
always @(sent_col_lcl) begin
cs_en1 = sent_col_lcl;
send_cmd1_col = sent_col_lcl;
end
assign col_channel_offset = 1;
end
always @(sent_pre_lcl) begin
cs_en2 = sent_pre_lcl;
send_cmd2_pre = sent_pre_lcl;
end
end
3'b101 : begin : four_one_2T
if(!(CWL % 2)) begin // Place column commands on slot 3->0 for even CWL
always @(sent_col_lcl or sent_col_lcl_r) begin
cs_en0 = sent_col_lcl_r;
send_cmd0_col = sent_col_lcl_r;
send_cmd3_col = sent_col_lcl;
end
always @(sent_row_or_maint) begin
cs_en2 = sent_row_or_maint;
send_cmd1_row = sent_row_or_maint;
send_cmd2_row = sent_row_or_maint;
end
assign col_channel_offset = 0;
end
else begin // Place column commands on slot 2->3 for odd CWL
always @(sent_row_or_maint) begin
cs_en1 = sent_row_or_maint;
send_cmd0_row = sent_row_or_maint;
send_cmd1_row = sent_row_or_maint;
end
always @(sent_col_lcl) begin
cs_en3 = sent_col_lcl;
send_cmd2_col = sent_col_lcl;
send_cmd3_col = sent_col_lcl;
end
assign col_channel_offset = 3;
end
end
endcase
endgenerate
endmodule
|
module altera_avalon_st_pipeline_base (
clk,
reset,
in_ready,
in_valid,
in_data,
out_ready,
out_valid,
out_data
);
parameter SYMBOLS_PER_BEAT = 1;
parameter BITS_PER_SYMBOL = 8;
parameter PIPELINE_READY = 1;
localparam DATA_WIDTH = SYMBOLS_PER_BEAT * BITS_PER_SYMBOL;
input clk;
input reset;
output in_ready;
input in_valid;
input [DATA_WIDTH-1:0] in_data;
input out_ready;
output out_valid;
output [DATA_WIDTH-1:0] out_data;
reg full0;
reg full1;
reg [DATA_WIDTH-1:0] data0;
reg [DATA_WIDTH-1:0] data1;
assign out_valid = full1;
assign out_data = data1;
generate if (PIPELINE_READY == 1)
begin : REGISTERED_READY_PLINE
assign in_ready = !full0;
always @(posedge clk, posedge reset) begin
if (reset) begin
data0 <= {DATA_WIDTH{1'b0}};
data1 <= {DATA_WIDTH{1'b0}};
end else begin
// ----------------------------
// always load the second slot if we can
// ----------------------------
if (~full0)
data0 <= in_data;
// ----------------------------
// first slot is loaded either from the second,
// or with new data
// ----------------------------
if (~full1 || (out_ready && out_valid)) begin
if (full0)
data1 <= data0;
else
data1 <= in_data;
end
end
end
always @(posedge clk or posedge reset) begin
if (reset) begin
full0 <= 1'b0;
full1 <= 1'b0;
end else begin
// no data in pipeline
if (~full0 & ~full1) begin
if (in_valid) begin
full1 <= 1'b1;
end
end // ~f1 & ~f0
// one datum in pipeline
if (full1 & ~full0) begin
if (in_valid & ~out_ready) begin
full0 <= 1'b1;
end
// back to empty
if (~in_valid & out_ready) begin
full1 <= 1'b0;
end
end // f1 & ~f0
// two data in pipeline
if (full1 & full0) begin
// go back to one datum state
if (out_ready) begin
full0 <= 1'b0;
end
end // end go back to one datum stage
end
end
end
else
begin : UNREGISTERED_READY_PLINE
// in_ready will be a pass through of the out_ready signal as it is not registered
assign in_ready = (~full1) | out_ready;
always @(posedge clk or posedge reset) begin
if (reset) begin
data1 <= 'b0;
full1 <= 1'b0;
end
else begin
if (in_ready) begin
data1 <= in_data;
full1 <= in_valid;
end
end
end
end
endgenerate
endmodule
|
module altera_avalon_st_pipeline_base (
clk,
reset,
in_ready,
in_valid,
in_data,
out_ready,
out_valid,
out_data
);
parameter SYMBOLS_PER_BEAT = 1;
parameter BITS_PER_SYMBOL = 8;
parameter PIPELINE_READY = 1;
localparam DATA_WIDTH = SYMBOLS_PER_BEAT * BITS_PER_SYMBOL;
input clk;
input reset;
output in_ready;
input in_valid;
input [DATA_WIDTH-1:0] in_data;
input out_ready;
output out_valid;
output [DATA_WIDTH-1:0] out_data;
reg full0;
reg full1;
reg [DATA_WIDTH-1:0] data0;
reg [DATA_WIDTH-1:0] data1;
assign out_valid = full1;
assign out_data = data1;
generate if (PIPELINE_READY == 1)
begin : REGISTERED_READY_PLINE
assign in_ready = !full0;
always @(posedge clk, posedge reset) begin
if (reset) begin
data0 <= {DATA_WIDTH{1'b0}};
data1 <= {DATA_WIDTH{1'b0}};
end else begin
// ----------------------------
// always load the second slot if we can
// ----------------------------
if (~full0)
data0 <= in_data;
// ----------------------------
// first slot is loaded either from the second,
// or with new data
// ----------------------------
if (~full1 || (out_ready && out_valid)) begin
if (full0)
data1 <= data0;
else
data1 <= in_data;
end
end
end
always @(posedge clk or posedge reset) begin
if (reset) begin
full0 <= 1'b0;
full1 <= 1'b0;
end else begin
// no data in pipeline
if (~full0 & ~full1) begin
if (in_valid) begin
full1 <= 1'b1;
end
end // ~f1 & ~f0
// one datum in pipeline
if (full1 & ~full0) begin
if (in_valid & ~out_ready) begin
full0 <= 1'b1;
end
// back to empty
if (~in_valid & out_ready) begin
full1 <= 1'b0;
end
end // f1 & ~f0
// two data in pipeline
if (full1 & full0) begin
// go back to one datum state
if (out_ready) begin
full0 <= 1'b0;
end
end // end go back to one datum stage
end
end
end
else
begin : UNREGISTERED_READY_PLINE
// in_ready will be a pass through of the out_ready signal as it is not registered
assign in_ready = (~full1) | out_ready;
always @(posedge clk or posedge reset) begin
if (reset) begin
data1 <= 'b0;
full1 <= 1'b0;
end
else begin
if (in_ready) begin
data1 <= in_data;
full1 <= in_valid;
end
end
end
end
endgenerate
endmodule
|
module outputs.
// Limit device_temp to 0C to 125C and assign it to flop input device_temp_100
// temp C = ( ( ADC CODE * 503.975 ) / 4096 ) - 273.15
wire device_temp_high = device_temp > TEMP_MAX_LIMIT;
wire device_temp_low = device_temp < TEMP_MIN_LIMIT;
wire [11:0] device_temp_100 = ( { 12 { device_temp_high } } & TEMP_MAX_LIMIT )
| ( { 12 { device_temp_low } } & TEMP_MIN_LIMIT )
| ( { 12 { ~device_temp_high & ~device_temp_low } } & device_temp );
// Capture/hold the initial temperature used in setting temperature bands and set init complete flag
// to enable normal sample operation.
wire [11:0] device_temp_init_nxt = tempmon_state_init ? device_temp_101 : device_temp_init;
wire tempmon_init_complete_nxt = tempmon_state_init ? 1'b1 : tempmon_init_complete;
// Capture/hold the current temperature on the sample enable signal rising edge after init is complete.
// The captured current temp is not used functionaly. It is just useful for debug and waveform review.
wire update_temp_101 = tempmon_init_complete & ~tempmon_sample_en_102 & tempmon_sample_en_101;
wire [11:0] device_temp_capture_101 = update_temp_101 ? device_temp_101 : device_temp_capture_102;
//===========================================================================
// Generate FSM arc signals
//===========================================================================
// Temperature comparisons for increasing temperature.
wire temp_cmp_four_inc_max_101 = device_temp_101 >= four_inc_max_limit ;
wire temp_cmp_three_inc_max_101 = device_temp_101 >= three_inc_max_limit ;
wire temp_cmp_two_inc_max_101 = device_temp_101 >= two_inc_max_limit ;
wire temp_cmp_one_inc_max_101 = device_temp_101 >= one_inc_max_limit ;
wire temp_cmp_neutral_max_101 = device_temp_101 >= neutral_max_limit ;
wire temp_cmp_one_dec_max_101 = device_temp_101 >= one_dec_max_limit ;
wire temp_cmp_two_dec_max_101 = device_temp_101 >= two_dec_max_limit ;
wire temp_cmp_three_dec_max_101 = device_temp_101 >= three_dec_max_limit ;
// Temperature comparisons for decreasing temperature.
wire temp_cmp_three_inc_min_101 = device_temp_101 < three_inc_min_limit ;
wire temp_cmp_two_inc_min_101 = device_temp_101 < two_inc_min_limit ;
wire temp_cmp_one_inc_min_101 = device_temp_101 < one_inc_min_limit ;
wire temp_cmp_neutral_min_101 = device_temp_101 < neutral_min_limit ;
wire temp_cmp_one_dec_min_101 = device_temp_101 < one_dec_min_limit ;
wire temp_cmp_two_dec_min_101 = device_temp_101 < two_dec_min_limit ;
wire temp_cmp_three_dec_min_101 = device_temp_101 < three_dec_min_limit ;
wire temp_cmp_four_dec_min_101 = device_temp_101 < four_dec_min_limit ;
// FSM arcs for increasing temperature.
wire temp_gte_four_inc_max = update_temp_102 & temp_cmp_four_inc_max_102;
wire temp_gte_three_inc_max = update_temp_102 & temp_cmp_three_inc_max_102;
wire temp_gte_two_inc_max = update_temp_102 & temp_cmp_two_inc_max_102;
wire temp_gte_one_inc_max = update_temp_102 & temp_cmp_one_inc_max_102;
wire temp_gte_neutral_max = update_temp_102 & temp_cmp_neutral_max_102;
wire temp_gte_one_dec_max = update_temp_102 & temp_cmp_one_dec_max_102;
wire temp_gte_two_dec_max = update_temp_102 & temp_cmp_two_dec_max_102;
wire temp_gte_three_dec_max = update_temp_102 & temp_cmp_three_dec_max_102;
// FSM arcs for decreasing temperature.
wire temp_lte_three_inc_min = update_temp_102 & temp_cmp_three_inc_min_102;
wire temp_lte_two_inc_min = update_temp_102 & temp_cmp_two_inc_min_102;
wire temp_lte_one_inc_min = update_temp_102 & temp_cmp_one_inc_min_102;
wire temp_lte_neutral_min = update_temp_102 & temp_cmp_neutral_min_102;
wire temp_lte_one_dec_min = update_temp_102 & temp_cmp_one_dec_min_102;
wire temp_lte_two_dec_min = update_temp_102 & temp_cmp_two_dec_min_102;
wire temp_lte_three_dec_min = update_temp_102 & temp_cmp_three_dec_min_102;
wire temp_lte_four_dec_min = update_temp_102 & temp_cmp_four_dec_min_102;
//===========================================================================
// Implement FSM
//===========================================================================
// In addition to the nine temperature states, there are also IDLE and INIT states.
// The INIT state triggers the calculation of the temperature boundaries between the
// other states. After INIT, the FSM will always go to the NEUTRAL state. There is
// no timing restriction required between calib_complete and tempmon_sample_en.
always @(*) begin
tempmon_state_nxt = tempmon_state;
tempmon_state_init = 1'b0;
pi_f_inc_nxt = 1'b0;
pi_f_dec_nxt = 1'b0;
casez (tempmon_state)
IDLE: begin
if (calib_complete) tempmon_state_nxt = INIT;
end
INIT: begin
tempmon_state_nxt = NEUTRAL;
tempmon_state_init = 1'b1;
end
FOUR_INC: begin
if (temp_gte_four_inc_max) begin
tempmon_state_nxt = THREE_INC;
pi_f_dec_nxt = 1'b1;
end
end
THREE_INC: begin
if (temp_gte_three_inc_max) begin
tempmon_state_nxt = TWO_INC;
pi_f_dec_nxt = 1'b1;
end
else if (temp_lte_three_inc_min) begin
tempmon_state_nxt = FOUR_INC;
pi_f_inc_nxt = 1'b1;
end
end
TWO_INC: begin
if (temp_gte_two_inc_max) begin
tempmon_state_nxt = ONE_INC;
pi_f_dec_nxt = 1'b1;
end
else if (temp_lte_two_inc_min) begin
tempmon_state_nxt = THREE_INC;
pi_f_inc_nxt = 1'b1;
end
end
ONE_INC: begin
if (temp_gte_one_inc_max) begin
tempmon_state_nxt = NEUTRAL;
pi_f_dec_nxt = 1'b1;
end
else if (temp_lte_one_inc_min) begin
tempmon_state_nxt = TWO_INC;
pi_f_inc_nxt = 1'b1;
end
end
NEUTRAL: begin
if (temp_gte_neutral_max) begin
tempmon_state_nxt = ONE_DEC;
pi_f_dec_nxt = 1'b1;
end
else if (temp_lte_neutral_min) begin
tempmon_state_nxt = ONE_INC;
pi_f_inc_nxt = 1'b1;
end
end
ONE_DEC: begin
if (temp_gte_one_dec_max) begin
tempmon_state_nxt = TWO_DEC;
pi_f_dec_nxt = 1'b1;
end
else if (temp_lte_one_dec_min) begin
tempmon_state_nxt = NEUTRAL;
pi_f_inc_nxt = 1'b1;
end
end
TWO_DEC: begin
if (temp_gte_two_dec_max) begin
tempmon_state_nxt = THREE_DEC;
pi_f_dec_nxt = 1'b1;
end
else if (temp_lte_two_dec_min) begin
tempmon_state_nxt = ONE_DEC;
pi_f_inc_nxt = 1'b1;
end
end
THREE_DEC: begin
if (temp_gte_three_dec_max) begin
tempmon_state_nxt = FOUR_DEC;
pi_f_dec_nxt = 1'b1;
end
else if (temp_lte_three_dec_min) begin
tempmon_state_nxt = TWO_DEC;
pi_f_inc_nxt = 1'b1;
end
end
FOUR_DEC: begin
if (temp_lte_four_dec_min) begin
tempmon_state_nxt = THREE_DEC;
pi_f_inc_nxt = 1'b1;
end
end
default: begin
tempmon_state_nxt = IDLE;
end
endcase
end //always
//synopsys translate_off
reg [71:0] tempmon_state_name;
always @(*) casez (tempmon_state)
IDLE : tempmon_state_name = "IDLE";
INIT : tempmon_state_name = "INIT";
FOUR_INC : tempmon_state_name = "FOUR_INC";
THREE_INC : tempmon_state_name = "THREE_INC";
TWO_INC : tempmon_state_name = "TWO_INC";
ONE_INC : tempmon_state_name = "ONE_INC";
NEUTRAL : tempmon_state_name = "NEUTRAL";
ONE_DEC : tempmon_state_name = "ONE_DEC";
TWO_DEC : tempmon_state_name = "TWO_DEC";
THREE_DEC : tempmon_state_name = "THREE_DEC";
FOUR_DEC : tempmon_state_name = "FOUR_DEC";
default : tempmon_state_name = "BAD_STATE";
endcase
//synopsys translate_on
//===========================================================================
// Generate final output and implement flops
//===========================================================================
// Generate output
assign tempmon_pi_f_inc = pi_f_inc;
assign tempmon_pi_f_dec = pi_f_dec;
assign tempmon_sel_pi_incdec = pi_f_inc | pi_f_dec;
// Implement reset flops
always @(posedge clk) begin
if(rst) begin
tempmon_state <= #TCQ 11'b000_0000_0001;
pi_f_inc <= #TCQ 1'b0;
pi_f_dec <= #TCQ 1'b0;
four_inc_max_limit <= #TCQ 12'b0;
three_inc_max_limit <= #TCQ 12'b0;
two_inc_max_limit <= #TCQ 12'b0;
one_inc_max_limit <= #TCQ 12'b0;
neutral_max_limit <= #TCQ 12'b0;
one_dec_max_limit <= #TCQ 12'b0;
two_dec_max_limit <= #TCQ 12'b0;
three_dec_max_limit <= #TCQ 12'b0;
three_inc_min_limit <= #TCQ 12'b0;
two_inc_min_limit <= #TCQ 12'b0;
one_inc_min_limit <= #TCQ 12'b0;
neutral_min_limit <= #TCQ 12'b0;
one_dec_min_limit <= #TCQ 12'b0;
two_dec_min_limit <= #TCQ 12'b0;
three_dec_min_limit <= #TCQ 12'b0;
four_dec_min_limit <= #TCQ 12'b0;
device_temp_init <= #TCQ 12'b0;
tempmon_init_complete <= #TCQ 1'b0;
tempmon_sample_en_101 <= #TCQ 1'b0;
tempmon_sample_en_102 <= #TCQ 1'b0;
device_temp_101 <= #TCQ 12'b0;
device_temp_capture_102 <= #TCQ 12'b0;
end
else begin
tempmon_state <= #TCQ tempmon_state_nxt;
pi_f_inc <= #TCQ pi_f_inc_nxt;
pi_f_dec <= #TCQ pi_f_dec_nxt;
four_inc_max_limit <= #TCQ four_inc_max_limit_nxt;
three_inc_max_limit <= #TCQ three_inc_max_limit_nxt;
two_inc_max_limit <= #TCQ two_inc_max_limit_nxt;
one_inc_max_limit <= #TCQ one_inc_max_limit_nxt;
neutral_max_limit <= #TCQ neutral_max_limit_nxt;
one_dec_max_limit <= #TCQ one_dec_max_limit_nxt;
two_dec_max_limit <= #TCQ two_dec_max_limit_nxt;
three_dec_max_limit <= #TCQ three_dec_max_limit_nxt;
three_inc_min_limit <= #TCQ three_inc_min_limit_nxt;
two_inc_min_limit <= #TCQ two_inc_min_limit_nxt;
one_inc_min_limit <= #TCQ one_inc_min_limit_nxt;
neutral_min_limit <= #TCQ neutral_min_limit_nxt;
one_dec_min_limit <= #TCQ one_dec_min_limit_nxt;
two_dec_min_limit <= #TCQ two_dec_min_limit_nxt;
three_dec_min_limit <= #TCQ three_dec_min_limit_nxt;
four_dec_min_limit <= #TCQ four_dec_min_limit_nxt;
device_temp_init <= #TCQ device_temp_init_nxt;
tempmon_init_complete <= #TCQ tempmon_init_complete_nxt;
tempmon_sample_en_101 <= #TCQ tempmon_sample_en;
tempmon_sample_en_102 <= #TCQ tempmon_sample_en_101;
device_temp_101 <= #TCQ device_temp_100;
device_temp_capture_102 <= #TCQ device_temp_capture_101;
end
end
// Implement non-reset flops
always @(posedge clk) begin
temp_cmp_four_inc_max_102 <= #TCQ temp_cmp_four_inc_max_101;
temp_cmp_three_inc_max_102 <= #TCQ temp_cmp_three_inc_max_101;
temp_cmp_two_inc_max_102 <= #TCQ temp_cmp_two_inc_max_101;
temp_cmp_one_inc_max_102 <= #TCQ temp_cmp_one_inc_max_101;
temp_cmp_neutral_max_102 <= #TCQ temp_cmp_neutral_max_101;
temp_cmp_one_dec_max_102 <= #TCQ temp_cmp_one_dec_max_101;
temp_cmp_two_dec_max_102 <= #TCQ temp_cmp_two_dec_max_101;
temp_cmp_three_dec_max_102 <= #TCQ temp_cmp_three_dec_max_101;
temp_cmp_three_inc_min_102 <= #TCQ temp_cmp_three_inc_min_101;
temp_cmp_two_inc_min_102 <= #TCQ temp_cmp_two_inc_min_101;
temp_cmp_one_inc_min_102 <= #TCQ temp_cmp_one_inc_min_101;
temp_cmp_neutral_min_102 <= #TCQ temp_cmp_neutral_min_101;
temp_cmp_one_dec_min_102 <= #TCQ temp_cmp_one_dec_min_101;
temp_cmp_two_dec_min_102 <= #TCQ temp_cmp_two_dec_min_101;
temp_cmp_three_dec_min_102 <= #TCQ temp_cmp_three_dec_min_101;
temp_cmp_four_dec_min_102 <= #TCQ temp_cmp_four_dec_min_101;
update_temp_102 <= #TCQ update_temp_101;
end
endmodule
|
module mig_7series_v2_3_infrastructure #
(
parameter SIMULATION = "FALSE", // Should be TRUE during design simulations and
// FALSE during implementations
parameter TCQ = 100, // clk->out delay (sim only)
parameter CLKIN_PERIOD = 3000, // Memory clock period
parameter nCK_PER_CLK = 2, // Fabric clk period:Memory clk period
parameter SYSCLK_TYPE = "DIFFERENTIAL",
// input clock type
// "DIFFERENTIAL","SINGLE_ENDED"
parameter UI_EXTRA_CLOCKS = "FALSE",
// Generates extra clocks as
// 1/2, 1/4 and 1/8 of fabrick clock.
// Valid for DDR2/DDR3 AXI interfaces
// based on GUI selection
parameter CLKFBOUT_MULT = 4, // write PLL VCO multiplier
parameter DIVCLK_DIVIDE = 1, // write PLL VCO divisor
parameter CLKOUT0_PHASE = 45.0, // VCO output divisor for clkout0
parameter CLKOUT0_DIVIDE = 16, // VCO output divisor for PLL clkout0
parameter CLKOUT1_DIVIDE = 4, // VCO output divisor for PLL clkout1
parameter CLKOUT2_DIVIDE = 64, // VCO output divisor for PLL clkout2
parameter CLKOUT3_DIVIDE = 16, // VCO output divisor for PLL clkout3
parameter MMCM_VCO = 1200, // Max Freq (MHz) of MMCM VCO
parameter MMCM_MULT_F = 4, // write MMCM VCO multiplier
parameter MMCM_DIVCLK_DIVIDE = 1, // write MMCM VCO divisor
parameter MMCM_CLKOUT0_EN = "FALSE", // Enabled (or) Disable MMCM clkout0
parameter MMCM_CLKOUT1_EN = "FALSE", // Enabled (or) Disable MMCM clkout1
parameter MMCM_CLKOUT2_EN = "FALSE", // Enabled (or) Disable MMCM clkout2
parameter MMCM_CLKOUT3_EN = "FALSE", // Enabled (or) Disable MMCM clkout3
parameter MMCM_CLKOUT4_EN = "FALSE", // Enabled (or) Disable MMCM clkout4
parameter MMCM_CLKOUT0_DIVIDE = 1, // VCO output divisor for MMCM clkout0
parameter MMCM_CLKOUT1_DIVIDE = 1, // VCO output divisor for MMCM clkout1
parameter MMCM_CLKOUT2_DIVIDE = 1, // VCO output divisor for MMCM clkout2
parameter MMCM_CLKOUT3_DIVIDE = 1, // VCO output divisor for MMCM clkout3
parameter MMCM_CLKOUT4_DIVIDE = 1, // VCO output divisor for MMCM clkout4
parameter RST_ACT_LOW = 1,
parameter tCK = 1250,
// memory tCK paramter.
// # = Clock Period in pS.
parameter MEM_TYPE = "DDR3"
)
(
// Clock inputs
input mmcm_clk, // System clock diff input
// System reset input
input sys_rst, // core reset from user application
// PLLE2/IDELAYCTRL Lock status
input [1:0] iodelay_ctrl_rdy, // IDELAYCTRL lock status
// Clock outputs
output clk, // fabric clock freq ; either half rate or quarter rate and is
// determined by PLL parameters settings.
output mem_refclk, // equal to memory clock
output freq_refclk, // freq above 400 MHz: set freq_refclk = mem_refclk
// freq below 400 MHz: set freq_refclk = 2* mem_refclk or 4* mem_refclk;
// to hard PHY for phaser
output sync_pulse, // exactly 1/16 of mem_refclk and the sync pulse is exactly 1 memref_clk wide
output auxout_clk, // IO clk used to clock out Aux_Out ports
output mmcm_ps_clk, // Phase shift clock
output poc_sample_pd, // Tell POC when to sample phase detector output.
output ui_addn_clk_0, // MMCM out0 clk
output ui_addn_clk_1, // MMCM out1 clk
output ui_addn_clk_2, // MMCM out2 clk
output ui_addn_clk_3, // MMCM out3 clk
output ui_addn_clk_4, // MMCM out4 clk
output pll_locked, // locked output from PLLE2_ADV
output mmcm_locked, // locked output from MMCME2_ADV
// Reset outputs
output rstdiv0, // Reset CLK and CLKDIV logic (incl I/O),
output iddr_rst
,output rst_phaser_ref
,input ref_dll_lock
,input psen
,input psincdec
,output psdone
);
// # of clock cycles to delay deassertion of reset. Needs to be a fairly
// high number not so much for metastability protection, but to give time
// for reset (i.e. stable clock cycles) to propagate through all state
// machines and to all control signals (i.e. not all control signals have
// resets, instead they rely on base state logic being reset, and the effect
// of that reset propagating through the logic). Need this because we may not
// be getting stable clock cycles while reset asserted (i.e. since reset
// depends on DCM lock status)
localparam RST_SYNC_NUM = 25;
// Round up for clk reset delay to ensure that CLKDIV reset deassertion
// occurs at same time or after CLK reset deassertion (still need to
// consider route delay - add one or two extra cycles to be sure!)
localparam RST_DIV_SYNC_NUM = (RST_SYNC_NUM+1)/2;
// Input clock is assumed to be equal to the memory clock frequency
// User should change the parameter as necessary if a different input
// clock frequency is used
localparam real CLKIN1_PERIOD_NS = CLKIN_PERIOD / 1000.0;
localparam CLKOUT4_DIVIDE = 2 * CLKOUT1_DIVIDE;
localparam integer VCO_PERIOD
= (CLKIN1_PERIOD_NS * DIVCLK_DIVIDE * 1000) / CLKFBOUT_MULT;
localparam CLKOUT0_PERIOD = VCO_PERIOD * CLKOUT0_DIVIDE;
localparam CLKOUT1_PERIOD = VCO_PERIOD * CLKOUT1_DIVIDE;
localparam CLKOUT2_PERIOD = VCO_PERIOD * CLKOUT2_DIVIDE;
localparam CLKOUT3_PERIOD = VCO_PERIOD * CLKOUT3_DIVIDE;
localparam CLKOUT4_PERIOD = VCO_PERIOD * CLKOUT4_DIVIDE;
localparam CLKOUT4_PHASE = (SIMULATION == "TRUE") ? 22.5 : 168.75;
localparam real CLKOUT3_PERIOD_NS = CLKOUT3_PERIOD / 1000.0;
localparam real CLKOUT4_PERIOD_NS = CLKOUT4_PERIOD / 1000.0;
//synthesis translate_off
initial begin
$display("############# Write Clocks PLLE2_ADV Parameters #############\n");
$display("nCK_PER_CLK = %7d", nCK_PER_CLK );
$display("CLK_PERIOD = %7d", CLKIN_PERIOD );
$display("CLKIN1_PERIOD = %7.3f", CLKIN1_PERIOD_NS);
$display("DIVCLK_DIVIDE = %7d", DIVCLK_DIVIDE );
$display("CLKFBOUT_MULT = %7d", CLKFBOUT_MULT );
$display("VCO_PERIOD = %7.1f", VCO_PERIOD );
$display("CLKOUT0_DIVIDE_F = %7d", CLKOUT0_DIVIDE );
$display("CLKOUT1_DIVIDE = %7d", CLKOUT1_DIVIDE );
$display("CLKOUT2_DIVIDE = %7d", CLKOUT2_DIVIDE );
$display("CLKOUT3_DIVIDE = %7d", CLKOUT3_DIVIDE );
$display("CLKOUT0_PERIOD = %7d", CLKOUT0_PERIOD );
$display("CLKOUT1_PERIOD = %7d", CLKOUT1_PERIOD );
$display("CLKOUT2_PERIOD = %7d", CLKOUT2_PERIOD );
$display("CLKOUT3_PERIOD = %7d", CLKOUT3_PERIOD );
$display("CLKOUT4_PERIOD = %7d", CLKOUT4_PERIOD );
$display("############################################################\n");
end
//synthesis translate_on
wire clk_bufg;
wire clk_pll;
wire clkfbout_pll;
wire mmcm_clkfbout;
wire pll_locked_i
/* synthesis syn_maxfan = 10 */;
(* max_fanout = 50 *) reg [RST_DIV_SYNC_NUM-2:0] rstdiv0_sync_r;
wire rst_tmp;
(* max_fanout = 50 *) reg rstdiv0_sync_r1
/* synthesis syn_maxfan = 50 */;
reg [RST_DIV_SYNC_NUM-2:0] rst_sync_r;
(* max_fanout = 10 *) reg rst_sync_r1
/* synthesis syn_maxfan = 10 */;
wire sys_rst_act_hi;
wire rst_tmp_phaser_ref;
(* max_fanout = 50 *) reg [RST_DIV_SYNC_NUM-1:0] rst_phaser_ref_sync_r
/* synthesis syn_maxfan = 10 */;
// Instantiation of the MMCM primitive
wire clkfbout;
wire MMCM_Locked_i;
wire mmcm_clkout0;
wire mmcm_clkout1;
wire mmcm_clkout2;
wire mmcm_clkout3;
wire mmcm_clkout4;
wire mmcm_ps_clk_bufg_in;
wire pll_clk3_out;
wire pll_clk3;
assign sys_rst_act_hi = RST_ACT_LOW ? ~sys_rst: sys_rst;
//***************************************************************************
// Assign global clocks:
// 2. clk : Half rate / Quarter rate(used for majority of internal logic)
//***************************************************************************
assign clk = clk_bufg;
assign pll_locked = pll_locked_i & MMCM_Locked_i;
assign mmcm_locked = MMCM_Locked_i;
//***************************************************************************
// Global base clock generation and distribution
//***************************************************************************
//*****************************************************************
// NOTES ON CALCULTING PROPER VCO FREQUENCY
// 1. VCO frequency =
// 1/((DIVCLK_DIVIDE * CLKIN_PERIOD)/(CLKFBOUT_MULT * nCK_PER_CLK))
// 2. VCO frequency must be in the range [TBD, TBD]
//*****************************************************************
PLLE2_ADV #
(
.BANDWIDTH ("OPTIMIZED"),
.COMPENSATION ("INTERNAL"),
.STARTUP_WAIT ("FALSE"),
.CLKOUT0_DIVIDE (CLKOUT0_DIVIDE), // 4 freq_ref
.CLKOUT1_DIVIDE (CLKOUT1_DIVIDE), // 4 mem_ref
.CLKOUT2_DIVIDE (CLKOUT2_DIVIDE), // 16 sync
.CLKOUT3_DIVIDE (CLKOUT3_DIVIDE), // 16 sysclk
.CLKOUT4_DIVIDE (CLKOUT4_DIVIDE),
.CLKOUT5_DIVIDE (),
.DIVCLK_DIVIDE (DIVCLK_DIVIDE),
.CLKFBOUT_MULT (CLKFBOUT_MULT),
.CLKFBOUT_PHASE (0.000),
.CLKIN1_PERIOD (CLKIN1_PERIOD_NS),
.CLKIN2_PERIOD (),
.CLKOUT0_DUTY_CYCLE (0.500),
.CLKOUT0_PHASE (CLKOUT0_PHASE),
.CLKOUT1_DUTY_CYCLE (0.500),
.CLKOUT1_PHASE (0.000),
.CLKOUT2_DUTY_CYCLE (1.0/16.0),
.CLKOUT2_PHASE (9.84375), // PHASE shift is required for sync pulse generation.
.CLKOUT3_DUTY_CYCLE (0.500),
.CLKOUT3_PHASE (0.000),
.CLKOUT4_DUTY_CYCLE (0.500),
.CLKOUT4_PHASE (CLKOUT4_PHASE),
.CLKOUT5_DUTY_CYCLE (0.500),
.CLKOUT5_PHASE (0.000),
.REF_JITTER1 (0.010),
.REF_JITTER2 (0.010)
)
plle2_i
(
.CLKFBOUT (pll_clkfbout),
.CLKOUT0 (freq_refclk),
.CLKOUT1 (mem_refclk),
.CLKOUT2 (sync_pulse), // always 1/16 of mem_ref_clk
.CLKOUT3 (pll_clk3_out),
.CLKOUT4 (auxout_clk_i),
.CLKOUT5 (),
.DO (),
.DRDY (),
.LOCKED (pll_locked_i),
.CLKFBIN (pll_clkfbout),
.CLKIN1 (mmcm_clk),
.CLKIN2 (),
.CLKINSEL (1'b1),
.DADDR (7'b0),
.DCLK (1'b0),
.DEN (1'b0),
.DI (16'b0),
.DWE (1'b0),
.PWRDWN (1'b0),
.RST ( sys_rst_act_hi)
);
BUFH u_bufh_auxout_clk
(
.O (auxout_clk),
.I (auxout_clk_i)
);
BUFG u_bufg_clkdiv0
(
.O (clk_bufg),
.I (clk_pll_i)
);
BUFH u_bufh_pll_clk3
(
.O (pll_clk3),
.I (pll_clk3_out)
);
localparam real MMCM_VCO_PERIOD = 1000000.0/MMCM_VCO;
//synthesis translate_off
initial begin
$display("############# MMCME2_ADV Parameters #############\n");
$display("MMCM_MULT_F = %d", MMCM_MULT_F);
$display("MMCM_VCO_FREQ (MHz) = %7.3f", MMCM_VCO*1000.0);
$display("MMCM_VCO_PERIOD = %7.3f", MMCM_VCO_PERIOD);
$display("#################################################\n");
end
//synthesis translate_on
generate
if (UI_EXTRA_CLOCKS == "TRUE") begin: gen_ui_extra_clocks
localparam MMCM_CLKOUT0_DIVIDE_CAL = (MMCM_CLKOUT0_EN == "TRUE") ? MMCM_CLKOUT0_DIVIDE : MMCM_MULT_F;
localparam MMCM_CLKOUT1_DIVIDE_CAL = (MMCM_CLKOUT1_EN == "TRUE") ? MMCM_CLKOUT1_DIVIDE : MMCM_MULT_F;
localparam MMCM_CLKOUT2_DIVIDE_CAL = (MMCM_CLKOUT2_EN == "TRUE") ? MMCM_CLKOUT2_DIVIDE : MMCM_MULT_F;
localparam MMCM_CLKOUT3_DIVIDE_CAL = (MMCM_CLKOUT3_EN == "TRUE") ? MMCM_CLKOUT3_DIVIDE : MMCM_MULT_F;
localparam MMCM_CLKOUT4_DIVIDE_CAL = (MMCM_CLKOUT4_EN == "TRUE") ? MMCM_CLKOUT4_DIVIDE : MMCM_MULT_F;
MMCME2_ADV
#(.BANDWIDTH ("HIGH"),
.CLKOUT4_CASCADE ("FALSE"),
.COMPENSATION ("BUF_IN"),
.STARTUP_WAIT ("FALSE"),
// .DIVCLK_DIVIDE (1),
.DIVCLK_DIVIDE (MMCM_DIVCLK_DIVIDE),
.CLKFBOUT_MULT_F (MMCM_MULT_F),
.CLKFBOUT_PHASE (0.000),
.CLKFBOUT_USE_FINE_PS ("FALSE"),
.CLKOUT0_DIVIDE_F (MMCM_CLKOUT0_DIVIDE_CAL),
.CLKOUT0_PHASE (0.000),
.CLKOUT0_DUTY_CYCLE (0.500),
.CLKOUT0_USE_FINE_PS ("FALSE"),
.CLKOUT1_DIVIDE (MMCM_CLKOUT1_DIVIDE_CAL),
.CLKOUT1_PHASE (0.000),
.CLKOUT1_DUTY_CYCLE (0.500),
.CLKOUT1_USE_FINE_PS ("FALSE"),
.CLKOUT2_DIVIDE (MMCM_CLKOUT2_DIVIDE_CAL),
.CLKOUT2_PHASE (0.000),
.CLKOUT2_DUTY_CYCLE (0.500),
.CLKOUT2_USE_FINE_PS ("FALSE"),
.CLKOUT3_DIVIDE (MMCM_CLKOUT3_DIVIDE_CAL),
.CLKOUT3_PHASE (0.000),
.CLKOUT3_DUTY_CYCLE (0.500),
.CLKOUT3_USE_FINE_PS ("FALSE"),
.CLKOUT4_DIVIDE (MMCM_CLKOUT4_DIVIDE_CAL),
.CLKOUT4_PHASE (0.000),
.CLKOUT4_DUTY_CYCLE (0.500),
.CLKOUT4_USE_FINE_PS ("FALSE"),
.CLKOUT5_DIVIDE (((MMCM_MULT_F*2)/MMCM_DIVCLK_DIVIDE)),
.CLKOUT5_PHASE (0.000),
.CLKOUT5_DUTY_CYCLE (0.500),
.CLKOUT5_USE_FINE_PS ("TRUE"),
.CLKIN1_PERIOD (CLKOUT3_PERIOD_NS),
.REF_JITTER1 (0.000))
mmcm_i
// Output clocks
(.CLKFBOUT (clk_pll_i),
.CLKFBOUTB (),
.CLKOUT0 (mmcm_clkout0),
.CLKOUT0B (),
.CLKOUT1 (mmcm_clkout1),
.CLKOUT1B (),
.CLKOUT2 (mmcm_clkout2),
.CLKOUT2B (),
.CLKOUT3 (mmcm_clkout3),
.CLKOUT3B (),
.CLKOUT4 (mmcm_clkout4),
.CLKOUT5 (mmcm_ps_clk_bufg_in),
.CLKOUT6 (),
// Input clock control
.CLKFBIN (clk_bufg), // From BUFH network
.CLKIN1 (pll_clk3), // From PLL
.CLKIN2 (1'b0),
// Tied to always select the primary input clock
.CLKINSEL (1'b1),
// Ports for dynamic reconfiguration
.DADDR (7'h0),
.DCLK (1'b0),
.DEN (1'b0),
.DI (16'h0),
.DO (),
.DRDY (),
.DWE (1'b0),
// Ports for dynamic phase shift
.PSCLK (clk),
.PSEN (psen),
.PSINCDEC (psincdec),
.PSDONE (psdone),
// Other control and status signals
.LOCKED (MMCM_Locked_i),
.CLKINSTOPPED (),
.CLKFBSTOPPED (),
.PWRDWN (1'b0),
.RST (~pll_locked_i));
BUFG u_bufg_ui_addn_clk_0
(
.O (ui_addn_clk_0),
.I (mmcm_clkout0)
);
BUFG u_bufg_ui_addn_clk_1
(
.O (ui_addn_clk_1),
.I (mmcm_clkout1)
);
BUFG u_bufg_ui_addn_clk_2
(
.O (ui_addn_clk_2),
.I (mmcm_clkout2)
);
BUFG u_bufg_ui_addn_clk_3
(
.O (ui_addn_clk_3),
.I (mmcm_clkout3)
);
BUFG u_bufg_ui_addn_clk_4
(
.O (ui_addn_clk_4),
.I (mmcm_clkout4)
);
BUFG u_bufg_mmcm_ps_clk
(
.O (mmcm_ps_clk),
.I (mmcm_ps_clk_bufg_in)
);
end else begin: gen_mmcm
MMCME2_ADV
#(.BANDWIDTH ("HIGH"),
.CLKOUT4_CASCADE ("FALSE"),
.COMPENSATION ("BUF_IN"),
.STARTUP_WAIT ("FALSE"),
// .DIVCLK_DIVIDE (1),
.DIVCLK_DIVIDE (MMCM_DIVCLK_DIVIDE),
.CLKFBOUT_MULT_F (MMCM_MULT_F),
.CLKFBOUT_PHASE (0.000),
.CLKFBOUT_USE_FINE_PS ("FALSE"),
.CLKOUT0_DIVIDE_F (((MMCM_MULT_F*2)/MMCM_DIVCLK_DIVIDE)),
.CLKOUT0_PHASE (0.000),
.CLKOUT0_DUTY_CYCLE (0.500),
.CLKOUT0_USE_FINE_PS ("TRUE"),
.CLKOUT1_DIVIDE (),
.CLKOUT1_PHASE (0.000),
.CLKOUT1_DUTY_CYCLE (0.500),
.CLKOUT1_USE_FINE_PS ("FALSE"),
.CLKIN1_PERIOD (CLKOUT3_PERIOD_NS),
.REF_JITTER1 (0.000))
mmcm_i
// Output clocks
(.CLKFBOUT (clk_pll_i),
.CLKFBOUTB (),
.CLKOUT0 (mmcm_ps_clk_bufg_in),
.CLKOUT0B (),
.CLKOUT1 (),
.CLKOUT1B (),
.CLKOUT2 (),
.CLKOUT2B (),
.CLKOUT3 (),
.CLKOUT3B (),
.CLKOUT4 (),
.CLKOUT5 (),
.CLKOUT6 (),
// Input clock control
.CLKFBIN (clk_bufg), // From BUFH network
.CLKIN1 (pll_clk3), // From PLL
.CLKIN2 (1'b0),
// Tied to always select the primary input clock
.CLKINSEL (1'b1),
// Ports for dynamic reconfiguration
.DADDR (7'h0),
.DCLK (1'b0),
.DEN (1'b0),
.DI (16'h0),
.DO (),
.DRDY (),
.DWE (1'b0),
// Ports for dynamic phase shift
.PSCLK (clk),
.PSEN (psen),
.PSINCDEC (psincdec),
.PSDONE (psdone),
// Other control and status signals
.LOCKED (MMCM_Locked_i),
.CLKINSTOPPED (),
.CLKFBSTOPPED (),
.PWRDWN (1'b0),
.RST (~pll_locked_i));
BUFG u_bufg_mmcm_ps_clk
(
.O (mmcm_ps_clk),
.I (mmcm_ps_clk_bufg_in)
);
end // block: gen_mmcm
endgenerate
//***************************************************************************
// Generate poc_sample_pd.
//
// As the phase shift clocks precesses around kclk, it also precesses
// around the fabric clock. Noise may be generated as output of the
// IDDR is registered into the fabric clock domain.
//
// The mmcm_ps_clk signal runs at half the rate of the fabric clock.
// This means that there are two rising edges of fabric clock per mmcm_ps_clk.
// If we can guarantee that the POC uses the data sampled on the second
// fabric clock, then we are certain that the setup time to the second
// fabric clock is greater than 1 fabric clock cycle.
//
// To predict when the phase detctor output is from this second edge, we
// need to know two things. The initial phase of fabric clock and mmcm_ps_clk
// and the number of phase offsets set into the mmcm. The later is a
// trivial count of the PSEN signal.
//
// The former is a bit tricky because latching a clock with a clock is
// not well defined. This problem is solved by generating a signal
// the goes high on the first rising edge of mmcm_ps_clk. Logic in
// the fabric domain can look at this signal and then develop an analog
// the mmcm_ps_clk with zero offset.
//
// This all depends on the timing tools making the timing work when
// when the mmcm phase offset is zero.
//
// poc_sample_pd tells the POC when to sample the phase detector output.
// Setup from the IDDR to the fabric clock is always one plus some
// fraction of the fabric clock.
//***************************************************************************
localparam ONE = 1;
localparam integer TAPSPERFCLK = 56 * MMCM_MULT_F;
localparam TAPSPERFCLK_MINUS_ONE = TAPSPERFCLK - 1;
localparam QCNTR_WIDTH = clogb2(TAPSPERFCLK);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
reg [QCNTR_WIDTH-1:0] qcntr_ns, qcntr_r;
always @(posedge clk) qcntr_r <= #TCQ qcntr_ns;
reg inv_poc_sample_ns, inv_poc_sample_r;
always @(posedge clk) inv_poc_sample_r <= #TCQ inv_poc_sample_ns;
always @(*) begin
qcntr_ns = qcntr_r;
inv_poc_sample_ns = inv_poc_sample_r;
if (rstdiv0) begin
qcntr_ns = TAPSPERFCLK_MINUS_ONE[QCNTR_WIDTH-1:0];
inv_poc_sample_ns = 1'b1;
end else if (psen) begin
if (qcntr_r < TAPSPERFCLK_MINUS_ONE[QCNTR_WIDTH-1:0])
qcntr_ns = (qcntr_r + ONE[QCNTR_WIDTH-1:0]);
else begin
qcntr_ns = {QCNTR_WIDTH{1'b0}};
inv_poc_sample_ns = ~inv_poc_sample_r;
end
end
end
// Be vewy vewy careful to make sure this path is aligned with the
// phase detector out pipeline.
reg first_rising_ps_clk_ns, first_rising_ps_clk_r;
always @(posedge mmcm_ps_clk) first_rising_ps_clk_r <= #TCQ first_rising_ps_clk_ns;
always @(*) first_rising_ps_clk_ns = ~rstdiv0;
reg mmcm_hi0_ns, mmcm_hi0_r;
always @(posedge clk) mmcm_hi0_r <= #TCQ mmcm_hi0_ns;
always @(*) mmcm_hi0_ns = ~first_rising_ps_clk_r || ~mmcm_hi0_r;
reg poc_sample_pd_ns, poc_sample_pd_r;
always @(*) poc_sample_pd_ns = inv_poc_sample_ns ^ mmcm_hi0_r;
always @(posedge clk) poc_sample_pd_r <= #TCQ poc_sample_pd_ns;
assign poc_sample_pd = poc_sample_pd_r;
//***************************************************************************
// Make sure logic acheives 90 degree setup time from rising mmcm_ps_clk
// to the appropriate edge of fabric clock
//***************************************************************************
//synthesis translate_off
generate
if ( tCK <= 2500 ) begin : check_ocal_timing
localparam CLK_PERIOD_PS = MMCM_VCO_PERIOD * MMCM_MULT_F;
localparam integer CLK_PERIOD_PS_DIV4 = CLK_PERIOD_PS/4;
time rising_mmcm_ps_clk;
always @(posedge mmcm_ps_clk) rising_mmcm_ps_clk = $time();
time pdiff; // Not used, except in waveform plots.
always @(posedge clk) pdiff = $time() - rising_mmcm_ps_clk;
end
endgenerate
//synthesis translate_on
//***************************************************************************
// RESET SYNCHRONIZATION DESCRIPTION:
// Various resets are generated to ensure that:
// 1. All resets are synchronously deasserted with respect to the clock
// domain they are interfacing to. There are several different clock
// domains - each one will receive a synchronized reset.
// 2. The reset deassertion order starts with deassertion of SYS_RST,
// followed by deassertion of resets for various parts of the design
// (see "RESET ORDER" below) based on the lock status of PLLE2s.
// RESET ORDER:
// 1. User deasserts SYS_RST
// 2. Reset PLLE2 and IDELAYCTRL
// 3. Wait for PLLE2 and IDELAYCTRL to lock
// 4. Release reset for all I/O primitives and internal logic
// OTHER NOTES:
// 1. Asynchronously assert reset. This way we can assert reset even if
// there is no clock (needed for things like 3-stating output buffers
// to prevent initial bus contention). Reset deassertion is synchronous.
//***************************************************************************
//*****************************************************************
// CLKDIV logic reset
//*****************************************************************
// Wait for PLLE2 and IDELAYCTRL to lock before releasing reset
// current O,25.0 unisim phaser_ref never locks. Need to find out why .
generate
if (MEM_TYPE == "DDR3" && tCK <= 1500) begin: rst_tmp_300_400
assign rst_tmp = sys_rst_act_hi | ~iodelay_ctrl_rdy[1] |
~ref_dll_lock | ~MMCM_Locked_i;
end else begin: rst_tmp_200
assign rst_tmp = sys_rst_act_hi | ~iodelay_ctrl_rdy[0] |
~ref_dll_lock | ~MMCM_Locked_i;
end
endgenerate
always @(posedge clk_bufg or posedge rst_tmp) begin
if (rst_tmp) begin
rstdiv0_sync_r <= #TCQ {RST_DIV_SYNC_NUM-1{1'b1}};
rstdiv0_sync_r1 <= #TCQ 1'b1 ;
end else begin
rstdiv0_sync_r <= #TCQ rstdiv0_sync_r << 1;
rstdiv0_sync_r1 <= #TCQ rstdiv0_sync_r[RST_DIV_SYNC_NUM-2];
end
end
assign rstdiv0 = rstdiv0_sync_r1 ;
//IDDR rest
always @(posedge mmcm_ps_clk or posedge rst_tmp) begin
if (rst_tmp) begin
rst_sync_r <= #TCQ {RST_DIV_SYNC_NUM-1{1'b1}};
rst_sync_r1 <= #TCQ 1'b1 ;
end else begin
rst_sync_r <= #TCQ rst_sync_r << 1;
rst_sync_r1 <= #TCQ rst_sync_r[RST_DIV_SYNC_NUM-2];
end
end
assign iddr_rst = rst_sync_r1 ;
generate
if (MEM_TYPE == "DDR3" && tCK <= 1500) begin: rst_tmp_phaser_ref_300_400
assign rst_tmp_phaser_ref = sys_rst_act_hi | ~MMCM_Locked_i | ~iodelay_ctrl_rdy[1];
end else begin: rst_tmp_phaser_ref_200
assign rst_tmp_phaser_ref = sys_rst_act_hi | ~MMCM_Locked_i | ~iodelay_ctrl_rdy[0];
end
endgenerate
always @(posedge clk_bufg or posedge rst_tmp_phaser_ref)
if (rst_tmp_phaser_ref)
rst_phaser_ref_sync_r <= #TCQ {RST_DIV_SYNC_NUM{1'b1}};
else
rst_phaser_ref_sync_r <= #TCQ rst_phaser_ref_sync_r << 1;
assign rst_phaser_ref = rst_phaser_ref_sync_r[RST_DIV_SYNC_NUM-1];
endmodule
|
module outputs)
wire maint_prescaler_tick_r; // From rank_common0 of rank_common.v
wire refresh_tick; // From rank_common0 of rank_common.v
// End of automatics
output [RANKS-1:0] inhbt_act_faw_r;
output [RANKS-1:0] inhbt_rd;
output [RANKS-1:0] inhbt_wr;
output [RANK_WIDTH-1:0] maint_rank_r;
output maint_zq_r;
output maint_sre_r;
output maint_srx_r;
output app_sr_active;
output app_ref_ack;
output app_zq_ack;
output maint_ref_zq_wip;
wire [RANKS-1:0] refresh_request;
wire [RANKS-1:0] periodic_rd_request;
wire [RANKS-1:0] clear_periodic_rd_request;
genvar ID;
generate
for (ID=0; ID<RANKS; ID=ID+1) begin:rank_cntrl
mig_7series_v2_3_rank_cntrl #
(/*AUTOINSTPARAM*/
// Parameters
.BURST_MODE (BURST_MODE),
.ID (ID),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.CL (CL),
.CWL (CWL),
.DQRD2DQWR_DLY (DQRD2DQWR_DLY),
.nFAW (nFAW),
.nREFRESH_BANK (nREFRESH_BANK),
.nRRD (nRRD),
.nWTR (nWTR),
.PERIODIC_RD_TIMER_DIV (PERIODIC_RD_TIMER_DIV),
.RANK_BM_BV_WIDTH (RANK_BM_BV_WIDTH),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.REFRESH_TIMER_DIV (REFRESH_TIMER_DIV))
rank_cntrl0
(.clear_periodic_rd_request (clear_periodic_rd_request[ID]),
.inhbt_act_faw_r (inhbt_act_faw_r[ID]),
.inhbt_rd (inhbt_rd[ID]),
.inhbt_wr (inhbt_wr[ID]),
.periodic_rd_request (periodic_rd_request[ID]),
.refresh_request (refresh_request[ID]),
/*AUTOINST*/
// Inputs
.clk (clk),
.rst (rst),
.col_rd_wr (col_rd_wr),
.sending_row (sending_row[nBANK_MACHS-1:0]),
.act_this_rank_r (act_this_rank_r[RANK_BM_BV_WIDTH-1:0]),
.sending_col (sending_col[nBANK_MACHS-1:0]),
.wr_this_rank_r (wr_this_rank_r[RANK_BM_BV_WIDTH-1:0]),
.app_ref_req (app_ref_req),
.init_calib_complete (init_calib_complete),
.rank_busy_r (rank_busy_r[(RANKS*nBANK_MACHS)-1:0]),
.refresh_tick (refresh_tick),
.insert_maint_r1 (insert_maint_r1),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.maint_srx_r (maint_srx_r),
.maint_rank_r (maint_rank_r[RANK_WIDTH-1:0]),
.app_periodic_rd_req (app_periodic_rd_req),
.maint_prescaler_tick_r (maint_prescaler_tick_r),
.rd_this_rank_r (rd_this_rank_r[RANK_BM_BV_WIDTH-1:0]));
end
endgenerate
mig_7series_v2_3_rank_common #
(/*AUTOINSTPARAM*/
// Parameters
.DRAM_TYPE (DRAM_TYPE),
.MAINT_PRESCALER_DIV (MAINT_PRESCALER_DIV),
.nBANK_MACHS (nBANK_MACHS),
.nCKESR (nCKESR),
.nCK_PER_CLK (nCK_PER_CLK),
.PERIODIC_RD_TIMER_DIV (PERIODIC_RD_TIMER_DIV),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.REFRESH_TIMER_DIV (REFRESH_TIMER_DIV),
.ZQ_TIMER_DIV (ZQ_TIMER_DIV))
rank_common0
(.clear_periodic_rd_request (clear_periodic_rd_request[RANKS-1:0]),
/*AUTOINST*/
// Outputs
.maint_prescaler_tick_r (maint_prescaler_tick_r),
.refresh_tick (refresh_tick),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.maint_srx_r (maint_srx_r),
.maint_req_r (maint_req_r),
.maint_rank_r (maint_rank_r[RANK_WIDTH-1:0]),
.maint_ref_zq_wip (maint_ref_zq_wip),
.periodic_rd_r (periodic_rd_r),
.periodic_rd_rank_r (periodic_rd_rank_r[RANK_WIDTH-1:0]),
// Inputs
.clk (clk),
.rst (rst),
.init_calib_complete (init_calib_complete),
.app_ref_req (app_ref_req),
.app_ref_ack (app_ref_ack),
.app_zq_req (app_zq_req),
.app_zq_ack (app_zq_ack),
.app_sr_req (app_sr_req),
.app_sr_active (app_sr_active),
.insert_maint_r1 (insert_maint_r1),
.refresh_request (refresh_request[RANKS-1:0]),
.maint_wip_r (maint_wip_r),
.slot_0_present (slot_0_present[7:0]),
.slot_1_present (slot_1_present[7:0]),
.periodic_rd_request (periodic_rd_request[RANKS-1:0]),
.periodic_rd_ack_r (periodic_rd_ack_r));
endmodule
|
module mig_7series_v2_3_bank_compare #
(parameter BANK_WIDTH = 3,
parameter TCQ = 100,
parameter BURST_MODE = "8",
parameter COL_WIDTH = 12,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter ECC = "OFF",
parameter RANK_WIDTH = 2,
parameter RANKS = 4,
parameter ROW_WIDTH = 16)
(/*AUTOARG*/
// Outputs
req_data_buf_addr_r, req_periodic_rd_r, req_size_r, rd_wr_r,
req_rank_r, req_bank_r, req_row_r, req_wr_r, req_priority_r,
rb_hit_busy_r, rb_hit_busy_ns, row_hit_r, maint_hit, col_addr,
req_ras, req_cas, row_cmd_wr, row_addr, rank_busy_r,
// Inputs
clk, idle_ns, idle_r, data_buf_addr, periodic_rd_insert, size, cmd,
sending_col, rank, periodic_rd_rank_r, bank, row, col, hi_priority,
maint_rank_r, maint_zq_r, maint_sre_r, auto_pre_r, rd_half_rmw, act_wait_r
);
input clk;
input idle_ns;
input idle_r;
input [DATA_BUF_ADDR_WIDTH-1:0]data_buf_addr;
output reg [DATA_BUF_ADDR_WIDTH-1:0] req_data_buf_addr_r;
wire [DATA_BUF_ADDR_WIDTH-1:0] req_data_buf_addr_ns =
idle_r
? data_buf_addr
: req_data_buf_addr_r;
always @(posedge clk) req_data_buf_addr_r <= #TCQ req_data_buf_addr_ns;
input periodic_rd_insert;
reg req_periodic_rd_r_lcl;
wire req_periodic_rd_ns = idle_ns
? periodic_rd_insert
: req_periodic_rd_r_lcl;
always @(posedge clk) req_periodic_rd_r_lcl <= #TCQ req_periodic_rd_ns;
output wire req_periodic_rd_r;
assign req_periodic_rd_r = req_periodic_rd_r_lcl;
input size;
wire req_size_r_lcl;
generate
if (BURST_MODE == "4") begin : burst_mode_4
assign req_size_r_lcl = 1'b0;
end
else
if (BURST_MODE == "8") begin : burst_mode_8
assign req_size_r_lcl = 1'b1;
end
else
if (BURST_MODE == "OTF") begin : burst_mode_otf
reg req_size;
wire req_size_ns = idle_ns
? (periodic_rd_insert || size)
: req_size;
always @(posedge clk) req_size <= #TCQ req_size_ns;
assign req_size_r_lcl = req_size;
end
endgenerate
output wire req_size_r;
assign req_size_r = req_size_r_lcl;
input [2:0] cmd;
reg [2:0] req_cmd_r;
wire [2:0] req_cmd_ns = idle_ns
? (periodic_rd_insert ? 3'b001 : cmd)
: req_cmd_r;
always @(posedge clk) req_cmd_r <= #TCQ req_cmd_ns;
`ifdef MC_SVA
rd_wr_only_wo_ecc: assert property
(@(posedge clk) ((ECC != "OFF") || idle_ns || ~|req_cmd_ns[2:1]));
`endif
input sending_col;
reg rd_wr_r_lcl;
wire rd_wr_ns = idle_ns
? ((req_cmd_ns[1:0] == 2'b11) || req_cmd_ns[0])
: ~sending_col && rd_wr_r_lcl;
always @(posedge clk) rd_wr_r_lcl <= #TCQ rd_wr_ns;
output wire rd_wr_r;
assign rd_wr_r = rd_wr_r_lcl;
input [RANK_WIDTH-1:0] rank;
input [RANK_WIDTH-1:0] periodic_rd_rank_r;
reg [RANK_WIDTH-1:0] req_rank_r_lcl = {RANK_WIDTH{1'b0}};
reg [RANK_WIDTH-1:0] req_rank_ns = {RANK_WIDTH{1'b0}};
generate
if (RANKS != 1) begin
always @(/*AS*/idle_ns or periodic_rd_insert
or periodic_rd_rank_r or rank or req_rank_r_lcl) req_rank_ns = idle_ns
? periodic_rd_insert
? periodic_rd_rank_r
: rank
: req_rank_r_lcl;
always @(posedge clk) req_rank_r_lcl <= #TCQ req_rank_ns;
end
endgenerate
output wire [RANK_WIDTH-1:0] req_rank_r;
assign req_rank_r = req_rank_r_lcl;
input [BANK_WIDTH-1:0] bank;
reg [BANK_WIDTH-1:0] req_bank_r_lcl;
wire [BANK_WIDTH-1:0] req_bank_ns = idle_ns ? bank : req_bank_r_lcl;
always @(posedge clk) req_bank_r_lcl <= #TCQ req_bank_ns;
output wire[BANK_WIDTH-1:0] req_bank_r;
assign req_bank_r = req_bank_r_lcl;
input [ROW_WIDTH-1:0] row;
reg [ROW_WIDTH-1:0] req_row_r_lcl;
wire [ROW_WIDTH-1:0] req_row_ns = idle_ns ? row : req_row_r_lcl;
always @(posedge clk) req_row_r_lcl <= #TCQ req_row_ns;
output wire [ROW_WIDTH-1:0] req_row_r;
assign req_row_r = req_row_r_lcl;
// Make req_col_r as wide as the max row address. This
// makes it easier to deal with indexing different column widths.
input [COL_WIDTH-1:0] col;
reg [15:0] req_col_r = 16'b0;
wire [COL_WIDTH-1:0] req_col_ns = idle_ns ? col : req_col_r[COL_WIDTH-1:0];
always @(posedge clk) req_col_r[COL_WIDTH-1:0] <= #TCQ req_col_ns;
reg req_wr_r_lcl;
wire req_wr_ns = idle_ns
? ((req_cmd_ns[1:0] == 2'b11) || ~req_cmd_ns[0])
: req_wr_r_lcl;
always @(posedge clk) req_wr_r_lcl <= #TCQ req_wr_ns;
output wire req_wr_r;
assign req_wr_r = req_wr_r_lcl;
input hi_priority;
output reg req_priority_r;
wire req_priority_ns = idle_ns ? hi_priority : req_priority_r;
always @(posedge clk) req_priority_r <= #TCQ req_priority_ns;
wire rank_hit = (req_rank_r_lcl == (periodic_rd_insert
? periodic_rd_rank_r
: rank));
wire bank_hit = (req_bank_r_lcl == bank);
wire rank_bank_hit = rank_hit && bank_hit;
output reg rb_hit_busy_r; // rank-bank hit on non idle row machine
wire rb_hit_busy_ns_lcl;
assign rb_hit_busy_ns_lcl = rank_bank_hit && ~idle_ns;
output wire rb_hit_busy_ns;
assign rb_hit_busy_ns = rb_hit_busy_ns_lcl;
wire row_hit_ns = (req_row_r_lcl == row);
output reg row_hit_r;
always @(posedge clk) rb_hit_busy_r <= #TCQ rb_hit_busy_ns_lcl;
always @(posedge clk) row_hit_r <= #TCQ row_hit_ns;
input [RANK_WIDTH-1:0] maint_rank_r;
input maint_zq_r;
input maint_sre_r;
output wire maint_hit;
assign maint_hit = (req_rank_r_lcl == maint_rank_r) || maint_zq_r || maint_sre_r;
// Assemble column address. Structure to be the same
// width as the row address. This makes it easier
// for the downstream muxing. Depending on the sizes
// of the row and column addresses, fill in as appropriate.
input auto_pre_r;
input rd_half_rmw;
reg [15:0] col_addr_template = 16'b0;
always @(/*AS*/auto_pre_r or rd_half_rmw or req_col_r
or req_size_r_lcl) begin
col_addr_template = req_col_r;
col_addr_template[10] = auto_pre_r && ~rd_half_rmw;
col_addr_template[11] = req_col_r[10];
col_addr_template[12] = req_size_r_lcl;
col_addr_template[13] = req_col_r[11];
end
output wire [ROW_WIDTH-1:0] col_addr;
assign col_addr = col_addr_template[ROW_WIDTH-1:0];
output wire req_ras;
output wire req_cas;
output wire row_cmd_wr;
input act_wait_r;
assign req_ras = 1'b0;
assign req_cas = 1'b1;
assign row_cmd_wr = act_wait_r;
output reg [ROW_WIDTH-1:0] row_addr;
always @(/*AS*/act_wait_r or req_row_r_lcl) begin
row_addr = req_row_r_lcl;
// This causes all precharges to be precharge single bank command.
if (~act_wait_r) row_addr[10] = 1'b0;
end
// Indicate which, if any, rank this bank machine is busy with.
// Not registering the result would probably be more accurate, but
// would create timing issues. This is used for refresh banking, perfect
// accuracy is not required.
localparam ONE = 1;
output reg [RANKS-1:0] rank_busy_r;
wire [RANKS-1:0] rank_busy_ns = {RANKS{~idle_ns}} & (ONE[RANKS-1:0] << req_rank_ns);
always @(posedge clk) rank_busy_r <= #TCQ rank_busy_ns;
endmodule
|
module mig_7series_v2_3_bank_compare #
(parameter BANK_WIDTH = 3,
parameter TCQ = 100,
parameter BURST_MODE = "8",
parameter COL_WIDTH = 12,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter ECC = "OFF",
parameter RANK_WIDTH = 2,
parameter RANKS = 4,
parameter ROW_WIDTH = 16)
(/*AUTOARG*/
// Outputs
req_data_buf_addr_r, req_periodic_rd_r, req_size_r, rd_wr_r,
req_rank_r, req_bank_r, req_row_r, req_wr_r, req_priority_r,
rb_hit_busy_r, rb_hit_busy_ns, row_hit_r, maint_hit, col_addr,
req_ras, req_cas, row_cmd_wr, row_addr, rank_busy_r,
// Inputs
clk, idle_ns, idle_r, data_buf_addr, periodic_rd_insert, size, cmd,
sending_col, rank, periodic_rd_rank_r, bank, row, col, hi_priority,
maint_rank_r, maint_zq_r, maint_sre_r, auto_pre_r, rd_half_rmw, act_wait_r
);
input clk;
input idle_ns;
input idle_r;
input [DATA_BUF_ADDR_WIDTH-1:0]data_buf_addr;
output reg [DATA_BUF_ADDR_WIDTH-1:0] req_data_buf_addr_r;
wire [DATA_BUF_ADDR_WIDTH-1:0] req_data_buf_addr_ns =
idle_r
? data_buf_addr
: req_data_buf_addr_r;
always @(posedge clk) req_data_buf_addr_r <= #TCQ req_data_buf_addr_ns;
input periodic_rd_insert;
reg req_periodic_rd_r_lcl;
wire req_periodic_rd_ns = idle_ns
? periodic_rd_insert
: req_periodic_rd_r_lcl;
always @(posedge clk) req_periodic_rd_r_lcl <= #TCQ req_periodic_rd_ns;
output wire req_periodic_rd_r;
assign req_periodic_rd_r = req_periodic_rd_r_lcl;
input size;
wire req_size_r_lcl;
generate
if (BURST_MODE == "4") begin : burst_mode_4
assign req_size_r_lcl = 1'b0;
end
else
if (BURST_MODE == "8") begin : burst_mode_8
assign req_size_r_lcl = 1'b1;
end
else
if (BURST_MODE == "OTF") begin : burst_mode_otf
reg req_size;
wire req_size_ns = idle_ns
? (periodic_rd_insert || size)
: req_size;
always @(posedge clk) req_size <= #TCQ req_size_ns;
assign req_size_r_lcl = req_size;
end
endgenerate
output wire req_size_r;
assign req_size_r = req_size_r_lcl;
input [2:0] cmd;
reg [2:0] req_cmd_r;
wire [2:0] req_cmd_ns = idle_ns
? (periodic_rd_insert ? 3'b001 : cmd)
: req_cmd_r;
always @(posedge clk) req_cmd_r <= #TCQ req_cmd_ns;
`ifdef MC_SVA
rd_wr_only_wo_ecc: assert property
(@(posedge clk) ((ECC != "OFF") || idle_ns || ~|req_cmd_ns[2:1]));
`endif
input sending_col;
reg rd_wr_r_lcl;
wire rd_wr_ns = idle_ns
? ((req_cmd_ns[1:0] == 2'b11) || req_cmd_ns[0])
: ~sending_col && rd_wr_r_lcl;
always @(posedge clk) rd_wr_r_lcl <= #TCQ rd_wr_ns;
output wire rd_wr_r;
assign rd_wr_r = rd_wr_r_lcl;
input [RANK_WIDTH-1:0] rank;
input [RANK_WIDTH-1:0] periodic_rd_rank_r;
reg [RANK_WIDTH-1:0] req_rank_r_lcl = {RANK_WIDTH{1'b0}};
reg [RANK_WIDTH-1:0] req_rank_ns = {RANK_WIDTH{1'b0}};
generate
if (RANKS != 1) begin
always @(/*AS*/idle_ns or periodic_rd_insert
or periodic_rd_rank_r or rank or req_rank_r_lcl) req_rank_ns = idle_ns
? periodic_rd_insert
? periodic_rd_rank_r
: rank
: req_rank_r_lcl;
always @(posedge clk) req_rank_r_lcl <= #TCQ req_rank_ns;
end
endgenerate
output wire [RANK_WIDTH-1:0] req_rank_r;
assign req_rank_r = req_rank_r_lcl;
input [BANK_WIDTH-1:0] bank;
reg [BANK_WIDTH-1:0] req_bank_r_lcl;
wire [BANK_WIDTH-1:0] req_bank_ns = idle_ns ? bank : req_bank_r_lcl;
always @(posedge clk) req_bank_r_lcl <= #TCQ req_bank_ns;
output wire[BANK_WIDTH-1:0] req_bank_r;
assign req_bank_r = req_bank_r_lcl;
input [ROW_WIDTH-1:0] row;
reg [ROW_WIDTH-1:0] req_row_r_lcl;
wire [ROW_WIDTH-1:0] req_row_ns = idle_ns ? row : req_row_r_lcl;
always @(posedge clk) req_row_r_lcl <= #TCQ req_row_ns;
output wire [ROW_WIDTH-1:0] req_row_r;
assign req_row_r = req_row_r_lcl;
// Make req_col_r as wide as the max row address. This
// makes it easier to deal with indexing different column widths.
input [COL_WIDTH-1:0] col;
reg [15:0] req_col_r = 16'b0;
wire [COL_WIDTH-1:0] req_col_ns = idle_ns ? col : req_col_r[COL_WIDTH-1:0];
always @(posedge clk) req_col_r[COL_WIDTH-1:0] <= #TCQ req_col_ns;
reg req_wr_r_lcl;
wire req_wr_ns = idle_ns
? ((req_cmd_ns[1:0] == 2'b11) || ~req_cmd_ns[0])
: req_wr_r_lcl;
always @(posedge clk) req_wr_r_lcl <= #TCQ req_wr_ns;
output wire req_wr_r;
assign req_wr_r = req_wr_r_lcl;
input hi_priority;
output reg req_priority_r;
wire req_priority_ns = idle_ns ? hi_priority : req_priority_r;
always @(posedge clk) req_priority_r <= #TCQ req_priority_ns;
wire rank_hit = (req_rank_r_lcl == (periodic_rd_insert
? periodic_rd_rank_r
: rank));
wire bank_hit = (req_bank_r_lcl == bank);
wire rank_bank_hit = rank_hit && bank_hit;
output reg rb_hit_busy_r; // rank-bank hit on non idle row machine
wire rb_hit_busy_ns_lcl;
assign rb_hit_busy_ns_lcl = rank_bank_hit && ~idle_ns;
output wire rb_hit_busy_ns;
assign rb_hit_busy_ns = rb_hit_busy_ns_lcl;
wire row_hit_ns = (req_row_r_lcl == row);
output reg row_hit_r;
always @(posedge clk) rb_hit_busy_r <= #TCQ rb_hit_busy_ns_lcl;
always @(posedge clk) row_hit_r <= #TCQ row_hit_ns;
input [RANK_WIDTH-1:0] maint_rank_r;
input maint_zq_r;
input maint_sre_r;
output wire maint_hit;
assign maint_hit = (req_rank_r_lcl == maint_rank_r) || maint_zq_r || maint_sre_r;
// Assemble column address. Structure to be the same
// width as the row address. This makes it easier
// for the downstream muxing. Depending on the sizes
// of the row and column addresses, fill in as appropriate.
input auto_pre_r;
input rd_half_rmw;
reg [15:0] col_addr_template = 16'b0;
always @(/*AS*/auto_pre_r or rd_half_rmw or req_col_r
or req_size_r_lcl) begin
col_addr_template = req_col_r;
col_addr_template[10] = auto_pre_r && ~rd_half_rmw;
col_addr_template[11] = req_col_r[10];
col_addr_template[12] = req_size_r_lcl;
col_addr_template[13] = req_col_r[11];
end
output wire [ROW_WIDTH-1:0] col_addr;
assign col_addr = col_addr_template[ROW_WIDTH-1:0];
output wire req_ras;
output wire req_cas;
output wire row_cmd_wr;
input act_wait_r;
assign req_ras = 1'b0;
assign req_cas = 1'b1;
assign row_cmd_wr = act_wait_r;
output reg [ROW_WIDTH-1:0] row_addr;
always @(/*AS*/act_wait_r or req_row_r_lcl) begin
row_addr = req_row_r_lcl;
// This causes all precharges to be precharge single bank command.
if (~act_wait_r) row_addr[10] = 1'b0;
end
// Indicate which, if any, rank this bank machine is busy with.
// Not registering the result would probably be more accurate, but
// would create timing issues. This is used for refresh banking, perfect
// accuracy is not required.
localparam ONE = 1;
output reg [RANKS-1:0] rank_busy_r;
wire [RANKS-1:0] rank_busy_ns = {RANKS{~idle_ns}} & (ONE[RANKS-1:0] << req_rank_ns);
always @(posedge clk) rank_busy_r <= #TCQ rank_busy_ns;
endmodule
|
module altera_reset_synchronizer
#(
parameter ASYNC_RESET = 1,
parameter DEPTH = 2
)
(
input reset_in /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=R101" */,
input clk,
output reset_out
);
// -----------------------------------------------
// Synchronizer register chain. We cannot reuse the
// standard synchronizer in this implementation
// because our timing constraints are different.
//
// Instead of cutting the timing path to the d-input
// on the first flop we need to cut the aclr input.
//
// We omit the "preserve" attribute on the final
// output register, so that the synthesis tool can
// duplicate it where needed.
// -----------------------------------------------
(*preserve*) reg [DEPTH-1:0] altera_reset_synchronizer_int_chain;
reg altera_reset_synchronizer_int_chain_out;
generate if (ASYNC_RESET) begin
// -----------------------------------------------
// Assert asynchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk or posedge reset_in) begin
if (reset_in) begin
altera_reset_synchronizer_int_chain <= {DEPTH{1'b1}};
altera_reset_synchronizer_int_chain_out <= 1'b1;
end
else begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= 0;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end else begin
// -----------------------------------------------
// Assert synchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk) begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= reset_in;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end
endgenerate
endmodule
|
module altera_reset_synchronizer
#(
parameter ASYNC_RESET = 1,
parameter DEPTH = 2
)
(
input reset_in /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=R101" */,
input clk,
output reset_out
);
// -----------------------------------------------
// Synchronizer register chain. We cannot reuse the
// standard synchronizer in this implementation
// because our timing constraints are different.
//
// Instead of cutting the timing path to the d-input
// on the first flop we need to cut the aclr input.
//
// We omit the "preserve" attribute on the final
// output register, so that the synthesis tool can
// duplicate it where needed.
// -----------------------------------------------
(*preserve*) reg [DEPTH-1:0] altera_reset_synchronizer_int_chain;
reg altera_reset_synchronizer_int_chain_out;
generate if (ASYNC_RESET) begin
// -----------------------------------------------
// Assert asynchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk or posedge reset_in) begin
if (reset_in) begin
altera_reset_synchronizer_int_chain <= {DEPTH{1'b1}};
altera_reset_synchronizer_int_chain_out <= 1'b1;
end
else begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= 0;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end else begin
// -----------------------------------------------
// Assert synchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk) begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= reset_in;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end
endgenerate
endmodule
|
module altera_reset_synchronizer
#(
parameter ASYNC_RESET = 1,
parameter DEPTH = 2
)
(
input reset_in /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=R101" */,
input clk,
output reset_out
);
// -----------------------------------------------
// Synchronizer register chain. We cannot reuse the
// standard synchronizer in this implementation
// because our timing constraints are different.
//
// Instead of cutting the timing path to the d-input
// on the first flop we need to cut the aclr input.
//
// We omit the "preserve" attribute on the final
// output register, so that the synthesis tool can
// duplicate it where needed.
// -----------------------------------------------
(*preserve*) reg [DEPTH-1:0] altera_reset_synchronizer_int_chain;
reg altera_reset_synchronizer_int_chain_out;
generate if (ASYNC_RESET) begin
// -----------------------------------------------
// Assert asynchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk or posedge reset_in) begin
if (reset_in) begin
altera_reset_synchronizer_int_chain <= {DEPTH{1'b1}};
altera_reset_synchronizer_int_chain_out <= 1'b1;
end
else begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= 0;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end else begin
// -----------------------------------------------
// Assert synchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk) begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= reset_in;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end
endgenerate
endmodule
|
module altera_reset_synchronizer
#(
parameter ASYNC_RESET = 1,
parameter DEPTH = 2
)
(
input reset_in /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=R101" */,
input clk,
output reset_out
);
// -----------------------------------------------
// Synchronizer register chain. We cannot reuse the
// standard synchronizer in this implementation
// because our timing constraints are different.
//
// Instead of cutting the timing path to the d-input
// on the first flop we need to cut the aclr input.
//
// We omit the "preserve" attribute on the final
// output register, so that the synthesis tool can
// duplicate it where needed.
// -----------------------------------------------
(*preserve*) reg [DEPTH-1:0] altera_reset_synchronizer_int_chain;
reg altera_reset_synchronizer_int_chain_out;
generate if (ASYNC_RESET) begin
// -----------------------------------------------
// Assert asynchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk or posedge reset_in) begin
if (reset_in) begin
altera_reset_synchronizer_int_chain <= {DEPTH{1'b1}};
altera_reset_synchronizer_int_chain_out <= 1'b1;
end
else begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= 0;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end else begin
// -----------------------------------------------
// Assert synchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk) begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= reset_in;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end
endgenerate
endmodule
|
module
wire lim2init_write_request;
wire lim_done;
// Bypass complex ocal
wire complex_oclkdelay_calib_start_w;
wire complex_oclkdelay_calib_done_w;
wire [2:0] complex_ocal_rd_victim_sel_w;
wire complex_wrlvl_final_w;
wire [255:0] dbg_ocd_lim;
//with MMCM phase detect logic
//wire mmcm_edge_detect_rdy; // ready for MMCM detect
//wire ktap_at_rightedge; // stg3 tap at right edge
//wire ktap_at_leftedge; // stg3 tap at left edge
//wire mmcm_tap_at_center; // indicate stg3 tap at center
//wire mmcm_ps_clkphase_ok; // ps clkphase is OK
//wire mmcm_edge_detect_done; // mmcm edge detect is done
//wire mmcm_lbclk_edges_aligned; // mmcm edge detect is done
//wire reset_mmcm; //mmcm detect logic reset per byte
// wire [255:0] dbg_phy_oclkdelay_center_cal;
//*****************************************************************************
// Assertions to check correctness of parameter values
//*****************************************************************************
// synthesis translate_off
initial
begin
if (RANKS == 0) begin
$display ("Error: Invalid RANKS parameter. Must be 1 or greater");
$finish;
end
if (phy_ctl_full == 1'b1) begin
$display ("Error: Incorrect phy_ctl_full input value in 2:1 or 4:1 mode");
$finish;
end
end
// synthesis translate_on
//***************************************************************************
// Debug
//***************************************************************************
assign dbg_pi_phaselock_start = pi_phaselock_start;
assign dbg_pi_dqsfound_start = pi_dqs_found_start;
assign dbg_pi_dqsfound_done = pi_dqs_found_done;
assign dbg_wrcal_start = wrcal_start;
assign dbg_wrcal_done = wrcal_done;
// Unused for now - use these as needed to bring up lower level signals
assign dbg_calib_top = dbg_ocd_lim;
// Write Level and write calibration debug observation ports
assign dbg_wrlvl_start = wrlvl_start;
assign dbg_wrlvl_done = wrlvl_done;
assign dbg_wrlvl_err = wrlvl_err;
// Read Level debug observation ports
assign dbg_rdlvl_start = {mpr_rdlvl_start, rdlvl_stg1_start};
assign dbg_rdlvl_done = {mpr_rdlvl_done, rdlvl_stg1_done};
assign dbg_rdlvl_err = {mpr_rdlvl_err, rdlvl_err};
assign dbg_oclkdelay_calib_done = oclkdelay_calib_done;
assign dbg_oclkdelay_calib_start = oclkdelay_calib_start;
//***************************************************************************
// Write leveling dependent signals
//***************************************************************************
assign wrcal_resume_w = (WRLVL == "ON") ? wrcal_pat_resume : 1'b0;
assign wrlvl_done_w = (WRLVL == "ON") ? wrlvl_done : 1'b1;
assign ck_addr_cmd_delay_done = (WRLVL == "ON") ? po_ck_addr_cmd_delay_done :
(po_ck_addr_cmd_delay_done
&& pi_fine_dly_dec_done) ;
generate
if((WRLVL == "ON") && (BYPASS_COMPLEX_OCAL=="FALSE")) begin: complex_oclk_calib
assign complex_oclkdelay_calib_start_w = complex_oclkdelay_calib_start;
assign complex_oclkdelay_calib_done_w = complex_oclkdelay_calib_done;
assign complex_ocal_rd_victim_sel_w = complex_ocal_rd_victim_sel;
assign complex_wrlvl_final_w = complex_wrlvl_final;
end else begin: bypass_complex_ocal
assign complex_oclkdelay_calib_start_w = 1'b0;
assign complex_oclkdelay_calib_done_w = prbs_rdlvl_done;
assign complex_ocal_rd_victim_sel_w = 'd0;
assign complex_wrlvl_final_w = 1'b0;
end
endgenerate
generate
genvar i;
for (i = 0; i <= 2; i = i+1) begin : bankwise_signal
assign po_sel_stg2stg3[i] = ((ck_addr_cmd_delay_done && ~oclkdelay_calib_done && mpr_rdlvl_done) ? po_stg23_sel :
(complex_oclkdelay_calib_start_w&&~complex_oclkdelay_calib_done_w? po_stg23_sel : 1'b0 )
// (~oclkdelay_center_calib_done? ocal_ctr_po_stg23_sel:1'b0))
) | dbg_po_f_stg23_sel_r;
assign po_stg2_c_incdec[i] = cmd_po_stg2_c_incdec ||
cmd_po_stg2_incdec_ddr2_c ||
dqs_wl_po_stg2_c_incdec;
assign po_en_stg2_c[i] = cmd_po_en_stg2_c ||
cmd_po_en_stg2_ddr2_c ||
dqs_wl_po_en_stg2_c;
assign po_stg2_f_incdec[i] = dqs_po_stg2_f_incdec ||
cmd_po_stg2_f_incdec ||
//po_stg3_incdec ||
ck_po_stg2_f_indec ||
po_stg23_incdec ||
// complex_po_stg23_incdec ||
// ocal_ctr_po_stg23_incdec ||
dbg_po_f_inc_r;
assign po_en_stg2_f[i] = dqs_po_en_stg2_f ||
cmd_po_en_stg2_f ||
//po_en_stg3 ||
ck_po_stg2_f_en ||
po_en_stg23 ||
// complex_po_en_stg23 ||
// ocal_ctr_po_en_stg23 ||
dbg_po_f_en_r;
end
endgenerate
assign pi_stg2_f_incdec = (dbg_pi_f_inc_r | rdlvl_pi_stg2_f_incdec | prbs_pi_stg2_f_incdec | tempmon_pi_f_inc_r);
assign pi_en_stg2_f = (dbg_pi_f_en_r | rdlvl_pi_stg2_f_en | prbs_pi_stg2_f_en | tempmon_pi_f_en_r);
assign idelay_ce = idelay_ce_r2;
assign idelay_inc = idelay_inc_r2;
assign po_counter_load_en = 1'b0;
assign complex_oclkdelay_calib_cnt = oclkdelay_calib_cnt;
assign complex_oclk_calib_resume = oclk_calib_resume;
assign complex_ocal_ref_req = oclk_prech_req;
// Added single stage flop to meet timing
always @(posedge clk)
init_calib_complete <= calib_complete;
assign calib_rd_data_offset_0 = rd_data_offset_ranks_mc_0;
assign calib_rd_data_offset_1 = rd_data_offset_ranks_mc_1;
assign calib_rd_data_offset_2 = rd_data_offset_ranks_mc_2;
//***************************************************************************
// Hard PHY signals
//***************************************************************************
assign pi_phase_locked_err = phase_locked_err;
assign pi_dqsfound_err = pi_dqs_found_err;
assign wrcal_err = wrcal_pat_err;
assign rst_tg_mc = 1'b0;
//Restart WRLVL after oclkdealy cal
always @ (posedge clk)
wrlvl_final_mux <= #TCQ complex_oclkdelay_calib_start_w? complex_wrlvl_final_w: wrlvl_final;
always @(posedge clk)
phy_if_reset <= #TCQ (phy_if_reset_w | mpr_end_if_reset |
reset_if | wrlvl_final_if_rst);
//***************************************************************************
// Phaser_IN inc dec control for debug
//***************************************************************************
always @(posedge clk) begin
if (rst) begin
dbg_pi_f_inc_r <= #TCQ 1'b0;
dbg_pi_f_en_r <= #TCQ 1'b0;
dbg_sel_pi_incdec_r <= #TCQ 1'b0;
end else begin
dbg_pi_f_inc_r <= #TCQ dbg_pi_f_inc;
dbg_pi_f_en_r <= #TCQ (dbg_pi_f_inc | dbg_pi_f_dec);
dbg_sel_pi_incdec_r <= #TCQ dbg_sel_pi_incdec;
end
end
//***************************************************************************
// Phaser_OUT inc dec control for debug
//***************************************************************************
always @(posedge clk) begin
if (rst) begin
dbg_po_f_inc_r <= #TCQ 1'b0;
dbg_po_f_stg23_sel_r<= #TCQ 1'b0;
dbg_po_f_en_r <= #TCQ 1'b0;
dbg_sel_po_incdec_r <= #TCQ 1'b0;
end else begin
dbg_po_f_inc_r <= #TCQ dbg_po_f_inc;
dbg_po_f_stg23_sel_r<= #TCQ dbg_po_f_stg23_sel;
dbg_po_f_en_r <= #TCQ (dbg_po_f_inc | dbg_po_f_dec);
dbg_sel_po_incdec_r <= #TCQ dbg_sel_po_incdec;
end
end
//***************************************************************************
// Phaser_IN inc dec control for temperature tracking
//***************************************************************************
always @(posedge clk) begin
if (rst) begin
tempmon_pi_f_inc_r <= #TCQ 1'b0;
tempmon_pi_f_en_r <= #TCQ 1'b0;
tempmon_sel_pi_incdec_r <= #TCQ 1'b0;
end else begin
tempmon_pi_f_inc_r <= #TCQ tempmon_pi_f_inc;
tempmon_pi_f_en_r <= #TCQ (tempmon_pi_f_inc | tempmon_pi_f_dec);
tempmon_sel_pi_incdec_r <= #TCQ tempmon_sel_pi_incdec;
end
end
//***************************************************************************
// OCLKDELAY calibration signals
//***************************************************************************
// Minimum of 5 'clk' cycles required between assertion of po_sel_stg2stg3
// and increment/decrement of Phaser_Out stage 3 delay
always @(posedge clk) begin
ck_addr_cmd_delay_done_r1 <= #TCQ ck_addr_cmd_delay_done;
ck_addr_cmd_delay_done_r2 <= #TCQ ck_addr_cmd_delay_done_r1;
ck_addr_cmd_delay_done_r3 <= #TCQ ck_addr_cmd_delay_done_r2;
ck_addr_cmd_delay_done_r4 <= #TCQ ck_addr_cmd_delay_done_r3;
ck_addr_cmd_delay_done_r5 <= #TCQ ck_addr_cmd_delay_done_r4;
ck_addr_cmd_delay_done_r6 <= #TCQ ck_addr_cmd_delay_done_r5;
end
//***************************************************************************
// MUX select logic to select current byte undergoing calibration
// Use DQS_CAL_MAP to determine the correlation between the physical
// byte numbering, and the byte numbering within the hard PHY
//***************************************************************************
generate
if (tCK > 2500) begin: gen_byte_sel_div2
always @(posedge clk) begin
if (rst) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b0;
end else if (~(dqs_po_dec_done && pi_fine_dly_dec_done)) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~ck_addr_cmd_delay_done && (WRLVL !="ON")) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~ck_addr_cmd_delay_done) begin
ctl_lane_sel <= #TCQ ctl_lane_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~fine_adjust_done && rd_data_offset_cal_done) begin
if ((|pi_rst_stg1_cal) || (DRAM_TYPE == "DDR2")) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ fine_adjust_lane_cnt;
calib_in_common <= #TCQ 1'b0;
end
end else if (~pi_calib_done) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~pi_dqs_found_done) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~wrlvl_done_w) begin
if (SIM_CAL_OPTION != "FAST_CAL") begin
byte_sel_cnt <= #TCQ po_stg2_wl_cnt;
calib_in_common <= #TCQ 1'b0;
end else begin
// Special case for FAST_CAL simulation only to ensure that
// calib_in_common isn't asserted too soon
if (!phy_ctl_rdy_dly) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b0;
end else begin
byte_sel_cnt <= #TCQ po_stg2_wl_cnt;
calib_in_common <= #TCQ 1'b1;
end
end
end else if (~mpr_rdlvl_done) begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~oclkdelay_calib_done) begin
byte_sel_cnt <= #TCQ oclkdelay_calib_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~rdlvl_stg1_done && pi_calib_done) begin
if ((SIM_CAL_OPTION == "FAST_CAL") && rdlvl_assrt_common) begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b1;
end else begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end
end else if (~prbs_rdlvl_done && rdlvl_stg1_done) begin
byte_sel_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~complex_oclkdelay_calib_done_w && prbs_rdlvl_done) begin
byte_sel_cnt <= #TCQ complex_oclkdelay_calib_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~wrcal_done) begin
byte_sel_cnt <= #TCQ po_stg2_wrcal_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (dbg_sel_pi_incdec_r | dbg_sel_po_incdec_r) begin
byte_sel_cnt <= #TCQ dbg_byte_sel;
calib_in_common <= #TCQ 1'b0;
end else if (tempmon_sel_pi_incdec) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end
end
end else begin: gen_byte_sel_div1
always @(posedge clk) begin
if (rst) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b0;
end else if (~(dqs_po_dec_done && pi_fine_dly_dec_done)) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~ck_addr_cmd_delay_done && (WRLVL !="ON")) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~ck_addr_cmd_delay_done) begin
ctl_lane_sel <= #TCQ ctl_lane_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~fine_adjust_done && rd_data_offset_cal_done) begin
if ((|pi_rst_stg1_cal) || (DRAM_TYPE == "DDR2")) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ fine_adjust_lane_cnt;
calib_in_common <= #TCQ 1'b0;
end
end else if (~pi_calib_done) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~pi_dqs_found_done) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~wrlvl_done_w) begin
if (SIM_CAL_OPTION != "FAST_CAL") begin
byte_sel_cnt <= #TCQ po_stg2_wl_cnt;
calib_in_common <= #TCQ 1'b0;
end else begin
// Special case for FAST_CAL simulation only to ensure that
// calib_in_common isn't asserted too soon
if (!phy_ctl_rdy_dly) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b0;
end else begin
byte_sel_cnt <= #TCQ po_stg2_wl_cnt;
calib_in_common <= #TCQ 1'b1;
end
end
end else if (~mpr_rdlvl_done) begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~oclkdelay_calib_done) begin
byte_sel_cnt <= #TCQ oclkdelay_calib_cnt;
calib_in_common <= #TCQ 1'b0;
end else if ((~wrcal_done)&& (DRAM_TYPE == "DDR3")) begin
byte_sel_cnt <= #TCQ po_stg2_wrcal_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~rdlvl_stg1_done && pi_calib_done) begin
if ((SIM_CAL_OPTION == "FAST_CAL") && rdlvl_assrt_common) begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b1;
end else begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end
end else if (~prbs_rdlvl_done && rdlvl_stg1_done) begin
byte_sel_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~complex_oclkdelay_calib_done_w && prbs_rdlvl_done) begin
byte_sel_cnt <= #TCQ complex_oclkdelay_calib_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (dbg_sel_pi_incdec_r | dbg_sel_po_incdec_r) begin
byte_sel_cnt <= #TCQ dbg_byte_sel;
calib_in_common <= #TCQ 1'b0;
end else if (tempmon_sel_pi_incdec) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end
end
end
endgenerate
// verilint STARC-2.2.3.3 off
always @(posedge clk) begin
if (rst || (calib_complete && ~ (dbg_sel_pi_incdec_r|dbg_sel_po_incdec_r|tempmon_sel_pi_incdec) )) begin
calib_sel <= #TCQ 6'b000100;
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b1}};
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else if (~(dqs_po_dec_done && pi_fine_dly_dec_done)) begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
if (~dqs_po_dec_done && (WRLVL != "ON"))
//if (~dqs_po_dec_done && ((SIM_CAL_OPTION == "FAST_CAL") ||(WRLVL != "ON")))
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b0}};
else
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else if (~ck_addr_cmd_delay_done || (~fine_adjust_done && rd_data_offset_cal_done)) begin
if(WRLVL =="ON") begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ CTL_BYTE_LANE[(ctl_lane_sel*2)+:2];
calib_sel[5:3] <= #TCQ CTL_BANK;
if (|pi_rst_stg1_cal) begin
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
end else begin
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b1}};
calib_zero_inputs[1*CTL_BANK] <= #TCQ 1'b0;
end
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else begin // if (WRLVL =="ON")
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
if(~ck_addr_cmd_delay_done)
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
else
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b0}};
end // else: !if(WRLVL =="ON")
end else if ((~wrlvl_done_w) && (SIM_CAL_OPTION == "FAST_CAL")) begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else if (~rdlvl_stg1_done && (SIM_CAL_OPTION == "FAST_CAL") &&
rdlvl_assrt_common) begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else if (tempmon_sel_pi_incdec) begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
if (~calib_in_common) begin
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b1}};
calib_zero_inputs[(1*DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3])] <= #TCQ 1'b0;
end else
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
end
end
// verilint STARC-2.2.3.3 on
// Logic to reset IN_FIFO flags to account for the possibility that
// one or more PHASER_IN's have not correctly found the DQS preamble
// If this happens, we can still complete read leveling, but the # of
// words written into the IN_FIFO's may be an odd #, so that if the
// IN_FIFO is used in 2:1 mode ("8:4 mode"), there may be a "half" word
// of data left that can only be flushed out by reseting the IN_FIFO
always @(posedge clk) begin
rdlvl_stg1_done_r1 <= #TCQ rdlvl_stg1_done;
prbs_rdlvl_done_r1 <= #TCQ prbs_rdlvl_done;
reset_if_r1 <= #TCQ reset_if;
reset_if_r2 <= #TCQ reset_if_r1;
reset_if_r3 <= #TCQ reset_if_r2;
reset_if_r4 <= #TCQ reset_if_r3;
reset_if_r5 <= #TCQ reset_if_r4;
reset_if_r6 <= #TCQ reset_if_r5;
reset_if_r7 <= #TCQ reset_if_r6;
reset_if_r8 <= #TCQ reset_if_r7;
reset_if_r9 <= #TCQ reset_if_r8;
end
always @(posedge clk) begin
if (rst || reset_if_r9)
reset_if <= #TCQ 1'b0;
else if ((rdlvl_stg1_done && ~rdlvl_stg1_done_r1) ||
(prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
reset_if <= #TCQ 1'b1;
end
assign phy_if_empty_def = 1'b0;
// DQ IDELAY tap inc and ce signals registered to control calib_in_common
// signal during read leveling in FAST_CAL mode. The calib_in_common signal
// is only asserted for IDELAY tap increments not Phaser_IN tap increments
// in FAST_CAL mode. For Phaser_IN tap increments the Phaser_IN counter load
// inputs are used.
always @(posedge clk) begin
if (rst) begin
idelay_ce_r1 <= #TCQ 1'b0;
idelay_ce_r2 <= #TCQ 1'b0;
idelay_inc_r1 <= #TCQ 1'b0;
idelay_inc_r2 <= #TCQ 1'b0;
end else begin
idelay_ce_r1 <= #TCQ idelay_ce_int;
idelay_ce_r2 <= #TCQ idelay_ce_r1;
idelay_inc_r1 <= #TCQ idelay_inc_int;
idelay_inc_r2 <= #TCQ idelay_inc_r1;
end
end
//***************************************************************************
// Delay all Outputs using Phaser_Out fine taps
//***************************************************************************
assign init_wrcal_complete = 1'b0;
//***************************************************************************
// PRBS Generator for Read Leveling Stage 1 - read window detection and
// DQS Centering
//***************************************************************************
// Assign initial seed (used for 1st data word in 8-burst sequence); use alternating 1/0 pat
assign prbs_seed = 64'h9966aa559966aa55;
// A single PRBS generator
// writes 64-bits every 4to1 fabric clock cycle and
// write 32-bits every 2to1 fabric clock cycle
// used for complex read leveling and complex oclkdealy calib
mig_7series_v2_3_ddr_prbs_gen #
(
.TCQ (TCQ),
.PRBS_WIDTH (2*8*nCK_PER_CLK),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.VCCO_PAT_EN (VCCO_PAT_EN),
.VCCAUX_PAT_EN (VCCAUX_PAT_EN),
.ISI_PAT_EN (ISI_PAT_EN),
.FIXED_VICTIM (FIXED_VICTIM)
)
u_ddr_prbs_gen
(.prbs_ignore_first_byte (prbs_ignore_first_byte),
.prbs_ignore_last_bytes (prbs_ignore_last_bytes),
.clk_i (clk),
.clk_en_i (prbs_gen_clk_en | prbs_gen_oclk_clk_en),
.rst_i (rst),
.prbs_o (prbs_out),
.prbs_seed_i (prbs_seed),
.phy_if_empty (phy_if_empty),
.prbs_rdlvl_start (prbs_rdlvl_start),
.prbs_rdlvl_done (prbs_rdlvl_done),
.complex_wr_done (complex_wr_done),
.victim_sel (victim_sel),
.byte_cnt (victim_byte_cnt),
.dbg_prbs_gen (),
.reset_rd_addr (reset_rd_addr | complex_ocal_reset_rd_addr)
);
// PRBS data slice that decides the Rise0, Fall0, Rise1, Fall1,
// Rise2, Fall2, Rise3, Fall3 data
generate
if (nCK_PER_CLK == 4) begin: gen_ck_per_clk4
assign prbs_o = prbs_out;
/*assign prbs_rise0 = prbs_out[7:0];
assign prbs_fall0 = prbs_out[15:8];
assign prbs_rise1 = prbs_out[23:16];
assign prbs_fall1 = prbs_out[31:24];
assign prbs_rise2 = prbs_out[39:32];
assign prbs_fall2 = prbs_out[47:40];
assign prbs_rise3 = prbs_out[55:48];
assign prbs_fall3 = prbs_out[63:56];
assign prbs_o = {prbs_fall3, prbs_rise3, prbs_fall2, prbs_rise2,
prbs_fall1, prbs_rise1, prbs_fall0, prbs_rise0};*/
end else begin :gen_ck_per_clk2
assign prbs_o = prbs_out[4*DQ_WIDTH-1:0];
/*assign prbs_rise0 = prbs_out[7:0];
assign prbs_fall0 = prbs_out[15:8];
assign prbs_rise1 = prbs_out[23:16];
assign prbs_fall1 = prbs_out[31:24];
assign prbs_o = {prbs_fall1, prbs_rise1, prbs_fall0, prbs_rise0};*/
end
endgenerate
//***************************************************************************
// Initialization / Master PHY state logic (overall control during memory
// init, timing leveling)
//***************************************************************************
mig_7series_v2_3_ddr_phy_init #
(
.tCK (tCK),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.CLK_PERIOD (CLK_PERIOD),
.DRAM_TYPE (DRAM_TYPE),
.PRBS_WIDTH (PRBS_WIDTH),
.BANK_WIDTH (BANK_WIDTH),
.CA_MIRROR (CA_MIRROR),
.COL_WIDTH (COL_WIDTH),
.nCS_PER_RANK (nCS_PER_RANK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.CS_WIDTH (CS_WIDTH),
.RANKS (RANKS),
.CKE_WIDTH (CKE_WIDTH),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.AL (AL),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.nCL (nCL),
.nCWL (nCWL),
.tRFC (tRFC),
.REFRESH_TIMER (REFRESH_TIMER),
.REFRESH_TIMER_WIDTH (REFRESH_TIMER_WIDTH),
.OUTPUT_DRV (OUTPUT_DRV),
.REG_CTRL (REG_CTRL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.WRLVL (WRLVL),
.USE_ODT_PORT (USE_ODT_PORT),
.DDR2_DQSN_ENABLE(DDR2_DQSN_ENABLE),
.nSLOTS (nSLOTS),
.SIM_INIT_OPTION (SIM_INIT_OPTION),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.CKE_ODT_AUX (CKE_ODT_AUX),
.PRE_REV3ES (PRE_REV3ES),
.TEST_AL (TEST_AL),
.FIXED_VICTIM (FIXED_VICTIM),
.BYPASS_COMPLEX_OCAL(BYPASS_COMPLEX_OCAL)
)
u_ddr_phy_init
(
.clk (clk),
.rst (rst),
.prbs_o (prbs_o),
.ck_addr_cmd_delay_done(ck_addr_cmd_delay_done),
.delay_incdec_done (ck_addr_cmd_delay_done),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_phaselock_start (pi_phaselock_start),
.pi_phase_locked_err (phase_locked_err),
.pi_calib_done (pi_calib_done),
.phy_if_empty (phy_if_empty),
.phy_ctl_ready (phy_ctl_ready),
.phy_ctl_full (phy_ctl_full),
.phy_cmd_full (phy_cmd_full),
.phy_data_full (phy_data_full),
.calib_ctl_wren (calib_ctl_wren),
.calib_cmd_wren (calib_cmd_wren),
.calib_wrdata_en (calib_wrdata_en),
.calib_seq (calib_seq),
.calib_aux_out (calib_aux_out),
.calib_rank_cnt (calib_rank_cnt),
.calib_cas_slot (calib_cas_slot),
.calib_data_offset_0 (calib_data_offset_0),
.calib_data_offset_1 (calib_data_offset_1),
.calib_data_offset_2 (calib_data_offset_2),
.calib_cmd (calib_cmd),
.calib_cke (calib_cke),
.calib_odt (calib_odt),
.write_calib (write_calib),
.read_calib (read_calib),
.wrlvl_done (wrlvl_done),
.wrlvl_rank_done (wrlvl_rank_done),
.wrlvl_byte_done (wrlvl_byte_done),
.wrlvl_byte_redo (wrlvl_byte_redo),
.wrlvl_final (wrlvl_final_mux),
.wrlvl_final_if_rst (wrlvl_final_if_rst),
.oclkdelay_calib_start (oclkdelay_calib_start),
.oclkdelay_calib_done (oclkdelay_calib_done),
.oclk_prech_req (oclk_prech_req),
.oclk_calib_resume (oclk_calib_resume),
.lim_wr_req (lim2init_write_request),
.lim_done (lim_done),
.complex_oclkdelay_calib_start (complex_oclkdelay_calib_start),
.complex_oclkdelay_calib_done (complex_oclkdelay_calib_done_w),
.complex_oclk_calib_resume (complex_oclk_calib_resume),
.complex_oclkdelay_calib_cnt (complex_oclkdelay_calib_cnt),
.complex_sample_cnt_inc_ocal (complex_sample_cnt_inc_ocal),
.complex_ocal_num_samples_inc (complex_ocal_num_samples_inc),
.complex_ocal_num_samples_done_r (complex_ocal_num_samples_done_r),
.complex_ocal_reset_rd_addr (complex_ocal_reset_rd_addr),
.complex_ocal_ref_req (complex_ocal_ref_req),
.complex_ocal_ref_done (complex_ocal_ref_done),
.done_dqs_tap_inc (done_dqs_tap_inc),
.wl_sm_start (wl_sm_start),
.wr_lvl_start (wrlvl_start),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
.mpr_rdlvl_done (mpr_rdlvl_done),
.mpr_rdlvl_start (mpr_rdlvl_start),
.mpr_last_byte_done (mpr_last_byte_done),
.mpr_rnk_done (mpr_rnk_done),
.mpr_end_if_reset (mpr_end_if_reset),
.rdlvl_stg1_done (rdlvl_stg1_done),
.rdlvl_stg1_rank_done (rdlvl_stg1_rank_done),
.rdlvl_stg1_start (rdlvl_stg1_start),
.rdlvl_prech_req (rdlvl_prech_req),
.rdlvl_last_byte_done (rdlvl_last_byte_done),
.prbs_rdlvl_start (prbs_rdlvl_start),
.complex_wr_done (complex_wr_done),
.prbs_rdlvl_done (prbs_rdlvl_done),
.prbs_last_byte_done (prbs_last_byte_done),
.prbs_rdlvl_prech_req (prbs_rdlvl_prech_req),
.complex_victim_inc (complex_victim_inc),
.rd_victim_sel (rd_victim_sel),
.complex_ocal_rd_victim_sel (complex_ocal_rd_victim_sel),
.pi_stg2_prbs_rdlvl_cnt(pi_stg2_prbs_rdlvl_cnt),
.victim_sel (victim_sel),
.victim_byte_cnt (victim_byte_cnt),
.prbs_gen_clk_en (prbs_gen_clk_en),
.prbs_gen_oclk_clk_en (prbs_gen_oclk_clk_en),
.complex_sample_cnt_inc(complex_sample_cnt_inc),
.pi_dqs_found_start (pi_dqs_found_start),
.dqsfound_retry (dqsfound_retry),
.dqs_found_prech_req (dqs_found_prech_req),
.pi_dqs_found_rank_done(pi_dqs_found_rank_done),
.pi_dqs_found_done (pi_dqs_found_done),
.detect_pi_found_dqs (detect_pi_found_dqs),
.rd_data_offset_0 (rd_data_offset_0),
.rd_data_offset_1 (rd_data_offset_1),
.rd_data_offset_2 (rd_data_offset_2),
.rd_data_offset_ranks_0(rd_data_offset_ranks_0),
.rd_data_offset_ranks_1(rd_data_offset_ranks_1),
.rd_data_offset_ranks_2(rd_data_offset_ranks_2),
.wrcal_start (wrcal_start),
.wrcal_rd_wait (wrcal_rd_wait),
.wrcal_prech_req (wrcal_prech_req),
.wrcal_resume (wrcal_resume_w),
.wrcal_read_req (wrcal_read_req),
.wrcal_act_req (wrcal_act_req),
.wrcal_sanity_chk (wrcal_sanity_chk),
.temp_wrcal_done (temp_wrcal_done),
.wrcal_sanity_chk_done (wrcal_sanity_chk_done),
.tg_timer_done (tg_timer_done),
.no_rst_tg_mc (no_rst_tg_mc),
.wrcal_done (wrcal_done),
.prech_done (prech_done),
.calib_writes (calib_writes),
.init_calib_complete (calib_complete),
.phy_address (phy_address),
.phy_bank (phy_bank),
.phy_cas_n (phy_cas_n),
.phy_cs_n (phy_cs_n),
.phy_ras_n (phy_ras_n),
.phy_reset_n (phy_reset_n),
.phy_we_n (phy_we_n),
.phy_wrdata (phy_wrdata),
.phy_rddata_en (phy_rddata_en),
.phy_rddata_valid (phy_rddata_valid),
.dbg_phy_init (dbg_phy_init),
.read_pause (read_pause),
.reset_rd_addr (reset_rd_addr | complex_ocal_reset_rd_addr),
.oclkdelay_center_calib_start (oclkdelay_center_calib_start),
.oclk_center_write_resume (oclk_center_write_resume),
.oclkdelay_center_calib_done (oclkdelay_center_calib_done)
);
//*****************************************************************
// Write Calibration
//*****************************************************************
mig_7series_v2_3_ddr_phy_wrcal #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.CLK_PERIOD (CLK_PERIOD),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.SIM_CAL_OPTION (SIM_CAL_OPTION)
)
u_ddr_phy_wrcal
(
.clk (clk),
.rst (rst),
.wrcal_start (wrcal_start),
.wrcal_rd_wait (wrcal_rd_wait),
.wrcal_sanity_chk (wrcal_sanity_chk),
.dqsfound_retry_done (pi_dqs_found_done),
.dqsfound_retry (dqsfound_retry),
.wrcal_read_req (wrcal_read_req),
.wrcal_act_req (wrcal_act_req),
.phy_rddata_en (phy_rddata_en),
.wrcal_done (wrcal_done),
.wrcal_pat_err (wrcal_pat_err),
.wrcal_prech_req (wrcal_prech_req),
.temp_wrcal_done (temp_wrcal_done),
.wrcal_sanity_chk_done (wrcal_sanity_chk_done),
.prech_done (prech_done),
.rd_data (phy_rddata),
.wrcal_pat_resume (wrcal_pat_resume),
.po_stg2_wrcal_cnt (po_stg2_wrcal_cnt),
.phy_if_reset (phy_if_reset_w),
.wl_po_coarse_cnt (wl_po_coarse_cnt),
.wl_po_fine_cnt (wl_po_fine_cnt),
.wrlvl_byte_redo (wrlvl_byte_redo),
.wrlvl_byte_done (wrlvl_byte_done),
.early1_data (early1_data),
.early2_data (early2_data),
.idelay_ld (idelay_ld),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt)
);
//***************************************************************************
// Write-leveling calibration logic
//***************************************************************************
generate
if (WRLVL == "ON") begin: mb_wrlvl_inst
mig_7series_v2_3_ddr_phy_wrlvl #
(
.TCQ (TCQ),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.RANKS (1),
.CLK_PERIOD (CLK_PERIOD),
.nCK_PER_CLK (nCK_PER_CLK),
.SIM_CAL_OPTION (SIM_CAL_OPTION)
)
u_ddr_phy_wrlvl
(
.clk (clk),
.rst (rst),
.phy_ctl_ready (phy_ctl_ready),
.wr_level_start (wrlvl_start),
.wl_sm_start (wl_sm_start),
.wrlvl_byte_redo (wrlvl_byte_redo),
.wrcal_cnt (po_stg2_wrcal_cnt),
.early1_data (early1_data),
.early2_data (early2_data),
.wrlvl_final (wrlvl_final_mux),
.oclkdelay_calib_cnt (oclkdelay_calib_cnt),
.wrlvl_byte_done (wrlvl_byte_done),
.oclkdelay_calib_done (oclkdelay_calib_done),
.rd_data_rise0 (phy_rddata[DQ_WIDTH-1:0]),
.dqs_po_dec_done (dqs_po_dec_done),
.phy_ctl_rdy_dly (phy_ctl_rdy_dly),
.wr_level_done (wrlvl_done),
.wrlvl_rank_done (wrlvl_rank_done),
.done_dqs_tap_inc (done_dqs_tap_inc),
.dqs_po_stg2_f_incdec (dqs_po_stg2_f_incdec),
.dqs_po_en_stg2_f (dqs_po_en_stg2_f),
.dqs_wl_po_stg2_c_incdec (dqs_wl_po_stg2_c_incdec),
.dqs_wl_po_en_stg2_c (dqs_wl_po_en_stg2_c),
.po_counter_read_val (po_counter_read_val),
.po_stg2_wl_cnt (po_stg2_wl_cnt),
.wrlvl_err (wrlvl_err),
.wl_po_coarse_cnt (wl_po_coarse_cnt),
.wl_po_fine_cnt (wl_po_fine_cnt),
.dbg_wl_tap_cnt (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_dqs_count (),
.dbg_wl_state (),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl)
);
mig_7series_v2_3_ddr_phy_ck_addr_cmd_delay #
(
.TCQ (TCQ),
.tCK (tCK),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.N_CTL_LANES (N_CTL_LANES),
.SIM_CAL_OPTION(SIM_CAL_OPTION)
)
u_ddr_phy_ck_addr_cmd_delay
(
.clk (clk),
.rst (rst),
.cmd_delay_start (dqs_po_dec_done & pi_fine_dly_dec_done),
.ctl_lane_cnt (ctl_lane_cnt),
.po_stg2_f_incdec (cmd_po_stg2_f_incdec),
.po_en_stg2_f (cmd_po_en_stg2_f),
.po_stg2_c_incdec (cmd_po_stg2_c_incdec),
.po_en_stg2_c (cmd_po_en_stg2_c),
.po_ck_addr_cmd_delay_done (po_ck_addr_cmd_delay_done)
);
assign cmd_po_stg2_incdec_ddr2_c = 1'b0;
assign cmd_po_en_stg2_ddr2_c = 1'b0;
end else begin: mb_wrlvl_off
mig_7series_v2_3_ddr_phy_wrlvl_off_delay #
(
.TCQ (TCQ),
.tCK (tCK),
.nCK_PER_CLK (nCK_PER_CLK),
.CLK_PERIOD (CLK_PERIOD),
.PO_INITIAL_DLY(60),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.N_CTL_LANES (N_CTL_LANES)
)
u_phy_wrlvl_off_delay
(
.clk (clk),
.rst (rst),
.pi_fine_dly_dec_done (pi_fine_dly_dec_done),
.cmd_delay_start (phy_ctl_ready),
.ctl_lane_cnt (ctl_lane_cnt),
.po_s2_incdec_f (cmd_po_stg2_f_incdec),
.po_en_s2_f (cmd_po_en_stg2_f),
.po_s2_incdec_c (cmd_po_stg2_incdec_ddr2_c),
.po_en_s2_c (cmd_po_en_stg2_ddr2_c),
.po_ck_addr_cmd_delay_done (po_ck_addr_cmd_delay_done),
.po_dec_done (dqs_po_dec_done),
.phy_ctl_rdy_dly (phy_ctl_rdy_dly)
);
assign wrlvl_byte_done = 1'b1;
assign wrlvl_rank_done = 1'b1;
assign po_stg2_wl_cnt = 'h0;
assign wl_po_coarse_cnt = 'h0;
assign wl_po_fine_cnt = 'h0;
assign dbg_tap_cnt_during_wrlvl = 'h0;
assign dbg_wl_edge_detect_valid = 'h0;
assign dbg_rd_data_edge_detect = 'h0;
assign dbg_wrlvl_fine_tap_cnt = 'h0;
assign dbg_wrlvl_coarse_tap_cnt = 'h0;
assign dbg_phy_wrlvl = 'h0;
assign wrlvl_done = 1'b1;
assign wrlvl_err = 1'b0;
assign dqs_po_stg2_f_incdec = 1'b0;
assign dqs_po_en_stg2_f = 1'b0;
assign dqs_wl_po_en_stg2_c = 1'b0;
assign cmd_po_stg2_c_incdec = 1'b0;
assign dqs_wl_po_stg2_c_incdec = 1'b0;
assign cmd_po_en_stg2_c = 1'b0;
end
endgenerate
generate
if((WRLVL == "ON") && (OCAL_EN == "ON")) begin: oclk_calib
localparam SAMPCNTRWIDTH = 17;
localparam SAMPLES = (SIM_CAL_OPTION=="NONE") ? 2048 : 4;
localparam TAPCNTRWIDTH = clogb2(TAPSPERKCLK);
localparam MMCM_SAMP_WAIT = (SIM_CAL_OPTION=="NONE") ? 256 : 10;
localparam OCAL_SIMPLE_SCAN_SAMPS = (SIM_CAL_OPTION=="NONE") ? 2048 : 1;
localparam POC_PCT_SAMPS_SOLID = 80;
localparam SCAN_PCT_SAMPS_SOLID = 95;
mig_7series_v2_3_ddr_phy_oclkdelay_cal #
(/*AUTOINSTPARAM*/
// Parameters
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
//.DRAM_TYPE (DRAM_TYPE),
.DRAM_WIDTH (DRAM_WIDTH),
//.OCAL_EN (OCAL_EN),
.OCAL_SIMPLE_SCAN_SAMPS (OCAL_SIMPLE_SCAN_SAMPS),
.PCT_SAMPS_SOLID (POC_PCT_SAMPS_SOLID),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP),
.SCAN_PCT_SAMPS_SOLID (SCAN_PCT_SAMPS_SOLID),
.SAMPCNTRWIDTH (SAMPCNTRWIDTH),
.SAMPLES (SAMPLES),
.MMCM_SAMP_WAIT (MMCM_SAMP_WAIT),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.TAPCNTRWIDTH (TAPCNTRWIDTH),
.TAPSPERKCLK (TAPSPERKCLK),
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.BYPASS_COMPLEX_OCAL (BYPASS_COMPLEX_OCAL)
//.tCK (tCK)
)
u_ddr_phy_oclkdelay_cal
(/*AUTOINST*/
// Outputs
.prbs_ignore_first_byte (prbs_ignore_first_byte),
.prbs_ignore_last_bytes (prbs_ignore_last_bytes),
.complex_oclkdelay_calib_done (complex_oclkdelay_calib_done),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data[16*DRAM_WIDTH-1:0]),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal[255:0]),
.lim2init_write_request (lim2init_write_request),
.lim_done (lim_done),
.oclk_calib_resume (oclk_calib_resume),
//.oclk_init_delay_done (oclk_init_delay_done),
.oclk_prech_req (oclk_prech_req),
.oclkdelay_calib_cnt (oclkdelay_calib_cnt[DQS_CNT_WIDTH:0]),
.oclkdelay_calib_done (oclkdelay_calib_done),
.po_en_stg23 (po_en_stg23),
//.po_en_stg3 (po_en_stg3),
.po_stg23_incdec (po_stg23_incdec),
.po_stg23_sel (po_stg23_sel),
//.po_stg3_incdec (po_stg3_incdec),
.psen (psen),
.psincdec (psincdec),
.wrlvl_final (wrlvl_final),
.rd_victim_sel (complex_ocal_rd_victim_sel),
.ocal_num_samples_done_r (complex_ocal_num_samples_done_r),
.complex_wrlvl_final (complex_wrlvl_final),
.poc_error (poc_error),
// Inputs
.clk (clk),
.complex_oclkdelay_calib_start (complex_oclkdelay_calib_start_w),
.metaQ (pd_out),
//.oclk_init_delay_start (oclk_init_delay_start),
.po_counter_read_val (po_counter_read_val),
.oclkdelay_calib_start (oclkdelay_calib_start),
.oclkdelay_init_val (oclkdelay_init_val[5:0]),
.poc_sample_pd (poc_sample_pd),
.phy_rddata (phy_rddata[2*nCK_PER_CLK*DQ_WIDTH-1:0]),
.phy_rddata_en (phy_rddata_en),
.prbs_o (prbs_o[2*nCK_PER_CLK*DQ_WIDTH-1:0]),
.prech_done (prech_done),
.psdone (psdone),
.rst (rst),
.wl_po_fine_cnt (wl_po_fine_cnt[6*DQS_WIDTH-1:0]),
.ocal_num_samples_inc (complex_ocal_num_samples_inc),
.oclkdelay_center_calib_start (oclkdelay_center_calib_start),
.oclk_center_write_resume (oclk_center_write_resume),
.oclkdelay_center_calib_done (oclkdelay_center_calib_done),
.dbg_ocd_lim (dbg_ocd_lim));
end else begin : oclk_calib_disabled
assign wrlvl_final = 'b0;
assign psen = 'b0;
assign psincdec = 'b0;
assign po_stg23_sel = 'b0;
assign po_stg23_incdec = 'b0;
assign po_en_stg23 = 'b0;
//assign oclk_init_delay_done = 1'b1;
assign oclkdelay_calib_cnt = 'b0;
assign oclk_prech_req = 'b0;
assign oclk_calib_resume = 'b0;
assign oclkdelay_calib_done = 1'b1;
assign dbg_phy_oclkdelay_cal = 'h0;
assign dbg_oclkdelay_rd_data = 'h0;
end
endgenerate
//***************************************************************************
// Read data-offset calibration required for Phaser_In
//***************************************************************************
generate
if(DQSFOUND_CAL == "RIGHT") begin: dqsfind_calib_right
mig_7series_v2_3_ddr_phy_dqs_found_cal #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.nCL (nCL),
.AL (AL),
.nCWL (nCWL),
//.RANKS (RANKS),
.RANKS (1),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.REG_CTRL (REG_CTRL),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DRAM_TYPE (DRAM_TYPE),
.NUM_DQSFOUND_CAL (NUM_DQSFOUND_CAL),
.N_CTL_LANES (DQS_FOUND_N_CTL_LANES),
.HIGHEST_LANE (HIGHEST_LANE),
.HIGHEST_BANK (HIGHEST_BANK),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4)
)
u_ddr_phy_dqs_found_cal
(
.clk (clk),
.rst (rst),
.pi_dqs_found_start (pi_dqs_found_start),
.dqsfound_retry (dqsfound_retry),
.detect_pi_found_dqs (detect_pi_found_dqs),
.prech_done (prech_done),
.pi_dqs_found_lanes (pi_dqs_found_lanes),
.pi_rst_stg1_cal (pi_rst_stg1_cal),
.rd_data_offset_0 (rd_data_offset_0),
.rd_data_offset_1 (rd_data_offset_1),
.rd_data_offset_2 (rd_data_offset_2),
.pi_dqs_found_rank_done (pi_dqs_found_rank_done),
.pi_dqs_found_done (pi_dqs_found_done),
.dqsfound_retry_done (dqsfound_retry_done),
.dqs_found_prech_req (dqs_found_prech_req),
.pi_dqs_found_err (pi_dqs_found_err),
.rd_data_offset_ranks_0 (rd_data_offset_ranks_0),
.rd_data_offset_ranks_1 (rd_data_offset_ranks_1),
.rd_data_offset_ranks_2 (rd_data_offset_ranks_2),
.rd_data_offset_ranks_mc_0 (rd_data_offset_ranks_mc_0),
.rd_data_offset_ranks_mc_1 (rd_data_offset_ranks_mc_1),
.rd_data_offset_ranks_mc_2 (rd_data_offset_ranks_mc_2),
.po_counter_read_val (po_counter_read_val),
.rd_data_offset_cal_done (rd_data_offset_cal_done),
.fine_adjust_done (fine_adjust_done),
.fine_adjust_lane_cnt (fine_adjust_lane_cnt),
.ck_po_stg2_f_indec (ck_po_stg2_f_indec),
.ck_po_stg2_f_en (ck_po_stg2_f_en),
.dbg_dqs_found_cal (dbg_dqs_found_cal)
);
end else begin: dqsfind_calib_left
mig_7series_v2_3_ddr_phy_dqs_found_cal_hr #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.nCL (nCL),
.AL (AL),
.nCWL (nCWL),
//.RANKS (RANKS),
.RANKS (1),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.REG_CTRL (REG_CTRL),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DRAM_TYPE (DRAM_TYPE),
.NUM_DQSFOUND_CAL (NUM_DQSFOUND_CAL),
.N_CTL_LANES (DQS_FOUND_N_CTL_LANES),
.HIGHEST_LANE (HIGHEST_LANE),
.HIGHEST_BANK (HIGHEST_BANK),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4)
)
u_ddr_phy_dqs_found_cal_hr
(
.clk (clk),
.rst (rst),
.pi_dqs_found_start (pi_dqs_found_start),
.dqsfound_retry (dqsfound_retry),
.detect_pi_found_dqs (detect_pi_found_dqs),
.prech_done (prech_done),
.pi_dqs_found_lanes (pi_dqs_found_lanes),
.pi_rst_stg1_cal (pi_rst_stg1_cal),
.rd_data_offset_0 (rd_data_offset_0),
.rd_data_offset_1 (rd_data_offset_1),
.rd_data_offset_2 (rd_data_offset_2),
.pi_dqs_found_rank_done (pi_dqs_found_rank_done),
.pi_dqs_found_done (pi_dqs_found_done),
.dqsfound_retry_done (dqsfound_retry_done),
.dqs_found_prech_req (dqs_found_prech_req),
.pi_dqs_found_err (pi_dqs_found_err),
.rd_data_offset_ranks_0 (rd_data_offset_ranks_0),
.rd_data_offset_ranks_1 (rd_data_offset_ranks_1),
.rd_data_offset_ranks_2 (rd_data_offset_ranks_2),
.rd_data_offset_ranks_mc_0 (rd_data_offset_ranks_mc_0),
.rd_data_offset_ranks_mc_1 (rd_data_offset_ranks_mc_1),
.rd_data_offset_ranks_mc_2 (rd_data_offset_ranks_mc_2),
.po_counter_read_val (po_counter_read_val),
.rd_data_offset_cal_done (rd_data_offset_cal_done),
.fine_adjust_done (fine_adjust_done),
.fine_adjust_lane_cnt (fine_adjust_lane_cnt),
.ck_po_stg2_f_indec (ck_po_stg2_f_indec),
.ck_po_stg2_f_en (ck_po_stg2_f_en),
.dbg_dqs_found_cal (dbg_dqs_found_cal)
);
end
endgenerate
//***************************************************************************
// Read-leveling calibration logic
//***************************************************************************
mig_7series_v2_3_ddr_phy_rdlvl #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.CLK_PERIOD (CLK_PERIOD),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.RANKS (1),
.PER_BIT_DESKEW (PER_BIT_DESKEW),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DEBUG_PORT (DEBUG_PORT),
.DRAM_TYPE (DRAM_TYPE),
.OCAL_EN (OCAL_EN),
.IDELAY_ADJ (IDELAY_ADJ)
)
u_ddr_phy_rdlvl
(
.clk (clk),
.rst (rst),
.mpr_rdlvl_done (mpr_rdlvl_done),
.mpr_rdlvl_start (mpr_rdlvl_start),
.mpr_last_byte_done (mpr_last_byte_done),
.mpr_rnk_done (mpr_rnk_done),
.rdlvl_stg1_start (rdlvl_stg1_start),
.rdlvl_stg1_done (rdlvl_stg1_done),
.rdlvl_stg1_rnk_done (rdlvl_stg1_rank_done),
.rdlvl_stg1_err (rdlvl_stg1_err),
.mpr_rdlvl_err (mpr_rdlvl_err),
.rdlvl_err (rdlvl_err),
.rdlvl_prech_req (rdlvl_prech_req),
.rdlvl_last_byte_done (rdlvl_last_byte_done),
.rdlvl_assrt_common (rdlvl_assrt_common),
.prech_done (prech_done),
.phy_if_empty (phy_if_empty),
.idelaye2_init_val (idelaye2_init_val),
.rd_data (phy_rddata),
.pi_en_stg2_f (rdlvl_pi_stg2_f_en),
.pi_stg2_f_incdec (rdlvl_pi_stg2_f_incdec),
.pi_stg2_load (pi_stg2_load),
.pi_stg2_reg_l (pi_stg2_reg_l),
.dqs_po_dec_done (dqs_po_dec_done),
.pi_counter_read_val (pi_counter_read_val),
.pi_fine_dly_dec_done (pi_fine_dly_dec_done),
.idelay_ce (idelay_ce_int),
.idelay_inc (idelay_inc_int),
.idelay_ld (idelay_ld),
.wrcal_cnt (po_stg2_wrcal_cnt),
.pi_stg2_rdlvl_cnt (pi_stg2_rdlvl_cnt),
.dlyval_dq (dlyval_dq),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_phy_rdlvl (dbg_phy_rdlvl)
);
generate
if((DRAM_TYPE == "DDR3") && (nCK_PER_CLK == 4) && (BYPASS_COMPLEX_RDLVL=="FALSE")) begin:ddr_phy_prbs_rdlvl_gen
mig_7series_v2_3_ddr_phy_prbs_rdlvl #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.RANKS (1),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.PRBS_WIDTH (PRBS_WIDTH),
.FIXED_VICTIM (FIXED_VICTIM),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ)
)
u_ddr_phy_prbs_rdlvl
(
.clk (clk),
.rst (rst),
.prbs_rdlvl_start (prbs_rdlvl_start),
.prbs_rdlvl_done (prbs_rdlvl_done),
.prbs_last_byte_done (prbs_last_byte_done),
.prbs_rdlvl_prech_req (prbs_rdlvl_prech_req),
.complex_sample_cnt_inc (complex_sample_cnt_inc),
.prech_done (prech_done),
.phy_if_empty (phy_if_empty),
.rd_data (phy_rddata),
.compare_data (prbs_o),
.pi_counter_read_val (pi_counter_read_val),
.pi_en_stg2_f (prbs_pi_stg2_f_en),
.pi_stg2_f_incdec (prbs_pi_stg2_f_incdec),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.pi_stg2_prbs_rdlvl_cnt (pi_stg2_prbs_rdlvl_cnt),
.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps),
.rd_victim_sel (rd_victim_sel),
.complex_victim_inc (complex_victim_inc),
.reset_rd_addr (reset_rd_addr),
.read_pause (read_pause),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
end else begin:ddr_phy_prbs_rdlvl_off
assign prbs_rdlvl_done = rdlvl_stg1_done ;
//assign prbs_last_byte_done = rdlvl_stg1_rank_done ;
assign prbs_last_byte_done = rdlvl_stg1_done;
assign read_pause = 1'b0;
assign reset_rd_addr = 1'b0;
assign prbs_rdlvl_prech_req = 1'b0 ;
assign prbs_pi_stg2_f_en = 1'b0 ;
assign prbs_pi_stg2_f_incdec = 1'b0 ;
assign pi_stg2_prbs_rdlvl_cnt = 'b0 ;
assign dbg_prbs_rdlvl = 'h0 ;
assign prbs_final_dqs_tap_cnt_r = {(6*DQS_WIDTH*RANKS){1'b0}};
assign dbg_prbs_first_edge_taps = {(6*DQS_WIDTH*RANKS){1'b0}};
assign dbg_prbs_second_edge_taps = {(6*DQS_WIDTH*RANKS){1'b0}};
end
endgenerate
//***************************************************************************
// Temperature induced PI tap adjustment logic
//***************************************************************************
mig_7series_v2_3_ddr_phy_tempmon #
(
.TCQ (TCQ)
)
ddr_phy_tempmon_0
(
.rst (rst),
.clk (clk),
.calib_complete (calib_complete),
.tempmon_pi_f_inc (tempmon_pi_f_inc),
.tempmon_pi_f_dec (tempmon_pi_f_dec),
.tempmon_sel_pi_incdec (tempmon_sel_pi_incdec),
.device_temp (device_temp),
.tempmon_sample_en (tempmon_sample_en)
);
endmodule
|
module
wire lim2init_write_request;
wire lim_done;
// Bypass complex ocal
wire complex_oclkdelay_calib_start_w;
wire complex_oclkdelay_calib_done_w;
wire [2:0] complex_ocal_rd_victim_sel_w;
wire complex_wrlvl_final_w;
wire [255:0] dbg_ocd_lim;
//with MMCM phase detect logic
//wire mmcm_edge_detect_rdy; // ready for MMCM detect
//wire ktap_at_rightedge; // stg3 tap at right edge
//wire ktap_at_leftedge; // stg3 tap at left edge
//wire mmcm_tap_at_center; // indicate stg3 tap at center
//wire mmcm_ps_clkphase_ok; // ps clkphase is OK
//wire mmcm_edge_detect_done; // mmcm edge detect is done
//wire mmcm_lbclk_edges_aligned; // mmcm edge detect is done
//wire reset_mmcm; //mmcm detect logic reset per byte
// wire [255:0] dbg_phy_oclkdelay_center_cal;
//*****************************************************************************
// Assertions to check correctness of parameter values
//*****************************************************************************
// synthesis translate_off
initial
begin
if (RANKS == 0) begin
$display ("Error: Invalid RANKS parameter. Must be 1 or greater");
$finish;
end
if (phy_ctl_full == 1'b1) begin
$display ("Error: Incorrect phy_ctl_full input value in 2:1 or 4:1 mode");
$finish;
end
end
// synthesis translate_on
//***************************************************************************
// Debug
//***************************************************************************
assign dbg_pi_phaselock_start = pi_phaselock_start;
assign dbg_pi_dqsfound_start = pi_dqs_found_start;
assign dbg_pi_dqsfound_done = pi_dqs_found_done;
assign dbg_wrcal_start = wrcal_start;
assign dbg_wrcal_done = wrcal_done;
// Unused for now - use these as needed to bring up lower level signals
assign dbg_calib_top = dbg_ocd_lim;
// Write Level and write calibration debug observation ports
assign dbg_wrlvl_start = wrlvl_start;
assign dbg_wrlvl_done = wrlvl_done;
assign dbg_wrlvl_err = wrlvl_err;
// Read Level debug observation ports
assign dbg_rdlvl_start = {mpr_rdlvl_start, rdlvl_stg1_start};
assign dbg_rdlvl_done = {mpr_rdlvl_done, rdlvl_stg1_done};
assign dbg_rdlvl_err = {mpr_rdlvl_err, rdlvl_err};
assign dbg_oclkdelay_calib_done = oclkdelay_calib_done;
assign dbg_oclkdelay_calib_start = oclkdelay_calib_start;
//***************************************************************************
// Write leveling dependent signals
//***************************************************************************
assign wrcal_resume_w = (WRLVL == "ON") ? wrcal_pat_resume : 1'b0;
assign wrlvl_done_w = (WRLVL == "ON") ? wrlvl_done : 1'b1;
assign ck_addr_cmd_delay_done = (WRLVL == "ON") ? po_ck_addr_cmd_delay_done :
(po_ck_addr_cmd_delay_done
&& pi_fine_dly_dec_done) ;
generate
if((WRLVL == "ON") && (BYPASS_COMPLEX_OCAL=="FALSE")) begin: complex_oclk_calib
assign complex_oclkdelay_calib_start_w = complex_oclkdelay_calib_start;
assign complex_oclkdelay_calib_done_w = complex_oclkdelay_calib_done;
assign complex_ocal_rd_victim_sel_w = complex_ocal_rd_victim_sel;
assign complex_wrlvl_final_w = complex_wrlvl_final;
end else begin: bypass_complex_ocal
assign complex_oclkdelay_calib_start_w = 1'b0;
assign complex_oclkdelay_calib_done_w = prbs_rdlvl_done;
assign complex_ocal_rd_victim_sel_w = 'd0;
assign complex_wrlvl_final_w = 1'b0;
end
endgenerate
generate
genvar i;
for (i = 0; i <= 2; i = i+1) begin : bankwise_signal
assign po_sel_stg2stg3[i] = ((ck_addr_cmd_delay_done && ~oclkdelay_calib_done && mpr_rdlvl_done) ? po_stg23_sel :
(complex_oclkdelay_calib_start_w&&~complex_oclkdelay_calib_done_w? po_stg23_sel : 1'b0 )
// (~oclkdelay_center_calib_done? ocal_ctr_po_stg23_sel:1'b0))
) | dbg_po_f_stg23_sel_r;
assign po_stg2_c_incdec[i] = cmd_po_stg2_c_incdec ||
cmd_po_stg2_incdec_ddr2_c ||
dqs_wl_po_stg2_c_incdec;
assign po_en_stg2_c[i] = cmd_po_en_stg2_c ||
cmd_po_en_stg2_ddr2_c ||
dqs_wl_po_en_stg2_c;
assign po_stg2_f_incdec[i] = dqs_po_stg2_f_incdec ||
cmd_po_stg2_f_incdec ||
//po_stg3_incdec ||
ck_po_stg2_f_indec ||
po_stg23_incdec ||
// complex_po_stg23_incdec ||
// ocal_ctr_po_stg23_incdec ||
dbg_po_f_inc_r;
assign po_en_stg2_f[i] = dqs_po_en_stg2_f ||
cmd_po_en_stg2_f ||
//po_en_stg3 ||
ck_po_stg2_f_en ||
po_en_stg23 ||
// complex_po_en_stg23 ||
// ocal_ctr_po_en_stg23 ||
dbg_po_f_en_r;
end
endgenerate
assign pi_stg2_f_incdec = (dbg_pi_f_inc_r | rdlvl_pi_stg2_f_incdec | prbs_pi_stg2_f_incdec | tempmon_pi_f_inc_r);
assign pi_en_stg2_f = (dbg_pi_f_en_r | rdlvl_pi_stg2_f_en | prbs_pi_stg2_f_en | tempmon_pi_f_en_r);
assign idelay_ce = idelay_ce_r2;
assign idelay_inc = idelay_inc_r2;
assign po_counter_load_en = 1'b0;
assign complex_oclkdelay_calib_cnt = oclkdelay_calib_cnt;
assign complex_oclk_calib_resume = oclk_calib_resume;
assign complex_ocal_ref_req = oclk_prech_req;
// Added single stage flop to meet timing
always @(posedge clk)
init_calib_complete <= calib_complete;
assign calib_rd_data_offset_0 = rd_data_offset_ranks_mc_0;
assign calib_rd_data_offset_1 = rd_data_offset_ranks_mc_1;
assign calib_rd_data_offset_2 = rd_data_offset_ranks_mc_2;
//***************************************************************************
// Hard PHY signals
//***************************************************************************
assign pi_phase_locked_err = phase_locked_err;
assign pi_dqsfound_err = pi_dqs_found_err;
assign wrcal_err = wrcal_pat_err;
assign rst_tg_mc = 1'b0;
//Restart WRLVL after oclkdealy cal
always @ (posedge clk)
wrlvl_final_mux <= #TCQ complex_oclkdelay_calib_start_w? complex_wrlvl_final_w: wrlvl_final;
always @(posedge clk)
phy_if_reset <= #TCQ (phy_if_reset_w | mpr_end_if_reset |
reset_if | wrlvl_final_if_rst);
//***************************************************************************
// Phaser_IN inc dec control for debug
//***************************************************************************
always @(posedge clk) begin
if (rst) begin
dbg_pi_f_inc_r <= #TCQ 1'b0;
dbg_pi_f_en_r <= #TCQ 1'b0;
dbg_sel_pi_incdec_r <= #TCQ 1'b0;
end else begin
dbg_pi_f_inc_r <= #TCQ dbg_pi_f_inc;
dbg_pi_f_en_r <= #TCQ (dbg_pi_f_inc | dbg_pi_f_dec);
dbg_sel_pi_incdec_r <= #TCQ dbg_sel_pi_incdec;
end
end
//***************************************************************************
// Phaser_OUT inc dec control for debug
//***************************************************************************
always @(posedge clk) begin
if (rst) begin
dbg_po_f_inc_r <= #TCQ 1'b0;
dbg_po_f_stg23_sel_r<= #TCQ 1'b0;
dbg_po_f_en_r <= #TCQ 1'b0;
dbg_sel_po_incdec_r <= #TCQ 1'b0;
end else begin
dbg_po_f_inc_r <= #TCQ dbg_po_f_inc;
dbg_po_f_stg23_sel_r<= #TCQ dbg_po_f_stg23_sel;
dbg_po_f_en_r <= #TCQ (dbg_po_f_inc | dbg_po_f_dec);
dbg_sel_po_incdec_r <= #TCQ dbg_sel_po_incdec;
end
end
//***************************************************************************
// Phaser_IN inc dec control for temperature tracking
//***************************************************************************
always @(posedge clk) begin
if (rst) begin
tempmon_pi_f_inc_r <= #TCQ 1'b0;
tempmon_pi_f_en_r <= #TCQ 1'b0;
tempmon_sel_pi_incdec_r <= #TCQ 1'b0;
end else begin
tempmon_pi_f_inc_r <= #TCQ tempmon_pi_f_inc;
tempmon_pi_f_en_r <= #TCQ (tempmon_pi_f_inc | tempmon_pi_f_dec);
tempmon_sel_pi_incdec_r <= #TCQ tempmon_sel_pi_incdec;
end
end
//***************************************************************************
// OCLKDELAY calibration signals
//***************************************************************************
// Minimum of 5 'clk' cycles required between assertion of po_sel_stg2stg3
// and increment/decrement of Phaser_Out stage 3 delay
always @(posedge clk) begin
ck_addr_cmd_delay_done_r1 <= #TCQ ck_addr_cmd_delay_done;
ck_addr_cmd_delay_done_r2 <= #TCQ ck_addr_cmd_delay_done_r1;
ck_addr_cmd_delay_done_r3 <= #TCQ ck_addr_cmd_delay_done_r2;
ck_addr_cmd_delay_done_r4 <= #TCQ ck_addr_cmd_delay_done_r3;
ck_addr_cmd_delay_done_r5 <= #TCQ ck_addr_cmd_delay_done_r4;
ck_addr_cmd_delay_done_r6 <= #TCQ ck_addr_cmd_delay_done_r5;
end
//***************************************************************************
// MUX select logic to select current byte undergoing calibration
// Use DQS_CAL_MAP to determine the correlation between the physical
// byte numbering, and the byte numbering within the hard PHY
//***************************************************************************
generate
if (tCK > 2500) begin: gen_byte_sel_div2
always @(posedge clk) begin
if (rst) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b0;
end else if (~(dqs_po_dec_done && pi_fine_dly_dec_done)) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~ck_addr_cmd_delay_done && (WRLVL !="ON")) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~ck_addr_cmd_delay_done) begin
ctl_lane_sel <= #TCQ ctl_lane_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~fine_adjust_done && rd_data_offset_cal_done) begin
if ((|pi_rst_stg1_cal) || (DRAM_TYPE == "DDR2")) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ fine_adjust_lane_cnt;
calib_in_common <= #TCQ 1'b0;
end
end else if (~pi_calib_done) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~pi_dqs_found_done) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~wrlvl_done_w) begin
if (SIM_CAL_OPTION != "FAST_CAL") begin
byte_sel_cnt <= #TCQ po_stg2_wl_cnt;
calib_in_common <= #TCQ 1'b0;
end else begin
// Special case for FAST_CAL simulation only to ensure that
// calib_in_common isn't asserted too soon
if (!phy_ctl_rdy_dly) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b0;
end else begin
byte_sel_cnt <= #TCQ po_stg2_wl_cnt;
calib_in_common <= #TCQ 1'b1;
end
end
end else if (~mpr_rdlvl_done) begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~oclkdelay_calib_done) begin
byte_sel_cnt <= #TCQ oclkdelay_calib_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~rdlvl_stg1_done && pi_calib_done) begin
if ((SIM_CAL_OPTION == "FAST_CAL") && rdlvl_assrt_common) begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b1;
end else begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end
end else if (~prbs_rdlvl_done && rdlvl_stg1_done) begin
byte_sel_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~complex_oclkdelay_calib_done_w && prbs_rdlvl_done) begin
byte_sel_cnt <= #TCQ complex_oclkdelay_calib_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~wrcal_done) begin
byte_sel_cnt <= #TCQ po_stg2_wrcal_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (dbg_sel_pi_incdec_r | dbg_sel_po_incdec_r) begin
byte_sel_cnt <= #TCQ dbg_byte_sel;
calib_in_common <= #TCQ 1'b0;
end else if (tempmon_sel_pi_incdec) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end
end
end else begin: gen_byte_sel_div1
always @(posedge clk) begin
if (rst) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b0;
end else if (~(dqs_po_dec_done && pi_fine_dly_dec_done)) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~ck_addr_cmd_delay_done && (WRLVL !="ON")) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~ck_addr_cmd_delay_done) begin
ctl_lane_sel <= #TCQ ctl_lane_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~fine_adjust_done && rd_data_offset_cal_done) begin
if ((|pi_rst_stg1_cal) || (DRAM_TYPE == "DDR2")) begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else begin
byte_sel_cnt <= #TCQ 'd0;
ctl_lane_sel <= #TCQ fine_adjust_lane_cnt;
calib_in_common <= #TCQ 1'b0;
end
end else if (~pi_calib_done) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~pi_dqs_found_done) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end else if (~wrlvl_done_w) begin
if (SIM_CAL_OPTION != "FAST_CAL") begin
byte_sel_cnt <= #TCQ po_stg2_wl_cnt;
calib_in_common <= #TCQ 1'b0;
end else begin
// Special case for FAST_CAL simulation only to ensure that
// calib_in_common isn't asserted too soon
if (!phy_ctl_rdy_dly) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b0;
end else begin
byte_sel_cnt <= #TCQ po_stg2_wl_cnt;
calib_in_common <= #TCQ 1'b1;
end
end
end else if (~mpr_rdlvl_done) begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~oclkdelay_calib_done) begin
byte_sel_cnt <= #TCQ oclkdelay_calib_cnt;
calib_in_common <= #TCQ 1'b0;
end else if ((~wrcal_done)&& (DRAM_TYPE == "DDR3")) begin
byte_sel_cnt <= #TCQ po_stg2_wrcal_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~rdlvl_stg1_done && pi_calib_done) begin
if ((SIM_CAL_OPTION == "FAST_CAL") && rdlvl_assrt_common) begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b1;
end else begin
byte_sel_cnt <= #TCQ pi_stg2_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end
end else if (~prbs_rdlvl_done && rdlvl_stg1_done) begin
byte_sel_cnt <= #TCQ pi_stg2_prbs_rdlvl_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (~complex_oclkdelay_calib_done_w && prbs_rdlvl_done) begin
byte_sel_cnt <= #TCQ complex_oclkdelay_calib_cnt;
calib_in_common <= #TCQ 1'b0;
end else if (dbg_sel_pi_incdec_r | dbg_sel_po_incdec_r) begin
byte_sel_cnt <= #TCQ dbg_byte_sel;
calib_in_common <= #TCQ 1'b0;
end else if (tempmon_sel_pi_incdec) begin
byte_sel_cnt <= #TCQ 'd0;
calib_in_common <= #TCQ 1'b1;
end
end
end
endgenerate
// verilint STARC-2.2.3.3 off
always @(posedge clk) begin
if (rst || (calib_complete && ~ (dbg_sel_pi_incdec_r|dbg_sel_po_incdec_r|tempmon_sel_pi_incdec) )) begin
calib_sel <= #TCQ 6'b000100;
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b1}};
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else if (~(dqs_po_dec_done && pi_fine_dly_dec_done)) begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
if (~dqs_po_dec_done && (WRLVL != "ON"))
//if (~dqs_po_dec_done && ((SIM_CAL_OPTION == "FAST_CAL") ||(WRLVL != "ON")))
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b0}};
else
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else if (~ck_addr_cmd_delay_done || (~fine_adjust_done && rd_data_offset_cal_done)) begin
if(WRLVL =="ON") begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ CTL_BYTE_LANE[(ctl_lane_sel*2)+:2];
calib_sel[5:3] <= #TCQ CTL_BANK;
if (|pi_rst_stg1_cal) begin
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
end else begin
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b1}};
calib_zero_inputs[1*CTL_BANK] <= #TCQ 1'b0;
end
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else begin // if (WRLVL =="ON")
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
if(~ck_addr_cmd_delay_done)
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
else
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b0}};
end // else: !if(WRLVL =="ON")
end else if ((~wrlvl_done_w) && (SIM_CAL_OPTION == "FAST_CAL")) begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else if (~rdlvl_stg1_done && (SIM_CAL_OPTION == "FAST_CAL") &&
rdlvl_assrt_common) begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else if (tempmon_sel_pi_incdec) begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
end else begin
calib_sel[2] <= #TCQ 1'b0;
calib_sel[1:0] <= #TCQ DQS_BYTE_MAP[(byte_sel_cnt*8)+:2];
calib_sel[5:3] <= #TCQ DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3];
calib_zero_ctrl <= #TCQ {HIGHEST_BANK{1'b1}};
if (~calib_in_common) begin
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b1}};
calib_zero_inputs[(1*DQS_BYTE_MAP[((byte_sel_cnt*8)+4)+:3])] <= #TCQ 1'b0;
end else
calib_zero_inputs <= #TCQ {HIGHEST_BANK{1'b0}};
end
end
// verilint STARC-2.2.3.3 on
// Logic to reset IN_FIFO flags to account for the possibility that
// one or more PHASER_IN's have not correctly found the DQS preamble
// If this happens, we can still complete read leveling, but the # of
// words written into the IN_FIFO's may be an odd #, so that if the
// IN_FIFO is used in 2:1 mode ("8:4 mode"), there may be a "half" word
// of data left that can only be flushed out by reseting the IN_FIFO
always @(posedge clk) begin
rdlvl_stg1_done_r1 <= #TCQ rdlvl_stg1_done;
prbs_rdlvl_done_r1 <= #TCQ prbs_rdlvl_done;
reset_if_r1 <= #TCQ reset_if;
reset_if_r2 <= #TCQ reset_if_r1;
reset_if_r3 <= #TCQ reset_if_r2;
reset_if_r4 <= #TCQ reset_if_r3;
reset_if_r5 <= #TCQ reset_if_r4;
reset_if_r6 <= #TCQ reset_if_r5;
reset_if_r7 <= #TCQ reset_if_r6;
reset_if_r8 <= #TCQ reset_if_r7;
reset_if_r9 <= #TCQ reset_if_r8;
end
always @(posedge clk) begin
if (rst || reset_if_r9)
reset_if <= #TCQ 1'b0;
else if ((rdlvl_stg1_done && ~rdlvl_stg1_done_r1) ||
(prbs_rdlvl_done && ~prbs_rdlvl_done_r1))
reset_if <= #TCQ 1'b1;
end
assign phy_if_empty_def = 1'b0;
// DQ IDELAY tap inc and ce signals registered to control calib_in_common
// signal during read leveling in FAST_CAL mode. The calib_in_common signal
// is only asserted for IDELAY tap increments not Phaser_IN tap increments
// in FAST_CAL mode. For Phaser_IN tap increments the Phaser_IN counter load
// inputs are used.
