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module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module
input wire load_a_i,
input wire load_b_i,
input wire [EW-1:0] Data_A_i,
input wire [EW-1:0] Data_B_i,
input wire Add_Subt_i,
///////////////////////////////////////////////////////////////////77
output wire [EW-1:0] Data_Result_o,
output wire Overflow_flag_o,
output wire Underflow_flag_o
);
//wire [EW-1:0] Data_B;
wire [EW:0] Data_S;
/////////////////////////////////////////7
//genvar j;
//for (j=0; j<EW; j=j+1)begin
// assign Data_B[j] = PreData_B_i[j] ^ Add_Subt_i;
//end
/////////////////////////////////////////
add_sub_carry_out #(.W(EW)) exp_add_subt(
.op_mode (Add_Subt_i),
.Data_A (Data_A_i),
.Data_B (Data_B_i),
.Data_S (Data_S)
);
//assign Overflow_flag_o = 1'b0;
//assign Underflow_flag_o = 1'b0;
Comparators #(.W_Exp(EW+1)) array_comparators(
.exp(Data_S),
.overflow(Overflow_flag),
.underflow(Underflow_flag)
);
RegisterAdd #(.W(EW)) exp_result(
.clk (clk),
.rst (rst),
.load (load_a_i),
.D (Data_S[EW-1:0]),
.Q (Data_Result_o)
);
RegisterAdd #(.W(1)) Overflow (
.clk(clk),
.rst(rst),
.load(load_a_i),
.D(Overflow_flag),
.Q(Overflow_flag_o)
);
RegisterAdd #(.W(1)) Underflow (
.clk(clk),
.rst(rst),
.load(load_b_i),
.D(Underflow_flag),
.Q(Underflow_flag_o)
);
endmodule |
module
input wire load_a_i,
input wire load_b_i,
input wire [EW-1:0] Data_A_i,
input wire [EW-1:0] Data_B_i,
input wire Add_Subt_i,
///////////////////////////////////////////////////////////////////77
output wire [EW-1:0] Data_Result_o,
output wire Overflow_flag_o,
output wire Underflow_flag_o
);
//wire [EW-1:0] Data_B;
wire [EW:0] Data_S;
/////////////////////////////////////////7
//genvar j;
//for (j=0; j<EW; j=j+1)begin
// assign Data_B[j] = PreData_B_i[j] ^ Add_Subt_i;
//end
/////////////////////////////////////////
add_sub_carry_out #(.W(EW)) exp_add_subt(
.op_mode (Add_Subt_i),
.Data_A (Data_A_i),
.Data_B (Data_B_i),
.Data_S (Data_S)
);
//assign Overflow_flag_o = 1'b0;
//assign Underflow_flag_o = 1'b0;
Comparators #(.W_Exp(EW+1)) array_comparators(
.exp(Data_S),
.overflow(Overflow_flag),
.underflow(Underflow_flag)
);
RegisterAdd #(.W(EW)) exp_result(
.clk (clk),
.rst (rst),
.load (load_a_i),
.D (Data_S[EW-1:0]),
.Q (Data_Result_o)
);
RegisterAdd #(.W(1)) Overflow (
.clk(clk),
.rst(rst),
.load(load_a_i),
.D(Overflow_flag),
.Q(Overflow_flag_o)
);
RegisterAdd #(.W(1)) Underflow (
.clk(clk),
.rst(rst),
.load(load_b_i),
.D(Underflow_flag),
.Q(Underflow_flag_o)
);
endmodule |
module
input wire load_a_i,
input wire load_b_i,
input wire [EW-1:0] Data_A_i,
input wire [EW-1:0] Data_B_i,
input wire Add_Subt_i,
///////////////////////////////////////////////////////////////////77
output wire [EW-1:0] Data_Result_o,
output wire Overflow_flag_o,
output wire Underflow_flag_o
);
//wire [EW-1:0] Data_B;
wire [EW:0] Data_S;
/////////////////////////////////////////7
//genvar j;
//for (j=0; j<EW; j=j+1)begin
// assign Data_B[j] = PreData_B_i[j] ^ Add_Subt_i;
//end
/////////////////////////////////////////
add_sub_carry_out #(.W(EW)) exp_add_subt(
.op_mode (Add_Subt_i),
.Data_A (Data_A_i),
.Data_B (Data_B_i),
.Data_S (Data_S)
);
//assign Overflow_flag_o = 1'b0;
//assign Underflow_flag_o = 1'b0;
Comparators #(.W_Exp(EW+1)) array_comparators(
.exp(Data_S),
.overflow(Overflow_flag),
.underflow(Underflow_flag)
);
RegisterAdd #(.W(EW)) exp_result(
.clk (clk),
.rst (rst),
.load (load_a_i),
.D (Data_S[EW-1:0]),
.Q (Data_Result_o)
);
RegisterAdd #(.W(1)) Overflow (
.clk(clk),
.rst(rst),
.load(load_a_i),
.D(Overflow_flag),
.Q(Overflow_flag_o)
);
RegisterAdd #(.W(1)) Underflow (
.clk(clk),
.rst(rst),
.load(load_b_i),
.D(Underflow_flag),
.Q(Underflow_flag_o)
);
endmodule |
module vga (
// Wishbone signals
input wb_clk_i, // 25 Mhz VDU clock
input wb_rst_i,
input [15:0] wb_dat_i,
output [15:0] wb_dat_o,
input [16:1] wb_adr_i,
input wb_we_i,
input wb_tga_i,
input [ 1:0] wb_sel_i,
input wb_stb_i,
input wb_cyc_i,
output wb_ack_o,
// VGA pad signals
output [ 3:0] vga_red_o,
output [ 3:0] vga_green_o,
output [ 3:0] vga_blue_o,
output horiz_sync,
output vert_sync,
// CSR SRAM master interface
output [17:1] csrm_adr_o,
output [ 1:0] csrm_sel_o,
output csrm_we_o,
output [15:0] csrm_dat_o,
input [15:0] csrm_dat_i
);
// Registers and nets
//
// csr address
reg [17:1] csr_adr_i;
reg csr_stb_i;
// Config wires
wire [15:0] conf_wb_dat_o;
wire conf_wb_ack_o;
// Mem wires
wire [15:0] mem_wb_dat_o;
wire mem_wb_ack_o;
// LCD wires
wire [17:1] csr_adr_o;
wire [15:0] csr_dat_i;
wire csr_stb_o;
wire v_retrace;
wire vh_retrace;
wire w_vert_sync;
// VGA configuration registers
wire shift_reg1;
wire graphics_alpha;
wire memory_mapping1;
wire [ 1:0] write_mode;
wire [ 1:0] raster_op;
wire read_mode;
wire [ 7:0] bitmask;
wire [ 3:0] set_reset;
wire [ 3:0] enable_set_reset;
wire [ 3:0] map_mask;
wire x_dotclockdiv2;
wire chain_four;
wire [ 1:0] read_map_select;
wire [ 3:0] color_compare;
wire [ 3:0] color_dont_care;
// Wishbone master to SRAM
wire [17:1] wbm_adr_o;
wire [ 1:0] wbm_sel_o;
wire wbm_we_o;
wire [15:0] wbm_dat_o;
wire [15:0] wbm_dat_i;
wire wbm_stb_o;
wire wbm_ack_i;
wire stb;
// CRT wires
wire [ 5:0] cur_start;
wire [ 5:0] cur_end;
wire [15:0] start_addr;
wire [ 4:0] vcursor;
wire [ 6:0] hcursor;
wire [ 6:0] horiz_total;
wire [ 6:0] end_horiz;
wire [ 6:0] st_hor_retr;
wire [ 4:0] end_hor_retr;
wire [ 9:0] vert_total;
wire [ 9:0] end_vert;
wire [ 9:0] st_ver_retr;
wire [ 3:0] end_ver_retr;
// attribute_ctrl wires
wire [3:0] pal_addr;
wire pal_we;
wire [7:0] pal_read;
wire [7:0] pal_write;
// dac_regs wires
wire dac_we;
wire [1:0] dac_read_data_cycle;
wire [7:0] dac_read_data_register;
wire [3:0] dac_read_data;
wire [1:0] dac_write_data_cycle;
wire [7:0] dac_write_data_register;
wire [3:0] dac_write_data;
// Module instances
//
vga_config_iface config_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wb_dat_i (wb_dat_i),
.wb_dat_o (conf_wb_dat_o),
.wb_adr_i (wb_adr_i[4:1]),
.wb_we_i (wb_we_i),
.wb_sel_i (wb_sel_i),
.wb_stb_i (stb & wb_tga_i),
.wb_ack_o (conf_wb_ack_o),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.x_dotclockdiv2 (x_dotclockdiv2),
.chain_four (chain_four),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.cur_start (cur_start),
.cur_end (cur_end),
.start_addr (start_addr),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_lcd lcd (
.clk (wb_clk_i),
.rst (wb_rst_i),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.csr_adr_o (csr_adr_o),
.csr_dat_i (csr_dat_i),
.csr_stb_o (csr_stb_o),
.vga_red_o (vga_red_o),
.vga_green_o (vga_green_o),
.vga_blue_o (vga_blue_o),
.horiz_sync (horiz_sync),
.vert_sync (w_vert_sync),
.cur_start (cur_start),
.cur_end (cur_end),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.x_dotclockdiv2 (x_dotclockdiv2),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_cpu_mem_iface cpu_mem_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wbs_adr_i (wb_adr_i),
.wbs_sel_i (wb_sel_i),
.wbs_we_i (wb_we_i),
.wbs_dat_i (wb_dat_i),
.wbs_dat_o (mem_wb_dat_o),
.wbs_stb_i (stb & !wb_tga_i),
.wbs_ack_o (mem_wb_ack_o),
.wbm_adr_o (wbm_adr_o),
.wbm_sel_o (wbm_sel_o),
.wbm_we_o (wbm_we_o),
.wbm_dat_o (wbm_dat_o),
.wbm_dat_i (wbm_dat_i),
.wbm_stb_o (wbm_stb_o),
.wbm_ack_i (wbm_ack_i),
.chain_four (chain_four),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care)
);
vga_mem_arbitrer mem_arbitrer (
.clk_i (wb_clk_i),
.rst_i (wb_rst_i),
.wb_adr_i (wbm_adr_o),
.wb_sel_i (wbm_sel_o),
.wb_we_i (wbm_we_o),
.wb_dat_i (wbm_dat_o),
.wb_dat_o (wbm_dat_i),
.wb_stb_i (wbm_stb_o),
.wb_ack_o (wbm_ack_i),
.csr_adr_i (csr_adr_i),
.csr_dat_o (csr_dat_i),
.csr_stb_i (csr_stb_i),
.csrm_adr_o (csrm_adr_o),
.csrm_sel_o (csrm_sel_o),
.csrm_we_o (csrm_we_o),
.csrm_dat_o (csrm_dat_o),
.csrm_dat_i (csrm_dat_i)
);
// Continous assignments
assign wb_dat_o = wb_tga_i ? conf_wb_dat_o : mem_wb_dat_o;
assign wb_ack_o = wb_tga_i ? conf_wb_ack_o : mem_wb_ack_o;
assign stb = wb_stb_i & wb_cyc_i;
assign vert_sync = ~graphics_alpha ^ w_vert_sync;
// Behaviour
// csr_adr_i
always @(posedge wb_clk_i)
csr_adr_i <= wb_rst_i ? 17'h0 : csr_adr_o + start_addr[15:1];
// csr_stb_i
always @(posedge wb_clk_i)
csr_stb_i <= wb_rst_i ? 1'b0 : csr_stb_o;
endmodule |
module vga (
// Wishbone signals
input wb_clk_i, // 25 Mhz VDU clock
input wb_rst_i,
input [15:0] wb_dat_i,
output [15:0] wb_dat_o,
input [16:1] wb_adr_i,
input wb_we_i,
input wb_tga_i,
input [ 1:0] wb_sel_i,
input wb_stb_i,
input wb_cyc_i,
output wb_ack_o,
// VGA pad signals
output [ 3:0] vga_red_o,
output [ 3:0] vga_green_o,
output [ 3:0] vga_blue_o,
output horiz_sync,
output vert_sync,
// CSR SRAM master interface
output [17:1] csrm_adr_o,
output [ 1:0] csrm_sel_o,
output csrm_we_o,
output [15:0] csrm_dat_o,
input [15:0] csrm_dat_i
);
// Registers and nets
//
// csr address
reg [17:1] csr_adr_i;
reg csr_stb_i;
// Config wires
wire [15:0] conf_wb_dat_o;
wire conf_wb_ack_o;
// Mem wires
wire [15:0] mem_wb_dat_o;
wire mem_wb_ack_o;
// LCD wires
wire [17:1] csr_adr_o;
wire [15:0] csr_dat_i;
wire csr_stb_o;
wire v_retrace;
wire vh_retrace;
wire w_vert_sync;
// VGA configuration registers
wire shift_reg1;
wire graphics_alpha;
wire memory_mapping1;
wire [ 1:0] write_mode;
wire [ 1:0] raster_op;
wire read_mode;
wire [ 7:0] bitmask;
wire [ 3:0] set_reset;
wire [ 3:0] enable_set_reset;
wire [ 3:0] map_mask;
wire x_dotclockdiv2;
wire chain_four;
wire [ 1:0] read_map_select;
wire [ 3:0] color_compare;
wire [ 3:0] color_dont_care;
// Wishbone master to SRAM
wire [17:1] wbm_adr_o;
wire [ 1:0] wbm_sel_o;
wire wbm_we_o;
wire [15:0] wbm_dat_o;
wire [15:0] wbm_dat_i;
wire wbm_stb_o;
wire wbm_ack_i;
wire stb;
// CRT wires
wire [ 5:0] cur_start;
wire [ 5:0] cur_end;
wire [15:0] start_addr;
wire [ 4:0] vcursor;
wire [ 6:0] hcursor;
wire [ 6:0] horiz_total;
wire [ 6:0] end_horiz;
wire [ 6:0] st_hor_retr;
wire [ 4:0] end_hor_retr;
wire [ 9:0] vert_total;
wire [ 9:0] end_vert;
wire [ 9:0] st_ver_retr;
wire [ 3:0] end_ver_retr;
// attribute_ctrl wires
wire [3:0] pal_addr;
wire pal_we;
wire [7:0] pal_read;
wire [7:0] pal_write;
// dac_regs wires
wire dac_we;
wire [1:0] dac_read_data_cycle;
wire [7:0] dac_read_data_register;
wire [3:0] dac_read_data;
wire [1:0] dac_write_data_cycle;