always @(posedge clk) begin
if (rst) begin
idelay_ce_r1 <= #TCQ 1'b0;
idelay_ce_r2 <= #TCQ 1'b0;
idelay_inc_r1 <= #TCQ 1'b0;
idelay_inc_r2 <= #TCQ 1'b0;
end else begin
idelay_ce_r1 <= #TCQ idelay_ce_int;
idelay_ce_r2 <= #TCQ idelay_ce_r1;
idelay_inc_r1 <= #TCQ idelay_inc_int;
idelay_inc_r2 <= #TCQ idelay_inc_r1;
end
end
//***************************************************************************
// Delay all Outputs using Phaser_Out fine taps
//***************************************************************************
assign init_wrcal_complete = 1'b0;
//***************************************************************************
// PRBS Generator for Read Leveling Stage 1 - read window detection and
// DQS Centering
//***************************************************************************
// Assign initial seed (used for 1st data word in 8-burst sequence); use alternating 1/0 pat
assign prbs_seed = 64'h9966aa559966aa55;
// A single PRBS generator
// writes 64-bits every 4to1 fabric clock cycle and
// write 32-bits every 2to1 fabric clock cycle
// used for complex read leveling and complex oclkdealy calib
mig_7series_v2_3_ddr_prbs_gen #
(
.TCQ (TCQ),
.PRBS_WIDTH (2*8*nCK_PER_CLK),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.VCCO_PAT_EN (VCCO_PAT_EN),
.VCCAUX_PAT_EN (VCCAUX_PAT_EN),
.ISI_PAT_EN (ISI_PAT_EN),
.FIXED_VICTIM (FIXED_VICTIM)
)
u_ddr_prbs_gen
(.prbs_ignore_first_byte (prbs_ignore_first_byte),
.prbs_ignore_last_bytes (prbs_ignore_last_bytes),
.clk_i (clk),
.clk_en_i (prbs_gen_clk_en | prbs_gen_oclk_clk_en),
.rst_i (rst),
.prbs_o (prbs_out),
.prbs_seed_i (prbs_seed),
.phy_if_empty (phy_if_empty),
.prbs_rdlvl_start (prbs_rdlvl_start),
.prbs_rdlvl_done (prbs_rdlvl_done),
.complex_wr_done (complex_wr_done),
.victim_sel (victim_sel),
.byte_cnt (victim_byte_cnt),
.dbg_prbs_gen (),
.reset_rd_addr (reset_rd_addr | complex_ocal_reset_rd_addr)
);
// PRBS data slice that decides the Rise0, Fall0, Rise1, Fall1,
// Rise2, Fall2, Rise3, Fall3 data
generate
if (nCK_PER_CLK == 4) begin: gen_ck_per_clk4
assign prbs_o = prbs_out;
/*assign prbs_rise0 = prbs_out[7:0];
assign prbs_fall0 = prbs_out[15:8];
assign prbs_rise1 = prbs_out[23:16];
assign prbs_fall1 = prbs_out[31:24];
assign prbs_rise2 = prbs_out[39:32];
assign prbs_fall2 = prbs_out[47:40];
assign prbs_rise3 = prbs_out[55:48];
assign prbs_fall3 = prbs_out[63:56];
assign prbs_o = {prbs_fall3, prbs_rise3, prbs_fall2, prbs_rise2,
prbs_fall1, prbs_rise1, prbs_fall0, prbs_rise0};*/
end else begin :gen_ck_per_clk2
assign prbs_o = prbs_out[4*DQ_WIDTH-1:0];
/*assign prbs_rise0 = prbs_out[7:0];
assign prbs_fall0 = prbs_out[15:8];
assign prbs_rise1 = prbs_out[23:16];
assign prbs_fall1 = prbs_out[31:24];
assign prbs_o = {prbs_fall1, prbs_rise1, prbs_fall0, prbs_rise0};*/
end
endgenerate
//***************************************************************************
// Initialization / Master PHY state logic (overall control during memory
// init, timing leveling)
//***************************************************************************
mig_7series_v2_3_ddr_phy_init #
(
.tCK (tCK),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.CLK_PERIOD (CLK_PERIOD),
.DRAM_TYPE (DRAM_TYPE),
.PRBS_WIDTH (PRBS_WIDTH),
.BANK_WIDTH (BANK_WIDTH),
.CA_MIRROR (CA_MIRROR),
.COL_WIDTH (COL_WIDTH),
.nCS_PER_RANK (nCS_PER_RANK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.CS_WIDTH (CS_WIDTH),
.RANKS (RANKS),
.CKE_WIDTH (CKE_WIDTH),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.AL (AL),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.nCL (nCL),
.nCWL (nCWL),
.tRFC (tRFC),
.REFRESH_TIMER (REFRESH_TIMER),
.REFRESH_TIMER_WIDTH (REFRESH_TIMER_WIDTH),
.OUTPUT_DRV (OUTPUT_DRV),
.REG_CTRL (REG_CTRL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.WRLVL (WRLVL),
.USE_ODT_PORT (USE_ODT_PORT),
.DDR2_DQSN_ENABLE(DDR2_DQSN_ENABLE),
.nSLOTS (nSLOTS),
.SIM_INIT_OPTION (SIM_INIT_OPTION),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.CKE_ODT_AUX (CKE_ODT_AUX),
.PRE_REV3ES (PRE_REV3ES),
.TEST_AL (TEST_AL),
.FIXED_VICTIM (FIXED_VICTIM),
.BYPASS_COMPLEX_OCAL(BYPASS_COMPLEX_OCAL)
)
u_ddr_phy_init
(
.clk (clk),
.rst (rst),
.prbs_o (prbs_o),
.ck_addr_cmd_delay_done(ck_addr_cmd_delay_done),
.delay_incdec_done (ck_addr_cmd_delay_done),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_phaselock_start (pi_phaselock_start),
.pi_phase_locked_err (phase_locked_err),
.pi_calib_done (pi_calib_done),
.phy_if_empty (phy_if_empty),
.phy_ctl_ready (phy_ctl_ready),
.phy_ctl_full (phy_ctl_full),
.phy_cmd_full (phy_cmd_full),
.phy_data_full (phy_data_full),
.calib_ctl_wren (calib_ctl_wren),
.calib_cmd_wren (calib_cmd_wren),
.calib_wrdata_en (calib_wrdata_en),
.calib_seq (calib_seq),
.calib_aux_out (calib_aux_out),
.calib_rank_cnt (calib_rank_cnt),
.calib_cas_slot (calib_cas_slot),
.calib_data_offset_0 (calib_data_offset_0),
.calib_data_offset_1 (calib_data_offset_1),
.calib_data_offset_2 (calib_data_offset_2),
.calib_cmd (calib_cmd),
.calib_cke (calib_cke),
.calib_odt (calib_odt),
.write_calib (write_calib),
.read_calib (read_calib),
.wrlvl_done (wrlvl_done),
.wrlvl_rank_done (wrlvl_rank_done),
.wrlvl_byte_done (wrlvl_byte_done),
.wrlvl_byte_redo (wrlvl_byte_redo),
.wrlvl_final (wrlvl_final_mux),
.wrlvl_final_if_rst (wrlvl_final_if_rst),
.oclkdelay_calib_start (oclkdelay_calib_start),
.oclkdelay_calib_done (oclkdelay_calib_done),
.oclk_prech_req (oclk_prech_req),
.oclk_calib_resume (oclk_calib_resume),
.lim_wr_req (lim2init_write_request),
.lim_done (lim_done),
.complex_oclkdelay_calib_start (complex_oclkdelay_calib_start),
.complex_oclkdelay_calib_done (complex_oclkdelay_calib_done_w),
.complex_oclk_calib_resume (complex_oclk_calib_resume),
.complex_oclkdelay_calib_cnt (complex_oclkdelay_calib_cnt),
.complex_sample_cnt_inc_ocal (complex_sample_cnt_inc_ocal),
.complex_ocal_num_samples_inc (complex_ocal_num_samples_inc),
.complex_ocal_num_samples_done_r (complex_ocal_num_samples_done_r),
.complex_ocal_reset_rd_addr (complex_ocal_reset_rd_addr),
.complex_ocal_ref_req (complex_ocal_ref_req),
.complex_ocal_ref_done (complex_ocal_ref_done),
.done_dqs_tap_inc (done_dqs_tap_inc),
.wl_sm_start (wl_sm_start),
.wr_lvl_start (wrlvl_start),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
.mpr_rdlvl_done (mpr_rdlvl_done),
.mpr_rdlvl_start (mpr_rdlvl_start),
.mpr_last_byte_done (mpr_last_byte_done),
.mpr_rnk_done (mpr_rnk_done),
.mpr_end_if_reset (mpr_end_if_reset),
.rdlvl_stg1_done (rdlvl_stg1_done),
.rdlvl_stg1_rank_done (rdlvl_stg1_rank_done),
.rdlvl_stg1_start (rdlvl_stg1_start),
.rdlvl_prech_req (rdlvl_prech_req),
.rdlvl_last_byte_done (rdlvl_last_byte_done),
.prbs_rdlvl_start (prbs_rdlvl_start),
.complex_wr_done (complex_wr_done),
.prbs_rdlvl_done (prbs_rdlvl_done),
.prbs_last_byte_done (prbs_last_byte_done),
.prbs_rdlvl_prech_req (prbs_rdlvl_prech_req),
.complex_victim_inc (complex_victim_inc),
.rd_victim_sel (rd_victim_sel),
.complex_ocal_rd_victim_sel (complex_ocal_rd_victim_sel),
.pi_stg2_prbs_rdlvl_cnt(pi_stg2_prbs_rdlvl_cnt),
.victim_sel (victim_sel),
.victim_byte_cnt (victim_byte_cnt),
.prbs_gen_clk_en (prbs_gen_clk_en),
.prbs_gen_oclk_clk_en (prbs_gen_oclk_clk_en),
.complex_sample_cnt_inc(complex_sample_cnt_inc),
.pi_dqs_found_start (pi_dqs_found_start),
.dqsfound_retry (dqsfound_retry),
.dqs_found_prech_req (dqs_found_prech_req),
.pi_dqs_found_rank_done(pi_dqs_found_rank_done),
.pi_dqs_found_done (pi_dqs_found_done),
.detect_pi_found_dqs (detect_pi_found_dqs),
.rd_data_offset_0 (rd_data_offset_0),
.rd_data_offset_1 (rd_data_offset_1),
.rd_data_offset_2 (rd_data_offset_2),
.rd_data_offset_ranks_0(rd_data_offset_ranks_0),
.rd_data_offset_ranks_1(rd_data_offset_ranks_1),
.rd_data_offset_ranks_2(rd_data_offset_ranks_2),
.wrcal_start (wrcal_start),
.wrcal_rd_wait (wrcal_rd_wait),
.wrcal_prech_req (wrcal_prech_req),
.wrcal_resume (wrcal_resume_w),
.wrcal_read_req (wrcal_read_req),
.wrcal_act_req (wrcal_act_req),
.wrcal_sanity_chk (wrcal_sanity_chk),
.temp_wrcal_done (temp_wrcal_done),
.wrcal_sanity_chk_done (wrcal_sanity_chk_done),
.tg_timer_done (tg_timer_done),
.no_rst_tg_mc (no_rst_tg_mc),
.wrcal_done (wrcal_done),
.prech_done (prech_done),
.calib_writes (calib_writes),
.init_calib_complete (calib_complete),
.phy_address (phy_address),
.phy_bank (phy_bank),
.phy_cas_n (phy_cas_n),
.phy_cs_n (phy_cs_n),
.phy_ras_n (phy_ras_n),
.phy_reset_n (phy_reset_n),
.phy_we_n (phy_we_n),
.phy_wrdata (phy_wrdata),
.phy_rddata_en (phy_rddata_en),
.phy_rddata_valid (phy_rddata_valid),
.dbg_phy_init (dbg_phy_init),
.read_pause (read_pause),
.reset_rd_addr (reset_rd_addr | complex_ocal_reset_rd_addr),
.oclkdelay_center_calib_start (oclkdelay_center_calib_start),
.oclk_center_write_resume (oclk_center_write_resume),
.oclkdelay_center_calib_done (oclkdelay_center_calib_done)
);
//*****************************************************************
// Write Calibration
//*****************************************************************
mig_7series_v2_3_ddr_phy_wrcal #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.CLK_PERIOD (CLK_PERIOD),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.SIM_CAL_OPTION (SIM_CAL_OPTION)
)
u_ddr_phy_wrcal
(
.clk (clk),
.rst (rst),
.wrcal_start (wrcal_start),
.wrcal_rd_wait (wrcal_rd_wait),
.wrcal_sanity_chk (wrcal_sanity_chk),
.dqsfound_retry_done (pi_dqs_found_done),
.dqsfound_retry (dqsfound_retry),
.wrcal_read_req (wrcal_read_req),
.wrcal_act_req (wrcal_act_req),
.phy_rddata_en (phy_rddata_en),
.wrcal_done (wrcal_done),
.wrcal_pat_err (wrcal_pat_err),
.wrcal_prech_req (wrcal_prech_req),
.temp_wrcal_done (temp_wrcal_done),
.wrcal_sanity_chk_done (wrcal_sanity_chk_done),
.prech_done (prech_done),
.rd_data (phy_rddata),
.wrcal_pat_resume (wrcal_pat_resume),
.po_stg2_wrcal_cnt (po_stg2_wrcal_cnt),
.phy_if_reset (phy_if_reset_w),
.wl_po_coarse_cnt (wl_po_coarse_cnt),
.wl_po_fine_cnt (wl_po_fine_cnt),
.wrlvl_byte_redo (wrlvl_byte_redo),
.wrlvl_byte_done (wrlvl_byte_done),
.early1_data (early1_data),
.early2_data (early2_data),
.idelay_ld (idelay_ld),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt)
);
//***************************************************************************
// Write-leveling calibration logic
//***************************************************************************
generate
if (WRLVL == "ON") begin: mb_wrlvl_inst
mig_7series_v2_3_ddr_phy_wrlvl #
(
.TCQ (TCQ),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.RANKS (1),
.CLK_PERIOD (CLK_PERIOD),
.nCK_PER_CLK (nCK_PER_CLK),
.SIM_CAL_OPTION (SIM_CAL_OPTION)
)
u_ddr_phy_wrlvl
(
.clk (clk),
.rst (rst),
.phy_ctl_ready (phy_ctl_ready),
.wr_level_start (wrlvl_start),
.wl_sm_start (wl_sm_start),
.wrlvl_byte_redo (wrlvl_byte_redo),
.wrcal_cnt (po_stg2_wrcal_cnt),
.early1_data (early1_data),
.early2_data (early2_data),
.wrlvl_final (wrlvl_final_mux),
.oclkdelay_calib_cnt (oclkdelay_calib_cnt),
.wrlvl_byte_done (wrlvl_byte_done),
.oclkdelay_calib_done (oclkdelay_calib_done),
.rd_data_rise0 (phy_rddata[DQ_WIDTH-1:0]),
.dqs_po_dec_done (dqs_po_dec_done),
.phy_ctl_rdy_dly (phy_ctl_rdy_dly),
.wr_level_done (wrlvl_done),
.wrlvl_rank_done (wrlvl_rank_done),
.done_dqs_tap_inc (done_dqs_tap_inc),
.dqs_po_stg2_f_incdec (dqs_po_stg2_f_incdec),
.dqs_po_en_stg2_f (dqs_po_en_stg2_f),
.dqs_wl_po_stg2_c_incdec (dqs_wl_po_stg2_c_incdec),
.dqs_wl_po_en_stg2_c (dqs_wl_po_en_stg2_c),
.po_counter_read_val (po_counter_read_val),
.po_stg2_wl_cnt (po_stg2_wl_cnt),
.wrlvl_err (wrlvl_err),
.wl_po_coarse_cnt (wl_po_coarse_cnt),
.wl_po_fine_cnt (wl_po_fine_cnt),
.dbg_wl_tap_cnt (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_dqs_count (),
.dbg_wl_state (),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl)
);
mig_7series_v2_3_ddr_phy_ck_addr_cmd_delay #
(
.TCQ (TCQ),
.tCK (tCK),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.N_CTL_LANES (N_CTL_LANES),
.SIM_CAL_OPTION(SIM_CAL_OPTION)
)
u_ddr_phy_ck_addr_cmd_delay
(
.clk (clk),
.rst (rst),
.cmd_delay_start (dqs_po_dec_done & pi_fine_dly_dec_done),
.ctl_lane_cnt (ctl_lane_cnt),
.po_stg2_f_incdec (cmd_po_stg2_f_incdec),
.po_en_stg2_f (cmd_po_en_stg2_f),
.po_stg2_c_incdec (cmd_po_stg2_c_incdec),
.po_en_stg2_c (cmd_po_en_stg2_c),
.po_ck_addr_cmd_delay_done (po_ck_addr_cmd_delay_done)
);
assign cmd_po_stg2_incdec_ddr2_c = 1'b0;
assign cmd_po_en_stg2_ddr2_c = 1'b0;
end else begin: mb_wrlvl_off
mig_7series_v2_3_ddr_phy_wrlvl_off_delay #
(
.TCQ (TCQ),
.tCK (tCK),
.nCK_PER_CLK (nCK_PER_CLK),
.CLK_PERIOD (CLK_PERIOD),
.PO_INITIAL_DLY(60),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.N_CTL_LANES (N_CTL_LANES)
)
u_phy_wrlvl_off_delay
(
.clk (clk),
.rst (rst),
.pi_fine_dly_dec_done (pi_fine_dly_dec_done),
.cmd_delay_start (phy_ctl_ready),
.ctl_lane_cnt (ctl_lane_cnt),
.po_s2_incdec_f (cmd_po_stg2_f_incdec),
.po_en_s2_f (cmd_po_en_stg2_f),
.po_s2_incdec_c (cmd_po_stg2_incdec_ddr2_c),
.po_en_s2_c (cmd_po_en_stg2_ddr2_c),
.po_ck_addr_cmd_delay_done (po_ck_addr_cmd_delay_done),
.po_dec_done (dqs_po_dec_done),
.phy_ctl_rdy_dly (phy_ctl_rdy_dly)
);
assign wrlvl_byte_done = 1'b1;
assign wrlvl_rank_done = 1'b1;
assign po_stg2_wl_cnt = 'h0;
assign wl_po_coarse_cnt = 'h0;
assign wl_po_fine_cnt = 'h0;
assign dbg_tap_cnt_during_wrlvl = 'h0;
assign dbg_wl_edge_detect_valid = 'h0;
assign dbg_rd_data_edge_detect = 'h0;
assign dbg_wrlvl_fine_tap_cnt = 'h0;
assign dbg_wrlvl_coarse_tap_cnt = 'h0;
assign dbg_phy_wrlvl = 'h0;
assign wrlvl_done = 1'b1;
assign wrlvl_err = 1'b0;
assign dqs_po_stg2_f_incdec = 1'b0;
assign dqs_po_en_stg2_f = 1'b0;
assign dqs_wl_po_en_stg2_c = 1'b0;
assign cmd_po_stg2_c_incdec = 1'b0;
assign dqs_wl_po_stg2_c_incdec = 1'b0;
assign cmd_po_en_stg2_c = 1'b0;
end
endgenerate
generate
if((WRLVL == "ON") && (OCAL_EN == "ON")) begin: oclk_calib
localparam SAMPCNTRWIDTH = 17;
localparam SAMPLES = (SIM_CAL_OPTION=="NONE") ? 2048 : 4;
localparam TAPCNTRWIDTH = clogb2(TAPSPERKCLK);
localparam MMCM_SAMP_WAIT = (SIM_CAL_OPTION=="NONE") ? 256 : 10;
localparam OCAL_SIMPLE_SCAN_SAMPS = (SIM_CAL_OPTION=="NONE") ? 2048 : 1;
localparam POC_PCT_SAMPS_SOLID = 80;
localparam SCAN_PCT_SAMPS_SOLID = 95;
mig_7series_v2_3_ddr_phy_oclkdelay_cal #
(/*AUTOINSTPARAM*/
// Parameters
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
//.DRAM_TYPE (DRAM_TYPE),
.DRAM_WIDTH (DRAM_WIDTH),
//.OCAL_EN (OCAL_EN),
.OCAL_SIMPLE_SCAN_SAMPS (OCAL_SIMPLE_SCAN_SAMPS),
.PCT_SAMPS_SOLID (POC_PCT_SAMPS_SOLID),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP),
.SCAN_PCT_SAMPS_SOLID (SCAN_PCT_SAMPS_SOLID),
.SAMPCNTRWIDTH (SAMPCNTRWIDTH),
.SAMPLES (SAMPLES),
.MMCM_SAMP_WAIT (MMCM_SAMP_WAIT),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.TAPCNTRWIDTH (TAPCNTRWIDTH),
.TAPSPERKCLK (TAPSPERKCLK),
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.BYPASS_COMPLEX_OCAL (BYPASS_COMPLEX_OCAL)
//.tCK (tCK)
)
u_ddr_phy_oclkdelay_cal
(/*AUTOINST*/
// Outputs
.prbs_ignore_first_byte (prbs_ignore_first_byte),
.prbs_ignore_last_bytes (prbs_ignore_last_bytes),
.complex_oclkdelay_calib_done (complex_oclkdelay_calib_done),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data[16*DRAM_WIDTH-1:0]),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal[255:0]),
.lim2init_write_request (lim2init_write_request),
.lim_done (lim_done),
.oclk_calib_resume (oclk_calib_resume),
//.oclk_init_delay_done (oclk_init_delay_done),
.oclk_prech_req (oclk_prech_req),
.oclkdelay_calib_cnt (oclkdelay_calib_cnt[DQS_CNT_WIDTH:0]),
.oclkdelay_calib_done (oclkdelay_calib_done),
.po_en_stg23 (po_en_stg23),
//.po_en_stg3 (po_en_stg3),
.po_stg23_incdec (po_stg23_incdec),
.po_stg23_sel (po_stg23_sel),
//.po_stg3_incdec (po_stg3_incdec),
.psen (psen),
.psincdec (psincdec),
.wrlvl_final (wrlvl_final),
.rd_victim_sel (complex_ocal_rd_victim_sel),
.ocal_num_samples_done_r (complex_ocal_num_samples_done_r),
.complex_wrlvl_final (complex_wrlvl_final),
.poc_error (poc_error),
// Inputs
.clk (clk),
.complex_oclkdelay_calib_start (complex_oclkdelay_calib_start_w),
.metaQ (pd_out),
//.oclk_init_delay_start (oclk_init_delay_start),
.po_counter_read_val (po_counter_read_val),
.oclkdelay_calib_start (oclkdelay_calib_start),
.oclkdelay_init_val (oclkdelay_init_val[5:0]),
.poc_sample_pd (poc_sample_pd),
.phy_rddata (phy_rddata[2*nCK_PER_CLK*DQ_WIDTH-1:0]),
.phy_rddata_en (phy_rddata_en),
.prbs_o (prbs_o[2*nCK_PER_CLK*DQ_WIDTH-1:0]),
.prech_done (prech_done),
.psdone (psdone),
.rst (rst),
.wl_po_fine_cnt (wl_po_fine_cnt[6*DQS_WIDTH-1:0]),
.ocal_num_samples_inc (complex_ocal_num_samples_inc),
.oclkdelay_center_calib_start (oclkdelay_center_calib_start),
.oclk_center_write_resume (oclk_center_write_resume),
.oclkdelay_center_calib_done (oclkdelay_center_calib_done),
.dbg_ocd_lim (dbg_ocd_lim));
end else begin : oclk_calib_disabled
assign wrlvl_final = 'b0;
assign psen = 'b0;
assign psincdec = 'b0;
assign po_stg23_sel = 'b0;
assign po_stg23_incdec = 'b0;
assign po_en_stg23 = 'b0;
//assign oclk_init_delay_done = 1'b1;
assign oclkdelay_calib_cnt = 'b0;
assign oclk_prech_req = 'b0;
assign oclk_calib_resume = 'b0;
assign oclkdelay_calib_done = 1'b1;
assign dbg_phy_oclkdelay_cal = 'h0;
assign dbg_oclkdelay_rd_data = 'h0;
end
endgenerate
//***************************************************************************
// Read data-offset calibration required for Phaser_In
//***************************************************************************
generate
if(DQSFOUND_CAL == "RIGHT") begin: dqsfind_calib_right
mig_7series_v2_3_ddr_phy_dqs_found_cal #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.nCL (nCL),
.AL (AL),
.nCWL (nCWL),
//.RANKS (RANKS),
.RANKS (1),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.REG_CTRL (REG_CTRL),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DRAM_TYPE (DRAM_TYPE),
.NUM_DQSFOUND_CAL (NUM_DQSFOUND_CAL),
.N_CTL_LANES (DQS_FOUND_N_CTL_LANES),
.HIGHEST_LANE (HIGHEST_LANE),
.HIGHEST_BANK (HIGHEST_BANK),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4)
)
u_ddr_phy_dqs_found_cal
(
.clk (clk),
.rst (rst),
.pi_dqs_found_start (pi_dqs_found_start),
.dqsfound_retry (dqsfound_retry),
.detect_pi_found_dqs (detect_pi_found_dqs),
.prech_done (prech_done),
.pi_dqs_found_lanes (pi_dqs_found_lanes),
.pi_rst_stg1_cal (pi_rst_stg1_cal),
.rd_data_offset_0 (rd_data_offset_0),
.rd_data_offset_1 (rd_data_offset_1),
.rd_data_offset_2 (rd_data_offset_2),
.pi_dqs_found_rank_done (pi_dqs_found_rank_done),
.pi_dqs_found_done (pi_dqs_found_done),
.dqsfound_retry_done (dqsfound_retry_done),
.dqs_found_prech_req (dqs_found_prech_req),
.pi_dqs_found_err (pi_dqs_found_err),
.rd_data_offset_ranks_0 (rd_data_offset_ranks_0),
.rd_data_offset_ranks_1 (rd_data_offset_ranks_1),
.rd_data_offset_ranks_2 (rd_data_offset_ranks_2),
.rd_data_offset_ranks_mc_0 (rd_data_offset_ranks_mc_0),
.rd_data_offset_ranks_mc_1 (rd_data_offset_ranks_mc_1),
.rd_data_offset_ranks_mc_2 (rd_data_offset_ranks_mc_2),
.po_counter_read_val (po_counter_read_val),
.rd_data_offset_cal_done (rd_data_offset_cal_done),
.fine_adjust_done (fine_adjust_done),
.fine_adjust_lane_cnt (fine_adjust_lane_cnt),
.ck_po_stg2_f_indec (ck_po_stg2_f_indec),
.ck_po_stg2_f_en (ck_po_stg2_f_en),
.dbg_dqs_found_cal (dbg_dqs_found_cal)
);
end else begin: dqsfind_calib_left
mig_7series_v2_3_ddr_phy_dqs_found_cal_hr #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.nCL (nCL),
.AL (AL),
.nCWL (nCWL),
//.RANKS (RANKS),
.RANKS (1),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.REG_CTRL (REG_CTRL),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DRAM_TYPE (DRAM_TYPE),
.NUM_DQSFOUND_CAL (NUM_DQSFOUND_CAL),
.N_CTL_LANES (DQS_FOUND_N_CTL_LANES),
.HIGHEST_LANE (HIGHEST_LANE),
.HIGHEST_BANK (HIGHEST_BANK),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4)
)
u_ddr_phy_dqs_found_cal_hr
(
.clk (clk),
.rst (rst),
.pi_dqs_found_start (pi_dqs_found_start),
.dqsfound_retry (dqsfound_retry),
.detect_pi_found_dqs (detect_pi_found_dqs),
.prech_done (prech_done),
.pi_dqs_found_lanes (pi_dqs_found_lanes),
.pi_rst_stg1_cal (pi_rst_stg1_cal),
.rd_data_offset_0 (rd_data_offset_0),
.rd_data_offset_1 (rd_data_offset_1),
.rd_data_offset_2 (rd_data_offset_2),
.pi_dqs_found_rank_done (pi_dqs_found_rank_done),
.pi_dqs_found_done (pi_dqs_found_done),
.dqsfound_retry_done (dqsfound_retry_done),
.dqs_found_prech_req (dqs_found_prech_req),
.pi_dqs_found_err (pi_dqs_found_err),
.rd_data_offset_ranks_0 (rd_data_offset_ranks_0),
.rd_data_offset_ranks_1 (rd_data_offset_ranks_1),
.rd_data_offset_ranks_2 (rd_data_offset_ranks_2),
.rd_data_offset_ranks_mc_0 (rd_data_offset_ranks_mc_0),
.rd_data_offset_ranks_mc_1 (rd_data_offset_ranks_mc_1),
.rd_data_offset_ranks_mc_2 (rd_data_offset_ranks_mc_2),
.po_counter_read_val (po_counter_read_val),
.rd_data_offset_cal_done (rd_data_offset_cal_done),
.fine_adjust_done (fine_adjust_done),
.fine_adjust_lane_cnt (fine_adjust_lane_cnt),
.ck_po_stg2_f_indec (ck_po_stg2_f_indec),
.ck_po_stg2_f_en (ck_po_stg2_f_en),
.dbg_dqs_found_cal (dbg_dqs_found_cal)
);
end
endgenerate
//***************************************************************************
// Read-leveling calibration logic
//***************************************************************************
mig_7series_v2_3_ddr_phy_rdlvl #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.CLK_PERIOD (CLK_PERIOD),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.RANKS (1),
.PER_BIT_DESKEW (PER_BIT_DESKEW),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DEBUG_PORT (DEBUG_PORT),
.DRAM_TYPE (DRAM_TYPE),
.OCAL_EN (OCAL_EN),
.IDELAY_ADJ (IDELAY_ADJ)
)
u_ddr_phy_rdlvl
(
.clk (clk),
.rst (rst),
.mpr_rdlvl_done (mpr_rdlvl_done),
.mpr_rdlvl_start (mpr_rdlvl_start),
.mpr_last_byte_done (mpr_last_byte_done),
.mpr_rnk_done (mpr_rnk_done),
.rdlvl_stg1_start (rdlvl_stg1_start),
.rdlvl_stg1_done (rdlvl_stg1_done),
.rdlvl_stg1_rnk_done (rdlvl_stg1_rank_done),
.rdlvl_stg1_err (rdlvl_stg1_err),
.mpr_rdlvl_err (mpr_rdlvl_err),
.rdlvl_err (rdlvl_err),
.rdlvl_prech_req (rdlvl_prech_req),
.rdlvl_last_byte_done (rdlvl_last_byte_done),
.rdlvl_assrt_common (rdlvl_assrt_common),
.prech_done (prech_done),
.phy_if_empty (phy_if_empty),
.idelaye2_init_val (idelaye2_init_val),
.rd_data (phy_rddata),
.pi_en_stg2_f (rdlvl_pi_stg2_f_en),
.pi_stg2_f_incdec (rdlvl_pi_stg2_f_incdec),
.pi_stg2_load (pi_stg2_load),
.pi_stg2_reg_l (pi_stg2_reg_l),
.dqs_po_dec_done (dqs_po_dec_done),
.pi_counter_read_val (pi_counter_read_val),
.pi_fine_dly_dec_done (pi_fine_dly_dec_done),
.idelay_ce (idelay_ce_int),
.idelay_inc (idelay_inc_int),
.idelay_ld (idelay_ld),
.wrcal_cnt (po_stg2_wrcal_cnt),
.pi_stg2_rdlvl_cnt (pi_stg2_rdlvl_cnt),
.dlyval_dq (dlyval_dq),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_phy_rdlvl (dbg_phy_rdlvl)
);
generate
if((DRAM_TYPE == "DDR3") && (nCK_PER_CLK == 4) && (BYPASS_COMPLEX_RDLVL=="FALSE")) begin:ddr_phy_prbs_rdlvl_gen
mig_7series_v2_3_ddr_phy_prbs_rdlvl #
(
.TCQ (TCQ),
.nCK_PER_CLK (nCK_PER_CLK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.RANKS (1),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.PRBS_WIDTH (PRBS_WIDTH),
.FIXED_VICTIM (FIXED_VICTIM),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ)
)
u_ddr_phy_prbs_rdlvl
(
.clk (clk),
.rst (rst),
.prbs_rdlvl_start (prbs_rdlvl_start),
.prbs_rdlvl_done (prbs_rdlvl_done),
.prbs_last_byte_done (prbs_last_byte_done),
.prbs_rdlvl_prech_req (prbs_rdlvl_prech_req),
.complex_sample_cnt_inc (complex_sample_cnt_inc),
.prech_done (prech_done),
.phy_if_empty (phy_if_empty),
.rd_data (phy_rddata),
.compare_data (prbs_o),
.pi_counter_read_val (pi_counter_read_val),
.pi_en_stg2_f (prbs_pi_stg2_f_en),
.pi_stg2_f_incdec (prbs_pi_stg2_f_incdec),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.pi_stg2_prbs_rdlvl_cnt (pi_stg2_prbs_rdlvl_cnt),
.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps),
.rd_victim_sel (rd_victim_sel),
.complex_victim_inc (complex_victim_inc),
.reset_rd_addr (reset_rd_addr),
.read_pause (read_pause),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
end else begin:ddr_phy_prbs_rdlvl_off
assign prbs_rdlvl_done = rdlvl_stg1_done ;
//assign prbs_last_byte_done = rdlvl_stg1_rank_done ;
assign prbs_last_byte_done = rdlvl_stg1_done;
assign read_pause = 1'b0;
assign reset_rd_addr = 1'b0;
assign prbs_rdlvl_prech_req = 1'b0 ;
assign prbs_pi_stg2_f_en = 1'b0 ;
assign prbs_pi_stg2_f_incdec = 1'b0 ;
assign pi_stg2_prbs_rdlvl_cnt = 'b0 ;
assign dbg_prbs_rdlvl = 'h0 ;
assign prbs_final_dqs_tap_cnt_r = {(6*DQS_WIDTH*RANKS){1'b0}};
assign dbg_prbs_first_edge_taps = {(6*DQS_WIDTH*RANKS){1'b0}};
assign dbg_prbs_second_edge_taps = {(6*DQS_WIDTH*RANKS){1'b0}};
end
endgenerate
//***************************************************************************
// Temperature induced PI tap adjustment logic
//***************************************************************************
mig_7series_v2_3_ddr_phy_tempmon #
(
.TCQ (TCQ)
)
ddr_phy_tempmon_0
(
.rst (rst),
.clk (clk),
.calib_complete (calib_complete),
.tempmon_pi_f_inc (tempmon_pi_f_inc),
.tempmon_pi_f_dec (tempmon_pi_f_dec),
.tempmon_sel_pi_incdec (tempmon_sel_pi_incdec),
.device_temp (device_temp),
.tempmon_sample_en (tempmon_sample_en)
);
endmodule
|
module mig_7series_v2_3_bank_common #
(
parameter TCQ = 100,
parameter BM_CNT_WIDTH = 2,
parameter LOW_IDLE_CNT = 1,
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2,
parameter nOP_WAIT = 0,
parameter nRFC = 44,
parameter nXSDLL = 512,
parameter RANK_WIDTH = 2,
parameter RANKS = 4,
parameter CWL = 5,
parameter tZQCS = 64
)
(/*AUTOARG*/
// Outputs
accept_internal_r, accept_ns, accept, periodic_rd_insert,
periodic_rd_ack_r, accept_req, rb_hit_busy_cnt, idle, idle_cnt, order_cnt,
adv_order_q, bank_mach_next, op_exit_grant, low_idle_cnt_r, was_wr,
was_priority, maint_wip_r, maint_idle, insert_maint_r,
// Inputs
clk, rst, idle_ns, init_calib_complete, periodic_rd_r, use_addr,
rb_hit_busy_r, idle_r, ordered_r, ordered_issued, head_r, end_rtp,
passing_open_bank, op_exit_req, start_pre_wait, cmd, hi_priority, maint_req_r,
maint_zq_r, maint_sre_r, maint_srx_r, maint_hit, bm_end,
slot_0_present, slot_1_present
);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
localparam ZERO = 0;
localparam ONE = 1;
localparam [BM_CNT_WIDTH-1:0] BM_CNT_ZERO = ZERO[0+:BM_CNT_WIDTH];
localparam [BM_CNT_WIDTH-1:0] BM_CNT_ONE = ONE[0+:BM_CNT_WIDTH];
input clk;
input rst;
input [nBANK_MACHS-1:0] idle_ns;
input init_calib_complete;
wire accept_internal_ns = init_calib_complete && |idle_ns;
output reg accept_internal_r;
always @(posedge clk) accept_internal_r <= accept_internal_ns;
wire periodic_rd_ack_ns;
wire accept_ns_lcl = accept_internal_ns && ~periodic_rd_ack_ns;
output wire accept_ns;
assign accept_ns = accept_ns_lcl;
reg accept_r;
always @(posedge clk) accept_r <= #TCQ accept_ns_lcl;
// Wire to user interface informing user that the request has been accepted.
output wire accept;
assign accept = accept_r;
`ifdef MC_SVA
property none_idle;
@(posedge clk) (init_calib_complete && ~|idle_r);
endproperty
all_bank_machines_busy: cover property (none_idle);
`endif
// periodic_rd_insert tells everyone to mux in the periodic read.
input periodic_rd_r;
reg periodic_rd_ack_r_lcl;
reg periodic_rd_cntr_r ;
always @(posedge clk) begin
if (rst) periodic_rd_cntr_r <= #TCQ 1'b0;
else if (periodic_rd_r && periodic_rd_ack_r_lcl)
periodic_rd_cntr_r <= #TCQ ~periodic_rd_cntr_r;
end
wire internal_periodic_rd_ack_r_lcl = (periodic_rd_cntr_r && periodic_rd_ack_r_lcl);
// wire periodic_rd_insert_lcl = periodic_rd_r && ~periodic_rd_ack_r_lcl;
wire periodic_rd_insert_lcl = periodic_rd_r && ~internal_periodic_rd_ack_r_lcl;
output wire periodic_rd_insert;
assign periodic_rd_insert = periodic_rd_insert_lcl;
// periodic_rd_ack_r acknowledges that the read has been accepted
// into the queue.
assign periodic_rd_ack_ns = periodic_rd_insert_lcl && accept_internal_ns;
always @(posedge clk) periodic_rd_ack_r_lcl <= #TCQ periodic_rd_ack_ns;
output wire periodic_rd_ack_r;
assign periodic_rd_ack_r = periodic_rd_ack_r_lcl;
// accept_req tells all q entries that a request has been accepted.
input use_addr;
wire accept_req_lcl = periodic_rd_ack_r_lcl || (accept_r && use_addr);
output wire accept_req;
assign accept_req = accept_req_lcl;
// Count how many non idle bank machines hit on the rank and bank.
input [nBANK_MACHS-1:0] rb_hit_busy_r;
output reg [BM_CNT_WIDTH-1:0] rb_hit_busy_cnt;
integer i;
always @(/*AS*/rb_hit_busy_r) begin
rb_hit_busy_cnt = BM_CNT_ZERO;
for (i = 0; i < nBANK_MACHS; i = i + 1)
if (rb_hit_busy_r[i]) rb_hit_busy_cnt = rb_hit_busy_cnt + BM_CNT_ONE;
end
// Count the number of idle bank machines.
input [nBANK_MACHS-1:0] idle_r;
output reg [BM_CNT_WIDTH-1:0] idle_cnt;
always @(/*AS*/idle_r) begin
idle_cnt = BM_CNT_ZERO;
for (i = 0; i < nBANK_MACHS; i = i + 1)
if (idle_r[i]) idle_cnt = idle_cnt + BM_CNT_ONE;
end
// Report an overall idle status
output idle;
assign idle = init_calib_complete && &idle_r;
// Count the number of bank machines in the ordering queue.
input [nBANK_MACHS-1:0] ordered_r;
output reg [BM_CNT_WIDTH-1:0] order_cnt;
always @(/*AS*/ordered_r) begin
order_cnt = BM_CNT_ZERO;
for (i = 0; i < nBANK_MACHS; i = i + 1)
if (ordered_r[i]) order_cnt = order_cnt + BM_CNT_ONE;
end
input [nBANK_MACHS-1:0] ordered_issued;
output wire adv_order_q;
assign adv_order_q = |ordered_issued;
// Figure out which bank machine is going to accept the next request.
input [nBANK_MACHS-1:0] head_r;
wire [nBANK_MACHS-1:0] next = idle_r & head_r;
output reg[BM_CNT_WIDTH-1:0] bank_mach_next;
always @(/*AS*/next) begin
bank_mach_next = BM_CNT_ZERO;
for (i = 0; i <= nBANK_MACHS-1; i = i + 1)
if (next[i]) bank_mach_next = i[BM_CNT_WIDTH-1:0];
end
input [nBANK_MACHS-1:0] end_rtp;
input [nBANK_MACHS-1:0] passing_open_bank;
input [nBANK_MACHS-1:0] op_exit_req;
output wire [nBANK_MACHS-1:0] op_exit_grant;
output reg low_idle_cnt_r = 1'b0;
input [nBANK_MACHS-1:0] start_pre_wait;
generate
// In support of open page mode, the following logic
// keeps track of how many "idle" bank machines there
// are. In this case, idle means a bank machine is on
// the idle list, or is in the process of precharging and
// will soon be idle.
if (nOP_WAIT == 0) begin : op_mode_disabled
assign op_exit_grant = {nBANK_MACHS{1'b0}};
end
else begin : op_mode_enabled
reg [BM_CNT_WIDTH:0] idle_cnt_r;
reg [BM_CNT_WIDTH:0] idle_cnt_ns;
always @(/*AS*/accept_req_lcl or idle_cnt_r or passing_open_bank
or rst or start_pre_wait)
if (rst) idle_cnt_ns = nBANK_MACHS;
else begin
idle_cnt_ns = idle_cnt_r - accept_req_lcl;
for (i = 0; i <= nBANK_MACHS-1; i = i + 1) begin
idle_cnt_ns = idle_cnt_ns + passing_open_bank[i];
end
idle_cnt_ns = idle_cnt_ns + |start_pre_wait;
end
always @(posedge clk) idle_cnt_r <= #TCQ idle_cnt_ns;
wire low_idle_cnt_ns = (idle_cnt_ns <= LOW_IDLE_CNT[0+:BM_CNT_WIDTH]);
always @(posedge clk) low_idle_cnt_r <= #TCQ low_idle_cnt_ns;
// This arbiter determines which bank machine should transition
// from open page wait to precharge. Ideally, this process
// would take the oldest waiter, but don't have any reasonable
// way to implement that. Instead, just use simple round robin
// arb with the small enhancement that the most recent bank machine
// to enter open page wait is given lowest priority in the arbiter.
wire upd_last_master = |end_rtp; // should be one bit set at most
mig_7series_v2_3_round_robin_arb #
(.WIDTH (nBANK_MACHS))
op_arb0
(.grant_ns (op_exit_grant[nBANK_MACHS-1:0]),
.grant_r (),
.upd_last_master (upd_last_master),
.current_master (end_rtp[nBANK_MACHS-1:0]),
.clk (clk),
.rst (rst),
.req (op_exit_req[nBANK_MACHS-1:0]),
.disable_grant (1'b0));
end
endgenerate
// Register some command information. This information will be used
// by the bank machines to figure out if there is something behind it
// in the queue that require hi priority.
input [2:0] cmd;
output reg was_wr;
always @(posedge clk) was_wr <= #TCQ
cmd[0] && ~(periodic_rd_r && ~periodic_rd_ack_r_lcl);
input hi_priority;
output reg was_priority;
always @(posedge clk) begin
if (hi_priority)
was_priority <= #TCQ 1'b1;
else
was_priority <= #TCQ 1'b0;
end
// DRAM maintenance (refresh and ZQ) and self-refresh controller
input maint_req_r;
reg maint_wip_r_lcl;
output wire maint_wip_r;
assign maint_wip_r = maint_wip_r_lcl;
wire maint_idle_lcl;
output wire maint_idle;
assign maint_idle = maint_idle_lcl;
input maint_zq_r;
input maint_sre_r;
input maint_srx_r;
input [nBANK_MACHS-1:0] maint_hit;
input [nBANK_MACHS-1:0] bm_end;
wire start_maint;
wire maint_end;
generate begin : maint_controller
// Idle when not (maintenance work in progress (wip), OR maintenance
// starting tick).
assign maint_idle_lcl = ~(maint_req_r || maint_wip_r_lcl);
// Maintenance work in progress starts with maint_reg_r tick, terminated
// with maint_end tick. maint_end tick is generated by the RFC/ZQ/XSDLL timer
// below.
wire maint_wip_ns =
~rst && ~maint_end && (maint_wip_r_lcl || maint_req_r);
always @(posedge clk) maint_wip_r_lcl <= #TCQ maint_wip_ns;
// Keep track of which bank machines hit on the maintenance request
// when the request is made. As bank machines complete, an assertion
// of the bm_end signal clears the correspoding bit in the
// maint_hit_busies_r vector. Eventually, all bits should clear and
// the maintenance operation will proceed. ZQ and self-refresh hit on all
// non idle banks. Refresh hits only on non idle banks with the same rank as
// the refresh request.
wire [nBANK_MACHS-1:0] clear_vector = {nBANK_MACHS{rst}} | bm_end;
wire [nBANK_MACHS-1:0] maint_zq_hits = {nBANK_MACHS{maint_idle_lcl}} &
(maint_hit | {nBANK_MACHS{maint_zq_r}}) & ~idle_ns;
wire [nBANK_MACHS-1:0] maint_sre_hits = {nBANK_MACHS{maint_idle_lcl}} &
(maint_hit | {nBANK_MACHS{maint_sre_r}}) & ~idle_ns;
reg [nBANK_MACHS-1:0] maint_hit_busies_r;
wire [nBANK_MACHS-1:0] maint_hit_busies_ns =
~clear_vector & (maint_hit_busies_r | maint_zq_hits | maint_sre_hits);
always @(posedge clk) maint_hit_busies_r <= #TCQ maint_hit_busies_ns;
// Queue is clear of requests conflicting with maintenance.
wire maint_clear = ~maint_idle_lcl && ~|maint_hit_busies_ns;
// Ready to start sending maintenance commands.
wire maint_rdy = maint_clear;
reg maint_rdy_r1;
reg maint_srx_r1;
always @(posedge clk) maint_rdy_r1 <= #TCQ maint_rdy;
always @(posedge clk) maint_srx_r1 <= #TCQ maint_srx_r;
assign start_maint = maint_rdy && ~maint_rdy_r1 || maint_srx_r && ~maint_srx_r1;
end // block: maint_controller
endgenerate
// Figure out how many maintenance commands to send, and send them.
input [7:0] slot_0_present;
input [7:0] slot_1_present;
reg insert_maint_r_lcl;
output wire insert_maint_r;
assign insert_maint_r = insert_maint_r_lcl;
generate begin : generate_maint_cmds
// Count up how many slots are occupied. This tells
// us how many ZQ, SRE or SRX commands to send out.
reg [RANK_WIDTH:0] present_count;
wire [7:0] present = slot_0_present | slot_1_present;
always @(/*AS*/present) begin
present_count = {RANK_WIDTH{1'b0}};
for (i=0; i<8; i=i+1)
present_count = present_count + {{RANK_WIDTH{1'b0}}, present[i]};
end
// For refresh, there is only a single command sent. For
// ZQ, SRE and SRX, each rank present will receive a command. The counter
// below counts down the number of ranks present.
reg [RANK_WIDTH:0] send_cnt_ns;
reg [RANK_WIDTH:0] send_cnt_r;
always @(/*AS*/maint_zq_r or maint_sre_r or maint_srx_r or present_count
or rst or send_cnt_r or start_maint)
if (rst) send_cnt_ns = 4'b0;
else begin
send_cnt_ns = send_cnt_r;
if (start_maint && (maint_zq_r || maint_sre_r || maint_srx_r)) send_cnt_ns = present_count;
if (|send_cnt_ns)
send_cnt_ns = send_cnt_ns - ONE[RANK_WIDTH-1:0];
end
always @(posedge clk) send_cnt_r <= #TCQ send_cnt_ns;
// Insert a maintenance command for start_maint, or when the sent count
// is not zero.
wire insert_maint_ns = start_maint || |send_cnt_r;
always @(posedge clk) insert_maint_r_lcl <= #TCQ insert_maint_ns;
end // block: generate_maint_cmds
endgenerate
// RFC ZQ XSDLL timer. Generates delay from refresh, self-refresh exit or ZQ
// command until the end of the maintenance operation.
// Compute values for RFC, ZQ and XSDLL periods.
localparam nRFC_CLKS = (nCK_PER_CLK == 1) ?
nRFC :
(nCK_PER_CLK == 2) ?
((nRFC/2) + (nRFC%2)) :
// (nCK_PER_CLK == 4)
((nRFC/4) + ((nRFC%4) ? 1 : 0));
localparam nZQCS_CLKS = (nCK_PER_CLK == 1) ?
tZQCS :
(nCK_PER_CLK == 2) ?
((tZQCS/2) + (tZQCS%2)) :
// (nCK_PER_CLK == 4)
((tZQCS/4) + ((tZQCS%4) ? 1 : 0));
localparam nXSDLL_CLKS = (nCK_PER_CLK == 1) ?
nXSDLL :
(nCK_PER_CLK == 2) ?
((nXSDLL/2) + (nXSDLL%2)) :
// (nCK_PER_CLK == 4)
((nXSDLL/4) + ((nXSDLL%4) ? 1 : 0));
localparam RFC_ZQ_TIMER_WIDTH = clogb2(nXSDLL_CLKS + 1);
localparam THREE = 3;
generate begin : rfc_zq_xsdll_timer
reg [RFC_ZQ_TIMER_WIDTH-1:0] rfc_zq_xsdll_timer_ns;
reg [RFC_ZQ_TIMER_WIDTH-1:0] rfc_zq_xsdll_timer_r;
always @(/*AS*/insert_maint_r_lcl or maint_zq_r or maint_sre_r or maint_srx_r
or rfc_zq_xsdll_timer_r or rst) begin
rfc_zq_xsdll_timer_ns = rfc_zq_xsdll_timer_r;
if (rst) rfc_zq_xsdll_timer_ns = {RFC_ZQ_TIMER_WIDTH{1'b0}};
else if (insert_maint_r_lcl) rfc_zq_xsdll_timer_ns = maint_zq_r ?
nZQCS_CLKS :
maint_sre_r ?
{RFC_ZQ_TIMER_WIDTH{1'b0}} :
maint_srx_r ?
nXSDLL_CLKS :
nRFC_CLKS;
else if (|rfc_zq_xsdll_timer_r) rfc_zq_xsdll_timer_ns =
rfc_zq_xsdll_timer_r - ONE[RFC_ZQ_TIMER_WIDTH-1:0];
end
always @(posedge clk) rfc_zq_xsdll_timer_r <= #TCQ rfc_zq_xsdll_timer_ns;
// Based on rfc_zq_xsdll_timer_r, figure out when to release any bank
// machines waiting to send an activate. Need to add two to the end count.
// One because the counter starts a state after the insert_refresh_r, and
// one more because bm_end to insert_refresh_r is one state shorter
// than bm_end to rts_row.
assign maint_end = (rfc_zq_xsdll_timer_r == THREE[RFC_ZQ_TIMER_WIDTH-1:0]);
end // block: rfc_zq_xsdll_timer
endgenerate
endmodule
|
module mig_7series_v2_3_bank_common #
(
parameter TCQ = 100,
parameter BM_CNT_WIDTH = 2,
parameter LOW_IDLE_CNT = 1,
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2,
parameter nOP_WAIT = 0,
parameter nRFC = 44,
parameter nXSDLL = 512,
parameter RANK_WIDTH = 2,
parameter RANKS = 4,
parameter CWL = 5,
parameter tZQCS = 64
)
(/*AUTOARG*/
// Outputs
accept_internal_r, accept_ns, accept, periodic_rd_insert,
periodic_rd_ack_r, accept_req, rb_hit_busy_cnt, idle, idle_cnt, order_cnt,
adv_order_q, bank_mach_next, op_exit_grant, low_idle_cnt_r, was_wr,
was_priority, maint_wip_r, maint_idle, insert_maint_r,
// Inputs
clk, rst, idle_ns, init_calib_complete, periodic_rd_r, use_addr,
rb_hit_busy_r, idle_r, ordered_r, ordered_issued, head_r, end_rtp,
passing_open_bank, op_exit_req, start_pre_wait, cmd, hi_priority, maint_req_r,
maint_zq_r, maint_sre_r, maint_srx_r, maint_hit, bm_end,
slot_0_present, slot_1_present
);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
localparam ZERO = 0;
localparam ONE = 1;
localparam [BM_CNT_WIDTH-1:0] BM_CNT_ZERO = ZERO[0+:BM_CNT_WIDTH];
localparam [BM_CNT_WIDTH-1:0] BM_CNT_ONE = ONE[0+:BM_CNT_WIDTH];
input clk;
input rst;
input [nBANK_MACHS-1:0] idle_ns;
input init_calib_complete;
wire accept_internal_ns = init_calib_complete && |idle_ns;
output reg accept_internal_r;
always @(posedge clk) accept_internal_r <= accept_internal_ns;
wire periodic_rd_ack_ns;
wire accept_ns_lcl = accept_internal_ns && ~periodic_rd_ack_ns;
output wire accept_ns;
assign accept_ns = accept_ns_lcl;
reg accept_r;
always @(posedge clk) accept_r <= #TCQ accept_ns_lcl;
// Wire to user interface informing user that the request has been accepted.
output wire accept;
assign accept = accept_r;
`ifdef MC_SVA
property none_idle;
@(posedge clk) (init_calib_complete && ~|idle_r);
endproperty
all_bank_machines_busy: cover property (none_idle);
`endif
// periodic_rd_insert tells everyone to mux in the periodic read.
input periodic_rd_r;
reg periodic_rd_ack_r_lcl;
reg periodic_rd_cntr_r ;
always @(posedge clk) begin
if (rst) periodic_rd_cntr_r <= #TCQ 1'b0;
else if (periodic_rd_r && periodic_rd_ack_r_lcl)
periodic_rd_cntr_r <= #TCQ ~periodic_rd_cntr_r;
end
wire internal_periodic_rd_ack_r_lcl = (periodic_rd_cntr_r && periodic_rd_ack_r_lcl);
// wire periodic_rd_insert_lcl = periodic_rd_r && ~periodic_rd_ack_r_lcl;
wire periodic_rd_insert_lcl = periodic_rd_r && ~internal_periodic_rd_ack_r_lcl;
output wire periodic_rd_insert;
assign periodic_rd_insert = periodic_rd_insert_lcl;
// periodic_rd_ack_r acknowledges that the read has been accepted
// into the queue.
assign periodic_rd_ack_ns = periodic_rd_insert_lcl && accept_internal_ns;
always @(posedge clk) periodic_rd_ack_r_lcl <= #TCQ periodic_rd_ack_ns;
output wire periodic_rd_ack_r;
assign periodic_rd_ack_r = periodic_rd_ack_r_lcl;
// accept_req tells all q entries that a request has been accepted.
input use_addr;
wire accept_req_lcl = periodic_rd_ack_r_lcl || (accept_r && use_addr);
output wire accept_req;
assign accept_req = accept_req_lcl;
// Count how many non idle bank machines hit on the rank and bank.
input [nBANK_MACHS-1:0] rb_hit_busy_r;
output reg [BM_CNT_WIDTH-1:0] rb_hit_busy_cnt;
integer i;
always @(/*AS*/rb_hit_busy_r) begin
rb_hit_busy_cnt = BM_CNT_ZERO;
for (i = 0; i < nBANK_MACHS; i = i + 1)
if (rb_hit_busy_r[i]) rb_hit_busy_cnt = rb_hit_busy_cnt + BM_CNT_ONE;
end
// Count the number of idle bank machines.
input [nBANK_MACHS-1:0] idle_r;
output reg [BM_CNT_WIDTH-1:0] idle_cnt;
always @(/*AS*/idle_r) begin
idle_cnt = BM_CNT_ZERO;
for (i = 0; i < nBANK_MACHS; i = i + 1)
if (idle_r[i]) idle_cnt = idle_cnt + BM_CNT_ONE;
end
// Report an overall idle status
output idle;
assign idle = init_calib_complete && &idle_r;
// Count the number of bank machines in the ordering queue.
input [nBANK_MACHS-1:0] ordered_r;
output reg [BM_CNT_WIDTH-1:0] order_cnt;
always @(/*AS*/ordered_r) begin
order_cnt = BM_CNT_ZERO;
for (i = 0; i < nBANK_MACHS; i = i + 1)
if (ordered_r[i]) order_cnt = order_cnt + BM_CNT_ONE;
end
input [nBANK_MACHS-1:0] ordered_issued;
output wire adv_order_q;
assign adv_order_q = |ordered_issued;
// Figure out which bank machine is going to accept the next request.
input [nBANK_MACHS-1:0] head_r;
wire [nBANK_MACHS-1:0] next = idle_r & head_r;
output reg[BM_CNT_WIDTH-1:0] bank_mach_next;
always @(/*AS*/next) begin
bank_mach_next = BM_CNT_ZERO;
for (i = 0; i <= nBANK_MACHS-1; i = i + 1)
if (next[i]) bank_mach_next = i[BM_CNT_WIDTH-1:0];
end
input [nBANK_MACHS-1:0] end_rtp;
input [nBANK_MACHS-1:0] passing_open_bank;
input [nBANK_MACHS-1:0] op_exit_req;
output wire [nBANK_MACHS-1:0] op_exit_grant;
output reg low_idle_cnt_r = 1'b0;
input [nBANK_MACHS-1:0] start_pre_wait;
generate
// In support of open page mode, the following logic
// keeps track of how many "idle" bank machines there
// are. In this case, idle means a bank machine is on
// the idle list, or is in the process of precharging and
// will soon be idle.
if (nOP_WAIT == 0) begin : op_mode_disabled
assign op_exit_grant = {nBANK_MACHS{1'b0}};
end
else begin : op_mode_enabled
reg [BM_CNT_WIDTH:0] idle_cnt_r;
reg [BM_CNT_WIDTH:0] idle_cnt_ns;
always @(/*AS*/accept_req_lcl or idle_cnt_r or passing_open_bank
or rst or start_pre_wait)
if (rst) idle_cnt_ns = nBANK_MACHS;
else begin
idle_cnt_ns = idle_cnt_r - accept_req_lcl;
for (i = 0; i <= nBANK_MACHS-1; i = i + 1) begin
idle_cnt_ns = idle_cnt_ns + passing_open_bank[i];
end
idle_cnt_ns = idle_cnt_ns + |start_pre_wait;
end
always @(posedge clk) idle_cnt_r <= #TCQ idle_cnt_ns;
wire low_idle_cnt_ns = (idle_cnt_ns <= LOW_IDLE_CNT[0+:BM_CNT_WIDTH]);
always @(posedge clk) low_idle_cnt_r <= #TCQ low_idle_cnt_ns;
// This arbiter determines which bank machine should transition
// from open page wait to precharge. Ideally, this process
// would take the oldest waiter, but don't have any reasonable
// way to implement that. Instead, just use simple round robin
// arb with the small enhancement that the most recent bank machine
// to enter open page wait is given lowest priority in the arbiter.
wire upd_last_master = |end_rtp; // should be one bit set at most
mig_7series_v2_3_round_robin_arb #
(.WIDTH (nBANK_MACHS))
op_arb0
(.grant_ns (op_exit_grant[nBANK_MACHS-1:0]),
.grant_r (),
.upd_last_master (upd_last_master),
.current_master (end_rtp[nBANK_MACHS-1:0]),
.clk (clk),
.rst (rst),
.req (op_exit_req[nBANK_MACHS-1:0]),
.disable_grant (1'b0));
end
endgenerate
// Register some command information. This information will be used
// by the bank machines to figure out if there is something behind it
// in the queue that require hi priority.
input [2:0] cmd;
output reg was_wr;
always @(posedge clk) was_wr <= #TCQ
cmd[0] && ~(periodic_rd_r && ~periodic_rd_ack_r_lcl);
input hi_priority;
output reg was_priority;
always @(posedge clk) begin
if (hi_priority)
was_priority <= #TCQ 1'b1;
else
was_priority <= #TCQ 1'b0;
end
// DRAM maintenance (refresh and ZQ) and self-refresh controller
input maint_req_r;
reg maint_wip_r_lcl;
output wire maint_wip_r;
assign maint_wip_r = maint_wip_r_lcl;
wire maint_idle_lcl;
output wire maint_idle;
assign maint_idle = maint_idle_lcl;
input maint_zq_r;
input maint_sre_r;
input maint_srx_r;
input [nBANK_MACHS-1:0] maint_hit;
input [nBANK_MACHS-1:0] bm_end;
wire start_maint;
wire maint_end;
generate begin : maint_controller
// Idle when not (maintenance work in progress (wip), OR maintenance
// starting tick).
assign maint_idle_lcl = ~(maint_req_r || maint_wip_r_lcl);
// Maintenance work in progress starts with maint_reg_r tick, terminated
// with maint_end tick. maint_end tick is generated by the RFC/ZQ/XSDLL timer
// below.
wire maint_wip_ns =
~rst && ~maint_end && (maint_wip_r_lcl || maint_req_r);
always @(posedge clk) maint_wip_r_lcl <= #TCQ maint_wip_ns;
// Keep track of which bank machines hit on the maintenance request
// when the request is made. As bank machines complete, an assertion
// of the bm_end signal clears the correspoding bit in the
// maint_hit_busies_r vector. Eventually, all bits should clear and
// the maintenance operation will proceed. ZQ and self-refresh hit on all
// non idle banks. Refresh hits only on non idle banks with the same rank as
// the refresh request.
wire [nBANK_MACHS-1:0] clear_vector = {nBANK_MACHS{rst}} | bm_end;
wire [nBANK_MACHS-1:0] maint_zq_hits = {nBANK_MACHS{maint_idle_lcl}} &
(maint_hit | {nBANK_MACHS{maint_zq_r}}) & ~idle_ns;
wire [nBANK_MACHS-1:0] maint_sre_hits = {nBANK_MACHS{maint_idle_lcl}} &
(maint_hit | {nBANK_MACHS{maint_sre_r}}) & ~idle_ns;
reg [nBANK_MACHS-1:0] maint_hit_busies_r;
wire [nBANK_MACHS-1:0] maint_hit_busies_ns =
~clear_vector & (maint_hit_busies_r | maint_zq_hits | maint_sre_hits);
always @(posedge clk) maint_hit_busies_r <= #TCQ maint_hit_busies_ns;
// Queue is clear of requests conflicting with maintenance.
wire maint_clear = ~maint_idle_lcl && ~|maint_hit_busies_ns;
// Ready to start sending maintenance commands.
wire maint_rdy = maint_clear;
reg maint_rdy_r1;
reg maint_srx_r1;
always @(posedge clk) maint_rdy_r1 <= #TCQ maint_rdy;
always @(posedge clk) maint_srx_r1 <= #TCQ maint_srx_r;
assign start_maint = maint_rdy && ~maint_rdy_r1 || maint_srx_r && ~maint_srx_r1;
end // block: maint_controller
endgenerate
// Figure out how many maintenance commands to send, and send them.
input [7:0] slot_0_present;
input [7:0] slot_1_present;
reg insert_maint_r_lcl;
output wire insert_maint_r;
assign insert_maint_r = insert_maint_r_lcl;
generate begin : generate_maint_cmds
// Count up how many slots are occupied. This tells
// us how many ZQ, SRE or SRX commands to send out.
reg [RANK_WIDTH:0] present_count;
wire [7:0] present = slot_0_present | slot_1_present;
always @(/*AS*/present) begin
present_count = {RANK_WIDTH{1'b0}};
for (i=0; i<8; i=i+1)
present_count = present_count + {{RANK_WIDTH{1'b0}}, present[i]};
end
// For refresh, there is only a single command sent. For
// ZQ, SRE and SRX, each rank present will receive a command. The counter
// below counts down the number of ranks present.
reg [RANK_WIDTH:0] send_cnt_ns;
reg [RANK_WIDTH:0] send_cnt_r;
always @(/*AS*/maint_zq_r or maint_sre_r or maint_srx_r or present_count
or rst or send_cnt_r or start_maint)
if (rst) send_cnt_ns = 4'b0;
else begin
send_cnt_ns = send_cnt_r;
if (start_maint && (maint_zq_r || maint_sre_r || maint_srx_r)) send_cnt_ns = present_count;
if (|send_cnt_ns)
send_cnt_ns = send_cnt_ns - ONE[RANK_WIDTH-1:0];
end
always @(posedge clk) send_cnt_r <= #TCQ send_cnt_ns;
// Insert a maintenance command for start_maint, or when the sent count
// is not zero.
wire insert_maint_ns = start_maint || |send_cnt_r;
always @(posedge clk) insert_maint_r_lcl <= #TCQ insert_maint_ns;
end // block: generate_maint_cmds
endgenerate
// RFC ZQ XSDLL timer. Generates delay from refresh, self-refresh exit or ZQ
// command until the end of the maintenance operation.
// Compute values for RFC, ZQ and XSDLL periods.
localparam nRFC_CLKS = (nCK_PER_CLK == 1) ?
nRFC :
(nCK_PER_CLK == 2) ?
((nRFC/2) + (nRFC%2)) :
// (nCK_PER_CLK == 4)
((nRFC/4) + ((nRFC%4) ? 1 : 0));
localparam nZQCS_CLKS = (nCK_PER_CLK == 1) ?
tZQCS :
(nCK_PER_CLK == 2) ?
((tZQCS/2) + (tZQCS%2)) :
// (nCK_PER_CLK == 4)
((tZQCS/4) + ((tZQCS%4) ? 1 : 0));
localparam nXSDLL_CLKS = (nCK_PER_CLK == 1) ?
nXSDLL :
(nCK_PER_CLK == 2) ?
((nXSDLL/2) + (nXSDLL%2)) :
// (nCK_PER_CLK == 4)
((nXSDLL/4) + ((nXSDLL%4) ? 1 : 0));
localparam RFC_ZQ_TIMER_WIDTH = clogb2(nXSDLL_CLKS + 1);
localparam THREE = 3;
generate begin : rfc_zq_xsdll_timer
reg [RFC_ZQ_TIMER_WIDTH-1:0] rfc_zq_xsdll_timer_ns;
reg [RFC_ZQ_TIMER_WIDTH-1:0] rfc_zq_xsdll_timer_r;
always @(/*AS*/insert_maint_r_lcl or maint_zq_r or maint_sre_r or maint_srx_r
or rfc_zq_xsdll_timer_r or rst) begin
rfc_zq_xsdll_timer_ns = rfc_zq_xsdll_timer_r;
if (rst) rfc_zq_xsdll_timer_ns = {RFC_ZQ_TIMER_WIDTH{1'b0}};
else if (insert_maint_r_lcl) rfc_zq_xsdll_timer_ns = maint_zq_r ?
nZQCS_CLKS :
maint_sre_r ?
{RFC_ZQ_TIMER_WIDTH{1'b0}} :
maint_srx_r ?
nXSDLL_CLKS :
nRFC_CLKS;
else if (|rfc_zq_xsdll_timer_r) rfc_zq_xsdll_timer_ns =
rfc_zq_xsdll_timer_r - ONE[RFC_ZQ_TIMER_WIDTH-1:0];
end
always @(posedge clk) rfc_zq_xsdll_timer_r <= #TCQ rfc_zq_xsdll_timer_ns;
// Based on rfc_zq_xsdll_timer_r, figure out when to release any bank
// machines waiting to send an activate. Need to add two to the end count.
// One because the counter starts a state after the insert_refresh_r, and
// one more because bm_end to insert_refresh_r is one state shorter
// than bm_end to rts_row.
assign maint_end = (rfc_zq_xsdll_timer_r == THREE[RFC_ZQ_TIMER_WIDTH-1:0]);
end // block: rfc_zq_xsdll_timer
endgenerate
endmodule
|
module mig_7series_v2_3_bank_common #
(
parameter TCQ = 100,
parameter BM_CNT_WIDTH = 2,
parameter LOW_IDLE_CNT = 1,
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2,
parameter nOP_WAIT = 0,
parameter nRFC = 44,
parameter nXSDLL = 512,
parameter RANK_WIDTH = 2,
parameter RANKS = 4,
parameter CWL = 5,
parameter tZQCS = 64
)
(/*AUTOARG*/
// Outputs
accept_internal_r, accept_ns, accept, periodic_rd_insert,
periodic_rd_ack_r, accept_req, rb_hit_busy_cnt, idle, idle_cnt, order_cnt,
adv_order_q, bank_mach_next, op_exit_grant, low_idle_cnt_r, was_wr,
was_priority, maint_wip_r, maint_idle, insert_maint_r,
// Inputs
clk, rst, idle_ns, init_calib_complete, periodic_rd_r, use_addr,
rb_hit_busy_r, idle_r, ordered_r, ordered_issued, head_r, end_rtp,
passing_open_bank, op_exit_req, start_pre_wait, cmd, hi_priority, maint_req_r,
maint_zq_r, maint_sre_r, maint_srx_r, maint_hit, bm_end,
slot_0_present, slot_1_present
);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
localparam ZERO = 0;
localparam ONE = 1;
localparam [BM_CNT_WIDTH-1:0] BM_CNT_ZERO = ZERO[0+:BM_CNT_WIDTH];
localparam [BM_CNT_WIDTH-1:0] BM_CNT_ONE = ONE[0+:BM_CNT_WIDTH];
input clk;
input rst;
input [nBANK_MACHS-1:0] idle_ns;
input init_calib_complete;
wire accept_internal_ns = init_calib_complete && |idle_ns;
output reg accept_internal_r;
always @(posedge clk) accept_internal_r <= accept_internal_ns;
wire periodic_rd_ack_ns;
wire accept_ns_lcl = accept_internal_ns && ~periodic_rd_ack_ns;
output wire accept_ns;
assign accept_ns = accept_ns_lcl;
reg accept_r;
always @(posedge clk) accept_r <= #TCQ accept_ns_lcl;
// Wire to user interface informing user that the request has been accepted.
output wire accept;
assign accept = accept_r;
`ifdef MC_SVA
property none_idle;
@(posedge clk) (init_calib_complete && ~|idle_r);
endproperty
all_bank_machines_busy: cover property (none_idle);
`endif
// periodic_rd_insert tells everyone to mux in the periodic read.
input periodic_rd_r;
reg periodic_rd_ack_r_lcl;
reg periodic_rd_cntr_r ;
always @(posedge clk) begin
if (rst) periodic_rd_cntr_r <= #TCQ 1'b0;
else if (periodic_rd_r && periodic_rd_ack_r_lcl)
periodic_rd_cntr_r <= #TCQ ~periodic_rd_cntr_r;
end
wire internal_periodic_rd_ack_r_lcl = (periodic_rd_cntr_r && periodic_rd_ack_r_lcl);
// wire periodic_rd_insert_lcl = periodic_rd_r && ~periodic_rd_ack_r_lcl;
wire periodic_rd_insert_lcl = periodic_rd_r && ~internal_periodic_rd_ack_r_lcl;
output wire periodic_rd_insert;
assign periodic_rd_insert = periodic_rd_insert_lcl;
// periodic_rd_ack_r acknowledges that the read has been accepted
// into the queue.
assign periodic_rd_ack_ns = periodic_rd_insert_lcl && accept_internal_ns;
always @(posedge clk) periodic_rd_ack_r_lcl <= #TCQ periodic_rd_ack_ns;
output wire periodic_rd_ack_r;
assign periodic_rd_ack_r = periodic_rd_ack_r_lcl;
// accept_req tells all q entries that a request has been accepted.
input use_addr;
wire accept_req_lcl = periodic_rd_ack_r_lcl || (accept_r && use_addr);
output wire accept_req;
assign accept_req = accept_req_lcl;
// Count how many non idle bank machines hit on the rank and bank.
input [nBANK_MACHS-1:0] rb_hit_busy_r;
output reg [BM_CNT_WIDTH-1:0] rb_hit_busy_cnt;
integer i;
always @(/*AS*/rb_hit_busy_r) begin
rb_hit_busy_cnt = BM_CNT_ZERO;
for (i = 0; i < nBANK_MACHS; i = i + 1)
if (rb_hit_busy_r[i]) rb_hit_busy_cnt = rb_hit_busy_cnt + BM_CNT_ONE;
end
// Count the number of idle bank machines.
input [nBANK_MACHS-1:0] idle_r;
output reg [BM_CNT_WIDTH-1:0] idle_cnt;
always @(/*AS*/idle_r) begin
idle_cnt = BM_CNT_ZERO;
for (i = 0; i < nBANK_MACHS; i = i + 1)
if (idle_r[i]) idle_cnt = idle_cnt + BM_CNT_ONE;
end
// Report an overall idle status
output idle;
assign idle = init_calib_complete && &idle_r;
// Count the number of bank machines in the ordering queue.
input [nBANK_MACHS-1:0] ordered_r;
output reg [BM_CNT_WIDTH-1:0] order_cnt;
always @(/*AS*/ordered_r) begin
order_cnt = BM_CNT_ZERO;
for (i = 0; i < nBANK_MACHS; i = i + 1)
if (ordered_r[i]) order_cnt = order_cnt + BM_CNT_ONE;
end
input [nBANK_MACHS-1:0] ordered_issued;
output wire adv_order_q;
assign adv_order_q = |ordered_issued;
// Figure out which bank machine is going to accept the next request.
input [nBANK_MACHS-1:0] head_r;
wire [nBANK_MACHS-1:0] next = idle_r & head_r;
output reg[BM_CNT_WIDTH-1:0] bank_mach_next;
always @(/*AS*/next) begin
bank_mach_next = BM_CNT_ZERO;
for (i = 0; i <= nBANK_MACHS-1; i = i + 1)
if (next[i]) bank_mach_next = i[BM_CNT_WIDTH-1:0];
end
input [nBANK_MACHS-1:0] end_rtp;
input [nBANK_MACHS-1:0] passing_open_bank;
input [nBANK_MACHS-1:0] op_exit_req;
output wire [nBANK_MACHS-1:0] op_exit_grant;
output reg low_idle_cnt_r = 1'b0;
input [nBANK_MACHS-1:0] start_pre_wait;
generate
// In support of open page mode, the following logic
// keeps track of how many "idle" bank machines there
// are. In this case, idle means a bank machine is on
// the idle list, or is in the process of precharging and
// will soon be idle.
if (nOP_WAIT == 0) begin : op_mode_disabled
assign op_exit_grant = {nBANK_MACHS{1'b0}};
end
else begin : op_mode_enabled
reg [BM_CNT_WIDTH:0] idle_cnt_r;
reg [BM_CNT_WIDTH:0] idle_cnt_ns;
always @(/*AS*/accept_req_lcl or idle_cnt_r or passing_open_bank
or rst or start_pre_wait)
if (rst) idle_cnt_ns = nBANK_MACHS;
else begin
idle_cnt_ns = idle_cnt_r - accept_req_lcl;
for (i = 0; i <= nBANK_MACHS-1; i = i + 1) begin
idle_cnt_ns = idle_cnt_ns + passing_open_bank[i];
end
idle_cnt_ns = idle_cnt_ns + |start_pre_wait;
end
always @(posedge clk) idle_cnt_r <= #TCQ idle_cnt_ns;
wire low_idle_cnt_ns = (idle_cnt_ns <= LOW_IDLE_CNT[0+:BM_CNT_WIDTH]);
always @(posedge clk) low_idle_cnt_r <= #TCQ low_idle_cnt_ns;
// This arbiter determines which bank machine should transition
// from open page wait to precharge. Ideally, this process
// would take the oldest waiter, but don't have any reasonable
// way to implement that. Instead, just use simple round robin
// arb with the small enhancement that the most recent bank machine
// to enter open page wait is given lowest priority in the arbiter.
wire upd_last_master = |end_rtp; // should be one bit set at most
mig_7series_v2_3_round_robin_arb #
(.WIDTH (nBANK_MACHS))
op_arb0
(.grant_ns (op_exit_grant[nBANK_MACHS-1:0]),
.grant_r (),
.upd_last_master (upd_last_master),
.current_master (end_rtp[nBANK_MACHS-1:0]),
.clk (clk),
.rst (rst),
.req (op_exit_req[nBANK_MACHS-1:0]),
.disable_grant (1'b0));
end
endgenerate
// Register some command information. This information will be used
// by the bank machines to figure out if there is something behind it
// in the queue that require hi priority.
input [2:0] cmd;
output reg was_wr;
always @(posedge clk) was_wr <= #TCQ
cmd[0] && ~(periodic_rd_r && ~periodic_rd_ack_r_lcl);
input hi_priority;
output reg was_priority;
always @(posedge clk) begin
if (hi_priority)
was_priority <= #TCQ 1'b1;
else
was_priority <= #TCQ 1'b0;
end
// DRAM maintenance (refresh and ZQ) and self-refresh controller
input maint_req_r;
reg maint_wip_r_lcl;
output wire maint_wip_r;
assign maint_wip_r = maint_wip_r_lcl;
wire maint_idle_lcl;
output wire maint_idle;
assign maint_idle = maint_idle_lcl;
input maint_zq_r;
input maint_sre_r;
input maint_srx_r;
input [nBANK_MACHS-1:0] maint_hit;
input [nBANK_MACHS-1:0] bm_end;
wire start_maint;
wire maint_end;
generate begin : maint_controller
// Idle when not (maintenance work in progress (wip), OR maintenance
// starting tick).
assign maint_idle_lcl = ~(maint_req_r || maint_wip_r_lcl);
// Maintenance work in progress starts with maint_reg_r tick, terminated
// with maint_end tick. maint_end tick is generated by the RFC/ZQ/XSDLL timer
// below.
wire maint_wip_ns =
~rst && ~maint_end && (maint_wip_r_lcl || maint_req_r);
always @(posedge clk) maint_wip_r_lcl <= #TCQ maint_wip_ns;
// Keep track of which bank machines hit on the maintenance request
// when the request is made. As bank machines complete, an assertion
// of the bm_end signal clears the correspoding bit in the
// maint_hit_busies_r vector. Eventually, all bits should clear and
// the maintenance operation will proceed. ZQ and self-refresh hit on all
// non idle banks. Refresh hits only on non idle banks with the same rank as
// the refresh request.
wire [nBANK_MACHS-1:0] clear_vector = {nBANK_MACHS{rst}} | bm_end;
wire [nBANK_MACHS-1:0] maint_zq_hits = {nBANK_MACHS{maint_idle_lcl}} &
(maint_hit | {nBANK_MACHS{maint_zq_r}}) & ~idle_ns;
wire [nBANK_MACHS-1:0] maint_sre_hits = {nBANK_MACHS{maint_idle_lcl}} &
(maint_hit | {nBANK_MACHS{maint_sre_r}}) & ~idle_ns;
reg [nBANK_MACHS-1:0] maint_hit_busies_r;
wire [nBANK_MACHS-1:0] maint_hit_busies_ns =
~clear_vector & (maint_hit_busies_r | maint_zq_hits | maint_sre_hits);
always @(posedge clk) maint_hit_busies_r <= #TCQ maint_hit_busies_ns;
// Queue is clear of requests conflicting with maintenance.
wire maint_clear = ~maint_idle_lcl && ~|maint_hit_busies_ns;
// Ready to start sending maintenance commands.
wire maint_rdy = maint_clear;
reg maint_rdy_r1;
reg maint_srx_r1;
always @(posedge clk) maint_rdy_r1 <= #TCQ maint_rdy;
always @(posedge clk) maint_srx_r1 <= #TCQ maint_srx_r;
assign start_maint = maint_rdy && ~maint_rdy_r1 || maint_srx_r && ~maint_srx_r1;
end // block: maint_controller
endgenerate
// Figure out how many maintenance commands to send, and send them.
input [7:0] slot_0_present;
input [7:0] slot_1_present;
reg insert_maint_r_lcl;
output wire insert_maint_r;
assign insert_maint_r = insert_maint_r_lcl;
generate begin : generate_maint_cmds
// Count up how many slots are occupied. This tells
// us how many ZQ, SRE or SRX commands to send out.
reg [RANK_WIDTH:0] present_count;
wire [7:0] present = slot_0_present | slot_1_present;
always @(/*AS*/present) begin
present_count = {RANK_WIDTH{1'b0}};
for (i=0; i<8; i=i+1)
present_count = present_count + {{RANK_WIDTH{1'b0}}, present[i]};
end
// For refresh, there is only a single command sent. For
// ZQ, SRE and SRX, each rank present will receive a command. The counter
// below counts down the number of ranks present.
reg [RANK_WIDTH:0] send_cnt_ns;
reg [RANK_WIDTH:0] send_cnt_r;
always @(/*AS*/maint_zq_r or maint_sre_r or maint_srx_r or present_count
or rst or send_cnt_r or start_maint)
if (rst) send_cnt_ns = 4'b0;
else begin
send_cnt_ns = send_cnt_r;
if (start_maint && (maint_zq_r || maint_sre_r || maint_srx_r)) send_cnt_ns = present_count;
if (|send_cnt_ns)
send_cnt_ns = send_cnt_ns - ONE[RANK_WIDTH-1:0];
end
always @(posedge clk) send_cnt_r <= #TCQ send_cnt_ns;
// Insert a maintenance command for start_maint, or when the sent count
// is not zero.
wire insert_maint_ns = start_maint || |send_cnt_r;
always @(posedge clk) insert_maint_r_lcl <= #TCQ insert_maint_ns;
end // block: generate_maint_cmds
endgenerate
// RFC ZQ XSDLL timer. Generates delay from refresh, self-refresh exit or ZQ
// command until the end of the maintenance operation.
// Compute values for RFC, ZQ and XSDLL periods.
localparam nRFC_CLKS = (nCK_PER_CLK == 1) ?
nRFC :
(nCK_PER_CLK == 2) ?
((nRFC/2) + (nRFC%2)) :
// (nCK_PER_CLK == 4)
((nRFC/4) + ((nRFC%4) ? 1 : 0));
localparam nZQCS_CLKS = (nCK_PER_CLK == 1) ?
tZQCS :
(nCK_PER_CLK == 2) ?
((tZQCS/2) + (tZQCS%2)) :
// (nCK_PER_CLK == 4)
((tZQCS/4) + ((tZQCS%4) ? 1 : 0));
localparam nXSDLL_CLKS = (nCK_PER_CLK == 1) ?
nXSDLL :
(nCK_PER_CLK == 2) ?
((nXSDLL/2) + (nXSDLL%2)) :
// (nCK_PER_CLK == 4)
((nXSDLL/4) + ((nXSDLL%4) ? 1 : 0));
localparam RFC_ZQ_TIMER_WIDTH = clogb2(nXSDLL_CLKS + 1);
localparam THREE = 3;
generate begin : rfc_zq_xsdll_timer
reg [RFC_ZQ_TIMER_WIDTH-1:0] rfc_zq_xsdll_timer_ns;
reg [RFC_ZQ_TIMER_WIDTH-1:0] rfc_zq_xsdll_timer_r;
always @(/*AS*/insert_maint_r_lcl or maint_zq_r or maint_sre_r or maint_srx_r
or rfc_zq_xsdll_timer_r or rst) begin
rfc_zq_xsdll_timer_ns = rfc_zq_xsdll_timer_r;
if (rst) rfc_zq_xsdll_timer_ns = {RFC_ZQ_TIMER_WIDTH{1'b0}};
else if (insert_maint_r_lcl) rfc_zq_xsdll_timer_ns = maint_zq_r ?
nZQCS_CLKS :
maint_sre_r ?
{RFC_ZQ_TIMER_WIDTH{1'b0}} :
maint_srx_r ?
nXSDLL_CLKS :
nRFC_CLKS;
else if (|rfc_zq_xsdll_timer_r) rfc_zq_xsdll_timer_ns =
rfc_zq_xsdll_timer_r - ONE[RFC_ZQ_TIMER_WIDTH-1:0];
end
always @(posedge clk) rfc_zq_xsdll_timer_r <= #TCQ rfc_zq_xsdll_timer_ns;
// Based on rfc_zq_xsdll_timer_r, figure out when to release any bank
// machines waiting to send an activate. Need to add two to the end count.
// One because the counter starts a state after the insert_refresh_r, and
// one more because bm_end to insert_refresh_r is one state shorter
// than bm_end to rts_row.
assign maint_end = (rfc_zq_xsdll_timer_r == THREE[RFC_ZQ_TIMER_WIDTH-1:0]);
end // block: rfc_zq_xsdll_timer
endgenerate
endmodule
|
module mig_7series_v2_3_poc_edge_store #
(parameter TCQ = 100,
parameter TAPCNTRWIDTH = 7,
parameter TAPSPERKCLK = 112)
(/*AUTOARG*/
// Outputs
fall_lead, fall_trail, rise_lead, rise_trail,
// Inputs
clk, run_polarity, run_end, select0, select1, tap, run
);
input clk;
input run_polarity;
input run_end;
input select0;
input select1;
input [TAPCNTRWIDTH-1:0] tap;
input [TAPCNTRWIDTH-1:0] run;
wire [TAPCNTRWIDTH:0] trailing_edge = run > tap ? tap + TAPSPERKCLK[TAPCNTRWIDTH-1:0] - run
: tap - run;
wire run_end_this = run_end && select0 && select1;
reg [TAPCNTRWIDTH-1:0] fall_lead_r, fall_trail_r, rise_lead_r, rise_trail_r;
output [TAPCNTRWIDTH-1:0] fall_lead, fall_trail, rise_lead, rise_trail;
assign fall_lead = fall_lead_r;
assign fall_trail = fall_trail_r;
assign rise_lead = rise_lead_r;
assign rise_trail = rise_trail_r;
wire [TAPCNTRWIDTH-1:0] fall_lead_ns = run_end_this & run_polarity ? tap : fall_lead_r;
wire [TAPCNTRWIDTH-1:0] rise_trail_ns = run_end_this & run_polarity ? trailing_edge[TAPCNTRWIDTH-1:0]
: rise_trail_r;
wire [TAPCNTRWIDTH-1:0] rise_lead_ns = run_end_this & ~run_polarity ? tap : rise_lead_r;
wire [TAPCNTRWIDTH-1:0] fall_trail_ns = run_end_this & ~run_polarity ? trailing_edge[TAPCNTRWIDTH-1:0]
: fall_trail_r;
always @(posedge clk) fall_lead_r <= #TCQ fall_lead_ns;
always @(posedge clk) fall_trail_r <= #TCQ fall_trail_ns;
always @(posedge clk) rise_lead_r <= #TCQ rise_lead_ns;
always @(posedge clk) rise_trail_r <= #TCQ rise_trail_ns;
endmodule
|
module mig_7series_v2_3_poc_edge_store #
(parameter TCQ = 100,
parameter TAPCNTRWIDTH = 7,
parameter TAPSPERKCLK = 112)
(/*AUTOARG*/
// Outputs
fall_lead, fall_trail, rise_lead, rise_trail,
// Inputs
clk, run_polarity, run_end, select0, select1, tap, run
);
input clk;
input run_polarity;
input run_end;
input select0;
input select1;
input [TAPCNTRWIDTH-1:0] tap;
input [TAPCNTRWIDTH-1:0] run;
wire [TAPCNTRWIDTH:0] trailing_edge = run > tap ? tap + TAPSPERKCLK[TAPCNTRWIDTH-1:0] - run
: tap - run;
wire run_end_this = run_end && select0 && select1;
reg [TAPCNTRWIDTH-1:0] fall_lead_r, fall_trail_r, rise_lead_r, rise_trail_r;
output [TAPCNTRWIDTH-1:0] fall_lead, fall_trail, rise_lead, rise_trail;
assign fall_lead = fall_lead_r;
assign fall_trail = fall_trail_r;
assign rise_lead = rise_lead_r;
assign rise_trail = rise_trail_r;
wire [TAPCNTRWIDTH-1:0] fall_lead_ns = run_end_this & run_polarity ? tap : fall_lead_r;
wire [TAPCNTRWIDTH-1:0] rise_trail_ns = run_end_this & run_polarity ? trailing_edge[TAPCNTRWIDTH-1:0]
: rise_trail_r;
wire [TAPCNTRWIDTH-1:0] rise_lead_ns = run_end_this & ~run_polarity ? tap : rise_lead_r;
wire [TAPCNTRWIDTH-1:0] fall_trail_ns = run_end_this & ~run_polarity ? trailing_edge[TAPCNTRWIDTH-1:0]
: fall_trail_r;
always @(posedge clk) fall_lead_r <= #TCQ fall_lead_ns;
always @(posedge clk) fall_trail_r <= #TCQ fall_trail_ns;
always @(posedge clk) rise_lead_r <= #TCQ rise_lead_ns;
always @(posedge clk) rise_trail_r <= #TCQ rise_trail_ns;
endmodule
|
module mig_7series_v2_3_poc_edge_store #
(parameter TCQ = 100,
parameter TAPCNTRWIDTH = 7,
parameter TAPSPERKCLK = 112)
(/*AUTOARG*/
// Outputs
fall_lead, fall_trail, rise_lead, rise_trail,
// Inputs
clk, run_polarity, run_end, select0, select1, tap, run
);
input clk;
input run_polarity;
input run_end;
input select0;
input select1;
input [TAPCNTRWIDTH-1:0] tap;
input [TAPCNTRWIDTH-1:0] run;
wire [TAPCNTRWIDTH:0] trailing_edge = run > tap ? tap + TAPSPERKCLK[TAPCNTRWIDTH-1:0] - run
: tap - run;
wire run_end_this = run_end && select0 && select1;
reg [TAPCNTRWIDTH-1:0] fall_lead_r, fall_trail_r, rise_lead_r, rise_trail_r;
output [TAPCNTRWIDTH-1:0] fall_lead, fall_trail, rise_lead, rise_trail;
assign fall_lead = fall_lead_r;
assign fall_trail = fall_trail_r;
assign rise_lead = rise_lead_r;
assign rise_trail = rise_trail_r;
wire [TAPCNTRWIDTH-1:0] fall_lead_ns = run_end_this & run_polarity ? tap : fall_lead_r;
wire [TAPCNTRWIDTH-1:0] rise_trail_ns = run_end_this & run_polarity ? trailing_edge[TAPCNTRWIDTH-1:0]
: rise_trail_r;
wire [TAPCNTRWIDTH-1:0] rise_lead_ns = run_end_this & ~run_polarity ? tap : rise_lead_r;
wire [TAPCNTRWIDTH-1:0] fall_trail_ns = run_end_this & ~run_polarity ? trailing_edge[TAPCNTRWIDTH-1:0]
: fall_trail_r;
always @(posedge clk) fall_lead_r <= #TCQ fall_lead_ns;
always @(posedge clk) fall_trail_r <= #TCQ fall_trail_ns;
always @(posedge clk) rise_lead_r <= #TCQ rise_lead_ns;
always @(posedge clk) rise_trail_r <= #TCQ rise_trail_ns;
endmodule
|
module mig_7series_v2_3_ddr_phy_ocd_cntlr #
(parameter TCQ = 100,
parameter DQS_CNT_WIDTH = 3,
parameter DQS_WIDTH = 8)
(/*AUTOARG*/
// Outputs
wrlvl_final, complex_wrlvl_final, oclk_init_delay_done,
ocd_prech_req, lim_start, complex_oclkdelay_calib_done,
oclkdelay_calib_done, phy_rddata_en_1, phy_rddata_en_2,
phy_rddata_en_3, ocd_cntlr2stg2_dec, oclkdelay_calib_cnt,
reset_scan,
// Inputs
clk, rst, prech_done, oclkdelay_calib_start,
complex_oclkdelay_calib_start, lim_done, phy_rddata_en,
po_counter_read_val, po_rdy, scan_done
);
localparam ONE = 1;
input clk;
input rst;
output wrlvl_final, complex_wrlvl_final;
reg wrlvl_final_ns, wrlvl_final_r, complex_wrlvl_final_ns, complex_wrlvl_final_r;
always @(posedge clk) wrlvl_final_r <= #TCQ wrlvl_final_ns;
always @(posedge clk) complex_wrlvl_final_r <= #TCQ complex_wrlvl_final_ns;
assign wrlvl_final = wrlvl_final_r;
assign complex_wrlvl_final = complex_wrlvl_final_r;
// Completed initial delay increment
output oclk_init_delay_done; // may not need this... maybe for fast cal mode.
assign oclk_init_delay_done = 1'b1;
// Precharge done status from ddr_phy_init
input prech_done;
reg ocd_prech_req_ns, ocd_prech_req_r;
always @(posedge clk) ocd_prech_req_r <= #TCQ ocd_prech_req_ns;
output ocd_prech_req;
assign ocd_prech_req = ocd_prech_req_r;
input oclkdelay_calib_start, complex_oclkdelay_calib_start;
input lim_done;
reg lim_start_ns, lim_start_r;
always @(posedge clk) lim_start_r <= #TCQ lim_start_ns;
output lim_start;
assign lim_start = lim_start_r;
reg complex_oclkdelay_calib_done_ns, complex_oclkdelay_calib_done_r;
always @(posedge clk) complex_oclkdelay_calib_done_r <= #TCQ complex_oclkdelay_calib_done_ns;
output complex_oclkdelay_calib_done;
assign complex_oclkdelay_calib_done = complex_oclkdelay_calib_done_r;
reg oclkdelay_calib_done_ns, oclkdelay_calib_done_r;
always @(posedge clk) oclkdelay_calib_done_r <= #TCQ oclkdelay_calib_done_ns;
output oclkdelay_calib_done;
assign oclkdelay_calib_done = oclkdelay_calib_done_r;
input phy_rddata_en;
reg prde_r1, prde_r2;
always @(posedge clk) prde_r1 <= #TCQ phy_rddata_en;
always @(posedge clk) prde_r2 <= #TCQ prde_r1;
wire prde = complex_oclkdelay_calib_start ? prde_r2 : phy_rddata_en;
reg phy_rddata_en_r1, phy_rddata_en_r2, phy_rddata_en_r3;
always @(posedge clk) phy_rddata_en_r1 <= #TCQ prde;
always @(posedge clk) phy_rddata_en_r2 <= #TCQ phy_rddata_en_r1;
always @(posedge clk) phy_rddata_en_r3 <= #TCQ phy_rddata_en_r2;
output phy_rddata_en_1, phy_rddata_en_2, phy_rddata_en_3;
assign phy_rddata_en_1 = phy_rddata_en_r1;
assign phy_rddata_en_2 = phy_rddata_en_r2;
assign phy_rddata_en_3 = phy_rddata_en_r3;
input [8:0] po_counter_read_val;
reg ocd_cntlr2stg2_dec_r;
output ocd_cntlr2stg2_dec;
assign ocd_cntlr2stg2_dec = ocd_cntlr2stg2_dec_r;
input po_rdy;
reg [3:0] po_rd_wait_ns, po_rd_wait_r;
always @(posedge clk) po_rd_wait_r <= #TCQ po_rd_wait_ns;
reg [DQS_CNT_WIDTH-1:0] byte_ns, byte_r;
always @(posedge clk) byte_r <= #TCQ byte_ns;
output [DQS_CNT_WIDTH:0] oclkdelay_calib_cnt;
assign oclkdelay_calib_cnt = {1'b0, byte_r};
reg reset_scan_ns, reset_scan_r;
always @(posedge clk) reset_scan_r <= #TCQ reset_scan_ns;
output reset_scan;
assign reset_scan = reset_scan_r;
input scan_done;
reg [2:0] sm_ns, sm_r;
always @(posedge clk) sm_r <= #TCQ sm_ns;
// Primary state machine.
always @(*) begin
// Default next state assignments.
byte_ns = byte_r;
complex_wrlvl_final_ns = complex_wrlvl_final_r;
lim_start_ns = lim_start_r;
oclkdelay_calib_done_ns = oclkdelay_calib_done_r;
complex_oclkdelay_calib_done_ns = complex_oclkdelay_calib_done_r;
ocd_cntlr2stg2_dec_r = 1'b0;
po_rd_wait_ns = po_rd_wait_r;
if (|po_rd_wait_r) po_rd_wait_ns = po_rd_wait_r - 4'b1;
reset_scan_ns = reset_scan_r;
wrlvl_final_ns = wrlvl_final_r;
sm_ns = sm_r;
ocd_prech_req_ns= 1'b0;
if (rst == 1'b1) begin
// RESET next states
complex_oclkdelay_calib_done_ns = 1'b0;
complex_wrlvl_final_ns = 1'b0;
sm_ns = /*AK("READY")*/3'd0;
lim_start_ns = 1'b0;
oclkdelay_calib_done_ns = 1'b0;
reset_scan_ns = 1'b1;
wrlvl_final_ns = 1'b0;
end else
// State based actions and next states.
case (sm_r)
/*AL("READY")*/3'd0: begin
byte_ns = {DQS_CNT_WIDTH{1'b0}};
if (oclkdelay_calib_start && ~oclkdelay_calib_done_r ||
complex_oclkdelay_calib_start && ~complex_oclkdelay_calib_done_r)
begin
sm_ns = /*AK("LIMIT_START")*/3'd1;
lim_start_ns = 1'b1;
end
end
/*AL("LIMIT_START")*/3'd1:
sm_ns = /*AK("LIMIT_WAIT")*/3'd2;
/*AL("LIMIT_WAIT")*/3'd2:begin
if (lim_done) begin
lim_start_ns = 1'b0;
sm_ns = /*AK("SCAN")*/3'd3;
reset_scan_ns = 1'b0;
end
end
/*AL("SCAN")*/3'd3:begin
if (scan_done) begin
reset_scan_ns = 1'b1;
sm_ns = /*AK("COMPUTE")*/3'd4;
end
end
/*AL("COMPUTE")*/3'd4:begin
sm_ns = /*AK("PRECHARGE")*/3'd5;
ocd_prech_req_ns = 1'b1;
end
/*AL("PRECHARGE")*/3'd5:begin
if (prech_done) sm_ns = /*AK("DONE")*/3'd6;
end
/*AL("DONE")*/3'd6:begin
byte_ns = byte_r + ONE[DQS_CNT_WIDTH-1:0];
if ({1'b0, byte_r} == DQS_WIDTH[DQS_CNT_WIDTH:0] - ONE[DQS_WIDTH:0]) begin
byte_ns = {DQS_CNT_WIDTH{1'b0}};
po_rd_wait_ns = 4'd8;
sm_ns = /*AK("STG2_2_ZERO")*/3'd7;
end else begin
sm_ns = /*AK("LIMIT_START")*/3'd1;
lim_start_ns = 1'b1;
end
end
/*AL("STG2_2_ZERO")*/3'd7:
if (~|po_rd_wait_r && po_rdy)
if (|po_counter_read_val[5:0]) ocd_cntlr2stg2_dec_r = 1'b1;
else begin
if ({1'b0, byte_r} == DQS_WIDTH[DQS_CNT_WIDTH:0] - ONE[DQS_WIDTH:0]) begin
sm_ns = /*AK("READY")*/3'd0;
oclkdelay_calib_done_ns= 1'b1;
wrlvl_final_ns = 1'b1;
if (complex_oclkdelay_calib_start) begin
complex_oclkdelay_calib_done_ns = 1'b1;
complex_wrlvl_final_ns = 1'b1;
end
end else begin
byte_ns = byte_r + ONE[DQS_CNT_WIDTH-1:0];
po_rd_wait_ns = 4'd8;
end
end // else: !if(|po_counter_read_val[5:0])
endcase // case (sm_r)
end // always @ begin
endmodule
|
module outputs)
wire cs_en0; // From arb_row_col0 of arb_row_col.v
wire cs_en1; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_col_r; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_col_wr; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_config_r; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_row_r; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_pre_r; // From arb_row_col0 of arb_row_col.v
wire send_cmd0_row; // From arb_row_col0 of arb_row_col.v
wire send_cmd0_col; // From arb_row_col0 of arb_row_col.v
wire send_cmd1_row; // From arb_row_col0 of arb_row_col.v
wire send_cmd1_col;
wire send_cmd2_row;
wire send_cmd2_col;
wire send_cmd2_pre;
wire send_cmd3_col;
wire [5:0] col_channel_offset;
// End of automatics
wire sent_col_i;
wire cs_en2;
wire cs_en3;
assign sent_col = sent_col_i;
mig_7series_v2_3_arb_row_col #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.CWL (CWL),
.EARLY_WR_DATA_ADDR (EARLY_WR_DATA_ADDR),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nRAS (nRAS),
.nRCD (nRCD),
.nWR (nWR))
arb_row_col0
(/*AUTOINST*/
// Outputs
.grant_row_r (grant_row_r[nBANK_MACHS-1:0]),
.grant_pre_r (grant_pre_r[nBANK_MACHS-1:0]),
.sent_row (sent_row),
.sending_row (sending_row[nBANK_MACHS-1:0]),
.sending_pre (sending_pre[nBANK_MACHS-1:0]),
.grant_config_r (grant_config_r[nBANK_MACHS-1:0]),
.rnk_config_strobe (rnk_config_strobe),
.rnk_config_kill_rts_col (rnk_config_kill_rts_col),
.rnk_config_valid_r (rnk_config_valid_r),
.grant_col_r (grant_col_r[nBANK_MACHS-1:0]),
.sending_col (sending_col[nBANK_MACHS-1:0]),
.sent_col (sent_col_i),
.sent_col_r (sent_col_r),
.grant_col_wr (grant_col_wr[nBANK_MACHS-1:0]),
.send_cmd0_row (send_cmd0_row),
.send_cmd0_col (send_cmd0_col),
.send_cmd1_row (send_cmd1_row),
.send_cmd1_col (send_cmd1_col),
.send_cmd2_row (send_cmd2_row),
.send_cmd2_col (send_cmd2_col),
.send_cmd2_pre (send_cmd2_pre),
.send_cmd3_col (send_cmd3_col),
.col_channel_offset (col_channel_offset),
.cs_en0 (cs_en0),
.cs_en1 (cs_en1),
.cs_en2 (cs_en2),
.cs_en3 (cs_en3),
.insert_maint_r1 (insert_maint_r1),
// Inputs
.clk (clk),
.rst (rst),
.rts_row (rts_row[nBANK_MACHS-1:0]),
.rts_pre (rts_pre[nBANK_MACHS-1:0]),
.insert_maint_r (insert_maint_r),
.rts_col (rts_col[nBANK_MACHS-1:0]),
.rtc (rtc[nBANK_MACHS-1:0]),
.col_rdy_wr (col_rdy_wr[nBANK_MACHS-1:0]));
mig_7series_v2_3_arb_select #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.EVEN_CWL_2T_MODE (EVEN_CWL_2T_MODE),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_VECT_INDX (BANK_VECT_INDX),
.BANK_WIDTH (BANK_WIDTH),
.BURST_MODE (BURST_MODE),
.CS_WIDTH (CS_WIDTH),
.CL (CL),
.CWL (CWL),
.DATA_BUF_ADDR_VECT_INDX (DATA_BUF_ADDR_VECT_INDX),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.EARLY_WR_DATA_ADDR (EARLY_WR_DATA_ADDR),
.ECC (ECC),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.nSLOTS (nSLOTS),
.RANKS (RANKS),
.RANK_VECT_INDX (RANK_VECT_INDX),
.RANK_WIDTH (RANK_WIDTH),
.ROW_VECT_INDX (ROW_VECT_INDX),
.ROW_WIDTH (ROW_WIDTH),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.SLOT_0_CONFIG (SLOT_0_CONFIG),
.SLOT_1_CONFIG (SLOT_1_CONFIG))
arb_select0
(/*AUTOINST*/
// Outputs
.col_periodic_rd (col_periodic_rd),
.col_ra (col_ra[RANK_WIDTH-1:0]),
.col_ba (col_ba[BANK_WIDTH-1:0]),
.col_a (col_a[ROW_WIDTH-1:0]),
.col_rmw (col_rmw),
.col_rd_wr (col_rd_wr),
.col_size (col_size),
.col_row (col_row[ROW_WIDTH-1:0]),
.col_data_buf_addr (col_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.col_wr_data_buf_addr (col_wr_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.mc_bank (mc_bank),
.mc_address (mc_address),
.mc_ras_n (mc_ras_n),
.mc_cas_n (mc_cas_n),
.mc_we_n (mc_we_n),
.mc_cs_n (mc_cs_n),
.mc_odt (mc_odt),
.mc_cke (mc_cke),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_cmd (mc_cmd),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_cas_slot (mc_cas_slot),
.col_channel_offset (col_channel_offset),
.rnk_config (rnk_config),
// Inputs
.clk (clk),
.rst (rst),
.init_calib_complete (init_calib_complete),
.calib_rddata_offset (calib_rddata_offset),
.calib_rddata_offset_1 (calib_rddata_offset_1),
.calib_rddata_offset_2 (calib_rddata_offset_2),
.req_rank_r (req_rank_r[RANK_VECT_INDX:0]),
.req_bank_r (req_bank_r[BANK_VECT_INDX:0]),
.req_ras (req_ras[nBANK_MACHS-1:0]),
.req_cas (req_cas[nBANK_MACHS-1:0]),
.req_wr_r (req_wr_r[nBANK_MACHS-1:0]),
.grant_row_r (grant_row_r[nBANK_MACHS-1:0]),
.grant_pre_r (grant_pre_r[nBANK_MACHS-1:0]),
.row_addr (row_addr[ROW_VECT_INDX:0]),
.row_cmd_wr (row_cmd_wr[nBANK_MACHS-1:0]),
.insert_maint_r1 (insert_maint_r1),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.maint_srx_r (maint_srx_r),
.maint_rank_r (maint_rank_r[RANK_WIDTH-1:0]),
.req_periodic_rd_r (req_periodic_rd_r[nBANK_MACHS-1:0]),
.req_size_r (req_size_r[nBANK_MACHS-1:0]),
.rd_wr_r (rd_wr_r[nBANK_MACHS-1:0]),
.req_row_r (req_row_r[ROW_VECT_INDX:0]),
.col_addr (col_addr[ROW_VECT_INDX:0]),
.req_data_buf_addr_r (req_data_buf_addr_r[DATA_BUF_ADDR_VECT_INDX:0]),
.grant_col_r (grant_col_r[nBANK_MACHS-1:0]),
.grant_col_wr (grant_col_wr[nBANK_MACHS-1:0]),
.send_cmd0_row (send_cmd0_row),
.send_cmd0_col (send_cmd0_col),
.send_cmd1_row (send_cmd1_row),
.send_cmd1_col (send_cmd1_col),
.send_cmd2_row (send_cmd2_row),
.send_cmd2_col (send_cmd2_col),
.send_cmd2_pre (send_cmd2_pre),
.send_cmd3_col (send_cmd3_col),
.sent_col (EVEN_CWL_2T_MODE == "ON" ? sent_col_r : sent_col),
.cs_en0 (cs_en0),
.cs_en1 (cs_en1),
.cs_en2 (cs_en2),
.cs_en3 (cs_en3),
.grant_config_r (grant_config_r[nBANK_MACHS-1:0]),
.rnk_config_strobe (rnk_config_strobe),
.slot_0_present (slot_0_present[7:0]),
.slot_1_present (slot_1_present[7:0]));
endmodule
|
module outputs)
wire cs_en0; // From arb_row_col0 of arb_row_col.v
wire cs_en1; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_col_r; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_col_wr; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_config_r; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_row_r; // From arb_row_col0 of arb_row_col.v
wire [nBANK_MACHS-1:0] grant_pre_r; // From arb_row_col0 of arb_row_col.v
wire send_cmd0_row; // From arb_row_col0 of arb_row_col.v
wire send_cmd0_col; // From arb_row_col0 of arb_row_col.v
wire send_cmd1_row; // From arb_row_col0 of arb_row_col.v
wire send_cmd1_col;
wire send_cmd2_row;
wire send_cmd2_col;
wire send_cmd2_pre;
wire send_cmd3_col;
wire [5:0] col_channel_offset;
// End of automatics
wire sent_col_i;
wire cs_en2;
wire cs_en3;
assign sent_col = sent_col_i;
mig_7series_v2_3_arb_row_col #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.CWL (CWL),
.EARLY_WR_DATA_ADDR (EARLY_WR_DATA_ADDR),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nRAS (nRAS),
.nRCD (nRCD),
.nWR (nWR))
arb_row_col0
(/*AUTOINST*/
// Outputs
.grant_row_r (grant_row_r[nBANK_MACHS-1:0]),
.grant_pre_r (grant_pre_r[nBANK_MACHS-1:0]),
.sent_row (sent_row),
.sending_row (sending_row[nBANK_MACHS-1:0]),
.sending_pre (sending_pre[nBANK_MACHS-1:0]),
.grant_config_r (grant_config_r[nBANK_MACHS-1:0]),
.rnk_config_strobe (rnk_config_strobe),
.rnk_config_kill_rts_col (rnk_config_kill_rts_col),
.rnk_config_valid_r (rnk_config_valid_r),
.grant_col_r (grant_col_r[nBANK_MACHS-1:0]),
.sending_col (sending_col[nBANK_MACHS-1:0]),
.sent_col (sent_col_i),
.sent_col_r (sent_col_r),
.grant_col_wr (grant_col_wr[nBANK_MACHS-1:0]),
.send_cmd0_row (send_cmd0_row),
.send_cmd0_col (send_cmd0_col),
.send_cmd1_row (send_cmd1_row),
.send_cmd1_col (send_cmd1_col),
.send_cmd2_row (send_cmd2_row),
.send_cmd2_col (send_cmd2_col),
.send_cmd2_pre (send_cmd2_pre),
.send_cmd3_col (send_cmd3_col),
.col_channel_offset (col_channel_offset),
.cs_en0 (cs_en0),
.cs_en1 (cs_en1),
.cs_en2 (cs_en2),
.cs_en3 (cs_en3),
.insert_maint_r1 (insert_maint_r1),
// Inputs
.clk (clk),
.rst (rst),
.rts_row (rts_row[nBANK_MACHS-1:0]),
.rts_pre (rts_pre[nBANK_MACHS-1:0]),
.insert_maint_r (insert_maint_r),
.rts_col (rts_col[nBANK_MACHS-1:0]),
.rtc (rtc[nBANK_MACHS-1:0]),
.col_rdy_wr (col_rdy_wr[nBANK_MACHS-1:0]));
mig_7series_v2_3_arb_select #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.EVEN_CWL_2T_MODE (EVEN_CWL_2T_MODE),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_VECT_INDX (BANK_VECT_INDX),
.BANK_WIDTH (BANK_WIDTH),
.BURST_MODE (BURST_MODE),
.CS_WIDTH (CS_WIDTH),
.CL (CL),
.CWL (CWL),
.DATA_BUF_ADDR_VECT_INDX (DATA_BUF_ADDR_VECT_INDX),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.EARLY_WR_DATA_ADDR (EARLY_WR_DATA_ADDR),
.ECC (ECC),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.nSLOTS (nSLOTS),
.RANKS (RANKS),
.RANK_VECT_INDX (RANK_VECT_INDX),
.RANK_WIDTH (RANK_WIDTH),
.ROW_VECT_INDX (ROW_VECT_INDX),
.ROW_WIDTH (ROW_WIDTH),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.SLOT_0_CONFIG (SLOT_0_CONFIG),
.SLOT_1_CONFIG (SLOT_1_CONFIG))
arb_select0
(/*AUTOINST*/
// Outputs
.col_periodic_rd (col_periodic_rd),
.col_ra (col_ra[RANK_WIDTH-1:0]),
.col_ba (col_ba[BANK_WIDTH-1:0]),
.col_a (col_a[ROW_WIDTH-1:0]),
.col_rmw (col_rmw),
.col_rd_wr (col_rd_wr),
.col_size (col_size),
.col_row (col_row[ROW_WIDTH-1:0]),
.col_data_buf_addr (col_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.col_wr_data_buf_addr (col_wr_data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.mc_bank (mc_bank),
.mc_address (mc_address),
.mc_ras_n (mc_ras_n),
.mc_cas_n (mc_cas_n),
.mc_we_n (mc_we_n),
.mc_cs_n (mc_cs_n),
.mc_odt (mc_odt),
.mc_cke (mc_cke),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_cmd (mc_cmd),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_cas_slot (mc_cas_slot),
.col_channel_offset (col_channel_offset),
.rnk_config (rnk_config),
// Inputs
.clk (clk),
.rst (rst),
.init_calib_complete (init_calib_complete),
.calib_rddata_offset (calib_rddata_offset),
.calib_rddata_offset_1 (calib_rddata_offset_1),
.calib_rddata_offset_2 (calib_rddata_offset_2),
.req_rank_r (req_rank_r[RANK_VECT_INDX:0]),
.req_bank_r (req_bank_r[BANK_VECT_INDX:0]),
.req_ras (req_ras[nBANK_MACHS-1:0]),
.req_cas (req_cas[nBANK_MACHS-1:0]),
.req_wr_r (req_wr_r[nBANK_MACHS-1:0]),
.grant_row_r (grant_row_r[nBANK_MACHS-1:0]),
.grant_pre_r (grant_pre_r[nBANK_MACHS-1:0]),
.row_addr (row_addr[ROW_VECT_INDX:0]),
.row_cmd_wr (row_cmd_wr[nBANK_MACHS-1:0]),
.insert_maint_r1 (insert_maint_r1),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.maint_srx_r (maint_srx_r),
.maint_rank_r (maint_rank_r[RANK_WIDTH-1:0]),
.req_periodic_rd_r (req_periodic_rd_r[nBANK_MACHS-1:0]),
.req_size_r (req_size_r[nBANK_MACHS-1:0]),
.rd_wr_r (rd_wr_r[nBANK_MACHS-1:0]),
.req_row_r (req_row_r[ROW_VECT_INDX:0]),
.col_addr (col_addr[ROW_VECT_INDX:0]),
.req_data_buf_addr_r (req_data_buf_addr_r[DATA_BUF_ADDR_VECT_INDX:0]),
.grant_col_r (grant_col_r[nBANK_MACHS-1:0]),
.grant_col_wr (grant_col_wr[nBANK_MACHS-1:0]),
.send_cmd0_row (send_cmd0_row),
.send_cmd0_col (send_cmd0_col),
.send_cmd1_row (send_cmd1_row),
.send_cmd1_col (send_cmd1_col),
.send_cmd2_row (send_cmd2_row),
.send_cmd2_col (send_cmd2_col),
.send_cmd2_pre (send_cmd2_pre),
.send_cmd3_col (send_cmd3_col),
.sent_col (EVEN_CWL_2T_MODE == "ON" ? sent_col_r : sent_col),
.cs_en0 (cs_en0),
.cs_en1 (cs_en1),
.cs_en2 (cs_en2),
.cs_en3 (cs_en3),
.grant_config_r (grant_config_r[nBANK_MACHS-1:0]),
.rnk_config_strobe (rnk_config_strobe),
.slot_0_present (slot_0_present[7:0]),
.slot_1_present (slot_1_present[7:0]));
endmodule
|
module mig_7series_v2_3_clk_ibuf #
(
parameter SYSCLK_TYPE = "DIFFERENTIAL",
// input clock type
parameter DIFF_TERM_SYSCLK = "TRUE"
// Differential Termination
)
(
// Clock inputs
input sys_clk_p, // System clock diff input
input sys_clk_n,
input sys_clk_i,
output mmcm_clk
);
(* KEEP = "TRUE" *) wire sys_clk_ibufg /* synthesis syn_keep = 1 */;
generate
if (SYSCLK_TYPE == "DIFFERENTIAL") begin: diff_input_clk
//***********************************************************************
// Differential input clock input buffers
//***********************************************************************
IBUFGDS #
(
.DIFF_TERM (DIFF_TERM_SYSCLK),
.IBUF_LOW_PWR ("FALSE")
)
u_ibufg_sys_clk
(
.I (sys_clk_p),
.IB (sys_clk_n),
.O (sys_clk_ibufg)
);
end else if (SYSCLK_TYPE == "SINGLE_ENDED") begin: se_input_clk
//***********************************************************************
// SINGLE_ENDED input clock input buffers
//***********************************************************************
IBUFG #
(
.IBUF_LOW_PWR ("FALSE")
)
u_ibufg_sys_clk
(
.I (sys_clk_i),
.O (sys_clk_ibufg)
);
end else if (SYSCLK_TYPE == "NO_BUFFER") begin: internal_clk
//***********************************************************************
// System clock is driven from FPGA internal clock (clock from fabric)
//***********************************************************************
assign sys_clk_ibufg = sys_clk_i;
end
endgenerate
assign mmcm_clk = sys_clk_ibufg;
endmodule
|
module mig_7series_v2_3_clk_ibuf #
(
parameter SYSCLK_TYPE = "DIFFERENTIAL",
// input clock type
parameter DIFF_TERM_SYSCLK = "TRUE"
// Differential Termination
)
(
// Clock inputs
input sys_clk_p, // System clock diff input
input sys_clk_n,
input sys_clk_i,
output mmcm_clk
);
(* KEEP = "TRUE" *) wire sys_clk_ibufg /* synthesis syn_keep = 1 */;
generate
if (SYSCLK_TYPE == "DIFFERENTIAL") begin: diff_input_clk
//***********************************************************************
// Differential input clock input buffers
//***********************************************************************
IBUFGDS #
(
.DIFF_TERM (DIFF_TERM_SYSCLK),
.IBUF_LOW_PWR ("FALSE")
)
u_ibufg_sys_clk
(
.I (sys_clk_p),
.IB (sys_clk_n),
.O (sys_clk_ibufg)
);
end else if (SYSCLK_TYPE == "SINGLE_ENDED") begin: se_input_clk
//***********************************************************************
// SINGLE_ENDED input clock input buffers
//***********************************************************************
IBUFG #
(
.IBUF_LOW_PWR ("FALSE")
)
u_ibufg_sys_clk
(
.I (sys_clk_i),
.O (sys_clk_ibufg)
);
end else if (SYSCLK_TYPE == "NO_BUFFER") begin: internal_clk
//***********************************************************************
// System clock is driven from FPGA internal clock (clock from fabric)
//***********************************************************************
assign sys_clk_ibufg = sys_clk_i;
end
endgenerate
assign mmcm_clk = sys_clk_ibufg;
endmodule
|
module mig_7series_v2_3_mem_intfc #
(
parameter TCQ = 100,
parameter DDR3_VDD_OP_VOLT = "135", // Voltage mode used for DDR3
parameter PAYLOAD_WIDTH = 64,
parameter ADDR_CMD_MODE = "1T",
parameter AL = "0", // Additive Latency option
parameter BANK_WIDTH = 3, // # of bank bits
parameter BM_CNT_WIDTH = 2, // Bank machine counter width
parameter BURST_MODE = "8", // Burst length
parameter BURST_TYPE = "SEQ", // Burst type
parameter CA_MIRROR = "OFF", // C/A mirror opt for DDR3 dual rank
parameter CK_WIDTH = 1, // # of CK/CK# outputs to memory
// five fields, one per possible I/O bank, 4 bits in each field, 1 per lane
// data=1/ctl=0
parameter DATA_CTL_B0 = 4'hc,
parameter DATA_CTL_B1 = 4'hf,
parameter DATA_CTL_B2 = 4'hf,
parameter DATA_CTL_B3 = 4'hf,
parameter DATA_CTL_B4 = 4'hf,
// defines the byte lanes in I/O banks being used in the interface
// 1- Used, 0- Unused
parameter BYTE_LANES_B0 = 4'b1111,
parameter BYTE_LANES_B1 = 4'b0000,
parameter BYTE_LANES_B2 = 4'b0000,
parameter BYTE_LANES_B3 = 4'b0000,
parameter BYTE_LANES_B4 = 4'b0000,
// defines the bit lanes in I/O banks being used in the interface. Each
// parameter = 1 I/O bank = 4 byte lanes = 48 bit lanes. 1-Used, 0-Unused
parameter PHY_0_BITLANES = 48'h0000_0000_0000,
parameter PHY_1_BITLANES = 48'h0000_0000_0000,
parameter PHY_2_BITLANES = 48'h0000_0000_0000,
// control/address/data pin mapping parameters
parameter CK_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter ADDR_MAP
= 192'h000_000_000_000_000_000_000_000_000_000_000_000_000_000_000_000,
parameter BANK_MAP = 36'h000_000_000,
parameter CAS_MAP = 12'h000,
parameter CKE_ODT_BYTE_MAP = 8'h00,
parameter CKE_MAP = 96'h000_000_000_000_000_000_000_000,
parameter ODT_MAP = 96'h000_000_000_000_000_000_000_000,
parameter CKE_ODT_AUX = "FALSE",
parameter CS_MAP = 120'h000_000_000_000_000_000_000_000_000_000,
parameter PARITY_MAP = 12'h000,
parameter RAS_MAP = 12'h000,
parameter WE_MAP = 12'h000,
parameter DQS_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter DATA0_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA1_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA2_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA3_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA4_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA5_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA6_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA7_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA8_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA9_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA10_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA11_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA12_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA13_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA14_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA15_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA16_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA17_MAP = 96'h000_000_000_000_000_000_000_000,
parameter MASK0_MAP = 108'h000_000_000_000_000_000_000_000_000,
parameter MASK1_MAP = 108'h000_000_000_000_000_000_000_000_000,
// calibration Address. The address given below will be used for calibration
// read and write operations.
parameter CALIB_ROW_ADD = 16'h0000,// Calibration row address
parameter CALIB_COL_ADD = 12'h000, // Calibration column address
parameter CALIB_BA_ADD = 3'h0, // Calibration bank address
parameter CL = 5,
parameter COL_WIDTH = 12, // column address width
parameter CMD_PIPE_PLUS1 = "ON", // add pipeline stage between MC and PHY
parameter CS_WIDTH = 1, // # of unique CS outputs
parameter CKE_WIDTH = 1, // # of cke outputs
parameter CWL = 5,
parameter DATA_WIDTH = 64,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DDR2_DQSN_ENABLE = "YES", // Enable differential DQS for DDR2
parameter DM_WIDTH = 8, // # of DM (data mask)
parameter DQ_CNT_WIDTH = 6, // = ceil(log2(DQ_WIDTH))
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_TYPE = "DDR3",
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter ECC = "OFF",
parameter ECC_WIDTH = 8,
parameter MC_ERR_ADDR_WIDTH = 31,
parameter nAL = 0, // Additive latency (in clk cyc)
parameter nBANK_MACHS = 4,
parameter PRE_REV3ES = "OFF", // Delay O/Ps using Phaser_Out fine dly
parameter nCK_PER_CLK = 4, // # of memory CKs per fabric CLK
parameter nCS_PER_RANK = 1, // # of unique CS outputs per rank
// Hard PHY parameters
parameter PHYCTL_CMD_FIFO = "FALSE",
parameter ORDERING = "NORM",
parameter PHASE_DETECT = "OFF" , // to phy_top
parameter IBUF_LPWR_MODE = "OFF", // to phy_top
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter DATA_IO_PRIM_TYPE = "DEFAULT", // # = "HP_LP", "HR_LP", "DEFAULT"
parameter DATA_IO_IDLE_PWRDWN = "ON", // "ON" or "OFF"
parameter IODELAY_GRP = "IODELAY_MIG", //to phy_top
parameter FPGA_SPEED_GRADE = 1,
parameter OUTPUT_DRV = "HIGH" , // to phy_top
parameter REG_CTRL = "OFF" , // to phy_top
parameter RTT_NOM = "60" , // to phy_top
parameter RTT_WR = "120" , // to phy_top
parameter STARVE_LIMIT = 2,
parameter tCK = 2500, // pS
parameter tCKE = 10000, // pS
parameter tFAW = 40000, // pS
parameter tPRDI = 1_000_000, // pS
parameter tRAS = 37500, // pS
parameter tRCD = 12500, // pS
parameter tREFI = 7800000, // pS
parameter tRFC = 110000, // pS
parameter tRP = 12500, // pS
parameter tRRD = 10000, // pS
parameter tRTP = 7500, // pS
parameter tWTR = 7500, // pS
parameter tZQI = 128_000_000, // nS
parameter tZQCS = 64, // CKs
parameter WRLVL = "OFF" , // to phy_top
parameter DEBUG_PORT = "OFF" , // to phy_top
parameter CAL_WIDTH = "HALF" , // to phy_top
parameter RANK_WIDTH = 1,
parameter RANKS = 4,
parameter ODT_WIDTH = 1,
parameter ROW_WIDTH = 16, // DRAM address bus width
parameter [7:0] SLOT_0_CONFIG = 8'b0000_0001,
parameter [7:0] SLOT_1_CONFIG = 8'b0000_0000,
parameter SIM_BYPASS_INIT_CAL = "OFF",
parameter REFCLK_FREQ = 300.0,
parameter nDQS_COL0 = DQS_WIDTH,
parameter nDQS_COL1 = 0,
parameter nDQS_COL2 = 0,
parameter nDQS_COL3 = 0,
parameter DQS_LOC_COL0 = 144'h11100F0E0D0C0B0A09080706050403020100,
parameter DQS_LOC_COL1 = 0,
parameter DQS_LOC_COL2 = 0,
parameter DQS_LOC_COL3 = 0,
parameter USE_CS_PORT = 1, // Support chip select output
parameter USE_DM_PORT = 1, // Support data mask output
parameter USE_ODT_PORT = 1, // Support ODT output
parameter MASTER_PHY_CTL = 0, // The bank number where master PHY_CONTROL resides
parameter USER_REFRESH = "OFF", // Choose whether MC or User manages REF
parameter TEMP_MON_EN = "ON", // Enable/disable temperature monitoring
parameter IDELAY_ADJ = "ON", // Adjust IDELAY value (-1)
parameter FINE_PER_BIT = "ON", // Use finedelay per-bit de-skew
parameter CENTER_COMP_MODE = "ON", // Use Center compensation table for PI
parameter PI_VAL_ADJ = "ON", // Adjust PI final value (-1)
parameter TAPSPERKCLK = 56
)
(
input clk_ref,
input freq_refclk,
input mem_refclk,
input pll_lock,
input sync_pulse,
input mmcm_ps_clk,
input poc_sample_pd,
input error,
input reset,
output rst_tg_mc,
input [BANK_WIDTH-1:0] bank, // To mc0 of mc.v
input clk ,
input [2:0] cmd, // To mc0 of mc.v
input [COL_WIDTH-1:0] col, // To mc0 of mc.v
input correct_en,
input [DATA_BUF_ADDR_WIDTH-1:0] data_buf_addr, // To mc0 of mc.v
input dbg_idel_down_all,
input dbg_idel_down_cpt,
input dbg_idel_up_all,
input dbg_idel_up_cpt,
input dbg_sel_all_idel_cpt,
input [DQS_CNT_WIDTH-1:0] dbg_sel_idel_cpt,
input hi_priority, // To mc0 of mc.v
input [RANK_WIDTH-1:0] rank, // To mc0 of mc.v
input [2*nCK_PER_CLK-1:0] raw_not_ecc,
input [ROW_WIDTH-1:0] row, // To mc0 of mc.v
input rst, // To mc0 of mc.v, ...
input size, // To mc0 of mc.v
input [7:0] slot_0_present, // To mc0 of mc.v
input [7:0] slot_1_present, // To mc0 of mc.v
input use_addr, // To mc0 of mc.v
input [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data,
input [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask,
output accept, // From mc0 of mc.v
output accept_ns, // From mc0 of mc.v
output [BM_CNT_WIDTH-1:0] bank_mach_next, // From mc0 of mc.v
input app_sr_req,
output app_sr_active,
input app_ref_req,
output app_ref_ack,
input app_zq_req,
output app_zq_ack,
output [255:0] dbg_calib_top,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_first_edge_cnt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_second_edge_cnt,
output [255:0] dbg_phy_rdlvl,
output [99:0] dbg_phy_wrcal,
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output [DQS_WIDTH-1:0] dbg_rd_data_edge_detect,
output [2*nCK_PER_CLK*DQ_WIDTH-1:0] dbg_rddata,
output [1:0] dbg_rdlvl_done,
output [1:0] dbg_rdlvl_err,
output [1:0] dbg_rdlvl_start,
output [5:0] dbg_tap_cnt_during_wrlvl,
output dbg_wl_edge_detect_valid,
output dbg_wrlvl_done,
output dbg_wrlvl_err,
output dbg_wrlvl_start,
output [ROW_WIDTH-1:0] ddr_addr, // From phy_top0 of phy_top.v
output [BANK_WIDTH-1:0] ddr_ba, // From phy_top0 of phy_top.v
output ddr_cas_n, // From phy_top0 of phy_top.v
output [CK_WIDTH-1:0] ddr_ck_n, // From phy_top0 of phy_top.v
output [CK_WIDTH-1:0] ddr_ck , // From phy_top0 of phy_top.v
output [CKE_WIDTH-1:0] ddr_cke, // From phy_top0 of phy_top.v
output [CS_WIDTH*nCS_PER_RANK-1:0] ddr_cs_n, // From phy_top0 of phy_top.v
output [DM_WIDTH-1:0] ddr_dm, // From phy_top0 of phy_top.v
output [ODT_WIDTH-1:0] ddr_odt, // From phy_top0 of phy_top.v
output ddr_ras_n, // From phy_top0 of phy_top.v
output ddr_reset_n, // From phy_top0 of phy_top.v
output ddr_parity,
output ddr_we_n, // From phy_top0 of phy_top.v
output init_calib_complete,
output init_wrcal_complete,
output [MC_ERR_ADDR_WIDTH-1:0] ecc_err_addr,
output [2*nCK_PER_CLK-1:0] ecc_multiple,
output [2*nCK_PER_CLK-1:0] ecc_single,
output wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] rd_data,
output [DATA_BUF_ADDR_WIDTH-1:0] rd_data_addr,
// From mc0 of mc.v
output rd_data_en, // From mc0 of mc.v
output rd_data_end, // From mc0 of mc.v
output [DATA_BUF_OFFSET_WIDTH-1:0] rd_data_offset, // From mc0 of mc.v
output [DATA_BUF_ADDR_WIDTH-1:0] wr_data_addr, // From mc0 of mc.v
output wr_data_en, // From mc0 of mc.v
output [DATA_BUF_OFFSET_WIDTH-1:0] wr_data_offset, // From mc0 of mc.v
inout [DQ_WIDTH-1:0] ddr_dq, // To/From phy_top0 of phy_top.v
inout [DQS_WIDTH-1:0] ddr_dqs_n, // To/From phy_top0 of phy_top.v
inout [DQS_WIDTH-1:0] ddr_dqs // To/From phy_top0 of phy_top.v
,input [11:0] device_temp
//phase shift clock control
,output psen
,output psincdec
,input psdone
,input [DQ_WIDTH/8-1:0] fi_xor_we
,input [DQ_WIDTH-1:0] fi_xor_wrdata
,input dbg_sel_pi_incdec
,input dbg_sel_po_incdec
,input [DQS_CNT_WIDTH:0] dbg_byte_sel
,input dbg_pi_f_inc
,input dbg_pi_f_dec
,input dbg_po_f_inc
,input dbg_po_f_stg23_sel
,input dbg_po_f_dec
,output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_tap_cnt
,output [5*DQS_WIDTH*RANKS-1:0] dbg_dq_idelay_tap_cnt
,output dbg_rddata_valid
,output [6*DQS_WIDTH-1:0] dbg_wrlvl_fine_tap_cnt
,output [3*DQS_WIDTH-1:0] dbg_wrlvl_coarse_tap_cnt
,output [255:0] dbg_phy_wrlvl
,output [5:0] dbg_pi_counter_read_val
,output [8:0] dbg_po_counter_read_val
,output ref_dll_lock
,input rst_phaser_ref
,input iddr_rst
,output [6*RANKS-1:0] dbg_rd_data_offset
,output [255:0] dbg_phy_init
,output [255:0] dbg_prbs_rdlvl
,output [255:0] dbg_dqs_found_cal
,output dbg_pi_phaselock_start
,output dbg_pi_phaselocked_done
,output dbg_pi_phaselock_err
,output dbg_pi_dqsfound_start
,output dbg_pi_dqsfound_done
,output dbg_pi_dqsfound_err
,output dbg_wrcal_start
,output dbg_wrcal_done
,output dbg_wrcal_err
,output [11:0] dbg_pi_dqs_found_lanes_phy4lanes
,output [11:0] dbg_pi_phase_locked_phy4lanes
,output [6*RANKS-1:0] dbg_calib_rd_data_offset_1
,output [6*RANKS-1:0] dbg_calib_rd_data_offset_2
,output [5:0] dbg_data_offset
,output [5:0] dbg_data_offset_1
,output [5:0] dbg_data_offset_2
,output dbg_oclkdelay_calib_start
,output dbg_oclkdelay_calib_done
,output [255:0] dbg_phy_oclkdelay_cal
,output [DRAM_WIDTH*16 -1:0]dbg_oclkdelay_rd_data
,output [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r
,output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps
,output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps
);
localparam nSLOTS = 1 + (|SLOT_1_CONFIG ? 1 : 0);
localparam SLOT_0_CONFIG_MC = (nSLOTS == 2)? 8'b0000_0101 : 8'b0000_1111;
localparam SLOT_1_CONFIG_MC = (nSLOTS == 2)? 8'b0000_1010 : 8'b0000_0000;
// 8*tREFI in ps is divided by fabric clock period also in ps. 270 is the number
// of fabric clock cycles that accounts for the Writes, read, and PRECHARGE time
localparam REFRESH_TIMER = (8*tREFI/(tCK*nCK_PER_CLK)) - 270;
reg [7:0] slot_0_present_mc;
reg [7:0] slot_1_present_mc;
reg user_periodic_rd_req = 1'b0;
reg user_ref_req = 1'b0;
reg user_zq_req = 1'b0;
// MC/PHY interface
wire [nCK_PER_CLK-1:0] mc_ras_n;
wire [nCK_PER_CLK-1:0] mc_cas_n;
wire [nCK_PER_CLK-1:0] mc_we_n;
wire [nCK_PER_CLK*ROW_WIDTH-1:0] mc_address;
wire [nCK_PER_CLK*BANK_WIDTH-1:0] mc_bank;
wire [nCK_PER_CLK-1 :0] mc_cke ;
wire [1:0] mc_odt ;
wire [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] mc_cs_n;
wire mc_reset_n;
wire [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata;
wire [2*nCK_PER_CLK*DQ_WIDTH/8-1:0] mc_wrdata_mask;
wire mc_wrdata_en;
wire mc_ref_zq_wip;
wire tempmon_sample_en;
wire idle;
wire mc_cmd_wren;
wire mc_ctl_wren;
wire [2:0] mc_cmd;
wire [1:0] mc_cas_slot;
wire [5:0] mc_data_offset;
wire [5:0] mc_data_offset_1;
wire [5:0] mc_data_offset_2;
wire [3:0] mc_aux_out0;
wire [3:0] mc_aux_out1;
wire [1:0] mc_rank_cnt;
wire phy_mc_ctl_full;
wire phy_mc_cmd_full;
wire phy_mc_data_full;
wire [2*nCK_PER_CLK*DQ_WIDTH-1:0] phy_rd_data;
wire phy_rddata_valid;
wire [6*RANKS-1:0] calib_rd_data_offset_0;
wire [6*RANKS-1:0] calib_rd_data_offset_1;
wire [6*RANKS-1:0] calib_rd_data_offset_2;
wire init_calib_complete_w;
wire init_wrcal_complete_w;
wire mux_rst;
wire mux_calib_complete;
// assigning CWL = CL -1 for DDR2. DDR2 customers will not know anything
// about CWL. There is also nCWL parameter. Need to clean it up.
localparam CWL_T = (DRAM_TYPE == "DDR3") ? CWL : CL-1;
assign init_calib_complete = init_calib_complete_w;
assign init_wrcal_complete = init_wrcal_complete_w;
assign mux_calib_complete = (PRE_REV3ES == "OFF") ? init_calib_complete_w :
(init_calib_complete_w | init_wrcal_complete_w);
assign mux_rst = (PRE_REV3ES == "OFF") ? rst : reset;
assign dbg_calib_rd_data_offset_1 = calib_rd_data_offset_1;
assign dbg_calib_rd_data_offset_2 = calib_rd_data_offset_2;
assign dbg_data_offset = mc_data_offset;
assign dbg_data_offset_1 = mc_data_offset_1;
assign dbg_data_offset_2 = mc_data_offset_2;
// Enable / disable temperature monitoring
assign tempmon_sample_en = TEMP_MON_EN == "OFF" ? 1'b0 : mc_ref_zq_wip;
generate
if (nSLOTS == 1) begin: gen_single_slot_odt
always @ (slot_0_present or slot_1_present) begin
slot_0_present_mc = slot_0_present;
slot_1_present_mc = slot_1_present;
end
end else if (nSLOTS == 2) begin: gen_dual_slot_odt
always @ (slot_0_present[0] or slot_0_present[1]
or slot_1_present[0] or slot_1_present[1]) begin
case ({slot_0_present[0],slot_0_present[1],
slot_1_present[0],slot_1_present[1]})
//Two slot configuration, one slot present, single rank
4'b1000: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_0000;
end
4'b0010: begin
slot_0_present_mc = 8'b0000_0000;
slot_1_present_mc = 8'b0000_0010;
end
// Two slot configuration, one slot present, dual rank
4'b1100: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_0000;
end
4'b0011: begin
slot_0_present_mc = 8'b0000_0000;
slot_1_present_mc = 8'b0000_1010;
end
// Two slot configuration, one rank per slot
4'b1010: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_0010;
end
// Two Slots - One slot with dual rank and the other with single rank
4'b1011: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_1010;
end
4'b1110: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_0010;
end
// Two Slots - two ranks per slot
4'b1111: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_1010;
end
endcase
end
end
endgenerate
mig_7series_v2_3_mc #
(
.TCQ (TCQ),
.PAYLOAD_WIDTH (PAYLOAD_WIDTH),
.MC_ERR_ADDR_WIDTH (MC_ERR_ADDR_WIDTH),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_WIDTH (BANK_WIDTH),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.BURST_MODE (BURST_MODE),
.COL_WIDTH (COL_WIDTH),
.CMD_PIPE_PLUS1 (CMD_PIPE_PLUS1),
.CS_WIDTH (CS_WIDTH),
.DATA_WIDTH (DATA_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DATA_BUF_OFFSET_WIDTH (DATA_BUF_OFFSET_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.CKE_ODT_AUX (CKE_ODT_AUX),
.DQS_WIDTH (DQS_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.ECC (ECC),
.ECC_WIDTH (ECC_WIDTH),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nSLOTS (nSLOTS),
.CL (CL),
.nCS_PER_RANK (nCS_PER_RANK),
.CWL (CWL_T),
.ORDERING (ORDERING),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.STARVE_LIMIT (STARVE_LIMIT),
.SLOT_0_CONFIG (SLOT_0_CONFIG_MC),
.SLOT_1_CONFIG (SLOT_1_CONFIG_MC),
.tCK (tCK),
.tCKE (tCKE),
.tFAW (tFAW),
.tRAS (tRAS),
.tRCD (tRCD),
.tREFI (tREFI),
.tRFC (tRFC),
.tRP (tRP),
.tRRD (tRRD),
.tRTP (tRTP),
.tWTR (tWTR),
.tZQI (tZQI),
.tZQCS (tZQCS),
.tPRDI (tPRDI),
.USER_REFRESH (USER_REFRESH))
mc0
(.app_periodic_rd_req (1'b0),
.app_sr_req (app_sr_req),
.app_sr_active (app_sr_active),
.app_ref_req (app_ref_req),
.app_ref_ack (app_ref_ack),
.app_zq_req (app_zq_req),
.app_zq_ack (app_zq_ack),
.ecc_single (ecc_single),
.ecc_multiple (ecc_multiple),
.ecc_err_addr (ecc_err_addr),
.mc_address (mc_address),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_bank (mc_bank),
.mc_cke (mc_cke),
.mc_odt (mc_odt),
.mc_cas_n (mc_cas_n),
.mc_cmd (mc_cmd),
.mc_cmd_wren (mc_cmd_wren),
.mc_cs_n (mc_cs_n),
.mc_ctl_wren (mc_ctl_wren),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_cas_slot (mc_cas_slot),
.mc_rank_cnt (mc_rank_cnt),
.mc_ras_n (mc_ras_n),
.mc_reset_n (mc_reset_n),
.mc_we_n (mc_we_n),
.mc_wrdata (mc_wrdata),
.mc_wrdata_en (mc_wrdata_en),
.mc_wrdata_mask (mc_wrdata_mask),
// Outputs
.accept (accept),
.accept_ns (accept_ns),
.bank_mach_next (bank_mach_next[BM_CNT_WIDTH-1:0]),
.rd_data_addr (rd_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.rd_data_en (rd_data_en),
.rd_data_end (rd_data_end),
.rd_data_offset (rd_data_offset),
.wr_data_addr (wr_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.wr_data_en (wr_data_en),
.wr_data_offset (wr_data_offset),
.rd_data (rd_data),
.wr_data (wr_data),
.wr_data_mask (wr_data_mask),
.mc_read_idle (idle),
.mc_ref_zq_wip (mc_ref_zq_wip),
// Inputs
.init_calib_complete (mux_calib_complete),
.calib_rd_data_offset (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_data_full (phy_mc_data_full),
.phy_rd_data (phy_rd_data),
.phy_rddata_valid (phy_rddata_valid),
.correct_en (correct_en),
.bank (bank[BANK_WIDTH-1:0]),
.clk (clk),
.cmd (cmd[2:0]),
.col (col[COL_WIDTH-1:0]),
.data_buf_addr (data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.hi_priority (hi_priority),
.rank (rank[RANK_WIDTH-1:0]),
.raw_not_ecc (raw_not_ecc[2*nCK_PER_CLK-1 :0]),
.row (row[ROW_WIDTH-1:0]),
.rst (mux_rst),
.size (size),
.slot_0_present (slot_0_present_mc[7:0]),
.slot_1_present (slot_1_present_mc[7:0]),
.fi_xor_we (fi_xor_we),
.fi_xor_wrdata (fi_xor_wrdata),
.use_addr (use_addr));
// following calculations should be moved inside PHY
// odt bus should be added to PHY.
localparam CLK_PERIOD = tCK * nCK_PER_CLK;
localparam nCL = CL;
localparam nCWL = CWL_T;
`ifdef MC_SVA
ddr2_improper_CL: assert property
(@(posedge clk) (~((DRAM_TYPE == "DDR2") && ((CL > 6) || (CL < 3)))));
// Not needed after the CWL fix for DDR2
// ddr2_improper_CWL: assert property
// (@(posedge clk) (~((DRAM_TYPE == "DDR2") && ((CL - CWL) != 1))));
`endif
mig_7series_v2_3_ddr_phy_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.REFCLK_FREQ (REFCLK_FREQ),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.CA_MIRROR (CA_MIRROR),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.nCS_PER_RANK (nCS_PER_RANK),
.CS_WIDTH (CS_WIDTH),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.CKE_WIDTH (CKE_WIDTH),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.DRAM_TYPE (DRAM_TYPE),
.BANK_WIDTH (BANK_WIDTH),
.CK_WIDTH (CK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.ROW_WIDTH (ROW_WIDTH),
.AL (AL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.CL (nCL),
.CWL (nCWL),
.tRFC (tRFC),
.tREFI (tREFI),
.tCK (tCK),
.OUTPUT_DRV (OUTPUT_DRV),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.WRLVL (WRLVL),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
// Prevent the following simulation-related parameters from
// being overridden for synthesis - for synthesis only the
// default values of these parameters should be used
// synthesis translate_off
.SIM_BYPASS_INIT_CAL (SIM_BYPASS_INIT_CAL),
// synthesis translate_on
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK)
)
ddr_phy_top0
(
// Outputs
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.ddr_ck (ddr_ck),
.ddr_ck_n (ddr_ck_n),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_ras_n (ddr_ras_n),
.ddr_cas_n (ddr_cas_n),
.ddr_we_n (ddr_we_n),
.ddr_cs_n (ddr_cs_n),
.ddr_cke (ddr_cke),
.ddr_odt (ddr_odt),
.ddr_reset_n (ddr_reset_n),
.ddr_parity (ddr_parity),
.ddr_dm (ddr_dm),
.dbg_calib_top (dbg_calib_top),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_rddata (dbg_rddata),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.init_calib_complete (init_calib_complete_w),
.init_wrcal_complete (init_wrcal_complete_w),
.mc_address (mc_address),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_bank (mc_bank),
.mc_cke (mc_cke),
.mc_odt (mc_odt),
.mc_cas_n (mc_cas_n),
.mc_cmd (mc_cmd),
.mc_cmd_wren (mc_cmd_wren),
.mc_cas_slot (mc_cas_slot),
.mc_cs_n (mc_cs_n),
.mc_ctl_wren (mc_ctl_wren),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_rank_cnt (mc_rank_cnt),
.mc_ras_n (mc_ras_n),
.mc_reset_n (mc_reset_n),
.mc_we_n (mc_we_n),
.mc_wrdata (mc_wrdata),
.mc_wrdata_en (mc_wrdata_en),
.mc_wrdata_mask (mc_wrdata_mask),
.idle (idle),
.mem_refclk (mem_refclk),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_data_full (phy_mc_data_full),
.phy_rd_data (phy_rd_data),
.phy_rddata_valid (phy_rddata_valid),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
// Inouts
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_dq (ddr_dq),
// Inputs
.clk_ref (clk_ref),
.freq_refclk (freq_refclk),
.clk (clk),
.mmcm_ps_clk (mmcm_ps_clk),
.poc_sample_pd (poc_sample_pd),
.rst (rst),
.error (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt)
,.device_temp (device_temp)
,.tempmon_sample_en (tempmon_sample_en)
,.psen (psen)
,.psincdec (psincdec)
,.psdone (psdone)
,.dbg_sel_pi_incdec (dbg_sel_pi_incdec)
,.dbg_sel_po_incdec (dbg_sel_po_incdec)
,.dbg_byte_sel (dbg_byte_sel)
,.dbg_pi_f_inc (dbg_pi_f_inc)
,.dbg_po_f_inc (dbg_po_f_inc)
,.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel)
,.dbg_pi_f_dec (dbg_pi_f_dec)
,.dbg_po_f_dec (dbg_po_f_dec)
,.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt)
,.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt)
,.dbg_rddata_valid (dbg_rddata_valid)
,.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt)
,.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt)
,.dbg_phy_wrlvl (dbg_phy_wrlvl)
,.ref_dll_lock (ref_dll_lock)
,.rst_phaser_ref (rst_phaser_ref)
,.iddr_rst (iddr_rst)
,.dbg_rd_data_offset (dbg_rd_data_offset)
,.dbg_phy_init (dbg_phy_init)
,.dbg_prbs_rdlvl (dbg_prbs_rdlvl)
,.dbg_dqs_found_cal (dbg_dqs_found_cal)
,.dbg_po_counter_read_val (dbg_po_counter_read_val)
,.dbg_pi_counter_read_val (dbg_pi_counter_read_val)
,.dbg_pi_phaselock_start (dbg_pi_phaselock_start)
,.dbg_pi_phaselocked_done (dbg_pi_phaselocked_done)
,.dbg_pi_phaselock_err (dbg_pi_phaselock_err)
,.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start)
,.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done)
,.dbg_pi_dqsfound_err (dbg_pi_dqsfound_err)
,.dbg_wrcal_start (dbg_wrcal_start)
,.dbg_wrcal_done (dbg_wrcal_done)
,.dbg_wrcal_err (dbg_wrcal_err)
,.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal)
,.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data)
,.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start)
,.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done)
,.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r)
,.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps)
,.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps)
);
endmodule
|
module mig_7series_v2_3_mem_intfc #
(
parameter TCQ = 100,
parameter DDR3_VDD_OP_VOLT = "135", // Voltage mode used for DDR3
parameter PAYLOAD_WIDTH = 64,
parameter ADDR_CMD_MODE = "1T",
parameter AL = "0", // Additive Latency option
parameter BANK_WIDTH = 3, // # of bank bits
parameter BM_CNT_WIDTH = 2, // Bank machine counter width
parameter BURST_MODE = "8", // Burst length
parameter BURST_TYPE = "SEQ", // Burst type
parameter CA_MIRROR = "OFF", // C/A mirror opt for DDR3 dual rank
parameter CK_WIDTH = 1, // # of CK/CK# outputs to memory
// five fields, one per possible I/O bank, 4 bits in each field, 1 per lane
// data=1/ctl=0
parameter DATA_CTL_B0 = 4'hc,
parameter DATA_CTL_B1 = 4'hf,
parameter DATA_CTL_B2 = 4'hf,
parameter DATA_CTL_B3 = 4'hf,
parameter DATA_CTL_B4 = 4'hf,
// defines the byte lanes in I/O banks being used in the interface
// 1- Used, 0- Unused
parameter BYTE_LANES_B0 = 4'b1111,
parameter BYTE_LANES_B1 = 4'b0000,
parameter BYTE_LANES_B2 = 4'b0000,
parameter BYTE_LANES_B3 = 4'b0000,
parameter BYTE_LANES_B4 = 4'b0000,
// defines the bit lanes in I/O banks being used in the interface. Each
// parameter = 1 I/O bank = 4 byte lanes = 48 bit lanes. 1-Used, 0-Unused
parameter PHY_0_BITLANES = 48'h0000_0000_0000,
parameter PHY_1_BITLANES = 48'h0000_0000_0000,
parameter PHY_2_BITLANES = 48'h0000_0000_0000,
// control/address/data pin mapping parameters
parameter CK_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter ADDR_MAP
= 192'h000_000_000_000_000_000_000_000_000_000_000_000_000_000_000_000,
parameter BANK_MAP = 36'h000_000_000,
parameter CAS_MAP = 12'h000,
parameter CKE_ODT_BYTE_MAP = 8'h00,
parameter CKE_MAP = 96'h000_000_000_000_000_000_000_000,
parameter ODT_MAP = 96'h000_000_000_000_000_000_000_000,
parameter CKE_ODT_AUX = "FALSE",
parameter CS_MAP = 120'h000_000_000_000_000_000_000_000_000_000,
parameter PARITY_MAP = 12'h000,
parameter RAS_MAP = 12'h000,
parameter WE_MAP = 12'h000,
parameter DQS_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter DATA0_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA1_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA2_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA3_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA4_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA5_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA6_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA7_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA8_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA9_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA10_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA11_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA12_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA13_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA14_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA15_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA16_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA17_MAP = 96'h000_000_000_000_000_000_000_000,
parameter MASK0_MAP = 108'h000_000_000_000_000_000_000_000_000,
parameter MASK1_MAP = 108'h000_000_000_000_000_000_000_000_000,
// calibration Address. The address given below will be used for calibration
// read and write operations.
parameter CALIB_ROW_ADD = 16'h0000,// Calibration row address
parameter CALIB_COL_ADD = 12'h000, // Calibration column address
parameter CALIB_BA_ADD = 3'h0, // Calibration bank address
parameter CL = 5,
parameter COL_WIDTH = 12, // column address width
parameter CMD_PIPE_PLUS1 = "ON", // add pipeline stage between MC and PHY
parameter CS_WIDTH = 1, // # of unique CS outputs
parameter CKE_WIDTH = 1, // # of cke outputs
parameter CWL = 5,
parameter DATA_WIDTH = 64,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DDR2_DQSN_ENABLE = "YES", // Enable differential DQS for DDR2
parameter DM_WIDTH = 8, // # of DM (data mask)
parameter DQ_CNT_WIDTH = 6, // = ceil(log2(DQ_WIDTH))
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_TYPE = "DDR3",
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter ECC = "OFF",
parameter ECC_WIDTH = 8,
parameter MC_ERR_ADDR_WIDTH = 31,
parameter nAL = 0, // Additive latency (in clk cyc)
parameter nBANK_MACHS = 4,
parameter PRE_REV3ES = "OFF", // Delay O/Ps using Phaser_Out fine dly
parameter nCK_PER_CLK = 4, // # of memory CKs per fabric CLK
parameter nCS_PER_RANK = 1, // # of unique CS outputs per rank
// Hard PHY parameters
parameter PHYCTL_CMD_FIFO = "FALSE",
parameter ORDERING = "NORM",
parameter PHASE_DETECT = "OFF" , // to phy_top
parameter IBUF_LPWR_MODE = "OFF", // to phy_top
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter DATA_IO_PRIM_TYPE = "DEFAULT", // # = "HP_LP", "HR_LP", "DEFAULT"
parameter DATA_IO_IDLE_PWRDWN = "ON", // "ON" or "OFF"
parameter IODELAY_GRP = "IODELAY_MIG", //to phy_top
parameter FPGA_SPEED_GRADE = 1,
parameter OUTPUT_DRV = "HIGH" , // to phy_top
parameter REG_CTRL = "OFF" , // to phy_top
parameter RTT_NOM = "60" , // to phy_top
parameter RTT_WR = "120" , // to phy_top
parameter STARVE_LIMIT = 2,
parameter tCK = 2500, // pS
parameter tCKE = 10000, // pS
parameter tFAW = 40000, // pS
parameter tPRDI = 1_000_000, // pS
parameter tRAS = 37500, // pS
parameter tRCD = 12500, // pS
parameter tREFI = 7800000, // pS
parameter tRFC = 110000, // pS
parameter tRP = 12500, // pS
parameter tRRD = 10000, // pS
parameter tRTP = 7500, // pS
parameter tWTR = 7500, // pS
parameter tZQI = 128_000_000, // nS
parameter tZQCS = 64, // CKs
parameter WRLVL = "OFF" , // to phy_top
parameter DEBUG_PORT = "OFF" , // to phy_top
parameter CAL_WIDTH = "HALF" , // to phy_top
parameter RANK_WIDTH = 1,
parameter RANKS = 4,
parameter ODT_WIDTH = 1,
parameter ROW_WIDTH = 16, // DRAM address bus width
parameter [7:0] SLOT_0_CONFIG = 8'b0000_0001,
parameter [7:0] SLOT_1_CONFIG = 8'b0000_0000,
parameter SIM_BYPASS_INIT_CAL = "OFF",
parameter REFCLK_FREQ = 300.0,
parameter nDQS_COL0 = DQS_WIDTH,
parameter nDQS_COL1 = 0,
parameter nDQS_COL2 = 0,
parameter nDQS_COL3 = 0,
parameter DQS_LOC_COL0 = 144'h11100F0E0D0C0B0A09080706050403020100,
parameter DQS_LOC_COL1 = 0,
parameter DQS_LOC_COL2 = 0,
parameter DQS_LOC_COL3 = 0,
parameter USE_CS_PORT = 1, // Support chip select output
parameter USE_DM_PORT = 1, // Support data mask output
parameter USE_ODT_PORT = 1, // Support ODT output
parameter MASTER_PHY_CTL = 0, // The bank number where master PHY_CONTROL resides
parameter USER_REFRESH = "OFF", // Choose whether MC or User manages REF
parameter TEMP_MON_EN = "ON", // Enable/disable temperature monitoring
parameter IDELAY_ADJ = "ON", // Adjust IDELAY value (-1)
parameter FINE_PER_BIT = "ON", // Use finedelay per-bit de-skew
parameter CENTER_COMP_MODE = "ON", // Use Center compensation table for PI
parameter PI_VAL_ADJ = "ON", // Adjust PI final value (-1)
parameter TAPSPERKCLK = 56
)
(
input clk_ref,
input freq_refclk,
input mem_refclk,
input pll_lock,
input sync_pulse,
input mmcm_ps_clk,
input poc_sample_pd,
input error,
input reset,
output rst_tg_mc,
input [BANK_WIDTH-1:0] bank, // To mc0 of mc.v
input clk ,
input [2:0] cmd, // To mc0 of mc.v
input [COL_WIDTH-1:0] col, // To mc0 of mc.v
input correct_en,
input [DATA_BUF_ADDR_WIDTH-1:0] data_buf_addr, // To mc0 of mc.v
input dbg_idel_down_all,
input dbg_idel_down_cpt,
input dbg_idel_up_all,
input dbg_idel_up_cpt,
input dbg_sel_all_idel_cpt,
input [DQS_CNT_WIDTH-1:0] dbg_sel_idel_cpt,
input hi_priority, // To mc0 of mc.v
input [RANK_WIDTH-1:0] rank, // To mc0 of mc.v
input [2*nCK_PER_CLK-1:0] raw_not_ecc,
input [ROW_WIDTH-1:0] row, // To mc0 of mc.v
input rst, // To mc0 of mc.v, ...
input size, // To mc0 of mc.v
input [7:0] slot_0_present, // To mc0 of mc.v
input [7:0] slot_1_present, // To mc0 of mc.v
input use_addr, // To mc0 of mc.v
input [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data,
input [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask,
output accept, // From mc0 of mc.v
output accept_ns, // From mc0 of mc.v
output [BM_CNT_WIDTH-1:0] bank_mach_next, // From mc0 of mc.v
input app_sr_req,
output app_sr_active,
input app_ref_req,
output app_ref_ack,
input app_zq_req,
output app_zq_ack,
output [255:0] dbg_calib_top,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_first_edge_cnt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_second_edge_cnt,
output [255:0] dbg_phy_rdlvl,
output [99:0] dbg_phy_wrcal,
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output [DQS_WIDTH-1:0] dbg_rd_data_edge_detect,
output [2*nCK_PER_CLK*DQ_WIDTH-1:0] dbg_rddata,
output [1:0] dbg_rdlvl_done,
output [1:0] dbg_rdlvl_err,
output [1:0] dbg_rdlvl_start,
output [5:0] dbg_tap_cnt_during_wrlvl,
output dbg_wl_edge_detect_valid,
output dbg_wrlvl_done,
output dbg_wrlvl_err,
output dbg_wrlvl_start,
output [ROW_WIDTH-1:0] ddr_addr, // From phy_top0 of phy_top.v
output [BANK_WIDTH-1:0] ddr_ba, // From phy_top0 of phy_top.v
output ddr_cas_n, // From phy_top0 of phy_top.v
output [CK_WIDTH-1:0] ddr_ck_n, // From phy_top0 of phy_top.v
output [CK_WIDTH-1:0] ddr_ck , // From phy_top0 of phy_top.v
output [CKE_WIDTH-1:0] ddr_cke, // From phy_top0 of phy_top.v
output [CS_WIDTH*nCS_PER_RANK-1:0] ddr_cs_n, // From phy_top0 of phy_top.v
output [DM_WIDTH-1:0] ddr_dm, // From phy_top0 of phy_top.v
output [ODT_WIDTH-1:0] ddr_odt, // From phy_top0 of phy_top.v
output ddr_ras_n, // From phy_top0 of phy_top.v
output ddr_reset_n, // From phy_top0 of phy_top.v
output ddr_parity,
output ddr_we_n, // From phy_top0 of phy_top.v
output init_calib_complete,
output init_wrcal_complete,
output [MC_ERR_ADDR_WIDTH-1:0] ecc_err_addr,
output [2*nCK_PER_CLK-1:0] ecc_multiple,
output [2*nCK_PER_CLK-1:0] ecc_single,
output wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] rd_data,
output [DATA_BUF_ADDR_WIDTH-1:0] rd_data_addr,
// From mc0 of mc.v
output rd_data_en, // From mc0 of mc.v
output rd_data_end, // From mc0 of mc.v
output [DATA_BUF_OFFSET_WIDTH-1:0] rd_data_offset, // From mc0 of mc.v
output [DATA_BUF_ADDR_WIDTH-1:0] wr_data_addr, // From mc0 of mc.v
output wr_data_en, // From mc0 of mc.v
output [DATA_BUF_OFFSET_WIDTH-1:0] wr_data_offset, // From mc0 of mc.v
inout [DQ_WIDTH-1:0] ddr_dq, // To/From phy_top0 of phy_top.v
inout [DQS_WIDTH-1:0] ddr_dqs_n, // To/From phy_top0 of phy_top.v
inout [DQS_WIDTH-1:0] ddr_dqs // To/From phy_top0 of phy_top.v
,input [11:0] device_temp
//phase shift clock control
,output psen
,output psincdec
,input psdone
,input [DQ_WIDTH/8-1:0] fi_xor_we
,input [DQ_WIDTH-1:0] fi_xor_wrdata
,input dbg_sel_pi_incdec
,input dbg_sel_po_incdec
,input [DQS_CNT_WIDTH:0] dbg_byte_sel
,input dbg_pi_f_inc
,input dbg_pi_f_dec
,input dbg_po_f_inc
,input dbg_po_f_stg23_sel
,input dbg_po_f_dec
,output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_tap_cnt
,output [5*DQS_WIDTH*RANKS-1:0] dbg_dq_idelay_tap_cnt
,output dbg_rddata_valid
,output [6*DQS_WIDTH-1:0] dbg_wrlvl_fine_tap_cnt
,output [3*DQS_WIDTH-1:0] dbg_wrlvl_coarse_tap_cnt
,output [255:0] dbg_phy_wrlvl
,output [5:0] dbg_pi_counter_read_val
,output [8:0] dbg_po_counter_read_val
,output ref_dll_lock
,input rst_phaser_ref
,input iddr_rst
,output [6*RANKS-1:0] dbg_rd_data_offset
,output [255:0] dbg_phy_init
,output [255:0] dbg_prbs_rdlvl
,output [255:0] dbg_dqs_found_cal
,output dbg_pi_phaselock_start
,output dbg_pi_phaselocked_done
,output dbg_pi_phaselock_err
,output dbg_pi_dqsfound_start
,output dbg_pi_dqsfound_done
,output dbg_pi_dqsfound_err
,output dbg_wrcal_start
,output dbg_wrcal_done
,output dbg_wrcal_err
,output [11:0] dbg_pi_dqs_found_lanes_phy4lanes
,output [11:0] dbg_pi_phase_locked_phy4lanes
,output [6*RANKS-1:0] dbg_calib_rd_data_offset_1
,output [6*RANKS-1:0] dbg_calib_rd_data_offset_2
,output [5:0] dbg_data_offset
,output [5:0] dbg_data_offset_1
,output [5:0] dbg_data_offset_2
,output dbg_oclkdelay_calib_start
,output dbg_oclkdelay_calib_done
,output [255:0] dbg_phy_oclkdelay_cal
,output [DRAM_WIDTH*16 -1:0]dbg_oclkdelay_rd_data
,output [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r
,output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps
,output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps
);
localparam nSLOTS = 1 + (|SLOT_1_CONFIG ? 1 : 0);
localparam SLOT_0_CONFIG_MC = (nSLOTS == 2)? 8'b0000_0101 : 8'b0000_1111;
localparam SLOT_1_CONFIG_MC = (nSLOTS == 2)? 8'b0000_1010 : 8'b0000_0000;
// 8*tREFI in ps is divided by fabric clock period also in ps. 270 is the number
// of fabric clock cycles that accounts for the Writes, read, and PRECHARGE time
localparam REFRESH_TIMER = (8*tREFI/(tCK*nCK_PER_CLK)) - 270;
reg [7:0] slot_0_present_mc;
reg [7:0] slot_1_present_mc;
reg user_periodic_rd_req = 1'b0;
reg user_ref_req = 1'b0;
reg user_zq_req = 1'b0;
// MC/PHY interface
wire [nCK_PER_CLK-1:0] mc_ras_n;
wire [nCK_PER_CLK-1:0] mc_cas_n;
wire [nCK_PER_CLK-1:0] mc_we_n;
wire [nCK_PER_CLK*ROW_WIDTH-1:0] mc_address;
wire [nCK_PER_CLK*BANK_WIDTH-1:0] mc_bank;
wire [nCK_PER_CLK-1 :0] mc_cke ;
wire [1:0] mc_odt ;
wire [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] mc_cs_n;
wire mc_reset_n;
wire [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata;
wire [2*nCK_PER_CLK*DQ_WIDTH/8-1:0] mc_wrdata_mask;
wire mc_wrdata_en;
wire mc_ref_zq_wip;
wire tempmon_sample_en;
wire idle;
wire mc_cmd_wren;
wire mc_ctl_wren;
wire [2:0] mc_cmd;
wire [1:0] mc_cas_slot;
wire [5:0] mc_data_offset;
wire [5:0] mc_data_offset_1;
wire [5:0] mc_data_offset_2;
wire [3:0] mc_aux_out0;
wire [3:0] mc_aux_out1;
wire [1:0] mc_rank_cnt;
wire phy_mc_ctl_full;
wire phy_mc_cmd_full;
wire phy_mc_data_full;
wire [2*nCK_PER_CLK*DQ_WIDTH-1:0] phy_rd_data;
wire phy_rddata_valid;
wire [6*RANKS-1:0] calib_rd_data_offset_0;
wire [6*RANKS-1:0] calib_rd_data_offset_1;
wire [6*RANKS-1:0] calib_rd_data_offset_2;
wire init_calib_complete_w;
wire init_wrcal_complete_w;
wire mux_rst;
wire mux_calib_complete;
// assigning CWL = CL -1 for DDR2. DDR2 customers will not know anything
// about CWL. There is also nCWL parameter. Need to clean it up.
localparam CWL_T = (DRAM_TYPE == "DDR3") ? CWL : CL-1;
assign init_calib_complete = init_calib_complete_w;
assign init_wrcal_complete = init_wrcal_complete_w;
assign mux_calib_complete = (PRE_REV3ES == "OFF") ? init_calib_complete_w :
(init_calib_complete_w | init_wrcal_complete_w);
assign mux_rst = (PRE_REV3ES == "OFF") ? rst : reset;
assign dbg_calib_rd_data_offset_1 = calib_rd_data_offset_1;
assign dbg_calib_rd_data_offset_2 = calib_rd_data_offset_2;
assign dbg_data_offset = mc_data_offset;
assign dbg_data_offset_1 = mc_data_offset_1;
assign dbg_data_offset_2 = mc_data_offset_2;
// Enable / disable temperature monitoring
assign tempmon_sample_en = TEMP_MON_EN == "OFF" ? 1'b0 : mc_ref_zq_wip;
generate
if (nSLOTS == 1) begin: gen_single_slot_odt
always @ (slot_0_present or slot_1_present) begin
slot_0_present_mc = slot_0_present;
slot_1_present_mc = slot_1_present;
end
end else if (nSLOTS == 2) begin: gen_dual_slot_odt
always @ (slot_0_present[0] or slot_0_present[1]
or slot_1_present[0] or slot_1_present[1]) begin
case ({slot_0_present[0],slot_0_present[1],
slot_1_present[0],slot_1_present[1]})
//Two slot configuration, one slot present, single rank
4'b1000: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_0000;
end
4'b0010: begin
slot_0_present_mc = 8'b0000_0000;
slot_1_present_mc = 8'b0000_0010;
end
// Two slot configuration, one slot present, dual rank
4'b1100: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_0000;
end
4'b0011: begin
slot_0_present_mc = 8'b0000_0000;
slot_1_present_mc = 8'b0000_1010;
end
// Two slot configuration, one rank per slot
4'b1010: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_0010;
end
// Two Slots - One slot with dual rank and the other with single rank
4'b1011: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_1010;
end
4'b1110: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_0010;
end
// Two Slots - two ranks per slot
4'b1111: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_1010;
end
endcase
end
end
endgenerate
mig_7series_v2_3_mc #
(
.TCQ (TCQ),
.PAYLOAD_WIDTH (PAYLOAD_WIDTH),
.MC_ERR_ADDR_WIDTH (MC_ERR_ADDR_WIDTH),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_WIDTH (BANK_WIDTH),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.BURST_MODE (BURST_MODE),
.COL_WIDTH (COL_WIDTH),
.CMD_PIPE_PLUS1 (CMD_PIPE_PLUS1),
.CS_WIDTH (CS_WIDTH),
.DATA_WIDTH (DATA_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DATA_BUF_OFFSET_WIDTH (DATA_BUF_OFFSET_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.CKE_ODT_AUX (CKE_ODT_AUX),
.DQS_WIDTH (DQS_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.ECC (ECC),
.ECC_WIDTH (ECC_WIDTH),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nSLOTS (nSLOTS),
.CL (CL),
.nCS_PER_RANK (nCS_PER_RANK),
.CWL (CWL_T),
.ORDERING (ORDERING),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.STARVE_LIMIT (STARVE_LIMIT),
.SLOT_0_CONFIG (SLOT_0_CONFIG_MC),
.SLOT_1_CONFIG (SLOT_1_CONFIG_MC),
.tCK (tCK),
.tCKE (tCKE),
.tFAW (tFAW),
.tRAS (tRAS),
.tRCD (tRCD),
.tREFI (tREFI),
.tRFC (tRFC),
.tRP (tRP),
.tRRD (tRRD),
.tRTP (tRTP),
.tWTR (tWTR),
.tZQI (tZQI),
.tZQCS (tZQCS),
.tPRDI (tPRDI),
.USER_REFRESH (USER_REFRESH))
mc0
(.app_periodic_rd_req (1'b0),
.app_sr_req (app_sr_req),
.app_sr_active (app_sr_active),
.app_ref_req (app_ref_req),
.app_ref_ack (app_ref_ack),
.app_zq_req (app_zq_req),
.app_zq_ack (app_zq_ack),
.ecc_single (ecc_single),
.ecc_multiple (ecc_multiple),
.ecc_err_addr (ecc_err_addr),
.mc_address (mc_address),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_bank (mc_bank),
.mc_cke (mc_cke),
.mc_odt (mc_odt),
.mc_cas_n (mc_cas_n),
.mc_cmd (mc_cmd),
.mc_cmd_wren (mc_cmd_wren),
.mc_cs_n (mc_cs_n),
.mc_ctl_wren (mc_ctl_wren),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_cas_slot (mc_cas_slot),
.mc_rank_cnt (mc_rank_cnt),
.mc_ras_n (mc_ras_n),
.mc_reset_n (mc_reset_n),
.mc_we_n (mc_we_n),
.mc_wrdata (mc_wrdata),
.mc_wrdata_en (mc_wrdata_en),
.mc_wrdata_mask (mc_wrdata_mask),
// Outputs
.accept (accept),
.accept_ns (accept_ns),
.bank_mach_next (bank_mach_next[BM_CNT_WIDTH-1:0]),
.rd_data_addr (rd_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.rd_data_en (rd_data_en),
.rd_data_end (rd_data_end),
.rd_data_offset (rd_data_offset),
.wr_data_addr (wr_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.wr_data_en (wr_data_en),
.wr_data_offset (wr_data_offset),
.rd_data (rd_data),
.wr_data (wr_data),
.wr_data_mask (wr_data_mask),
.mc_read_idle (idle),
.mc_ref_zq_wip (mc_ref_zq_wip),
// Inputs
.init_calib_complete (mux_calib_complete),
.calib_rd_data_offset (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_data_full (phy_mc_data_full),
.phy_rd_data (phy_rd_data),
.phy_rddata_valid (phy_rddata_valid),
.correct_en (correct_en),
.bank (bank[BANK_WIDTH-1:0]),
.clk (clk),
.cmd (cmd[2:0]),
.col (col[COL_WIDTH-1:0]),
.data_buf_addr (data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.hi_priority (hi_priority),
.rank (rank[RANK_WIDTH-1:0]),
.raw_not_ecc (raw_not_ecc[2*nCK_PER_CLK-1 :0]),
.row (row[ROW_WIDTH-1:0]),
.rst (mux_rst),
.size (size),
.slot_0_present (slot_0_present_mc[7:0]),
.slot_1_present (slot_1_present_mc[7:0]),
.fi_xor_we (fi_xor_we),
.fi_xor_wrdata (fi_xor_wrdata),
.use_addr (use_addr));
// following calculations should be moved inside PHY
// odt bus should be added to PHY.
localparam CLK_PERIOD = tCK * nCK_PER_CLK;
localparam nCL = CL;
localparam nCWL = CWL_T;
`ifdef MC_SVA
ddr2_improper_CL: assert property
(@(posedge clk) (~((DRAM_TYPE == "DDR2") && ((CL > 6) || (CL < 3)))));
// Not needed after the CWL fix for DDR2
// ddr2_improper_CWL: assert property
// (@(posedge clk) (~((DRAM_TYPE == "DDR2") && ((CL - CWL) != 1))));
`endif
mig_7series_v2_3_ddr_phy_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.REFCLK_FREQ (REFCLK_FREQ),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.CA_MIRROR (CA_MIRROR),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.nCS_PER_RANK (nCS_PER_RANK),
.CS_WIDTH (CS_WIDTH),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.CKE_WIDTH (CKE_WIDTH),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.DRAM_TYPE (DRAM_TYPE),
.BANK_WIDTH (BANK_WIDTH),
.CK_WIDTH (CK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.ROW_WIDTH (ROW_WIDTH),
.AL (AL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.CL (nCL),
.CWL (nCWL),
.tRFC (tRFC),
.tREFI (tREFI),
.tCK (tCK),
.OUTPUT_DRV (OUTPUT_DRV),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.WRLVL (WRLVL),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
// Prevent the following simulation-related parameters from
// being overridden for synthesis - for synthesis only the
// default values of these parameters should be used
// synthesis translate_off
.SIM_BYPASS_INIT_CAL (SIM_BYPASS_INIT_CAL),
// synthesis translate_on
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK)
)
ddr_phy_top0
(
// Outputs
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.ddr_ck (ddr_ck),
.ddr_ck_n (ddr_ck_n),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_ras_n (ddr_ras_n),
.ddr_cas_n (ddr_cas_n),
.ddr_we_n (ddr_we_n),
.ddr_cs_n (ddr_cs_n),
.ddr_cke (ddr_cke),
.ddr_odt (ddr_odt),
.ddr_reset_n (ddr_reset_n),
.ddr_parity (ddr_parity),
.ddr_dm (ddr_dm),
.dbg_calib_top (dbg_calib_top),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_rddata (dbg_rddata),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.init_calib_complete (init_calib_complete_w),
.init_wrcal_complete (init_wrcal_complete_w),
.mc_address (mc_address),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_bank (mc_bank),
.mc_cke (mc_cke),
.mc_odt (mc_odt),
.mc_cas_n (mc_cas_n),
.mc_cmd (mc_cmd),
.mc_cmd_wren (mc_cmd_wren),
.mc_cas_slot (mc_cas_slot),
.mc_cs_n (mc_cs_n),
.mc_ctl_wren (mc_ctl_wren),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_rank_cnt (mc_rank_cnt),
.mc_ras_n (mc_ras_n),
.mc_reset_n (mc_reset_n),
.mc_we_n (mc_we_n),
.mc_wrdata (mc_wrdata),
.mc_wrdata_en (mc_wrdata_en),
.mc_wrdata_mask (mc_wrdata_mask),
.idle (idle),
.mem_refclk (mem_refclk),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_data_full (phy_mc_data_full),
.phy_rd_data (phy_rd_data),
.phy_rddata_valid (phy_rddata_valid),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
// Inouts
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_dq (ddr_dq),
// Inputs
.clk_ref (clk_ref),
.freq_refclk (freq_refclk),
.clk (clk),
.mmcm_ps_clk (mmcm_ps_clk),
.poc_sample_pd (poc_sample_pd),
.rst (rst),
.error (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt)
,.device_temp (device_temp)
,.tempmon_sample_en (tempmon_sample_en)
,.psen (psen)
,.psincdec (psincdec)
,.psdone (psdone)
,.dbg_sel_pi_incdec (dbg_sel_pi_incdec)
,.dbg_sel_po_incdec (dbg_sel_po_incdec)
,.dbg_byte_sel (dbg_byte_sel)
,.dbg_pi_f_inc (dbg_pi_f_inc)
,.dbg_po_f_inc (dbg_po_f_inc)
,.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel)
,.dbg_pi_f_dec (dbg_pi_f_dec)
,.dbg_po_f_dec (dbg_po_f_dec)
,.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt)
,.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt)
,.dbg_rddata_valid (dbg_rddata_valid)
,.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt)
,.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt)
,.dbg_phy_wrlvl (dbg_phy_wrlvl)
,.ref_dll_lock (ref_dll_lock)
,.rst_phaser_ref (rst_phaser_ref)
,.iddr_rst (iddr_rst)
,.dbg_rd_data_offset (dbg_rd_data_offset)
,.dbg_phy_init (dbg_phy_init)
,.dbg_prbs_rdlvl (dbg_prbs_rdlvl)
,.dbg_dqs_found_cal (dbg_dqs_found_cal)
,.dbg_po_counter_read_val (dbg_po_counter_read_val)
,.dbg_pi_counter_read_val (dbg_pi_counter_read_val)
,.dbg_pi_phaselock_start (dbg_pi_phaselock_start)
,.dbg_pi_phaselocked_done (dbg_pi_phaselocked_done)
,.dbg_pi_phaselock_err (dbg_pi_phaselock_err)
,.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start)
,.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done)
,.dbg_pi_dqsfound_err (dbg_pi_dqsfound_err)
,.dbg_wrcal_start (dbg_wrcal_start)
,.dbg_wrcal_done (dbg_wrcal_done)
,.dbg_wrcal_err (dbg_wrcal_err)
,.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal)
,.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data)
,.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start)
,.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done)
,.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r)
,.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps)
,.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps)
);
endmodule
|
module mig_7series_v2_3_mem_intfc #
(
parameter TCQ = 100,
parameter DDR3_VDD_OP_VOLT = "135", // Voltage mode used for DDR3
parameter PAYLOAD_WIDTH = 64,
parameter ADDR_CMD_MODE = "1T",
parameter AL = "0", // Additive Latency option
parameter BANK_WIDTH = 3, // # of bank bits
parameter BM_CNT_WIDTH = 2, // Bank machine counter width
parameter BURST_MODE = "8", // Burst length
parameter BURST_TYPE = "SEQ", // Burst type
parameter CA_MIRROR = "OFF", // C/A mirror opt for DDR3 dual rank
parameter CK_WIDTH = 1, // # of CK/CK# outputs to memory
// five fields, one per possible I/O bank, 4 bits in each field, 1 per lane
// data=1/ctl=0
parameter DATA_CTL_B0 = 4'hc,
parameter DATA_CTL_B1 = 4'hf,
parameter DATA_CTL_B2 = 4'hf,
parameter DATA_CTL_B3 = 4'hf,
parameter DATA_CTL_B4 = 4'hf,
// defines the byte lanes in I/O banks being used in the interface
// 1- Used, 0- Unused
parameter BYTE_LANES_B0 = 4'b1111,
parameter BYTE_LANES_B1 = 4'b0000,
parameter BYTE_LANES_B2 = 4'b0000,
parameter BYTE_LANES_B3 = 4'b0000,
parameter BYTE_LANES_B4 = 4'b0000,
// defines the bit lanes in I/O banks being used in the interface. Each
// parameter = 1 I/O bank = 4 byte lanes = 48 bit lanes. 1-Used, 0-Unused
parameter PHY_0_BITLANES = 48'h0000_0000_0000,
parameter PHY_1_BITLANES = 48'h0000_0000_0000,
parameter PHY_2_BITLANES = 48'h0000_0000_0000,
// control/address/data pin mapping parameters
parameter CK_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter ADDR_MAP
= 192'h000_000_000_000_000_000_000_000_000_000_000_000_000_000_000_000,
parameter BANK_MAP = 36'h000_000_000,
parameter CAS_MAP = 12'h000,
parameter CKE_ODT_BYTE_MAP = 8'h00,
parameter CKE_MAP = 96'h000_000_000_000_000_000_000_000,
parameter ODT_MAP = 96'h000_000_000_000_000_000_000_000,
parameter CKE_ODT_AUX = "FALSE",
parameter CS_MAP = 120'h000_000_000_000_000_000_000_000_000_000,
parameter PARITY_MAP = 12'h000,
parameter RAS_MAP = 12'h000,
parameter WE_MAP = 12'h000,
parameter DQS_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter DATA0_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA1_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA2_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA3_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA4_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA5_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA6_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA7_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA8_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA9_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA10_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA11_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA12_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA13_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA14_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA15_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA16_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA17_MAP = 96'h000_000_000_000_000_000_000_000,
parameter MASK0_MAP = 108'h000_000_000_000_000_000_000_000_000,
parameter MASK1_MAP = 108'h000_000_000_000_000_000_000_000_000,
// calibration Address. The address given below will be used for calibration
// read and write operations.