wire [7:0] dac_write_data_register;
wire [3:0] dac_write_data;
// Module instances
//
vga_config_iface config_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wb_dat_i (wb_dat_i),
.wb_dat_o (conf_wb_dat_o),
.wb_adr_i (wb_adr_i[4:1]),
.wb_we_i (wb_we_i),
.wb_sel_i (wb_sel_i),
.wb_stb_i (stb & wb_tga_i),
.wb_ack_o (conf_wb_ack_o),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.x_dotclockdiv2 (x_dotclockdiv2),
.chain_four (chain_four),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.cur_start (cur_start),
.cur_end (cur_end),
.start_addr (start_addr),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_lcd lcd (
.clk (wb_clk_i),
.rst (wb_rst_i),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.csr_adr_o (csr_adr_o),
.csr_dat_i (csr_dat_i),
.csr_stb_o (csr_stb_o),
.vga_red_o (vga_red_o),
.vga_green_o (vga_green_o),
.vga_blue_o (vga_blue_o),
.horiz_sync (horiz_sync),
.vert_sync (w_vert_sync),
.cur_start (cur_start),
.cur_end (cur_end),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.x_dotclockdiv2 (x_dotclockdiv2),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_cpu_mem_iface cpu_mem_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wbs_adr_i (wb_adr_i),
.wbs_sel_i (wb_sel_i),
.wbs_we_i (wb_we_i),
.wbs_dat_i (wb_dat_i),
.wbs_dat_o (mem_wb_dat_o),
.wbs_stb_i (stb & !wb_tga_i),
.wbs_ack_o (mem_wb_ack_o),
.wbm_adr_o (wbm_adr_o),
.wbm_sel_o (wbm_sel_o),
.wbm_we_o (wbm_we_o),
.wbm_dat_o (wbm_dat_o),
.wbm_dat_i (wbm_dat_i),
.wbm_stb_o (wbm_stb_o),
.wbm_ack_i (wbm_ack_i),
.chain_four (chain_four),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care)
);
vga_mem_arbitrer mem_arbitrer (
.clk_i (wb_clk_i),
.rst_i (wb_rst_i),
.wb_adr_i (wbm_adr_o),
.wb_sel_i (wbm_sel_o),
.wb_we_i (wbm_we_o),
.wb_dat_i (wbm_dat_o),
.wb_dat_o (wbm_dat_i),
.wb_stb_i (wbm_stb_o),
.wb_ack_o (wbm_ack_i),
.csr_adr_i (csr_adr_i),
.csr_dat_o (csr_dat_i),
.csr_stb_i (csr_stb_i),
.csrm_adr_o (csrm_adr_o),
.csrm_sel_o (csrm_sel_o),
.csrm_we_o (csrm_we_o),
.csrm_dat_o (csrm_dat_o),
.csrm_dat_i (csrm_dat_i)
);
// Continous assignments
assign wb_dat_o = wb_tga_i ? conf_wb_dat_o : mem_wb_dat_o;
assign wb_ack_o = wb_tga_i ? conf_wb_ack_o : mem_wb_ack_o;
assign stb = wb_stb_i & wb_cyc_i;
assign vert_sync = ~graphics_alpha ^ w_vert_sync;
// Behaviour
// csr_adr_i
always @(posedge wb_clk_i)
csr_adr_i <= wb_rst_i ? 17'h0 : csr_adr_o + start_addr[15:1];
// csr_stb_i
always @(posedge wb_clk_i)
csr_stb_i <= wb_rst_i ? 1'b0 : csr_stb_o;
endmodule |
module vga (
// Wishbone signals
input wb_clk_i, // 25 Mhz VDU clock
input wb_rst_i,
input [15:0] wb_dat_i,
output [15:0] wb_dat_o,
input [16:1] wb_adr_i,
input wb_we_i,
input wb_tga_i,
input [ 1:0] wb_sel_i,
input wb_stb_i,
input wb_cyc_i,
output wb_ack_o,
// VGA pad signals
output [ 3:0] vga_red_o,
output [ 3:0] vga_green_o,
output [ 3:0] vga_blue_o,
output horiz_sync,
output vert_sync,
// CSR SRAM master interface
output [17:1] csrm_adr_o,
output [ 1:0] csrm_sel_o,
output csrm_we_o,
output [15:0] csrm_dat_o,
input [15:0] csrm_dat_i
);
// Registers and nets
//
// csr address
reg [17:1] csr_adr_i;
reg csr_stb_i;
// Config wires
wire [15:0] conf_wb_dat_o;
wire conf_wb_ack_o;
// Mem wires
wire [15:0] mem_wb_dat_o;
wire mem_wb_ack_o;
// LCD wires
wire [17:1] csr_adr_o;
wire [15:0] csr_dat_i;
wire csr_stb_o;
wire v_retrace;
wire vh_retrace;
wire w_vert_sync;
// VGA configuration registers
wire shift_reg1;
wire graphics_alpha;
wire memory_mapping1;
wire [ 1:0] write_mode;
wire [ 1:0] raster_op;
wire read_mode;
wire [ 7:0] bitmask;
wire [ 3:0] set_reset;
wire [ 3:0] enable_set_reset;
wire [ 3:0] map_mask;
wire x_dotclockdiv2;
wire chain_four;
wire [ 1:0] read_map_select;
wire [ 3:0] color_compare;
wire [ 3:0] color_dont_care;
// Wishbone master to SRAM
wire [17:1] wbm_adr_o;
wire [ 1:0] wbm_sel_o;
wire wbm_we_o;
wire [15:0] wbm_dat_o;
wire [15:0] wbm_dat_i;
wire wbm_stb_o;
wire wbm_ack_i;
wire stb;
// CRT wires
wire [ 5:0] cur_start;
wire [ 5:0] cur_end;
wire [15:0] start_addr;
wire [ 4:0] vcursor;
wire [ 6:0] hcursor;
wire [ 6:0] horiz_total;
wire [ 6:0] end_horiz;
wire [ 6:0] st_hor_retr;
wire [ 4:0] end_hor_retr;
wire [ 9:0] vert_total;
wire [ 9:0] end_vert;
wire [ 9:0] st_ver_retr;
wire [ 3:0] end_ver_retr;
// attribute_ctrl wires
wire [3:0] pal_addr;
wire pal_we;
wire [7:0] pal_read;
wire [7:0] pal_write;
// dac_regs wires
wire dac_we;
wire [1:0] dac_read_data_cycle;
wire [7:0] dac_read_data_register;
wire [3:0] dac_read_data;
wire [1:0] dac_write_data_cycle;
wire [7:0] dac_write_data_register;
wire [3:0] dac_write_data;
// Module instances
//
vga_config_iface config_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wb_dat_i (wb_dat_i),
.wb_dat_o (conf_wb_dat_o),
.wb_adr_i (wb_adr_i[4:1]),
.wb_we_i (wb_we_i),
.wb_sel_i (wb_sel_i),
.wb_stb_i (stb & wb_tga_i),
.wb_ack_o (conf_wb_ack_o),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.x_dotclockdiv2 (x_dotclockdiv2),
.chain_four (chain_four),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.cur_start (cur_start),
.cur_end (cur_end),
.start_addr (start_addr),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_lcd lcd (
.clk (wb_clk_i),
.rst (wb_rst_i),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.csr_adr_o (csr_adr_o),
.csr_dat_i (csr_dat_i),
.csr_stb_o (csr_stb_o),
.vga_red_o (vga_red_o),
.vga_green_o (vga_green_o),
.vga_blue_o (vga_blue_o),
.horiz_sync (horiz_sync),
.vert_sync (w_vert_sync),
.cur_start (cur_start),
.cur_end (cur_end),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.x_dotclockdiv2 (x_dotclockdiv2),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_cpu_mem_iface cpu_mem_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wbs_adr_i (wb_adr_i),
.wbs_sel_i (wb_sel_i),
.wbs_we_i (wb_we_i),
.wbs_dat_i (wb_dat_i),
.wbs_dat_o (mem_wb_dat_o),
.wbs_stb_i (stb & !wb_tga_i),
.wbs_ack_o (mem_wb_ack_o),
.wbm_adr_o (wbm_adr_o),
.wbm_sel_o (wbm_sel_o),
.wbm_we_o (wbm_we_o),
.wbm_dat_o (wbm_dat_o),
.wbm_dat_i (wbm_dat_i),
.wbm_stb_o (wbm_stb_o),
.wbm_ack_i (wbm_ack_i),
.chain_four (chain_four),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care)
);
vga_mem_arbitrer mem_arbitrer (
.clk_i (wb_clk_i),
.rst_i (wb_rst_i),
.wb_adr_i (wbm_adr_o),
.wb_sel_i (wbm_sel_o),
.wb_we_i (wbm_we_o),
.wb_dat_i (wbm_dat_o),
.wb_dat_o (wbm_dat_i),
.wb_stb_i (wbm_stb_o),
.wb_ack_o (wbm_ack_i),
.csr_adr_i (csr_adr_i),
.csr_dat_o (csr_dat_i),
.csr_stb_i (csr_stb_i),
.csrm_adr_o (csrm_adr_o),
.csrm_sel_o (csrm_sel_o),
.csrm_we_o (csrm_we_o),
.csrm_dat_o (csrm_dat_o),
.csrm_dat_i (csrm_dat_i)
);
// Continous assignments
assign wb_dat_o = wb_tga_i ? conf_wb_dat_o : mem_wb_dat_o;
assign wb_ack_o = wb_tga_i ? conf_wb_ack_o : mem_wb_ack_o;
assign stb = wb_stb_i & wb_cyc_i;
assign vert_sync = ~graphics_alpha ^ w_vert_sync;
// Behaviour
// csr_adr_i
always @(posedge wb_clk_i)
csr_adr_i <= wb_rst_i ? 17'h0 : csr_adr_o + start_addr[15:1];
// csr_stb_i
always @(posedge wb_clk_i)
csr_stb_i <= wb_rst_i ? 1'b0 : csr_stb_o;
endmodule |
module vga (
// Wishbone signals
input wb_clk_i, // 25 Mhz VDU clock
input wb_rst_i,
input [15:0] wb_dat_i,
output [15:0] wb_dat_o,
input [16:1] wb_adr_i,
input wb_we_i,
input wb_tga_i,
input [ 1:0] wb_sel_i,
input wb_stb_i,
input wb_cyc_i,
output wb_ack_o,
// VGA pad signals
output [ 3:0] vga_red_o,
output [ 3:0] vga_green_o,
output [ 3:0] vga_blue_o,
output horiz_sync,
output vert_sync,
// CSR SRAM master interface
output [17:1] csrm_adr_o,
output [ 1:0] csrm_sel_o,
output csrm_we_o,
output [15:0] csrm_dat_o,
input [15:0] csrm_dat_i
);
// Registers and nets
//
// csr address
reg [17:1] csr_adr_i;
reg csr_stb_i;
// Config wires
wire [15:0] conf_wb_dat_o;
wire conf_wb_ack_o;
// Mem wires
wire [15:0] mem_wb_dat_o;
wire mem_wb_ack_o;
// LCD wires
wire [17:1] csr_adr_o;
wire [15:0] csr_dat_i;
wire csr_stb_o;
wire v_retrace;
wire vh_retrace;
wire w_vert_sync;
// VGA configuration registers
wire shift_reg1;
wire graphics_alpha;
wire memory_mapping1;
wire [ 1:0] write_mode;
wire [ 1:0] raster_op;
wire read_mode;
wire [ 7:0] bitmask;
wire [ 3:0] set_reset;
wire [ 3:0] enable_set_reset;
wire [ 3:0] map_mask;
wire x_dotclockdiv2;
wire chain_four;
wire [ 1:0] read_map_select;
wire [ 3:0] color_compare;
wire [ 3:0] color_dont_care;
// Wishbone master to SRAM
wire [17:1] wbm_adr_o;
wire [ 1:0] wbm_sel_o;
wire wbm_we_o;
wire [15:0] wbm_dat_o;
wire [15:0] wbm_dat_i;
wire wbm_stb_o;
wire wbm_ack_i;
wire stb;
// CRT wires
wire [ 5:0] cur_start;
wire [ 5:0] cur_end;
wire [15:0] start_addr;
wire [ 4:0] vcursor;
wire [ 6:0] hcursor;
wire [ 6:0] horiz_total;
wire [ 6:0] end_horiz;
wire [ 6:0] st_hor_retr;
wire [ 4:0] end_hor_retr;
wire [ 9:0] vert_total;
wire [ 9:0] end_vert;
wire [ 9:0] st_ver_retr;
wire [ 3:0] end_ver_retr;
// attribute_ctrl wires
wire [3:0] pal_addr;
wire pal_we;
wire [7:0] pal_read;
wire [7:0] pal_write;
// dac_regs wires
wire dac_we;
wire [1:0] dac_read_data_cycle;
wire [7:0] dac_read_data_register;
wire [3:0] dac_read_data;
wire [1:0] dac_write_data_cycle;
wire [7:0] dac_write_data_register;
wire [3:0] dac_write_data;
// Module instances
//
vga_config_iface config_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wb_dat_i (wb_dat_i),
.wb_dat_o (conf_wb_dat_o),
.wb_adr_i (wb_adr_i[4:1]),
.wb_we_i (wb_we_i),
.wb_sel_i (wb_sel_i),
.wb_stb_i (stb & wb_tga_i),
.wb_ack_o (conf_wb_ack_o),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.x_dotclockdiv2 (x_dotclockdiv2),
.chain_four (chain_four),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.cur_start (cur_start),
.cur_end (cur_end),
.start_addr (start_addr),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_lcd lcd (
.clk (wb_clk_i),
.rst (wb_rst_i),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.csr_adr_o (csr_adr_o),
.csr_dat_i (csr_dat_i),
.csr_stb_o (csr_stb_o),
.vga_red_o (vga_red_o),
.vga_green_o (vga_green_o),
.vga_blue_o (vga_blue_o),
.horiz_sync (horiz_sync),
.vert_sync (w_vert_sync),
.cur_start (cur_start),
.cur_end (cur_end),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.x_dotclockdiv2 (x_dotclockdiv2),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_cpu_mem_iface cpu_mem_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wbs_adr_i (wb_adr_i),
.wbs_sel_i (wb_sel_i),
.wbs_we_i (wb_we_i),
.wbs_dat_i (wb_dat_i),