parameter CALIB_ROW_ADD = 16'h0000,// Calibration row address
parameter CALIB_COL_ADD = 12'h000, // Calibration column address
parameter CALIB_BA_ADD = 3'h0, // Calibration bank address
parameter CL = 5,
parameter COL_WIDTH = 12, // column address width
parameter CMD_PIPE_PLUS1 = "ON", // add pipeline stage between MC and PHY
parameter CS_WIDTH = 1, // # of unique CS outputs
parameter CKE_WIDTH = 1, // # of cke outputs
parameter CWL = 5,
parameter DATA_WIDTH = 64,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DDR2_DQSN_ENABLE = "YES", // Enable differential DQS for DDR2
parameter DM_WIDTH = 8, // # of DM (data mask)
parameter DQ_CNT_WIDTH = 6, // = ceil(log2(DQ_WIDTH))
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_TYPE = "DDR3",
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter ECC = "OFF",
parameter ECC_WIDTH = 8,
parameter MC_ERR_ADDR_WIDTH = 31,
parameter nAL = 0, // Additive latency (in clk cyc)
parameter nBANK_MACHS = 4,
parameter PRE_REV3ES = "OFF", // Delay O/Ps using Phaser_Out fine dly
parameter nCK_PER_CLK = 4, // # of memory CKs per fabric CLK
parameter nCS_PER_RANK = 1, // # of unique CS outputs per rank
// Hard PHY parameters
parameter PHYCTL_CMD_FIFO = "FALSE",
parameter ORDERING = "NORM",
parameter PHASE_DETECT = "OFF" , // to phy_top
parameter IBUF_LPWR_MODE = "OFF", // to phy_top
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter DATA_IO_PRIM_TYPE = "DEFAULT", // # = "HP_LP", "HR_LP", "DEFAULT"
parameter DATA_IO_IDLE_PWRDWN = "ON", // "ON" or "OFF"
parameter IODELAY_GRP = "IODELAY_MIG", //to phy_top
parameter FPGA_SPEED_GRADE = 1,
parameter OUTPUT_DRV = "HIGH" , // to phy_top
parameter REG_CTRL = "OFF" , // to phy_top
parameter RTT_NOM = "60" , // to phy_top
parameter RTT_WR = "120" , // to phy_top
parameter STARVE_LIMIT = 2,
parameter tCK = 2500, // pS
parameter tCKE = 10000, // pS
parameter tFAW = 40000, // pS
parameter tPRDI = 1_000_000, // pS
parameter tRAS = 37500, // pS
parameter tRCD = 12500, // pS
parameter tREFI = 7800000, // pS
parameter tRFC = 110000, // pS
parameter tRP = 12500, // pS
parameter tRRD = 10000, // pS
parameter tRTP = 7500, // pS
parameter tWTR = 7500, // pS
parameter tZQI = 128_000_000, // nS
parameter tZQCS = 64, // CKs
parameter WRLVL = "OFF" , // to phy_top
parameter DEBUG_PORT = "OFF" , // to phy_top
parameter CAL_WIDTH = "HALF" , // to phy_top
parameter RANK_WIDTH = 1,
parameter RANKS = 4,
parameter ODT_WIDTH = 1,
parameter ROW_WIDTH = 16, // DRAM address bus width
parameter [7:0] SLOT_0_CONFIG = 8'b0000_0001,
parameter [7:0] SLOT_1_CONFIG = 8'b0000_0000,
parameter SIM_BYPASS_INIT_CAL = "OFF",
parameter REFCLK_FREQ = 300.0,
parameter nDQS_COL0 = DQS_WIDTH,
parameter nDQS_COL1 = 0,
parameter nDQS_COL2 = 0,
parameter nDQS_COL3 = 0,
parameter DQS_LOC_COL0 = 144'h11100F0E0D0C0B0A09080706050403020100,
parameter DQS_LOC_COL1 = 0,
parameter DQS_LOC_COL2 = 0,
parameter DQS_LOC_COL3 = 0,
parameter USE_CS_PORT = 1, // Support chip select output
parameter USE_DM_PORT = 1, // Support data mask output
parameter USE_ODT_PORT = 1, // Support ODT output
parameter MASTER_PHY_CTL = 0, // The bank number where master PHY_CONTROL resides
parameter USER_REFRESH = "OFF", // Choose whether MC or User manages REF
parameter TEMP_MON_EN = "ON", // Enable/disable temperature monitoring
parameter IDELAY_ADJ = "ON", // Adjust IDELAY value (-1)
parameter FINE_PER_BIT = "ON", // Use finedelay per-bit de-skew
parameter CENTER_COMP_MODE = "ON", // Use Center compensation table for PI
parameter PI_VAL_ADJ = "ON", // Adjust PI final value (-1)
parameter TAPSPERKCLK = 56
)
(
input clk_ref,
input freq_refclk,
input mem_refclk,
input pll_lock,
input sync_pulse,
input mmcm_ps_clk,
input poc_sample_pd,
input error,
input reset,
output rst_tg_mc,
input [BANK_WIDTH-1:0] bank, // To mc0 of mc.v
input clk ,
input [2:0] cmd, // To mc0 of mc.v
input [COL_WIDTH-1:0] col, // To mc0 of mc.v
input correct_en,
input [DATA_BUF_ADDR_WIDTH-1:0] data_buf_addr, // To mc0 of mc.v
input dbg_idel_down_all,
input dbg_idel_down_cpt,
input dbg_idel_up_all,
input dbg_idel_up_cpt,
input dbg_sel_all_idel_cpt,
input [DQS_CNT_WIDTH-1:0] dbg_sel_idel_cpt,
input hi_priority, // To mc0 of mc.v
input [RANK_WIDTH-1:0] rank, // To mc0 of mc.v
input [2*nCK_PER_CLK-1:0] raw_not_ecc,
input [ROW_WIDTH-1:0] row, // To mc0 of mc.v
input rst, // To mc0 of mc.v, ...
input size, // To mc0 of mc.v
input [7:0] slot_0_present, // To mc0 of mc.v
input [7:0] slot_1_present, // To mc0 of mc.v
input use_addr, // To mc0 of mc.v
input [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data,
input [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask,
output accept, // From mc0 of mc.v
output accept_ns, // From mc0 of mc.v
output [BM_CNT_WIDTH-1:0] bank_mach_next, // From mc0 of mc.v
input app_sr_req,
output app_sr_active,
input app_ref_req,
output app_ref_ack,
input app_zq_req,
output app_zq_ack,
output [255:0] dbg_calib_top,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_first_edge_cnt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_second_edge_cnt,
output [255:0] dbg_phy_rdlvl,
output [99:0] dbg_phy_wrcal,
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output [DQS_WIDTH-1:0] dbg_rd_data_edge_detect,
output [2*nCK_PER_CLK*DQ_WIDTH-1:0] dbg_rddata,
output [1:0] dbg_rdlvl_done,
output [1:0] dbg_rdlvl_err,
output [1:0] dbg_rdlvl_start,
output [5:0] dbg_tap_cnt_during_wrlvl,
output dbg_wl_edge_detect_valid,
output dbg_wrlvl_done,
output dbg_wrlvl_err,
output dbg_wrlvl_start,
output [ROW_WIDTH-1:0] ddr_addr, // From phy_top0 of phy_top.v
output [BANK_WIDTH-1:0] ddr_ba, // From phy_top0 of phy_top.v
output ddr_cas_n, // From phy_top0 of phy_top.v
output [CK_WIDTH-1:0] ddr_ck_n, // From phy_top0 of phy_top.v
output [CK_WIDTH-1:0] ddr_ck , // From phy_top0 of phy_top.v
output [CKE_WIDTH-1:0] ddr_cke, // From phy_top0 of phy_top.v
output [CS_WIDTH*nCS_PER_RANK-1:0] ddr_cs_n, // From phy_top0 of phy_top.v
output [DM_WIDTH-1:0] ddr_dm, // From phy_top0 of phy_top.v
output [ODT_WIDTH-1:0] ddr_odt, // From phy_top0 of phy_top.v
output ddr_ras_n, // From phy_top0 of phy_top.v
output ddr_reset_n, // From phy_top0 of phy_top.v
output ddr_parity,
output ddr_we_n, // From phy_top0 of phy_top.v
output init_calib_complete,
output init_wrcal_complete,
output [MC_ERR_ADDR_WIDTH-1:0] ecc_err_addr,
output [2*nCK_PER_CLK-1:0] ecc_multiple,
output [2*nCK_PER_CLK-1:0] ecc_single,
output wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] rd_data,
output [DATA_BUF_ADDR_WIDTH-1:0] rd_data_addr,
// From mc0 of mc.v
output rd_data_en, // From mc0 of mc.v
output rd_data_end, // From mc0 of mc.v
output [DATA_BUF_OFFSET_WIDTH-1:0] rd_data_offset, // From mc0 of mc.v
output [DATA_BUF_ADDR_WIDTH-1:0] wr_data_addr, // From mc0 of mc.v
output wr_data_en, // From mc0 of mc.v
output [DATA_BUF_OFFSET_WIDTH-1:0] wr_data_offset, // From mc0 of mc.v
inout [DQ_WIDTH-1:0] ddr_dq, // To/From phy_top0 of phy_top.v
inout [DQS_WIDTH-1:0] ddr_dqs_n, // To/From phy_top0 of phy_top.v
inout [DQS_WIDTH-1:0] ddr_dqs // To/From phy_top0 of phy_top.v
,input [11:0] device_temp
//phase shift clock control
,output psen
,output psincdec
,input psdone
,input [DQ_WIDTH/8-1:0] fi_xor_we
,input [DQ_WIDTH-1:0] fi_xor_wrdata
,input dbg_sel_pi_incdec
,input dbg_sel_po_incdec
,input [DQS_CNT_WIDTH:0] dbg_byte_sel
,input dbg_pi_f_inc
,input dbg_pi_f_dec
,input dbg_po_f_inc
,input dbg_po_f_stg23_sel
,input dbg_po_f_dec
,output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_tap_cnt
,output [5*DQS_WIDTH*RANKS-1:0] dbg_dq_idelay_tap_cnt
,output dbg_rddata_valid
,output [6*DQS_WIDTH-1:0] dbg_wrlvl_fine_tap_cnt
,output [3*DQS_WIDTH-1:0] dbg_wrlvl_coarse_tap_cnt
,output [255:0] dbg_phy_wrlvl
,output [5:0] dbg_pi_counter_read_val
,output [8:0] dbg_po_counter_read_val
,output ref_dll_lock
,input rst_phaser_ref
,input iddr_rst
,output [6*RANKS-1:0] dbg_rd_data_offset
,output [255:0] dbg_phy_init
,output [255:0] dbg_prbs_rdlvl
,output [255:0] dbg_dqs_found_cal
,output dbg_pi_phaselock_start
,output dbg_pi_phaselocked_done
,output dbg_pi_phaselock_err
,output dbg_pi_dqsfound_start
,output dbg_pi_dqsfound_done
,output dbg_pi_dqsfound_err
,output dbg_wrcal_start
,output dbg_wrcal_done
,output dbg_wrcal_err
,output [11:0] dbg_pi_dqs_found_lanes_phy4lanes
,output [11:0] dbg_pi_phase_locked_phy4lanes
,output [6*RANKS-1:0] dbg_calib_rd_data_offset_1
,output [6*RANKS-1:0] dbg_calib_rd_data_offset_2
,output [5:0] dbg_data_offset
,output [5:0] dbg_data_offset_1
,output [5:0] dbg_data_offset_2
,output dbg_oclkdelay_calib_start
,output dbg_oclkdelay_calib_done
,output [255:0] dbg_phy_oclkdelay_cal
,output [DRAM_WIDTH*16 -1:0]dbg_oclkdelay_rd_data
,output [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r
,output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps
,output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps
);
localparam nSLOTS = 1 + (|SLOT_1_CONFIG ? 1 : 0);
localparam SLOT_0_CONFIG_MC = (nSLOTS == 2)? 8'b0000_0101 : 8'b0000_1111;
localparam SLOT_1_CONFIG_MC = (nSLOTS == 2)? 8'b0000_1010 : 8'b0000_0000;
// 8*tREFI in ps is divided by fabric clock period also in ps. 270 is the number
// of fabric clock cycles that accounts for the Writes, read, and PRECHARGE time
localparam REFRESH_TIMER = (8*tREFI/(tCK*nCK_PER_CLK)) - 270;
reg [7:0] slot_0_present_mc;
reg [7:0] slot_1_present_mc;
reg user_periodic_rd_req = 1'b0;
reg user_ref_req = 1'b0;
reg user_zq_req = 1'b0;
// MC/PHY interface
wire [nCK_PER_CLK-1:0] mc_ras_n;
wire [nCK_PER_CLK-1:0] mc_cas_n;
wire [nCK_PER_CLK-1:0] mc_we_n;
wire [nCK_PER_CLK*ROW_WIDTH-1:0] mc_address;
wire [nCK_PER_CLK*BANK_WIDTH-1:0] mc_bank;
wire [nCK_PER_CLK-1 :0] mc_cke ;
wire [1:0] mc_odt ;
wire [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] mc_cs_n;
wire mc_reset_n;
wire [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata;
wire [2*nCK_PER_CLK*DQ_WIDTH/8-1:0] mc_wrdata_mask;
wire mc_wrdata_en;
wire mc_ref_zq_wip;
wire tempmon_sample_en;
wire idle;
wire mc_cmd_wren;
wire mc_ctl_wren;
wire [2:0] mc_cmd;
wire [1:0] mc_cas_slot;
wire [5:0] mc_data_offset;
wire [5:0] mc_data_offset_1;
wire [5:0] mc_data_offset_2;
wire [3:0] mc_aux_out0;
wire [3:0] mc_aux_out1;
wire [1:0] mc_rank_cnt;
wire phy_mc_ctl_full;
wire phy_mc_cmd_full;
wire phy_mc_data_full;
wire [2*nCK_PER_CLK*DQ_WIDTH-1:0] phy_rd_data;
wire phy_rddata_valid;
wire [6*RANKS-1:0] calib_rd_data_offset_0;
wire [6*RANKS-1:0] calib_rd_data_offset_1;
wire [6*RANKS-1:0] calib_rd_data_offset_2;
wire init_calib_complete_w;
wire init_wrcal_complete_w;
wire mux_rst;
wire mux_calib_complete;
// assigning CWL = CL -1 for DDR2. DDR2 customers will not know anything
// about CWL. There is also nCWL parameter. Need to clean it up.
localparam CWL_T = (DRAM_TYPE == "DDR3") ? CWL : CL-1;
assign init_calib_complete = init_calib_complete_w;
assign init_wrcal_complete = init_wrcal_complete_w;
assign mux_calib_complete = (PRE_REV3ES == "OFF") ? init_calib_complete_w :
(init_calib_complete_w | init_wrcal_complete_w);
assign mux_rst = (PRE_REV3ES == "OFF") ? rst : reset;
assign dbg_calib_rd_data_offset_1 = calib_rd_data_offset_1;
assign dbg_calib_rd_data_offset_2 = calib_rd_data_offset_2;
assign dbg_data_offset = mc_data_offset;
assign dbg_data_offset_1 = mc_data_offset_1;
assign dbg_data_offset_2 = mc_data_offset_2;
// Enable / disable temperature monitoring
assign tempmon_sample_en = TEMP_MON_EN == "OFF" ? 1'b0 : mc_ref_zq_wip;
generate
if (nSLOTS == 1) begin: gen_single_slot_odt
always @ (slot_0_present or slot_1_present) begin
slot_0_present_mc = slot_0_present;
slot_1_present_mc = slot_1_present;
end
end else if (nSLOTS == 2) begin: gen_dual_slot_odt
always @ (slot_0_present[0] or slot_0_present[1]
or slot_1_present[0] or slot_1_present[1]) begin
case ({slot_0_present[0],slot_0_present[1],
slot_1_present[0],slot_1_present[1]})
//Two slot configuration, one slot present, single rank
4'b1000: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_0000;
end
4'b0010: begin
slot_0_present_mc = 8'b0000_0000;
slot_1_present_mc = 8'b0000_0010;
end
// Two slot configuration, one slot present, dual rank
4'b1100: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_0000;
end
4'b0011: begin
slot_0_present_mc = 8'b0000_0000;
slot_1_present_mc = 8'b0000_1010;
end
// Two slot configuration, one rank per slot
4'b1010: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_0010;
end
// Two Slots - One slot with dual rank and the other with single rank
4'b1011: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_1010;
end
4'b1110: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_0010;
end
// Two Slots - two ranks per slot
4'b1111: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_1010;
end
endcase
end
end
endgenerate
mig_7series_v2_3_mc #
(
.TCQ (TCQ),
.PAYLOAD_WIDTH (PAYLOAD_WIDTH),
.MC_ERR_ADDR_WIDTH (MC_ERR_ADDR_WIDTH),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_WIDTH (BANK_WIDTH),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.BURST_MODE (BURST_MODE),
.COL_WIDTH (COL_WIDTH),
.CMD_PIPE_PLUS1 (CMD_PIPE_PLUS1),
.CS_WIDTH (CS_WIDTH),
.DATA_WIDTH (DATA_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DATA_BUF_OFFSET_WIDTH (DATA_BUF_OFFSET_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.CKE_ODT_AUX (CKE_ODT_AUX),
.DQS_WIDTH (DQS_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.ECC (ECC),
.ECC_WIDTH (ECC_WIDTH),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nSLOTS (nSLOTS),
.CL (CL),
.nCS_PER_RANK (nCS_PER_RANK),
.CWL (CWL_T),
.ORDERING (ORDERING),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.STARVE_LIMIT (STARVE_LIMIT),
.SLOT_0_CONFIG (SLOT_0_CONFIG_MC),
.SLOT_1_CONFIG (SLOT_1_CONFIG_MC),
.tCK (tCK),
.tCKE (tCKE),
.tFAW (tFAW),
.tRAS (tRAS),
.tRCD (tRCD),
.tREFI (tREFI),
.tRFC (tRFC),
.tRP (tRP),
.tRRD (tRRD),
.tRTP (tRTP),
.tWTR (tWTR),
.tZQI (tZQI),
.tZQCS (tZQCS),
.tPRDI (tPRDI),
.USER_REFRESH (USER_REFRESH))
mc0
(.app_periodic_rd_req (1'b0),
.app_sr_req (app_sr_req),
.app_sr_active (app_sr_active),
.app_ref_req (app_ref_req),
.app_ref_ack (app_ref_ack),
.app_zq_req (app_zq_req),
.app_zq_ack (app_zq_ack),
.ecc_single (ecc_single),
.ecc_multiple (ecc_multiple),
.ecc_err_addr (ecc_err_addr),
.mc_address (mc_address),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_bank (mc_bank),
.mc_cke (mc_cke),
.mc_odt (mc_odt),
.mc_cas_n (mc_cas_n),
.mc_cmd (mc_cmd),
.mc_cmd_wren (mc_cmd_wren),
.mc_cs_n (mc_cs_n),
.mc_ctl_wren (mc_ctl_wren),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_cas_slot (mc_cas_slot),
.mc_rank_cnt (mc_rank_cnt),
.mc_ras_n (mc_ras_n),
.mc_reset_n (mc_reset_n),
.mc_we_n (mc_we_n),
.mc_wrdata (mc_wrdata),
.mc_wrdata_en (mc_wrdata_en),
.mc_wrdata_mask (mc_wrdata_mask),
// Outputs
.accept (accept),
.accept_ns (accept_ns),
.bank_mach_next (bank_mach_next[BM_CNT_WIDTH-1:0]),
.rd_data_addr (rd_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.rd_data_en (rd_data_en),
.rd_data_end (rd_data_end),
.rd_data_offset (rd_data_offset),
.wr_data_addr (wr_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.wr_data_en (wr_data_en),
.wr_data_offset (wr_data_offset),
.rd_data (rd_data),
.wr_data (wr_data),
.wr_data_mask (wr_data_mask),
.mc_read_idle (idle),
.mc_ref_zq_wip (mc_ref_zq_wip),
// Inputs
.init_calib_complete (mux_calib_complete),
.calib_rd_data_offset (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_data_full (phy_mc_data_full),
.phy_rd_data (phy_rd_data),
.phy_rddata_valid (phy_rddata_valid),
.correct_en (correct_en),
.bank (bank[BANK_WIDTH-1:0]),
.clk (clk),
.cmd (cmd[2:0]),
.col (col[COL_WIDTH-1:0]),
.data_buf_addr (data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.hi_priority (hi_priority),
.rank (rank[RANK_WIDTH-1:0]),
.raw_not_ecc (raw_not_ecc[2*nCK_PER_CLK-1 :0]),
.row (row[ROW_WIDTH-1:0]),
.rst (mux_rst),
.size (size),
.slot_0_present (slot_0_present_mc[7:0]),
.slot_1_present (slot_1_present_mc[7:0]),
.fi_xor_we (fi_xor_we),
.fi_xor_wrdata (fi_xor_wrdata),
.use_addr (use_addr));
// following calculations should be moved inside PHY
// odt bus should be added to PHY.
localparam CLK_PERIOD = tCK * nCK_PER_CLK;
localparam nCL = CL;
localparam nCWL = CWL_T;
`ifdef MC_SVA
ddr2_improper_CL: assert property
(@(posedge clk) (~((DRAM_TYPE == "DDR2") && ((CL > 6) || (CL < 3)))));
// Not needed after the CWL fix for DDR2
// ddr2_improper_CWL: assert property
// (@(posedge clk) (~((DRAM_TYPE == "DDR2") && ((CL - CWL) != 1))));
`endif
mig_7series_v2_3_ddr_phy_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.REFCLK_FREQ (REFCLK_FREQ),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.CA_MIRROR (CA_MIRROR),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.nCS_PER_RANK (nCS_PER_RANK),
.CS_WIDTH (CS_WIDTH),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.CKE_WIDTH (CKE_WIDTH),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.DRAM_TYPE (DRAM_TYPE),
.BANK_WIDTH (BANK_WIDTH),
.CK_WIDTH (CK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.ROW_WIDTH (ROW_WIDTH),
.AL (AL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.CL (nCL),
.CWL (nCWL),
.tRFC (tRFC),
.tREFI (tREFI),
.tCK (tCK),
.OUTPUT_DRV (OUTPUT_DRV),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.WRLVL (WRLVL),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
// Prevent the following simulation-related parameters from
// being overridden for synthesis - for synthesis only the
// default values of these parameters should be used
// synthesis translate_off
.SIM_BYPASS_INIT_CAL (SIM_BYPASS_INIT_CAL),
// synthesis translate_on
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK)
)
ddr_phy_top0
(
// Outputs
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.ddr_ck (ddr_ck),
.ddr_ck_n (ddr_ck_n),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_ras_n (ddr_ras_n),
.ddr_cas_n (ddr_cas_n),
.ddr_we_n (ddr_we_n),
.ddr_cs_n (ddr_cs_n),
.ddr_cke (ddr_cke),
.ddr_odt (ddr_odt),
.ddr_reset_n (ddr_reset_n),
.ddr_parity (ddr_parity),
.ddr_dm (ddr_dm),
.dbg_calib_top (dbg_calib_top),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_rddata (dbg_rddata),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.init_calib_complete (init_calib_complete_w),
.init_wrcal_complete (init_wrcal_complete_w),
.mc_address (mc_address),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_bank (mc_bank),
.mc_cke (mc_cke),
.mc_odt (mc_odt),
.mc_cas_n (mc_cas_n),
.mc_cmd (mc_cmd),
.mc_cmd_wren (mc_cmd_wren),
.mc_cas_slot (mc_cas_slot),
.mc_cs_n (mc_cs_n),
.mc_ctl_wren (mc_ctl_wren),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_rank_cnt (mc_rank_cnt),
.mc_ras_n (mc_ras_n),
.mc_reset_n (mc_reset_n),
.mc_we_n (mc_we_n),
.mc_wrdata (mc_wrdata),
.mc_wrdata_en (mc_wrdata_en),
.mc_wrdata_mask (mc_wrdata_mask),
.idle (idle),
.mem_refclk (mem_refclk),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_data_full (phy_mc_data_full),
.phy_rd_data (phy_rd_data),
.phy_rddata_valid (phy_rddata_valid),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
// Inouts
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_dq (ddr_dq),
// Inputs
.clk_ref (clk_ref),
.freq_refclk (freq_refclk),
.clk (clk),
.mmcm_ps_clk (mmcm_ps_clk),
.poc_sample_pd (poc_sample_pd),
.rst (rst),
.error (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt)
,.device_temp (device_temp)
,.tempmon_sample_en (tempmon_sample_en)
,.psen (psen)
,.psincdec (psincdec)
,.psdone (psdone)
,.dbg_sel_pi_incdec (dbg_sel_pi_incdec)
,.dbg_sel_po_incdec (dbg_sel_po_incdec)
,.dbg_byte_sel (dbg_byte_sel)
,.dbg_pi_f_inc (dbg_pi_f_inc)
,.dbg_po_f_inc (dbg_po_f_inc)
,.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel)
,.dbg_pi_f_dec (dbg_pi_f_dec)
,.dbg_po_f_dec (dbg_po_f_dec)
,.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt)
,.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt)
,.dbg_rddata_valid (dbg_rddata_valid)
,.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt)
,.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt)
,.dbg_phy_wrlvl (dbg_phy_wrlvl)
,.ref_dll_lock (ref_dll_lock)
,.rst_phaser_ref (rst_phaser_ref)
,.iddr_rst (iddr_rst)
,.dbg_rd_data_offset (dbg_rd_data_offset)
,.dbg_phy_init (dbg_phy_init)
,.dbg_prbs_rdlvl (dbg_prbs_rdlvl)
,.dbg_dqs_found_cal (dbg_dqs_found_cal)
,.dbg_po_counter_read_val (dbg_po_counter_read_val)
,.dbg_pi_counter_read_val (dbg_pi_counter_read_val)
,.dbg_pi_phaselock_start (dbg_pi_phaselock_start)
,.dbg_pi_phaselocked_done (dbg_pi_phaselocked_done)
,.dbg_pi_phaselock_err (dbg_pi_phaselock_err)
,.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start)
,.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done)
,.dbg_pi_dqsfound_err (dbg_pi_dqsfound_err)
,.dbg_wrcal_start (dbg_wrcal_start)
,.dbg_wrcal_done (dbg_wrcal_done)
,.dbg_wrcal_err (dbg_wrcal_err)
,.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal)
,.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data)
,.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start)
,.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done)
,.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r)
,.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps)
,.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps)
);
endmodule
|
module mig_7series_v2_3_mem_intfc #
(
parameter TCQ = 100,
parameter DDR3_VDD_OP_VOLT = "135", // Voltage mode used for DDR3
parameter PAYLOAD_WIDTH = 64,
parameter ADDR_CMD_MODE = "1T",
parameter AL = "0", // Additive Latency option
parameter BANK_WIDTH = 3, // # of bank bits
parameter BM_CNT_WIDTH = 2, // Bank machine counter width
parameter BURST_MODE = "8", // Burst length
parameter BURST_TYPE = "SEQ", // Burst type
parameter CA_MIRROR = "OFF", // C/A mirror opt for DDR3 dual rank
parameter CK_WIDTH = 1, // # of CK/CK# outputs to memory
// five fields, one per possible I/O bank, 4 bits in each field, 1 per lane
// data=1/ctl=0
parameter DATA_CTL_B0 = 4'hc,
parameter DATA_CTL_B1 = 4'hf,
parameter DATA_CTL_B2 = 4'hf,
parameter DATA_CTL_B3 = 4'hf,
parameter DATA_CTL_B4 = 4'hf,
// defines the byte lanes in I/O banks being used in the interface
// 1- Used, 0- Unused
parameter BYTE_LANES_B0 = 4'b1111,
parameter BYTE_LANES_B1 = 4'b0000,
parameter BYTE_LANES_B2 = 4'b0000,
parameter BYTE_LANES_B3 = 4'b0000,
parameter BYTE_LANES_B4 = 4'b0000,
// defines the bit lanes in I/O banks being used in the interface. Each
// parameter = 1 I/O bank = 4 byte lanes = 48 bit lanes. 1-Used, 0-Unused
parameter PHY_0_BITLANES = 48'h0000_0000_0000,
parameter PHY_1_BITLANES = 48'h0000_0000_0000,
parameter PHY_2_BITLANES = 48'h0000_0000_0000,
// control/address/data pin mapping parameters
parameter CK_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter ADDR_MAP
= 192'h000_000_000_000_000_000_000_000_000_000_000_000_000_000_000_000,
parameter BANK_MAP = 36'h000_000_000,
parameter CAS_MAP = 12'h000,
parameter CKE_ODT_BYTE_MAP = 8'h00,
parameter CKE_MAP = 96'h000_000_000_000_000_000_000_000,
parameter ODT_MAP = 96'h000_000_000_000_000_000_000_000,
parameter CKE_ODT_AUX = "FALSE",
parameter CS_MAP = 120'h000_000_000_000_000_000_000_000_000_000,
parameter PARITY_MAP = 12'h000,
parameter RAS_MAP = 12'h000,
parameter WE_MAP = 12'h000,
parameter DQS_BYTE_MAP
= 144'h00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00_00,
parameter DATA0_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA1_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA2_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA3_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA4_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA5_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA6_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA7_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA8_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA9_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA10_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA11_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA12_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA13_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA14_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA15_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA16_MAP = 96'h000_000_000_000_000_000_000_000,
parameter DATA17_MAP = 96'h000_000_000_000_000_000_000_000,
parameter MASK0_MAP = 108'h000_000_000_000_000_000_000_000_000,
parameter MASK1_MAP = 108'h000_000_000_000_000_000_000_000_000,
// calibration Address. The address given below will be used for calibration
// read and write operations.
parameter CALIB_ROW_ADD = 16'h0000,// Calibration row address
parameter CALIB_COL_ADD = 12'h000, // Calibration column address
parameter CALIB_BA_ADD = 3'h0, // Calibration bank address
parameter CL = 5,
parameter COL_WIDTH = 12, // column address width
parameter CMD_PIPE_PLUS1 = "ON", // add pipeline stage between MC and PHY
parameter CS_WIDTH = 1, // # of unique CS outputs
parameter CKE_WIDTH = 1, // # of cke outputs
parameter CWL = 5,
parameter DATA_WIDTH = 64,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DDR2_DQSN_ENABLE = "YES", // Enable differential DQS for DDR2
parameter DM_WIDTH = 8, // # of DM (data mask)
parameter DQ_CNT_WIDTH = 6, // = ceil(log2(DQ_WIDTH))
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_TYPE = "DDR3",
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter ECC = "OFF",
parameter ECC_WIDTH = 8,
parameter MC_ERR_ADDR_WIDTH = 31,
parameter nAL = 0, // Additive latency (in clk cyc)
parameter nBANK_MACHS = 4,
parameter PRE_REV3ES = "OFF", // Delay O/Ps using Phaser_Out fine dly
parameter nCK_PER_CLK = 4, // # of memory CKs per fabric CLK
parameter nCS_PER_RANK = 1, // # of unique CS outputs per rank
// Hard PHY parameters
parameter PHYCTL_CMD_FIFO = "FALSE",
parameter ORDERING = "NORM",
parameter PHASE_DETECT = "OFF" , // to phy_top
parameter IBUF_LPWR_MODE = "OFF", // to phy_top
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter DATA_IO_PRIM_TYPE = "DEFAULT", // # = "HP_LP", "HR_LP", "DEFAULT"
parameter DATA_IO_IDLE_PWRDWN = "ON", // "ON" or "OFF"
parameter IODELAY_GRP = "IODELAY_MIG", //to phy_top
parameter FPGA_SPEED_GRADE = 1,
parameter OUTPUT_DRV = "HIGH" , // to phy_top
parameter REG_CTRL = "OFF" , // to phy_top
parameter RTT_NOM = "60" , // to phy_top
parameter RTT_WR = "120" , // to phy_top
parameter STARVE_LIMIT = 2,
parameter tCK = 2500, // pS
parameter tCKE = 10000, // pS
parameter tFAW = 40000, // pS
parameter tPRDI = 1_000_000, // pS
parameter tRAS = 37500, // pS
parameter tRCD = 12500, // pS
parameter tREFI = 7800000, // pS
parameter tRFC = 110000, // pS
parameter tRP = 12500, // pS
parameter tRRD = 10000, // pS
parameter tRTP = 7500, // pS
parameter tWTR = 7500, // pS
parameter tZQI = 128_000_000, // nS
parameter tZQCS = 64, // CKs
parameter WRLVL = "OFF" , // to phy_top
parameter DEBUG_PORT = "OFF" , // to phy_top
parameter CAL_WIDTH = "HALF" , // to phy_top
parameter RANK_WIDTH = 1,
parameter RANKS = 4,
parameter ODT_WIDTH = 1,
parameter ROW_WIDTH = 16, // DRAM address bus width
parameter [7:0] SLOT_0_CONFIG = 8'b0000_0001,
parameter [7:0] SLOT_1_CONFIG = 8'b0000_0000,
parameter SIM_BYPASS_INIT_CAL = "OFF",
parameter REFCLK_FREQ = 300.0,
parameter nDQS_COL0 = DQS_WIDTH,
parameter nDQS_COL1 = 0,
parameter nDQS_COL2 = 0,
parameter nDQS_COL3 = 0,
parameter DQS_LOC_COL0 = 144'h11100F0E0D0C0B0A09080706050403020100,
parameter DQS_LOC_COL1 = 0,
parameter DQS_LOC_COL2 = 0,
parameter DQS_LOC_COL3 = 0,
parameter USE_CS_PORT = 1, // Support chip select output
parameter USE_DM_PORT = 1, // Support data mask output
parameter USE_ODT_PORT = 1, // Support ODT output
parameter MASTER_PHY_CTL = 0, // The bank number where master PHY_CONTROL resides
parameter USER_REFRESH = "OFF", // Choose whether MC or User manages REF
parameter TEMP_MON_EN = "ON", // Enable/disable temperature monitoring
parameter IDELAY_ADJ = "ON", // Adjust IDELAY value (-1)
parameter FINE_PER_BIT = "ON", // Use finedelay per-bit de-skew
parameter CENTER_COMP_MODE = "ON", // Use Center compensation table for PI
parameter PI_VAL_ADJ = "ON", // Adjust PI final value (-1)
parameter TAPSPERKCLK = 56
)
(
input clk_ref,
input freq_refclk,
input mem_refclk,
input pll_lock,
input sync_pulse,
input mmcm_ps_clk,
input poc_sample_pd,
input error,
input reset,
output rst_tg_mc,
input [BANK_WIDTH-1:0] bank, // To mc0 of mc.v
input clk ,
input [2:0] cmd, // To mc0 of mc.v
input [COL_WIDTH-1:0] col, // To mc0 of mc.v
input correct_en,
input [DATA_BUF_ADDR_WIDTH-1:0] data_buf_addr, // To mc0 of mc.v
input dbg_idel_down_all,
input dbg_idel_down_cpt,
input dbg_idel_up_all,
input dbg_idel_up_cpt,
input dbg_sel_all_idel_cpt,
input [DQS_CNT_WIDTH-1:0] dbg_sel_idel_cpt,
input hi_priority, // To mc0 of mc.v
input [RANK_WIDTH-1:0] rank, // To mc0 of mc.v
input [2*nCK_PER_CLK-1:0] raw_not_ecc,
input [ROW_WIDTH-1:0] row, // To mc0 of mc.v
input rst, // To mc0 of mc.v, ...
input size, // To mc0 of mc.v
input [7:0] slot_0_present, // To mc0 of mc.v
input [7:0] slot_1_present, // To mc0 of mc.v
input use_addr, // To mc0 of mc.v
input [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data,
input [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask,
output accept, // From mc0 of mc.v
output accept_ns, // From mc0 of mc.v
output [BM_CNT_WIDTH-1:0] bank_mach_next, // From mc0 of mc.v
input app_sr_req,
output app_sr_active,
input app_ref_req,
output app_ref_ack,
input app_zq_req,
output app_zq_ack,
output [255:0] dbg_calib_top,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_first_edge_cnt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_second_edge_cnt,
output [255:0] dbg_phy_rdlvl,
output [99:0] dbg_phy_wrcal,
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output [DQS_WIDTH-1:0] dbg_rd_data_edge_detect,
output [2*nCK_PER_CLK*DQ_WIDTH-1:0] dbg_rddata,
output [1:0] dbg_rdlvl_done,
output [1:0] dbg_rdlvl_err,
output [1:0] dbg_rdlvl_start,
output [5:0] dbg_tap_cnt_during_wrlvl,
output dbg_wl_edge_detect_valid,
output dbg_wrlvl_done,
output dbg_wrlvl_err,
output dbg_wrlvl_start,
output [ROW_WIDTH-1:0] ddr_addr, // From phy_top0 of phy_top.v
output [BANK_WIDTH-1:0] ddr_ba, // From phy_top0 of phy_top.v
output ddr_cas_n, // From phy_top0 of phy_top.v
output [CK_WIDTH-1:0] ddr_ck_n, // From phy_top0 of phy_top.v
output [CK_WIDTH-1:0] ddr_ck , // From phy_top0 of phy_top.v
output [CKE_WIDTH-1:0] ddr_cke, // From phy_top0 of phy_top.v
output [CS_WIDTH*nCS_PER_RANK-1:0] ddr_cs_n, // From phy_top0 of phy_top.v
output [DM_WIDTH-1:0] ddr_dm, // From phy_top0 of phy_top.v
output [ODT_WIDTH-1:0] ddr_odt, // From phy_top0 of phy_top.v
output ddr_ras_n, // From phy_top0 of phy_top.v
output ddr_reset_n, // From phy_top0 of phy_top.v
output ddr_parity,
output ddr_we_n, // From phy_top0 of phy_top.v
output init_calib_complete,
output init_wrcal_complete,
output [MC_ERR_ADDR_WIDTH-1:0] ecc_err_addr,
output [2*nCK_PER_CLK-1:0] ecc_multiple,
output [2*nCK_PER_CLK-1:0] ecc_single,
output wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] rd_data,
output [DATA_BUF_ADDR_WIDTH-1:0] rd_data_addr,
// From mc0 of mc.v
output rd_data_en, // From mc0 of mc.v
output rd_data_end, // From mc0 of mc.v
output [DATA_BUF_OFFSET_WIDTH-1:0] rd_data_offset, // From mc0 of mc.v
output [DATA_BUF_ADDR_WIDTH-1:0] wr_data_addr, // From mc0 of mc.v
output wr_data_en, // From mc0 of mc.v
output [DATA_BUF_OFFSET_WIDTH-1:0] wr_data_offset, // From mc0 of mc.v
inout [DQ_WIDTH-1:0] ddr_dq, // To/From phy_top0 of phy_top.v
inout [DQS_WIDTH-1:0] ddr_dqs_n, // To/From phy_top0 of phy_top.v
inout [DQS_WIDTH-1:0] ddr_dqs // To/From phy_top0 of phy_top.v
,input [11:0] device_temp
//phase shift clock control
,output psen
,output psincdec
,input psdone
,input [DQ_WIDTH/8-1:0] fi_xor_we
,input [DQ_WIDTH-1:0] fi_xor_wrdata
,input dbg_sel_pi_incdec
,input dbg_sel_po_incdec
,input [DQS_CNT_WIDTH:0] dbg_byte_sel
,input dbg_pi_f_inc
,input dbg_pi_f_dec
,input dbg_po_f_inc
,input dbg_po_f_stg23_sel
,input dbg_po_f_dec
,output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_tap_cnt
,output [5*DQS_WIDTH*RANKS-1:0] dbg_dq_idelay_tap_cnt
,output dbg_rddata_valid
,output [6*DQS_WIDTH-1:0] dbg_wrlvl_fine_tap_cnt
,output [3*DQS_WIDTH-1:0] dbg_wrlvl_coarse_tap_cnt
,output [255:0] dbg_phy_wrlvl
,output [5:0] dbg_pi_counter_read_val
,output [8:0] dbg_po_counter_read_val
,output ref_dll_lock
,input rst_phaser_ref
,input iddr_rst
,output [6*RANKS-1:0] dbg_rd_data_offset
,output [255:0] dbg_phy_init
,output [255:0] dbg_prbs_rdlvl
,output [255:0] dbg_dqs_found_cal
,output dbg_pi_phaselock_start
,output dbg_pi_phaselocked_done
,output dbg_pi_phaselock_err
,output dbg_pi_dqsfound_start
,output dbg_pi_dqsfound_done
,output dbg_pi_dqsfound_err
,output dbg_wrcal_start
,output dbg_wrcal_done
,output dbg_wrcal_err
,output [11:0] dbg_pi_dqs_found_lanes_phy4lanes
,output [11:0] dbg_pi_phase_locked_phy4lanes
,output [6*RANKS-1:0] dbg_calib_rd_data_offset_1
,output [6*RANKS-1:0] dbg_calib_rd_data_offset_2
,output [5:0] dbg_data_offset
,output [5:0] dbg_data_offset_1
,output [5:0] dbg_data_offset_2
,output dbg_oclkdelay_calib_start
,output dbg_oclkdelay_calib_done
,output [255:0] dbg_phy_oclkdelay_cal
,output [DRAM_WIDTH*16 -1:0]dbg_oclkdelay_rd_data
,output [6*DQS_WIDTH*RANKS-1:0] prbs_final_dqs_tap_cnt_r
,output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_first_edge_taps
,output [6*DQS_WIDTH*RANKS-1:0] dbg_prbs_second_edge_taps
);
localparam nSLOTS = 1 + (|SLOT_1_CONFIG ? 1 : 0);
localparam SLOT_0_CONFIG_MC = (nSLOTS == 2)? 8'b0000_0101 : 8'b0000_1111;
localparam SLOT_1_CONFIG_MC = (nSLOTS == 2)? 8'b0000_1010 : 8'b0000_0000;
// 8*tREFI in ps is divided by fabric clock period also in ps. 270 is the number
// of fabric clock cycles that accounts for the Writes, read, and PRECHARGE time
localparam REFRESH_TIMER = (8*tREFI/(tCK*nCK_PER_CLK)) - 270;
reg [7:0] slot_0_present_mc;
reg [7:0] slot_1_present_mc;
reg user_periodic_rd_req = 1'b0;
reg user_ref_req = 1'b0;
reg user_zq_req = 1'b0;
// MC/PHY interface
wire [nCK_PER_CLK-1:0] mc_ras_n;
wire [nCK_PER_CLK-1:0] mc_cas_n;
wire [nCK_PER_CLK-1:0] mc_we_n;
wire [nCK_PER_CLK*ROW_WIDTH-1:0] mc_address;
wire [nCK_PER_CLK*BANK_WIDTH-1:0] mc_bank;
wire [nCK_PER_CLK-1 :0] mc_cke ;
wire [1:0] mc_odt ;
wire [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] mc_cs_n;
wire mc_reset_n;
wire [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata;
wire [2*nCK_PER_CLK*DQ_WIDTH/8-1:0] mc_wrdata_mask;
wire mc_wrdata_en;
wire mc_ref_zq_wip;
wire tempmon_sample_en;
wire idle;
wire mc_cmd_wren;
wire mc_ctl_wren;
wire [2:0] mc_cmd;
wire [1:0] mc_cas_slot;
wire [5:0] mc_data_offset;
wire [5:0] mc_data_offset_1;
wire [5:0] mc_data_offset_2;
wire [3:0] mc_aux_out0;
wire [3:0] mc_aux_out1;
wire [1:0] mc_rank_cnt;
wire phy_mc_ctl_full;
wire phy_mc_cmd_full;
wire phy_mc_data_full;
wire [2*nCK_PER_CLK*DQ_WIDTH-1:0] phy_rd_data;
wire phy_rddata_valid;
wire [6*RANKS-1:0] calib_rd_data_offset_0;
wire [6*RANKS-1:0] calib_rd_data_offset_1;
wire [6*RANKS-1:0] calib_rd_data_offset_2;
wire init_calib_complete_w;
wire init_wrcal_complete_w;
wire mux_rst;
wire mux_calib_complete;
// assigning CWL = CL -1 for DDR2. DDR2 customers will not know anything
// about CWL. There is also nCWL parameter. Need to clean it up.
localparam CWL_T = (DRAM_TYPE == "DDR3") ? CWL : CL-1;
assign init_calib_complete = init_calib_complete_w;
assign init_wrcal_complete = init_wrcal_complete_w;
assign mux_calib_complete = (PRE_REV3ES == "OFF") ? init_calib_complete_w :
(init_calib_complete_w | init_wrcal_complete_w);
assign mux_rst = (PRE_REV3ES == "OFF") ? rst : reset;
assign dbg_calib_rd_data_offset_1 = calib_rd_data_offset_1;
assign dbg_calib_rd_data_offset_2 = calib_rd_data_offset_2;
assign dbg_data_offset = mc_data_offset;
assign dbg_data_offset_1 = mc_data_offset_1;
assign dbg_data_offset_2 = mc_data_offset_2;
// Enable / disable temperature monitoring
assign tempmon_sample_en = TEMP_MON_EN == "OFF" ? 1'b0 : mc_ref_zq_wip;
generate
if (nSLOTS == 1) begin: gen_single_slot_odt
always @ (slot_0_present or slot_1_present) begin
slot_0_present_mc = slot_0_present;
slot_1_present_mc = slot_1_present;
end
end else if (nSLOTS == 2) begin: gen_dual_slot_odt
always @ (slot_0_present[0] or slot_0_present[1]
or slot_1_present[0] or slot_1_present[1]) begin
case ({slot_0_present[0],slot_0_present[1],
slot_1_present[0],slot_1_present[1]})
//Two slot configuration, one slot present, single rank
4'b1000: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_0000;
end
4'b0010: begin
slot_0_present_mc = 8'b0000_0000;
slot_1_present_mc = 8'b0000_0010;
end
// Two slot configuration, one slot present, dual rank
4'b1100: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_0000;
end
4'b0011: begin
slot_0_present_mc = 8'b0000_0000;
slot_1_present_mc = 8'b0000_1010;
end
// Two slot configuration, one rank per slot
4'b1010: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_0010;
end
// Two Slots - One slot with dual rank and the other with single rank
4'b1011: begin
slot_0_present_mc = 8'b0000_0001;
slot_1_present_mc = 8'b0000_1010;
end
4'b1110: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_0010;
end
// Two Slots - two ranks per slot
4'b1111: begin
slot_0_present_mc = 8'b0000_0101;
slot_1_present_mc = 8'b0000_1010;
end
endcase
end
end
endgenerate
mig_7series_v2_3_mc #
(
.TCQ (TCQ),
.PAYLOAD_WIDTH (PAYLOAD_WIDTH),
.MC_ERR_ADDR_WIDTH (MC_ERR_ADDR_WIDTH),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BANK_WIDTH (BANK_WIDTH),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.BURST_MODE (BURST_MODE),
.COL_WIDTH (COL_WIDTH),
.CMD_PIPE_PLUS1 (CMD_PIPE_PLUS1),
.CS_WIDTH (CS_WIDTH),
.DATA_WIDTH (DATA_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DATA_BUF_OFFSET_WIDTH (DATA_BUF_OFFSET_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.CKE_ODT_AUX (CKE_ODT_AUX),
.DQS_WIDTH (DQS_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.ECC (ECC),
.ECC_WIDTH (ECC_WIDTH),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nSLOTS (nSLOTS),
.CL (CL),
.nCS_PER_RANK (nCS_PER_RANK),
.CWL (CWL_T),
.ORDERING (ORDERING),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.STARVE_LIMIT (STARVE_LIMIT),
.SLOT_0_CONFIG (SLOT_0_CONFIG_MC),
.SLOT_1_CONFIG (SLOT_1_CONFIG_MC),
.tCK (tCK),
.tCKE (tCKE),
.tFAW (tFAW),
.tRAS (tRAS),
.tRCD (tRCD),
.tREFI (tREFI),
.tRFC (tRFC),
.tRP (tRP),
.tRRD (tRRD),
.tRTP (tRTP),
.tWTR (tWTR),
.tZQI (tZQI),
.tZQCS (tZQCS),
.tPRDI (tPRDI),
.USER_REFRESH (USER_REFRESH))
mc0
(.app_periodic_rd_req (1'b0),
.app_sr_req (app_sr_req),
.app_sr_active (app_sr_active),
.app_ref_req (app_ref_req),
.app_ref_ack (app_ref_ack),
.app_zq_req (app_zq_req),
.app_zq_ack (app_zq_ack),
.ecc_single (ecc_single),
.ecc_multiple (ecc_multiple),
.ecc_err_addr (ecc_err_addr),
.mc_address (mc_address),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_bank (mc_bank),
.mc_cke (mc_cke),
.mc_odt (mc_odt),
.mc_cas_n (mc_cas_n),
.mc_cmd (mc_cmd),
.mc_cmd_wren (mc_cmd_wren),
.mc_cs_n (mc_cs_n),
.mc_ctl_wren (mc_ctl_wren),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_cas_slot (mc_cas_slot),
.mc_rank_cnt (mc_rank_cnt),
.mc_ras_n (mc_ras_n),
.mc_reset_n (mc_reset_n),
.mc_we_n (mc_we_n),
.mc_wrdata (mc_wrdata),
.mc_wrdata_en (mc_wrdata_en),
.mc_wrdata_mask (mc_wrdata_mask),
// Outputs
.accept (accept),
.accept_ns (accept_ns),
.bank_mach_next (bank_mach_next[BM_CNT_WIDTH-1:0]),
.rd_data_addr (rd_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.rd_data_en (rd_data_en),
.rd_data_end (rd_data_end),
.rd_data_offset (rd_data_offset),
.wr_data_addr (wr_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.wr_data_en (wr_data_en),
.wr_data_offset (wr_data_offset),
.rd_data (rd_data),
.wr_data (wr_data),
.wr_data_mask (wr_data_mask),
.mc_read_idle (idle),
.mc_ref_zq_wip (mc_ref_zq_wip),
// Inputs
.init_calib_complete (mux_calib_complete),
.calib_rd_data_offset (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_data_full (phy_mc_data_full),
.phy_rd_data (phy_rd_data),
.phy_rddata_valid (phy_rddata_valid),
.correct_en (correct_en),
.bank (bank[BANK_WIDTH-1:0]),
.clk (clk),
.cmd (cmd[2:0]),
.col (col[COL_WIDTH-1:0]),
.data_buf_addr (data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.hi_priority (hi_priority),
.rank (rank[RANK_WIDTH-1:0]),
.raw_not_ecc (raw_not_ecc[2*nCK_PER_CLK-1 :0]),
.row (row[ROW_WIDTH-1:0]),
.rst (mux_rst),
.size (size),
.slot_0_present (slot_0_present_mc[7:0]),
.slot_1_present (slot_1_present_mc[7:0]),
.fi_xor_we (fi_xor_we),
.fi_xor_wrdata (fi_xor_wrdata),
.use_addr (use_addr));
// following calculations should be moved inside PHY
// odt bus should be added to PHY.
localparam CLK_PERIOD = tCK * nCK_PER_CLK;
localparam nCL = CL;
localparam nCWL = CWL_T;
`ifdef MC_SVA
ddr2_improper_CL: assert property
(@(posedge clk) (~((DRAM_TYPE == "DDR2") && ((CL > 6) || (CL < 3)))));
// Not needed after the CWL fix for DDR2
// ddr2_improper_CWL: assert property
// (@(posedge clk) (~((DRAM_TYPE == "DDR2") && ((CL - CWL) != 1))));
`endif
mig_7series_v2_3_ddr_phy_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.REFCLK_FREQ (REFCLK_FREQ),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.CA_MIRROR (CA_MIRROR),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.nCS_PER_RANK (nCS_PER_RANK),
.CS_WIDTH (CS_WIDTH),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.CKE_WIDTH (CKE_WIDTH),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.DRAM_TYPE (DRAM_TYPE),
.BANK_WIDTH (BANK_WIDTH),
.CK_WIDTH (CK_WIDTH),
.COL_WIDTH (COL_WIDTH),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.ROW_WIDTH (ROW_WIDTH),
.AL (AL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.CL (nCL),
.CWL (nCWL),
.tRFC (tRFC),
.tREFI (tREFI),
.tCK (tCK),
.OUTPUT_DRV (OUTPUT_DRV),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.WRLVL (WRLVL),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
// Prevent the following simulation-related parameters from
// being overridden for synthesis - for synthesis only the
// default values of these parameters should be used
// synthesis translate_off
.SIM_BYPASS_INIT_CAL (SIM_BYPASS_INIT_CAL),
// synthesis translate_on
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK)
)
ddr_phy_top0
(
// Outputs
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.ddr_ck (ddr_ck),
.ddr_ck_n (ddr_ck_n),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_ras_n (ddr_ras_n),
.ddr_cas_n (ddr_cas_n),
.ddr_we_n (ddr_we_n),
.ddr_cs_n (ddr_cs_n),
.ddr_cke (ddr_cke),
.ddr_odt (ddr_odt),
.ddr_reset_n (ddr_reset_n),
.ddr_parity (ddr_parity),
.ddr_dm (ddr_dm),
.dbg_calib_top (dbg_calib_top),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_rddata (dbg_rddata),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.init_calib_complete (init_calib_complete_w),
.init_wrcal_complete (init_wrcal_complete_w),
.mc_address (mc_address),
.mc_aux_out0 (mc_aux_out0),
.mc_aux_out1 (mc_aux_out1),
.mc_bank (mc_bank),
.mc_cke (mc_cke),
.mc_odt (mc_odt),
.mc_cas_n (mc_cas_n),
.mc_cmd (mc_cmd),
.mc_cmd_wren (mc_cmd_wren),
.mc_cas_slot (mc_cas_slot),
.mc_cs_n (mc_cs_n),
.mc_ctl_wren (mc_ctl_wren),
.mc_data_offset (mc_data_offset),
.mc_data_offset_1 (mc_data_offset_1),
.mc_data_offset_2 (mc_data_offset_2),
.mc_rank_cnt (mc_rank_cnt),
.mc_ras_n (mc_ras_n),
.mc_reset_n (mc_reset_n),
.mc_we_n (mc_we_n),
.mc_wrdata (mc_wrdata),
.mc_wrdata_en (mc_wrdata_en),
.mc_wrdata_mask (mc_wrdata_mask),
.idle (idle),
.mem_refclk (mem_refclk),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_data_full (phy_mc_data_full),
.phy_rd_data (phy_rd_data),
.phy_rddata_valid (phy_rddata_valid),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
// Inouts
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_dq (ddr_dq),
// Inputs
.clk_ref (clk_ref),
.freq_refclk (freq_refclk),
.clk (clk),
.mmcm_ps_clk (mmcm_ps_clk),
.poc_sample_pd (poc_sample_pd),
.rst (rst),
.error (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt)
,.device_temp (device_temp)
,.tempmon_sample_en (tempmon_sample_en)
,.psen (psen)
,.psincdec (psincdec)
,.psdone (psdone)
,.dbg_sel_pi_incdec (dbg_sel_pi_incdec)
,.dbg_sel_po_incdec (dbg_sel_po_incdec)
,.dbg_byte_sel (dbg_byte_sel)
,.dbg_pi_f_inc (dbg_pi_f_inc)
,.dbg_po_f_inc (dbg_po_f_inc)
,.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel)
,.dbg_pi_f_dec (dbg_pi_f_dec)
,.dbg_po_f_dec (dbg_po_f_dec)
,.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt)
,.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt)
,.dbg_rddata_valid (dbg_rddata_valid)
,.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt)
,.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt)
,.dbg_phy_wrlvl (dbg_phy_wrlvl)
,.ref_dll_lock (ref_dll_lock)
,.rst_phaser_ref (rst_phaser_ref)
,.iddr_rst (iddr_rst)
,.dbg_rd_data_offset (dbg_rd_data_offset)
,.dbg_phy_init (dbg_phy_init)
,.dbg_prbs_rdlvl (dbg_prbs_rdlvl)
,.dbg_dqs_found_cal (dbg_dqs_found_cal)
,.dbg_po_counter_read_val (dbg_po_counter_read_val)
,.dbg_pi_counter_read_val (dbg_pi_counter_read_val)
,.dbg_pi_phaselock_start (dbg_pi_phaselock_start)
,.dbg_pi_phaselocked_done (dbg_pi_phaselocked_done)
,.dbg_pi_phaselock_err (dbg_pi_phaselock_err)
,.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start)
,.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done)
,.dbg_pi_dqsfound_err (dbg_pi_dqsfound_err)
,.dbg_wrcal_start (dbg_wrcal_start)
,.dbg_wrcal_done (dbg_wrcal_done)
,.dbg_wrcal_err (dbg_wrcal_err)
,.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal)
,.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data)
,.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start)
,.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done)
,.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r)
,.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps)
,.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps)
);
endmodule
|
module mig_7series_v2_3_ddr_prbs_gen #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter PRBS_WIDTH = 64, // LFSR shift register length
parameter DQS_CNT_WIDTH = 5,
parameter DQ_WIDTH = 72,
parameter VCCO_PAT_EN = 1,
parameter VCCAUX_PAT_EN = 1,
parameter ISI_PAT_EN = 1,
parameter FIXED_VICTIM = "TRUE"
)
(
input clk_i, // input clock
input clk_en_i, // clock enable
input rst_i, // synchronous reset
input [PRBS_WIDTH-1:0] prbs_seed_i, // initial LFSR seed
input phy_if_empty, // IN_FIFO empty flag
input prbs_rdlvl_start, // PRBS read lveling start
input prbs_rdlvl_done,
input complex_wr_done,
input [2:0] victim_sel,
input [DQS_CNT_WIDTH:0] byte_cnt,
//output [PRBS_WIDTH-1:0] prbs_o // generated pseudo random data
output [8*DQ_WIDTH-1:0] prbs_o,
output [9:0] dbg_prbs_gen,
input reset_rd_addr,
output prbs_ignore_first_byte,
output prbs_ignore_last_bytes
);
//***************************************************************************
function integer clogb2 (input integer size);
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction
// Number of internal clock cycles before the PRBS sequence will repeat
localparam PRBS_SEQ_LEN_CYCLES = 128;
localparam PRBS_SEQ_LEN_CYCLES_BITS = clogb2(PRBS_SEQ_LEN_CYCLES);
reg phy_if_empty_r;
reg reseed_prbs_r;
reg [PRBS_SEQ_LEN_CYCLES_BITS-1:0] sample_cnt_r;
reg [PRBS_WIDTH - 1 :0] prbs;
reg [PRBS_WIDTH :1] lfsr_q;
//***************************************************************************
always @(posedge clk_i) begin
phy_if_empty_r <= #TCQ phy_if_empty;
end
//***************************************************************************
// Generate PRBS reset signal to ensure that PRBS sequence repeats after
// every 2**PRBS_WIDTH samples. Basically what happens is that we let the
// LFSR run for an extra cycle after "truly PRBS" 2**PRBS_WIDTH - 1
// samples have past. Once that extra cycle is finished, we reseed the LFSR
always @(posedge clk_i)
begin
if (rst_i || ~clk_en_i) begin
sample_cnt_r <= #TCQ 'b0;
reseed_prbs_r <= #TCQ 1'b0;
end else if (clk_en_i && (~phy_if_empty_r || ~prbs_rdlvl_start)) begin
// The rollver count should always be [(power of 2) - 1]
sample_cnt_r <= #TCQ sample_cnt_r + 1;
// Assert PRBS reset signal so that it is simultaneously with the
// last sample of the sequence
if (sample_cnt_r == PRBS_SEQ_LEN_CYCLES - 2)
reseed_prbs_r <= #TCQ 1'b1;
else
reseed_prbs_r <= #TCQ 1'b0;
end
end
always @ (posedge clk_i)
begin
//reset it to a known good state to prevent it locks up
if ((reseed_prbs_r && clk_en_i) || rst_i || ~clk_en_i) begin
lfsr_q[4:1] <= #TCQ prbs_seed_i[3:0] | 4'h5;
lfsr_q[PRBS_WIDTH:5] <= #TCQ prbs_seed_i[PRBS_WIDTH-1:4];
end
else if (clk_en_i && (~phy_if_empty_r || ~prbs_rdlvl_start)) begin
lfsr_q[PRBS_WIDTH:31] <= #TCQ lfsr_q[PRBS_WIDTH-1:30];
lfsr_q[30] <= #TCQ lfsr_q[16] ^ lfsr_q[13] ^ lfsr_q[5] ^ lfsr_q[1];
lfsr_q[29:9] <= #TCQ lfsr_q[28:8];
lfsr_q[8] <= #TCQ lfsr_q[32] ^ lfsr_q[7];
lfsr_q[7] <= #TCQ lfsr_q[32] ^ lfsr_q[6];
lfsr_q[6:4] <= #TCQ lfsr_q[5:3];
lfsr_q[3] <= #TCQ lfsr_q[32] ^ lfsr_q[2];
lfsr_q[2] <= #TCQ lfsr_q[1] ;
lfsr_q[1] <= #TCQ lfsr_q[32];
end
end
always @ (lfsr_q[PRBS_WIDTH:1]) begin
prbs = lfsr_q[PRBS_WIDTH:1];
end
//******************************************************************************
// Complex pattern BRAM
//******************************************************************************
localparam BRAM_ADDR_WIDTH = 8;
localparam BRAM_DATA_WIDTH = 18;
localparam BRAM_DEPTH = 256;
integer i;
(* RAM_STYLE = "distributed" *) reg [BRAM_ADDR_WIDTH - 1:0] rd_addr;
//reg [BRAM_DATA_WIDTH - 1:0] mem[0:BRAM_DEPTH - 1];
reg [BRAM_DATA_WIDTH - 1:0] mem_out;
reg [BRAM_DATA_WIDTH - 3:0] dout_o;
reg [DQ_WIDTH-1:0] sel;
reg [DQ_WIDTH-1:0] dout_rise0;
reg [DQ_WIDTH-1:0] dout_fall0;
reg [DQ_WIDTH-1:0] dout_rise1;
reg [DQ_WIDTH-1:0] dout_fall1;
reg [DQ_WIDTH-1:0] dout_rise2;
reg [DQ_WIDTH-1:0] dout_fall2;
reg [DQ_WIDTH-1:0] dout_rise3;
reg [DQ_WIDTH-1:0] dout_fall3;
// VCCO noise injection pattern with matching victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
always @ (rd_addr) begin
case (rd_addr)
8'd0 : mem_out = {2'b11, 8'b10101010,8'b10101010}; //1 read
8'd1 : mem_out = {2'b01, 8'b11001100,8'b11001100}; //2 reads
8'd2 : mem_out = {2'b10, 8'b11001100,8'b11001100}; //2 reads
8'd3 : mem_out = {2'b01, 8'b11100011,8'b11100011}; //3 reads
8'd4 : mem_out = {2'b00, 8'b10001110,8'b10001110}; //3 reads
8'd5 : mem_out = {2'b10, 8'b00111000,8'b00111000}; //3 reads
8'd6 : mem_out = {2'b01, 8'b11110000,8'b11110000}; //4 reads
8'd7 : mem_out = {2'b00, 8'b11110000,8'b11110000}; //4 reads
8'd8 : mem_out = {2'b00, 8'b11110000,8'b11110000}; //4 reads
8'd9 : mem_out = {2'b10, 8'b11110000,8'b11110000}; //4 reads
8'd10 : mem_out = {2'b01, 8'b11111000,8'b11111000}; //5 reads
8'd11 : mem_out = {2'b00, 8'b00111110,8'b00111110}; //5 reads
8'd12 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //5 reads
8'd13 : mem_out = {2'b00, 8'b10000011,8'b10000011}; //5 reads
8'd14 : mem_out = {2'b10, 8'b11100000,8'b11100000}; //5 reads
8'd15 : mem_out = {2'b01, 8'b11111100,8'b11111100}; //6 reads
8'd16 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //6 reads
8'd17 : mem_out = {2'b00, 8'b11000000,8'b11000000}; //6 reads
8'd18 : mem_out = {2'b00, 8'b11111100,8'b11111100}; //6 reads
8'd19 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //6 reads
8'd20 : mem_out = {2'b10, 8'b11000000,8'b11000000}; //6 reads
// VCCO noise injection pattern with non-matching victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
8'd21 : mem_out = {2'b11, 8'b10101010,8'b01010101}; //1 read
8'd22 : mem_out = {2'b01, 8'b11001100,8'b00110011}; //2 reads
8'd23 : mem_out = {2'b10, 8'b11001100,8'b00110011}; //2 reads
8'd24 : mem_out = {2'b01, 8'b11100011,8'b00011100}; //3 reads
8'd25 : mem_out = {2'b00, 8'b10001110,8'b01110001}; //3 reads
8'd26 : mem_out = {2'b10, 8'b00111000,8'b11000111}; //3 reads
8'd27 : mem_out = {2'b01, 8'b11110000,8'b00001111}; //4 reads
8'd28 : mem_out = {2'b00, 8'b11110000,8'b00001111}; //4 reads
8'd29 : mem_out = {2'b00, 8'b11110000,8'b00001111}; //4 reads
8'd30 : mem_out = {2'b10, 8'b11110000,8'b00001111}; //4 reads
8'd31 : mem_out = {2'b01, 8'b11111000,8'b00000111}; //5 reads
8'd32 : mem_out = {2'b00, 8'b00111110,8'b11000001}; //5 reads
8'd33 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //5 reads
8'd34 : mem_out = {2'b00, 8'b10000011,8'b01111100}; //5 reads
8'd35 : mem_out = {2'b10, 8'b11100000,8'b00011111}; //5 reads
8'd36 : mem_out = {2'b01, 8'b11111100,8'b00000011}; //6 reads
8'd37 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //6 reads
8'd38 : mem_out = {2'b00, 8'b11000000,8'b00111111}; //6 reads
8'd39 : mem_out = {2'b00, 8'b11111100,8'b00000011}; //6 reads
8'd40 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //6 reads
8'd41 : mem_out = {2'b10, 8'b11000000,8'b00111111}; //6 reads
// VCCAUX noise injection pattern with ISI pattern on victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
8'd42 : mem_out = {2'b01, 8'b10110100,8'b01010111}; //3 reads
8'd43 : mem_out = {2'b00, 8'b10110100,8'b01101111}; //3 reads
8'd44 : mem_out = {2'b10, 8'b10110100,8'b11000000}; //3 reads
8'd45 : mem_out = {2'b01, 8'b10100010,8'b10000100}; //4 reads
8'd46 : mem_out = {2'b00, 8'b10001010,8'b00110001}; //4 reads
8'd47 : mem_out = {2'b00, 8'b00101000,8'b01000111}; //4 reads
8'd48 : mem_out = {2'b10, 8'b10100010,8'b00100101}; //4 reads
8'd49 : mem_out = {2'b01, 8'b10101111,8'b10011010}; //5 reads
8'd50 : mem_out = {2'b00, 8'b01010000,8'b01111010}; //5 reads
8'd51 : mem_out = {2'b00, 8'b10101111,8'b10010101}; //5 reads
8'd52 : mem_out = {2'b00, 8'b01010000,8'b11011011}; //5 reads
8'd53 : mem_out = {2'b10, 8'b10101111,8'b11110000}; //5 reads
8'd54 : mem_out = {2'b01, 8'b10101000,8'b00100001}; //7 reads
8'd55 : mem_out = {2'b00, 8'b00101010,8'b10001010}; //7 reads
8'd56 : mem_out = {2'b00, 8'b00001010,8'b00100101}; //7 reads
8'd57 : mem_out = {2'b00, 8'b10000010,8'b10011010}; //7 reads
8'd58 : mem_out = {2'b00, 8'b10100000,8'b01111010}; //7 reads
8'd59 : mem_out = {2'b00, 8'b10101000,8'b10111111}; //7 reads
8'd60 : mem_out = {2'b10, 8'b00101010,8'b01010111}; //7 reads
8'd61 : mem_out = {2'b01, 8'b10101011,8'b01101111}; //8 reads
8'd62 : mem_out = {2'b00, 8'b11110101,8'b11000000}; //8 reads
8'd63 : mem_out = {2'b00, 8'b01000000,8'b10000100}; //8 reads
8'd64 : mem_out = {2'b00, 8'b10101011,8'b00110001}; //8 reads
8'd65 : mem_out = {2'b00, 8'b11110101,8'b01000111}; //8 reads
8'd66 : mem_out = {2'b00, 8'b01000000,8'b00100101}; //8 reads
8'd67 : mem_out = {2'b00, 8'b10101011,8'b10011010}; //8 reads
8'd68 : mem_out = {2'b10, 8'b11110101,8'b01111010}; //8 reads
8'd69 : mem_out = {2'b01, 8'b10101010,8'b10010101}; //9 reads
8'd70 : mem_out = {2'b00, 8'b00000010,8'b11011011}; //9 reads
8'd71 : mem_out = {2'b00, 8'b10101000,8'b11110000}; //9 reads
8'd72 : mem_out = {2'b00, 8'b00001010,8'b00100001}; //9 reads
8'd73 : mem_out = {2'b00, 8'b10100000,8'b10001010}; //9 reads
8'd74 : mem_out = {2'b00, 8'b00101010,8'b00100101}; //9 reads
8'd75 : mem_out = {2'b00, 8'b10000000,8'b10011010}; //9 reads
8'd76 : mem_out = {2'b00, 8'b10101010,8'b01111010}; //9 reads
8'd77 : mem_out = {2'b10, 8'b00000010,8'b10111111}; //9 reads
8'd78 : mem_out = {2'b01, 8'b10101010,8'b01010111}; //10 reads
8'd79 : mem_out = {2'b00, 8'b11111111,8'b01101111}; //10 reads
8'd80 : mem_out = {2'b00, 8'b01010101,8'b11000000}; //10 reads
8'd81 : mem_out = {2'b00, 8'b00000000,8'b10000100}; //10 reads
8'd82 : mem_out = {2'b00, 8'b10101010,8'b00110001}; //10 reads
8'd83 : mem_out = {2'b00, 8'b11111111,8'b01000111}; //10 reads
8'd84 : mem_out = {2'b00, 8'b01010101,8'b00100101}; //10 reads
8'd85 : mem_out = {2'b00, 8'b00000000,8'b10011010}; //10 reads
8'd86 : mem_out = {2'b00, 8'b10101010,8'b01111010}; //10 reads
8'd87 : mem_out = {2'b10, 8'b11111111,8'b10010101}; //10 reads
8'd88 : mem_out = {2'b01, 8'b10101010,8'b11011011}; //12 reads
8'd89 : mem_out = {2'b00, 8'b10000000,8'b11110000}; //12 reads
8'd90 : mem_out = {2'b00, 8'b00101010,8'b00100001}; //12 reads
8'd91 : mem_out = {2'b00, 8'b10100000,8'b10001010}; //12 reads
8'd92 : mem_out = {2'b00, 8'b00001010,8'b00100101}; //12 reads
8'd93 : mem_out = {2'b00, 8'b10101000,8'b10011010}; //12 reads
8'd94 : mem_out = {2'b00, 8'b00000010,8'b01111010}; //12 reads
8'd95 : mem_out = {2'b00, 8'b10101010,8'b10111111}; //12 reads
8'd96 : mem_out = {2'b00, 8'b00000000,8'b01010111}; //12 reads
8'd97 : mem_out = {2'b00, 8'b10101010,8'b01101111}; //12 reads
8'd98 : mem_out = {2'b00, 8'b10000000,8'b11000000}; //12 reads
8'd99 : mem_out = {2'b10, 8'b00101010,8'b10000100}; //12 reads
8'd100 : mem_out = {2'b01, 8'b10101010,8'b00110001}; //13 reads
8'd101 : mem_out = {2'b00, 8'b10111111,8'b01000111}; //13 reads
8'd102 : mem_out = {2'b00, 8'b11110101,8'b00100101}; //13 reads
8'd103 : mem_out = {2'b00, 8'b01010100,8'b10011010}; //13 reads
8'd104 : mem_out = {2'b00, 8'b00000000,8'b01111010}; //13 reads
8'd105 : mem_out = {2'b00, 8'b10101010,8'b10010101}; //13 reads
8'd106 : mem_out = {2'b00, 8'b10111111,8'b11011011}; //13 reads
8'd107 : mem_out = {2'b00, 8'b11110101,8'b11110000}; //13 reads
8'd108 : mem_out = {2'b00, 8'b01010100,8'b00100001}; //13 reads
8'd109 : mem_out = {2'b00, 8'b00000000,8'b10001010}; //13 reads
8'd110 : mem_out = {2'b00, 8'b10101010,8'b00100101}; //13 reads
8'd111 : mem_out = {2'b00, 8'b10111111,8'b10011010}; //13 reads
8'd112 : mem_out = {2'b10, 8'b11110101,8'b01111010}; //13 reads
8'd113 : mem_out = {2'b01, 8'b10101010,8'b10111111}; //14 reads
8'd114 : mem_out = {2'b00, 8'b10100000,8'b01010111}; //14 reads
8'd115 : mem_out = {2'b00, 8'b00000010,8'b01101111}; //14 reads
8'd116 : mem_out = {2'b00, 8'b10101010,8'b11000000}; //14 reads
8'd117 : mem_out = {2'b00, 8'b10000000,8'b10000100}; //14 reads
8'd118 : mem_out = {2'b00, 8'b00001010,8'b00110001}; //14 reads
8'd119 : mem_out = {2'b00, 8'b10101010,8'b01000111}; //14 reads
8'd120 : mem_out = {2'b00, 8'b00000000,8'b00100101}; //14 reads
8'd121 : mem_out = {2'b00, 8'b00101010,8'b10011010}; //14 reads
8'd122 : mem_out = {2'b00, 8'b10101000,8'b01111010}; //14 reads
8'd123 : mem_out = {2'b00, 8'b00000000,8'b10010101}; //14 reads
8'd124 : mem_out = {2'b00, 8'b10101010,8'b11011011}; //14 reads
8'd125 : mem_out = {2'b00, 8'b10100000,8'b11110000}; //14 reads
8'd126 : mem_out = {2'b10, 8'b00000010,8'b00100001}; //14 reads
// ISI pattern (Back-to-back reads)
// content format
// {aggressor pattern, victim pattern}
8'd127 : mem_out = {2'b01, 8'b01010111,8'b01010111};
8'd128 : mem_out = {2'b00, 8'b01101111,8'b01101111};
8'd129 : mem_out = {2'b00, 8'b11000000,8'b11000000};
8'd130 : mem_out = {2'b00, 8'b10000110,8'b10000100};
8'd131 : mem_out = {2'b00, 8'b00101000,8'b00110001};
8'd132 : mem_out = {2'b00, 8'b11100100,8'b01000111};
8'd133 : mem_out = {2'b00, 8'b10110011,8'b00100101};
8'd134 : mem_out = {2'b00, 8'b01001111,8'b10011011};
8'd135 : mem_out = {2'b00, 8'b10110101,8'b01010101};
8'd136 : mem_out = {2'b00, 8'b10110101,8'b01010101};
8'd137 : mem_out = {2'b00, 8'b10000111,8'b10011000};
8'd138 : mem_out = {2'b00, 8'b11100011,8'b00011100};
8'd139 : mem_out = {2'b00, 8'b00001010,8'b11110101};
8'd140 : mem_out = {2'b00, 8'b11010100,8'b00101011};
8'd141 : mem_out = {2'b00, 8'b01001000,8'b10110111};
8'd142 : mem_out = {2'b00, 8'b00011111,8'b11100000};
8'd143 : mem_out = {2'b00, 8'b10111100,8'b01000011};
8'd144 : mem_out = {2'b00, 8'b10001111,8'b00010100};
8'd145 : mem_out = {2'b00, 8'b10110100,8'b01001011};
8'd146 : mem_out = {2'b00, 8'b11001011,8'b00110100};
8'd147 : mem_out = {2'b00, 8'b00001010,8'b11110101};
8'd148 : mem_out = {2'b00, 8'b10000000,8'b00000000};
//Additional for ISI
8'd149 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd150 : mem_out = {2'b00, 8'b01010101,8'b01010101};
8'd151 : mem_out = {2'b00, 8'b01010101,8'b01010101};
8'd152 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd153 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd154 : mem_out = {2'b00, 8'b01010101,8'b00101010};
8'd155 : mem_out = {2'b00, 8'b01010101,8'b10101010};
8'd156 : mem_out = {2'b10, 8'b00000000,8'b10000000};
//Available
8'd157 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd158 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd159 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd160 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd161 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd162 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd163 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd164 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd165 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd166 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd167 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd168 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd169 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd170 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd171 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd172 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd173 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd174 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd175 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd176 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd177 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd178 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd179 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd180 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd181 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd182 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd183 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd184 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd185 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd186 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd187 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd188 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd189 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd190 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd191 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd192 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd193 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd194 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd195 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd196 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd197 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd198 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd199 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd200 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd201 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd202 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd203 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd204 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd205 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd206 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd207 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd208 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd209 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd210 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd211 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd212 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd213 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd214 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd215 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd216 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd217 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd218 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd219 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd220 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd221 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd222 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd223 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd224 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd225 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd226 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd227 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd228 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd229 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd230 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd231 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd232 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd233 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd234 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd235 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd236 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd237 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd238 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd239 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd240 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd241 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd242 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd243 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd244 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd245 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd246 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd247 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd248 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd249 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd250 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd251 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd252 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd253 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd254 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd255 : mem_out = {2'b00, 8'b00000001,8'b00000001};
endcase
end
always @ (posedge clk_i) begin
if (rst_i | reset_rd_addr)
rd_addr <= #TCQ 'b0;
//rd_addr for complex oclkdelay calib
else if (clk_en_i && prbs_rdlvl_done && (~phy_if_empty_r || ~complex_wr_done)) begin
if (rd_addr == 'd156) rd_addr <= #TCQ 'b0;
else rd_addr <= #TCQ rd_addr + 1;
end
//rd_addr for complex rdlvl
else if (clk_en_i && (~phy_if_empty_r || (~prbs_rdlvl_start && ~complex_wr_done))) begin
if (rd_addr == 'd148) rd_addr <= #TCQ 'b0;
else rd_addr <= #TCQ rd_addr+1;
end
end
// Each pattern can be disabled independently
// When disabled zeros are written to and read from the DRAM
always @ (posedge clk_i) begin
if ((rd_addr < 42) && VCCO_PAT_EN)
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else if ((rd_addr < 127) && VCCAUX_PAT_EN)
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else if (ISI_PAT_EN && (rd_addr > 126))
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else
dout_o <= #TCQ 'd0;
end
reg prbs_ignore_first_byte_r;
always @(posedge clk_i) prbs_ignore_first_byte_r <= #TCQ mem_out[16];
assign prbs_ignore_first_byte = prbs_ignore_first_byte_r;
reg prbs_ignore_last_bytes_r;
always @(posedge clk_i) prbs_ignore_last_bytes_r <= #TCQ mem_out[17];
assign prbs_ignore_last_bytes = prbs_ignore_last_bytes_r;
generate
if (FIXED_VICTIM == "TRUE") begin: victim_sel_fixed
// Fixed victim bit 3
always @(posedge clk_i)
sel <= #TCQ {DQ_WIDTH/8{8'h08}};
end else begin: victim_sel_rotate
// One-hot victim select
always @(posedge clk_i)
if (rst_i)
sel <= #TCQ 'd0;
else begin
for (i = 0; i < DQ_WIDTH; i = i+1) begin
if (i == byte_cnt*8+victim_sel)
sel[i] <= #TCQ 1'b1;
else
sel[i] <= #TCQ 1'b0;
end
end
end
endgenerate
// construct 8 X DATA_WIDTH output bus
always @(*)
for (i = 0; i < DQ_WIDTH; i = i+1) begin
dout_rise0[i] = (dout_o[7]&&sel[i] || dout_o[15]&&~sel[i]);
dout_fall0[i] = (dout_o[6]&&sel[i] || dout_o[14]&&~sel[i]);
dout_rise1[i] = (dout_o[5]&&sel[i] || dout_o[13]&&~sel[i]);
dout_fall1[i] = (dout_o[4]&&sel[i] || dout_o[12]&&~sel[i]);
dout_rise2[i] = (dout_o[3]&&sel[i] || dout_o[11]&&~sel[i]);
dout_fall2[i] = (dout_o[2]&&sel[i] || dout_o[10]&&~sel[i]);
dout_rise3[i] = (dout_o[1]&&sel[i] || dout_o[9]&&~sel[i]);
dout_fall3[i] = (dout_o[0]&&sel[i] || dout_o[8]&&~sel[i]);
end
assign prbs_o = {dout_fall3, dout_rise3, dout_fall2, dout_rise2, dout_fall1, dout_rise1, dout_fall0, dout_rise0};
assign dbg_prbs_gen[9] = phy_if_empty_r;
assign dbg_prbs_gen[8] = clk_en_i;
assign dbg_prbs_gen[7:0] = rd_addr[7:0];
endmodule
|
module mig_7series_v2_3_ddr_prbs_gen #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter PRBS_WIDTH = 64, // LFSR shift register length
parameter DQS_CNT_WIDTH = 5,
parameter DQ_WIDTH = 72,
parameter VCCO_PAT_EN = 1,
parameter VCCAUX_PAT_EN = 1,
parameter ISI_PAT_EN = 1,
parameter FIXED_VICTIM = "TRUE"
)
(
input clk_i, // input clock
input clk_en_i, // clock enable
input rst_i, // synchronous reset
input [PRBS_WIDTH-1:0] prbs_seed_i, // initial LFSR seed
input phy_if_empty, // IN_FIFO empty flag
input prbs_rdlvl_start, // PRBS read lveling start
input prbs_rdlvl_done,
input complex_wr_done,
input [2:0] victim_sel,
input [DQS_CNT_WIDTH:0] byte_cnt,
//output [PRBS_WIDTH-1:0] prbs_o // generated pseudo random data
output [8*DQ_WIDTH-1:0] prbs_o,
output [9:0] dbg_prbs_gen,
input reset_rd_addr,
output prbs_ignore_first_byte,
output prbs_ignore_last_bytes
);
//***************************************************************************
function integer clogb2 (input integer size);
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction
// Number of internal clock cycles before the PRBS sequence will repeat
localparam PRBS_SEQ_LEN_CYCLES = 128;
localparam PRBS_SEQ_LEN_CYCLES_BITS = clogb2(PRBS_SEQ_LEN_CYCLES);
reg phy_if_empty_r;
reg reseed_prbs_r;
reg [PRBS_SEQ_LEN_CYCLES_BITS-1:0] sample_cnt_r;
reg [PRBS_WIDTH - 1 :0] prbs;
reg [PRBS_WIDTH :1] lfsr_q;
//***************************************************************************
always @(posedge clk_i) begin
phy_if_empty_r <= #TCQ phy_if_empty;
end
//***************************************************************************
// Generate PRBS reset signal to ensure that PRBS sequence repeats after
// every 2**PRBS_WIDTH samples. Basically what happens is that we let the
// LFSR run for an extra cycle after "truly PRBS" 2**PRBS_WIDTH - 1
// samples have past. Once that extra cycle is finished, we reseed the LFSR
always @(posedge clk_i)
begin
if (rst_i || ~clk_en_i) begin
sample_cnt_r <= #TCQ 'b0;
reseed_prbs_r <= #TCQ 1'b0;
end else if (clk_en_i && (~phy_if_empty_r || ~prbs_rdlvl_start)) begin
// The rollver count should always be [(power of 2) - 1]
sample_cnt_r <= #TCQ sample_cnt_r + 1;
// Assert PRBS reset signal so that it is simultaneously with the
// last sample of the sequence
if (sample_cnt_r == PRBS_SEQ_LEN_CYCLES - 2)
reseed_prbs_r <= #TCQ 1'b1;
else
reseed_prbs_r <= #TCQ 1'b0;
end
end
always @ (posedge clk_i)
begin
//reset it to a known good state to prevent it locks up
if ((reseed_prbs_r && clk_en_i) || rst_i || ~clk_en_i) begin
lfsr_q[4:1] <= #TCQ prbs_seed_i[3:0] | 4'h5;
lfsr_q[PRBS_WIDTH:5] <= #TCQ prbs_seed_i[PRBS_WIDTH-1:4];
end
else if (clk_en_i && (~phy_if_empty_r || ~prbs_rdlvl_start)) begin
lfsr_q[PRBS_WIDTH:31] <= #TCQ lfsr_q[PRBS_WIDTH-1:30];
lfsr_q[30] <= #TCQ lfsr_q[16] ^ lfsr_q[13] ^ lfsr_q[5] ^ lfsr_q[1];
lfsr_q[29:9] <= #TCQ lfsr_q[28:8];
lfsr_q[8] <= #TCQ lfsr_q[32] ^ lfsr_q[7];
lfsr_q[7] <= #TCQ lfsr_q[32] ^ lfsr_q[6];
lfsr_q[6:4] <= #TCQ lfsr_q[5:3];
lfsr_q[3] <= #TCQ lfsr_q[32] ^ lfsr_q[2];
lfsr_q[2] <= #TCQ lfsr_q[1] ;
lfsr_q[1] <= #TCQ lfsr_q[32];
end
end
always @ (lfsr_q[PRBS_WIDTH:1]) begin
prbs = lfsr_q[PRBS_WIDTH:1];
end
//******************************************************************************
// Complex pattern BRAM
//******************************************************************************
localparam BRAM_ADDR_WIDTH = 8;
localparam BRAM_DATA_WIDTH = 18;
localparam BRAM_DEPTH = 256;
integer i;
(* RAM_STYLE = "distributed" *) reg [BRAM_ADDR_WIDTH - 1:0] rd_addr;
//reg [BRAM_DATA_WIDTH - 1:0] mem[0:BRAM_DEPTH - 1];
reg [BRAM_DATA_WIDTH - 1:0] mem_out;
reg [BRAM_DATA_WIDTH - 3:0] dout_o;
reg [DQ_WIDTH-1:0] sel;
reg [DQ_WIDTH-1:0] dout_rise0;
reg [DQ_WIDTH-1:0] dout_fall0;
reg [DQ_WIDTH-1:0] dout_rise1;
reg [DQ_WIDTH-1:0] dout_fall1;
reg [DQ_WIDTH-1:0] dout_rise2;
reg [DQ_WIDTH-1:0] dout_fall2;
reg [DQ_WIDTH-1:0] dout_rise3;
reg [DQ_WIDTH-1:0] dout_fall3;
// VCCO noise injection pattern with matching victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
always @ (rd_addr) begin
case (rd_addr)
8'd0 : mem_out = {2'b11, 8'b10101010,8'b10101010}; //1 read
8'd1 : mem_out = {2'b01, 8'b11001100,8'b11001100}; //2 reads
8'd2 : mem_out = {2'b10, 8'b11001100,8'b11001100}; //2 reads
8'd3 : mem_out = {2'b01, 8'b11100011,8'b11100011}; //3 reads
8'd4 : mem_out = {2'b00, 8'b10001110,8'b10001110}; //3 reads
8'd5 : mem_out = {2'b10, 8'b00111000,8'b00111000}; //3 reads
8'd6 : mem_out = {2'b01, 8'b11110000,8'b11110000}; //4 reads
8'd7 : mem_out = {2'b00, 8'b11110000,8'b11110000}; //4 reads
8'd8 : mem_out = {2'b00, 8'b11110000,8'b11110000}; //4 reads
8'd9 : mem_out = {2'b10, 8'b11110000,8'b11110000}; //4 reads
8'd10 : mem_out = {2'b01, 8'b11111000,8'b11111000}; //5 reads
8'd11 : mem_out = {2'b00, 8'b00111110,8'b00111110}; //5 reads
8'd12 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //5 reads
8'd13 : mem_out = {2'b00, 8'b10000011,8'b10000011}; //5 reads
8'd14 : mem_out = {2'b10, 8'b11100000,8'b11100000}; //5 reads
8'd15 : mem_out = {2'b01, 8'b11111100,8'b11111100}; //6 reads
8'd16 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //6 reads
8'd17 : mem_out = {2'b00, 8'b11000000,8'b11000000}; //6 reads
8'd18 : mem_out = {2'b00, 8'b11111100,8'b11111100}; //6 reads
8'd19 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //6 reads
8'd20 : mem_out = {2'b10, 8'b11000000,8'b11000000}; //6 reads
// VCCO noise injection pattern with non-matching victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
8'd21 : mem_out = {2'b11, 8'b10101010,8'b01010101}; //1 read
8'd22 : mem_out = {2'b01, 8'b11001100,8'b00110011}; //2 reads
8'd23 : mem_out = {2'b10, 8'b11001100,8'b00110011}; //2 reads
8'd24 : mem_out = {2'b01, 8'b11100011,8'b00011100}; //3 reads
8'd25 : mem_out = {2'b00, 8'b10001110,8'b01110001}; //3 reads
8'd26 : mem_out = {2'b10, 8'b00111000,8'b11000111}; //3 reads
8'd27 : mem_out = {2'b01, 8'b11110000,8'b00001111}; //4 reads
8'd28 : mem_out = {2'b00, 8'b11110000,8'b00001111}; //4 reads
8'd29 : mem_out = {2'b00, 8'b11110000,8'b00001111}; //4 reads
8'd30 : mem_out = {2'b10, 8'b11110000,8'b00001111}; //4 reads
8'd31 : mem_out = {2'b01, 8'b11111000,8'b00000111}; //5 reads
8'd32 : mem_out = {2'b00, 8'b00111110,8'b11000001}; //5 reads
8'd33 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //5 reads
8'd34 : mem_out = {2'b00, 8'b10000011,8'b01111100}; //5 reads
8'd35 : mem_out = {2'b10, 8'b11100000,8'b00011111}; //5 reads
8'd36 : mem_out = {2'b01, 8'b11111100,8'b00000011}; //6 reads
8'd37 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //6 reads
8'd38 : mem_out = {2'b00, 8'b11000000,8'b00111111}; //6 reads
8'd39 : mem_out = {2'b00, 8'b11111100,8'b00000011}; //6 reads
8'd40 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //6 reads
8'd41 : mem_out = {2'b10, 8'b11000000,8'b00111111}; //6 reads
// VCCAUX noise injection pattern with ISI pattern on victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
8'd42 : mem_out = {2'b01, 8'b10110100,8'b01010111}; //3 reads
8'd43 : mem_out = {2'b00, 8'b10110100,8'b01101111}; //3 reads
8'd44 : mem_out = {2'b10, 8'b10110100,8'b11000000}; //3 reads
8'd45 : mem_out = {2'b01, 8'b10100010,8'b10000100}; //4 reads
8'd46 : mem_out = {2'b00, 8'b10001010,8'b00110001}; //4 reads
8'd47 : mem_out = {2'b00, 8'b00101000,8'b01000111}; //4 reads
8'd48 : mem_out = {2'b10, 8'b10100010,8'b00100101}; //4 reads
8'd49 : mem_out = {2'b01, 8'b10101111,8'b10011010}; //5 reads
8'd50 : mem_out = {2'b00, 8'b01010000,8'b01111010}; //5 reads
8'd51 : mem_out = {2'b00, 8'b10101111,8'b10010101}; //5 reads
8'd52 : mem_out = {2'b00, 8'b01010000,8'b11011011}; //5 reads
8'd53 : mem_out = {2'b10, 8'b10101111,8'b11110000}; //5 reads
8'd54 : mem_out = {2'b01, 8'b10101000,8'b00100001}; //7 reads
8'd55 : mem_out = {2'b00, 8'b00101010,8'b10001010}; //7 reads
8'd56 : mem_out = {2'b00, 8'b00001010,8'b00100101}; //7 reads
8'd57 : mem_out = {2'b00, 8'b10000010,8'b10011010}; //7 reads
8'd58 : mem_out = {2'b00, 8'b10100000,8'b01111010}; //7 reads
8'd59 : mem_out = {2'b00, 8'b10101000,8'b10111111}; //7 reads
8'd60 : mem_out = {2'b10, 8'b00101010,8'b01010111}; //7 reads
8'd61 : mem_out = {2'b01, 8'b10101011,8'b01101111}; //8 reads
8'd62 : mem_out = {2'b00, 8'b11110101,8'b11000000}; //8 reads
8'd63 : mem_out = {2'b00, 8'b01000000,8'b10000100}; //8 reads
8'd64 : mem_out = {2'b00, 8'b10101011,8'b00110001}; //8 reads
8'd65 : mem_out = {2'b00, 8'b11110101,8'b01000111}; //8 reads
8'd66 : mem_out = {2'b00, 8'b01000000,8'b00100101}; //8 reads
8'd67 : mem_out = {2'b00, 8'b10101011,8'b10011010}; //8 reads
8'd68 : mem_out = {2'b10, 8'b11110101,8'b01111010}; //8 reads
8'd69 : mem_out = {2'b01, 8'b10101010,8'b10010101}; //9 reads
8'd70 : mem_out = {2'b00, 8'b00000010,8'b11011011}; //9 reads
8'd71 : mem_out = {2'b00, 8'b10101000,8'b11110000}; //9 reads
8'd72 : mem_out = {2'b00, 8'b00001010,8'b00100001}; //9 reads
8'd73 : mem_out = {2'b00, 8'b10100000,8'b10001010}; //9 reads
8'd74 : mem_out = {2'b00, 8'b00101010,8'b00100101}; //9 reads
8'd75 : mem_out = {2'b00, 8'b10000000,8'b10011010}; //9 reads
8'd76 : mem_out = {2'b00, 8'b10101010,8'b01111010}; //9 reads
8'd77 : mem_out = {2'b10, 8'b00000010,8'b10111111}; //9 reads
8'd78 : mem_out = {2'b01, 8'b10101010,8'b01010111}; //10 reads
8'd79 : mem_out = {2'b00, 8'b11111111,8'b01101111}; //10 reads
8'd80 : mem_out = {2'b00, 8'b01010101,8'b11000000}; //10 reads
8'd81 : mem_out = {2'b00, 8'b00000000,8'b10000100}; //10 reads
8'd82 : mem_out = {2'b00, 8'b10101010,8'b00110001}; //10 reads
8'd83 : mem_out = {2'b00, 8'b11111111,8'b01000111}; //10 reads
8'd84 : mem_out = {2'b00, 8'b01010101,8'b00100101}; //10 reads
8'd85 : mem_out = {2'b00, 8'b00000000,8'b10011010}; //10 reads
8'd86 : mem_out = {2'b00, 8'b10101010,8'b01111010}; //10 reads
8'd87 : mem_out = {2'b10, 8'b11111111,8'b10010101}; //10 reads
8'd88 : mem_out = {2'b01, 8'b10101010,8'b11011011}; //12 reads
8'd89 : mem_out = {2'b00, 8'b10000000,8'b11110000}; //12 reads
8'd90 : mem_out = {2'b00, 8'b00101010,8'b00100001}; //12 reads
8'd91 : mem_out = {2'b00, 8'b10100000,8'b10001010}; //12 reads
8'd92 : mem_out = {2'b00, 8'b00001010,8'b00100101}; //12 reads
8'd93 : mem_out = {2'b00, 8'b10101000,8'b10011010}; //12 reads
8'd94 : mem_out = {2'b00, 8'b00000010,8'b01111010}; //12 reads
8'd95 : mem_out = {2'b00, 8'b10101010,8'b10111111}; //12 reads
8'd96 : mem_out = {2'b00, 8'b00000000,8'b01010111}; //12 reads
8'd97 : mem_out = {2'b00, 8'b10101010,8'b01101111}; //12 reads
8'd98 : mem_out = {2'b00, 8'b10000000,8'b11000000}; //12 reads
8'd99 : mem_out = {2'b10, 8'b00101010,8'b10000100}; //12 reads
8'd100 : mem_out = {2'b01, 8'b10101010,8'b00110001}; //13 reads
8'd101 : mem_out = {2'b00, 8'b10111111,8'b01000111}; //13 reads
8'd102 : mem_out = {2'b00, 8'b11110101,8'b00100101}; //13 reads
8'd103 : mem_out = {2'b00, 8'b01010100,8'b10011010}; //13 reads
8'd104 : mem_out = {2'b00, 8'b00000000,8'b01111010}; //13 reads
8'd105 : mem_out = {2'b00, 8'b10101010,8'b10010101}; //13 reads
8'd106 : mem_out = {2'b00, 8'b10111111,8'b11011011}; //13 reads
8'd107 : mem_out = {2'b00, 8'b11110101,8'b11110000}; //13 reads
8'd108 : mem_out = {2'b00, 8'b01010100,8'b00100001}; //13 reads
8'd109 : mem_out = {2'b00, 8'b00000000,8'b10001010}; //13 reads
8'd110 : mem_out = {2'b00, 8'b10101010,8'b00100101}; //13 reads
8'd111 : mem_out = {2'b00, 8'b10111111,8'b10011010}; //13 reads
8'd112 : mem_out = {2'b10, 8'b11110101,8'b01111010}; //13 reads
8'd113 : mem_out = {2'b01, 8'b10101010,8'b10111111}; //14 reads
8'd114 : mem_out = {2'b00, 8'b10100000,8'b01010111}; //14 reads
8'd115 : mem_out = {2'b00, 8'b00000010,8'b01101111}; //14 reads
8'd116 : mem_out = {2'b00, 8'b10101010,8'b11000000}; //14 reads
8'd117 : mem_out = {2'b00, 8'b10000000,8'b10000100}; //14 reads
8'd118 : mem_out = {2'b00, 8'b00001010,8'b00110001}; //14 reads
8'd119 : mem_out = {2'b00, 8'b10101010,8'b01000111}; //14 reads
8'd120 : mem_out = {2'b00, 8'b00000000,8'b00100101}; //14 reads
8'd121 : mem_out = {2'b00, 8'b00101010,8'b10011010}; //14 reads
8'd122 : mem_out = {2'b00, 8'b10101000,8'b01111010}; //14 reads
8'd123 : mem_out = {2'b00, 8'b00000000,8'b10010101}; //14 reads
8'd124 : mem_out = {2'b00, 8'b10101010,8'b11011011}; //14 reads
8'd125 : mem_out = {2'b00, 8'b10100000,8'b11110000}; //14 reads
8'd126 : mem_out = {2'b10, 8'b00000010,8'b00100001}; //14 reads
// ISI pattern (Back-to-back reads)
// content format
// {aggressor pattern, victim pattern}
8'd127 : mem_out = {2'b01, 8'b01010111,8'b01010111};
8'd128 : mem_out = {2'b00, 8'b01101111,8'b01101111};
8'd129 : mem_out = {2'b00, 8'b11000000,8'b11000000};
8'd130 : mem_out = {2'b00, 8'b10000110,8'b10000100};
8'd131 : mem_out = {2'b00, 8'b00101000,8'b00110001};
8'd132 : mem_out = {2'b00, 8'b11100100,8'b01000111};
8'd133 : mem_out = {2'b00, 8'b10110011,8'b00100101};
8'd134 : mem_out = {2'b00, 8'b01001111,8'b10011011};
8'd135 : mem_out = {2'b00, 8'b10110101,8'b01010101};
8'd136 : mem_out = {2'b00, 8'b10110101,8'b01010101};
8'd137 : mem_out = {2'b00, 8'b10000111,8'b10011000};
8'd138 : mem_out = {2'b00, 8'b11100011,8'b00011100};
8'd139 : mem_out = {2'b00, 8'b00001010,8'b11110101};
8'd140 : mem_out = {2'b00, 8'b11010100,8'b00101011};
8'd141 : mem_out = {2'b00, 8'b01001000,8'b10110111};
8'd142 : mem_out = {2'b00, 8'b00011111,8'b11100000};
8'd143 : mem_out = {2'b00, 8'b10111100,8'b01000011};
8'd144 : mem_out = {2'b00, 8'b10001111,8'b00010100};
8'd145 : mem_out = {2'b00, 8'b10110100,8'b01001011};
8'd146 : mem_out = {2'b00, 8'b11001011,8'b00110100};
8'd147 : mem_out = {2'b00, 8'b00001010,8'b11110101};
8'd148 : mem_out = {2'b00, 8'b10000000,8'b00000000};
//Additional for ISI
8'd149 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd150 : mem_out = {2'b00, 8'b01010101,8'b01010101};
8'd151 : mem_out = {2'b00, 8'b01010101,8'b01010101};
8'd152 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd153 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd154 : mem_out = {2'b00, 8'b01010101,8'b00101010};
8'd155 : mem_out = {2'b00, 8'b01010101,8'b10101010};
8'd156 : mem_out = {2'b10, 8'b00000000,8'b10000000};
//Available
8'd157 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd158 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd159 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd160 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd161 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd162 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd163 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd164 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd165 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd166 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd167 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd168 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd169 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd170 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd171 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd172 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd173 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd174 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd175 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd176 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd177 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd178 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd179 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd180 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd181 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd182 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd183 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd184 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd185 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd186 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd187 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd188 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd189 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd190 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd191 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd192 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd193 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd194 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd195 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd196 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd197 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd198 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd199 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd200 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd201 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd202 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd203 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd204 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd205 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd206 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd207 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd208 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd209 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd210 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd211 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd212 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd213 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd214 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd215 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd216 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd217 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd218 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd219 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd220 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd221 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd222 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd223 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd224 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd225 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd226 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd227 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd228 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd229 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd230 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd231 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd232 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd233 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd234 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd235 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd236 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd237 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd238 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd239 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd240 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd241 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd242 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd243 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd244 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd245 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd246 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd247 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd248 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd249 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd250 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd251 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd252 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd253 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd254 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd255 : mem_out = {2'b00, 8'b00000001,8'b00000001};
endcase
end
always @ (posedge clk_i) begin
if (rst_i | reset_rd_addr)
rd_addr <= #TCQ 'b0;
//rd_addr for complex oclkdelay calib
else if (clk_en_i && prbs_rdlvl_done && (~phy_if_empty_r || ~complex_wr_done)) begin
if (rd_addr == 'd156) rd_addr <= #TCQ 'b0;
else rd_addr <= #TCQ rd_addr + 1;
end
//rd_addr for complex rdlvl
else if (clk_en_i && (~phy_if_empty_r || (~prbs_rdlvl_start && ~complex_wr_done))) begin
if (rd_addr == 'd148) rd_addr <= #TCQ 'b0;
else rd_addr <= #TCQ rd_addr+1;
end
end
// Each pattern can be disabled independently
// When disabled zeros are written to and read from the DRAM
always @ (posedge clk_i) begin
if ((rd_addr < 42) && VCCO_PAT_EN)
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else if ((rd_addr < 127) && VCCAUX_PAT_EN)
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else if (ISI_PAT_EN && (rd_addr > 126))
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else
dout_o <= #TCQ 'd0;
end
reg prbs_ignore_first_byte_r;
always @(posedge clk_i) prbs_ignore_first_byte_r <= #TCQ mem_out[16];
assign prbs_ignore_first_byte = prbs_ignore_first_byte_r;
reg prbs_ignore_last_bytes_r;
always @(posedge clk_i) prbs_ignore_last_bytes_r <= #TCQ mem_out[17];
assign prbs_ignore_last_bytes = prbs_ignore_last_bytes_r;
generate
if (FIXED_VICTIM == "TRUE") begin: victim_sel_fixed
// Fixed victim bit 3
always @(posedge clk_i)
sel <= #TCQ {DQ_WIDTH/8{8'h08}};
end else begin: victim_sel_rotate
// One-hot victim select
always @(posedge clk_i)
if (rst_i)
sel <= #TCQ 'd0;
else begin
for (i = 0; i < DQ_WIDTH; i = i+1) begin
if (i == byte_cnt*8+victim_sel)
sel[i] <= #TCQ 1'b1;
else
sel[i] <= #TCQ 1'b0;
end
end
end
endgenerate
// construct 8 X DATA_WIDTH output bus
always @(*)
for (i = 0; i < DQ_WIDTH; i = i+1) begin
dout_rise0[i] = (dout_o[7]&&sel[i] || dout_o[15]&&~sel[i]);
dout_fall0[i] = (dout_o[6]&&sel[i] || dout_o[14]&&~sel[i]);
dout_rise1[i] = (dout_o[5]&&sel[i] || dout_o[13]&&~sel[i]);
dout_fall1[i] = (dout_o[4]&&sel[i] || dout_o[12]&&~sel[i]);
dout_rise2[i] = (dout_o[3]&&sel[i] || dout_o[11]&&~sel[i]);
dout_fall2[i] = (dout_o[2]&&sel[i] || dout_o[10]&&~sel[i]);
dout_rise3[i] = (dout_o[1]&&sel[i] || dout_o[9]&&~sel[i]);
dout_fall3[i] = (dout_o[0]&&sel[i] || dout_o[8]&&~sel[i]);
end
assign prbs_o = {dout_fall3, dout_rise3, dout_fall2, dout_rise2, dout_fall1, dout_rise1, dout_fall0, dout_rise0};
assign dbg_prbs_gen[9] = phy_if_empty_r;
assign dbg_prbs_gen[8] = clk_en_i;
assign dbg_prbs_gen[7:0] = rd_addr[7:0];
endmodule
|
module mig_7series_v2_3_ddr_prbs_gen #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter PRBS_WIDTH = 64, // LFSR shift register length
parameter DQS_CNT_WIDTH = 5,
parameter DQ_WIDTH = 72,
parameter VCCO_PAT_EN = 1,
parameter VCCAUX_PAT_EN = 1,
parameter ISI_PAT_EN = 1,
parameter FIXED_VICTIM = "TRUE"
)
(
input clk_i, // input clock
input clk_en_i, // clock enable
input rst_i, // synchronous reset
input [PRBS_WIDTH-1:0] prbs_seed_i, // initial LFSR seed
input phy_if_empty, // IN_FIFO empty flag
input prbs_rdlvl_start, // PRBS read lveling start
input prbs_rdlvl_done,
input complex_wr_done,
input [2:0] victim_sel,
input [DQS_CNT_WIDTH:0] byte_cnt,
//output [PRBS_WIDTH-1:0] prbs_o // generated pseudo random data
output [8*DQ_WIDTH-1:0] prbs_o,
output [9:0] dbg_prbs_gen,
input reset_rd_addr,
output prbs_ignore_first_byte,
output prbs_ignore_last_bytes
);
//***************************************************************************
function integer clogb2 (input integer size);
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction
// Number of internal clock cycles before the PRBS sequence will repeat
localparam PRBS_SEQ_LEN_CYCLES = 128;
localparam PRBS_SEQ_LEN_CYCLES_BITS = clogb2(PRBS_SEQ_LEN_CYCLES);
reg phy_if_empty_r;
reg reseed_prbs_r;
reg [PRBS_SEQ_LEN_CYCLES_BITS-1:0] sample_cnt_r;
reg [PRBS_WIDTH - 1 :0] prbs;
reg [PRBS_WIDTH :1] lfsr_q;
//***************************************************************************
always @(posedge clk_i) begin
phy_if_empty_r <= #TCQ phy_if_empty;
end
//***************************************************************************
// Generate PRBS reset signal to ensure that PRBS sequence repeats after
// every 2**PRBS_WIDTH samples. Basically what happens is that we let the
// LFSR run for an extra cycle after "truly PRBS" 2**PRBS_WIDTH - 1
// samples have past. Once that extra cycle is finished, we reseed the LFSR
always @(posedge clk_i)
begin
if (rst_i || ~clk_en_i) begin
sample_cnt_r <= #TCQ 'b0;
reseed_prbs_r <= #TCQ 1'b0;
end else if (clk_en_i && (~phy_if_empty_r || ~prbs_rdlvl_start)) begin
// The rollver count should always be [(power of 2) - 1]
sample_cnt_r <= #TCQ sample_cnt_r + 1;
// Assert PRBS reset signal so that it is simultaneously with the
// last sample of the sequence
if (sample_cnt_r == PRBS_SEQ_LEN_CYCLES - 2)
reseed_prbs_r <= #TCQ 1'b1;
else
reseed_prbs_r <= #TCQ 1'b0;
end
end
always @ (posedge clk_i)
begin
//reset it to a known good state to prevent it locks up
if ((reseed_prbs_r && clk_en_i) || rst_i || ~clk_en_i) begin
lfsr_q[4:1] <= #TCQ prbs_seed_i[3:0] | 4'h5;
lfsr_q[PRBS_WIDTH:5] <= #TCQ prbs_seed_i[PRBS_WIDTH-1:4];
end
else if (clk_en_i && (~phy_if_empty_r || ~prbs_rdlvl_start)) begin
lfsr_q[PRBS_WIDTH:31] <= #TCQ lfsr_q[PRBS_WIDTH-1:30];
lfsr_q[30] <= #TCQ lfsr_q[16] ^ lfsr_q[13] ^ lfsr_q[5] ^ lfsr_q[1];
lfsr_q[29:9] <= #TCQ lfsr_q[28:8];
lfsr_q[8] <= #TCQ lfsr_q[32] ^ lfsr_q[7];
lfsr_q[7] <= #TCQ lfsr_q[32] ^ lfsr_q[6];
lfsr_q[6:4] <= #TCQ lfsr_q[5:3];
lfsr_q[3] <= #TCQ lfsr_q[32] ^ lfsr_q[2];
lfsr_q[2] <= #TCQ lfsr_q[1] ;
lfsr_q[1] <= #TCQ lfsr_q[32];
end
end
always @ (lfsr_q[PRBS_WIDTH:1]) begin
prbs = lfsr_q[PRBS_WIDTH:1];
end
//******************************************************************************
// Complex pattern BRAM
//******************************************************************************
localparam BRAM_ADDR_WIDTH = 8;
localparam BRAM_DATA_WIDTH = 18;
localparam BRAM_DEPTH = 256;
integer i;
(* RAM_STYLE = "distributed" *) reg [BRAM_ADDR_WIDTH - 1:0] rd_addr;
//reg [BRAM_DATA_WIDTH - 1:0] mem[0:BRAM_DEPTH - 1];
reg [BRAM_DATA_WIDTH - 1:0] mem_out;
reg [BRAM_DATA_WIDTH - 3:0] dout_o;
reg [DQ_WIDTH-1:0] sel;
reg [DQ_WIDTH-1:0] dout_rise0;
reg [DQ_WIDTH-1:0] dout_fall0;
reg [DQ_WIDTH-1:0] dout_rise1;
reg [DQ_WIDTH-1:0] dout_fall1;
reg [DQ_WIDTH-1:0] dout_rise2;
reg [DQ_WIDTH-1:0] dout_fall2;
reg [DQ_WIDTH-1:0] dout_rise3;
reg [DQ_WIDTH-1:0] dout_fall3;
// VCCO noise injection pattern with matching victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
always @ (rd_addr) begin
case (rd_addr)
8'd0 : mem_out = {2'b11, 8'b10101010,8'b10101010}; //1 read
8'd1 : mem_out = {2'b01, 8'b11001100,8'b11001100}; //2 reads
8'd2 : mem_out = {2'b10, 8'b11001100,8'b11001100}; //2 reads
8'd3 : mem_out = {2'b01, 8'b11100011,8'b11100011}; //3 reads
8'd4 : mem_out = {2'b00, 8'b10001110,8'b10001110}; //3 reads
8'd5 : mem_out = {2'b10, 8'b00111000,8'b00111000}; //3 reads
8'd6 : mem_out = {2'b01, 8'b11110000,8'b11110000}; //4 reads
8'd7 : mem_out = {2'b00, 8'b11110000,8'b11110000}; //4 reads
8'd8 : mem_out = {2'b00, 8'b11110000,8'b11110000}; //4 reads
8'd9 : mem_out = {2'b10, 8'b11110000,8'b11110000}; //4 reads
8'd10 : mem_out = {2'b01, 8'b11111000,8'b11111000}; //5 reads
8'd11 : mem_out = {2'b00, 8'b00111110,8'b00111110}; //5 reads
8'd12 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //5 reads
8'd13 : mem_out = {2'b00, 8'b10000011,8'b10000011}; //5 reads
8'd14 : mem_out = {2'b10, 8'b11100000,8'b11100000}; //5 reads
8'd15 : mem_out = {2'b01, 8'b11111100,8'b11111100}; //6 reads
8'd16 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //6 reads
8'd17 : mem_out = {2'b00, 8'b11000000,8'b11000000}; //6 reads
8'd18 : mem_out = {2'b00, 8'b11111100,8'b11111100}; //6 reads
8'd19 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //6 reads
8'd20 : mem_out = {2'b10, 8'b11000000,8'b11000000}; //6 reads
// VCCO noise injection pattern with non-matching victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
8'd21 : mem_out = {2'b11, 8'b10101010,8'b01010101}; //1 read
8'd22 : mem_out = {2'b01, 8'b11001100,8'b00110011}; //2 reads
8'd23 : mem_out = {2'b10, 8'b11001100,8'b00110011}; //2 reads
8'd24 : mem_out = {2'b01, 8'b11100011,8'b00011100}; //3 reads
8'd25 : mem_out = {2'b00, 8'b10001110,8'b01110001}; //3 reads
8'd26 : mem_out = {2'b10, 8'b00111000,8'b11000111}; //3 reads
8'd27 : mem_out = {2'b01, 8'b11110000,8'b00001111}; //4 reads
8'd28 : mem_out = {2'b00, 8'b11110000,8'b00001111}; //4 reads
8'd29 : mem_out = {2'b00, 8'b11110000,8'b00001111}; //4 reads
8'd30 : mem_out = {2'b10, 8'b11110000,8'b00001111}; //4 reads
8'd31 : mem_out = {2'b01, 8'b11111000,8'b00000111}; //5 reads
8'd32 : mem_out = {2'b00, 8'b00111110,8'b11000001}; //5 reads
8'd33 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //5 reads
8'd34 : mem_out = {2'b00, 8'b10000011,8'b01111100}; //5 reads
8'd35 : mem_out = {2'b10, 8'b11100000,8'b00011111}; //5 reads
8'd36 : mem_out = {2'b01, 8'b11111100,8'b00000011}; //6 reads
8'd37 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //6 reads
8'd38 : mem_out = {2'b00, 8'b11000000,8'b00111111}; //6 reads
8'd39 : mem_out = {2'b00, 8'b11111100,8'b00000011}; //6 reads
8'd40 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //6 reads
8'd41 : mem_out = {2'b10, 8'b11000000,8'b00111111}; //6 reads
// VCCAUX noise injection pattern with ISI pattern on victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
8'd42 : mem_out = {2'b01, 8'b10110100,8'b01010111}; //3 reads
8'd43 : mem_out = {2'b00, 8'b10110100,8'b01101111}; //3 reads
8'd44 : mem_out = {2'b10, 8'b10110100,8'b11000000}; //3 reads
8'd45 : mem_out = {2'b01, 8'b10100010,8'b10000100}; //4 reads
8'd46 : mem_out = {2'b00, 8'b10001010,8'b00110001}; //4 reads
8'd47 : mem_out = {2'b00, 8'b00101000,8'b01000111}; //4 reads
8'd48 : mem_out = {2'b10, 8'b10100010,8'b00100101}; //4 reads
8'd49 : mem_out = {2'b01, 8'b10101111,8'b10011010}; //5 reads
8'd50 : mem_out = {2'b00, 8'b01010000,8'b01111010}; //5 reads
8'd51 : mem_out = {2'b00, 8'b10101111,8'b10010101}; //5 reads
8'd52 : mem_out = {2'b00, 8'b01010000,8'b11011011}; //5 reads
8'd53 : mem_out = {2'b10, 8'b10101111,8'b11110000}; //5 reads
8'd54 : mem_out = {2'b01, 8'b10101000,8'b00100001}; //7 reads
8'd55 : mem_out = {2'b00, 8'b00101010,8'b10001010}; //7 reads
8'd56 : mem_out = {2'b00, 8'b00001010,8'b00100101}; //7 reads
8'd57 : mem_out = {2'b00, 8'b10000010,8'b10011010}; //7 reads
8'd58 : mem_out = {2'b00, 8'b10100000,8'b01111010}; //7 reads
8'd59 : mem_out = {2'b00, 8'b10101000,8'b10111111}; //7 reads
8'd60 : mem_out = {2'b10, 8'b00101010,8'b01010111}; //7 reads
8'd61 : mem_out = {2'b01, 8'b10101011,8'b01101111}; //8 reads
8'd62 : mem_out = {2'b00, 8'b11110101,8'b11000000}; //8 reads
8'd63 : mem_out = {2'b00, 8'b01000000,8'b10000100}; //8 reads
8'd64 : mem_out = {2'b00, 8'b10101011,8'b00110001}; //8 reads
8'd65 : mem_out = {2'b00, 8'b11110101,8'b01000111}; //8 reads
8'd66 : mem_out = {2'b00, 8'b01000000,8'b00100101}; //8 reads
8'd67 : mem_out = {2'b00, 8'b10101011,8'b10011010}; //8 reads
8'd68 : mem_out = {2'b10, 8'b11110101,8'b01111010}; //8 reads
8'd69 : mem_out = {2'b01, 8'b10101010,8'b10010101}; //9 reads
8'd70 : mem_out = {2'b00, 8'b00000010,8'b11011011}; //9 reads
8'd71 : mem_out = {2'b00, 8'b10101000,8'b11110000}; //9 reads
8'd72 : mem_out = {2'b00, 8'b00001010,8'b00100001}; //9 reads
8'd73 : mem_out = {2'b00, 8'b10100000,8'b10001010}; //9 reads
8'd74 : mem_out = {2'b00, 8'b00101010,8'b00100101}; //9 reads
8'd75 : mem_out = {2'b00, 8'b10000000,8'b10011010}; //9 reads
8'd76 : mem_out = {2'b00, 8'b10101010,8'b01111010}; //9 reads
8'd77 : mem_out = {2'b10, 8'b00000010,8'b10111111}; //9 reads
8'd78 : mem_out = {2'b01, 8'b10101010,8'b01010111}; //10 reads
8'd79 : mem_out = {2'b00, 8'b11111111,8'b01101111}; //10 reads
8'd80 : mem_out = {2'b00, 8'b01010101,8'b11000000}; //10 reads
8'd81 : mem_out = {2'b00, 8'b00000000,8'b10000100}; //10 reads
8'd82 : mem_out = {2'b00, 8'b10101010,8'b00110001}; //10 reads
8'd83 : mem_out = {2'b00, 8'b11111111,8'b01000111}; //10 reads
8'd84 : mem_out = {2'b00, 8'b01010101,8'b00100101}; //10 reads
8'd85 : mem_out = {2'b00, 8'b00000000,8'b10011010}; //10 reads
8'd86 : mem_out = {2'b00, 8'b10101010,8'b01111010}; //10 reads
8'd87 : mem_out = {2'b10, 8'b11111111,8'b10010101}; //10 reads
8'd88 : mem_out = {2'b01, 8'b10101010,8'b11011011}; //12 reads
8'd89 : mem_out = {2'b00, 8'b10000000,8'b11110000}; //12 reads
8'd90 : mem_out = {2'b00, 8'b00101010,8'b00100001}; //12 reads
8'd91 : mem_out = {2'b00, 8'b10100000,8'b10001010}; //12 reads
8'd92 : mem_out = {2'b00, 8'b00001010,8'b00100101}; //12 reads
8'd93 : mem_out = {2'b00, 8'b10101000,8'b10011010}; //12 reads
8'd94 : mem_out = {2'b00, 8'b00000010,8'b01111010}; //12 reads
8'd95 : mem_out = {2'b00, 8'b10101010,8'b10111111}; //12 reads
8'd96 : mem_out = {2'b00, 8'b00000000,8'b01010111}; //12 reads
8'd97 : mem_out = {2'b00, 8'b10101010,8'b01101111}; //12 reads
8'd98 : mem_out = {2'b00, 8'b10000000,8'b11000000}; //12 reads
8'd99 : mem_out = {2'b10, 8'b00101010,8'b10000100}; //12 reads
8'd100 : mem_out = {2'b01, 8'b10101010,8'b00110001}; //13 reads
8'd101 : mem_out = {2'b00, 8'b10111111,8'b01000111}; //13 reads
8'd102 : mem_out = {2'b00, 8'b11110101,8'b00100101}; //13 reads
8'd103 : mem_out = {2'b00, 8'b01010100,8'b10011010}; //13 reads
8'd104 : mem_out = {2'b00, 8'b00000000,8'b01111010}; //13 reads
8'd105 : mem_out = {2'b00, 8'b10101010,8'b10010101}; //13 reads
8'd106 : mem_out = {2'b00, 8'b10111111,8'b11011011}; //13 reads
8'd107 : mem_out = {2'b00, 8'b11110101,8'b11110000}; //13 reads
8'd108 : mem_out = {2'b00, 8'b01010100,8'b00100001}; //13 reads
8'd109 : mem_out = {2'b00, 8'b00000000,8'b10001010}; //13 reads
8'd110 : mem_out = {2'b00, 8'b10101010,8'b00100101}; //13 reads
8'd111 : mem_out = {2'b00, 8'b10111111,8'b10011010}; //13 reads
8'd112 : mem_out = {2'b10, 8'b11110101,8'b01111010}; //13 reads
8'd113 : mem_out = {2'b01, 8'b10101010,8'b10111111}; //14 reads
8'd114 : mem_out = {2'b00, 8'b10100000,8'b01010111}; //14 reads
8'd115 : mem_out = {2'b00, 8'b00000010,8'b01101111}; //14 reads
8'd116 : mem_out = {2'b00, 8'b10101010,8'b11000000}; //14 reads
8'd117 : mem_out = {2'b00, 8'b10000000,8'b10000100}; //14 reads
8'd118 : mem_out = {2'b00, 8'b00001010,8'b00110001}; //14 reads
8'd119 : mem_out = {2'b00, 8'b10101010,8'b01000111}; //14 reads
8'd120 : mem_out = {2'b00, 8'b00000000,8'b00100101}; //14 reads
8'd121 : mem_out = {2'b00, 8'b00101010,8'b10011010}; //14 reads
8'd122 : mem_out = {2'b00, 8'b10101000,8'b01111010}; //14 reads
8'd123 : mem_out = {2'b00, 8'b00000000,8'b10010101}; //14 reads
8'd124 : mem_out = {2'b00, 8'b10101010,8'b11011011}; //14 reads
8'd125 : mem_out = {2'b00, 8'b10100000,8'b11110000}; //14 reads
8'd126 : mem_out = {2'b10, 8'b00000010,8'b00100001}; //14 reads
// ISI pattern (Back-to-back reads)
// content format
// {aggressor pattern, victim pattern}
8'd127 : mem_out = {2'b01, 8'b01010111,8'b01010111};
8'd128 : mem_out = {2'b00, 8'b01101111,8'b01101111};
8'd129 : mem_out = {2'b00, 8'b11000000,8'b11000000};
8'd130 : mem_out = {2'b00, 8'b10000110,8'b10000100};
8'd131 : mem_out = {2'b00, 8'b00101000,8'b00110001};
8'd132 : mem_out = {2'b00, 8'b11100100,8'b01000111};
8'd133 : mem_out = {2'b00, 8'b10110011,8'b00100101};
8'd134 : mem_out = {2'b00, 8'b01001111,8'b10011011};
8'd135 : mem_out = {2'b00, 8'b10110101,8'b01010101};
8'd136 : mem_out = {2'b00, 8'b10110101,8'b01010101};
8'd137 : mem_out = {2'b00, 8'b10000111,8'b10011000};
8'd138 : mem_out = {2'b00, 8'b11100011,8'b00011100};
8'd139 : mem_out = {2'b00, 8'b00001010,8'b11110101};
8'd140 : mem_out = {2'b00, 8'b11010100,8'b00101011};
8'd141 : mem_out = {2'b00, 8'b01001000,8'b10110111};
8'd142 : mem_out = {2'b00, 8'b00011111,8'b11100000};
8'd143 : mem_out = {2'b00, 8'b10111100,8'b01000011};
8'd144 : mem_out = {2'b00, 8'b10001111,8'b00010100};
8'd145 : mem_out = {2'b00, 8'b10110100,8'b01001011};
8'd146 : mem_out = {2'b00, 8'b11001011,8'b00110100};
8'd147 : mem_out = {2'b00, 8'b00001010,8'b11110101};
8'd148 : mem_out = {2'b00, 8'b10000000,8'b00000000};
//Additional for ISI
8'd149 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd150 : mem_out = {2'b00, 8'b01010101,8'b01010101};
8'd151 : mem_out = {2'b00, 8'b01010101,8'b01010101};
8'd152 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd153 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd154 : mem_out = {2'b00, 8'b01010101,8'b00101010};
8'd155 : mem_out = {2'b00, 8'b01010101,8'b10101010};
8'd156 : mem_out = {2'b10, 8'b00000000,8'b10000000};
//Available
8'd157 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd158 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd159 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd160 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd161 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd162 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd163 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd164 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd165 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd166 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd167 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd168 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd169 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd170 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd171 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd172 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd173 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd174 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd175 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd176 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd177 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd178 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd179 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd180 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd181 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd182 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd183 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd184 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd185 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd186 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd187 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd188 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd189 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd190 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd191 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd192 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd193 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd194 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd195 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd196 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd197 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd198 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd199 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd200 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd201 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd202 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd203 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd204 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd205 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd206 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd207 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd208 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd209 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd210 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd211 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd212 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd213 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd214 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd215 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd216 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd217 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd218 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd219 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd220 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd221 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd222 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd223 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd224 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd225 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd226 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd227 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd228 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd229 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd230 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd231 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd232 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd233 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd234 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd235 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd236 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd237 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd238 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd239 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd240 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd241 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd242 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd243 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd244 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd245 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd246 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd247 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd248 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd249 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd250 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd251 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd252 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd253 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd254 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd255 : mem_out = {2'b00, 8'b00000001,8'b00000001};
endcase
end
always @ (posedge clk_i) begin
if (rst_i | reset_rd_addr)
rd_addr <= #TCQ 'b0;
//rd_addr for complex oclkdelay calib
else if (clk_en_i && prbs_rdlvl_done && (~phy_if_empty_r || ~complex_wr_done)) begin
if (rd_addr == 'd156) rd_addr <= #TCQ 'b0;
else rd_addr <= #TCQ rd_addr + 1;
end
//rd_addr for complex rdlvl
else if (clk_en_i && (~phy_if_empty_r || (~prbs_rdlvl_start && ~complex_wr_done))) begin
if (rd_addr == 'd148) rd_addr <= #TCQ 'b0;
else rd_addr <= #TCQ rd_addr+1;
end
end
// Each pattern can be disabled independently
// When disabled zeros are written to and read from the DRAM
always @ (posedge clk_i) begin
if ((rd_addr < 42) && VCCO_PAT_EN)
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else if ((rd_addr < 127) && VCCAUX_PAT_EN)
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else if (ISI_PAT_EN && (rd_addr > 126))
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else
dout_o <= #TCQ 'd0;
end
reg prbs_ignore_first_byte_r;
always @(posedge clk_i) prbs_ignore_first_byte_r <= #TCQ mem_out[16];
assign prbs_ignore_first_byte = prbs_ignore_first_byte_r;
reg prbs_ignore_last_bytes_r;
always @(posedge clk_i) prbs_ignore_last_bytes_r <= #TCQ mem_out[17];
assign prbs_ignore_last_bytes = prbs_ignore_last_bytes_r;
generate
if (FIXED_VICTIM == "TRUE") begin: victim_sel_fixed
// Fixed victim bit 3
always @(posedge clk_i)
sel <= #TCQ {DQ_WIDTH/8{8'h08}};
end else begin: victim_sel_rotate
// One-hot victim select
always @(posedge clk_i)
if (rst_i)
sel <= #TCQ 'd0;
else begin
for (i = 0; i < DQ_WIDTH; i = i+1) begin
if (i == byte_cnt*8+victim_sel)
sel[i] <= #TCQ 1'b1;
else
sel[i] <= #TCQ 1'b0;
end
end
end
endgenerate
// construct 8 X DATA_WIDTH output bus
always @(*)
for (i = 0; i < DQ_WIDTH; i = i+1) begin
dout_rise0[i] = (dout_o[7]&&sel[i] || dout_o[15]&&~sel[i]);
dout_fall0[i] = (dout_o[6]&&sel[i] || dout_o[14]&&~sel[i]);
dout_rise1[i] = (dout_o[5]&&sel[i] || dout_o[13]&&~sel[i]);
dout_fall1[i] = (dout_o[4]&&sel[i] || dout_o[12]&&~sel[i]);
dout_rise2[i] = (dout_o[3]&&sel[i] || dout_o[11]&&~sel[i]);
dout_fall2[i] = (dout_o[2]&&sel[i] || dout_o[10]&&~sel[i]);
dout_rise3[i] = (dout_o[1]&&sel[i] || dout_o[9]&&~sel[i]);
dout_fall3[i] = (dout_o[0]&&sel[i] || dout_o[8]&&~sel[i]);
end
assign prbs_o = {dout_fall3, dout_rise3, dout_fall2, dout_rise2, dout_fall1, dout_rise1, dout_fall0, dout_rise0};
assign dbg_prbs_gen[9] = phy_if_empty_r;
assign dbg_prbs_gen[8] = clk_en_i;
assign dbg_prbs_gen[7:0] = rd_addr[7:0];
endmodule
|
module mig_7series_v2_3_ddr_prbs_gen #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter PRBS_WIDTH = 64, // LFSR shift register length
parameter DQS_CNT_WIDTH = 5,
parameter DQ_WIDTH = 72,
parameter VCCO_PAT_EN = 1,
parameter VCCAUX_PAT_EN = 1,
parameter ISI_PAT_EN = 1,
parameter FIXED_VICTIM = "TRUE"
)
(
input clk_i, // input clock
input clk_en_i, // clock enable
input rst_i, // synchronous reset
input [PRBS_WIDTH-1:0] prbs_seed_i, // initial LFSR seed
input phy_if_empty, // IN_FIFO empty flag
input prbs_rdlvl_start, // PRBS read lveling start
input prbs_rdlvl_done,
input complex_wr_done,
input [2:0] victim_sel,
input [DQS_CNT_WIDTH:0] byte_cnt,
//output [PRBS_WIDTH-1:0] prbs_o // generated pseudo random data
output [8*DQ_WIDTH-1:0] prbs_o,
output [9:0] dbg_prbs_gen,
input reset_rd_addr,
output prbs_ignore_first_byte,
output prbs_ignore_last_bytes
);
//***************************************************************************
function integer clogb2 (input integer size);
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction
// Number of internal clock cycles before the PRBS sequence will repeat
localparam PRBS_SEQ_LEN_CYCLES = 128;
localparam PRBS_SEQ_LEN_CYCLES_BITS = clogb2(PRBS_SEQ_LEN_CYCLES);
reg phy_if_empty_r;
reg reseed_prbs_r;
reg [PRBS_SEQ_LEN_CYCLES_BITS-1:0] sample_cnt_r;
reg [PRBS_WIDTH - 1 :0] prbs;
reg [PRBS_WIDTH :1] lfsr_q;
//***************************************************************************
always @(posedge clk_i) begin
phy_if_empty_r <= #TCQ phy_if_empty;
end
//***************************************************************************
// Generate PRBS reset signal to ensure that PRBS sequence repeats after
// every 2**PRBS_WIDTH samples. Basically what happens is that we let the
// LFSR run for an extra cycle after "truly PRBS" 2**PRBS_WIDTH - 1
// samples have past. Once that extra cycle is finished, we reseed the LFSR
always @(posedge clk_i)
begin
if (rst_i || ~clk_en_i) begin
sample_cnt_r <= #TCQ 'b0;
reseed_prbs_r <= #TCQ 1'b0;
end else if (clk_en_i && (~phy_if_empty_r || ~prbs_rdlvl_start)) begin
// The rollver count should always be [(power of 2) - 1]
sample_cnt_r <= #TCQ sample_cnt_r + 1;
// Assert PRBS reset signal so that it is simultaneously with the
// last sample of the sequence
if (sample_cnt_r == PRBS_SEQ_LEN_CYCLES - 2)
reseed_prbs_r <= #TCQ 1'b1;
else
reseed_prbs_r <= #TCQ 1'b0;
end
end
always @ (posedge clk_i)
begin
//reset it to a known good state to prevent it locks up
if ((reseed_prbs_r && clk_en_i) || rst_i || ~clk_en_i) begin
lfsr_q[4:1] <= #TCQ prbs_seed_i[3:0] | 4'h5;
lfsr_q[PRBS_WIDTH:5] <= #TCQ prbs_seed_i[PRBS_WIDTH-1:4];
end
else if (clk_en_i && (~phy_if_empty_r || ~prbs_rdlvl_start)) begin
lfsr_q[PRBS_WIDTH:31] <= #TCQ lfsr_q[PRBS_WIDTH-1:30];
lfsr_q[30] <= #TCQ lfsr_q[16] ^ lfsr_q[13] ^ lfsr_q[5] ^ lfsr_q[1];
lfsr_q[29:9] <= #TCQ lfsr_q[28:8];
lfsr_q[8] <= #TCQ lfsr_q[32] ^ lfsr_q[7];
lfsr_q[7] <= #TCQ lfsr_q[32] ^ lfsr_q[6];
lfsr_q[6:4] <= #TCQ lfsr_q[5:3];
lfsr_q[3] <= #TCQ lfsr_q[32] ^ lfsr_q[2];
lfsr_q[2] <= #TCQ lfsr_q[1] ;
lfsr_q[1] <= #TCQ lfsr_q[32];
end
end
always @ (lfsr_q[PRBS_WIDTH:1]) begin
prbs = lfsr_q[PRBS_WIDTH:1];
end
//******************************************************************************
// Complex pattern BRAM
//******************************************************************************
localparam BRAM_ADDR_WIDTH = 8;
localparam BRAM_DATA_WIDTH = 18;
localparam BRAM_DEPTH = 256;
integer i;
(* RAM_STYLE = "distributed" *) reg [BRAM_ADDR_WIDTH - 1:0] rd_addr;
//reg [BRAM_DATA_WIDTH - 1:0] mem[0:BRAM_DEPTH - 1];
reg [BRAM_DATA_WIDTH - 1:0] mem_out;
reg [BRAM_DATA_WIDTH - 3:0] dout_o;
reg [DQ_WIDTH-1:0] sel;
reg [DQ_WIDTH-1:0] dout_rise0;
reg [DQ_WIDTH-1:0] dout_fall0;
reg [DQ_WIDTH-1:0] dout_rise1;
reg [DQ_WIDTH-1:0] dout_fall1;
reg [DQ_WIDTH-1:0] dout_rise2;
reg [DQ_WIDTH-1:0] dout_fall2;
reg [DQ_WIDTH-1:0] dout_rise3;
reg [DQ_WIDTH-1:0] dout_fall3;
// VCCO noise injection pattern with matching victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
always @ (rd_addr) begin
case (rd_addr)
8'd0 : mem_out = {2'b11, 8'b10101010,8'b10101010}; //1 read
8'd1 : mem_out = {2'b01, 8'b11001100,8'b11001100}; //2 reads
8'd2 : mem_out = {2'b10, 8'b11001100,8'b11001100}; //2 reads
8'd3 : mem_out = {2'b01, 8'b11100011,8'b11100011}; //3 reads
8'd4 : mem_out = {2'b00, 8'b10001110,8'b10001110}; //3 reads
8'd5 : mem_out = {2'b10, 8'b00111000,8'b00111000}; //3 reads
8'd6 : mem_out = {2'b01, 8'b11110000,8'b11110000}; //4 reads
8'd7 : mem_out = {2'b00, 8'b11110000,8'b11110000}; //4 reads
8'd8 : mem_out = {2'b00, 8'b11110000,8'b11110000}; //4 reads
8'd9 : mem_out = {2'b10, 8'b11110000,8'b11110000}; //4 reads
8'd10 : mem_out = {2'b01, 8'b11111000,8'b11111000}; //5 reads
8'd11 : mem_out = {2'b00, 8'b00111110,8'b00111110}; //5 reads
8'd12 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //5 reads
8'd13 : mem_out = {2'b00, 8'b10000011,8'b10000011}; //5 reads
8'd14 : mem_out = {2'b10, 8'b11100000,8'b11100000}; //5 reads
8'd15 : mem_out = {2'b01, 8'b11111100,8'b11111100}; //6 reads
8'd16 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //6 reads
8'd17 : mem_out = {2'b00, 8'b11000000,8'b11000000}; //6 reads
8'd18 : mem_out = {2'b00, 8'b11111100,8'b11111100}; //6 reads
8'd19 : mem_out = {2'b00, 8'b00001111,8'b00001111}; //6 reads
8'd20 : mem_out = {2'b10, 8'b11000000,8'b11000000}; //6 reads
// VCCO noise injection pattern with non-matching victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
8'd21 : mem_out = {2'b11, 8'b10101010,8'b01010101}; //1 read
8'd22 : mem_out = {2'b01, 8'b11001100,8'b00110011}; //2 reads
8'd23 : mem_out = {2'b10, 8'b11001100,8'b00110011}; //2 reads
8'd24 : mem_out = {2'b01, 8'b11100011,8'b00011100}; //3 reads
8'd25 : mem_out = {2'b00, 8'b10001110,8'b01110001}; //3 reads
8'd26 : mem_out = {2'b10, 8'b00111000,8'b11000111}; //3 reads
8'd27 : mem_out = {2'b01, 8'b11110000,8'b00001111}; //4 reads
8'd28 : mem_out = {2'b00, 8'b11110000,8'b00001111}; //4 reads
8'd29 : mem_out = {2'b00, 8'b11110000,8'b00001111}; //4 reads
8'd30 : mem_out = {2'b10, 8'b11110000,8'b00001111}; //4 reads
8'd31 : mem_out = {2'b01, 8'b11111000,8'b00000111}; //5 reads
8'd32 : mem_out = {2'b00, 8'b00111110,8'b11000001}; //5 reads
8'd33 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //5 reads
8'd34 : mem_out = {2'b00, 8'b10000011,8'b01111100}; //5 reads
8'd35 : mem_out = {2'b10, 8'b11100000,8'b00011111}; //5 reads
8'd36 : mem_out = {2'b01, 8'b11111100,8'b00000011}; //6 reads
8'd37 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //6 reads
8'd38 : mem_out = {2'b00, 8'b11000000,8'b00111111}; //6 reads
8'd39 : mem_out = {2'b00, 8'b11111100,8'b00000011}; //6 reads
8'd40 : mem_out = {2'b00, 8'b00001111,8'b11110000}; //6 reads
8'd41 : mem_out = {2'b10, 8'b11000000,8'b00111111}; //6 reads
// VCCAUX noise injection pattern with ISI pattern on victim (reads with gaps)
// content format
// {aggressor pattern, victim pattern}
8'd42 : mem_out = {2'b01, 8'b10110100,8'b01010111}; //3 reads
8'd43 : mem_out = {2'b00, 8'b10110100,8'b01101111}; //3 reads
8'd44 : mem_out = {2'b10, 8'b10110100,8'b11000000}; //3 reads
8'd45 : mem_out = {2'b01, 8'b10100010,8'b10000100}; //4 reads
8'd46 : mem_out = {2'b00, 8'b10001010,8'b00110001}; //4 reads
8'd47 : mem_out = {2'b00, 8'b00101000,8'b01000111}; //4 reads
8'd48 : mem_out = {2'b10, 8'b10100010,8'b00100101}; //4 reads
8'd49 : mem_out = {2'b01, 8'b10101111,8'b10011010}; //5 reads
8'd50 : mem_out = {2'b00, 8'b01010000,8'b01111010}; //5 reads
8'd51 : mem_out = {2'b00, 8'b10101111,8'b10010101}; //5 reads
8'd52 : mem_out = {2'b00, 8'b01010000,8'b11011011}; //5 reads
8'd53 : mem_out = {2'b10, 8'b10101111,8'b11110000}; //5 reads
8'd54 : mem_out = {2'b01, 8'b10101000,8'b00100001}; //7 reads
8'd55 : mem_out = {2'b00, 8'b00101010,8'b10001010}; //7 reads
8'd56 : mem_out = {2'b00, 8'b00001010,8'b00100101}; //7 reads
8'd57 : mem_out = {2'b00, 8'b10000010,8'b10011010}; //7 reads
8'd58 : mem_out = {2'b00, 8'b10100000,8'b01111010}; //7 reads
8'd59 : mem_out = {2'b00, 8'b10101000,8'b10111111}; //7 reads
8'd60 : mem_out = {2'b10, 8'b00101010,8'b01010111}; //7 reads
8'd61 : mem_out = {2'b01, 8'b10101011,8'b01101111}; //8 reads
8'd62 : mem_out = {2'b00, 8'b11110101,8'b11000000}; //8 reads
8'd63 : mem_out = {2'b00, 8'b01000000,8'b10000100}; //8 reads
8'd64 : mem_out = {2'b00, 8'b10101011,8'b00110001}; //8 reads
8'd65 : mem_out = {2'b00, 8'b11110101,8'b01000111}; //8 reads
8'd66 : mem_out = {2'b00, 8'b01000000,8'b00100101}; //8 reads
8'd67 : mem_out = {2'b00, 8'b10101011,8'b10011010}; //8 reads
8'd68 : mem_out = {2'b10, 8'b11110101,8'b01111010}; //8 reads
8'd69 : mem_out = {2'b01, 8'b10101010,8'b10010101}; //9 reads
8'd70 : mem_out = {2'b00, 8'b00000010,8'b11011011}; //9 reads
8'd71 : mem_out = {2'b00, 8'b10101000,8'b11110000}; //9 reads
8'd72 : mem_out = {2'b00, 8'b00001010,8'b00100001}; //9 reads
8'd73 : mem_out = {2'b00, 8'b10100000,8'b10001010}; //9 reads
8'd74 : mem_out = {2'b00, 8'b00101010,8'b00100101}; //9 reads
8'd75 : mem_out = {2'b00, 8'b10000000,8'b10011010}; //9 reads
8'd76 : mem_out = {2'b00, 8'b10101010,8'b01111010}; //9 reads
8'd77 : mem_out = {2'b10, 8'b00000010,8'b10111111}; //9 reads
8'd78 : mem_out = {2'b01, 8'b10101010,8'b01010111}; //10 reads
8'd79 : mem_out = {2'b00, 8'b11111111,8'b01101111}; //10 reads
8'd80 : mem_out = {2'b00, 8'b01010101,8'b11000000}; //10 reads
8'd81 : mem_out = {2'b00, 8'b00000000,8'b10000100}; //10 reads
8'd82 : mem_out = {2'b00, 8'b10101010,8'b00110001}; //10 reads
8'd83 : mem_out = {2'b00, 8'b11111111,8'b01000111}; //10 reads
8'd84 : mem_out = {2'b00, 8'b01010101,8'b00100101}; //10 reads
8'd85 : mem_out = {2'b00, 8'b00000000,8'b10011010}; //10 reads
8'd86 : mem_out = {2'b00, 8'b10101010,8'b01111010}; //10 reads
8'd87 : mem_out = {2'b10, 8'b11111111,8'b10010101}; //10 reads
8'd88 : mem_out = {2'b01, 8'b10101010,8'b11011011}; //12 reads
8'd89 : mem_out = {2'b00, 8'b10000000,8'b11110000}; //12 reads
8'd90 : mem_out = {2'b00, 8'b00101010,8'b00100001}; //12 reads
8'd91 : mem_out = {2'b00, 8'b10100000,8'b10001010}; //12 reads
8'd92 : mem_out = {2'b00, 8'b00001010,8'b00100101}; //12 reads
8'd93 : mem_out = {2'b00, 8'b10101000,8'b10011010}; //12 reads
8'd94 : mem_out = {2'b00, 8'b00000010,8'b01111010}; //12 reads
8'd95 : mem_out = {2'b00, 8'b10101010,8'b10111111}; //12 reads
8'd96 : mem_out = {2'b00, 8'b00000000,8'b01010111}; //12 reads
8'd97 : mem_out = {2'b00, 8'b10101010,8'b01101111}; //12 reads
8'd98 : mem_out = {2'b00, 8'b10000000,8'b11000000}; //12 reads
8'd99 : mem_out = {2'b10, 8'b00101010,8'b10000100}; //12 reads
8'd100 : mem_out = {2'b01, 8'b10101010,8'b00110001}; //13 reads
8'd101 : mem_out = {2'b00, 8'b10111111,8'b01000111}; //13 reads
8'd102 : mem_out = {2'b00, 8'b11110101,8'b00100101}; //13 reads
8'd103 : mem_out = {2'b00, 8'b01010100,8'b10011010}; //13 reads
8'd104 : mem_out = {2'b00, 8'b00000000,8'b01111010}; //13 reads
8'd105 : mem_out = {2'b00, 8'b10101010,8'b10010101}; //13 reads
8'd106 : mem_out = {2'b00, 8'b10111111,8'b11011011}; //13 reads
8'd107 : mem_out = {2'b00, 8'b11110101,8'b11110000}; //13 reads
8'd108 : mem_out = {2'b00, 8'b01010100,8'b00100001}; //13 reads
8'd109 : mem_out = {2'b00, 8'b00000000,8'b10001010}; //13 reads
8'd110 : mem_out = {2'b00, 8'b10101010,8'b00100101}; //13 reads
8'd111 : mem_out = {2'b00, 8'b10111111,8'b10011010}; //13 reads
8'd112 : mem_out = {2'b10, 8'b11110101,8'b01111010}; //13 reads
8'd113 : mem_out = {2'b01, 8'b10101010,8'b10111111}; //14 reads
8'd114 : mem_out = {2'b00, 8'b10100000,8'b01010111}; //14 reads
8'd115 : mem_out = {2'b00, 8'b00000010,8'b01101111}; //14 reads
8'd116 : mem_out = {2'b00, 8'b10101010,8'b11000000}; //14 reads
8'd117 : mem_out = {2'b00, 8'b10000000,8'b10000100}; //14 reads
8'd118 : mem_out = {2'b00, 8'b00001010,8'b00110001}; //14 reads
8'd119 : mem_out = {2'b00, 8'b10101010,8'b01000111}; //14 reads
8'd120 : mem_out = {2'b00, 8'b00000000,8'b00100101}; //14 reads
8'd121 : mem_out = {2'b00, 8'b00101010,8'b10011010}; //14 reads
8'd122 : mem_out = {2'b00, 8'b10101000,8'b01111010}; //14 reads
8'd123 : mem_out = {2'b00, 8'b00000000,8'b10010101}; //14 reads
8'd124 : mem_out = {2'b00, 8'b10101010,8'b11011011}; //14 reads
8'd125 : mem_out = {2'b00, 8'b10100000,8'b11110000}; //14 reads
8'd126 : mem_out = {2'b10, 8'b00000010,8'b00100001}; //14 reads
// ISI pattern (Back-to-back reads)
// content format
// {aggressor pattern, victim pattern}
8'd127 : mem_out = {2'b01, 8'b01010111,8'b01010111};
8'd128 : mem_out = {2'b00, 8'b01101111,8'b01101111};
8'd129 : mem_out = {2'b00, 8'b11000000,8'b11000000};
8'd130 : mem_out = {2'b00, 8'b10000110,8'b10000100};
8'd131 : mem_out = {2'b00, 8'b00101000,8'b00110001};
8'd132 : mem_out = {2'b00, 8'b11100100,8'b01000111};
8'd133 : mem_out = {2'b00, 8'b10110011,8'b00100101};
8'd134 : mem_out = {2'b00, 8'b01001111,8'b10011011};
8'd135 : mem_out = {2'b00, 8'b10110101,8'b01010101};
8'd136 : mem_out = {2'b00, 8'b10110101,8'b01010101};
8'd137 : mem_out = {2'b00, 8'b10000111,8'b10011000};
8'd138 : mem_out = {2'b00, 8'b11100011,8'b00011100};
8'd139 : mem_out = {2'b00, 8'b00001010,8'b11110101};
8'd140 : mem_out = {2'b00, 8'b11010100,8'b00101011};
8'd141 : mem_out = {2'b00, 8'b01001000,8'b10110111};
8'd142 : mem_out = {2'b00, 8'b00011111,8'b11100000};
8'd143 : mem_out = {2'b00, 8'b10111100,8'b01000011};
8'd144 : mem_out = {2'b00, 8'b10001111,8'b00010100};
8'd145 : mem_out = {2'b00, 8'b10110100,8'b01001011};
8'd146 : mem_out = {2'b00, 8'b11001011,8'b00110100};
8'd147 : mem_out = {2'b00, 8'b00001010,8'b11110101};
8'd148 : mem_out = {2'b00, 8'b10000000,8'b00000000};
//Additional for ISI
8'd149 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd150 : mem_out = {2'b00, 8'b01010101,8'b01010101};
8'd151 : mem_out = {2'b00, 8'b01010101,8'b01010101};
8'd152 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd153 : mem_out = {2'b00, 8'b00000000,8'b00000000};
8'd154 : mem_out = {2'b00, 8'b01010101,8'b00101010};
8'd155 : mem_out = {2'b00, 8'b01010101,8'b10101010};
8'd156 : mem_out = {2'b10, 8'b00000000,8'b10000000};
//Available
8'd157 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd158 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd159 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd160 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd161 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd162 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd163 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd164 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd165 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd166 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd167 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd168 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd169 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd170 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd171 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd172 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd173 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd174 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd175 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd176 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd177 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd178 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd179 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd180 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd181 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd182 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd183 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd184 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd185 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd186 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd187 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd188 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd189 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd190 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd191 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd192 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd193 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd194 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd195 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd196 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd197 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd198 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd199 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd200 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd201 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd202 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd203 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd204 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd205 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd206 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd207 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd208 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd209 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd210 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd211 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd212 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd213 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd214 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd215 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd216 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd217 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd218 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd219 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd220 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd221 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd222 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd223 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd224 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd225 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd226 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd227 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd228 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd229 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd230 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd231 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd232 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd233 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd234 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd235 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd236 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd237 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd238 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd239 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd240 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd241 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd242 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd243 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd244 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd245 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd246 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd247 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd248 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd249 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd250 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd251 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd252 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd253 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd254 : mem_out = {2'b00, 8'b00000001,8'b00000001};
8'd255 : mem_out = {2'b00, 8'b00000001,8'b00000001};
endcase
end
always @ (posedge clk_i) begin
if (rst_i | reset_rd_addr)
rd_addr <= #TCQ 'b0;
//rd_addr for complex oclkdelay calib
else if (clk_en_i && prbs_rdlvl_done && (~phy_if_empty_r || ~complex_wr_done)) begin
if (rd_addr == 'd156) rd_addr <= #TCQ 'b0;
else rd_addr <= #TCQ rd_addr + 1;
end
//rd_addr for complex rdlvl
else if (clk_en_i && (~phy_if_empty_r || (~prbs_rdlvl_start && ~complex_wr_done))) begin
if (rd_addr == 'd148) rd_addr <= #TCQ 'b0;
else rd_addr <= #TCQ rd_addr+1;
end
end
// Each pattern can be disabled independently
// When disabled zeros are written to and read from the DRAM
always @ (posedge clk_i) begin
if ((rd_addr < 42) && VCCO_PAT_EN)
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else if ((rd_addr < 127) && VCCAUX_PAT_EN)
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else if (ISI_PAT_EN && (rd_addr > 126))
dout_o <= #TCQ mem_out[BRAM_DATA_WIDTH-3:0];
else
dout_o <= #TCQ 'd0;
end
reg prbs_ignore_first_byte_r;
always @(posedge clk_i) prbs_ignore_first_byte_r <= #TCQ mem_out[16];
assign prbs_ignore_first_byte = prbs_ignore_first_byte_r;
reg prbs_ignore_last_bytes_r;
always @(posedge clk_i) prbs_ignore_last_bytes_r <= #TCQ mem_out[17];
assign prbs_ignore_last_bytes = prbs_ignore_last_bytes_r;
generate
if (FIXED_VICTIM == "TRUE") begin: victim_sel_fixed
// Fixed victim bit 3
always @(posedge clk_i)
sel <= #TCQ {DQ_WIDTH/8{8'h08}};
end else begin: victim_sel_rotate
// One-hot victim select
always @(posedge clk_i)
if (rst_i)
sel <= #TCQ 'd0;
else begin
for (i = 0; i < DQ_WIDTH; i = i+1) begin
if (i == byte_cnt*8+victim_sel)
sel[i] <= #TCQ 1'b1;
else
sel[i] <= #TCQ 1'b0;
end
end
end
endgenerate
// construct 8 X DATA_WIDTH output bus
always @(*)
for (i = 0; i < DQ_WIDTH; i = i+1) begin
dout_rise0[i] = (dout_o[7]&&sel[i] || dout_o[15]&&~sel[i]);
dout_fall0[i] = (dout_o[6]&&sel[i] || dout_o[14]&&~sel[i]);
dout_rise1[i] = (dout_o[5]&&sel[i] || dout_o[13]&&~sel[i]);
dout_fall1[i] = (dout_o[4]&&sel[i] || dout_o[12]&&~sel[i]);
dout_rise2[i] = (dout_o[3]&&sel[i] || dout_o[11]&&~sel[i]);
dout_fall2[i] = (dout_o[2]&&sel[i] || dout_o[10]&&~sel[i]);
dout_rise3[i] = (dout_o[1]&&sel[i] || dout_o[9]&&~sel[i]);
dout_fall3[i] = (dout_o[0]&&sel[i] || dout_o[8]&&~sel[i]);
end
assign prbs_o = {dout_fall3, dout_rise3, dout_fall2, dout_rise2, dout_fall1, dout_rise1, dout_fall0, dout_rise0};
assign dbg_prbs_gen[9] = phy_if_empty_r;
assign dbg_prbs_gen[8] = clk_en_i;
assign dbg_prbs_gen[7:0] = rd_addr[7:0];
endmodule
|
module mig_7series_v2_3_ui_cmd #
(
parameter TCQ = 100,
parameter ADDR_WIDTH = 33,
parameter BANK_WIDTH = 3,
parameter COL_WIDTH = 12,
parameter DATA_BUF_ADDR_WIDTH = 5,
parameter RANK_WIDTH = 2,
parameter ROW_WIDTH = 16,
parameter RANKS = 4,
parameter MEM_ADDR_ORDER = "BANK_ROW_COLUMN"
)
(/*AUTOARG*/
// Outputs
app_rdy, use_addr, rank, bank, row, col, size, cmd, hi_priority,
rd_accepted, wr_accepted, data_buf_addr,
// Inputs
rst, clk, accept_ns, rd_buf_full, wr_req_16, app_addr, app_cmd,
app_sz, app_hi_pri, app_en, wr_data_buf_addr, rd_data_buf_addr_r
);
input rst;
input clk;
input accept_ns;
input rd_buf_full;
input wr_req_16;
wire app_rdy_ns = accept_ns && ~rd_buf_full && ~wr_req_16;
reg app_rdy_r = 1'b0 /* synthesis syn_maxfan = 10 */;
always @(posedge clk) app_rdy_r <= #TCQ app_rdy_ns;
output wire app_rdy;
assign app_rdy = app_rdy_r;
input [ADDR_WIDTH-1:0] app_addr;
input [2:0] app_cmd;
input app_sz;
input app_hi_pri;
input app_en;
reg [ADDR_WIDTH-1:0] app_addr_r1 = {ADDR_WIDTH{1'b0}};
reg [ADDR_WIDTH-1:0] app_addr_r2 = {ADDR_WIDTH{1'b0}};
reg [2:0] app_cmd_r1;
reg [2:0] app_cmd_r2;
reg app_sz_r1;
reg app_sz_r2;
reg app_hi_pri_r1;
reg app_hi_pri_r2;
reg app_en_r1;
reg app_en_r2;
wire [ADDR_WIDTH-1:0] app_addr_ns1 = app_rdy_r && app_en ? app_addr : app_addr_r1;
wire [ADDR_WIDTH-1:0] app_addr_ns2 = app_rdy_r ? app_addr_r1 : app_addr_r2;
wire [2:0] app_cmd_ns1 = app_rdy_r ? app_cmd : app_cmd_r1;
wire [2:0] app_cmd_ns2 = app_rdy_r ? app_cmd_r1 : app_cmd_r2;
wire app_sz_ns1 = app_rdy_r ? app_sz : app_sz_r1;
wire app_sz_ns2 = app_rdy_r ? app_sz_r1 : app_sz_r2;
wire app_hi_pri_ns1 = app_rdy_r ? app_hi_pri : app_hi_pri_r1;
wire app_hi_pri_ns2 = app_rdy_r ? app_hi_pri_r1 : app_hi_pri_r2;
wire app_en_ns1 = ~rst && (app_rdy_r ? app_en : app_en_r1);
wire app_en_ns2 = ~rst && (app_rdy_r ? app_en_r1 : app_en_r2);
always @(posedge clk) begin
if (rst) begin
app_addr_r1 <= #TCQ {ADDR_WIDTH{1'b0}};
app_addr_r2 <= #TCQ {ADDR_WIDTH{1'b0}};
end else begin
app_addr_r1 <= #TCQ app_addr_ns1;
app_addr_r2 <= #TCQ app_addr_ns2;
end
app_cmd_r1 <= #TCQ app_cmd_ns1;
app_cmd_r2 <= #TCQ app_cmd_ns2;
app_sz_r1 <= #TCQ app_sz_ns1;
app_sz_r2 <= #TCQ app_sz_ns2;
app_hi_pri_r1 <= #TCQ app_hi_pri_ns1;
app_hi_pri_r2 <= #TCQ app_hi_pri_ns2;
app_en_r1 <= #TCQ app_en_ns1;
app_en_r2 <= #TCQ app_en_ns2;
end // always @ (posedge clk)
wire use_addr_lcl = app_en_r2 && app_rdy_r;
output wire use_addr;
assign use_addr = use_addr_lcl;
output wire [RANK_WIDTH-1:0] rank;
output wire [BANK_WIDTH-1:0] bank;
output wire [ROW_WIDTH-1:0] row;
output wire [COL_WIDTH-1:0] col;
output wire size;
output wire [2:0] cmd;
output wire hi_priority;
/* assign col = app_rdy_r
? app_addr_r1[0+:COL_WIDTH]
: app_addr_r2[0+:COL_WIDTH];*/
generate
begin
if (MEM_ADDR_ORDER == "TG_TEST")
begin
assign col[4:0] = app_rdy_r
? app_addr_r1[0+:5]
: app_addr_r2[0+:5];
if (RANKS==1)
begin
assign col[COL_WIDTH-1:COL_WIDTH-2] = app_rdy_r
? app_addr_r1[5+3+BANK_WIDTH+:2]
: app_addr_r2[5+3+BANK_WIDTH+:2];
assign col[COL_WIDTH-3:5] = app_rdy_r
? app_addr_r1[5+3+BANK_WIDTH+2+2+:COL_WIDTH-7]
: app_addr_r2[5+3+BANK_WIDTH+2+2+:COL_WIDTH-7];
end
else
begin
assign col[COL_WIDTH-1:COL_WIDTH-2] = app_rdy_r
? app_addr_r1[5+3+BANK_WIDTH+RANK_WIDTH+:2]
: app_addr_r2[5+3+BANK_WIDTH+RANK_WIDTH+:2];
assign col[COL_WIDTH-3:5] = app_rdy_r
? app_addr_r1[5+3+BANK_WIDTH+RANK_WIDTH+2+2+:COL_WIDTH-7]
: app_addr_r2[5+3+BANK_WIDTH+RANK_WIDTH+2+2+:COL_WIDTH-7];
end
assign row[2:0] = app_rdy_r
? app_addr_r1[5+:3]
: app_addr_r2[5+:3];
if (RANKS==1)
begin
assign row[ROW_WIDTH-1:ROW_WIDTH-2] = app_rdy_r
? app_addr_r1[5+3+BANK_WIDTH+2+:2]
: app_addr_r2[5+3+BANK_WIDTH+2+:2];
assign row[ROW_WIDTH-3:3] = app_rdy_r
? app_addr_r1[5+3+BANK_WIDTH+2+2+COL_WIDTH-7+:ROW_WIDTH-5]
: app_addr_r2[5+3+BANK_WIDTH+2+2+COL_WIDTH-7+:ROW_WIDTH-5];
end
else
begin
assign row[ROW_WIDTH-1:ROW_WIDTH-2] = app_rdy_r
? app_addr_r1[5+3+BANK_WIDTH+RANK_WIDTH+2+:2]
: app_addr_r2[5+3+BANK_WIDTH+RANK_WIDTH+2+:2];
assign row[ROW_WIDTH-3:3] = app_rdy_r
? app_addr_r1[5+3+BANK_WIDTH+RANK_WIDTH+2+2+COL_WIDTH-7+:ROW_WIDTH-5]
: app_addr_r2[5+3+BANK_WIDTH+RANK_WIDTH+2+2+COL_WIDTH-7+:ROW_WIDTH-5];
end
assign bank = app_rdy_r
? app_addr_r1[5+3+:BANK_WIDTH]
: app_addr_r2[5+3+:BANK_WIDTH];
assign rank = (RANKS == 1)
? 1'b0
: app_rdy_r
? app_addr_r1[5+3+BANK_WIDTH+:RANK_WIDTH]
: app_addr_r2[5+3+BANK_WIDTH+:RANK_WIDTH];
end
else if (MEM_ADDR_ORDER == "ROW_BANK_COLUMN")
begin
assign col = app_rdy_r
? app_addr_r1[0+:COL_WIDTH]
: app_addr_r2[0+:COL_WIDTH];
assign row = app_rdy_r
? app_addr_r1[COL_WIDTH+BANK_WIDTH+:ROW_WIDTH]
: app_addr_r2[COL_WIDTH+BANK_WIDTH+:ROW_WIDTH];
assign bank = app_rdy_r
? app_addr_r1[COL_WIDTH+:BANK_WIDTH]
: app_addr_r2[COL_WIDTH+:BANK_WIDTH];
assign rank = (RANKS == 1)
? 1'b0
: app_rdy_r
? app_addr_r1[COL_WIDTH+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH]
: app_addr_r2[COL_WIDTH+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH];
end
else
begin
assign col = app_rdy_r
? app_addr_r1[0+:COL_WIDTH]
: app_addr_r2[0+:COL_WIDTH];
assign row = app_rdy_r
? app_addr_r1[COL_WIDTH+:ROW_WIDTH]
: app_addr_r2[COL_WIDTH+:ROW_WIDTH];
assign bank = app_rdy_r
? app_addr_r1[COL_WIDTH+ROW_WIDTH+:BANK_WIDTH]
: app_addr_r2[COL_WIDTH+ROW_WIDTH+:BANK_WIDTH];
assign rank = (RANKS == 1)
? 1'b0
: app_rdy_r
? app_addr_r1[COL_WIDTH+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH]
: app_addr_r2[COL_WIDTH+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH];
end
end
endgenerate
/* assign rank = (RANKS == 1)
? 1'b0
: app_rdy_r
? app_addr_r1[COL_WIDTH+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH]
: app_addr_r2[COL_WIDTH+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH];*/
assign size = app_rdy_r
? app_sz_r1
: app_sz_r2;
assign cmd = app_rdy_r
? app_cmd_r1
: app_cmd_r2;
assign hi_priority = app_rdy_r
? app_hi_pri_r1
: app_hi_pri_r2;
wire request_accepted = use_addr_lcl && app_rdy_r;
wire rd = app_cmd_r2[1:0] == 2'b01;
wire wr = app_cmd_r2[1:0] == 2'b00;
wire wr_bytes = app_cmd_r2[1:0] == 2'b11;
wire write = wr || wr_bytes;
output wire rd_accepted;
assign rd_accepted = request_accepted && rd;
output wire wr_accepted;
assign wr_accepted = request_accepted && write;
input [DATA_BUF_ADDR_WIDTH-1:0] wr_data_buf_addr;
input [DATA_BUF_ADDR_WIDTH-1:0] rd_data_buf_addr_r;
output wire [DATA_BUF_ADDR_WIDTH-1:0] data_buf_addr;
assign data_buf_addr = ~write ? rd_data_buf_addr_r : wr_data_buf_addr;
endmodule
|
module outputs)
wire act_wait_r; // From bank_state0 of bank_state.v
wire allow_auto_pre; // From bank_state0 of bank_state.v
wire auto_pre_r; // From bank_queue0 of bank_queue.v
wire bank_wait_in_progress; // From bank_state0 of bank_state.v
wire order_q_zero; // From bank_queue0 of bank_queue.v
wire pass_open_bank_ns; // From bank_queue0 of bank_queue.v
wire pass_open_bank_r; // From bank_queue0 of bank_queue.v
wire pre_wait_r; // From bank_state0 of bank_state.v
wire precharge_bm_end; // From bank_state0 of bank_state.v
wire q_has_priority; // From bank_queue0 of bank_queue.v
wire q_has_rd; // From bank_queue0 of bank_queue.v
wire [nBANK_MACHS*2-1:0] rb_hit_busies_r; // From bank_queue0 of bank_queue.v
wire rcv_open_bank; // From bank_queue0 of bank_queue.v
wire rd_half_rmw; // From bank_state0 of bank_state.v
wire req_priority_r; // From bank_compare0 of bank_compare.v
wire row_hit_r; // From bank_compare0 of bank_compare.v
wire tail_r; // From bank_queue0 of bank_queue.v
wire wait_for_maint_r; // From bank_queue0 of bank_queue.v
// End of automatics
output idle_ns;
output req_wr_r;
output rd_wr_r;
output bm_end;
output idle_r;
output head_r;
output [RANK_WIDTH-1:0] req_rank_r;
output rb_hit_busy_r;
output passing_open_bank;
output maint_hit;
output [DATA_BUF_ADDR_WIDTH-1:0] req_data_buf_addr_r;
mig_7series_v2_3_bank_compare #
(/*AUTOINSTPARAM*/
// Parameters
.BANK_WIDTH (BANK_WIDTH),
.TCQ (TCQ),
.BURST_MODE (BURST_MODE),
.COL_WIDTH (COL_WIDTH),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.ECC (ECC),
.RANK_WIDTH (RANK_WIDTH),
.RANKS (RANKS),
.ROW_WIDTH (ROW_WIDTH))
bank_compare0
(/*AUTOINST*/
// Outputs
.req_data_buf_addr_r (req_data_buf_addr_r[DATA_BUF_ADDR_WIDTH-1:0]),
.req_periodic_rd_r (req_periodic_rd_r),
.req_size_r (req_size_r),
.rd_wr_r (rd_wr_r),
.req_rank_r (req_rank_r[RANK_WIDTH-1:0]),
.req_bank_r (req_bank_r[BANK_WIDTH-1:0]),
.req_row_r (req_row_r[ROW_WIDTH-1:0]),
.req_wr_r (req_wr_r),
.req_priority_r (req_priority_r),
.rb_hit_busy_r (rb_hit_busy_r),
.rb_hit_busy_ns (rb_hit_busy_ns),
.row_hit_r (row_hit_r),
.maint_hit (maint_hit),
.col_addr (col_addr[ROW_WIDTH-1:0]),
.req_ras (req_ras),
.req_cas (req_cas),
.row_cmd_wr (row_cmd_wr),
.row_addr (row_addr[ROW_WIDTH-1:0]),
.rank_busy_r (rank_busy_r[RANKS-1:0]),
// Inputs
.clk (clk),
.idle_ns (idle_ns),
.idle_r (idle_r),
.data_buf_addr (data_buf_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.periodic_rd_insert (periodic_rd_insert),
.size (size),
.cmd (cmd[2:0]),
.sending_col (sending_col),
.rank (rank[RANK_WIDTH-1:0]),
.periodic_rd_rank_r (periodic_rd_rank_r[RANK_WIDTH-1:0]),
.bank (bank[BANK_WIDTH-1:0]),
.row (row[ROW_WIDTH-1:0]),
.col (col[COL_WIDTH-1:0]),
.hi_priority (hi_priority),
.maint_rank_r (maint_rank_r[RANK_WIDTH-1:0]),
.maint_zq_r (maint_zq_r),
.maint_sre_r (maint_sre_r),
.auto_pre_r (auto_pre_r),
.rd_half_rmw (rd_half_rmw),
.act_wait_r (act_wait_r));
mig_7series_v2_3_bank_state #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.BURST_MODE (BURST_MODE),
.CWL (CWL),
.DATA_BUF_ADDR_WIDTH (DATA_BUF_ADDR_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.ECC (ECC),
.ID (ID),
.nBANK_MACHS (nBANK_MACHS),
.nCK_PER_CLK (nCK_PER_CLK),
.nOP_WAIT (nOP_WAIT),
.nRAS_CLKS (nRAS_CLKS),
.nRP (nRP),
.nRTP (nRTP),
.nRCD (nRCD),
.nWTP_CLKS (nWTP_CLKS),
.ORDERING (ORDERING),
.RANKS (RANKS),
.RANK_WIDTH (RANK_WIDTH),
.RAS_TIMER_WIDTH (RAS_TIMER_WIDTH),
.STARVE_LIMIT (STARVE_LIMIT))
bank_state0
(/*AUTOINST*/
// Outputs
.start_rcd (start_rcd),
.act_wait_r (act_wait_r),
.rd_half_rmw (rd_half_rmw),
.ras_timer_ns (ras_timer_ns[RAS_TIMER_WIDTH-1:0]),
.end_rtp (end_rtp),
.bank_wait_in_progress (bank_wait_in_progress),
.start_pre_wait (start_pre_wait),
.op_exit_req (op_exit_req),
.pre_wait_r (pre_wait_r),
.allow_auto_pre (allow_auto_pre),
.precharge_bm_end (precharge_bm_end),
.demand_act_priority (demand_act_priority),
.rts_row (rts_row),
.rts_pre (rts_pre),
.act_this_rank_r (act_this_rank_r[RANKS-1:0]),
.demand_priority (demand_priority),
.col_rdy_wr (col_rdy_wr),
.rts_col (rts_col),
.wr_this_rank_r (wr_this_rank_r[RANKS-1:0]),
.rd_this_rank_r (rd_this_rank_r[RANKS-1:0]),
// Inputs
.clk (clk),
.rst (rst),
.bm_end (bm_end),
.pass_open_bank_r (pass_open_bank_r),
.sending_row (sending_row),
.sending_pre (sending_pre),
.rcv_open_bank (rcv_open_bank),
.sending_col (sending_col),
.rd_wr_r (rd_wr_r),
.req_wr_r (req_wr_r),
.rd_data_addr (rd_data_addr[DATA_BUF_ADDR_WIDTH-1:0]),
.req_data_buf_addr_r (req_data_buf_addr_r[DATA_BUF_ADDR_WIDTH-1:0]),
.phy_rddata_valid (phy_rddata_valid),
.rd_rmw (rd_rmw),
.ras_timer_ns_in (ras_timer_ns_in[(2*(RAS_TIMER_WIDTH*nBANK_MACHS))-1:0]),
.rb_hit_busies_r (rb_hit_busies_r[(nBANK_MACHS*2)-1:0]),
.idle_r (idle_r),
.passing_open_bank (passing_open_bank),
.low_idle_cnt_r (low_idle_cnt_r),
.op_exit_grant (op_exit_grant),
.tail_r (tail_r),
.auto_pre_r (auto_pre_r),
.pass_open_bank_ns (pass_open_bank_ns),
.phy_mc_cmd_full (phy_mc_cmd_full),
.phy_mc_ctl_full (phy_mc_ctl_full),
.phy_mc_data_full (phy_mc_data_full),
.rnk_config (rnk_config[RANK_WIDTH-1:0]),
.rnk_config_strobe (rnk_config_strobe),
.rnk_config_kill_rts_col (rnk_config_kill_rts_col),
.rnk_config_valid_r (rnk_config_valid_r),
.rtc (rtc),
.req_rank_r (req_rank_r[RANK_WIDTH-1:0]),
.req_rank_r_in (req_rank_r_in[(RANK_WIDTH*nBANK_MACHS*2)-1:0]),
.start_rcd_in (start_rcd_in[(nBANK_MACHS*2)-1:0]),
.inhbt_act_faw_r (inhbt_act_faw_r[RANKS-1:0]),
.wait_for_maint_r (wait_for_maint_r),
.head_r (head_r),
.sent_row (sent_row),
.demand_act_priority_in (demand_act_priority_in[(nBANK_MACHS*2)-1:0]),
.order_q_zero (order_q_zero),
.sent_col (sent_col),
.q_has_rd (q_has_rd),
.q_has_priority (q_has_priority),
.req_priority_r (req_priority_r),
.idle_ns (idle_ns),
.demand_priority_in (demand_priority_in[(nBANK_MACHS*2)-1:0]),
.inhbt_rd (inhbt_rd[RANKS-1:0]),
.inhbt_wr (inhbt_wr[RANKS-1:0]),
.dq_busy_data (dq_busy_data));
mig_7series_v2_3_bank_queue #
(/*AUTOINSTPARAM*/
// Parameters
.TCQ (TCQ),
.BM_CNT_WIDTH (BM_CNT_WIDTH),
.nBANK_MACHS (nBANK_MACHS),
.ORDERING (ORDERING),
.ID (ID))
bank_queue0
(/*AUTOINST*/
// Outputs
.head_r (head_r),
.tail_r (tail_r),
.idle_ns (idle_ns),
.idle_r (idle_r),
.pass_open_bank_ns (pass_open_bank_ns),
.pass_open_bank_r (pass_open_bank_r),
.auto_pre_r (auto_pre_r),
.bm_end (bm_end),
.passing_open_bank (passing_open_bank),
.ordered_issued (ordered_issued),
.ordered_r (ordered_r),
.order_q_zero (order_q_zero),
.rcv_open_bank (rcv_open_bank),
.rb_hit_busies_r (rb_hit_busies_r[nBANK_MACHS*2-1:0]),
.q_has_rd (q_has_rd),
.q_has_priority (q_has_priority),
.wait_for_maint_r (wait_for_maint_r),
// Inputs
.clk (clk),
.rst (rst),
.accept_internal_r (accept_internal_r),
.use_addr (use_addr),
.periodic_rd_ack_r (periodic_rd_ack_r),
.bm_end_in (bm_end_in[(nBANK_MACHS*2)-1:0]),
.idle_cnt (idle_cnt[BM_CNT_WIDTH-1:0]),
.rb_hit_busy_cnt (rb_hit_busy_cnt[BM_CNT_WIDTH-1:0]),
.accept_req (accept_req),
.rb_hit_busy_r (rb_hit_busy_r),
.maint_idle (maint_idle),
.maint_hit (maint_hit),
.row_hit_r (row_hit_r),
.pre_wait_r (pre_wait_r),
.allow_auto_pre (allow_auto_pre),
.sending_col (sending_col),
.req_wr_r (req_wr_r),
.rd_wr_r (rd_wr_r),
.bank_wait_in_progress (bank_wait_in_progress),
.precharge_bm_end (precharge_bm_end),
.adv_order_q (adv_order_q),
.order_cnt (order_cnt[BM_CNT_WIDTH-1:0]),
.rb_hit_busy_ns_in (rb_hit_busy_ns_in[(nBANK_MACHS*2)-1:0]),
.passing_open_bank_in (passing_open_bank_in[(nBANK_MACHS*2)-1:0]),
.was_wr (was_wr),
.maint_req_r (maint_req_r),
.was_priority (was_priority));
endmodule
|
module mig_7series_v2_3_arb_select #
(
parameter TCQ = 100,
parameter EVEN_CWL_2T_MODE = "OFF",
parameter ADDR_CMD_MODE = "1T",
parameter BANK_VECT_INDX = 11,
parameter BANK_WIDTH = 3,
parameter BURST_MODE = "8",
parameter CS_WIDTH = 4,
parameter CL = 5,
parameter CWL = 5,
parameter DATA_BUF_ADDR_VECT_INDX = 31,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter DRAM_TYPE = "DDR3",
parameter EARLY_WR_DATA_ADDR = "OFF",
parameter ECC = "OFF",
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2,
parameter nCS_PER_RANK = 1,
parameter CKE_ODT_AUX = "FALSE",
parameter nSLOTS = 2,
parameter RANKS = 1,
parameter RANK_VECT_INDX = 15,
parameter RANK_WIDTH = 2,
parameter ROW_VECT_INDX = 63,
parameter ROW_WIDTH = 16,
parameter RTT_NOM = "40",
parameter RTT_WR = "120",
parameter SLOT_0_CONFIG = 8'b0000_0101,
parameter SLOT_1_CONFIG = 8'b0000_1010
)
(
// Outputs
output wire col_periodic_rd,
output wire [RANK_WIDTH-1:0] col_ra,
output wire [BANK_WIDTH-1:0] col_ba,
output wire [ROW_WIDTH-1:0] col_a,
output wire col_rmw,
output wire col_rd_wr,
output wire col_size,
output wire [ROW_WIDTH-1:0] col_row,
output wire [DATA_BUF_ADDR_WIDTH-1:0] col_data_buf_addr,
output wire [DATA_BUF_ADDR_WIDTH-1:0] col_wr_data_buf_addr,
output wire [nCK_PER_CLK-1:0] mc_ras_n,
output wire [nCK_PER_CLK-1:0] mc_cas_n,
output wire [nCK_PER_CLK-1:0] mc_we_n,
output wire [nCK_PER_CLK*ROW_WIDTH-1:0] mc_address,
output wire [nCK_PER_CLK*BANK_WIDTH-1:0] mc_bank,
output wire [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] mc_cs_n,
output wire [1:0] mc_odt,
output wire [nCK_PER_CLK-1:0] mc_cke,
output wire [3:0] mc_aux_out0,
output wire [3:0] mc_aux_out1,
output [2:0] mc_cmd,
output wire [5:0] mc_data_offset,
output wire [5:0] mc_data_offset_1,
output wire [5:0] mc_data_offset_2,
output wire [1:0] mc_cas_slot,
output wire [RANK_WIDTH-1:0] rnk_config,
// Inputs
input clk,
input rst,
input init_calib_complete,
input [RANK_VECT_INDX:0] req_rank_r,
input [BANK_VECT_INDX:0] req_bank_r,
input [nBANK_MACHS-1:0] req_ras,
input [nBANK_MACHS-1:0] req_cas,
input [nBANK_MACHS-1:0] req_wr_r,
input [nBANK_MACHS-1:0] grant_row_r,
input [nBANK_MACHS-1:0] grant_pre_r,
input [ROW_VECT_INDX:0] row_addr,
input [nBANK_MACHS-1:0] row_cmd_wr,
input insert_maint_r1,
input maint_zq_r,
input maint_sre_r,
input maint_srx_r,
input [RANK_WIDTH-1:0] maint_rank_r,
input [nBANK_MACHS-1:0] req_periodic_rd_r,
input [nBANK_MACHS-1:0] req_size_r,
input [nBANK_MACHS-1:0] rd_wr_r,
input [ROW_VECT_INDX:0] req_row_r,
input [ROW_VECT_INDX:0] col_addr,
input [DATA_BUF_ADDR_VECT_INDX:0] req_data_buf_addr_r,
input [nBANK_MACHS-1:0] grant_col_r,
input [nBANK_MACHS-1:0] grant_col_wr,
input [6*RANKS-1:0] calib_rddata_offset,
input [6*RANKS-1:0] calib_rddata_offset_1,
input [6*RANKS-1:0] calib_rddata_offset_2,
input [5:0] col_channel_offset,
input [nBANK_MACHS-1:0] grant_config_r,
input rnk_config_strobe,
input [7:0] slot_0_present,
input [7:0] slot_1_present,
input send_cmd0_row,
input send_cmd0_col,
input send_cmd1_row,
input send_cmd1_col,
input send_cmd2_row,
input send_cmd2_col,
input send_cmd2_pre,
input send_cmd3_col,
input sent_col,
input cs_en0,
input cs_en1,
input cs_en2,
input cs_en3
);
localparam OUT_CMD_WIDTH = RANK_WIDTH + BANK_WIDTH + ROW_WIDTH + 1 + 1 + 1;
reg col_rd_wr_ns;
reg col_rd_wr_r = 1'b0;
reg [OUT_CMD_WIDTH-1:0] col_cmd_r = {OUT_CMD_WIDTH {1'b0}};
reg [OUT_CMD_WIDTH-1:0] row_cmd_r = {OUT_CMD_WIDTH {1'b0}};
// calib_rd_data_offset for currently targeted rank
reg [5:0] rank_rddata_offset_0;
reg [5:0] rank_rddata_offset_1;
reg [5:0] rank_rddata_offset_2;
// Toggle CKE[0] when entering and exiting self-refresh, disable CKE[1]
assign mc_aux_out0[0] = (maint_sre_r || maint_srx_r) & insert_maint_r1;
assign mc_aux_out0[2] = 1'b0;
reg cke_r;
reg cke_ns;
generate
if(CKE_ODT_AUX == "FALSE")begin
always @(posedge clk)
begin
if (rst)
cke_r = 1'b1;
else
cke_r = cke_ns;
end
always @(*)
begin
cke_ns = 1'b1;
if (maint_sre_r & insert_maint_r1)
cke_ns = 1'b0;
else if (cke_r==1'b0)
begin
if (maint_srx_r & insert_maint_r1)
cke_ns = 1'b1;
else
cke_ns = 1'b0;
end
end
end
endgenerate
// Disable ODT & CKE toggle enable high bits
assign mc_aux_out1 = 4'b0;
// implement PHY command word
assign mc_cmd[0] = sent_col;
assign mc_cmd[1] = EVEN_CWL_2T_MODE == "ON" ?
sent_col && col_rd_wr_r :
sent_col && col_rd_wr_ns;
assign mc_cmd[2] = ~sent_col;
// generate calib_rd_data_offset for current rank - only use rank 0 values for now
always @(calib_rddata_offset or calib_rddata_offset_1 or calib_rddata_offset_2) begin
rank_rddata_offset_0 = calib_rddata_offset[5:0];
rank_rddata_offset_1 = calib_rddata_offset_1[5:0];
rank_rddata_offset_2 = calib_rddata_offset_2[5:0];
end
// generate data offset
generate
if(EVEN_CWL_2T_MODE == "ON") begin : gen_mc_data_offset_even_cwl_2t
assign mc_data_offset = ~sent_col ?
6'b0 :
col_rd_wr_r ?
rank_rddata_offset_0 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
assign mc_data_offset_1 = ~sent_col ?
6'b0 :
col_rd_wr_r ?
rank_rddata_offset_1 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
assign mc_data_offset_2 = ~sent_col ?
6'b0 :
col_rd_wr_r ?
rank_rddata_offset_2 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
end
else begin : gen_mc_data_offset_not_even_cwl_2t
assign mc_data_offset = ~sent_col ?
6'b0 :
col_rd_wr_ns ?
rank_rddata_offset_0 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
assign mc_data_offset_1 = ~sent_col ?
6'b0 :
col_rd_wr_ns ?
rank_rddata_offset_1 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
assign mc_data_offset_2 = ~sent_col ?
6'b0 :
col_rd_wr_ns ?
rank_rddata_offset_2 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
end
endgenerate
assign mc_cas_slot = col_channel_offset[1:0];
// Based on arbitration results, select the row and column commands.
integer i;
reg [OUT_CMD_WIDTH-1:0] row_cmd_ns;
generate
begin : row_mux
wire [OUT_CMD_WIDTH-1:0] maint_cmd =
{maint_rank_r, // maintenance rank
row_cmd_r[15+:(BANK_WIDTH+ROW_WIDTH-11)],
// bank plus upper address bits
1'b0, // A10 = 0 for ZQCS
row_cmd_r[3+:10], // address bits [9:0]
// ZQ, SRX or SRE/REFRESH
(maint_zq_r ? 3'b110 : maint_srx_r ? 3'b111 : 3'b001)
};
always @(/*AS*/grant_row_r or insert_maint_r1 or maint_cmd
or req_bank_r or req_cas or req_rank_r or req_ras
or row_addr or row_cmd_r or row_cmd_wr or rst)
begin
row_cmd_ns = rst
? {RANK_WIDTH{1'b0}}
: insert_maint_r1
? maint_cmd
: row_cmd_r;
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_row_r[i])
row_cmd_ns = {req_rank_r[(RANK_WIDTH*i)+:RANK_WIDTH],
req_bank_r[(BANK_WIDTH*i)+:BANK_WIDTH],
row_addr[(ROW_WIDTH*i)+:ROW_WIDTH],
req_ras[i],
req_cas[i],
row_cmd_wr[i]};
end
if (ADDR_CMD_MODE == "2T" && nCK_PER_CLK == 2)
always @(posedge clk) row_cmd_r <= #TCQ row_cmd_ns;
end // row_mux
endgenerate
reg [OUT_CMD_WIDTH-1:0] pre_cmd_ns;
generate
if((nCK_PER_CLK == 4) && (ADDR_CMD_MODE != "2T")) begin : pre_mux
reg [OUT_CMD_WIDTH-1:0] pre_cmd_r = {OUT_CMD_WIDTH {1'b0}};
always @(/*AS*/grant_pre_r or req_bank_r or req_cas or req_rank_r or req_ras
or row_addr or pre_cmd_r or row_cmd_wr or rst)
begin
pre_cmd_ns = rst
? {RANK_WIDTH{1'b0}}
: pre_cmd_r;
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_pre_r[i])
pre_cmd_ns = {req_rank_r[(RANK_WIDTH*i)+:RANK_WIDTH],
req_bank_r[(BANK_WIDTH*i)+:BANK_WIDTH],
row_addr[(ROW_WIDTH*i)+:ROW_WIDTH],
req_ras[i],
req_cas[i],
row_cmd_wr[i]};
end
end // pre_mux
endgenerate
reg [OUT_CMD_WIDTH-1:0] col_cmd_ns;
generate
begin : col_mux
reg col_periodic_rd_ns;
reg col_periodic_rd_r;
reg col_rmw_ns;
reg col_rmw_r;
reg col_size_ns;
reg col_size_r;
reg [ROW_WIDTH-1:0] col_row_ns;
reg [ROW_WIDTH-1:0] col_row_r;
reg [DATA_BUF_ADDR_WIDTH-1:0] col_data_buf_addr_ns;
reg [DATA_BUF_ADDR_WIDTH-1:0] col_data_buf_addr_r;
always @(col_addr or col_cmd_r or col_data_buf_addr_r
or col_periodic_rd_r or col_rmw_r or col_row_r
or col_size_r or grant_col_r or rd_wr_r or req_bank_r
or req_data_buf_addr_r or req_periodic_rd_r
or req_rank_r or req_row_r or req_size_r or req_wr_r
or rst or col_rd_wr_r)
begin
col_periodic_rd_ns = ~rst && col_periodic_rd_r;
col_cmd_ns = {(rst ? {RANK_WIDTH{1'b0}}
: col_cmd_r[(OUT_CMD_WIDTH-1)-:RANK_WIDTH]),
((rst && ECC != "OFF")
? {OUT_CMD_WIDTH-3-RANK_WIDTH{1'b0}}
: col_cmd_r[3+:(OUT_CMD_WIDTH-3-RANK_WIDTH)]),
(rst ? 3'b0 : col_cmd_r[2:0])};
col_rmw_ns = col_rmw_r;
col_size_ns = rst ? 1'b0 : col_size_r;
col_row_ns = col_row_r;
col_rd_wr_ns = col_rd_wr_r;
col_data_buf_addr_ns = col_data_buf_addr_r;
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_col_r[i]) begin
col_periodic_rd_ns = req_periodic_rd_r[i];
col_cmd_ns = {req_rank_r[(RANK_WIDTH*i)+:RANK_WIDTH],
req_bank_r[(BANK_WIDTH*i)+:BANK_WIDTH],
col_addr[(ROW_WIDTH*i)+:ROW_WIDTH],
1'b1,
1'b0,
rd_wr_r[i]};
col_rmw_ns = req_wr_r[i] && rd_wr_r[i];
col_size_ns = req_size_r[i];
col_row_ns = req_row_r[(ROW_WIDTH*i)+:ROW_WIDTH];
col_rd_wr_ns = rd_wr_r[i];
col_data_buf_addr_ns =
req_data_buf_addr_r[(DATA_BUF_ADDR_WIDTH*i)+:DATA_BUF_ADDR_WIDTH];
end
end // always @ (...
if (EARLY_WR_DATA_ADDR == "OFF") begin : early_wr_data_addr_off
assign col_wr_data_buf_addr = col_data_buf_addr_ns;
end
else begin : early_wr_data_addr_on
reg [DATA_BUF_ADDR_WIDTH-1:0] col_wr_data_buf_addr_ns;
reg [DATA_BUF_ADDR_WIDTH-1:0] col_wr_data_buf_addr_r;
always @(/*AS*/col_wr_data_buf_addr_r or grant_col_wr
or req_data_buf_addr_r) begin
col_wr_data_buf_addr_ns = col_wr_data_buf_addr_r;
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_col_wr[i])
col_wr_data_buf_addr_ns =
req_data_buf_addr_r[(DATA_BUF_ADDR_WIDTH*i)+:DATA_BUF_ADDR_WIDTH];
end
always @(posedge clk) col_wr_data_buf_addr_r <=
#TCQ col_wr_data_buf_addr_ns;
assign col_wr_data_buf_addr = col_wr_data_buf_addr_ns;
end
always @(posedge clk) col_periodic_rd_r <= #TCQ col_periodic_rd_ns;
always @(posedge clk) col_rmw_r <= #TCQ col_rmw_ns;
always @(posedge clk) col_size_r <= #TCQ col_size_ns;
always @(posedge clk) col_data_buf_addr_r <=
#TCQ col_data_buf_addr_ns;
if (ECC != "OFF" || EVEN_CWL_2T_MODE == "ON") begin
always @(posedge clk) col_cmd_r <= #TCQ col_cmd_ns;
always @(posedge clk) col_row_r <= #TCQ col_row_ns;
end
always @(posedge clk) col_rd_wr_r <= #TCQ col_rd_wr_ns;
if(EVEN_CWL_2T_MODE == "ON") begin
assign col_periodic_rd = col_periodic_rd_r;
assign col_ra = col_cmd_r[3+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH];
assign col_ba = col_cmd_r[3+ROW_WIDTH+:BANK_WIDTH];
assign col_a = col_cmd_r[3+:ROW_WIDTH];
assign col_rmw = col_rmw_r;
assign col_rd_wr = col_rd_wr_r;
assign col_size = col_size_r;
assign col_row = col_row_r;
assign col_data_buf_addr = col_data_buf_addr_r;
end
else begin
assign col_periodic_rd = col_periodic_rd_ns;
assign col_ra = col_cmd_ns[3+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH];
assign col_ba = col_cmd_ns[3+ROW_WIDTH+:BANK_WIDTH];
assign col_a = col_cmd_ns[3+:ROW_WIDTH];
assign col_rmw = col_rmw_ns;
assign col_rd_wr = col_rd_wr_ns;
assign col_size = col_size_ns;
assign col_row = col_row_ns;
assign col_data_buf_addr = col_data_buf_addr_ns;
end
end // col_mux
endgenerate
reg [OUT_CMD_WIDTH-1:0] cmd0 = {OUT_CMD_WIDTH{1'b1}};
reg cke0;
always @(send_cmd0_row or send_cmd0_col or row_cmd_ns or row_cmd_r or col_cmd_ns or col_cmd_r or cke_ns or cke_r ) begin
cmd0 = {OUT_CMD_WIDTH{1'b1}};
if (send_cmd0_row) cmd0 = row_cmd_ns;
if (send_cmd0_row && EVEN_CWL_2T_MODE == "ON" && nCK_PER_CLK == 2) cmd0 = row_cmd_r;
if (send_cmd0_col) cmd0 = col_cmd_ns;
if (send_cmd0_col && EVEN_CWL_2T_MODE == "ON") cmd0 = col_cmd_r;
if (send_cmd0_row) cke0 = cke_ns;
else cke0 = cke_r ;
end
reg [OUT_CMD_WIDTH-1:0] cmd1 = {OUT_CMD_WIDTH{1'b1}};
generate
if ((nCK_PER_CLK == 2) || (nCK_PER_CLK == 4))
always @(send_cmd1_row or send_cmd1_col or row_cmd_ns or col_cmd_ns or pre_cmd_ns) begin
cmd1 = {OUT_CMD_WIDTH{1'b1}};
if (send_cmd1_row) cmd1 = row_cmd_ns;
if (send_cmd1_col) cmd1 = col_cmd_ns;
end
endgenerate
reg [OUT_CMD_WIDTH-1:0] cmd2 = {OUT_CMD_WIDTH{1'b1}};
reg [OUT_CMD_WIDTH-1:0] cmd3 = {OUT_CMD_WIDTH{1'b1}};
generate
if (nCK_PER_CLK == 4)
always @(send_cmd2_row or send_cmd2_col or send_cmd2_pre or send_cmd3_col or row_cmd_ns or col_cmd_ns or pre_cmd_ns) begin
cmd2 = {OUT_CMD_WIDTH{1'b1}};
cmd3 = {OUT_CMD_WIDTH{1'b1}};
if (send_cmd2_row) cmd2 = row_cmd_ns;
if (send_cmd2_col) cmd2 = col_cmd_ns;
if (send_cmd2_pre) cmd2 = pre_cmd_ns;
if (send_cmd3_col) cmd3 = col_cmd_ns;
end
endgenerate
// Output command bus 0.
wire [RANK_WIDTH-1:0] ra0;
// assign address
assign {ra0, mc_bank[BANK_WIDTH-1:0], mc_address[ROW_WIDTH-1:0], mc_ras_n[0], mc_cas_n[0], mc_we_n[0]} = cmd0;
// Output command bus 1.
wire [RANK_WIDTH-1:0] ra1;
// assign address
assign {ra1, mc_bank[2*BANK_WIDTH-1:BANK_WIDTH], mc_address[2*ROW_WIDTH-1:ROW_WIDTH], mc_ras_n[1], mc_cas_n[1], mc_we_n[1]} = cmd1;
wire [RANK_WIDTH-1:0] ra2;
wire [RANK_WIDTH-1:0] ra3;
generate
if(nCK_PER_CLK == 4) begin
// Output command bus 2.
// assign address
assign {ra2, mc_bank[3*BANK_WIDTH-1:2*BANK_WIDTH], mc_address[3*ROW_WIDTH-1:2*ROW_WIDTH], mc_ras_n[2], mc_cas_n[2], mc_we_n[2]} = cmd2;
// Output command bus 3.
// assign address
assign {ra3, mc_bank[4*BANK_WIDTH-1:3*BANK_WIDTH], mc_address[4*ROW_WIDTH-1:3*ROW_WIDTH], mc_ras_n[3], mc_cas_n[3], mc_we_n[3]} =
cmd3;
end
endgenerate
generate
if(CKE_ODT_AUX == "FALSE")begin
assign mc_cke[0] = cke0;
assign mc_cke[1] = cke_ns;
if(nCK_PER_CLK == 4) begin
assign mc_cke[2] = cke_ns;
assign mc_cke[3] = cke_ns;
end
end
endgenerate
// Output cs busses.
localparam ONE = {nCS_PER_RANK{1'b1}};
wire [(CS_WIDTH*nCS_PER_RANK)-1:0] cs_one_hot =
{{CS_WIDTH{1'b0}},ONE};
assign mc_cs_n[CS_WIDTH*nCS_PER_RANK -1 :0 ] =
{(~(cs_one_hot << (nCS_PER_RANK*ra0)) | {CS_WIDTH*nCS_PER_RANK{~cs_en0}})};
assign mc_cs_n[2*CS_WIDTH*nCS_PER_RANK -1 : CS_WIDTH*nCS_PER_RANK ] =
{(~(cs_one_hot << (nCS_PER_RANK*ra1)) | {CS_WIDTH*nCS_PER_RANK{~cs_en1}})};
generate
if(nCK_PER_CLK == 4) begin
assign mc_cs_n[3*CS_WIDTH*nCS_PER_RANK -1 :2*CS_WIDTH*nCS_PER_RANK ] =
{(~(cs_one_hot << (nCS_PER_RANK*ra2)) | {CS_WIDTH*nCS_PER_RANK{~cs_en2}})};
assign mc_cs_n[4*CS_WIDTH*nCS_PER_RANK -1 :3*CS_WIDTH*nCS_PER_RANK ] =
{(~(cs_one_hot << (nCS_PER_RANK*ra3)) | {CS_WIDTH*nCS_PER_RANK{~cs_en3}})};
end
endgenerate
// Output rnk_config info.
reg [RANK_WIDTH-1:0] rnk_config_ns;
reg [RANK_WIDTH-1:0] rnk_config_r;
always @(/*AS*/grant_config_r
or rnk_config_r or rnk_config_strobe or req_rank_r or rst) begin
if (rst) rnk_config_ns = {RANK_WIDTH{1'b0}};
else begin
rnk_config_ns = rnk_config_r;
if (rnk_config_strobe)
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_config_r[i]) rnk_config_ns = req_rank_r[(RANK_WIDTH*i)+:RANK_WIDTH];
end
end
always @(posedge clk) rnk_config_r <= #TCQ rnk_config_ns;
assign rnk_config = rnk_config_ns;
// Generate ODT signals.
wire [CS_WIDTH-1:0] col_ra_one_hot = cs_one_hot << col_ra;
wire slot_0_select = (nSLOTS == 1) ? |(col_ra_one_hot & slot_0_present)
: (slot_0_present[2] & slot_0_present[0]) ?
|(col_ra_one_hot[CS_WIDTH-1:0] & {slot_0_present[2],
slot_0_present[0]}) : (slot_0_present[0])?
col_ra_one_hot[0] : 1'b0;
wire slot_0_read = EVEN_CWL_2T_MODE == "ON" ?
slot_0_select && col_rd_wr_r :
slot_0_select && col_rd_wr_ns;
wire slot_0_write = EVEN_CWL_2T_MODE == "ON" ?
slot_0_select && ~col_rd_wr_r :
slot_0_select && ~col_rd_wr_ns;
reg [1:0] slot_1_population = 2'b0;
reg[1:0] slot_0_population;
always @(/*AS*/slot_0_present) begin
slot_0_population = 2'b0;
for (i=0; i<8; i=i+1)
if (~slot_0_population[1])
if (slot_0_present[i] == 1'b1) slot_0_population =
slot_0_population + 2'b1;
end
// ODT on in slot 0 for writes to slot 0 (and R/W to slot 1 for DDR3)
wire slot_0_odt = (DRAM_TYPE == "DDR3") ? ~slot_0_read : slot_0_write;
assign mc_aux_out0[1] = slot_0_odt & sent_col; // Only send for COL cmds
generate
if (nSLOTS > 1) begin : slot_1_configured
wire slot_1_select = (slot_1_present[3] & slot_1_present[1])?
|({col_ra_one_hot[slot_0_population+1],
col_ra_one_hot[slot_0_population]}) :
(slot_1_present[1]) ? col_ra_one_hot[slot_0_population] :1'b0;
wire slot_1_read = EVEN_CWL_2T_MODE == "ON" ?
slot_1_select && col_rd_wr_r :
slot_1_select && col_rd_wr_ns;
wire slot_1_write = EVEN_CWL_2T_MODE == "ON" ?
slot_1_select && ~col_rd_wr_r :
slot_1_select && ~col_rd_wr_ns;
// ODT on in slot 1 for writes to slot 1 (and R/W to slot 0 for DDR3)
wire slot_1_odt = (DRAM_TYPE == "DDR3") ? ~slot_1_read : slot_1_write;
assign mc_aux_out0[3] = slot_1_odt & sent_col; // Only send for COL cmds
end // if (nSLOTS > 1)
else begin
// Disable slot 1 ODT when not present
assign mc_aux_out0[3] = 1'b0;
end // else: !if(nSLOTS > 1)
endgenerate
generate
if(CKE_ODT_AUX == "FALSE")begin
reg[1:0] mc_aux_out_r ;
reg[1:0] mc_aux_out_r_1 ;
reg[1:0] mc_aux_out_r_2 ;
always@(posedge clk) begin
mc_aux_out_r[0] <= #TCQ mc_aux_out0[1] ;
mc_aux_out_r[1] <= #TCQ mc_aux_out0[3] ;
mc_aux_out_r_1 <= #TCQ mc_aux_out_r ;
mc_aux_out_r_2 <= #TCQ mc_aux_out_r_1 ;
end
if((nCK_PER_CLK == 4) && (nSLOTS > 1 )) begin:odt_high_time_4_1_dslot
assign mc_odt[0] = mc_aux_out0[1] | mc_aux_out_r[0] | mc_aux_out_r_1[0];
assign mc_odt[1] = mc_aux_out0[3] | mc_aux_out_r[1] | mc_aux_out_r_1[1];
end else if(nCK_PER_CLK == 4) begin:odt_high_time_4_1
assign mc_odt[0] = mc_aux_out0[1] | mc_aux_out_r[0] ;
assign mc_odt[1] = mc_aux_out0[3] | mc_aux_out_r[1] ;
end else if(nCK_PER_CLK == 2) begin:odt_high_time_2_1
assign mc_odt[0] = mc_aux_out0[1] | mc_aux_out_r[0] | mc_aux_out_r_1[0] | mc_aux_out_r_2[0] ;
assign mc_odt[1] = mc_aux_out0[3] | mc_aux_out_r[1] | mc_aux_out_r_1[1] | mc_aux_out_r_2[1] ;
end
end
endgenerate
endmodule
|
module mig_7series_v2_3_arb_select #
(
parameter TCQ = 100,
parameter EVEN_CWL_2T_MODE = "OFF",
parameter ADDR_CMD_MODE = "1T",
parameter BANK_VECT_INDX = 11,
parameter BANK_WIDTH = 3,
parameter BURST_MODE = "8",
parameter CS_WIDTH = 4,
parameter CL = 5,
parameter CWL = 5,
parameter DATA_BUF_ADDR_VECT_INDX = 31,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter DRAM_TYPE = "DDR3",
parameter EARLY_WR_DATA_ADDR = "OFF",
parameter ECC = "OFF",
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2,
parameter nCS_PER_RANK = 1,
parameter CKE_ODT_AUX = "FALSE",
parameter nSLOTS = 2,
parameter RANKS = 1,
parameter RANK_VECT_INDX = 15,
parameter RANK_WIDTH = 2,
parameter ROW_VECT_INDX = 63,
parameter ROW_WIDTH = 16,
parameter RTT_NOM = "40",
parameter RTT_WR = "120",
parameter SLOT_0_CONFIG = 8'b0000_0101,
parameter SLOT_1_CONFIG = 8'b0000_1010
)
(
// Outputs
output wire col_periodic_rd,
output wire [RANK_WIDTH-1:0] col_ra,
output wire [BANK_WIDTH-1:0] col_ba,
output wire [ROW_WIDTH-1:0] col_a,
output wire col_rmw,
output wire col_rd_wr,
output wire col_size,
output wire [ROW_WIDTH-1:0] col_row,
output wire [DATA_BUF_ADDR_WIDTH-1:0] col_data_buf_addr,
output wire [DATA_BUF_ADDR_WIDTH-1:0] col_wr_data_buf_addr,
output wire [nCK_PER_CLK-1:0] mc_ras_n,
output wire [nCK_PER_CLK-1:0] mc_cas_n,
output wire [nCK_PER_CLK-1:0] mc_we_n,
output wire [nCK_PER_CLK*ROW_WIDTH-1:0] mc_address,
output wire [nCK_PER_CLK*BANK_WIDTH-1:0] mc_bank,
output wire [CS_WIDTH*nCS_PER_RANK*nCK_PER_CLK-1:0] mc_cs_n,
output wire [1:0] mc_odt,
output wire [nCK_PER_CLK-1:0] mc_cke,
output wire [3:0] mc_aux_out0,
output wire [3:0] mc_aux_out1,
output [2:0] mc_cmd,
output wire [5:0] mc_data_offset,
output wire [5:0] mc_data_offset_1,
output wire [5:0] mc_data_offset_2,
output wire [1:0] mc_cas_slot,
output wire [RANK_WIDTH-1:0] rnk_config,
// Inputs
input clk,
input rst,
input init_calib_complete,
input [RANK_VECT_INDX:0] req_rank_r,
input [BANK_VECT_INDX:0] req_bank_r,
input [nBANK_MACHS-1:0] req_ras,
input [nBANK_MACHS-1:0] req_cas,
input [nBANK_MACHS-1:0] req_wr_r,
input [nBANK_MACHS-1:0] grant_row_r,
input [nBANK_MACHS-1:0] grant_pre_r,
input [ROW_VECT_INDX:0] row_addr,
input [nBANK_MACHS-1:0] row_cmd_wr,
input insert_maint_r1,
input maint_zq_r,
input maint_sre_r,
input maint_srx_r,
input [RANK_WIDTH-1:0] maint_rank_r,
input [nBANK_MACHS-1:0] req_periodic_rd_r,
input [nBANK_MACHS-1:0] req_size_r,
input [nBANK_MACHS-1:0] rd_wr_r,
input [ROW_VECT_INDX:0] req_row_r,
input [ROW_VECT_INDX:0] col_addr,
input [DATA_BUF_ADDR_VECT_INDX:0] req_data_buf_addr_r,
input [nBANK_MACHS-1:0] grant_col_r,
input [nBANK_MACHS-1:0] grant_col_wr,
input [6*RANKS-1:0] calib_rddata_offset,
input [6*RANKS-1:0] calib_rddata_offset_1,
input [6*RANKS-1:0] calib_rddata_offset_2,
input [5:0] col_channel_offset,
input [nBANK_MACHS-1:0] grant_config_r,
input rnk_config_strobe,
input [7:0] slot_0_present,
input [7:0] slot_1_present,
input send_cmd0_row,
input send_cmd0_col,
input send_cmd1_row,
input send_cmd1_col,
input send_cmd2_row,
input send_cmd2_col,
input send_cmd2_pre,
input send_cmd3_col,
input sent_col,
input cs_en0,
input cs_en1,
input cs_en2,
input cs_en3
);
localparam OUT_CMD_WIDTH = RANK_WIDTH + BANK_WIDTH + ROW_WIDTH + 1 + 1 + 1;
reg col_rd_wr_ns;
reg col_rd_wr_r = 1'b0;
reg [OUT_CMD_WIDTH-1:0] col_cmd_r = {OUT_CMD_WIDTH {1'b0}};
reg [OUT_CMD_WIDTH-1:0] row_cmd_r = {OUT_CMD_WIDTH {1'b0}};
// calib_rd_data_offset for currently targeted rank
reg [5:0] rank_rddata_offset_0;
reg [5:0] rank_rddata_offset_1;
reg [5:0] rank_rddata_offset_2;
// Toggle CKE[0] when entering and exiting self-refresh, disable CKE[1]
assign mc_aux_out0[0] = (maint_sre_r || maint_srx_r) & insert_maint_r1;
assign mc_aux_out0[2] = 1'b0;
reg cke_r;
reg cke_ns;
generate
if(CKE_ODT_AUX == "FALSE")begin
always @(posedge clk)
begin
if (rst)
cke_r = 1'b1;
else
cke_r = cke_ns;
end
always @(*)
begin
cke_ns = 1'b1;
if (maint_sre_r & insert_maint_r1)
cke_ns = 1'b0;
else if (cke_r==1'b0)
begin
if (maint_srx_r & insert_maint_r1)
cke_ns = 1'b1;
else
cke_ns = 1'b0;
end
end
end
endgenerate
// Disable ODT & CKE toggle enable high bits
assign mc_aux_out1 = 4'b0;
// implement PHY command word
assign mc_cmd[0] = sent_col;
assign mc_cmd[1] = EVEN_CWL_2T_MODE == "ON" ?
sent_col && col_rd_wr_r :
sent_col && col_rd_wr_ns;
assign mc_cmd[2] = ~sent_col;
// generate calib_rd_data_offset for current rank - only use rank 0 values for now
always @(calib_rddata_offset or calib_rddata_offset_1 or calib_rddata_offset_2) begin
rank_rddata_offset_0 = calib_rddata_offset[5:0];
rank_rddata_offset_1 = calib_rddata_offset_1[5:0];
rank_rddata_offset_2 = calib_rddata_offset_2[5:0];
end
// generate data offset
generate
if(EVEN_CWL_2T_MODE == "ON") begin : gen_mc_data_offset_even_cwl_2t
assign mc_data_offset = ~sent_col ?
6'b0 :
col_rd_wr_r ?
rank_rddata_offset_0 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
assign mc_data_offset_1 = ~sent_col ?
6'b0 :
col_rd_wr_r ?
rank_rddata_offset_1 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
assign mc_data_offset_2 = ~sent_col ?
6'b0 :
col_rd_wr_r ?
rank_rddata_offset_2 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
end
else begin : gen_mc_data_offset_not_even_cwl_2t
assign mc_data_offset = ~sent_col ?
6'b0 :
col_rd_wr_ns ?
rank_rddata_offset_0 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
assign mc_data_offset_1 = ~sent_col ?
6'b0 :
col_rd_wr_ns ?
rank_rddata_offset_1 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
assign mc_data_offset_2 = ~sent_col ?
6'b0 :
col_rd_wr_ns ?
rank_rddata_offset_2 + col_channel_offset :
nCK_PER_CLK == 2 ?
CWL - 2 + col_channel_offset :
// nCK_PER_CLK == 4
CWL + 2 + col_channel_offset;
end
endgenerate
assign mc_cas_slot = col_channel_offset[1:0];
// Based on arbitration results, select the row and column commands.
integer i;
reg [OUT_CMD_WIDTH-1:0] row_cmd_ns;
generate
begin : row_mux
wire [OUT_CMD_WIDTH-1:0] maint_cmd =
{maint_rank_r, // maintenance rank
row_cmd_r[15+:(BANK_WIDTH+ROW_WIDTH-11)],
// bank plus upper address bits
1'b0, // A10 = 0 for ZQCS
row_cmd_r[3+:10], // address bits [9:0]
// ZQ, SRX or SRE/REFRESH
(maint_zq_r ? 3'b110 : maint_srx_r ? 3'b111 : 3'b001)
};
always @(/*AS*/grant_row_r or insert_maint_r1 or maint_cmd
or req_bank_r or req_cas or req_rank_r or req_ras
or row_addr or row_cmd_r or row_cmd_wr or rst)
begin
row_cmd_ns = rst
? {RANK_WIDTH{1'b0}}
: insert_maint_r1
? maint_cmd
: row_cmd_r;
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_row_r[i])
row_cmd_ns = {req_rank_r[(RANK_WIDTH*i)+:RANK_WIDTH],
req_bank_r[(BANK_WIDTH*i)+:BANK_WIDTH],
row_addr[(ROW_WIDTH*i)+:ROW_WIDTH],
req_ras[i],
req_cas[i],
row_cmd_wr[i]};
end
if (ADDR_CMD_MODE == "2T" && nCK_PER_CLK == 2)
always @(posedge clk) row_cmd_r <= #TCQ row_cmd_ns;
end // row_mux
endgenerate
reg [OUT_CMD_WIDTH-1:0] pre_cmd_ns;
generate
if((nCK_PER_CLK == 4) && (ADDR_CMD_MODE != "2T")) begin : pre_mux
reg [OUT_CMD_WIDTH-1:0] pre_cmd_r = {OUT_CMD_WIDTH {1'b0}};
always @(/*AS*/grant_pre_r or req_bank_r or req_cas or req_rank_r or req_ras
or row_addr or pre_cmd_r or row_cmd_wr or rst)
begin
pre_cmd_ns = rst
? {RANK_WIDTH{1'b0}}
: pre_cmd_r;
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_pre_r[i])
pre_cmd_ns = {req_rank_r[(RANK_WIDTH*i)+:RANK_WIDTH],
req_bank_r[(BANK_WIDTH*i)+:BANK_WIDTH],
row_addr[(ROW_WIDTH*i)+:ROW_WIDTH],
req_ras[i],
req_cas[i],
row_cmd_wr[i]};
end
end // pre_mux
endgenerate
reg [OUT_CMD_WIDTH-1:0] col_cmd_ns;
generate
begin : col_mux
reg col_periodic_rd_ns;
reg col_periodic_rd_r;
reg col_rmw_ns;
reg col_rmw_r;
reg col_size_ns;
reg col_size_r;
reg [ROW_WIDTH-1:0] col_row_ns;
reg [ROW_WIDTH-1:0] col_row_r;
reg [DATA_BUF_ADDR_WIDTH-1:0] col_data_buf_addr_ns;
reg [DATA_BUF_ADDR_WIDTH-1:0] col_data_buf_addr_r;
always @(col_addr or col_cmd_r or col_data_buf_addr_r
or col_periodic_rd_r or col_rmw_r or col_row_r
or col_size_r or grant_col_r or rd_wr_r or req_bank_r
or req_data_buf_addr_r or req_periodic_rd_r
or req_rank_r or req_row_r or req_size_r or req_wr_r
or rst or col_rd_wr_r)
begin
col_periodic_rd_ns = ~rst && col_periodic_rd_r;
col_cmd_ns = {(rst ? {RANK_WIDTH{1'b0}}
: col_cmd_r[(OUT_CMD_WIDTH-1)-:RANK_WIDTH]),
((rst && ECC != "OFF")
? {OUT_CMD_WIDTH-3-RANK_WIDTH{1'b0}}
: col_cmd_r[3+:(OUT_CMD_WIDTH-3-RANK_WIDTH)]),
(rst ? 3'b0 : col_cmd_r[2:0])};
col_rmw_ns = col_rmw_r;
col_size_ns = rst ? 1'b0 : col_size_r;
col_row_ns = col_row_r;
col_rd_wr_ns = col_rd_wr_r;
col_data_buf_addr_ns = col_data_buf_addr_r;
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_col_r[i]) begin
col_periodic_rd_ns = req_periodic_rd_r[i];
col_cmd_ns = {req_rank_r[(RANK_WIDTH*i)+:RANK_WIDTH],
req_bank_r[(BANK_WIDTH*i)+:BANK_WIDTH],
col_addr[(ROW_WIDTH*i)+:ROW_WIDTH],
1'b1,
1'b0,
rd_wr_r[i]};
col_rmw_ns = req_wr_r[i] && rd_wr_r[i];
col_size_ns = req_size_r[i];
col_row_ns = req_row_r[(ROW_WIDTH*i)+:ROW_WIDTH];
col_rd_wr_ns = rd_wr_r[i];
col_data_buf_addr_ns =
req_data_buf_addr_r[(DATA_BUF_ADDR_WIDTH*i)+:DATA_BUF_ADDR_WIDTH];
end
end // always @ (...
if (EARLY_WR_DATA_ADDR == "OFF") begin : early_wr_data_addr_off
assign col_wr_data_buf_addr = col_data_buf_addr_ns;
end
else begin : early_wr_data_addr_on
reg [DATA_BUF_ADDR_WIDTH-1:0] col_wr_data_buf_addr_ns;
reg [DATA_BUF_ADDR_WIDTH-1:0] col_wr_data_buf_addr_r;
always @(/*AS*/col_wr_data_buf_addr_r or grant_col_wr
or req_data_buf_addr_r) begin
col_wr_data_buf_addr_ns = col_wr_data_buf_addr_r;
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_col_wr[i])
col_wr_data_buf_addr_ns =
req_data_buf_addr_r[(DATA_BUF_ADDR_WIDTH*i)+:DATA_BUF_ADDR_WIDTH];
end
always @(posedge clk) col_wr_data_buf_addr_r <=
#TCQ col_wr_data_buf_addr_ns;
assign col_wr_data_buf_addr = col_wr_data_buf_addr_ns;
end
always @(posedge clk) col_periodic_rd_r <= #TCQ col_periodic_rd_ns;
always @(posedge clk) col_rmw_r <= #TCQ col_rmw_ns;
always @(posedge clk) col_size_r <= #TCQ col_size_ns;
always @(posedge clk) col_data_buf_addr_r <=
#TCQ col_data_buf_addr_ns;
if (ECC != "OFF" || EVEN_CWL_2T_MODE == "ON") begin
always @(posedge clk) col_cmd_r <= #TCQ col_cmd_ns;
always @(posedge clk) col_row_r <= #TCQ col_row_ns;
end
always @(posedge clk) col_rd_wr_r <= #TCQ col_rd_wr_ns;
if(EVEN_CWL_2T_MODE == "ON") begin
assign col_periodic_rd = col_periodic_rd_r;
assign col_ra = col_cmd_r[3+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH];
assign col_ba = col_cmd_r[3+ROW_WIDTH+:BANK_WIDTH];
assign col_a = col_cmd_r[3+:ROW_WIDTH];
assign col_rmw = col_rmw_r;
assign col_rd_wr = col_rd_wr_r;
assign col_size = col_size_r;
assign col_row = col_row_r;
assign col_data_buf_addr = col_data_buf_addr_r;
end
else begin
assign col_periodic_rd = col_periodic_rd_ns;
assign col_ra = col_cmd_ns[3+ROW_WIDTH+BANK_WIDTH+:RANK_WIDTH];
assign col_ba = col_cmd_ns[3+ROW_WIDTH+:BANK_WIDTH];
assign col_a = col_cmd_ns[3+:ROW_WIDTH];
assign col_rmw = col_rmw_ns;
assign col_rd_wr = col_rd_wr_ns;
assign col_size = col_size_ns;
assign col_row = col_row_ns;
assign col_data_buf_addr = col_data_buf_addr_ns;
end
end // col_mux
endgenerate
reg [OUT_CMD_WIDTH-1:0] cmd0 = {OUT_CMD_WIDTH{1'b1}};
reg cke0;
always @(send_cmd0_row or send_cmd0_col or row_cmd_ns or row_cmd_r or col_cmd_ns or col_cmd_r or cke_ns or cke_r ) begin
cmd0 = {OUT_CMD_WIDTH{1'b1}};
if (send_cmd0_row) cmd0 = row_cmd_ns;
if (send_cmd0_row && EVEN_CWL_2T_MODE == "ON" && nCK_PER_CLK == 2) cmd0 = row_cmd_r;
if (send_cmd0_col) cmd0 = col_cmd_ns;
if (send_cmd0_col && EVEN_CWL_2T_MODE == "ON") cmd0 = col_cmd_r;
if (send_cmd0_row) cke0 = cke_ns;
else cke0 = cke_r ;
end
reg [OUT_CMD_WIDTH-1:0] cmd1 = {OUT_CMD_WIDTH{1'b1}};
generate
if ((nCK_PER_CLK == 2) || (nCK_PER_CLK == 4))
always @(send_cmd1_row or send_cmd1_col or row_cmd_ns or col_cmd_ns or pre_cmd_ns) begin
cmd1 = {OUT_CMD_WIDTH{1'b1}};
if (send_cmd1_row) cmd1 = row_cmd_ns;
if (send_cmd1_col) cmd1 = col_cmd_ns;
end
endgenerate
reg [OUT_CMD_WIDTH-1:0] cmd2 = {OUT_CMD_WIDTH{1'b1}};
reg [OUT_CMD_WIDTH-1:0] cmd3 = {OUT_CMD_WIDTH{1'b1}};
generate
if (nCK_PER_CLK == 4)
always @(send_cmd2_row or send_cmd2_col or send_cmd2_pre or send_cmd3_col or row_cmd_ns or col_cmd_ns or pre_cmd_ns) begin
cmd2 = {OUT_CMD_WIDTH{1'b1}};
cmd3 = {OUT_CMD_WIDTH{1'b1}};
if (send_cmd2_row) cmd2 = row_cmd_ns;
if (send_cmd2_col) cmd2 = col_cmd_ns;
if (send_cmd2_pre) cmd2 = pre_cmd_ns;
if (send_cmd3_col) cmd3 = col_cmd_ns;
end
endgenerate
// Output command bus 0.
wire [RANK_WIDTH-1:0] ra0;
// assign address
assign {ra0, mc_bank[BANK_WIDTH-1:0], mc_address[ROW_WIDTH-1:0], mc_ras_n[0], mc_cas_n[0], mc_we_n[0]} = cmd0;
// Output command bus 1.
wire [RANK_WIDTH-1:0] ra1;
// assign address
assign {ra1, mc_bank[2*BANK_WIDTH-1:BANK_WIDTH], mc_address[2*ROW_WIDTH-1:ROW_WIDTH], mc_ras_n[1], mc_cas_n[1], mc_we_n[1]} = cmd1;
wire [RANK_WIDTH-1:0] ra2;
wire [RANK_WIDTH-1:0] ra3;
generate
if(nCK_PER_CLK == 4) begin
// Output command bus 2.
// assign address
assign {ra2, mc_bank[3*BANK_WIDTH-1:2*BANK_WIDTH], mc_address[3*ROW_WIDTH-1:2*ROW_WIDTH], mc_ras_n[2], mc_cas_n[2], mc_we_n[2]} = cmd2;
// Output command bus 3.
// assign address
assign {ra3, mc_bank[4*BANK_WIDTH-1:3*BANK_WIDTH], mc_address[4*ROW_WIDTH-1:3*ROW_WIDTH], mc_ras_n[3], mc_cas_n[3], mc_we_n[3]} =
cmd3;
end
endgenerate
generate
if(CKE_ODT_AUX == "FALSE")begin
assign mc_cke[0] = cke0;
assign mc_cke[1] = cke_ns;
if(nCK_PER_CLK == 4) begin
assign mc_cke[2] = cke_ns;
assign mc_cke[3] = cke_ns;
end
end
endgenerate
// Output cs busses.
localparam ONE = {nCS_PER_RANK{1'b1}};
wire [(CS_WIDTH*nCS_PER_RANK)-1:0] cs_one_hot =
{{CS_WIDTH{1'b0}},ONE};
assign mc_cs_n[CS_WIDTH*nCS_PER_RANK -1 :0 ] =
{(~(cs_one_hot << (nCS_PER_RANK*ra0)) | {CS_WIDTH*nCS_PER_RANK{~cs_en0}})};
assign mc_cs_n[2*CS_WIDTH*nCS_PER_RANK -1 : CS_WIDTH*nCS_PER_RANK ] =
{(~(cs_one_hot << (nCS_PER_RANK*ra1)) | {CS_WIDTH*nCS_PER_RANK{~cs_en1}})};
generate
if(nCK_PER_CLK == 4) begin
assign mc_cs_n[3*CS_WIDTH*nCS_PER_RANK -1 :2*CS_WIDTH*nCS_PER_RANK ] =
{(~(cs_one_hot << (nCS_PER_RANK*ra2)) | {CS_WIDTH*nCS_PER_RANK{~cs_en2}})};
assign mc_cs_n[4*CS_WIDTH*nCS_PER_RANK -1 :3*CS_WIDTH*nCS_PER_RANK ] =
{(~(cs_one_hot << (nCS_PER_RANK*ra3)) | {CS_WIDTH*nCS_PER_RANK{~cs_en3}})};
end
endgenerate
// Output rnk_config info.
reg [RANK_WIDTH-1:0] rnk_config_ns;
reg [RANK_WIDTH-1:0] rnk_config_r;
always @(/*AS*/grant_config_r
or rnk_config_r or rnk_config_strobe or req_rank_r or rst) begin
if (rst) rnk_config_ns = {RANK_WIDTH{1'b0}};
else begin
rnk_config_ns = rnk_config_r;
if (rnk_config_strobe)
for (i=0; i<nBANK_MACHS; i=i+1)
if (grant_config_r[i]) rnk_config_ns = req_rank_r[(RANK_WIDTH*i)+:RANK_WIDTH];
end
end
always @(posedge clk) rnk_config_r <= #TCQ rnk_config_ns;
assign rnk_config = rnk_config_ns;
// Generate ODT signals.
wire [CS_WIDTH-1:0] col_ra_one_hot = cs_one_hot << col_ra;
wire slot_0_select = (nSLOTS == 1) ? |(col_ra_one_hot & slot_0_present)
: (slot_0_present[2] & slot_0_present[0]) ?
|(col_ra_one_hot[CS_WIDTH-1:0] & {slot_0_present[2],
slot_0_present[0]}) : (slot_0_present[0])?
col_ra_one_hot[0] : 1'b0;
wire slot_0_read = EVEN_CWL_2T_MODE == "ON" ?
slot_0_select && col_rd_wr_r :
slot_0_select && col_rd_wr_ns;
wire slot_0_write = EVEN_CWL_2T_MODE == "ON" ?
slot_0_select && ~col_rd_wr_r :
slot_0_select && ~col_rd_wr_ns;
reg [1:0] slot_1_population = 2'b0;
reg[1:0] slot_0_population;
always @(/*AS*/slot_0_present) begin
slot_0_population = 2'b0;
for (i=0; i<8; i=i+1)
if (~slot_0_population[1])
if (slot_0_present[i] == 1'b1) slot_0_population =
slot_0_population + 2'b1;
end
// ODT on in slot 0 for writes to slot 0 (and R/W to slot 1 for DDR3)
wire slot_0_odt = (DRAM_TYPE == "DDR3") ? ~slot_0_read : slot_0_write;
assign mc_aux_out0[1] = slot_0_odt & sent_col; // Only send for COL cmds
generate
if (nSLOTS > 1) begin : slot_1_configured
wire slot_1_select = (slot_1_present[3] & slot_1_present[1])?
|({col_ra_one_hot[slot_0_population+1],
col_ra_one_hot[slot_0_population]}) :
(slot_1_present[1]) ? col_ra_one_hot[slot_0_population] :1'b0;
wire slot_1_read = EVEN_CWL_2T_MODE == "ON" ?
slot_1_select && col_rd_wr_r :
slot_1_select && col_rd_wr_ns;
wire slot_1_write = EVEN_CWL_2T_MODE == "ON" ?
slot_1_select && ~col_rd_wr_r :
slot_1_select && ~col_rd_wr_ns;
// ODT on in slot 1 for writes to slot 1 (and R/W to slot 0 for DDR3)
wire slot_1_odt = (DRAM_TYPE == "DDR3") ? ~slot_1_read : slot_1_write;
assign mc_aux_out0[3] = slot_1_odt & sent_col; // Only send for COL cmds
end // if (nSLOTS > 1)
else begin
// Disable slot 1 ODT when not present
assign mc_aux_out0[3] = 1'b0;
end // else: !if(nSLOTS > 1)
endgenerate
generate
if(CKE_ODT_AUX == "FALSE")begin
reg[1:0] mc_aux_out_r ;
reg[1:0] mc_aux_out_r_1 ;
reg[1:0] mc_aux_out_r_2 ;
always@(posedge clk) begin
mc_aux_out_r[0] <= #TCQ mc_aux_out0[1] ;
mc_aux_out_r[1] <= #TCQ mc_aux_out0[3] ;
mc_aux_out_r_1 <= #TCQ mc_aux_out_r ;
mc_aux_out_r_2 <= #TCQ mc_aux_out_r_1 ;
end
if((nCK_PER_CLK == 4) && (nSLOTS > 1 )) begin:odt_high_time_4_1_dslot
assign mc_odt[0] = mc_aux_out0[1] | mc_aux_out_r[0] | mc_aux_out_r_1[0];
assign mc_odt[1] = mc_aux_out0[3] | mc_aux_out_r[1] | mc_aux_out_r_1[1];
end else if(nCK_PER_CLK == 4) begin:odt_high_time_4_1
assign mc_odt[0] = mc_aux_out0[1] | mc_aux_out_r[0] ;
assign mc_odt[1] = mc_aux_out0[3] | mc_aux_out_r[1] ;
end else if(nCK_PER_CLK == 2) begin:odt_high_time_2_1
assign mc_odt[0] = mc_aux_out0[1] | mc_aux_out_r[0] | mc_aux_out_r_1[0] | mc_aux_out_r_2[0] ;
assign mc_odt[1] = mc_aux_out0[3] | mc_aux_out_r[1] | mc_aux_out_r_1[1] | mc_aux_out_r_2[1] ;
end
end
endgenerate
endmodule
|
module mig_7series_v2_3_ddr_byte_lane #(
// these are used to scale the index into phaser,calib,scan,mc vectors
// to access fields used in this instance
parameter ABCD = "A", // A,B,C, or D
parameter PO_DATA_CTL = "FALSE",
parameter BITLANES = 12'b1111_1111_1111,
parameter BITLANES_OUTONLY = 12'b1111_1111_1111,
parameter BYTELANES_DDR_CK = 24'b0010_0010_0010_0010_0010_0010,
parameter RCLK_SELECT_LANE = "B",
parameter PC_CLK_RATIO = 4,
parameter USE_PRE_POST_FIFO = "FALSE",
//OUT_FIFO
parameter OF_ALMOST_EMPTY_VALUE = 1,
parameter OF_ALMOST_FULL_VALUE = 1,
parameter OF_ARRAY_MODE = "UNDECLARED",
parameter OF_OUTPUT_DISABLE = "FALSE",
parameter OF_SYNCHRONOUS_MODE = "TRUE",
//IN_FIFO
parameter IF_ALMOST_EMPTY_VALUE = 1,
parameter IF_ALMOST_FULL_VALUE = 1,
parameter IF_ARRAY_MODE = "UNDECLARED",
parameter IF_SYNCHRONOUS_MODE = "TRUE",
//PHASER_IN
parameter PI_BURST_MODE = "TRUE",
parameter PI_CLKOUT_DIV = 2,
parameter PI_FREQ_REF_DIV = "NONE",
parameter PI_FINE_DELAY = 1,
parameter PI_OUTPUT_CLK_SRC = "DELAYED_REF" , //"DELAYED_REF",
parameter PI_SEL_CLK_OFFSET = 0,
parameter PI_SYNC_IN_DIV_RST = "FALSE",
//PHASER_OUT
parameter PO_CLKOUT_DIV = (PO_DATA_CTL == "FALSE") ? 4 : 2,
parameter PO_FINE_DELAY = 0,
parameter PO_COARSE_BYPASS = "FALSE",
parameter PO_COARSE_DELAY = 0,
parameter PO_OCLK_DELAY = 0,
parameter PO_OCLKDELAY_INV = "TRUE",
parameter PO_OUTPUT_CLK_SRC = "DELAYED_REF",
parameter PO_SYNC_IN_DIV_RST = "FALSE",
// OSERDES
parameter OSERDES_DATA_RATE = "DDR",
parameter OSERDES_DATA_WIDTH = 4,
//IDELAY
parameter IDELAYE2_IDELAY_TYPE = "VARIABLE",
parameter IDELAYE2_IDELAY_VALUE = 00,
parameter IODELAY_GRP = "IODELAY_MIG",
parameter FPGA_SPEED_GRADE = 1,
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter real TCK = 0.00,
parameter SYNTHESIS = "FALSE",
// local constants, do not pass in from above
parameter BUS_WIDTH = 12,
parameter MSB_BURST_PEND_PO = 3,
parameter MSB_BURST_PEND_PI = 7,
parameter MSB_RANK_SEL_I = MSB_BURST_PEND_PI + 8,
parameter PHASER_CTL_BUS_WIDTH = MSB_RANK_SEL_I + 1
,parameter CKE_ODT_AUX = "FALSE"
)(
input rst,
input phy_clk,
input freq_refclk,
input mem_refclk,
input idelayctrl_refclk,
input sync_pulse,
output [BUS_WIDTH-1:0] mem_dq_out,
output [BUS_WIDTH-1:0] mem_dq_ts,
input [9:0] mem_dq_in,
output mem_dqs_out,
output mem_dqs_ts,
input mem_dqs_in,
output [11:0] ddr_ck_out,
output rclk,
input if_empty_def,
output if_a_empty,
output if_empty,
output if_a_full,
output if_full,
output of_a_empty,
output of_empty,
output of_a_full,
output of_full,
output pre_fifo_a_full,
output [79:0] phy_din,
input [79:0] phy_dout,
input phy_cmd_wr_en,
input phy_data_wr_en,
input phy_rd_en,
input [PHASER_CTL_BUS_WIDTH-1:0] phaser_ctl_bus,
input idelay_inc,
input idelay_ce,
input idelay_ld,
input if_rst,
input [2:0] byte_rd_en_oth_lanes,
input [1:0] byte_rd_en_oth_banks,
output byte_rd_en,
output po_coarse_overflow,
output po_fine_overflow,
output [8:0] po_counter_read_val,
input po_fine_enable,
input po_coarse_enable,
input [1:0] po_en_calib,
input po_fine_inc,
input po_coarse_inc,
input po_counter_load_en,
input po_counter_read_en,
input po_sel_fine_oclk_delay,
input [8:0] po_counter_load_val,
input [1:0] pi_en_calib,
input pi_rst_dqs_find,
input pi_fine_enable,
input pi_fine_inc,
input pi_counter_load_en,
input pi_counter_read_en,
input [5:0] pi_counter_load_val,
output wire pi_iserdes_rst,
output pi_phase_locked,
output pi_fine_overflow,
output [5:0] pi_counter_read_val,
output wire pi_dqs_found,
output dqs_out_of_range,
input [29:0] fine_delay,
input fine_delay_sel
);
localparam PHASER_INDEX =
(ABCD=="B" ? 1 : (ABCD == "C") ? 2 : (ABCD == "D" ? 3 : 0));
localparam L_OF_ARRAY_MODE =
(OF_ARRAY_MODE != "UNDECLARED") ? OF_ARRAY_MODE :
(PO_DATA_CTL == "FALSE" || PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_8_X_4";
localparam L_IF_ARRAY_MODE = (IF_ARRAY_MODE != "UNDECLARED") ? IF_ARRAY_MODE :
(PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_4_X_8";
localparam L_OSERDES_DATA_RATE = (OSERDES_DATA_RATE != "UNDECLARED") ? OSERDES_DATA_RATE : ((PO_DATA_CTL == "FALSE" && PC_CLK_RATIO == 4) ? "SDR" : "DDR") ;
localparam L_OSERDES_DATA_WIDTH = (OSERDES_DATA_WIDTH != "UNDECLARED") ? OSERDES_DATA_WIDTH : 4;
localparam real L_FREQ_REF_PERIOD_NS = TCK > 2500.0 ? (TCK/(PI_FREQ_REF_DIV == "DIV2" ? 2 : 1)/1000.0) : TCK/1000.0;
localparam real L_MEM_REF_PERIOD_NS = TCK/1000.0;
localparam real L_PHASE_REF_PERIOD_NS = TCK/1000.0;
localparam ODDR_CLK_EDGE = "SAME_EDGE";
localparam PO_DCD_CORRECTION = "ON";
localparam [2:0] PO_DCD_SETTING = (PO_DCD_CORRECTION == "ON") ? 3'b111 : 3'b000;
localparam DQS_AUTO_RECAL = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? 1 : 0;
localparam DQS_FIND_PATTERN = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? "001" : "000";
wire [1:0] oserdes_dqs;
wire [1:0] oserdes_dqs_ts;
wire [1:0] oserdes_dq_ts;
wire [3:0] of_q9;
wire [3:0] of_q8;
wire [3:0] of_q7;
wire [7:0] of_q6;
wire [7:0] of_q5;
wire [3:0] of_q4;
wire [3:0] of_q3;
wire [3:0] of_q2;
wire [3:0] of_q1;
wire [3:0] of_q0;
wire [7:0] of_d9;
wire [7:0] of_d8;
wire [7:0] of_d7;
wire [7:0] of_d6;
wire [7:0] of_d5;
wire [7:0] of_d4;
wire [7:0] of_d3;
wire [7:0] of_d2;
wire [7:0] of_d1;
wire [7:0] of_d0;
wire [7:0] if_q9;
wire [7:0] if_q8;
wire [7:0] if_q7;
wire [7:0] if_q6;
wire [7:0] if_q5;
wire [7:0] if_q4;
wire [7:0] if_q3;
wire [7:0] if_q2;
wire [7:0] if_q1;
wire [7:0] if_q0;
wire [3:0] if_d9;
wire [3:0] if_d8;
wire [3:0] if_d7;
wire [3:0] if_d6;
wire [3:0] if_d5;
wire [3:0] if_d4;
wire [3:0] if_d3;
wire [3:0] if_d2;
wire [3:0] if_d1;
wire [3:0] if_d0;
wire [3:0] dummy_i5;
wire [3:0] dummy_i6;
wire [48-1:0] of_dqbus;
wire [10*4-1:0] iserdes_dout;
wire iserdes_clk;
wire iserdes_clkdiv;
wire ififo_wr_enable;
wire phy_rd_en_;
wire dqs_to_phaser;
wire phy_wr_en = ( PO_DATA_CTL == "FALSE" ) ? phy_cmd_wr_en : phy_data_wr_en;
wire if_empty_;
wire if_a_empty_;
wire if_full_;
wire if_a_full_;
wire po_oserdes_rst;
wire empty_post_fifo;
reg [3:0] if_empty_r /* synthesis syn_maxfan = 3 */;
wire [79:0] rd_data;
reg [79:0] rd_data_r;
reg ififo_rst = 1'b1;
reg ofifo_rst = 1'b1;
wire of_wren_pre;
wire [79:0] pre_fifo_dout;
wire pre_fifo_full;
wire pre_fifo_rden;
wire [5:0] ddr_ck_out_q;
wire ififo_rd_en_in /* synthesis syn_maxfan = 10 */;
wire oserdes_clkdiv;
wire oserdes_clk_delayed;
wire po_rd_enable;
always @(posedge phy_clk) begin
ififo_rst <= #1 pi_rst_dqs_find | if_rst ;
// reset only data o-fifos on reset of dqs_found
ofifo_rst <= #1 (pi_rst_dqs_find & PO_DATA_CTL == "TRUE") | rst;
end
// IN_FIFO EMPTY->RDEN TIMING FIX:
// Always read from IN_FIFO - it doesn't hurt to read from an empty FIFO
// since the IN_FIFO read pointers are not incr'ed when the FIFO is empty
assign #(25) phy_rd_en_ = 1'b1;
//assign #(25) phy_rd_en_ = phy_rd_en;
generate
if ( PO_DATA_CTL == "FALSE" ) begin : if_empty_null
assign if_empty = 0;
assign if_a_empty = 0;
assign if_full = 0;
assign if_a_full = 0;
end
else begin : if_empty_gen
assign if_empty = empty_post_fifo;
assign if_a_empty = if_a_empty_;
assign if_full = if_full_;
assign if_a_full = if_a_full_;
end
endgenerate
generate
if ( PO_DATA_CTL == "FALSE" ) begin : dq_gen_48
assign of_dqbus[48-1:0] = {of_q6[7:4], of_q5[7:4], of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign phy_din = 80'h0;
assign byte_rd_en = 1'b1;
end
else begin : dq_gen_40
assign of_dqbus[40-1:0] = {of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign ififo_rd_en_in = !if_empty_def ? ((&byte_rd_en_oth_banks) && (&byte_rd_en_oth_lanes) && byte_rd_en) :
((|byte_rd_en_oth_banks) || (|byte_rd_en_oth_lanes) || byte_rd_en);
if (USE_PRE_POST_FIFO == "TRUE") begin : if_post_fifo_gen
// IN_FIFO EMPTY->RDEN TIMING FIX:
assign rd_data = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
always @(posedge phy_clk) begin
rd_data_r <= #(025) rd_data;
if_empty_r[0] <= #(025) if_empty_;
if_empty_r[1] <= #(025) if_empty_;
if_empty_r[2] <= #(025) if_empty_;
if_empty_r[3] <= #(025) if_empty_;
end
mig_7series_v2_3_ddr_if_post_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (4), //2 // depth - account for up to 2 cycles of skew
.WIDTH (80) // width
)
u_ddr_if_post_fifo
(
.clk (phy_clk),
.rst (ififo_rst),
.empty_in (if_empty_r),
.rd_en_in (ififo_rd_en_in),
.d_in (rd_data_r),
.empty_out (empty_post_fifo),
.byte_rd_en (byte_rd_en),
.d_out (phy_din)
);
end
else begin : phy_din_gen
assign phy_din = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
assign empty_post_fifo = if_empty_;
end
end
endgenerate
assign { if_d9, if_d8, if_d7, if_d6, if_d5, if_d4, if_d3, if_d2, if_d1, if_d0} = iserdes_dout;
wire [1:0] rank_sel_i = ((phaser_ctl_bus[MSB_RANK_SEL_I :MSB_RANK_SEL_I -7] >> (PHASER_INDEX << 1)) & 2'b11);
generate
if ( USE_PRE_POST_FIFO == "TRUE" ) begin : of_pre_fifo_gen
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = pre_fifo_dout;
mig_7series_v2_3_ddr_of_pre_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (9), // depth - set to 9 to accommodate flow control
.WIDTH (80) // width
)
u_ddr_of_pre_fifo
(
.clk (phy_clk),
.rst (ofifo_rst),
.full_in (of_full),
.wr_en_in (phy_wr_en),
.d_in (phy_dout),
.wr_en_out (of_wren_pre),
.d_out (pre_fifo_dout),
.afull (pre_fifo_a_full)
);
end
else begin
// wire direct to ofifo
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = phy_dout;
assign of_wren_pre = phy_wr_en;
end
endgenerate
generate
if ( PO_DATA_CTL == "TRUE" || ((RCLK_SELECT_LANE==ABCD) && (CKE_ODT_AUX =="TRUE"))) begin : phaser_in_gen
PHASER_IN_PHY #(
.BURST_MODE ( PI_BURST_MODE),
.CLKOUT_DIV ( PI_CLKOUT_DIV),
.DQS_AUTO_RECAL ( DQS_AUTO_RECAL),
.DQS_FIND_PATTERN ( DQS_FIND_PATTERN),
.SEL_CLK_OFFSET ( PI_SEL_CLK_OFFSET),
.FINE_DELAY ( PI_FINE_DELAY),
.FREQ_REF_DIV ( PI_FREQ_REF_DIV),
.OUTPUT_CLK_SRC ( PI_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PI_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( L_PHASE_REF_PERIOD_NS)
) phaser_in (
.DQSFOUND (pi_dqs_found),
.DQSOUTOFRANGE (dqs_out_of_range),
.FINEOVERFLOW (pi_fine_overflow),
.PHASELOCKED (pi_phase_locked),
.ISERDESRST (pi_iserdes_rst),
.ICLKDIV (iserdes_clkdiv),
.ICLK (iserdes_clk),
.COUNTERREADVAL (pi_counter_read_val),
.RCLK (rclk),
.WRENABLE (ififo_wr_enable),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PI - 3 + PHASER_INDEX]),
.ENCALIBPHY (pi_en_calib),
.FINEENABLE (pi_fine_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.RANKSELPHY (rank_sel_i),
.PHASEREFCLK (dqs_to_phaser),
.RSTDQSFIND (pi_rst_dqs_find),
.RST (rst),
.FINEINC (pi_fine_inc),
.COUNTERLOADEN (pi_counter_load_en),
.COUNTERREADEN (pi_counter_read_en),
.COUNTERLOADVAL (pi_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
end
else begin
assign pi_dqs_found = 1'b1;
// assign pi_dqs_out_of_range = 1'b0;
assign pi_phase_locked = 1'b1;
end
endgenerate
wire #0 phase_ref = freq_refclk;
wire oserdes_clk;
PHASER_OUT_PHY #(
.CLKOUT_DIV ( PO_CLKOUT_DIV),
.DATA_CTL_N ( PO_DATA_CTL ),
.FINE_DELAY ( PO_FINE_DELAY),
.COARSE_BYPASS ( PO_COARSE_BYPASS ),
.COARSE_DELAY ( PO_COARSE_DELAY),
.OCLK_DELAY ( PO_OCLK_DELAY),
.OCLKDELAY_INV ( PO_OCLKDELAY_INV),
.OUTPUT_CLK_SRC ( PO_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PO_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( 1), // dummy, not used
.PO ( PO_DCD_SETTING ),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS)
) phaser_out (
.COARSEOVERFLOW (po_coarse_overflow),
.CTSBUS (oserdes_dqs_ts),
.DQSBUS (oserdes_dqs),
.DTSBUS (oserdes_dq_ts),
.FINEOVERFLOW (po_fine_overflow),
.OCLKDIV (oserdes_clkdiv),
.OCLK (oserdes_clk),
.OCLKDELAYED (oserdes_clk_delayed),
.COUNTERREADVAL (po_counter_read_val),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PO -3 + PHASER_INDEX]),
.ENCALIBPHY (po_en_calib),
.RDENABLE (po_rd_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.PHASEREFCLK (/*phase_ref*/),
.RST (rst),
.OSERDESRST (po_oserdes_rst),
.COARSEENABLE (po_coarse_enable),
.FINEENABLE (po_fine_enable),
.COARSEINC (po_coarse_inc),
.FINEINC (po_fine_inc),
.SELFINEOCLKDELAY (po_sel_fine_oclk_delay),
.COUNTERLOADEN (po_counter_load_en),
.COUNTERREADEN (po_counter_read_en),
.COUNTERLOADVAL (po_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
generate
if (PO_DATA_CTL == "TRUE") begin : in_fifo_gen
IN_FIFO #(
.ALMOST_EMPTY_VALUE ( IF_ALMOST_EMPTY_VALUE ),
.ALMOST_FULL_VALUE ( IF_ALMOST_FULL_VALUE ),
.ARRAY_MODE ( L_IF_ARRAY_MODE),
.SYNCHRONOUS_MODE ( IF_SYNCHRONOUS_MODE)
) in_fifo (
.ALMOSTEMPTY (if_a_empty_),
.ALMOSTFULL (if_a_full_),
.EMPTY (if_empty_),
.FULL (if_full_),
.Q0 (if_q0),
.Q1 (if_q1),
.Q2 (if_q2),
.Q3 (if_q3),
.Q4 (if_q4),
.Q5 (if_q5),
.Q6 (if_q6),
.Q7 (if_q7),
.Q8 (if_q8),
.Q9 (if_q9),
//===
.D0 (if_d0),
.D1 (if_d1),
.D2 (if_d2),
.D3 (if_d3),
.D4 (if_d4),
.D5 ({dummy_i5,if_d5}),
.D6 ({dummy_i6,if_d6}),
.D7 (if_d7),
.D8 (if_d8),
.D9 (if_d9),
.RDCLK (phy_clk),
.RDEN (phy_rd_en_),
.RESET (ififo_rst),
.WRCLK (iserdes_clkdiv),
.WREN (ififo_wr_enable)
);
end
endgenerate
OUT_FIFO #(
.ALMOST_EMPTY_VALUE (OF_ALMOST_EMPTY_VALUE),
.ALMOST_FULL_VALUE (OF_ALMOST_FULL_VALUE),
.ARRAY_MODE (L_OF_ARRAY_MODE),
.OUTPUT_DISABLE (OF_OUTPUT_DISABLE),
.SYNCHRONOUS_MODE (OF_SYNCHRONOUS_MODE)
) out_fifo (
.ALMOSTEMPTY (of_a_empty),
.ALMOSTFULL (of_a_full),
.EMPTY (of_empty),
.FULL (of_full),
.Q0 (of_q0),
.Q1 (of_q1),
.Q2 (of_q2),
.Q3 (of_q3),
.Q4 (of_q4),
.Q5 (of_q5),
.Q6 (of_q6),
.Q7 (of_q7),
.Q8 (of_q8),
.Q9 (of_q9),
.D0 (of_d0),
.D1 (of_d1),
.D2 (of_d2),
.D3 (of_d3),
.D4 (of_d4),
.D5 (of_d5),
.D6 (of_d6),
.D7 (of_d7),
.D8 (of_d8),
.D9 (of_d9),
.RDCLK (oserdes_clkdiv),
.RDEN (po_rd_enable),
.RESET (ofifo_rst),
.WRCLK (phy_clk),
.WREN (of_wren_pre)
);
mig_7series_v2_3_ddr_byte_group_io #
(
.PO_DATA_CTL (PO_DATA_CTL),
.BITLANES (BITLANES),
.BITLANES_OUTONLY (BITLANES_OUTONLY),
.OSERDES_DATA_RATE (L_OSERDES_DATA_RATE),
.OSERDES_DATA_WIDTH (L_OSERDES_DATA_WIDTH),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.IDELAYE2_IDELAY_TYPE (IDELAYE2_IDELAY_TYPE),
.IDELAYE2_IDELAY_VALUE (IDELAYE2_IDELAY_VALUE),
.TCK (TCK),
.SYNTHESIS (SYNTHESIS)
)
ddr_byte_group_io
(
.mem_dq_out (mem_dq_out),
.mem_dq_ts (mem_dq_ts),
.mem_dq_in (mem_dq_in),
.mem_dqs_in (mem_dqs_in),
.mem_dqs_out (mem_dqs_out),
.mem_dqs_ts (mem_dqs_ts),
.rst (rst),
.oserdes_rst (po_oserdes_rst),
.iserdes_rst (pi_iserdes_rst ),
.iserdes_dout (iserdes_dout),
.dqs_to_phaser (dqs_to_phaser),
.phy_clk (phy_clk),
.iserdes_clk (iserdes_clk),
.iserdes_clkb (!iserdes_clk),
.iserdes_clkdiv (iserdes_clkdiv),
.idelay_inc (idelay_inc),
.idelay_ce (idelay_ce),
.idelay_ld (idelay_ld),
.idelayctrl_refclk (idelayctrl_refclk),
.oserdes_clk (oserdes_clk),
.oserdes_clk_delayed (oserdes_clk_delayed),
.oserdes_clkdiv (oserdes_clkdiv),
.oserdes_dqs ({oserdes_dqs[1], oserdes_dqs[0]}),
.oserdes_dqsts ({oserdes_dqs_ts[1], oserdes_dqs_ts[0]}),
.oserdes_dq (of_dqbus),
.oserdes_dqts ({oserdes_dq_ts[1], oserdes_dq_ts[0]}),
.fine_delay (fine_delay),
.fine_delay_sel (fine_delay_sel)
);
genvar i;
generate
for (i = 0; i <= 5; i = i+1) begin : ddr_ck_gen_loop
if (PO_DATA_CTL== "FALSE" && (BYTELANES_DDR_CK[i*4+PHASER_INDEX])) begin : ddr_ck_gen
ODDR #(.DDR_CLK_EDGE (ODDR_CLK_EDGE))
ddr_ck (
.C (oserdes_clk),
.R (1'b0),
.S (),
.D1 (1'b0),
.D2 (1'b1),
.CE (1'b1),
.Q (ddr_ck_out_q[i])
);
OBUFDS ddr_ck_obuf (.I(ddr_ck_out_q[i]), .O(ddr_ck_out[i*2]), .OB(ddr_ck_out[i*2+1]));
end // ddr_ck_gen
else begin : ddr_ck_null
assign ddr_ck_out[i*2+1:i*2] = 2'b0;
end
end // ddr_ck_gen_loop
endgenerate
endmodule
|
module mig_7series_v2_3_ddr_byte_lane #(
// these are used to scale the index into phaser,calib,scan,mc vectors
// to access fields used in this instance
parameter ABCD = "A", // A,B,C, or D
parameter PO_DATA_CTL = "FALSE",
parameter BITLANES = 12'b1111_1111_1111,
parameter BITLANES_OUTONLY = 12'b1111_1111_1111,
parameter BYTELANES_DDR_CK = 24'b0010_0010_0010_0010_0010_0010,
parameter RCLK_SELECT_LANE = "B",
parameter PC_CLK_RATIO = 4,
parameter USE_PRE_POST_FIFO = "FALSE",
//OUT_FIFO
parameter OF_ALMOST_EMPTY_VALUE = 1,
parameter OF_ALMOST_FULL_VALUE = 1,
parameter OF_ARRAY_MODE = "UNDECLARED",
parameter OF_OUTPUT_DISABLE = "FALSE",
parameter OF_SYNCHRONOUS_MODE = "TRUE",
//IN_FIFO
parameter IF_ALMOST_EMPTY_VALUE = 1,
parameter IF_ALMOST_FULL_VALUE = 1,
parameter IF_ARRAY_MODE = "UNDECLARED",
parameter IF_SYNCHRONOUS_MODE = "TRUE",
//PHASER_IN
parameter PI_BURST_MODE = "TRUE",
parameter PI_CLKOUT_DIV = 2,
parameter PI_FREQ_REF_DIV = "NONE",
parameter PI_FINE_DELAY = 1,
parameter PI_OUTPUT_CLK_SRC = "DELAYED_REF" , //"DELAYED_REF",
parameter PI_SEL_CLK_OFFSET = 0,
parameter PI_SYNC_IN_DIV_RST = "FALSE",
//PHASER_OUT
parameter PO_CLKOUT_DIV = (PO_DATA_CTL == "FALSE") ? 4 : 2,
parameter PO_FINE_DELAY = 0,
parameter PO_COARSE_BYPASS = "FALSE",
parameter PO_COARSE_DELAY = 0,
parameter PO_OCLK_DELAY = 0,
parameter PO_OCLKDELAY_INV = "TRUE",
parameter PO_OUTPUT_CLK_SRC = "DELAYED_REF",
parameter PO_SYNC_IN_DIV_RST = "FALSE",
// OSERDES
parameter OSERDES_DATA_RATE = "DDR",
parameter OSERDES_DATA_WIDTH = 4,
//IDELAY
parameter IDELAYE2_IDELAY_TYPE = "VARIABLE",
parameter IDELAYE2_IDELAY_VALUE = 00,
parameter IODELAY_GRP = "IODELAY_MIG",
parameter FPGA_SPEED_GRADE = 1,
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter real TCK = 0.00,
parameter SYNTHESIS = "FALSE",
// local constants, do not pass in from above
parameter BUS_WIDTH = 12,
parameter MSB_BURST_PEND_PO = 3,
parameter MSB_BURST_PEND_PI = 7,
parameter MSB_RANK_SEL_I = MSB_BURST_PEND_PI + 8,
parameter PHASER_CTL_BUS_WIDTH = MSB_RANK_SEL_I + 1
,parameter CKE_ODT_AUX = "FALSE"
)(
input rst,
input phy_clk,
input freq_refclk,
input mem_refclk,
input idelayctrl_refclk,
input sync_pulse,
output [BUS_WIDTH-1:0] mem_dq_out,
output [BUS_WIDTH-1:0] mem_dq_ts,
input [9:0] mem_dq_in,
output mem_dqs_out,
output mem_dqs_ts,
input mem_dqs_in,
output [11:0] ddr_ck_out,
output rclk,
input if_empty_def,
output if_a_empty,
output if_empty,
output if_a_full,
output if_full,
output of_a_empty,
output of_empty,
output of_a_full,
output of_full,
output pre_fifo_a_full,
output [79:0] phy_din,
input [79:0] phy_dout,
input phy_cmd_wr_en,
input phy_data_wr_en,
input phy_rd_en,
input [PHASER_CTL_BUS_WIDTH-1:0] phaser_ctl_bus,
input idelay_inc,
input idelay_ce,
input idelay_ld,
input if_rst,
input [2:0] byte_rd_en_oth_lanes,
input [1:0] byte_rd_en_oth_banks,
output byte_rd_en,
output po_coarse_overflow,
output po_fine_overflow,
output [8:0] po_counter_read_val,
input po_fine_enable,
input po_coarse_enable,
input [1:0] po_en_calib,
input po_fine_inc,
input po_coarse_inc,
input po_counter_load_en,
input po_counter_read_en,
input po_sel_fine_oclk_delay,
input [8:0] po_counter_load_val,
input [1:0] pi_en_calib,
input pi_rst_dqs_find,
input pi_fine_enable,
input pi_fine_inc,
input pi_counter_load_en,
input pi_counter_read_en,
input [5:0] pi_counter_load_val,
output wire pi_iserdes_rst,
output pi_phase_locked,
output pi_fine_overflow,
output [5:0] pi_counter_read_val,
output wire pi_dqs_found,
output dqs_out_of_range,
input [29:0] fine_delay,
input fine_delay_sel
);
localparam PHASER_INDEX =
(ABCD=="B" ? 1 : (ABCD == "C") ? 2 : (ABCD == "D" ? 3 : 0));
localparam L_OF_ARRAY_MODE =
(OF_ARRAY_MODE != "UNDECLARED") ? OF_ARRAY_MODE :
(PO_DATA_CTL == "FALSE" || PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_8_X_4";
localparam L_IF_ARRAY_MODE = (IF_ARRAY_MODE != "UNDECLARED") ? IF_ARRAY_MODE :
(PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_4_X_8";
localparam L_OSERDES_DATA_RATE = (OSERDES_DATA_RATE != "UNDECLARED") ? OSERDES_DATA_RATE : ((PO_DATA_CTL == "FALSE" && PC_CLK_RATIO == 4) ? "SDR" : "DDR") ;
localparam L_OSERDES_DATA_WIDTH = (OSERDES_DATA_WIDTH != "UNDECLARED") ? OSERDES_DATA_WIDTH : 4;
localparam real L_FREQ_REF_PERIOD_NS = TCK > 2500.0 ? (TCK/(PI_FREQ_REF_DIV == "DIV2" ? 2 : 1)/1000.0) : TCK/1000.0;
localparam real L_MEM_REF_PERIOD_NS = TCK/1000.0;
localparam real L_PHASE_REF_PERIOD_NS = TCK/1000.0;
localparam ODDR_CLK_EDGE = "SAME_EDGE";
localparam PO_DCD_CORRECTION = "ON";
localparam [2:0] PO_DCD_SETTING = (PO_DCD_CORRECTION == "ON") ? 3'b111 : 3'b000;
localparam DQS_AUTO_RECAL = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? 1 : 0;
localparam DQS_FIND_PATTERN = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? "001" : "000";
wire [1:0] oserdes_dqs;
wire [1:0] oserdes_dqs_ts;
wire [1:0] oserdes_dq_ts;
wire [3:0] of_q9;
wire [3:0] of_q8;
wire [3:0] of_q7;
wire [7:0] of_q6;
wire [7:0] of_q5;
wire [3:0] of_q4;
wire [3:0] of_q3;
wire [3:0] of_q2;
wire [3:0] of_q1;
wire [3:0] of_q0;
wire [7:0] of_d9;
wire [7:0] of_d8;
wire [7:0] of_d7;
wire [7:0] of_d6;
wire [7:0] of_d5;
wire [7:0] of_d4;
wire [7:0] of_d3;
wire [7:0] of_d2;
wire [7:0] of_d1;
wire [7:0] of_d0;
wire [7:0] if_q9;
wire [7:0] if_q8;
wire [7:0] if_q7;
wire [7:0] if_q6;
wire [7:0] if_q5;
wire [7:0] if_q4;
wire [7:0] if_q3;
wire [7:0] if_q2;
wire [7:0] if_q1;
wire [7:0] if_q0;
wire [3:0] if_d9;
wire [3:0] if_d8;
wire [3:0] if_d7;
wire [3:0] if_d6;
wire [3:0] if_d5;
wire [3:0] if_d4;
wire [3:0] if_d3;
wire [3:0] if_d2;
wire [3:0] if_d1;
wire [3:0] if_d0;
wire [3:0] dummy_i5;
wire [3:0] dummy_i6;
wire [48-1:0] of_dqbus;
wire [10*4-1:0] iserdes_dout;
wire iserdes_clk;
wire iserdes_clkdiv;
wire ififo_wr_enable;
wire phy_rd_en_;
wire dqs_to_phaser;
wire phy_wr_en = ( PO_DATA_CTL == "FALSE" ) ? phy_cmd_wr_en : phy_data_wr_en;
wire if_empty_;
wire if_a_empty_;
wire if_full_;
wire if_a_full_;
wire po_oserdes_rst;
wire empty_post_fifo;
reg [3:0] if_empty_r /* synthesis syn_maxfan = 3 */;
wire [79:0] rd_data;
reg [79:0] rd_data_r;
reg ififo_rst = 1'b1;
reg ofifo_rst = 1'b1;
wire of_wren_pre;
wire [79:0] pre_fifo_dout;
wire pre_fifo_full;
wire pre_fifo_rden;
wire [5:0] ddr_ck_out_q;
wire ififo_rd_en_in /* synthesis syn_maxfan = 10 */;
wire oserdes_clkdiv;
wire oserdes_clk_delayed;
wire po_rd_enable;
always @(posedge phy_clk) begin
ififo_rst <= #1 pi_rst_dqs_find | if_rst ;
// reset only data o-fifos on reset of dqs_found
ofifo_rst <= #1 (pi_rst_dqs_find & PO_DATA_CTL == "TRUE") | rst;
end
// IN_FIFO EMPTY->RDEN TIMING FIX:
// Always read from IN_FIFO - it doesn't hurt to read from an empty FIFO
// since the IN_FIFO read pointers are not incr'ed when the FIFO is empty
assign #(25) phy_rd_en_ = 1'b1;
//assign #(25) phy_rd_en_ = phy_rd_en;
generate
if ( PO_DATA_CTL == "FALSE" ) begin : if_empty_null
assign if_empty = 0;
assign if_a_empty = 0;
assign if_full = 0;
assign if_a_full = 0;
end
else begin : if_empty_gen
assign if_empty = empty_post_fifo;
assign if_a_empty = if_a_empty_;
assign if_full = if_full_;
assign if_a_full = if_a_full_;
end
endgenerate
generate
if ( PO_DATA_CTL == "FALSE" ) begin : dq_gen_48
assign of_dqbus[48-1:0] = {of_q6[7:4], of_q5[7:4], of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign phy_din = 80'h0;
assign byte_rd_en = 1'b1;
end
else begin : dq_gen_40
assign of_dqbus[40-1:0] = {of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign ififo_rd_en_in = !if_empty_def ? ((&byte_rd_en_oth_banks) && (&byte_rd_en_oth_lanes) && byte_rd_en) :
((|byte_rd_en_oth_banks) || (|byte_rd_en_oth_lanes) || byte_rd_en);
if (USE_PRE_POST_FIFO == "TRUE") begin : if_post_fifo_gen
// IN_FIFO EMPTY->RDEN TIMING FIX:
assign rd_data = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
always @(posedge phy_clk) begin
rd_data_r <= #(025) rd_data;
if_empty_r[0] <= #(025) if_empty_;
if_empty_r[1] <= #(025) if_empty_;
if_empty_r[2] <= #(025) if_empty_;
if_empty_r[3] <= #(025) if_empty_;
end
mig_7series_v2_3_ddr_if_post_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (4), //2 // depth - account for up to 2 cycles of skew
.WIDTH (80) // width
)
u_ddr_if_post_fifo
(
.clk (phy_clk),
.rst (ififo_rst),
.empty_in (if_empty_r),
.rd_en_in (ififo_rd_en_in),
.d_in (rd_data_r),
.empty_out (empty_post_fifo),
.byte_rd_en (byte_rd_en),
.d_out (phy_din)
);
end
else begin : phy_din_gen
assign phy_din = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
assign empty_post_fifo = if_empty_;
end
end
endgenerate
assign { if_d9, if_d8, if_d7, if_d6, if_d5, if_d4, if_d3, if_d2, if_d1, if_d0} = iserdes_dout;
wire [1:0] rank_sel_i = ((phaser_ctl_bus[MSB_RANK_SEL_I :MSB_RANK_SEL_I -7] >> (PHASER_INDEX << 1)) & 2'b11);
generate
if ( USE_PRE_POST_FIFO == "TRUE" ) begin : of_pre_fifo_gen
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = pre_fifo_dout;
mig_7series_v2_3_ddr_of_pre_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (9), // depth - set to 9 to accommodate flow control
.WIDTH (80) // width
)
u_ddr_of_pre_fifo
(
.clk (phy_clk),
.rst (ofifo_rst),
.full_in (of_full),
.wr_en_in (phy_wr_en),
.d_in (phy_dout),
.wr_en_out (of_wren_pre),
.d_out (pre_fifo_dout),
.afull (pre_fifo_a_full)
);
end
else begin
// wire direct to ofifo
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = phy_dout;
assign of_wren_pre = phy_wr_en;
end
endgenerate
generate
if ( PO_DATA_CTL == "TRUE" || ((RCLK_SELECT_LANE==ABCD) && (CKE_ODT_AUX =="TRUE"))) begin : phaser_in_gen
PHASER_IN_PHY #(
.BURST_MODE ( PI_BURST_MODE),
.CLKOUT_DIV ( PI_CLKOUT_DIV),
.DQS_AUTO_RECAL ( DQS_AUTO_RECAL),
.DQS_FIND_PATTERN ( DQS_FIND_PATTERN),
.SEL_CLK_OFFSET ( PI_SEL_CLK_OFFSET),
.FINE_DELAY ( PI_FINE_DELAY),
.FREQ_REF_DIV ( PI_FREQ_REF_DIV),
.OUTPUT_CLK_SRC ( PI_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PI_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( L_PHASE_REF_PERIOD_NS)
) phaser_in (
.DQSFOUND (pi_dqs_found),
.DQSOUTOFRANGE (dqs_out_of_range),
.FINEOVERFLOW (pi_fine_overflow),
.PHASELOCKED (pi_phase_locked),
.ISERDESRST (pi_iserdes_rst),
.ICLKDIV (iserdes_clkdiv),
.ICLK (iserdes_clk),
.COUNTERREADVAL (pi_counter_read_val),
.RCLK (rclk),
.WRENABLE (ififo_wr_enable),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PI - 3 + PHASER_INDEX]),
.ENCALIBPHY (pi_en_calib),
.FINEENABLE (pi_fine_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.RANKSELPHY (rank_sel_i),
.PHASEREFCLK (dqs_to_phaser),
.RSTDQSFIND (pi_rst_dqs_find),
.RST (rst),
.FINEINC (pi_fine_inc),
.COUNTERLOADEN (pi_counter_load_en),
.COUNTERREADEN (pi_counter_read_en),
.COUNTERLOADVAL (pi_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
end
else begin
assign pi_dqs_found = 1'b1;
// assign pi_dqs_out_of_range = 1'b0;
assign pi_phase_locked = 1'b1;
end
endgenerate
wire #0 phase_ref = freq_refclk;
wire oserdes_clk;
PHASER_OUT_PHY #(
.CLKOUT_DIV ( PO_CLKOUT_DIV),
.DATA_CTL_N ( PO_DATA_CTL ),
.FINE_DELAY ( PO_FINE_DELAY),
.COARSE_BYPASS ( PO_COARSE_BYPASS ),
.COARSE_DELAY ( PO_COARSE_DELAY),
.OCLK_DELAY ( PO_OCLK_DELAY),
.OCLKDELAY_INV ( PO_OCLKDELAY_INV),
.OUTPUT_CLK_SRC ( PO_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PO_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( 1), // dummy, not used
.PO ( PO_DCD_SETTING ),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS)
) phaser_out (
.COARSEOVERFLOW (po_coarse_overflow),
.CTSBUS (oserdes_dqs_ts),
.DQSBUS (oserdes_dqs),
.DTSBUS (oserdes_dq_ts),
.FINEOVERFLOW (po_fine_overflow),
.OCLKDIV (oserdes_clkdiv),
.OCLK (oserdes_clk),
.OCLKDELAYED (oserdes_clk_delayed),
.COUNTERREADVAL (po_counter_read_val),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PO -3 + PHASER_INDEX]),
.ENCALIBPHY (po_en_calib),
.RDENABLE (po_rd_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.PHASEREFCLK (/*phase_ref*/),
.RST (rst),
.OSERDESRST (po_oserdes_rst),
.COARSEENABLE (po_coarse_enable),
.FINEENABLE (po_fine_enable),
.COARSEINC (po_coarse_inc),
.FINEINC (po_fine_inc),
.SELFINEOCLKDELAY (po_sel_fine_oclk_delay),
.COUNTERLOADEN (po_counter_load_en),
.COUNTERREADEN (po_counter_read_en),
.COUNTERLOADVAL (po_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
generate
if (PO_DATA_CTL == "TRUE") begin : in_fifo_gen
IN_FIFO #(
.ALMOST_EMPTY_VALUE ( IF_ALMOST_EMPTY_VALUE ),
.ALMOST_FULL_VALUE ( IF_ALMOST_FULL_VALUE ),
.ARRAY_MODE ( L_IF_ARRAY_MODE),
.SYNCHRONOUS_MODE ( IF_SYNCHRONOUS_MODE)
) in_fifo (
.ALMOSTEMPTY (if_a_empty_),
.ALMOSTFULL (if_a_full_),
.EMPTY (if_empty_),
.FULL (if_full_),
.Q0 (if_q0),
.Q1 (if_q1),
.Q2 (if_q2),
.Q3 (if_q3),
.Q4 (if_q4),
.Q5 (if_q5),
.Q6 (if_q6),
.Q7 (if_q7),
.Q8 (if_q8),
.Q9 (if_q9),
//===
.D0 (if_d0),
.D1 (if_d1),
.D2 (if_d2),
.D3 (if_d3),
.D4 (if_d4),
.D5 ({dummy_i5,if_d5}),
.D6 ({dummy_i6,if_d6}),
.D7 (if_d7),
.D8 (if_d8),
.D9 (if_d9),
.RDCLK (phy_clk),
.RDEN (phy_rd_en_),
.RESET (ififo_rst),
.WRCLK (iserdes_clkdiv),
.WREN (ififo_wr_enable)
);
end
endgenerate
OUT_FIFO #(
.ALMOST_EMPTY_VALUE (OF_ALMOST_EMPTY_VALUE),
.ALMOST_FULL_VALUE (OF_ALMOST_FULL_VALUE),
.ARRAY_MODE (L_OF_ARRAY_MODE),
.OUTPUT_DISABLE (OF_OUTPUT_DISABLE),
.SYNCHRONOUS_MODE (OF_SYNCHRONOUS_MODE)
) out_fifo (
.ALMOSTEMPTY (of_a_empty),
.ALMOSTFULL (of_a_full),
.EMPTY (of_empty),
.FULL (of_full),
.Q0 (of_q0),
.Q1 (of_q1),
.Q2 (of_q2),
.Q3 (of_q3),
.Q4 (of_q4),
.Q5 (of_q5),
.Q6 (of_q6),
.Q7 (of_q7),
.Q8 (of_q8),
.Q9 (of_q9),
.D0 (of_d0),
.D1 (of_d1),
.D2 (of_d2),
.D3 (of_d3),
.D4 (of_d4),
.D5 (of_d5),
.D6 (of_d6),
.D7 (of_d7),
.D8 (of_d8),
.D9 (of_d9),
.RDCLK (oserdes_clkdiv),
.RDEN (po_rd_enable),
.RESET (ofifo_rst),
.WRCLK (phy_clk),
.WREN (of_wren_pre)
);
mig_7series_v2_3_ddr_byte_group_io #
(
.PO_DATA_CTL (PO_DATA_CTL),
.BITLANES (BITLANES),
.BITLANES_OUTONLY (BITLANES_OUTONLY),
.OSERDES_DATA_RATE (L_OSERDES_DATA_RATE),
.OSERDES_DATA_WIDTH (L_OSERDES_DATA_WIDTH),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.IDELAYE2_IDELAY_TYPE (IDELAYE2_IDELAY_TYPE),
.IDELAYE2_IDELAY_VALUE (IDELAYE2_IDELAY_VALUE),
.TCK (TCK),
.SYNTHESIS (SYNTHESIS)
)
ddr_byte_group_io
(
.mem_dq_out (mem_dq_out),
.mem_dq_ts (mem_dq_ts),
.mem_dq_in (mem_dq_in),
.mem_dqs_in (mem_dqs_in),
.mem_dqs_out (mem_dqs_out),
.mem_dqs_ts (mem_dqs_ts),
.rst (rst),
.oserdes_rst (po_oserdes_rst),
.iserdes_rst (pi_iserdes_rst ),
.iserdes_dout (iserdes_dout),
.dqs_to_phaser (dqs_to_phaser),
.phy_clk (phy_clk),
.iserdes_clk (iserdes_clk),
.iserdes_clkb (!iserdes_clk),
.iserdes_clkdiv (iserdes_clkdiv),
.idelay_inc (idelay_inc),
.idelay_ce (idelay_ce),
.idelay_ld (idelay_ld),
.idelayctrl_refclk (idelayctrl_refclk),
.oserdes_clk (oserdes_clk),
.oserdes_clk_delayed (oserdes_clk_delayed),
.oserdes_clkdiv (oserdes_clkdiv),
.oserdes_dqs ({oserdes_dqs[1], oserdes_dqs[0]}),
.oserdes_dqsts ({oserdes_dqs_ts[1], oserdes_dqs_ts[0]}),
.oserdes_dq (of_dqbus),
.oserdes_dqts ({oserdes_dq_ts[1], oserdes_dq_ts[0]}),
.fine_delay (fine_delay),
.fine_delay_sel (fine_delay_sel)
);
genvar i;
generate
for (i = 0; i <= 5; i = i+1) begin : ddr_ck_gen_loop
if (PO_DATA_CTL== "FALSE" && (BYTELANES_DDR_CK[i*4+PHASER_INDEX])) begin : ddr_ck_gen
ODDR #(.DDR_CLK_EDGE (ODDR_CLK_EDGE))
ddr_ck (
.C (oserdes_clk),
.R (1'b0),
.S (),
.D1 (1'b0),
.D2 (1'b1),
.CE (1'b1),
.Q (ddr_ck_out_q[i])
);
OBUFDS ddr_ck_obuf (.I(ddr_ck_out_q[i]), .O(ddr_ck_out[i*2]), .OB(ddr_ck_out[i*2+1]));
end // ddr_ck_gen
else begin : ddr_ck_null
assign ddr_ck_out[i*2+1:i*2] = 2'b0;
end
end // ddr_ck_gen_loop
endgenerate
endmodule
|
module mig_7series_v2_3_ddr_byte_lane #(
// these are used to scale the index into phaser,calib,scan,mc vectors
// to access fields used in this instance
parameter ABCD = "A", // A,B,C, or D
parameter PO_DATA_CTL = "FALSE",
parameter BITLANES = 12'b1111_1111_1111,
parameter BITLANES_OUTONLY = 12'b1111_1111_1111,
parameter BYTELANES_DDR_CK = 24'b0010_0010_0010_0010_0010_0010,
parameter RCLK_SELECT_LANE = "B",
parameter PC_CLK_RATIO = 4,
parameter USE_PRE_POST_FIFO = "FALSE",
//OUT_FIFO
parameter OF_ALMOST_EMPTY_VALUE = 1,
parameter OF_ALMOST_FULL_VALUE = 1,
parameter OF_ARRAY_MODE = "UNDECLARED",
parameter OF_OUTPUT_DISABLE = "FALSE",
parameter OF_SYNCHRONOUS_MODE = "TRUE",
//IN_FIFO
parameter IF_ALMOST_EMPTY_VALUE = 1,
parameter IF_ALMOST_FULL_VALUE = 1,
parameter IF_ARRAY_MODE = "UNDECLARED",
parameter IF_SYNCHRONOUS_MODE = "TRUE",
//PHASER_IN
parameter PI_BURST_MODE = "TRUE",
parameter PI_CLKOUT_DIV = 2,
parameter PI_FREQ_REF_DIV = "NONE",
parameter PI_FINE_DELAY = 1,
parameter PI_OUTPUT_CLK_SRC = "DELAYED_REF" , //"DELAYED_REF",
parameter PI_SEL_CLK_OFFSET = 0,
parameter PI_SYNC_IN_DIV_RST = "FALSE",
//PHASER_OUT
parameter PO_CLKOUT_DIV = (PO_DATA_CTL == "FALSE") ? 4 : 2,
parameter PO_FINE_DELAY = 0,
parameter PO_COARSE_BYPASS = "FALSE",
parameter PO_COARSE_DELAY = 0,
parameter PO_OCLK_DELAY = 0,
parameter PO_OCLKDELAY_INV = "TRUE",
parameter PO_OUTPUT_CLK_SRC = "DELAYED_REF",
parameter PO_SYNC_IN_DIV_RST = "FALSE",
// OSERDES
parameter OSERDES_DATA_RATE = "DDR",
parameter OSERDES_DATA_WIDTH = 4,
//IDELAY
parameter IDELAYE2_IDELAY_TYPE = "VARIABLE",
parameter IDELAYE2_IDELAY_VALUE = 00,
parameter IODELAY_GRP = "IODELAY_MIG",
parameter FPGA_SPEED_GRADE = 1,
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter real TCK = 0.00,
parameter SYNTHESIS = "FALSE",
// local constants, do not pass in from above
parameter BUS_WIDTH = 12,
parameter MSB_BURST_PEND_PO = 3,
parameter MSB_BURST_PEND_PI = 7,
parameter MSB_RANK_SEL_I = MSB_BURST_PEND_PI + 8,
parameter PHASER_CTL_BUS_WIDTH = MSB_RANK_SEL_I + 1
,parameter CKE_ODT_AUX = "FALSE"
)(
input rst,
input phy_clk,
input freq_refclk,
input mem_refclk,
input idelayctrl_refclk,
input sync_pulse,
output [BUS_WIDTH-1:0] mem_dq_out,
output [BUS_WIDTH-1:0] mem_dq_ts,
input [9:0] mem_dq_in,
output mem_dqs_out,
output mem_dqs_ts,
input mem_dqs_in,
output [11:0] ddr_ck_out,
output rclk,
input if_empty_def,
output if_a_empty,
output if_empty,
output if_a_full,
output if_full,
output of_a_empty,
output of_empty,
output of_a_full,
output of_full,
output pre_fifo_a_full,
output [79:0] phy_din,
input [79:0] phy_dout,
input phy_cmd_wr_en,
input phy_data_wr_en,
input phy_rd_en,
input [PHASER_CTL_BUS_WIDTH-1:0] phaser_ctl_bus,
input idelay_inc,
input idelay_ce,
input idelay_ld,
input if_rst,
input [2:0] byte_rd_en_oth_lanes,
input [1:0] byte_rd_en_oth_banks,
output byte_rd_en,
output po_coarse_overflow,
output po_fine_overflow,
output [8:0] po_counter_read_val,
input po_fine_enable,
input po_coarse_enable,
input [1:0] po_en_calib,
input po_fine_inc,
input po_coarse_inc,
input po_counter_load_en,
input po_counter_read_en,
input po_sel_fine_oclk_delay,
input [8:0] po_counter_load_val,
input [1:0] pi_en_calib,
input pi_rst_dqs_find,
input pi_fine_enable,
input pi_fine_inc,
input pi_counter_load_en,
input pi_counter_read_en,
input [5:0] pi_counter_load_val,
output wire pi_iserdes_rst,
output pi_phase_locked,
output pi_fine_overflow,
output [5:0] pi_counter_read_val,
output wire pi_dqs_found,
output dqs_out_of_range,
input [29:0] fine_delay,
input fine_delay_sel
);
localparam PHASER_INDEX =
(ABCD=="B" ? 1 : (ABCD == "C") ? 2 : (ABCD == "D" ? 3 : 0));
localparam L_OF_ARRAY_MODE =
(OF_ARRAY_MODE != "UNDECLARED") ? OF_ARRAY_MODE :
(PO_DATA_CTL == "FALSE" || PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_8_X_4";
localparam L_IF_ARRAY_MODE = (IF_ARRAY_MODE != "UNDECLARED") ? IF_ARRAY_MODE :
(PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_4_X_8";
localparam L_OSERDES_DATA_RATE = (OSERDES_DATA_RATE != "UNDECLARED") ? OSERDES_DATA_RATE : ((PO_DATA_CTL == "FALSE" && PC_CLK_RATIO == 4) ? "SDR" : "DDR") ;
localparam L_OSERDES_DATA_WIDTH = (OSERDES_DATA_WIDTH != "UNDECLARED") ? OSERDES_DATA_WIDTH : 4;
localparam real L_FREQ_REF_PERIOD_NS = TCK > 2500.0 ? (TCK/(PI_FREQ_REF_DIV == "DIV2" ? 2 : 1)/1000.0) : TCK/1000.0;
localparam real L_MEM_REF_PERIOD_NS = TCK/1000.0;
localparam real L_PHASE_REF_PERIOD_NS = TCK/1000.0;
localparam ODDR_CLK_EDGE = "SAME_EDGE";
localparam PO_DCD_CORRECTION = "ON";
localparam [2:0] PO_DCD_SETTING = (PO_DCD_CORRECTION == "ON") ? 3'b111 : 3'b000;
localparam DQS_AUTO_RECAL = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? 1 : 0;
localparam DQS_FIND_PATTERN = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? "001" : "000";
wire [1:0] oserdes_dqs;
wire [1:0] oserdes_dqs_ts;
wire [1:0] oserdes_dq_ts;
wire [3:0] of_q9;
wire [3:0] of_q8;
wire [3:0] of_q7;
wire [7:0] of_q6;
wire [7:0] of_q5;
wire [3:0] of_q4;
wire [3:0] of_q3;
wire [3:0] of_q2;
wire [3:0] of_q1;
wire [3:0] of_q0;
wire [7:0] of_d9;
wire [7:0] of_d8;
wire [7:0] of_d7;
wire [7:0] of_d6;
wire [7:0] of_d5;
wire [7:0] of_d4;
wire [7:0] of_d3;
wire [7:0] of_d2;
wire [7:0] of_d1;
wire [7:0] of_d0;
wire [7:0] if_q9;
wire [7:0] if_q8;
wire [7:0] if_q7;
wire [7:0] if_q6;
wire [7:0] if_q5;
wire [7:0] if_q4;
wire [7:0] if_q3;
wire [7:0] if_q2;
wire [7:0] if_q1;
wire [7:0] if_q0;
wire [3:0] if_d9;
wire [3:0] if_d8;
wire [3:0] if_d7;
wire [3:0] if_d6;
wire [3:0] if_d5;
wire [3:0] if_d4;
wire [3:0] if_d3;
wire [3:0] if_d2;
wire [3:0] if_d1;
wire [3:0] if_d0;
wire [3:0] dummy_i5;
wire [3:0] dummy_i6;
wire [48-1:0] of_dqbus;
wire [10*4-1:0] iserdes_dout;
wire iserdes_clk;
wire iserdes_clkdiv;
wire ififo_wr_enable;
wire phy_rd_en_;
wire dqs_to_phaser;
wire phy_wr_en = ( PO_DATA_CTL == "FALSE" ) ? phy_cmd_wr_en : phy_data_wr_en;
wire if_empty_;
wire if_a_empty_;
wire if_full_;
wire if_a_full_;
wire po_oserdes_rst;
wire empty_post_fifo;
reg [3:0] if_empty_r /* synthesis syn_maxfan = 3 */;
wire [79:0] rd_data;
reg [79:0] rd_data_r;
reg ififo_rst = 1'b1;
reg ofifo_rst = 1'b1;
wire of_wren_pre;
wire [79:0] pre_fifo_dout;
wire pre_fifo_full;
wire pre_fifo_rden;
wire [5:0] ddr_ck_out_q;
wire ififo_rd_en_in /* synthesis syn_maxfan = 10 */;
wire oserdes_clkdiv;
wire oserdes_clk_delayed;
wire po_rd_enable;
always @(posedge phy_clk) begin
ififo_rst <= #1 pi_rst_dqs_find | if_rst ;
// reset only data o-fifos on reset of dqs_found
ofifo_rst <= #1 (pi_rst_dqs_find & PO_DATA_CTL == "TRUE") | rst;
end
// IN_FIFO EMPTY->RDEN TIMING FIX:
// Always read from IN_FIFO - it doesn't hurt to read from an empty FIFO
// since the IN_FIFO read pointers are not incr'ed when the FIFO is empty
assign #(25) phy_rd_en_ = 1'b1;
//assign #(25) phy_rd_en_ = phy_rd_en;
generate
if ( PO_DATA_CTL == "FALSE" ) begin : if_empty_null
assign if_empty = 0;
assign if_a_empty = 0;
assign if_full = 0;
assign if_a_full = 0;
end
else begin : if_empty_gen
assign if_empty = empty_post_fifo;
assign if_a_empty = if_a_empty_;
assign if_full = if_full_;
assign if_a_full = if_a_full_;
end
endgenerate
generate
if ( PO_DATA_CTL == "FALSE" ) begin : dq_gen_48
assign of_dqbus[48-1:0] = {of_q6[7:4], of_q5[7:4], of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign phy_din = 80'h0;
assign byte_rd_en = 1'b1;
end
else begin : dq_gen_40
assign of_dqbus[40-1:0] = {of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign ififo_rd_en_in = !if_empty_def ? ((&byte_rd_en_oth_banks) && (&byte_rd_en_oth_lanes) && byte_rd_en) :
((|byte_rd_en_oth_banks) || (|byte_rd_en_oth_lanes) || byte_rd_en);
if (USE_PRE_POST_FIFO == "TRUE") begin : if_post_fifo_gen
// IN_FIFO EMPTY->RDEN TIMING FIX:
assign rd_data = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
always @(posedge phy_clk) begin
rd_data_r <= #(025) rd_data;
if_empty_r[0] <= #(025) if_empty_;
if_empty_r[1] <= #(025) if_empty_;
if_empty_r[2] <= #(025) if_empty_;
if_empty_r[3] <= #(025) if_empty_;
end
mig_7series_v2_3_ddr_if_post_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (4), //2 // depth - account for up to 2 cycles of skew
.WIDTH (80) // width
)
u_ddr_if_post_fifo
(
.clk (phy_clk),
.rst (ififo_rst),
.empty_in (if_empty_r),
.rd_en_in (ififo_rd_en_in),
.d_in (rd_data_r),
.empty_out (empty_post_fifo),
.byte_rd_en (byte_rd_en),
.d_out (phy_din)
);
end
else begin : phy_din_gen
assign phy_din = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
assign empty_post_fifo = if_empty_;
end
end
endgenerate
assign { if_d9, if_d8, if_d7, if_d6, if_d5, if_d4, if_d3, if_d2, if_d1, if_d0} = iserdes_dout;
wire [1:0] rank_sel_i = ((phaser_ctl_bus[MSB_RANK_SEL_I :MSB_RANK_SEL_I -7] >> (PHASER_INDEX << 1)) & 2'b11);
generate
if ( USE_PRE_POST_FIFO == "TRUE" ) begin : of_pre_fifo_gen
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = pre_fifo_dout;
mig_7series_v2_3_ddr_of_pre_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (9), // depth - set to 9 to accommodate flow control
.WIDTH (80) // width
)
u_ddr_of_pre_fifo
(
.clk (phy_clk),
.rst (ofifo_rst),
.full_in (of_full),
.wr_en_in (phy_wr_en),
.d_in (phy_dout),
.wr_en_out (of_wren_pre),
.d_out (pre_fifo_dout),
.afull (pre_fifo_a_full)
);
end
else begin
// wire direct to ofifo
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = phy_dout;
assign of_wren_pre = phy_wr_en;
end
endgenerate
generate
if ( PO_DATA_CTL == "TRUE" || ((RCLK_SELECT_LANE==ABCD) && (CKE_ODT_AUX =="TRUE"))) begin : phaser_in_gen
PHASER_IN_PHY #(
.BURST_MODE ( PI_BURST_MODE),
.CLKOUT_DIV ( PI_CLKOUT_DIV),
.DQS_AUTO_RECAL ( DQS_AUTO_RECAL),
.DQS_FIND_PATTERN ( DQS_FIND_PATTERN),
.SEL_CLK_OFFSET ( PI_SEL_CLK_OFFSET),
.FINE_DELAY ( PI_FINE_DELAY),
.FREQ_REF_DIV ( PI_FREQ_REF_DIV),
.OUTPUT_CLK_SRC ( PI_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PI_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( L_PHASE_REF_PERIOD_NS)
) phaser_in (
.DQSFOUND (pi_dqs_found),
.DQSOUTOFRANGE (dqs_out_of_range),
.FINEOVERFLOW (pi_fine_overflow),
.PHASELOCKED (pi_phase_locked),
.ISERDESRST (pi_iserdes_rst),
.ICLKDIV (iserdes_clkdiv),
.ICLK (iserdes_clk),
.COUNTERREADVAL (pi_counter_read_val),
.RCLK (rclk),
.WRENABLE (ififo_wr_enable),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PI - 3 + PHASER_INDEX]),
.ENCALIBPHY (pi_en_calib),
.FINEENABLE (pi_fine_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.RANKSELPHY (rank_sel_i),
.PHASEREFCLK (dqs_to_phaser),
.RSTDQSFIND (pi_rst_dqs_find),
.RST (rst),
.FINEINC (pi_fine_inc),
.COUNTERLOADEN (pi_counter_load_en),
.COUNTERREADEN (pi_counter_read_en),
.COUNTERLOADVAL (pi_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
end
else begin
assign pi_dqs_found = 1'b1;
// assign pi_dqs_out_of_range = 1'b0;
assign pi_phase_locked = 1'b1;
end
endgenerate
wire #0 phase_ref = freq_refclk;
wire oserdes_clk;
PHASER_OUT_PHY #(
.CLKOUT_DIV ( PO_CLKOUT_DIV),
.DATA_CTL_N ( PO_DATA_CTL ),
.FINE_DELAY ( PO_FINE_DELAY),
.COARSE_BYPASS ( PO_COARSE_BYPASS ),
.COARSE_DELAY ( PO_COARSE_DELAY),
.OCLK_DELAY ( PO_OCLK_DELAY),
.OCLKDELAY_INV ( PO_OCLKDELAY_INV),
.OUTPUT_CLK_SRC ( PO_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PO_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( 1), // dummy, not used
.PO ( PO_DCD_SETTING ),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS)
) phaser_out (
.COARSEOVERFLOW (po_coarse_overflow),
.CTSBUS (oserdes_dqs_ts),
.DQSBUS (oserdes_dqs),
.DTSBUS (oserdes_dq_ts),
.FINEOVERFLOW (po_fine_overflow),
.OCLKDIV (oserdes_clkdiv),
.OCLK (oserdes_clk),
.OCLKDELAYED (oserdes_clk_delayed),
.COUNTERREADVAL (po_counter_read_val),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PO -3 + PHASER_INDEX]),
.ENCALIBPHY (po_en_calib),
.RDENABLE (po_rd_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.PHASEREFCLK (/*phase_ref*/),
.RST (rst),
.OSERDESRST (po_oserdes_rst),
.COARSEENABLE (po_coarse_enable),
.FINEENABLE (po_fine_enable),
.COARSEINC (po_coarse_inc),
.FINEINC (po_fine_inc),
.SELFINEOCLKDELAY (po_sel_fine_oclk_delay),
.COUNTERLOADEN (po_counter_load_en),
.COUNTERREADEN (po_counter_read_en),
.COUNTERLOADVAL (po_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
generate
if (PO_DATA_CTL == "TRUE") begin : in_fifo_gen
IN_FIFO #(
.ALMOST_EMPTY_VALUE ( IF_ALMOST_EMPTY_VALUE ),
.ALMOST_FULL_VALUE ( IF_ALMOST_FULL_VALUE ),
.ARRAY_MODE ( L_IF_ARRAY_MODE),
.SYNCHRONOUS_MODE ( IF_SYNCHRONOUS_MODE)
) in_fifo (
.ALMOSTEMPTY (if_a_empty_),
.ALMOSTFULL (if_a_full_),
.EMPTY (if_empty_),
.FULL (if_full_),
.Q0 (if_q0),
.Q1 (if_q1),
.Q2 (if_q2),
.Q3 (if_q3),
.Q4 (if_q4),
.Q5 (if_q5),
.Q6 (if_q6),
.Q7 (if_q7),
.Q8 (if_q8),
.Q9 (if_q9),
//===
.D0 (if_d0),
.D1 (if_d1),
.D2 (if_d2),
.D3 (if_d3),
.D4 (if_d4),
.D5 ({dummy_i5,if_d5}),
.D6 ({dummy_i6,if_d6}),
.D7 (if_d7),
.D8 (if_d8),
.D9 (if_d9),
.RDCLK (phy_clk),
.RDEN (phy_rd_en_),
.RESET (ififo_rst),
.WRCLK (iserdes_clkdiv),
.WREN (ififo_wr_enable)
);
end
endgenerate
OUT_FIFO #(
.ALMOST_EMPTY_VALUE (OF_ALMOST_EMPTY_VALUE),
.ALMOST_FULL_VALUE (OF_ALMOST_FULL_VALUE),
.ARRAY_MODE (L_OF_ARRAY_MODE),
.OUTPUT_DISABLE (OF_OUTPUT_DISABLE),
.SYNCHRONOUS_MODE (OF_SYNCHRONOUS_MODE)
) out_fifo (
.ALMOSTEMPTY (of_a_empty),
.ALMOSTFULL (of_a_full),
.EMPTY (of_empty),
.FULL (of_full),
.Q0 (of_q0),
.Q1 (of_q1),
.Q2 (of_q2),
.Q3 (of_q3),
.Q4 (of_q4),
.Q5 (of_q5),
.Q6 (of_q6),
.Q7 (of_q7),
.Q8 (of_q8),
.Q9 (of_q9),
.D0 (of_d0),
.D1 (of_d1),
.D2 (of_d2),
.D3 (of_d3),
.D4 (of_d4),
.D5 (of_d5),
.D6 (of_d6),
.D7 (of_d7),
.D8 (of_d8),
.D9 (of_d9),
.RDCLK (oserdes_clkdiv),
.RDEN (po_rd_enable),
.RESET (ofifo_rst),
.WRCLK (phy_clk),
.WREN (of_wren_pre)
);
mig_7series_v2_3_ddr_byte_group_io #
(
.PO_DATA_CTL (PO_DATA_CTL),
.BITLANES (BITLANES),
.BITLANES_OUTONLY (BITLANES_OUTONLY),
.OSERDES_DATA_RATE (L_OSERDES_DATA_RATE),
.OSERDES_DATA_WIDTH (L_OSERDES_DATA_WIDTH),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.IDELAYE2_IDELAY_TYPE (IDELAYE2_IDELAY_TYPE),
.IDELAYE2_IDELAY_VALUE (IDELAYE2_IDELAY_VALUE),
.TCK (TCK),
.SYNTHESIS (SYNTHESIS)
)
ddr_byte_group_io
(
.mem_dq_out (mem_dq_out),
.mem_dq_ts (mem_dq_ts),
.mem_dq_in (mem_dq_in),
.mem_dqs_in (mem_dqs_in),
.mem_dqs_out (mem_dqs_out),
.mem_dqs_ts (mem_dqs_ts),
.rst (rst),
.oserdes_rst (po_oserdes_rst),
.iserdes_rst (pi_iserdes_rst ),
.iserdes_dout (iserdes_dout),
.dqs_to_phaser (dqs_to_phaser),
.phy_clk (phy_clk),
.iserdes_clk (iserdes_clk),
.iserdes_clkb (!iserdes_clk),
.iserdes_clkdiv (iserdes_clkdiv),
.idelay_inc (idelay_inc),
.idelay_ce (idelay_ce),
.idelay_ld (idelay_ld),
.idelayctrl_refclk (idelayctrl_refclk),
.oserdes_clk (oserdes_clk),
.oserdes_clk_delayed (oserdes_clk_delayed),
.oserdes_clkdiv (oserdes_clkdiv),
.oserdes_dqs ({oserdes_dqs[1], oserdes_dqs[0]}),
.oserdes_dqsts ({oserdes_dqs_ts[1], oserdes_dqs_ts[0]}),
.oserdes_dq (of_dqbus),
.oserdes_dqts ({oserdes_dq_ts[1], oserdes_dq_ts[0]}),
.fine_delay (fine_delay),
.fine_delay_sel (fine_delay_sel)
);
genvar i;
generate
for (i = 0; i <= 5; i = i+1) begin : ddr_ck_gen_loop
if (PO_DATA_CTL== "FALSE" && (BYTELANES_DDR_CK[i*4+PHASER_INDEX])) begin : ddr_ck_gen
ODDR #(.DDR_CLK_EDGE (ODDR_CLK_EDGE))
ddr_ck (
.C (oserdes_clk),
.R (1'b0),
.S (),
.D1 (1'b0),
.D2 (1'b1),
.CE (1'b1),
.Q (ddr_ck_out_q[i])
);
OBUFDS ddr_ck_obuf (.I(ddr_ck_out_q[i]), .O(ddr_ck_out[i*2]), .OB(ddr_ck_out[i*2+1]));
end // ddr_ck_gen
else begin : ddr_ck_null
assign ddr_ck_out[i*2+1:i*2] = 2'b0;
end
end // ddr_ck_gen_loop
endgenerate
endmodule
|
module mig_7series_v2_3_ddr_byte_lane #(
// these are used to scale the index into phaser,calib,scan,mc vectors
// to access fields used in this instance
parameter ABCD = "A", // A,B,C, or D
parameter PO_DATA_CTL = "FALSE",
parameter BITLANES = 12'b1111_1111_1111,
parameter BITLANES_OUTONLY = 12'b1111_1111_1111,
parameter BYTELANES_DDR_CK = 24'b0010_0010_0010_0010_0010_0010,
parameter RCLK_SELECT_LANE = "B",
parameter PC_CLK_RATIO = 4,
parameter USE_PRE_POST_FIFO = "FALSE",
//OUT_FIFO
parameter OF_ALMOST_EMPTY_VALUE = 1,
parameter OF_ALMOST_FULL_VALUE = 1,
parameter OF_ARRAY_MODE = "UNDECLARED",
parameter OF_OUTPUT_DISABLE = "FALSE",
parameter OF_SYNCHRONOUS_MODE = "TRUE",
//IN_FIFO
parameter IF_ALMOST_EMPTY_VALUE = 1,
parameter IF_ALMOST_FULL_VALUE = 1,
parameter IF_ARRAY_MODE = "UNDECLARED",
parameter IF_SYNCHRONOUS_MODE = "TRUE",
//PHASER_IN
parameter PI_BURST_MODE = "TRUE",
parameter PI_CLKOUT_DIV = 2,
parameter PI_FREQ_REF_DIV = "NONE",
parameter PI_FINE_DELAY = 1,
parameter PI_OUTPUT_CLK_SRC = "DELAYED_REF" , //"DELAYED_REF",
parameter PI_SEL_CLK_OFFSET = 0,
parameter PI_SYNC_IN_DIV_RST = "FALSE",
//PHASER_OUT
parameter PO_CLKOUT_DIV = (PO_DATA_CTL == "FALSE") ? 4 : 2,
parameter PO_FINE_DELAY = 0,
parameter PO_COARSE_BYPASS = "FALSE",
parameter PO_COARSE_DELAY = 0,
parameter PO_OCLK_DELAY = 0,
parameter PO_OCLKDELAY_INV = "TRUE",
parameter PO_OUTPUT_CLK_SRC = "DELAYED_REF",
parameter PO_SYNC_IN_DIV_RST = "FALSE",
// OSERDES
parameter OSERDES_DATA_RATE = "DDR",
parameter OSERDES_DATA_WIDTH = 4,
//IDELAY
parameter IDELAYE2_IDELAY_TYPE = "VARIABLE",
parameter IDELAYE2_IDELAY_VALUE = 00,
parameter IODELAY_GRP = "IODELAY_MIG",
parameter FPGA_SPEED_GRADE = 1,
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter real TCK = 0.00,
parameter SYNTHESIS = "FALSE",
// local constants, do not pass in from above
parameter BUS_WIDTH = 12,
parameter MSB_BURST_PEND_PO = 3,
parameter MSB_BURST_PEND_PI = 7,
parameter MSB_RANK_SEL_I = MSB_BURST_PEND_PI + 8,
parameter PHASER_CTL_BUS_WIDTH = MSB_RANK_SEL_I + 1
,parameter CKE_ODT_AUX = "FALSE"
)(
input rst,
input phy_clk,
input freq_refclk,
input mem_refclk,
input idelayctrl_refclk,
input sync_pulse,
output [BUS_WIDTH-1:0] mem_dq_out,
output [BUS_WIDTH-1:0] mem_dq_ts,
input [9:0] mem_dq_in,
output mem_dqs_out,
output mem_dqs_ts,
input mem_dqs_in,
output [11:0] ddr_ck_out,
output rclk,
input if_empty_def,
output if_a_empty,
output if_empty,
output if_a_full,
output if_full,
output of_a_empty,
output of_empty,
output of_a_full,
output of_full,
output pre_fifo_a_full,
output [79:0] phy_din,
input [79:0] phy_dout,
input phy_cmd_wr_en,
input phy_data_wr_en,
input phy_rd_en,
input [PHASER_CTL_BUS_WIDTH-1:0] phaser_ctl_bus,
input idelay_inc,
input idelay_ce,
input idelay_ld,
input if_rst,
input [2:0] byte_rd_en_oth_lanes,
input [1:0] byte_rd_en_oth_banks,
output byte_rd_en,
output po_coarse_overflow,
output po_fine_overflow,
output [8:0] po_counter_read_val,
input po_fine_enable,
input po_coarse_enable,
input [1:0] po_en_calib,
input po_fine_inc,
input po_coarse_inc,
input po_counter_load_en,
input po_counter_read_en,
input po_sel_fine_oclk_delay,
input [8:0] po_counter_load_val,
input [1:0] pi_en_calib,
input pi_rst_dqs_find,
input pi_fine_enable,
input pi_fine_inc,
input pi_counter_load_en,
input pi_counter_read_en,
input [5:0] pi_counter_load_val,
output wire pi_iserdes_rst,
output pi_phase_locked,
output pi_fine_overflow,
output [5:0] pi_counter_read_val,
output wire pi_dqs_found,
output dqs_out_of_range,
input [29:0] fine_delay,
input fine_delay_sel
);
localparam PHASER_INDEX =
(ABCD=="B" ? 1 : (ABCD == "C") ? 2 : (ABCD == "D" ? 3 : 0));
localparam L_OF_ARRAY_MODE =
(OF_ARRAY_MODE != "UNDECLARED") ? OF_ARRAY_MODE :
(PO_DATA_CTL == "FALSE" || PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_8_X_4";
localparam L_IF_ARRAY_MODE = (IF_ARRAY_MODE != "UNDECLARED") ? IF_ARRAY_MODE :
(PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_4_X_8";
localparam L_OSERDES_DATA_RATE = (OSERDES_DATA_RATE != "UNDECLARED") ? OSERDES_DATA_RATE : ((PO_DATA_CTL == "FALSE" && PC_CLK_RATIO == 4) ? "SDR" : "DDR") ;
localparam L_OSERDES_DATA_WIDTH = (OSERDES_DATA_WIDTH != "UNDECLARED") ? OSERDES_DATA_WIDTH : 4;
localparam real L_FREQ_REF_PERIOD_NS = TCK > 2500.0 ? (TCK/(PI_FREQ_REF_DIV == "DIV2" ? 2 : 1)/1000.0) : TCK/1000.0;
localparam real L_MEM_REF_PERIOD_NS = TCK/1000.0;
localparam real L_PHASE_REF_PERIOD_NS = TCK/1000.0;
localparam ODDR_CLK_EDGE = "SAME_EDGE";
localparam PO_DCD_CORRECTION = "ON";
localparam [2:0] PO_DCD_SETTING = (PO_DCD_CORRECTION == "ON") ? 3'b111 : 3'b000;
localparam DQS_AUTO_RECAL = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? 1 : 0;
localparam DQS_FIND_PATTERN = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? "001" : "000";
wire [1:0] oserdes_dqs;
wire [1:0] oserdes_dqs_ts;
wire [1:0] oserdes_dq_ts;
wire [3:0] of_q9;
wire [3:0] of_q8;
wire [3:0] of_q7;
wire [7:0] of_q6;
wire [7:0] of_q5;
wire [3:0] of_q4;
wire [3:0] of_q3;
wire [3:0] of_q2;
wire [3:0] of_q1;
wire [3:0] of_q0;
wire [7:0] of_d9;
wire [7:0] of_d8;
wire [7:0] of_d7;
wire [7:0] of_d6;
wire [7:0] of_d5;
wire [7:0] of_d4;
wire [7:0] of_d3;
wire [7:0] of_d2;
wire [7:0] of_d1;
wire [7:0] of_d0;
wire [7:0] if_q9;
wire [7:0] if_q8;
wire [7:0] if_q7;
wire [7:0] if_q6;
wire [7:0] if_q5;
wire [7:0] if_q4;
wire [7:0] if_q3;
wire [7:0] if_q2;
wire [7:0] if_q1;
wire [7:0] if_q0;
wire [3:0] if_d9;
wire [3:0] if_d8;
wire [3:0] if_d7;
wire [3:0] if_d6;
wire [3:0] if_d5;
wire [3:0] if_d4;
wire [3:0] if_d3;
wire [3:0] if_d2;
wire [3:0] if_d1;
wire [3:0] if_d0;
wire [3:0] dummy_i5;
wire [3:0] dummy_i6;
wire [48-1:0] of_dqbus;
wire [10*4-1:0] iserdes_dout;
wire iserdes_clk;
wire iserdes_clkdiv;
wire ififo_wr_enable;
wire phy_rd_en_;
wire dqs_to_phaser;
wire phy_wr_en = ( PO_DATA_CTL == "FALSE" ) ? phy_cmd_wr_en : phy_data_wr_en;
wire if_empty_;
wire if_a_empty_;
wire if_full_;
wire if_a_full_;
wire po_oserdes_rst;
wire empty_post_fifo;
reg [3:0] if_empty_r /* synthesis syn_maxfan = 3 */;
wire [79:0] rd_data;
reg [79:0] rd_data_r;
reg ififo_rst = 1'b1;
reg ofifo_rst = 1'b1;
wire of_wren_pre;
wire [79:0] pre_fifo_dout;
wire pre_fifo_full;
wire pre_fifo_rden;
wire [5:0] ddr_ck_out_q;
wire ififo_rd_en_in /* synthesis syn_maxfan = 10 */;
wire oserdes_clkdiv;
wire oserdes_clk_delayed;
wire po_rd_enable;
always @(posedge phy_clk) begin
ififo_rst <= #1 pi_rst_dqs_find | if_rst ;
// reset only data o-fifos on reset of dqs_found
ofifo_rst <= #1 (pi_rst_dqs_find & PO_DATA_CTL == "TRUE") | rst;
end
// IN_FIFO EMPTY->RDEN TIMING FIX:
// Always read from IN_FIFO - it doesn't hurt to read from an empty FIFO
// since the IN_FIFO read pointers are not incr'ed when the FIFO is empty
assign #(25) phy_rd_en_ = 1'b1;
//assign #(25) phy_rd_en_ = phy_rd_en;
generate
if ( PO_DATA_CTL == "FALSE" ) begin : if_empty_null
assign if_empty = 0;
assign if_a_empty = 0;
assign if_full = 0;
assign if_a_full = 0;
end
else begin : if_empty_gen
assign if_empty = empty_post_fifo;
assign if_a_empty = if_a_empty_;
assign if_full = if_full_;
assign if_a_full = if_a_full_;
end
endgenerate
generate
if ( PO_DATA_CTL == "FALSE" ) begin : dq_gen_48
assign of_dqbus[48-1:0] = {of_q6[7:4], of_q5[7:4], of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign phy_din = 80'h0;
assign byte_rd_en = 1'b1;
end
else begin : dq_gen_40
assign of_dqbus[40-1:0] = {of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign ififo_rd_en_in = !if_empty_def ? ((&byte_rd_en_oth_banks) && (&byte_rd_en_oth_lanes) && byte_rd_en) :
((|byte_rd_en_oth_banks) || (|byte_rd_en_oth_lanes) || byte_rd_en);
if (USE_PRE_POST_FIFO == "TRUE") begin : if_post_fifo_gen
// IN_FIFO EMPTY->RDEN TIMING FIX:
assign rd_data = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
always @(posedge phy_clk) begin
rd_data_r <= #(025) rd_data;
if_empty_r[0] <= #(025) if_empty_;
if_empty_r[1] <= #(025) if_empty_;
if_empty_r[2] <= #(025) if_empty_;
if_empty_r[3] <= #(025) if_empty_;
end
mig_7series_v2_3_ddr_if_post_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (4), //2 // depth - account for up to 2 cycles of skew
.WIDTH (80) // width
)
u_ddr_if_post_fifo
(
.clk (phy_clk),
.rst (ififo_rst),
.empty_in (if_empty_r),
.rd_en_in (ififo_rd_en_in),
.d_in (rd_data_r),
.empty_out (empty_post_fifo),
.byte_rd_en (byte_rd_en),
.d_out (phy_din)
);
end
else begin : phy_din_gen
assign phy_din = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
assign empty_post_fifo = if_empty_;
end
end
endgenerate
assign { if_d9, if_d8, if_d7, if_d6, if_d5, if_d4, if_d3, if_d2, if_d1, if_d0} = iserdes_dout;
wire [1:0] rank_sel_i = ((phaser_ctl_bus[MSB_RANK_SEL_I :MSB_RANK_SEL_I -7] >> (PHASER_INDEX << 1)) & 2'b11);
generate
if ( USE_PRE_POST_FIFO == "TRUE" ) begin : of_pre_fifo_gen
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = pre_fifo_dout;
mig_7series_v2_3_ddr_of_pre_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (9), // depth - set to 9 to accommodate flow control
.WIDTH (80) // width
)
u_ddr_of_pre_fifo
(
.clk (phy_clk),
.rst (ofifo_rst),
.full_in (of_full),
.wr_en_in (phy_wr_en),
.d_in (phy_dout),
.wr_en_out (of_wren_pre),
.d_out (pre_fifo_dout),
.afull (pre_fifo_a_full)
);
end
else begin
// wire direct to ofifo
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = phy_dout;
assign of_wren_pre = phy_wr_en;
end
endgenerate
generate
if ( PO_DATA_CTL == "TRUE" || ((RCLK_SELECT_LANE==ABCD) && (CKE_ODT_AUX =="TRUE"))) begin : phaser_in_gen
PHASER_IN_PHY #(
.BURST_MODE ( PI_BURST_MODE),
.CLKOUT_DIV ( PI_CLKOUT_DIV),
.DQS_AUTO_RECAL ( DQS_AUTO_RECAL),
.DQS_FIND_PATTERN ( DQS_FIND_PATTERN),
.SEL_CLK_OFFSET ( PI_SEL_CLK_OFFSET),
.FINE_DELAY ( PI_FINE_DELAY),
.FREQ_REF_DIV ( PI_FREQ_REF_DIV),
.OUTPUT_CLK_SRC ( PI_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PI_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( L_PHASE_REF_PERIOD_NS)
) phaser_in (
.DQSFOUND (pi_dqs_found),
.DQSOUTOFRANGE (dqs_out_of_range),
.FINEOVERFLOW (pi_fine_overflow),
.PHASELOCKED (pi_phase_locked),
.ISERDESRST (pi_iserdes_rst),
.ICLKDIV (iserdes_clkdiv),
.ICLK (iserdes_clk),
.COUNTERREADVAL (pi_counter_read_val),
.RCLK (rclk),
.WRENABLE (ififo_wr_enable),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PI - 3 + PHASER_INDEX]),
.ENCALIBPHY (pi_en_calib),
.FINEENABLE (pi_fine_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.RANKSELPHY (rank_sel_i),
.PHASEREFCLK (dqs_to_phaser),
.RSTDQSFIND (pi_rst_dqs_find),
.RST (rst),
.FINEINC (pi_fine_inc),
.COUNTERLOADEN (pi_counter_load_en),
.COUNTERREADEN (pi_counter_read_en),
.COUNTERLOADVAL (pi_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
end
else begin
assign pi_dqs_found = 1'b1;
// assign pi_dqs_out_of_range = 1'b0;
assign pi_phase_locked = 1'b1;
end
endgenerate
wire #0 phase_ref = freq_refclk;
wire oserdes_clk;
PHASER_OUT_PHY #(
.CLKOUT_DIV ( PO_CLKOUT_DIV),
.DATA_CTL_N ( PO_DATA_CTL ),
.FINE_DELAY ( PO_FINE_DELAY),
.COARSE_BYPASS ( PO_COARSE_BYPASS ),
.COARSE_DELAY ( PO_COARSE_DELAY),
.OCLK_DELAY ( PO_OCLK_DELAY),
.OCLKDELAY_INV ( PO_OCLKDELAY_INV),
.OUTPUT_CLK_SRC ( PO_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PO_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( 1), // dummy, not used
.PO ( PO_DCD_SETTING ),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS)
) phaser_out (
.COARSEOVERFLOW (po_coarse_overflow),
.CTSBUS (oserdes_dqs_ts),
.DQSBUS (oserdes_dqs),
.DTSBUS (oserdes_dq_ts),
.FINEOVERFLOW (po_fine_overflow),
.OCLKDIV (oserdes_clkdiv),
.OCLK (oserdes_clk),
.OCLKDELAYED (oserdes_clk_delayed),
.COUNTERREADVAL (po_counter_read_val),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PO -3 + PHASER_INDEX]),
.ENCALIBPHY (po_en_calib),
.RDENABLE (po_rd_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.PHASEREFCLK (/*phase_ref*/),
.RST (rst),
.OSERDESRST (po_oserdes_rst),
.COARSEENABLE (po_coarse_enable),
.FINEENABLE (po_fine_enable),
.COARSEINC (po_coarse_inc),
.FINEINC (po_fine_inc),
.SELFINEOCLKDELAY (po_sel_fine_oclk_delay),
.COUNTERLOADEN (po_counter_load_en),
.COUNTERREADEN (po_counter_read_en),
.COUNTERLOADVAL (po_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
generate
if (PO_DATA_CTL == "TRUE") begin : in_fifo_gen
IN_FIFO #(
.ALMOST_EMPTY_VALUE ( IF_ALMOST_EMPTY_VALUE ),
.ALMOST_FULL_VALUE ( IF_ALMOST_FULL_VALUE ),
.ARRAY_MODE ( L_IF_ARRAY_MODE),
.SYNCHRONOUS_MODE ( IF_SYNCHRONOUS_MODE)
) in_fifo (
.ALMOSTEMPTY (if_a_empty_),
.ALMOSTFULL (if_a_full_),
.EMPTY (if_empty_),
.FULL (if_full_),
.Q0 (if_q0),
.Q1 (if_q1),
.Q2 (if_q2),
.Q3 (if_q3),
.Q4 (if_q4),
.Q5 (if_q5),
.Q6 (if_q6),
.Q7 (if_q7),
.Q8 (if_q8),
.Q9 (if_q9),
//===
.D0 (if_d0),
.D1 (if_d1),
.D2 (if_d2),
.D3 (if_d3),
.D4 (if_d4),
.D5 ({dummy_i5,if_d5}),
.D6 ({dummy_i6,if_d6}),
.D7 (if_d7),
.D8 (if_d8),
.D9 (if_d9),
.RDCLK (phy_clk),
.RDEN (phy_rd_en_),
.RESET (ififo_rst),
.WRCLK (iserdes_clkdiv),
.WREN (ififo_wr_enable)
);
end
endgenerate
OUT_FIFO #(
.ALMOST_EMPTY_VALUE (OF_ALMOST_EMPTY_VALUE),
.ALMOST_FULL_VALUE (OF_ALMOST_FULL_VALUE),
.ARRAY_MODE (L_OF_ARRAY_MODE),
.OUTPUT_DISABLE (OF_OUTPUT_DISABLE),
.SYNCHRONOUS_MODE (OF_SYNCHRONOUS_MODE)
) out_fifo (
.ALMOSTEMPTY (of_a_empty),
.ALMOSTFULL (of_a_full),
.EMPTY (of_empty),
.FULL (of_full),
.Q0 (of_q0),
.Q1 (of_q1),
.Q2 (of_q2),
.Q3 (of_q3),
.Q4 (of_q4),
.Q5 (of_q5),
.Q6 (of_q6),
.Q7 (of_q7),
.Q8 (of_q8),
.Q9 (of_q9),
.D0 (of_d0),
.D1 (of_d1),
.D2 (of_d2),
.D3 (of_d3),
.D4 (of_d4),
.D5 (of_d5),
.D6 (of_d6),
.D7 (of_d7),
.D8 (of_d8),
.D9 (of_d9),
.RDCLK (oserdes_clkdiv),
.RDEN (po_rd_enable),
.RESET (ofifo_rst),
.WRCLK (phy_clk),
.WREN (of_wren_pre)
);
mig_7series_v2_3_ddr_byte_group_io #
(
.PO_DATA_CTL (PO_DATA_CTL),
.BITLANES (BITLANES),
.BITLANES_OUTONLY (BITLANES_OUTONLY),
.OSERDES_DATA_RATE (L_OSERDES_DATA_RATE),
.OSERDES_DATA_WIDTH (L_OSERDES_DATA_WIDTH),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.IDELAYE2_IDELAY_TYPE (IDELAYE2_IDELAY_TYPE),
.IDELAYE2_IDELAY_VALUE (IDELAYE2_IDELAY_VALUE),
.TCK (TCK),
.SYNTHESIS (SYNTHESIS)
)
ddr_byte_group_io
(
.mem_dq_out (mem_dq_out),
.mem_dq_ts (mem_dq_ts),
.mem_dq_in (mem_dq_in),
.mem_dqs_in (mem_dqs_in),
.mem_dqs_out (mem_dqs_out),
.mem_dqs_ts (mem_dqs_ts),
.rst (rst),
.oserdes_rst (po_oserdes_rst),
.iserdes_rst (pi_iserdes_rst ),
.iserdes_dout (iserdes_dout),
.dqs_to_phaser (dqs_to_phaser),
.phy_clk (phy_clk),
.iserdes_clk (iserdes_clk),
.iserdes_clkb (!iserdes_clk),
.iserdes_clkdiv (iserdes_clkdiv),
.idelay_inc (idelay_inc),
.idelay_ce (idelay_ce),
.idelay_ld (idelay_ld),
.idelayctrl_refclk (idelayctrl_refclk),
.oserdes_clk (oserdes_clk),
.oserdes_clk_delayed (oserdes_clk_delayed),
.oserdes_clkdiv (oserdes_clkdiv),
.oserdes_dqs ({oserdes_dqs[1], oserdes_dqs[0]}),
.oserdes_dqsts ({oserdes_dqs_ts[1], oserdes_dqs_ts[0]}),
.oserdes_dq (of_dqbus),
.oserdes_dqts ({oserdes_dq_ts[1], oserdes_dq_ts[0]}),
.fine_delay (fine_delay),
.fine_delay_sel (fine_delay_sel)
);
genvar i;
generate
for (i = 0; i <= 5; i = i+1) begin : ddr_ck_gen_loop
if (PO_DATA_CTL== "FALSE" && (BYTELANES_DDR_CK[i*4+PHASER_INDEX])) begin : ddr_ck_gen
ODDR #(.DDR_CLK_EDGE (ODDR_CLK_EDGE))
ddr_ck (
.C (oserdes_clk),
.R (1'b0),
.S (),
.D1 (1'b0),
.D2 (1'b1),
.CE (1'b1),
.Q (ddr_ck_out_q[i])
);
OBUFDS ddr_ck_obuf (.I(ddr_ck_out_q[i]), .O(ddr_ck_out[i*2]), .OB(ddr_ck_out[i*2+1]));
end // ddr_ck_gen
else begin : ddr_ck_null
assign ddr_ck_out[i*2+1:i*2] = 2'b0;
end
end // ddr_ck_gen_loop
endgenerate
endmodule
|
module mig_7series_v2_3_ddr_byte_lane #(
// these are used to scale the index into phaser,calib,scan,mc vectors
// to access fields used in this instance
parameter ABCD = "A", // A,B,C, or D
parameter PO_DATA_CTL = "FALSE",
parameter BITLANES = 12'b1111_1111_1111,
parameter BITLANES_OUTONLY = 12'b1111_1111_1111,
parameter BYTELANES_DDR_CK = 24'b0010_0010_0010_0010_0010_0010,
parameter RCLK_SELECT_LANE = "B",
parameter PC_CLK_RATIO = 4,
parameter USE_PRE_POST_FIFO = "FALSE",
//OUT_FIFO
parameter OF_ALMOST_EMPTY_VALUE = 1,
parameter OF_ALMOST_FULL_VALUE = 1,
parameter OF_ARRAY_MODE = "UNDECLARED",
parameter OF_OUTPUT_DISABLE = "FALSE",
parameter OF_SYNCHRONOUS_MODE = "TRUE",
//IN_FIFO
parameter IF_ALMOST_EMPTY_VALUE = 1,
parameter IF_ALMOST_FULL_VALUE = 1,
parameter IF_ARRAY_MODE = "UNDECLARED",
parameter IF_SYNCHRONOUS_MODE = "TRUE",
//PHASER_IN
parameter PI_BURST_MODE = "TRUE",
parameter PI_CLKOUT_DIV = 2,
parameter PI_FREQ_REF_DIV = "NONE",
parameter PI_FINE_DELAY = 1,
parameter PI_OUTPUT_CLK_SRC = "DELAYED_REF" , //"DELAYED_REF",
parameter PI_SEL_CLK_OFFSET = 0,
parameter PI_SYNC_IN_DIV_RST = "FALSE",
//PHASER_OUT
parameter PO_CLKOUT_DIV = (PO_DATA_CTL == "FALSE") ? 4 : 2,
parameter PO_FINE_DELAY = 0,
parameter PO_COARSE_BYPASS = "FALSE",
parameter PO_COARSE_DELAY = 0,
parameter PO_OCLK_DELAY = 0,
parameter PO_OCLKDELAY_INV = "TRUE",
parameter PO_OUTPUT_CLK_SRC = "DELAYED_REF",
parameter PO_SYNC_IN_DIV_RST = "FALSE",
// OSERDES
parameter OSERDES_DATA_RATE = "DDR",
parameter OSERDES_DATA_WIDTH = 4,
//IDELAY
parameter IDELAYE2_IDELAY_TYPE = "VARIABLE",
parameter IDELAYE2_IDELAY_VALUE = 00,
parameter IODELAY_GRP = "IODELAY_MIG",
parameter FPGA_SPEED_GRADE = 1,
parameter BANK_TYPE = "HP_IO", // # = "HP_IO", "HPL_IO", "HR_IO", "HRL_IO"
parameter real TCK = 0.00,
parameter SYNTHESIS = "FALSE",
// local constants, do not pass in from above
parameter BUS_WIDTH = 12,
parameter MSB_BURST_PEND_PO = 3,
parameter MSB_BURST_PEND_PI = 7,
parameter MSB_RANK_SEL_I = MSB_BURST_PEND_PI + 8,
parameter PHASER_CTL_BUS_WIDTH = MSB_RANK_SEL_I + 1
,parameter CKE_ODT_AUX = "FALSE"
)(
input rst,
input phy_clk,
input freq_refclk,
input mem_refclk,
input idelayctrl_refclk,
input sync_pulse,
output [BUS_WIDTH-1:0] mem_dq_out,
output [BUS_WIDTH-1:0] mem_dq_ts,
input [9:0] mem_dq_in,
output mem_dqs_out,
output mem_dqs_ts,
input mem_dqs_in,
output [11:0] ddr_ck_out,
output rclk,
input if_empty_def,
output if_a_empty,
output if_empty,
output if_a_full,
output if_full,
output of_a_empty,
output of_empty,
output of_a_full,
output of_full,
output pre_fifo_a_full,
output [79:0] phy_din,
input [79:0] phy_dout,
input phy_cmd_wr_en,
input phy_data_wr_en,
input phy_rd_en,
input [PHASER_CTL_BUS_WIDTH-1:0] phaser_ctl_bus,
input idelay_inc,
input idelay_ce,
input idelay_ld,
input if_rst,
input [2:0] byte_rd_en_oth_lanes,
input [1:0] byte_rd_en_oth_banks,
output byte_rd_en,
output po_coarse_overflow,
output po_fine_overflow,
output [8:0] po_counter_read_val,
input po_fine_enable,
input po_coarse_enable,
input [1:0] po_en_calib,
input po_fine_inc,
input po_coarse_inc,
input po_counter_load_en,
input po_counter_read_en,
input po_sel_fine_oclk_delay,
input [8:0] po_counter_load_val,
input [1:0] pi_en_calib,
input pi_rst_dqs_find,
input pi_fine_enable,
input pi_fine_inc,
input pi_counter_load_en,
input pi_counter_read_en,
input [5:0] pi_counter_load_val,
output wire pi_iserdes_rst,
output pi_phase_locked,
output pi_fine_overflow,
output [5:0] pi_counter_read_val,
output wire pi_dqs_found,
output dqs_out_of_range,
input [29:0] fine_delay,
input fine_delay_sel
);
localparam PHASER_INDEX =
(ABCD=="B" ? 1 : (ABCD == "C") ? 2 : (ABCD == "D" ? 3 : 0));
localparam L_OF_ARRAY_MODE =
(OF_ARRAY_MODE != "UNDECLARED") ? OF_ARRAY_MODE :
(PO_DATA_CTL == "FALSE" || PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_8_X_4";
localparam L_IF_ARRAY_MODE = (IF_ARRAY_MODE != "UNDECLARED") ? IF_ARRAY_MODE :
(PC_CLK_RATIO == 2) ? "ARRAY_MODE_4_X_4" : "ARRAY_MODE_4_X_8";
localparam L_OSERDES_DATA_RATE = (OSERDES_DATA_RATE != "UNDECLARED") ? OSERDES_DATA_RATE : ((PO_DATA_CTL == "FALSE" && PC_CLK_RATIO == 4) ? "SDR" : "DDR") ;
localparam L_OSERDES_DATA_WIDTH = (OSERDES_DATA_WIDTH != "UNDECLARED") ? OSERDES_DATA_WIDTH : 4;
localparam real L_FREQ_REF_PERIOD_NS = TCK > 2500.0 ? (TCK/(PI_FREQ_REF_DIV == "DIV2" ? 2 : 1)/1000.0) : TCK/1000.0;
localparam real L_MEM_REF_PERIOD_NS = TCK/1000.0;
localparam real L_PHASE_REF_PERIOD_NS = TCK/1000.0;
localparam ODDR_CLK_EDGE = "SAME_EDGE";
localparam PO_DCD_CORRECTION = "ON";
localparam [2:0] PO_DCD_SETTING = (PO_DCD_CORRECTION == "ON") ? 3'b111 : 3'b000;
localparam DQS_AUTO_RECAL = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? 1 : 0;
localparam DQS_FIND_PATTERN = (BANK_TYPE == "HR_IO" || BANK_TYPE == "HRL_IO" || (BANK_TYPE == "HPL_IO" && TCK > 2500)) ? "001" : "000";
wire [1:0] oserdes_dqs;
wire [1:0] oserdes_dqs_ts;
wire [1:0] oserdes_dq_ts;
wire [3:0] of_q9;
wire [3:0] of_q8;
wire [3:0] of_q7;
wire [7:0] of_q6;
wire [7:0] of_q5;
wire [3:0] of_q4;
wire [3:0] of_q3;
wire [3:0] of_q2;
wire [3:0] of_q1;
wire [3:0] of_q0;
wire [7:0] of_d9;
wire [7:0] of_d8;
wire [7:0] of_d7;
wire [7:0] of_d6;
wire [7:0] of_d5;
wire [7:0] of_d4;
wire [7:0] of_d3;
wire [7:0] of_d2;
wire [7:0] of_d1;
wire [7:0] of_d0;
wire [7:0] if_q9;
wire [7:0] if_q8;
wire [7:0] if_q7;
wire [7:0] if_q6;
wire [7:0] if_q5;
wire [7:0] if_q4;
wire [7:0] if_q3;
wire [7:0] if_q2;
wire [7:0] if_q1;
wire [7:0] if_q0;
wire [3:0] if_d9;
wire [3:0] if_d8;
wire [3:0] if_d7;
wire [3:0] if_d6;
wire [3:0] if_d5;
wire [3:0] if_d4;
wire [3:0] if_d3;
wire [3:0] if_d2;
wire [3:0] if_d1;
wire [3:0] if_d0;
wire [3:0] dummy_i5;
wire [3:0] dummy_i6;
wire [48-1:0] of_dqbus;
wire [10*4-1:0] iserdes_dout;
wire iserdes_clk;
wire iserdes_clkdiv;
wire ififo_wr_enable;
wire phy_rd_en_;
wire dqs_to_phaser;
wire phy_wr_en = ( PO_DATA_CTL == "FALSE" ) ? phy_cmd_wr_en : phy_data_wr_en;
wire if_empty_;
wire if_a_empty_;
wire if_full_;
wire if_a_full_;
wire po_oserdes_rst;
wire empty_post_fifo;
reg [3:0] if_empty_r /* synthesis syn_maxfan = 3 */;
wire [79:0] rd_data;
reg [79:0] rd_data_r;
reg ififo_rst = 1'b1;
reg ofifo_rst = 1'b1;
wire of_wren_pre;
wire [79:0] pre_fifo_dout;
wire pre_fifo_full;
wire pre_fifo_rden;
wire [5:0] ddr_ck_out_q;
wire ififo_rd_en_in /* synthesis syn_maxfan = 10 */;
wire oserdes_clkdiv;
wire oserdes_clk_delayed;
wire po_rd_enable;
always @(posedge phy_clk) begin
ififo_rst <= #1 pi_rst_dqs_find | if_rst ;
// reset only data o-fifos on reset of dqs_found
ofifo_rst <= #1 (pi_rst_dqs_find & PO_DATA_CTL == "TRUE") | rst;
end
// IN_FIFO EMPTY->RDEN TIMING FIX:
// Always read from IN_FIFO - it doesn't hurt to read from an empty FIFO
// since the IN_FIFO read pointers are not incr'ed when the FIFO is empty
assign #(25) phy_rd_en_ = 1'b1;
//assign #(25) phy_rd_en_ = phy_rd_en;
generate
if ( PO_DATA_CTL == "FALSE" ) begin : if_empty_null
assign if_empty = 0;
assign if_a_empty = 0;
assign if_full = 0;
assign if_a_full = 0;
end
else begin : if_empty_gen
assign if_empty = empty_post_fifo;
assign if_a_empty = if_a_empty_;
assign if_full = if_full_;
assign if_a_full = if_a_full_;
end
endgenerate
generate
if ( PO_DATA_CTL == "FALSE" ) begin : dq_gen_48
assign of_dqbus[48-1:0] = {of_q6[7:4], of_q5[7:4], of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign phy_din = 80'h0;
assign byte_rd_en = 1'b1;
end
else begin : dq_gen_40
assign of_dqbus[40-1:0] = {of_q9, of_q8, of_q7, of_q6[3:0], of_q5[3:0], of_q4, of_q3, of_q2, of_q1, of_q0};
assign ififo_rd_en_in = !if_empty_def ? ((&byte_rd_en_oth_banks) && (&byte_rd_en_oth_lanes) && byte_rd_en) :
((|byte_rd_en_oth_banks) || (|byte_rd_en_oth_lanes) || byte_rd_en);
if (USE_PRE_POST_FIFO == "TRUE") begin : if_post_fifo_gen
// IN_FIFO EMPTY->RDEN TIMING FIX:
assign rd_data = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
always @(posedge phy_clk) begin
rd_data_r <= #(025) rd_data;
if_empty_r[0] <= #(025) if_empty_;
if_empty_r[1] <= #(025) if_empty_;
if_empty_r[2] <= #(025) if_empty_;
if_empty_r[3] <= #(025) if_empty_;
end
mig_7series_v2_3_ddr_if_post_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (4), //2 // depth - account for up to 2 cycles of skew
.WIDTH (80) // width
)
u_ddr_if_post_fifo
(
.clk (phy_clk),
.rst (ififo_rst),
.empty_in (if_empty_r),
.rd_en_in (ififo_rd_en_in),
.d_in (rd_data_r),
.empty_out (empty_post_fifo),
.byte_rd_en (byte_rd_en),
.d_out (phy_din)
);
end
else begin : phy_din_gen
assign phy_din = {if_q9, if_q8, if_q7, if_q6, if_q5, if_q4, if_q3, if_q2, if_q1, if_q0};
assign empty_post_fifo = if_empty_;
end
end
endgenerate
assign { if_d9, if_d8, if_d7, if_d6, if_d5, if_d4, if_d3, if_d2, if_d1, if_d0} = iserdes_dout;
wire [1:0] rank_sel_i = ((phaser_ctl_bus[MSB_RANK_SEL_I :MSB_RANK_SEL_I -7] >> (PHASER_INDEX << 1)) & 2'b11);
generate
if ( USE_PRE_POST_FIFO == "TRUE" ) begin : of_pre_fifo_gen
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = pre_fifo_dout;
mig_7series_v2_3_ddr_of_pre_fifo #
(
.TCQ (25), // simulation CK->Q delay
.DEPTH (9), // depth - set to 9 to accommodate flow control
.WIDTH (80) // width
)
u_ddr_of_pre_fifo
(
.clk (phy_clk),
.rst (ofifo_rst),
.full_in (of_full),
.wr_en_in (phy_wr_en),
.d_in (phy_dout),
.wr_en_out (of_wren_pre),
.d_out (pre_fifo_dout),
.afull (pre_fifo_a_full)
);
end
else begin
// wire direct to ofifo
assign {of_d9, of_d8, of_d7, of_d6, of_d5, of_d4, of_d3, of_d2, of_d1, of_d0} = phy_dout;
assign of_wren_pre = phy_wr_en;
end
endgenerate
generate
if ( PO_DATA_CTL == "TRUE" || ((RCLK_SELECT_LANE==ABCD) && (CKE_ODT_AUX =="TRUE"))) begin : phaser_in_gen
PHASER_IN_PHY #(
.BURST_MODE ( PI_BURST_MODE),
.CLKOUT_DIV ( PI_CLKOUT_DIV),
.DQS_AUTO_RECAL ( DQS_AUTO_RECAL),
.DQS_FIND_PATTERN ( DQS_FIND_PATTERN),
.SEL_CLK_OFFSET ( PI_SEL_CLK_OFFSET),
.FINE_DELAY ( PI_FINE_DELAY),
.FREQ_REF_DIV ( PI_FREQ_REF_DIV),
.OUTPUT_CLK_SRC ( PI_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PI_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( L_PHASE_REF_PERIOD_NS)
) phaser_in (
.DQSFOUND (pi_dqs_found),
.DQSOUTOFRANGE (dqs_out_of_range),
.FINEOVERFLOW (pi_fine_overflow),
.PHASELOCKED (pi_phase_locked),
.ISERDESRST (pi_iserdes_rst),
.ICLKDIV (iserdes_clkdiv),
.ICLK (iserdes_clk),
.COUNTERREADVAL (pi_counter_read_val),
.RCLK (rclk),
.WRENABLE (ififo_wr_enable),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PI - 3 + PHASER_INDEX]),
.ENCALIBPHY (pi_en_calib),
.FINEENABLE (pi_fine_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.RANKSELPHY (rank_sel_i),
.PHASEREFCLK (dqs_to_phaser),
.RSTDQSFIND (pi_rst_dqs_find),
.RST (rst),
.FINEINC (pi_fine_inc),
.COUNTERLOADEN (pi_counter_load_en),
.COUNTERREADEN (pi_counter_read_en),
.COUNTERLOADVAL (pi_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
end
else begin
assign pi_dqs_found = 1'b1;
// assign pi_dqs_out_of_range = 1'b0;
assign pi_phase_locked = 1'b1;
end
endgenerate
wire #0 phase_ref = freq_refclk;
wire oserdes_clk;
PHASER_OUT_PHY #(
.CLKOUT_DIV ( PO_CLKOUT_DIV),
.DATA_CTL_N ( PO_DATA_CTL ),
.FINE_DELAY ( PO_FINE_DELAY),
.COARSE_BYPASS ( PO_COARSE_BYPASS ),
.COARSE_DELAY ( PO_COARSE_DELAY),
.OCLK_DELAY ( PO_OCLK_DELAY),
.OCLKDELAY_INV ( PO_OCLKDELAY_INV),
.OUTPUT_CLK_SRC ( PO_OUTPUT_CLK_SRC),
.SYNC_IN_DIV_RST ( PO_SYNC_IN_DIV_RST),
.REFCLK_PERIOD ( L_FREQ_REF_PERIOD_NS),
.PHASEREFCLK_PERIOD ( 1), // dummy, not used
.PO ( PO_DCD_SETTING ),
.MEMREFCLK_PERIOD ( L_MEM_REF_PERIOD_NS)
) phaser_out (
.COARSEOVERFLOW (po_coarse_overflow),
.CTSBUS (oserdes_dqs_ts),
.DQSBUS (oserdes_dqs),
.DTSBUS (oserdes_dq_ts),
.FINEOVERFLOW (po_fine_overflow),
.OCLKDIV (oserdes_clkdiv),
.OCLK (oserdes_clk),
.OCLKDELAYED (oserdes_clk_delayed),
.COUNTERREADVAL (po_counter_read_val),
.BURSTPENDINGPHY (phaser_ctl_bus[MSB_BURST_PEND_PO -3 + PHASER_INDEX]),
.ENCALIBPHY (po_en_calib),
.RDENABLE (po_rd_enable),
.FREQREFCLK (freq_refclk),
.MEMREFCLK (mem_refclk),
.PHASEREFCLK (/*phase_ref*/),
.RST (rst),
.OSERDESRST (po_oserdes_rst),
.COARSEENABLE (po_coarse_enable),
.FINEENABLE (po_fine_enable),
.COARSEINC (po_coarse_inc),
.FINEINC (po_fine_inc),
.SELFINEOCLKDELAY (po_sel_fine_oclk_delay),
.COUNTERLOADEN (po_counter_load_en),
.COUNTERREADEN (po_counter_read_en),
.COUNTERLOADVAL (po_counter_load_val),
.SYNCIN (sync_pulse),
.SYSCLK (phy_clk)
);
generate
if (PO_DATA_CTL == "TRUE") begin : in_fifo_gen
IN_FIFO #(
.ALMOST_EMPTY_VALUE ( IF_ALMOST_EMPTY_VALUE ),
.ALMOST_FULL_VALUE ( IF_ALMOST_FULL_VALUE ),
.ARRAY_MODE ( L_IF_ARRAY_MODE),
.SYNCHRONOUS_MODE ( IF_SYNCHRONOUS_MODE)
) in_fifo (
.ALMOSTEMPTY (if_a_empty_),
.ALMOSTFULL (if_a_full_),
.EMPTY (if_empty_),
.FULL (if_full_),
.Q0 (if_q0),
.Q1 (if_q1),
.Q2 (if_q2),
.Q3 (if_q3),
.Q4 (if_q4),
.Q5 (if_q5),
.Q6 (if_q6),
.Q7 (if_q7),
.Q8 (if_q8),
.Q9 (if_q9),
//===
.D0 (if_d0),
.D1 (if_d1),
.D2 (if_d2),
.D3 (if_d3),
.D4 (if_d4),
.D5 ({dummy_i5,if_d5}),
.D6 ({dummy_i6,if_d6}),
.D7 (if_d7),
.D8 (if_d8),
.D9 (if_d9),
.RDCLK (phy_clk),
.RDEN (phy_rd_en_),
.RESET (ififo_rst),
.WRCLK (iserdes_clkdiv),
.WREN (ififo_wr_enable)
);
end
endgenerate
OUT_FIFO #(
.ALMOST_EMPTY_VALUE (OF_ALMOST_EMPTY_VALUE),
.ALMOST_FULL_VALUE (OF_ALMOST_FULL_VALUE),
.ARRAY_MODE (L_OF_ARRAY_MODE),
.OUTPUT_DISABLE (OF_OUTPUT_DISABLE),
.SYNCHRONOUS_MODE (OF_SYNCHRONOUS_MODE)
) out_fifo (
.ALMOSTEMPTY (of_a_empty),
.ALMOSTFULL (of_a_full),
.EMPTY (of_empty),
.FULL (of_full),
.Q0 (of_q0),
.Q1 (of_q1),
.Q2 (of_q2),
.Q3 (of_q3),
.Q4 (of_q4),
.Q5 (of_q5),
.Q6 (of_q6),
.Q7 (of_q7),
.Q8 (of_q8),
.Q9 (of_q9),
.D0 (of_d0),
.D1 (of_d1),
.D2 (of_d2),
.D3 (of_d3),
.D4 (of_d4),
.D5 (of_d5),
.D6 (of_d6),
.D7 (of_d7),
.D8 (of_d8),
.D9 (of_d9),
.RDCLK (oserdes_clkdiv),
.RDEN (po_rd_enable),
.RESET (ofifo_rst),
.WRCLK (phy_clk),
.WREN (of_wren_pre)
);
mig_7series_v2_3_ddr_byte_group_io #
(
.PO_DATA_CTL (PO_DATA_CTL),
.BITLANES (BITLANES),
.BITLANES_OUTONLY (BITLANES_OUTONLY),
.OSERDES_DATA_RATE (L_OSERDES_DATA_RATE),
.OSERDES_DATA_WIDTH (L_OSERDES_DATA_WIDTH),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.IDELAYE2_IDELAY_TYPE (IDELAYE2_IDELAY_TYPE),
.IDELAYE2_IDELAY_VALUE (IDELAYE2_IDELAY_VALUE),
.TCK (TCK),
.SYNTHESIS (SYNTHESIS)
)
ddr_byte_group_io
(
.mem_dq_out (mem_dq_out),
.mem_dq_ts (mem_dq_ts),
.mem_dq_in (mem_dq_in),
.mem_dqs_in (mem_dqs_in),
.mem_dqs_out (mem_dqs_out),
.mem_dqs_ts (mem_dqs_ts),
.rst (rst),
.oserdes_rst (po_oserdes_rst),
.iserdes_rst (pi_iserdes_rst ),
.iserdes_dout (iserdes_dout),
.dqs_to_phaser (dqs_to_phaser),
.phy_clk (phy_clk),
.iserdes_clk (iserdes_clk),
.iserdes_clkb (!iserdes_clk),
.iserdes_clkdiv (iserdes_clkdiv),
.idelay_inc (idelay_inc),
.idelay_ce (idelay_ce),
.idelay_ld (idelay_ld),
.idelayctrl_refclk (idelayctrl_refclk),
.oserdes_clk (oserdes_clk),
.oserdes_clk_delayed (oserdes_clk_delayed),
.oserdes_clkdiv (oserdes_clkdiv),
.oserdes_dqs ({oserdes_dqs[1], oserdes_dqs[0]}),
.oserdes_dqsts ({oserdes_dqs_ts[1], oserdes_dqs_ts[0]}),
.oserdes_dq (of_dqbus),
.oserdes_dqts ({oserdes_dq_ts[1], oserdes_dq_ts[0]}),
.fine_delay (fine_delay),
.fine_delay_sel (fine_delay_sel)
);
genvar i;
generate
for (i = 0; i <= 5; i = i+1) begin : ddr_ck_gen_loop
if (PO_DATA_CTL== "FALSE" && (BYTELANES_DDR_CK[i*4+PHASER_INDEX])) begin : ddr_ck_gen
ODDR #(.DDR_CLK_EDGE (ODDR_CLK_EDGE))
ddr_ck (
.C (oserdes_clk),
.R (1'b0),
.S (),
.D1 (1'b0),
.D2 (1'b1),
.CE (1'b1),
.Q (ddr_ck_out_q[i])
);
OBUFDS ddr_ck_obuf (.I(ddr_ck_out_q[i]), .O(ddr_ck_out[i*2]), .OB(ddr_ck_out[i*2+1]));
end // ddr_ck_gen
else begin : ddr_ck_null
assign ddr_ck_out[i*2+1:i*2] = 2'b0;
end
end // ddr_ck_gen_loop
endgenerate
endmodule
|
module mig_7series_v2_3_poc_meta #
(parameter SCANFROMRIGHT = 0,
parameter TCQ = 100,
parameter TAPCNTRWIDTH = 7,
parameter TAPSPERKCLK = 112)
(/*AUTOARG*/
// Outputs
mmcm_edge_detect_done, poc_backup, mmcm_lbclk_edge_aligned,
// Inputs
rst, clk, mmcm_edge_detect_rdy, run, run_polarity, run_end,
rise_lead_right, rise_trail_left, rise_lead_center,
rise_trail_center, rise_trail_right, rise_lead_left, ninety_offsets,
use_noise_window, ktap_at_right_edge, ktap_at_left_edge
);
localparam NINETY = TAPSPERKCLK/4;
function [TAPCNTRWIDTH-1:0] offset (input [TAPCNTRWIDTH-1:0] a,
input [1:0] b,
input integer base);
integer offset_ii;
begin
offset_ii = (a + b * NINETY) < base
? (a + b * NINETY)
: (a + b * NINETY - base);
offset = offset_ii[TAPCNTRWIDTH-1:0];
end
endfunction // offset
function [TAPCNTRWIDTH-1:0] mod_sub (input [TAPCNTRWIDTH-1:0] a,
input [TAPCNTRWIDTH-1:0] b,
input integer base);
begin
mod_sub = (a>=b) ? a-b : a+base-b;
end
endfunction // mod_sub
function [TAPCNTRWIDTH:0] center (input [TAPCNTRWIDTH-1:0] left,
input [TAPCNTRWIDTH-1:0] diff,
input integer base);
integer center_ii;
begin
center_ii = ({left, 1'b0} + diff < base * 2)
? {left, 1'b0} + diff + 32'h0
: {left, 1'b0} + diff - base * 2;
center = center_ii[TAPCNTRWIDTH:0];
end
endfunction // center
input rst;
input clk;
input mmcm_edge_detect_rdy;
wire reset_run_ends = rst || ~mmcm_edge_detect_rdy;
// This input used only for the SVA.
input [TAPCNTRWIDTH-1:0] run;
input run_end;
reg run_end_r, run_end_r1, run_end_r2, run_end_r3;
always @(posedge clk) run_end_r <= #TCQ run_end;
always @(posedge clk) run_end_r1 <= #TCQ run_end_r;
always @(posedge clk) run_end_r2 <= #TCQ run_end_r1;
always @(posedge clk) run_end_r3 <= #TCQ run_end_r2;
input run_polarity;
reg run_polarity_held_ns, run_polarity_held_r;
always @(posedge clk) run_polarity_held_r <= #TCQ run_polarity_held_ns;
always @(*) run_polarity_held_ns = run_end ? run_polarity : run_polarity_held_r;
reg [1:0] run_ends_r;
reg [1:0] run_ends_ns;
always @(posedge clk) run_ends_r <= #TCQ run_ends_ns;
always @(*) begin
run_ends_ns = run_ends_r;
if (reset_run_ends) run_ends_ns = 2'b0;
else case (run_ends_r)
2'b00 : run_ends_ns = run_ends_r + {1'b0, run_end_r3 && run_polarity_held_r};
2'b01, 2'b10 : run_ends_ns = run_ends_r + {1'b0, run_end_r3};
endcase // case (run_ends_r)
end
reg done_r;
wire done_ns = mmcm_edge_detect_rdy && &run_ends_r;
always @(posedge clk) done_r <= #TCQ done_ns;
output mmcm_edge_detect_done;
assign mmcm_edge_detect_done = done_r;
input [TAPCNTRWIDTH-1:0] rise_lead_right;
input [TAPCNTRWIDTH-1:0] rise_trail_left;
input [TAPCNTRWIDTH-1:0] rise_lead_center;
input [TAPCNTRWIDTH-1:0] rise_trail_center;
input [TAPCNTRWIDTH-1:0] rise_trail_right;
input [TAPCNTRWIDTH-1:0] rise_lead_left;
input [1:0] ninety_offsets;
wire [1:0] offsets = SCANFROMRIGHT == 1 ? ninety_offsets : 2'b00 - ninety_offsets;
wire [TAPCNTRWIDTH-1:0] rise_lead_center_offset_ns = offset(rise_lead_center, offsets, TAPSPERKCLK);
wire [TAPCNTRWIDTH-1:0] rise_trail_center_offset_ns = offset(rise_trail_center, offsets, TAPSPERKCLK);
reg [TAPCNTRWIDTH-1:0] rise_lead_center_offset_r, rise_trail_center_offset_r;
always @(posedge clk) rise_lead_center_offset_r <= #TCQ rise_lead_center_offset_ns;
always @(posedge clk) rise_trail_center_offset_r <= #TCQ rise_trail_center_offset_ns;
wire [TAPCNTRWIDTH-1:0] edge_diff_ns = mod_sub(rise_trail_center_offset_r, rise_lead_center_offset_r, TAPSPERKCLK);
reg [TAPCNTRWIDTH-1:0] edge_diff_r;
always @(posedge clk) edge_diff_r <= #TCQ edge_diff_ns;
wire [TAPCNTRWIDTH:0] edge_center_ns = center(rise_lead_center_offset_r, edge_diff_r, TAPSPERKCLK);
reg [TAPCNTRWIDTH:0] edge_center_r;
always @(posedge clk) edge_center_r <= #TCQ edge_center_ns;
input use_noise_window;
wire [TAPCNTRWIDTH-1:0] left = use_noise_window ? rise_lead_left : rise_trail_left;
wire [TAPCNTRWIDTH-1:0] right = use_noise_window ? rise_trail_right : rise_lead_right;
wire [TAPCNTRWIDTH-1:0] center_diff_ns = mod_sub(right, left, TAPSPERKCLK);
reg [TAPCNTRWIDTH-1:0] center_diff_r;
always @(posedge clk) center_diff_r <= #TCQ center_diff_ns;
wire [TAPCNTRWIDTH:0] window_center_ns = center(left, center_diff_r, TAPSPERKCLK);
reg [TAPCNTRWIDTH:0] window_center_r;
always @(posedge clk) window_center_r <= #TCQ window_center_ns;
localparam TAPSPERKCLKX2 = TAPSPERKCLK * 2;
wire [TAPCNTRWIDTH+1:0] left_center = {1'b0, SCANFROMRIGHT == 1 ? window_center_r : edge_center_r};
wire [TAPCNTRWIDTH+1:0] right_center = {1'b0, SCANFROMRIGHT == 1 ? edge_center_r : window_center_r};
wire [TAPCNTRWIDTH+1:0] diff_ns = right_center >= left_center
? right_center - left_center
: right_center + TAPSPERKCLKX2[TAPCNTRWIDTH+1:0] - left_center;
reg [TAPCNTRWIDTH+1:0] diff_r;
always @(posedge clk) diff_r <= #TCQ diff_ns;
wire [TAPCNTRWIDTH+1:0] abs_diff = diff_r > TAPSPERKCLKX2[TAPCNTRWIDTH+1:0]/2
? TAPSPERKCLKX2[TAPCNTRWIDTH+1:0] - diff_r
: diff_r;
reg [TAPCNTRWIDTH+1:0] prev_ns, prev_r;
always @(posedge clk) prev_r <= #TCQ prev_ns;
always @(*) prev_ns = done_ns ? diff_r : prev_r;
input ktap_at_right_edge;
input ktap_at_left_edge;
wire centering = !(ktap_at_right_edge || ktap_at_left_edge);
wire diffs_eq = abs_diff == diff_r;
reg diffs_eq_ns, diffs_eq_r;
always @(*) diffs_eq_ns = centering && ((done_r && done_ns) ? diffs_eq : diffs_eq_r);
always @(posedge clk) diffs_eq_r <= #TCQ diffs_eq_ns;
reg edge_aligned_r;
reg prev_valid_ns, prev_valid_r;
always @(posedge clk) prev_valid_r <= #TCQ prev_valid_ns;
always @(*) prev_valid_ns = (~rst && ~ktap_at_right_edge && ~ktap_at_left_edge && ~edge_aligned_r) && prev_valid_r | done_ns;
wire indicate_alignment = ~rst && centering && done_ns;
wire edge_aligned_ns = indicate_alignment && (~|diff_r || ~diffs_eq & diffs_eq_r);
always @(posedge clk) edge_aligned_r <= #TCQ edge_aligned_ns;
reg poc_backup_r;
wire poc_backup_ns = edge_aligned_ns && abs_diff > prev_r;
always @(posedge clk) poc_backup_r <= #TCQ poc_backup_ns;
output poc_backup;
assign poc_backup = poc_backup_r;
output mmcm_lbclk_edge_aligned;
assign mmcm_lbclk_edge_aligned = edge_aligned_r;
endmodule
|
module mig_7series_v2_3_bank_state #
(
parameter TCQ = 100,
parameter ADDR_CMD_MODE = "1T",
parameter BM_CNT_WIDTH = 2,
parameter BURST_MODE = "8",
parameter CWL = 5,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter DRAM_TYPE = "DDR3",
parameter ECC = "OFF",
parameter ID = 0,
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2,
parameter nOP_WAIT = 0,
parameter nRAS_CLKS = 10,
parameter nRP = 10,
parameter nRTP = 4,
parameter nRCD = 5,
parameter nWTP_CLKS = 5,
parameter ORDERING = "NORM",
parameter RANKS = 4,
parameter RANK_WIDTH = 4,
parameter RAS_TIMER_WIDTH = 5,
parameter STARVE_LIMIT = 2
)
(/*AUTOARG*/
// Outputs
start_rcd, act_wait_r, rd_half_rmw, ras_timer_ns, end_rtp,
bank_wait_in_progress, start_pre_wait, op_exit_req, pre_wait_r,
allow_auto_pre, precharge_bm_end, demand_act_priority, rts_row,
act_this_rank_r, demand_priority, col_rdy_wr, rts_col, wr_this_rank_r,
rd_this_rank_r, rts_pre, rtc,
// Inputs
clk, rst, bm_end, pass_open_bank_r, sending_row, sending_pre, rcv_open_bank,
sending_col, rd_wr_r, req_wr_r, rd_data_addr, req_data_buf_addr_r,
phy_rddata_valid, rd_rmw, ras_timer_ns_in, rb_hit_busies_r, idle_r,
passing_open_bank, low_idle_cnt_r, op_exit_grant, tail_r,
auto_pre_r, pass_open_bank_ns, req_rank_r, req_rank_r_in,
start_rcd_in, inhbt_act_faw_r, wait_for_maint_r, head_r, sent_row,
demand_act_priority_in, order_q_zero, sent_col, q_has_rd,
q_has_priority, req_priority_r, idle_ns, demand_priority_in, inhbt_rd,
inhbt_wr, dq_busy_data, rnk_config_strobe, rnk_config_valid_r, rnk_config,
rnk_config_kill_rts_col, phy_mc_cmd_full, phy_mc_ctl_full, phy_mc_data_full
);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
input clk;
input rst;
// Activate wait state machine.
input bm_end;
reg bm_end_r1;
always @(posedge clk) bm_end_r1 <= #TCQ bm_end;
reg col_wait_r;
input pass_open_bank_r;
input sending_row;
reg act_wait_r_lcl;
input rcv_open_bank;
wire start_rcd_lcl = act_wait_r_lcl && sending_row;
output wire start_rcd;
assign start_rcd = start_rcd_lcl;
wire act_wait_ns = rst ||
((act_wait_r_lcl && ~start_rcd_lcl && ~rcv_open_bank) ||
bm_end_r1 || (pass_open_bank_r && bm_end));
always @(posedge clk) act_wait_r_lcl <= #TCQ act_wait_ns;
output wire act_wait_r;
assign act_wait_r = act_wait_r_lcl;
// RCD timer
//
// When CWL is even, CAS commands are issued on slot 0 and RAS commands are
// issued on slot 1. This implies that the RCD can never expire in the same
// cycle as the RAS (otherwise the CAS for a given transaction would precede
// the RAS). Similarly, this can also cause premature expiration for longer
// RCD. An offset must be added to RCD before translating it to the FPGA clock
// domain. In this mode, CAS are on the first DRAM clock cycle corresponding to
// a given FPGA cycle. In 2:1 mode add 2 to generate this offset aligned to
// the FPGA cycle. Likewise, add 4 to generate an aligned offset in 4:1 mode.