.wbs_dat_o (mem_wb_dat_o),
.wbs_stb_i (stb & !wb_tga_i),
.wbs_ack_o (mem_wb_ack_o),
.wbm_adr_o (wbm_adr_o),
.wbm_sel_o (wbm_sel_o),
.wbm_we_o (wbm_we_o),
.wbm_dat_o (wbm_dat_o),
.wbm_dat_i (wbm_dat_i),
.wbm_stb_o (wbm_stb_o),
.wbm_ack_i (wbm_ack_i),
.chain_four (chain_four),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care)
);
vga_mem_arbitrer mem_arbitrer (
.clk_i (wb_clk_i),
.rst_i (wb_rst_i),
.wb_adr_i (wbm_adr_o),
.wb_sel_i (wbm_sel_o),
.wb_we_i (wbm_we_o),
.wb_dat_i (wbm_dat_o),
.wb_dat_o (wbm_dat_i),
.wb_stb_i (wbm_stb_o),
.wb_ack_o (wbm_ack_i),
.csr_adr_i (csr_adr_i),
.csr_dat_o (csr_dat_i),
.csr_stb_i (csr_stb_i),
.csrm_adr_o (csrm_adr_o),
.csrm_sel_o (csrm_sel_o),
.csrm_we_o (csrm_we_o),
.csrm_dat_o (csrm_dat_o),
.csrm_dat_i (csrm_dat_i)
);
// Continous assignments
assign wb_dat_o = wb_tga_i ? conf_wb_dat_o : mem_wb_dat_o;
assign wb_ack_o = wb_tga_i ? conf_wb_ack_o : mem_wb_ack_o;
assign stb = wb_stb_i & wb_cyc_i;
assign vert_sync = ~graphics_alpha ^ w_vert_sync;
// Behaviour
// csr_adr_i
always @(posedge wb_clk_i)
csr_adr_i <= wb_rst_i ? 17'h0 : csr_adr_o + start_addr[15:1];
// csr_stb_i
always @(posedge wb_clk_i)
csr_stb_i <= wb_rst_i ? 1'b0 : csr_stb_o;
endmodule |
module vga (
// Wishbone signals
input wb_clk_i, // 25 Mhz VDU clock
input wb_rst_i,
input [15:0] wb_dat_i,
output [15:0] wb_dat_o,
input [16:1] wb_adr_i,
input wb_we_i,
input wb_tga_i,
input [ 1:0] wb_sel_i,
input wb_stb_i,
input wb_cyc_i,
output wb_ack_o,
// VGA pad signals
output [ 3:0] vga_red_o,
output [ 3:0] vga_green_o,
output [ 3:0] vga_blue_o,
output horiz_sync,
output vert_sync,
// CSR SRAM master interface
output [17:1] csrm_adr_o,
output [ 1:0] csrm_sel_o,
output csrm_we_o,
output [15:0] csrm_dat_o,
input [15:0] csrm_dat_i
);
// Registers and nets
//
// csr address
reg [17:1] csr_adr_i;
reg csr_stb_i;
// Config wires
wire [15:0] conf_wb_dat_o;
wire conf_wb_ack_o;
// Mem wires
wire [15:0] mem_wb_dat_o;
wire mem_wb_ack_o;
// LCD wires
wire [17:1] csr_adr_o;
wire [15:0] csr_dat_i;
wire csr_stb_o;
wire v_retrace;
wire vh_retrace;
wire w_vert_sync;
// VGA configuration registers
wire shift_reg1;
wire graphics_alpha;
wire memory_mapping1;
wire [ 1:0] write_mode;
wire [ 1:0] raster_op;
wire read_mode;
wire [ 7:0] bitmask;
wire [ 3:0] set_reset;
wire [ 3:0] enable_set_reset;
wire [ 3:0] map_mask;
wire x_dotclockdiv2;
wire chain_four;
wire [ 1:0] read_map_select;
wire [ 3:0] color_compare;
wire [ 3:0] color_dont_care;
// Wishbone master to SRAM
wire [17:1] wbm_adr_o;
wire [ 1:0] wbm_sel_o;
wire wbm_we_o;
wire [15:0] wbm_dat_o;
wire [15:0] wbm_dat_i;
wire wbm_stb_o;
wire wbm_ack_i;
wire stb;
// CRT wires
wire [ 5:0] cur_start;
wire [ 5:0] cur_end;
wire [15:0] start_addr;
wire [ 4:0] vcursor;
wire [ 6:0] hcursor;
wire [ 6:0] horiz_total;
wire [ 6:0] end_horiz;
wire [ 6:0] st_hor_retr;
wire [ 4:0] end_hor_retr;
wire [ 9:0] vert_total;
wire [ 9:0] end_vert;
wire [ 9:0] st_ver_retr;
wire [ 3:0] end_ver_retr;
// attribute_ctrl wires
wire [3:0] pal_addr;
wire pal_we;
wire [7:0] pal_read;
wire [7:0] pal_write;
// dac_regs wires
wire dac_we;
wire [1:0] dac_read_data_cycle;
wire [7:0] dac_read_data_register;
wire [3:0] dac_read_data;
wire [1:0] dac_write_data_cycle;
wire [7:0] dac_write_data_register;
wire [3:0] dac_write_data;
// Module instances
//
vga_config_iface config_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wb_dat_i (wb_dat_i),
.wb_dat_o (conf_wb_dat_o),
.wb_adr_i (wb_adr_i[4:1]),
.wb_we_i (wb_we_i),
.wb_sel_i (wb_sel_i),
.wb_stb_i (stb & wb_tga_i),
.wb_ack_o (conf_wb_ack_o),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.x_dotclockdiv2 (x_dotclockdiv2),
.chain_four (chain_four),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.cur_start (cur_start),
.cur_end (cur_end),
.start_addr (start_addr),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_lcd lcd (
.clk (wb_clk_i),
.rst (wb_rst_i),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.csr_adr_o (csr_adr_o),
.csr_dat_i (csr_dat_i),
.csr_stb_o (csr_stb_o),
.vga_red_o (vga_red_o),
.vga_green_o (vga_green_o),
.vga_blue_o (vga_blue_o),
.horiz_sync (horiz_sync),
.vert_sync (w_vert_sync),
.cur_start (cur_start),
.cur_end (cur_end),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.x_dotclockdiv2 (x_dotclockdiv2),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_cpu_mem_iface cpu_mem_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wbs_adr_i (wb_adr_i),
.wbs_sel_i (wb_sel_i),
.wbs_we_i (wb_we_i),
.wbs_dat_i (wb_dat_i),
.wbs_dat_o (mem_wb_dat_o),
.wbs_stb_i (stb & !wb_tga_i),
.wbs_ack_o (mem_wb_ack_o),
.wbm_adr_o (wbm_adr_o),
.wbm_sel_o (wbm_sel_o),
.wbm_we_o (wbm_we_o),
.wbm_dat_o (wbm_dat_o),
.wbm_dat_i (wbm_dat_i),
.wbm_stb_o (wbm_stb_o),
.wbm_ack_i (wbm_ack_i),
.chain_four (chain_four),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care)
);
vga_mem_arbitrer mem_arbitrer (
.clk_i (wb_clk_i),
.rst_i (wb_rst_i),
.wb_adr_i (wbm_adr_o),
.wb_sel_i (wbm_sel_o),
.wb_we_i (wbm_we_o),
.wb_dat_i (wbm_dat_o),
.wb_dat_o (wbm_dat_i),
.wb_stb_i (wbm_stb_o),
.wb_ack_o (wbm_ack_i),
.csr_adr_i (csr_adr_i),
.csr_dat_o (csr_dat_i),
.csr_stb_i (csr_stb_i),
.csrm_adr_o (csrm_adr_o),
.csrm_sel_o (csrm_sel_o),
.csrm_we_o (csrm_we_o),
.csrm_dat_o (csrm_dat_o),
.csrm_dat_i (csrm_dat_i)
);
// Continous assignments
assign wb_dat_o = wb_tga_i ? conf_wb_dat_o : mem_wb_dat_o;
assign wb_ack_o = wb_tga_i ? conf_wb_ack_o : mem_wb_ack_o;
assign stb = wb_stb_i & wb_cyc_i;
assign vert_sync = ~graphics_alpha ^ w_vert_sync;
// Behaviour
// csr_adr_i
always @(posedge wb_clk_i)
csr_adr_i <= wb_rst_i ? 17'h0 : csr_adr_o + start_addr[15:1];
// csr_stb_i
always @(posedge wb_clk_i)
csr_stb_i <= wb_rst_i ? 1'b0 : csr_stb_o;
endmodule |
module vga (
// Wishbone signals
input wb_clk_i, // 25 Mhz VDU clock
input wb_rst_i,
input [15:0] wb_dat_i,
output [15:0] wb_dat_o,
input [16:1] wb_adr_i,
input wb_we_i,
input wb_tga_i,
input [ 1:0] wb_sel_i,
input wb_stb_i,
input wb_cyc_i,
output wb_ack_o,
// VGA pad signals
output [ 3:0] vga_red_o,
output [ 3:0] vga_green_o,
output [ 3:0] vga_blue_o,
output horiz_sync,
output vert_sync,
// CSR SRAM master interface
output [17:1] csrm_adr_o,
output [ 1:0] csrm_sel_o,
output csrm_we_o,
output [15:0] csrm_dat_o,
input [15:0] csrm_dat_i
);
// Registers and nets
//
// csr address
reg [17:1] csr_adr_i;
reg csr_stb_i;
// Config wires
wire [15:0] conf_wb_dat_o;
wire conf_wb_ack_o;
// Mem wires
wire [15:0] mem_wb_dat_o;
wire mem_wb_ack_o;
// LCD wires
wire [17:1] csr_adr_o;
wire [15:0] csr_dat_i;
wire csr_stb_o;
wire v_retrace;
wire vh_retrace;
wire w_vert_sync;
// VGA configuration registers
wire shift_reg1;
wire graphics_alpha;
wire memory_mapping1;
wire [ 1:0] write_mode;
wire [ 1:0] raster_op;
wire read_mode;
wire [ 7:0] bitmask;
wire [ 3:0] set_reset;
wire [ 3:0] enable_set_reset;
wire [ 3:0] map_mask;
wire x_dotclockdiv2;
wire chain_four;
wire [ 1:0] read_map_select;
wire [ 3:0] color_compare;
wire [ 3:0] color_dont_care;
// Wishbone master to SRAM
wire [17:1] wbm_adr_o;
wire [ 1:0] wbm_sel_o;
wire wbm_we_o;
wire [15:0] wbm_dat_o;
wire [15:0] wbm_dat_i;
wire wbm_stb_o;
wire wbm_ack_i;
wire stb;
// CRT wires
wire [ 5:0] cur_start;
wire [ 5:0] cur_end;
wire [15:0] start_addr;
wire [ 4:0] vcursor;
wire [ 6:0] hcursor;
wire [ 6:0] horiz_total;
wire [ 6:0] end_horiz;
wire [ 6:0] st_hor_retr;
wire [ 4:0] end_hor_retr;
wire [ 9:0] vert_total;
wire [ 9:0] end_vert;
wire [ 9:0] st_ver_retr;
wire [ 3:0] end_ver_retr;
// attribute_ctrl wires
wire [3:0] pal_addr;
wire pal_we;
wire [7:0] pal_read;
wire [7:0] pal_write;
// dac_regs wires
wire dac_we;
wire [1:0] dac_read_data_cycle;
wire [7:0] dac_read_data_register;
wire [3:0] dac_read_data;
wire [1:0] dac_write_data_cycle;
wire [7:0] dac_write_data_register;
wire [3:0] dac_write_data;
// Module instances
//
vga_config_iface config_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wb_dat_i (wb_dat_i),
.wb_dat_o (conf_wb_dat_o),
.wb_adr_i (wb_adr_i[4:1]),
.wb_we_i (wb_we_i),
.wb_sel_i (wb_sel_i),
.wb_stb_i (stb & wb_tga_i),
.wb_ack_o (conf_wb_ack_o),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.x_dotclockdiv2 (x_dotclockdiv2),
.chain_four (chain_four),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.cur_start (cur_start),
.cur_end (cur_end),
.start_addr (start_addr),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_lcd lcd (
.clk (wb_clk_i),
.rst (wb_rst_i),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.csr_adr_o (csr_adr_o),
.csr_dat_i (csr_dat_i),
.csr_stb_o (csr_stb_o),
.vga_red_o (vga_red_o),
.vga_green_o (vga_green_o),
.vga_blue_o (vga_blue_o),
.horiz_sync (horiz_sync),
.vert_sync (w_vert_sync),
.cur_start (cur_start),
.cur_end (cur_end),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.x_dotclockdiv2 (x_dotclockdiv2),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_cpu_mem_iface cpu_mem_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wbs_adr_i (wb_adr_i),
.wbs_sel_i (wb_sel_i),
.wbs_we_i (wb_we_i),
.wbs_dat_i (wb_dat_i),
.wbs_dat_o (mem_wb_dat_o),
.wbs_stb_i (stb & !wb_tga_i),
.wbs_ack_o (mem_wb_ack_o),
.wbm_adr_o (wbm_adr_o),
.wbm_sel_o (wbm_sel_o),
.wbm_we_o (wbm_we_o),
.wbm_dat_o (wbm_dat_o),
.wbm_dat_i (wbm_dat_i),
.wbm_stb_o (wbm_stb_o),
.wbm_ack_i (wbm_ack_i),
.chain_four (chain_four),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care)
);
vga_mem_arbitrer mem_arbitrer (
.clk_i (wb_clk_i),
.rst_i (wb_rst_i),
.wb_adr_i (wbm_adr_o),
.wb_sel_i (wbm_sel_o),
.wb_we_i (wbm_we_o),
.wb_dat_i (wbm_dat_o),
.wb_dat_o (wbm_dat_i),
.wb_stb_i (wbm_stb_o),
.wb_ack_o (wbm_ack_i),
.csr_adr_i (csr_adr_i),
.csr_dat_o (csr_dat_i),
.csr_stb_i (csr_stb_i),
.csrm_adr_o (csrm_adr_o),
.csrm_sel_o (csrm_sel_o),
.csrm_we_o (csrm_we_o),
.csrm_dat_o (csrm_dat_o),
.csrm_dat_i (csrm_dat_i)
);
// Continous assignments
assign wb_dat_o = wb_tga_i ? conf_wb_dat_o : mem_wb_dat_o;
assign wb_ack_o = wb_tga_i ? conf_wb_ack_o : mem_wb_ack_o;
assign stb = wb_stb_i & wb_cyc_i;
assign vert_sync = ~graphics_alpha ^ w_vert_sync;
// Behaviour
// csr_adr_i
always @(posedge wb_clk_i)
csr_adr_i <= wb_rst_i ? 17'h0 : csr_adr_o + start_addr[15:1];
// csr_stb_i
always @(posedge wb_clk_i)
csr_stb_i <= wb_rst_i ? 1'b0 : csr_stb_o;
endmodule |
module vga (
// Wishbone signals