//
// When CWL is odd, RAS commands are issued on slot 0 and CAS commands are
// issued on slot 1. There is a natural 1 cycle seperation between RAS and CAS
// in the DRAM clock domain so the RCD can expire in the same FPGA cycle as the
// RAS command. In 2:1 mode, there are only 2 slots so direct translation
// correctly places the CAS with respect to the corresponding RAS. In 4:1 mode,
// there are two slots after CAS, so 2 is added to shift the timer into the
// next FPGA cycle for cases that can't expire in the current cycle.
//
// In 2T mode, the offset from ROW to COL commands is fixed at 2. In 2:1 mode,
// It is sufficient to translate to the half-rate domain and add the remainder.
// In 4:1 mode, we must translate to the quarter-rate domain and add an
// additional fabric cycle only if the remainder exceeds the fixed offset of 2
localparam nRCD_CLKS =
nCK_PER_CLK == 1 ?
nRCD :
nCK_PER_CLK == 2 ?
ADDR_CMD_MODE == "2T" ?
(nRCD/2) + (nRCD%2) :
CWL % 2 ?
(nRCD/2) :
(nRCD+2) / 2 :
// (nCK_PER_CLK == 4)
ADDR_CMD_MODE == "2T" ?
(nRCD/4) + (nRCD%4 > 2 ? 1 : 0) :
CWL % 2 ?
(nRCD-2 ? (nRCD-2) / 4 + 1 : 1) :
nRCD/4 + 1;
localparam nRCD_CLKS_M2 = (nRCD_CLKS-2 <0) ? 0 : nRCD_CLKS-2;
localparam RCD_TIMER_WIDTH = clogb2(nRCD_CLKS_M2+1);
localparam ZERO = 0;
localparam ONE = 1;
reg [RCD_TIMER_WIDTH-1:0] rcd_timer_r = {RCD_TIMER_WIDTH{1'b0}};
reg end_rcd;
reg rcd_active_r = 1'b0;
generate
if (nRCD_CLKS <= 2) begin : rcd_timer_leq_2
always @(/*AS*/start_rcd_lcl) end_rcd = start_rcd_lcl;
end
else if (nRCD_CLKS > 2) begin : rcd_timer_gt_2
reg [RCD_TIMER_WIDTH-1:0] rcd_timer_ns;
always @(/*AS*/rcd_timer_r or rst or start_rcd_lcl) begin
if (rst) rcd_timer_ns = ZERO[RCD_TIMER_WIDTH-1:0];
else begin
rcd_timer_ns = rcd_timer_r;
if (start_rcd_lcl) rcd_timer_ns = nRCD_CLKS_M2[RCD_TIMER_WIDTH-1:0];
else if (|rcd_timer_r) rcd_timer_ns =
rcd_timer_r - ONE[RCD_TIMER_WIDTH-1:0];
end
end
always @(posedge clk) rcd_timer_r <= #TCQ rcd_timer_ns;
wire end_rcd_ns = (rcd_timer_ns == ONE[RCD_TIMER_WIDTH-1:0]);
always @(posedge clk) end_rcd = end_rcd_ns;
wire rcd_active_ns = |rcd_timer_ns;
always @(posedge clk) rcd_active_r <= #TCQ rcd_active_ns;
end
endgenerate
// Figure out if the read that's completing is for an RMW for
// this bank machine. Delay by a state if CWL != 8 since the
// data is not ready in the RMW buffer for the early write
// data fetch that happens with ECC and CWL != 8.
// Create a state bit indicating we're waiting for the read
// half of the rmw to complete.
input sending_col;
input rd_wr_r;
input req_wr_r;
input [DATA_BUF_ADDR_WIDTH-1:0] rd_data_addr;
input [DATA_BUF_ADDR_WIDTH-1:0] req_data_buf_addr_r;
input phy_rddata_valid;
input rd_rmw;
reg rmw_rd_done = 1'b0;
reg rd_half_rmw_lcl = 1'b0;
output wire rd_half_rmw;
assign rd_half_rmw = rd_half_rmw_lcl;
reg rmw_wait_r = 1'b0;
generate
if (ECC != "OFF") begin : rmw_on
// Delay phy_rddata_valid and rd_rmw by one cycle to align them
// to req_data_buf_addr_r so that rmw_wait_r clears properly
reg phy_rddata_valid_r;
reg rd_rmw_r;
always @(posedge clk) begin
phy_rddata_valid_r <= #TCQ phy_rddata_valid;
rd_rmw_r <= #TCQ rd_rmw;
end
wire my_rmw_rd_ns = phy_rddata_valid_r && rd_rmw_r &&
(rd_data_addr == req_data_buf_addr_r);
if (CWL == 8) always @(my_rmw_rd_ns) rmw_rd_done = my_rmw_rd_ns;
else always @(posedge clk) rmw_rd_done = #TCQ my_rmw_rd_ns;
always @(/*AS*/rd_wr_r or req_wr_r) rd_half_rmw_lcl = req_wr_r && rd_wr_r;
wire rmw_wait_ns = ~rst &&
((rmw_wait_r && ~rmw_rd_done) || (rd_half_rmw_lcl && sending_col));
always @(posedge clk) rmw_wait_r <= #TCQ rmw_wait_ns;
end
endgenerate
// column wait state machine.
wire col_wait_ns = ~rst && ((col_wait_r && ~sending_col) || end_rcd
|| rcv_open_bank || (rmw_rd_done && rmw_wait_r));
always @(posedge clk) col_wait_r <= #TCQ col_wait_ns;
// Set up various RAS timer parameters, wires, etc.
localparam TWO = 2;
output reg [RAS_TIMER_WIDTH-1:0] ras_timer_ns;
reg [RAS_TIMER_WIDTH-1:0] ras_timer_r;
input [(2*(RAS_TIMER_WIDTH*nBANK_MACHS))-1:0] ras_timer_ns_in;
input [(nBANK_MACHS*2)-1:0] rb_hit_busies_r;
// On a bank pass, select the RAS timer from the passing bank machine.
reg [RAS_TIMER_WIDTH-1:0] passed_ras_timer;
integer i;
always @(/*AS*/ras_timer_ns_in or rb_hit_busies_r) begin
passed_ras_timer = {RAS_TIMER_WIDTH{1'b0}};
for (i=ID+1; i<(ID+nBANK_MACHS); i=i+1)
if (rb_hit_busies_r[i])
passed_ras_timer = ras_timer_ns_in[i*RAS_TIMER_WIDTH+:RAS_TIMER_WIDTH];
end
// RAS and (reused for) WTP timer. When an open bank is passed, this
// timer is passed to the new owner. The existing RAS prevents
// an activate from occuring too early.
wire start_wtp_timer = sending_col && ~rd_wr_r;
input idle_r;
always @(/*AS*/bm_end_r1 or ras_timer_r or rst or start_rcd_lcl
or start_wtp_timer) begin
if (bm_end_r1 || rst) ras_timer_ns = ZERO[RAS_TIMER_WIDTH-1:0];
else begin
ras_timer_ns = ras_timer_r;
if (start_rcd_lcl) ras_timer_ns =
nRAS_CLKS[RAS_TIMER_WIDTH-1:0] - TWO[RAS_TIMER_WIDTH-1:0];
if (start_wtp_timer) ras_timer_ns =
// As the timer is being reused, it is essential to compare
// before new value is loaded.
(ras_timer_r <= (nWTP_CLKS-2)) ? nWTP_CLKS[RAS_TIMER_WIDTH-1:0] - TWO[RAS_TIMER_WIDTH-1:0]
: ras_timer_r - ONE[RAS_TIMER_WIDTH-1:0];
if (|ras_timer_r && ~start_wtp_timer) ras_timer_ns =
ras_timer_r - ONE[RAS_TIMER_WIDTH-1:0];
end
end // always @ (...
wire [RAS_TIMER_WIDTH-1:0] ras_timer_passed_ns = rcv_open_bank
? passed_ras_timer
: ras_timer_ns;
always @(posedge clk) ras_timer_r <= #TCQ ras_timer_passed_ns;
wire ras_timer_zero_ns = (ras_timer_ns == ZERO[RAS_TIMER_WIDTH-1:0]);
reg ras_timer_zero_r;
always @(posedge clk) ras_timer_zero_r <= #TCQ ras_timer_zero_ns;
// RTP timer. Unless 2T mode, add one for 2:1 mode. This accounts for loss of
// one DRAM CK due to column command to row command fixed offset. In 2T mode,
// Add the remainder. In 4:1 mode, the fixed offset is -2. Add 2 unless in 2T
// mode, in which case we add 1 if the remainder exceeds the fixed offset.
localparam nRTP_CLKS = (nCK_PER_CLK == 1)
? nRTP :
(nCK_PER_CLK == 2)
? (nRTP/2) + ((ADDR_CMD_MODE == "2T") ? nRTP%2 : 1) :
(nRTP/4) + ((ADDR_CMD_MODE == "2T") ? (nRTP%4 > 2 ? 2 : 1) : 2);
localparam nRTP_CLKS_M1 = ((nRTP_CLKS-1) <= 0) ? 0 : nRTP_CLKS-1;
localparam RTP_TIMER_WIDTH = clogb2(nRTP_CLKS_M1 + 1);
reg [RTP_TIMER_WIDTH-1:0] rtp_timer_ns;
reg [RTP_TIMER_WIDTH-1:0] rtp_timer_r;
wire sending_col_not_rmw_rd = sending_col && ~rd_half_rmw_lcl;
always @(/*AS*/pass_open_bank_r or rst or rtp_timer_r
or sending_col_not_rmw_rd) begin
rtp_timer_ns = rtp_timer_r;
if (rst || pass_open_bank_r)
rtp_timer_ns = ZERO[RTP_TIMER_WIDTH-1:0];
else begin
if (sending_col_not_rmw_rd)
rtp_timer_ns = nRTP_CLKS_M1[RTP_TIMER_WIDTH-1:0];
if (|rtp_timer_r) rtp_timer_ns = rtp_timer_r - ONE[RTP_TIMER_WIDTH-1:0];
end
end
always @(posedge clk) rtp_timer_r <= #TCQ rtp_timer_ns;
wire end_rtp_lcl = ~pass_open_bank_r &&
((rtp_timer_r == ONE[RTP_TIMER_WIDTH-1:0]) ||
((nRTP_CLKS_M1 == 0) && sending_col_not_rmw_rd));
output wire end_rtp;
assign end_rtp = end_rtp_lcl;
// Optionally implement open page mode timer.
localparam OP_WIDTH = clogb2(nOP_WAIT + 1);
output wire bank_wait_in_progress;
output wire start_pre_wait;
input passing_open_bank;
input low_idle_cnt_r;
output wire op_exit_req;
input op_exit_grant;
input tail_r;
output reg pre_wait_r;
generate
if (nOP_WAIT == 0) begin : op_mode_disabled
assign bank_wait_in_progress = sending_col_not_rmw_rd || |rtp_timer_r ||
(pre_wait_r && ~ras_timer_zero_r);
assign start_pre_wait = end_rtp_lcl;
assign op_exit_req = 1'b0;
end
else begin : op_mode_enabled
reg op_wait_r;
assign bank_wait_in_progress = sending_col || |rtp_timer_r ||
(pre_wait_r && ~ras_timer_zero_r) ||
op_wait_r;
wire op_active = ~rst && ~passing_open_bank && ((end_rtp_lcl && tail_r)
|| op_wait_r);
wire op_wait_ns = ~op_exit_grant && op_active;
always @(posedge clk) op_wait_r <= #TCQ op_wait_ns;
assign start_pre_wait = op_exit_grant ||
(end_rtp_lcl && ~tail_r && ~passing_open_bank);
if (nOP_WAIT == -1)
assign op_exit_req = (low_idle_cnt_r && op_active);
else begin : op_cnt
reg [OP_WIDTH-1:0] op_cnt_r;
wire [OP_WIDTH-1:0] op_cnt_ns =
(passing_open_bank || op_exit_grant || rst)
? ZERO[OP_WIDTH-1:0]
: end_rtp_lcl
? nOP_WAIT[OP_WIDTH-1:0]
: |op_cnt_r
? op_cnt_r - ONE[OP_WIDTH-1:0]
: op_cnt_r;
always @(posedge clk) op_cnt_r <= #TCQ op_cnt_ns;
assign op_exit_req = (low_idle_cnt_r && op_active) ||
(op_wait_r && ~|op_cnt_r);
end
end
endgenerate
output allow_auto_pre;
wire allow_auto_pre = act_wait_r_lcl || rcd_active_r ||
(col_wait_r && ~sending_col);
// precharge wait state machine.
input auto_pre_r;
wire start_pre;
input pass_open_bank_ns;
wire pre_wait_ns = ~rst && (~pass_open_bank_ns &&
(start_pre_wait || (pre_wait_r && ~start_pre)));
always @(posedge clk) pre_wait_r <= #TCQ pre_wait_ns;
wire pre_request = pre_wait_r && ras_timer_zero_r && ~auto_pre_r;
// precharge timer.
localparam nRP_CLKS = (nCK_PER_CLK == 1) ? nRP :
(nCK_PER_CLK == 2) ? ((nRP/2) + (nRP%2)) :
/*(nCK_PER_CLK == 4)*/ ((nRP/4) + ((nRP%4) ? 1 : 0));
// Subtract two because there are a minimum of two fabric states from
// end of RP timer until earliest possible arb to send act.
localparam nRP_CLKS_M2 = (nRP_CLKS-2 < 0) ? 0 : nRP_CLKS-2;
localparam RP_TIMER_WIDTH = clogb2(nRP_CLKS_M2 + 1);
input sending_pre;
output rts_pre;
generate
if((nCK_PER_CLK == 4) && (ADDR_CMD_MODE != "2T")) begin
assign start_pre = pre_wait_r && ras_timer_zero_r &&
(sending_pre || auto_pre_r);
assign rts_pre = ~sending_pre && pre_request;
end
else begin
assign start_pre = pre_wait_r && ras_timer_zero_r &&
(sending_row || auto_pre_r);
assign rts_pre = 1'b0;
end
endgenerate
reg [RP_TIMER_WIDTH-1:0] rp_timer_r = ZERO[RP_TIMER_WIDTH-1:0];
generate
if (nRP_CLKS_M2 > ZERO) begin : rp_timer
reg [RP_TIMER_WIDTH-1:0] rp_timer_ns;
always @(/*AS*/rp_timer_r or rst or start_pre)
if (rst) rp_timer_ns = ZERO[RP_TIMER_WIDTH-1:0];
else begin
rp_timer_ns = rp_timer_r;
if (start_pre) rp_timer_ns = nRP_CLKS_M2[RP_TIMER_WIDTH-1:0];
else if (|rp_timer_r) rp_timer_ns =
rp_timer_r - ONE[RP_TIMER_WIDTH-1:0];
end
always @(posedge clk) rp_timer_r <= #TCQ rp_timer_ns;
end // block: rp_timer
endgenerate
output wire precharge_bm_end;
assign precharge_bm_end = (rp_timer_r == ONE[RP_TIMER_WIDTH-1:0]) ||
(start_pre && (nRP_CLKS_M2 == ZERO));
// Compute RRD related activate inhibit.
// Compare this bank machine's rank with others, then
// select result based on grant. An alternative is to
// select the just issued rank with the grant and simply
// compare against this bank machine's rank. However, this
// serializes the selection of the rank and the compare processes.
// As implemented below, the compare occurs first, then the
// selection based on grant. This is faster.
input [RANK_WIDTH-1:0] req_rank_r;
input [(RANK_WIDTH*nBANK_MACHS*2)-1:0] req_rank_r_in;
reg inhbt_act_rrd;
input [(nBANK_MACHS*2)-1:0] start_rcd_in;
generate
integer j;
if (RANKS == 1)
always @(/*AS*/req_rank_r or req_rank_r_in or start_rcd_in) begin
inhbt_act_rrd = 1'b0;
for (j=(ID+1); j<(ID+nBANK_MACHS); j=j+1)
inhbt_act_rrd = inhbt_act_rrd || start_rcd_in[j];
end
else begin
always @(/*AS*/req_rank_r or req_rank_r_in or start_rcd_in) begin
inhbt_act_rrd = 1'b0;
for (j=(ID+1); j<(ID+nBANK_MACHS); j=j+1)
inhbt_act_rrd = inhbt_act_rrd ||
(start_rcd_in[j] &&
(req_rank_r_in[(j*RANK_WIDTH)+:RANK_WIDTH] == req_rank_r));
end
end
endgenerate
// Extract the activate command inhibit for the rank associated
// with this request. FAW and RRD are computed separately so that
// gate level timing can be carefully managed.
input [RANKS-1:0] inhbt_act_faw_r;
wire my_inhbt_act_faw = inhbt_act_faw_r[req_rank_r];
input wait_for_maint_r;
input head_r;
wire act_req = ~idle_r && head_r && act_wait_r && ras_timer_zero_r &&
~wait_for_maint_r;
// Implement simple starvation avoidance for act requests. Precharge
// requests don't need this because they are never gated off by
// timing events such as inhbt_act_rrd. Priority request timeout
// is fixed at a single trip around the round robin arbiter.
input sent_row;
wire rts_act_denied = act_req && sent_row && ~sending_row;
reg [BM_CNT_WIDTH-1:0] act_starve_limit_cntr_ns;
reg [BM_CNT_WIDTH-1:0] act_starve_limit_cntr_r;
generate
if (BM_CNT_WIDTH > 1) // Number of Bank Machs > 2
begin :BM_MORE_THAN_2
always @(/*AS*/act_req or act_starve_limit_cntr_r or rts_act_denied)
begin
act_starve_limit_cntr_ns = act_starve_limit_cntr_r;
if (~act_req)
act_starve_limit_cntr_ns = {BM_CNT_WIDTH{1'b0}};
else
if (rts_act_denied && &act_starve_limit_cntr_r)
act_starve_limit_cntr_ns = act_starve_limit_cntr_r +
{{BM_CNT_WIDTH-1{1'b0}}, 1'b1};
end
end
else // Number of Bank Machs == 2
begin :BM_EQUAL_2
always @(/*AS*/act_req or act_starve_limit_cntr_r or rts_act_denied)
begin
act_starve_limit_cntr_ns = act_starve_limit_cntr_r;
if (~act_req)
act_starve_limit_cntr_ns = {BM_CNT_WIDTH{1'b0}};
else
if (rts_act_denied && &act_starve_limit_cntr_r)
act_starve_limit_cntr_ns = act_starve_limit_cntr_r +
{1'b1};
end
end
endgenerate
always @(posedge clk) act_starve_limit_cntr_r <=
#TCQ act_starve_limit_cntr_ns;
reg demand_act_priority_r;
wire demand_act_priority_ns = act_req &&
(demand_act_priority_r || (rts_act_denied && &act_starve_limit_cntr_r));
always @(posedge clk) demand_act_priority_r <= #TCQ demand_act_priority_ns;
`ifdef MC_SVA
cover_demand_act_priority:
cover property (@(posedge clk) (~rst && demand_act_priority_r));
`endif
output wire demand_act_priority;
assign demand_act_priority = demand_act_priority_r && ~sending_row;
// compute act_demanded from other demand_act_priorities
input [(nBANK_MACHS*2)-1:0] demand_act_priority_in;
reg act_demanded = 1'b0;
generate
if (nBANK_MACHS > 1) begin : compute_act_demanded
always @(demand_act_priority_in[`BM_SHARED_BV])
act_demanded = |demand_act_priority_in[`BM_SHARED_BV];
end
endgenerate
wire row_demand_ok = demand_act_priority_r || ~act_demanded;
// Generate the Request To Send row arbitation signal.
output wire rts_row;
generate
if((nCK_PER_CLK == 4) && (ADDR_CMD_MODE != "2T"))
assign rts_row = ~sending_row && row_demand_ok &&
(act_req && ~my_inhbt_act_faw && ~inhbt_act_rrd);
else
assign rts_row = ~sending_row && row_demand_ok &&
((act_req && ~my_inhbt_act_faw && ~inhbt_act_rrd) ||
pre_request);
endgenerate
`ifdef MC_SVA
four_activate_window_wait:
cover property (@(posedge clk)
(~rst && ~sending_row && act_req && my_inhbt_act_faw));
ras_ras_delay_wait:
cover property (@(posedge clk)
(~rst && ~sending_row && act_req && inhbt_act_rrd));
`endif
// Provide rank machines early knowledge that this bank machine is
// going to send an activate to the rank. In this way, the rank
// machines just need to use the sending_row wire to figure out if
// they need to keep track of the activate.
output reg [RANKS-1:0] act_this_rank_r;
reg [RANKS-1:0] act_this_rank_ns;
always @(/*AS*/act_wait_r or req_rank_r) begin
act_this_rank_ns = {RANKS{1'b0}};
for (i = 0; i < RANKS; i = i + 1)
act_this_rank_ns[i] = act_wait_r && (i[RANK_WIDTH-1:0] == req_rank_r);
end
always @(posedge clk) act_this_rank_r <= #TCQ act_this_rank_ns;
// Generate request to send column command signal.
input order_q_zero;
wire req_bank_rdy_ns = order_q_zero && col_wait_r;
reg req_bank_rdy_r;
always @(posedge clk) req_bank_rdy_r <= #TCQ req_bank_rdy_ns;
// Determine is we have been denied a column command request.
input sent_col;
wire rts_col_denied = req_bank_rdy_r && sent_col && ~sending_col;
// Implement a starvation limit counter. Count the number of times a
// request to send a column command has been denied.
localparam STARVE_LIMIT_CNT = STARVE_LIMIT * nBANK_MACHS;
localparam STARVE_LIMIT_WIDTH = clogb2(STARVE_LIMIT_CNT);
reg [STARVE_LIMIT_WIDTH-1:0] starve_limit_cntr_r;
reg [STARVE_LIMIT_WIDTH-1:0] starve_limit_cntr_ns;
always @(/*AS*/col_wait_r or rts_col_denied or starve_limit_cntr_r)
if (~col_wait_r)
starve_limit_cntr_ns = {STARVE_LIMIT_WIDTH{1'b0}};
else
if (rts_col_denied && (starve_limit_cntr_r != STARVE_LIMIT_CNT-1))
starve_limit_cntr_ns = starve_limit_cntr_r +
{{STARVE_LIMIT_WIDTH-1{1'b0}}, 1'b1};
else starve_limit_cntr_ns = starve_limit_cntr_r;
always @(posedge clk) starve_limit_cntr_r <= #TCQ starve_limit_cntr_ns;
input q_has_rd;
input q_has_priority;
// Decide if this bank machine should demand priority. Priority is demanded
// when starvation limit counter is reached, or a bit in the request.
wire starved = ((starve_limit_cntr_r == (STARVE_LIMIT_CNT-1)) &&
rts_col_denied);
input req_priority_r;
input idle_ns;
reg demand_priority_r;
wire demand_priority_ns = ~idle_ns && col_wait_ns &&
(demand_priority_r ||
(order_q_zero &&
(req_priority_r || q_has_priority)) ||
(starved && (q_has_rd || ~req_wr_r)));
always @(posedge clk) demand_priority_r <= #TCQ demand_priority_ns;
`ifdef MC_SVA
wire rdy_for_priority = ~rst && ~demand_priority_r && ~idle_ns &&
col_wait_ns;
req_triggers_demand_priority:
cover property (@(posedge clk)
(rdy_for_priority && req_priority_r && ~q_has_priority && ~starved));
q_priority_triggers_demand_priority:
cover property (@(posedge clk)
(rdy_for_priority && ~req_priority_r && q_has_priority && ~starved));
wire not_req_or_q_rdy_for_priority =
rdy_for_priority && ~req_priority_r && ~q_has_priority;
starved_req_triggers_demand_priority:
cover property (@(posedge clk)
(not_req_or_q_rdy_for_priority && starved && ~q_has_rd && ~req_wr_r));
starved_q_triggers_demand_priority:
cover property (@(posedge clk)
(not_req_or_q_rdy_for_priority && starved && q_has_rd && req_wr_r));
`endif
// compute demanded from other demand_priorities
input [(nBANK_MACHS*2)-1:0] demand_priority_in;
reg demanded = 1'b0;
generate
if (nBANK_MACHS > 1) begin : compute_demanded
always @(demand_priority_in[`BM_SHARED_BV]) demanded =
|demand_priority_in[`BM_SHARED_BV];
end
endgenerate
// In order to make sure that there is no starvation amongst a possibly
// unlimited stream of priority requests, add a second stage to the demand
// priority signal. If there are no other requests demanding priority, then
// go ahead and assert demand_priority. If any other requests are asserting
// demand_priority, hold off asserting demand_priority until these clear, then
// assert demand priority. Its possible to get multiple requests asserting
// demand priority simultaneously, but that's OK. Those requests will be
// serviced, demanded will fall, and another group of requests will be
// allowed to assert demand_priority.
reg demanded_prior_r;
wire demanded_prior_ns = demanded &&
(demanded_prior_r || ~demand_priority_r);
always @(posedge clk) demanded_prior_r <= #TCQ demanded_prior_ns;
output wire demand_priority;
assign demand_priority = demand_priority_r && ~demanded_prior_r &&
~sending_col;
`ifdef MC_SVA
demand_priority_gated:
cover property (@(posedge clk) (demand_priority_r && ~demand_priority));
generate
if (nBANK_MACHS >1) multiple_demand_priority:
cover property (@(posedge clk)
($countones(demand_priority_in[`BM_SHARED_BV]) > 1));
endgenerate
`endif
wire demand_ok = demand_priority_r || ~demanded;
// Figure out if the request in this bank machine matches the current rank
// configuration.
input rnk_config_strobe;
input rnk_config_kill_rts_col;
input rnk_config_valid_r;
input [RANK_WIDTH-1:0] rnk_config;
output wire rtc;
wire rnk_config_match = rnk_config_valid_r && (rnk_config == req_rank_r);
assign rtc = ~rnk_config_match && ~rnk_config_kill_rts_col && order_q_zero && col_wait_r && demand_ok;
// Using rank state provided by the rank machines, figure out if
// a read requests should wait for WTR or RTW.
input [RANKS-1:0] inhbt_rd;
wire my_inhbt_rd = inhbt_rd[req_rank_r];
input [RANKS-1:0] inhbt_wr;
wire my_inhbt_wr = inhbt_wr[req_rank_r];
wire allow_rw = ~rd_wr_r ? ~my_inhbt_wr : ~my_inhbt_rd;
// DQ bus timing constraints.
input dq_busy_data;
// Column command is ready to arbitrate, except for databus restrictions.
wire col_rdy = (col_wait_r || ((nRCD_CLKS <= 1) && end_rcd) ||
(rcv_open_bank && nCK_PER_CLK == 2 && DRAM_TYPE=="DDR2" && BURST_MODE == "4") ||
(rcv_open_bank && nCK_PER_CLK == 4 && BURST_MODE == "8")) &&
order_q_zero;
// Column command is ready to arbitrate for sending a write. Used
// to generate early wr_data_addr for ECC mode.
output wire col_rdy_wr;
assign col_rdy_wr = col_rdy && ~rd_wr_r;
// Figure out if we're ready to send a column command based on all timing
// constraints.
// if timing is an issue.
wire col_cmd_rts = col_rdy && ~dq_busy_data && allow_rw && rnk_config_match;
`ifdef MC_SVA
col_wait_for_order_q: cover property
(@(posedge clk)
(~rst && col_wait_r && ~order_q_zero && ~dq_busy_data &&
allow_rw));
col_wait_for_dq_busy: cover property
(@(posedge clk)
(~rst && col_wait_r && order_q_zero && dq_busy_data &&
allow_rw));
col_wait_for_allow_rw: cover property
(@(posedge clk)
(~rst && col_wait_r && order_q_zero && ~dq_busy_data &&
~allow_rw));
`endif
// Implement flow control for the command and control FIFOs and for the data
// FIFO during writes
input phy_mc_ctl_full;
input phy_mc_cmd_full;
input phy_mc_data_full;
// Register ctl_full and cmd_full
reg phy_mc_ctl_full_r = 1'b0;
reg phy_mc_cmd_full_r = 1'b0;
always @(posedge clk)
if(rst) begin
phy_mc_ctl_full_r <= #TCQ 1'b0;
phy_mc_cmd_full_r <= #TCQ 1'b0;
end else begin
phy_mc_ctl_full_r <= #TCQ phy_mc_ctl_full;
phy_mc_cmd_full_r <= #TCQ phy_mc_cmd_full;
end
// register output data pre-fifo almost full condition and fold in WR status
reg ofs_rdy_r = 1'b0;
always @(posedge clk)
if(rst)
ofs_rdy_r <= #TCQ 1'b0;
else
ofs_rdy_r <= #TCQ ~phy_mc_cmd_full_r && ~phy_mc_ctl_full_r && ~(phy_mc_data_full && ~rd_wr_r);
// Disable priority feature for one state after a config to insure
// forward progress on the just installed io config.
reg override_demand_r;
wire override_demand_ns = rnk_config_strobe || rnk_config_kill_rts_col;
always @(posedge clk) override_demand_r <= override_demand_ns;
output wire rts_col;
assign rts_col = ~sending_col && (demand_ok || override_demand_r) &&
col_cmd_rts && ofs_rdy_r;
// As in act_this_rank, wr/rd_this_rank informs rank machines
// that this bank machine is doing a write/rd. Removes logic
// after the grant.
reg [RANKS-1:0] wr_this_rank_ns;
reg [RANKS-1:0] rd_this_rank_ns;
always @(/*AS*/rd_wr_r or req_rank_r) begin
wr_this_rank_ns = {RANKS{1'b0}};
rd_this_rank_ns = {RANKS{1'b0}};
for (i=0; i<RANKS; i=i+1) begin
wr_this_rank_ns[i] = ~rd_wr_r && (i[RANK_WIDTH-1:0] == req_rank_r);
rd_this_rank_ns[i] = rd_wr_r && (i[RANK_WIDTH-1:0] == req_rank_r);
end
end
output reg [RANKS-1:0] wr_this_rank_r;
always @(posedge clk) wr_this_rank_r <= #TCQ wr_this_rank_ns;
output reg [RANKS-1:0] rd_this_rank_r;
always @(posedge clk) rd_this_rank_r <= #TCQ rd_this_rank_ns;
endmodule
|
module mig_7series_v2_3_bank_state #
(
parameter TCQ = 100,
parameter ADDR_CMD_MODE = "1T",
parameter BM_CNT_WIDTH = 2,
parameter BURST_MODE = "8",
parameter CWL = 5,
parameter DATA_BUF_ADDR_WIDTH = 8,
parameter DRAM_TYPE = "DDR3",
parameter ECC = "OFF",
parameter ID = 0,
parameter nBANK_MACHS = 4,
parameter nCK_PER_CLK = 2,
parameter nOP_WAIT = 0,
parameter nRAS_CLKS = 10,
parameter nRP = 10,
parameter nRTP = 4,
parameter nRCD = 5,
parameter nWTP_CLKS = 5,
parameter ORDERING = "NORM",
parameter RANKS = 4,
parameter RANK_WIDTH = 4,
parameter RAS_TIMER_WIDTH = 5,
parameter STARVE_LIMIT = 2
)
(/*AUTOARG*/
// Outputs
start_rcd, act_wait_r, rd_half_rmw, ras_timer_ns, end_rtp,
bank_wait_in_progress, start_pre_wait, op_exit_req, pre_wait_r,
allow_auto_pre, precharge_bm_end, demand_act_priority, rts_row,
act_this_rank_r, demand_priority, col_rdy_wr, rts_col, wr_this_rank_r,
rd_this_rank_r, rts_pre, rtc,
// Inputs
clk, rst, bm_end, pass_open_bank_r, sending_row, sending_pre, rcv_open_bank,
sending_col, rd_wr_r, req_wr_r, rd_data_addr, req_data_buf_addr_r,
phy_rddata_valid, rd_rmw, ras_timer_ns_in, rb_hit_busies_r, idle_r,
passing_open_bank, low_idle_cnt_r, op_exit_grant, tail_r,
auto_pre_r, pass_open_bank_ns, req_rank_r, req_rank_r_in,
start_rcd_in, inhbt_act_faw_r, wait_for_maint_r, head_r, sent_row,
demand_act_priority_in, order_q_zero, sent_col, q_has_rd,
q_has_priority, req_priority_r, idle_ns, demand_priority_in, inhbt_rd,
inhbt_wr, dq_busy_data, rnk_config_strobe, rnk_config_valid_r, rnk_config,
rnk_config_kill_rts_col, phy_mc_cmd_full, phy_mc_ctl_full, phy_mc_data_full
);
function integer clogb2 (input integer size); // ceiling logb2
begin
size = size - 1;
for (clogb2=1; size>1; clogb2=clogb2+1)
size = size >> 1;
end
endfunction // clogb2
input clk;
input rst;
// Activate wait state machine.
input bm_end;
reg bm_end_r1;
always @(posedge clk) bm_end_r1 <= #TCQ bm_end;
reg col_wait_r;
input pass_open_bank_r;
input sending_row;
reg act_wait_r_lcl;
input rcv_open_bank;
wire start_rcd_lcl = act_wait_r_lcl && sending_row;
output wire start_rcd;
assign start_rcd = start_rcd_lcl;
wire act_wait_ns = rst ||
((act_wait_r_lcl && ~start_rcd_lcl && ~rcv_open_bank) ||
bm_end_r1 || (pass_open_bank_r && bm_end));
always @(posedge clk) act_wait_r_lcl <= #TCQ act_wait_ns;
output wire act_wait_r;
assign act_wait_r = act_wait_r_lcl;
// RCD timer
//
// When CWL is even, CAS commands are issued on slot 0 and RAS commands are
// issued on slot 1. This implies that the RCD can never expire in the same
// cycle as the RAS (otherwise the CAS for a given transaction would precede
// the RAS). Similarly, this can also cause premature expiration for longer
// RCD. An offset must be added to RCD before translating it to the FPGA clock
// domain. In this mode, CAS are on the first DRAM clock cycle corresponding to
// a given FPGA cycle. In 2:1 mode add 2 to generate this offset aligned to
// the FPGA cycle. Likewise, add 4 to generate an aligned offset in 4:1 mode.
//
// When CWL is odd, RAS commands are issued on slot 0 and CAS commands are
// issued on slot 1. There is a natural 1 cycle seperation between RAS and CAS
// in the DRAM clock domain so the RCD can expire in the same FPGA cycle as the
// RAS command. In 2:1 mode, there are only 2 slots so direct translation
// correctly places the CAS with respect to the corresponding RAS. In 4:1 mode,
// there are two slots after CAS, so 2 is added to shift the timer into the
// next FPGA cycle for cases that can't expire in the current cycle.
//
// In 2T mode, the offset from ROW to COL commands is fixed at 2. In 2:1 mode,
// It is sufficient to translate to the half-rate domain and add the remainder.
// In 4:1 mode, we must translate to the quarter-rate domain and add an
// additional fabric cycle only if the remainder exceeds the fixed offset of 2
localparam nRCD_CLKS =
nCK_PER_CLK == 1 ?
nRCD :
nCK_PER_CLK == 2 ?
ADDR_CMD_MODE == "2T" ?
(nRCD/2) + (nRCD%2) :
CWL % 2 ?
(nRCD/2) :
(nRCD+2) / 2 :
// (nCK_PER_CLK == 4)
ADDR_CMD_MODE == "2T" ?
(nRCD/4) + (nRCD%4 > 2 ? 1 : 0) :
CWL % 2 ?
(nRCD-2 ? (nRCD-2) / 4 + 1 : 1) :
nRCD/4 + 1;
localparam nRCD_CLKS_M2 = (nRCD_CLKS-2 <0) ? 0 : nRCD_CLKS-2;
localparam RCD_TIMER_WIDTH = clogb2(nRCD_CLKS_M2+1);
localparam ZERO = 0;
localparam ONE = 1;
reg [RCD_TIMER_WIDTH-1:0] rcd_timer_r = {RCD_TIMER_WIDTH{1'b0}};
reg end_rcd;
reg rcd_active_r = 1'b0;
generate
if (nRCD_CLKS <= 2) begin : rcd_timer_leq_2
always @(/*AS*/start_rcd_lcl) end_rcd = start_rcd_lcl;
end
else if (nRCD_CLKS > 2) begin : rcd_timer_gt_2
reg [RCD_TIMER_WIDTH-1:0] rcd_timer_ns;
always @(/*AS*/rcd_timer_r or rst or start_rcd_lcl) begin
if (rst) rcd_timer_ns = ZERO[RCD_TIMER_WIDTH-1:0];
else begin
rcd_timer_ns = rcd_timer_r;
if (start_rcd_lcl) rcd_timer_ns = nRCD_CLKS_M2[RCD_TIMER_WIDTH-1:0];
else if (|rcd_timer_r) rcd_timer_ns =
rcd_timer_r - ONE[RCD_TIMER_WIDTH-1:0];
end
end
always @(posedge clk) rcd_timer_r <= #TCQ rcd_timer_ns;
wire end_rcd_ns = (rcd_timer_ns == ONE[RCD_TIMER_WIDTH-1:0]);
always @(posedge clk) end_rcd = end_rcd_ns;
wire rcd_active_ns = |rcd_timer_ns;
always @(posedge clk) rcd_active_r <= #TCQ rcd_active_ns;
end
endgenerate
// Figure out if the read that's completing is for an RMW for
// this bank machine. Delay by a state if CWL != 8 since the
// data is not ready in the RMW buffer for the early write
// data fetch that happens with ECC and CWL != 8.
// Create a state bit indicating we're waiting for the read
// half of the rmw to complete.
input sending_col;
input rd_wr_r;
input req_wr_r;
input [DATA_BUF_ADDR_WIDTH-1:0] rd_data_addr;
input [DATA_BUF_ADDR_WIDTH-1:0] req_data_buf_addr_r;
input phy_rddata_valid;
input rd_rmw;
reg rmw_rd_done = 1'b0;
reg rd_half_rmw_lcl = 1'b0;
output wire rd_half_rmw;
assign rd_half_rmw = rd_half_rmw_lcl;
reg rmw_wait_r = 1'b0;
generate
if (ECC != "OFF") begin : rmw_on
// Delay phy_rddata_valid and rd_rmw by one cycle to align them
// to req_data_buf_addr_r so that rmw_wait_r clears properly
reg phy_rddata_valid_r;
reg rd_rmw_r;
always @(posedge clk) begin
phy_rddata_valid_r <= #TCQ phy_rddata_valid;
rd_rmw_r <= #TCQ rd_rmw;
end
wire my_rmw_rd_ns = phy_rddata_valid_r && rd_rmw_r &&
(rd_data_addr == req_data_buf_addr_r);
if (CWL == 8) always @(my_rmw_rd_ns) rmw_rd_done = my_rmw_rd_ns;
else always @(posedge clk) rmw_rd_done = #TCQ my_rmw_rd_ns;
always @(/*AS*/rd_wr_r or req_wr_r) rd_half_rmw_lcl = req_wr_r && rd_wr_r;
wire rmw_wait_ns = ~rst &&
((rmw_wait_r && ~rmw_rd_done) || (rd_half_rmw_lcl && sending_col));
always @(posedge clk) rmw_wait_r <= #TCQ rmw_wait_ns;
end
endgenerate
// column wait state machine.
wire col_wait_ns = ~rst && ((col_wait_r && ~sending_col) || end_rcd
|| rcv_open_bank || (rmw_rd_done && rmw_wait_r));
always @(posedge clk) col_wait_r <= #TCQ col_wait_ns;
// Set up various RAS timer parameters, wires, etc.
localparam TWO = 2;
output reg [RAS_TIMER_WIDTH-1:0] ras_timer_ns;
reg [RAS_TIMER_WIDTH-1:0] ras_timer_r;
input [(2*(RAS_TIMER_WIDTH*nBANK_MACHS))-1:0] ras_timer_ns_in;
input [(nBANK_MACHS*2)-1:0] rb_hit_busies_r;
// On a bank pass, select the RAS timer from the passing bank machine.
reg [RAS_TIMER_WIDTH-1:0] passed_ras_timer;
integer i;
always @(/*AS*/ras_timer_ns_in or rb_hit_busies_r) begin
passed_ras_timer = {RAS_TIMER_WIDTH{1'b0}};
for (i=ID+1; i<(ID+nBANK_MACHS); i=i+1)
if (rb_hit_busies_r[i])
passed_ras_timer = ras_timer_ns_in[i*RAS_TIMER_WIDTH+:RAS_TIMER_WIDTH];
end
// RAS and (reused for) WTP timer. When an open bank is passed, this
// timer is passed to the new owner. The existing RAS prevents
// an activate from occuring too early.
wire start_wtp_timer = sending_col && ~rd_wr_r;
input idle_r;
always @(/*AS*/bm_end_r1 or ras_timer_r or rst or start_rcd_lcl
or start_wtp_timer) begin
if (bm_end_r1 || rst) ras_timer_ns = ZERO[RAS_TIMER_WIDTH-1:0];
else begin
ras_timer_ns = ras_timer_r;
if (start_rcd_lcl) ras_timer_ns =
nRAS_CLKS[RAS_TIMER_WIDTH-1:0] - TWO[RAS_TIMER_WIDTH-1:0];
if (start_wtp_timer) ras_timer_ns =
// As the timer is being reused, it is essential to compare
// before new value is loaded.
(ras_timer_r <= (nWTP_CLKS-2)) ? nWTP_CLKS[RAS_TIMER_WIDTH-1:0] - TWO[RAS_TIMER_WIDTH-1:0]
: ras_timer_r - ONE[RAS_TIMER_WIDTH-1:0];
if (|ras_timer_r && ~start_wtp_timer) ras_timer_ns =
ras_timer_r - ONE[RAS_TIMER_WIDTH-1:0];
end
end // always @ (...
wire [RAS_TIMER_WIDTH-1:0] ras_timer_passed_ns = rcv_open_bank
? passed_ras_timer
: ras_timer_ns;
always @(posedge clk) ras_timer_r <= #TCQ ras_timer_passed_ns;
wire ras_timer_zero_ns = (ras_timer_ns == ZERO[RAS_TIMER_WIDTH-1:0]);
reg ras_timer_zero_r;
always @(posedge clk) ras_timer_zero_r <= #TCQ ras_timer_zero_ns;
// RTP timer. Unless 2T mode, add one for 2:1 mode. This accounts for loss of
// one DRAM CK due to column command to row command fixed offset. In 2T mode,
// Add the remainder. In 4:1 mode, the fixed offset is -2. Add 2 unless in 2T
// mode, in which case we add 1 if the remainder exceeds the fixed offset.
localparam nRTP_CLKS = (nCK_PER_CLK == 1)
? nRTP :
(nCK_PER_CLK == 2)
? (nRTP/2) + ((ADDR_CMD_MODE == "2T") ? nRTP%2 : 1) :
(nRTP/4) + ((ADDR_CMD_MODE == "2T") ? (nRTP%4 > 2 ? 2 : 1) : 2);
localparam nRTP_CLKS_M1 = ((nRTP_CLKS-1) <= 0) ? 0 : nRTP_CLKS-1;
localparam RTP_TIMER_WIDTH = clogb2(nRTP_CLKS_M1 + 1);
reg [RTP_TIMER_WIDTH-1:0] rtp_timer_ns;
reg [RTP_TIMER_WIDTH-1:0] rtp_timer_r;
wire sending_col_not_rmw_rd = sending_col && ~rd_half_rmw_lcl;
always @(/*AS*/pass_open_bank_r or rst or rtp_timer_r
or sending_col_not_rmw_rd) begin
rtp_timer_ns = rtp_timer_r;
if (rst || pass_open_bank_r)
rtp_timer_ns = ZERO[RTP_TIMER_WIDTH-1:0];
else begin
if (sending_col_not_rmw_rd)
rtp_timer_ns = nRTP_CLKS_M1[RTP_TIMER_WIDTH-1:0];
if (|rtp_timer_r) rtp_timer_ns = rtp_timer_r - ONE[RTP_TIMER_WIDTH-1:0];
end
end
always @(posedge clk) rtp_timer_r <= #TCQ rtp_timer_ns;
wire end_rtp_lcl = ~pass_open_bank_r &&
((rtp_timer_r == ONE[RTP_TIMER_WIDTH-1:0]) ||
((nRTP_CLKS_M1 == 0) && sending_col_not_rmw_rd));
output wire end_rtp;
assign end_rtp = end_rtp_lcl;
// Optionally implement open page mode timer.
localparam OP_WIDTH = clogb2(nOP_WAIT + 1);
output wire bank_wait_in_progress;
output wire start_pre_wait;
input passing_open_bank;
input low_idle_cnt_r;
output wire op_exit_req;
input op_exit_grant;
input tail_r;
output reg pre_wait_r;
generate
if (nOP_WAIT == 0) begin : op_mode_disabled
assign bank_wait_in_progress = sending_col_not_rmw_rd || |rtp_timer_r ||
(pre_wait_r && ~ras_timer_zero_r);
assign start_pre_wait = end_rtp_lcl;
assign op_exit_req = 1'b0;
end
else begin : op_mode_enabled
reg op_wait_r;
assign bank_wait_in_progress = sending_col || |rtp_timer_r ||
(pre_wait_r && ~ras_timer_zero_r) ||
op_wait_r;
wire op_active = ~rst && ~passing_open_bank && ((end_rtp_lcl && tail_r)
|| op_wait_r);
wire op_wait_ns = ~op_exit_grant && op_active;
always @(posedge clk) op_wait_r <= #TCQ op_wait_ns;
assign start_pre_wait = op_exit_grant ||
(end_rtp_lcl && ~tail_r && ~passing_open_bank);
if (nOP_WAIT == -1)
assign op_exit_req = (low_idle_cnt_r && op_active);
else begin : op_cnt
reg [OP_WIDTH-1:0] op_cnt_r;
wire [OP_WIDTH-1:0] op_cnt_ns =
(passing_open_bank || op_exit_grant || rst)
? ZERO[OP_WIDTH-1:0]
: end_rtp_lcl
? nOP_WAIT[OP_WIDTH-1:0]
: |op_cnt_r
? op_cnt_r - ONE[OP_WIDTH-1:0]
: op_cnt_r;
always @(posedge clk) op_cnt_r <= #TCQ op_cnt_ns;
assign op_exit_req = (low_idle_cnt_r && op_active) ||
(op_wait_r && ~|op_cnt_r);
end
end
endgenerate
output allow_auto_pre;
wire allow_auto_pre = act_wait_r_lcl || rcd_active_r ||
(col_wait_r && ~sending_col);
// precharge wait state machine.
input auto_pre_r;
wire start_pre;
input pass_open_bank_ns;
wire pre_wait_ns = ~rst && (~pass_open_bank_ns &&
(start_pre_wait || (pre_wait_r && ~start_pre)));
always @(posedge clk) pre_wait_r <= #TCQ pre_wait_ns;
wire pre_request = pre_wait_r && ras_timer_zero_r && ~auto_pre_r;
// precharge timer.
localparam nRP_CLKS = (nCK_PER_CLK == 1) ? nRP :
(nCK_PER_CLK == 2) ? ((nRP/2) + (nRP%2)) :
/*(nCK_PER_CLK == 4)*/ ((nRP/4) + ((nRP%4) ? 1 : 0));
// Subtract two because there are a minimum of two fabric states from
// end of RP timer until earliest possible arb to send act.
localparam nRP_CLKS_M2 = (nRP_CLKS-2 < 0) ? 0 : nRP_CLKS-2;
localparam RP_TIMER_WIDTH = clogb2(nRP_CLKS_M2 + 1);
input sending_pre;
output rts_pre;
generate
if((nCK_PER_CLK == 4) && (ADDR_CMD_MODE != "2T")) begin
assign start_pre = pre_wait_r && ras_timer_zero_r &&
(sending_pre || auto_pre_r);
assign rts_pre = ~sending_pre && pre_request;
end
else begin
assign start_pre = pre_wait_r && ras_timer_zero_r &&
(sending_row || auto_pre_r);
assign rts_pre = 1'b0;
end
endgenerate
reg [RP_TIMER_WIDTH-1:0] rp_timer_r = ZERO[RP_TIMER_WIDTH-1:0];
generate
if (nRP_CLKS_M2 > ZERO) begin : rp_timer
reg [RP_TIMER_WIDTH-1:0] rp_timer_ns;
always @(/*AS*/rp_timer_r or rst or start_pre)
if (rst) rp_timer_ns = ZERO[RP_TIMER_WIDTH-1:0];
else begin
rp_timer_ns = rp_timer_r;
if (start_pre) rp_timer_ns = nRP_CLKS_M2[RP_TIMER_WIDTH-1:0];
else if (|rp_timer_r) rp_timer_ns =
rp_timer_r - ONE[RP_TIMER_WIDTH-1:0];
end
always @(posedge clk) rp_timer_r <= #TCQ rp_timer_ns;
end // block: rp_timer
endgenerate
output wire precharge_bm_end;
assign precharge_bm_end = (rp_timer_r == ONE[RP_TIMER_WIDTH-1:0]) ||
(start_pre && (nRP_CLKS_M2 == ZERO));
// Compute RRD related activate inhibit.
// Compare this bank machine's rank with others, then
// select result based on grant. An alternative is to
// select the just issued rank with the grant and simply
// compare against this bank machine's rank. However, this
// serializes the selection of the rank and the compare processes.
// As implemented below, the compare occurs first, then the
// selection based on grant. This is faster.
input [RANK_WIDTH-1:0] req_rank_r;
input [(RANK_WIDTH*nBANK_MACHS*2)-1:0] req_rank_r_in;
reg inhbt_act_rrd;
input [(nBANK_MACHS*2)-1:0] start_rcd_in;
generate
integer j;
if (RANKS == 1)
always @(/*AS*/req_rank_r or req_rank_r_in or start_rcd_in) begin
inhbt_act_rrd = 1'b0;
for (j=(ID+1); j<(ID+nBANK_MACHS); j=j+1)
inhbt_act_rrd = inhbt_act_rrd || start_rcd_in[j];
end
else begin
always @(/*AS*/req_rank_r or req_rank_r_in or start_rcd_in) begin
inhbt_act_rrd = 1'b0;
for (j=(ID+1); j<(ID+nBANK_MACHS); j=j+1)
inhbt_act_rrd = inhbt_act_rrd ||
(start_rcd_in[j] &&
(req_rank_r_in[(j*RANK_WIDTH)+:RANK_WIDTH] == req_rank_r));
end
end
endgenerate
// Extract the activate command inhibit for the rank associated
// with this request. FAW and RRD are computed separately so that
// gate level timing can be carefully managed.
input [RANKS-1:0] inhbt_act_faw_r;
wire my_inhbt_act_faw = inhbt_act_faw_r[req_rank_r];
input wait_for_maint_r;
input head_r;
wire act_req = ~idle_r && head_r && act_wait_r && ras_timer_zero_r &&
~wait_for_maint_r;
// Implement simple starvation avoidance for act requests. Precharge
// requests don't need this because they are never gated off by
// timing events such as inhbt_act_rrd. Priority request timeout
// is fixed at a single trip around the round robin arbiter.
input sent_row;
wire rts_act_denied = act_req && sent_row && ~sending_row;
reg [BM_CNT_WIDTH-1:0] act_starve_limit_cntr_ns;
reg [BM_CNT_WIDTH-1:0] act_starve_limit_cntr_r;
generate
if (BM_CNT_WIDTH > 1) // Number of Bank Machs > 2
begin :BM_MORE_THAN_2
always @(/*AS*/act_req or act_starve_limit_cntr_r or rts_act_denied)
begin
act_starve_limit_cntr_ns = act_starve_limit_cntr_r;
if (~act_req)
act_starve_limit_cntr_ns = {BM_CNT_WIDTH{1'b0}};
else
if (rts_act_denied && &act_starve_limit_cntr_r)
act_starve_limit_cntr_ns = act_starve_limit_cntr_r +
{{BM_CNT_WIDTH-1{1'b0}}, 1'b1};
end
end
else // Number of Bank Machs == 2
begin :BM_EQUAL_2
always @(/*AS*/act_req or act_starve_limit_cntr_r or rts_act_denied)
begin
act_starve_limit_cntr_ns = act_starve_limit_cntr_r;
if (~act_req)
act_starve_limit_cntr_ns = {BM_CNT_WIDTH{1'b0}};
else
if (rts_act_denied && &act_starve_limit_cntr_r)
act_starve_limit_cntr_ns = act_starve_limit_cntr_r +
{1'b1};
end
end
endgenerate
always @(posedge clk) act_starve_limit_cntr_r <=
#TCQ act_starve_limit_cntr_ns;
reg demand_act_priority_r;
wire demand_act_priority_ns = act_req &&
(demand_act_priority_r || (rts_act_denied && &act_starve_limit_cntr_r));
always @(posedge clk) demand_act_priority_r <= #TCQ demand_act_priority_ns;
`ifdef MC_SVA
cover_demand_act_priority:
cover property (@(posedge clk) (~rst && demand_act_priority_r));
`endif
output wire demand_act_priority;
assign demand_act_priority = demand_act_priority_r && ~sending_row;
// compute act_demanded from other demand_act_priorities
input [(nBANK_MACHS*2)-1:0] demand_act_priority_in;
reg act_demanded = 1'b0;
generate
if (nBANK_MACHS > 1) begin : compute_act_demanded
always @(demand_act_priority_in[`BM_SHARED_BV])
act_demanded = |demand_act_priority_in[`BM_SHARED_BV];
end
endgenerate
wire row_demand_ok = demand_act_priority_r || ~act_demanded;
// Generate the Request To Send row arbitation signal.
output wire rts_row;
generate
if((nCK_PER_CLK == 4) && (ADDR_CMD_MODE != "2T"))
assign rts_row = ~sending_row && row_demand_ok &&
(act_req && ~my_inhbt_act_faw && ~inhbt_act_rrd);
else
assign rts_row = ~sending_row && row_demand_ok &&
((act_req && ~my_inhbt_act_faw && ~inhbt_act_rrd) ||
pre_request);
endgenerate
`ifdef MC_SVA
four_activate_window_wait:
cover property (@(posedge clk)
(~rst && ~sending_row && act_req && my_inhbt_act_faw));
ras_ras_delay_wait:
cover property (@(posedge clk)
(~rst && ~sending_row && act_req && inhbt_act_rrd));
`endif
// Provide rank machines early knowledge that this bank machine is
// going to send an activate to the rank. In this way, the rank
// machines just need to use the sending_row wire to figure out if
// they need to keep track of the activate.
output reg [RANKS-1:0] act_this_rank_r;
reg [RANKS-1:0] act_this_rank_ns;
always @(/*AS*/act_wait_r or req_rank_r) begin
act_this_rank_ns = {RANKS{1'b0}};
for (i = 0; i < RANKS; i = i + 1)
act_this_rank_ns[i] = act_wait_r && (i[RANK_WIDTH-1:0] == req_rank_r);
end
always @(posedge clk) act_this_rank_r <= #TCQ act_this_rank_ns;
// Generate request to send column command signal.
input order_q_zero;
wire req_bank_rdy_ns = order_q_zero && col_wait_r;
reg req_bank_rdy_r;
always @(posedge clk) req_bank_rdy_r <= #TCQ req_bank_rdy_ns;
// Determine is we have been denied a column command request.
input sent_col;
wire rts_col_denied = req_bank_rdy_r && sent_col && ~sending_col;
// Implement a starvation limit counter. Count the number of times a
// request to send a column command has been denied.
localparam STARVE_LIMIT_CNT = STARVE_LIMIT * nBANK_MACHS;
localparam STARVE_LIMIT_WIDTH = clogb2(STARVE_LIMIT_CNT);
reg [STARVE_LIMIT_WIDTH-1:0] starve_limit_cntr_r;
reg [STARVE_LIMIT_WIDTH-1:0] starve_limit_cntr_ns;
always @(/*AS*/col_wait_r or rts_col_denied or starve_limit_cntr_r)
if (~col_wait_r)
starve_limit_cntr_ns = {STARVE_LIMIT_WIDTH{1'b0}};
else
if (rts_col_denied && (starve_limit_cntr_r != STARVE_LIMIT_CNT-1))
starve_limit_cntr_ns = starve_limit_cntr_r +
{{STARVE_LIMIT_WIDTH-1{1'b0}}, 1'b1};
else starve_limit_cntr_ns = starve_limit_cntr_r;
always @(posedge clk) starve_limit_cntr_r <= #TCQ starve_limit_cntr_ns;
input q_has_rd;
input q_has_priority;
// Decide if this bank machine should demand priority. Priority is demanded
// when starvation limit counter is reached, or a bit in the request.
wire starved = ((starve_limit_cntr_r == (STARVE_LIMIT_CNT-1)) &&
rts_col_denied);
input req_priority_r;
input idle_ns;
reg demand_priority_r;
wire demand_priority_ns = ~idle_ns && col_wait_ns &&
(demand_priority_r ||
(order_q_zero &&
(req_priority_r || q_has_priority)) ||
(starved && (q_has_rd || ~req_wr_r)));
always @(posedge clk) demand_priority_r <= #TCQ demand_priority_ns;
`ifdef MC_SVA
wire rdy_for_priority = ~rst && ~demand_priority_r && ~idle_ns &&
col_wait_ns;
req_triggers_demand_priority:
cover property (@(posedge clk)
(rdy_for_priority && req_priority_r && ~q_has_priority && ~starved));
q_priority_triggers_demand_priority:
cover property (@(posedge clk)
(rdy_for_priority && ~req_priority_r && q_has_priority && ~starved));
wire not_req_or_q_rdy_for_priority =
rdy_for_priority && ~req_priority_r && ~q_has_priority;
starved_req_triggers_demand_priority:
cover property (@(posedge clk)
(not_req_or_q_rdy_for_priority && starved && ~q_has_rd && ~req_wr_r));
starved_q_triggers_demand_priority:
cover property (@(posedge clk)
(not_req_or_q_rdy_for_priority && starved && q_has_rd && req_wr_r));
`endif
// compute demanded from other demand_priorities
input [(nBANK_MACHS*2)-1:0] demand_priority_in;
reg demanded = 1'b0;
generate
if (nBANK_MACHS > 1) begin : compute_demanded
always @(demand_priority_in[`BM_SHARED_BV]) demanded =
|demand_priority_in[`BM_SHARED_BV];
end
endgenerate
// In order to make sure that there is no starvation amongst a possibly
// unlimited stream of priority requests, add a second stage to the demand
// priority signal. If there are no other requests demanding priority, then
// go ahead and assert demand_priority. If any other requests are asserting
// demand_priority, hold off asserting demand_priority until these clear, then
// assert demand priority. Its possible to get multiple requests asserting
// demand priority simultaneously, but that's OK. Those requests will be
// serviced, demanded will fall, and another group of requests will be
// allowed to assert demand_priority.
reg demanded_prior_r;
wire demanded_prior_ns = demanded &&
(demanded_prior_r || ~demand_priority_r);
always @(posedge clk) demanded_prior_r <= #TCQ demanded_prior_ns;
output wire demand_priority;
assign demand_priority = demand_priority_r && ~demanded_prior_r &&
~sending_col;
`ifdef MC_SVA
demand_priority_gated:
cover property (@(posedge clk) (demand_priority_r && ~demand_priority));
generate
if (nBANK_MACHS >1) multiple_demand_priority:
cover property (@(posedge clk)
($countones(demand_priority_in[`BM_SHARED_BV]) > 1));
endgenerate
`endif
wire demand_ok = demand_priority_r || ~demanded;
// Figure out if the request in this bank machine matches the current rank
// configuration.
input rnk_config_strobe;
input rnk_config_kill_rts_col;
input rnk_config_valid_r;
input [RANK_WIDTH-1:0] rnk_config;
output wire rtc;
wire rnk_config_match = rnk_config_valid_r && (rnk_config == req_rank_r);
assign rtc = ~rnk_config_match && ~rnk_config_kill_rts_col && order_q_zero && col_wait_r && demand_ok;
// Using rank state provided by the rank machines, figure out if
// a read requests should wait for WTR or RTW.
input [RANKS-1:0] inhbt_rd;
wire my_inhbt_rd = inhbt_rd[req_rank_r];
input [RANKS-1:0] inhbt_wr;
wire my_inhbt_wr = inhbt_wr[req_rank_r];
wire allow_rw = ~rd_wr_r ? ~my_inhbt_wr : ~my_inhbt_rd;
// DQ bus timing constraints.
input dq_busy_data;
// Column command is ready to arbitrate, except for databus restrictions.
wire col_rdy = (col_wait_r || ((nRCD_CLKS <= 1) && end_rcd) ||
(rcv_open_bank && nCK_PER_CLK == 2 && DRAM_TYPE=="DDR2" && BURST_MODE == "4") ||
(rcv_open_bank && nCK_PER_CLK == 4 && BURST_MODE == "8")) &&
order_q_zero;
// Column command is ready to arbitrate for sending a write. Used
// to generate early wr_data_addr for ECC mode.
output wire col_rdy_wr;
assign col_rdy_wr = col_rdy && ~rd_wr_r;
// Figure out if we're ready to send a column command based on all timing
// constraints.
// if timing is an issue.
wire col_cmd_rts = col_rdy && ~dq_busy_data && allow_rw && rnk_config_match;
`ifdef MC_SVA
col_wait_for_order_q: cover property
(@(posedge clk)
(~rst && col_wait_r && ~order_q_zero && ~dq_busy_data &&
allow_rw));
col_wait_for_dq_busy: cover property
(@(posedge clk)
(~rst && col_wait_r && order_q_zero && dq_busy_data &&
allow_rw));
col_wait_for_allow_rw: cover property
(@(posedge clk)
(~rst && col_wait_r && order_q_zero && ~dq_busy_data &&
~allow_rw));
`endif
// Implement flow control for the command and control FIFOs and for the data
// FIFO during writes
input phy_mc_ctl_full;
input phy_mc_cmd_full;
input phy_mc_data_full;
// Register ctl_full and cmd_full
reg phy_mc_ctl_full_r = 1'b0;
reg phy_mc_cmd_full_r = 1'b0;
always @(posedge clk)
if(rst) begin
phy_mc_ctl_full_r <= #TCQ 1'b0;
phy_mc_cmd_full_r <= #TCQ 1'b0;
end else begin
phy_mc_ctl_full_r <= #TCQ phy_mc_ctl_full;
phy_mc_cmd_full_r <= #TCQ phy_mc_cmd_full;
end
// register output data pre-fifo almost full condition and fold in WR status
reg ofs_rdy_r = 1'b0;
always @(posedge clk)
if(rst)
ofs_rdy_r <= #TCQ 1'b0;
else
ofs_rdy_r <= #TCQ ~phy_mc_cmd_full_r && ~phy_mc_ctl_full_r && ~(phy_mc_data_full && ~rd_wr_r);
// Disable priority feature for one state after a config to insure
// forward progress on the just installed io config.
reg override_demand_r;
wire override_demand_ns = rnk_config_strobe || rnk_config_kill_rts_col;
always @(posedge clk) override_demand_r <= override_demand_ns;
output wire rts_col;
assign rts_col = ~sending_col && (demand_ok || override_demand_r) &&
col_cmd_rts && ofs_rdy_r;
// As in act_this_rank, wr/rd_this_rank informs rank machines
// that this bank machine is doing a write/rd. Removes logic
// after the grant.
reg [RANKS-1:0] wr_this_rank_ns;
reg [RANKS-1:0] rd_this_rank_ns;
always @(/*AS*/rd_wr_r or req_rank_r) begin
wr_this_rank_ns = {RANKS{1'b0}};
rd_this_rank_ns = {RANKS{1'b0}};
for (i=0; i<RANKS; i=i+1) begin
wr_this_rank_ns[i] = ~rd_wr_r && (i[RANK_WIDTH-1:0] == req_rank_r);
rd_this_rank_ns[i] = rd_wr_r && (i[RANK_WIDTH-1:0] == req_rank_r);
end
end
output reg [RANKS-1:0] wr_this_rank_r;
always @(posedge clk) wr_this_rank_r <= #TCQ wr_this_rank_ns;
output reg [RANKS-1:0] rd_this_rank_r;
always @(posedge clk) rd_this_rank_r <= #TCQ rd_this_rank_ns;
endmodule
|
module outputs)
wire [TAPCNTRWIDTH-1:0] fall_lead_center; // From u_edge_center of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] fall_lead_left; // From u_edge_left of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] fall_lead_right; // From u_edge_right of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] fall_trail_center; // From u_edge_center of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] fall_trail_left; // From u_edge_left of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] fall_trail_right; // From u_edge_right of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] rise_lead_center; // From u_edge_center of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] rise_lead_left; // From u_edge_left of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] rise_trail_center; // From u_edge_center of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] rise_trail_left; // From u_edge_left of mig_7series_v2_3_poc_edge_store.v
wire [TAPCNTRWIDTH-1:0] run; // From u_poc_tap_base of mig_7series_v2_3_poc_tap_base.v
wire run_end; // From u_poc_tap_base of mig_7series_v2_3_poc_tap_base.v
wire run_polarity; // From u_poc_tap_base of mig_7series_v2_3_poc_tap_base.v
wire [SAMPCNTRWIDTH:0] samples; // From u_poc_cc of mig_7series_v2_3_poc_cc.v
wire [SAMPCNTRWIDTH:0] samps_hi_held; // From u_poc_tap_base of mig_7series_v2_3_poc_tap_base.v
wire [SAMPCNTRWIDTH:0] samps_solid_thresh; // From u_poc_cc of mig_7series_v2_3_poc_cc.v
wire [TAPCNTRWIDTH-1:0] tap; // From u_poc_tap_base of mig_7series_v2_3_poc_tap_base.v
// End of automatics
output psen;
output [TAPCNTRWIDTH-1:0] rise_lead_right;
output [TAPCNTRWIDTH-1:0] rise_trail_right;
output mmcm_edge_detect_done;
output mmcm_lbclk_edge_aligned;
mig_7series_v2_3_poc_tap_base #
(/*AUTOINSTPARAM*/
// Parameters
.MMCM_SAMP_WAIT (MMCM_SAMP_WAIT),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP),
.SAMPCNTRWIDTH (SAMPCNTRWIDTH),
.TAPCNTRWIDTH (TAPCNTRWIDTH),
.TAPSPERKCLK (TAPSPERKCLK),
.TCQ (TCQ))
u_poc_tap_base
(/*AUTOINST*/
// Outputs
.psen (psen),
.psincdec (psincdec),
.run (run[TAPCNTRWIDTH-1:0]),
.run_end (run_end),
.run_polarity (run_polarity),
.samps_hi_held (samps_hi_held[SAMPCNTRWIDTH:0]),
.tap (tap[TAPCNTRWIDTH-1:0]),
// Inputs
.clk (clk),
.pd_out (pd_out),
.poc_sample_pd (poc_sample_pd),
.psdone (psdone),
.rst (rst),
.samples (samples[SAMPCNTRWIDTH:0]),
.samps_solid_thresh (samps_solid_thresh[SAMPCNTRWIDTH:0]));
mig_7series_v2_3_poc_meta #
(/*AUTOINSTPARAM*/
// Parameters
.SCANFROMRIGHT (SCANFROMRIGHT),
.TAPCNTRWIDTH (TAPCNTRWIDTH),
.TAPSPERKCLK (TAPSPERKCLK),
.TCQ (TCQ))
u_poc_meta
(/*AUTOINST*/
// Outputs
.mmcm_edge_detect_done (mmcm_edge_detect_done),
.mmcm_lbclk_edge_aligned (mmcm_lbclk_edge_aligned),
.poc_backup (poc_backup),
// Inputs
.clk (clk),
.ktap_at_left_edge (ktap_at_left_edge),
.ktap_at_right_edge (ktap_at_right_edge),
.mmcm_edge_detect_rdy (mmcm_edge_detect_rdy),
.ninety_offsets (ninety_offsets[1:0]),
.rise_lead_center (rise_lead_center[TAPCNTRWIDTH-1:0]),
.rise_lead_left (rise_lead_left[TAPCNTRWIDTH-1:0]),
.rise_lead_right (rise_lead_right[TAPCNTRWIDTH-1:0]),
.rise_trail_center (rise_trail_center[TAPCNTRWIDTH-1:0]),
.rise_trail_left (rise_trail_left[TAPCNTRWIDTH-1:0]),
.rise_trail_right (rise_trail_right[TAPCNTRWIDTH-1:0]),
.rst (rst),
.run (run[TAPCNTRWIDTH-1:0]),
.run_end (run_end),
.run_polarity (run_polarity),
.use_noise_window (use_noise_window));
/*mig_7series_v2_3_poc_edge_store AUTO_TEMPLATE "edge_\(.*\)$" (
.\(.*\)lead (\1lead_@@"vl-bits"),
.\(.*\)trail (\1trail_@@"vl-bits"),
.select0 (ktap_at_@_edge),
.select1 (1'b1),)*/
mig_7series_v2_3_poc_edge_store #
(/*AUTOINSTPARAM*/
// Parameters
.TAPCNTRWIDTH (TAPCNTRWIDTH),
.TAPSPERKCLK (TAPSPERKCLK),
.TCQ (TCQ))
u_edge_right
(/*AUTOINST*/
// Outputs
.fall_lead (fall_lead_right[TAPCNTRWIDTH-1:0]), // Templated
.fall_trail (fall_trail_right[TAPCNTRWIDTH-1:0]), // Templated
.rise_lead (rise_lead_right[TAPCNTRWIDTH-1:0]), // Templated
.rise_trail (rise_trail_right[TAPCNTRWIDTH-1:0]), // Templated
// Inputs
.clk (clk),
.run (run[TAPCNTRWIDTH-1:0]),
.run_end (run_end),
.run_polarity (run_polarity),
.select0 (ktap_at_right_edge), // Templated
.select1 (1'b1), // Templated
.tap (tap[TAPCNTRWIDTH-1:0]));
mig_7series_v2_3_poc_edge_store #
(/*AUTOINSTPARAM*/
// Parameters
.TAPCNTRWIDTH (TAPCNTRWIDTH),
.TAPSPERKCLK (TAPSPERKCLK),
.TCQ (TCQ))
u_edge_left
(/*AUTOINST*/
// Outputs
.fall_lead (fall_lead_left[TAPCNTRWIDTH-1:0]), // Templated
.fall_trail (fall_trail_left[TAPCNTRWIDTH-1:0]), // Templated
.rise_lead (rise_lead_left[TAPCNTRWIDTH-1:0]), // Templated
.rise_trail (rise_trail_left[TAPCNTRWIDTH-1:0]), // Templated
// Inputs
.clk (clk),
.run (run[TAPCNTRWIDTH-1:0]),
.run_end (run_end),
.run_polarity (run_polarity),
.select0 (ktap_at_left_edge), // Templated
.select1 (1'b1), // Templated
.tap (tap[TAPCNTRWIDTH-1:0]));
wire not_ktap_at_right_edge = ~ktap_at_right_edge;
wire not_ktap_at_left_edge = ~ktap_at_left_edge;
/*mig_7series_v2_3_poc_edge_store AUTO_TEMPLATE "edge_\(.*\)$" (
.\(.*\)lead (\1lead_@@"vl-bits"),
.\(.*\)trail (\1trail_@@"vl-bits"),
.select0 (not_ktap_at_right_edge),
.select1 (not_ktap_at_left_edge),)*/
mig_7series_v2_3_poc_edge_store #
(/*AUTOINSTPARAM*/
// Parameters
.TAPCNTRWIDTH (TAPCNTRWIDTH),
.TAPSPERKCLK (TAPSPERKCLK),
.TCQ (TCQ))
u_edge_center
(/*AUTOINST*/
// Outputs
.fall_lead (fall_lead_center[TAPCNTRWIDTH-1:0]), // Templated
.fall_trail (fall_trail_center[TAPCNTRWIDTH-1:0]), // Templated
.rise_lead (rise_lead_center[TAPCNTRWIDTH-1:0]), // Templated
.rise_trail (rise_trail_center[TAPCNTRWIDTH-1:0]), // Templated
// Inputs
.clk (clk),
.run (run[TAPCNTRWIDTH-1:0]),
.run_end (run_end),
.run_polarity (run_polarity),
.select0 (not_ktap_at_right_edge), // Templated
.select1 (not_ktap_at_left_edge), // Templated
.tap (tap[TAPCNTRWIDTH-1:0]));
mig_7series_v2_3_poc_cc #
(/*AUTOINSTPARAM*/
// Parameters
.CCENABLE (CCENABLE),
.PCT_SAMPS_SOLID (PCT_SAMPS_SOLID),
.SAMPCNTRWIDTH (SAMPCNTRWIDTH),
.SAMPLES (SAMPLES),
.TAPCNTRWIDTH (TAPCNTRWIDTH),
.TCQ (TCQ))
u_poc_cc
(/*AUTOINST*/
// Outputs
.poc_error (poc_error),
.samples (samples[SAMPCNTRWIDTH:0]),
.samps_solid_thresh (samps_solid_thresh[SAMPCNTRWIDTH:0]),
// Inputs
.clk (clk),
.fall_lead_center (fall_lead_center[TAPCNTRWIDTH-1:0]),
.fall_lead_left (fall_lead_left[TAPCNTRWIDTH-1:0]),
.fall_lead_right (fall_lead_right[TAPCNTRWIDTH-1:0]),
.fall_trail_center (fall_trail_center[TAPCNTRWIDTH-1:0]),
.fall_trail_left (fall_trail_left[TAPCNTRWIDTH-1:0]),
.fall_trail_right (fall_trail_right[TAPCNTRWIDTH-1:0]),
.ktap_at_left_edge (ktap_at_left_edge),
.ktap_at_right_edge (ktap_at_right_edge),
.mmcm_edge_detect_done (mmcm_edge_detect_done),
.mmcm_lbclk_edge_aligned (mmcm_lbclk_edge_aligned),
.psen (psen),
.rise_lead_center (rise_lead_center[TAPCNTRWIDTH-1:0]),
.rise_lead_left (rise_lead_left[TAPCNTRWIDTH-1:0]),
.rise_lead_right (rise_lead_right[TAPCNTRWIDTH-1:0]),
.rise_trail_center (rise_trail_center[TAPCNTRWIDTH-1:0]),
.rise_trail_left (rise_trail_left[TAPCNTRWIDTH-1:0]),
.rise_trail_right (rise_trail_right[TAPCNTRWIDTH-1:0]),
.rst (rst),
.samps_hi_held (samps_hi_held[SAMPCNTRWIDTH:0]),
.tap (tap[TAPCNTRWIDTH-1:0]));
endmodule
|
module for complex oclkdelay calib
else if (oclkdelay_calib_done && !oclkdelay_calib_done_r && (BYPASS_COMPLEX_OCAL == "FALSE")) begin
done = 1'b0;
end
end
INIT: begin
ktap_right = 1'b1;
// Initial stage 2 increment to 63 for left limit
if (wait_cnt_done)
lim_nxt_state = STAGE2_TAP_CHK;
end
// Wait for DQS to toggle before asserting poc_ready
WAIT_WR_REQ: begin
write_request = 1'b1;
if (wait_cnt_done) begin
poc_ready = 1'b1;
lim_nxt_state = WAIT_POC_DONE;
end
end
// Wait for POC detect done signal
WAIT_POC_DONE: begin
if (poc2lim_detect_done) begin
write_request = 1'b0;
poc_ready = 1'b0;
lim_nxt_state = WAIT_STG3;
end
end
// Wait for DQS to stop toggling before stage3 inc/dec
WAIT_STG3: begin
if (wait_cnt_done) begin
if (stg3_dec_r) begin
// Check for Stage 3 underflow and MMCM tap limit
if ((stg3_tap_cnt > 'd0) && (mmcm_sub_dec < TDQSS_LIM_MMCM_TAPS))
lim_nxt_state = STAGE3_DEC;
else begin
stg3_dec = 1'b0;
stg3_inc2init_val = 1'b1;
lim_nxt_state = STAGE3_INC;
end
end else begin // Stage 3 being incremented
// Check for Stage 3 overflow and MMCM tap limit
if ((stg3_tap_cnt < 'd63) && (mmcm_sub_inc < TDQSS_LIM_MMCM_TAPS))
lim_nxt_state = STAGE3_INC;
else begin
stg3_dec2init_val = 1'b1;
lim_nxt_state = STAGE3_DEC;
end
end
end
end
STAGE3_INC: begin
stg3_inc_req = 1'b1;
lim_nxt_state = STG3_INCDEC_WAIT;
end
STAGE3_DEC: begin
stg3_dec_req = 1'b1;
lim_nxt_state = STG3_INCDEC_WAIT;
end
// Wait for stage3 inc/dec to complete (po_rdy)
STG3_INCDEC_WAIT: begin
stg3_dec_req = 1'b0;
stg3_inc_req = 1'b0;
if (!stg3_dec_req_r && !stg3_inc_req_r && po_rdy) begin
if (stg3_init_dec_r) begin
// Initial decrement of stage 3
if (stg3_tap_cnt > stg3_dec_val)
lim_nxt_state = STAGE3_DEC;
else begin
lim_nxt_state = WAIT_WR_REQ;
stg3_init_dec = 1'b0;
end
end else if (stg3_dec2init_val_r) begin
if (stg3_tap_cnt > stg3_init_val)
lim_nxt_state = STAGE3_DEC;
else
lim_nxt_state = STAGE2_TAP_CHK;
end else if (stg3_inc2init_val_r) begin
if (stg3_tap_cnt < stg3_inc_val)
lim_nxt_state = STAGE3_INC;
else
lim_nxt_state = STAGE2_TAP_CHK;
end else begin
lim_nxt_state = WAIT_WR_REQ;
end
end
end
// Check for overflow and underflow of stage2 taps
STAGE2_TAP_CHK: begin
if (stg3_dec2init_val_r) begin
// Increment stage 2 to write level tap value at the end of limit detection
if (stg2_tap_cnt < wl_po_fine_cnt)
lim_nxt_state = STAGE2_INC;
else begin
lim_nxt_state = PRECH_REQUEST;
end
end else if (stg3_inc2init_val_r) begin
// Decrement stage 2 to '0' to determine right limit
if (stg2_tap_cnt > 'd0)
lim_nxt_state = STAGE2_DEC;
else begin
lim_nxt_state = PRECH_REQUEST;
stg3_inc2init_val = 1'b0;
end
end else if (stg2_inc_r && (stg2_tap_cnt < 'd63)) begin
// Initial increment to 63
lim_nxt_state = STAGE2_INC;
end else begin
lim_nxt_state = STG3_INCDEC_WAIT;
stg2_inc = 1'b0;
end
end
STAGE2_INC: begin
stg2_inc_req = 1'b1;
lim_nxt_state = STG2_INCDEC_WAIT;
end
STAGE2_DEC: begin
stg2_dec_req = 1'b1;
lim_nxt_state = STG2_INCDEC_WAIT;
end
// Wait for stage3 inc/dec to complete (po_rdy)
STG2_INCDEC_WAIT: begin
stg2_inc_req = 1'b0;
stg2_dec_req = 1'b0;
if (!stg2_inc_req_r && !stg2_dec_req_r && po_rdy)
lim_nxt_state = STAGE2_TAP_CHK;
end
PRECH_REQUEST: begin
prech_req = 1'b1;
if (prech_done) begin
prech_req = 1'b0;
if (stg3_dec2init_val_r)
lim_nxt_state = LIMIT_DONE;
else
lim_nxt_state = WAIT_WR_REQ;
end
end
LIMIT_DONE: begin
done = 1'b1;
ktap_right = 1'b0;
stg3_dec2init_val = 1'b0;
lim_nxt_state = IDLE;
end
default: begin
lim_nxt_state = IDLE;
end
endcase
end
endmodule
|
module for complex oclkdelay calib
else if (oclkdelay_calib_done && !oclkdelay_calib_done_r && (BYPASS_COMPLEX_OCAL == "FALSE")) begin
done = 1'b0;
end
end
INIT: begin
ktap_right = 1'b1;
// Initial stage 2 increment to 63 for left limit
if (wait_cnt_done)
lim_nxt_state = STAGE2_TAP_CHK;
end
// Wait for DQS to toggle before asserting poc_ready
WAIT_WR_REQ: begin
write_request = 1'b1;
if (wait_cnt_done) begin
poc_ready = 1'b1;
lim_nxt_state = WAIT_POC_DONE;
end
end
// Wait for POC detect done signal
WAIT_POC_DONE: begin
if (poc2lim_detect_done) begin
write_request = 1'b0;
poc_ready = 1'b0;
lim_nxt_state = WAIT_STG3;
end
end
// Wait for DQS to stop toggling before stage3 inc/dec
WAIT_STG3: begin
if (wait_cnt_done) begin
if (stg3_dec_r) begin
// Check for Stage 3 underflow and MMCM tap limit
if ((stg3_tap_cnt > 'd0) && (mmcm_sub_dec < TDQSS_LIM_MMCM_TAPS))
lim_nxt_state = STAGE3_DEC;
else begin
stg3_dec = 1'b0;
stg3_inc2init_val = 1'b1;
lim_nxt_state = STAGE3_INC;
end
end else begin // Stage 3 being incremented
// Check for Stage 3 overflow and MMCM tap limit
if ((stg3_tap_cnt < 'd63) && (mmcm_sub_inc < TDQSS_LIM_MMCM_TAPS))
lim_nxt_state = STAGE3_INC;
else begin
stg3_dec2init_val = 1'b1;
lim_nxt_state = STAGE3_DEC;
end
end
end
end
STAGE3_INC: begin
stg3_inc_req = 1'b1;
lim_nxt_state = STG3_INCDEC_WAIT;
end
STAGE3_DEC: begin
stg3_dec_req = 1'b1;
lim_nxt_state = STG3_INCDEC_WAIT;
end
// Wait for stage3 inc/dec to complete (po_rdy)
STG3_INCDEC_WAIT: begin
stg3_dec_req = 1'b0;
stg3_inc_req = 1'b0;
if (!stg3_dec_req_r && !stg3_inc_req_r && po_rdy) begin
if (stg3_init_dec_r) begin
// Initial decrement of stage 3
if (stg3_tap_cnt > stg3_dec_val)
lim_nxt_state = STAGE3_DEC;
else begin
lim_nxt_state = WAIT_WR_REQ;
stg3_init_dec = 1'b0;
end
end else if (stg3_dec2init_val_r) begin
if (stg3_tap_cnt > stg3_init_val)
lim_nxt_state = STAGE3_DEC;
else
lim_nxt_state = STAGE2_TAP_CHK;
end else if (stg3_inc2init_val_r) begin
if (stg3_tap_cnt < stg3_inc_val)
lim_nxt_state = STAGE3_INC;
else
lim_nxt_state = STAGE2_TAP_CHK;
end else begin
lim_nxt_state = WAIT_WR_REQ;
end
end
end
// Check for overflow and underflow of stage2 taps
STAGE2_TAP_CHK: begin
if (stg3_dec2init_val_r) begin
// Increment stage 2 to write level tap value at the end of limit detection
if (stg2_tap_cnt < wl_po_fine_cnt)
lim_nxt_state = STAGE2_INC;
else begin
lim_nxt_state = PRECH_REQUEST;
end
end else if (stg3_inc2init_val_r) begin
// Decrement stage 2 to '0' to determine right limit
if (stg2_tap_cnt > 'd0)
lim_nxt_state = STAGE2_DEC;
else begin
lim_nxt_state = PRECH_REQUEST;
stg3_inc2init_val = 1'b0;
end
end else if (stg2_inc_r && (stg2_tap_cnt < 'd63)) begin
// Initial increment to 63
lim_nxt_state = STAGE2_INC;
end else begin
lim_nxt_state = STG3_INCDEC_WAIT;
stg2_inc = 1'b0;
end
end
STAGE2_INC: begin
stg2_inc_req = 1'b1;
lim_nxt_state = STG2_INCDEC_WAIT;
end
STAGE2_DEC: begin
stg2_dec_req = 1'b1;
lim_nxt_state = STG2_INCDEC_WAIT;
end
// Wait for stage3 inc/dec to complete (po_rdy)
STG2_INCDEC_WAIT: begin
stg2_inc_req = 1'b0;
stg2_dec_req = 1'b0;
if (!stg2_inc_req_r && !stg2_dec_req_r && po_rdy)
lim_nxt_state = STAGE2_TAP_CHK;
end
PRECH_REQUEST: begin
prech_req = 1'b1;
if (prech_done) begin
prech_req = 1'b0;
if (stg3_dec2init_val_r)
lim_nxt_state = LIMIT_DONE;
else
lim_nxt_state = WAIT_WR_REQ;
end
end
LIMIT_DONE: begin
done = 1'b1;
ktap_right = 1'b0;
stg3_dec2init_val = 1'b0;
lim_nxt_state = IDLE;
end
default: begin
lim_nxt_state = IDLE;
end
endcase
end
endmodule
|
module for complex oclkdelay calib
else if (oclkdelay_calib_done && !oclkdelay_calib_done_r && (BYPASS_COMPLEX_OCAL == "FALSE")) begin
done = 1'b0;
end
end
INIT: begin
ktap_right = 1'b1;
// Initial stage 2 increment to 63 for left limit
if (wait_cnt_done)
lim_nxt_state = STAGE2_TAP_CHK;
end
// Wait for DQS to toggle before asserting poc_ready
WAIT_WR_REQ: begin
write_request = 1'b1;
if (wait_cnt_done) begin
poc_ready = 1'b1;
lim_nxt_state = WAIT_POC_DONE;
end
end
// Wait for POC detect done signal
WAIT_POC_DONE: begin
if (poc2lim_detect_done) begin
write_request = 1'b0;
poc_ready = 1'b0;
lim_nxt_state = WAIT_STG3;
end
end
// Wait for DQS to stop toggling before stage3 inc/dec
WAIT_STG3: begin
if (wait_cnt_done) begin
if (stg3_dec_r) begin
// Check for Stage 3 underflow and MMCM tap limit
if ((stg3_tap_cnt > 'd0) && (mmcm_sub_dec < TDQSS_LIM_MMCM_TAPS))
lim_nxt_state = STAGE3_DEC;
else begin
stg3_dec = 1'b0;
stg3_inc2init_val = 1'b1;
lim_nxt_state = STAGE3_INC;
end
end else begin // Stage 3 being incremented
// Check for Stage 3 overflow and MMCM tap limit
if ((stg3_tap_cnt < 'd63) && (mmcm_sub_inc < TDQSS_LIM_MMCM_TAPS))
lim_nxt_state = STAGE3_INC;
else begin
stg3_dec2init_val = 1'b1;
lim_nxt_state = STAGE3_DEC;
end
end
end
end
STAGE3_INC: begin
stg3_inc_req = 1'b1;
lim_nxt_state = STG3_INCDEC_WAIT;
end
STAGE3_DEC: begin
stg3_dec_req = 1'b1;
lim_nxt_state = STG3_INCDEC_WAIT;
end
// Wait for stage3 inc/dec to complete (po_rdy)
STG3_INCDEC_WAIT: begin
stg3_dec_req = 1'b0;
stg3_inc_req = 1'b0;
if (!stg3_dec_req_r && !stg3_inc_req_r && po_rdy) begin
if (stg3_init_dec_r) begin
// Initial decrement of stage 3
if (stg3_tap_cnt > stg3_dec_val)
lim_nxt_state = STAGE3_DEC;
else begin
lim_nxt_state = WAIT_WR_REQ;
stg3_init_dec = 1'b0;
end
end else if (stg3_dec2init_val_r) begin
if (stg3_tap_cnt > stg3_init_val)
lim_nxt_state = STAGE3_DEC;
else
lim_nxt_state = STAGE2_TAP_CHK;
end else if (stg3_inc2init_val_r) begin
if (stg3_tap_cnt < stg3_inc_val)
lim_nxt_state = STAGE3_INC;
else
lim_nxt_state = STAGE2_TAP_CHK;
end else begin
lim_nxt_state = WAIT_WR_REQ;
end
end
end
// Check for overflow and underflow of stage2 taps
STAGE2_TAP_CHK: begin
if (stg3_dec2init_val_r) begin
// Increment stage 2 to write level tap value at the end of limit detection
if (stg2_tap_cnt < wl_po_fine_cnt)
lim_nxt_state = STAGE2_INC;
else begin
lim_nxt_state = PRECH_REQUEST;
end
end else if (stg3_inc2init_val_r) begin
// Decrement stage 2 to '0' to determine right limit
if (stg2_tap_cnt > 'd0)
lim_nxt_state = STAGE2_DEC;
else begin
lim_nxt_state = PRECH_REQUEST;
stg3_inc2init_val = 1'b0;
end
end else if (stg2_inc_r && (stg2_tap_cnt < 'd63)) begin
// Initial increment to 63
lim_nxt_state = STAGE2_INC;
end else begin
lim_nxt_state = STG3_INCDEC_WAIT;
stg2_inc = 1'b0;
end
end
STAGE2_INC: begin
stg2_inc_req = 1'b1;
lim_nxt_state = STG2_INCDEC_WAIT;
end
STAGE2_DEC: begin
stg2_dec_req = 1'b1;
lim_nxt_state = STG2_INCDEC_WAIT;
end
// Wait for stage3 inc/dec to complete (po_rdy)
STG2_INCDEC_WAIT: begin
stg2_inc_req = 1'b0;
stg2_dec_req = 1'b0;
if (!stg2_inc_req_r && !stg2_dec_req_r && po_rdy)
lim_nxt_state = STAGE2_TAP_CHK;
end
PRECH_REQUEST: begin
prech_req = 1'b1;
if (prech_done) begin
prech_req = 1'b0;
if (stg3_dec2init_val_r)
lim_nxt_state = LIMIT_DONE;
else
lim_nxt_state = WAIT_WR_REQ;
end
end
LIMIT_DONE: begin
done = 1'b1;
ktap_right = 1'b0;
stg3_dec2init_val = 1'b0;
lim_nxt_state = IDLE;
end
default: begin
lim_nxt_state = IDLE;
end
endcase
end
endmodule
|
module dram (
// Inouts
inout [63:0] ddr3_dq,
inout [7:0] ddr3_dqs_n,
inout [7:0] ddr3_dqs_p,
// Outputs
output [15:0] ddr3_addr,
output [2:0] ddr3_ba,
output ddr3_ras_n,
output ddr3_cas_n,
output ddr3_we_n,
output ddr3_reset_n,
output [0:0] ddr3_ck_p,
output [0:0] ddr3_ck_n,
output [0:0] ddr3_cke,
output [0:0] ddr3_cs_n,
output [7:0] ddr3_dm,
output [0:0] ddr3_odt,
// Inputs
// Differential system clocks
input sys_clk_p,
input sys_clk_n,
// user interface signals
input [29:0] app_addr,
input [2:0] app_cmd,
input app_en,
input [511:0] app_wdf_data,
input app_wdf_end,
input [63:0] app_wdf_mask,
input app_wdf_wren,
output [511:0] app_rd_data,
output app_rd_data_end,
output app_rd_data_valid,
output app_rdy,
output app_wdf_rdy,
input app_sr_req,
input app_ref_req,
input app_zq_req,
output app_sr_active,
output app_ref_ack,
output app_zq_ack,
output ui_clk,
output ui_clk_sync_rst,
output init_calib_complete,
input sys_rst
);
// Start of IP top instance
dram_mig u_dram_mig (
// Memory interface ports
.ddr3_addr (ddr3_addr),
.ddr3_ba (ddr3_ba),
.ddr3_cas_n (ddr3_cas_n),
.ddr3_ck_n (ddr3_ck_n),
.ddr3_ck_p (ddr3_ck_p),
.ddr3_cke (ddr3_cke),
.ddr3_ras_n (ddr3_ras_n),
.ddr3_reset_n (ddr3_reset_n),
.ddr3_we_n (ddr3_we_n),
.ddr3_dq (ddr3_dq),
.ddr3_dqs_n (ddr3_dqs_n),
.ddr3_dqs_p (ddr3_dqs_p),
.init_calib_complete (init_calib_complete),
.ddr3_cs_n (ddr3_cs_n),
.ddr3_dm (ddr3_dm),
.ddr3_odt (ddr3_odt),
// Application interface ports
.app_addr (app_addr),
.app_cmd (app_cmd),
.app_en (app_en),
.app_wdf_data (app_wdf_data),
.app_wdf_end (app_wdf_end),
.app_wdf_wren (app_wdf_wren),
.app_rd_data (app_rd_data),
.app_rd_data_end (app_rd_data_end),
.app_rd_data_valid (app_rd_data_valid),
.app_rdy (app_rdy),
.app_wdf_rdy (app_wdf_rdy),
.app_sr_req (app_sr_req),
.app_ref_req (app_ref_req),
.app_zq_req (app_zq_req),
.app_sr_active (app_sr_active),
.app_ref_ack (app_ref_ack),
.app_zq_ack (app_zq_ack),
.ui_clk (ui_clk),
.ui_clk_sync_rst (ui_clk_sync_rst),
.app_wdf_mask (app_wdf_mask),
// System Clock Ports
.sys_clk_p (sys_clk_p),
.sys_clk_n (sys_clk_n),
.sys_rst (sys_rst)
);
// End of IP top instance
endmodule
|
module dram (
// Inouts
inout [63:0] ddr3_dq,
inout [7:0] ddr3_dqs_n,
inout [7:0] ddr3_dqs_p,
// Outputs
output [15:0] ddr3_addr,
output [2:0] ddr3_ba,
output ddr3_ras_n,
output ddr3_cas_n,
output ddr3_we_n,
output ddr3_reset_n,
output [0:0] ddr3_ck_p,
output [0:0] ddr3_ck_n,
output [0:0] ddr3_cke,
output [0:0] ddr3_cs_n,
output [7:0] ddr3_dm,
output [0:0] ddr3_odt,
// Inputs
// Differential system clocks
input sys_clk_p,
input sys_clk_n,
// user interface signals
input [29:0] app_addr,
input [2:0] app_cmd,
input app_en,
input [511:0] app_wdf_data,
input app_wdf_end,
input [63:0] app_wdf_mask,
input app_wdf_wren,
output [511:0] app_rd_data,
output app_rd_data_end,
output app_rd_data_valid,
output app_rdy,
output app_wdf_rdy,
input app_sr_req,
input app_ref_req,
input app_zq_req,
output app_sr_active,
output app_ref_ack,
output app_zq_ack,
output ui_clk,
output ui_clk_sync_rst,
output init_calib_complete,
input sys_rst
);
// Start of IP top instance
dram_mig u_dram_mig (
// Memory interface ports
.ddr3_addr (ddr3_addr),
.ddr3_ba (ddr3_ba),
.ddr3_cas_n (ddr3_cas_n),
.ddr3_ck_n (ddr3_ck_n),
.ddr3_ck_p (ddr3_ck_p),
.ddr3_cke (ddr3_cke),
.ddr3_ras_n (ddr3_ras_n),
.ddr3_reset_n (ddr3_reset_n),
.ddr3_we_n (ddr3_we_n),
.ddr3_dq (ddr3_dq),
.ddr3_dqs_n (ddr3_dqs_n),
.ddr3_dqs_p (ddr3_dqs_p),
.init_calib_complete (init_calib_complete),
.ddr3_cs_n (ddr3_cs_n),
.ddr3_dm (ddr3_dm),
.ddr3_odt (ddr3_odt),
// Application interface ports
.app_addr (app_addr),
.app_cmd (app_cmd),
.app_en (app_en),
.app_wdf_data (app_wdf_data),
.app_wdf_end (app_wdf_end),
.app_wdf_wren (app_wdf_wren),
.app_rd_data (app_rd_data),
.app_rd_data_end (app_rd_data_end),
.app_rd_data_valid (app_rd_data_valid),
.app_rdy (app_rdy),
.app_wdf_rdy (app_wdf_rdy),
.app_sr_req (app_sr_req),
.app_ref_req (app_ref_req),
.app_zq_req (app_zq_req),
.app_sr_active (app_sr_active),
.app_ref_ack (app_ref_ack),
.app_zq_ack (app_zq_ack),
.ui_clk (ui_clk),
.ui_clk_sync_rst (ui_clk_sync_rst),
.app_wdf_mask (app_wdf_mask),
// System Clock Ports
.sys_clk_p (sys_clk_p),
.sys_clk_n (sys_clk_n),
.sys_rst (sys_rst)
);
// End of IP top instance
endmodule
|
module dram (
// Inouts
inout [63:0] ddr3_dq,
inout [7:0] ddr3_dqs_n,
inout [7:0] ddr3_dqs_p,
// Outputs
output [15:0] ddr3_addr,
output [2:0] ddr3_ba,
output ddr3_ras_n,
output ddr3_cas_n,
output ddr3_we_n,
output ddr3_reset_n,
output [0:0] ddr3_ck_p,
output [0:0] ddr3_ck_n,
output [0:0] ddr3_cke,
output [0:0] ddr3_cs_n,
output [7:0] ddr3_dm,
output [0:0] ddr3_odt,
// Inputs
// Differential system clocks
input sys_clk_p,
input sys_clk_n,
// user interface signals
input [29:0] app_addr,
input [2:0] app_cmd,
input app_en,
input [511:0] app_wdf_data,
input app_wdf_end,
input [63:0] app_wdf_mask,
input app_wdf_wren,
output [511:0] app_rd_data,
output app_rd_data_end,
output app_rd_data_valid,
output app_rdy,
output app_wdf_rdy,
input app_sr_req,
input app_ref_req,
input app_zq_req,
output app_sr_active,
output app_ref_ack,
output app_zq_ack,
output ui_clk,
output ui_clk_sync_rst,
output init_calib_complete,
input sys_rst
);
// Start of IP top instance
dram_mig u_dram_mig (
// Memory interface ports
.ddr3_addr (ddr3_addr),
.ddr3_ba (ddr3_ba),
.ddr3_cas_n (ddr3_cas_n),
.ddr3_ck_n (ddr3_ck_n),
.ddr3_ck_p (ddr3_ck_p),
.ddr3_cke (ddr3_cke),
.ddr3_ras_n (ddr3_ras_n),
.ddr3_reset_n (ddr3_reset_n),
.ddr3_we_n (ddr3_we_n),
.ddr3_dq (ddr3_dq),
.ddr3_dqs_n (ddr3_dqs_n),
.ddr3_dqs_p (ddr3_dqs_p),
.init_calib_complete (init_calib_complete),
.ddr3_cs_n (ddr3_cs_n),
.ddr3_dm (ddr3_dm),
.ddr3_odt (ddr3_odt),
// Application interface ports
.app_addr (app_addr),
.app_cmd (app_cmd),
.app_en (app_en),
.app_wdf_data (app_wdf_data),
.app_wdf_end (app_wdf_end),
.app_wdf_wren (app_wdf_wren),
.app_rd_data (app_rd_data),
.app_rd_data_end (app_rd_data_end),
.app_rd_data_valid (app_rd_data_valid),
.app_rdy (app_rdy),
.app_wdf_rdy (app_wdf_rdy),
.app_sr_req (app_sr_req),
.app_ref_req (app_ref_req),
.app_zq_req (app_zq_req),
.app_sr_active (app_sr_active),
.app_ref_ack (app_ref_ack),
.app_zq_ack (app_zq_ack),
.ui_clk (ui_clk),
.ui_clk_sync_rst (ui_clk_sync_rst),
.app_wdf_mask (app_wdf_mask),
// System Clock Ports
.sys_clk_p (sys_clk_p),
.sys_clk_n (sys_clk_n),
.sys_rst (sys_rst)
);
// End of IP top instance
endmodule
|
module mig_7series_v2_3_ddr_phy_ck_addr_cmd_delay #
(
parameter TCQ = 100,
parameter tCK = 3636,
parameter DQS_CNT_WIDTH = 3,
parameter N_CTL_LANES = 3,
parameter SIM_CAL_OPTION = "NONE"
)
(
input clk,
input rst,
// Start only after PO_CIRC_BUF_DELAY decremented
input cmd_delay_start,
// Control lane being shifted using Phaser_Out fine delay taps
output reg [N_CTL_LANES-1:0] ctl_lane_cnt,
// Inc/dec Phaser_Out fine delay line
output reg po_stg2_f_incdec,
output reg po_en_stg2_f,
output reg po_stg2_c_incdec,
output reg po_en_stg2_c,
// Completed delaying CK/Address/Commands/Controls
output po_ck_addr_cmd_delay_done
);
localparam TAP_CNT_LIMIT = 63;
//Calculate the tap resolution of the PHASER based on the clock period
localparam FREQ_REF_DIV = (tCK > 5000 ? 4 :
tCK > 2500 ? 2 : 1);
localparam integer PHASER_TAP_RES = ((tCK/2)/64);
// Determine whether 300 ps or 350 ps delay required
localparam CALC_TAP_CNT = (tCK >= 1250) ? 350 : 300;
// Determine the number of Phaser_Out taps required to delay by 300 ps
// 300 ps is the PCB trace uncertainty between CK and DQS byte groups
// Increment control byte lanes
localparam TAP_CNT = 0;
//localparam TAP_CNT = (CALC_TAP_CNT + PHASER_TAP_RES - 1)/PHASER_TAP_RES;
//Decrement control byte lanes
localparam TAP_DEC = (SIM_CAL_OPTION == "FAST_CAL") ? 0 : 29;
reg delay_dec_done;
reg delay_done_r1;
reg delay_done_r2;
reg delay_done_r3;
reg delay_done_r4 /* synthesis syn_maxfan = 10 */;
reg [5:0] delay_cnt_r;
reg [5:0] delaydec_cnt_r;
reg po_cnt_inc;
reg po_cnt_dec;
reg [3:0] wait_cnt_r;
assign po_ck_addr_cmd_delay_done = ((TAP_CNT == 0) && (TAP_DEC == 0)) ? 1'b1 : delay_done_r4;
always @(posedge clk) begin
if (rst || po_cnt_dec || po_cnt_inc)
wait_cnt_r <= #TCQ 'd8;
else if (cmd_delay_start && (wait_cnt_r > 'd0))
wait_cnt_r <= #TCQ wait_cnt_r - 1;
end
always @(posedge clk) begin
if (rst || (delaydec_cnt_r > 6'd0) || (delay_cnt_r == 'd0) || (TAP_DEC == 0))
po_cnt_inc <= #TCQ 1'b0;
else if ((delay_cnt_r > 'd0) && (wait_cnt_r == 'd1))
po_cnt_inc <= #TCQ 1'b1;
else
po_cnt_inc <= #TCQ 1'b0;
end
//Tap decrement
always @(posedge clk) begin
if (rst || (delaydec_cnt_r == 'd0))
po_cnt_dec <= #TCQ 1'b0;
else if (cmd_delay_start && (delaydec_cnt_r > 'd0) && (wait_cnt_r == 'd1))
po_cnt_dec <= #TCQ 1'b1;
else
po_cnt_dec <= #TCQ 1'b0;
end
//po_stg2_f_incdec and po_en_stg2_f stay asserted HIGH for TAP_COUNT cycles for every control byte lane
//the alignment is started once the
always @(posedge clk) begin
if (rst) begin
po_stg2_f_incdec <= #TCQ 1'b0;
po_en_stg2_f <= #TCQ 1'b0;
po_stg2_c_incdec <= #TCQ 1'b0;
po_en_stg2_c <= #TCQ 1'b0;
end else begin
if (po_cnt_dec) begin
po_stg2_f_incdec <= #TCQ 1'b0;
po_en_stg2_f <= #TCQ 1'b1;
end else begin
po_stg2_f_incdec <= #TCQ 1'b0;
po_en_stg2_f <= #TCQ 1'b0;
end
if (po_cnt_inc) begin
po_stg2_c_incdec <= #TCQ 1'b1;
po_en_stg2_c <= #TCQ 1'b1;
end else begin
po_stg2_c_incdec <= #TCQ 1'b0;
po_en_stg2_c <= #TCQ 1'b0;
end
end
end
// delay counter to count 2 cycles
// Increment coarse taps by 2 for all control byte lanes
// to mitigate late writes
always @(posedge clk) begin
// load delay counter with init value
if (rst || (tCK > 2500) || (SIM_CAL_OPTION == "FAST_CAL"))
delay_cnt_r <= #TCQ 'd0;
else if ((delaydec_cnt_r > 6'd0) ||((delay_cnt_r == 6'd0) && (ctl_lane_cnt != N_CTL_LANES-1)))
delay_cnt_r <= #TCQ 'd1;
else if (po_cnt_inc && (delay_cnt_r > 6'd0))
delay_cnt_r <= #TCQ delay_cnt_r - 1;
end
// delay counter to count TAP_DEC cycles
always @(posedge clk) begin
// load delay counter with init value of TAP_DEC
if (rst || ~cmd_delay_start ||((delaydec_cnt_r == 6'd0) && (delay_cnt_r == 6'd0) && (ctl_lane_cnt != N_CTL_LANES-1)))
delaydec_cnt_r <= #TCQ TAP_DEC;
else if (po_cnt_dec && (delaydec_cnt_r > 6'd0))
delaydec_cnt_r <= #TCQ delaydec_cnt_r - 1;
end
//ctl_lane_cnt is used to count the number of CTL_LANES or byte lanes that have the address/command phase shifted by 1/4 mem. cycle
//This ensures all ctrl byte lanes have had their output phase shifted.
always @(posedge clk) begin
if (rst || ~cmd_delay_start )
ctl_lane_cnt <= #TCQ 6'b0;
else if (~delay_dec_done && (ctl_lane_cnt == N_CTL_LANES-1) && (delaydec_cnt_r == 6'd1))
ctl_lane_cnt <= #TCQ ctl_lane_cnt;
else if ((ctl_lane_cnt != N_CTL_LANES-1) && (delaydec_cnt_r == 6'd0) && (delay_cnt_r == 'd0))
ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1;
end
// All control lanes have decremented to 31 fine taps from 46
always @(posedge clk) begin
if (rst || ~cmd_delay_start) begin
delay_dec_done <= #TCQ 1'b0;
end else if (((TAP_CNT == 0) && (TAP_DEC == 0)) ||
((delaydec_cnt_r == 6'd0) && (delay_cnt_r == 'd0) && (ctl_lane_cnt == N_CTL_LANES-1))) begin
delay_dec_done <= #TCQ 1'b1;
end
end
always @(posedge clk) begin
delay_done_r1 <= #TCQ delay_dec_done;
delay_done_r2 <= #TCQ delay_done_r1;
delay_done_r3 <= #TCQ delay_done_r2;
delay_done_r4 <= #TCQ delay_done_r3;
end
endmodule
|
module mig_7series_v2_3_ddr_phy_ck_addr_cmd_delay #
(
parameter TCQ = 100,
parameter tCK = 3636,
parameter DQS_CNT_WIDTH = 3,
parameter N_CTL_LANES = 3,
parameter SIM_CAL_OPTION = "NONE"
)
(
input clk,
input rst,
// Start only after PO_CIRC_BUF_DELAY decremented
input cmd_delay_start,
// Control lane being shifted using Phaser_Out fine delay taps
output reg [N_CTL_LANES-1:0] ctl_lane_cnt,
// Inc/dec Phaser_Out fine delay line
output reg po_stg2_f_incdec,
output reg po_en_stg2_f,
output reg po_stg2_c_incdec,
output reg po_en_stg2_c,
// Completed delaying CK/Address/Commands/Controls
output po_ck_addr_cmd_delay_done
);
localparam TAP_CNT_LIMIT = 63;
//Calculate the tap resolution of the PHASER based on the clock period
localparam FREQ_REF_DIV = (tCK > 5000 ? 4 :
tCK > 2500 ? 2 : 1);
localparam integer PHASER_TAP_RES = ((tCK/2)/64);
// Determine whether 300 ps or 350 ps delay required
localparam CALC_TAP_CNT = (tCK >= 1250) ? 350 : 300;
// Determine the number of Phaser_Out taps required to delay by 300 ps
// 300 ps is the PCB trace uncertainty between CK and DQS byte groups
// Increment control byte lanes
localparam TAP_CNT = 0;
//localparam TAP_CNT = (CALC_TAP_CNT + PHASER_TAP_RES - 1)/PHASER_TAP_RES;
//Decrement control byte lanes
localparam TAP_DEC = (SIM_CAL_OPTION == "FAST_CAL") ? 0 : 29;
reg delay_dec_done;
reg delay_done_r1;
reg delay_done_r2;
reg delay_done_r3;
reg delay_done_r4 /* synthesis syn_maxfan = 10 */;
reg [5:0] delay_cnt_r;
reg [5:0] delaydec_cnt_r;
reg po_cnt_inc;
reg po_cnt_dec;
reg [3:0] wait_cnt_r;
assign po_ck_addr_cmd_delay_done = ((TAP_CNT == 0) && (TAP_DEC == 0)) ? 1'b1 : delay_done_r4;
always @(posedge clk) begin
if (rst || po_cnt_dec || po_cnt_inc)
wait_cnt_r <= #TCQ 'd8;
else if (cmd_delay_start && (wait_cnt_r > 'd0))
wait_cnt_r <= #TCQ wait_cnt_r - 1;
end
always @(posedge clk) begin
if (rst || (delaydec_cnt_r > 6'd0) || (delay_cnt_r == 'd0) || (TAP_DEC == 0))
po_cnt_inc <= #TCQ 1'b0;
else if ((delay_cnt_r > 'd0) && (wait_cnt_r == 'd1))
po_cnt_inc <= #TCQ 1'b1;
else
po_cnt_inc <= #TCQ 1'b0;
end
//Tap decrement
always @(posedge clk) begin
if (rst || (delaydec_cnt_r == 'd0))
po_cnt_dec <= #TCQ 1'b0;
else if (cmd_delay_start && (delaydec_cnt_r > 'd0) && (wait_cnt_r == 'd1))
po_cnt_dec <= #TCQ 1'b1;
else
po_cnt_dec <= #TCQ 1'b0;
end
//po_stg2_f_incdec and po_en_stg2_f stay asserted HIGH for TAP_COUNT cycles for every control byte lane
//the alignment is started once the
always @(posedge clk) begin
if (rst) begin
po_stg2_f_incdec <= #TCQ 1'b0;
po_en_stg2_f <= #TCQ 1'b0;
po_stg2_c_incdec <= #TCQ 1'b0;
po_en_stg2_c <= #TCQ 1'b0;
end else begin
if (po_cnt_dec) begin
po_stg2_f_incdec <= #TCQ 1'b0;
po_en_stg2_f <= #TCQ 1'b1;
end else begin
po_stg2_f_incdec <= #TCQ 1'b0;
po_en_stg2_f <= #TCQ 1'b0;
end
if (po_cnt_inc) begin
po_stg2_c_incdec <= #TCQ 1'b1;
po_en_stg2_c <= #TCQ 1'b1;
end else begin
po_stg2_c_incdec <= #TCQ 1'b0;
po_en_stg2_c <= #TCQ 1'b0;
end
end
end
// delay counter to count 2 cycles
// Increment coarse taps by 2 for all control byte lanes
// to mitigate late writes
always @(posedge clk) begin
// load delay counter with init value
if (rst || (tCK > 2500) || (SIM_CAL_OPTION == "FAST_CAL"))
delay_cnt_r <= #TCQ 'd0;
else if ((delaydec_cnt_r > 6'd0) ||((delay_cnt_r == 6'd0) && (ctl_lane_cnt != N_CTL_LANES-1)))
delay_cnt_r <= #TCQ 'd1;
else if (po_cnt_inc && (delay_cnt_r > 6'd0))
delay_cnt_r <= #TCQ delay_cnt_r - 1;
end
// delay counter to count TAP_DEC cycles
always @(posedge clk) begin
// load delay counter with init value of TAP_DEC
if (rst || ~cmd_delay_start ||((delaydec_cnt_r == 6'd0) && (delay_cnt_r == 6'd0) && (ctl_lane_cnt != N_CTL_LANES-1)))
delaydec_cnt_r <= #TCQ TAP_DEC;
else if (po_cnt_dec && (delaydec_cnt_r > 6'd0))
delaydec_cnt_r <= #TCQ delaydec_cnt_r - 1;
end
//ctl_lane_cnt is used to count the number of CTL_LANES or byte lanes that have the address/command phase shifted by 1/4 mem. cycle
//This ensures all ctrl byte lanes have had their output phase shifted.
always @(posedge clk) begin
if (rst || ~cmd_delay_start )
ctl_lane_cnt <= #TCQ 6'b0;
else if (~delay_dec_done && (ctl_lane_cnt == N_CTL_LANES-1) && (delaydec_cnt_r == 6'd1))
ctl_lane_cnt <= #TCQ ctl_lane_cnt;
else if ((ctl_lane_cnt != N_CTL_LANES-1) && (delaydec_cnt_r == 6'd0) && (delay_cnt_r == 'd0))
ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1;
end
// All control lanes have decremented to 31 fine taps from 46
always @(posedge clk) begin
if (rst || ~cmd_delay_start) begin
delay_dec_done <= #TCQ 1'b0;
end else if (((TAP_CNT == 0) && (TAP_DEC == 0)) ||
((delaydec_cnt_r == 6'd0) && (delay_cnt_r == 'd0) && (ctl_lane_cnt == N_CTL_LANES-1))) begin
delay_dec_done <= #TCQ 1'b1;
end
end
always @(posedge clk) begin
delay_done_r1 <= #TCQ delay_dec_done;
delay_done_r2 <= #TCQ delay_done_r1;
delay_done_r3 <= #TCQ delay_done_r2;
delay_done_r4 <= #TCQ delay_done_r3;
end
endmodule
|
module mig_7series_v2_3_ddr_phy_ck_addr_cmd_delay #
(
parameter TCQ = 100,
parameter tCK = 3636,
parameter DQS_CNT_WIDTH = 3,
parameter N_CTL_LANES = 3,
parameter SIM_CAL_OPTION = "NONE"
)
(
input clk,
input rst,
// Start only after PO_CIRC_BUF_DELAY decremented
input cmd_delay_start,
// Control lane being shifted using Phaser_Out fine delay taps
output reg [N_CTL_LANES-1:0] ctl_lane_cnt,
// Inc/dec Phaser_Out fine delay line
output reg po_stg2_f_incdec,
output reg po_en_stg2_f,
output reg po_stg2_c_incdec,
output reg po_en_stg2_c,
// Completed delaying CK/Address/Commands/Controls
output po_ck_addr_cmd_delay_done
);
localparam TAP_CNT_LIMIT = 63;
//Calculate the tap resolution of the PHASER based on the clock period
localparam FREQ_REF_DIV = (tCK > 5000 ? 4 :
tCK > 2500 ? 2 : 1);
localparam integer PHASER_TAP_RES = ((tCK/2)/64);
// Determine whether 300 ps or 350 ps delay required
localparam CALC_TAP_CNT = (tCK >= 1250) ? 350 : 300;
// Determine the number of Phaser_Out taps required to delay by 300 ps
// 300 ps is the PCB trace uncertainty between CK and DQS byte groups
// Increment control byte lanes
localparam TAP_CNT = 0;
//localparam TAP_CNT = (CALC_TAP_CNT + PHASER_TAP_RES - 1)/PHASER_TAP_RES;
//Decrement control byte lanes
localparam TAP_DEC = (SIM_CAL_OPTION == "FAST_CAL") ? 0 : 29;
reg delay_dec_done;
reg delay_done_r1;
reg delay_done_r2;
reg delay_done_r3;
reg delay_done_r4 /* synthesis syn_maxfan = 10 */;
reg [5:0] delay_cnt_r;
reg [5:0] delaydec_cnt_r;
reg po_cnt_inc;
reg po_cnt_dec;
reg [3:0] wait_cnt_r;
assign po_ck_addr_cmd_delay_done = ((TAP_CNT == 0) && (TAP_DEC == 0)) ? 1'b1 : delay_done_r4;
always @(posedge clk) begin
if (rst || po_cnt_dec || po_cnt_inc)
wait_cnt_r <= #TCQ 'd8;
else if (cmd_delay_start && (wait_cnt_r > 'd0))
wait_cnt_r <= #TCQ wait_cnt_r - 1;
end
always @(posedge clk) begin
if (rst || (delaydec_cnt_r > 6'd0) || (delay_cnt_r == 'd0) || (TAP_DEC == 0))
po_cnt_inc <= #TCQ 1'b0;
else if ((delay_cnt_r > 'd0) && (wait_cnt_r == 'd1))
po_cnt_inc <= #TCQ 1'b1;
else
po_cnt_inc <= #TCQ 1'b0;
end
//Tap decrement
always @(posedge clk) begin
if (rst || (delaydec_cnt_r == 'd0))
po_cnt_dec <= #TCQ 1'b0;
else if (cmd_delay_start && (delaydec_cnt_r > 'd0) && (wait_cnt_r == 'd1))
po_cnt_dec <= #TCQ 1'b1;
else
po_cnt_dec <= #TCQ 1'b0;
end
//po_stg2_f_incdec and po_en_stg2_f stay asserted HIGH for TAP_COUNT cycles for every control byte lane
//the alignment is started once the
always @(posedge clk) begin
if (rst) begin
po_stg2_f_incdec <= #TCQ 1'b0;
po_en_stg2_f <= #TCQ 1'b0;
po_stg2_c_incdec <= #TCQ 1'b0;
po_en_stg2_c <= #TCQ 1'b0;
end else begin
if (po_cnt_dec) begin
po_stg2_f_incdec <= #TCQ 1'b0;
po_en_stg2_f <= #TCQ 1'b1;
end else begin
po_stg2_f_incdec <= #TCQ 1'b0;
po_en_stg2_f <= #TCQ 1'b0;
end
if (po_cnt_inc) begin
po_stg2_c_incdec <= #TCQ 1'b1;
po_en_stg2_c <= #TCQ 1'b1;
end else begin
po_stg2_c_incdec <= #TCQ 1'b0;
po_en_stg2_c <= #TCQ 1'b0;
end
end
end
// delay counter to count 2 cycles
// Increment coarse taps by 2 for all control byte lanes
// to mitigate late writes
always @(posedge clk) begin
// load delay counter with init value
if (rst || (tCK > 2500) || (SIM_CAL_OPTION == "FAST_CAL"))
delay_cnt_r <= #TCQ 'd0;
else if ((delaydec_cnt_r > 6'd0) ||((delay_cnt_r == 6'd0) && (ctl_lane_cnt != N_CTL_LANES-1)))
delay_cnt_r <= #TCQ 'd1;
else if (po_cnt_inc && (delay_cnt_r > 6'd0))
delay_cnt_r <= #TCQ delay_cnt_r - 1;
end
// delay counter to count TAP_DEC cycles
always @(posedge clk) begin
// load delay counter with init value of TAP_DEC
if (rst || ~cmd_delay_start ||((delaydec_cnt_r == 6'd0) && (delay_cnt_r == 6'd0) && (ctl_lane_cnt != N_CTL_LANES-1)))
delaydec_cnt_r <= #TCQ TAP_DEC;
else if (po_cnt_dec && (delaydec_cnt_r > 6'd0))
delaydec_cnt_r <= #TCQ delaydec_cnt_r - 1;
end
//ctl_lane_cnt is used to count the number of CTL_LANES or byte lanes that have the address/command phase shifted by 1/4 mem. cycle
//This ensures all ctrl byte lanes have had their output phase shifted.
always @(posedge clk) begin
if (rst || ~cmd_delay_start )
ctl_lane_cnt <= #TCQ 6'b0;
else if (~delay_dec_done && (ctl_lane_cnt == N_CTL_LANES-1) && (delaydec_cnt_r == 6'd1))
ctl_lane_cnt <= #TCQ ctl_lane_cnt;
else if ((ctl_lane_cnt != N_CTL_LANES-1) && (delaydec_cnt_r == 6'd0) && (delay_cnt_r == 'd0))
ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1;
end
// All control lanes have decremented to 31 fine taps from 46
always @(posedge clk) begin
if (rst || ~cmd_delay_start) begin
delay_dec_done <= #TCQ 1'b0;
end else if (((TAP_CNT == 0) && (TAP_DEC == 0)) ||
((delaydec_cnt_r == 6'd0) && (delay_cnt_r == 'd0) && (ctl_lane_cnt == N_CTL_LANES-1))) begin
delay_dec_done <= #TCQ 1'b1;
end
end
always @(posedge clk) begin
delay_done_r1 <= #TCQ delay_dec_done;
delay_done_r2 <= #TCQ delay_done_r1;
delay_done_r3 <= #TCQ delay_done_r2;
delay_done_r4 <= #TCQ delay_done_r3;
end
endmodule
|
module mig_7series_v2_3_ecc_merge_enc
#(
parameter TCQ = 100,
parameter PAYLOAD_WIDTH = 64,
parameter CODE_WIDTH = 72,
parameter DATA_BUF_ADDR_WIDTH = 4,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DATA_WIDTH = 64,
parameter DQ_WIDTH = 72,
parameter ECC_WIDTH = 8,
parameter nCK_PER_CLK = 4
)
(
/*AUTOARG*/
// Outputs
mc_wrdata, mc_wrdata_mask,
// Inputs
clk, rst, wr_data, wr_data_mask, rd_merge_data, h_rows, raw_not_ecc
);
input clk;
input rst;
input [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data;
input [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask;
input [2*nCK_PER_CLK*DATA_WIDTH-1:0] rd_merge_data;
reg [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data_r;
reg [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask_r;
reg [2*nCK_PER_CLK*DATA_WIDTH-1:0] rd_merge_data_r;
always @(posedge clk) wr_data_r <= #TCQ wr_data;
always @(posedge clk) wr_data_mask_r <= #TCQ wr_data_mask;
always @(posedge clk) rd_merge_data_r <= #TCQ rd_merge_data;
// Merge new data with memory read data.
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] merged_data;
genvar h;
genvar i;
generate
for (h=0; h<2*nCK_PER_CLK; h=h+1) begin : merge_data_outer
for (i=0; i<DATA_WIDTH/8; i=i+1) begin : merge_data_inner
assign merged_data[h*PAYLOAD_WIDTH+i*8+:8] =
wr_data_mask[h*DATA_WIDTH/8+i]
? rd_merge_data[h*DATA_WIDTH+i*8+:8]
: wr_data[h*PAYLOAD_WIDTH+i*8+:8];
end
if (PAYLOAD_WIDTH > DATA_WIDTH)
assign merged_data[(h+1)*PAYLOAD_WIDTH-1-:PAYLOAD_WIDTH-DATA_WIDTH]=
wr_data[(h+1)*PAYLOAD_WIDTH-1-:PAYLOAD_WIDTH-DATA_WIDTH];
end
endgenerate
// Generate ECC and overlay onto mc_wrdata.
input [CODE_WIDTH*ECC_WIDTH-1:0] h_rows;
input [2*nCK_PER_CLK-1:0] raw_not_ecc;
reg [2*nCK_PER_CLK-1:0] raw_not_ecc_r;
always @(posedge clk) raw_not_ecc_r <= #TCQ raw_not_ecc;
output reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata;
reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata_c;
genvar j;
integer k;
generate
for (j=0; j<2*nCK_PER_CLK; j=j+1) begin : ecc_word
always @(/*AS*/h_rows or merged_data or raw_not_ecc_r) begin
mc_wrdata_c[j*DQ_WIDTH+:DQ_WIDTH] =
{{DQ_WIDTH-PAYLOAD_WIDTH{1'b0}},
merged_data[j*PAYLOAD_WIDTH+:PAYLOAD_WIDTH]};
for (k=0; k<ECC_WIDTH; k=k+1)
if (~raw_not_ecc_r[j])
mc_wrdata_c[j*DQ_WIDTH+CODE_WIDTH-k-1] =
^(merged_data[j*PAYLOAD_WIDTH+:DATA_WIDTH] &
h_rows[k*CODE_WIDTH+:DATA_WIDTH]);
end
end
endgenerate
always @(posedge clk) mc_wrdata <= mc_wrdata_c;
// Set all DRAM masks to zero.
output wire[2*nCK_PER_CLK*DQ_WIDTH/8-1:0] mc_wrdata_mask;
assign mc_wrdata_mask = {2*nCK_PER_CLK*DQ_WIDTH/8{1'b0}};
endmodule
|
module mig_7series_v2_3_ecc_merge_enc
#(
parameter TCQ = 100,
parameter PAYLOAD_WIDTH = 64,
parameter CODE_WIDTH = 72,
parameter DATA_BUF_ADDR_WIDTH = 4,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DATA_WIDTH = 64,
parameter DQ_WIDTH = 72,
parameter ECC_WIDTH = 8,
parameter nCK_PER_CLK = 4
)
(
/*AUTOARG*/
// Outputs
mc_wrdata, mc_wrdata_mask,
// Inputs
clk, rst, wr_data, wr_data_mask, rd_merge_data, h_rows, raw_not_ecc
);
input clk;
input rst;
input [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data;
input [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask;
input [2*nCK_PER_CLK*DATA_WIDTH-1:0] rd_merge_data;
reg [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data_r;
reg [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask_r;
reg [2*nCK_PER_CLK*DATA_WIDTH-1:0] rd_merge_data_r;
always @(posedge clk) wr_data_r <= #TCQ wr_data;
always @(posedge clk) wr_data_mask_r <= #TCQ wr_data_mask;
always @(posedge clk) rd_merge_data_r <= #TCQ rd_merge_data;
// Merge new data with memory read data.
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] merged_data;
genvar h;
genvar i;
generate
for (h=0; h<2*nCK_PER_CLK; h=h+1) begin : merge_data_outer
for (i=0; i<DATA_WIDTH/8; i=i+1) begin : merge_data_inner
assign merged_data[h*PAYLOAD_WIDTH+i*8+:8] =
wr_data_mask[h*DATA_WIDTH/8+i]
? rd_merge_data[h*DATA_WIDTH+i*8+:8]
: wr_data[h*PAYLOAD_WIDTH+i*8+:8];
end
if (PAYLOAD_WIDTH > DATA_WIDTH)
assign merged_data[(h+1)*PAYLOAD_WIDTH-1-:PAYLOAD_WIDTH-DATA_WIDTH]=
wr_data[(h+1)*PAYLOAD_WIDTH-1-:PAYLOAD_WIDTH-DATA_WIDTH];
end
endgenerate
// Generate ECC and overlay onto mc_wrdata.
input [CODE_WIDTH*ECC_WIDTH-1:0] h_rows;
input [2*nCK_PER_CLK-1:0] raw_not_ecc;
reg [2*nCK_PER_CLK-1:0] raw_not_ecc_r;
always @(posedge clk) raw_not_ecc_r <= #TCQ raw_not_ecc;
output reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata;
reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata_c;
genvar j;
integer k;
generate
for (j=0; j<2*nCK_PER_CLK; j=j+1) begin : ecc_word
always @(/*AS*/h_rows or merged_data or raw_not_ecc_r) begin
mc_wrdata_c[j*DQ_WIDTH+:DQ_WIDTH] =
{{DQ_WIDTH-PAYLOAD_WIDTH{1'b0}},
merged_data[j*PAYLOAD_WIDTH+:PAYLOAD_WIDTH]};
for (k=0; k<ECC_WIDTH; k=k+1)
if (~raw_not_ecc_r[j])
mc_wrdata_c[j*DQ_WIDTH+CODE_WIDTH-k-1] =
^(merged_data[j*PAYLOAD_WIDTH+:DATA_WIDTH] &
h_rows[k*CODE_WIDTH+:DATA_WIDTH]);
end
end
endgenerate
always @(posedge clk) mc_wrdata <= mc_wrdata_c;
// Set all DRAM masks to zero.
output wire[2*nCK_PER_CLK*DQ_WIDTH/8-1:0] mc_wrdata_mask;
assign mc_wrdata_mask = {2*nCK_PER_CLK*DQ_WIDTH/8{1'b0}};
endmodule
|
module mig_7series_v2_3_ecc_merge_enc
#(
parameter TCQ = 100,
parameter PAYLOAD_WIDTH = 64,
parameter CODE_WIDTH = 72,
parameter DATA_BUF_ADDR_WIDTH = 4,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DATA_WIDTH = 64,
parameter DQ_WIDTH = 72,
parameter ECC_WIDTH = 8,
parameter nCK_PER_CLK = 4
)
(
/*AUTOARG*/
// Outputs
mc_wrdata, mc_wrdata_mask,
// Inputs
clk, rst, wr_data, wr_data_mask, rd_merge_data, h_rows, raw_not_ecc
);
input clk;
input rst;
input [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data;
input [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask;
input [2*nCK_PER_CLK*DATA_WIDTH-1:0] rd_merge_data;
reg [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data_r;
reg [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask_r;
reg [2*nCK_PER_CLK*DATA_WIDTH-1:0] rd_merge_data_r;
always @(posedge clk) wr_data_r <= #TCQ wr_data;
always @(posedge clk) wr_data_mask_r <= #TCQ wr_data_mask;
always @(posedge clk) rd_merge_data_r <= #TCQ rd_merge_data;
// Merge new data with memory read data.
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] merged_data;
genvar h;
genvar i;
generate
for (h=0; h<2*nCK_PER_CLK; h=h+1) begin : merge_data_outer
for (i=0; i<DATA_WIDTH/8; i=i+1) begin : merge_data_inner
assign merged_data[h*PAYLOAD_WIDTH+i*8+:8] =
wr_data_mask[h*DATA_WIDTH/8+i]
? rd_merge_data[h*DATA_WIDTH+i*8+:8]
: wr_data[h*PAYLOAD_WIDTH+i*8+:8];
end
if (PAYLOAD_WIDTH > DATA_WIDTH)
assign merged_data[(h+1)*PAYLOAD_WIDTH-1-:PAYLOAD_WIDTH-DATA_WIDTH]=
wr_data[(h+1)*PAYLOAD_WIDTH-1-:PAYLOAD_WIDTH-DATA_WIDTH];
end
endgenerate
// Generate ECC and overlay onto mc_wrdata.
input [CODE_WIDTH*ECC_WIDTH-1:0] h_rows;
input [2*nCK_PER_CLK-1:0] raw_not_ecc;
reg [2*nCK_PER_CLK-1:0] raw_not_ecc_r;
always @(posedge clk) raw_not_ecc_r <= #TCQ raw_not_ecc;
output reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata;
reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata_c;
genvar j;
integer k;
generate
for (j=0; j<2*nCK_PER_CLK; j=j+1) begin : ecc_word
always @(/*AS*/h_rows or merged_data or raw_not_ecc_r) begin
mc_wrdata_c[j*DQ_WIDTH+:DQ_WIDTH] =
{{DQ_WIDTH-PAYLOAD_WIDTH{1'b0}},
merged_data[j*PAYLOAD_WIDTH+:PAYLOAD_WIDTH]};
for (k=0; k<ECC_WIDTH; k=k+1)
if (~raw_not_ecc_r[j])
mc_wrdata_c[j*DQ_WIDTH+CODE_WIDTH-k-1] =
^(merged_data[j*PAYLOAD_WIDTH+:DATA_WIDTH] &
h_rows[k*CODE_WIDTH+:DATA_WIDTH]);
end
end
endgenerate
always @(posedge clk) mc_wrdata <= mc_wrdata_c;
// Set all DRAM masks to zero.
output wire[2*nCK_PER_CLK*DQ_WIDTH/8-1:0] mc_wrdata_mask;
assign mc_wrdata_mask = {2*nCK_PER_CLK*DQ_WIDTH/8{1'b0}};
endmodule
|
module mig_7series_v2_3_ecc_merge_enc
#(
parameter TCQ = 100,
parameter PAYLOAD_WIDTH = 64,
parameter CODE_WIDTH = 72,
parameter DATA_BUF_ADDR_WIDTH = 4,
parameter DATA_BUF_OFFSET_WIDTH = 1,
parameter DATA_WIDTH = 64,
parameter DQ_WIDTH = 72,
parameter ECC_WIDTH = 8,
parameter nCK_PER_CLK = 4
)
(
/*AUTOARG*/
// Outputs
mc_wrdata, mc_wrdata_mask,
// Inputs
clk, rst, wr_data, wr_data_mask, rd_merge_data, h_rows, raw_not_ecc
);
input clk;
input rst;
input [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data;
input [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask;
input [2*nCK_PER_CLK*DATA_WIDTH-1:0] rd_merge_data;
reg [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] wr_data_r;
reg [2*nCK_PER_CLK*DATA_WIDTH/8-1:0] wr_data_mask_r;
reg [2*nCK_PER_CLK*DATA_WIDTH-1:0] rd_merge_data_r;
always @(posedge clk) wr_data_r <= #TCQ wr_data;
always @(posedge clk) wr_data_mask_r <= #TCQ wr_data_mask;
always @(posedge clk) rd_merge_data_r <= #TCQ rd_merge_data;
// Merge new data with memory read data.
wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] merged_data;
genvar h;
genvar i;
generate
for (h=0; h<2*nCK_PER_CLK; h=h+1) begin : merge_data_outer
for (i=0; i<DATA_WIDTH/8; i=i+1) begin : merge_data_inner
assign merged_data[h*PAYLOAD_WIDTH+i*8+:8] =
wr_data_mask[h*DATA_WIDTH/8+i]
? rd_merge_data[h*DATA_WIDTH+i*8+:8]
: wr_data[h*PAYLOAD_WIDTH+i*8+:8];
end
if (PAYLOAD_WIDTH > DATA_WIDTH)
assign merged_data[(h+1)*PAYLOAD_WIDTH-1-:PAYLOAD_WIDTH-DATA_WIDTH]=
wr_data[(h+1)*PAYLOAD_WIDTH-1-:PAYLOAD_WIDTH-DATA_WIDTH];
end
endgenerate
// Generate ECC and overlay onto mc_wrdata.
input [CODE_WIDTH*ECC_WIDTH-1:0] h_rows;
input [2*nCK_PER_CLK-1:0] raw_not_ecc;
reg [2*nCK_PER_CLK-1:0] raw_not_ecc_r;
always @(posedge clk) raw_not_ecc_r <= #TCQ raw_not_ecc;
output reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata;
reg [2*nCK_PER_CLK*DQ_WIDTH-1:0] mc_wrdata_c;
genvar j;
integer k;
generate
for (j=0; j<2*nCK_PER_CLK; j=j+1) begin : ecc_word
always @(/*AS*/h_rows or merged_data or raw_not_ecc_r) begin
mc_wrdata_c[j*DQ_WIDTH+:DQ_WIDTH] =
{{DQ_WIDTH-PAYLOAD_WIDTH{1'b0}},
merged_data[j*PAYLOAD_WIDTH+:PAYLOAD_WIDTH]};
for (k=0; k<ECC_WIDTH; k=k+1)
if (~raw_not_ecc_r[j])
mc_wrdata_c[j*DQ_WIDTH+CODE_WIDTH-k-1] =
^(merged_data[j*PAYLOAD_WIDTH+:DATA_WIDTH] &
h_rows[k*CODE_WIDTH+:DATA_WIDTH]);
end
end
endgenerate
always @(posedge clk) mc_wrdata <= mc_wrdata_c;
// Set all DRAM masks to zero.
output wire[2*nCK_PER_CLK*DQ_WIDTH/8-1:0] mc_wrdata_mask;
assign mc_wrdata_mask = {2*nCK_PER_CLK*DQ_WIDTH/8{1'b0}};
endmodule
|
module, since this is a DQ/DQS bus-level requirement,
// not a per-rank requirement.
localparam CASRD2CASWR = CL + (BURST_MODE == "4" ? 2 : 4) + DQRD2DQWR_DLY - CWL;
localparam CASRD2CASWR_CLKS = (nCK_PER_CLK == 1)
? CASRD2CASWR :
(nCK_PER_CLK == 2)
? ((CASRD2CASWR / 2) + (CASRD2CASWR % 2)) :
((CASRD2CASWR / 4) + ((CASRD2CASWR % 4) ? 1 :0));
localparam RTW_CNT_WIDTH = clogb2(CASRD2CASWR_CLKS);
generate
begin : rtw_timer
reg read_this_rank;
always @(/*AS*/sending_col or rd_this_rank_r) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_r;
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_ns;
always @(/*AS*/rst or col_rd_wr or sending_col or rtw_cnt_r)
if (rst) rtw_cnt_ns = {RTW_CNT_WIDTH{1'b0}};
else begin
rtw_cnt_ns = rtw_cnt_r;
if (col_rd_wr && |sending_col) rtw_cnt_ns =
CASRD2CASWR_CLKS[RTW_CNT_WIDTH-1:0] - ONE[RTW_CNT_WIDTH-1:0];
else if (|rtw_cnt_r) rtw_cnt_ns = rtw_cnt_r - ONE[RTW_CNT_WIDTH-1:0];
end
wire inhbt_wr_ns = |rtw_cnt_ns;
always @(posedge clk) rtw_cnt_r <= #TCQ rtw_cnt_ns;
always @(inhbt_wr_ns) inhbt_wr = inhbt_wr_ns;
end
endgenerate
// Refresh request generation. Implement a "refresh bank". Referred
// to as pullin-in refresh in the JEDEC spec.
// The refresh_rank_r counter increments when a refresh to this
// rank has been decoded. In the up direction, the count saturates
// at nREFRESH_BANK. As specified in the JEDEC spec, nREFRESH_BANK
// is normally eight. The counter decrements with each refresh_tick,
// saturating at zero. A refresh will be requests when the rank is
// not busy and refresh_rank_r != nREFRESH_BANK, or refresh_rank_r
// equals zero.
localparam REFRESH_BANK_WIDTH = clogb2(nREFRESH_BANK + 1);
generate begin : refresh_generation
reg my_rank_busy;
always @(/*AS*/rank_busy_r) begin
my_rank_busy = 1'b0;
for (i=0; i < nBANK_MACHS; i=i+1)
my_rank_busy = my_rank_busy || rank_busy_r[(i*RANKS)+ID];
end
wire my_refresh =
insert_maint_r1 && ~maint_zq_r && ~maint_sre_r && ~maint_srx_r &&
(maint_rank_r == ID[RANK_WIDTH-1:0]);
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_r;
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_ns;
always @(/*AS*/app_ref_req or init_calib_complete or my_refresh
or refresh_bank_r or refresh_tick)
if (~init_calib_complete)
if (REFRESH_TIMER_DIV == 0)
refresh_bank_ns = nREFRESH_BANK[0+:REFRESH_BANK_WIDTH];
else refresh_bank_ns = {REFRESH_BANK_WIDTH{1'b0}};
else
case ({my_refresh, refresh_tick, app_ref_req})
3'b000, 3'b110, 3'b101, 3'b111 : refresh_bank_ns = refresh_bank_r;
3'b010, 3'b001, 3'b011 : refresh_bank_ns =
(|refresh_bank_r)?
refresh_bank_r - ONE[0+:REFRESH_BANK_WIDTH]:
refresh_bank_r;
3'b100 : refresh_bank_ns =
refresh_bank_r + ONE[0+:REFRESH_BANK_WIDTH];
endcase // case ({my_refresh, refresh_tick})
always @(posedge clk) refresh_bank_r <= #TCQ refresh_bank_ns;
`ifdef MC_SVA
refresh_bank_overflow: assert property (@(posedge clk)
(rst || (refresh_bank_r <= nREFRESH_BANK)));
refresh_bank_underflow: assert property (@(posedge clk)
(rst || ~(~|refresh_bank_r && ~my_refresh && refresh_tick)));
refresh_hi_priority: cover property (@(posedge clk)
(rst && ~|refresh_bank_ns && (refresh_bank_r ==
ONE[0+:REFRESH_BANK_WIDTH])));
refresh_bank_full: cover property (@(posedge clk)
(rst && (refresh_bank_r ==
nREFRESH_BANK[0+:REFRESH_BANK_WIDTH])));
`endif
assign refresh_request = init_calib_complete &&
(~|refresh_bank_r ||
((refresh_bank_r != nREFRESH_BANK[0+:REFRESH_BANK_WIDTH]) && ~my_rank_busy));
end
endgenerate
// Periodic read request generation.
localparam PERIODIC_RD_TIMER_WIDTH = clogb2(PERIODIC_RD_TIMER_DIV + /*idle state*/ 1);
generate begin : periodic_rd_generation
if ( PERIODIC_RD_TIMER_DIV != 0 ) begin // enable periodic reads
reg read_this_rank;
always @(/*AS*/rd_this_rank_r or sending_col) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg read_this_rank_r;
reg read_this_rank_r1;
always @(posedge clk) read_this_rank_r <= #TCQ read_this_rank;
always @(posedge clk) read_this_rank_r1 <= #TCQ read_this_rank_r;
wire int_read_this_rank = read_this_rank &&
(((nCK_PER_CLK == 4) && read_this_rank_r) ||
((nCK_PER_CLK != 4) && read_this_rank_r1));
reg periodic_rd_cntr1_ns;
reg periodic_rd_cntr1_r;
always @(/*AS*/clear_periodic_rd_request or periodic_rd_cntr1_r) begin
periodic_rd_cntr1_ns = periodic_rd_cntr1_r;
if (clear_periodic_rd_request)
periodic_rd_cntr1_ns = periodic_rd_cntr1_r + 1'b1;
end
always @(posedge clk) begin
if (rst) periodic_rd_cntr1_r <= #TCQ 1'b0;
else periodic_rd_cntr1_r <= #TCQ periodic_rd_cntr1_ns;
end
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_r;
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_ns;
always @(/*AS*/init_calib_complete or maint_prescaler_tick_r
or periodic_rd_timer_r or int_read_this_rank) begin
periodic_rd_timer_ns = periodic_rd_timer_r;
if (~init_calib_complete)
periodic_rd_timer_ns = {PERIODIC_RD_TIMER_WIDTH{1'b0}};
else if (int_read_this_rank)
periodic_rd_timer_ns =
PERIODIC_RD_TIMER_DIV[0+:PERIODIC_RD_TIMER_WIDTH];
else if (|periodic_rd_timer_r && maint_prescaler_tick_r)
periodic_rd_timer_ns =
periodic_rd_timer_r - ONE[0+:PERIODIC_RD_TIMER_WIDTH];
end
always @(posedge clk) periodic_rd_timer_r <= #TCQ periodic_rd_timer_ns;
wire periodic_rd_timer_one = maint_prescaler_tick_r &&
(periodic_rd_timer_r == ONE[0+:PERIODIC_RD_TIMER_WIDTH]);
reg periodic_rd_request_r;
wire periodic_rd_request_ns = ~rst &&
((app_periodic_rd_req && init_calib_complete) ||
((PERIODIC_RD_TIMER_DIV != 0) && ~init_calib_complete) ||
// (~(read_this_rank || clear_periodic_rd_request) &&
(~((int_read_this_rank) || (clear_periodic_rd_request && periodic_rd_cntr1_r)) &&
(periodic_rd_request_r || periodic_rd_timer_one)));
always @(posedge clk) periodic_rd_request_r <=
#TCQ periodic_rd_request_ns;
`ifdef MC_SVA
read_clears_periodic_rd_request: cover property (@(posedge clk)
(rst && (periodic_rd_request_r && read_this_rank)));
`endif
assign periodic_rd_request = init_calib_complete && periodic_rd_request_r;
end else
assign periodic_rd_request = 1'b0; //to disable periodic reads
end
endgenerate
endmodule
|
module, since this is a DQ/DQS bus-level requirement,
// not a per-rank requirement.
localparam CASRD2CASWR = CL + (BURST_MODE == "4" ? 2 : 4) + DQRD2DQWR_DLY - CWL;
localparam CASRD2CASWR_CLKS = (nCK_PER_CLK == 1)
? CASRD2CASWR :
(nCK_PER_CLK == 2)
? ((CASRD2CASWR / 2) + (CASRD2CASWR % 2)) :
((CASRD2CASWR / 4) + ((CASRD2CASWR % 4) ? 1 :0));
localparam RTW_CNT_WIDTH = clogb2(CASRD2CASWR_CLKS);
generate
begin : rtw_timer
reg read_this_rank;
always @(/*AS*/sending_col or rd_this_rank_r) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_r;
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_ns;
always @(/*AS*/rst or col_rd_wr or sending_col or rtw_cnt_r)
if (rst) rtw_cnt_ns = {RTW_CNT_WIDTH{1'b0}};
else begin
rtw_cnt_ns = rtw_cnt_r;
if (col_rd_wr && |sending_col) rtw_cnt_ns =
CASRD2CASWR_CLKS[RTW_CNT_WIDTH-1:0] - ONE[RTW_CNT_WIDTH-1:0];
else if (|rtw_cnt_r) rtw_cnt_ns = rtw_cnt_r - ONE[RTW_CNT_WIDTH-1:0];
end
wire inhbt_wr_ns = |rtw_cnt_ns;
always @(posedge clk) rtw_cnt_r <= #TCQ rtw_cnt_ns;
always @(inhbt_wr_ns) inhbt_wr = inhbt_wr_ns;
end
endgenerate
// Refresh request generation. Implement a "refresh bank". Referred
// to as pullin-in refresh in the JEDEC spec.