input wb_clk_i, // 25 Mhz VDU clock
input wb_rst_i,
input [15:0] wb_dat_i,
output [15:0] wb_dat_o,
input [16:1] wb_adr_i,
input wb_we_i,
input wb_tga_i,
input [ 1:0] wb_sel_i,
input wb_stb_i,
input wb_cyc_i,
output wb_ack_o,
// VGA pad signals
output [ 3:0] vga_red_o,
output [ 3:0] vga_green_o,
output [ 3:0] vga_blue_o,
output horiz_sync,
output vert_sync,
// CSR SRAM master interface
output [17:1] csrm_adr_o,
output [ 1:0] csrm_sel_o,
output csrm_we_o,
output [15:0] csrm_dat_o,
input [15:0] csrm_dat_i
);
// Registers and nets
//
// csr address
reg [17:1] csr_adr_i;
reg csr_stb_i;
// Config wires
wire [15:0] conf_wb_dat_o;
wire conf_wb_ack_o;
// Mem wires
wire [15:0] mem_wb_dat_o;
wire mem_wb_ack_o;
// LCD wires
wire [17:1] csr_adr_o;
wire [15:0] csr_dat_i;
wire csr_stb_o;
wire v_retrace;
wire vh_retrace;
wire w_vert_sync;
// VGA configuration registers
wire shift_reg1;
wire graphics_alpha;
wire memory_mapping1;
wire [ 1:0] write_mode;
wire [ 1:0] raster_op;
wire read_mode;
wire [ 7:0] bitmask;
wire [ 3:0] set_reset;
wire [ 3:0] enable_set_reset;
wire [ 3:0] map_mask;
wire x_dotclockdiv2;
wire chain_four;
wire [ 1:0] read_map_select;
wire [ 3:0] color_compare;
wire [ 3:0] color_dont_care;
// Wishbone master to SRAM
wire [17:1] wbm_adr_o;
wire [ 1:0] wbm_sel_o;
wire wbm_we_o;
wire [15:0] wbm_dat_o;
wire [15:0] wbm_dat_i;
wire wbm_stb_o;
wire wbm_ack_i;
wire stb;
// CRT wires
wire [ 5:0] cur_start;
wire [ 5:0] cur_end;
wire [15:0] start_addr;
wire [ 4:0] vcursor;
wire [ 6:0] hcursor;
wire [ 6:0] horiz_total;
wire [ 6:0] end_horiz;
wire [ 6:0] st_hor_retr;
wire [ 4:0] end_hor_retr;
wire [ 9:0] vert_total;
wire [ 9:0] end_vert;
wire [ 9:0] st_ver_retr;
wire [ 3:0] end_ver_retr;
// attribute_ctrl wires
wire [3:0] pal_addr;
wire pal_we;
wire [7:0] pal_read;
wire [7:0] pal_write;
// dac_regs wires
wire dac_we;
wire [1:0] dac_read_data_cycle;
wire [7:0] dac_read_data_register;
wire [3:0] dac_read_data;
wire [1:0] dac_write_data_cycle;
wire [7:0] dac_write_data_register;
wire [3:0] dac_write_data;
// Module instances
//
vga_config_iface config_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wb_dat_i (wb_dat_i),
.wb_dat_o (conf_wb_dat_o),
.wb_adr_i (wb_adr_i[4:1]),
.wb_we_i (wb_we_i),
.wb_sel_i (wb_sel_i),
.wb_stb_i (stb & wb_tga_i),
.wb_ack_o (conf_wb_ack_o),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.x_dotclockdiv2 (x_dotclockdiv2),
.chain_four (chain_four),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.cur_start (cur_start),
.cur_end (cur_end),
.start_addr (start_addr),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_lcd lcd (
.clk (wb_clk_i),
.rst (wb_rst_i),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.csr_adr_o (csr_adr_o),
.csr_dat_i (csr_dat_i),
.csr_stb_o (csr_stb_o),
.vga_red_o (vga_red_o),
.vga_green_o (vga_green_o),
.vga_blue_o (vga_blue_o),
.horiz_sync (horiz_sync),
.vert_sync (w_vert_sync),
.cur_start (cur_start),
.cur_end (cur_end),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.x_dotclockdiv2 (x_dotclockdiv2),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_cpu_mem_iface cpu_mem_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wbs_adr_i (wb_adr_i),
.wbs_sel_i (wb_sel_i),
.wbs_we_i (wb_we_i),
.wbs_dat_i (wb_dat_i),
.wbs_dat_o (mem_wb_dat_o),
.wbs_stb_i (stb & !wb_tga_i),
.wbs_ack_o (mem_wb_ack_o),
.wbm_adr_o (wbm_adr_o),
.wbm_sel_o (wbm_sel_o),
.wbm_we_o (wbm_we_o),
.wbm_dat_o (wbm_dat_o),
.wbm_dat_i (wbm_dat_i),
.wbm_stb_o (wbm_stb_o),
.wbm_ack_i (wbm_ack_i),
.chain_four (chain_four),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care)
);
vga_mem_arbitrer mem_arbitrer (
.clk_i (wb_clk_i),
.rst_i (wb_rst_i),
.wb_adr_i (wbm_adr_o),
.wb_sel_i (wbm_sel_o),
.wb_we_i (wbm_we_o),
.wb_dat_i (wbm_dat_o),
.wb_dat_o (wbm_dat_i),
.wb_stb_i (wbm_stb_o),
.wb_ack_o (wbm_ack_i),
.csr_adr_i (csr_adr_i),
.csr_dat_o (csr_dat_i),
.csr_stb_i (csr_stb_i),
.csrm_adr_o (csrm_adr_o),
.csrm_sel_o (csrm_sel_o),
.csrm_we_o (csrm_we_o),
.csrm_dat_o (csrm_dat_o),
.csrm_dat_i (csrm_dat_i)
);
// Continous assignments
assign wb_dat_o = wb_tga_i ? conf_wb_dat_o : mem_wb_dat_o;
assign wb_ack_o = wb_tga_i ? conf_wb_ack_o : mem_wb_ack_o;
assign stb = wb_stb_i & wb_cyc_i;
assign vert_sync = ~graphics_alpha ^ w_vert_sync;
// Behaviour
// csr_adr_i
always @(posedge wb_clk_i)
csr_adr_i <= wb_rst_i ? 17'h0 : csr_adr_o + start_addr[15:1];
// csr_stb_i
always @(posedge wb_clk_i)
csr_stb_i <= wb_rst_i ? 1'b0 : csr_stb_o;
endmodule |
module vga (
// Wishbone signals
input wb_clk_i, // 25 Mhz VDU clock
input wb_rst_i,
input [15:0] wb_dat_i,
output [15:0] wb_dat_o,
input [16:1] wb_adr_i,
input wb_we_i,
input wb_tga_i,
input [ 1:0] wb_sel_i,
input wb_stb_i,
input wb_cyc_i,
output wb_ack_o,
// VGA pad signals
output [ 3:0] vga_red_o,
output [ 3:0] vga_green_o,
output [ 3:0] vga_blue_o,
output horiz_sync,
output vert_sync,
// CSR SRAM master interface
output [17:1] csrm_adr_o,
output [ 1:0] csrm_sel_o,
output csrm_we_o,
output [15:0] csrm_dat_o,
input [15:0] csrm_dat_i
);
// Registers and nets
//
// csr address
reg [17:1] csr_adr_i;
reg csr_stb_i;
// Config wires
wire [15:0] conf_wb_dat_o;
wire conf_wb_ack_o;
// Mem wires
wire [15:0] mem_wb_dat_o;
wire mem_wb_ack_o;
// LCD wires
wire [17:1] csr_adr_o;
wire [15:0] csr_dat_i;
wire csr_stb_o;
wire v_retrace;
wire vh_retrace;
wire w_vert_sync;
// VGA configuration registers
wire shift_reg1;
wire graphics_alpha;
wire memory_mapping1;
wire [ 1:0] write_mode;
wire [ 1:0] raster_op;
wire read_mode;
wire [ 7:0] bitmask;
wire [ 3:0] set_reset;
wire [ 3:0] enable_set_reset;
wire [ 3:0] map_mask;
wire x_dotclockdiv2;
wire chain_four;
wire [ 1:0] read_map_select;
wire [ 3:0] color_compare;
wire [ 3:0] color_dont_care;
// Wishbone master to SRAM
wire [17:1] wbm_adr_o;
wire [ 1:0] wbm_sel_o;
wire wbm_we_o;
wire [15:0] wbm_dat_o;
wire [15:0] wbm_dat_i;
wire wbm_stb_o;
wire wbm_ack_i;
wire stb;
// CRT wires
wire [ 5:0] cur_start;
wire [ 5:0] cur_end;
wire [15:0] start_addr;
wire [ 4:0] vcursor;
wire [ 6:0] hcursor;
wire [ 6:0] horiz_total;
wire [ 6:0] end_horiz;
wire [ 6:0] st_hor_retr;
wire [ 4:0] end_hor_retr;
wire [ 9:0] vert_total;
wire [ 9:0] end_vert;
wire [ 9:0] st_ver_retr;
wire [ 3:0] end_ver_retr;
// attribute_ctrl wires
wire [3:0] pal_addr;
wire pal_we;
wire [7:0] pal_read;
wire [7:0] pal_write;
// dac_regs wires
wire dac_we;
wire [1:0] dac_read_data_cycle;
wire [7:0] dac_read_data_register;
wire [3:0] dac_read_data;
wire [1:0] dac_write_data_cycle;
wire [7:0] dac_write_data_register;
wire [3:0] dac_write_data;
// Module instances
//
vga_config_iface config_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wb_dat_i (wb_dat_i),
.wb_dat_o (conf_wb_dat_o),
.wb_adr_i (wb_adr_i[4:1]),
.wb_we_i (wb_we_i),
.wb_sel_i (wb_sel_i),
.wb_stb_i (stb & wb_tga_i),
.wb_ack_o (conf_wb_ack_o),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.x_dotclockdiv2 (x_dotclockdiv2),
.chain_four (chain_four),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.cur_start (cur_start),
.cur_end (cur_end),
.start_addr (start_addr),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_lcd lcd (
.clk (wb_clk_i),
.rst (wb_rst_i),
.shift_reg1 (shift_reg1),
.graphics_alpha (graphics_alpha),
.pal_addr (pal_addr),
.pal_we (pal_we),
.pal_read (pal_read),
.pal_write (pal_write),
.dac_we (dac_we),
.dac_read_data_cycle (dac_read_data_cycle),
.dac_read_data_register (dac_read_data_register),
.dac_read_data (dac_read_data),
.dac_write_data_cycle (dac_write_data_cycle),
.dac_write_data_register (dac_write_data_register),
.dac_write_data (dac_write_data),
.csr_adr_o (csr_adr_o),
.csr_dat_i (csr_dat_i),
.csr_stb_o (csr_stb_o),
.vga_red_o (vga_red_o),
.vga_green_o (vga_green_o),
.vga_blue_o (vga_blue_o),
.horiz_sync (horiz_sync),
.vert_sync (w_vert_sync),
.cur_start (cur_start),
.cur_end (cur_end),
.vcursor (vcursor),
.hcursor (hcursor),
.horiz_total (horiz_total),
.end_horiz (end_horiz),
.st_hor_retr (st_hor_retr),
.end_hor_retr (end_hor_retr),
.vert_total (vert_total),
.end_vert (end_vert),
.st_ver_retr (st_ver_retr),
.end_ver_retr (end_ver_retr),
.x_dotclockdiv2 (x_dotclockdiv2),
.v_retrace (v_retrace),
.vh_retrace (vh_retrace)
);
vga_cpu_mem_iface cpu_mem_iface (
.wb_clk_i (wb_clk_i),
.wb_rst_i (wb_rst_i),
.wbs_adr_i (wb_adr_i),
.wbs_sel_i (wb_sel_i),
.wbs_we_i (wb_we_i),
.wbs_dat_i (wb_dat_i),
.wbs_dat_o (mem_wb_dat_o),
.wbs_stb_i (stb & !wb_tga_i),
.wbs_ack_o (mem_wb_ack_o),
.wbm_adr_o (wbm_adr_o),
.wbm_sel_o (wbm_sel_o),
.wbm_we_o (wbm_we_o),
.wbm_dat_o (wbm_dat_o),
.wbm_dat_i (wbm_dat_i),
.wbm_stb_o (wbm_stb_o),
.wbm_ack_i (wbm_ack_i),
.chain_four (chain_four),
.memory_mapping1 (memory_mapping1),
.write_mode (write_mode),
.raster_op (raster_op),
.read_mode (read_mode),
.bitmask (bitmask),
.set_reset (set_reset),
.enable_set_reset (enable_set_reset),
.map_mask (map_mask),
.read_map_select (read_map_select),
.color_compare (color_compare),
.color_dont_care (color_dont_care)
);
vga_mem_arbitrer mem_arbitrer (
.clk_i (wb_clk_i),
.rst_i (wb_rst_i),
.wb_adr_i (wbm_adr_o),
.wb_sel_i (wbm_sel_o),
.wb_we_i (wbm_we_o),
.wb_dat_i (wbm_dat_o),
.wb_dat_o (wbm_dat_i),
.wb_stb_i (wbm_stb_o),
.wb_ack_o (wbm_ack_i),
.csr_adr_i (csr_adr_i),
.csr_dat_o (csr_dat_i),
.csr_stb_i (csr_stb_i),
.csrm_adr_o (csrm_adr_o),
.csrm_sel_o (csrm_sel_o),
.csrm_we_o (csrm_we_o),
.csrm_dat_o (csrm_dat_o),
.csrm_dat_i (csrm_dat_i)
);
// Continous assignments
assign wb_dat_o = wb_tga_i ? conf_wb_dat_o : mem_wb_dat_o;
assign wb_ack_o = wb_tga_i ? conf_wb_ack_o : mem_wb_ack_o;
assign stb = wb_stb_i & wb_cyc_i;
assign vert_sync = ~graphics_alpha ^ w_vert_sync;
// Behaviour
// csr_adr_i
always @(posedge wb_clk_i)
csr_adr_i <= wb_rst_i ? 17'h0 : csr_adr_o + start_addr[15:1];
// csr_stb_i
always @(posedge wb_clk_i)
csr_stb_i <= wb_rst_i ? 1'b0 : csr_stb_o;
endmodule |
module main(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, step, dir);
parameter W=10;
parameter F=11;
parameter T=4;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
input [15:0] din;
reg Spolarity;
reg[13:0] real_dout; output [13:0] dout = do_tristate ? 14'bZ : real_dout;
wire[3:0] real_step; output [3:0] step = do_tristate ? 4'bZ : real_step ^ {4{Spolarity}};
wire[3:0] real_dir; output [3:0] dir = do_tristate ? 4'bZ : real_dir;
wire [W+F-1:0] pos0, pos1, pos2, pos3;
reg [F:0] vel0, vel1, vel2, vel3;
reg [T-1:0] dirtime, steptime;
reg [1:0] tap;
reg [10:0] div2048;
wire stepcnt = ~|(div2048[5:0]);
always @(posedge clk) begin
div2048 <= div2048 + 1'd1;
end
wire do_enable_wdt, do_tristate;
wdt w(clk, do_enable_wdt, &div2048, do_tristate);
stepgen #(W,F,T) s0(clk, stepcnt, pos0, vel0, dirtime, steptime, real_step[0], real_dir[0], tap);
stepgen #(W,F,T) s1(clk, stepcnt, pos1, vel1, dirtime, steptime, real_step[1], real_dir[1], tap);
stepgen #(W,F,T) s2(clk, stepcnt, pos2, vel2, dirtime, steptime, real_step[2], real_dir[2], tap);
stepgen #(W,F,T) s3(clk, stepcnt, pos3, vel3, dirtime, steptime, real_step[3], real_dir[3], tap);
// EPP stuff
wire EPP_write = ~nWrite;
wire EPP_read = nWrite;
wire EPP_addr_strobe = ~nAddrStr;
wire EPP_data_strobe = ~nDataStr;
wire EPP_strobe = EPP_data_strobe | EPP_addr_strobe;
wire EPP_wait; assign nWait = ~EPP_wait;
wire [7:0] EPP_datain = pport_data;
wire [7:0] EPP_dataout; assign pport_data = EPP_dataout;
reg [4:0] EPP_strobe_reg;
always @(posedge clk) EPP_strobe_reg <= {EPP_strobe_reg[3:0], EPP_strobe};
wire EPP_strobe_edge1 = (EPP_strobe_reg[2:1]==2'b01);
// reg led;
assign EPP_wait = EPP_strobe_reg[4];
wire[15:0] EPP_dataword = {EPP_datain, lowbyte};
reg[4:0] addr_reg;
reg[7:0] lowbyte;
always @(posedge clk)
if(EPP_strobe_edge1 & EPP_write & EPP_addr_strobe) begin
addr_reg <= EPP_datain[4:0];
end
else if(EPP_strobe_edge1 & !EPP_addr_strobe) addr_reg <= addr_reg + 4'd1;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_write & EPP_data_strobe) begin
if(addr_reg[3:0] == 4'd1) vel0 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd3) vel1 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd5) vel2 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd7) vel3 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd9) begin
real_dout <= { EPP_datain[5:0], lowbyte };
end
else if(addr_reg[3:0] == 4'd11) begin
tap <= lowbyte[7:6];
steptime <= lowbyte[T-1:0];
Spolarity <= EPP_datain[7];
// EPP_datain[6] is do_enable_wdt
dirtime <= EPP_datain[T-1:0];
end
else lowbyte <= EPP_datain;
end
end
reg [31:0] data_buf;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_read && addr_reg[1:0] == 2'd0) begin
if(addr_reg[4:2] == 3'd0) data_buf <= pos0;
else if(addr_reg[4:2] == 3'd1) data_buf <= pos1;
else if(addr_reg[4:2] == 3'd2) data_buf <= pos2;
else if(addr_reg[4:2] == 3'd3) data_buf <= pos3;
else if(addr_reg[4:2] == 3'd4)
data_buf <= din;
end
end
// the addr_reg test looks funny because it is auto-incremented in an always
// block so "1" reads the low byte, "2 and "3" read middle bytes, and "0"
// reads the high byte I have a feeling that I'm doing this in the wrong way.
wire [7:0] data_reg = addr_reg[1:0] == 2'd1 ? data_buf[7:0] :
(addr_reg[1:0] == 2'd2 ? data_buf[15:8] :
(addr_reg[1:0] == 2'd3 ? data_buf[23:16] :
data_buf[31:24]));
wire [7:0] EPP_data_mux = data_reg;
assign EPP_dataout = (EPP_read & EPP_wait) ? EPP_data_mux : 8'hZZ;
// assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
// assign led = do_tristate ? 1'BZ : (real_step[0] ^ real_dir[0]);
assign led = do_tristate ? 1'bZ : (real_step[0] ^ real_dir[0]);
assign nConfig = epp_nReset; // 1'b1;
assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
endmodule |
module main(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, step, dir);
parameter W=10;
parameter F=11;
parameter T=4;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
input [15:0] din;
reg Spolarity;
reg[13:0] real_dout; output [13:0] dout = do_tristate ? 14'bZ : real_dout;
wire[3:0] real_step; output [3:0] step = do_tristate ? 4'bZ : real_step ^ {4{Spolarity}};
wire[3:0] real_dir; output [3:0] dir = do_tristate ? 4'bZ : real_dir;
wire [W+F-1:0] pos0, pos1, pos2, pos3;
reg [F:0] vel0, vel1, vel2, vel3;
reg [T-1:0] dirtime, steptime;
reg [1:0] tap;
reg [10:0] div2048;
wire stepcnt = ~|(div2048[5:0]);
always @(posedge clk) begin
div2048 <= div2048 + 1'd1;
end
wire do_enable_wdt, do_tristate;
wdt w(clk, do_enable_wdt, &div2048, do_tristate);
stepgen #(W,F,T) s0(clk, stepcnt, pos0, vel0, dirtime, steptime, real_step[0], real_dir[0], tap);
stepgen #(W,F,T) s1(clk, stepcnt, pos1, vel1, dirtime, steptime, real_step[1], real_dir[1], tap);
stepgen #(W,F,T) s2(clk, stepcnt, pos2, vel2, dirtime, steptime, real_step[2], real_dir[2], tap);
stepgen #(W,F,T) s3(clk, stepcnt, pos3, vel3, dirtime, steptime, real_step[3], real_dir[3], tap);
// EPP stuff
wire EPP_write = ~nWrite;
wire EPP_read = nWrite;
wire EPP_addr_strobe = ~nAddrStr;
wire EPP_data_strobe = ~nDataStr;
wire EPP_strobe = EPP_data_strobe | EPP_addr_strobe;
wire EPP_wait; assign nWait = ~EPP_wait;
wire [7:0] EPP_datain = pport_data;
wire [7:0] EPP_dataout; assign pport_data = EPP_dataout;
reg [4:0] EPP_strobe_reg;
always @(posedge clk) EPP_strobe_reg <= {EPP_strobe_reg[3:0], EPP_strobe};
wire EPP_strobe_edge1 = (EPP_strobe_reg[2:1]==2'b01);
// reg led;
assign EPP_wait = EPP_strobe_reg[4];
wire[15:0] EPP_dataword = {EPP_datain, lowbyte};
reg[4:0] addr_reg;
reg[7:0] lowbyte;
always @(posedge clk)
if(EPP_strobe_edge1 & EPP_write & EPP_addr_strobe) begin
addr_reg <= EPP_datain[4:0];
end
else if(EPP_strobe_edge1 & !EPP_addr_strobe) addr_reg <= addr_reg + 4'd1;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_write & EPP_data_strobe) begin
if(addr_reg[3:0] == 4'd1) vel0 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd3) vel1 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd5) vel2 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd7) vel3 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd9) begin
real_dout <= { EPP_datain[5:0], lowbyte };
end
else if(addr_reg[3:0] == 4'd11) begin
tap <= lowbyte[7:6];
steptime <= lowbyte[T-1:0];
Spolarity <= EPP_datain[7];
// EPP_datain[6] is do_enable_wdt
dirtime <= EPP_datain[T-1:0];
end
else lowbyte <= EPP_datain;
end
end
reg [31:0] data_buf;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_read && addr_reg[1:0] == 2'd0) begin
if(addr_reg[4:2] == 3'd0) data_buf <= pos0;
else if(addr_reg[4:2] == 3'd1) data_buf <= pos1;
else if(addr_reg[4:2] == 3'd2) data_buf <= pos2;
else if(addr_reg[4:2] == 3'd3) data_buf <= pos3;
else if(addr_reg[4:2] == 3'd4)
data_buf <= din;
end
end
// the addr_reg test looks funny because it is auto-incremented in an always
// block so "1" reads the low byte, "2 and "3" read middle bytes, and "0"
// reads the high byte I have a feeling that I'm doing this in the wrong way.
wire [7:0] data_reg = addr_reg[1:0] == 2'd1 ? data_buf[7:0] :
(addr_reg[1:0] == 2'd2 ? data_buf[15:8] :
(addr_reg[1:0] == 2'd3 ? data_buf[23:16] :
data_buf[31:24]));
wire [7:0] EPP_data_mux = data_reg;
assign EPP_dataout = (EPP_read & EPP_wait) ? EPP_data_mux : 8'hZZ;
// assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
// assign led = do_tristate ? 1'BZ : (real_step[0] ^ real_dir[0]);
assign led = do_tristate ? 1'bZ : (real_step[0] ^ real_dir[0]);
assign nConfig = epp_nReset; // 1'b1;
assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
endmodule |
module main(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, step, dir);
parameter W=10;
parameter F=11;
parameter T=4;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
input [15:0] din;
reg Spolarity;
reg[13:0] real_dout; output [13:0] dout = do_tristate ? 14'bZ : real_dout;
wire[3:0] real_step; output [3:0] step = do_tristate ? 4'bZ : real_step ^ {4{Spolarity}};
wire[3:0] real_dir; output [3:0] dir = do_tristate ? 4'bZ : real_dir;
wire [W+F-1:0] pos0, pos1, pos2, pos3;
reg [F:0] vel0, vel1, vel2, vel3;
reg [T-1:0] dirtime, steptime;
reg [1:0] tap;
reg [10:0] div2048;
wire stepcnt = ~|(div2048[5:0]);
always @(posedge clk) begin
div2048 <= div2048 + 1'd1;
end
wire do_enable_wdt, do_tristate;
wdt w(clk, do_enable_wdt, &div2048, do_tristate);
stepgen #(W,F,T) s0(clk, stepcnt, pos0, vel0, dirtime, steptime, real_step[0], real_dir[0], tap);
stepgen #(W,F,T) s1(clk, stepcnt, pos1, vel1, dirtime, steptime, real_step[1], real_dir[1], tap);
stepgen #(W,F,T) s2(clk, stepcnt, pos2, vel2, dirtime, steptime, real_step[2], real_dir[2], tap);
stepgen #(W,F,T) s3(clk, stepcnt, pos3, vel3, dirtime, steptime, real_step[3], real_dir[3], tap);
// EPP stuff
wire EPP_write = ~nWrite;
wire EPP_read = nWrite;
wire EPP_addr_strobe = ~nAddrStr;
wire EPP_data_strobe = ~nDataStr;
wire EPP_strobe = EPP_data_strobe | EPP_addr_strobe;
wire EPP_wait; assign nWait = ~EPP_wait;
wire [7:0] EPP_datain = pport_data;
wire [7:0] EPP_dataout; assign pport_data = EPP_dataout;
reg [4:0] EPP_strobe_reg;
always @(posedge clk) EPP_strobe_reg <= {EPP_strobe_reg[3:0], EPP_strobe};
wire EPP_strobe_edge1 = (EPP_strobe_reg[2:1]==2'b01);
// reg led;
assign EPP_wait = EPP_strobe_reg[4];
wire[15:0] EPP_dataword = {EPP_datain, lowbyte};
reg[4:0] addr_reg;
reg[7:0] lowbyte;
always @(posedge clk)
if(EPP_strobe_edge1 & EPP_write & EPP_addr_strobe) begin
addr_reg <= EPP_datain[4:0];
end
else if(EPP_strobe_edge1 & !EPP_addr_strobe) addr_reg <= addr_reg + 4'd1;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_write & EPP_data_strobe) begin
if(addr_reg[3:0] == 4'd1) vel0 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd3) vel1 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd5) vel2 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd7) vel3 <= EPP_dataword[F:0];
else if(addr_reg[3:0] == 4'd9) begin
real_dout <= { EPP_datain[5:0], lowbyte };
end
else if(addr_reg[3:0] == 4'd11) begin
tap <= lowbyte[7:6];
steptime <= lowbyte[T-1:0];
Spolarity <= EPP_datain[7];
// EPP_datain[6] is do_enable_wdt
dirtime <= EPP_datain[T-1:0];
end
else lowbyte <= EPP_datain;
end
end
reg [31:0] data_buf;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_read && addr_reg[1:0] == 2'd0) begin
if(addr_reg[4:2] == 3'd0) data_buf <= pos0;
else if(addr_reg[4:2] == 3'd1) data_buf <= pos1;
else if(addr_reg[4:2] == 3'd2) data_buf <= pos2;
else if(addr_reg[4:2] == 3'd3) data_buf <= pos3;
else if(addr_reg[4:2] == 3'd4)
data_buf <= din;
end
end
// the addr_reg test looks funny because it is auto-incremented in an always
// block so "1" reads the low byte, "2 and "3" read middle bytes, and "0"
// reads the high byte I have a feeling that I'm doing this in the wrong way.