// The refresh_rank_r counter increments when a refresh to this
// rank has been decoded. In the up direction, the count saturates
// at nREFRESH_BANK. As specified in the JEDEC spec, nREFRESH_BANK
// is normally eight. The counter decrements with each refresh_tick,
// saturating at zero. A refresh will be requests when the rank is
// not busy and refresh_rank_r != nREFRESH_BANK, or refresh_rank_r
// equals zero.
localparam REFRESH_BANK_WIDTH = clogb2(nREFRESH_BANK + 1);
generate begin : refresh_generation
reg my_rank_busy;
always @(/*AS*/rank_busy_r) begin
my_rank_busy = 1'b0;
for (i=0; i < nBANK_MACHS; i=i+1)
my_rank_busy = my_rank_busy || rank_busy_r[(i*RANKS)+ID];
end
wire my_refresh =
insert_maint_r1 && ~maint_zq_r && ~maint_sre_r && ~maint_srx_r &&
(maint_rank_r == ID[RANK_WIDTH-1:0]);
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_r;
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_ns;
always @(/*AS*/app_ref_req or init_calib_complete or my_refresh
or refresh_bank_r or refresh_tick)
if (~init_calib_complete)
if (REFRESH_TIMER_DIV == 0)
refresh_bank_ns = nREFRESH_BANK[0+:REFRESH_BANK_WIDTH];
else refresh_bank_ns = {REFRESH_BANK_WIDTH{1'b0}};
else
case ({my_refresh, refresh_tick, app_ref_req})
3'b000, 3'b110, 3'b101, 3'b111 : refresh_bank_ns = refresh_bank_r;
3'b010, 3'b001, 3'b011 : refresh_bank_ns =
(|refresh_bank_r)?
refresh_bank_r - ONE[0+:REFRESH_BANK_WIDTH]:
refresh_bank_r;
3'b100 : refresh_bank_ns =
refresh_bank_r + ONE[0+:REFRESH_BANK_WIDTH];
endcase // case ({my_refresh, refresh_tick})
always @(posedge clk) refresh_bank_r <= #TCQ refresh_bank_ns;
`ifdef MC_SVA
refresh_bank_overflow: assert property (@(posedge clk)
(rst || (refresh_bank_r <= nREFRESH_BANK)));
refresh_bank_underflow: assert property (@(posedge clk)
(rst || ~(~|refresh_bank_r && ~my_refresh && refresh_tick)));
refresh_hi_priority: cover property (@(posedge clk)
(rst && ~|refresh_bank_ns && (refresh_bank_r ==
ONE[0+:REFRESH_BANK_WIDTH])));
refresh_bank_full: cover property (@(posedge clk)
(rst && (refresh_bank_r ==
nREFRESH_BANK[0+:REFRESH_BANK_WIDTH])));
`endif
assign refresh_request = init_calib_complete &&
(~|refresh_bank_r ||
((refresh_bank_r != nREFRESH_BANK[0+:REFRESH_BANK_WIDTH]) && ~my_rank_busy));
end
endgenerate
// Periodic read request generation.
localparam PERIODIC_RD_TIMER_WIDTH = clogb2(PERIODIC_RD_TIMER_DIV + /*idle state*/ 1);
generate begin : periodic_rd_generation
if ( PERIODIC_RD_TIMER_DIV != 0 ) begin // enable periodic reads
reg read_this_rank;
always @(/*AS*/rd_this_rank_r or sending_col) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg read_this_rank_r;
reg read_this_rank_r1;
always @(posedge clk) read_this_rank_r <= #TCQ read_this_rank;
always @(posedge clk) read_this_rank_r1 <= #TCQ read_this_rank_r;
wire int_read_this_rank = read_this_rank &&
(((nCK_PER_CLK == 4) && read_this_rank_r) ||
((nCK_PER_CLK != 4) && read_this_rank_r1));
reg periodic_rd_cntr1_ns;
reg periodic_rd_cntr1_r;
always @(/*AS*/clear_periodic_rd_request or periodic_rd_cntr1_r) begin
periodic_rd_cntr1_ns = periodic_rd_cntr1_r;
if (clear_periodic_rd_request)
periodic_rd_cntr1_ns = periodic_rd_cntr1_r + 1'b1;
end
always @(posedge clk) begin
if (rst) periodic_rd_cntr1_r <= #TCQ 1'b0;
else periodic_rd_cntr1_r <= #TCQ periodic_rd_cntr1_ns;
end
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_r;
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_ns;
always @(/*AS*/init_calib_complete or maint_prescaler_tick_r
or periodic_rd_timer_r or int_read_this_rank) begin
periodic_rd_timer_ns = periodic_rd_timer_r;
if (~init_calib_complete)
periodic_rd_timer_ns = {PERIODIC_RD_TIMER_WIDTH{1'b0}};
else if (int_read_this_rank)
periodic_rd_timer_ns =
PERIODIC_RD_TIMER_DIV[0+:PERIODIC_RD_TIMER_WIDTH];
else if (|periodic_rd_timer_r && maint_prescaler_tick_r)
periodic_rd_timer_ns =
periodic_rd_timer_r - ONE[0+:PERIODIC_RD_TIMER_WIDTH];
end
always @(posedge clk) periodic_rd_timer_r <= #TCQ periodic_rd_timer_ns;
wire periodic_rd_timer_one = maint_prescaler_tick_r &&
(periodic_rd_timer_r == ONE[0+:PERIODIC_RD_TIMER_WIDTH]);
reg periodic_rd_request_r;
wire periodic_rd_request_ns = ~rst &&
((app_periodic_rd_req && init_calib_complete) ||
((PERIODIC_RD_TIMER_DIV != 0) && ~init_calib_complete) ||
// (~(read_this_rank || clear_periodic_rd_request) &&
(~((int_read_this_rank) || (clear_periodic_rd_request && periodic_rd_cntr1_r)) &&
(periodic_rd_request_r || periodic_rd_timer_one)));
always @(posedge clk) periodic_rd_request_r <=
#TCQ periodic_rd_request_ns;
`ifdef MC_SVA
read_clears_periodic_rd_request: cover property (@(posedge clk)
(rst && (periodic_rd_request_r && read_this_rank)));
`endif
assign periodic_rd_request = init_calib_complete && periodic_rd_request_r;
end else
assign periodic_rd_request = 1'b0; //to disable periodic reads
end
endgenerate
endmodule
|
module, since this is a DQ/DQS bus-level requirement,
// not a per-rank requirement.
localparam CASRD2CASWR = CL + (BURST_MODE == "4" ? 2 : 4) + DQRD2DQWR_DLY - CWL;
localparam CASRD2CASWR_CLKS = (nCK_PER_CLK == 1)
? CASRD2CASWR :
(nCK_PER_CLK == 2)
? ((CASRD2CASWR / 2) + (CASRD2CASWR % 2)) :
((CASRD2CASWR / 4) + ((CASRD2CASWR % 4) ? 1 :0));
localparam RTW_CNT_WIDTH = clogb2(CASRD2CASWR_CLKS);
generate
begin : rtw_timer
reg read_this_rank;
always @(/*AS*/sending_col or rd_this_rank_r) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_r;
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_ns;
always @(/*AS*/rst or col_rd_wr or sending_col or rtw_cnt_r)
if (rst) rtw_cnt_ns = {RTW_CNT_WIDTH{1'b0}};
else begin
rtw_cnt_ns = rtw_cnt_r;
if (col_rd_wr && |sending_col) rtw_cnt_ns =
CASRD2CASWR_CLKS[RTW_CNT_WIDTH-1:0] - ONE[RTW_CNT_WIDTH-1:0];
else if (|rtw_cnt_r) rtw_cnt_ns = rtw_cnt_r - ONE[RTW_CNT_WIDTH-1:0];
end
wire inhbt_wr_ns = |rtw_cnt_ns;
always @(posedge clk) rtw_cnt_r <= #TCQ rtw_cnt_ns;
always @(inhbt_wr_ns) inhbt_wr = inhbt_wr_ns;
end
endgenerate
// Refresh request generation. Implement a "refresh bank". Referred
// to as pullin-in refresh in the JEDEC spec.
// The refresh_rank_r counter increments when a refresh to this
// rank has been decoded. In the up direction, the count saturates
// at nREFRESH_BANK. As specified in the JEDEC spec, nREFRESH_BANK
// is normally eight. The counter decrements with each refresh_tick,
// saturating at zero. A refresh will be requests when the rank is
// not busy and refresh_rank_r != nREFRESH_BANK, or refresh_rank_r
// equals zero.
localparam REFRESH_BANK_WIDTH = clogb2(nREFRESH_BANK + 1);
generate begin : refresh_generation
reg my_rank_busy;
always @(/*AS*/rank_busy_r) begin
my_rank_busy = 1'b0;
for (i=0; i < nBANK_MACHS; i=i+1)
my_rank_busy = my_rank_busy || rank_busy_r[(i*RANKS)+ID];
end
wire my_refresh =
insert_maint_r1 && ~maint_zq_r && ~maint_sre_r && ~maint_srx_r &&
(maint_rank_r == ID[RANK_WIDTH-1:0]);
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_r;
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_ns;
always @(/*AS*/app_ref_req or init_calib_complete or my_refresh
or refresh_bank_r or refresh_tick)
if (~init_calib_complete)
if (REFRESH_TIMER_DIV == 0)
refresh_bank_ns = nREFRESH_BANK[0+:REFRESH_BANK_WIDTH];
else refresh_bank_ns = {REFRESH_BANK_WIDTH{1'b0}};
else
case ({my_refresh, refresh_tick, app_ref_req})
3'b000, 3'b110, 3'b101, 3'b111 : refresh_bank_ns = refresh_bank_r;
3'b010, 3'b001, 3'b011 : refresh_bank_ns =
(|refresh_bank_r)?
refresh_bank_r - ONE[0+:REFRESH_BANK_WIDTH]:
refresh_bank_r;
3'b100 : refresh_bank_ns =
refresh_bank_r + ONE[0+:REFRESH_BANK_WIDTH];
endcase // case ({my_refresh, refresh_tick})
always @(posedge clk) refresh_bank_r <= #TCQ refresh_bank_ns;
`ifdef MC_SVA
refresh_bank_overflow: assert property (@(posedge clk)
(rst || (refresh_bank_r <= nREFRESH_BANK)));
refresh_bank_underflow: assert property (@(posedge clk)
(rst || ~(~|refresh_bank_r && ~my_refresh && refresh_tick)));
refresh_hi_priority: cover property (@(posedge clk)
(rst && ~|refresh_bank_ns && (refresh_bank_r ==
ONE[0+:REFRESH_BANK_WIDTH])));
refresh_bank_full: cover property (@(posedge clk)
(rst && (refresh_bank_r ==
nREFRESH_BANK[0+:REFRESH_BANK_WIDTH])));
`endif
assign refresh_request = init_calib_complete &&
(~|refresh_bank_r ||
((refresh_bank_r != nREFRESH_BANK[0+:REFRESH_BANK_WIDTH]) && ~my_rank_busy));
end
endgenerate
// Periodic read request generation.
localparam PERIODIC_RD_TIMER_WIDTH = clogb2(PERIODIC_RD_TIMER_DIV + /*idle state*/ 1);
generate begin : periodic_rd_generation
if ( PERIODIC_RD_TIMER_DIV != 0 ) begin // enable periodic reads
reg read_this_rank;
always @(/*AS*/rd_this_rank_r or sending_col) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg read_this_rank_r;
reg read_this_rank_r1;
always @(posedge clk) read_this_rank_r <= #TCQ read_this_rank;
always @(posedge clk) read_this_rank_r1 <= #TCQ read_this_rank_r;
wire int_read_this_rank = read_this_rank &&
(((nCK_PER_CLK == 4) && read_this_rank_r) ||
((nCK_PER_CLK != 4) && read_this_rank_r1));
reg periodic_rd_cntr1_ns;
reg periodic_rd_cntr1_r;
always @(/*AS*/clear_periodic_rd_request or periodic_rd_cntr1_r) begin
periodic_rd_cntr1_ns = periodic_rd_cntr1_r;
if (clear_periodic_rd_request)
periodic_rd_cntr1_ns = periodic_rd_cntr1_r + 1'b1;
end
always @(posedge clk) begin
if (rst) periodic_rd_cntr1_r <= #TCQ 1'b0;
else periodic_rd_cntr1_r <= #TCQ periodic_rd_cntr1_ns;
end
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_r;
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_ns;
always @(/*AS*/init_calib_complete or maint_prescaler_tick_r
or periodic_rd_timer_r or int_read_this_rank) begin
periodic_rd_timer_ns = periodic_rd_timer_r;
if (~init_calib_complete)
periodic_rd_timer_ns = {PERIODIC_RD_TIMER_WIDTH{1'b0}};
else if (int_read_this_rank)
periodic_rd_timer_ns =
PERIODIC_RD_TIMER_DIV[0+:PERIODIC_RD_TIMER_WIDTH];
else if (|periodic_rd_timer_r && maint_prescaler_tick_r)
periodic_rd_timer_ns =
periodic_rd_timer_r - ONE[0+:PERIODIC_RD_TIMER_WIDTH];
end
always @(posedge clk) periodic_rd_timer_r <= #TCQ periodic_rd_timer_ns;
wire periodic_rd_timer_one = maint_prescaler_tick_r &&
(periodic_rd_timer_r == ONE[0+:PERIODIC_RD_TIMER_WIDTH]);
reg periodic_rd_request_r;
wire periodic_rd_request_ns = ~rst &&
((app_periodic_rd_req && init_calib_complete) ||
((PERIODIC_RD_TIMER_DIV != 0) && ~init_calib_complete) ||
// (~(read_this_rank || clear_periodic_rd_request) &&
(~((int_read_this_rank) || (clear_periodic_rd_request && periodic_rd_cntr1_r)) &&
(periodic_rd_request_r || periodic_rd_timer_one)));
always @(posedge clk) periodic_rd_request_r <=
#TCQ periodic_rd_request_ns;
`ifdef MC_SVA
read_clears_periodic_rd_request: cover property (@(posedge clk)
(rst && (periodic_rd_request_r && read_this_rank)));
`endif
assign periodic_rd_request = init_calib_complete && periodic_rd_request_r;
end else
assign periodic_rd_request = 1'b0; //to disable periodic reads
end
endgenerate
endmodule
|
module, since this is a DQ/DQS bus-level requirement,
// not a per-rank requirement.
localparam CASRD2CASWR = CL + (BURST_MODE == "4" ? 2 : 4) + DQRD2DQWR_DLY - CWL;
localparam CASRD2CASWR_CLKS = (nCK_PER_CLK == 1)
? CASRD2CASWR :
(nCK_PER_CLK == 2)
? ((CASRD2CASWR / 2) + (CASRD2CASWR % 2)) :
((CASRD2CASWR / 4) + ((CASRD2CASWR % 4) ? 1 :0));
localparam RTW_CNT_WIDTH = clogb2(CASRD2CASWR_CLKS);
generate
begin : rtw_timer
reg read_this_rank;
always @(/*AS*/sending_col or rd_this_rank_r) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_r;
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_ns;
always @(/*AS*/rst or col_rd_wr or sending_col or rtw_cnt_r)
if (rst) rtw_cnt_ns = {RTW_CNT_WIDTH{1'b0}};
else begin
rtw_cnt_ns = rtw_cnt_r;
if (col_rd_wr && |sending_col) rtw_cnt_ns =
CASRD2CASWR_CLKS[RTW_CNT_WIDTH-1:0] - ONE[RTW_CNT_WIDTH-1:0];
else if (|rtw_cnt_r) rtw_cnt_ns = rtw_cnt_r - ONE[RTW_CNT_WIDTH-1:0];
end
wire inhbt_wr_ns = |rtw_cnt_ns;
always @(posedge clk) rtw_cnt_r <= #TCQ rtw_cnt_ns;
always @(inhbt_wr_ns) inhbt_wr = inhbt_wr_ns;
end
endgenerate
// Refresh request generation. Implement a "refresh bank". Referred
// to as pullin-in refresh in the JEDEC spec.
// The refresh_rank_r counter increments when a refresh to this
// rank has been decoded. In the up direction, the count saturates
// at nREFRESH_BANK. As specified in the JEDEC spec, nREFRESH_BANK
// is normally eight. The counter decrements with each refresh_tick,
// saturating at zero. A refresh will be requests when the rank is
// not busy and refresh_rank_r != nREFRESH_BANK, or refresh_rank_r
// equals zero.
localparam REFRESH_BANK_WIDTH = clogb2(nREFRESH_BANK + 1);
generate begin : refresh_generation
reg my_rank_busy;
always @(/*AS*/rank_busy_r) begin
my_rank_busy = 1'b0;
for (i=0; i < nBANK_MACHS; i=i+1)
my_rank_busy = my_rank_busy || rank_busy_r[(i*RANKS)+ID];
end
wire my_refresh =
insert_maint_r1 && ~maint_zq_r && ~maint_sre_r && ~maint_srx_r &&
(maint_rank_r == ID[RANK_WIDTH-1:0]);
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_r;
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_ns;
always @(/*AS*/app_ref_req or init_calib_complete or my_refresh
or refresh_bank_r or refresh_tick)
if (~init_calib_complete)
if (REFRESH_TIMER_DIV == 0)
refresh_bank_ns = nREFRESH_BANK[0+:REFRESH_BANK_WIDTH];
else refresh_bank_ns = {REFRESH_BANK_WIDTH{1'b0}};
else
case ({my_refresh, refresh_tick, app_ref_req})
3'b000, 3'b110, 3'b101, 3'b111 : refresh_bank_ns = refresh_bank_r;
3'b010, 3'b001, 3'b011 : refresh_bank_ns =
(|refresh_bank_r)?
refresh_bank_r - ONE[0+:REFRESH_BANK_WIDTH]:
refresh_bank_r;
3'b100 : refresh_bank_ns =
refresh_bank_r + ONE[0+:REFRESH_BANK_WIDTH];
endcase // case ({my_refresh, refresh_tick})
always @(posedge clk) refresh_bank_r <= #TCQ refresh_bank_ns;
`ifdef MC_SVA
refresh_bank_overflow: assert property (@(posedge clk)
(rst || (refresh_bank_r <= nREFRESH_BANK)));
refresh_bank_underflow: assert property (@(posedge clk)
(rst || ~(~|refresh_bank_r && ~my_refresh && refresh_tick)));
refresh_hi_priority: cover property (@(posedge clk)
(rst && ~|refresh_bank_ns && (refresh_bank_r ==
ONE[0+:REFRESH_BANK_WIDTH])));
refresh_bank_full: cover property (@(posedge clk)
(rst && (refresh_bank_r ==
nREFRESH_BANK[0+:REFRESH_BANK_WIDTH])));
`endif
assign refresh_request = init_calib_complete &&
(~|refresh_bank_r ||
((refresh_bank_r != nREFRESH_BANK[0+:REFRESH_BANK_WIDTH]) && ~my_rank_busy));
end
endgenerate
// Periodic read request generation.
localparam PERIODIC_RD_TIMER_WIDTH = clogb2(PERIODIC_RD_TIMER_DIV + /*idle state*/ 1);
generate begin : periodic_rd_generation
if ( PERIODIC_RD_TIMER_DIV != 0 ) begin // enable periodic reads
reg read_this_rank;
always @(/*AS*/rd_this_rank_r or sending_col) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg read_this_rank_r;
reg read_this_rank_r1;
always @(posedge clk) read_this_rank_r <= #TCQ read_this_rank;
always @(posedge clk) read_this_rank_r1 <= #TCQ read_this_rank_r;
wire int_read_this_rank = read_this_rank &&
(((nCK_PER_CLK == 4) && read_this_rank_r) ||
((nCK_PER_CLK != 4) && read_this_rank_r1));
reg periodic_rd_cntr1_ns;
reg periodic_rd_cntr1_r;
always @(/*AS*/clear_periodic_rd_request or periodic_rd_cntr1_r) begin
periodic_rd_cntr1_ns = periodic_rd_cntr1_r;
if (clear_periodic_rd_request)
periodic_rd_cntr1_ns = periodic_rd_cntr1_r + 1'b1;
end
always @(posedge clk) begin
if (rst) periodic_rd_cntr1_r <= #TCQ 1'b0;
else periodic_rd_cntr1_r <= #TCQ periodic_rd_cntr1_ns;
end
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_r;
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_ns;
always @(/*AS*/init_calib_complete or maint_prescaler_tick_r
or periodic_rd_timer_r or int_read_this_rank) begin
periodic_rd_timer_ns = periodic_rd_timer_r;
if (~init_calib_complete)
periodic_rd_timer_ns = {PERIODIC_RD_TIMER_WIDTH{1'b0}};
else if (int_read_this_rank)
periodic_rd_timer_ns =
PERIODIC_RD_TIMER_DIV[0+:PERIODIC_RD_TIMER_WIDTH];
else if (|periodic_rd_timer_r && maint_prescaler_tick_r)
periodic_rd_timer_ns =
periodic_rd_timer_r - ONE[0+:PERIODIC_RD_TIMER_WIDTH];
end
always @(posedge clk) periodic_rd_timer_r <= #TCQ periodic_rd_timer_ns;
wire periodic_rd_timer_one = maint_prescaler_tick_r &&
(periodic_rd_timer_r == ONE[0+:PERIODIC_RD_TIMER_WIDTH]);
reg periodic_rd_request_r;
wire periodic_rd_request_ns = ~rst &&
((app_periodic_rd_req && init_calib_complete) ||
((PERIODIC_RD_TIMER_DIV != 0) && ~init_calib_complete) ||
// (~(read_this_rank || clear_periodic_rd_request) &&
(~((int_read_this_rank) || (clear_periodic_rd_request && periodic_rd_cntr1_r)) &&
(periodic_rd_request_r || periodic_rd_timer_one)));
always @(posedge clk) periodic_rd_request_r <=
#TCQ periodic_rd_request_ns;
`ifdef MC_SVA
read_clears_periodic_rd_request: cover property (@(posedge clk)
(rst && (periodic_rd_request_r && read_this_rank)));
`endif
assign periodic_rd_request = init_calib_complete && periodic_rd_request_r;
end else
assign periodic_rd_request = 1'b0; //to disable periodic reads
end
endgenerate
endmodule
|
module, since this is a DQ/DQS bus-level requirement,
// not a per-rank requirement.
localparam CASRD2CASWR = CL + (BURST_MODE == "4" ? 2 : 4) + DQRD2DQWR_DLY - CWL;
localparam CASRD2CASWR_CLKS = (nCK_PER_CLK == 1)
? CASRD2CASWR :
(nCK_PER_CLK == 2)
? ((CASRD2CASWR / 2) + (CASRD2CASWR % 2)) :
((CASRD2CASWR / 4) + ((CASRD2CASWR % 4) ? 1 :0));
localparam RTW_CNT_WIDTH = clogb2(CASRD2CASWR_CLKS);
generate
begin : rtw_timer
reg read_this_rank;
always @(/*AS*/sending_col or rd_this_rank_r) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_r;
reg [RTW_CNT_WIDTH-1:0] rtw_cnt_ns;
always @(/*AS*/rst or col_rd_wr or sending_col or rtw_cnt_r)
if (rst) rtw_cnt_ns = {RTW_CNT_WIDTH{1'b0}};
else begin
rtw_cnt_ns = rtw_cnt_r;
if (col_rd_wr && |sending_col) rtw_cnt_ns =
CASRD2CASWR_CLKS[RTW_CNT_WIDTH-1:0] - ONE[RTW_CNT_WIDTH-1:0];
else if (|rtw_cnt_r) rtw_cnt_ns = rtw_cnt_r - ONE[RTW_CNT_WIDTH-1:0];
end
wire inhbt_wr_ns = |rtw_cnt_ns;
always @(posedge clk) rtw_cnt_r <= #TCQ rtw_cnt_ns;
always @(inhbt_wr_ns) inhbt_wr = inhbt_wr_ns;
end
endgenerate
// Refresh request generation. Implement a "refresh bank". Referred
// to as pullin-in refresh in the JEDEC spec.
// The refresh_rank_r counter increments when a refresh to this
// rank has been decoded. In the up direction, the count saturates
// at nREFRESH_BANK. As specified in the JEDEC spec, nREFRESH_BANK
// is normally eight. The counter decrements with each refresh_tick,
// saturating at zero. A refresh will be requests when the rank is
// not busy and refresh_rank_r != nREFRESH_BANK, or refresh_rank_r
// equals zero.
localparam REFRESH_BANK_WIDTH = clogb2(nREFRESH_BANK + 1);
generate begin : refresh_generation
reg my_rank_busy;
always @(/*AS*/rank_busy_r) begin
my_rank_busy = 1'b0;
for (i=0; i < nBANK_MACHS; i=i+1)
my_rank_busy = my_rank_busy || rank_busy_r[(i*RANKS)+ID];
end
wire my_refresh =
insert_maint_r1 && ~maint_zq_r && ~maint_sre_r && ~maint_srx_r &&
(maint_rank_r == ID[RANK_WIDTH-1:0]);
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_r;
reg [REFRESH_BANK_WIDTH-1:0] refresh_bank_ns;
always @(/*AS*/app_ref_req or init_calib_complete or my_refresh
or refresh_bank_r or refresh_tick)
if (~init_calib_complete)
if (REFRESH_TIMER_DIV == 0)
refresh_bank_ns = nREFRESH_BANK[0+:REFRESH_BANK_WIDTH];
else refresh_bank_ns = {REFRESH_BANK_WIDTH{1'b0}};
else
case ({my_refresh, refresh_tick, app_ref_req})
3'b000, 3'b110, 3'b101, 3'b111 : refresh_bank_ns = refresh_bank_r;
3'b010, 3'b001, 3'b011 : refresh_bank_ns =
(|refresh_bank_r)?
refresh_bank_r - ONE[0+:REFRESH_BANK_WIDTH]:
refresh_bank_r;
3'b100 : refresh_bank_ns =
refresh_bank_r + ONE[0+:REFRESH_BANK_WIDTH];
endcase // case ({my_refresh, refresh_tick})
always @(posedge clk) refresh_bank_r <= #TCQ refresh_bank_ns;
`ifdef MC_SVA
refresh_bank_overflow: assert property (@(posedge clk)
(rst || (refresh_bank_r <= nREFRESH_BANK)));
refresh_bank_underflow: assert property (@(posedge clk)
(rst || ~(~|refresh_bank_r && ~my_refresh && refresh_tick)));
refresh_hi_priority: cover property (@(posedge clk)
(rst && ~|refresh_bank_ns && (refresh_bank_r ==
ONE[0+:REFRESH_BANK_WIDTH])));
refresh_bank_full: cover property (@(posedge clk)
(rst && (refresh_bank_r ==
nREFRESH_BANK[0+:REFRESH_BANK_WIDTH])));
`endif
assign refresh_request = init_calib_complete &&
(~|refresh_bank_r ||
((refresh_bank_r != nREFRESH_BANK[0+:REFRESH_BANK_WIDTH]) && ~my_rank_busy));
end
endgenerate
// Periodic read request generation.
localparam PERIODIC_RD_TIMER_WIDTH = clogb2(PERIODIC_RD_TIMER_DIV + /*idle state*/ 1);
generate begin : periodic_rd_generation
if ( PERIODIC_RD_TIMER_DIV != 0 ) begin // enable periodic reads
reg read_this_rank;
always @(/*AS*/rd_this_rank_r or sending_col) begin
read_this_rank = 1'b0;
for (i = 0; i < nBANK_MACHS; i = i + 1)
read_this_rank =
read_this_rank || (sending_col[i] && rd_this_rank_r[(i*RANKS)+ID]);
end
reg read_this_rank_r;
reg read_this_rank_r1;
always @(posedge clk) read_this_rank_r <= #TCQ read_this_rank;
always @(posedge clk) read_this_rank_r1 <= #TCQ read_this_rank_r;
wire int_read_this_rank = read_this_rank &&
(((nCK_PER_CLK == 4) && read_this_rank_r) ||
((nCK_PER_CLK != 4) && read_this_rank_r1));
reg periodic_rd_cntr1_ns;
reg periodic_rd_cntr1_r;
always @(/*AS*/clear_periodic_rd_request or periodic_rd_cntr1_r) begin
periodic_rd_cntr1_ns = periodic_rd_cntr1_r;
if (clear_periodic_rd_request)
periodic_rd_cntr1_ns = periodic_rd_cntr1_r + 1'b1;
end
always @(posedge clk) begin
if (rst) periodic_rd_cntr1_r <= #TCQ 1'b0;
else periodic_rd_cntr1_r <= #TCQ periodic_rd_cntr1_ns;
end
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_r;
reg [PERIODIC_RD_TIMER_WIDTH-1:0] periodic_rd_timer_ns;
always @(/*AS*/init_calib_complete or maint_prescaler_tick_r
or periodic_rd_timer_r or int_read_this_rank) begin
periodic_rd_timer_ns = periodic_rd_timer_r;
if (~init_calib_complete)
periodic_rd_timer_ns = {PERIODIC_RD_TIMER_WIDTH{1'b0}};
else if (int_read_this_rank)
periodic_rd_timer_ns =
PERIODIC_RD_TIMER_DIV[0+:PERIODIC_RD_TIMER_WIDTH];
else if (|periodic_rd_timer_r && maint_prescaler_tick_r)
periodic_rd_timer_ns =
periodic_rd_timer_r - ONE[0+:PERIODIC_RD_TIMER_WIDTH];
end
always @(posedge clk) periodic_rd_timer_r <= #TCQ periodic_rd_timer_ns;
wire periodic_rd_timer_one = maint_prescaler_tick_r &&
(periodic_rd_timer_r == ONE[0+:PERIODIC_RD_TIMER_WIDTH]);
reg periodic_rd_request_r;
wire periodic_rd_request_ns = ~rst &&
((app_periodic_rd_req && init_calib_complete) ||
((PERIODIC_RD_TIMER_DIV != 0) && ~init_calib_complete) ||
// (~(read_this_rank || clear_periodic_rd_request) &&
(~((int_read_this_rank) || (clear_periodic_rd_request && periodic_rd_cntr1_r)) &&
(periodic_rd_request_r || periodic_rd_timer_one)));
always @(posedge clk) periodic_rd_request_r <=
#TCQ periodic_rd_request_ns;
`ifdef MC_SVA
read_clears_periodic_rd_request: cover property (@(posedge clk)
(rst && (periodic_rd_request_r && read_this_rank)));
`endif
assign periodic_rd_request = init_calib_complete && periodic_rd_request_r;
end else
assign periodic_rd_request = 1'b0; //to disable periodic reads
end
endgenerate
endmodule
|
module mig_7series_v2_3_ddr_phy_ocd_edge #
(parameter TCQ = 100)
(/*AUTOARG*/
// Outputs
scan_right, z2f, f2z, o2f, f2o, zero2fuzz, fuzz2zero,
oneeighty2fuzz, fuzz2oneeighty,
// Inputs
clk, samp_done, phy_rddata_en_2, reset_scan, scanning_right,
samp_result, stg3
);
localparam [1:0] NULL = 2'b11,
FUZZ = 2'b00,
ONEEIGHTY = 2'b10,
ZERO = 2'b01;
input clk;
input samp_done;
input phy_rddata_en_2;
wire samp_valid = samp_done && phy_rddata_en_2;
input reset_scan;
input scanning_right;
reg prev_samp_valid_ns, prev_samp_valid_r;
always @(posedge clk) prev_samp_valid_r <= #TCQ prev_samp_valid_ns;
always @(*) begin
prev_samp_valid_ns = prev_samp_valid_r;
if (reset_scan) prev_samp_valid_ns = 1'b0;
else if (samp_valid) prev_samp_valid_ns = 1'b1;
end
input [1:0] samp_result;
reg [1:0] prev_samp_ns, prev_samp_r;
always @(posedge clk) prev_samp_r <= #TCQ prev_samp_ns;
always @(*)
if (samp_valid) prev_samp_ns = samp_result;
else prev_samp_ns = prev_samp_r;
reg scan_right_ns, scan_right_r;
always @(posedge clk) scan_right_r <= #TCQ scan_right_ns;
output scan_right;
assign scan_right = scan_right_r;
input [5:0] stg3;
reg z2f_ns, z2f_r, f2z_ns, f2z_r, o2f_ns, o2f_r, f2o_ns, f2o_r;
always @(posedge clk) z2f_r <= #TCQ z2f_ns;
always @(posedge clk) f2z_r <= #TCQ f2z_ns;
always @(posedge clk) o2f_r <= #TCQ o2f_ns;
always @(posedge clk) f2o_r <= #TCQ f2o_ns;
output z2f, f2z, o2f, f2o;
assign z2f = z2f_r;
assign f2z = f2z_r;
assign o2f = o2f_r;
assign f2o = f2o_r;
reg [5:0] zero2fuzz_ns, zero2fuzz_r, fuzz2zero_ns, fuzz2zero_r,
oneeighty2fuzz_ns, oneeighty2fuzz_r, fuzz2oneeighty_ns, fuzz2oneeighty_r;
always @(posedge clk) zero2fuzz_r <= #TCQ zero2fuzz_ns;
always @(posedge clk) fuzz2zero_r <= #TCQ fuzz2zero_ns;
always @(posedge clk) oneeighty2fuzz_r <= #TCQ oneeighty2fuzz_ns;
always @(posedge clk) fuzz2oneeighty_r <= #TCQ fuzz2oneeighty_ns;
output [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty;
assign zero2fuzz = zero2fuzz_r;
assign fuzz2zero = fuzz2zero_r;
assign oneeighty2fuzz = oneeighty2fuzz_r;
assign fuzz2oneeighty = fuzz2oneeighty_r;
always @(*) begin
z2f_ns = z2f_r;
f2z_ns = f2z_r;
o2f_ns = o2f_r;
f2o_ns = f2o_r;
zero2fuzz_ns = zero2fuzz_r;
fuzz2zero_ns = fuzz2zero_r;
oneeighty2fuzz_ns = oneeighty2fuzz_r;
fuzz2oneeighty_ns = fuzz2oneeighty_r;
scan_right_ns = 1'b0;
if (reset_scan) begin
z2f_ns = 1'b0;
f2z_ns = 1'b0;
o2f_ns = 1'b0;
f2o_ns = 1'b0;
end
else if (samp_valid && prev_samp_valid_r)
case (prev_samp_r)
FUZZ :
if (scanning_right) begin
if (samp_result == ZERO) begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
ZERO : begin
if (samp_result == FUZZ || samp_result == ONEEIGHTY) scan_right_ns = !scanning_right;
if (scanning_right) begin
if (samp_result == FUZZ) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
end
ONEEIGHTY :
if (scanning_right) begin
if (samp_result == FUZZ) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end
if (samp_result == ZERO)
if (f2o_r) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end else begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
end // if (scanning_right)
// NULL : // Should never happen
endcase
end
endmodule
|
module mig_7series_v2_3_ddr_phy_ocd_edge #
(parameter TCQ = 100)
(/*AUTOARG*/
// Outputs
scan_right, z2f, f2z, o2f, f2o, zero2fuzz, fuzz2zero,
oneeighty2fuzz, fuzz2oneeighty,
// Inputs
clk, samp_done, phy_rddata_en_2, reset_scan, scanning_right,
samp_result, stg3
);
localparam [1:0] NULL = 2'b11,
FUZZ = 2'b00,
ONEEIGHTY = 2'b10,
ZERO = 2'b01;
input clk;
input samp_done;
input phy_rddata_en_2;
wire samp_valid = samp_done && phy_rddata_en_2;
input reset_scan;
input scanning_right;
reg prev_samp_valid_ns, prev_samp_valid_r;
always @(posedge clk) prev_samp_valid_r <= #TCQ prev_samp_valid_ns;
always @(*) begin
prev_samp_valid_ns = prev_samp_valid_r;
if (reset_scan) prev_samp_valid_ns = 1'b0;
else if (samp_valid) prev_samp_valid_ns = 1'b1;
end
input [1:0] samp_result;
reg [1:0] prev_samp_ns, prev_samp_r;
always @(posedge clk) prev_samp_r <= #TCQ prev_samp_ns;
always @(*)
if (samp_valid) prev_samp_ns = samp_result;
else prev_samp_ns = prev_samp_r;
reg scan_right_ns, scan_right_r;
always @(posedge clk) scan_right_r <= #TCQ scan_right_ns;
output scan_right;
assign scan_right = scan_right_r;
input [5:0] stg3;
reg z2f_ns, z2f_r, f2z_ns, f2z_r, o2f_ns, o2f_r, f2o_ns, f2o_r;
always @(posedge clk) z2f_r <= #TCQ z2f_ns;
always @(posedge clk) f2z_r <= #TCQ f2z_ns;
always @(posedge clk) o2f_r <= #TCQ o2f_ns;
always @(posedge clk) f2o_r <= #TCQ f2o_ns;
output z2f, f2z, o2f, f2o;
assign z2f = z2f_r;
assign f2z = f2z_r;
assign o2f = o2f_r;
assign f2o = f2o_r;
reg [5:0] zero2fuzz_ns, zero2fuzz_r, fuzz2zero_ns, fuzz2zero_r,
oneeighty2fuzz_ns, oneeighty2fuzz_r, fuzz2oneeighty_ns, fuzz2oneeighty_r;
always @(posedge clk) zero2fuzz_r <= #TCQ zero2fuzz_ns;
always @(posedge clk) fuzz2zero_r <= #TCQ fuzz2zero_ns;
always @(posedge clk) oneeighty2fuzz_r <= #TCQ oneeighty2fuzz_ns;
always @(posedge clk) fuzz2oneeighty_r <= #TCQ fuzz2oneeighty_ns;
output [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty;
assign zero2fuzz = zero2fuzz_r;
assign fuzz2zero = fuzz2zero_r;
assign oneeighty2fuzz = oneeighty2fuzz_r;
assign fuzz2oneeighty = fuzz2oneeighty_r;
always @(*) begin
z2f_ns = z2f_r;
f2z_ns = f2z_r;
o2f_ns = o2f_r;
f2o_ns = f2o_r;
zero2fuzz_ns = zero2fuzz_r;
fuzz2zero_ns = fuzz2zero_r;
oneeighty2fuzz_ns = oneeighty2fuzz_r;
fuzz2oneeighty_ns = fuzz2oneeighty_r;
scan_right_ns = 1'b0;
if (reset_scan) begin
z2f_ns = 1'b0;
f2z_ns = 1'b0;
o2f_ns = 1'b0;
f2o_ns = 1'b0;
end
else if (samp_valid && prev_samp_valid_r)
case (prev_samp_r)
FUZZ :
if (scanning_right) begin
if (samp_result == ZERO) begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
ZERO : begin
if (samp_result == FUZZ || samp_result == ONEEIGHTY) scan_right_ns = !scanning_right;
if (scanning_right) begin
if (samp_result == FUZZ) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
end
ONEEIGHTY :
if (scanning_right) begin
if (samp_result == FUZZ) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end
if (samp_result == ZERO)
if (f2o_r) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end else begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
end // if (scanning_right)
// NULL : // Should never happen
endcase
end
endmodule
|
module mig_7series_v2_3_ddr_phy_ocd_edge #
(parameter TCQ = 100)
(/*AUTOARG*/
// Outputs
scan_right, z2f, f2z, o2f, f2o, zero2fuzz, fuzz2zero,
oneeighty2fuzz, fuzz2oneeighty,
// Inputs
clk, samp_done, phy_rddata_en_2, reset_scan, scanning_right,
samp_result, stg3
);
localparam [1:0] NULL = 2'b11,
FUZZ = 2'b00,
ONEEIGHTY = 2'b10,
ZERO = 2'b01;
input clk;
input samp_done;
input phy_rddata_en_2;
wire samp_valid = samp_done && phy_rddata_en_2;
input reset_scan;
input scanning_right;
reg prev_samp_valid_ns, prev_samp_valid_r;
always @(posedge clk) prev_samp_valid_r <= #TCQ prev_samp_valid_ns;
always @(*) begin
prev_samp_valid_ns = prev_samp_valid_r;
if (reset_scan) prev_samp_valid_ns = 1'b0;
else if (samp_valid) prev_samp_valid_ns = 1'b1;
end
input [1:0] samp_result;
reg [1:0] prev_samp_ns, prev_samp_r;
always @(posedge clk) prev_samp_r <= #TCQ prev_samp_ns;
always @(*)
if (samp_valid) prev_samp_ns = samp_result;
else prev_samp_ns = prev_samp_r;
reg scan_right_ns, scan_right_r;
always @(posedge clk) scan_right_r <= #TCQ scan_right_ns;
output scan_right;
assign scan_right = scan_right_r;
input [5:0] stg3;
reg z2f_ns, z2f_r, f2z_ns, f2z_r, o2f_ns, o2f_r, f2o_ns, f2o_r;
always @(posedge clk) z2f_r <= #TCQ z2f_ns;
always @(posedge clk) f2z_r <= #TCQ f2z_ns;
always @(posedge clk) o2f_r <= #TCQ o2f_ns;
always @(posedge clk) f2o_r <= #TCQ f2o_ns;
output z2f, f2z, o2f, f2o;
assign z2f = z2f_r;
assign f2z = f2z_r;
assign o2f = o2f_r;
assign f2o = f2o_r;
reg [5:0] zero2fuzz_ns, zero2fuzz_r, fuzz2zero_ns, fuzz2zero_r,
oneeighty2fuzz_ns, oneeighty2fuzz_r, fuzz2oneeighty_ns, fuzz2oneeighty_r;
always @(posedge clk) zero2fuzz_r <= #TCQ zero2fuzz_ns;
always @(posedge clk) fuzz2zero_r <= #TCQ fuzz2zero_ns;
always @(posedge clk) oneeighty2fuzz_r <= #TCQ oneeighty2fuzz_ns;
always @(posedge clk) fuzz2oneeighty_r <= #TCQ fuzz2oneeighty_ns;
output [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty;
assign zero2fuzz = zero2fuzz_r;
assign fuzz2zero = fuzz2zero_r;
assign oneeighty2fuzz = oneeighty2fuzz_r;
assign fuzz2oneeighty = fuzz2oneeighty_r;
always @(*) begin
z2f_ns = z2f_r;
f2z_ns = f2z_r;
o2f_ns = o2f_r;
f2o_ns = f2o_r;
zero2fuzz_ns = zero2fuzz_r;
fuzz2zero_ns = fuzz2zero_r;
oneeighty2fuzz_ns = oneeighty2fuzz_r;
fuzz2oneeighty_ns = fuzz2oneeighty_r;
scan_right_ns = 1'b0;
if (reset_scan) begin
z2f_ns = 1'b0;
f2z_ns = 1'b0;
o2f_ns = 1'b0;
f2o_ns = 1'b0;
end
else if (samp_valid && prev_samp_valid_r)
case (prev_samp_r)
FUZZ :
if (scanning_right) begin
if (samp_result == ZERO) begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
ZERO : begin
if (samp_result == FUZZ || samp_result == ONEEIGHTY) scan_right_ns = !scanning_right;
if (scanning_right) begin
if (samp_result == FUZZ) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
end
ONEEIGHTY :
if (scanning_right) begin
if (samp_result == FUZZ) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end
if (samp_result == ZERO)
if (f2o_r) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end else begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
end // if (scanning_right)
// NULL : // Should never happen
endcase
end
endmodule
|
module mig_7series_v2_3_ddr_phy_ocd_edge #
(parameter TCQ = 100)
(/*AUTOARG*/
// Outputs
scan_right, z2f, f2z, o2f, f2o, zero2fuzz, fuzz2zero,
oneeighty2fuzz, fuzz2oneeighty,
// Inputs
clk, samp_done, phy_rddata_en_2, reset_scan, scanning_right,
samp_result, stg3
);
localparam [1:0] NULL = 2'b11,
FUZZ = 2'b00,
ONEEIGHTY = 2'b10,
ZERO = 2'b01;
input clk;
input samp_done;
input phy_rddata_en_2;
wire samp_valid = samp_done && phy_rddata_en_2;
input reset_scan;
input scanning_right;
reg prev_samp_valid_ns, prev_samp_valid_r;
always @(posedge clk) prev_samp_valid_r <= #TCQ prev_samp_valid_ns;
always @(*) begin
prev_samp_valid_ns = prev_samp_valid_r;
if (reset_scan) prev_samp_valid_ns = 1'b0;
else if (samp_valid) prev_samp_valid_ns = 1'b1;
end
input [1:0] samp_result;
reg [1:0] prev_samp_ns, prev_samp_r;
always @(posedge clk) prev_samp_r <= #TCQ prev_samp_ns;
always @(*)
if (samp_valid) prev_samp_ns = samp_result;
else prev_samp_ns = prev_samp_r;
reg scan_right_ns, scan_right_r;
always @(posedge clk) scan_right_r <= #TCQ scan_right_ns;
output scan_right;
assign scan_right = scan_right_r;
input [5:0] stg3;
reg z2f_ns, z2f_r, f2z_ns, f2z_r, o2f_ns, o2f_r, f2o_ns, f2o_r;
always @(posedge clk) z2f_r <= #TCQ z2f_ns;
always @(posedge clk) f2z_r <= #TCQ f2z_ns;
always @(posedge clk) o2f_r <= #TCQ o2f_ns;
always @(posedge clk) f2o_r <= #TCQ f2o_ns;
output z2f, f2z, o2f, f2o;
assign z2f = z2f_r;
assign f2z = f2z_r;
assign o2f = o2f_r;
assign f2o = f2o_r;
reg [5:0] zero2fuzz_ns, zero2fuzz_r, fuzz2zero_ns, fuzz2zero_r,
oneeighty2fuzz_ns, oneeighty2fuzz_r, fuzz2oneeighty_ns, fuzz2oneeighty_r;
always @(posedge clk) zero2fuzz_r <= #TCQ zero2fuzz_ns;
always @(posedge clk) fuzz2zero_r <= #TCQ fuzz2zero_ns;
always @(posedge clk) oneeighty2fuzz_r <= #TCQ oneeighty2fuzz_ns;
always @(posedge clk) fuzz2oneeighty_r <= #TCQ fuzz2oneeighty_ns;
output [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty;
assign zero2fuzz = zero2fuzz_r;
assign fuzz2zero = fuzz2zero_r;
assign oneeighty2fuzz = oneeighty2fuzz_r;
assign fuzz2oneeighty = fuzz2oneeighty_r;
always @(*) begin
z2f_ns = z2f_r;
f2z_ns = f2z_r;
o2f_ns = o2f_r;
f2o_ns = f2o_r;
zero2fuzz_ns = zero2fuzz_r;
fuzz2zero_ns = fuzz2zero_r;
oneeighty2fuzz_ns = oneeighty2fuzz_r;
fuzz2oneeighty_ns = fuzz2oneeighty_r;
scan_right_ns = 1'b0;
if (reset_scan) begin
z2f_ns = 1'b0;
f2z_ns = 1'b0;
o2f_ns = 1'b0;
f2o_ns = 1'b0;
end
else if (samp_valid && prev_samp_valid_r)
case (prev_samp_r)
FUZZ :
if (scanning_right) begin
if (samp_result == ZERO) begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
ZERO : begin
if (samp_result == FUZZ || samp_result == ONEEIGHTY) scan_right_ns = !scanning_right;
if (scanning_right) begin
if (samp_result == FUZZ) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
end
ONEEIGHTY :
if (scanning_right) begin
if (samp_result == FUZZ) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end
if (samp_result == ZERO)
if (f2o_r) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end else begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
end // if (scanning_right)
// NULL : // Should never happen
endcase
end
endmodule
|
module mig_7series_v2_3_ddr_phy_ocd_edge #
(parameter TCQ = 100)
(/*AUTOARG*/
// Outputs
scan_right, z2f, f2z, o2f, f2o, zero2fuzz, fuzz2zero,
oneeighty2fuzz, fuzz2oneeighty,
// Inputs
clk, samp_done, phy_rddata_en_2, reset_scan, scanning_right,
samp_result, stg3
);
localparam [1:0] NULL = 2'b11,
FUZZ = 2'b00,
ONEEIGHTY = 2'b10,
ZERO = 2'b01;
input clk;
input samp_done;
input phy_rddata_en_2;
wire samp_valid = samp_done && phy_rddata_en_2;
input reset_scan;
input scanning_right;
reg prev_samp_valid_ns, prev_samp_valid_r;
always @(posedge clk) prev_samp_valid_r <= #TCQ prev_samp_valid_ns;
always @(*) begin
prev_samp_valid_ns = prev_samp_valid_r;
if (reset_scan) prev_samp_valid_ns = 1'b0;
else if (samp_valid) prev_samp_valid_ns = 1'b1;
end
input [1:0] samp_result;
reg [1:0] prev_samp_ns, prev_samp_r;
always @(posedge clk) prev_samp_r <= #TCQ prev_samp_ns;
always @(*)
if (samp_valid) prev_samp_ns = samp_result;
else prev_samp_ns = prev_samp_r;
reg scan_right_ns, scan_right_r;
always @(posedge clk) scan_right_r <= #TCQ scan_right_ns;
output scan_right;
assign scan_right = scan_right_r;
input [5:0] stg3;
reg z2f_ns, z2f_r, f2z_ns, f2z_r, o2f_ns, o2f_r, f2o_ns, f2o_r;
always @(posedge clk) z2f_r <= #TCQ z2f_ns;
always @(posedge clk) f2z_r <= #TCQ f2z_ns;
always @(posedge clk) o2f_r <= #TCQ o2f_ns;
always @(posedge clk) f2o_r <= #TCQ f2o_ns;
output z2f, f2z, o2f, f2o;
assign z2f = z2f_r;
assign f2z = f2z_r;
assign o2f = o2f_r;
assign f2o = f2o_r;
reg [5:0] zero2fuzz_ns, zero2fuzz_r, fuzz2zero_ns, fuzz2zero_r,
oneeighty2fuzz_ns, oneeighty2fuzz_r, fuzz2oneeighty_ns, fuzz2oneeighty_r;
always @(posedge clk) zero2fuzz_r <= #TCQ zero2fuzz_ns;
always @(posedge clk) fuzz2zero_r <= #TCQ fuzz2zero_ns;
always @(posedge clk) oneeighty2fuzz_r <= #TCQ oneeighty2fuzz_ns;
always @(posedge clk) fuzz2oneeighty_r <= #TCQ fuzz2oneeighty_ns;
output [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty;
assign zero2fuzz = zero2fuzz_r;
assign fuzz2zero = fuzz2zero_r;
assign oneeighty2fuzz = oneeighty2fuzz_r;
assign fuzz2oneeighty = fuzz2oneeighty_r;
always @(*) begin
z2f_ns = z2f_r;
f2z_ns = f2z_r;
o2f_ns = o2f_r;
f2o_ns = f2o_r;
zero2fuzz_ns = zero2fuzz_r;
fuzz2zero_ns = fuzz2zero_r;
oneeighty2fuzz_ns = oneeighty2fuzz_r;
fuzz2oneeighty_ns = fuzz2oneeighty_r;
scan_right_ns = 1'b0;
if (reset_scan) begin
z2f_ns = 1'b0;
f2z_ns = 1'b0;
o2f_ns = 1'b0;
f2o_ns = 1'b0;
end
else if (samp_valid && prev_samp_valid_r)
case (prev_samp_r)
FUZZ :
if (scanning_right) begin
if (samp_result == ZERO) begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
ZERO : begin
if (samp_result == FUZZ || samp_result == ONEEIGHTY) scan_right_ns = !scanning_right;
if (scanning_right) begin
if (samp_result == FUZZ) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
end
ONEEIGHTY :
if (scanning_right) begin
if (samp_result == FUZZ) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end
if (samp_result == ZERO)
if (f2o_r) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end else begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
end // if (scanning_right)
// NULL : // Should never happen
endcase
end
endmodule
|
module mig_7series_v2_3_ddr_phy_ocd_edge #
(parameter TCQ = 100)
(/*AUTOARG*/
// Outputs
scan_right, z2f, f2z, o2f, f2o, zero2fuzz, fuzz2zero,
oneeighty2fuzz, fuzz2oneeighty,
// Inputs
clk, samp_done, phy_rddata_en_2, reset_scan, scanning_right,
samp_result, stg3
);
localparam [1:0] NULL = 2'b11,
FUZZ = 2'b00,
ONEEIGHTY = 2'b10,
ZERO = 2'b01;
input clk;
input samp_done;
input phy_rddata_en_2;
wire samp_valid = samp_done && phy_rddata_en_2;
input reset_scan;
input scanning_right;
reg prev_samp_valid_ns, prev_samp_valid_r;
always @(posedge clk) prev_samp_valid_r <= #TCQ prev_samp_valid_ns;
always @(*) begin
prev_samp_valid_ns = prev_samp_valid_r;
if (reset_scan) prev_samp_valid_ns = 1'b0;
else if (samp_valid) prev_samp_valid_ns = 1'b1;
end
input [1:0] samp_result;
reg [1:0] prev_samp_ns, prev_samp_r;
always @(posedge clk) prev_samp_r <= #TCQ prev_samp_ns;
always @(*)
if (samp_valid) prev_samp_ns = samp_result;
else prev_samp_ns = prev_samp_r;
reg scan_right_ns, scan_right_r;
always @(posedge clk) scan_right_r <= #TCQ scan_right_ns;
output scan_right;
assign scan_right = scan_right_r;
input [5:0] stg3;
reg z2f_ns, z2f_r, f2z_ns, f2z_r, o2f_ns, o2f_r, f2o_ns, f2o_r;
always @(posedge clk) z2f_r <= #TCQ z2f_ns;
always @(posedge clk) f2z_r <= #TCQ f2z_ns;
always @(posedge clk) o2f_r <= #TCQ o2f_ns;
always @(posedge clk) f2o_r <= #TCQ f2o_ns;
output z2f, f2z, o2f, f2o;
assign z2f = z2f_r;
assign f2z = f2z_r;
assign o2f = o2f_r;
assign f2o = f2o_r;
reg [5:0] zero2fuzz_ns, zero2fuzz_r, fuzz2zero_ns, fuzz2zero_r,
oneeighty2fuzz_ns, oneeighty2fuzz_r, fuzz2oneeighty_ns, fuzz2oneeighty_r;
always @(posedge clk) zero2fuzz_r <= #TCQ zero2fuzz_ns;
always @(posedge clk) fuzz2zero_r <= #TCQ fuzz2zero_ns;
always @(posedge clk) oneeighty2fuzz_r <= #TCQ oneeighty2fuzz_ns;
always @(posedge clk) fuzz2oneeighty_r <= #TCQ fuzz2oneeighty_ns;
output [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty;
assign zero2fuzz = zero2fuzz_r;
assign fuzz2zero = fuzz2zero_r;
assign oneeighty2fuzz = oneeighty2fuzz_r;
assign fuzz2oneeighty = fuzz2oneeighty_r;
always @(*) begin
z2f_ns = z2f_r;
f2z_ns = f2z_r;
o2f_ns = o2f_r;
f2o_ns = f2o_r;
zero2fuzz_ns = zero2fuzz_r;
fuzz2zero_ns = fuzz2zero_r;
oneeighty2fuzz_ns = oneeighty2fuzz_r;
fuzz2oneeighty_ns = fuzz2oneeighty_r;
scan_right_ns = 1'b0;
if (reset_scan) begin
z2f_ns = 1'b0;
f2z_ns = 1'b0;
o2f_ns = 1'b0;
f2o_ns = 1'b0;
end
else if (samp_valid && prev_samp_valid_r)
case (prev_samp_r)
FUZZ :
if (scanning_right) begin
if (samp_result == ZERO) begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
ZERO : begin
if (samp_result == FUZZ || samp_result == ONEEIGHTY) scan_right_ns = !scanning_right;
if (scanning_right) begin
if (samp_result == FUZZ) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
end
if (samp_result == ONEEIGHTY) begin
zero2fuzz_ns = stg3 - 6'b1;
z2f_ns = 1'b1;
fuzz2oneeighty_ns = stg3;
f2o_ns = 1'b1;
end
end
end
ONEEIGHTY :
if (scanning_right) begin
if (samp_result == FUZZ) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end
if (samp_result == ZERO)
if (f2o_r) begin
oneeighty2fuzz_ns = stg3 - 6'b1;
o2f_ns = 1'b1;
end else begin
fuzz2zero_ns = stg3;
f2z_ns = 1'b1;
end
end // if (scanning_right)
// NULL : // Should never happen
endcase
end
endmodule
|
module mig_7series_v2_3_ddr_phy_rdlvl #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter nCK_PER_CLK = 2, // # of memory clocks per CLK
parameter CLK_PERIOD = 3333, // Internal clock period (in ps)
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter RANKS = 1, // # of DRAM ranks
parameter PER_BIT_DESKEW = "ON", // Enable per-bit DQ deskew
parameter SIM_CAL_OPTION = "NONE", // Skip various calibration steps
parameter DEBUG_PORT = "OFF", // Enable debug port
parameter DRAM_TYPE = "DDR3", // Memory I/F type: "DDR3", "DDR2"
parameter OCAL_EN = "ON",
parameter IDELAY_ADJ = "ON"
)
(
input clk,
input rst,
// Calibration status, control signals
input mpr_rdlvl_start,
output mpr_rdlvl_done,
output reg mpr_last_byte_done,
output mpr_rnk_done,
input rdlvl_stg1_start,
output reg rdlvl_stg1_done /* synthesis syn_maxfan = 30 */,
output rdlvl_stg1_rnk_done,
output reg rdlvl_stg1_err,
output mpr_rdlvl_err,
output rdlvl_err,
output reg rdlvl_prech_req,
output reg rdlvl_last_byte_done,
output reg rdlvl_assrt_common,
input prech_done,
input phy_if_empty,
input [4:0] idelaye2_init_val,
// Captured data in fabric clock domain
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] rd_data,
// Decrement initial Phaser_IN Fine tap delay
input dqs_po_dec_done,
input [5:0] pi_counter_read_val,
// Stage 1 calibration outputs
output reg pi_fine_dly_dec_done,
output reg pi_en_stg2_f,
output reg pi_stg2_f_incdec,
output reg pi_stg2_load,
output reg [5:0] pi_stg2_reg_l,
output [DQS_CNT_WIDTH:0] pi_stg2_rdlvl_cnt,
// To DQ IDELAY required to find left edge of
// valid window
output idelay_ce,
output idelay_inc,
input idelay_ld,
input [DQS_CNT_WIDTH:0] wrcal_cnt,
// Only output if Per-bit de-skew enabled
output reg [5*RANKS*DQ_WIDTH-1:0] dlyval_dq,
// Debug Port
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_first_edge_cnt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_second_edge_cnt,
output [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_tap_cnt,
output [5*DQS_WIDTH*RANKS-1:0] dbg_dq_idelay_tap_cnt,
input dbg_idel_up_all,
input dbg_idel_down_all,
input dbg_idel_up_cpt,
input dbg_idel_down_cpt,
input [DQS_CNT_WIDTH-1:0] dbg_sel_idel_cpt,
input dbg_sel_all_idel_cpt,
output [255:0] dbg_phy_rdlvl
);
// minimum time (in IDELAY taps) for which capture data must be stable for
// algorithm to consider a valid data eye to be found. The read leveling
// logic will ignore any window found smaller than this value. Limitations
// on how small this number can be is determined by: (1) the algorithmic
// limitation of how many taps wide the data eye can be (3 taps), and (2)
// how wide regions of "instability" that occur around the edges of the
// read valid window can be (i.e. need to be able to filter out "false"
// windows that occur for a short # of taps around the edges of the true
// data window, although with multi-sampling during read leveling, this is
// not as much a concern) - the larger the value, the more protection
// against "false" windows
localparam MIN_EYE_SIZE = 16;
// Length of calibration sequence (in # of words)
localparam CAL_PAT_LEN = 8;
// Read data shift register length
localparam RD_SHIFT_LEN = CAL_PAT_LEN / (2*nCK_PER_CLK);
// # of cycles required to perform read data shift register compare
// This is defined as from the cycle the new data is loaded until
// signal found_edge_r is valid
localparam RD_SHIFT_COMP_DELAY = 5;
// worst-case # of cycles to wait to ensure that both the SR and
// PREV_SR shift registers have valid data, and that the comparison
// of the two shift register values is valid. The "+1" at the end of
// this equation is a fudge factor, I freely admit that
localparam SR_VALID_DELAY = (2 * RD_SHIFT_LEN) + RD_SHIFT_COMP_DELAY + 1;
// # of clock cycles to wait after changing tap value or read data MUX
// to allow: (1) tap chain to settle, (2) for delayed input to propagate
// thru ISERDES, (3) for the read data comparison logic to have time to
// output the comparison of two consecutive samples of the settled read data
// The minimum delay is 16 cycles, which should be good enough to handle all
// three of the above conditions for the simulation-only case with a short
// training pattern. For H/W (or for simulation with longer training
// pattern), it will take longer to store and compare two consecutive
// samples, and the value of this parameter will reflect that
localparam PIPE_WAIT_CNT = (SR_VALID_DELAY < 8) ? 16 : (SR_VALID_DELAY + 8);
// # of read data samples to examine when detecting whether an edge has
// occured during stage 1 calibration. Width of local param must be
// changed as appropriate. Note that there are two counters used, each
// counter can be changed independently of the other - they are used in
// cascade to create a larger counter
localparam [11:0] DETECT_EDGE_SAMPLE_CNT0 = 12'h001; //12'hFFF;
localparam [11:0] DETECT_EDGE_SAMPLE_CNT1 = 12'h001; // 12'h1FF Must be > 0
localparam [5:0] CAL1_IDLE = 6'h00;
localparam [5:0] CAL1_NEW_DQS_WAIT = 6'h01;
localparam [5:0] CAL1_STORE_FIRST_WAIT = 6'h02;
localparam [5:0] CAL1_PAT_DETECT = 6'h03;
localparam [5:0] CAL1_DQ_IDEL_TAP_INC = 6'h04;
localparam [5:0] CAL1_DQ_IDEL_TAP_INC_WAIT = 6'h05;
localparam [5:0] CAL1_DQ_IDEL_TAP_DEC = 6'h06;
localparam [5:0] CAL1_DQ_IDEL_TAP_DEC_WAIT = 6'h07;
localparam [5:0] CAL1_DETECT_EDGE = 6'h08;
localparam [5:0] CAL1_IDEL_INC_CPT = 6'h09;
localparam [5:0] CAL1_IDEL_INC_CPT_WAIT = 6'h0A;
localparam [5:0] CAL1_CALC_IDEL = 6'h0B;
localparam [5:0] CAL1_IDEL_DEC_CPT = 6'h0C;
localparam [5:0] CAL1_IDEL_DEC_CPT_WAIT = 6'h0D;
localparam [5:0] CAL1_NEXT_DQS = 6'h0E;
localparam [5:0] CAL1_DONE = 6'h0F;
localparam [5:0] CAL1_PB_STORE_FIRST_WAIT = 6'h10;
localparam [5:0] CAL1_PB_DETECT_EDGE = 6'h11;
localparam [5:0] CAL1_PB_INC_CPT = 6'h12;
localparam [5:0] CAL1_PB_INC_CPT_WAIT = 6'h13;
localparam [5:0] CAL1_PB_DEC_CPT_LEFT = 6'h14;
localparam [5:0] CAL1_PB_DEC_CPT_LEFT_WAIT = 6'h15;
localparam [5:0] CAL1_PB_DETECT_EDGE_DQ = 6'h16;
localparam [5:0] CAL1_PB_INC_DQ = 6'h17;
localparam [5:0] CAL1_PB_INC_DQ_WAIT = 6'h18;
localparam [5:0] CAL1_PB_DEC_CPT = 6'h19;
localparam [5:0] CAL1_PB_DEC_CPT_WAIT = 6'h1A;
localparam [5:0] CAL1_REGL_LOAD = 6'h1B;
localparam [5:0] CAL1_RDLVL_ERR = 6'h1C;
localparam [5:0] CAL1_MPR_NEW_DQS_WAIT = 6'h1D;
localparam [5:0] CAL1_VALID_WAIT = 6'h1E;
localparam [5:0] CAL1_MPR_PAT_DETECT = 6'h1F;
localparam [5:0] CAL1_NEW_DQS_PREWAIT = 6'h20;
integer a;
integer b;
integer d;
integer e;
integer f;
integer h;
integer g;
integer i;
integer j;
integer k;
integer l;
integer m;
integer n;
integer r;
integer p;
integer q;
integer s;
integer t;
integer u;
integer w;
integer ce_i;
integer ce_rnk_i;
integer aa;
integer bb;
integer cc;
integer dd;
genvar x;
genvar z;
reg [DQS_CNT_WIDTH:0] cal1_cnt_cpt_r;
wire [DQS_CNT_WIDTH+2:0]cal1_cnt_cpt_timing;
reg [DQS_CNT_WIDTH:0] cal1_cnt_cpt_timing_r;
reg cal1_dq_idel_ce;
reg cal1_dq_idel_inc;
reg cal1_dlyce_cpt_r;
reg cal1_dlyinc_cpt_r;
reg cal1_dlyce_dq_r;
reg cal1_dlyinc_dq_r;
reg cal1_wait_cnt_en_r;
reg [4:0] cal1_wait_cnt_r;
reg cal1_wait_r;
reg [DQ_WIDTH-1:0] dlyce_dq_r;
reg dlyinc_dq_r;
reg [4:0] dlyval_dq_reg_r [0:RANKS-1][0:DQ_WIDTH-1];
reg cal1_prech_req_r;
reg [5:0] cal1_state_r;
reg [5:0] cal1_state_r1;
reg [5:0] cnt_idel_dec_cpt_r;
reg [3:0] cnt_shift_r;
reg detect_edge_done_r;
reg [5:0] right_edge_taps_r;
reg [5:0] first_edge_taps_r;
reg found_edge_r;
reg found_first_edge_r;
reg found_second_edge_r;
reg found_stable_eye_r;
reg found_stable_eye_last_r;
reg found_edge_all_r;
reg [5:0] tap_cnt_cpt_r;
reg tap_limit_cpt_r;
reg [4:0] idel_tap_cnt_dq_pb_r;
reg idel_tap_limit_dq_pb_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r;
reg mux_rd_valid_r;
reg new_cnt_cpt_r;
reg [RD_SHIFT_LEN-1:0] old_sr_fall0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] old_sr_fall1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] old_sr_rise0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] old_sr_rise1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] old_sr_fall2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] old_sr_fall3_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] old_sr_rise2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] old_sr_rise3_r [DRAM_WIDTH-1:0];
reg [DRAM_WIDTH-1:0] old_sr_match_fall0_r;
reg [DRAM_WIDTH-1:0] old_sr_match_fall1_r;
reg [DRAM_WIDTH-1:0] old_sr_match_rise0_r;
reg [DRAM_WIDTH-1:0] old_sr_match_rise1_r;
reg [DRAM_WIDTH-1:0] old_sr_match_fall2_r;
reg [DRAM_WIDTH-1:0] old_sr_match_fall3_r;
reg [DRAM_WIDTH-1:0] old_sr_match_rise2_r;
reg [DRAM_WIDTH-1:0] old_sr_match_rise3_r;
reg [4:0] pb_cnt_eye_size_r [DRAM_WIDTH-1:0];
reg [DRAM_WIDTH-1:0] pb_detect_edge_done_r;
reg [DRAM_WIDTH-1:0] pb_found_edge_last_r;
reg [DRAM_WIDTH-1:0] pb_found_edge_r;
reg [DRAM_WIDTH-1:0] pb_found_first_edge_r;
reg [DRAM_WIDTH-1:0] pb_found_stable_eye_r;
reg [DRAM_WIDTH-1:0] pb_last_tap_jitter_r;
reg pi_en_stg2_f_timing;
reg pi_stg2_f_incdec_timing;
reg pi_stg2_load_timing;
reg [5:0] pi_stg2_reg_l_timing;
reg [DRAM_WIDTH-1:0] prev_sr_diff_r;
reg [RD_SHIFT_LEN-1:0] prev_sr_fall0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] prev_sr_fall1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] prev_sr_rise0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] prev_sr_rise1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] prev_sr_fall2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] prev_sr_fall3_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] prev_sr_rise2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] prev_sr_rise3_r [DRAM_WIDTH-1:0];
reg [DRAM_WIDTH-1:0] prev_sr_match_cyc2_r;
reg [DRAM_WIDTH-1:0] prev_sr_match_fall0_r;
reg [DRAM_WIDTH-1:0] prev_sr_match_fall1_r;
reg [DRAM_WIDTH-1:0] prev_sr_match_rise0_r;
reg [DRAM_WIDTH-1:0] prev_sr_match_rise1_r;
reg [DRAM_WIDTH-1:0] prev_sr_match_fall2_r;
reg [DRAM_WIDTH-1:0] prev_sr_match_fall3_r;
reg [DRAM_WIDTH-1:0] prev_sr_match_rise2_r;
reg [DRAM_WIDTH-1:0] prev_sr_match_rise3_r;
wire [DQ_WIDTH-1:0] rd_data_rise0;
wire [DQ_WIDTH-1:0] rd_data_fall0;
wire [DQ_WIDTH-1:0] rd_data_rise1;
wire [DQ_WIDTH-1:0] rd_data_fall1;
wire [DQ_WIDTH-1:0] rd_data_rise2;
wire [DQ_WIDTH-1:0] rd_data_fall2;
wire [DQ_WIDTH-1:0] rd_data_rise3;
wire [DQ_WIDTH-1:0] rd_data_fall3;
reg samp_cnt_done_r;
reg samp_edge_cnt0_en_r;
reg [11:0] samp_edge_cnt0_r;
reg samp_edge_cnt1_en_r;
reg [11:0] samp_edge_cnt1_r;
reg [DQS_CNT_WIDTH:0] rd_mux_sel_r;
reg [5:0] second_edge_taps_r;
reg [RD_SHIFT_LEN-1:0] sr_fall0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall3_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise3_r [DRAM_WIDTH-1:0];
reg store_sr_r;
reg store_sr_req_pulsed_r;
reg store_sr_req_r;
reg sr_valid_r;
reg sr_valid_r1;
reg sr_valid_r2;
reg [DRAM_WIDTH-1:0] old_sr_diff_r;
reg [DRAM_WIDTH-1:0] old_sr_match_cyc2_r;
reg pat0_data_match_r;
reg pat1_data_match_r;
wire pat_data_match_r;
wire [RD_SHIFT_LEN-1:0] pat0_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat0_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat0_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat0_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall3 [3:0];
reg [DRAM_WIDTH-1:0] pat0_match_fall0_r;
reg pat0_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] pat0_match_fall1_r;
reg pat0_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] pat0_match_fall2_r;
reg pat0_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] pat0_match_fall3_r;
reg pat0_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] pat0_match_rise0_r;
reg pat0_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] pat0_match_rise1_r;
reg pat0_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] pat0_match_rise2_r;
reg pat0_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] pat0_match_rise3_r;
reg pat0_match_rise3_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall0_r;
reg pat1_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall1_r;
reg pat1_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall2_r;
reg pat1_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall3_r;
reg pat1_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise0_r;
reg pat1_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise1_r;
reg pat1_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise2_r;
reg pat1_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise3_r;
reg pat1_match_rise3_and_r;
reg [4:0] idelay_tap_cnt_r [0:RANKS-1][0:DQS_WIDTH-1];
reg [5*DQS_WIDTH*RANKS-1:0] idelay_tap_cnt_w;
reg [4:0] idelay_tap_cnt_slice_r;
reg idelay_tap_limit_r;
wire [RD_SHIFT_LEN-1:0] pat0_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat0_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat0_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat0_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat0_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat0_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat0_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat0_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat0_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat0_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat0_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat0_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat1_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat1_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat1_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] idel_pat1_fall3 [3:0];
reg [DRAM_WIDTH-1:0] idel_pat0_match_rise0_r;
reg [DRAM_WIDTH-1:0] idel_pat0_match_fall0_r;
reg [DRAM_WIDTH-1:0] idel_pat0_match_rise1_r;
reg [DRAM_WIDTH-1:0] idel_pat0_match_fall1_r;
reg [DRAM_WIDTH-1:0] idel_pat0_match_rise2_r;
reg [DRAM_WIDTH-1:0] idel_pat0_match_fall2_r;
reg [DRAM_WIDTH-1:0] idel_pat0_match_rise3_r;
reg [DRAM_WIDTH-1:0] idel_pat0_match_fall3_r;
reg [DRAM_WIDTH-1:0] idel_pat1_match_rise0_r;
reg [DRAM_WIDTH-1:0] idel_pat1_match_fall0_r;
reg [DRAM_WIDTH-1:0] idel_pat1_match_rise1_r;
reg [DRAM_WIDTH-1:0] idel_pat1_match_fall1_r;
reg [DRAM_WIDTH-1:0] idel_pat1_match_rise2_r;
reg [DRAM_WIDTH-1:0] idel_pat1_match_fall2_r;
reg [DRAM_WIDTH-1:0] idel_pat1_match_rise3_r;
reg [DRAM_WIDTH-1:0] idel_pat1_match_fall3_r;
reg idel_pat0_match_rise0_and_r;
reg idel_pat0_match_fall0_and_r;
reg idel_pat0_match_rise1_and_r;
reg idel_pat0_match_fall1_and_r;
reg idel_pat0_match_rise2_and_r;
reg idel_pat0_match_fall2_and_r;
reg idel_pat0_match_rise3_and_r;
reg idel_pat0_match_fall3_and_r;
reg idel_pat1_match_rise0_and_r;
reg idel_pat1_match_fall0_and_r;
reg idel_pat1_match_rise1_and_r;
reg idel_pat1_match_fall1_and_r;
reg idel_pat1_match_rise2_and_r;
reg idel_pat1_match_fall2_and_r;
reg idel_pat1_match_rise3_and_r;
reg idel_pat1_match_fall3_and_r;
reg idel_pat0_data_match_r;
reg idel_pat1_data_match_r;
reg idel_pat_data_match;
reg idel_pat_data_match_r;
reg [4:0] idel_dec_cnt;
reg [5:0] rdlvl_dqs_tap_cnt_r [0:RANKS-1][0:DQS_WIDTH-1];
reg [1:0] rnk_cnt_r;
reg rdlvl_rank_done_r;
reg [3:0] done_cnt;
reg [1:0] regl_rank_cnt;
reg [DQS_CNT_WIDTH:0] regl_dqs_cnt;
reg [DQS_CNT_WIDTH:0] regl_dqs_cnt_r;
wire [DQS_CNT_WIDTH+2:0]regl_dqs_cnt_timing;
reg regl_rank_done_r;
reg rdlvl_stg1_start_r;
reg dqs_po_dec_done_r1;
reg dqs_po_dec_done_r2;
reg fine_dly_dec_done_r1;
reg fine_dly_dec_done_r2;
reg [3:0] wait_cnt_r;
reg [5:0] pi_rdval_cnt;
reg pi_cnt_dec;
reg mpr_valid_r;
reg mpr_valid_r1;
reg mpr_valid_r2;
reg mpr_rd_rise0_prev_r;
reg mpr_rd_fall0_prev_r;
reg mpr_rd_rise1_prev_r;
reg mpr_rd_fall1_prev_r;
reg mpr_rd_rise2_prev_r;
reg mpr_rd_fall2_prev_r;
reg mpr_rd_rise3_prev_r;
reg mpr_rd_fall3_prev_r;
reg mpr_rdlvl_done_r;
reg mpr_rdlvl_done_r1;
reg mpr_rdlvl_done_r2;
reg mpr_rdlvl_start_r;
reg mpr_rank_done_r;
reg [2:0] stable_idel_cnt;
reg inhibit_edge_detect_r;
reg idel_pat_detect_valid_r;
reg idel_mpr_pat_detect_r;
reg mpr_pat_detect_r;
reg mpr_dec_cpt_r;
reg idel_adj_inc; //IDELAY adjustment
wire [1:0] idelay_adj;
wire pb_detect_edge_setup;
wire pb_detect_edge;
// Debug
reg [6*DQS_WIDTH-1:0] dbg_cpt_first_edge_taps;
reg [6*DQS_WIDTH-1:0] dbg_cpt_second_edge_taps;
reg [6*DQS_WIDTH*RANKS-1:0] dbg_cpt_tap_cnt_w;
//IDELAY adjustment setting for -1
//2'b10 : IDELAY - 1
//2'b01 : IDELAY + 1
//2'b00 : No IDELAY adjustment
assign idelay_adj = (IDELAY_ADJ == "ON") ? 2'b10: 2'b00;
//***************************************************************************
// Debug
//***************************************************************************
always @(*) begin
for (d = 0; d < RANKS; d = d + 1) begin
for (e = 0; e < DQS_WIDTH; e = e + 1) begin
idelay_tap_cnt_w[(5*e+5*DQS_WIDTH*d)+:5] = idelay_tap_cnt_r[d][e];
dbg_cpt_tap_cnt_w[(6*e+6*DQS_WIDTH*d)+:6] = rdlvl_dqs_tap_cnt_r[d][e];
end
end
end
assign mpr_rdlvl_err = rdlvl_stg1_err & (!mpr_rdlvl_done);
assign rdlvl_err = rdlvl_stg1_err & (mpr_rdlvl_done);
assign dbg_phy_rdlvl[0] = rdlvl_stg1_start;
assign dbg_phy_rdlvl[1] = pat_data_match_r;
assign dbg_phy_rdlvl[2] = mux_rd_valid_r;
assign dbg_phy_rdlvl[3] = idelay_tap_limit_r;
assign dbg_phy_rdlvl[8:4] = 'b0;
assign dbg_phy_rdlvl[14:9] = cal1_state_r[5:0];
assign dbg_phy_rdlvl[20:15] = cnt_idel_dec_cpt_r;
assign dbg_phy_rdlvl[21] = found_first_edge_r;
assign dbg_phy_rdlvl[22] = found_second_edge_r;
assign dbg_phy_rdlvl[23] = found_edge_r;
assign dbg_phy_rdlvl[24] = store_sr_r;
// [40:25] previously used for sr, old_sr shift registers. If connecting
// these signals again, don't forget to parameterize based on RD_SHIFT_LEN
assign dbg_phy_rdlvl[40:25] = 'b0;
assign dbg_phy_rdlvl[41] = sr_valid_r;
assign dbg_phy_rdlvl[42] = found_stable_eye_r;
assign dbg_phy_rdlvl[48:43] = tap_cnt_cpt_r;
assign dbg_phy_rdlvl[54:49] = first_edge_taps_r;
assign dbg_phy_rdlvl[60:55] = second_edge_taps_r;
assign dbg_phy_rdlvl[64:61] = cal1_cnt_cpt_timing_r;
assign dbg_phy_rdlvl[65] = cal1_dlyce_cpt_r;
assign dbg_phy_rdlvl[66] = cal1_dlyinc_cpt_r;
assign dbg_phy_rdlvl[67] = found_edge_r;
assign dbg_phy_rdlvl[68] = found_first_edge_r;
assign dbg_phy_rdlvl[73:69] = 'b0;
assign dbg_phy_rdlvl[74] = idel_pat_data_match;
assign dbg_phy_rdlvl[75] = idel_pat0_data_match_r;
assign dbg_phy_rdlvl[76] = idel_pat1_data_match_r;
assign dbg_phy_rdlvl[77] = pat0_data_match_r;
assign dbg_phy_rdlvl[78] = pat1_data_match_r;
assign dbg_phy_rdlvl[79+:5*DQS_WIDTH*RANKS] = idelay_tap_cnt_w;
assign dbg_phy_rdlvl[170+:8] = mux_rd_rise0_r;
assign dbg_phy_rdlvl[178+:8] = mux_rd_fall0_r;
assign dbg_phy_rdlvl[186+:8] = mux_rd_rise1_r;
assign dbg_phy_rdlvl[194+:8] = mux_rd_fall1_r;
assign dbg_phy_rdlvl[202+:8] = mux_rd_rise2_r;
assign dbg_phy_rdlvl[210+:8] = mux_rd_fall2_r;
assign dbg_phy_rdlvl[218+:8] = mux_rd_rise3_r;
assign dbg_phy_rdlvl[226+:8] = mux_rd_fall3_r;
//***************************************************************************
// Debug output
//***************************************************************************
// CPT taps
assign dbg_cpt_first_edge_cnt = dbg_cpt_first_edge_taps;
assign dbg_cpt_second_edge_cnt = dbg_cpt_second_edge_taps;
assign dbg_cpt_tap_cnt = dbg_cpt_tap_cnt_w;
assign dbg_dq_idelay_tap_cnt = idelay_tap_cnt_w;
// Record first and second edges found during CPT calibration
generate
always @(posedge clk)
if (rst) begin
dbg_cpt_first_edge_taps <= #TCQ 'b0;
dbg_cpt_second_edge_taps <= #TCQ 'b0;
end else if ((SIM_CAL_OPTION == "FAST_CAL") & (cal1_state_r1 == CAL1_CALC_IDEL)) begin
//for (ce_rnk_i = 0; ce_rnk_i < RANKS; ce_rnk_i = ce_rnk_i + 1) begin: gen_dbg_cpt_rnk
for (ce_i = 0; ce_i < DQS_WIDTH; ce_i = ce_i + 1) begin: gen_dbg_cpt_edge
if (found_first_edge_r)
dbg_cpt_first_edge_taps[(6*ce_i)+:6]
<= #TCQ first_edge_taps_r;
if (found_second_edge_r)
dbg_cpt_second_edge_taps[(6*ce_i)+:6]
<= #TCQ second_edge_taps_r;
end
//end
end else if (cal1_state_r == CAL1_CALC_IDEL) begin
// Record tap counts of first and second edge edges during
// CPT calibration for each DQS group. If neither edge has
// been found, then those taps will remain 0
if (found_first_edge_r)
dbg_cpt_first_edge_taps[((cal1_cnt_cpt_timing <<2) + (cal1_cnt_cpt_timing <<1))+:6]
<= #TCQ first_edge_taps_r;
if (found_second_edge_r)
dbg_cpt_second_edge_taps[((cal1_cnt_cpt_timing <<2) + (cal1_cnt_cpt_timing <<1))+:6]
<= #TCQ second_edge_taps_r;
end
endgenerate
assign rdlvl_stg1_rnk_done = rdlvl_rank_done_r;// || regl_rank_done_r;
assign mpr_rnk_done = mpr_rank_done_r;
assign mpr_rdlvl_done = ((DRAM_TYPE == "DDR3") && (OCAL_EN == "ON")) ? //&& (SIM_CAL_OPTION == "NONE")
mpr_rdlvl_done_r : 1'b1;
//**************************************************************************
// DQS count to hard PHY during write calibration using Phaser_OUT Stage2
// coarse delay
//**************************************************************************
assign pi_stg2_rdlvl_cnt = (cal1_state_r == CAL1_REGL_LOAD) ? regl_dqs_cnt_r : cal1_cnt_cpt_r;
assign idelay_ce = cal1_dq_idel_ce;
assign idelay_inc = cal1_dq_idel_inc;
//***************************************************************************
// Assert calib_in_common in FAST_CAL mode for IDELAY tap increments to all
// DQs simultaneously
//***************************************************************************
always @(posedge clk) begin
if (rst)
rdlvl_assrt_common <= #TCQ 1'b0;
else if ((SIM_CAL_OPTION == "FAST_CAL") & rdlvl_stg1_start &
!rdlvl_stg1_start_r)
rdlvl_assrt_common <= #TCQ 1'b1;
else if (!idel_pat_data_match_r & idel_pat_data_match)
rdlvl_assrt_common <= #TCQ 1'b0;
end
//***************************************************************************
// Data mux to route appropriate bit to calibration logic - i.e. calibration
// is done sequentially, one bit (or DQS group) at a time
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: rd_data_div4_logic_clk
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign rd_data_rise2 = rd_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign rd_data_fall2 = rd_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign rd_data_rise3 = rd_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign rd_data_fall3 = rd_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
end else begin: rd_data_div2_logic_clk
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
end
endgenerate
always @(posedge clk) begin
rd_mux_sel_r <= #TCQ cal1_cnt_cpt_r;
end
// Register outputs for improved timing.
// NOTE: Will need to change when per-bit DQ deskew is supported.
// Currenly all bits in DQS group are checked in aggregate
generate
genvar mux_i;
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r +
mux_i];
mux_rd_fall0_r[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r +
mux_i];
mux_rd_rise1_r[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r +
mux_i];
mux_rd_fall1_r[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r +
mux_i];
mux_rd_rise2_r[mux_i] <= #TCQ rd_data_rise2[DRAM_WIDTH*rd_mux_sel_r +
mux_i];
mux_rd_fall2_r[mux_i] <= #TCQ rd_data_fall2[DRAM_WIDTH*rd_mux_sel_r +
mux_i];
mux_rd_rise3_r[mux_i] <= #TCQ rd_data_rise3[DRAM_WIDTH*rd_mux_sel_r +
mux_i];
mux_rd_fall3_r[mux_i] <= #TCQ rd_data_fall3[DRAM_WIDTH*rd_mux_sel_r +
mux_i];
end
end
endgenerate
//***************************************************************************
// MPR Read Leveling
//***************************************************************************
// storing the previous read data for checking later. Only bit 0 is used
// since MPR contents (01010101) are available generally on DQ[0] per
// JEDEC spec.
always @(posedge clk)begin
if ((cal1_state_r == CAL1_MPR_NEW_DQS_WAIT) ||
((cal1_state_r == CAL1_MPR_PAT_DETECT) && (idel_pat_detect_valid_r)))begin
mpr_rd_rise0_prev_r <= #TCQ mux_rd_rise0_r[0];
mpr_rd_fall0_prev_r <= #TCQ mux_rd_fall0_r[0];
mpr_rd_rise1_prev_r <= #TCQ mux_rd_rise1_r[0];
mpr_rd_fall1_prev_r <= #TCQ mux_rd_fall1_r[0];
mpr_rd_rise2_prev_r <= #TCQ mux_rd_rise2_r[0];
mpr_rd_fall2_prev_r <= #TCQ mux_rd_fall2_r[0];
mpr_rd_rise3_prev_r <= #TCQ mux_rd_rise3_r[0];
mpr_rd_fall3_prev_r <= #TCQ mux_rd_fall3_r[0];
end
end
generate
if (nCK_PER_CLK == 4) begin: mpr_4to1
// changed stable count of 2 IDELAY taps at 78 ps resolution
always @(posedge clk) begin
if (rst | (cal1_state_r == CAL1_NEW_DQS_PREWAIT) |
//(cal1_state_r == CAL1_DETECT_EDGE) |
(mpr_rd_rise0_prev_r != mux_rd_rise0_r[0]) |
(mpr_rd_fall0_prev_r != mux_rd_fall0_r[0]) |
(mpr_rd_rise1_prev_r != mux_rd_rise1_r[0]) |
(mpr_rd_fall1_prev_r != mux_rd_fall1_r[0]) |
(mpr_rd_rise2_prev_r != mux_rd_rise2_r[0]) |
(mpr_rd_fall2_prev_r != mux_rd_fall2_r[0]) |
(mpr_rd_rise3_prev_r != mux_rd_rise3_r[0]) |
(mpr_rd_fall3_prev_r != mux_rd_fall3_r[0]))
stable_idel_cnt <= #TCQ 3'd0;
else if ((|idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing]) &
((cal1_state_r == CAL1_MPR_PAT_DETECT) &
(idel_pat_detect_valid_r))) begin
if ((mpr_rd_rise0_prev_r == mux_rd_rise0_r[0]) &
(mpr_rd_fall0_prev_r == mux_rd_fall0_r[0]) &
(mpr_rd_rise1_prev_r == mux_rd_rise1_r[0]) &
(mpr_rd_fall1_prev_r == mux_rd_fall1_r[0]) &
(mpr_rd_rise2_prev_r == mux_rd_rise2_r[0]) &
(mpr_rd_fall2_prev_r == mux_rd_fall2_r[0]) &
(mpr_rd_rise3_prev_r == mux_rd_rise3_r[0]) &
(mpr_rd_fall3_prev_r == mux_rd_fall3_r[0]) &
(stable_idel_cnt < 3'd2))
stable_idel_cnt <= #TCQ stable_idel_cnt + 1;
end
end
always @(posedge clk) begin
if (rst |
(mpr_rd_rise0_prev_r & ~mpr_rd_fall0_prev_r &
mpr_rd_rise1_prev_r & ~mpr_rd_fall1_prev_r &
mpr_rd_rise2_prev_r & ~mpr_rd_fall2_prev_r &
mpr_rd_rise3_prev_r & ~mpr_rd_fall3_prev_r))
inhibit_edge_detect_r <= 1'b1;
// Wait for settling time after idelay tap increment before
// de-asserting inhibit_edge_detect_r
else if ((cal1_state_r == CAL1_MPR_PAT_DETECT) &
(idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing] > 5'd1) &
(~mpr_rd_rise0_prev_r & mpr_rd_fall0_prev_r &
~mpr_rd_rise1_prev_r & mpr_rd_fall1_prev_r &
~mpr_rd_rise2_prev_r & mpr_rd_fall2_prev_r &
~mpr_rd_rise3_prev_r & mpr_rd_fall3_prev_r))
inhibit_edge_detect_r <= 1'b0;
end
//checking for transition from 01010101 to 10101010
always @(posedge clk)begin
if (rst | (cal1_state_r == CAL1_MPR_NEW_DQS_WAIT) |
inhibit_edge_detect_r)
idel_mpr_pat_detect_r <= #TCQ 1'b0;
// 10101010 is not the correct pattern
else if ((mpr_rd_rise0_prev_r & ~mpr_rd_fall0_prev_r &
mpr_rd_rise1_prev_r & ~mpr_rd_fall1_prev_r &
mpr_rd_rise2_prev_r & ~mpr_rd_fall2_prev_r &
mpr_rd_rise3_prev_r & ~mpr_rd_fall3_prev_r) ||
((stable_idel_cnt < 3'd2) & (cal1_state_r == CAL1_MPR_PAT_DETECT)
&& (idel_pat_detect_valid_r)))
//|| (idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing] < 5'd2))
idel_mpr_pat_detect_r <= #TCQ 1'b0;
// 01010101 to 10101010 is the correct transition
else if ((~mpr_rd_rise0_prev_r & mpr_rd_fall0_prev_r &
~mpr_rd_rise1_prev_r & mpr_rd_fall1_prev_r &
~mpr_rd_rise2_prev_r & mpr_rd_fall2_prev_r &
~mpr_rd_rise3_prev_r & mpr_rd_fall3_prev_r) &
(stable_idel_cnt == 3'd2) &
((mpr_rd_rise0_prev_r != mux_rd_rise0_r[0]) ||
(mpr_rd_fall0_prev_r != mux_rd_fall0_r[0]) ||
(mpr_rd_rise1_prev_r != mux_rd_rise1_r[0]) ||
(mpr_rd_fall1_prev_r != mux_rd_fall1_r[0]) ||
(mpr_rd_rise2_prev_r != mux_rd_rise2_r[0]) ||
(mpr_rd_fall2_prev_r != mux_rd_fall2_r[0]) ||
(mpr_rd_rise3_prev_r != mux_rd_rise3_r[0]) ||
(mpr_rd_fall3_prev_r != mux_rd_fall3_r[0])))
idel_mpr_pat_detect_r <= #TCQ 1'b1;
end
end else if (nCK_PER_CLK == 2) begin: mpr_2to1
// changed stable count of 2 IDELAY taps at 78 ps resolution
always @(posedge clk) begin
if (rst | (cal1_state_r == CAL1_MPR_NEW_DQS_WAIT) |
(mpr_rd_rise0_prev_r != mux_rd_rise0_r[0]) |
(mpr_rd_fall0_prev_r != mux_rd_fall0_r[0]) |
(mpr_rd_rise1_prev_r != mux_rd_rise1_r[0]) |
(mpr_rd_fall1_prev_r != mux_rd_fall1_r[0]))
stable_idel_cnt <= #TCQ 3'd0;
else if ((idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing] > 5'd0) &
((cal1_state_r == CAL1_MPR_PAT_DETECT) &
(idel_pat_detect_valid_r))) begin
if ((mpr_rd_rise0_prev_r == mux_rd_rise0_r[0]) &
(mpr_rd_fall0_prev_r == mux_rd_fall0_r[0]) &
(mpr_rd_rise1_prev_r == mux_rd_rise1_r[0]) &
(mpr_rd_fall1_prev_r == mux_rd_fall1_r[0]) &
(stable_idel_cnt < 3'd2))
stable_idel_cnt <= #TCQ stable_idel_cnt + 1;
end
end
always @(posedge clk) begin
if (rst |
(mpr_rd_rise0_prev_r & ~mpr_rd_fall0_prev_r &
mpr_rd_rise1_prev_r & ~mpr_rd_fall1_prev_r))
inhibit_edge_detect_r <= 1'b1;
else if ((cal1_state_r == CAL1_MPR_PAT_DETECT) &
(idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing] > 5'd1) &
(~mpr_rd_rise0_prev_r & mpr_rd_fall0_prev_r &
~mpr_rd_rise1_prev_r & mpr_rd_fall1_prev_r))
inhibit_edge_detect_r <= 1'b0;
end
//checking for transition from 01010101 to 10101010
always @(posedge clk)begin
if (rst | (cal1_state_r == CAL1_MPR_NEW_DQS_WAIT) |
inhibit_edge_detect_r)
idel_mpr_pat_detect_r <= #TCQ 1'b0;
// 1010 is not the correct pattern
else if ((mpr_rd_rise0_prev_r & ~mpr_rd_fall0_prev_r &
mpr_rd_rise1_prev_r & ~mpr_rd_fall1_prev_r) ||
((stable_idel_cnt < 3'd2) & (cal1_state_r == CAL1_MPR_PAT_DETECT)
& (idel_pat_detect_valid_r)))
// ||(idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing] < 5'd2))
idel_mpr_pat_detect_r <= #TCQ 1'b0;
// 0101 to 1010 is the correct transition
else if ((~mpr_rd_rise0_prev_r & mpr_rd_fall0_prev_r &
~mpr_rd_rise1_prev_r & mpr_rd_fall1_prev_r) &
(stable_idel_cnt == 3'd2) &
((mpr_rd_rise0_prev_r != mux_rd_rise0_r[0]) ||
(mpr_rd_fall0_prev_r != mux_rd_fall0_r[0]) ||
(mpr_rd_rise1_prev_r != mux_rd_rise1_r[0]) ||
(mpr_rd_fall1_prev_r != mux_rd_fall1_r[0])))
idel_mpr_pat_detect_r <= #TCQ 1'b1;
end
end
endgenerate
// Registered signal indicates when mux_rd_rise/fall_r is valid
always @(posedge clk)
mux_rd_valid_r <= #TCQ ~phy_if_empty;
//***************************************************************************
// Decrement initial Phaser_IN fine delay value before proceeding with
// read calibration
//***************************************************************************
always @(posedge clk) begin
dqs_po_dec_done_r1 <= #TCQ dqs_po_dec_done;
dqs_po_dec_done_r2 <= #TCQ dqs_po_dec_done_r1;
fine_dly_dec_done_r2 <= #TCQ fine_dly_dec_done_r1;
pi_fine_dly_dec_done <= #TCQ fine_dly_dec_done_r2;
end
always @(posedge clk) begin
if (rst || pi_cnt_dec)
wait_cnt_r <= #TCQ 'd8;
else if (dqs_po_dec_done_r2 && (wait_cnt_r > 'd0))
wait_cnt_r <= #TCQ wait_cnt_r - 1;
end
always @(posedge clk) begin
if (rst) begin
pi_rdval_cnt <= #TCQ 'd0;
end else if (dqs_po_dec_done_r1 && ~dqs_po_dec_done_r2) begin
pi_rdval_cnt <= #TCQ pi_counter_read_val;
end else if (pi_rdval_cnt > 'd0) begin
if (pi_cnt_dec)
pi_rdval_cnt <= #TCQ pi_rdval_cnt - 1;
else
pi_rdval_cnt <= #TCQ pi_rdval_cnt;
end else if (pi_rdval_cnt == 'd0) begin
pi_rdval_cnt <= #TCQ pi_rdval_cnt;
end
end
always @(posedge clk) begin
if (rst || (pi_rdval_cnt == 'd0))
pi_cnt_dec <= #TCQ 1'b0;
else if (dqs_po_dec_done_r2 && (pi_rdval_cnt > 'd0)
&& (wait_cnt_r == 'd1))
pi_cnt_dec <= #TCQ 1'b1;
else
pi_cnt_dec <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst) begin
fine_dly_dec_done_r1 <= #TCQ 1'b0;
end else if (((pi_cnt_dec == 'd1) && (pi_rdval_cnt == 'd1)) ||
(dqs_po_dec_done_r2 && (pi_rdval_cnt == 'd0))) begin
fine_dly_dec_done_r1 <= #TCQ 1'b1;
end
end
//***************************************************************************
// Demultiplexor to control Phaser_IN delay values
//***************************************************************************
// Read DQS
always @(posedge clk) begin
if (rst) begin
pi_en_stg2_f_timing <= #TCQ 'b0;
pi_stg2_f_incdec_timing <= #TCQ 'b0;
end else if (pi_cnt_dec) begin
pi_en_stg2_f_timing <= #TCQ 'b1;
pi_stg2_f_incdec_timing <= #TCQ 'b0;
end else if (cal1_dlyce_cpt_r) begin
if ((SIM_CAL_OPTION == "NONE") ||
(SIM_CAL_OPTION == "FAST_WIN_DETECT")) begin
// Change only specified DQS
pi_en_stg2_f_timing <= #TCQ 1'b1;
pi_stg2_f_incdec_timing <= #TCQ cal1_dlyinc_cpt_r;
end else if (SIM_CAL_OPTION == "FAST_CAL") begin
// if simulating, and "shortcuts" for calibration enabled, apply
// results to all DQSs (i.e. assume same delay on all
// DQSs).
pi_en_stg2_f_timing <= #TCQ 1'b1;
pi_stg2_f_incdec_timing <= #TCQ cal1_dlyinc_cpt_r;
end
end else begin
pi_en_stg2_f_timing <= #TCQ 'b0;
pi_stg2_f_incdec_timing <= #TCQ 'b0;
end
end
// registered for timing
always @(posedge clk) begin
pi_en_stg2_f <= #TCQ pi_en_stg2_f_timing;
pi_stg2_f_incdec <= #TCQ pi_stg2_f_incdec_timing;
end
// This counter used to implement settling time between
// Phaser_IN rank register loads to different DQSs
always @(posedge clk) begin
if (rst)
done_cnt <= #TCQ 'b0;
else if (((cal1_state_r == CAL1_REGL_LOAD) &&
(cal1_state_r1 == CAL1_NEXT_DQS)) ||
((done_cnt == 4'd1) && (cal1_state_r != CAL1_DONE)))
done_cnt <= #TCQ 4'b1010;
else if (done_cnt > 'b0)
done_cnt <= #TCQ done_cnt - 1;
end
// During rank register loading the rank count must be sent to
// Phaser_IN via the phy_ctl_wd?? If so phy_init will have to
// issue NOPs during rank register loading with the appropriate
// rank count
always @(posedge clk) begin
if (rst || (regl_rank_done_r == 1'b1))
regl_rank_done_r <= #TCQ 1'b0;
else if ((regl_dqs_cnt == DQS_WIDTH-1) &&
(regl_rank_cnt != RANKS-1) &&
(done_cnt == 4'd1))
regl_rank_done_r <= #TCQ 1'b1;
end
// Temp wire for timing.
// The following in the always block below causes timing issues
// due to DSP block inference
// 6*regl_dqs_cnt.
// replacing this with two left shifts + 1 left shift to avoid
// DSP multiplier.
assign regl_dqs_cnt_timing = {2'd0, regl_dqs_cnt};
// Load Phaser_OUT rank register with rdlvl delay value
// for each DQS per rank.
always @(posedge clk) begin
if (rst || (done_cnt == 4'd0)) begin
pi_stg2_load_timing <= #TCQ 'b0;
pi_stg2_reg_l_timing <= #TCQ 'b0;
end else if ((cal1_state_r == CAL1_REGL_LOAD) &&
(regl_dqs_cnt <= DQS_WIDTH-1) && (done_cnt == 4'd1)) begin
pi_stg2_load_timing <= #TCQ 'b1;
pi_stg2_reg_l_timing <= #TCQ
rdlvl_dqs_tap_cnt_r[rnk_cnt_r][regl_dqs_cnt];
end else begin
pi_stg2_load_timing <= #TCQ 'b0;
pi_stg2_reg_l_timing <= #TCQ 'b0;
end
end
// registered for timing
always @(posedge clk) begin
pi_stg2_load <= #TCQ pi_stg2_load_timing;
pi_stg2_reg_l <= #TCQ pi_stg2_reg_l_timing;
end
always @(posedge clk) begin
if (rst || (done_cnt == 4'd0) ||
(mpr_rdlvl_done_r1 && ~mpr_rdlvl_done_r2))
regl_rank_cnt <= #TCQ 2'b00;
else if ((cal1_state_r == CAL1_REGL_LOAD) &&
(regl_dqs_cnt == DQS_WIDTH-1) && (done_cnt == 4'd1)) begin
if (regl_rank_cnt == RANKS-1)
regl_rank_cnt <= #TCQ regl_rank_cnt;
else
regl_rank_cnt <= #TCQ regl_rank_cnt + 1;
end
end
always @(posedge clk) begin
if (rst || (done_cnt == 4'd0) ||
(mpr_rdlvl_done_r1 && ~mpr_rdlvl_done_r2))
regl_dqs_cnt <= #TCQ {DQS_CNT_WIDTH+1{1'b0}};
else if ((cal1_state_r == CAL1_REGL_LOAD) &&
(regl_dqs_cnt == DQS_WIDTH-1) && (done_cnt == 4'd1)) begin
if (regl_rank_cnt == RANKS-1)
regl_dqs_cnt <= #TCQ regl_dqs_cnt;
else
regl_dqs_cnt <= #TCQ 'b0;
end else if ((cal1_state_r == CAL1_REGL_LOAD) && (regl_dqs_cnt != DQS_WIDTH-1)
&& (done_cnt == 4'd1))
regl_dqs_cnt <= #TCQ regl_dqs_cnt + 1;
else
regl_dqs_cnt <= #TCQ regl_dqs_cnt;
end
always @(posedge clk)
regl_dqs_cnt_r <= #TCQ regl_dqs_cnt;
//*****************************************************************
// DQ Stage 1 CALIBRATION INCREMENT/DECREMENT LOGIC:
// The actual IDELAY elements for each of the DQ bits is set via the
// DLYVAL parallel load port. However, the stage 1 calibration
// algorithm (well most of it) only needs to increment or decrement the DQ
// IDELAY value by 1 at any one time.
//*****************************************************************
// Chip-select generation for each of the individual counters tracking
// IDELAY tap values for each DQ
generate
for (z = 0; z < DQS_WIDTH; z = z + 1) begin: gen_dlyce_dq
always @(posedge clk)
if (rst)
dlyce_dq_r[DRAM_WIDTH*z+:DRAM_WIDTH] <= #TCQ 'b0;
else
if (SIM_CAL_OPTION == "SKIP_CAL")
// If skipping calibration altogether (only for simulation), no
// need to set DQ IODELAY values - they are hardcoded
dlyce_dq_r[DRAM_WIDTH*z+:DRAM_WIDTH] <= #TCQ 'b0;
else if (SIM_CAL_OPTION == "FAST_CAL") begin
// If fast calibration option (simulation only) selected, DQ
// IODELAYs across all bytes are updated simultaneously
// (although per-bit deskew within DQS[0] is still supported)
for (h = 0; h < DRAM_WIDTH; h = h + 1) begin
dlyce_dq_r[DRAM_WIDTH*z + h] <= #TCQ cal1_dlyce_dq_r;
end
end else if ((SIM_CAL_OPTION == "NONE") ||
(SIM_CAL_OPTION == "FAST_WIN_DETECT")) begin
if (cal1_cnt_cpt_r == z) begin
for (g = 0; g < DRAM_WIDTH; g = g + 1) begin
dlyce_dq_r[DRAM_WIDTH*z + g]
<= #TCQ cal1_dlyce_dq_r;
end
end else
dlyce_dq_r[DRAM_WIDTH*z+:DRAM_WIDTH] <= #TCQ 'b0;
end
end
endgenerate
// Also delay increment/decrement control to match delay on DLYCE
always @(posedge clk)
if (rst)
dlyinc_dq_r <= #TCQ 1'b0;
else
dlyinc_dq_r <= #TCQ cal1_dlyinc_dq_r;
// Each DQ has a counter associated with it to record current read-leveling
// delay value
always @(posedge clk)
// Reset or skipping calibration all together
if (rst | (SIM_CAL_OPTION == "SKIP_CAL")) begin
for (aa = 0; aa < RANKS; aa = aa + 1) begin: rst_dlyval_dq_reg_r
for (bb = 0; bb < DQ_WIDTH; bb = bb + 1)
dlyval_dq_reg_r[aa][bb] <= #TCQ 'b0;
end
end else if (SIM_CAL_OPTION == "FAST_CAL") begin
for (n = 0; n < RANKS; n = n + 1) begin: gen_dlyval_dq_reg_rnk
for (r = 0; r < DQ_WIDTH; r = r + 1) begin: gen_dlyval_dq_reg
if (dlyce_dq_r[r]) begin
if (dlyinc_dq_r)
dlyval_dq_reg_r[n][r] <= #TCQ dlyval_dq_reg_r[n][r] + 5'h01;
else
dlyval_dq_reg_r[n][r] <= #TCQ dlyval_dq_reg_r[n][r] - 5'h01;
end
end
end
end else begin
if (dlyce_dq_r[cal1_cnt_cpt_r]) begin
if (dlyinc_dq_r)
dlyval_dq_reg_r[rnk_cnt_r][cal1_cnt_cpt_r] <= #TCQ
dlyval_dq_reg_r[rnk_cnt_r][cal1_cnt_cpt_r] + 5'h01;
else
dlyval_dq_reg_r[rnk_cnt_r][cal1_cnt_cpt_r] <= #TCQ
dlyval_dq_reg_r[rnk_cnt_r][cal1_cnt_cpt_r] - 5'h01;
end
end
// Register for timing (help with logic placement)
always @(posedge clk) begin
for (cc = 0; cc < RANKS; cc = cc + 1) begin: dlyval_dq_assgn
for (dd = 0; dd < DQ_WIDTH; dd = dd + 1)
dlyval_dq[((5*dd)+(cc*DQ_WIDTH*5))+:5] <= #TCQ dlyval_dq_reg_r[cc][dd];
end
end
//***************************************************************************
// Generate signal used to delay calibration state machine - used when:
// (1) IDELAY value changed
// (2) RD_MUX_SEL value changed
// Use when a delay is necessary to give the change time to propagate
// through the data pipeline (through IDELAY and ISERDES, and fabric
// pipeline stages)
//***************************************************************************
// List all the stage 1 calibration wait states here.
// verilint STARC-2.7.3.3b off
always @(posedge clk)
if ((cal1_state_r == CAL1_NEW_DQS_WAIT) ||
(cal1_state_r == CAL1_MPR_NEW_DQS_WAIT) ||
(cal1_state_r == CAL1_NEW_DQS_PREWAIT) ||
(cal1_state_r == CAL1_VALID_WAIT) ||
(cal1_state_r == CAL1_PB_STORE_FIRST_WAIT) ||
(cal1_state_r == CAL1_PB_INC_CPT_WAIT) ||
(cal1_state_r == CAL1_PB_DEC_CPT_LEFT_WAIT) ||
(cal1_state_r == CAL1_PB_INC_DQ_WAIT) ||
(cal1_state_r == CAL1_PB_DEC_CPT_WAIT) ||
(cal1_state_r == CAL1_IDEL_INC_CPT_WAIT) ||
(cal1_state_r == CAL1_IDEL_DEC_CPT_WAIT) ||
(cal1_state_r == CAL1_STORE_FIRST_WAIT) ||
(cal1_state_r == CAL1_DQ_IDEL_TAP_INC_WAIT) ||
(cal1_state_r == CAL1_DQ_IDEL_TAP_DEC_WAIT))
cal1_wait_cnt_en_r <= #TCQ 1'b1;
else
cal1_wait_cnt_en_r <= #TCQ 1'b0;
// verilint STARC-2.7.3.3b on
always @(posedge clk)
if (!cal1_wait_cnt_en_r) begin
cal1_wait_cnt_r <= #TCQ 5'b00000;
cal1_wait_r <= #TCQ 1'b1;
end else begin
if (cal1_wait_cnt_r != PIPE_WAIT_CNT - 1) begin
cal1_wait_cnt_r <= #TCQ cal1_wait_cnt_r + 1;
cal1_wait_r <= #TCQ 1'b1;
end else begin
// Need to reset to 0 to handle the case when there are two
// different WAIT states back-to-back
cal1_wait_cnt_r <= #TCQ 5'b00000;
cal1_wait_r <= #TCQ 1'b0;
end
end
//***************************************************************************
// generate request to PHY_INIT logic to issue precharged. Required when
// calibration can take a long time (during which there are only constant
// reads present on this bus). In this case need to issue perioidic
// precharges to avoid tRAS violation. This signal must meet the following
// requirements: (1) only transition from 0->1 when prech is first needed,
// (2) stay at 1 and only transition 1->0 when RDLVL_PRECH_DONE asserted
//***************************************************************************
always @(posedge clk)
if (rst)
rdlvl_prech_req <= #TCQ 1'b0;
else
rdlvl_prech_req <= #TCQ cal1_prech_req_r;
//***************************************************************************
// Serial-to-parallel register to store last RDDATA_SHIFT_LEN cycles of
// data from ISERDES. The value of this register is also stored, so that
// previous and current values of the ISERDES data can be compared while
// varying the IODELAY taps to see if an "edge" of the data valid window
// has been encountered since the last IODELAY tap adjustment
//***************************************************************************
//***************************************************************************
// Shift register to store last RDDATA_SHIFT_LEN cycles of data from ISERDES
// NOTE: Written using discrete flops, but SRL can be used if the matching
// logic does the comparison sequentially, rather than parallel
//***************************************************************************
generate
genvar rd_i;
if (nCK_PER_CLK == 4) begin: gen_sr_div4
if (RD_SHIFT_LEN == 1) begin: gen_sr_len_eq1
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
if (mux_rd_valid_r) begin
sr_rise0_r[rd_i] <= #TCQ mux_rd_rise0_r[rd_i];
sr_fall0_r[rd_i] <= #TCQ mux_rd_fall0_r[rd_i];
sr_rise1_r[rd_i] <= #TCQ mux_rd_rise1_r[rd_i];
sr_fall1_r[rd_i] <= #TCQ mux_rd_fall1_r[rd_i];
sr_rise2_r[rd_i] <= #TCQ mux_rd_rise2_r[rd_i];
sr_fall2_r[rd_i] <= #TCQ mux_rd_fall2_r[rd_i];
sr_rise3_r[rd_i] <= #TCQ mux_rd_rise3_r[rd_i];
sr_fall3_r[rd_i] <= #TCQ mux_rd_fall3_r[rd_i];
end
end
end
end else if (RD_SHIFT_LEN > 1) begin: gen_sr_len_gt1
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
if (mux_rd_valid_r) begin
sr_rise0_r[rd_i] <= #TCQ {sr_rise0_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_rise0_r[rd_i]};
sr_fall0_r[rd_i] <= #TCQ {sr_fall0_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_fall0_r[rd_i]};
sr_rise1_r[rd_i] <= #TCQ {sr_rise1_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_rise1_r[rd_i]};
sr_fall1_r[rd_i] <= #TCQ {sr_fall1_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_fall1_r[rd_i]};
sr_rise2_r[rd_i] <= #TCQ {sr_rise2_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_rise2_r[rd_i]};
sr_fall2_r[rd_i] <= #TCQ {sr_fall2_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_fall2_r[rd_i]};
sr_rise3_r[rd_i] <= #TCQ {sr_rise3_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_rise3_r[rd_i]};
sr_fall3_r[rd_i] <= #TCQ {sr_fall3_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_fall3_r[rd_i]};
end
end
end
end
end else if (nCK_PER_CLK == 2) begin: gen_sr_div2
if (RD_SHIFT_LEN == 1) begin: gen_sr_len_eq1
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
if (mux_rd_valid_r) begin
sr_rise0_r[rd_i] <= #TCQ {mux_rd_rise0_r[rd_i]};
sr_fall0_r[rd_i] <= #TCQ {mux_rd_fall0_r[rd_i]};
sr_rise1_r[rd_i] <= #TCQ {mux_rd_rise1_r[rd_i]};
sr_fall1_r[rd_i] <= #TCQ {mux_rd_fall1_r[rd_i]};
end
end
end
end else if (RD_SHIFT_LEN > 1) begin: gen_sr_len_gt1
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
if (mux_rd_valid_r) begin
sr_rise0_r[rd_i] <= #TCQ {sr_rise0_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_rise0_r[rd_i]};
sr_fall0_r[rd_i] <= #TCQ {sr_fall0_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_fall0_r[rd_i]};
sr_rise1_r[rd_i] <= #TCQ {sr_rise1_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_rise1_r[rd_i]};
sr_fall1_r[rd_i] <= #TCQ {sr_fall1_r[rd_i][RD_SHIFT_LEN-2:0],
mux_rd_fall1_r[rd_i]};
end
end
end
end
end
endgenerate
//***************************************************************************
// Conversion to pattern calibration
//***************************************************************************
// Pattern for DQ IDELAY calibration
//*****************************************************************
// Expected data pattern when DQ shifted to the right such that
// DQS before the left edge of the DVW:
// Based on pattern of ({rise,fall}) =
// 0x1, 0xB, 0x4, 0x4, 0xB, 0x9
// Each nibble will look like:
// bit3: 0, 1, 0, 0, 1, 1
// bit2: 0, 0, 1, 1, 0, 0
// bit1: 0, 1, 0, 0, 1, 0
// bit0: 1, 1, 0, 0, 1, 1
// Or if the write is early it could look like:
// 0x4, 0x4, 0xB, 0x9, 0x6, 0xE
// bit3: 0, 0, 1, 1, 0, 1
// bit2: 1, 1, 0, 0, 1, 1
// bit1: 0, 0, 1, 0, 1, 1
// bit0: 0, 0, 1, 1, 0, 0
// Change the hard-coded pattern below accordingly as RD_SHIFT_LEN
// and the actual training pattern contents change
//*****************************************************************
generate
if (nCK_PER_CLK == 4) begin: gen_pat_div4
// Pattern for DQ IDELAY increment
// Target pattern for "early write"
assign {idel_pat0_rise0[3], idel_pat0_rise0[2],
idel_pat0_rise0[1], idel_pat0_rise0[0]} = 4'h1;
assign {idel_pat0_fall0[3], idel_pat0_fall0[2],
idel_pat0_fall0[1], idel_pat0_fall0[0]} = 4'h7;
assign {idel_pat0_rise1[3], idel_pat0_rise1[2],
idel_pat0_rise1[1], idel_pat0_rise1[0]} = 4'hE;
assign {idel_pat0_fall1[3], idel_pat0_fall1[2],
idel_pat0_fall1[1], idel_pat0_fall1[0]} = 4'hC;
assign {idel_pat0_rise2[3], idel_pat0_rise2[2],
idel_pat0_rise2[1], idel_pat0_rise2[0]} = 4'h9;
assign {idel_pat0_fall2[3], idel_pat0_fall2[2],
idel_pat0_fall2[1], idel_pat0_fall2[0]} = 4'h2;
assign {idel_pat0_rise3[3], idel_pat0_rise3[2],
idel_pat0_rise3[1], idel_pat0_rise3[0]} = 4'h4;
assign {idel_pat0_fall3[3], idel_pat0_fall3[2],
idel_pat0_fall3[1], idel_pat0_fall3[0]} = 4'hB;
// Target pattern for "on-time write"
assign {idel_pat1_rise0[3], idel_pat1_rise0[2],
idel_pat1_rise0[1], idel_pat1_rise0[0]} = 4'h4;
assign {idel_pat1_fall0[3], idel_pat1_fall0[2],
idel_pat1_fall0[1], idel_pat1_fall0[0]} = 4'h9;
assign {idel_pat1_rise1[3], idel_pat1_rise1[2],
idel_pat1_rise1[1], idel_pat1_rise1[0]} = 4'h3;
assign {idel_pat1_fall1[3], idel_pat1_fall1[2],
idel_pat1_fall1[1], idel_pat1_fall1[0]} = 4'h7;
assign {idel_pat1_rise2[3], idel_pat1_rise2[2],
idel_pat1_rise2[1], idel_pat1_rise2[0]} = 4'hE;
assign {idel_pat1_fall2[3], idel_pat1_fall2[2],
idel_pat1_fall2[1], idel_pat1_fall2[0]} = 4'hC;
assign {idel_pat1_rise3[3], idel_pat1_rise3[2],
idel_pat1_rise3[1], idel_pat1_rise3[0]} = 4'h9;
assign {idel_pat1_fall3[3], idel_pat1_fall3[2],
idel_pat1_fall3[1], idel_pat1_fall3[0]} = 4'h2;
// Correct data valid window for "early write"
assign {pat0_rise0[3], pat0_rise0[2],
pat0_rise0[1], pat0_rise0[0]} = 4'h7;
assign {pat0_fall0[3], pat0_fall0[2],
pat0_fall0[1], pat0_fall0[0]} = 4'hE;
assign {pat0_rise1[3], pat0_rise1[2],
pat0_rise1[1], pat0_rise1[0]} = 4'hC;
assign {pat0_fall1[3], pat0_fall1[2],
pat0_fall1[1], pat0_fall1[0]} = 4'h9;
assign {pat0_rise2[3], pat0_rise2[2],
pat0_rise2[1], pat0_rise2[0]} = 4'h2;
assign {pat0_fall2[3], pat0_fall2[2],
pat0_fall2[1], pat0_fall2[0]} = 4'h4;
assign {pat0_rise3[3], pat0_rise3[2],
pat0_rise3[1], pat0_rise3[0]} = 4'hB;
assign {pat0_fall3[3], pat0_fall3[2],
pat0_fall3[1], pat0_fall3[0]} = 4'h1;
// Correct data valid window for "on-time write"
assign {pat1_rise0[3], pat1_rise0[2],
pat1_rise0[1], pat1_rise0[0]} = 4'h9;
assign {pat1_fall0[3], pat1_fall0[2],
pat1_fall0[1], pat1_fall0[0]} = 4'h3;
assign {pat1_rise1[3], pat1_rise1[2],
pat1_rise1[1], pat1_rise1[0]} = 4'h7;
assign {pat1_fall1[3], pat1_fall1[2],
pat1_fall1[1], pat1_fall1[0]} = 4'hE;
assign {pat1_rise2[3], pat1_rise2[2],
pat1_rise2[1], pat1_rise2[0]} = 4'hC;
assign {pat1_fall2[3], pat1_fall2[2],
pat1_fall2[1], pat1_fall2[0]} = 4'h9;
assign {pat1_rise3[3], pat1_rise3[2],
pat1_rise3[1], pat1_rise3[0]} = 4'h2;
assign {pat1_fall3[3], pat1_fall3[2],
pat1_fall3[1], pat1_fall3[0]} = 4'h4;
end else if (nCK_PER_CLK == 2) begin: gen_pat_div2
// Pattern for DQ IDELAY increment
// Target pattern for "early write"
assign idel_pat0_rise0[3] = 2'b01;
assign idel_pat0_fall0[3] = 2'b00;
assign idel_pat0_rise1[3] = 2'b10;
assign idel_pat0_fall1[3] = 2'b11;
assign idel_pat0_rise0[2] = 2'b00;
assign idel_pat0_fall0[2] = 2'b10;
assign idel_pat0_rise1[2] = 2'b11;
assign idel_pat0_fall1[2] = 2'b10;
assign idel_pat0_rise0[1] = 2'b00;
assign idel_pat0_fall0[1] = 2'b11;
assign idel_pat0_rise1[1] = 2'b10;
assign idel_pat0_fall1[1] = 2'b01;
assign idel_pat0_rise0[0] = 2'b11;
assign idel_pat0_fall0[0] = 2'b10;
assign idel_pat0_rise1[0] = 2'b00;
assign idel_pat0_fall1[0] = 2'b01;
// Target pattern for "on-time write"
assign idel_pat1_rise0[3] = 2'b01;
assign idel_pat1_fall0[3] = 2'b11;
assign idel_pat1_rise1[3] = 2'b01;
assign idel_pat1_fall1[3] = 2'b00;
assign idel_pat1_rise0[2] = 2'b11;
assign idel_pat1_fall0[2] = 2'b01;
assign idel_pat1_rise1[2] = 2'b00;
assign idel_pat1_fall1[2] = 2'b10;
assign idel_pat1_rise0[1] = 2'b01;
assign idel_pat1_fall0[1] = 2'b00;
assign idel_pat1_rise1[1] = 2'b10;
assign idel_pat1_fall1[1] = 2'b11;
assign idel_pat1_rise0[0] = 2'b00;
assign idel_pat1_fall0[0] = 2'b10;
assign idel_pat1_rise1[0] = 2'b11;
assign idel_pat1_fall1[0] = 2'b10;
// Correct data valid window for "early write"
assign pat0_rise0[3] = 2'b00;
assign pat0_fall0[3] = 2'b10;
assign pat0_rise1[3] = 2'b11;
assign pat0_fall1[3] = 2'b10;
assign pat0_rise0[2] = 2'b10;
assign pat0_fall0[2] = 2'b11;
assign pat0_rise1[2] = 2'b10;
assign pat0_fall1[2] = 2'b00;
assign pat0_rise0[1] = 2'b11;
assign pat0_fall0[1] = 2'b10;
assign pat0_rise1[1] = 2'b01;
assign pat0_fall1[1] = 2'b00;
assign pat0_rise0[0] = 2'b10;
assign pat0_fall0[0] = 2'b00;
assign pat0_rise1[0] = 2'b01;
assign pat0_fall1[0] = 2'b11;
// Correct data valid window for "on-time write"
assign pat1_rise0[3] = 2'b11;
assign pat1_fall0[3] = 2'b01;
assign pat1_rise1[3] = 2'b00;
assign pat1_fall1[3] = 2'b10;
assign pat1_rise0[2] = 2'b01;
assign pat1_fall0[2] = 2'b00;
assign pat1_rise1[2] = 2'b10;
assign pat1_fall1[2] = 2'b11;
assign pat1_rise0[1] = 2'b00;
assign pat1_fall0[1] = 2'b10;
assign pat1_rise1[1] = 2'b11;
assign pat1_fall1[1] = 2'b10;
assign pat1_rise0[0] = 2'b10;
assign pat1_fall0[0] = 2'b11;
assign pat1_rise1[0] = 2'b10;
assign pat1_fall1[0] = 2'b00;
end
endgenerate
// Each bit of each byte is compared to expected pattern.
// This was done to prevent (and "drastically decrease") the chance that
// invalid data clocked in when the DQ bus is tri-state (along with a
// combination of the correct data) will resemble the expected data
// pattern. A better fix for this is to change the training pattern and/or
// make the pattern longer.
generate
genvar pt_i;
if (nCK_PER_CLK == 4) begin: gen_pat_match_div4
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
// DQ IDELAY pattern detection
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == idel_pat0_rise0[pt_i%4])
idel_pat0_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == idel_pat0_fall0[pt_i%4])
idel_pat0_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == idel_pat0_rise1[pt_i%4])
idel_pat0_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == idel_pat0_fall1[pt_i%4])
idel_pat0_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == idel_pat0_rise2[pt_i%4])
idel_pat0_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == idel_pat0_fall2[pt_i%4])
idel_pat0_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == idel_pat0_rise3[pt_i%4])
idel_pat0_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == idel_pat0_fall3[pt_i%4])
idel_pat0_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == idel_pat1_rise0[pt_i%4])
idel_pat1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == idel_pat1_fall0[pt_i%4])
idel_pat1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == idel_pat1_rise1[pt_i%4])
idel_pat1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == idel_pat1_fall1[pt_i%4])
idel_pat1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == idel_pat1_rise2[pt_i%4])
idel_pat1_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == idel_pat1_fall2[pt_i%4])
idel_pat1_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == idel_pat1_rise3[pt_i%4])
idel_pat1_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == idel_pat1_fall3[pt_i%4])
idel_pat1_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
// DQS DVW pattern detection
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat0_rise0[pt_i%4])
pat0_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat0_fall0[pt_i%4])
pat0_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat0_rise1[pt_i%4])
pat0_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat0_fall1[pt_i%4])
pat0_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat0_rise2[pt_i%4])
pat0_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat0_fall2[pt_i%4])
pat0_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == pat0_rise3[pt_i%4])
pat0_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == pat0_fall3[pt_i%4])
pat0_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat1_rise0[pt_i%4])
pat1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat1_fall0[pt_i%4])
pat1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat1_rise1[pt_i%4])
pat1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat1_fall1[pt_i%4])
pat1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat1_rise2[pt_i%4])
pat1_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat1_fall2[pt_i%4])
pat1_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == pat1_rise3[pt_i%4])
pat1_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == pat1_fall3[pt_i%4])
pat1_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
end
// Combine pattern match "subterms" for DQ-IDELAY stage
always @(posedge clk) begin
idel_pat0_match_rise0_and_r <= #TCQ &idel_pat0_match_rise0_r;
idel_pat0_match_fall0_and_r <= #TCQ &idel_pat0_match_fall0_r;
idel_pat0_match_rise1_and_r <= #TCQ &idel_pat0_match_rise1_r;
idel_pat0_match_fall1_and_r <= #TCQ &idel_pat0_match_fall1_r;
idel_pat0_match_rise2_and_r <= #TCQ &idel_pat0_match_rise2_r;
idel_pat0_match_fall2_and_r <= #TCQ &idel_pat0_match_fall2_r;
idel_pat0_match_rise3_and_r <= #TCQ &idel_pat0_match_rise3_r;
idel_pat0_match_fall3_and_r <= #TCQ &idel_pat0_match_fall3_r;
idel_pat0_data_match_r <= #TCQ (idel_pat0_match_rise0_and_r &&
idel_pat0_match_fall0_and_r &&
idel_pat0_match_rise1_and_r &&
idel_pat0_match_fall1_and_r &&
idel_pat0_match_rise2_and_r &&
idel_pat0_match_fall2_and_r &&
idel_pat0_match_rise3_and_r &&
idel_pat0_match_fall3_and_r);
end
always @(posedge clk) begin
idel_pat1_match_rise0_and_r <= #TCQ &idel_pat1_match_rise0_r;
idel_pat1_match_fall0_and_r <= #TCQ &idel_pat1_match_fall0_r;
idel_pat1_match_rise1_and_r <= #TCQ &idel_pat1_match_rise1_r;
idel_pat1_match_fall1_and_r <= #TCQ &idel_pat1_match_fall1_r;
idel_pat1_match_rise2_and_r <= #TCQ &idel_pat1_match_rise2_r;
idel_pat1_match_fall2_and_r <= #TCQ &idel_pat1_match_fall2_r;
idel_pat1_match_rise3_and_r <= #TCQ &idel_pat1_match_rise3_r;
idel_pat1_match_fall3_and_r <= #TCQ &idel_pat1_match_fall3_r;
idel_pat1_data_match_r <= #TCQ (idel_pat1_match_rise0_and_r &&
idel_pat1_match_fall0_and_r &&
idel_pat1_match_rise1_and_r &&
idel_pat1_match_fall1_and_r &&
idel_pat1_match_rise2_and_r &&
idel_pat1_match_fall2_and_r &&
idel_pat1_match_rise3_and_r &&
idel_pat1_match_fall3_and_r);
end
always @(*)
idel_pat_data_match <= #TCQ idel_pat0_data_match_r |
idel_pat1_data_match_r;
always @(posedge clk)
idel_pat_data_match_r <= #TCQ idel_pat_data_match;
// Combine pattern match "subterms" for DQS-PHASER_IN stage
always @(posedge clk) begin
pat0_match_rise0_and_r <= #TCQ &pat0_match_rise0_r;
pat0_match_fall0_and_r <= #TCQ &pat0_match_fall0_r;
pat0_match_rise1_and_r <= #TCQ &pat0_match_rise1_r;
pat0_match_fall1_and_r <= #TCQ &pat0_match_fall1_r;
pat0_match_rise2_and_r <= #TCQ &pat0_match_rise2_r;
pat0_match_fall2_and_r <= #TCQ &pat0_match_fall2_r;
pat0_match_rise3_and_r <= #TCQ &pat0_match_rise3_r;
pat0_match_fall3_and_r <= #TCQ &pat0_match_fall3_r;
pat0_data_match_r <= #TCQ (pat0_match_rise0_and_r &&
pat0_match_fall0_and_r &&
pat0_match_rise1_and_r &&
pat0_match_fall1_and_r &&
pat0_match_rise2_and_r &&
pat0_match_fall2_and_r &&
pat0_match_rise3_and_r &&
pat0_match_fall3_and_r);
end
always @(posedge clk) begin
pat1_match_rise0_and_r <= #TCQ &pat1_match_rise0_r;
pat1_match_fall0_and_r <= #TCQ &pat1_match_fall0_r;
pat1_match_rise1_and_r <= #TCQ &pat1_match_rise1_r;
pat1_match_fall1_and_r <= #TCQ &pat1_match_fall1_r;
pat1_match_rise2_and_r <= #TCQ &pat1_match_rise2_r;
pat1_match_fall2_and_r <= #TCQ &pat1_match_fall2_r;
pat1_match_rise3_and_r <= #TCQ &pat1_match_rise3_r;
pat1_match_fall3_and_r <= #TCQ &pat1_match_fall3_r;
pat1_data_match_r <= #TCQ (pat1_match_rise0_and_r &&
pat1_match_fall0_and_r &&
pat1_match_rise1_and_r &&
pat1_match_fall1_and_r &&
pat1_match_rise2_and_r &&
pat1_match_fall2_and_r &&
pat1_match_rise3_and_r &&
pat1_match_fall3_and_r);
end
assign pat_data_match_r = pat0_data_match_r | pat1_data_match_r;
end else if (nCK_PER_CLK == 2) begin: gen_pat_match_div2
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
// DQ IDELAY pattern detection
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == idel_pat0_rise0[pt_i%4])
idel_pat0_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == idel_pat0_fall0[pt_i%4])
idel_pat0_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == idel_pat0_rise1[pt_i%4])
idel_pat0_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == idel_pat0_fall1[pt_i%4])
idel_pat0_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
idel_pat0_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == idel_pat1_rise0[pt_i%4])
idel_pat1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == idel_pat1_fall0[pt_i%4])
idel_pat1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == idel_pat1_rise1[pt_i%4])
idel_pat1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == idel_pat1_fall1[pt_i%4])
idel_pat1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
idel_pat1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
// DQS DVW pattern detection
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat0_rise0[pt_i%4])
pat0_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat0_fall0[pt_i%4])
pat0_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat0_rise1[pt_i%4])
pat0_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat0_fall1[pt_i%4])
pat0_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat0_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat1_rise0[pt_i%4])
pat1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat1_fall0[pt_i%4])
pat1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat1_rise1[pt_i%4])
pat1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat1_fall1[pt_i%4])
pat1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
end
// Combine pattern match "subterms" for DQ-IDELAY stage
always @(posedge clk) begin
idel_pat0_match_rise0_and_r <= #TCQ &idel_pat0_match_rise0_r;
idel_pat0_match_fall0_and_r <= #TCQ &idel_pat0_match_fall0_r;
idel_pat0_match_rise1_and_r <= #TCQ &idel_pat0_match_rise1_r;
idel_pat0_match_fall1_and_r <= #TCQ &idel_pat0_match_fall1_r;
idel_pat0_data_match_r <= #TCQ (idel_pat0_match_rise0_and_r &&
idel_pat0_match_fall0_and_r &&
idel_pat0_match_rise1_and_r &&
idel_pat0_match_fall1_and_r);
end
always @(posedge clk) begin
idel_pat1_match_rise0_and_r <= #TCQ &idel_pat1_match_rise0_r;
idel_pat1_match_fall0_and_r <= #TCQ &idel_pat1_match_fall0_r;
idel_pat1_match_rise1_and_r <= #TCQ &idel_pat1_match_rise1_r;
idel_pat1_match_fall1_and_r <= #TCQ &idel_pat1_match_fall1_r;
idel_pat1_data_match_r <= #TCQ (idel_pat1_match_rise0_and_r &&
idel_pat1_match_fall0_and_r &&
idel_pat1_match_rise1_and_r &&
idel_pat1_match_fall1_and_r);
end
always @(posedge clk) begin
if (sr_valid_r2)
idel_pat_data_match <= #TCQ idel_pat0_data_match_r |
idel_pat1_data_match_r;
end
//assign idel_pat_data_match = idel_pat0_data_match_r |
// idel_pat1_data_match_r;
always @(posedge clk)
idel_pat_data_match_r <= #TCQ idel_pat_data_match;
// Combine pattern match "subterms" for DQS-PHASER_IN stage
always @(posedge clk) begin
pat0_match_rise0_and_r <= #TCQ &pat0_match_rise0_r;
pat0_match_fall0_and_r <= #TCQ &pat0_match_fall0_r;
pat0_match_rise1_and_r <= #TCQ &pat0_match_rise1_r;
pat0_match_fall1_and_r <= #TCQ &pat0_match_fall1_r;
pat0_data_match_r <= #TCQ (pat0_match_rise0_and_r &&
pat0_match_fall0_and_r &&
pat0_match_rise1_and_r &&
pat0_match_fall1_and_r);
end
always @(posedge clk) begin
pat1_match_rise0_and_r <= #TCQ &pat1_match_rise0_r;
pat1_match_fall0_and_r <= #TCQ &pat1_match_fall0_r;
pat1_match_rise1_and_r <= #TCQ &pat1_match_rise1_r;
pat1_match_fall1_and_r <= #TCQ &pat1_match_fall1_r;
pat1_data_match_r <= #TCQ (pat1_match_rise0_and_r &&
pat1_match_fall0_and_r &&
pat1_match_rise1_and_r &&
pat1_match_fall1_and_r);
end
assign pat_data_match_r = pat0_data_match_r | pat1_data_match_r;
end
endgenerate
always @(posedge clk) begin
rdlvl_stg1_start_r <= #TCQ rdlvl_stg1_start;
mpr_rdlvl_done_r1 <= #TCQ mpr_rdlvl_done_r;
mpr_rdlvl_done_r2 <= #TCQ mpr_rdlvl_done_r1;
mpr_rdlvl_start_r <= #TCQ mpr_rdlvl_start;
end
//***************************************************************************
// First stage calibration: Capture clock
//***************************************************************************
//*****************************************************************
// Keep track of how many samples have been written to shift registers
// Every time RD_SHIFT_LEN samples have been written, then we have a
// full read training pattern loaded into the sr_* registers. Then assert
// sr_valid_r to indicate that: (1) comparison between the sr_* and
// old_sr_* and prev_sr_* registers can take place, (2) transfer of
// the contents of sr_* to old_sr_* and prev_sr_* registers can also
// take place
//*****************************************************************
// verilint STARC-2.2.3.3 off
always @(posedge clk)
if (rst || (mpr_rdlvl_done_r && ~rdlvl_stg1_start)) begin
cnt_shift_r <= #TCQ 'b1;
sr_valid_r <= #TCQ 1'b0;
mpr_valid_r <= #TCQ 1'b0;
end else begin
if (mux_rd_valid_r && mpr_rdlvl_start && ~mpr_rdlvl_done_r) begin
if (cnt_shift_r == 'b0)
mpr_valid_r <= #TCQ 1'b1;
else begin
mpr_valid_r <= #TCQ 1'b0;
cnt_shift_r <= #TCQ cnt_shift_r + 1;
end
end else
mpr_valid_r <= #TCQ 1'b0;
if (mux_rd_valid_r && rdlvl_stg1_start) begin
if (cnt_shift_r == RD_SHIFT_LEN-1) begin
sr_valid_r <= #TCQ 1'b1;
cnt_shift_r <= #TCQ 'b0;
end else begin
sr_valid_r <= #TCQ 1'b0;
cnt_shift_r <= #TCQ cnt_shift_r + 1;
end
end else
// When the current mux_rd_* contents are not valid, then
// retain the current value of cnt_shift_r, and make sure
// that sr_valid_r = 0 to prevent any downstream loads or
// comparisons
sr_valid_r <= #TCQ 1'b0;
end
// verilint STARC-2.2.3.3 on
//*****************************************************************
// Logic to determine when either edge of the data eye encountered
// Pre- and post-IDELAY update data pattern is compared, if they
// differ, than an edge has been encountered. Currently no attempt
// made to determine if the data pattern itself is "correct", only
// whether it changes after incrementing the IDELAY (possible
// future enhancement)
//*****************************************************************
// One-way control for ensuring that state machine request to store
// current read data into OLD SR shift register only occurs on a
// valid clock cycle. The FSM provides a one-cycle request pulse.
// It is the responsibility of the FSM to wait the worst-case time
// before relying on any downstream results of this load.
always @(posedge clk)
if (rst)
store_sr_r <= #TCQ 1'b0;
else begin
if (store_sr_req_r)
store_sr_r <= #TCQ 1'b1;
else if ((sr_valid_r || mpr_valid_r) && store_sr_r)
store_sr_r <= #TCQ 1'b0;
end
// Transfer current data to old data, prior to incrementing delay
// Also store data from current sampling window - so that we can detect
// if the current delay tap yields data that is "jittery"
generate
if (nCK_PER_CLK == 4) begin: gen_old_sr_div4
for (z = 0; z < DRAM_WIDTH; z = z + 1) begin: gen_old_sr
always @(posedge clk) begin
if (sr_valid_r || mpr_valid_r) begin
// Load last sample (i.e. from current sampling interval)
prev_sr_rise0_r[z] <= #TCQ sr_rise0_r[z];
prev_sr_fall0_r[z] <= #TCQ sr_fall0_r[z];
prev_sr_rise1_r[z] <= #TCQ sr_rise1_r[z];
prev_sr_fall1_r[z] <= #TCQ sr_fall1_r[z];
prev_sr_rise2_r[z] <= #TCQ sr_rise2_r[z];
prev_sr_fall2_r[z] <= #TCQ sr_fall2_r[z];
prev_sr_rise3_r[z] <= #TCQ sr_rise3_r[z];
prev_sr_fall3_r[z] <= #TCQ sr_fall3_r[z];
end
if ((sr_valid_r || mpr_valid_r) && store_sr_r) begin
old_sr_rise0_r[z] <= #TCQ sr_rise0_r[z];
old_sr_fall0_r[z] <= #TCQ sr_fall0_r[z];
old_sr_rise1_r[z] <= #TCQ sr_rise1_r[z];
old_sr_fall1_r[z] <= #TCQ sr_fall1_r[z];
old_sr_rise2_r[z] <= #TCQ sr_rise2_r[z];
old_sr_fall2_r[z] <= #TCQ sr_fall2_r[z];
old_sr_rise3_r[z] <= #TCQ sr_rise3_r[z];
old_sr_fall3_r[z] <= #TCQ sr_fall3_r[z];
end
end
end
end else if (nCK_PER_CLK == 2) begin: gen_old_sr_div2
for (z = 0; z < DRAM_WIDTH; z = z + 1) begin: gen_old_sr
always @(posedge clk) begin
if (sr_valid_r || mpr_valid_r) begin
prev_sr_rise0_r[z] <= #TCQ sr_rise0_r[z];
prev_sr_fall0_r[z] <= #TCQ sr_fall0_r[z];
prev_sr_rise1_r[z] <= #TCQ sr_rise1_r[z];
prev_sr_fall1_r[z] <= #TCQ sr_fall1_r[z];
end
if ((sr_valid_r || mpr_valid_r) && store_sr_r) begin
old_sr_rise0_r[z] <= #TCQ sr_rise0_r[z];
old_sr_fall0_r[z] <= #TCQ sr_fall0_r[z];
old_sr_rise1_r[z] <= #TCQ sr_rise1_r[z];
old_sr_fall1_r[z] <= #TCQ sr_fall1_r[z];
end
end
end
end
endgenerate
//*******************************************************
// Match determination occurs over 3 cycles - pipelined for better timing
//*******************************************************
// Match valid with # of cycles of pipelining in match determination
always @(posedge clk) begin
sr_valid_r1 <= #TCQ sr_valid_r;
sr_valid_r2 <= #TCQ sr_valid_r1;
mpr_valid_r1 <= #TCQ mpr_valid_r;
mpr_valid_r2 <= #TCQ mpr_valid_r1;
end
generate
if (nCK_PER_CLK == 4) begin: gen_sr_match_div4
for (z = 0; z < DRAM_WIDTH; z = z + 1) begin: gen_sr_match
always @(posedge clk) begin
// CYCLE1: Compare all bits in DQS grp, generate separate term for
// each bit over four bit times. For example, if there are 8-bits
// per DQS group, 32 terms are generated on cycle 1
// NOTE: Structure HDL such that X on data bus will result in a
// mismatch. This is required for memory models that can drive the
// bus with X's to model uncertainty regions (e.g. Denali)
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise0_r[z] == old_sr_rise0_r[z]))
old_sr_match_rise0_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_rise0_r[z] <= #TCQ old_sr_match_rise0_r[z];
else
old_sr_match_rise0_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall0_r[z] == old_sr_fall0_r[z]))
old_sr_match_fall0_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_fall0_r[z] <= #TCQ old_sr_match_fall0_r[z];
else
old_sr_match_fall0_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise1_r[z] == old_sr_rise1_r[z]))
old_sr_match_rise1_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_rise1_r[z] <= #TCQ old_sr_match_rise1_r[z];
else
old_sr_match_rise1_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall1_r[z] == old_sr_fall1_r[z]))
old_sr_match_fall1_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_fall1_r[z] <= #TCQ old_sr_match_fall1_r[z];
else
old_sr_match_fall1_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise2_r[z] == old_sr_rise2_r[z]))
old_sr_match_rise2_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_rise2_r[z] <= #TCQ old_sr_match_rise2_r[z];
else
old_sr_match_rise2_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall2_r[z] == old_sr_fall2_r[z]))
old_sr_match_fall2_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_fall2_r[z] <= #TCQ old_sr_match_fall2_r[z];
else
old_sr_match_fall2_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise3_r[z] == old_sr_rise3_r[z]))
old_sr_match_rise3_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_rise3_r[z] <= #TCQ old_sr_match_rise3_r[z];
else
old_sr_match_rise3_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall3_r[z] == old_sr_fall3_r[z]))
old_sr_match_fall3_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_fall3_r[z] <= #TCQ old_sr_match_fall3_r[z];
else
old_sr_match_fall3_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise0_r[z] == prev_sr_rise0_r[z]))
prev_sr_match_rise0_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_rise0_r[z] <= #TCQ prev_sr_match_rise0_r[z];
else
prev_sr_match_rise0_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall0_r[z] == prev_sr_fall0_r[z]))
prev_sr_match_fall0_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_fall0_r[z] <= #TCQ prev_sr_match_fall0_r[z];
else
prev_sr_match_fall0_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise1_r[z] == prev_sr_rise1_r[z]))
prev_sr_match_rise1_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_rise1_r[z] <= #TCQ prev_sr_match_rise1_r[z];
else
prev_sr_match_rise1_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall1_r[z] == prev_sr_fall1_r[z]))
prev_sr_match_fall1_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_fall1_r[z] <= #TCQ prev_sr_match_fall1_r[z];
else
prev_sr_match_fall1_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise2_r[z] == prev_sr_rise2_r[z]))
prev_sr_match_rise2_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_rise2_r[z] <= #TCQ prev_sr_match_rise2_r[z];
else
prev_sr_match_rise2_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall2_r[z] == prev_sr_fall2_r[z]))
prev_sr_match_fall2_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_fall2_r[z] <= #TCQ prev_sr_match_fall2_r[z];
else
prev_sr_match_fall2_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise3_r[z] == prev_sr_rise3_r[z]))
prev_sr_match_rise3_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_rise3_r[z] <= #TCQ prev_sr_match_rise3_r[z];
else
prev_sr_match_rise3_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall3_r[z] == prev_sr_fall3_r[z]))
prev_sr_match_fall3_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_fall3_r[z] <= #TCQ prev_sr_match_fall3_r[z];
else
prev_sr_match_fall3_r[z] <= #TCQ 1'b0;
// CYCLE2: Combine all the comparisons for every 8 words (rise0,
// fall0,rise1, fall1) in the calibration sequence. Now we're down
// to DRAM_WIDTH terms
old_sr_match_cyc2_r[z] <= #TCQ
old_sr_match_rise0_r[z] &
old_sr_match_fall0_r[z] &
old_sr_match_rise1_r[z] &
old_sr_match_fall1_r[z] &
old_sr_match_rise2_r[z] &
old_sr_match_fall2_r[z] &
old_sr_match_rise3_r[z] &
old_sr_match_fall3_r[z];
prev_sr_match_cyc2_r[z] <= #TCQ
prev_sr_match_rise0_r[z] &
prev_sr_match_fall0_r[z] &
prev_sr_match_rise1_r[z] &
prev_sr_match_fall1_r[z] &
prev_sr_match_rise2_r[z] &
prev_sr_match_fall2_r[z] &
prev_sr_match_rise3_r[z] &
prev_sr_match_fall3_r[z];
// CYCLE3: Invert value (i.e. assert when DIFFERENCE in value seen),
// and qualify with pipelined valid signal) - probably don't need
// a cycle just do do this....
if (sr_valid_r2 || mpr_valid_r2) begin
old_sr_diff_r[z] <= #TCQ ~old_sr_match_cyc2_r[z];
prev_sr_diff_r[z] <= #TCQ ~prev_sr_match_cyc2_r[z];
end else begin
old_sr_diff_r[z] <= #TCQ 'b0;
prev_sr_diff_r[z] <= #TCQ 'b0;
end
end
end
end if (nCK_PER_CLK == 2) begin: gen_sr_match_div2
for (z = 0; z < DRAM_WIDTH; z = z + 1) begin: gen_sr_match
always @(posedge clk) begin
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise0_r[z] == old_sr_rise0_r[z]))
old_sr_match_rise0_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_rise0_r[z] <= #TCQ old_sr_match_rise0_r[z];
else
old_sr_match_rise0_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall0_r[z] == old_sr_fall0_r[z]))
old_sr_match_fall0_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_fall0_r[z] <= #TCQ old_sr_match_fall0_r[z];
else
old_sr_match_fall0_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise1_r[z] == old_sr_rise1_r[z]))
old_sr_match_rise1_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_rise1_r[z] <= #TCQ old_sr_match_rise1_r[z];
else
old_sr_match_rise1_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall1_r[z] == old_sr_fall1_r[z]))
old_sr_match_fall1_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
old_sr_match_fall1_r[z] <= #TCQ old_sr_match_fall1_r[z];
else
old_sr_match_fall1_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise0_r[z] == prev_sr_rise0_r[z]))
prev_sr_match_rise0_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_rise0_r[z] <= #TCQ prev_sr_match_rise0_r[z];
else
prev_sr_match_rise0_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall0_r[z] == prev_sr_fall0_r[z]))
prev_sr_match_fall0_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_fall0_r[z] <= #TCQ prev_sr_match_fall0_r[z];
else
prev_sr_match_fall0_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_rise1_r[z] == prev_sr_rise1_r[z]))
prev_sr_match_rise1_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_rise1_r[z] <= #TCQ prev_sr_match_rise1_r[z];
else
prev_sr_match_rise1_r[z] <= #TCQ 1'b0;
if ((pat_data_match_r || mpr_valid_r1) && (sr_fall1_r[z] == prev_sr_fall1_r[z]))
prev_sr_match_fall1_r[z] <= #TCQ 1'b1;
else if (~mpr_valid_r1 && mpr_rdlvl_start && ~mpr_rdlvl_done_r)
prev_sr_match_fall1_r[z] <= #TCQ prev_sr_match_fall1_r[z];
else
prev_sr_match_fall1_r[z] <= #TCQ 1'b0;
old_sr_match_cyc2_r[z] <= #TCQ
old_sr_match_rise0_r[z] &
old_sr_match_fall0_r[z] &
old_sr_match_rise1_r[z] &
old_sr_match_fall1_r[z];
prev_sr_match_cyc2_r[z] <= #TCQ
prev_sr_match_rise0_r[z] &
prev_sr_match_fall0_r[z] &
prev_sr_match_rise1_r[z] &
prev_sr_match_fall1_r[z];
// CYCLE3: Invert value (i.e. assert when DIFFERENCE in value seen),
// and qualify with pipelined valid signal) - probably don't need
// a cycle just do do this....
if (sr_valid_r2 || mpr_valid_r2) begin
old_sr_diff_r[z] <= #TCQ ~old_sr_match_cyc2_r[z];
prev_sr_diff_r[z] <= #TCQ ~prev_sr_match_cyc2_r[z];
end else begin
old_sr_diff_r[z] <= #TCQ 'b0;
prev_sr_diff_r[z] <= #TCQ 'b0;
end
end
end
end
endgenerate
//***************************************************************************
// First stage calibration: DQS Capture
//***************************************************************************
//*******************************************************
// Counters for tracking # of samples compared
// For each comparision point (i.e. to determine if an edge has
// occurred after each IODELAY increment when read leveling),
// multiple samples are compared in order to average out the effects
// of jitter. If any one of these samples is different than the "old"
// sample corresponding to the previous IODELAY value, then an edge
// is declared to be detected.
//*******************************************************
// Two cascaded counters are used to keep track of # of samples compared,
// in order to make it easier to meeting timing on these paths. Once
// optimal sampling interval is determined, it may be possible to remove
// the second counter
always @(posedge clk)
samp_edge_cnt0_en_r <= #TCQ
(cal1_state_r == CAL1_PAT_DETECT) ||
(cal1_state_r == CAL1_DETECT_EDGE) ||
(cal1_state_r == CAL1_PB_DETECT_EDGE) ||
(cal1_state_r == CAL1_PB_DETECT_EDGE_DQ);
// First counter counts # of samples compared
always @(posedge clk)
if (rst)
samp_edge_cnt0_r <= #TCQ 'b0;
else begin
if (!samp_edge_cnt0_en_r)
// Reset sample counter when not in any of the "sampling" states
samp_edge_cnt0_r <= #TCQ 'b0;
else if (sr_valid_r2 || mpr_valid_r2)
// Otherwise, count # of samples compared
samp_edge_cnt0_r <= #TCQ samp_edge_cnt0_r + 1;
end
// Counter #2 enable generation
always @(posedge clk)
if (rst)
samp_edge_cnt1_en_r <= #TCQ 1'b0;
else begin
// Assert pulse when correct number of samples compared
if ((samp_edge_cnt0_r == DETECT_EDGE_SAMPLE_CNT0) &&
(sr_valid_r2 || mpr_valid_r2))
samp_edge_cnt1_en_r <= #TCQ 1'b1;
else
samp_edge_cnt1_en_r <= #TCQ 1'b0;
end
// Counter #2
always @(posedge clk)
if (rst)
samp_edge_cnt1_r <= #TCQ 'b0;
else
if (!samp_edge_cnt0_en_r)
samp_edge_cnt1_r <= #TCQ 'b0;
else if (samp_edge_cnt1_en_r)
samp_edge_cnt1_r <= #TCQ samp_edge_cnt1_r + 1;
always @(posedge clk)
if (rst)
samp_cnt_done_r <= #TCQ 1'b0;
else begin
if (!samp_edge_cnt0_en_r)
samp_cnt_done_r <= #TCQ 'b0;
else if ((SIM_CAL_OPTION == "FAST_CAL") ||
(SIM_CAL_OPTION == "FAST_WIN_DETECT")) begin
if (samp_edge_cnt0_r == SR_VALID_DELAY-1)
// For simulation only, stay in edge detection mode a minimum
// amount of time - just enough for two data compares to finish
samp_cnt_done_r <= #TCQ 1'b1;
end else begin
if (samp_edge_cnt1_r == DETECT_EDGE_SAMPLE_CNT1)
samp_cnt_done_r <= #TCQ 1'b1;
end
end
//*****************************************************************
// Logic to keep track of (on per-bit basis):
// 1. When a region of stability preceded by a known edge occurs
// 2. If for the current tap, the read data jitters
// 3. If an edge occured between the current and previous tap
// 4. When the current edge detection/sampling interval can end
// Essentially, these are a series of status bits - the stage 1
// calibration FSM monitors these to determine when an edge is
// found. Additional information is provided to help the FSM
// determine if a left or right edge has been found.
//****************************************************************
assign pb_detect_edge_setup
= (cal1_state_r == CAL1_STORE_FIRST_WAIT) ||
(cal1_state_r == CAL1_PB_STORE_FIRST_WAIT) ||
(cal1_state_r == CAL1_PB_DEC_CPT_LEFT_WAIT);
assign pb_detect_edge
= (cal1_state_r == CAL1_PAT_DETECT) ||
(cal1_state_r == CAL1_DETECT_EDGE) ||
(cal1_state_r == CAL1_PB_DETECT_EDGE) ||
(cal1_state_r == CAL1_PB_DETECT_EDGE_DQ);
generate
for (z = 0; z < DRAM_WIDTH; z = z + 1) begin: gen_track_left_edge
always @(posedge clk) begin
if (pb_detect_edge_setup) begin
// Reset eye size, stable eye marker, and jitter marker before
// starting new edge detection iteration
pb_cnt_eye_size_r[z] <= #TCQ 5'd0;
pb_detect_edge_done_r[z] <= #TCQ 1'b0;
pb_found_stable_eye_r[z] <= #TCQ 1'b0;
pb_last_tap_jitter_r[z] <= #TCQ 1'b0;
pb_found_edge_last_r[z] <= #TCQ 1'b0;
pb_found_edge_r[z] <= #TCQ 1'b0;
pb_found_first_edge_r[z] <= #TCQ 1'b0;
end else if (pb_detect_edge) begin
// Save information on which DQ bits are already out of the
// data valid window - those DQ bits will later not have their
// IDELAY tap value incremented
pb_found_edge_last_r[z] <= #TCQ pb_found_edge_r[z];
if (!pb_detect_edge_done_r[z]) begin
if (samp_cnt_done_r) begin
// If we've reached end of sampling interval, no jitter on
// current tap has been found (although an edge could have
// been found between the current and previous taps), and
// the sampling interval is complete. Increment the stable
// eye counter if no edge found, and always clear the jitter
// flag in preparation for the next tap.
pb_last_tap_jitter_r[z] <= #TCQ 1'b0;
pb_detect_edge_done_r[z] <= #TCQ 1'b1;
if (!pb_found_edge_r[z] && !pb_last_tap_jitter_r[z]) begin
// If the data was completely stable during this tap and
// no edge was found between this and the previous tap
// then increment the stable eye counter "as appropriate"
if (pb_cnt_eye_size_r[z] != MIN_EYE_SIZE-1)
pb_cnt_eye_size_r[z] <= #TCQ pb_cnt_eye_size_r[z] + 1;
else //if (pb_found_first_edge_r[z])
// We've reached minimum stable eye width
pb_found_stable_eye_r[z] <= #TCQ 1'b1;
end else begin
// Otherwise, an edge was found, either because of a
// difference between this and the previous tap's read
// data, and/or because the previous tap's data jittered
// (but not the current tap's data), then just set the
// edge found flag, and enable the stable eye counter
pb_cnt_eye_size_r[z] <= #TCQ 5'd0;
pb_found_stable_eye_r[z] <= #TCQ 1'b0;
pb_found_edge_r[z] <= #TCQ 1'b1;
pb_detect_edge_done_r[z] <= #TCQ 1'b1;
end
end else if (prev_sr_diff_r[z]) begin
// If we find that the current tap read data jitters, then
// set edge and jitter found flags, "enable" the eye size
// counter, and stop sampling interval for this bit
pb_cnt_eye_size_r[z] <= #TCQ 5'd0;
pb_found_stable_eye_r[z] <= #TCQ 1'b0;
pb_last_tap_jitter_r[z] <= #TCQ 1'b1;
pb_found_edge_r[z] <= #TCQ 1'b1;
pb_found_first_edge_r[z] <= #TCQ 1'b1;
pb_detect_edge_done_r[z] <= #TCQ 1'b1;
end else if (old_sr_diff_r[z] || pb_last_tap_jitter_r[z]) begin
// If either an edge was found (i.e. difference between
// current tap and previous tap read data), or the previous
// tap exhibited jitter (which means by definition that the
// current tap cannot match the previous tap because the
// previous tap gave unstable data), then set the edge found
// flag, and "enable" eye size counter. But do not stop
// sampling interval - we still need to check if the current
// tap exhibits jitter
pb_cnt_eye_size_r[z] <= #TCQ 5'd0;
pb_found_stable_eye_r[z] <= #TCQ 1'b0;
pb_found_edge_r[z] <= #TCQ 1'b1;
pb_found_first_edge_r[z] <= #TCQ 1'b1;
end
end
end else begin
// Before every edge detection interval, reset "intra-tap" flags
pb_found_edge_r[z] <= #TCQ 1'b0;
pb_detect_edge_done_r[z] <= #TCQ 1'b0;
end
end
end
endgenerate
// Combine the above per-bit status flags into combined terms when
// performing deskew on the aggregate data window
always @(posedge clk) begin
detect_edge_done_r <= #TCQ &pb_detect_edge_done_r;
found_edge_r <= #TCQ |pb_found_edge_r;
found_edge_all_r <= #TCQ &pb_found_edge_r;
found_stable_eye_r <= #TCQ &pb_found_stable_eye_r;
end
// last IODELAY "stable eye" indicator is updated only after
// detect_edge_done_r is asserted - so that when we do find the "right edge"
// of the data valid window, found_edge_r = 1, AND found_stable_eye_r = 1
// when detect_edge_done_r = 1 (otherwise, if found_stable_eye_r updates
// immediately, then it never possible to have found_stable_eye_r = 1
// when we detect an edge - and we'll never know whether we've found
// a "right edge")
always @(posedge clk)
if (pb_detect_edge_setup)
found_stable_eye_last_r <= #TCQ 1'b0;
else if (detect_edge_done_r)
found_stable_eye_last_r <= #TCQ found_stable_eye_r;
//*****************************************************************
// Keep track of DQ IDELAYE2 taps used
//*****************************************************************
// Added additional register stage to improve timing
always @(posedge clk)
if (rst)
idelay_tap_cnt_slice_r <= 5'h0;
else
idelay_tap_cnt_slice_r <= idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing];
always @(posedge clk)
if (rst || (SIM_CAL_OPTION == "SKIP_CAL")) begin //|| new_cnt_cpt_r
for (s = 0; s < RANKS; s = s + 1) begin
for (t = 0; t < DQS_WIDTH; t = t + 1) begin
idelay_tap_cnt_r[s][t] <= #TCQ idelaye2_init_val;
end
end
end else if (SIM_CAL_OPTION == "FAST_CAL") begin
for (u = 0; u < RANKS; u = u + 1) begin
for (w = 0; w < DQS_WIDTH; w = w + 1) begin
if (cal1_dq_idel_ce) begin
if (cal1_dq_idel_inc)
idelay_tap_cnt_r[u][w] <= #TCQ idelay_tap_cnt_r[u][w] + 1;
else
idelay_tap_cnt_r[u][w] <= #TCQ idelay_tap_cnt_r[u][w] - 1;
end
end
end
end else if ((rnk_cnt_r == RANKS-1) && (RANKS == 2) &&
rdlvl_rank_done_r && (cal1_state_r == CAL1_IDLE)) begin
for (f = 0; f < DQS_WIDTH; f = f + 1) begin
idelay_tap_cnt_r[rnk_cnt_r][f] <= #TCQ idelay_tap_cnt_r[(rnk_cnt_r-1)][f];
end
end else if (cal1_dq_idel_ce) begin
if (cal1_dq_idel_inc)
idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing] <= #TCQ idelay_tap_cnt_slice_r + 5'h1;
else
idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing] <= #TCQ idelay_tap_cnt_slice_r - 5'h1;
end else if (idelay_ld)
idelay_tap_cnt_r[0][wrcal_cnt] <= #TCQ 5'b00000;
always @(posedge clk)
if (rst || new_cnt_cpt_r)
idelay_tap_limit_r <= #TCQ 1'b0;
else if (idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_r] == 'd31)
idelay_tap_limit_r <= #TCQ 1'b1;
//*****************************************************************
// keep track of edge tap counts found, and current capture clock
// tap count
//*****************************************************************
always @(posedge clk)
if (rst || new_cnt_cpt_r ||
(mpr_rdlvl_done_r1 && ~mpr_rdlvl_done_r2))
tap_cnt_cpt_r <= #TCQ 'b0;
else if (cal1_dlyce_cpt_r) begin
if (cal1_dlyinc_cpt_r)
tap_cnt_cpt_r <= #TCQ tap_cnt_cpt_r + 1;
else if (tap_cnt_cpt_r != 'd0)
tap_cnt_cpt_r <= #TCQ tap_cnt_cpt_r - 1;
end
always @(posedge clk)
if (rst || new_cnt_cpt_r ||
(cal1_state_r1 == CAL1_DQ_IDEL_TAP_INC) ||
(mpr_rdlvl_done_r1 && ~mpr_rdlvl_done_r2))
tap_limit_cpt_r <= #TCQ 1'b0;
else if (tap_cnt_cpt_r == 6'd63)
tap_limit_cpt_r <= #TCQ 1'b1;
always @(posedge clk)
cal1_cnt_cpt_timing_r <= #TCQ cal1_cnt_cpt_r;
assign cal1_cnt_cpt_timing = {2'b00, cal1_cnt_cpt_r};
// Storing DQS tap values at the end of each DQS read leveling
always @(posedge clk) begin
if (rst) begin
for (a = 0; a < RANKS; a = a + 1) begin: rst_rdlvl_dqs_tap_count_loop
for (b = 0; b < DQS_WIDTH; b = b + 1)
rdlvl_dqs_tap_cnt_r[a][b] <= #TCQ 'b0;
end
end else if ((SIM_CAL_OPTION == "FAST_CAL") & (cal1_state_r1 == CAL1_NEXT_DQS)) begin
for (p = 0; p < RANKS; p = p +1) begin: rdlvl_dqs_tap_rank_cnt
for(q = 0; q < DQS_WIDTH; q = q +1) begin: rdlvl_dqs_tap_cnt
rdlvl_dqs_tap_cnt_r[p][q] <= #TCQ tap_cnt_cpt_r;
end
end
end else if (SIM_CAL_OPTION == "SKIP_CAL") begin
for (j = 0; j < RANKS; j = j +1) begin: rdlvl_dqs_tap_rnk_cnt
for(i = 0; i < DQS_WIDTH; i = i +1) begin: rdlvl_dqs_cnt
rdlvl_dqs_tap_cnt_r[j][i] <= #TCQ 6'd31;
end
end
end else if (cal1_state_r1 == CAL1_NEXT_DQS) begin
rdlvl_dqs_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing_r] <= #TCQ tap_cnt_cpt_r;
end
end
// Counter to track maximum DQ IODELAY tap usage during the per-bit
// deskew portion of stage 1 calibration
always @(posedge clk)
if (rst) begin
idel_tap_cnt_dq_pb_r <= #TCQ 'b0;
idel_tap_limit_dq_pb_r <= #TCQ 1'b0;
end else
if (new_cnt_cpt_r) begin
idel_tap_cnt_dq_pb_r <= #TCQ 'b0;
idel_tap_limit_dq_pb_r <= #TCQ 1'b0;
end else if (|cal1_dlyce_dq_r) begin
if (cal1_dlyinc_dq_r)
idel_tap_cnt_dq_pb_r <= #TCQ idel_tap_cnt_dq_pb_r + 1;
else
idel_tap_cnt_dq_pb_r <= #TCQ idel_tap_cnt_dq_pb_r - 1;
if (idel_tap_cnt_dq_pb_r == 31)
idel_tap_limit_dq_pb_r <= #TCQ 1'b1;
else
idel_tap_limit_dq_pb_r <= #TCQ 1'b0;
end
//*****************************************************************
always @(posedge clk)
cal1_state_r1 <= #TCQ cal1_state_r;
always @(posedge clk)
if (rst) begin
cal1_cnt_cpt_r <= #TCQ 'b0;
cal1_dlyce_cpt_r <= #TCQ 1'b0;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
cal1_dq_idel_ce <= #TCQ 1'b0;
cal1_dq_idel_inc <= #TCQ 1'b0;
cal1_prech_req_r <= #TCQ 1'b0;
cal1_state_r <= #TCQ CAL1_IDLE;
cnt_idel_dec_cpt_r <= #TCQ 6'bxxxxxx;
found_first_edge_r <= #TCQ 1'b0;
found_second_edge_r <= #TCQ 1'b0;
right_edge_taps_r <= #TCQ 6'bxxxxxx;
first_edge_taps_r <= #TCQ 6'bxxxxxx;
new_cnt_cpt_r <= #TCQ 1'b0;
rdlvl_stg1_done <= #TCQ 1'b0;
rdlvl_stg1_err <= #TCQ 1'b0;
second_edge_taps_r <= #TCQ 6'bxxxxxx;
store_sr_req_pulsed_r <= #TCQ 1'b0;
store_sr_req_r <= #TCQ 1'b0;
rnk_cnt_r <= #TCQ 2'b00;
rdlvl_rank_done_r <= #TCQ 1'b0;
idel_dec_cnt <= #TCQ 'd0;
rdlvl_last_byte_done <= #TCQ 1'b0;
idel_pat_detect_valid_r <= #TCQ 1'b0;
mpr_rank_done_r <= #TCQ 1'b0;
mpr_last_byte_done <= #TCQ 1'b0;
idel_adj_inc <= #TCQ 1'b0;
if (OCAL_EN == "ON")
mpr_rdlvl_done_r <= #TCQ 1'b0;
else
mpr_rdlvl_done_r <= #TCQ 1'b1;
mpr_dec_cpt_r <= #TCQ 1'b0;
end else begin
// default (inactive) states for all "pulse" outputs
// verilint STARC-2.2.3.3 off
cal1_prech_req_r <= #TCQ 1'b0;
cal1_dlyce_cpt_r <= #TCQ 1'b0;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
cal1_dq_idel_ce <= #TCQ 1'b0;
cal1_dq_idel_inc <= #TCQ 1'b0;
new_cnt_cpt_r <= #TCQ 1'b0;
store_sr_req_pulsed_r <= #TCQ 1'b0;
store_sr_req_r <= #TCQ 1'b0;
case (cal1_state_r)
CAL1_IDLE: begin
rdlvl_rank_done_r <= #TCQ 1'b0;
rdlvl_last_byte_done <= #TCQ 1'b0;
mpr_rank_done_r <= #TCQ 1'b0;
mpr_last_byte_done <= #TCQ 1'b0;
if (mpr_rdlvl_start && ~mpr_rdlvl_start_r) begin
cal1_state_r <= #TCQ CAL1_MPR_NEW_DQS_WAIT;
end else
if (rdlvl_stg1_start && ~rdlvl_stg1_start_r) begin
if (SIM_CAL_OPTION == "SKIP_CAL")
cal1_state_r <= #TCQ CAL1_REGL_LOAD;
else if (SIM_CAL_OPTION == "FAST_CAL")
cal1_state_r <= #TCQ CAL1_NEXT_DQS;
else begin
new_cnt_cpt_r <= #TCQ 1'b1;
cal1_state_r <= #TCQ CAL1_NEW_DQS_WAIT;
end
end
end
CAL1_MPR_NEW_DQS_WAIT: begin
cal1_prech_req_r <= #TCQ 1'b0;
if (!cal1_wait_r && mpr_valid_r)
cal1_state_r <= #TCQ CAL1_MPR_PAT_DETECT;
end
// Wait for the new DQS group to change
// also gives time for the read data IN_FIFO to
// output the updated data for the new DQS group
CAL1_NEW_DQS_WAIT: begin
rdlvl_rank_done_r <= #TCQ 1'b0;
rdlvl_last_byte_done <= #TCQ 1'b0;
mpr_rank_done_r <= #TCQ 1'b0;
mpr_last_byte_done <= #TCQ 1'b0;
cal1_prech_req_r <= #TCQ 1'b0;
if (|pi_counter_read_val) begin //VK_REVIEW
mpr_dec_cpt_r <= #TCQ 1'b1;
cal1_state_r <= #TCQ CAL1_IDEL_DEC_CPT;
cnt_idel_dec_cpt_r <= #TCQ pi_counter_read_val;
end else if (!cal1_wait_r) begin
//if (!cal1_wait_r) begin
// Store "previous tap" read data. Technically there is no
// "previous" read data, since we are starting a new DQS
// group, so we'll never find an edge at tap 0 unless the
// data is fluctuating/jittering
store_sr_req_r <= #TCQ 1'b1;
// If per-bit deskew is disabled, then skip the first
// portion of stage 1 calibration
if (PER_BIT_DESKEW == "OFF")
cal1_state_r <= #TCQ CAL1_STORE_FIRST_WAIT;
else if (PER_BIT_DESKEW == "ON")
cal1_state_r <= #TCQ CAL1_PB_STORE_FIRST_WAIT;
end
end
//*****************************************************************
// Per-bit deskew states
//*****************************************************************
// Wait state following storage of initial read data
CAL1_PB_STORE_FIRST_WAIT:
if (!cal1_wait_r)
cal1_state_r <= #TCQ CAL1_PB_DETECT_EDGE;
// Look for an edge on all DQ bits in current DQS group
CAL1_PB_DETECT_EDGE:
if (detect_edge_done_r) begin
if (found_stable_eye_r) begin
// If we've found the left edge for all bits (or more precisely,
// we've found the left edge, and then part of the stable
// window thereafter), then proceed to positioning the CPT clock
// right before the left margin
cnt_idel_dec_cpt_r <= #TCQ MIN_EYE_SIZE + 1;
cal1_state_r <= #TCQ CAL1_PB_DEC_CPT_LEFT;
end else begin
// If we've reached the end of the sampling time, and haven't
// yet found the left margin of all the DQ bits, then:
if (!tap_limit_cpt_r) begin
// If we still have taps left to use, then store current value
// of read data, increment the capture clock, and continue to
// look for (left) edges
store_sr_req_r <= #TCQ 1'b1;
cal1_state_r <= #TCQ CAL1_PB_INC_CPT;
end else begin
// If we ran out of taps moving the capture clock, and we
// haven't finished edge detection, then reset the capture
// clock taps to 0 (gradually, one tap at a time...