wire [7:0] data_reg = addr_reg[1:0] == 2'd1 ? data_buf[7:0] :
(addr_reg[1:0] == 2'd2 ? data_buf[15:8] :
(addr_reg[1:0] == 2'd3 ? data_buf[23:16] :
data_buf[31:24]));
wire [7:0] EPP_data_mux = data_reg;
assign EPP_dataout = (EPP_read & EPP_wait) ? EPP_data_mux : 8'hZZ;
// assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
// assign led = do_tristate ? 1'BZ : (real_step[0] ^ real_dir[0]);
assign led = do_tristate ? 1'bZ : (real_step[0] ^ real_dir[0]);
assign nConfig = epp_nReset; // 1'b1;
assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
endmodule |
module ddc(input clock,
input reset,
input enable,
input [3:0] rate1,
input [3:0] rate2,
output strobe,
input [31:0] freq,
input [15:0] i_in,
input [15:0] q_in,
output [15:0] i_out,
output [15:0] q_out
);
parameter bw = 16;
parameter zw = 16;
wire [15:0] i_cordic_out, q_cordic_out;
wire [31:0] phase;
wire strobe1, strobe2;
reg [3:0] strobe_ctr1,strobe_ctr2;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr2 <= #1 4'd0;
else if(strobe2)
strobe_ctr2 <= #1 4'd0;
else
strobe_ctr2 <= #1 strobe_ctr2 + 4'd1;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr1 <= #1 4'd0;
else if(strobe1)
strobe_ctr1 <= #1 4'd0;
else if(strobe2)
strobe_ctr1 <= #1 strobe_ctr1 + 4'd1;
assign strobe2 = enable & ( strobe_ctr2 == rate2 );
assign strobe1 = strobe2 & ( strobe_ctr1 == rate1 );
assign strobe = strobe1;
function [2:0] log_ceil;
input [3:0] val;
log_ceil = val[3] ? 3'd4 : val[2] ? 3'd3 : val[1] ? 3'd2 : 3'd1;
endfunction
wire [2:0] shift1 = log_ceil(rate1);
wire [2:0] shift2 = log_ceil(rate2);
cordic #(.bitwidth(bw),.zwidth(zw),.stages(16))
cordic(.clock(clock), .reset(reset), .enable(enable),
.xi(i_in), .yi(q_in), .zi(phase[31:32-zw]),
.xo(i_cordic_out), .yo(q_cordic_out), .zo() );
cic_decim_2stage #(.bw(bw),.N(4))
decim_i(.clock(clock),.reset(reset),.enable(enable),
.strobe1(1'b1),.strobe2(strobe2),.strobe3(strobe1),.shift1(shift2),.shift2(shift1),
.signal_in(i_cordic_out),.signal_out(i_out));
cic_decim_2stage #(.bw(bw),.N(4))
decim_q(.clock(clock),.reset(reset),.enable(enable),
.strobe1(1'b1),.strobe2(strobe2),.strobe3(strobe1),.shift1(shift2),.shift2(shift1),
.signal_in(q_cordic_out),.signal_out(q_out));
phase_acc #(.resolution(32))
nco (.clk(clock),.reset(reset),.enable(enable),
.freq(freq),.phase(phase));
endmodule |
module ddc(input clock,
input reset,
input enable,
input [3:0] rate1,
input [3:0] rate2,
output strobe,
input [31:0] freq,
input [15:0] i_in,
input [15:0] q_in,
output [15:0] i_out,
output [15:0] q_out
);
parameter bw = 16;
parameter zw = 16;
wire [15:0] i_cordic_out, q_cordic_out;
wire [31:0] phase;
wire strobe1, strobe2;
reg [3:0] strobe_ctr1,strobe_ctr2;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr2 <= #1 4'd0;
else if(strobe2)
strobe_ctr2 <= #1 4'd0;
else
strobe_ctr2 <= #1 strobe_ctr2 + 4'd1;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr1 <= #1 4'd0;
else if(strobe1)
strobe_ctr1 <= #1 4'd0;
else if(strobe2)
strobe_ctr1 <= #1 strobe_ctr1 + 4'd1;
assign strobe2 = enable & ( strobe_ctr2 == rate2 );
assign strobe1 = strobe2 & ( strobe_ctr1 == rate1 );
assign strobe = strobe1;
function [2:0] log_ceil;
input [3:0] val;
log_ceil = val[3] ? 3'd4 : val[2] ? 3'd3 : val[1] ? 3'd2 : 3'd1;
endfunction
wire [2:0] shift1 = log_ceil(rate1);
wire [2:0] shift2 = log_ceil(rate2);
cordic #(.bitwidth(bw),.zwidth(zw),.stages(16))
cordic(.clock(clock), .reset(reset), .enable(enable),
.xi(i_in), .yi(q_in), .zi(phase[31:32-zw]),
.xo(i_cordic_out), .yo(q_cordic_out), .zo() );
cic_decim_2stage #(.bw(bw),.N(4))
decim_i(.clock(clock),.reset(reset),.enable(enable),
.strobe1(1'b1),.strobe2(strobe2),.strobe3(strobe1),.shift1(shift2),.shift2(shift1),
.signal_in(i_cordic_out),.signal_out(i_out));
cic_decim_2stage #(.bw(bw),.N(4))
decim_q(.clock(clock),.reset(reset),.enable(enable),
.strobe1(1'b1),.strobe2(strobe2),.strobe3(strobe1),.shift1(shift2),.shift2(shift1),
.signal_in(q_cordic_out),.signal_out(q_out));
phase_acc #(.resolution(32))
nco (.clk(clock),.reset(reset),.enable(enable),
.freq(freq),.phase(phase));
endmodule |
module mux(opA,opB,sum,dsp_sel,out);
input [3:0] opA,opB;
input [4:0] sum;
input [1:0] dsp_sel;
output [3:0] out;
reg cout;
always @ (sum)
begin
if (sum[4] == 1)
cout <= 4'b0001;
else
cout <= 4'b0000;
end
reg out;
always @(dsp_sel,sum,cout,opB,opA)
begin
if (dsp_sel == 2'b00)
out <= sum[3:0];
else if (dsp_sel == 2'b01)
out <= cout;
else if (dsp_sel == 2'b10)
out <= opB;
else if (dsp_sel == 2'b11)
out <= opA;
end
endmodule |
module mux(opA,opB,sum,dsp_sel,out);
input [3:0] opA,opB;
input [4:0] sum;
input [1:0] dsp_sel;
output [3:0] out;
reg cout;
always @ (sum)
begin
if (sum[4] == 1)
cout <= 4'b0001;
else
cout <= 4'b0000;
end
reg out;
always @(dsp_sel,sum,cout,opB,opA)
begin
if (dsp_sel == 2'b00)
out <= sum[3:0];
else if (dsp_sel == 2'b01)
out <= cout;
else if (dsp_sel == 2'b10)
out <= opB;
else if (dsp_sel == 2'b11)
out <= opA;
end
endmodule |
module mux(opA,opB,sum,dsp_sel,out);
input [3:0] opA,opB;
input [4:0] sum;
input [1:0] dsp_sel;
output [3:0] out;
reg cout;
always @ (sum)
begin
if (sum[4] == 1)
cout <= 4'b0001;
else
cout <= 4'b0000;
end
reg out;
always @(dsp_sel,sum,cout,opB,opA)
begin
if (dsp_sel == 2'b00)
out <= sum[3:0];
else if (dsp_sel == 2'b01)
out <= cout;
else if (dsp_sel == 2'b10)
out <= opB;
else if (dsp_sel == 2'b11)
out <= opA;
end
endmodule |
module mux(opA,opB,sum,dsp_sel,out);
input [3:0] opA,opB;
input [4:0] sum;
input [1:0] dsp_sel;
output [3:0] out;
reg cout;
always @ (sum)
begin
if (sum[4] == 1)
cout <= 4'b0001;
else
cout <= 4'b0000;
end
reg out;
always @(dsp_sel,sum,cout,opB,opA)
begin
if (dsp_sel == 2'b00)
out <= sum[3:0];
else if (dsp_sel == 2'b01)
out <= cout;
else if (dsp_sel == 2'b10)
out <= opB;
else if (dsp_sel == 2'b11)
out <= opA;
end
endmodule |
module mux(opA,opB,sum,dsp_sel,out);
input [3:0] opA,opB;
input [4:0] sum;
input [1:0] dsp_sel;
output [3:0] out;
reg cout;
always @ (sum)
begin
if (sum[4] == 1)
cout <= 4'b0001;
else
cout <= 4'b0000;
end
reg out;
always @(dsp_sel,sum,cout,opB,opA)
begin
if (dsp_sel == 2'b00)
out <= sum[3:0];
else if (dsp_sel == 2'b01)
out <= cout;
else if (dsp_sel == 2'b10)
out <= opB;
else if (dsp_sel == 2'b11)
out <= opA;
end
endmodule |
module mux(opA,opB,sum,dsp_sel,out);
input [3:0] opA,opB;
input [4:0] sum;
input [1:0] dsp_sel;
output [3:0] out;
reg cout;
always @ (sum)
begin
if (sum[4] == 1)
cout <= 4'b0001;
else
cout <= 4'b0000;
end
reg out;
always @(dsp_sel,sum,cout,opB,opA)
begin
if (dsp_sel == 2'b00)
out <= sum[3:0];
else if (dsp_sel == 2'b01)
out <= cout;
else if (dsp_sel == 2'b10)
out <= opB;
else if (dsp_sel == 2'b11)
out <= opA;
end
endmodule |
module Rotate_Mux_Array
#(parameter SWR=26)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
output wire [SWR-1:0] Data_o
);
genvar j;//Create a variable for the loop FOR
generate for (j=0; j <= SWR-1; j=j+1) begin // generate enough Multiplexers modules for each bit
case (j)
SWR-1-j:begin
assign Data_o[j]=Data_i[SWR-1-j];
end
default:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (Data_i[SWR-1-j]),
.S (Data_o[j])
);
end
endcase
end
endgenerate
endmodule |
module Rotate_Mux_Array
#(parameter SWR=26)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
output wire [SWR-1:0] Data_o
);
genvar j;//Create a variable for the loop FOR
generate for (j=0; j <= SWR-1; j=j+1) begin // generate enough Multiplexers modules for each bit
case (j)
SWR-1-j:begin
assign Data_o[j]=Data_i[SWR-1-j];
end
default:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (Data_i[SWR-1-j]),
.S (Data_o[j])
);
end
endcase
end
endgenerate
endmodule |
module Rotate_Mux_Array
#(parameter SWR=26)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
output wire [SWR-1:0] Data_o
);
genvar j;//Create a variable for the loop FOR
generate for (j=0; j <= SWR-1; j=j+1) begin // generate enough Multiplexers modules for each bit
case (j)
SWR-1-j:begin
assign Data_o[j]=Data_i[SWR-1-j];
end
default:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (Data_i[SWR-1-j]),
.S (Data_o[j])
);
end
endcase
end
endgenerate
endmodule |
module Rotate_Mux_Array
#(parameter SWR=26)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
output wire [SWR-1:0] Data_o
);
genvar j;//Create a variable for the loop FOR
generate for (j=0; j <= SWR-1; j=j+1) begin // generate enough Multiplexers modules for each bit
case (j)
SWR-1-j:begin
assign Data_o[j]=Data_i[SWR-1-j];
end
default:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (Data_i[SWR-1-j]),
.S (Data_o[j])
);
end
endcase
end
endgenerate
endmodule |
module Rotate_Mux_Array
#(parameter SWR=26)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
output wire [SWR-1:0] Data_o
);
genvar j;//Create a variable for the loop FOR
generate for (j=0; j <= SWR-1; j=j+1) begin // generate enough Multiplexers modules for each bit
case (j)
SWR-1-j:begin
assign Data_o[j]=Data_i[SWR-1-j];
end
default:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (Data_i[SWR-1-j]),
.S (Data_o[j])
);
end
endcase
end
endgenerate
endmodule |
module quad(clk, A, B, Z, zr, out);
parameter W=14;
input clk, A, B, Z, zr;
reg [(W-1):0] c, i; reg zl;
output [2*W:0] out = { zl, i, c };
// reg [(W-1):0] c, i; reg zl;
reg [2:0] Ad, Bd;
reg [2:0] Zc;
always @(posedge clk) Ad <= {Ad[1:0], A};
always @(posedge clk) Bd <= {Bd[1:0], B};
wire good_one = &Zc;
wire good_zero = ~|Zc;
reg last_good;
wire index_pulse = good_one && ! last_good;
wire count_enable = Ad[1] ^ Ad[2] ^ Bd[1] ^ Bd[2];
wire count_direction = Ad[1] ^ Bd[2];
always @(posedge clk)
begin
if(Z && !good_one) Zc <= Zc + 2'b1;
else if(!good_zero) Zc <= Zc - 2'b1;
if(good_one) last_good <= 1;
else if(good_zero) last_good <= 0;
if(count_enable)
begin
if(count_direction) c <= c + 1'd1;
else c <= c - 1'd1;
end
if(index_pulse) begin
i <= c;
zl <= 1;
end else if(zr) begin
zl <= 0;
end
end
endmodule |
module quad(clk, A, B, Z, zr, out);
parameter W=14;
input clk, A, B, Z, zr;
reg [(W-1):0] c, i; reg zl;
output [2*W:0] out = { zl, i, c };
// reg [(W-1):0] c, i; reg zl;
reg [2:0] Ad, Bd;
reg [2:0] Zc;
always @(posedge clk) Ad <= {Ad[1:0], A};
always @(posedge clk) Bd <= {Bd[1:0], B};
wire good_one = &Zc;
wire good_zero = ~|Zc;
reg last_good;
wire index_pulse = good_one && ! last_good;
wire count_enable = Ad[1] ^ Ad[2] ^ Bd[1] ^ Bd[2];
wire count_direction = Ad[1] ^ Bd[2];
always @(posedge clk)
begin
if(Z && !good_one) Zc <= Zc + 2'b1;
else if(!good_zero) Zc <= Zc - 2'b1;
if(good_one) last_good <= 1;
else if(good_zero) last_good <= 0;
if(count_enable)
begin
if(count_direction) c <= c + 1'd1;
else c <= c - 1'd1;
end
if(index_pulse) begin
i <= c;
zl <= 1;
end else if(zr) begin
zl <= 0;
end
end
endmodule |
module t_div_pipelined();
reg clk, start, reset_n;
reg [7:0] dividend, divisor;
wire data_valid, div_by_zero;
wire [7:0] quotient, quotient_correct;
parameter
BITS = 8;
div_pipelined
#(
.BITS(BITS)
)
div_pipelined
(
.clk(clk),
.reset_n(reset_n),
.dividend(dividend),
.divisor(divisor),
.quotient(quotient),
.div_by_zero(div_by_zero),
// .quotient_correct(quotient_correct),
.start(start),
.data_valid(data_valid)
);
initial begin
#10 reset_n = 0;
#50 reset_n = 1;
#1
clk = 0;
dividend = -1;
divisor = 127;
#1000 $finish;
end
// always
// #20 dividend = dividend + 1;
always begin
#10 divisor = divisor - 1; start = 1;
#10 start = 0;
end
always
#5 clk = ~clk;
endmodule |
module t_div_pipelined();
reg clk, start, reset_n;
reg [7:0] dividend, divisor;
wire data_valid, div_by_zero;
wire [7:0] quotient, quotient_correct;
parameter
BITS = 8;
div_pipelined
#(
.BITS(BITS)
)
div_pipelined
(
.clk(clk),
.reset_n(reset_n),
.dividend(dividend),
.divisor(divisor),
.quotient(quotient),
.div_by_zero(div_by_zero),
// .quotient_correct(quotient_correct),
.start(start),
.data_valid(data_valid)
);
initial begin
#10 reset_n = 0;
#50 reset_n = 1;
#1
clk = 0;
dividend = -1;
divisor = 127;
#1000 $finish;
end
// always
// #20 dividend = dividend + 1;
always begin
#10 divisor = divisor - 1; start = 1;
#10 start = 0;
end
always
#5 clk = ~clk;
endmodule |
module t_div_pipelined();
reg clk, start, reset_n;
reg [7:0] dividend, divisor;
wire data_valid, div_by_zero;
wire [7:0] quotient, quotient_correct;
parameter
BITS = 8;
div_pipelined
#(
.BITS(BITS)
)
div_pipelined
(
.clk(clk),
.reset_n(reset_n),
.dividend(dividend),
.divisor(divisor),
.quotient(quotient),
.div_by_zero(div_by_zero),
// .quotient_correct(quotient_correct),
.start(start),
.data_valid(data_valid)
);
initial begin
#10 reset_n = 0;
#50 reset_n = 1;
#1
clk = 0;
dividend = -1;
divisor = 127;
#1000 $finish;
end
// always
// #20 dividend = dividend + 1;
always begin
#10 divisor = divisor - 1; start = 1;
#10 start = 0;
end
always
#5 clk = ~clk;
endmodule |
module t_div_pipelined();
reg clk, start, reset_n;
reg [7:0] dividend, divisor;
wire data_valid, div_by_zero;
wire [7:0] quotient, quotient_correct;
parameter
BITS = 8;
div_pipelined
#(
.BITS(BITS)
)
div_pipelined
(
.clk(clk),
.reset_n(reset_n),
.dividend(dividend),
.divisor(divisor),
.quotient(quotient),
.div_by_zero(div_by_zero),
// .quotient_correct(quotient_correct),
.start(start),
.data_valid(data_valid)
);
initial begin
#10 reset_n = 0;
#50 reset_n = 1;
#1
clk = 0;
dividend = -1;
divisor = 127;
#1000 $finish;
end
// always
// #20 dividend = dividend + 1;
always begin
#10 divisor = divisor - 1; start = 1;
#10 start = 0;
end
always
#5 clk = ~clk;
endmodule |
module t_div_pipelined();
reg clk, start, reset_n;
reg [7:0] dividend, divisor;
wire data_valid, div_by_zero;
wire [7:0] quotient, quotient_correct;
parameter
BITS = 8;
div_pipelined
#(
.BITS(BITS)
)
div_pipelined
(
.clk(clk),
.reset_n(reset_n),
.dividend(dividend),
.divisor(divisor),
.quotient(quotient),
.div_by_zero(div_by_zero),
// .quotient_correct(quotient_correct),
.start(start),
.data_valid(data_valid)
);
initial begin
#10 reset_n = 0;
#50 reset_n = 1;
#1
clk = 0;
dividend = -1;
divisor = 127;
#1000 $finish;
end
// always
// #20 dividend = dividend + 1;
always begin
#10 divisor = divisor - 1; start = 1;
#10 start = 0;
end
always
#5 clk = ~clk;
endmodule |
module t_div_pipelined();
reg clk, start, reset_n;
reg [7:0] dividend, divisor;
wire data_valid, div_by_zero;
wire [7:0] quotient, quotient_correct;
parameter
BITS = 8;
div_pipelined
#(
.BITS(BITS)
)
div_pipelined
(
.clk(clk),
.reset_n(reset_n),
.dividend(dividend),
.divisor(divisor),
.quotient(quotient),
.div_by_zero(div_by_zero),
// .quotient_correct(quotient_correct),
.start(start),
.data_valid(data_valid)
);
initial begin
#10 reset_n = 0;
#50 reset_n = 1;
#1
clk = 0;
dividend = -1;
divisor = 127;
#1000 $finish;
end
// always
// #20 dividend = dividend + 1;
always begin
#10 divisor = divisor - 1; start = 1;
#10 start = 0;
end
always
#5 clk = ~clk;
endmodule |
module t_div_pipelined();
reg clk, start, reset_n;
reg [7:0] dividend, divisor;
wire data_valid, div_by_zero;
wire [7:0] quotient, quotient_correct;
parameter
BITS = 8;
div_pipelined
#(
.BITS(BITS)
)
div_pipelined
(
.clk(clk),
.reset_n(reset_n),
.dividend(dividend),
.divisor(divisor),
.quotient(quotient),
.div_by_zero(div_by_zero),
// .quotient_correct(quotient_correct),
.start(start),
.data_valid(data_valid)
);
initial begin
#10 reset_n = 0;
#50 reset_n = 1;
#1
clk = 0;
dividend = -1;
divisor = 127;
#1000 $finish;
end
// always
// #20 dividend = dividend + 1;
always begin
#10 divisor = divisor - 1; start = 1;
#10 start = 0;
end
always
#5 clk = ~clk;
endmodule |
module t_div_pipelined();
reg clk, start, reset_n;
reg [7:0] dividend, divisor;
wire data_valid, div_by_zero;
wire [7:0] quotient, quotient_correct;
parameter
BITS = 8;
div_pipelined
#(
.BITS(BITS)
)
div_pipelined
(
.clk(clk),
.reset_n(reset_n),
.dividend(dividend),
.divisor(divisor),
.quotient(quotient),
.div_by_zero(div_by_zero),
// .quotient_correct(quotient_correct),
.start(start),
.data_valid(data_valid)
);
initial begin
#10 reset_n = 0;
#50 reset_n = 1;
#1
clk = 0;
dividend = -1;
divisor = 127;
#1000 $finish;
end
// always
// #20 dividend = dividend + 1;
always begin
#10 divisor = divisor - 1; start = 1;
#10 start = 0;
end
always
#5 clk = ~clk;
endmodule |
module STATE_LOGIC_v8_2 (O, I0, I1, I2, I3, I4, I5);
parameter INIT = 64'h0000000000000000;
input I0, I1, I2, I3, I4, I5;
output O;
reg O;
reg tmp;
always @( I5 or I4 or I3 or I2 or I1 or I0 ) begin
tmp = I0 ^ I1 ^ I2 ^ I3 ^ I4 ^ I5;
if ( tmp == 0 || tmp == 1)
O = INIT[{I5, I4, I3, I2, I1, I0}];
end
endmodule |
module beh_vlog_muxf7_v8_2 (O, I0, I1, S);
output O;
reg O;
input I0, I1, S;
always @(I0 or I1 or S)
if (S)
O = I1;
else
O = I0;
endmodule |
module beh_vlog_ff_clr_v8_2 (Q, C, CLR, D);
parameter INIT = 0;
localparam FLOP_DELAY = 100;
output Q;
input C, CLR, D;
reg Q;
initial Q= 1'b0;
always @(posedge C )
if (CLR)
Q<= 1'b0;
else
Q<= #FLOP_DELAY D;
endmodule |
module beh_vlog_ff_pre_v8_2 (Q, C, D, PRE);
parameter INIT = 0;
localparam FLOP_DELAY = 100;
output Q;
input C, D, PRE;
reg Q;
initial Q= 1'b0;
always @(posedge C )
if (PRE)
Q <= 1'b1;
else
Q <= #FLOP_DELAY D;
endmodule |
module beh_vlog_ff_ce_clr_v8_2 (Q, C, CE, CLR, D);
parameter INIT = 0;
localparam FLOP_DELAY = 100;
output Q;
input C, CE, CLR, D;
reg Q;
initial Q= 1'b0;
always @(posedge C )
if (CLR)
Q <= 1'b0;
else if (CE)
Q <= #FLOP_DELAY D;
endmodule |
module write_netlist_v8_2
#(
parameter C_AXI_TYPE = 0
)
(
S_ACLK, S_ARESETN, S_AXI_AWVALID, S_AXI_WVALID, S_AXI_BREADY,
w_last_c, bready_timeout_c, aw_ready_r, S_AXI_WREADY, S_AXI_BVALID,
S_AXI_WR_EN, addr_en_c, incr_addr_c, bvalid_c
);
input S_ACLK;
input S_ARESETN;
input S_AXI_AWVALID;
input S_AXI_WVALID;
input S_AXI_BREADY;
input w_last_c;
input bready_timeout_c;
output aw_ready_r;
output S_AXI_WREADY;
output S_AXI_BVALID;
output S_AXI_WR_EN;
output addr_en_c;
output incr_addr_c;
output bvalid_c;
//-------------------------------------------------------------------------
//AXI LITE
//-------------------------------------------------------------------------
generate if (C_AXI_TYPE == 0 ) begin : gbeh_axi_lite_sm
wire w_ready_r_7;
wire w_ready_c;
wire aw_ready_c;
wire NlwRenamedSignal_bvalid_c;
wire NlwRenamedSignal_incr_addr_c;
wire present_state_FSM_FFd3_13;
wire present_state_FSM_FFd2_14;
wire present_state_FSM_FFd1_15;
wire present_state_FSM_FFd4_16;
wire present_state_FSM_FFd4_In;
wire present_state_FSM_FFd3_In;
wire present_state_FSM_FFd2_In;
wire present_state_FSM_FFd1_In;
wire present_state_FSM_FFd4_In1_21;
wire [0:0] Mmux_aw_ready_c ;
begin
assign
S_AXI_WREADY = w_ready_r_7,
S_AXI_BVALID = NlwRenamedSignal_incr_addr_c,
S_AXI_WR_EN = NlwRenamedSignal_bvalid_c,
incr_addr_c = NlwRenamedSignal_incr_addr_c,
bvalid_c = NlwRenamedSignal_bvalid_c;
assign NlwRenamedSignal_incr_addr_c = 1'b0;
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
aw_ready_r_2 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( aw_ready_c),
.Q ( aw_ready_r)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
w_ready_r (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( w_ready_c),
.Q ( w_ready_r_7)
);
beh_vlog_ff_pre_v8_2 #(
.INIT (1'b1))
present_state_FSM_FFd4 (
.C ( S_ACLK),
.D ( present_state_FSM_FFd4_In),
.PRE ( S_ARESETN),
.Q ( present_state_FSM_FFd4_16)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd3 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd3_In),
.Q ( present_state_FSM_FFd3_13)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd2 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd2_In),
.Q ( present_state_FSM_FFd2_14)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd1 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd1_In),
.Q ( present_state_FSM_FFd1_15)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000055554440))
present_state_FSM_FFd3_In1 (
.I0 ( S_AXI_WVALID),
.I1 ( S_AXI_AWVALID),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( present_state_FSM_FFd4_16),
.I4 ( present_state_FSM_FFd3_13),
.I5 (1'b0),
.O ( present_state_FSM_FFd3_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000088880800))
present_state_FSM_FFd2_In1 (
.I0 ( S_AXI_AWVALID),
.I1 ( S_AXI_WVALID),
.I2 ( bready_timeout_c),
.I3 ( present_state_FSM_FFd2_14),
.I4 ( present_state_FSM_FFd4_16),
.I5 (1'b0),
.O ( present_state_FSM_FFd2_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000AAAA2000))
Mmux_addr_en_c_0_1 (
.I0 ( S_AXI_AWVALID),
.I1 ( bready_timeout_c),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( S_AXI_WVALID),
.I4 ( present_state_FSM_FFd4_16),
.I5 (1'b0),
.O ( addr_en_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hF5F07570F5F05500))
Mmux_w_ready_c_0_1 (
.I0 ( S_AXI_WVALID),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd3_13),
.I4 ( present_state_FSM_FFd4_16),
.I5 ( present_state_FSM_FFd2_14),
.O ( w_ready_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h88808880FFFF8880))
present_state_FSM_FFd1_In1 (
.I0 ( S_AXI_WVALID),
.I1 ( bready_timeout_c),
.I2 ( present_state_FSM_FFd3_13),
.I3 ( present_state_FSM_FFd2_14),
.I4 ( present_state_FSM_FFd1_15),
.I5 ( S_AXI_BREADY),
.O ( present_state_FSM_FFd1_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000A8))
Mmux_S_AXI_WR_EN_0_1 (
.I0 ( S_AXI_WVALID),
.I1 ( present_state_FSM_FFd2_14),
.I2 ( present_state_FSM_FFd3_13),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( NlwRenamedSignal_bvalid_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h2F0F27072F0F2200))
present_state_FSM_FFd4_In1 (
.I0 ( S_AXI_WVALID),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd3_13),