// then exit the per-bit portion of the algorithm -
// i.e. proceed to adjust the capture clock and DQ IODELAYs as
cnt_idel_dec_cpt_r <= #TCQ 6'd63;
cal1_state_r <= #TCQ CAL1_PB_DEC_CPT;
end
end
end
// Increment delay for DQS
CAL1_PB_INC_CPT: begin
cal1_dlyce_cpt_r <= #TCQ 1'b1;
cal1_dlyinc_cpt_r <= #TCQ 1'b1;
cal1_state_r <= #TCQ CAL1_PB_INC_CPT_WAIT;
end
// Wait for IODELAY for both capture and internal nodes within
// ISERDES to settle, before checking again for an edge
CAL1_PB_INC_CPT_WAIT: begin
cal1_dlyce_cpt_r <= #TCQ 1'b0;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
if (!cal1_wait_r)
cal1_state_r <= #TCQ CAL1_PB_DETECT_EDGE;
end
// We've found the left edges of the windows for all DQ bits
// (actually, we found it MIN_EYE_SIZE taps ago) Decrement capture
// clock IDELAY to position just outside left edge of data window
CAL1_PB_DEC_CPT_LEFT:
if (cnt_idel_dec_cpt_r == 6'b000000)
cal1_state_r <= #TCQ CAL1_PB_DEC_CPT_LEFT_WAIT;
else begin
cal1_dlyce_cpt_r <= #TCQ 1'b1;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
cnt_idel_dec_cpt_r <= #TCQ cnt_idel_dec_cpt_r - 1;
end
CAL1_PB_DEC_CPT_LEFT_WAIT:
if (!cal1_wait_r)
cal1_state_r <= #TCQ CAL1_PB_DETECT_EDGE_DQ;
// If there is skew between individual DQ bits, then after we've
// positioned the CPT clock, we will be "in the window" for some
// DQ bits ("early" DQ bits), and "out of the window" for others
// ("late" DQ bits). Increase DQ taps until we are out of the
// window for all DQ bits
CAL1_PB_DETECT_EDGE_DQ:
if (detect_edge_done_r)
if (found_edge_all_r) begin
// We're out of the window for all DQ bits in this DQS group
// We're done with per-bit deskew for this group - now decr
// capture clock IODELAY tap count back to 0, and proceed
// with the rest of stage 1 calibration for this DQS group
cnt_idel_dec_cpt_r <= #TCQ tap_cnt_cpt_r;
cal1_state_r <= #TCQ CAL1_PB_DEC_CPT;
end else
if (!idel_tap_limit_dq_pb_r)
// If we still have DQ taps available for deskew, keep
// incrementing IODELAY tap count for the appropriate DQ bits
cal1_state_r <= #TCQ CAL1_PB_INC_DQ;
else begin
// Otherwise, stop immediately (we've done the best we can)
// and proceed with rest of stage 1 calibration
cnt_idel_dec_cpt_r <= #TCQ tap_cnt_cpt_r;
cal1_state_r <= #TCQ CAL1_PB_DEC_CPT;
end
CAL1_PB_INC_DQ: begin
// Increment only those DQ for which an edge hasn't been found yet
cal1_dlyce_dq_r <= #TCQ ~pb_found_edge_last_r;
cal1_dlyinc_dq_r <= #TCQ 1'b1;
cal1_state_r <= #TCQ CAL1_PB_INC_DQ_WAIT;
end
CAL1_PB_INC_DQ_WAIT:
if (!cal1_wait_r)
cal1_state_r <= #TCQ CAL1_PB_DETECT_EDGE_DQ;
// Decrement capture clock taps back to initial value
CAL1_PB_DEC_CPT:
if (cnt_idel_dec_cpt_r == 6'b000000)
cal1_state_r <= #TCQ CAL1_PB_DEC_CPT_WAIT;
else begin
cal1_dlyce_cpt_r <= #TCQ 1'b1;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
cnt_idel_dec_cpt_r <= #TCQ cnt_idel_dec_cpt_r - 1;
end
// Wait for capture clock to settle, then proceed to rest of
// state 1 calibration for this DQS group
CAL1_PB_DEC_CPT_WAIT:
if (!cal1_wait_r) begin
store_sr_req_r <= #TCQ 1'b1;
cal1_state_r <= #TCQ CAL1_STORE_FIRST_WAIT;
end
// When first starting calibration for a DQS group, save the
// current value of the read data shift register, and use this
// as a reference. Note that for the first iteration of the
// edge detection loop, we will in effect be checking for an edge
// at IODELAY taps = 0 - normally, we are comparing the read data
// for IODELAY taps = N, with the read data for IODELAY taps = N-1
// An edge can only be found at IODELAY taps = 0 if the read data
// is changing during this time (possible due to jitter)
CAL1_STORE_FIRST_WAIT: begin
mpr_dec_cpt_r <= #TCQ 1'b0;
if (!cal1_wait_r)
cal1_state_r <= #TCQ CAL1_PAT_DETECT;
end
CAL1_VALID_WAIT: begin
if (!cal1_wait_r)
cal1_state_r <= #TCQ CAL1_MPR_PAT_DETECT;
end
CAL1_MPR_PAT_DETECT: begin
// MPR read leveling for centering DQS in valid window before
// OCLKDELAYED calibration begins in order to eliminate read issues
if (idel_pat_detect_valid_r == 1'b0) begin
cal1_state_r <= #TCQ CAL1_VALID_WAIT;
idel_pat_detect_valid_r <= #TCQ 1'b1;
end else if (idel_pat_detect_valid_r && idel_mpr_pat_detect_r) begin
cal1_state_r <= #TCQ CAL1_DETECT_EDGE;
idel_dec_cnt <= #TCQ 'd0;
end else if (!idelay_tap_limit_r)
cal1_state_r <= #TCQ CAL1_DQ_IDEL_TAP_INC;
else
cal1_state_r <= #TCQ CAL1_RDLVL_ERR;
end
CAL1_PAT_DETECT: begin
// All DQ bits associated with a DQS are pushed to the right one IDELAY
// tap at a time until first rising DQS is in the tri-state region
// before first rising edge window.
// The detect_edge_done_r condition included to support averaging
// during IDELAY tap increments
if (detect_edge_done_r) begin
if (idel_pat_data_match) begin
case (idelay_adj)
2'b01: begin
cal1_state_r <= CAL1_DQ_IDEL_TAP_INC;
idel_dec_cnt <= #TCQ 1'b0;
idel_adj_inc <= #TCQ 1'b1;
end
2'b10: begin //DEC by 1
cal1_state_r <= #TCQ CAL1_DQ_IDEL_TAP_DEC ;
idel_dec_cnt <= #TCQ 1'b1;
idel_adj_inc <= #TCQ 1'b0;
end
default: begin
cal1_state_r <= #TCQ CAL1_DETECT_EDGE;
idel_dec_cnt <= #TCQ 1'b0;
idel_adj_inc <= #TCQ 1'b0;
end
endcase
end else if (!idelay_tap_limit_r) begin
cal1_state_r <= #TCQ CAL1_DQ_IDEL_TAP_INC;
end else begin
cal1_state_r <= #TCQ CAL1_RDLVL_ERR;
end
end
end
// Increment IDELAY tap by 1 for DQ bits in the byte being calibrated
// until left edge of valid window detected
CAL1_DQ_IDEL_TAP_INC: begin
cal1_dq_idel_ce <= #TCQ 1'b1;
cal1_dq_idel_inc <= #TCQ 1'b1;
cal1_state_r <= #TCQ CAL1_DQ_IDEL_TAP_INC_WAIT;
idel_pat_detect_valid_r <= #TCQ 1'b0;
end
CAL1_DQ_IDEL_TAP_INC_WAIT: begin
cal1_dq_idel_ce <= #TCQ 1'b0;
cal1_dq_idel_inc <= #TCQ 1'b0;
if (!cal1_wait_r) begin
idel_adj_inc <= #TCQ 1'b0;
if (idel_adj_inc)
cal1_state_r <= #TCQ CAL1_DETECT_EDGE;
else if (~mpr_rdlvl_done_r & (DRAM_TYPE == "DDR3"))
cal1_state_r <= #TCQ CAL1_MPR_PAT_DETECT;
else
cal1_state_r <= #TCQ CAL1_PAT_DETECT;
end
end
// Decrement by 2 IDELAY taps once idel_pat_data_match detected
CAL1_DQ_IDEL_TAP_DEC: begin
cal1_dq_idel_inc <= #TCQ 1'b0;
cal1_state_r <= #TCQ CAL1_DQ_IDEL_TAP_DEC_WAIT;
if (idel_dec_cnt >= 'd0)
cal1_dq_idel_ce <= #TCQ 1'b1;
else
cal1_dq_idel_ce <= #TCQ 1'b0;
if (idel_dec_cnt > 'd0)
idel_dec_cnt <= #TCQ idel_dec_cnt - 1;
else
idel_dec_cnt <= #TCQ idel_dec_cnt;
end
CAL1_DQ_IDEL_TAP_DEC_WAIT: begin
cal1_dq_idel_ce <= #TCQ 1'b0;
cal1_dq_idel_inc <= #TCQ 1'b0;
if (!cal1_wait_r) begin
if ((idel_dec_cnt > 'd0) || (pi_rdval_cnt > 'd0))
cal1_state_r <= #TCQ CAL1_DQ_IDEL_TAP_DEC;
else if (mpr_dec_cpt_r)
cal1_state_r <= #TCQ CAL1_STORE_FIRST_WAIT;
else
cal1_state_r <= #TCQ CAL1_DETECT_EDGE;
end
end
// Check for presence of data eye edge. During this state, we
// sample the read data multiple times, and look for changes
// in the read data, specifically:
// 1. A change in the read data compared with the value of
// read data from the previous delay tap. This indicates
// that the most recent tap delay increment has moved us
// into either a new window, or moved/kept us in the
// transition/jitter region between windows. Note that this
// condition only needs to be checked for once, and for
// logistical purposes, we check this soon after entering
// this state (see comment in CAL1_DETECT_EDGE below for
// why this is done)
// 2. A change in the read data while we are in this state
// (i.e. in the absence of a tap delay increment). This
// indicates that we're close enough to a window edge that
// jitter will cause the read data to change even in the
// absence of a tap delay change
CAL1_DETECT_EDGE: begin
// Essentially wait for the first comparision to finish, then
// store current data into "old" data register. This store
// happens now, rather than later (e.g. when we've have already
// left this state) in order to avoid the situation the data that
// is stored as "old" data has not been used in an "active
// comparison" - i.e. data is stored after the last comparison
// of this state. In this case, we can miss an edge if the
// following sequence occurs:
// 1. Comparison completes in this state - no edge found
// 2. "Momentary jitter" occurs which "pushes" the data out the
// equivalent of one delay tap
// 3. We store this jittered data as the "old" data
// 4. "Jitter" no longer present
// 5. We increment the delay tap by one
// 6. Now we compare the current with the "old" data - they're
// the same, and no edge is detected
// NOTE: Given the large # of comparisons done in this state, it's
// highly unlikely the above sequence will occur in actual H/W
// Wait for the first load of read data into the comparison
// shift register to finish, then load the current read data
// into the "old" data register. This allows us to do one
// initial comparision between the current read data, and
// stored data corresponding to the previous delay tap
idel_pat_detect_valid_r <= #TCQ 1'b0;
if (!store_sr_req_pulsed_r) begin
// Pulse store_sr_req_r only once in this state
store_sr_req_r <= #TCQ 1'b1;
store_sr_req_pulsed_r <= #TCQ 1'b1;
end else begin
store_sr_req_r <= #TCQ 1'b0;
store_sr_req_pulsed_r <= #TCQ 1'b1;
end
// Continue to sample read data and look for edges until the
// appropriate time interval (shorter for simulation-only,
// much, much longer for actual h/w) has elapsed
if (detect_edge_done_r) begin
if (tap_limit_cpt_r)
// Only one edge detected and ran out of taps since only one
// bit time worth of taps available for window detection. This
// can happen if at tap 0 DQS is in previous window which results
// in only left edge being detected. Or at tap 0 DQS is in the
// current window resulting in only right edge being detected.
// Depending on the frequency this case can also happen if at
// tap 0 DQS is in the left noise region resulting in only left
// edge being detected.
cal1_state_r <= #TCQ CAL1_CALC_IDEL;
else if (found_edge_r) begin
// Sticky bit - asserted after we encounter an edge, although
// the current edge may not be considered the "first edge" this
// just means we found at least one edge
found_first_edge_r <= #TCQ 1'b1;
// Only the right edge of the data valid window is found
// Record the inner right edge tap value
if (!found_first_edge_r && found_stable_eye_last_r) begin
if (tap_cnt_cpt_r == 'd0)
right_edge_taps_r <= #TCQ 'd0;
else
right_edge_taps_r <= #TCQ tap_cnt_cpt_r;
end
// Both edges of data valid window found:
// If we've found a second edge after a region of stability
// then we must have just passed the second ("right" edge of
// the window. Record this second_edge_taps = current tap-1,
// because we're one past the actual second edge tap, where
// the edge taps represent the extremes of the data valid
// window (i.e. smallest & largest taps where data still valid
if (found_first_edge_r && found_stable_eye_last_r) begin
found_second_edge_r <= #TCQ 1'b1;
second_edge_taps_r <= #TCQ tap_cnt_cpt_r - 1;
cal1_state_r <= #TCQ CAL1_CALC_IDEL;
end else begin
// Otherwise, an edge was found (just not the "second" edge)
// Assuming DQS is in the correct window at tap 0 of Phaser IN
// fine tap. The first edge found is the right edge of the valid
// window and is the beginning of the jitter region hence done!
first_edge_taps_r <= #TCQ tap_cnt_cpt_r;
cal1_state_r <= #TCQ CAL1_IDEL_INC_CPT;
end
end else
// Otherwise, if we haven't found an edge....
// If we still have taps left to use, then keep incrementing
cal1_state_r <= #TCQ CAL1_IDEL_INC_CPT;
end
end
// Increment Phaser_IN delay for DQS
CAL1_IDEL_INC_CPT: begin
cal1_state_r <= #TCQ CAL1_IDEL_INC_CPT_WAIT;
if (~tap_limit_cpt_r) begin
cal1_dlyce_cpt_r <= #TCQ 1'b1;
cal1_dlyinc_cpt_r <= #TCQ 1'b1;
end else begin
cal1_dlyce_cpt_r <= #TCQ 1'b0;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
end
end
// Wait for Phaser_In to settle, before checking again for an edge
CAL1_IDEL_INC_CPT_WAIT: begin
cal1_dlyce_cpt_r <= #TCQ 1'b0;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
if (!cal1_wait_r)
cal1_state_r <= #TCQ CAL1_DETECT_EDGE;
end
// Calculate final value of Phaser_IN taps. At this point, one or both
// edges of data eye have been found, and/or all taps have been
// exhausted looking for the edges
// NOTE: We're calculating the amount to decrement by, not the
// absolute setting for DQS.
CAL1_CALC_IDEL: begin
// CASE1: If 2 edges found.
if (found_second_edge_r)
cnt_idel_dec_cpt_r
<= #TCQ ((second_edge_taps_r -
first_edge_taps_r)>>1) + 1;
else if (right_edge_taps_r > 6'd0)
// Only right edge detected
// right_edge_taps_r is the inner right edge tap value
// hence used for calculation
cnt_idel_dec_cpt_r
<= #TCQ (tap_cnt_cpt_r - (right_edge_taps_r>>1));
else if (found_first_edge_r)
// Only left edge detected
cnt_idel_dec_cpt_r
<= #TCQ ((tap_cnt_cpt_r - first_edge_taps_r)>>1);
else
cnt_idel_dec_cpt_r
<= #TCQ (tap_cnt_cpt_r>>1);
// Now use the value we just calculated to decrement CPT taps
// to the desired calibration point
cal1_state_r <= #TCQ CAL1_IDEL_DEC_CPT;
end
// decrement capture clock for final adjustment - center
// capture clock in middle of data eye. This adjustment will occur
// only when both the edges are found usign CPT taps. Must do this
// incrementally to avoid clock glitching (since CPT drives clock
// divider within each ISERDES)
CAL1_IDEL_DEC_CPT: begin
cal1_dlyce_cpt_r <= #TCQ 1'b1;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
// once adjustment is complete, we're done with calibration for
// this DQS, repeat for next DQS
cnt_idel_dec_cpt_r <= #TCQ cnt_idel_dec_cpt_r - 1;
if (cnt_idel_dec_cpt_r == 6'b000001) begin
if (mpr_dec_cpt_r) begin
if (|idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing]) begin
idel_dec_cnt <= #TCQ idelay_tap_cnt_r[rnk_cnt_r][cal1_cnt_cpt_timing];
cal1_state_r <= #TCQ CAL1_DQ_IDEL_TAP_DEC;
end else
cal1_state_r <= #TCQ CAL1_STORE_FIRST_WAIT;
end else
cal1_state_r <= #TCQ CAL1_NEXT_DQS;
end else
cal1_state_r <= #TCQ CAL1_IDEL_DEC_CPT_WAIT;
end
CAL1_IDEL_DEC_CPT_WAIT: begin
cal1_dlyce_cpt_r <= #TCQ 1'b0;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
if (!cal1_wait_r)
cal1_state_r <= #TCQ CAL1_IDEL_DEC_CPT;
end
// Determine whether we're done, or have more DQS's to calibrate
// Also request precharge after every byte, as appropriate
CAL1_NEXT_DQS: begin
//if (mpr_rdlvl_done_r || (DRAM_TYPE == "DDR2"))
cal1_prech_req_r <= #TCQ 1'b1;
//else
// cal1_prech_req_r <= #TCQ 1'b0;
cal1_dlyce_cpt_r <= #TCQ 1'b0;
cal1_dlyinc_cpt_r <= #TCQ 1'b0;
// Prepare for another iteration with next DQS group
found_first_edge_r <= #TCQ 1'b0;
found_second_edge_r <= #TCQ 1'b0;
first_edge_taps_r <= #TCQ 'd0;
second_edge_taps_r <= #TCQ 'd0;
if ((SIM_CAL_OPTION == "FAST_CAL") ||
(cal1_cnt_cpt_r >= DQS_WIDTH-1)) begin
if (mpr_rdlvl_done_r) begin
rdlvl_last_byte_done <= #TCQ 1'b1;
mpr_last_byte_done <= #TCQ 1'b0;
end else begin
rdlvl_last_byte_done <= #TCQ 1'b0;
mpr_last_byte_done <= #TCQ 1'b1;
end
end
// Wait until precharge that occurs in between calibration of
// DQS groups is finished
if (prech_done) begin // || (~mpr_rdlvl_done_r & (DRAM_TYPE == "DDR3"))) begin
if (SIM_CAL_OPTION == "FAST_CAL") begin
//rdlvl_rank_done_r <= #TCQ 1'b1;
rdlvl_last_byte_done <= #TCQ 1'b0;
mpr_last_byte_done <= #TCQ 1'b0;
cal1_state_r <= #TCQ CAL1_DONE; //CAL1_REGL_LOAD;
end else if (cal1_cnt_cpt_r >= DQS_WIDTH-1) begin
if (~mpr_rdlvl_done_r) begin
mpr_rank_done_r <= #TCQ 1'b1;
// if (rnk_cnt_r == RANKS-1) begin
// All DQS groups in all ranks done
cal1_state_r <= #TCQ CAL1_DONE;
cal1_cnt_cpt_r <= #TCQ 'b0;
// end else begin
// // Process DQS groups in next rank
// rnk_cnt_r <= #TCQ rnk_cnt_r + 1;
// new_cnt_cpt_r <= #TCQ 1'b1;
// cal1_cnt_cpt_r <= #TCQ 'b0;
// cal1_state_r <= #TCQ CAL1_IDLE;
// end
end else begin
// All DQS groups in a rank done
rdlvl_rank_done_r <= #TCQ 1'b1;
if (rnk_cnt_r == RANKS-1) begin
// All DQS groups in all ranks done
cal1_state_r <= #TCQ CAL1_REGL_LOAD;
end else begin
// Process DQS groups in next rank
rnk_cnt_r <= #TCQ rnk_cnt_r + 1;
new_cnt_cpt_r <= #TCQ 1'b1;
cal1_cnt_cpt_r <= #TCQ 'b0;
cal1_state_r <= #TCQ CAL1_IDLE;
end
end
end else begin
// Process next DQS group
new_cnt_cpt_r <= #TCQ 1'b1;
cal1_cnt_cpt_r <= #TCQ cal1_cnt_cpt_r + 1;
cal1_state_r <= #TCQ CAL1_NEW_DQS_PREWAIT;
end
end
end
CAL1_NEW_DQS_PREWAIT: begin
if (!cal1_wait_r) begin
if (~mpr_rdlvl_done_r & (DRAM_TYPE == "DDR3"))
cal1_state_r <= #TCQ CAL1_MPR_NEW_DQS_WAIT;
else
cal1_state_r <= #TCQ CAL1_NEW_DQS_WAIT;
end
end
// Load rank registers in Phaser_IN
CAL1_REGL_LOAD: begin
rdlvl_rank_done_r <= #TCQ 1'b0;
mpr_rank_done_r <= #TCQ 1'b0;
cal1_prech_req_r <= #TCQ 1'b0;
cal1_cnt_cpt_r <= #TCQ 'b0;
rnk_cnt_r <= #TCQ 2'b00;
if ((regl_rank_cnt == RANKS-1) &&
((regl_dqs_cnt == DQS_WIDTH-1) && (done_cnt == 4'd1))) begin
cal1_state_r <= #TCQ CAL1_DONE;
rdlvl_last_byte_done <= #TCQ 1'b0;
mpr_last_byte_done <= #TCQ 1'b0;
end else
cal1_state_r <= #TCQ CAL1_REGL_LOAD;
end
CAL1_RDLVL_ERR: begin
rdlvl_stg1_err <= #TCQ 1'b1;
end
// Done with this stage of calibration
// if used, allow DEBUG_PORT to control taps
CAL1_DONE: begin
mpr_rdlvl_done_r <= #TCQ 1'b1;
cal1_prech_req_r <= #TCQ 1'b0;
if (~mpr_rdlvl_done_r && (OCAL_EN=="ON") && (DRAM_TYPE == "DDR3")) begin
rdlvl_stg1_done <= #TCQ 1'b0;
cal1_state_r <= #TCQ CAL1_IDLE;
end else
rdlvl_stg1_done <= #TCQ 1'b1;
end
endcase
end
// verilint STARC-2.2.3.3 on
endmodule
|
module
generate
if(CKE_ODT_AUX == "TRUE") begin
assign aux_out_map = ((DRAM_TYPE == "DDR2") && (RANKS == 1)) ?
{mux_aux_out[1],mux_aux_out[1],mux_aux_out[1],mux_aux_out[0]} :
mux_aux_out;
end else begin
assign aux_out_map = 4'b0000 ;
end
endgenerate
assign init_calib_complete = phy_init_data_sel;
assign phy_mc_ctl_full = phy_ctl_full;
assign phy_mc_cmd_full = phy_cmd_full;
assign phy_mc_data_full = phy_pre_data_a_full;
//***************************************************************************
// Generate parity for DDR3 RDIMM.
//***************************************************************************
generate
if ((DRAM_TYPE == "DDR3") && (REG_CTRL == "ON")) begin: gen_ddr3_parity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ (^{mux_address[(ROW_WIDTH*4)-1:ROW_WIDTH*3],
mux_bank[(BANK_WIDTH*4)-1:BANK_WIDTH*3],
mux_cas_n[3], mux_ras_n[3], mux_we_n[3]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0], mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0],mux_ras_n[0], mux_we_n[0]});
parity[2] = (^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
parity[3] = (^{mux_address[(ROW_WIDTH*3)-1:ROW_WIDTH*2],
mux_bank[(BANK_WIDTH*3)-1:BANK_WIDTH*2],
mux_cas_n[2],mux_ras_n[2], mux_we_n[2]});
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ(^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0],
mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0], mux_ras_n[0], mux_we_n[0]});
end
end
end else begin: gen_ddr3_noparity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
parity[2] <= #TCQ 1'b0;
parity[3] <= #TCQ 1'b0;
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
end
end
end
endgenerate
//***************************************************************************
// Code for optional register stage in read path to MC for timing
//***************************************************************************
generate
if(RD_PATH_REG == 1)begin:RD_REG_TIMING
always @(posedge clk)begin
rddata_valid_reg <= #TCQ phy_rddata_valid_w;
rd_data_reg <= #TCQ rd_data_map;
end // always @ (posedge clk)
end else begin : RD_REG_NO_TIMING // block: RD_REG_TIMING
always @(phy_rddata_valid_w or rd_data_map)begin
rddata_valid_reg = phy_rddata_valid_w;
rd_data_reg = rd_data_map;
end
end
endgenerate
assign phy_rddata_valid = rddata_valid_reg;
assign phy_rd_data = rd_data_reg;
//***************************************************************************
// Hard PHY and accompanying bit mapping logic
//***************************************************************************
mig_7series_v2_3_ddr_mc_phy_wrapper #
(
.TCQ (TCQ),
.tCK (tCK),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.BANK_WIDTH (BANK_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.CS_WIDTH (CS_WIDTH),
.CK_WIDTH (CK_WIDTH),
.LP_DDR_CK_WIDTH (LP_DDR_CK_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.CWL (CWL),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.IBUF_LPWR_MODE (IBUF_LPWR_MODE),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.HIGHEST_BANK (HIGHEST_BANK),
.HIGHEST_LANE (HIGHEST_LANE),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DRAM_WIDTH (DRAM_WIDTH),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_mc_phy_wrapper
(
.rst (rst),
.iddr_rst (iddr_rst),
.clk (clk),
// For memory frequencies between 400~1066 MHz freq_refclk = mem_refclk
// For memory frequencies below 400 MHz mem_refclk = mem_refclk and
// freq_refclk = 2x or 4x mem_refclk such that it remains in the
// 400~1066 MHz range
.freq_refclk (freq_refclk),
.mem_refclk (mem_refclk),
.mmcm_ps_clk (mmcm_ps_clk),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
.idelayctrl_refclk (clk_ref),
.phy_cmd_wr_en (mux_cmd_wren),
.phy_data_wr_en (mux_wrdata_en),
// phy_ctl_wd = {ACTPRE[31:30],EventDelay[29:25],seq[24:23],
// DataOffset[22:17],HiIndex[16:15],LowIndex[14:12],
// AuxOut[11:8],ControlOffset[7:3],PHYCmd[2:0]}
// The fields ACTPRE, and BankCount are only used
// when the hard PHY counters are used by the MC.
.phy_ctl_wd ({5'd0, mux_cas_slot, calib_seq, mux_data_offset,
mux_rank_cnt, 3'd0, aux_out_map,
5'd0, mux_cmd}),
.phy_ctl_wr (mux_ctl_wren),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
.data_offset_1 (mux_data_offset_1),
.data_offset_2 (mux_data_offset_2),
.aux_in_1 (aux_out_map),
.aux_in_2 (aux_out_map),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
.if_empty (if_empty),
.phy_ctl_full (phy_ctl_full),
.phy_cmd_full (phy_cmd_full),
.phy_data_full (phy_data_full),
.phy_pre_data_a_full (phy_pre_data_a_full),
.ddr_clk (ddr_clk),
.phy_mc_go (phy_mc_go),
.phy_write_calib (phy_write_calib),
.phy_read_calib (phy_read_calib),
.po_fine_enable (po_enstg2_f),
.po_coarse_enable (po_enstg2_c),
.po_fine_inc (po_stg2_fincdec),
.po_coarse_inc (po_stg2_cincdec),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_en (1'b1),
.po_sel_fine_oclk_delay (po_sel_stg2stg3),
.po_counter_load_val (),
.po_counter_read_val (po_counter_read_val),
.pi_rst_dqs_find (rst_stg1_cal),
.pi_fine_enable (pi_enstg2_f),
.pi_fine_inc (pi_stg2_fincdec),
.pi_counter_load_en (pi_stg2_load),
.pi_counter_load_val (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
.pi_phase_locked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_dqs_found (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
// Currently not being used. May be used in future if periodic reads
// become a requirement. This output could also be used to signal a
// catastrophic failure in read capture and the need for re-cal
.pi_dqs_out_of_range (pi_dqs_out_of_range),
.phy_init_data_sel (phy_init_data_sel),
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.mux_address (mux_address),
.mux_bank (mux_bank),
.mux_cs_n (mux_cs_n),
.mux_ras_n (mux_ras_n),
.mux_cas_n (mux_cas_n),
.mux_we_n (mux_we_n),
.mux_reset_n (mux_reset_n),
.parity_in (parity),
.mux_wrdata (mux_wrdata),
.mux_wrdata_mask (mux_wrdata_mask),
.mux_odt (mux_odt),
.mux_cke (mux_cke),
.idle (idle),
.rd_data (rd_data_map),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_cas_n (ddr_cas_n),
.ddr_cke (ddr_cke),
.ddr_cs_n (ddr_cs_n),
.ddr_dm (ddr_dm),
.ddr_odt (ddr_odt),
.ddr_parity (ddr_parity),
.ddr_ras_n (ddr_ras_n),
.ddr_we_n (ddr_we_n),
.ddr_dq (ddr_dq),
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_reset_n (ddr_reset_n),
.dbg_pi_counter_read_en (1'b1),
.ref_dll_lock (ref_dll_lock),
.rst_phaser_ref (rst_phaser_ref),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.byte_sel_cnt (byte_sel_cnt),
.pd_out (pd_out),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
//***************************************************************************
// Soft memory initialization and calibration logic
//***************************************************************************
mig_7series_v2_3_ddr_calib_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.tCK (tCK),
.CLK_PERIOD (CLK_PERIOD),
.N_CTL_LANES (N_CTL_LANES),
.CTL_BYTE_LANE (CTL_BYTE_LANE),
.CTL_BANK (CTL_BANK),
.DRAM_TYPE (DRAM_TYPE),
.PRBS_WIDTH (8),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.HIGHEST_BANK (HIGHEST_BANK),
.BANK_TYPE (BANK_TYPE),
.HIGHEST_LANE (HIGHEST_LANE),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.BANK_WIDTH (BANK_WIDTH),
.CA_MIRROR (CA_MIRROR),
.COL_WIDTH (COL_WIDTH),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nCS_PER_RANK (nCS_PER_RANK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.RANKS (RANKS),
.CS_WIDTH (CS_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.PER_BIT_DESKEW ("OFF"),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.AL (AL),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.nCL (CL),
.nCWL (CWL),
.tRFC (tRFC),
.tREFI (tREFI),
.OUTPUT_DRV (OUTPUT_DRV),
.REG_CTRL (REG_CTRL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.WRLVL (WRLVL_W),
.USE_ODT_PORT (USE_ODT_PORT),
.SIM_INIT_OPTION (SIM_INIT_OPTION),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_calib_top
(
.clk (clk),
.rst (rst),
.tg_err (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
// PHY Control Block and IN_FIFO status
.phy_ctl_ready (phy_mc_go),
.phy_ctl_full (1'b0),
.phy_cmd_full (1'b0),
.phy_data_full (1'b0),
.phy_if_empty (if_empty),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
// From calib logic To data IN_FIFO
// DQ IDELAY tap value from Calib logic
// port to be added to mc_phy by Gary
.dlyval_dq (),
// hard PHY calibration modes
.write_calib (phy_write_calib),
.read_calib (phy_read_calib),
// DQS count and ck/addr/cmd to be mapped to calib_sel
// based on parameter that defines placement of ctl lanes
// and DQS byte groups in each bank. When phy_write_calib
// is de-asserted calib_sel should select CK/addr/cmd/ctl.
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
// Signals from calib logic to be MUXED with MC
// signals before sending to hard PHY
.calib_ctl_wren (calib_ctl_wren),
.calib_cmd_wren (calib_cmd_wren),
.calib_seq (calib_seq),
.calib_aux_out (calib_aux_out),
.calib_odt (calib_odt),
.calib_cke (calib_cke),
.calib_cmd (calib_cmd),
.calib_wrdata_en (calib_wrdata_en),
.calib_rank_cnt (calib_rank_cnt),
.calib_cas_slot (calib_cas_slot),
.calib_data_offset_0 (calib_data_offset_0),
.calib_data_offset_1 (calib_data_offset_1),
.calib_data_offset_2 (calib_data_offset_2),
.phy_reset_n (phy_reset_n),
.phy_address (phy_address),
.phy_bank (phy_bank),
.phy_cs_n (phy_cs_n),
.phy_ras_n (phy_ras_n),
.phy_cas_n (phy_cas_n),
.phy_we_n (phy_we_n),
.phy_wrdata (phy_wrdata),
// DQS Phaser_IN calibration/status signals
.pi_phaselocked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_found_dqs (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
.pi_dqs_found_lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.pi_rst_stg1_cal (rst_stg1_cal),
.pi_en_stg2_f (pi_enstg2_f),
.pi_stg2_f_incdec (pi_stg2_fincdec),
.pi_stg2_load (pi_stg2_load),
.pi_stg2_reg_l (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.device_temp (device_temp),
.tempmon_sample_en (tempmon_sample_en),
// IDELAY tap enable and inc signals
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
// DQS Phaser_OUT calibration/status signals
.po_sel_stg2stg3 (po_sel_stg2stg3),
.po_stg2_c_incdec (po_stg2_cincdec),
.po_en_stg2_c (po_enstg2_c),
.po_stg2_f_incdec (po_stg2_fincdec),
.po_en_stg2_f (po_enstg2_f),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_val (po_counter_read_val),
// From data IN_FIFO To Calib logic and MC/UI
.phy_rddata (rd_data_map),
// From calib logic To MC
.phy_rddata_valid (phy_rddata_valid_w),
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.calib_writes (),
// Mem Init and Calibration status To MC
.init_calib_complete (phy_init_data_sel),
.init_wrcal_complete (init_wrcal_complete),
// Debug Error signals
.pi_phase_locked_err (dbg_pi_phaselock_err),
.pi_dqsfound_err (dbg_pi_dqsfound_err),
.wrcal_err (dbg_wrcal_err),
//used for oclk stg3 centering
.pd_out (pd_out),
.psen (psen),
.psincdec (psincdec),
.psdone (psdone),
.poc_sample_pd (poc_sample_pd),
// Debug Signals
.dbg_pi_phaselock_start (dbg_pi_phaselock_start),
.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start),
.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_wrcal_start (dbg_wrcal_start),
.dbg_wrcal_done (dbg_wrcal_done),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_sel_pi_incdec (dbg_sel_pi_incdec),
.dbg_sel_po_incdec (dbg_sel_po_incdec),
.dbg_byte_sel (dbg_byte_sel),
.dbg_pi_f_inc (dbg_pi_f_inc),
.dbg_pi_f_dec (dbg_pi_f_dec),
.dbg_po_f_inc (dbg_po_f_inc),
.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel),
.dbg_po_f_dec (dbg_po_f_dec),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_calib_top (dbg_calib_top),
.dbg_phy_init (dbg_phy_init),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.dbg_dqs_found_cal (dbg_dqs_found_cal),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data),
.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start),
.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done),
.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps),
.byte_sel_cnt (byte_sel_cnt),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
endmodule
|
module
generate
if(CKE_ODT_AUX == "TRUE") begin
assign aux_out_map = ((DRAM_TYPE == "DDR2") && (RANKS == 1)) ?
{mux_aux_out[1],mux_aux_out[1],mux_aux_out[1],mux_aux_out[0]} :
mux_aux_out;
end else begin
assign aux_out_map = 4'b0000 ;
end
endgenerate
assign init_calib_complete = phy_init_data_sel;
assign phy_mc_ctl_full = phy_ctl_full;
assign phy_mc_cmd_full = phy_cmd_full;
assign phy_mc_data_full = phy_pre_data_a_full;
//***************************************************************************
// Generate parity for DDR3 RDIMM.
//***************************************************************************
generate
if ((DRAM_TYPE == "DDR3") && (REG_CTRL == "ON")) begin: gen_ddr3_parity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ (^{mux_address[(ROW_WIDTH*4)-1:ROW_WIDTH*3],
mux_bank[(BANK_WIDTH*4)-1:BANK_WIDTH*3],
mux_cas_n[3], mux_ras_n[3], mux_we_n[3]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0], mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0],mux_ras_n[0], mux_we_n[0]});
parity[2] = (^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
parity[3] = (^{mux_address[(ROW_WIDTH*3)-1:ROW_WIDTH*2],
mux_bank[(BANK_WIDTH*3)-1:BANK_WIDTH*2],
mux_cas_n[2],mux_ras_n[2], mux_we_n[2]});
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ(^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0],
mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0], mux_ras_n[0], mux_we_n[0]});
end
end
end else begin: gen_ddr3_noparity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
parity[2] <= #TCQ 1'b0;
parity[3] <= #TCQ 1'b0;
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
end
end
end
endgenerate
//***************************************************************************
// Code for optional register stage in read path to MC for timing
//***************************************************************************
generate
if(RD_PATH_REG == 1)begin:RD_REG_TIMING
always @(posedge clk)begin
rddata_valid_reg <= #TCQ phy_rddata_valid_w;
rd_data_reg <= #TCQ rd_data_map;
end // always @ (posedge clk)
end else begin : RD_REG_NO_TIMING // block: RD_REG_TIMING
always @(phy_rddata_valid_w or rd_data_map)begin
rddata_valid_reg = phy_rddata_valid_w;
rd_data_reg = rd_data_map;
end
end
endgenerate
assign phy_rddata_valid = rddata_valid_reg;
assign phy_rd_data = rd_data_reg;
//***************************************************************************
// Hard PHY and accompanying bit mapping logic
//***************************************************************************
mig_7series_v2_3_ddr_mc_phy_wrapper #
(
.TCQ (TCQ),
.tCK (tCK),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.BANK_WIDTH (BANK_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.CS_WIDTH (CS_WIDTH),
.CK_WIDTH (CK_WIDTH),
.LP_DDR_CK_WIDTH (LP_DDR_CK_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.CWL (CWL),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.IBUF_LPWR_MODE (IBUF_LPWR_MODE),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.HIGHEST_BANK (HIGHEST_BANK),
.HIGHEST_LANE (HIGHEST_LANE),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DRAM_WIDTH (DRAM_WIDTH),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_mc_phy_wrapper
(
.rst (rst),
.iddr_rst (iddr_rst),
.clk (clk),
// For memory frequencies between 400~1066 MHz freq_refclk = mem_refclk
// For memory frequencies below 400 MHz mem_refclk = mem_refclk and
// freq_refclk = 2x or 4x mem_refclk such that it remains in the
// 400~1066 MHz range
.freq_refclk (freq_refclk),
.mem_refclk (mem_refclk),
.mmcm_ps_clk (mmcm_ps_clk),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
.idelayctrl_refclk (clk_ref),
.phy_cmd_wr_en (mux_cmd_wren),
.phy_data_wr_en (mux_wrdata_en),
// phy_ctl_wd = {ACTPRE[31:30],EventDelay[29:25],seq[24:23],
// DataOffset[22:17],HiIndex[16:15],LowIndex[14:12],
// AuxOut[11:8],ControlOffset[7:3],PHYCmd[2:0]}
// The fields ACTPRE, and BankCount are only used
// when the hard PHY counters are used by the MC.
.phy_ctl_wd ({5'd0, mux_cas_slot, calib_seq, mux_data_offset,
mux_rank_cnt, 3'd0, aux_out_map,
5'd0, mux_cmd}),
.phy_ctl_wr (mux_ctl_wren),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
.data_offset_1 (mux_data_offset_1),
.data_offset_2 (mux_data_offset_2),
.aux_in_1 (aux_out_map),
.aux_in_2 (aux_out_map),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
.if_empty (if_empty),
.phy_ctl_full (phy_ctl_full),
.phy_cmd_full (phy_cmd_full),
.phy_data_full (phy_data_full),
.phy_pre_data_a_full (phy_pre_data_a_full),
.ddr_clk (ddr_clk),
.phy_mc_go (phy_mc_go),
.phy_write_calib (phy_write_calib),
.phy_read_calib (phy_read_calib),
.po_fine_enable (po_enstg2_f),
.po_coarse_enable (po_enstg2_c),
.po_fine_inc (po_stg2_fincdec),
.po_coarse_inc (po_stg2_cincdec),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_en (1'b1),
.po_sel_fine_oclk_delay (po_sel_stg2stg3),
.po_counter_load_val (),
.po_counter_read_val (po_counter_read_val),
.pi_rst_dqs_find (rst_stg1_cal),
.pi_fine_enable (pi_enstg2_f),
.pi_fine_inc (pi_stg2_fincdec),
.pi_counter_load_en (pi_stg2_load),
.pi_counter_load_val (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
.pi_phase_locked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_dqs_found (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
// Currently not being used. May be used in future if periodic reads
// become a requirement. This output could also be used to signal a
// catastrophic failure in read capture and the need for re-cal
.pi_dqs_out_of_range (pi_dqs_out_of_range),
.phy_init_data_sel (phy_init_data_sel),
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.mux_address (mux_address),
.mux_bank (mux_bank),
.mux_cs_n (mux_cs_n),
.mux_ras_n (mux_ras_n),
.mux_cas_n (mux_cas_n),
.mux_we_n (mux_we_n),
.mux_reset_n (mux_reset_n),
.parity_in (parity),
.mux_wrdata (mux_wrdata),
.mux_wrdata_mask (mux_wrdata_mask),
.mux_odt (mux_odt),
.mux_cke (mux_cke),
.idle (idle),
.rd_data (rd_data_map),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_cas_n (ddr_cas_n),
.ddr_cke (ddr_cke),
.ddr_cs_n (ddr_cs_n),
.ddr_dm (ddr_dm),
.ddr_odt (ddr_odt),
.ddr_parity (ddr_parity),
.ddr_ras_n (ddr_ras_n),
.ddr_we_n (ddr_we_n),
.ddr_dq (ddr_dq),
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_reset_n (ddr_reset_n),
.dbg_pi_counter_read_en (1'b1),
.ref_dll_lock (ref_dll_lock),
.rst_phaser_ref (rst_phaser_ref),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.byte_sel_cnt (byte_sel_cnt),
.pd_out (pd_out),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
//***************************************************************************
// Soft memory initialization and calibration logic
//***************************************************************************
mig_7series_v2_3_ddr_calib_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.tCK (tCK),
.CLK_PERIOD (CLK_PERIOD),
.N_CTL_LANES (N_CTL_LANES),
.CTL_BYTE_LANE (CTL_BYTE_LANE),
.CTL_BANK (CTL_BANK),
.DRAM_TYPE (DRAM_TYPE),
.PRBS_WIDTH (8),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.HIGHEST_BANK (HIGHEST_BANK),
.BANK_TYPE (BANK_TYPE),
.HIGHEST_LANE (HIGHEST_LANE),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.BANK_WIDTH (BANK_WIDTH),
.CA_MIRROR (CA_MIRROR),
.COL_WIDTH (COL_WIDTH),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nCS_PER_RANK (nCS_PER_RANK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.RANKS (RANKS),
.CS_WIDTH (CS_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.PER_BIT_DESKEW ("OFF"),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.AL (AL),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.nCL (CL),
.nCWL (CWL),
.tRFC (tRFC),
.tREFI (tREFI),
.OUTPUT_DRV (OUTPUT_DRV),
.REG_CTRL (REG_CTRL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.WRLVL (WRLVL_W),
.USE_ODT_PORT (USE_ODT_PORT),
.SIM_INIT_OPTION (SIM_INIT_OPTION),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_calib_top
(
.clk (clk),
.rst (rst),
.tg_err (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
// PHY Control Block and IN_FIFO status
.phy_ctl_ready (phy_mc_go),
.phy_ctl_full (1'b0),
.phy_cmd_full (1'b0),
.phy_data_full (1'b0),
.phy_if_empty (if_empty),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
// From calib logic To data IN_FIFO
// DQ IDELAY tap value from Calib logic
// port to be added to mc_phy by Gary
.dlyval_dq (),
// hard PHY calibration modes
.write_calib (phy_write_calib),
.read_calib (phy_read_calib),
// DQS count and ck/addr/cmd to be mapped to calib_sel
// based on parameter that defines placement of ctl lanes
// and DQS byte groups in each bank. When phy_write_calib
// is de-asserted calib_sel should select CK/addr/cmd/ctl.
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
// Signals from calib logic to be MUXED with MC
// signals before sending to hard PHY
.calib_ctl_wren (calib_ctl_wren),
.calib_cmd_wren (calib_cmd_wren),
.calib_seq (calib_seq),
.calib_aux_out (calib_aux_out),
.calib_odt (calib_odt),
.calib_cke (calib_cke),
.calib_cmd (calib_cmd),
.calib_wrdata_en (calib_wrdata_en),
.calib_rank_cnt (calib_rank_cnt),
.calib_cas_slot (calib_cas_slot),
.calib_data_offset_0 (calib_data_offset_0),
.calib_data_offset_1 (calib_data_offset_1),
.calib_data_offset_2 (calib_data_offset_2),
.phy_reset_n (phy_reset_n),
.phy_address (phy_address),
.phy_bank (phy_bank),
.phy_cs_n (phy_cs_n),
.phy_ras_n (phy_ras_n),
.phy_cas_n (phy_cas_n),
.phy_we_n (phy_we_n),
.phy_wrdata (phy_wrdata),
// DQS Phaser_IN calibration/status signals
.pi_phaselocked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_found_dqs (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
.pi_dqs_found_lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.pi_rst_stg1_cal (rst_stg1_cal),
.pi_en_stg2_f (pi_enstg2_f),
.pi_stg2_f_incdec (pi_stg2_fincdec),
.pi_stg2_load (pi_stg2_load),
.pi_stg2_reg_l (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.device_temp (device_temp),
.tempmon_sample_en (tempmon_sample_en),
// IDELAY tap enable and inc signals
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
// DQS Phaser_OUT calibration/status signals
.po_sel_stg2stg3 (po_sel_stg2stg3),
.po_stg2_c_incdec (po_stg2_cincdec),
.po_en_stg2_c (po_enstg2_c),
.po_stg2_f_incdec (po_stg2_fincdec),
.po_en_stg2_f (po_enstg2_f),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_val (po_counter_read_val),
// From data IN_FIFO To Calib logic and MC/UI
.phy_rddata (rd_data_map),
// From calib logic To MC
.phy_rddata_valid (phy_rddata_valid_w),
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.calib_writes (),
// Mem Init and Calibration status To MC
.init_calib_complete (phy_init_data_sel),
.init_wrcal_complete (init_wrcal_complete),
// Debug Error signals
.pi_phase_locked_err (dbg_pi_phaselock_err),
.pi_dqsfound_err (dbg_pi_dqsfound_err),
.wrcal_err (dbg_wrcal_err),
//used for oclk stg3 centering
.pd_out (pd_out),
.psen (psen),
.psincdec (psincdec),
.psdone (psdone),
.poc_sample_pd (poc_sample_pd),
// Debug Signals
.dbg_pi_phaselock_start (dbg_pi_phaselock_start),
.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start),
.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_wrcal_start (dbg_wrcal_start),
.dbg_wrcal_done (dbg_wrcal_done),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_sel_pi_incdec (dbg_sel_pi_incdec),
.dbg_sel_po_incdec (dbg_sel_po_incdec),
.dbg_byte_sel (dbg_byte_sel),
.dbg_pi_f_inc (dbg_pi_f_inc),
.dbg_pi_f_dec (dbg_pi_f_dec),
.dbg_po_f_inc (dbg_po_f_inc),
.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel),
.dbg_po_f_dec (dbg_po_f_dec),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_calib_top (dbg_calib_top),
.dbg_phy_init (dbg_phy_init),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.dbg_dqs_found_cal (dbg_dqs_found_cal),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data),
.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start),
.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done),
.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps),
.byte_sel_cnt (byte_sel_cnt),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
endmodule
|
module
generate
if(CKE_ODT_AUX == "TRUE") begin
assign aux_out_map = ((DRAM_TYPE == "DDR2") && (RANKS == 1)) ?
{mux_aux_out[1],mux_aux_out[1],mux_aux_out[1],mux_aux_out[0]} :
mux_aux_out;
end else begin
assign aux_out_map = 4'b0000 ;
end
endgenerate
assign init_calib_complete = phy_init_data_sel;
assign phy_mc_ctl_full = phy_ctl_full;
assign phy_mc_cmd_full = phy_cmd_full;
assign phy_mc_data_full = phy_pre_data_a_full;
//***************************************************************************
// Generate parity for DDR3 RDIMM.
//***************************************************************************
generate
if ((DRAM_TYPE == "DDR3") && (REG_CTRL == "ON")) begin: gen_ddr3_parity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ (^{mux_address[(ROW_WIDTH*4)-1:ROW_WIDTH*3],
mux_bank[(BANK_WIDTH*4)-1:BANK_WIDTH*3],
mux_cas_n[3], mux_ras_n[3], mux_we_n[3]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0], mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0],mux_ras_n[0], mux_we_n[0]});
parity[2] = (^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
parity[3] = (^{mux_address[(ROW_WIDTH*3)-1:ROW_WIDTH*2],
mux_bank[(BANK_WIDTH*3)-1:BANK_WIDTH*2],
mux_cas_n[2],mux_ras_n[2], mux_we_n[2]});
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ(^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0],
mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0], mux_ras_n[0], mux_we_n[0]});
end
end
end else begin: gen_ddr3_noparity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
parity[2] <= #TCQ 1'b0;
parity[3] <= #TCQ 1'b0;
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
end
end
end
endgenerate
//***************************************************************************
// Code for optional register stage in read path to MC for timing
//***************************************************************************
generate
if(RD_PATH_REG == 1)begin:RD_REG_TIMING
always @(posedge clk)begin
rddata_valid_reg <= #TCQ phy_rddata_valid_w;
rd_data_reg <= #TCQ rd_data_map;
end // always @ (posedge clk)
end else begin : RD_REG_NO_TIMING // block: RD_REG_TIMING
always @(phy_rddata_valid_w or rd_data_map)begin
rddata_valid_reg = phy_rddata_valid_w;
rd_data_reg = rd_data_map;
end
end
endgenerate
assign phy_rddata_valid = rddata_valid_reg;
assign phy_rd_data = rd_data_reg;
//***************************************************************************
// Hard PHY and accompanying bit mapping logic
//***************************************************************************
mig_7series_v2_3_ddr_mc_phy_wrapper #
(
.TCQ (TCQ),
.tCK (tCK),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.BANK_WIDTH (BANK_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.CS_WIDTH (CS_WIDTH),
.CK_WIDTH (CK_WIDTH),
.LP_DDR_CK_WIDTH (LP_DDR_CK_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.CWL (CWL),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.IBUF_LPWR_MODE (IBUF_LPWR_MODE),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.HIGHEST_BANK (HIGHEST_BANK),
.HIGHEST_LANE (HIGHEST_LANE),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DRAM_WIDTH (DRAM_WIDTH),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_mc_phy_wrapper
(
.rst (rst),
.iddr_rst (iddr_rst),
.clk (clk),
// For memory frequencies between 400~1066 MHz freq_refclk = mem_refclk
// For memory frequencies below 400 MHz mem_refclk = mem_refclk and
// freq_refclk = 2x or 4x mem_refclk such that it remains in the
// 400~1066 MHz range
.freq_refclk (freq_refclk),
.mem_refclk (mem_refclk),
.mmcm_ps_clk (mmcm_ps_clk),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
.idelayctrl_refclk (clk_ref),
.phy_cmd_wr_en (mux_cmd_wren),
.phy_data_wr_en (mux_wrdata_en),
// phy_ctl_wd = {ACTPRE[31:30],EventDelay[29:25],seq[24:23],
// DataOffset[22:17],HiIndex[16:15],LowIndex[14:12],
// AuxOut[11:8],ControlOffset[7:3],PHYCmd[2:0]}
// The fields ACTPRE, and BankCount are only used
// when the hard PHY counters are used by the MC.
.phy_ctl_wd ({5'd0, mux_cas_slot, calib_seq, mux_data_offset,
mux_rank_cnt, 3'd0, aux_out_map,
5'd0, mux_cmd}),
.phy_ctl_wr (mux_ctl_wren),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
.data_offset_1 (mux_data_offset_1),
.data_offset_2 (mux_data_offset_2),
.aux_in_1 (aux_out_map),
.aux_in_2 (aux_out_map),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
.if_empty (if_empty),
.phy_ctl_full (phy_ctl_full),
.phy_cmd_full (phy_cmd_full),
.phy_data_full (phy_data_full),
.phy_pre_data_a_full (phy_pre_data_a_full),
.ddr_clk (ddr_clk),
.phy_mc_go (phy_mc_go),
.phy_write_calib (phy_write_calib),
.phy_read_calib (phy_read_calib),
.po_fine_enable (po_enstg2_f),
.po_coarse_enable (po_enstg2_c),
.po_fine_inc (po_stg2_fincdec),
.po_coarse_inc (po_stg2_cincdec),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_en (1'b1),
.po_sel_fine_oclk_delay (po_sel_stg2stg3),
.po_counter_load_val (),
.po_counter_read_val (po_counter_read_val),
.pi_rst_dqs_find (rst_stg1_cal),
.pi_fine_enable (pi_enstg2_f),
.pi_fine_inc (pi_stg2_fincdec),
.pi_counter_load_en (pi_stg2_load),
.pi_counter_load_val (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
.pi_phase_locked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_dqs_found (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
// Currently not being used. May be used in future if periodic reads
// become a requirement. This output could also be used to signal a
// catastrophic failure in read capture and the need for re-cal
.pi_dqs_out_of_range (pi_dqs_out_of_range),
.phy_init_data_sel (phy_init_data_sel),
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.mux_address (mux_address),
.mux_bank (mux_bank),
.mux_cs_n (mux_cs_n),
.mux_ras_n (mux_ras_n),
.mux_cas_n (mux_cas_n),
.mux_we_n (mux_we_n),
.mux_reset_n (mux_reset_n),
.parity_in (parity),
.mux_wrdata (mux_wrdata),
.mux_wrdata_mask (mux_wrdata_mask),
.mux_odt (mux_odt),
.mux_cke (mux_cke),
.idle (idle),
.rd_data (rd_data_map),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_cas_n (ddr_cas_n),
.ddr_cke (ddr_cke),
.ddr_cs_n (ddr_cs_n),
.ddr_dm (ddr_dm),
.ddr_odt (ddr_odt),
.ddr_parity (ddr_parity),
.ddr_ras_n (ddr_ras_n),
.ddr_we_n (ddr_we_n),
.ddr_dq (ddr_dq),
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_reset_n (ddr_reset_n),
.dbg_pi_counter_read_en (1'b1),
.ref_dll_lock (ref_dll_lock),
.rst_phaser_ref (rst_phaser_ref),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.byte_sel_cnt (byte_sel_cnt),
.pd_out (pd_out),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
//***************************************************************************
// Soft memory initialization and calibration logic
//***************************************************************************
mig_7series_v2_3_ddr_calib_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.tCK (tCK),
.CLK_PERIOD (CLK_PERIOD),
.N_CTL_LANES (N_CTL_LANES),
.CTL_BYTE_LANE (CTL_BYTE_LANE),
.CTL_BANK (CTL_BANK),
.DRAM_TYPE (DRAM_TYPE),
.PRBS_WIDTH (8),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.HIGHEST_BANK (HIGHEST_BANK),
.BANK_TYPE (BANK_TYPE),
.HIGHEST_LANE (HIGHEST_LANE),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.BANK_WIDTH (BANK_WIDTH),
.CA_MIRROR (CA_MIRROR),
.COL_WIDTH (COL_WIDTH),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nCS_PER_RANK (nCS_PER_RANK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.RANKS (RANKS),
.CS_WIDTH (CS_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.PER_BIT_DESKEW ("OFF"),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.AL (AL),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.nCL (CL),
.nCWL (CWL),
.tRFC (tRFC),
.tREFI (tREFI),
.OUTPUT_DRV (OUTPUT_DRV),
.REG_CTRL (REG_CTRL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.WRLVL (WRLVL_W),
.USE_ODT_PORT (USE_ODT_PORT),
.SIM_INIT_OPTION (SIM_INIT_OPTION),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_calib_top
(
.clk (clk),
.rst (rst),
.tg_err (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
// PHY Control Block and IN_FIFO status
.phy_ctl_ready (phy_mc_go),
.phy_ctl_full (1'b0),
.phy_cmd_full (1'b0),
.phy_data_full (1'b0),
.phy_if_empty (if_empty),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
// From calib logic To data IN_FIFO
// DQ IDELAY tap value from Calib logic
// port to be added to mc_phy by Gary
.dlyval_dq (),
// hard PHY calibration modes
.write_calib (phy_write_calib),
.read_calib (phy_read_calib),
// DQS count and ck/addr/cmd to be mapped to calib_sel
// based on parameter that defines placement of ctl lanes
// and DQS byte groups in each bank. When phy_write_calib
// is de-asserted calib_sel should select CK/addr/cmd/ctl.
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
// Signals from calib logic to be MUXED with MC
// signals before sending to hard PHY
.calib_ctl_wren (calib_ctl_wren),
.calib_cmd_wren (calib_cmd_wren),
.calib_seq (calib_seq),
.calib_aux_out (calib_aux_out),
.calib_odt (calib_odt),
.calib_cke (calib_cke),
.calib_cmd (calib_cmd),
.calib_wrdata_en (calib_wrdata_en),
.calib_rank_cnt (calib_rank_cnt),
.calib_cas_slot (calib_cas_slot),
.calib_data_offset_0 (calib_data_offset_0),
.calib_data_offset_1 (calib_data_offset_1),
.calib_data_offset_2 (calib_data_offset_2),
.phy_reset_n (phy_reset_n),
.phy_address (phy_address),
.phy_bank (phy_bank),
.phy_cs_n (phy_cs_n),
.phy_ras_n (phy_ras_n),
.phy_cas_n (phy_cas_n),
.phy_we_n (phy_we_n),
.phy_wrdata (phy_wrdata),
// DQS Phaser_IN calibration/status signals
.pi_phaselocked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_found_dqs (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
.pi_dqs_found_lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.pi_rst_stg1_cal (rst_stg1_cal),
.pi_en_stg2_f (pi_enstg2_f),
.pi_stg2_f_incdec (pi_stg2_fincdec),
.pi_stg2_load (pi_stg2_load),
.pi_stg2_reg_l (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.device_temp (device_temp),
.tempmon_sample_en (tempmon_sample_en),
// IDELAY tap enable and inc signals
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
// DQS Phaser_OUT calibration/status signals
.po_sel_stg2stg3 (po_sel_stg2stg3),
.po_stg2_c_incdec (po_stg2_cincdec),
.po_en_stg2_c (po_enstg2_c),
.po_stg2_f_incdec (po_stg2_fincdec),
.po_en_stg2_f (po_enstg2_f),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_val (po_counter_read_val),
// From data IN_FIFO To Calib logic and MC/UI
.phy_rddata (rd_data_map),
// From calib logic To MC
.phy_rddata_valid (phy_rddata_valid_w),
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.calib_writes (),
// Mem Init and Calibration status To MC
.init_calib_complete (phy_init_data_sel),
.init_wrcal_complete (init_wrcal_complete),
// Debug Error signals
.pi_phase_locked_err (dbg_pi_phaselock_err),
.pi_dqsfound_err (dbg_pi_dqsfound_err),
.wrcal_err (dbg_wrcal_err),
//used for oclk stg3 centering
.pd_out (pd_out),
.psen (psen),
.psincdec (psincdec),
.psdone (psdone),
.poc_sample_pd (poc_sample_pd),
// Debug Signals
.dbg_pi_phaselock_start (dbg_pi_phaselock_start),
.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start),
.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_wrcal_start (dbg_wrcal_start),
.dbg_wrcal_done (dbg_wrcal_done),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_sel_pi_incdec (dbg_sel_pi_incdec),
.dbg_sel_po_incdec (dbg_sel_po_incdec),
.dbg_byte_sel (dbg_byte_sel),
.dbg_pi_f_inc (dbg_pi_f_inc),
.dbg_pi_f_dec (dbg_pi_f_dec),
.dbg_po_f_inc (dbg_po_f_inc),
.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel),
.dbg_po_f_dec (dbg_po_f_dec),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_calib_top (dbg_calib_top),
.dbg_phy_init (dbg_phy_init),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.dbg_dqs_found_cal (dbg_dqs_found_cal),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data),
.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start),
.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done),
.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps),
.byte_sel_cnt (byte_sel_cnt),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
endmodule
|
module
generate
if(CKE_ODT_AUX == "TRUE") begin
assign aux_out_map = ((DRAM_TYPE == "DDR2") && (RANKS == 1)) ?
{mux_aux_out[1],mux_aux_out[1],mux_aux_out[1],mux_aux_out[0]} :
mux_aux_out;
end else begin
assign aux_out_map = 4'b0000 ;
end
endgenerate
assign init_calib_complete = phy_init_data_sel;
assign phy_mc_ctl_full = phy_ctl_full;
assign phy_mc_cmd_full = phy_cmd_full;
assign phy_mc_data_full = phy_pre_data_a_full;
//***************************************************************************
// Generate parity for DDR3 RDIMM.
//***************************************************************************
generate
if ((DRAM_TYPE == "DDR3") && (REG_CTRL == "ON")) begin: gen_ddr3_parity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ (^{mux_address[(ROW_WIDTH*4)-1:ROW_WIDTH*3],
mux_bank[(BANK_WIDTH*4)-1:BANK_WIDTH*3],
mux_cas_n[3], mux_ras_n[3], mux_we_n[3]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0], mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0],mux_ras_n[0], mux_we_n[0]});
parity[2] = (^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
parity[3] = (^{mux_address[(ROW_WIDTH*3)-1:ROW_WIDTH*2],
mux_bank[(BANK_WIDTH*3)-1:BANK_WIDTH*2],
mux_cas_n[2],mux_ras_n[2], mux_we_n[2]});
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ(^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0],
mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0], mux_ras_n[0], mux_we_n[0]});
end
end
end else begin: gen_ddr3_noparity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
parity[2] <= #TCQ 1'b0;
parity[3] <= #TCQ 1'b0;
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
end
end
end
endgenerate
//***************************************************************************
// Code for optional register stage in read path to MC for timing
//***************************************************************************
generate
if(RD_PATH_REG == 1)begin:RD_REG_TIMING
always @(posedge clk)begin
rddata_valid_reg <= #TCQ phy_rddata_valid_w;
rd_data_reg <= #TCQ rd_data_map;
end // always @ (posedge clk)
end else begin : RD_REG_NO_TIMING // block: RD_REG_TIMING
always @(phy_rddata_valid_w or rd_data_map)begin
rddata_valid_reg = phy_rddata_valid_w;
rd_data_reg = rd_data_map;
end
end
endgenerate
assign phy_rddata_valid = rddata_valid_reg;
assign phy_rd_data = rd_data_reg;
//***************************************************************************
// Hard PHY and accompanying bit mapping logic
//***************************************************************************
mig_7series_v2_3_ddr_mc_phy_wrapper #
(
.TCQ (TCQ),
.tCK (tCK),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.BANK_WIDTH (BANK_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.CS_WIDTH (CS_WIDTH),
.CK_WIDTH (CK_WIDTH),
.LP_DDR_CK_WIDTH (LP_DDR_CK_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.CWL (CWL),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.IBUF_LPWR_MODE (IBUF_LPWR_MODE),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.HIGHEST_BANK (HIGHEST_BANK),
.HIGHEST_LANE (HIGHEST_LANE),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DRAM_WIDTH (DRAM_WIDTH),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_mc_phy_wrapper
(
.rst (rst),
.iddr_rst (iddr_rst),
.clk (clk),
// For memory frequencies between 400~1066 MHz freq_refclk = mem_refclk
// For memory frequencies below 400 MHz mem_refclk = mem_refclk and
// freq_refclk = 2x or 4x mem_refclk such that it remains in the
// 400~1066 MHz range
.freq_refclk (freq_refclk),
.mem_refclk (mem_refclk),
.mmcm_ps_clk (mmcm_ps_clk),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
.idelayctrl_refclk (clk_ref),
.phy_cmd_wr_en (mux_cmd_wren),
.phy_data_wr_en (mux_wrdata_en),
// phy_ctl_wd = {ACTPRE[31:30],EventDelay[29:25],seq[24:23],
// DataOffset[22:17],HiIndex[16:15],LowIndex[14:12],
// AuxOut[11:8],ControlOffset[7:3],PHYCmd[2:0]}
// The fields ACTPRE, and BankCount are only used
// when the hard PHY counters are used by the MC.
.phy_ctl_wd ({5'd0, mux_cas_slot, calib_seq, mux_data_offset,
mux_rank_cnt, 3'd0, aux_out_map,
5'd0, mux_cmd}),
.phy_ctl_wr (mux_ctl_wren),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
.data_offset_1 (mux_data_offset_1),
.data_offset_2 (mux_data_offset_2),
.aux_in_1 (aux_out_map),
.aux_in_2 (aux_out_map),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
.if_empty (if_empty),
.phy_ctl_full (phy_ctl_full),
.phy_cmd_full (phy_cmd_full),
.phy_data_full (phy_data_full),
.phy_pre_data_a_full (phy_pre_data_a_full),
.ddr_clk (ddr_clk),
.phy_mc_go (phy_mc_go),
.phy_write_calib (phy_write_calib),
.phy_read_calib (phy_read_calib),
.po_fine_enable (po_enstg2_f),
.po_coarse_enable (po_enstg2_c),
.po_fine_inc (po_stg2_fincdec),
.po_coarse_inc (po_stg2_cincdec),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_en (1'b1),
.po_sel_fine_oclk_delay (po_sel_stg2stg3),
.po_counter_load_val (),
.po_counter_read_val (po_counter_read_val),
.pi_rst_dqs_find (rst_stg1_cal),
.pi_fine_enable (pi_enstg2_f),
.pi_fine_inc (pi_stg2_fincdec),
.pi_counter_load_en (pi_stg2_load),
.pi_counter_load_val (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
.pi_phase_locked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_dqs_found (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
// Currently not being used. May be used in future if periodic reads
// become a requirement. This output could also be used to signal a
// catastrophic failure in read capture and the need for re-cal
.pi_dqs_out_of_range (pi_dqs_out_of_range),
.phy_init_data_sel (phy_init_data_sel),
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.mux_address (mux_address),
.mux_bank (mux_bank),
.mux_cs_n (mux_cs_n),
.mux_ras_n (mux_ras_n),
.mux_cas_n (mux_cas_n),
.mux_we_n (mux_we_n),
.mux_reset_n (mux_reset_n),
.parity_in (parity),
.mux_wrdata (mux_wrdata),
.mux_wrdata_mask (mux_wrdata_mask),
.mux_odt (mux_odt),
.mux_cke (mux_cke),
.idle (idle),
.rd_data (rd_data_map),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_cas_n (ddr_cas_n),
.ddr_cke (ddr_cke),
.ddr_cs_n (ddr_cs_n),
.ddr_dm (ddr_dm),
.ddr_odt (ddr_odt),
.ddr_parity (ddr_parity),
.ddr_ras_n (ddr_ras_n),
.ddr_we_n (ddr_we_n),
.ddr_dq (ddr_dq),
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_reset_n (ddr_reset_n),
.dbg_pi_counter_read_en (1'b1),
.ref_dll_lock (ref_dll_lock),
.rst_phaser_ref (rst_phaser_ref),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.byte_sel_cnt (byte_sel_cnt),
.pd_out (pd_out),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
//***************************************************************************
// Soft memory initialization and calibration logic
//***************************************************************************
mig_7series_v2_3_ddr_calib_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.tCK (tCK),
.CLK_PERIOD (CLK_PERIOD),
.N_CTL_LANES (N_CTL_LANES),
.CTL_BYTE_LANE (CTL_BYTE_LANE),
.CTL_BANK (CTL_BANK),
.DRAM_TYPE (DRAM_TYPE),
.PRBS_WIDTH (8),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.HIGHEST_BANK (HIGHEST_BANK),
.BANK_TYPE (BANK_TYPE),
.HIGHEST_LANE (HIGHEST_LANE),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.BANK_WIDTH (BANK_WIDTH),
.CA_MIRROR (CA_MIRROR),
.COL_WIDTH (COL_WIDTH),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nCS_PER_RANK (nCS_PER_RANK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.RANKS (RANKS),
.CS_WIDTH (CS_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.PER_BIT_DESKEW ("OFF"),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.AL (AL),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.nCL (CL),
.nCWL (CWL),
.tRFC (tRFC),
.tREFI (tREFI),
.OUTPUT_DRV (OUTPUT_DRV),
.REG_CTRL (REG_CTRL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.WRLVL (WRLVL_W),
.USE_ODT_PORT (USE_ODT_PORT),
.SIM_INIT_OPTION (SIM_INIT_OPTION),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_calib_top
(
.clk (clk),
.rst (rst),
.tg_err (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
// PHY Control Block and IN_FIFO status
.phy_ctl_ready (phy_mc_go),
.phy_ctl_full (1'b0),
.phy_cmd_full (1'b0),
.phy_data_full (1'b0),
.phy_if_empty (if_empty),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
// From calib logic To data IN_FIFO
// DQ IDELAY tap value from Calib logic
// port to be added to mc_phy by Gary
.dlyval_dq (),
// hard PHY calibration modes
.write_calib (phy_write_calib),
.read_calib (phy_read_calib),
// DQS count and ck/addr/cmd to be mapped to calib_sel
// based on parameter that defines placement of ctl lanes
// and DQS byte groups in each bank. When phy_write_calib
// is de-asserted calib_sel should select CK/addr/cmd/ctl.
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
// Signals from calib logic to be MUXED with MC
// signals before sending to hard PHY
.calib_ctl_wren (calib_ctl_wren),
.calib_cmd_wren (calib_cmd_wren),
.calib_seq (calib_seq),
.calib_aux_out (calib_aux_out),
.calib_odt (calib_odt),
.calib_cke (calib_cke),
.calib_cmd (calib_cmd),
.calib_wrdata_en (calib_wrdata_en),
.calib_rank_cnt (calib_rank_cnt),
.calib_cas_slot (calib_cas_slot),
.calib_data_offset_0 (calib_data_offset_0),
.calib_data_offset_1 (calib_data_offset_1),
.calib_data_offset_2 (calib_data_offset_2),
.phy_reset_n (phy_reset_n),
.phy_address (phy_address),
.phy_bank (phy_bank),
.phy_cs_n (phy_cs_n),
.phy_ras_n (phy_ras_n),
.phy_cas_n (phy_cas_n),
.phy_we_n (phy_we_n),
.phy_wrdata (phy_wrdata),
// DQS Phaser_IN calibration/status signals
.pi_phaselocked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_found_dqs (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
.pi_dqs_found_lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.pi_rst_stg1_cal (rst_stg1_cal),
.pi_en_stg2_f (pi_enstg2_f),
.pi_stg2_f_incdec (pi_stg2_fincdec),
.pi_stg2_load (pi_stg2_load),
.pi_stg2_reg_l (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.device_temp (device_temp),
.tempmon_sample_en (tempmon_sample_en),
// IDELAY tap enable and inc signals
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
// DQS Phaser_OUT calibration/status signals
.po_sel_stg2stg3 (po_sel_stg2stg3),
.po_stg2_c_incdec (po_stg2_cincdec),
.po_en_stg2_c (po_enstg2_c),
.po_stg2_f_incdec (po_stg2_fincdec),
.po_en_stg2_f (po_enstg2_f),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_val (po_counter_read_val),
// From data IN_FIFO To Calib logic and MC/UI
.phy_rddata (rd_data_map),
// From calib logic To MC
.phy_rddata_valid (phy_rddata_valid_w),
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.calib_writes (),
// Mem Init and Calibration status To MC
.init_calib_complete (phy_init_data_sel),
.init_wrcal_complete (init_wrcal_complete),
// Debug Error signals
.pi_phase_locked_err (dbg_pi_phaselock_err),
.pi_dqsfound_err (dbg_pi_dqsfound_err),
.wrcal_err (dbg_wrcal_err),
//used for oclk stg3 centering
.pd_out (pd_out),
.psen (psen),
.psincdec (psincdec),
.psdone (psdone),
.poc_sample_pd (poc_sample_pd),
// Debug Signals
.dbg_pi_phaselock_start (dbg_pi_phaselock_start),
.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start),
.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_wrcal_start (dbg_wrcal_start),
.dbg_wrcal_done (dbg_wrcal_done),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_sel_pi_incdec (dbg_sel_pi_incdec),
.dbg_sel_po_incdec (dbg_sel_po_incdec),
.dbg_byte_sel (dbg_byte_sel),
.dbg_pi_f_inc (dbg_pi_f_inc),
.dbg_pi_f_dec (dbg_pi_f_dec),
.dbg_po_f_inc (dbg_po_f_inc),
.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel),
.dbg_po_f_dec (dbg_po_f_dec),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_calib_top (dbg_calib_top),
.dbg_phy_init (dbg_phy_init),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.dbg_dqs_found_cal (dbg_dqs_found_cal),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data),
.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start),
.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done),
.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps),
.byte_sel_cnt (byte_sel_cnt),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
endmodule
|
module
generate
if(CKE_ODT_AUX == "TRUE") begin
assign aux_out_map = ((DRAM_TYPE == "DDR2") && (RANKS == 1)) ?
{mux_aux_out[1],mux_aux_out[1],mux_aux_out[1],mux_aux_out[0]} :
mux_aux_out;
end else begin
assign aux_out_map = 4'b0000 ;
end
endgenerate
assign init_calib_complete = phy_init_data_sel;
assign phy_mc_ctl_full = phy_ctl_full;
assign phy_mc_cmd_full = phy_cmd_full;
assign phy_mc_data_full = phy_pre_data_a_full;
//***************************************************************************
// Generate parity for DDR3 RDIMM.
//***************************************************************************
generate
if ((DRAM_TYPE == "DDR3") && (REG_CTRL == "ON")) begin: gen_ddr3_parity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ (^{mux_address[(ROW_WIDTH*4)-1:ROW_WIDTH*3],
mux_bank[(BANK_WIDTH*4)-1:BANK_WIDTH*3],
mux_cas_n[3], mux_ras_n[3], mux_we_n[3]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0], mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0],mux_ras_n[0], mux_we_n[0]});
parity[2] = (^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
parity[3] = (^{mux_address[(ROW_WIDTH*3)-1:ROW_WIDTH*2],
mux_bank[(BANK_WIDTH*3)-1:BANK_WIDTH*2],
mux_cas_n[2],mux_ras_n[2], mux_we_n[2]});
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ(^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0],
mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0], mux_ras_n[0], mux_we_n[0]});
end
end
end else begin: gen_ddr3_noparity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
parity[2] <= #TCQ 1'b0;
parity[3] <= #TCQ 1'b0;
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
end
end
end
endgenerate
//***************************************************************************
// Code for optional register stage in read path to MC for timing
//***************************************************************************
generate
if(RD_PATH_REG == 1)begin:RD_REG_TIMING
always @(posedge clk)begin
rddata_valid_reg <= #TCQ phy_rddata_valid_w;
rd_data_reg <= #TCQ rd_data_map;
end // always @ (posedge clk)
end else begin : RD_REG_NO_TIMING // block: RD_REG_TIMING
always @(phy_rddata_valid_w or rd_data_map)begin
rddata_valid_reg = phy_rddata_valid_w;
rd_data_reg = rd_data_map;
end
end
endgenerate
assign phy_rddata_valid = rddata_valid_reg;
assign phy_rd_data = rd_data_reg;
//***************************************************************************
// Hard PHY and accompanying bit mapping logic
//***************************************************************************
mig_7series_v2_3_ddr_mc_phy_wrapper #
(
.TCQ (TCQ),
.tCK (tCK),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.BANK_WIDTH (BANK_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.CS_WIDTH (CS_WIDTH),
.CK_WIDTH (CK_WIDTH),
.LP_DDR_CK_WIDTH (LP_DDR_CK_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.CWL (CWL),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.IBUF_LPWR_MODE (IBUF_LPWR_MODE),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.HIGHEST_BANK (HIGHEST_BANK),
.HIGHEST_LANE (HIGHEST_LANE),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DRAM_WIDTH (DRAM_WIDTH),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_mc_phy_wrapper
(
.rst (rst),
.iddr_rst (iddr_rst),
.clk (clk),
// For memory frequencies between 400~1066 MHz freq_refclk = mem_refclk
// For memory frequencies below 400 MHz mem_refclk = mem_refclk and
// freq_refclk = 2x or 4x mem_refclk such that it remains in the
// 400~1066 MHz range
.freq_refclk (freq_refclk),
.mem_refclk (mem_refclk),
.mmcm_ps_clk (mmcm_ps_clk),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
.idelayctrl_refclk (clk_ref),
.phy_cmd_wr_en (mux_cmd_wren),
.phy_data_wr_en (mux_wrdata_en),
// phy_ctl_wd = {ACTPRE[31:30],EventDelay[29:25],seq[24:23],
// DataOffset[22:17],HiIndex[16:15],LowIndex[14:12],
// AuxOut[11:8],ControlOffset[7:3],PHYCmd[2:0]}
// The fields ACTPRE, and BankCount are only used
// when the hard PHY counters are used by the MC.
.phy_ctl_wd ({5'd0, mux_cas_slot, calib_seq, mux_data_offset,
mux_rank_cnt, 3'd0, aux_out_map,
5'd0, mux_cmd}),
.phy_ctl_wr (mux_ctl_wren),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
.data_offset_1 (mux_data_offset_1),
.data_offset_2 (mux_data_offset_2),
.aux_in_1 (aux_out_map),
.aux_in_2 (aux_out_map),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
.if_empty (if_empty),
.phy_ctl_full (phy_ctl_full),
.phy_cmd_full (phy_cmd_full),
.phy_data_full (phy_data_full),
.phy_pre_data_a_full (phy_pre_data_a_full),
.ddr_clk (ddr_clk),
.phy_mc_go (phy_mc_go),
.phy_write_calib (phy_write_calib),
.phy_read_calib (phy_read_calib),
.po_fine_enable (po_enstg2_f),
.po_coarse_enable (po_enstg2_c),
.po_fine_inc (po_stg2_fincdec),
.po_coarse_inc (po_stg2_cincdec),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_en (1'b1),
.po_sel_fine_oclk_delay (po_sel_stg2stg3),
.po_counter_load_val (),
.po_counter_read_val (po_counter_read_val),
.pi_rst_dqs_find (rst_stg1_cal),
.pi_fine_enable (pi_enstg2_f),
.pi_fine_inc (pi_stg2_fincdec),
.pi_counter_load_en (pi_stg2_load),
.pi_counter_load_val (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
.pi_phase_locked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_dqs_found (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
// Currently not being used. May be used in future if periodic reads
// become a requirement. This output could also be used to signal a
// catastrophic failure in read capture and the need for re-cal
.pi_dqs_out_of_range (pi_dqs_out_of_range),
.phy_init_data_sel (phy_init_data_sel),
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.mux_address (mux_address),
.mux_bank (mux_bank),
.mux_cs_n (mux_cs_n),
.mux_ras_n (mux_ras_n),
.mux_cas_n (mux_cas_n),
.mux_we_n (mux_we_n),
.mux_reset_n (mux_reset_n),
.parity_in (parity),
.mux_wrdata (mux_wrdata),
.mux_wrdata_mask (mux_wrdata_mask),
.mux_odt (mux_odt),
.mux_cke (mux_cke),
.idle (idle),
.rd_data (rd_data_map),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_cas_n (ddr_cas_n),
.ddr_cke (ddr_cke),
.ddr_cs_n (ddr_cs_n),
.ddr_dm (ddr_dm),
.ddr_odt (ddr_odt),
.ddr_parity (ddr_parity),
.ddr_ras_n (ddr_ras_n),
.ddr_we_n (ddr_we_n),
.ddr_dq (ddr_dq),
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_reset_n (ddr_reset_n),
.dbg_pi_counter_read_en (1'b1),
.ref_dll_lock (ref_dll_lock),
.rst_phaser_ref (rst_phaser_ref),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.byte_sel_cnt (byte_sel_cnt),
.pd_out (pd_out),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
//***************************************************************************
// Soft memory initialization and calibration logic
//***************************************************************************
mig_7series_v2_3_ddr_calib_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.tCK (tCK),
.CLK_PERIOD (CLK_PERIOD),
.N_CTL_LANES (N_CTL_LANES),
.CTL_BYTE_LANE (CTL_BYTE_LANE),
.CTL_BANK (CTL_BANK),
.DRAM_TYPE (DRAM_TYPE),
.PRBS_WIDTH (8),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.HIGHEST_BANK (HIGHEST_BANK),
.BANK_TYPE (BANK_TYPE),
.HIGHEST_LANE (HIGHEST_LANE),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.BANK_WIDTH (BANK_WIDTH),
.CA_MIRROR (CA_MIRROR),
.COL_WIDTH (COL_WIDTH),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nCS_PER_RANK (nCS_PER_RANK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.RANKS (RANKS),
.CS_WIDTH (CS_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.PER_BIT_DESKEW ("OFF"),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.AL (AL),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.nCL (CL),
.nCWL (CWL),
.tRFC (tRFC),
.tREFI (tREFI),
.OUTPUT_DRV (OUTPUT_DRV),
.REG_CTRL (REG_CTRL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.WRLVL (WRLVL_W),
.USE_ODT_PORT (USE_ODT_PORT),
.SIM_INIT_OPTION (SIM_INIT_OPTION),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_calib_top
(
.clk (clk),
.rst (rst),
.tg_err (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
// PHY Control Block and IN_FIFO status
.phy_ctl_ready (phy_mc_go),
.phy_ctl_full (1'b0),
.phy_cmd_full (1'b0),
.phy_data_full (1'b0),
.phy_if_empty (if_empty),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
// From calib logic To data IN_FIFO
// DQ IDELAY tap value from Calib logic
// port to be added to mc_phy by Gary
.dlyval_dq (),
// hard PHY calibration modes
.write_calib (phy_write_calib),
.read_calib (phy_read_calib),
// DQS count and ck/addr/cmd to be mapped to calib_sel
// based on parameter that defines placement of ctl lanes
// and DQS byte groups in each bank. When phy_write_calib
// is de-asserted calib_sel should select CK/addr/cmd/ctl.
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
// Signals from calib logic to be MUXED with MC
// signals before sending to hard PHY
.calib_ctl_wren (calib_ctl_wren),
.calib_cmd_wren (calib_cmd_wren),
.calib_seq (calib_seq),
.calib_aux_out (calib_aux_out),
.calib_odt (calib_odt),
.calib_cke (calib_cke),
.calib_cmd (calib_cmd),
.calib_wrdata_en (calib_wrdata_en),
.calib_rank_cnt (calib_rank_cnt),
.calib_cas_slot (calib_cas_slot),
.calib_data_offset_0 (calib_data_offset_0),
.calib_data_offset_1 (calib_data_offset_1),
.calib_data_offset_2 (calib_data_offset_2),
.phy_reset_n (phy_reset_n),
.phy_address (phy_address),
.phy_bank (phy_bank),
.phy_cs_n (phy_cs_n),
.phy_ras_n (phy_ras_n),
.phy_cas_n (phy_cas_n),
.phy_we_n (phy_we_n),
.phy_wrdata (phy_wrdata),
// DQS Phaser_IN calibration/status signals
.pi_phaselocked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_found_dqs (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
.pi_dqs_found_lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.pi_rst_stg1_cal (rst_stg1_cal),
.pi_en_stg2_f (pi_enstg2_f),
.pi_stg2_f_incdec (pi_stg2_fincdec),
.pi_stg2_load (pi_stg2_load),
.pi_stg2_reg_l (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.device_temp (device_temp),
.tempmon_sample_en (tempmon_sample_en),
// IDELAY tap enable and inc signals
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
// DQS Phaser_OUT calibration/status signals
.po_sel_stg2stg3 (po_sel_stg2stg3),
.po_stg2_c_incdec (po_stg2_cincdec),
.po_en_stg2_c (po_enstg2_c),
.po_stg2_f_incdec (po_stg2_fincdec),
.po_en_stg2_f (po_enstg2_f),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_val (po_counter_read_val),
// From data IN_FIFO To Calib logic and MC/UI
.phy_rddata (rd_data_map),
// From calib logic To MC
.phy_rddata_valid (phy_rddata_valid_w),
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.calib_writes (),
// Mem Init and Calibration status To MC
.init_calib_complete (phy_init_data_sel),
.init_wrcal_complete (init_wrcal_complete),
// Debug Error signals
.pi_phase_locked_err (dbg_pi_phaselock_err),
.pi_dqsfound_err (dbg_pi_dqsfound_err),
.wrcal_err (dbg_wrcal_err),
//used for oclk stg3 centering
.pd_out (pd_out),
.psen (psen),
.psincdec (psincdec),
.psdone (psdone),
.poc_sample_pd (poc_sample_pd),
// Debug Signals
.dbg_pi_phaselock_start (dbg_pi_phaselock_start),
.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start),
.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_wrcal_start (dbg_wrcal_start),
.dbg_wrcal_done (dbg_wrcal_done),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_sel_pi_incdec (dbg_sel_pi_incdec),
.dbg_sel_po_incdec (dbg_sel_po_incdec),
.dbg_byte_sel (dbg_byte_sel),
.dbg_pi_f_inc (dbg_pi_f_inc),
.dbg_pi_f_dec (dbg_pi_f_dec),
.dbg_po_f_inc (dbg_po_f_inc),
.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel),
.dbg_po_f_dec (dbg_po_f_dec),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_calib_top (dbg_calib_top),
.dbg_phy_init (dbg_phy_init),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.dbg_dqs_found_cal (dbg_dqs_found_cal),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data),
.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start),
.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done),
.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps),
.byte_sel_cnt (byte_sel_cnt),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
endmodule
|
module
generate
if(CKE_ODT_AUX == "TRUE") begin
assign aux_out_map = ((DRAM_TYPE == "DDR2") && (RANKS == 1)) ?
{mux_aux_out[1],mux_aux_out[1],mux_aux_out[1],mux_aux_out[0]} :
mux_aux_out;
end else begin
assign aux_out_map = 4'b0000 ;
end
endgenerate
assign init_calib_complete = phy_init_data_sel;
assign phy_mc_ctl_full = phy_ctl_full;
assign phy_mc_cmd_full = phy_cmd_full;
assign phy_mc_data_full = phy_pre_data_a_full;
//***************************************************************************
// Generate parity for DDR3 RDIMM.
//***************************************************************************
generate
if ((DRAM_TYPE == "DDR3") && (REG_CTRL == "ON")) begin: gen_ddr3_parity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ (^{mux_address[(ROW_WIDTH*4)-1:ROW_WIDTH*3],
mux_bank[(BANK_WIDTH*4)-1:BANK_WIDTH*3],
mux_cas_n[3], mux_ras_n[3], mux_we_n[3]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0], mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0],mux_ras_n[0], mux_we_n[0]});
parity[2] = (^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
parity[3] = (^{mux_address[(ROW_WIDTH*3)-1:ROW_WIDTH*2],
mux_bank[(BANK_WIDTH*3)-1:BANK_WIDTH*2],
mux_cas_n[2],mux_ras_n[2], mux_we_n[2]});
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ(^{mux_address[(ROW_WIDTH*2)-1:ROW_WIDTH],
mux_bank[(BANK_WIDTH*2)-1:BANK_WIDTH],
mux_cas_n[1], mux_ras_n[1], mux_we_n[1]});
end
always @(*) begin
parity[1] = (^{mux_address[ROW_WIDTH-1:0],
mux_bank[BANK_WIDTH-1:0],
mux_cas_n[0], mux_ras_n[0], mux_we_n[0]});
end
end
end else begin: gen_ddr3_noparity
if (nCK_PER_CLK == 4) begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
parity[2] <= #TCQ 1'b0;
parity[3] <= #TCQ 1'b0;
end
end else begin
always @(posedge clk) begin
parity[0] <= #TCQ 1'b0;
parity[1] <= #TCQ 1'b0;
end
end
end
endgenerate
//***************************************************************************
// Code for optional register stage in read path to MC for timing
//***************************************************************************
generate
if(RD_PATH_REG == 1)begin:RD_REG_TIMING
always @(posedge clk)begin
rddata_valid_reg <= #TCQ phy_rddata_valid_w;
rd_data_reg <= #TCQ rd_data_map;
end // always @ (posedge clk)
end else begin : RD_REG_NO_TIMING // block: RD_REG_TIMING
always @(phy_rddata_valid_w or rd_data_map)begin
rddata_valid_reg = phy_rddata_valid_w;
rd_data_reg = rd_data_map;
end
end
endgenerate
assign phy_rddata_valid = rddata_valid_reg;
assign phy_rd_data = rd_data_reg;
//***************************************************************************
// Hard PHY and accompanying bit mapping logic
//***************************************************************************
mig_7series_v2_3_ddr_mc_phy_wrapper #
(
.TCQ (TCQ),
.tCK (tCK),
.BANK_TYPE (BANK_TYPE),
.DATA_IO_PRIM_TYPE (DATA_IO_PRIM_TYPE),
.DATA_IO_IDLE_PWRDWN(DATA_IO_IDLE_PWRDWN),
.IODELAY_GRP (IODELAY_GRP),
.FPGA_SPEED_GRADE (FPGA_SPEED_GRADE),
.nCK_PER_CLK (nCK_PER_CLK),
.nCS_PER_RANK (nCS_PER_RANK),
.BANK_WIDTH (BANK_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.CS_WIDTH (CS_WIDTH),
.CK_WIDTH (CK_WIDTH),
.LP_DDR_CK_WIDTH (LP_DDR_CK_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.CWL (CWL),
.DM_WIDTH (DM_WIDTH),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_TYPE (DRAM_TYPE),
.RANKS (RANKS),
.ODT_WIDTH (ODT_WIDTH),
.REG_CTRL (REG_CTRL),
.ROW_WIDTH (ROW_WIDTH),
.USE_CS_PORT (USE_CS_PORT),
.USE_DM_PORT (USE_DM_PORT),
.USE_ODT_PORT (USE_ODT_PORT),
.IBUF_LPWR_MODE (IBUF_LPWR_MODE),
.PHYCTL_CMD_FIFO (PHYCTL_CMD_FIFO),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.PHY_0_BITLANES (PHY_0_BITLANES),
.PHY_1_BITLANES (PHY_1_BITLANES),
.PHY_2_BITLANES (PHY_2_BITLANES),
.HIGHEST_BANK (HIGHEST_BANK),
.HIGHEST_LANE (HIGHEST_LANE),
.CK_BYTE_MAP (CK_BYTE_MAP),
.ADDR_MAP (ADDR_MAP),
.BANK_MAP (BANK_MAP),
.CAS_MAP (CAS_MAP),
.CKE_ODT_BYTE_MAP (CKE_ODT_BYTE_MAP),
.CKE_MAP (CKE_MAP),
.ODT_MAP (ODT_MAP),
.CKE_ODT_AUX (CKE_ODT_AUX),
.CS_MAP (CS_MAP),
.PARITY_MAP (PARITY_MAP),
.RAS_MAP (RAS_MAP),
.WE_MAP (WE_MAP),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.DATA0_MAP (DATA0_MAP),
.DATA1_MAP (DATA1_MAP),
.DATA2_MAP (DATA2_MAP),
.DATA3_MAP (DATA3_MAP),
.DATA4_MAP (DATA4_MAP),
.DATA5_MAP (DATA5_MAP),
.DATA6_MAP (DATA6_MAP),
.DATA7_MAP (DATA7_MAP),
.DATA8_MAP (DATA8_MAP),
.DATA9_MAP (DATA9_MAP),
.DATA10_MAP (DATA10_MAP),
.DATA11_MAP (DATA11_MAP),
.DATA12_MAP (DATA12_MAP),
.DATA13_MAP (DATA13_MAP),
.DATA14_MAP (DATA14_MAP),
.DATA15_MAP (DATA15_MAP),
.DATA16_MAP (DATA16_MAP),
.DATA17_MAP (DATA17_MAP),
.MASK0_MAP (MASK0_MAP),
.MASK1_MAP (MASK1_MAP),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.MASTER_PHY_CTL (MASTER_PHY_CTL),
.DRAM_WIDTH (DRAM_WIDTH),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_mc_phy_wrapper
(
.rst (rst),
.iddr_rst (iddr_rst),
.clk (clk),
// For memory frequencies between 400~1066 MHz freq_refclk = mem_refclk
// For memory frequencies below 400 MHz mem_refclk = mem_refclk and
// freq_refclk = 2x or 4x mem_refclk such that it remains in the
// 400~1066 MHz range
.freq_refclk (freq_refclk),
.mem_refclk (mem_refclk),
.mmcm_ps_clk (mmcm_ps_clk),
.pll_lock (pll_lock),
.sync_pulse (sync_pulse),
.idelayctrl_refclk (clk_ref),
.phy_cmd_wr_en (mux_cmd_wren),
.phy_data_wr_en (mux_wrdata_en),
// phy_ctl_wd = {ACTPRE[31:30],EventDelay[29:25],seq[24:23],
// DataOffset[22:17],HiIndex[16:15],LowIndex[14:12],
// AuxOut[11:8],ControlOffset[7:3],PHYCmd[2:0]}
// The fields ACTPRE, and BankCount are only used
// when the hard PHY counters are used by the MC.
.phy_ctl_wd ({5'd0, mux_cas_slot, calib_seq, mux_data_offset,
mux_rank_cnt, 3'd0, aux_out_map,
5'd0, mux_cmd}),
.phy_ctl_wr (mux_ctl_wren),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
.data_offset_1 (mux_data_offset_1),
.data_offset_2 (mux_data_offset_2),
.aux_in_1 (aux_out_map),
.aux_in_2 (aux_out_map),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
.if_empty (if_empty),
.phy_ctl_full (phy_ctl_full),
.phy_cmd_full (phy_cmd_full),
.phy_data_full (phy_data_full),
.phy_pre_data_a_full (phy_pre_data_a_full),
.ddr_clk (ddr_clk),
.phy_mc_go (phy_mc_go),
.phy_write_calib (phy_write_calib),
.phy_read_calib (phy_read_calib),
.po_fine_enable (po_enstg2_f),
.po_coarse_enable (po_enstg2_c),
.po_fine_inc (po_stg2_fincdec),
.po_coarse_inc (po_stg2_cincdec),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_en (1'b1),
.po_sel_fine_oclk_delay (po_sel_stg2stg3),
.po_counter_load_val (),
.po_counter_read_val (po_counter_read_val),
.pi_rst_dqs_find (rst_stg1_cal),
.pi_fine_enable (pi_enstg2_f),
.pi_fine_inc (pi_stg2_fincdec),
.pi_counter_load_en (pi_stg2_load),
.pi_counter_load_val (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
.pi_phase_locked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_dqs_found (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
// Currently not being used. May be used in future if periodic reads
// become a requirement. This output could also be used to signal a
// catastrophic failure in read capture and the need for re-cal
.pi_dqs_out_of_range (pi_dqs_out_of_range),
.phy_init_data_sel (phy_init_data_sel),
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.mux_address (mux_address),
.mux_bank (mux_bank),
.mux_cs_n (mux_cs_n),
.mux_ras_n (mux_ras_n),
.mux_cas_n (mux_cas_n),
.mux_we_n (mux_we_n),
.mux_reset_n (mux_reset_n),
.parity_in (parity),
.mux_wrdata (mux_wrdata),
.mux_wrdata_mask (mux_wrdata_mask),
.mux_odt (mux_odt),
.mux_cke (mux_cke),
.idle (idle),
.rd_data (rd_data_map),
.ddr_addr (ddr_addr),
.ddr_ba (ddr_ba),
.ddr_cas_n (ddr_cas_n),
.ddr_cke (ddr_cke),
.ddr_cs_n (ddr_cs_n),
.ddr_dm (ddr_dm),
.ddr_odt (ddr_odt),
.ddr_parity (ddr_parity),
.ddr_ras_n (ddr_ras_n),
.ddr_we_n (ddr_we_n),
.ddr_dq (ddr_dq),
.ddr_dqs (ddr_dqs),
.ddr_dqs_n (ddr_dqs_n),
.ddr_reset_n (ddr_reset_n),
.dbg_pi_counter_read_en (1'b1),
.ref_dll_lock (ref_dll_lock),
.rst_phaser_ref (rst_phaser_ref),
.dbg_pi_phase_locked_phy4lanes (dbg_pi_phase_locked_phy4lanes),
.dbg_pi_dqs_found_lanes_phy4lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.byte_sel_cnt (byte_sel_cnt),
.pd_out (pd_out),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
//***************************************************************************
// Soft memory initialization and calibration logic
//***************************************************************************
mig_7series_v2_3_ddr_calib_top #
(
.TCQ (TCQ),
.DDR3_VDD_OP_VOLT (DDR3_VDD_OP_VOLT),
.nCK_PER_CLK (nCK_PER_CLK),
.PRE_REV3ES (PRE_REV3ES),
.tCK (tCK),
.CLK_PERIOD (CLK_PERIOD),
.N_CTL_LANES (N_CTL_LANES),
.CTL_BYTE_LANE (CTL_BYTE_LANE),
.CTL_BANK (CTL_BANK),
.DRAM_TYPE (DRAM_TYPE),
.PRBS_WIDTH (8),
.DQS_BYTE_MAP (DQS_BYTE_MAP),
.HIGHEST_BANK (HIGHEST_BANK),
.BANK_TYPE (BANK_TYPE),
.HIGHEST_LANE (HIGHEST_LANE),
.BYTE_LANES_B0 (BYTE_LANES_B0),
.BYTE_LANES_B1 (BYTE_LANES_B1),
.BYTE_LANES_B2 (BYTE_LANES_B2),
.BYTE_LANES_B3 (BYTE_LANES_B3),
.BYTE_LANES_B4 (BYTE_LANES_B4),
.DATA_CTL_B0 (DATA_CTL_B0),
.DATA_CTL_B1 (DATA_CTL_B1),
.DATA_CTL_B2 (DATA_CTL_B2),
.DATA_CTL_B3 (DATA_CTL_B3),
.DATA_CTL_B4 (DATA_CTL_B4),
.SLOT_1_CONFIG (SLOT_1_CONFIG),
.BANK_WIDTH (BANK_WIDTH),
.CA_MIRROR (CA_MIRROR),
.COL_WIDTH (COL_WIDTH),
.CKE_ODT_AUX (CKE_ODT_AUX),
.nCS_PER_RANK (nCS_PER_RANK),
.DQ_WIDTH (DQ_WIDTH),
.DQS_CNT_WIDTH (DQS_CNT_WIDTH),
.DQS_WIDTH (DQS_WIDTH),
.DRAM_WIDTH (DRAM_WIDTH),
.ROW_WIDTH (ROW_WIDTH),
.RANKS (RANKS),
.CS_WIDTH (CS_WIDTH),
.CKE_WIDTH (CKE_WIDTH),
.DDR2_DQSN_ENABLE (DDR2_DQSN_ENABLE),
.PER_BIT_DESKEW ("OFF"),
.CALIB_ROW_ADD (CALIB_ROW_ADD),
.CALIB_COL_ADD (CALIB_COL_ADD),
.CALIB_BA_ADD (CALIB_BA_ADD),
.AL (AL),
.BURST_MODE (BURST_MODE),
.BURST_TYPE (BURST_TYPE),
.nCL (CL),
.nCWL (CWL),
.tRFC (tRFC),
.tREFI (tREFI),
.OUTPUT_DRV (OUTPUT_DRV),
.REG_CTRL (REG_CTRL),
.ADDR_CMD_MODE (ADDR_CMD_MODE),
.RTT_NOM (RTT_NOM),
.RTT_WR (RTT_WR),
.WRLVL (WRLVL_W),
.USE_ODT_PORT (USE_ODT_PORT),
.SIM_INIT_OPTION (SIM_INIT_OPTION),
.SIM_CAL_OPTION (SIM_CAL_OPTION),
.DEBUG_PORT (DEBUG_PORT),
.IDELAY_ADJ (IDELAY_ADJ),
.FINE_PER_BIT (FINE_PER_BIT),
.CENTER_COMP_MODE (CENTER_COMP_MODE),
.PI_VAL_ADJ (PI_VAL_ADJ),
.TAPSPERKCLK (TAPSPERKCLK),
.POC_USE_METASTABLE_SAMP (POC_USE_METASTABLE_SAMP)
)
u_ddr_calib_top
(
.clk (clk),
.rst (rst),
.tg_err (error),
.rst_tg_mc (rst_tg_mc),
.slot_0_present (slot_0_present),
.slot_1_present (slot_1_present),
// PHY Control Block and IN_FIFO status
.phy_ctl_ready (phy_mc_go),
.phy_ctl_full (1'b0),
.phy_cmd_full (1'b0),
.phy_data_full (1'b0),
.phy_if_empty (if_empty),
.idelaye2_init_val (idelaye2_init_val),
.oclkdelay_init_val (oclkdelay_init_val),
// From calib logic To data IN_FIFO
// DQ IDELAY tap value from Calib logic
// port to be added to mc_phy by Gary
.dlyval_dq (),
// hard PHY calibration modes
.write_calib (phy_write_calib),
.read_calib (phy_read_calib),
// DQS count and ck/addr/cmd to be mapped to calib_sel
// based on parameter that defines placement of ctl lanes
// and DQS byte groups in each bank. When phy_write_calib
// is de-asserted calib_sel should select CK/addr/cmd/ctl.
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.phy_if_empty_def (phy_if_empty_def),
.phy_if_reset (phy_if_reset),
// Signals from calib logic to be MUXED with MC
// signals before sending to hard PHY
.calib_ctl_wren (calib_ctl_wren),
.calib_cmd_wren (calib_cmd_wren),
.calib_seq (calib_seq),
.calib_aux_out (calib_aux_out),
.calib_odt (calib_odt),
.calib_cke (calib_cke),
.calib_cmd (calib_cmd),
.calib_wrdata_en (calib_wrdata_en),
.calib_rank_cnt (calib_rank_cnt),
.calib_cas_slot (calib_cas_slot),
.calib_data_offset_0 (calib_data_offset_0),
.calib_data_offset_1 (calib_data_offset_1),
.calib_data_offset_2 (calib_data_offset_2),
.phy_reset_n (phy_reset_n),
.phy_address (phy_address),
.phy_bank (phy_bank),
.phy_cs_n (phy_cs_n),
.phy_ras_n (phy_ras_n),
.phy_cas_n (phy_cas_n),
.phy_we_n (phy_we_n),
.phy_wrdata (phy_wrdata),
// DQS Phaser_IN calibration/status signals
.pi_phaselocked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_found_dqs (pi_found_dqs),
.pi_dqs_found_all (pi_dqs_found_all),
.pi_dqs_found_lanes (dbg_pi_dqs_found_lanes_phy4lanes),
.pi_rst_stg1_cal (rst_stg1_cal),
.pi_en_stg2_f (pi_enstg2_f),
.pi_stg2_f_incdec (pi_stg2_fincdec),
.pi_stg2_load (pi_stg2_load),
.pi_stg2_reg_l (pi_stg2_reg_l),
.pi_counter_read_val (pi_counter_read_val),
.device_temp (device_temp),
.tempmon_sample_en (tempmon_sample_en),
// IDELAY tap enable and inc signals
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.idelay_ld (idelay_ld),
// DQS Phaser_OUT calibration/status signals
.po_sel_stg2stg3 (po_sel_stg2stg3),
.po_stg2_c_incdec (po_stg2_cincdec),
.po_en_stg2_c (po_enstg2_c),
.po_stg2_f_incdec (po_stg2_fincdec),
.po_en_stg2_f (po_enstg2_f),
.po_counter_load_en (po_counter_load_en),
.po_counter_read_val (po_counter_read_val),
// From data IN_FIFO To Calib logic and MC/UI
.phy_rddata (rd_data_map),
// From calib logic To MC
.phy_rddata_valid (phy_rddata_valid_w),
.calib_rd_data_offset_0 (calib_rd_data_offset_0),
.calib_rd_data_offset_1 (calib_rd_data_offset_1),
.calib_rd_data_offset_2 (calib_rd_data_offset_2),
.calib_writes (),
// Mem Init and Calibration status To MC
.init_calib_complete (phy_init_data_sel),
.init_wrcal_complete (init_wrcal_complete),
// Debug Error signals
.pi_phase_locked_err (dbg_pi_phaselock_err),
.pi_dqsfound_err (dbg_pi_dqsfound_err),
.wrcal_err (dbg_wrcal_err),
//used for oclk stg3 centering
.pd_out (pd_out),
.psen (psen),
.psincdec (psincdec),
.psdone (psdone),
.poc_sample_pd (poc_sample_pd),
// Debug Signals
.dbg_pi_phaselock_start (dbg_pi_phaselock_start),
.dbg_pi_dqsfound_start (dbg_pi_dqsfound_start),
.dbg_pi_dqsfound_done (dbg_pi_dqsfound_done),
.dbg_wrlvl_start (dbg_wrlvl_start),
.dbg_wrlvl_done (dbg_wrlvl_done),
.dbg_wrlvl_err (dbg_wrlvl_err),
.dbg_wrlvl_fine_tap_cnt (dbg_wrlvl_fine_tap_cnt),
.dbg_wrlvl_coarse_tap_cnt (dbg_wrlvl_coarse_tap_cnt),
.dbg_phy_wrlvl (dbg_phy_wrlvl),
.dbg_tap_cnt_during_wrlvl (dbg_tap_cnt_during_wrlvl),
.dbg_wl_edge_detect_valid (dbg_wl_edge_detect_valid),
.dbg_rd_data_edge_detect (dbg_rd_data_edge_detect),
.dbg_wrcal_start (dbg_wrcal_start),
.dbg_wrcal_done (dbg_wrcal_done),
.dbg_phy_wrcal (dbg_phy_wrcal),
.dbg_final_po_fine_tap_cnt (dbg_final_po_fine_tap_cnt),
.dbg_final_po_coarse_tap_cnt (dbg_final_po_coarse_tap_cnt),
.dbg_rdlvl_start (dbg_rdlvl_start),
.dbg_rdlvl_done (dbg_rdlvl_done),
.dbg_rdlvl_err (dbg_rdlvl_err),
.dbg_cpt_first_edge_cnt (dbg_cpt_first_edge_cnt),
.dbg_cpt_second_edge_cnt (dbg_cpt_second_edge_cnt),
.dbg_cpt_tap_cnt (dbg_cpt_tap_cnt),
.dbg_dq_idelay_tap_cnt (dbg_dq_idelay_tap_cnt),
.dbg_sel_pi_incdec (dbg_sel_pi_incdec),
.dbg_sel_po_incdec (dbg_sel_po_incdec),
.dbg_byte_sel (dbg_byte_sel),
.dbg_pi_f_inc (dbg_pi_f_inc),
.dbg_pi_f_dec (dbg_pi_f_dec),
.dbg_po_f_inc (dbg_po_f_inc),
.dbg_po_f_stg23_sel (dbg_po_f_stg23_sel),
.dbg_po_f_dec (dbg_po_f_dec),
.dbg_idel_up_all (dbg_idel_up_all),
.dbg_idel_down_all (dbg_idel_down_all),
.dbg_idel_up_cpt (dbg_idel_up_cpt),
.dbg_idel_down_cpt (dbg_idel_down_cpt),
.dbg_sel_idel_cpt (dbg_sel_idel_cpt),
.dbg_sel_all_idel_cpt (dbg_sel_all_idel_cpt),
.dbg_phy_rdlvl (dbg_phy_rdlvl),
.dbg_calib_top (dbg_calib_top),
.dbg_phy_init (dbg_phy_init),
.dbg_prbs_rdlvl (dbg_prbs_rdlvl),
.dbg_dqs_found_cal (dbg_dqs_found_cal),
.dbg_phy_oclkdelay_cal (dbg_phy_oclkdelay_cal),
.dbg_oclkdelay_rd_data (dbg_oclkdelay_rd_data),
.dbg_oclkdelay_calib_start (dbg_oclkdelay_calib_start),
.dbg_oclkdelay_calib_done (dbg_oclkdelay_calib_done),
.prbs_final_dqs_tap_cnt_r (prbs_final_dqs_tap_cnt_r),
.dbg_prbs_first_edge_taps (dbg_prbs_first_edge_taps),
.dbg_prbs_second_edge_taps (dbg_prbs_second_edge_taps),
.byte_sel_cnt (byte_sel_cnt),
.fine_delay_incdec_pb (fine_delay_incdec_pb),
.fine_delay_sel (fine_delay_sel)
);
endmodule
|
module
.idelayctrl_refclk (),
.phy_dout (phy_dout),
.phy_cmd_wr_en (phy_cmd_wr_en),
.phy_data_wr_en (phy_data_wr_en),
.phy_rd_en (phy_rd_en),
.phy_ctl_wd (phy_ctl_wd_temp),
.phy_ctl_wr (phy_ctl_wr_temp),
.if_empty_def (phy_if_empty_def),
.if_rst (phy_if_reset),
.phyGo ('b1),
.aux_in_1 (aux_in_1),
.aux_in_2 (aux_in_2),
// No support yet for different data offsets for different I/O banks
// (possible use in supporting wider range of skew among bytes)
.data_offset_1 (data_offset_1_temp),
.data_offset_2 (data_offset_2_temp),
.cke_in (),
.if_a_empty (),
.if_empty (if_empty),
.if_empty_or (),
.if_empty_and (),
.of_ctl_a_full (),
// .of_data_a_full (phy_data_full),
.of_ctl_full (phy_cmd_full),
.of_data_full (),
.pre_data_a_full (phy_pre_data_a_full),
.idelay_ld (idelay_ld),
.idelay_ce (idelay_ce),
.idelay_inc (idelay_inc),
.input_sink (),
.phy_din (phy_din),
.phy_ctl_a_full (),
.phy_ctl_full (phy_ctl_full_temp),
.mem_dq_out (mem_dq_out),
.mem_dq_ts (mem_dq_ts),
.mem_dq_in (mem_dq_in),
.mem_dqs_out (mem_dqs_out),
.mem_dqs_ts (mem_dqs_ts),
.mem_dqs_in (mem_dqs_in),
.aux_out (aux_out),
.phy_ctl_ready (),
.rst_out (),
.ddr_clk (ddr_clk),
//.rclk (),
.mcGo (phy_mc_go),
.phy_write_calib (phy_write_calib),
.phy_read_calib (phy_read_calib),
.calib_sel (calib_sel),
.calib_in_common (calib_in_common),
.calib_zero_inputs (calib_zero_inputs),
.calib_zero_ctrl (calib_zero_ctrl),
.calib_zero_lanes ('b0),
.po_fine_enable (po_fine_enable),
.po_coarse_enable (po_coarse_enable),
.po_fine_inc (po_fine_inc),
.po_coarse_inc (po_coarse_inc),
.po_counter_load_en (po_counter_load_en),
.po_sel_fine_oclk_delay (po_sel_fine_oclk_delay),
.po_counter_load_val (po_counter_load_val),
.po_counter_read_en (po_counter_read_en),
.po_coarse_overflow (),
.po_fine_overflow (),
.po_counter_read_val (po_counter_read_val),
.pi_rst_dqs_find (pi_rst_dqs_find),
.pi_fine_enable (pi_fine_enable),
.pi_fine_inc (pi_fine_inc),
.pi_counter_load_en (pi_counter_load_en),
.pi_counter_read_en (dbg_pi_counter_read_en),
.pi_counter_load_val (pi_counter_load_val),
.pi_fine_overflow (),
.pi_counter_read_val (pi_counter_read_val),
.pi_phase_locked (pi_phase_locked),
.pi_phase_locked_all (pi_phase_locked_all),
.pi_dqs_found (),
.pi_dqs_found_any (pi_dqs_found),
.pi_dqs_found_all (pi_dqs_found_all),
.pi_dqs_found_lanes (dbg_pi_dqs_found_lanes_phy4lanes),
// Currently not being used. May be used in future if periodic
// reads become a requirement. This output could be used to signal
// a catastrophic failure in read capture and the need for
// re-calibration.
.pi_dqs_out_of_range (pi_dqs_out_of_range)
,.ref_dll_lock (ref_dll_lock)
,.pi_phase_locked_lanes (dbg_pi_phase_locked_phy4lanes)
,.fine_delay (fine_delay_mod)
,.fine_delay_sel (fine_delay_sel_r)
// ,.rst_phaser_ref (rst_phaser_ref)
);
endmodule
|
module mig_7series_v2_3_ddr_phy_wrcal #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter nCK_PER_CLK = 2, // # of memory clocks per CLK
parameter CLK_PERIOD = 2500,
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter PRE_REV3ES = "OFF", // Delay O/Ps using Phaser_Out fine dly
parameter SIM_CAL_OPTION = "NONE" // Skip various calibration steps
)
(
input clk,
input rst,
// Calibration status, control signals
input wrcal_start,
input wrcal_rd_wait,
input wrcal_sanity_chk,
input dqsfound_retry_done,
input phy_rddata_en,
output dqsfound_retry,
output wrcal_read_req,
output reg wrcal_act_req,
output reg wrcal_done,
output reg wrcal_pat_err,
output reg wrcal_prech_req,
output reg temp_wrcal_done,
output reg wrcal_sanity_chk_done,
input prech_done,
// Captured data in resync clock domain
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] rd_data,
// Write level values of Phaser_Out coarse and fine
// delay taps required to load Phaser_Out register
input [3*DQS_WIDTH-1:0] wl_po_coarse_cnt,
input [6*DQS_WIDTH-1:0] wl_po_fine_cnt,
input wrlvl_byte_done,
output reg wrlvl_byte_redo,
output reg early1_data,
output reg early2_data,
// DQ IDELAY
output reg idelay_ld,
output reg wrcal_pat_resume, // to phy_init for write
output reg [DQS_CNT_WIDTH:0] po_stg2_wrcal_cnt,
output phy_if_reset,
// Debug Port
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output [99:0] dbg_phy_wrcal
);
// Length of calibration sequence (in # of words)
//localparam CAL_PAT_LEN = 8;
// Read data shift register length
localparam RD_SHIFT_LEN = 1; //(nCK_PER_CLK == 4) ? 1 : 2;
// # of reads for reliable read capture
localparam NUM_READS = 2;
// # of cycles to wait after changing RDEN count value
localparam RDEN_WAIT_CNT = 12;
localparam COARSE_CNT = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 3 : 6;
localparam FINE_CNT = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 22 : 44;
localparam CAL2_IDLE = 4'h0;
localparam CAL2_READ_WAIT = 4'h1;
localparam CAL2_NEXT_DQS = 4'h2;
localparam CAL2_WRLVL_WAIT = 4'h3;
localparam CAL2_IFIFO_RESET = 4'h4;
localparam CAL2_DQ_IDEL_DEC = 4'h5;
localparam CAL2_DONE = 4'h6;
localparam CAL2_SANITY_WAIT = 4'h7;
localparam CAL2_ERR = 4'h8;
integer i,j,k,l,m,p,q,d;
reg [2:0] po_coarse_tap_cnt [0:DQS_WIDTH-1];
reg [3*DQS_WIDTH-1:0] po_coarse_tap_cnt_w;
reg [5:0] po_fine_tap_cnt [0:DQS_WIDTH-1];
reg [6*DQS_WIDTH-1:0] po_fine_tap_cnt_w;
reg [DQS_CNT_WIDTH:0] wrcal_dqs_cnt_r/* synthesis syn_maxfan = 10 */;
reg [4:0] not_empty_wait_cnt;
reg [3:0] tap_inc_wait_cnt;
reg cal2_done_r;
reg cal2_done_r1;
reg cal2_prech_req_r;
reg [3:0] cal2_state_r;
reg [3:0] cal2_state_r1;
reg [2:0] wl_po_coarse_cnt_w [0:DQS_WIDTH-1];
reg [5:0] wl_po_fine_cnt_w [0:DQS_WIDTH-1];
reg cal2_if_reset;
reg wrcal_pat_resume_r;
reg wrcal_pat_resume_r1;
reg wrcal_pat_resume_r2;
reg wrcal_pat_resume_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r;
reg pat_data_match_r;
reg pat1_data_match_r;
reg pat1_data_match_r1;
reg pat2_data_match_r;
reg pat_data_match_valid_r;
wire [RD_SHIFT_LEN-1:0] pat_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_fall1 [3:0];
reg [DRAM_WIDTH-1:0] pat_match_fall0_r;
reg pat_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall1_r;
reg pat_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall2_r;
reg pat_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall3_r;
reg pat_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise0_r;
reg pat_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise1_r;
reg pat_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise2_r;
reg pat_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise3_r;
reg pat_match_rise3_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise0_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise1_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall0_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall1_r;
reg [DRAM_WIDTH-1:0] pat2_match_rise0_r;
reg [DRAM_WIDTH-1:0] pat2_match_rise1_r;
reg [DRAM_WIDTH-1:0] pat2_match_fall0_r;
reg [DRAM_WIDTH-1:0] pat2_match_fall1_r;
reg pat1_match_rise0_and_r;
reg pat1_match_rise1_and_r;
reg pat1_match_fall0_and_r;
reg pat1_match_fall1_and_r;
reg pat2_match_rise0_and_r;
reg pat2_match_rise1_and_r;
reg pat2_match_fall0_and_r;
reg pat2_match_fall1_and_r;
reg early1_data_match_r;
reg early1_data_match_r1;
reg [DRAM_WIDTH-1:0] early1_match_fall0_r;
reg early1_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall1_r;
reg early1_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall2_r;
reg early1_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall3_r;
reg early1_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise0_r;
reg early1_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise1_r;
reg early1_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise2_r;
reg early1_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise3_r;
reg early1_match_rise3_and_r;
reg early2_data_match_r;
reg [DRAM_WIDTH-1:0] early2_match_fall0_r;
reg early2_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall1_r;
reg early2_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall2_r;
reg early2_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall3_r;
reg early2_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise0_r;
reg early2_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise1_r;
reg early2_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise2_r;
reg early2_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise3_r;
reg early2_match_rise3_and_r;
wire [RD_SHIFT_LEN-1:0] pat_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_rise1 [3:0];
wire [DQ_WIDTH-1:0] rd_data_rise0;
wire [DQ_WIDTH-1:0] rd_data_fall0;
wire [DQ_WIDTH-1:0] rd_data_rise1;
wire [DQ_WIDTH-1:0] rd_data_fall1;
wire [DQ_WIDTH-1:0] rd_data_rise2;
wire [DQ_WIDTH-1:0] rd_data_fall2;
wire [DQ_WIDTH-1:0] rd_data_rise3;
wire [DQ_WIDTH-1:0] rd_data_fall3;
reg [DQS_CNT_WIDTH:0] rd_mux_sel_r;
reg rd_active_posedge_r;
reg rd_active_r;
reg rd_active_r1;
reg rd_active_r2;
reg rd_active_r3;
reg rd_active_r4;
reg rd_active_r5;
reg [RD_SHIFT_LEN-1:0] sr_fall0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall3_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise3_r [DRAM_WIDTH-1:0];
reg wrlvl_byte_done_r;
reg idelay_ld_done;
reg pat1_detect;
reg early1_detect;
reg wrcal_sanity_chk_r;
reg wrcal_sanity_chk_err;
//***************************************************************************
// Debug
//***************************************************************************
always @(*) begin
for (d = 0; d < DQS_WIDTH; d = d + 1) begin
po_fine_tap_cnt_w[(6*d)+:6] = po_fine_tap_cnt[d];
po_coarse_tap_cnt_w[(3*d)+:3] = po_coarse_tap_cnt[d];
end
end
assign dbg_final_po_fine_tap_cnt = po_fine_tap_cnt_w;
assign dbg_final_po_coarse_tap_cnt = po_coarse_tap_cnt_w;
assign dbg_phy_wrcal[0] = pat_data_match_r;
assign dbg_phy_wrcal[4:1] = cal2_state_r1[3:0];
assign dbg_phy_wrcal[5] = wrcal_sanity_chk_err;
assign dbg_phy_wrcal[6] = wrcal_start;
assign dbg_phy_wrcal[7] = wrcal_done;
assign dbg_phy_wrcal[8] = pat_data_match_valid_r;
assign dbg_phy_wrcal[13+:DQS_CNT_WIDTH]= wrcal_dqs_cnt_r;
assign dbg_phy_wrcal[17+:5] = not_empty_wait_cnt;
assign dbg_phy_wrcal[22] = early1_data;
assign dbg_phy_wrcal[23] = early2_data;
assign dbg_phy_wrcal[24+:8] = mux_rd_rise0_r;
assign dbg_phy_wrcal[32+:8] = mux_rd_fall0_r;
assign dbg_phy_wrcal[40+:8] = mux_rd_rise1_r;
assign dbg_phy_wrcal[48+:8] = mux_rd_fall1_r;
assign dbg_phy_wrcal[56+:8] = mux_rd_rise2_r;
assign dbg_phy_wrcal[64+:8] = mux_rd_fall2_r;
assign dbg_phy_wrcal[72+:8] = mux_rd_rise3_r;
assign dbg_phy_wrcal[80+:8] = mux_rd_fall3_r;
assign dbg_phy_wrcal[88] = early1_data_match_r;
assign dbg_phy_wrcal[89] = early2_data_match_r;
assign dbg_phy_wrcal[90] = wrcal_sanity_chk_r & pat_data_match_valid_r;
assign dbg_phy_wrcal[91] = wrcal_sanity_chk_r;
assign dbg_phy_wrcal[92] = wrcal_sanity_chk_done;
assign dqsfound_retry = 1'b0;
assign wrcal_read_req = 1'b0;
assign phy_if_reset = cal2_if_reset;
//**************************************************************************
// DQS count to hard PHY during write calibration using Phaser_OUT Stage2
// coarse delay
//**************************************************************************
always @(posedge clk) begin
po_stg2_wrcal_cnt <= #TCQ wrcal_dqs_cnt_r;
wrlvl_byte_done_r <= #TCQ wrlvl_byte_done;
wrcal_sanity_chk_r <= #TCQ wrcal_sanity_chk;
end
//***************************************************************************
// Data mux to route appropriate byte to calibration logic - i.e. calibration
// is done sequentially, one byte (or DQS group) at a time
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: gen_rd_data_div4
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign rd_data_rise2 = rd_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign rd_data_fall2 = rd_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign rd_data_rise3 = rd_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign rd_data_fall3 = rd_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
end else if (nCK_PER_CLK == 2) begin: gen_rd_data_div2
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
end
endgenerate
//**************************************************************************
// Final Phaser OUT coarse and fine delay taps after write calibration
// Sum of taps used during write leveling taps and write calibration
//**************************************************************************
always @(*) begin
for (m = 0; m < DQS_WIDTH; m = m + 1) begin
wl_po_coarse_cnt_w[m] = wl_po_coarse_cnt[3*m+:3];
wl_po_fine_cnt_w[m] = wl_po_fine_cnt[6*m+:6];
end
end
always @(posedge clk) begin
if (rst) begin
for (p = 0; p < DQS_WIDTH; p = p + 1) begin
po_coarse_tap_cnt[p] <= #TCQ {3{1'b0}};
po_fine_tap_cnt[p] <= #TCQ {6{1'b0}};
end
end else if (cal2_done_r && ~cal2_done_r1) begin
for (q = 0; q < DQS_WIDTH; q = q + 1) begin
po_coarse_tap_cnt[q] <= #TCQ wl_po_coarse_cnt_w[i];
po_fine_tap_cnt[q] <= #TCQ wl_po_fine_cnt_w[i];
end
end
end
always @(posedge clk) begin
rd_mux_sel_r <= #TCQ wrcal_dqs_cnt_r;
end
// Register outputs for improved timing.
// NOTE: Will need to change when per-bit DQ deskew is supported.
// Currenly all bits in DQS group are checked in aggregate
generate
genvar mux_i;
if (nCK_PER_CLK == 4) begin: gen_mux_rd_div4
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise2_r[mux_i] <= #TCQ rd_data_rise2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall2_r[mux_i] <= #TCQ rd_data_fall2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise3_r[mux_i] <= #TCQ rd_data_rise3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall3_r[mux_i] <= #TCQ rd_data_fall3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_mux_rd_div2
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
end
endgenerate
//***************************************************************************
// generate request to PHY_INIT logic to issue precharged. Required when
// calibration can take a long time (during which there are only constant
// reads present on this bus). In this case need to issue perioidic
// precharges to avoid tRAS violation. This signal must meet the following
// requirements: (1) only transition from 0->1 when prech is first needed,
// (2) stay at 1 and only transition 1->0 when RDLVL_PRECH_DONE asserted
//***************************************************************************
always @(posedge clk)
if (rst)
wrcal_prech_req <= #TCQ 1'b0;
else
// Combine requests from all stages here
wrcal_prech_req <= #TCQ cal2_prech_req_r;
//***************************************************************************
// Shift register to store last RDDATA_SHIFT_LEN cycles of data from ISERDES
// NOTE: Written using discrete flops, but SRL can be used if the matching
// logic does the comparison sequentially, rather than parallel
//***************************************************************************
generate
genvar rd_i;
if (nCK_PER_CLK == 4) begin: gen_sr_div4
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
sr_rise0_r[rd_i] <= #TCQ mux_rd_rise0_r[rd_i];
sr_fall0_r[rd_i] <= #TCQ mux_rd_fall0_r[rd_i];
sr_rise1_r[rd_i] <= #TCQ mux_rd_rise1_r[rd_i];
sr_fall1_r[rd_i] <= #TCQ mux_rd_fall1_r[rd_i];
sr_rise2_r[rd_i] <= #TCQ mux_rd_rise2_r[rd_i];
sr_fall2_r[rd_i] <= #TCQ mux_rd_fall2_r[rd_i];
sr_rise3_r[rd_i] <= #TCQ mux_rd_rise3_r[rd_i];
sr_fall3_r[rd_i] <= #TCQ mux_rd_fall3_r[rd_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_sr_div2
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
sr_rise0_r[rd_i] <= #TCQ mux_rd_rise0_r[rd_i];
sr_fall0_r[rd_i] <= #TCQ mux_rd_fall0_r[rd_i];
sr_rise1_r[rd_i] <= #TCQ mux_rd_rise1_r[rd_i];
sr_fall1_r[rd_i] <= #TCQ mux_rd_fall1_r[rd_i];
end
end
end
endgenerate
//***************************************************************************
// Write calibration:
// During write leveling DQS is aligned to the nearest CK edge that may not
// be the correct CK edge. Write calibration is required to align the DQS to
// the correct CK edge that clocks the write command.
// The Phaser_Out coarse delay line is adjusted if required to add a memory
// clock cycle of delay in order to read back the expected pattern.
//***************************************************************************
always @(posedge clk) begin
rd_active_r <= #TCQ phy_rddata_en;
rd_active_r1 <= #TCQ rd_active_r;
rd_active_r2 <= #TCQ rd_active_r1;
rd_active_r3 <= #TCQ rd_active_r2;
rd_active_r4 <= #TCQ rd_active_r3;
rd_active_r5 <= #TCQ rd_active_r4;
end
//*****************************************************************
// Expected data pattern when properly received by read capture
// logic:
// Based on pattern of ({rise,fall}) =
// 0xF, 0x0, 0xA, 0x5, 0x5, 0xA, 0x9, 0x6
// Each nibble will look like:
// bit3: 1, 0, 1, 0, 0, 1, 1, 0
// bit2: 1, 0, 0, 1, 1, 0, 0, 1
// bit1: 1, 0, 1, 0, 0, 1, 0, 1
// bit0: 1, 0, 0, 1, 1, 0, 1, 0
// Change the hard-coded pattern below accordingly as RD_SHIFT_LEN
// and the actual training pattern contents change
//*****************************************************************
generate
if (nCK_PER_CLK == 4) begin: gen_pat_div4
// FF00AA5555AA9966
assign pat_rise0[3] = 1'b1;
assign pat_fall0[3] = 1'b0;
assign pat_rise1[3] = 1'b1;
assign pat_fall1[3] = 1'b0;
assign pat_rise2[3] = 1'b0;
assign pat_fall2[3] = 1'b1;
assign pat_rise3[3] = 1'b1;
assign pat_fall3[3] = 1'b0;
assign pat_rise0[2] = 1'b1;
assign pat_fall0[2] = 1'b0;
assign pat_rise1[2] = 1'b0;
assign pat_fall1[2] = 1'b1;
assign pat_rise2[2] = 1'b1;
assign pat_fall2[2] = 1'b0;
assign pat_rise3[2] = 1'b0;
assign pat_fall3[2] = 1'b1;
assign pat_rise0[1] = 1'b1;
assign pat_fall0[1] = 1'b0;
assign pat_rise1[1] = 1'b1;
assign pat_fall1[1] = 1'b0;
assign pat_rise2[1] = 1'b0;
assign pat_fall2[1] = 1'b1;
assign pat_rise3[1] = 1'b0;
assign pat_fall3[1] = 1'b1;
assign pat_rise0[0] = 1'b1;
assign pat_fall0[0] = 1'b0;
assign pat_rise1[0] = 1'b0;
assign pat_fall1[0] = 1'b1;
assign pat_rise2[0] = 1'b1;
assign pat_fall2[0] = 1'b0;
assign pat_rise3[0] = 1'b1;
assign pat_fall3[0] = 1'b0;
// Pattern to distinguish between early write and incorrect read
// BB11EE4444EEDD88
assign early_rise0[3] = 1'b1;
assign early_fall0[3] = 1'b0;
assign early_rise1[3] = 1'b1;
assign early_fall1[3] = 1'b0;
assign early_rise2[3] = 1'b0;
assign early_fall2[3] = 1'b1;
assign early_rise3[3] = 1'b1;
assign early_fall3[3] = 1'b1;
assign early_rise0[2] = 1'b0;
assign early_fall0[2] = 1'b0;
assign early_rise1[2] = 1'b1;
assign early_fall1[2] = 1'b1;
assign early_rise2[2] = 1'b1;
assign early_fall2[2] = 1'b1;
assign early_rise3[2] = 1'b1;
assign early_fall3[2] = 1'b0;
assign early_rise0[1] = 1'b1;
assign early_fall0[1] = 1'b0;
assign early_rise1[1] = 1'b1;
assign early_fall1[1] = 1'b0;
assign early_rise2[1] = 1'b0;
assign early_fall2[1] = 1'b1;
assign early_rise3[1] = 1'b0;
assign early_fall3[1] = 1'b0;
assign early_rise0[0] = 1'b1;
assign early_fall0[0] = 1'b1;
assign early_rise1[0] = 1'b0;
assign early_fall1[0] = 1'b0;
assign early_rise2[0] = 1'b0;
assign early_fall2[0] = 1'b0;
assign early_rise3[0] = 1'b1;
assign early_fall3[0] = 1'b0;
end else if (nCK_PER_CLK == 2) begin: gen_pat_div2
// First cycle pattern FF00AA55
assign pat1_rise0[3] = 1'b1;
assign pat1_fall0[3] = 1'b0;
assign pat1_rise1[3] = 1'b1;
assign pat1_fall1[3] = 1'b0;
assign pat1_rise0[2] = 1'b1;
assign pat1_fall0[2] = 1'b0;
assign pat1_rise1[2] = 1'b0;
assign pat1_fall1[2] = 1'b1;
assign pat1_rise0[1] = 1'b1;
assign pat1_fall0[1] = 1'b0;
assign pat1_rise1[1] = 1'b1;
assign pat1_fall1[1] = 1'b0;
assign pat1_rise0[0] = 1'b1;
assign pat1_fall0[0] = 1'b0;
assign pat1_rise1[0] = 1'b0;
assign pat1_fall1[0] = 1'b1;
// Second cycle pattern 55AA9966
assign pat2_rise0[3] = 1'b0;
assign pat2_fall0[3] = 1'b1;
assign pat2_rise1[3] = 1'b1;
assign pat2_fall1[3] = 1'b0;
assign pat2_rise0[2] = 1'b1;
assign pat2_fall0[2] = 1'b0;
assign pat2_rise1[2] = 1'b0;
assign pat2_fall1[2] = 1'b1;
assign pat2_rise0[1] = 1'b0;
assign pat2_fall0[1] = 1'b1;
assign pat2_rise1[1] = 1'b0;
assign pat2_fall1[1] = 1'b1;
assign pat2_rise0[0] = 1'b1;
assign pat2_fall0[0] = 1'b0;
assign pat2_rise1[0] = 1'b1;
assign pat2_fall1[0] = 1'b0;
//Pattern to distinguish between early write and incorrect read
// First cycle pattern AA5555AA
assign early1_rise0[3] = 2'b1;
assign early1_fall0[3] = 2'b0;
assign early1_rise1[3] = 2'b0;
assign early1_fall1[3] = 2'b1;
assign early1_rise0[2] = 2'b0;
assign early1_fall0[2] = 2'b1;
assign early1_rise1[2] = 2'b1;
assign early1_fall1[2] = 2'b0;
assign early1_rise0[1] = 2'b1;
assign early1_fall0[1] = 2'b0;
assign early1_rise1[1] = 2'b0;
assign early1_fall1[1] = 2'b1;
assign early1_rise0[0] = 2'b0;
assign early1_fall0[0] = 2'b1;
assign early1_rise1[0] = 2'b1;
assign early1_fall1[0] = 2'b0;
// Second cycle pattern 9966BB11
assign early2_rise0[3] = 2'b1;
assign early2_fall0[3] = 2'b0;
assign early2_rise1[3] = 2'b1;
assign early2_fall1[3] = 2'b0;
assign early2_rise0[2] = 2'b0;
assign early2_fall0[2] = 2'b1;
assign early2_rise1[2] = 2'b0;
assign early2_fall1[2] = 2'b0;
assign early2_rise0[1] = 2'b0;
assign early2_fall0[1] = 2'b1;
assign early2_rise1[1] = 2'b1;
assign early2_fall1[1] = 2'b0;
assign early2_rise0[0] = 2'b1;
assign early2_fall0[0] = 2'b0;
assign early2_rise1[0] = 2'b1;
assign early2_fall1[0] = 2'b1;
end
endgenerate
// Each bit of each byte is compared to expected pattern.
// This was done to prevent (and "drastically decrease") the chance that
// invalid data clocked in when the DQ bus is tri-state (along with a
// combination of the correct data) will resemble the expected data
// pattern. A better fix for this is to change the training pattern and/or
// make the pattern longer.
generate
genvar pt_i;
if (nCK_PER_CLK == 4) begin: gen_pat_match_div4
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise0[pt_i%4])
pat_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall0[pt_i%4])
pat_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise1[pt_i%4])
pat_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall1[pt_i%4])
pat_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat_rise2[pt_i%4])
pat_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat_fall2[pt_i%4])
pat_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == pat_rise3[pt_i%4])
pat_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == pat_fall3[pt_i%4])
pat_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise1[pt_i%4])
early1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall1[pt_i%4])
early1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise2[pt_i%4])
early1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall2[pt_i%4])
early1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat_rise3[pt_i%4])
early1_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat_fall3[pt_i%4])
early1_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == early_rise0[pt_i%4])
early1_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == early_fall0[pt_i%4])
early1_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise2[pt_i%4])
early2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall2[pt_i%4])
early2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise3[pt_i%4])
early2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall3[pt_i%4])
early2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == early_rise0[pt_i%4])
early2_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == early_fall0[pt_i%4])
early2_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == early_rise1[pt_i%4])
early2_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == early_fall1[pt_i%4])
early2_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
end
always @(posedge clk) begin
pat_match_rise0_and_r <= #TCQ &pat_match_rise0_r;
pat_match_fall0_and_r <= #TCQ &pat_match_fall0_r;
pat_match_rise1_and_r <= #TCQ &pat_match_rise1_r;
pat_match_fall1_and_r <= #TCQ &pat_match_fall1_r;
pat_match_rise2_and_r <= #TCQ &pat_match_rise2_r;
pat_match_fall2_and_r <= #TCQ &pat_match_fall2_r;
pat_match_rise3_and_r <= #TCQ &pat_match_rise3_r;
pat_match_fall3_and_r <= #TCQ &pat_match_fall3_r;
pat_data_match_r <= #TCQ (pat_match_rise0_and_r &&
pat_match_fall0_and_r &&
pat_match_rise1_and_r &&
pat_match_fall1_and_r &&
pat_match_rise2_and_r &&
pat_match_fall2_and_r &&
pat_match_rise3_and_r &&
pat_match_fall3_and_r);
pat_data_match_valid_r <= #TCQ rd_active_r3;
end
always @(posedge clk) begin
early1_match_rise0_and_r <= #TCQ &early1_match_rise0_r;
early1_match_fall0_and_r <= #TCQ &early1_match_fall0_r;
early1_match_rise1_and_r <= #TCQ &early1_match_rise1_r;
early1_match_fall1_and_r <= #TCQ &early1_match_fall1_r;
early1_match_rise2_and_r <= #TCQ &early1_match_rise2_r;
early1_match_fall2_and_r <= #TCQ &early1_match_fall2_r;
early1_match_rise3_and_r <= #TCQ &early1_match_rise3_r;
early1_match_fall3_and_r <= #TCQ &early1_match_fall3_r;
early1_data_match_r <= #TCQ (early1_match_rise0_and_r &&
early1_match_fall0_and_r &&
early1_match_rise1_and_r &&
early1_match_fall1_and_r &&
early1_match_rise2_and_r &&
early1_match_fall2_and_r &&
early1_match_rise3_and_r &&
early1_match_fall3_and_r);
end
always @(posedge clk) begin
early2_match_rise0_and_r <= #TCQ &early2_match_rise0_r;
early2_match_fall0_and_r <= #TCQ &early2_match_fall0_r;
early2_match_rise1_and_r <= #TCQ &early2_match_rise1_r;
early2_match_fall1_and_r <= #TCQ &early2_match_fall1_r;
early2_match_rise2_and_r <= #TCQ &early2_match_rise2_r;
early2_match_fall2_and_r <= #TCQ &early2_match_fall2_r;
early2_match_rise3_and_r <= #TCQ &early2_match_rise3_r;
early2_match_fall3_and_r <= #TCQ &early2_match_fall3_r;
early2_data_match_r <= #TCQ (early2_match_rise0_and_r &&
early2_match_fall0_and_r &&
early2_match_rise1_and_r &&
early2_match_fall1_and_r &&
early2_match_rise2_and_r &&
early2_match_fall2_and_r &&
early2_match_rise3_and_r &&
early2_match_fall3_and_r);
end
end else if (nCK_PER_CLK == 2) begin: gen_pat_match_div2
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat1_rise0[pt_i%4])
pat1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat1_fall0[pt_i%4])
pat1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat1_rise1[pt_i%4])
pat1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat1_fall1[pt_i%4])
pat1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat2_rise0[pt_i%4])
pat2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat2_fall0[pt_i%4])
pat2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat2_rise1[pt_i%4])
pat2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat2_fall1[pt_i%4])
pat2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == early1_rise0[pt_i%4])
early1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == early1_fall0[pt_i%4])
early1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == early1_rise1[pt_i%4])
early1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == early1_fall1[pt_i%4])
early1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
// early2 in this case does not mean 2 cycles early but
// the second cycle of read data in 2:1 mode
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == early2_rise0[pt_i%4])
early2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == early2_fall0[pt_i%4])
early2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == early2_rise1[pt_i%4])
early2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == early2_fall1[pt_i%4])
early2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
end
always @(posedge clk) begin
pat1_match_rise0_and_r <= #TCQ &pat1_match_rise0_r;
pat1_match_fall0_and_r <= #TCQ &pat1_match_fall0_r;
pat1_match_rise1_and_r <= #TCQ &pat1_match_rise1_r;
pat1_match_fall1_and_r <= #TCQ &pat1_match_fall1_r;
pat1_data_match_r <= #TCQ (pat1_match_rise0_and_r &&
pat1_match_fall0_and_r &&
pat1_match_rise1_and_r &&
pat1_match_fall1_and_r);
pat1_data_match_r1 <= #TCQ pat1_data_match_r;
pat2_match_rise0_and_r <= #TCQ &pat2_match_rise0_r && rd_active_r3;
pat2_match_fall0_and_r <= #TCQ &pat2_match_fall0_r && rd_active_r3;
pat2_match_rise1_and_r <= #TCQ &pat2_match_rise1_r && rd_active_r3;
pat2_match_fall1_and_r <= #TCQ &pat2_match_fall1_r && rd_active_r3;
pat2_data_match_r <= #TCQ (pat2_match_rise0_and_r &&
pat2_match_fall0_and_r &&
pat2_match_rise1_and_r &&
pat2_match_fall1_and_r);
// For 2:1 mode, read valid is asserted for 2 clock cycles -
// here we generate a "match valid" pulse that is only 1 clock
// cycle wide that is simulatenous when the match calculation
// is complete
pat_data_match_valid_r <= #TCQ rd_active_r4 & ~rd_active_r5;
end
always @(posedge clk) begin
early1_match_rise0_and_r <= #TCQ &early1_match_rise0_r;
early1_match_fall0_and_r <= #TCQ &early1_match_fall0_r;
early1_match_rise1_and_r <= #TCQ &early1_match_rise1_r;
early1_match_fall1_and_r <= #TCQ &early1_match_fall1_r;
early1_data_match_r <= #TCQ (early1_match_rise0_and_r &&
early1_match_fall0_and_r &&
early1_match_rise1_and_r &&
early1_match_fall1_and_r);
early1_data_match_r1 <= #TCQ early1_data_match_r;
early2_match_rise0_and_r <= #TCQ &early2_match_rise0_r && rd_active_r3;
early2_match_fall0_and_r <= #TCQ &early2_match_fall0_r && rd_active_r3;
early2_match_rise1_and_r <= #TCQ &early2_match_rise1_r && rd_active_r3;
early2_match_fall1_and_r <= #TCQ &early2_match_fall1_r && rd_active_r3;
early2_data_match_r <= #TCQ (early2_match_rise0_and_r &&
early2_match_fall0_and_r &&
early2_match_rise1_and_r &&
early2_match_fall1_and_r);
end
end
endgenerate
// Need to delay it by 3 cycles in order to wait for Phaser_Out
// coarse delay to take effect before issuing a write command
always @(posedge clk) begin
wrcal_pat_resume_r1 <= #TCQ wrcal_pat_resume_r;
wrcal_pat_resume_r2 <= #TCQ wrcal_pat_resume_r1;
wrcal_pat_resume <= #TCQ wrcal_pat_resume_r2;
end
always @(posedge clk) begin
if (rst)
tap_inc_wait_cnt <= #TCQ 'd0;
else if ((cal2_state_r == CAL2_DQ_IDEL_DEC) ||
(cal2_state_r == CAL2_IFIFO_RESET) ||
(cal2_state_r == CAL2_SANITY_WAIT))
tap_inc_wait_cnt <= #TCQ tap_inc_wait_cnt + 1;
else
tap_inc_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk) begin
if (rst)
not_empty_wait_cnt <= #TCQ 'd0;
else if ((cal2_state_r == CAL2_READ_WAIT) && wrcal_rd_wait)
not_empty_wait_cnt <= #TCQ not_empty_wait_cnt + 1;
else
not_empty_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk)
cal2_state_r1 <= #TCQ cal2_state_r;
//*****************************************************************
// Write Calibration state machine
//*****************************************************************
// when calibrating, check to see if the expected pattern is received.
// Otherwise delay DQS to align to correct CK edge.
// NOTES:
// 1. An error condition can occur due to two reasons:
// a. If the matching logic does not receive the expected data
// pattern. However, the error may be "recoverable" because
// the write calibration is still in progress. If an error is
// found the write calibration logic delays DQS by an additional
// clock cycle and restarts the pattern detection process.
// By design, if the write path timing is incorrect, the correct
// data pattern will never be detected.
// b. Valid data not found even after incrementing Phaser_Out
// coarse delay line.
always @(posedge clk) begin
if (rst) begin
wrcal_dqs_cnt_r <= #TCQ 'b0;
cal2_done_r <= #TCQ 1'b0;
cal2_prech_req_r <= #TCQ 1'b0;
cal2_state_r <= #TCQ CAL2_IDLE;
wrcal_pat_err <= #TCQ 1'b0;
wrcal_pat_resume_r <= #TCQ 1'b0;
wrcal_act_req <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
temp_wrcal_done <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b0;
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b0;
idelay_ld <= #TCQ 1'b0;
idelay_ld_done <= #TCQ 1'b0;
pat1_detect <= #TCQ 1'b0;
early1_detect <= #TCQ 1'b0;
wrcal_sanity_chk_done <= #TCQ 1'b0;
wrcal_sanity_chk_err <= #TCQ 1'b0;
end else begin
cal2_prech_req_r <= #TCQ 1'b0;
case (cal2_state_r)
CAL2_IDLE: begin
wrcal_pat_err <= #TCQ 1'b0;
if (wrcal_start) begin
cal2_if_reset <= #TCQ 1'b0;
if (SIM_CAL_OPTION == "SKIP_CAL")
// If skip write calibration, then proceed to end.
cal2_state_r <= #TCQ CAL2_DONE;
else
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end
end
// General wait state to wait for read data to be output by the
// IN_FIFO
CAL2_READ_WAIT: begin
wrcal_pat_resume_r <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
// Wait until read data is received, and pattern matching
// calculation is complete. NOTE: Need to add a timeout here
// in case for some reason data is never received (or rather
// the PHASER_IN and IN_FIFO think they never receives data)
if (pat_data_match_valid_r && (nCK_PER_CLK == 4)) begin
if (pat_data_match_r)
// If found data match, then move on to next DQS group
cal2_state_r <= #TCQ CAL2_NEXT_DQS;
else begin
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_ERR;
// If writes are one or two cycles early then redo
// write leveling for the byte
else if (early1_data_match_r) begin
early1_data <= #TCQ 1'b1;
early2_data <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
end else if (early2_data_match_r) begin
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b1;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
// Read late due to incorrect MPR idelay value
// Decrement Idelay to '0'for the current byte
end else if (~idelay_ld_done) begin
cal2_state_r <= #TCQ CAL2_DQ_IDEL_DEC;
idelay_ld <= #TCQ 1'b1;
end else
cal2_state_r <= #TCQ CAL2_ERR;
end
end else if (pat_data_match_valid_r && (nCK_PER_CLK == 2)) begin
if ((pat1_data_match_r1 && pat2_data_match_r) ||
(pat1_detect && pat2_data_match_r))
// If found data match, then move on to next DQS group
cal2_state_r <= #TCQ CAL2_NEXT_DQS;
else if (pat1_data_match_r1 && ~pat2_data_match_r) begin
cal2_state_r <= #TCQ CAL2_READ_WAIT;
pat1_detect <= #TCQ 1'b1;
end else begin
// If writes are one or two cycles early then redo
// write leveling for the byte
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_ERR;
else if ((early1_data_match_r1 && early2_data_match_r) ||
(early1_detect && early2_data_match_r)) begin
early1_data <= #TCQ 1'b1;
early2_data <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
end else if (early1_data_match_r1 && ~early2_data_match_r) begin
early1_detect <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
// Read late due to incorrect MPR idelay value
// Decrement Idelay to '0'for the current byte
end else if (~idelay_ld_done) begin
cal2_state_r <= #TCQ CAL2_DQ_IDEL_DEC;
idelay_ld <= #TCQ 1'b1;
end else
cal2_state_r <= #TCQ CAL2_ERR;
end
end else if (not_empty_wait_cnt == 'd31)
cal2_state_r <= #TCQ CAL2_ERR;
end
CAL2_WRLVL_WAIT: begin
early1_detect <= #TCQ 1'b0;
if (wrlvl_byte_done && ~wrlvl_byte_done_r)
wrlvl_byte_redo <= #TCQ 1'b0;
if (wrlvl_byte_done) begin
if (rd_active_r1 && ~rd_active_r) begin
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
cal2_if_reset <= #TCQ 1'b1;
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b0;
end
end
end
CAL2_DQ_IDEL_DEC: begin
if (tap_inc_wait_cnt == 'd4) begin
idelay_ld <= #TCQ 1'b0;
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
cal2_if_reset <= #TCQ 1'b1;
idelay_ld_done <= #TCQ 1'b1;
end
end
CAL2_IFIFO_RESET: begin
if (tap_inc_wait_cnt == 'd15) begin
cal2_if_reset <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_DONE;
else if (idelay_ld_done) begin
wrcal_pat_resume_r <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end else
cal2_state_r <= #TCQ CAL2_IDLE;
end
end
// Final processing for current DQS group. Move on to next group
CAL2_NEXT_DQS: begin
// At this point, we've just found the correct pattern for the
// current DQS group.
// Request bank/row precharge, and wait for its completion. Always
// precharge after each DQS group to avoid tRAS(max) violation
//verilint STARC-2.2.3.3 off
if (wrcal_sanity_chk_r && (wrcal_dqs_cnt_r != DQS_WIDTH-1)) begin
cal2_prech_req_r <= #TCQ 1'b0;
wrcal_dqs_cnt_r <= #TCQ wrcal_dqs_cnt_r + 1;
cal2_state_r <= #TCQ CAL2_SANITY_WAIT;
end else
cal2_prech_req_r <= #TCQ 1'b1;
idelay_ld_done <= #TCQ 1'b0;
pat1_detect <= #TCQ 1'b0;
if (prech_done)
if (((DQS_WIDTH == 1) || (SIM_CAL_OPTION == "FAST_CAL")) ||
(wrcal_dqs_cnt_r == DQS_WIDTH-1)) begin
// If either FAST_CAL is enabled and first DQS group is
// finished, or if the last DQS group was just finished,
// then end of write calibration
if (wrcal_sanity_chk_r) begin
cal2_if_reset <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
end else
cal2_state_r <= #TCQ CAL2_DONE;
end else begin
// Continue to next DQS group
wrcal_dqs_cnt_r <= #TCQ wrcal_dqs_cnt_r + 1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end
end
//verilint STARC-2.2.3.3 on
CAL2_SANITY_WAIT: begin
if (tap_inc_wait_cnt == 'd15) begin
cal2_state_r <= #TCQ CAL2_READ_WAIT;
wrcal_pat_resume_r <= #TCQ 1'b1;
end
end
// Finished with read enable calibration
CAL2_DONE: begin
if (wrcal_sanity_chk && ~wrcal_sanity_chk_r) begin
cal2_done_r <= #TCQ 1'b0;
wrcal_dqs_cnt_r <= #TCQ 'd0;
cal2_state_r <= #TCQ CAL2_IDLE;
end else
cal2_done_r <= #TCQ 1'b1;
cal2_prech_req_r <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
wrcal_sanity_chk_done <= #TCQ 1'b1;
end
// Assert error signal indicating that writes timing is incorrect
CAL2_ERR: begin
wrcal_pat_resume_r <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
wrcal_sanity_chk_err <= #TCQ 1'b1;
else
wrcal_pat_err <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_ERR;
end
endcase
end
end
// Delay assertion of wrcal_done for write calibration by a few cycles after
// we've reached CAL2_DONE
always @(posedge clk)
if (rst)
cal2_done_r1 <= #TCQ 1'b0;
else
cal2_done_r1 <= #TCQ cal2_done_r;
always @(posedge clk)
if (rst || (wrcal_sanity_chk && ~wrcal_sanity_chk_r))
wrcal_done <= #TCQ 1'b0;
else if (cal2_done_r)
wrcal_done <= #TCQ 1'b1;
endmodule
|
module mig_7series_v2_3_ddr_phy_wrcal #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter nCK_PER_CLK = 2, // # of memory clocks per CLK
parameter CLK_PERIOD = 2500,
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter PRE_REV3ES = "OFF", // Delay O/Ps using Phaser_Out fine dly
parameter SIM_CAL_OPTION = "NONE" // Skip various calibration steps
)
(
input clk,
input rst,
// Calibration status, control signals
input wrcal_start,
input wrcal_rd_wait,
input wrcal_sanity_chk,
input dqsfound_retry_done,
input phy_rddata_en,
output dqsfound_retry,
output wrcal_read_req,
output reg wrcal_act_req,
output reg wrcal_done,
output reg wrcal_pat_err,
output reg wrcal_prech_req,
output reg temp_wrcal_done,
output reg wrcal_sanity_chk_done,
input prech_done,
// Captured data in resync clock domain
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] rd_data,
// Write level values of Phaser_Out coarse and fine
// delay taps required to load Phaser_Out register
input [3*DQS_WIDTH-1:0] wl_po_coarse_cnt,
input [6*DQS_WIDTH-1:0] wl_po_fine_cnt,
input wrlvl_byte_done,
output reg wrlvl_byte_redo,
output reg early1_data,
output reg early2_data,
// DQ IDELAY
output reg idelay_ld,
output reg wrcal_pat_resume, // to phy_init for write
output reg [DQS_CNT_WIDTH:0] po_stg2_wrcal_cnt,
output phy_if_reset,
// Debug Port
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output [99:0] dbg_phy_wrcal
);
// Length of calibration sequence (in # of words)
//localparam CAL_PAT_LEN = 8;
// Read data shift register length
localparam RD_SHIFT_LEN = 1; //(nCK_PER_CLK == 4) ? 1 : 2;
// # of reads for reliable read capture
localparam NUM_READS = 2;
// # of cycles to wait after changing RDEN count value
localparam RDEN_WAIT_CNT = 12;
localparam COARSE_CNT = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 3 : 6;
localparam FINE_CNT = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 22 : 44;
localparam CAL2_IDLE = 4'h0;
localparam CAL2_READ_WAIT = 4'h1;
localparam CAL2_NEXT_DQS = 4'h2;
localparam CAL2_WRLVL_WAIT = 4'h3;
localparam CAL2_IFIFO_RESET = 4'h4;
localparam CAL2_DQ_IDEL_DEC = 4'h5;
localparam CAL2_DONE = 4'h6;
localparam CAL2_SANITY_WAIT = 4'h7;
localparam CAL2_ERR = 4'h8;
integer i,j,k,l,m,p,q,d;
reg [2:0] po_coarse_tap_cnt [0:DQS_WIDTH-1];
reg [3*DQS_WIDTH-1:0] po_coarse_tap_cnt_w;
reg [5:0] po_fine_tap_cnt [0:DQS_WIDTH-1];
reg [6*DQS_WIDTH-1:0] po_fine_tap_cnt_w;
reg [DQS_CNT_WIDTH:0] wrcal_dqs_cnt_r/* synthesis syn_maxfan = 10 */;
reg [4:0] not_empty_wait_cnt;
reg [3:0] tap_inc_wait_cnt;
reg cal2_done_r;
reg cal2_done_r1;
reg cal2_prech_req_r;
reg [3:0] cal2_state_r;
reg [3:0] cal2_state_r1;
reg [2:0] wl_po_coarse_cnt_w [0:DQS_WIDTH-1];
reg [5:0] wl_po_fine_cnt_w [0:DQS_WIDTH-1];
reg cal2_if_reset;
reg wrcal_pat_resume_r;
reg wrcal_pat_resume_r1;
reg wrcal_pat_resume_r2;
reg wrcal_pat_resume_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r;
reg pat_data_match_r;
reg pat1_data_match_r;
reg pat1_data_match_r1;
reg pat2_data_match_r;
reg pat_data_match_valid_r;
wire [RD_SHIFT_LEN-1:0] pat_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_fall1 [3:0];
reg [DRAM_WIDTH-1:0] pat_match_fall0_r;
reg pat_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall1_r;
reg pat_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall2_r;
reg pat_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall3_r;
reg pat_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise0_r;
reg pat_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise1_r;
reg pat_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise2_r;
reg pat_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise3_r;
reg pat_match_rise3_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise0_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise1_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall0_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall1_r;
reg [DRAM_WIDTH-1:0] pat2_match_rise0_r;
reg [DRAM_WIDTH-1:0] pat2_match_rise1_r;
reg [DRAM_WIDTH-1:0] pat2_match_fall0_r;
reg [DRAM_WIDTH-1:0] pat2_match_fall1_r;
reg pat1_match_rise0_and_r;
reg pat1_match_rise1_and_r;
reg pat1_match_fall0_and_r;
reg pat1_match_fall1_and_r;
reg pat2_match_rise0_and_r;
reg pat2_match_rise1_and_r;
reg pat2_match_fall0_and_r;
reg pat2_match_fall1_and_r;
reg early1_data_match_r;
reg early1_data_match_r1;
reg [DRAM_WIDTH-1:0] early1_match_fall0_r;
reg early1_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall1_r;
reg early1_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall2_r;
reg early1_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall3_r;
reg early1_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise0_r;
reg early1_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise1_r;
reg early1_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise2_r;
reg early1_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise3_r;
reg early1_match_rise3_and_r;
reg early2_data_match_r;
reg [DRAM_WIDTH-1:0] early2_match_fall0_r;
reg early2_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall1_r;
reg early2_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall2_r;
reg early2_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall3_r;
reg early2_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise0_r;
reg early2_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise1_r;
reg early2_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise2_r;
reg early2_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise3_r;
reg early2_match_rise3_and_r;
wire [RD_SHIFT_LEN-1:0] pat_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_rise1 [3:0];
wire [DQ_WIDTH-1:0] rd_data_rise0;
wire [DQ_WIDTH-1:0] rd_data_fall0;
wire [DQ_WIDTH-1:0] rd_data_rise1;
wire [DQ_WIDTH-1:0] rd_data_fall1;
wire [DQ_WIDTH-1:0] rd_data_rise2;
wire [DQ_WIDTH-1:0] rd_data_fall2;
wire [DQ_WIDTH-1:0] rd_data_rise3;
wire [DQ_WIDTH-1:0] rd_data_fall3;
reg [DQS_CNT_WIDTH:0] rd_mux_sel_r;
reg rd_active_posedge_r;
reg rd_active_r;
reg rd_active_r1;
reg rd_active_r2;
reg rd_active_r3;
reg rd_active_r4;
reg rd_active_r5;
reg [RD_SHIFT_LEN-1:0] sr_fall0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall3_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise3_r [DRAM_WIDTH-1:0];
reg wrlvl_byte_done_r;
reg idelay_ld_done;
reg pat1_detect;
reg early1_detect;
reg wrcal_sanity_chk_r;
reg wrcal_sanity_chk_err;
//***************************************************************************
// Debug
//***************************************************************************
always @(*) begin
for (d = 0; d < DQS_WIDTH; d = d + 1) begin
po_fine_tap_cnt_w[(6*d)+:6] = po_fine_tap_cnt[d];
po_coarse_tap_cnt_w[(3*d)+:3] = po_coarse_tap_cnt[d];
end
end
assign dbg_final_po_fine_tap_cnt = po_fine_tap_cnt_w;
assign dbg_final_po_coarse_tap_cnt = po_coarse_tap_cnt_w;
assign dbg_phy_wrcal[0] = pat_data_match_r;
assign dbg_phy_wrcal[4:1] = cal2_state_r1[3:0];
assign dbg_phy_wrcal[5] = wrcal_sanity_chk_err;
assign dbg_phy_wrcal[6] = wrcal_start;
assign dbg_phy_wrcal[7] = wrcal_done;
assign dbg_phy_wrcal[8] = pat_data_match_valid_r;
assign dbg_phy_wrcal[13+:DQS_CNT_WIDTH]= wrcal_dqs_cnt_r;
assign dbg_phy_wrcal[17+:5] = not_empty_wait_cnt;
assign dbg_phy_wrcal[22] = early1_data;
assign dbg_phy_wrcal[23] = early2_data;
assign dbg_phy_wrcal[24+:8] = mux_rd_rise0_r;
assign dbg_phy_wrcal[32+:8] = mux_rd_fall0_r;
assign dbg_phy_wrcal[40+:8] = mux_rd_rise1_r;
assign dbg_phy_wrcal[48+:8] = mux_rd_fall1_r;
assign dbg_phy_wrcal[56+:8] = mux_rd_rise2_r;
assign dbg_phy_wrcal[64+:8] = mux_rd_fall2_r;
assign dbg_phy_wrcal[72+:8] = mux_rd_rise3_r;
assign dbg_phy_wrcal[80+:8] = mux_rd_fall3_r;
assign dbg_phy_wrcal[88] = early1_data_match_r;
assign dbg_phy_wrcal[89] = early2_data_match_r;
assign dbg_phy_wrcal[90] = wrcal_sanity_chk_r & pat_data_match_valid_r;
assign dbg_phy_wrcal[91] = wrcal_sanity_chk_r;
assign dbg_phy_wrcal[92] = wrcal_sanity_chk_done;
assign dqsfound_retry = 1'b0;
assign wrcal_read_req = 1'b0;
assign phy_if_reset = cal2_if_reset;
//**************************************************************************
// DQS count to hard PHY during write calibration using Phaser_OUT Stage2
// coarse delay
//**************************************************************************
always @(posedge clk) begin
po_stg2_wrcal_cnt <= #TCQ wrcal_dqs_cnt_r;
wrlvl_byte_done_r <= #TCQ wrlvl_byte_done;
wrcal_sanity_chk_r <= #TCQ wrcal_sanity_chk;
end
//***************************************************************************
// Data mux to route appropriate byte to calibration logic - i.e. calibration
// is done sequentially, one byte (or DQS group) at a time
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: gen_rd_data_div4
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign rd_data_rise2 = rd_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign rd_data_fall2 = rd_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign rd_data_rise3 = rd_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign rd_data_fall3 = rd_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
end else if (nCK_PER_CLK == 2) begin: gen_rd_data_div2
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
end
endgenerate
//**************************************************************************
// Final Phaser OUT coarse and fine delay taps after write calibration
// Sum of taps used during write leveling taps and write calibration
//**************************************************************************
always @(*) begin
for (m = 0; m < DQS_WIDTH; m = m + 1) begin
wl_po_coarse_cnt_w[m] = wl_po_coarse_cnt[3*m+:3];
wl_po_fine_cnt_w[m] = wl_po_fine_cnt[6*m+:6];
end
end
always @(posedge clk) begin
if (rst) begin
for (p = 0; p < DQS_WIDTH; p = p + 1) begin
po_coarse_tap_cnt[p] <= #TCQ {3{1'b0}};
po_fine_tap_cnt[p] <= #TCQ {6{1'b0}};
end
end else if (cal2_done_r && ~cal2_done_r1) begin
for (q = 0; q < DQS_WIDTH; q = q + 1) begin
po_coarse_tap_cnt[q] <= #TCQ wl_po_coarse_cnt_w[i];
po_fine_tap_cnt[q] <= #TCQ wl_po_fine_cnt_w[i];
end
end
end
always @(posedge clk) begin
rd_mux_sel_r <= #TCQ wrcal_dqs_cnt_r;
end
// Register outputs for improved timing.
// NOTE: Will need to change when per-bit DQ deskew is supported.
// Currenly all bits in DQS group are checked in aggregate
generate
genvar mux_i;
if (nCK_PER_CLK == 4) begin: gen_mux_rd_div4
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise2_r[mux_i] <= #TCQ rd_data_rise2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall2_r[mux_i] <= #TCQ rd_data_fall2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise3_r[mux_i] <= #TCQ rd_data_rise3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall3_r[mux_i] <= #TCQ rd_data_fall3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_mux_rd_div2
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
end
endgenerate
//***************************************************************************
// generate request to PHY_INIT logic to issue precharged. Required when
// calibration can take a long time (during which there are only constant
// reads present on this bus). In this case need to issue perioidic
// precharges to avoid tRAS violation. This signal must meet the following
// requirements: (1) only transition from 0->1 when prech is first needed,
// (2) stay at 1 and only transition 1->0 when RDLVL_PRECH_DONE asserted
//***************************************************************************
always @(posedge clk)
if (rst)
wrcal_prech_req <= #TCQ 1'b0;
else
// Combine requests from all stages here
wrcal_prech_req <= #TCQ cal2_prech_req_r;
//***************************************************************************
// Shift register to store last RDDATA_SHIFT_LEN cycles of data from ISERDES
// NOTE: Written using discrete flops, but SRL can be used if the matching
// logic does the comparison sequentially, rather than parallel
//***************************************************************************
generate
genvar rd_i;
if (nCK_PER_CLK == 4) begin: gen_sr_div4
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
sr_rise0_r[rd_i] <= #TCQ mux_rd_rise0_r[rd_i];
sr_fall0_r[rd_i] <= #TCQ mux_rd_fall0_r[rd_i];
sr_rise1_r[rd_i] <= #TCQ mux_rd_rise1_r[rd_i];
sr_fall1_r[rd_i] <= #TCQ mux_rd_fall1_r[rd_i];
sr_rise2_r[rd_i] <= #TCQ mux_rd_rise2_r[rd_i];
sr_fall2_r[rd_i] <= #TCQ mux_rd_fall2_r[rd_i];
sr_rise3_r[rd_i] <= #TCQ mux_rd_rise3_r[rd_i];
sr_fall3_r[rd_i] <= #TCQ mux_rd_fall3_r[rd_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_sr_div2
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
sr_rise0_r[rd_i] <= #TCQ mux_rd_rise0_r[rd_i];
sr_fall0_r[rd_i] <= #TCQ mux_rd_fall0_r[rd_i];
sr_rise1_r[rd_i] <= #TCQ mux_rd_rise1_r[rd_i];
sr_fall1_r[rd_i] <= #TCQ mux_rd_fall1_r[rd_i];
end
end
end
endgenerate
//***************************************************************************
// Write calibration:
// During write leveling DQS is aligned to the nearest CK edge that may not
// be the correct CK edge. Write calibration is required to align the DQS to
// the correct CK edge that clocks the write command.
// The Phaser_Out coarse delay line is adjusted if required to add a memory
// clock cycle of delay in order to read back the expected pattern.
//***************************************************************************
always @(posedge clk) begin
rd_active_r <= #TCQ phy_rddata_en;
rd_active_r1 <= #TCQ rd_active_r;
rd_active_r2 <= #TCQ rd_active_r1;
rd_active_r3 <= #TCQ rd_active_r2;
rd_active_r4 <= #TCQ rd_active_r3;
rd_active_r5 <= #TCQ rd_active_r4;
end
//*****************************************************************
// Expected data pattern when properly received by read capture
// logic:
// Based on pattern of ({rise,fall}) =
// 0xF, 0x0, 0xA, 0x5, 0x5, 0xA, 0x9, 0x6
// Each nibble will look like:
// bit3: 1, 0, 1, 0, 0, 1, 1, 0
// bit2: 1, 0, 0, 1, 1, 0, 0, 1
// bit1: 1, 0, 1, 0, 0, 1, 0, 1
// bit0: 1, 0, 0, 1, 1, 0, 1, 0
// Change the hard-coded pattern below accordingly as RD_SHIFT_LEN
// and the actual training pattern contents change
//*****************************************************************
generate
if (nCK_PER_CLK == 4) begin: gen_pat_div4
// FF00AA5555AA9966
assign pat_rise0[3] = 1'b1;
assign pat_fall0[3] = 1'b0;
assign pat_rise1[3] = 1'b1;
assign pat_fall1[3] = 1'b0;
assign pat_rise2[3] = 1'b0;
assign pat_fall2[3] = 1'b1;
assign pat_rise3[3] = 1'b1;
assign pat_fall3[3] = 1'b0;
assign pat_rise0[2] = 1'b1;
assign pat_fall0[2] = 1'b0;
assign pat_rise1[2] = 1'b0;
assign pat_fall1[2] = 1'b1;
assign pat_rise2[2] = 1'b1;
assign pat_fall2[2] = 1'b0;
assign pat_rise3[2] = 1'b0;
assign pat_fall3[2] = 1'b1;
assign pat_rise0[1] = 1'b1;
assign pat_fall0[1] = 1'b0;
assign pat_rise1[1] = 1'b1;
assign pat_fall1[1] = 1'b0;
assign pat_rise2[1] = 1'b0;
assign pat_fall2[1] = 1'b1;
assign pat_rise3[1] = 1'b0;
assign pat_fall3[1] = 1'b1;
assign pat_rise0[0] = 1'b1;
assign pat_fall0[0] = 1'b0;
assign pat_rise1[0] = 1'b0;
assign pat_fall1[0] = 1'b1;
assign pat_rise2[0] = 1'b1;
assign pat_fall2[0] = 1'b0;
assign pat_rise3[0] = 1'b1;
assign pat_fall3[0] = 1'b0;
// Pattern to distinguish between early write and incorrect read
// BB11EE4444EEDD88
assign early_rise0[3] = 1'b1;
assign early_fall0[3] = 1'b0;
assign early_rise1[3] = 1'b1;
assign early_fall1[3] = 1'b0;
assign early_rise2[3] = 1'b0;
assign early_fall2[3] = 1'b1;
assign early_rise3[3] = 1'b1;
assign early_fall3[3] = 1'b1;
assign early_rise0[2] = 1'b0;
assign early_fall0[2] = 1'b0;
assign early_rise1[2] = 1'b1;
assign early_fall1[2] = 1'b1;
assign early_rise2[2] = 1'b1;
assign early_fall2[2] = 1'b1;
assign early_rise3[2] = 1'b1;
assign early_fall3[2] = 1'b0;
assign early_rise0[1] = 1'b1;
assign early_fall0[1] = 1'b0;
assign early_rise1[1] = 1'b1;
assign early_fall1[1] = 1'b0;
assign early_rise2[1] = 1'b0;
assign early_fall2[1] = 1'b1;
assign early_rise3[1] = 1'b0;
assign early_fall3[1] = 1'b0;
assign early_rise0[0] = 1'b1;
assign early_fall0[0] = 1'b1;
assign early_rise1[0] = 1'b0;
assign early_fall1[0] = 1'b0;
assign early_rise2[0] = 1'b0;
assign early_fall2[0] = 1'b0;
assign early_rise3[0] = 1'b1;
assign early_fall3[0] = 1'b0;
end else if (nCK_PER_CLK == 2) begin: gen_pat_div2
// First cycle pattern FF00AA55
assign pat1_rise0[3] = 1'b1;
assign pat1_fall0[3] = 1'b0;
assign pat1_rise1[3] = 1'b1;
assign pat1_fall1[3] = 1'b0;
assign pat1_rise0[2] = 1'b1;
assign pat1_fall0[2] = 1'b0;
assign pat1_rise1[2] = 1'b0;
assign pat1_fall1[2] = 1'b1;
assign pat1_rise0[1] = 1'b1;
assign pat1_fall0[1] = 1'b0;
assign pat1_rise1[1] = 1'b1;
assign pat1_fall1[1] = 1'b0;
assign pat1_rise0[0] = 1'b1;
assign pat1_fall0[0] = 1'b0;
assign pat1_rise1[0] = 1'b0;
assign pat1_fall1[0] = 1'b1;
// Second cycle pattern 55AA9966
assign pat2_rise0[3] = 1'b0;
assign pat2_fall0[3] = 1'b1;
assign pat2_rise1[3] = 1'b1;
assign pat2_fall1[3] = 1'b0;
assign pat2_rise0[2] = 1'b1;
assign pat2_fall0[2] = 1'b0;
assign pat2_rise1[2] = 1'b0;
assign pat2_fall1[2] = 1'b1;
assign pat2_rise0[1] = 1'b0;
assign pat2_fall0[1] = 1'b1;
assign pat2_rise1[1] = 1'b0;
assign pat2_fall1[1] = 1'b1;
assign pat2_rise0[0] = 1'b1;
assign pat2_fall0[0] = 1'b0;
assign pat2_rise1[0] = 1'b1;
assign pat2_fall1[0] = 1'b0;
//Pattern to distinguish between early write and incorrect read
// First cycle pattern AA5555AA
assign early1_rise0[3] = 2'b1;
assign early1_fall0[3] = 2'b0;
assign early1_rise1[3] = 2'b0;
assign early1_fall1[3] = 2'b1;
assign early1_rise0[2] = 2'b0;
assign early1_fall0[2] = 2'b1;
assign early1_rise1[2] = 2'b1;
assign early1_fall1[2] = 2'b0;
assign early1_rise0[1] = 2'b1;
assign early1_fall0[1] = 2'b0;
assign early1_rise1[1] = 2'b0;
assign early1_fall1[1] = 2'b1;
assign early1_rise0[0] = 2'b0;
assign early1_fall0[0] = 2'b1;
assign early1_rise1[0] = 2'b1;
assign early1_fall1[0] = 2'b0;
// Second cycle pattern 9966BB11
assign early2_rise0[3] = 2'b1;
assign early2_fall0[3] = 2'b0;
assign early2_rise1[3] = 2'b1;
assign early2_fall1[3] = 2'b0;
assign early2_rise0[2] = 2'b0;
assign early2_fall0[2] = 2'b1;
assign early2_rise1[2] = 2'b0;
assign early2_fall1[2] = 2'b0;
assign early2_rise0[1] = 2'b0;
assign early2_fall0[1] = 2'b1;
assign early2_rise1[1] = 2'b1;
assign early2_fall1[1] = 2'b0;
assign early2_rise0[0] = 2'b1;
assign early2_fall0[0] = 2'b0;
assign early2_rise1[0] = 2'b1;
assign early2_fall1[0] = 2'b1;
end
endgenerate
// Each bit of each byte is compared to expected pattern.
// This was done to prevent (and "drastically decrease") the chance that
// invalid data clocked in when the DQ bus is tri-state (along with a
// combination of the correct data) will resemble the expected data
// pattern. A better fix for this is to change the training pattern and/or
// make the pattern longer.
generate
genvar pt_i;
if (nCK_PER_CLK == 4) begin: gen_pat_match_div4
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise0[pt_i%4])
pat_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall0[pt_i%4])
pat_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise1[pt_i%4])
pat_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall1[pt_i%4])
pat_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat_rise2[pt_i%4])
pat_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat_fall2[pt_i%4])
pat_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == pat_rise3[pt_i%4])
pat_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == pat_fall3[pt_i%4])
pat_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise1[pt_i%4])
early1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall1[pt_i%4])
early1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise2[pt_i%4])
early1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall2[pt_i%4])
early1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat_rise3[pt_i%4])
early1_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat_fall3[pt_i%4])
early1_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == early_rise0[pt_i%4])
early1_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == early_fall0[pt_i%4])
early1_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise2[pt_i%4])
early2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall2[pt_i%4])
early2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise3[pt_i%4])
early2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall3[pt_i%4])
early2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == early_rise0[pt_i%4])
early2_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == early_fall0[pt_i%4])
early2_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == early_rise1[pt_i%4])
early2_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == early_fall1[pt_i%4])
early2_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
end
always @(posedge clk) begin
pat_match_rise0_and_r <= #TCQ &pat_match_rise0_r;
pat_match_fall0_and_r <= #TCQ &pat_match_fall0_r;
pat_match_rise1_and_r <= #TCQ &pat_match_rise1_r;
pat_match_fall1_and_r <= #TCQ &pat_match_fall1_r;
pat_match_rise2_and_r <= #TCQ &pat_match_rise2_r;
pat_match_fall2_and_r <= #TCQ &pat_match_fall2_r;
pat_match_rise3_and_r <= #TCQ &pat_match_rise3_r;
pat_match_fall3_and_r <= #TCQ &pat_match_fall3_r;
pat_data_match_r <= #TCQ (pat_match_rise0_and_r &&
pat_match_fall0_and_r &&
pat_match_rise1_and_r &&
pat_match_fall1_and_r &&
pat_match_rise2_and_r &&
pat_match_fall2_and_r &&
pat_match_rise3_and_r &&
pat_match_fall3_and_r);
pat_data_match_valid_r <= #TCQ rd_active_r3;
end
always @(posedge clk) begin
early1_match_rise0_and_r <= #TCQ &early1_match_rise0_r;
early1_match_fall0_and_r <= #TCQ &early1_match_fall0_r;
early1_match_rise1_and_r <= #TCQ &early1_match_rise1_r;
early1_match_fall1_and_r <= #TCQ &early1_match_fall1_r;
early1_match_rise2_and_r <= #TCQ &early1_match_rise2_r;
early1_match_fall2_and_r <= #TCQ &early1_match_fall2_r;
early1_match_rise3_and_r <= #TCQ &early1_match_rise3_r;
early1_match_fall3_and_r <= #TCQ &early1_match_fall3_r;
early1_data_match_r <= #TCQ (early1_match_rise0_and_r &&
early1_match_fall0_and_r &&
early1_match_rise1_and_r &&
early1_match_fall1_and_r &&
early1_match_rise2_and_r &&
early1_match_fall2_and_r &&
early1_match_rise3_and_r &&
early1_match_fall3_and_r);
end
always @(posedge clk) begin
early2_match_rise0_and_r <= #TCQ &early2_match_rise0_r;
early2_match_fall0_and_r <= #TCQ &early2_match_fall0_r;
early2_match_rise1_and_r <= #TCQ &early2_match_rise1_r;
early2_match_fall1_and_r <= #TCQ &early2_match_fall1_r;
early2_match_rise2_and_r <= #TCQ &early2_match_rise2_r;
early2_match_fall2_and_r <= #TCQ &early2_match_fall2_r;
early2_match_rise3_and_r <= #TCQ &early2_match_rise3_r;
early2_match_fall3_and_r <= #TCQ &early2_match_fall3_r;
early2_data_match_r <= #TCQ (early2_match_rise0_and_r &&
early2_match_fall0_and_r &&
early2_match_rise1_and_r &&
early2_match_fall1_and_r &&
early2_match_rise2_and_r &&
early2_match_fall2_and_r &&
early2_match_rise3_and_r &&
early2_match_fall3_and_r);
end
end else if (nCK_PER_CLK == 2) begin: gen_pat_match_div2
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat1_rise0[pt_i%4])
pat1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat1_fall0[pt_i%4])
pat1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat1_rise1[pt_i%4])
pat1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat1_fall1[pt_i%4])
pat1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat2_rise0[pt_i%4])
pat2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat2_fall0[pt_i%4])
pat2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat2_rise1[pt_i%4])
pat2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat2_fall1[pt_i%4])
pat2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == early1_rise0[pt_i%4])
early1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == early1_fall0[pt_i%4])
early1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == early1_rise1[pt_i%4])
early1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == early1_fall1[pt_i%4])
early1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
// early2 in this case does not mean 2 cycles early but
// the second cycle of read data in 2:1 mode
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == early2_rise0[pt_i%4])
early2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == early2_fall0[pt_i%4])
early2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == early2_rise1[pt_i%4])
early2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == early2_fall1[pt_i%4])
early2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
end
always @(posedge clk) begin
pat1_match_rise0_and_r <= #TCQ &pat1_match_rise0_r;
pat1_match_fall0_and_r <= #TCQ &pat1_match_fall0_r;
pat1_match_rise1_and_r <= #TCQ &pat1_match_rise1_r;
pat1_match_fall1_and_r <= #TCQ &pat1_match_fall1_r;
pat1_data_match_r <= #TCQ (pat1_match_rise0_and_r &&
pat1_match_fall0_and_r &&
pat1_match_rise1_and_r &&
pat1_match_fall1_and_r);
pat1_data_match_r1 <= #TCQ pat1_data_match_r;
pat2_match_rise0_and_r <= #TCQ &pat2_match_rise0_r && rd_active_r3;
pat2_match_fall0_and_r <= #TCQ &pat2_match_fall0_r && rd_active_r3;
pat2_match_rise1_and_r <= #TCQ &pat2_match_rise1_r && rd_active_r3;
pat2_match_fall1_and_r <= #TCQ &pat2_match_fall1_r && rd_active_r3;
pat2_data_match_r <= #TCQ (pat2_match_rise0_and_r &&
pat2_match_fall0_and_r &&
pat2_match_rise1_and_r &&
pat2_match_fall1_and_r);
// For 2:1 mode, read valid is asserted for 2 clock cycles -
// here we generate a "match valid" pulse that is only 1 clock
// cycle wide that is simulatenous when the match calculation
// is complete
pat_data_match_valid_r <= #TCQ rd_active_r4 & ~rd_active_r5;
end
always @(posedge clk) begin
early1_match_rise0_and_r <= #TCQ &early1_match_rise0_r;
early1_match_fall0_and_r <= #TCQ &early1_match_fall0_r;
early1_match_rise1_and_r <= #TCQ &early1_match_rise1_r;
early1_match_fall1_and_r <= #TCQ &early1_match_fall1_r;
early1_data_match_r <= #TCQ (early1_match_rise0_and_r &&
early1_match_fall0_and_r &&
early1_match_rise1_and_r &&
early1_match_fall1_and_r);
early1_data_match_r1 <= #TCQ early1_data_match_r;
early2_match_rise0_and_r <= #TCQ &early2_match_rise0_r && rd_active_r3;
early2_match_fall0_and_r <= #TCQ &early2_match_fall0_r && rd_active_r3;
early2_match_rise1_and_r <= #TCQ &early2_match_rise1_r && rd_active_r3;
early2_match_fall1_and_r <= #TCQ &early2_match_fall1_r && rd_active_r3;
early2_data_match_r <= #TCQ (early2_match_rise0_and_r &&
early2_match_fall0_and_r &&
early2_match_rise1_and_r &&
early2_match_fall1_and_r);
end
end
endgenerate
// Need to delay it by 3 cycles in order to wait for Phaser_Out
// coarse delay to take effect before issuing a write command
always @(posedge clk) begin
wrcal_pat_resume_r1 <= #TCQ wrcal_pat_resume_r;
wrcal_pat_resume_r2 <= #TCQ wrcal_pat_resume_r1;
wrcal_pat_resume <= #TCQ wrcal_pat_resume_r2;
end
always @(posedge clk) begin
if (rst)
tap_inc_wait_cnt <= #TCQ 'd0;
else if ((cal2_state_r == CAL2_DQ_IDEL_DEC) ||
(cal2_state_r == CAL2_IFIFO_RESET) ||
(cal2_state_r == CAL2_SANITY_WAIT))
tap_inc_wait_cnt <= #TCQ tap_inc_wait_cnt + 1;
else
tap_inc_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk) begin
if (rst)
not_empty_wait_cnt <= #TCQ 'd0;
else if ((cal2_state_r == CAL2_READ_WAIT) && wrcal_rd_wait)
not_empty_wait_cnt <= #TCQ not_empty_wait_cnt + 1;
else
not_empty_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk)
cal2_state_r1 <= #TCQ cal2_state_r;
//*****************************************************************
// Write Calibration state machine
//*****************************************************************
// when calibrating, check to see if the expected pattern is received.
// Otherwise delay DQS to align to correct CK edge.
// NOTES:
// 1. An error condition can occur due to two reasons:
// a. If the matching logic does not receive the expected data
// pattern. However, the error may be "recoverable" because
// the write calibration is still in progress. If an error is
// found the write calibration logic delays DQS by an additional
// clock cycle and restarts the pattern detection process.
// By design, if the write path timing is incorrect, the correct
// data pattern will never be detected.
// b. Valid data not found even after incrementing Phaser_Out
// coarse delay line.
always @(posedge clk) begin
if (rst) begin
wrcal_dqs_cnt_r <= #TCQ 'b0;
cal2_done_r <= #TCQ 1'b0;
cal2_prech_req_r <= #TCQ 1'b0;
cal2_state_r <= #TCQ CAL2_IDLE;
wrcal_pat_err <= #TCQ 1'b0;
wrcal_pat_resume_r <= #TCQ 1'b0;
wrcal_act_req <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
temp_wrcal_done <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b0;
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b0;
idelay_ld <= #TCQ 1'b0;
idelay_ld_done <= #TCQ 1'b0;
pat1_detect <= #TCQ 1'b0;
early1_detect <= #TCQ 1'b0;
wrcal_sanity_chk_done <= #TCQ 1'b0;
wrcal_sanity_chk_err <= #TCQ 1'b0;
end else begin
cal2_prech_req_r <= #TCQ 1'b0;
case (cal2_state_r)
CAL2_IDLE: begin
wrcal_pat_err <= #TCQ 1'b0;
if (wrcal_start) begin
cal2_if_reset <= #TCQ 1'b0;
if (SIM_CAL_OPTION == "SKIP_CAL")
// If skip write calibration, then proceed to end.
cal2_state_r <= #TCQ CAL2_DONE;
else
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end
end
// General wait state to wait for read data to be output by the
// IN_FIFO
CAL2_READ_WAIT: begin
wrcal_pat_resume_r <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
// Wait until read data is received, and pattern matching
// calculation is complete. NOTE: Need to add a timeout here
// in case for some reason data is never received (or rather
// the PHASER_IN and IN_FIFO think they never receives data)
if (pat_data_match_valid_r && (nCK_PER_CLK == 4)) begin
if (pat_data_match_r)
// If found data match, then move on to next DQS group
cal2_state_r <= #TCQ CAL2_NEXT_DQS;
else begin
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_ERR;
// If writes are one or two cycles early then redo
// write leveling for the byte
else if (early1_data_match_r) begin
early1_data <= #TCQ 1'b1;
early2_data <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
end else if (early2_data_match_r) begin
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b1;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
// Read late due to incorrect MPR idelay value
// Decrement Idelay to '0'for the current byte
end else if (~idelay_ld_done) begin
cal2_state_r <= #TCQ CAL2_DQ_IDEL_DEC;
idelay_ld <= #TCQ 1'b1;
end else
cal2_state_r <= #TCQ CAL2_ERR;
end
end else if (pat_data_match_valid_r && (nCK_PER_CLK == 2)) begin
if ((pat1_data_match_r1 && pat2_data_match_r) ||
(pat1_detect && pat2_data_match_r))
// If found data match, then move on to next DQS group
cal2_state_r <= #TCQ CAL2_NEXT_DQS;
else if (pat1_data_match_r1 && ~pat2_data_match_r) begin
cal2_state_r <= #TCQ CAL2_READ_WAIT;
pat1_detect <= #TCQ 1'b1;
end else begin
// If writes are one or two cycles early then redo
// write leveling for the byte
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_ERR;
else if ((early1_data_match_r1 && early2_data_match_r) ||
(early1_detect && early2_data_match_r)) begin
early1_data <= #TCQ 1'b1;
early2_data <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
end else if (early1_data_match_r1 && ~early2_data_match_r) begin
early1_detect <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
// Read late due to incorrect MPR idelay value
// Decrement Idelay to '0'for the current byte
end else if (~idelay_ld_done) begin
cal2_state_r <= #TCQ CAL2_DQ_IDEL_DEC;
idelay_ld <= #TCQ 1'b1;
end else
cal2_state_r <= #TCQ CAL2_ERR;
end
end else if (not_empty_wait_cnt == 'd31)
cal2_state_r <= #TCQ CAL2_ERR;
end
CAL2_WRLVL_WAIT: begin
early1_detect <= #TCQ 1'b0;
if (wrlvl_byte_done && ~wrlvl_byte_done_r)
wrlvl_byte_redo <= #TCQ 1'b0;
if (wrlvl_byte_done) begin
if (rd_active_r1 && ~rd_active_r) begin
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
cal2_if_reset <= #TCQ 1'b1;
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b0;
end
end
end
CAL2_DQ_IDEL_DEC: begin
if (tap_inc_wait_cnt == 'd4) begin
idelay_ld <= #TCQ 1'b0;
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
cal2_if_reset <= #TCQ 1'b1;
idelay_ld_done <= #TCQ 1'b1;
end
end
CAL2_IFIFO_RESET: begin
if (tap_inc_wait_cnt == 'd15) begin
cal2_if_reset <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_DONE;
else if (idelay_ld_done) begin
wrcal_pat_resume_r <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end else
cal2_state_r <= #TCQ CAL2_IDLE;
end
end
// Final processing for current DQS group. Move on to next group
CAL2_NEXT_DQS: begin
// At this point, we've just found the correct pattern for the
// current DQS group.
// Request bank/row precharge, and wait for its completion. Always
// precharge after each DQS group to avoid tRAS(max) violation
//verilint STARC-2.2.3.3 off
if (wrcal_sanity_chk_r && (wrcal_dqs_cnt_r != DQS_WIDTH-1)) begin
cal2_prech_req_r <= #TCQ 1'b0;
wrcal_dqs_cnt_r <= #TCQ wrcal_dqs_cnt_r + 1;
cal2_state_r <= #TCQ CAL2_SANITY_WAIT;
end else
cal2_prech_req_r <= #TCQ 1'b1;
idelay_ld_done <= #TCQ 1'b0;
pat1_detect <= #TCQ 1'b0;
if (prech_done)
if (((DQS_WIDTH == 1) || (SIM_CAL_OPTION == "FAST_CAL")) ||
(wrcal_dqs_cnt_r == DQS_WIDTH-1)) begin
// If either FAST_CAL is enabled and first DQS group is
// finished, or if the last DQS group was just finished,
// then end of write calibration
if (wrcal_sanity_chk_r) begin
cal2_if_reset <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
end else
cal2_state_r <= #TCQ CAL2_DONE;
end else begin
// Continue to next DQS group
wrcal_dqs_cnt_r <= #TCQ wrcal_dqs_cnt_r + 1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end
end
//verilint STARC-2.2.3.3 on
CAL2_SANITY_WAIT: begin
if (tap_inc_wait_cnt == 'd15) begin
cal2_state_r <= #TCQ CAL2_READ_WAIT;
wrcal_pat_resume_r <= #TCQ 1'b1;
end
end
// Finished with read enable calibration
CAL2_DONE: begin
if (wrcal_sanity_chk && ~wrcal_sanity_chk_r) begin
cal2_done_r <= #TCQ 1'b0;
wrcal_dqs_cnt_r <= #TCQ 'd0;
cal2_state_r <= #TCQ CAL2_IDLE;
end else
cal2_done_r <= #TCQ 1'b1;
cal2_prech_req_r <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
wrcal_sanity_chk_done <= #TCQ 1'b1;
end
// Assert error signal indicating that writes timing is incorrect
CAL2_ERR: begin
wrcal_pat_resume_r <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
wrcal_sanity_chk_err <= #TCQ 1'b1;
else
wrcal_pat_err <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_ERR;
end
endcase
end
end
// Delay assertion of wrcal_done for write calibration by a few cycles after
// we've reached CAL2_DONE
always @(posedge clk)
if (rst)
cal2_done_r1 <= #TCQ 1'b0;
else
cal2_done_r1 <= #TCQ cal2_done_r;
always @(posedge clk)
if (rst || (wrcal_sanity_chk && ~wrcal_sanity_chk_r))
wrcal_done <= #TCQ 1'b0;
else if (cal2_done_r)
wrcal_done <= #TCQ 1'b1;
endmodule
|
module mig_7series_v2_3_ddr_phy_wrcal #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter nCK_PER_CLK = 2, // # of memory clocks per CLK
parameter CLK_PERIOD = 2500,
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter PRE_REV3ES = "OFF", // Delay O/Ps using Phaser_Out fine dly
parameter SIM_CAL_OPTION = "NONE" // Skip various calibration steps
)
(
input clk,
input rst,
// Calibration status, control signals
input wrcal_start,
input wrcal_rd_wait,
input wrcal_sanity_chk,
input dqsfound_retry_done,
input phy_rddata_en,
output dqsfound_retry,
output wrcal_read_req,
output reg wrcal_act_req,
output reg wrcal_done,
output reg wrcal_pat_err,
output reg wrcal_prech_req,
output reg temp_wrcal_done,
output reg wrcal_sanity_chk_done,
input prech_done,
// Captured data in resync clock domain
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] rd_data,
// Write level values of Phaser_Out coarse and fine
// delay taps required to load Phaser_Out register
input [3*DQS_WIDTH-1:0] wl_po_coarse_cnt,
input [6*DQS_WIDTH-1:0] wl_po_fine_cnt,
input wrlvl_byte_done,
output reg wrlvl_byte_redo,
output reg early1_data,
output reg early2_data,
// DQ IDELAY
output reg idelay_ld,
output reg wrcal_pat_resume, // to phy_init for write
output reg [DQS_CNT_WIDTH:0] po_stg2_wrcal_cnt,
output phy_if_reset,
// Debug Port
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output [99:0] dbg_phy_wrcal
);
// Length of calibration sequence (in # of words)
//localparam CAL_PAT_LEN = 8;
// Read data shift register length
localparam RD_SHIFT_LEN = 1; //(nCK_PER_CLK == 4) ? 1 : 2;
// # of reads for reliable read capture
localparam NUM_READS = 2;
// # of cycles to wait after changing RDEN count value
localparam RDEN_WAIT_CNT = 12;
localparam COARSE_CNT = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 3 : 6;
localparam FINE_CNT = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 22 : 44;
localparam CAL2_IDLE = 4'h0;
localparam CAL2_READ_WAIT = 4'h1;
localparam CAL2_NEXT_DQS = 4'h2;
localparam CAL2_WRLVL_WAIT = 4'h3;
localparam CAL2_IFIFO_RESET = 4'h4;
localparam CAL2_DQ_IDEL_DEC = 4'h5;
localparam CAL2_DONE = 4'h6;
localparam CAL2_SANITY_WAIT = 4'h7;
localparam CAL2_ERR = 4'h8;
integer i,j,k,l,m,p,q,d;
reg [2:0] po_coarse_tap_cnt [0:DQS_WIDTH-1];
reg [3*DQS_WIDTH-1:0] po_coarse_tap_cnt_w;
reg [5:0] po_fine_tap_cnt [0:DQS_WIDTH-1];
reg [6*DQS_WIDTH-1:0] po_fine_tap_cnt_w;
reg [DQS_CNT_WIDTH:0] wrcal_dqs_cnt_r/* synthesis syn_maxfan = 10 */;
reg [4:0] not_empty_wait_cnt;
reg [3:0] tap_inc_wait_cnt;
reg cal2_done_r;
reg cal2_done_r1;
reg cal2_prech_req_r;
reg [3:0] cal2_state_r;
reg [3:0] cal2_state_r1;
reg [2:0] wl_po_coarse_cnt_w [0:DQS_WIDTH-1];
reg [5:0] wl_po_fine_cnt_w [0:DQS_WIDTH-1];
reg cal2_if_reset;
reg wrcal_pat_resume_r;
reg wrcal_pat_resume_r1;
reg wrcal_pat_resume_r2;
reg wrcal_pat_resume_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r;
reg pat_data_match_r;
reg pat1_data_match_r;
reg pat1_data_match_r1;
reg pat2_data_match_r;
reg pat_data_match_valid_r;
wire [RD_SHIFT_LEN-1:0] pat_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_fall1 [3:0];
reg [DRAM_WIDTH-1:0] pat_match_fall0_r;
reg pat_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall1_r;
reg pat_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall2_r;
reg pat_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall3_r;
reg pat_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise0_r;
reg pat_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise1_r;
reg pat_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise2_r;
reg pat_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise3_r;
reg pat_match_rise3_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise0_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise1_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall0_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall1_r;
reg [DRAM_WIDTH-1:0] pat2_match_rise0_r;
reg [DRAM_WIDTH-1:0] pat2_match_rise1_r;
reg [DRAM_WIDTH-1:0] pat2_match_fall0_r;
reg [DRAM_WIDTH-1:0] pat2_match_fall1_r;
reg pat1_match_rise0_and_r;
reg pat1_match_rise1_and_r;
reg pat1_match_fall0_and_r;
reg pat1_match_fall1_and_r;
reg pat2_match_rise0_and_r;
reg pat2_match_rise1_and_r;
reg pat2_match_fall0_and_r;
reg pat2_match_fall1_and_r;
reg early1_data_match_r;
reg early1_data_match_r1;
reg [DRAM_WIDTH-1:0] early1_match_fall0_r;
reg early1_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall1_r;
reg early1_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall2_r;
reg early1_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall3_r;
reg early1_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise0_r;
reg early1_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise1_r;
reg early1_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise2_r;
reg early1_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise3_r;
reg early1_match_rise3_and_r;
reg early2_data_match_r;
reg [DRAM_WIDTH-1:0] early2_match_fall0_r;
reg early2_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall1_r;
reg early2_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall2_r;
reg early2_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall3_r;
reg early2_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise0_r;
reg early2_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise1_r;
reg early2_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise2_r;
reg early2_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise3_r;
reg early2_match_rise3_and_r;
wire [RD_SHIFT_LEN-1:0] pat_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_rise1 [3:0];
wire [DQ_WIDTH-1:0] rd_data_rise0;
wire [DQ_WIDTH-1:0] rd_data_fall0;
wire [DQ_WIDTH-1:0] rd_data_rise1;
wire [DQ_WIDTH-1:0] rd_data_fall1;
wire [DQ_WIDTH-1:0] rd_data_rise2;
wire [DQ_WIDTH-1:0] rd_data_fall2;
wire [DQ_WIDTH-1:0] rd_data_rise3;
wire [DQ_WIDTH-1:0] rd_data_fall3;
reg [DQS_CNT_WIDTH:0] rd_mux_sel_r;
reg rd_active_posedge_r;
reg rd_active_r;
reg rd_active_r1;
reg rd_active_r2;
reg rd_active_r3;
reg rd_active_r4;
reg rd_active_r5;
reg [RD_SHIFT_LEN-1:0] sr_fall0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall3_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise3_r [DRAM_WIDTH-1:0];
reg wrlvl_byte_done_r;
reg idelay_ld_done;
reg pat1_detect;
reg early1_detect;
reg wrcal_sanity_chk_r;
reg wrcal_sanity_chk_err;
//***************************************************************************
// Debug
//***************************************************************************
always @(*) begin
for (d = 0; d < DQS_WIDTH; d = d + 1) begin
po_fine_tap_cnt_w[(6*d)+:6] = po_fine_tap_cnt[d];
po_coarse_tap_cnt_w[(3*d)+:3] = po_coarse_tap_cnt[d];
end
end
assign dbg_final_po_fine_tap_cnt = po_fine_tap_cnt_w;
assign dbg_final_po_coarse_tap_cnt = po_coarse_tap_cnt_w;
assign dbg_phy_wrcal[0] = pat_data_match_r;
assign dbg_phy_wrcal[4:1] = cal2_state_r1[3:0];
assign dbg_phy_wrcal[5] = wrcal_sanity_chk_err;
assign dbg_phy_wrcal[6] = wrcal_start;
assign dbg_phy_wrcal[7] = wrcal_done;
assign dbg_phy_wrcal[8] = pat_data_match_valid_r;
assign dbg_phy_wrcal[13+:DQS_CNT_WIDTH]= wrcal_dqs_cnt_r;
assign dbg_phy_wrcal[17+:5] = not_empty_wait_cnt;
assign dbg_phy_wrcal[22] = early1_data;
assign dbg_phy_wrcal[23] = early2_data;
assign dbg_phy_wrcal[24+:8] = mux_rd_rise0_r;
assign dbg_phy_wrcal[32+:8] = mux_rd_fall0_r;
assign dbg_phy_wrcal[40+:8] = mux_rd_rise1_r;
assign dbg_phy_wrcal[48+:8] = mux_rd_fall1_r;
assign dbg_phy_wrcal[56+:8] = mux_rd_rise2_r;
assign dbg_phy_wrcal[64+:8] = mux_rd_fall2_r;
assign dbg_phy_wrcal[72+:8] = mux_rd_rise3_r;
assign dbg_phy_wrcal[80+:8] = mux_rd_fall3_r;
assign dbg_phy_wrcal[88] = early1_data_match_r;
assign dbg_phy_wrcal[89] = early2_data_match_r;
assign dbg_phy_wrcal[90] = wrcal_sanity_chk_r & pat_data_match_valid_r;
assign dbg_phy_wrcal[91] = wrcal_sanity_chk_r;
assign dbg_phy_wrcal[92] = wrcal_sanity_chk_done;
assign dqsfound_retry = 1'b0;
assign wrcal_read_req = 1'b0;
assign phy_if_reset = cal2_if_reset;
//**************************************************************************
// DQS count to hard PHY during write calibration using Phaser_OUT Stage2
// coarse delay
//**************************************************************************
always @(posedge clk) begin
po_stg2_wrcal_cnt <= #TCQ wrcal_dqs_cnt_r;
wrlvl_byte_done_r <= #TCQ wrlvl_byte_done;
wrcal_sanity_chk_r <= #TCQ wrcal_sanity_chk;
end
//***************************************************************************
// Data mux to route appropriate byte to calibration logic - i.e. calibration
// is done sequentially, one byte (or DQS group) at a time
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: gen_rd_data_div4
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign rd_data_rise2 = rd_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign rd_data_fall2 = rd_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign rd_data_rise3 = rd_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign rd_data_fall3 = rd_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
end else if (nCK_PER_CLK == 2) begin: gen_rd_data_div2
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
end
endgenerate
//**************************************************************************
// Final Phaser OUT coarse and fine delay taps after write calibration
// Sum of taps used during write leveling taps and write calibration
//**************************************************************************
always @(*) begin
for (m = 0; m < DQS_WIDTH; m = m + 1) begin
wl_po_coarse_cnt_w[m] = wl_po_coarse_cnt[3*m+:3];
wl_po_fine_cnt_w[m] = wl_po_fine_cnt[6*m+:6];
end
end
always @(posedge clk) begin
if (rst) begin
for (p = 0; p < DQS_WIDTH; p = p + 1) begin
po_coarse_tap_cnt[p] <= #TCQ {3{1'b0}};
po_fine_tap_cnt[p] <= #TCQ {6{1'b0}};
end
end else if (cal2_done_r && ~cal2_done_r1) begin
for (q = 0; q < DQS_WIDTH; q = q + 1) begin
po_coarse_tap_cnt[q] <= #TCQ wl_po_coarse_cnt_w[i];
po_fine_tap_cnt[q] <= #TCQ wl_po_fine_cnt_w[i];
end
end
end
always @(posedge clk) begin
rd_mux_sel_r <= #TCQ wrcal_dqs_cnt_r;
end
// Register outputs for improved timing.
// NOTE: Will need to change when per-bit DQ deskew is supported.
// Currenly all bits in DQS group are checked in aggregate
generate
genvar mux_i;
if (nCK_PER_CLK == 4) begin: gen_mux_rd_div4
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise2_r[mux_i] <= #TCQ rd_data_rise2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall2_r[mux_i] <= #TCQ rd_data_fall2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise3_r[mux_i] <= #TCQ rd_data_rise3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall3_r[mux_i] <= #TCQ rd_data_fall3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_mux_rd_div2
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
end
endgenerate
//***************************************************************************
// generate request to PHY_INIT logic to issue precharged. Required when
// calibration can take a long time (during which there are only constant
// reads present on this bus). In this case need to issue perioidic
// precharges to avoid tRAS violation. This signal must meet the following
// requirements: (1) only transition from 0->1 when prech is first needed,
// (2) stay at 1 and only transition 1->0 when RDLVL_PRECH_DONE asserted
//***************************************************************************
always @(posedge clk)
if (rst)
wrcal_prech_req <= #TCQ 1'b0;
else
// Combine requests from all stages here
wrcal_prech_req <= #TCQ cal2_prech_req_r;
//***************************************************************************
// Shift register to store last RDDATA_SHIFT_LEN cycles of data from ISERDES
// NOTE: Written using discrete flops, but SRL can be used if the matching
// logic does the comparison sequentially, rather than parallel
//***************************************************************************
generate
genvar rd_i;
if (nCK_PER_CLK == 4) begin: gen_sr_div4
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
sr_rise0_r[rd_i] <= #TCQ mux_rd_rise0_r[rd_i];
sr_fall0_r[rd_i] <= #TCQ mux_rd_fall0_r[rd_i];
sr_rise1_r[rd_i] <= #TCQ mux_rd_rise1_r[rd_i];
sr_fall1_r[rd_i] <= #TCQ mux_rd_fall1_r[rd_i];
sr_rise2_r[rd_i] <= #TCQ mux_rd_rise2_r[rd_i];
sr_fall2_r[rd_i] <= #TCQ mux_rd_fall2_r[rd_i];
sr_rise3_r[rd_i] <= #TCQ mux_rd_rise3_r[rd_i];
sr_fall3_r[rd_i] <= #TCQ mux_rd_fall3_r[rd_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_sr_div2
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
sr_rise0_r[rd_i] <= #TCQ mux_rd_rise0_r[rd_i];
sr_fall0_r[rd_i] <= #TCQ mux_rd_fall0_r[rd_i];
sr_rise1_r[rd_i] <= #TCQ mux_rd_rise1_r[rd_i];
sr_fall1_r[rd_i] <= #TCQ mux_rd_fall1_r[rd_i];
end
end
end
endgenerate
//***************************************************************************
// Write calibration:
// During write leveling DQS is aligned to the nearest CK edge that may not
// be the correct CK edge. Write calibration is required to align the DQS to
// the correct CK edge that clocks the write command.
// The Phaser_Out coarse delay line is adjusted if required to add a memory
// clock cycle of delay in order to read back the expected pattern.
//***************************************************************************
always @(posedge clk) begin
rd_active_r <= #TCQ phy_rddata_en;
rd_active_r1 <= #TCQ rd_active_r;
rd_active_r2 <= #TCQ rd_active_r1;
rd_active_r3 <= #TCQ rd_active_r2;
rd_active_r4 <= #TCQ rd_active_r3;
rd_active_r5 <= #TCQ rd_active_r4;
end
//*****************************************************************
// Expected data pattern when properly received by read capture
// logic:
// Based on pattern of ({rise,fall}) =
// 0xF, 0x0, 0xA, 0x5, 0x5, 0xA, 0x9, 0x6
// Each nibble will look like:
// bit3: 1, 0, 1, 0, 0, 1, 1, 0
// bit2: 1, 0, 0, 1, 1, 0, 0, 1
// bit1: 1, 0, 1, 0, 0, 1, 0, 1
// bit0: 1, 0, 0, 1, 1, 0, 1, 0
// Change the hard-coded pattern below accordingly as RD_SHIFT_LEN
// and the actual training pattern contents change
//*****************************************************************
generate
if (nCK_PER_CLK == 4) begin: gen_pat_div4
// FF00AA5555AA9966
assign pat_rise0[3] = 1'b1;
assign pat_fall0[3] = 1'b0;
assign pat_rise1[3] = 1'b1;
assign pat_fall1[3] = 1'b0;
assign pat_rise2[3] = 1'b0;
assign pat_fall2[3] = 1'b1;
assign pat_rise3[3] = 1'b1;
assign pat_fall3[3] = 1'b0;
assign pat_rise0[2] = 1'b1;
assign pat_fall0[2] = 1'b0;
assign pat_rise1[2] = 1'b0;
assign pat_fall1[2] = 1'b1;
assign pat_rise2[2] = 1'b1;
assign pat_fall2[2] = 1'b0;
assign pat_rise3[2] = 1'b0;
assign pat_fall3[2] = 1'b1;
assign pat_rise0[1] = 1'b1;
assign pat_fall0[1] = 1'b0;
assign pat_rise1[1] = 1'b1;
assign pat_fall1[1] = 1'b0;
assign pat_rise2[1] = 1'b0;
assign pat_fall2[1] = 1'b1;
assign pat_rise3[1] = 1'b0;
assign pat_fall3[1] = 1'b1;
assign pat_rise0[0] = 1'b1;
assign pat_fall0[0] = 1'b0;
assign pat_rise1[0] = 1'b0;
assign pat_fall1[0] = 1'b1;
assign pat_rise2[0] = 1'b1;
assign pat_fall2[0] = 1'b0;
assign pat_rise3[0] = 1'b1;
assign pat_fall3[0] = 1'b0;
// Pattern to distinguish between early write and incorrect read
// BB11EE4444EEDD88
assign early_rise0[3] = 1'b1;
assign early_fall0[3] = 1'b0;
assign early_rise1[3] = 1'b1;
assign early_fall1[3] = 1'b0;
assign early_rise2[3] = 1'b0;
assign early_fall2[3] = 1'b1;
assign early_rise3[3] = 1'b1;
assign early_fall3[3] = 1'b1;
assign early_rise0[2] = 1'b0;
assign early_fall0[2] = 1'b0;
assign early_rise1[2] = 1'b1;
assign early_fall1[2] = 1'b1;
assign early_rise2[2] = 1'b1;
assign early_fall2[2] = 1'b1;
assign early_rise3[2] = 1'b1;
assign early_fall3[2] = 1'b0;
assign early_rise0[1] = 1'b1;
assign early_fall0[1] = 1'b0;
assign early_rise1[1] = 1'b1;
assign early_fall1[1] = 1'b0;
assign early_rise2[1] = 1'b0;
assign early_fall2[1] = 1'b1;
assign early_rise3[1] = 1'b0;
assign early_fall3[1] = 1'b0;
assign early_rise0[0] = 1'b1;
assign early_fall0[0] = 1'b1;
assign early_rise1[0] = 1'b0;
assign early_fall1[0] = 1'b0;
assign early_rise2[0] = 1'b0;
assign early_fall2[0] = 1'b0;
assign early_rise3[0] = 1'b1;
assign early_fall3[0] = 1'b0;
end else if (nCK_PER_CLK == 2) begin: gen_pat_div2
// First cycle pattern FF00AA55
assign pat1_rise0[3] = 1'b1;
assign pat1_fall0[3] = 1'b0;
assign pat1_rise1[3] = 1'b1;
assign pat1_fall1[3] = 1'b0;
assign pat1_rise0[2] = 1'b1;
assign pat1_fall0[2] = 1'b0;
assign pat1_rise1[2] = 1'b0;
assign pat1_fall1[2] = 1'b1;
assign pat1_rise0[1] = 1'b1;
assign pat1_fall0[1] = 1'b0;
assign pat1_rise1[1] = 1'b1;
assign pat1_fall1[1] = 1'b0;
assign pat1_rise0[0] = 1'b1;
assign pat1_fall0[0] = 1'b0;
assign pat1_rise1[0] = 1'b0;
assign pat1_fall1[0] = 1'b1;
// Second cycle pattern 55AA9966
assign pat2_rise0[3] = 1'b0;
assign pat2_fall0[3] = 1'b1;
assign pat2_rise1[3] = 1'b1;
assign pat2_fall1[3] = 1'b0;
assign pat2_rise0[2] = 1'b1;
assign pat2_fall0[2] = 1'b0;
assign pat2_rise1[2] = 1'b0;
assign pat2_fall1[2] = 1'b1;
assign pat2_rise0[1] = 1'b0;
assign pat2_fall0[1] = 1'b1;
assign pat2_rise1[1] = 1'b0;
assign pat2_fall1[1] = 1'b1;
assign pat2_rise0[0] = 1'b1;
assign pat2_fall0[0] = 1'b0;
assign pat2_rise1[0] = 1'b1;
assign pat2_fall1[0] = 1'b0;
//Pattern to distinguish between early write and incorrect read
// First cycle pattern AA5555AA
assign early1_rise0[3] = 2'b1;
assign early1_fall0[3] = 2'b0;
assign early1_rise1[3] = 2'b0;
assign early1_fall1[3] = 2'b1;
assign early1_rise0[2] = 2'b0;
assign early1_fall0[2] = 2'b1;
assign early1_rise1[2] = 2'b1;
assign early1_fall1[2] = 2'b0;
assign early1_rise0[1] = 2'b1;
assign early1_fall0[1] = 2'b0;
assign early1_rise1[1] = 2'b0;
assign early1_fall1[1] = 2'b1;
assign early1_rise0[0] = 2'b0;
assign early1_fall0[0] = 2'b1;
assign early1_rise1[0] = 2'b1;
assign early1_fall1[0] = 2'b0;
// Second cycle pattern 9966BB11
assign early2_rise0[3] = 2'b1;
assign early2_fall0[3] = 2'b0;
assign early2_rise1[3] = 2'b1;
assign early2_fall1[3] = 2'b0;
assign early2_rise0[2] = 2'b0;
assign early2_fall0[2] = 2'b1;
assign early2_rise1[2] = 2'b0;
assign early2_fall1[2] = 2'b0;
assign early2_rise0[1] = 2'b0;
assign early2_fall0[1] = 2'b1;
assign early2_rise1[1] = 2'b1;
assign early2_fall1[1] = 2'b0;
assign early2_rise0[0] = 2'b1;
assign early2_fall0[0] = 2'b0;
assign early2_rise1[0] = 2'b1;
assign early2_fall1[0] = 2'b1;
end
endgenerate
// Each bit of each byte is compared to expected pattern.
// This was done to prevent (and "drastically decrease") the chance that
// invalid data clocked in when the DQ bus is tri-state (along with a
// combination of the correct data) will resemble the expected data
// pattern. A better fix for this is to change the training pattern and/or
// make the pattern longer.
generate
genvar pt_i;
if (nCK_PER_CLK == 4) begin: gen_pat_match_div4
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise0[pt_i%4])
pat_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall0[pt_i%4])
pat_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise1[pt_i%4])
pat_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall1[pt_i%4])
pat_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat_rise2[pt_i%4])
pat_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat_fall2[pt_i%4])
pat_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == pat_rise3[pt_i%4])
pat_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == pat_fall3[pt_i%4])
pat_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise1[pt_i%4])
early1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall1[pt_i%4])
early1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise2[pt_i%4])
early1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall2[pt_i%4])
early1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat_rise3[pt_i%4])
early1_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat_fall3[pt_i%4])
early1_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == early_rise0[pt_i%4])
early1_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == early_fall0[pt_i%4])
early1_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise2[pt_i%4])
early2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall2[pt_i%4])
early2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise3[pt_i%4])
early2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall3[pt_i%4])
early2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == early_rise0[pt_i%4])
early2_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == early_fall0[pt_i%4])
early2_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == early_rise1[pt_i%4])
early2_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == early_fall1[pt_i%4])
early2_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
end
always @(posedge clk) begin
pat_match_rise0_and_r <= #TCQ &pat_match_rise0_r;
pat_match_fall0_and_r <= #TCQ &pat_match_fall0_r;
pat_match_rise1_and_r <= #TCQ &pat_match_rise1_r;
pat_match_fall1_and_r <= #TCQ &pat_match_fall1_r;
pat_match_rise2_and_r <= #TCQ &pat_match_rise2_r;
pat_match_fall2_and_r <= #TCQ &pat_match_fall2_r;
pat_match_rise3_and_r <= #TCQ &pat_match_rise3_r;
pat_match_fall3_and_r <= #TCQ &pat_match_fall3_r;
pat_data_match_r <= #TCQ (pat_match_rise0_and_r &&
pat_match_fall0_and_r &&
pat_match_rise1_and_r &&
pat_match_fall1_and_r &&
pat_match_rise2_and_r &&
pat_match_fall2_and_r &&
pat_match_rise3_and_r &&
pat_match_fall3_and_r);
pat_data_match_valid_r <= #TCQ rd_active_r3;
end
always @(posedge clk) begin
early1_match_rise0_and_r <= #TCQ &early1_match_rise0_r;
early1_match_fall0_and_r <= #TCQ &early1_match_fall0_r;
early1_match_rise1_and_r <= #TCQ &early1_match_rise1_r;
early1_match_fall1_and_r <= #TCQ &early1_match_fall1_r;
early1_match_rise2_and_r <= #TCQ &early1_match_rise2_r;
early1_match_fall2_and_r <= #TCQ &early1_match_fall2_r;
early1_match_rise3_and_r <= #TCQ &early1_match_rise3_r;
early1_match_fall3_and_r <= #TCQ &early1_match_fall3_r;
early1_data_match_r <= #TCQ (early1_match_rise0_and_r &&
early1_match_fall0_and_r &&
early1_match_rise1_and_r &&
early1_match_fall1_and_r &&
early1_match_rise2_and_r &&
early1_match_fall2_and_r &&
early1_match_rise3_and_r &&
early1_match_fall3_and_r);
end
always @(posedge clk) begin
early2_match_rise0_and_r <= #TCQ &early2_match_rise0_r;
early2_match_fall0_and_r <= #TCQ &early2_match_fall0_r;
early2_match_rise1_and_r <= #TCQ &early2_match_rise1_r;
early2_match_fall1_and_r <= #TCQ &early2_match_fall1_r;
early2_match_rise2_and_r <= #TCQ &early2_match_rise2_r;
early2_match_fall2_and_r <= #TCQ &early2_match_fall2_r;
early2_match_rise3_and_r <= #TCQ &early2_match_rise3_r;
early2_match_fall3_and_r <= #TCQ &early2_match_fall3_r;
early2_data_match_r <= #TCQ (early2_match_rise0_and_r &&
early2_match_fall0_and_r &&
early2_match_rise1_and_r &&
early2_match_fall1_and_r &&
early2_match_rise2_and_r &&
early2_match_fall2_and_r &&
early2_match_rise3_and_r &&
early2_match_fall3_and_r);
end
end else if (nCK_PER_CLK == 2) begin: gen_pat_match_div2
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat1_rise0[pt_i%4])
pat1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat1_fall0[pt_i%4])
pat1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat1_rise1[pt_i%4])
pat1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat1_fall1[pt_i%4])
pat1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat2_rise0[pt_i%4])
pat2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat2_fall0[pt_i%4])
pat2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat2_rise1[pt_i%4])
pat2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat2_fall1[pt_i%4])
pat2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == early1_rise0[pt_i%4])
early1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == early1_fall0[pt_i%4])
early1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == early1_rise1[pt_i%4])
early1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == early1_fall1[pt_i%4])
early1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
// early2 in this case does not mean 2 cycles early but
// the second cycle of read data in 2:1 mode
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == early2_rise0[pt_i%4])
early2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == early2_fall0[pt_i%4])
early2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == early2_rise1[pt_i%4])
early2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == early2_fall1[pt_i%4])
early2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
end
always @(posedge clk) begin
pat1_match_rise0_and_r <= #TCQ &pat1_match_rise0_r;
pat1_match_fall0_and_r <= #TCQ &pat1_match_fall0_r;
pat1_match_rise1_and_r <= #TCQ &pat1_match_rise1_r;
pat1_match_fall1_and_r <= #TCQ &pat1_match_fall1_r;
pat1_data_match_r <= #TCQ (pat1_match_rise0_and_r &&
pat1_match_fall0_and_r &&
pat1_match_rise1_and_r &&
pat1_match_fall1_and_r);
pat1_data_match_r1 <= #TCQ pat1_data_match_r;
pat2_match_rise0_and_r <= #TCQ &pat2_match_rise0_r && rd_active_r3;
pat2_match_fall0_and_r <= #TCQ &pat2_match_fall0_r && rd_active_r3;
pat2_match_rise1_and_r <= #TCQ &pat2_match_rise1_r && rd_active_r3;
pat2_match_fall1_and_r <= #TCQ &pat2_match_fall1_r && rd_active_r3;
pat2_data_match_r <= #TCQ (pat2_match_rise0_and_r &&
pat2_match_fall0_and_r &&
pat2_match_rise1_and_r &&
pat2_match_fall1_and_r);
// For 2:1 mode, read valid is asserted for 2 clock cycles -
// here we generate a "match valid" pulse that is only 1 clock
// cycle wide that is simulatenous when the match calculation
// is complete
pat_data_match_valid_r <= #TCQ rd_active_r4 & ~rd_active_r5;
end
always @(posedge clk) begin
early1_match_rise0_and_r <= #TCQ &early1_match_rise0_r;
early1_match_fall0_and_r <= #TCQ &early1_match_fall0_r;
early1_match_rise1_and_r <= #TCQ &early1_match_rise1_r;
early1_match_fall1_and_r <= #TCQ &early1_match_fall1_r;
early1_data_match_r <= #TCQ (early1_match_rise0_and_r &&
early1_match_fall0_and_r &&
early1_match_rise1_and_r &&
early1_match_fall1_and_r);
early1_data_match_r1 <= #TCQ early1_data_match_r;
early2_match_rise0_and_r <= #TCQ &early2_match_rise0_r && rd_active_r3;
early2_match_fall0_and_r <= #TCQ &early2_match_fall0_r && rd_active_r3;
early2_match_rise1_and_r <= #TCQ &early2_match_rise1_r && rd_active_r3;
early2_match_fall1_and_r <= #TCQ &early2_match_fall1_r && rd_active_r3;
early2_data_match_r <= #TCQ (early2_match_rise0_and_r &&
early2_match_fall0_and_r &&
early2_match_rise1_and_r &&
early2_match_fall1_and_r);
end
end
endgenerate
// Need to delay it by 3 cycles in order to wait for Phaser_Out
// coarse delay to take effect before issuing a write command
always @(posedge clk) begin
wrcal_pat_resume_r1 <= #TCQ wrcal_pat_resume_r;
wrcal_pat_resume_r2 <= #TCQ wrcal_pat_resume_r1;
wrcal_pat_resume <= #TCQ wrcal_pat_resume_r2;
end
always @(posedge clk) begin
if (rst)
tap_inc_wait_cnt <= #TCQ 'd0;
else if ((cal2_state_r == CAL2_DQ_IDEL_DEC) ||
(cal2_state_r == CAL2_IFIFO_RESET) ||
(cal2_state_r == CAL2_SANITY_WAIT))
tap_inc_wait_cnt <= #TCQ tap_inc_wait_cnt + 1;
else
tap_inc_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk) begin
if (rst)
not_empty_wait_cnt <= #TCQ 'd0;
else if ((cal2_state_r == CAL2_READ_WAIT) && wrcal_rd_wait)
not_empty_wait_cnt <= #TCQ not_empty_wait_cnt + 1;
else
not_empty_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk)
cal2_state_r1 <= #TCQ cal2_state_r;
//*****************************************************************
// Write Calibration state machine
//*****************************************************************
// when calibrating, check to see if the expected pattern is received.
// Otherwise delay DQS to align to correct CK edge.
// NOTES:
// 1. An error condition can occur due to two reasons:
// a. If the matching logic does not receive the expected data
// pattern. However, the error may be "recoverable" because
// the write calibration is still in progress. If an error is
// found the write calibration logic delays DQS by an additional
// clock cycle and restarts the pattern detection process.
// By design, if the write path timing is incorrect, the correct
// data pattern will never be detected.
// b. Valid data not found even after incrementing Phaser_Out
// coarse delay line.
always @(posedge clk) begin
if (rst) begin
wrcal_dqs_cnt_r <= #TCQ 'b0;
cal2_done_r <= #TCQ 1'b0;
cal2_prech_req_r <= #TCQ 1'b0;
cal2_state_r <= #TCQ CAL2_IDLE;
wrcal_pat_err <= #TCQ 1'b0;
wrcal_pat_resume_r <= #TCQ 1'b0;
wrcal_act_req <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
temp_wrcal_done <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b0;
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b0;
idelay_ld <= #TCQ 1'b0;
idelay_ld_done <= #TCQ 1'b0;
pat1_detect <= #TCQ 1'b0;
early1_detect <= #TCQ 1'b0;
wrcal_sanity_chk_done <= #TCQ 1'b0;
wrcal_sanity_chk_err <= #TCQ 1'b0;
end else begin
cal2_prech_req_r <= #TCQ 1'b0;
case (cal2_state_r)
CAL2_IDLE: begin
wrcal_pat_err <= #TCQ 1'b0;
if (wrcal_start) begin
cal2_if_reset <= #TCQ 1'b0;
if (SIM_CAL_OPTION == "SKIP_CAL")
// If skip write calibration, then proceed to end.
cal2_state_r <= #TCQ CAL2_DONE;
else
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end
end
// General wait state to wait for read data to be output by the
// IN_FIFO
CAL2_READ_WAIT: begin
wrcal_pat_resume_r <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
// Wait until read data is received, and pattern matching
// calculation is complete. NOTE: Need to add a timeout here
// in case for some reason data is never received (or rather
// the PHASER_IN and IN_FIFO think they never receives data)
if (pat_data_match_valid_r && (nCK_PER_CLK == 4)) begin
if (pat_data_match_r)
// If found data match, then move on to next DQS group
cal2_state_r <= #TCQ CAL2_NEXT_DQS;
else begin
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_ERR;
// If writes are one or two cycles early then redo
// write leveling for the byte
else if (early1_data_match_r) begin
early1_data <= #TCQ 1'b1;
early2_data <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
end else if (early2_data_match_r) begin
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b1;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
// Read late due to incorrect MPR idelay value
// Decrement Idelay to '0'for the current byte
end else if (~idelay_ld_done) begin
cal2_state_r <= #TCQ CAL2_DQ_IDEL_DEC;
idelay_ld <= #TCQ 1'b1;
end else
cal2_state_r <= #TCQ CAL2_ERR;
end
end else if (pat_data_match_valid_r && (nCK_PER_CLK == 2)) begin
if ((pat1_data_match_r1 && pat2_data_match_r) ||
(pat1_detect && pat2_data_match_r))
// If found data match, then move on to next DQS group
cal2_state_r <= #TCQ CAL2_NEXT_DQS;
else if (pat1_data_match_r1 && ~pat2_data_match_r) begin
cal2_state_r <= #TCQ CAL2_READ_WAIT;
pat1_detect <= #TCQ 1'b1;
end else begin
// If writes are one or two cycles early then redo
// write leveling for the byte
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_ERR;
else if ((early1_data_match_r1 && early2_data_match_r) ||
(early1_detect && early2_data_match_r)) begin
early1_data <= #TCQ 1'b1;
early2_data <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
end else if (early1_data_match_r1 && ~early2_data_match_r) begin
early1_detect <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
// Read late due to incorrect MPR idelay value
// Decrement Idelay to '0'for the current byte
end else if (~idelay_ld_done) begin
cal2_state_r <= #TCQ CAL2_DQ_IDEL_DEC;
idelay_ld <= #TCQ 1'b1;
end else
cal2_state_r <= #TCQ CAL2_ERR;
end
end else if (not_empty_wait_cnt == 'd31)
cal2_state_r <= #TCQ CAL2_ERR;
end
CAL2_WRLVL_WAIT: begin
early1_detect <= #TCQ 1'b0;
if (wrlvl_byte_done && ~wrlvl_byte_done_r)
wrlvl_byte_redo <= #TCQ 1'b0;
if (wrlvl_byte_done) begin
if (rd_active_r1 && ~rd_active_r) begin
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
cal2_if_reset <= #TCQ 1'b1;
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b0;
end
end
end
CAL2_DQ_IDEL_DEC: begin
if (tap_inc_wait_cnt == 'd4) begin
idelay_ld <= #TCQ 1'b0;
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
cal2_if_reset <= #TCQ 1'b1;
idelay_ld_done <= #TCQ 1'b1;
end
end
CAL2_IFIFO_RESET: begin
if (tap_inc_wait_cnt == 'd15) begin
cal2_if_reset <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_DONE;
else if (idelay_ld_done) begin
wrcal_pat_resume_r <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end else
cal2_state_r <= #TCQ CAL2_IDLE;
end
end
// Final processing for current DQS group. Move on to next group
CAL2_NEXT_DQS: begin
// At this point, we've just found the correct pattern for the
// current DQS group.
// Request bank/row precharge, and wait for its completion. Always
// precharge after each DQS group to avoid tRAS(max) violation
//verilint STARC-2.2.3.3 off
if (wrcal_sanity_chk_r && (wrcal_dqs_cnt_r != DQS_WIDTH-1)) begin
cal2_prech_req_r <= #TCQ 1'b0;
wrcal_dqs_cnt_r <= #TCQ wrcal_dqs_cnt_r + 1;
cal2_state_r <= #TCQ CAL2_SANITY_WAIT;
end else
cal2_prech_req_r <= #TCQ 1'b1;
idelay_ld_done <= #TCQ 1'b0;
pat1_detect <= #TCQ 1'b0;
if (prech_done)
if (((DQS_WIDTH == 1) || (SIM_CAL_OPTION == "FAST_CAL")) ||
(wrcal_dqs_cnt_r == DQS_WIDTH-1)) begin
// If either FAST_CAL is enabled and first DQS group is
// finished, or if the last DQS group was just finished,
// then end of write calibration
if (wrcal_sanity_chk_r) begin
cal2_if_reset <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
end else
cal2_state_r <= #TCQ CAL2_DONE;
end else begin
// Continue to next DQS group
wrcal_dqs_cnt_r <= #TCQ wrcal_dqs_cnt_r + 1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end
end
//verilint STARC-2.2.3.3 on
CAL2_SANITY_WAIT: begin
if (tap_inc_wait_cnt == 'd15) begin
cal2_state_r <= #TCQ CAL2_READ_WAIT;
wrcal_pat_resume_r <= #TCQ 1'b1;
end
end
// Finished with read enable calibration
CAL2_DONE: begin
if (wrcal_sanity_chk && ~wrcal_sanity_chk_r) begin
cal2_done_r <= #TCQ 1'b0;
wrcal_dqs_cnt_r <= #TCQ 'd0;
cal2_state_r <= #TCQ CAL2_IDLE;
end else
cal2_done_r <= #TCQ 1'b1;
cal2_prech_req_r <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
wrcal_sanity_chk_done <= #TCQ 1'b1;
end
// Assert error signal indicating that writes timing is incorrect
CAL2_ERR: begin
wrcal_pat_resume_r <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
wrcal_sanity_chk_err <= #TCQ 1'b1;
else
wrcal_pat_err <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_ERR;
end
endcase
end
end
// Delay assertion of wrcal_done for write calibration by a few cycles after
// we've reached CAL2_DONE
always @(posedge clk)
if (rst)
cal2_done_r1 <= #TCQ 1'b0;
else
cal2_done_r1 <= #TCQ cal2_done_r;
always @(posedge clk)
if (rst || (wrcal_sanity_chk && ~wrcal_sanity_chk_r))
wrcal_done <= #TCQ 1'b0;
else if (cal2_done_r)
wrcal_done <= #TCQ 1'b1;
endmodule
|
module mig_7series_v2_3_ddr_phy_wrcal #
(
parameter TCQ = 100, // clk->out delay (sim only)
parameter nCK_PER_CLK = 2, // # of memory clocks per CLK
parameter CLK_PERIOD = 2500,
parameter DQ_WIDTH = 64, // # of DQ (data)
parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH))
parameter DQS_WIDTH = 8, // # of DQS (strobe)
parameter DRAM_WIDTH = 8, // # of DQ per DQS
parameter PRE_REV3ES = "OFF", // Delay O/Ps using Phaser_Out fine dly
parameter SIM_CAL_OPTION = "NONE" // Skip various calibration steps
)
(
input clk,
input rst,
// Calibration status, control signals
input wrcal_start,
input wrcal_rd_wait,
input wrcal_sanity_chk,
input dqsfound_retry_done,
input phy_rddata_en,
output dqsfound_retry,
output wrcal_read_req,
output reg wrcal_act_req,
output reg wrcal_done,
output reg wrcal_pat_err,
output reg wrcal_prech_req,
output reg temp_wrcal_done,
output reg wrcal_sanity_chk_done,
input prech_done,
// Captured data in resync clock domain
input [2*nCK_PER_CLK*DQ_WIDTH-1:0] rd_data,
// Write level values of Phaser_Out coarse and fine
// delay taps required to load Phaser_Out register
input [3*DQS_WIDTH-1:0] wl_po_coarse_cnt,
input [6*DQS_WIDTH-1:0] wl_po_fine_cnt,
input wrlvl_byte_done,
output reg wrlvl_byte_redo,
output reg early1_data,
output reg early2_data,
// DQ IDELAY
output reg idelay_ld,
output reg wrcal_pat_resume, // to phy_init for write
output reg [DQS_CNT_WIDTH:0] po_stg2_wrcal_cnt,
output phy_if_reset,
// Debug Port
output [6*DQS_WIDTH-1:0] dbg_final_po_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_final_po_coarse_tap_cnt,
output [99:0] dbg_phy_wrcal
);
// Length of calibration sequence (in # of words)
//localparam CAL_PAT_LEN = 8;
// Read data shift register length
localparam RD_SHIFT_LEN = 1; //(nCK_PER_CLK == 4) ? 1 : 2;
// # of reads for reliable read capture
localparam NUM_READS = 2;
// # of cycles to wait after changing RDEN count value
localparam RDEN_WAIT_CNT = 12;
localparam COARSE_CNT = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 3 : 6;
localparam FINE_CNT = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 22 : 44;
localparam CAL2_IDLE = 4'h0;
localparam CAL2_READ_WAIT = 4'h1;
localparam CAL2_NEXT_DQS = 4'h2;
localparam CAL2_WRLVL_WAIT = 4'h3;
localparam CAL2_IFIFO_RESET = 4'h4;
localparam CAL2_DQ_IDEL_DEC = 4'h5;
localparam CAL2_DONE = 4'h6;
localparam CAL2_SANITY_WAIT = 4'h7;
localparam CAL2_ERR = 4'h8;
integer i,j,k,l,m,p,q,d;
reg [2:0] po_coarse_tap_cnt [0:DQS_WIDTH-1];
reg [3*DQS_WIDTH-1:0] po_coarse_tap_cnt_w;
reg [5:0] po_fine_tap_cnt [0:DQS_WIDTH-1];
reg [6*DQS_WIDTH-1:0] po_fine_tap_cnt_w;
reg [DQS_CNT_WIDTH:0] wrcal_dqs_cnt_r/* synthesis syn_maxfan = 10 */;
reg [4:0] not_empty_wait_cnt;
reg [3:0] tap_inc_wait_cnt;
reg cal2_done_r;
reg cal2_done_r1;
reg cal2_prech_req_r;
reg [3:0] cal2_state_r;
reg [3:0] cal2_state_r1;
reg [2:0] wl_po_coarse_cnt_w [0:DQS_WIDTH-1];
reg [5:0] wl_po_fine_cnt_w [0:DQS_WIDTH-1];
reg cal2_if_reset;
reg wrcal_pat_resume_r;
reg wrcal_pat_resume_r1;
reg wrcal_pat_resume_r2;
reg wrcal_pat_resume_r3;
reg [DRAM_WIDTH-1:0] mux_rd_fall0_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall1_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise0_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise1_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall2_r;
reg [DRAM_WIDTH-1:0] mux_rd_fall3_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise2_r;
reg [DRAM_WIDTH-1:0] mux_rd_rise3_r;
reg pat_data_match_r;
reg pat1_data_match_r;
reg pat1_data_match_r1;
reg pat2_data_match_r;
reg pat_data_match_valid_r;
wire [RD_SHIFT_LEN-1:0] pat_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall2 [3:0];
wire [RD_SHIFT_LEN-1:0] early_fall3 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_fall1 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_fall0 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_fall1 [3:0];
reg [DRAM_WIDTH-1:0] pat_match_fall0_r;
reg pat_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall1_r;
reg pat_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall2_r;
reg pat_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] pat_match_fall3_r;
reg pat_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise0_r;
reg pat_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise1_r;
reg pat_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise2_r;
reg pat_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] pat_match_rise3_r;
reg pat_match_rise3_and_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise0_r;
reg [DRAM_WIDTH-1:0] pat1_match_rise1_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall0_r;
reg [DRAM_WIDTH-1:0] pat1_match_fall1_r;
reg [DRAM_WIDTH-1:0] pat2_match_rise0_r;
reg [DRAM_WIDTH-1:0] pat2_match_rise1_r;
reg [DRAM_WIDTH-1:0] pat2_match_fall0_r;
reg [DRAM_WIDTH-1:0] pat2_match_fall1_r;
reg pat1_match_rise0_and_r;
reg pat1_match_rise1_and_r;
reg pat1_match_fall0_and_r;
reg pat1_match_fall1_and_r;
reg pat2_match_rise0_and_r;
reg pat2_match_rise1_and_r;
reg pat2_match_fall0_and_r;
reg pat2_match_fall1_and_r;
reg early1_data_match_r;
reg early1_data_match_r1;
reg [DRAM_WIDTH-1:0] early1_match_fall0_r;
reg early1_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall1_r;
reg early1_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall2_r;
reg early1_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] early1_match_fall3_r;
reg early1_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise0_r;
reg early1_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise1_r;
reg early1_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise2_r;
reg early1_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] early1_match_rise3_r;
reg early1_match_rise3_and_r;
reg early2_data_match_r;
reg [DRAM_WIDTH-1:0] early2_match_fall0_r;
reg early2_match_fall0_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall1_r;
reg early2_match_fall1_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall2_r;
reg early2_match_fall2_and_r;
reg [DRAM_WIDTH-1:0] early2_match_fall3_r;
reg early2_match_fall3_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise0_r;
reg early2_match_rise0_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise1_r;
reg early2_match_rise1_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise2_r;
reg early2_match_rise2_and_r;
reg [DRAM_WIDTH-1:0] early2_match_rise3_r;
reg early2_match_rise3_and_r;
wire [RD_SHIFT_LEN-1:0] pat_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] pat_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] pat2_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise2 [3:0];
wire [RD_SHIFT_LEN-1:0] early_rise3 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early1_rise1 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_rise0 [3:0];
wire [RD_SHIFT_LEN-1:0] early2_rise1 [3:0];
wire [DQ_WIDTH-1:0] rd_data_rise0;
wire [DQ_WIDTH-1:0] rd_data_fall0;
wire [DQ_WIDTH-1:0] rd_data_rise1;
wire [DQ_WIDTH-1:0] rd_data_fall1;
wire [DQ_WIDTH-1:0] rd_data_rise2;
wire [DQ_WIDTH-1:0] rd_data_fall2;
wire [DQ_WIDTH-1:0] rd_data_rise3;
wire [DQ_WIDTH-1:0] rd_data_fall3;
reg [DQS_CNT_WIDTH:0] rd_mux_sel_r;
reg rd_active_posedge_r;
reg rd_active_r;
reg rd_active_r1;
reg rd_active_r2;
reg rd_active_r3;
reg rd_active_r4;
reg rd_active_r5;
reg [RD_SHIFT_LEN-1:0] sr_fall0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise0_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise1_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_fall3_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise2_r [DRAM_WIDTH-1:0];
reg [RD_SHIFT_LEN-1:0] sr_rise3_r [DRAM_WIDTH-1:0];
reg wrlvl_byte_done_r;
reg idelay_ld_done;
reg pat1_detect;
reg early1_detect;
reg wrcal_sanity_chk_r;
reg wrcal_sanity_chk_err;
//***************************************************************************
// Debug
//***************************************************************************
always @(*) begin
for (d = 0; d < DQS_WIDTH; d = d + 1) begin
po_fine_tap_cnt_w[(6*d)+:6] = po_fine_tap_cnt[d];
po_coarse_tap_cnt_w[(3*d)+:3] = po_coarse_tap_cnt[d];
end
end
assign dbg_final_po_fine_tap_cnt = po_fine_tap_cnt_w;
assign dbg_final_po_coarse_tap_cnt = po_coarse_tap_cnt_w;
assign dbg_phy_wrcal[0] = pat_data_match_r;
assign dbg_phy_wrcal[4:1] = cal2_state_r1[3:0];
assign dbg_phy_wrcal[5] = wrcal_sanity_chk_err;
assign dbg_phy_wrcal[6] = wrcal_start;
assign dbg_phy_wrcal[7] = wrcal_done;
assign dbg_phy_wrcal[8] = pat_data_match_valid_r;
assign dbg_phy_wrcal[13+:DQS_CNT_WIDTH]= wrcal_dqs_cnt_r;
assign dbg_phy_wrcal[17+:5] = not_empty_wait_cnt;
assign dbg_phy_wrcal[22] = early1_data;
assign dbg_phy_wrcal[23] = early2_data;
assign dbg_phy_wrcal[24+:8] = mux_rd_rise0_r;
assign dbg_phy_wrcal[32+:8] = mux_rd_fall0_r;
assign dbg_phy_wrcal[40+:8] = mux_rd_rise1_r;
assign dbg_phy_wrcal[48+:8] = mux_rd_fall1_r;
assign dbg_phy_wrcal[56+:8] = mux_rd_rise2_r;
assign dbg_phy_wrcal[64+:8] = mux_rd_fall2_r;
assign dbg_phy_wrcal[72+:8] = mux_rd_rise3_r;
assign dbg_phy_wrcal[80+:8] = mux_rd_fall3_r;
assign dbg_phy_wrcal[88] = early1_data_match_r;
assign dbg_phy_wrcal[89] = early2_data_match_r;
assign dbg_phy_wrcal[90] = wrcal_sanity_chk_r & pat_data_match_valid_r;
assign dbg_phy_wrcal[91] = wrcal_sanity_chk_r;
assign dbg_phy_wrcal[92] = wrcal_sanity_chk_done;
assign dqsfound_retry = 1'b0;
assign wrcal_read_req = 1'b0;
assign phy_if_reset = cal2_if_reset;
//**************************************************************************
// DQS count to hard PHY during write calibration using Phaser_OUT Stage2
// coarse delay
//**************************************************************************
always @(posedge clk) begin
po_stg2_wrcal_cnt <= #TCQ wrcal_dqs_cnt_r;
wrlvl_byte_done_r <= #TCQ wrlvl_byte_done;
wrcal_sanity_chk_r <= #TCQ wrcal_sanity_chk;
end
//***************************************************************************
// Data mux to route appropriate byte to calibration logic - i.e. calibration
// is done sequentially, one byte (or DQS group) at a time
//***************************************************************************
generate
if (nCK_PER_CLK == 4) begin: gen_rd_data_div4
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
assign rd_data_rise2 = rd_data[5*DQ_WIDTH-1:4*DQ_WIDTH];
assign rd_data_fall2 = rd_data[6*DQ_WIDTH-1:5*DQ_WIDTH];
assign rd_data_rise3 = rd_data[7*DQ_WIDTH-1:6*DQ_WIDTH];
assign rd_data_fall3 = rd_data[8*DQ_WIDTH-1:7*DQ_WIDTH];
end else if (nCK_PER_CLK == 2) begin: gen_rd_data_div2
assign rd_data_rise0 = rd_data[DQ_WIDTH-1:0];
assign rd_data_fall0 = rd_data[2*DQ_WIDTH-1:DQ_WIDTH];
assign rd_data_rise1 = rd_data[3*DQ_WIDTH-1:2*DQ_WIDTH];
assign rd_data_fall1 = rd_data[4*DQ_WIDTH-1:3*DQ_WIDTH];
end
endgenerate
//**************************************************************************
// Final Phaser OUT coarse and fine delay taps after write calibration
// Sum of taps used during write leveling taps and write calibration
//**************************************************************************
always @(*) begin
for (m = 0; m < DQS_WIDTH; m = m + 1) begin
wl_po_coarse_cnt_w[m] = wl_po_coarse_cnt[3*m+:3];
wl_po_fine_cnt_w[m] = wl_po_fine_cnt[6*m+:6];
end
end
always @(posedge clk) begin
if (rst) begin
for (p = 0; p < DQS_WIDTH; p = p + 1) begin
po_coarse_tap_cnt[p] <= #TCQ {3{1'b0}};
po_fine_tap_cnt[p] <= #TCQ {6{1'b0}};
end
end else if (cal2_done_r && ~cal2_done_r1) begin
for (q = 0; q < DQS_WIDTH; q = q + 1) begin
po_coarse_tap_cnt[q] <= #TCQ wl_po_coarse_cnt_w[i];
po_fine_tap_cnt[q] <= #TCQ wl_po_fine_cnt_w[i];
end
end
end
always @(posedge clk) begin
rd_mux_sel_r <= #TCQ wrcal_dqs_cnt_r;
end
// Register outputs for improved timing.
// NOTE: Will need to change when per-bit DQ deskew is supported.
// Currenly all bits in DQS group are checked in aggregate
generate
genvar mux_i;
if (nCK_PER_CLK == 4) begin: gen_mux_rd_div4
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise2_r[mux_i] <= #TCQ rd_data_rise2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall2_r[mux_i] <= #TCQ rd_data_fall2[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise3_r[mux_i] <= #TCQ rd_data_rise3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall3_r[mux_i] <= #TCQ rd_data_fall3[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_mux_rd_div2
for (mux_i = 0; mux_i < DRAM_WIDTH; mux_i = mux_i + 1) begin: gen_mux_rd
always @(posedge clk) begin
mux_rd_rise0_r[mux_i] <= #TCQ rd_data_rise0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall0_r[mux_i] <= #TCQ rd_data_fall0[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_rise1_r[mux_i] <= #TCQ rd_data_rise1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
mux_rd_fall1_r[mux_i] <= #TCQ rd_data_fall1[DRAM_WIDTH*rd_mux_sel_r + mux_i];
end
end
end
endgenerate
//***************************************************************************
// generate request to PHY_INIT logic to issue precharged. Required when
// calibration can take a long time (during which there are only constant
// reads present on this bus). In this case need to issue perioidic
// precharges to avoid tRAS violation. This signal must meet the following
// requirements: (1) only transition from 0->1 when prech is first needed,
// (2) stay at 1 and only transition 1->0 when RDLVL_PRECH_DONE asserted
//***************************************************************************
always @(posedge clk)
if (rst)
wrcal_prech_req <= #TCQ 1'b0;
else
// Combine requests from all stages here
wrcal_prech_req <= #TCQ cal2_prech_req_r;
//***************************************************************************
// Shift register to store last RDDATA_SHIFT_LEN cycles of data from ISERDES
// NOTE: Written using discrete flops, but SRL can be used if the matching
// logic does the comparison sequentially, rather than parallel
//***************************************************************************
generate
genvar rd_i;
if (nCK_PER_CLK == 4) begin: gen_sr_div4
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
sr_rise0_r[rd_i] <= #TCQ mux_rd_rise0_r[rd_i];
sr_fall0_r[rd_i] <= #TCQ mux_rd_fall0_r[rd_i];
sr_rise1_r[rd_i] <= #TCQ mux_rd_rise1_r[rd_i];
sr_fall1_r[rd_i] <= #TCQ mux_rd_fall1_r[rd_i];
sr_rise2_r[rd_i] <= #TCQ mux_rd_rise2_r[rd_i];
sr_fall2_r[rd_i] <= #TCQ mux_rd_fall2_r[rd_i];
sr_rise3_r[rd_i] <= #TCQ mux_rd_rise3_r[rd_i];
sr_fall3_r[rd_i] <= #TCQ mux_rd_fall3_r[rd_i];
end
end
end else if (nCK_PER_CLK == 2) begin: gen_sr_div2
for (rd_i = 0; rd_i < DRAM_WIDTH; rd_i = rd_i + 1) begin: gen_sr
always @(posedge clk) begin
sr_rise0_r[rd_i] <= #TCQ mux_rd_rise0_r[rd_i];
sr_fall0_r[rd_i] <= #TCQ mux_rd_fall0_r[rd_i];
sr_rise1_r[rd_i] <= #TCQ mux_rd_rise1_r[rd_i];
sr_fall1_r[rd_i] <= #TCQ mux_rd_fall1_r[rd_i];
end
end
end
endgenerate
//***************************************************************************
// Write calibration:
// During write leveling DQS is aligned to the nearest CK edge that may not
// be the correct CK edge. Write calibration is required to align the DQS to
// the correct CK edge that clocks the write command.
// The Phaser_Out coarse delay line is adjusted if required to add a memory
// clock cycle of delay in order to read back the expected pattern.
//***************************************************************************
always @(posedge clk) begin
rd_active_r <= #TCQ phy_rddata_en;
rd_active_r1 <= #TCQ rd_active_r;
rd_active_r2 <= #TCQ rd_active_r1;
rd_active_r3 <= #TCQ rd_active_r2;
rd_active_r4 <= #TCQ rd_active_r3;
rd_active_r5 <= #TCQ rd_active_r4;
end
//*****************************************************************
// Expected data pattern when properly received by read capture
// logic:
// Based on pattern of ({rise,fall}) =
// 0xF, 0x0, 0xA, 0x5, 0x5, 0xA, 0x9, 0x6
// Each nibble will look like:
// bit3: 1, 0, 1, 0, 0, 1, 1, 0
// bit2: 1, 0, 0, 1, 1, 0, 0, 1
// bit1: 1, 0, 1, 0, 0, 1, 0, 1
// bit0: 1, 0, 0, 1, 1, 0, 1, 0
// Change the hard-coded pattern below accordingly as RD_SHIFT_LEN
// and the actual training pattern contents change
//*****************************************************************
generate
if (nCK_PER_CLK == 4) begin: gen_pat_div4
// FF00AA5555AA9966
assign pat_rise0[3] = 1'b1;
assign pat_fall0[3] = 1'b0;
assign pat_rise1[3] = 1'b1;
assign pat_fall1[3] = 1'b0;
assign pat_rise2[3] = 1'b0;
assign pat_fall2[3] = 1'b1;
assign pat_rise3[3] = 1'b1;
assign pat_fall3[3] = 1'b0;
assign pat_rise0[2] = 1'b1;
assign pat_fall0[2] = 1'b0;
assign pat_rise1[2] = 1'b0;
assign pat_fall1[2] = 1'b1;
assign pat_rise2[2] = 1'b1;
assign pat_fall2[2] = 1'b0;
assign pat_rise3[2] = 1'b0;
assign pat_fall3[2] = 1'b1;
assign pat_rise0[1] = 1'b1;
assign pat_fall0[1] = 1'b0;
assign pat_rise1[1] = 1'b1;
assign pat_fall1[1] = 1'b0;
assign pat_rise2[1] = 1'b0;
assign pat_fall2[1] = 1'b1;
assign pat_rise3[1] = 1'b0;
assign pat_fall3[1] = 1'b1;
assign pat_rise0[0] = 1'b1;
assign pat_fall0[0] = 1'b0;
assign pat_rise1[0] = 1'b0;
assign pat_fall1[0] = 1'b1;
assign pat_rise2[0] = 1'b1;
assign pat_fall2[0] = 1'b0;
assign pat_rise3[0] = 1'b1;
assign pat_fall3[0] = 1'b0;
// Pattern to distinguish between early write and incorrect read
// BB11EE4444EEDD88
assign early_rise0[3] = 1'b1;
assign early_fall0[3] = 1'b0;
assign early_rise1[3] = 1'b1;
assign early_fall1[3] = 1'b0;
assign early_rise2[3] = 1'b0;
assign early_fall2[3] = 1'b1;
assign early_rise3[3] = 1'b1;
assign early_fall3[3] = 1'b1;
assign early_rise0[2] = 1'b0;
assign early_fall0[2] = 1'b0;
assign early_rise1[2] = 1'b1;
assign early_fall1[2] = 1'b1;
assign early_rise2[2] = 1'b1;
assign early_fall2[2] = 1'b1;
assign early_rise3[2] = 1'b1;
assign early_fall3[2] = 1'b0;
assign early_rise0[1] = 1'b1;
assign early_fall0[1] = 1'b0;
assign early_rise1[1] = 1'b1;
assign early_fall1[1] = 1'b0;
assign early_rise2[1] = 1'b0;
assign early_fall2[1] = 1'b1;
assign early_rise3[1] = 1'b0;
assign early_fall3[1] = 1'b0;
assign early_rise0[0] = 1'b1;
assign early_fall0[0] = 1'b1;
assign early_rise1[0] = 1'b0;
assign early_fall1[0] = 1'b0;
assign early_rise2[0] = 1'b0;
assign early_fall2[0] = 1'b0;
assign early_rise3[0] = 1'b1;
assign early_fall3[0] = 1'b0;
end else if (nCK_PER_CLK == 2) begin: gen_pat_div2
// First cycle pattern FF00AA55
assign pat1_rise0[3] = 1'b1;
assign pat1_fall0[3] = 1'b0;
assign pat1_rise1[3] = 1'b1;
assign pat1_fall1[3] = 1'b0;
assign pat1_rise0[2] = 1'b1;
assign pat1_fall0[2] = 1'b0;
assign pat1_rise1[2] = 1'b0;
assign pat1_fall1[2] = 1'b1;
assign pat1_rise0[1] = 1'b1;
assign pat1_fall0[1] = 1'b0;
assign pat1_rise1[1] = 1'b1;
assign pat1_fall1[1] = 1'b0;
assign pat1_rise0[0] = 1'b1;
assign pat1_fall0[0] = 1'b0;
assign pat1_rise1[0] = 1'b0;
assign pat1_fall1[0] = 1'b1;
// Second cycle pattern 55AA9966
assign pat2_rise0[3] = 1'b0;
assign pat2_fall0[3] = 1'b1;
assign pat2_rise1[3] = 1'b1;
assign pat2_fall1[3] = 1'b0;
assign pat2_rise0[2] = 1'b1;
assign pat2_fall0[2] = 1'b0;
assign pat2_rise1[2] = 1'b0;
assign pat2_fall1[2] = 1'b1;
assign pat2_rise0[1] = 1'b0;
assign pat2_fall0[1] = 1'b1;
assign pat2_rise1[1] = 1'b0;
assign pat2_fall1[1] = 1'b1;
assign pat2_rise0[0] = 1'b1;
assign pat2_fall0[0] = 1'b0;
assign pat2_rise1[0] = 1'b1;
assign pat2_fall1[0] = 1'b0;
//Pattern to distinguish between early write and incorrect read
// First cycle pattern AA5555AA
assign early1_rise0[3] = 2'b1;
assign early1_fall0[3] = 2'b0;
assign early1_rise1[3] = 2'b0;
assign early1_fall1[3] = 2'b1;
assign early1_rise0[2] = 2'b0;
assign early1_fall0[2] = 2'b1;
assign early1_rise1[2] = 2'b1;
assign early1_fall1[2] = 2'b0;
assign early1_rise0[1] = 2'b1;
assign early1_fall0[1] = 2'b0;
assign early1_rise1[1] = 2'b0;
assign early1_fall1[1] = 2'b1;
assign early1_rise0[0] = 2'b0;
assign early1_fall0[0] = 2'b1;
assign early1_rise1[0] = 2'b1;
assign early1_fall1[0] = 2'b0;
// Second cycle pattern 9966BB11
assign early2_rise0[3] = 2'b1;
assign early2_fall0[3] = 2'b0;
assign early2_rise1[3] = 2'b1;
assign early2_fall1[3] = 2'b0;
assign early2_rise0[2] = 2'b0;
assign early2_fall0[2] = 2'b1;
assign early2_rise1[2] = 2'b0;
assign early2_fall1[2] = 2'b0;
assign early2_rise0[1] = 2'b0;
assign early2_fall0[1] = 2'b1;
assign early2_rise1[1] = 2'b1;
assign early2_fall1[1] = 2'b0;
assign early2_rise0[0] = 2'b1;
assign early2_fall0[0] = 2'b0;
assign early2_rise1[0] = 2'b1;
assign early2_fall1[0] = 2'b1;
end
endgenerate
// Each bit of each byte is compared to expected pattern.
// This was done to prevent (and "drastically decrease") the chance that
// invalid data clocked in when the DQ bus is tri-state (along with a
// combination of the correct data) will resemble the expected data
// pattern. A better fix for this is to change the training pattern and/or
// make the pattern longer.
generate
genvar pt_i;
if (nCK_PER_CLK == 4) begin: gen_pat_match_div4
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise0[pt_i%4])
pat_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall0[pt_i%4])
pat_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise1[pt_i%4])
pat_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall1[pt_i%4])
pat_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat_rise2[pt_i%4])
pat_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat_fall2[pt_i%4])
pat_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == pat_rise3[pt_i%4])
pat_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
pat_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == pat_fall3[pt_i%4])
pat_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
pat_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise1[pt_i%4])
early1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall1[pt_i%4])
early1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise2[pt_i%4])
early1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall2[pt_i%4])
early1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == pat_rise3[pt_i%4])
early1_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == pat_fall3[pt_i%4])
early1_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == early_rise0[pt_i%4])
early1_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == early_fall0[pt_i%4])
early1_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat_rise2[pt_i%4])
early2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat_fall2[pt_i%4])
early2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat_rise3[pt_i%4])
early2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat_fall3[pt_i%4])
early2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall1_r[pt_i] <= #TCQ 1'b0;
if (sr_rise2_r[pt_i] == early_rise0[pt_i%4])
early2_match_rise2_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise2_r[pt_i] <= #TCQ 1'b0;
if (sr_fall2_r[pt_i] == early_fall0[pt_i%4])
early2_match_fall2_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall2_r[pt_i] <= #TCQ 1'b0;
if (sr_rise3_r[pt_i] == early_rise1[pt_i%4])
early2_match_rise3_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise3_r[pt_i] <= #TCQ 1'b0;
if (sr_fall3_r[pt_i] == early_fall1[pt_i%4])
early2_match_fall3_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall3_r[pt_i] <= #TCQ 1'b0;
end
end
always @(posedge clk) begin
pat_match_rise0_and_r <= #TCQ &pat_match_rise0_r;
pat_match_fall0_and_r <= #TCQ &pat_match_fall0_r;
pat_match_rise1_and_r <= #TCQ &pat_match_rise1_r;
pat_match_fall1_and_r <= #TCQ &pat_match_fall1_r;
pat_match_rise2_and_r <= #TCQ &pat_match_rise2_r;
pat_match_fall2_and_r <= #TCQ &pat_match_fall2_r;
pat_match_rise3_and_r <= #TCQ &pat_match_rise3_r;
pat_match_fall3_and_r <= #TCQ &pat_match_fall3_r;
pat_data_match_r <= #TCQ (pat_match_rise0_and_r &&
pat_match_fall0_and_r &&
pat_match_rise1_and_r &&
pat_match_fall1_and_r &&
pat_match_rise2_and_r &&
pat_match_fall2_and_r &&
pat_match_rise3_and_r &&
pat_match_fall3_and_r);
pat_data_match_valid_r <= #TCQ rd_active_r3;
end
always @(posedge clk) begin
early1_match_rise0_and_r <= #TCQ &early1_match_rise0_r;
early1_match_fall0_and_r <= #TCQ &early1_match_fall0_r;
early1_match_rise1_and_r <= #TCQ &early1_match_rise1_r;
early1_match_fall1_and_r <= #TCQ &early1_match_fall1_r;
early1_match_rise2_and_r <= #TCQ &early1_match_rise2_r;
early1_match_fall2_and_r <= #TCQ &early1_match_fall2_r;
early1_match_rise3_and_r <= #TCQ &early1_match_rise3_r;
early1_match_fall3_and_r <= #TCQ &early1_match_fall3_r;
early1_data_match_r <= #TCQ (early1_match_rise0_and_r &&
early1_match_fall0_and_r &&
early1_match_rise1_and_r &&
early1_match_fall1_and_r &&
early1_match_rise2_and_r &&
early1_match_fall2_and_r &&
early1_match_rise3_and_r &&
early1_match_fall3_and_r);
end
always @(posedge clk) begin
early2_match_rise0_and_r <= #TCQ &early2_match_rise0_r;
early2_match_fall0_and_r <= #TCQ &early2_match_fall0_r;
early2_match_rise1_and_r <= #TCQ &early2_match_rise1_r;
early2_match_fall1_and_r <= #TCQ &early2_match_fall1_r;
early2_match_rise2_and_r <= #TCQ &early2_match_rise2_r;
early2_match_fall2_and_r <= #TCQ &early2_match_fall2_r;
early2_match_rise3_and_r <= #TCQ &early2_match_rise3_r;
early2_match_fall3_and_r <= #TCQ &early2_match_fall3_r;
early2_data_match_r <= #TCQ (early2_match_rise0_and_r &&
early2_match_fall0_and_r &&
early2_match_rise1_and_r &&
early2_match_fall1_and_r &&
early2_match_rise2_and_r &&
early2_match_fall2_and_r &&
early2_match_rise3_and_r &&
early2_match_fall3_and_r);
end
end else if (nCK_PER_CLK == 2) begin: gen_pat_match_div2
for (pt_i = 0; pt_i < DRAM_WIDTH; pt_i = pt_i + 1) begin: gen_pat_match
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat1_rise0[pt_i%4])
pat1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat1_fall0[pt_i%4])
pat1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat1_rise1[pt_i%4])
pat1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat1_fall1[pt_i%4])
pat1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == pat2_rise0[pt_i%4])
pat2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == pat2_fall0[pt_i%4])
pat2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == pat2_rise1[pt_i%4])
pat2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == pat2_fall1[pt_i%4])
pat2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
pat2_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == early1_rise0[pt_i%4])
early1_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == early1_fall0[pt_i%4])
early1_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == early1_rise1[pt_i%4])
early1_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == early1_fall1[pt_i%4])
early1_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early1_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
// early2 in this case does not mean 2 cycles early but
// the second cycle of read data in 2:1 mode
always @(posedge clk) begin
if (sr_rise0_r[pt_i] == early2_rise0[pt_i%4])
early2_match_rise0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise0_r[pt_i] <= #TCQ 1'b0;
if (sr_fall0_r[pt_i] == early2_fall0[pt_i%4])
early2_match_fall0_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall0_r[pt_i] <= #TCQ 1'b0;
if (sr_rise1_r[pt_i] == early2_rise1[pt_i%4])
early2_match_rise1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_rise1_r[pt_i] <= #TCQ 1'b0;
if (sr_fall1_r[pt_i] == early2_fall1[pt_i%4])
early2_match_fall1_r[pt_i] <= #TCQ 1'b1;
else
early2_match_fall1_r[pt_i] <= #TCQ 1'b0;
end
end
always @(posedge clk) begin
pat1_match_rise0_and_r <= #TCQ &pat1_match_rise0_r;
pat1_match_fall0_and_r <= #TCQ &pat1_match_fall0_r;
pat1_match_rise1_and_r <= #TCQ &pat1_match_rise1_r;
pat1_match_fall1_and_r <= #TCQ &pat1_match_fall1_r;
pat1_data_match_r <= #TCQ (pat1_match_rise0_and_r &&
pat1_match_fall0_and_r &&
pat1_match_rise1_and_r &&
pat1_match_fall1_and_r);
pat1_data_match_r1 <= #TCQ pat1_data_match_r;
pat2_match_rise0_and_r <= #TCQ &pat2_match_rise0_r && rd_active_r3;
pat2_match_fall0_and_r <= #TCQ &pat2_match_fall0_r && rd_active_r3;
pat2_match_rise1_and_r <= #TCQ &pat2_match_rise1_r && rd_active_r3;
pat2_match_fall1_and_r <= #TCQ &pat2_match_fall1_r && rd_active_r3;
pat2_data_match_r <= #TCQ (pat2_match_rise0_and_r &&
pat2_match_fall0_and_r &&
pat2_match_rise1_and_r &&
pat2_match_fall1_and_r);
// For 2:1 mode, read valid is asserted for 2 clock cycles -
// here we generate a "match valid" pulse that is only 1 clock
// cycle wide that is simulatenous when the match calculation
// is complete
pat_data_match_valid_r <= #TCQ rd_active_r4 & ~rd_active_r5;
end
always @(posedge clk) begin
early1_match_rise0_and_r <= #TCQ &early1_match_rise0_r;
early1_match_fall0_and_r <= #TCQ &early1_match_fall0_r;
early1_match_rise1_and_r <= #TCQ &early1_match_rise1_r;
early1_match_fall1_and_r <= #TCQ &early1_match_fall1_r;
early1_data_match_r <= #TCQ (early1_match_rise0_and_r &&
early1_match_fall0_and_r &&
early1_match_rise1_and_r &&
early1_match_fall1_and_r);
early1_data_match_r1 <= #TCQ early1_data_match_r;
early2_match_rise0_and_r <= #TCQ &early2_match_rise0_r && rd_active_r3;
early2_match_fall0_and_r <= #TCQ &early2_match_fall0_r && rd_active_r3;
early2_match_rise1_and_r <= #TCQ &early2_match_rise1_r && rd_active_r3;
early2_match_fall1_and_r <= #TCQ &early2_match_fall1_r && rd_active_r3;
early2_data_match_r <= #TCQ (early2_match_rise0_and_r &&
early2_match_fall0_and_r &&
early2_match_rise1_and_r &&
early2_match_fall1_and_r);
end
end
endgenerate
// Need to delay it by 3 cycles in order to wait for Phaser_Out
// coarse delay to take effect before issuing a write command
always @(posedge clk) begin
wrcal_pat_resume_r1 <= #TCQ wrcal_pat_resume_r;
wrcal_pat_resume_r2 <= #TCQ wrcal_pat_resume_r1;
wrcal_pat_resume <= #TCQ wrcal_pat_resume_r2;
end
always @(posedge clk) begin
if (rst)
tap_inc_wait_cnt <= #TCQ 'd0;
else if ((cal2_state_r == CAL2_DQ_IDEL_DEC) ||
(cal2_state_r == CAL2_IFIFO_RESET) ||
(cal2_state_r == CAL2_SANITY_WAIT))
tap_inc_wait_cnt <= #TCQ tap_inc_wait_cnt + 1;
else
tap_inc_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk) begin
if (rst)
not_empty_wait_cnt <= #TCQ 'd0;
else if ((cal2_state_r == CAL2_READ_WAIT) && wrcal_rd_wait)
not_empty_wait_cnt <= #TCQ not_empty_wait_cnt + 1;
else
not_empty_wait_cnt <= #TCQ 'd0;
end
always @(posedge clk)
cal2_state_r1 <= #TCQ cal2_state_r;
//*****************************************************************
// Write Calibration state machine
//*****************************************************************
// when calibrating, check to see if the expected pattern is received.
// Otherwise delay DQS to align to correct CK edge.
// NOTES:
// 1. An error condition can occur due to two reasons:
// a. If the matching logic does not receive the expected data
// pattern. However, the error may be "recoverable" because
// the write calibration is still in progress. If an error is
// found the write calibration logic delays DQS by an additional
// clock cycle and restarts the pattern detection process.
// By design, if the write path timing is incorrect, the correct
// data pattern will never be detected.
// b. Valid data not found even after incrementing Phaser_Out
// coarse delay line.
always @(posedge clk) begin
if (rst) begin
wrcal_dqs_cnt_r <= #TCQ 'b0;
cal2_done_r <= #TCQ 1'b0;
cal2_prech_req_r <= #TCQ 1'b0;
cal2_state_r <= #TCQ CAL2_IDLE;
wrcal_pat_err <= #TCQ 1'b0;
wrcal_pat_resume_r <= #TCQ 1'b0;
wrcal_act_req <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
temp_wrcal_done <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b0;
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b0;
idelay_ld <= #TCQ 1'b0;
idelay_ld_done <= #TCQ 1'b0;
pat1_detect <= #TCQ 1'b0;
early1_detect <= #TCQ 1'b0;
wrcal_sanity_chk_done <= #TCQ 1'b0;
wrcal_sanity_chk_err <= #TCQ 1'b0;
end else begin
cal2_prech_req_r <= #TCQ 1'b0;
case (cal2_state_r)
CAL2_IDLE: begin
wrcal_pat_err <= #TCQ 1'b0;
if (wrcal_start) begin
cal2_if_reset <= #TCQ 1'b0;
if (SIM_CAL_OPTION == "SKIP_CAL")
// If skip write calibration, then proceed to end.
cal2_state_r <= #TCQ CAL2_DONE;
else
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end
end
// General wait state to wait for read data to be output by the
// IN_FIFO
CAL2_READ_WAIT: begin
wrcal_pat_resume_r <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
// Wait until read data is received, and pattern matching
// calculation is complete. NOTE: Need to add a timeout here
// in case for some reason data is never received (or rather
// the PHASER_IN and IN_FIFO think they never receives data)
if (pat_data_match_valid_r && (nCK_PER_CLK == 4)) begin
if (pat_data_match_r)
// If found data match, then move on to next DQS group
cal2_state_r <= #TCQ CAL2_NEXT_DQS;
else begin
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_ERR;
// If writes are one or two cycles early then redo
// write leveling for the byte
else if (early1_data_match_r) begin
early1_data <= #TCQ 1'b1;
early2_data <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
end else if (early2_data_match_r) begin
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b1;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
// Read late due to incorrect MPR idelay value
// Decrement Idelay to '0'for the current byte
end else if (~idelay_ld_done) begin
cal2_state_r <= #TCQ CAL2_DQ_IDEL_DEC;
idelay_ld <= #TCQ 1'b1;
end else
cal2_state_r <= #TCQ CAL2_ERR;
end
end else if (pat_data_match_valid_r && (nCK_PER_CLK == 2)) begin
if ((pat1_data_match_r1 && pat2_data_match_r) ||
(pat1_detect && pat2_data_match_r))
// If found data match, then move on to next DQS group
cal2_state_r <= #TCQ CAL2_NEXT_DQS;
else if (pat1_data_match_r1 && ~pat2_data_match_r) begin
cal2_state_r <= #TCQ CAL2_READ_WAIT;
pat1_detect <= #TCQ 1'b1;
end else begin
// If writes are one or two cycles early then redo
// write leveling for the byte
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_ERR;
else if ((early1_data_match_r1 && early2_data_match_r) ||
(early1_detect && early2_data_match_r)) begin
early1_data <= #TCQ 1'b1;
early2_data <= #TCQ 1'b0;
wrlvl_byte_redo <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_WRLVL_WAIT;
end else if (early1_data_match_r1 && ~early2_data_match_r) begin
early1_detect <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
// Read late due to incorrect MPR idelay value
// Decrement Idelay to '0'for the current byte
end else if (~idelay_ld_done) begin
cal2_state_r <= #TCQ CAL2_DQ_IDEL_DEC;
idelay_ld <= #TCQ 1'b1;
end else
cal2_state_r <= #TCQ CAL2_ERR;
end
end else if (not_empty_wait_cnt == 'd31)
cal2_state_r <= #TCQ CAL2_ERR;
end
CAL2_WRLVL_WAIT: begin
early1_detect <= #TCQ 1'b0;
if (wrlvl_byte_done && ~wrlvl_byte_done_r)
wrlvl_byte_redo <= #TCQ 1'b0;
if (wrlvl_byte_done) begin
if (rd_active_r1 && ~rd_active_r) begin
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
cal2_if_reset <= #TCQ 1'b1;
early1_data <= #TCQ 1'b0;
early2_data <= #TCQ 1'b0;
end
end
end
CAL2_DQ_IDEL_DEC: begin
if (tap_inc_wait_cnt == 'd4) begin
idelay_ld <= #TCQ 1'b0;
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
cal2_if_reset <= #TCQ 1'b1;
idelay_ld_done <= #TCQ 1'b1;
end
end
CAL2_IFIFO_RESET: begin
if (tap_inc_wait_cnt == 'd15) begin
cal2_if_reset <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
cal2_state_r <= #TCQ CAL2_DONE;
else if (idelay_ld_done) begin
wrcal_pat_resume_r <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end else
cal2_state_r <= #TCQ CAL2_IDLE;
end
end
// Final processing for current DQS group. Move on to next group
CAL2_NEXT_DQS: begin
// At this point, we've just found the correct pattern for the
// current DQS group.
// Request bank/row precharge, and wait for its completion. Always
// precharge after each DQS group to avoid tRAS(max) violation
//verilint STARC-2.2.3.3 off
if (wrcal_sanity_chk_r && (wrcal_dqs_cnt_r != DQS_WIDTH-1)) begin
cal2_prech_req_r <= #TCQ 1'b0;
wrcal_dqs_cnt_r <= #TCQ wrcal_dqs_cnt_r + 1;
cal2_state_r <= #TCQ CAL2_SANITY_WAIT;
end else
cal2_prech_req_r <= #TCQ 1'b1;
idelay_ld_done <= #TCQ 1'b0;
pat1_detect <= #TCQ 1'b0;
if (prech_done)
if (((DQS_WIDTH == 1) || (SIM_CAL_OPTION == "FAST_CAL")) ||
(wrcal_dqs_cnt_r == DQS_WIDTH-1)) begin
// If either FAST_CAL is enabled and first DQS group is
// finished, or if the last DQS group was just finished,
// then end of write calibration
if (wrcal_sanity_chk_r) begin
cal2_if_reset <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_IFIFO_RESET;
end else
cal2_state_r <= #TCQ CAL2_DONE;
end else begin
// Continue to next DQS group
wrcal_dqs_cnt_r <= #TCQ wrcal_dqs_cnt_r + 1;
cal2_state_r <= #TCQ CAL2_READ_WAIT;
end
end
//verilint STARC-2.2.3.3 on
CAL2_SANITY_WAIT: begin
if (tap_inc_wait_cnt == 'd15) begin
cal2_state_r <= #TCQ CAL2_READ_WAIT;
wrcal_pat_resume_r <= #TCQ 1'b1;
end
end
// Finished with read enable calibration
CAL2_DONE: begin
if (wrcal_sanity_chk && ~wrcal_sanity_chk_r) begin
cal2_done_r <= #TCQ 1'b0;
wrcal_dqs_cnt_r <= #TCQ 'd0;
cal2_state_r <= #TCQ CAL2_IDLE;
end else
cal2_done_r <= #TCQ 1'b1;
cal2_prech_req_r <= #TCQ 1'b0;
cal2_if_reset <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
wrcal_sanity_chk_done <= #TCQ 1'b1;
end
// Assert error signal indicating that writes timing is incorrect
CAL2_ERR: begin
wrcal_pat_resume_r <= #TCQ 1'b0;
if (wrcal_sanity_chk_r)
wrcal_sanity_chk_err <= #TCQ 1'b1;
else
wrcal_pat_err <= #TCQ 1'b1;
cal2_state_r <= #TCQ CAL2_ERR;
end
endcase
end
end
// Delay assertion of wrcal_done for write calibration by a few cycles after
// we've reached CAL2_DONE
always @(posedge clk)
if (rst)
cal2_done_r1 <= #TCQ 1'b0;
else
cal2_done_r1 <= #TCQ cal2_done_r;
always @(posedge clk)
if (rst || (wrcal_sanity_chk && ~wrcal_sanity_chk_r))
wrcal_done <= #TCQ 1'b0;
else if (cal2_done_r)
wrcal_done <= #TCQ 1'b1;
endmodule
|
module mig_7series_v2_3_ddr_phy_wrlvl #
(
parameter TCQ = 100,
parameter DQS_CNT_WIDTH = 3,
parameter DQ_WIDTH = 64,
parameter DQS_WIDTH = 2,
parameter DRAM_WIDTH = 8,
parameter RANKS = 1,
parameter nCK_PER_CLK = 4,
parameter CLK_PERIOD = 4,
parameter SIM_CAL_OPTION = "NONE"
)
(
input clk,
input rst,
input phy_ctl_ready,
input wr_level_start,
input wl_sm_start,
input wrlvl_final,
input wrlvl_byte_redo,
input [DQS_CNT_WIDTH:0] wrcal_cnt,
input early1_data,
input early2_data,
input [DQS_CNT_WIDTH:0] oclkdelay_calib_cnt,
input oclkdelay_calib_done,
input [(DQ_WIDTH)-1:0] rd_data_rise0,
output reg wrlvl_byte_done,
output reg dqs_po_dec_done /* synthesis syn_maxfan = 2 */,
output phy_ctl_rdy_dly,
output reg wr_level_done /* synthesis syn_maxfan = 2 */,
// to phy_init for cs logic
output wrlvl_rank_done,
output done_dqs_tap_inc,
output [DQS_CNT_WIDTH:0] po_stg2_wl_cnt,
// Fine delay line used only during write leveling
// Inc/dec Phaser_Out fine delay line
output reg dqs_po_stg2_f_incdec,
// Enable Phaser_Out fine delay inc/dec
output reg dqs_po_en_stg2_f,
// Coarse delay line used during write leveling
// only if 64 taps of fine delay line were not
// sufficient to detect a 0->1 transition
// Inc Phaser_Out coarse delay line
output reg dqs_wl_po_stg2_c_incdec,
// Enable Phaser_Out coarse delay inc/dec
output reg dqs_wl_po_en_stg2_c,
// Read Phaser_Out delay value
input [8:0] po_counter_read_val,
// output reg dqs_wl_po_stg2_load,
// output reg [8:0] dqs_wl_po_stg2_reg_l,
// CK edge undetected
output reg wrlvl_err,
output reg [3*DQS_WIDTH-1:0] wl_po_coarse_cnt,
output reg [6*DQS_WIDTH-1:0] wl_po_fine_cnt,
// Debug ports
output [5:0] dbg_wl_tap_cnt,
output dbg_wl_edge_detect_valid,
output [(DQS_WIDTH)-1:0] dbg_rd_data_edge_detect,
output [DQS_CNT_WIDTH:0] dbg_dqs_count,
output [4:0] dbg_wl_state,
output [6*DQS_WIDTH-1:0] dbg_wrlvl_fine_tap_cnt,
output [3*DQS_WIDTH-1:0] dbg_wrlvl_coarse_tap_cnt,
output [255:0] dbg_phy_wrlvl
);
localparam WL_IDLE = 5'h0;
localparam WL_INIT = 5'h1;
localparam WL_INIT_FINE_INC = 5'h2;
localparam WL_INIT_FINE_INC_WAIT1= 5'h3;
localparam WL_INIT_FINE_INC_WAIT = 5'h4;
localparam WL_INIT_FINE_DEC = 5'h5;
localparam WL_INIT_FINE_DEC_WAIT = 5'h6;
localparam WL_FINE_INC = 5'h7;
localparam WL_WAIT = 5'h8;
localparam WL_EDGE_CHECK = 5'h9;
localparam WL_DQS_CHECK = 5'hA;
localparam WL_DQS_CNT = 5'hB;
localparam WL_2RANK_TAP_DEC = 5'hC;
localparam WL_2RANK_DQS_CNT = 5'hD;
localparam WL_FINE_DEC = 5'hE;
localparam WL_FINE_DEC_WAIT = 5'hF;
localparam WL_CORSE_INC = 5'h10;
localparam WL_CORSE_INC_WAIT = 5'h11;
localparam WL_CORSE_INC_WAIT1 = 5'h12;
localparam WL_CORSE_INC_WAIT2 = 5'h13;
localparam WL_CORSE_DEC = 5'h14;
localparam WL_CORSE_DEC_WAIT = 5'h15;
localparam WL_CORSE_DEC_WAIT1 = 5'h16;
localparam WL_FINE_INC_WAIT = 5'h17;
localparam WL_2RANK_FINAL_TAP = 5'h18;
localparam WL_INIT_FINE_DEC_WAIT1= 5'h19;
localparam WL_FINE_DEC_WAIT1 = 5'h1A;
localparam WL_CORSE_INC_WAIT_TMP = 5'h1B;
localparam COARSE_TAPS = 7;
localparam FAST_CAL_FINE = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 45 : 48;
localparam FAST_CAL_COARSE = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 1 : 2;
localparam REDO_COARSE = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 2 : 5;
integer i, j, k, l, p, q, r, s, t, m, n, u, v, w, x,y;
reg phy_ctl_ready_r1;
reg phy_ctl_ready_r2;
reg phy_ctl_ready_r3;
reg phy_ctl_ready_r4;
reg phy_ctl_ready_r5;
reg phy_ctl_ready_r6;
(* max_fanout = 50 *) reg [DQS_CNT_WIDTH:0] dqs_count_r;
reg [1:0] rank_cnt_r;
reg [DQS_WIDTH-1:0] rd_data_rise_wl_r;
reg [DQS_WIDTH-1:0] rd_data_previous_r;
reg [DQS_WIDTH-1:0] rd_data_edge_detect_r;
reg wr_level_done_r;
reg wrlvl_rank_done_r;
reg wr_level_start_r;
reg [4:0] wl_state_r, wl_state_r1;
reg inhibit_edge_detect_r;
reg wl_edge_detect_valid_r;
reg [5:0] wl_tap_count_r;
reg [5:0] fine_dec_cnt;
reg [5:0] fine_inc[0:DQS_WIDTH-1]; // DQS_WIDTH number of counters 6-bit each
reg [2:0] corse_dec[0:DQS_WIDTH-1];
reg [2:0] corse_inc[0:DQS_WIDTH-1];
reg dq_cnt_inc;
reg [3:0] stable_cnt;
reg flag_ck_negedge;
//reg past_negedge;
reg flag_init;
reg [2:0] corse_cnt[0:DQS_WIDTH-1];
reg [3*DQS_WIDTH-1:0] corse_cnt_dbg;
reg [2:0] wl_corse_cnt[0:RANKS-1][0:DQS_WIDTH-1];
//reg [3*DQS_WIDTH-1:0] coarse_tap_inc;
reg [2:0] final_coarse_tap[0:DQS_WIDTH-1];
reg [5:0] add_smallest[0:DQS_WIDTH-1];
reg [5:0] add_largest[0:DQS_WIDTH-1];
//reg [6*DQS_WIDTH-1:0] fine_tap_inc;
//reg [6*DQS_WIDTH-1:0] fine_tap_dec;
reg wr_level_done_r1;
reg wr_level_done_r2;
reg wr_level_done_r3;
reg wr_level_done_r4;
reg wr_level_done_r5;
reg [5:0] wl_dqs_tap_count_r[0:RANKS-1][0:DQS_WIDTH-1];
reg [5:0] smallest[0:DQS_WIDTH-1];
reg [5:0] largest[0:DQS_WIDTH-1];
reg [5:0] final_val[0:DQS_WIDTH-1];
reg [5:0] po_dec_cnt[0:DQS_WIDTH-1];
reg done_dqs_dec;
reg [8:0] po_rdval_cnt;
reg po_cnt_dec;
reg po_dec_done;
reg dual_rnk_dec;
wire [DQS_CNT_WIDTH+2:0] dqs_count_w;
reg [5:0] fast_cal_fine_cnt;
reg [2:0] fast_cal_coarse_cnt;
reg wrlvl_byte_redo_r;
reg [2:0] wrlvl_redo_corse_inc;
reg wrlvl_final_r;
reg final_corse_dec;
wire [DQS_CNT_WIDTH+2:0] oclk_count_w;
reg wrlvl_tap_done_r ;
reg [3:0] wait_cnt;
reg [3:0] incdec_wait_cnt;
// Debug ports
assign dbg_wl_edge_detect_valid = wl_edge_detect_valid_r;
assign dbg_rd_data_edge_detect = rd_data_edge_detect_r;
assign dbg_wl_tap_cnt = wl_tap_count_r;
assign dbg_dqs_count = dqs_count_r;
assign dbg_wl_state = wl_state_r;
assign dbg_wrlvl_fine_tap_cnt = wl_po_fine_cnt;
assign dbg_wrlvl_coarse_tap_cnt = wl_po_coarse_cnt;
always @(*) begin
for (v = 0; v < DQS_WIDTH; v = v + 1)
corse_cnt_dbg[3*v+:3] = corse_cnt[v];
end
assign dbg_phy_wrlvl[0+:27] = corse_cnt_dbg;
assign dbg_phy_wrlvl[27+:5] = wl_state_r;
assign dbg_phy_wrlvl[32+:4] = dqs_count_r;
assign dbg_phy_wrlvl[36+:9] = rd_data_rise_wl_r;
assign dbg_phy_wrlvl[45+:9] = rd_data_previous_r;
assign dbg_phy_wrlvl[54+:4] = stable_cnt;
assign dbg_phy_wrlvl[58] = 'd0;
assign dbg_phy_wrlvl[59] = flag_ck_negedge;
assign dbg_phy_wrlvl [60] = wl_edge_detect_valid_r;
assign dbg_phy_wrlvl [61+:6] = wl_tap_count_r;
assign dbg_phy_wrlvl [67+:9] = rd_data_edge_detect_r;
assign dbg_phy_wrlvl [76+:54] = wl_po_fine_cnt;
assign dbg_phy_wrlvl [130+:27] = wl_po_coarse_cnt;
//**************************************************************************
// DQS count to hard PHY during write leveling using Phaser_OUT Stage2 delay
//**************************************************************************
assign po_stg2_wl_cnt = dqs_count_r;
assign wrlvl_rank_done = wrlvl_rank_done_r;
assign done_dqs_tap_inc = done_dqs_dec;
assign phy_ctl_rdy_dly = phy_ctl_ready_r6;
always @(posedge clk) begin
phy_ctl_ready_r1 <= #TCQ phy_ctl_ready;
phy_ctl_ready_r2 <= #TCQ phy_ctl_ready_r1;
phy_ctl_ready_r3 <= #TCQ phy_ctl_ready_r2;
phy_ctl_ready_r4 <= #TCQ phy_ctl_ready_r3;
phy_ctl_ready_r5 <= #TCQ phy_ctl_ready_r4;
phy_ctl_ready_r6 <= #TCQ phy_ctl_ready_r5;
wrlvl_byte_redo_r <= #TCQ wrlvl_byte_redo;
wrlvl_final_r <= #TCQ wrlvl_final;
if ((wrlvl_byte_redo && ~wrlvl_byte_redo_r) ||
(wrlvl_final && ~wrlvl_final_r))
wr_level_done <= #TCQ 1'b0;
else
wr_level_done <= #TCQ done_dqs_dec;
end
// Status signal that will be asserted once the first
// pass of write leveling is done.
always @(posedge clk) begin
if(rst) begin
wrlvl_tap_done_r <= #TCQ 1'b0 ;
end else begin
if(wrlvl_tap_done_r == 1'b0) begin
if(oclkdelay_calib_done) begin
wrlvl_tap_done_r <= #TCQ 1'b1 ;
end
end
end
end
always @(posedge clk) begin
if (rst || po_cnt_dec)
wait_cnt <= #TCQ 'd8;
else if (phy_ctl_ready_r6 && (wait_cnt > 'd0))
wait_cnt <= #TCQ wait_cnt - 1;
end
always @(posedge clk) begin
if (rst) begin
po_rdval_cnt <= #TCQ 'd0;
end else if (phy_ctl_ready_r5 && ~phy_ctl_ready_r6) begin
po_rdval_cnt <= #TCQ po_counter_read_val;
end else if (po_rdval_cnt > 'd0) begin
if (po_cnt_dec)
po_rdval_cnt <= #TCQ po_rdval_cnt - 1;
else
po_rdval_cnt <= #TCQ po_rdval_cnt;
end else if (po_rdval_cnt == 'd0) begin
po_rdval_cnt <= #TCQ po_rdval_cnt;
end
end
always @(posedge clk) begin
if (rst || (po_rdval_cnt == 'd0))
po_cnt_dec <= #TCQ 1'b0;
else if (phy_ctl_ready_r6 && (po_rdval_cnt > 'd0) && (wait_cnt == 'd1))
po_cnt_dec <= #TCQ 1'b1;
else
po_cnt_dec <= #TCQ 1'b0;
end
always @(posedge clk) begin
if (rst)
po_dec_done <= #TCQ 1'b0;
else if (((po_cnt_dec == 'd1) && (po_rdval_cnt == 'd1)) ||
(phy_ctl_ready_r6 && (po_rdval_cnt == 'd0))) begin
po_dec_done <= #TCQ 1'b1;
end
end
always @(posedge clk) begin
dqs_po_dec_done <= #TCQ po_dec_done;
wr_level_done_r1 <= #TCQ wr_level_done_r;
wr_level_done_r2 <= #TCQ wr_level_done_r1;
wr_level_done_r3 <= #TCQ wr_level_done_r2;
wr_level_done_r4 <= #TCQ wr_level_done_r3;
wr_level_done_r5 <= #TCQ wr_level_done_r4;
for (l = 0; l < DQS_WIDTH; l = l + 1) begin
wl_po_coarse_cnt[3*l+:3] <= #TCQ final_coarse_tap[l];
if ((RANKS == 1) || ~oclkdelay_calib_done)
wl_po_fine_cnt[6*l+:6] <= #TCQ smallest[l];
else
wl_po_fine_cnt[6*l+:6] <= #TCQ final_val[l];
end
end
generate
if (RANKS == 2) begin: dual_rank
always @(posedge clk) begin
if (rst || (wrlvl_byte_redo && ~wrlvl_byte_redo_r) ||
(wrlvl_final && ~wrlvl_final_r))
done_dqs_dec <= #TCQ 1'b0;
else if ((SIM_CAL_OPTION == "FAST_CAL") || ~oclkdelay_calib_done)
done_dqs_dec <= #TCQ wr_level_done_r;
else if (wr_level_done_r5 && (wl_state_r == WL_IDLE))
done_dqs_dec <= #TCQ 1'b1;
end
end else begin: single_rank
always @(posedge clk) begin
if (rst || (wrlvl_byte_redo && ~wrlvl_byte_redo_r) ||
(wrlvl_final && ~wrlvl_final_r))
done_dqs_dec <= #TCQ 1'b0;
else if (~oclkdelay_calib_done)
done_dqs_dec <= #TCQ wr_level_done_r;
else if (wr_level_done_r3 && ~wr_level_done_r4)
done_dqs_dec <= #TCQ 1'b1;
end
end
endgenerate
always @(posedge clk)
if (rst || (wrlvl_byte_redo && ~wrlvl_byte_redo_r))
wrlvl_byte_done <= #TCQ 1'b0;
else if (wrlvl_byte_redo && wr_level_done_r3 && ~wr_level_done_r4)
wrlvl_byte_done <= #TCQ 1'b1;
// Storing DQS tap values at the end of each DQS write leveling
always @(posedge clk) begin
if (rst) begin
for (k = 0; k < RANKS; k = k + 1) begin: rst_wl_dqs_tap_count_loop
for (n = 0; n < DQS_WIDTH; n = n + 1) begin
wl_corse_cnt[k][n] <= #TCQ 'b0;
wl_dqs_tap_count_r[k][n] <= #TCQ 'b0;
end
end
end else if ((wl_state_r == WL_DQS_CNT) | (wl_state_r == WL_WAIT) |
(wl_state_r == WL_FINE_DEC_WAIT1) |
(wl_state_r == WL_2RANK_TAP_DEC)) begin
wl_dqs_tap_count_r[rank_cnt_r][dqs_count_r] <= #TCQ wl_tap_count_r;
wl_corse_cnt[rank_cnt_r][dqs_count_r] <= #TCQ corse_cnt[dqs_count_r];
end else if ((SIM_CAL_OPTION == "FAST_CAL") & (wl_state_r == WL_DQS_CHECK)) begin
for (p = 0; p < RANKS; p = p +1) begin: dqs_tap_rank_cnt
for(q = 0; q < DQS_WIDTH; q = q +1) begin: dqs_tap_dqs_cnt
wl_dqs_tap_count_r[p][q] <= #TCQ wl_tap_count_r;
wl_corse_cnt[p][q] <= #TCQ corse_cnt[0];
end
end
end
end
// Convert coarse delay to fine taps in case of unequal number of coarse
// taps between ranks. Assuming a difference of 1 coarse tap counts
// between ranks. A common fine and coarse tap value must be used for both ranks
// because Phaser_Out has only one rank register.
// Coarse tap1 = period(ps)*93/360 = 34 fine taps
// Other coarse taps = period(ps)*103/360 = 38 fine taps
generate
genvar cnt;
if (RANKS == 2) begin // Dual rank
for(cnt = 0; cnt < DQS_WIDTH; cnt = cnt +1) begin: coarse_dqs_cnt
always @(posedge clk) begin
if (rst) begin
//coarse_tap_inc[3*cnt+:3] <= #TCQ 'b0;
add_smallest[cnt] <= #TCQ 'd0;
add_largest[cnt] <= #TCQ 'd0;
final_coarse_tap[cnt] <= #TCQ 'd0;
end else if (wr_level_done_r1 & ~wr_level_done_r2) begin
if (~oclkdelay_calib_done) begin
for(y = 0 ; y < DQS_WIDTH; y = y+1) begin
final_coarse_tap[y] <= #TCQ wl_corse_cnt[0][y];
add_smallest[y] <= #TCQ 'd0;
add_largest[y] <= #TCQ 'd0;
end
end else
if (wl_corse_cnt[0][cnt] == wl_corse_cnt[1][cnt]) begin
// Both ranks have use the same number of coarse delay taps.
// No conversion of coarse tap to fine taps required.
//coarse_tap_inc[3*cnt+:3] <= #TCQ wl_corse_cnt[1][3*cnt+:3];
final_coarse_tap[cnt] <= #TCQ wl_corse_cnt[1][cnt];
add_smallest[cnt] <= #TCQ 'd0;
add_largest[cnt] <= #TCQ 'd0;
end else if (wl_corse_cnt[0][cnt] < wl_corse_cnt[1][cnt]) begin
// Rank 0 uses fewer coarse delay taps than rank1.
// conversion of coarse tap to fine taps required for rank1.
// The final coarse count will the smaller value.
//coarse_tap_inc[3*cnt+:3] <= #TCQ wl_corse_cnt[1][3*cnt+:3] - 1;
final_coarse_tap[cnt] <= #TCQ wl_corse_cnt[1][cnt] - 1;
if (|wl_corse_cnt[0][cnt])
// Coarse tap 2 or higher being converted to fine taps
// This will be added to 'largest' value in final_val
// computation
add_largest[cnt] <= #TCQ 'd38;
else
// Coarse tap 1 being converted to fine taps
// This will be added to 'largest' value in final_val
// computation
add_largest[cnt] <= #TCQ 'd34;
end else if (wl_corse_cnt[0][cnt] > wl_corse_cnt[1][cnt]) begin
// This may be an unlikely scenario in a real system.
// Rank 0 uses more coarse delay taps than rank1.
// conversion of coarse tap to fine taps required.
//coarse_tap_inc[3*cnt+:3] <= #TCQ 'd0;
final_coarse_tap[cnt] <= #TCQ wl_corse_cnt[1][cnt];
if (|wl_corse_cnt[1][cnt])
// Coarse tap 2 or higher being converted to fine taps
// This will be added to 'smallest' value in final_val
// computation
add_smallest[cnt] <= #TCQ 'd38;
else
// Coarse tap 1 being converted to fine taps
// This will be added to 'smallest' value in
// final_val computation
add_smallest[cnt] <= #TCQ 'd34;
end
end
end
end
end else begin
// Single rank
always @(posedge clk) begin
//coarse_tap_inc <= #TCQ 'd0;
for(w = 0; w < DQS_WIDTH; w = w + 1) begin
final_coarse_tap[w] <= #TCQ wl_corse_cnt[0][w];
add_smallest[w] <= #TCQ 'd0;
add_largest[w] <= #TCQ 'd0;
end
end
end
endgenerate
// Determine delay value for DQS in multirank system
// Assuming delay value is the smallest for rank 0 DQS
// and largest delay value for rank 4 DQS
// Set to smallest + ((largest-smallest)/2)
always @(posedge clk) begin
if (rst) begin
for(x = 0; x < DQS_WIDTH; x = x +1) begin
smallest[x] <= #TCQ 'b0;
largest[x] <= #TCQ 'b0;
end
end else if ((wl_state_r == WL_DQS_CNT) & wrlvl_byte_redo) begin
smallest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[0][dqs_count_r];
largest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[0][dqs_count_r];
end else if ((wl_state_r == WL_DQS_CNT) |
(wl_state_r == WL_2RANK_TAP_DEC)) begin
smallest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[0][dqs_count_r];
largest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[RANKS-1][dqs_count_r];
end else if (((SIM_CAL_OPTION == "FAST_CAL") |
(~oclkdelay_calib_done & ~wrlvl_byte_redo)) &
wr_level_done_r1 & ~wr_level_done_r2) begin
for(i = 0; i < DQS_WIDTH; i = i +1) begin: smallest_dqs
smallest[i] <= #TCQ wl_dqs_tap_count_r[0][i];
largest[i] <= #TCQ wl_dqs_tap_count_r[0][i];
end
end
end
// final_val to be used for all DQSs in all ranks
genvar wr_i;
generate
for (wr_i = 0; wr_i < DQS_WIDTH; wr_i = wr_i +1) begin: gen_final_tap
always @(posedge clk) begin
if (rst)
final_val[wr_i] <= #TCQ 'b0;
else if (wr_level_done_r2 && ~wr_level_done_r3) begin
if (~oclkdelay_calib_done)
final_val[wr_i] <= #TCQ (smallest[wr_i] + add_smallest[wr_i]);
else if ((smallest[wr_i] + add_smallest[wr_i]) <
(largest[wr_i] + add_largest[wr_i]))
final_val[wr_i] <= #TCQ ((smallest[wr_i] + add_smallest[wr_i]) +
(((largest[wr_i] + add_largest[wr_i]) -
(smallest[wr_i] + add_smallest[wr_i]))/2));
else if ((smallest[wr_i] + add_smallest[wr_i]) >
(largest[wr_i] + add_largest[wr_i]))
final_val[wr_i] <= #TCQ ((largest[wr_i] + add_largest[wr_i]) +
(((smallest[wr_i] + add_smallest[wr_i]) -
(largest[wr_i] + add_largest[wr_i]))/2));
else if ((smallest[wr_i] + add_smallest[wr_i]) ==
(largest[wr_i] + add_largest[wr_i]))
final_val[wr_i] <= #TCQ (largest[wr_i] + add_largest[wr_i]);
end
end
end
endgenerate
// // fine tap inc/dec value for all DQSs in all ranks
// genvar dqs_i;
// generate
// for (dqs_i = 0; dqs_i < DQS_WIDTH; dqs_i = dqs_i +1) begin: gen_fine_tap
// always @(posedge clk) begin
// if (rst)
// fine_tap_inc[6*dqs_i+:6] <= #TCQ 'd0;
// //fine_tap_dec[6*dqs_i+:6] <= #TCQ 'd0;
// else if (wr_level_done_r3 && ~wr_level_done_r4) begin
// fine_tap_inc[6*dqs_i+:6] <= #TCQ final_val[6*dqs_i+:6];
// //fine_tap_dec[6*dqs_i+:6] <= #TCQ 'd0;
// end
// end
// endgenerate
// Inc/Dec Phaser_Out stage 2 fine delay line
always @(posedge clk) begin
if (rst) begin
// Fine delay line used only during write leveling
dqs_po_stg2_f_incdec <= #TCQ 1'b0;
dqs_po_en_stg2_f <= #TCQ 1'b0;
// Dec Phaser_Out fine delay (1)before write leveling,
// (2)if no 0 to 1 transition detected with 63 fine delay taps, or
// (3)dual rank case where fine taps for the first rank need to be 0
end else if (po_cnt_dec || (wl_state_r == WL_INIT_FINE_DEC) ||
(wl_state_r == WL_FINE_DEC)) begin
dqs_po_stg2_f_incdec <= #TCQ 1'b0;
dqs_po_en_stg2_f <= #TCQ 1'b1;
// Inc Phaser_Out fine delay during write leveling
end else if ((wl_state_r == WL_INIT_FINE_INC) ||
(wl_state_r == WL_FINE_INC)) begin
dqs_po_stg2_f_incdec <= #TCQ 1'b1;
dqs_po_en_stg2_f <= #TCQ 1'b1;
end else begin
dqs_po_stg2_f_incdec <= #TCQ 1'b0;
dqs_po_en_stg2_f <= #TCQ 1'b0;
end
end
// Inc Phaser_Out stage 2 Coarse delay line
always @(posedge clk) begin
if (rst) begin
// Coarse delay line used during write leveling
// only if no 0->1 transition undetected with 64
// fine delay line taps
dqs_wl_po_stg2_c_incdec <= #TCQ 1'b0;
dqs_wl_po_en_stg2_c <= #TCQ 1'b0;
end else if (wl_state_r == WL_CORSE_INC) begin
// Inc Phaser_Out coarse delay during write leveling
dqs_wl_po_stg2_c_incdec <= #TCQ 1'b1;
dqs_wl_po_en_stg2_c <= #TCQ 1'b1;
end else begin
dqs_wl_po_stg2_c_incdec <= #TCQ 1'b0;
dqs_wl_po_en_stg2_c <= #TCQ 1'b0;
end
end
// only storing the rise data for checking. The data comming back during
// write leveling will be a static value. Just checking for rise data is
// enough.
genvar rd_i;
generate
for(rd_i = 0; rd_i < DQS_WIDTH; rd_i = rd_i +1)begin: gen_rd
always @(posedge clk)
rd_data_rise_wl_r[rd_i] <=
#TCQ |rd_data_rise0[(rd_i*DRAM_WIDTH)+DRAM_WIDTH-1:rd_i*DRAM_WIDTH];
end
endgenerate
// storing the previous data for checking later.
always @(posedge clk)begin
if ((wl_state_r == WL_INIT) || //(wl_state_r == WL_INIT_FINE_INC_WAIT) ||
//(wl_state_r == WL_INIT_FINE_INC_WAIT1) ||
((wl_state_r1 == WL_INIT_FINE_INC_WAIT) & (wl_state_r == WL_INIT_FINE_INC)) ||
(wl_state_r == WL_FINE_DEC) || (wl_state_r == WL_FINE_DEC_WAIT1) || (wl_state_r == WL_FINE_DEC_WAIT) ||
(wl_state_r == WL_CORSE_INC) || (wl_state_r == WL_CORSE_INC_WAIT) || (wl_state_r == WL_CORSE_INC_WAIT_TMP) ||
(wl_state_r == WL_CORSE_INC_WAIT1) || (wl_state_r == WL_CORSE_INC_WAIT2) ||
((wl_state_r == WL_EDGE_CHECK) & (wl_edge_detect_valid_r)))
rd_data_previous_r <= #TCQ rd_data_rise_wl_r;
end
// changed stable count from 3 to 7 because of fine tap resolution
always @(posedge clk)begin
if (rst | (wl_state_r == WL_DQS_CNT) |
(wl_state_r == WL_2RANK_TAP_DEC) |
(wl_state_r == WL_FINE_DEC) |
(rd_data_previous_r[dqs_count_r] != rd_data_rise_wl_r[dqs_count_r]) |
(wl_state_r1 == WL_INIT_FINE_DEC))
stable_cnt <= #TCQ 'd0;
else if ((wl_tap_count_r > 6'd0) &
(((wl_state_r == WL_EDGE_CHECK) & (wl_edge_detect_valid_r)) |
((wl_state_r1 == WL_INIT_FINE_INC_WAIT) & (wl_state_r == WL_INIT_FINE_INC)))) begin
if ((rd_data_previous_r[dqs_count_r] == rd_data_rise_wl_r[dqs_count_r])
& (stable_cnt < 'd14))
stable_cnt <= #TCQ stable_cnt + 1;
end
end
// Signal to ensure that flag_ck_negedge does not incorrectly assert
// when DQS is very close to CK rising edge
//always @(posedge clk) begin
// if (rst | (wl_state_r == WL_DQS_CNT) |
// (wl_state_r == WL_DQS_CHECK) | wr_level_done_r)
// past_negedge <= #TCQ 1'b0;
// else if (~flag_ck_negedge && ~rd_data_previous_r[dqs_count_r] &&
// (stable_cnt == 'd0) && ((wl_state_r == WL_CORSE_INC_WAIT1) |
// (wl_state_r == WL_CORSE_INC_WAIT2)))
// past_negedge <= #TCQ 1'b1;
//end
// Flag to indicate negedge of CK detected and ignore 0->1 transitions
// in this region
always @(posedge clk)begin
if (rst | (wl_state_r == WL_DQS_CNT) |
(wl_state_r == WL_DQS_CHECK) | wr_level_done_r |
(wl_state_r1 == WL_INIT_FINE_DEC))
flag_ck_negedge <= #TCQ 1'd0;
else if ((rd_data_previous_r[dqs_count_r] && ((stable_cnt > 'd0) |
(wl_state_r == WL_FINE_DEC) | (wl_state_r == WL_FINE_DEC_WAIT) | (wl_state_r == WL_FINE_DEC_WAIT1))) |
(wl_state_r == WL_CORSE_INC))
flag_ck_negedge <= #TCQ 1'd1;
else if (~rd_data_previous_r[dqs_count_r] && (stable_cnt == 'd14))
//&& flag_ck_negedge)
flag_ck_negedge <= #TCQ 1'd0;
end
// Flag to inhibit rd_data_edge_detect_r before stable DQ
always @(posedge clk) begin
if (rst)
flag_init <= #TCQ 1'b1;
else if ((wl_state_r == WL_WAIT) && ((wl_state_r1 == WL_INIT_FINE_INC_WAIT) ||
(wl_state_r1 == WL_INIT_FINE_DEC_WAIT)))
flag_init <= #TCQ 1'b0;
end
//checking for transition from 0 to 1
always @(posedge clk)begin
if (rst | flag_ck_negedge | flag_init | (wl_tap_count_r < 'd1) |
inhibit_edge_detect_r)
rd_data_edge_detect_r <= #TCQ {DQS_WIDTH{1'b0}};
else if (rd_data_edge_detect_r[dqs_count_r] == 1'b1) begin
if ((wl_state_r == WL_FINE_DEC) || (wl_state_r == WL_FINE_DEC_WAIT) || (wl_state_r == WL_FINE_DEC_WAIT1) ||
(wl_state_r == WL_CORSE_INC) || (wl_state_r == WL_CORSE_INC_WAIT) || (wl_state_r == WL_CORSE_INC_WAIT_TMP) ||
(wl_state_r == WL_CORSE_INC_WAIT1) || (wl_state_r == WL_CORSE_INC_WAIT2))
rd_data_edge_detect_r <= #TCQ {DQS_WIDTH{1'b0}};
else
rd_data_edge_detect_r <= #TCQ rd_data_edge_detect_r;
end else if (rd_data_previous_r[dqs_count_r] && (stable_cnt < 'd14))
rd_data_edge_detect_r <= #TCQ {DQS_WIDTH{1'b0}};
else
rd_data_edge_detect_r <= #TCQ (~rd_data_previous_r & rd_data_rise_wl_r);
end
// registring the write level start signal
always@(posedge clk) begin
wr_level_start_r <= #TCQ wr_level_start;
end
// Assign dqs_count_r to dqs_count_w to perform the shift operation
// instead of multiply operation
assign dqs_count_w = {2'b00, dqs_count_r};
assign oclk_count_w = {2'b00, oclkdelay_calib_cnt};
always @(posedge clk) begin
if (rst)
incdec_wait_cnt <= #TCQ 'd0;
else if ((wl_state_r == WL_FINE_DEC_WAIT1) ||
(wl_state_r == WL_INIT_FINE_DEC_WAIT1) ||
(wl_state_r == WL_CORSE_INC_WAIT_TMP))
incdec_wait_cnt <= #TCQ incdec_wait_cnt + 1;
else
incdec_wait_cnt <= #TCQ 'd0;
end
// state machine to initiate the write leveling sequence
// The state machine operates on one byte at a time.
// It will increment the delays to the DQS OSERDES
// and sample the DQ from the memory. When it detects
// a transition from 1 to 0 then the write leveling is considered
// done.
always @(posedge clk) begin
if(rst)begin
wrlvl_err <= #TCQ 1'b0;
wr_level_done_r <= #TCQ 1'b0;
wrlvl_rank_done_r <= #TCQ 1'b0;
dqs_count_r <= #TCQ {DQS_CNT_WIDTH+1{1'b0}};
dq_cnt_inc <= #TCQ 1'b1;
rank_cnt_r <= #TCQ 2'b00;
wl_state_r <= #TCQ WL_IDLE;
wl_state_r1 <= #TCQ WL_IDLE;
inhibit_edge_detect_r <= #TCQ 1'b1;
wl_edge_detect_valid_r <= #TCQ 1'b0;
wl_tap_count_r <= #TCQ 6'd0;
fine_dec_cnt <= #TCQ 6'd0;
for (r = 0; r < DQS_WIDTH; r = r + 1) begin
fine_inc[r] <= #TCQ 6'b0;
corse_dec[r] <= #TCQ 3'b0;
corse_inc[r] <= #TCQ 3'b0;
corse_cnt[r] <= #TCQ 3'b0;
end
dual_rnk_dec <= #TCQ 1'b0;
fast_cal_fine_cnt <= #TCQ FAST_CAL_FINE;
fast_cal_coarse_cnt <= #TCQ FAST_CAL_COARSE;
final_corse_dec <= #TCQ 1'b0;
//zero_tran_r <= #TCQ 1'b0;
wrlvl_redo_corse_inc <= #TCQ 'd0;
end else begin
wl_state_r1 <= #TCQ wl_state_r;
case (wl_state_r)
WL_IDLE: begin
wrlvl_rank_done_r <= #TCQ 1'd0;
inhibit_edge_detect_r <= #TCQ 1'b1;
if (wrlvl_byte_redo && ~wrlvl_byte_redo_r) begin
wr_level_done_r <= #TCQ 1'b0;
dqs_count_r <= #TCQ wrcal_cnt;
corse_cnt[wrcal_cnt] <= #TCQ final_coarse_tap[wrcal_cnt];
wl_tap_count_r <= #TCQ smallest[wrcal_cnt];
if (early1_data &&
(((final_coarse_tap[wrcal_cnt] < 'd6) && (CLK_PERIOD/nCK_PER_CLK <= 2500)) ||
((final_coarse_tap[wrcal_cnt] < 'd3) && (CLK_PERIOD/nCK_PER_CLK > 2500))))
wrlvl_redo_corse_inc <= #TCQ REDO_COARSE;
else if (early2_data && (final_coarse_tap[wrcal_cnt] < 'd2))
wrlvl_redo_corse_inc <= #TCQ 3'd6;
else begin
wl_state_r <= #TCQ WL_IDLE;
wrlvl_err <= #TCQ 1'b1;
end
end else if (wrlvl_final && ~wrlvl_final_r) begin
wr_level_done_r <= #TCQ 1'b0;
dqs_count_r <= #TCQ 'd0;
end
// verilint STARC-2.2.3.3 off
if(!wr_level_done_r & wr_level_start_r & wl_sm_start) begin
if (SIM_CAL_OPTION == "FAST_CAL")
wl_state_r <= #TCQ WL_FINE_INC;
else
wl_state_r <= #TCQ WL_INIT;
end
end
// verilint STARC-2.2.3.3 on
WL_INIT: begin
wl_edge_detect_valid_r <= #TCQ 1'b0;
inhibit_edge_detect_r <= #TCQ 1'b1;
wrlvl_rank_done_r <= #TCQ 1'd0;
//zero_tran_r <= #TCQ 1'b0;
if (wrlvl_final)
corse_cnt[dqs_count_w ] <= #TCQ final_coarse_tap[dqs_count_w ];
if (wrlvl_byte_redo) begin
if (|wl_tap_count_r) begin
wl_state_r <= #TCQ WL_FINE_DEC;
fine_dec_cnt <= #TCQ wl_tap_count_r;
end else if ((corse_cnt[dqs_count_w] + wrlvl_redo_corse_inc) <= 'd7)
wl_state_r <= #TCQ WL_CORSE_INC;
else begin
wl_state_r <= #TCQ WL_IDLE;
wrlvl_err <= #TCQ 1'b1;
end
end else if(wl_sm_start)
wl_state_r <= #TCQ WL_INIT_FINE_INC;
end
// Initially Phaser_Out fine delay taps incremented
// until stable_cnt=14. A stable_cnt of 14 indicates
// that rd_data_rise_wl_r=rd_data_previous_r for 14 fine
// tap increments. This is done to inhibit false 0->1
// edge detection when DQS is initially aligned to the
// negedge of CK
WL_INIT_FINE_INC: begin
wl_state_r <= #TCQ WL_INIT_FINE_INC_WAIT1;
wl_tap_count_r <= #TCQ wl_tap_count_r + 1'b1;
final_corse_dec <= #TCQ 1'b0;
end
WL_INIT_FINE_INC_WAIT1: begin
if (wl_sm_start)
wl_state_r <= #TCQ WL_INIT_FINE_INC_WAIT;
end
// Case1: stable value of rd_data_previous_r=0 then
// proceed to 0->1 edge detection.
// Case2: stable value of rd_data_previous_r=1 then
// decrement fine taps to '0' and proceed to 0->1
// edge detection. Need to decrement in this case to
// make sure a valid 0->1 transition was not left
// undetected.
WL_INIT_FINE_INC_WAIT: begin
if (wl_sm_start) begin
if (stable_cnt < 'd14)
wl_state_r <= #TCQ WL_INIT_FINE_INC;
else if (~rd_data_previous_r[dqs_count_r]) begin
wl_state_r <= #TCQ WL_WAIT;
inhibit_edge_detect_r <= #TCQ 1'b0;
end else begin
wl_state_r <= #TCQ WL_INIT_FINE_DEC;
fine_dec_cnt <= #TCQ wl_tap_count_r;
end
end
end
// Case2: stable value of rd_data_previous_r=1 then
// decrement fine taps to '0' and proceed to 0->1
// edge detection. Need to decrement in this case to
// make sure a valid 0->1 transition was not left
// undetected.
WL_INIT_FINE_DEC: begin
wl_tap_count_r <= #TCQ 'd0;
wl_state_r <= #TCQ WL_INIT_FINE_DEC_WAIT1;
if (fine_dec_cnt > 6'd0)
fine_dec_cnt <= #TCQ fine_dec_cnt - 1;
else
fine_dec_cnt <= #TCQ fine_dec_cnt;
end
WL_INIT_FINE_DEC_WAIT1: begin
if (incdec_wait_cnt == 'd8)
wl_state_r <= #TCQ WL_INIT_FINE_DEC_WAIT;
end
WL_INIT_FINE_DEC_WAIT: begin
if (fine_dec_cnt > 6'd0) begin
wl_state_r <= #TCQ WL_INIT_FINE_DEC;
inhibit_edge_detect_r <= #TCQ 1'b1;
end else begin
wl_state_r <= #TCQ WL_WAIT;
inhibit_edge_detect_r <= #TCQ 1'b0;
end
end
// Inc DQS Phaser_Out Stage2 Fine Delay line
WL_FINE_INC: begin
wl_edge_detect_valid_r <= #TCQ 1'b0;
if (SIM_CAL_OPTION == "FAST_CAL") begin
wl_state_r <= #TCQ WL_FINE_INC_WAIT;
if (fast_cal_fine_cnt > 'd0)
fast_cal_fine_cnt <= #TCQ fast_cal_fine_cnt - 1;
else
fast_cal_fine_cnt <= #TCQ fast_cal_fine_cnt;
end else if (wr_level_done_r5) begin
wl_tap_count_r <= #TCQ 'd0;
wl_state_r <= #TCQ WL_FINE_INC_WAIT;
if (|fine_inc[dqs_count_w])
fine_inc[dqs_count_w] <= #TCQ fine_inc[dqs_count_w] - 1;
end else begin
wl_state_r <= #TCQ WL_WAIT;
wl_tap_count_r <= #TCQ wl_tap_count_r + 1'b1;
end
end
WL_FINE_INC_WAIT: begin
if (SIM_CAL_OPTION == "FAST_CAL") begin
if (fast_cal_fine_cnt > 'd0)
wl_state_r <= #TCQ WL_FINE_INC;
else if (fast_cal_coarse_cnt > 'd0)
wl_state_r <= #TCQ WL_CORSE_INC;
else
wl_state_r <= #TCQ WL_DQS_CNT;
end else if (|fine_inc[dqs_count_w])
wl_state_r <= #TCQ WL_FINE_INC;
else if (dqs_count_r == (DQS_WIDTH-1))
wl_state_r <= #TCQ WL_IDLE;
else begin
wl_state_r <= #TCQ WL_2RANK_FINAL_TAP;
dqs_count_r <= #TCQ dqs_count_r + 1;
end
end
WL_FINE_DEC: begin
wl_edge_detect_valid_r <= #TCQ 1'b0;
wl_tap_count_r <= #TCQ 'd0;
wl_state_r <= #TCQ WL_FINE_DEC_WAIT1;
if (fine_dec_cnt > 6'd0)
fine_dec_cnt <= #TCQ fine_dec_cnt - 1;
else
fine_dec_cnt <= #TCQ fine_dec_cnt;
end
WL_FINE_DEC_WAIT1: begin
if (incdec_wait_cnt == 'd8)
wl_state_r <= #TCQ WL_FINE_DEC_WAIT;
end
WL_FINE_DEC_WAIT: begin
if (fine_dec_cnt > 6'd0)
wl_state_r <= #TCQ WL_FINE_DEC;
//else if (zero_tran_r)
// wl_state_r <= #TCQ WL_DQS_CNT;
else if (dual_rnk_dec) begin
if (|corse_dec[dqs_count_r])
wl_state_r <= #TCQ WL_CORSE_DEC;
else
wl_state_r <= #TCQ WL_2RANK_DQS_CNT;
end else if (wrlvl_byte_redo) begin
if ((corse_cnt[dqs_count_w] + wrlvl_redo_corse_inc) <= 'd7)
wl_state_r <= #TCQ WL_CORSE_INC;
else begin
wl_state_r <= #TCQ WL_IDLE;
wrlvl_err <= #TCQ 1'b1;
end
end else
wl_state_r <= #TCQ WL_CORSE_INC;
end
WL_CORSE_DEC: begin
wl_state_r <= #TCQ WL_CORSE_DEC_WAIT;
dual_rnk_dec <= #TCQ 1'b0;
if (|corse_dec[dqs_count_r])
corse_dec[dqs_count_r] <= #TCQ corse_dec[dqs_count_r] - 1;
else
corse_dec[dqs_count_r] <= #TCQ corse_dec[dqs_count_r];
end
WL_CORSE_DEC_WAIT: begin
if (wl_sm_start) begin
//if (|corse_dec[dqs_count_r])
// wl_state_r <= #TCQ WL_CORSE_DEC;
if (|corse_dec[dqs_count_r])
wl_state_r <= #TCQ WL_CORSE_DEC_WAIT1;
else
wl_state_r <= #TCQ WL_2RANK_DQS_CNT;
end
end
WL_CORSE_DEC_WAIT1: begin
if (wl_sm_start)
wl_state_r <= #TCQ WL_CORSE_DEC;
end
WL_CORSE_INC: begin
wl_state_r <= #TCQ WL_CORSE_INC_WAIT_TMP;
if (SIM_CAL_OPTION == "FAST_CAL") begin
if (fast_cal_coarse_cnt > 'd0)
fast_cal_coarse_cnt <= #TCQ fast_cal_coarse_cnt - 1;
else
fast_cal_coarse_cnt <= #TCQ fast_cal_coarse_cnt;
end else if (wrlvl_byte_redo) begin
corse_cnt[dqs_count_w] <= #TCQ corse_cnt[dqs_count_w] + 1;
if (|wrlvl_redo_corse_inc)
wrlvl_redo_corse_inc <= #TCQ wrlvl_redo_corse_inc - 1;
end else if (~wr_level_done_r5)
corse_cnt[dqs_count_r] <= #TCQ corse_cnt[dqs_count_r] + 1;
else if (|corse_inc[dqs_count_w])
corse_inc[dqs_count_w] <= #TCQ corse_inc[dqs_count_w] - 1;
end
WL_CORSE_INC_WAIT_TMP: begin
if (incdec_wait_cnt == 'd8)
wl_state_r <= #TCQ WL_CORSE_INC_WAIT;
end
WL_CORSE_INC_WAIT: begin
if (SIM_CAL_OPTION == "FAST_CAL") begin
if (fast_cal_coarse_cnt > 'd0)
wl_state_r <= #TCQ WL_CORSE_INC;
else
wl_state_r <= #TCQ WL_DQS_CNT;
end else if (wrlvl_byte_redo) begin
if (|wrlvl_redo_corse_inc)
wl_state_r <= #TCQ WL_CORSE_INC;
else begin
wl_state_r <= #TCQ WL_INIT_FINE_INC;
inhibit_edge_detect_r <= #TCQ 1'b1;
end
end else if (~wr_level_done_r5 && wl_sm_start)
wl_state_r <= #TCQ WL_CORSE_INC_WAIT1;
else if (wr_level_done_r5) begin
if (|corse_inc[dqs_count_r])
wl_state_r <= #TCQ WL_CORSE_INC;
else if (|fine_inc[dqs_count_w])
wl_state_r <= #TCQ WL_FINE_INC;
else if (dqs_count_r == (DQS_WIDTH-1))
wl_state_r <= #TCQ WL_IDLE;
else begin
wl_state_r <= #TCQ WL_2RANK_FINAL_TAP;
dqs_count_r <= #TCQ dqs_count_r + 1;
end
end
end
WL_CORSE_INC_WAIT1: begin
if (wl_sm_start)
wl_state_r <= #TCQ WL_CORSE_INC_WAIT2;
end
WL_CORSE_INC_WAIT2: begin
if (wl_sm_start)
wl_state_r <= #TCQ WL_WAIT;
end
WL_WAIT: begin
if (wl_sm_start)
wl_state_r <= #TCQ WL_EDGE_CHECK;
end
WL_EDGE_CHECK: begin // Look for the edge
if (wl_edge_detect_valid_r == 1'b0) begin
wl_state_r <= #TCQ WL_WAIT;
wl_edge_detect_valid_r <= #TCQ 1'b1;
end
// 0->1 transition detected with DQS
else if(rd_data_edge_detect_r[dqs_count_r] &&
wl_edge_detect_valid_r)
begin
wl_tap_count_r <= #TCQ wl_tap_count_r;
if ((SIM_CAL_OPTION == "FAST_CAL") || (RANKS < 2) ||
~oclkdelay_calib_done)
wl_state_r <= #TCQ WL_DQS_CNT;
else
wl_state_r <= #TCQ WL_2RANK_TAP_DEC;
end
// For initial writes check only upto 56 taps. Reserving the
// remaining taps for OCLK calibration.
else if((~wrlvl_tap_done_r) && (wl_tap_count_r > 6'd55)) begin
if (corse_cnt[dqs_count_r] < COARSE_TAPS) begin
wl_state_r <= #TCQ WL_FINE_DEC;
fine_dec_cnt <= #TCQ wl_tap_count_r;
end else begin
wrlvl_err <= #TCQ 1'b1;
wl_state_r <= #TCQ WL_IDLE;
end
end else begin
if (wl_tap_count_r < 6'd56) //for reuse wrlvl for complex ocal
wl_state_r <= #TCQ WL_FINE_INC;
else if (corse_cnt[dqs_count_r] < COARSE_TAPS) begin
wl_state_r <= #TCQ WL_FINE_DEC;
fine_dec_cnt <= #TCQ wl_tap_count_r;
end else begin
wrlvl_err <= #TCQ 1'b1;
wl_state_r <= #TCQ WL_IDLE;
end
end
end
WL_2RANK_TAP_DEC: begin
wl_state_r <= #TCQ WL_FINE_DEC;
fine_dec_cnt <= #TCQ wl_tap_count_r;
for (m = 0; m < DQS_WIDTH; m = m + 1)
corse_dec[m] <= #TCQ corse_cnt[m];
wl_edge_detect_valid_r <= #TCQ 1'b0;
dual_rnk_dec <= #TCQ 1'b1;
end
WL_DQS_CNT: begin
if ((SIM_CAL_OPTION == "FAST_CAL") ||
(dqs_count_r == (DQS_WIDTH-1)) ||
wrlvl_byte_redo) begin
dqs_count_r <= #TCQ dqs_count_r;
dq_cnt_inc <= #TCQ 1'b0;
end else begin
dqs_count_r <= #TCQ dqs_count_r + 1'b1;
dq_cnt_inc <= #TCQ 1'b1;
end
wl_state_r <= #TCQ WL_DQS_CHECK;
wl_edge_detect_valid_r <= #TCQ 1'b0;
end
WL_2RANK_DQS_CNT: begin
if ((SIM_CAL_OPTION == "FAST_CAL") ||
(dqs_count_r == (DQS_WIDTH-1))) begin
dqs_count_r <= #TCQ dqs_count_r;
dq_cnt_inc <= #TCQ 1'b0;
end else begin
dqs_count_r <= #TCQ dqs_count_r + 1'b1;
dq_cnt_inc <= #TCQ 1'b1;
end
wl_state_r <= #TCQ WL_DQS_CHECK;
wl_edge_detect_valid_r <= #TCQ 1'b0;
dual_rnk_dec <= #TCQ 1'b0;
end
WL_DQS_CHECK: begin // check if all DQS have been calibrated
wl_tap_count_r <= #TCQ 'd0;
if (dq_cnt_inc == 1'b0)begin
wrlvl_rank_done_r <= #TCQ 1'd1;
for (t = 0; t < DQS_WIDTH; t = t + 1)
corse_cnt[t] <= #TCQ 3'b0;
if ((SIM_CAL_OPTION == "FAST_CAL") || (RANKS < 2) || ~oclkdelay_calib_done) begin
wl_state_r <= #TCQ WL_IDLE;
if (wrlvl_byte_redo)
dqs_count_r <= #TCQ dqs_count_r;
else
dqs_count_r <= #TCQ 'd0;
end else if (rank_cnt_r == RANKS-1) begin
dqs_count_r <= #TCQ dqs_count_r;
if (RANKS > 1)
wl_state_r <= #TCQ WL_2RANK_FINAL_TAP;
else
wl_state_r <= #TCQ WL_IDLE;
end else begin
wl_state_r <= #TCQ WL_INIT;
dqs_count_r <= #TCQ 'd0;
end
if ((SIM_CAL_OPTION == "FAST_CAL") ||
(rank_cnt_r == RANKS-1)) begin
wr_level_done_r <= #TCQ 1'd1;
rank_cnt_r <= #TCQ 2'b00;
end else begin
wr_level_done_r <= #TCQ 1'd0;
rank_cnt_r <= #TCQ rank_cnt_r + 1'b1;
end
end else
wl_state_r <= #TCQ WL_INIT;
end
WL_2RANK_FINAL_TAP: begin
if (wr_level_done_r4 && ~wr_level_done_r5) begin
for(u = 0; u < DQS_WIDTH; u = u + 1) begin
corse_inc[u] <= #TCQ final_coarse_tap[u];
fine_inc[u] <= #TCQ final_val[u];
end
dqs_count_r <= #TCQ 'd0;
end else if (wr_level_done_r5) begin
if (|corse_inc[dqs_count_r])
wl_state_r <= #TCQ WL_CORSE_INC;
else if (|fine_inc[dqs_count_w])
wl_state_r <= #TCQ WL_FINE_INC;
end
end
endcase
end
end // always @ (posedge clk)
endmodule
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