.I4 ( present_state_FSM_FFd4_16),
.I5 ( present_state_FSM_FFd2_14),
.O ( present_state_FSM_FFd4_In1_21)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000F8))
present_state_FSM_FFd4_In2 (
.I0 ( present_state_FSM_FFd1_15),
.I1 ( S_AXI_BREADY),
.I2 ( present_state_FSM_FFd4_In1_21),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( present_state_FSM_FFd4_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h7535753575305500))
Mmux_aw_ready_c_0_1 (
.I0 ( S_AXI_AWVALID),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_WVALID),
.I3 ( present_state_FSM_FFd4_16),
.I4 ( present_state_FSM_FFd3_13),
.I5 ( present_state_FSM_FFd2_14),
.O ( Mmux_aw_ready_c[0])
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000F8))
Mmux_aw_ready_c_0_2 (
.I0 ( present_state_FSM_FFd1_15),
.I1 ( S_AXI_BREADY),
.I2 ( Mmux_aw_ready_c[0]),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( aw_ready_c)
);
end
end
endgenerate
//---------------------------------------------------------------------
// AXI FULL
//---------------------------------------------------------------------
generate if (C_AXI_TYPE == 1 ) begin : gbeh_axi_full_sm
wire w_ready_r_8;
wire w_ready_c;
wire aw_ready_c;
wire NlwRenamedSig_OI_bvalid_c;
wire present_state_FSM_FFd1_16;
wire present_state_FSM_FFd4_17;
wire present_state_FSM_FFd3_18;
wire present_state_FSM_FFd2_19;
wire present_state_FSM_FFd4_In;
wire present_state_FSM_FFd3_In;
wire present_state_FSM_FFd2_In;
wire present_state_FSM_FFd1_In;
wire present_state_FSM_FFd2_In1_24;
wire present_state_FSM_FFd4_In1_25;
wire N2;
wire N4;
begin
assign
S_AXI_WREADY = w_ready_r_8,
bvalid_c = NlwRenamedSig_OI_bvalid_c,
S_AXI_BVALID = 1'b0;
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
aw_ready_r_2
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( aw_ready_c),
.Q ( aw_ready_r)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
w_ready_r
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( w_ready_c),
.Q ( w_ready_r_8)
);
beh_vlog_ff_pre_v8_2 #(
.INIT (1'b1))
present_state_FSM_FFd4
(
.C ( S_ACLK),
.D ( present_state_FSM_FFd4_In),
.PRE ( S_ARESETN),
.Q ( present_state_FSM_FFd4_17)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd3
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd3_In),
.Q ( present_state_FSM_FFd3_18)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd2
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd2_In),
.Q ( present_state_FSM_FFd2_19)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd1
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd1_In),
.Q ( present_state_FSM_FFd1_16)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000005540))
present_state_FSM_FFd3_In1
(
.I0 ( S_AXI_WVALID),
.I1 ( present_state_FSM_FFd4_17),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd3_18),
.I4 (1'b0),
.I5 (1'b0),
.O ( present_state_FSM_FFd3_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hBF3FBB33AF0FAA00))
Mmux_aw_ready_c_0_2
(
.I0 ( S_AXI_BREADY),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd1_16),
.I4 ( present_state_FSM_FFd4_17),
.I5 ( NlwRenamedSig_OI_bvalid_c),
.O ( aw_ready_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hAAAAAAAA20000000))
Mmux_addr_en_c_0_1
(
.I0 ( S_AXI_AWVALID),
.I1 ( bready_timeout_c),
.I2 ( present_state_FSM_FFd2_19),
.I3 ( S_AXI_WVALID),
.I4 ( w_last_c),
.I5 ( present_state_FSM_FFd4_17),
.O ( addr_en_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000A8))
Mmux_S_AXI_WR_EN_0_1
(
.I0 ( S_AXI_WVALID),
.I1 ( present_state_FSM_FFd2_19),
.I2 ( present_state_FSM_FFd3_18),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( S_AXI_WR_EN)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000002220))
Mmux_incr_addr_c_0_1
(
.I0 ( S_AXI_WVALID),
.I1 ( w_last_c),
.I2 ( present_state_FSM_FFd2_19),
.I3 ( present_state_FSM_FFd3_18),
.I4 (1'b0),
.I5 (1'b0),
.O ( incr_addr_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000008880))
Mmux_aw_ready_c_0_11
(
.I0 ( S_AXI_WVALID),
.I1 ( w_last_c),
.I2 ( present_state_FSM_FFd2_19),
.I3 ( present_state_FSM_FFd3_18),
.I4 (1'b0),
.I5 (1'b0),
.O ( NlwRenamedSig_OI_bvalid_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h000000000000D5C0))
present_state_FSM_FFd2_In1
(
.I0 ( w_last_c),
.I1 ( S_AXI_AWVALID),
.I2 ( present_state_FSM_FFd4_17),
.I3 ( present_state_FSM_FFd3_18),
.I4 (1'b0),
.I5 (1'b0),
.O ( present_state_FSM_FFd2_In1_24)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hFFFFAAAA08AAAAAA))
present_state_FSM_FFd2_In2
(
.I0 ( present_state_FSM_FFd2_19),
.I1 ( S_AXI_AWVALID),
.I2 ( bready_timeout_c),
.I3 ( w_last_c),
.I4 ( S_AXI_WVALID),
.I5 ( present_state_FSM_FFd2_In1_24),
.O ( present_state_FSM_FFd2_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00C0004000C00000))
present_state_FSM_FFd4_In1
(
.I0 ( S_AXI_AWVALID),
.I1 ( w_last_c),
.I2 ( S_AXI_WVALID),
.I3 ( bready_timeout_c),
.I4 ( present_state_FSM_FFd3_18),
.I5 ( present_state_FSM_FFd2_19),
.O ( present_state_FSM_FFd4_In1_25)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000FFFF88F8))
present_state_FSM_FFd4_In2
(
.I0 ( present_state_FSM_FFd1_16),
.I1 ( S_AXI_BREADY),
.I2 ( present_state_FSM_FFd4_17),
.I3 ( S_AXI_AWVALID),
.I4 ( present_state_FSM_FFd4_In1_25),
.I5 (1'b0),
.O ( present_state_FSM_FFd4_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000007))
Mmux_w_ready_c_0_SW0
(
.I0 ( w_last_c),
.I1 ( S_AXI_WVALID),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( N2)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hFABAFABAFAAAF000))
Mmux_w_ready_c_0_Q
(
.I0 ( N2),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd4_17),
.I4 ( present_state_FSM_FFd3_18),
.I5 ( present_state_FSM_FFd2_19),
.O ( w_ready_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000008))
Mmux_aw_ready_c_0_11_SW0
(
.I0 ( bready_timeout_c),
.I1 ( S_AXI_WVALID),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( N4)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h88808880FFFF8880))
present_state_FSM_FFd1_In1
(
.I0 ( w_last_c),
.I1 ( N4),
.I2 ( present_state_FSM_FFd2_19),
.I3 ( present_state_FSM_FFd3_18),
.I4 ( present_state_FSM_FFd1_16),
.I5 ( S_AXI_BREADY),
.O ( present_state_FSM_FFd1_In)
);
end
end
endgenerate
endmodule |
module read_netlist_v8_2 #(
parameter C_AXI_TYPE = 1,
parameter C_ADDRB_WIDTH = 12
) ( S_AXI_R_LAST_INT, S_ACLK, S_ARESETN, S_AXI_ARVALID,
S_AXI_RREADY,S_AXI_INCR_ADDR,S_AXI_ADDR_EN,
S_AXI_SINGLE_TRANS,S_AXI_MUX_SEL, S_AXI_R_LAST, S_AXI_ARREADY,
S_AXI_RLAST, S_AXI_RVALID, S_AXI_RD_EN, S_AXI_ARLEN);
input S_AXI_R_LAST_INT;
input S_ACLK;
input S_ARESETN;
input S_AXI_ARVALID;
input S_AXI_RREADY;
output S_AXI_INCR_ADDR;
output S_AXI_ADDR_EN;
output S_AXI_SINGLE_TRANS;
output S_AXI_MUX_SEL;
output S_AXI_R_LAST;
output S_AXI_ARREADY;
output S_AXI_RLAST;
output S_AXI_RVALID;
output S_AXI_RD_EN;
input [7:0] S_AXI_ARLEN;
wire present_state_FSM_FFd1_13 ;
wire present_state_FSM_FFd2_14 ;
wire gaxi_full_sm_outstanding_read_r_15 ;
wire gaxi_full_sm_ar_ready_r_16 ;
wire gaxi_full_sm_r_last_r_17 ;
wire NlwRenamedSig_OI_gaxi_full_sm_r_valid_r ;
wire gaxi_full_sm_r_valid_c ;
wire S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o ;
wire gaxi_full_sm_ar_ready_c ;
wire gaxi_full_sm_outstanding_read_c ;
wire NlwRenamedSig_OI_S_AXI_R_LAST ;
wire S_AXI_ARLEN_7_GND_8_o_equal_1_o ;
wire present_state_FSM_FFd2_In ;
wire present_state_FSM_FFd1_In ;
wire Mmux_S_AXI_R_LAST13 ;
wire N01 ;
wire N2 ;
wire Mmux_gaxi_full_sm_ar_ready_c11 ;
wire N4 ;
wire N8 ;
wire N9 ;
wire N10 ;
wire N11 ;
wire N12 ;
wire N13 ;
assign
S_AXI_R_LAST = NlwRenamedSig_OI_S_AXI_R_LAST,
S_AXI_ARREADY = gaxi_full_sm_ar_ready_r_16,
S_AXI_RLAST = gaxi_full_sm_r_last_r_17,
S_AXI_RVALID = NlwRenamedSig_OI_gaxi_full_sm_r_valid_r;
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
gaxi_full_sm_outstanding_read_r (
.C (S_ACLK),
.CLR(S_ARESETN),
.D(gaxi_full_sm_outstanding_read_c),
.Q(gaxi_full_sm_outstanding_read_r_15)
);
beh_vlog_ff_ce_clr_v8_2 #(
.INIT (1'b0))
gaxi_full_sm_r_valid_r (
.C (S_ACLK),
.CE (S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o),
.CLR (S_ARESETN),
.D (gaxi_full_sm_r_valid_c),
.Q (NlwRenamedSig_OI_gaxi_full_sm_r_valid_r)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
gaxi_full_sm_ar_ready_r (
.C (S_ACLK),
.CLR (S_ARESETN),
.D (gaxi_full_sm_ar_ready_c),
.Q (gaxi_full_sm_ar_ready_r_16)
);
beh_vlog_ff_ce_clr_v8_2 #(
.INIT(1'b0))
gaxi_full_sm_r_last_r (
.C (S_ACLK),
.CE (S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o),
.CLR (S_ARESETN),
.D (NlwRenamedSig_OI_S_AXI_R_LAST),
.Q (gaxi_full_sm_r_last_r_17)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd2 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd2_In),
.Q ( present_state_FSM_FFd2_14)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd1 (
.C (S_ACLK),
.CLR (S_ARESETN),
.D (present_state_FSM_FFd1_In),
.Q (present_state_FSM_FFd1_13)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h000000000000000B))
S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o1 (
.I0 ( S_AXI_RREADY),
.I1 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O (S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000008))
Mmux_S_AXI_SINGLE_TRANS11 (
.I0 (S_AXI_ARVALID),
.I1 (S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O (S_AXI_SINGLE_TRANS)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000004))
Mmux_S_AXI_ADDR_EN11 (
.I0 (present_state_FSM_FFd1_13),
.I1 (S_AXI_ARVALID),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O (S_AXI_ADDR_EN)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hECEE2022EEEE2022))
present_state_FSM_FFd2_In1 (
.I0 ( S_AXI_ARVALID),
.I1 ( present_state_FSM_FFd1_13),
.I2 ( S_AXI_RREADY),
.I3 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I4 ( present_state_FSM_FFd2_14),
.I5 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.O ( present_state_FSM_FFd2_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000044440444))
Mmux_S_AXI_R_LAST131 (
.I0 ( present_state_FSM_FFd1_13),
.I1 ( S_AXI_ARVALID),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I4 ( S_AXI_RREADY),
.I5 (1'b0),
.O ( Mmux_S_AXI_R_LAST13)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h4000FFFF40004000))
Mmux_S_AXI_INCR_ADDR11 (
.I0 ( S_AXI_R_LAST_INT),
.I1 ( S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( present_state_FSM_FFd1_13),
.I4 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I5 ( Mmux_S_AXI_R_LAST13),
.O ( S_AXI_INCR_ADDR)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000FE))
S_AXI_ARLEN_7_GND_8_o_equal_1_o_7_SW0 (
.I0 ( S_AXI_ARLEN[2]),
.I1 ( S_AXI_ARLEN[1]),
.I2 ( S_AXI_ARLEN[0]),
.I3 ( 1'b0),
.I4 ( 1'b0),
.I5 ( 1'b0),
.O ( N01)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000001))
S_AXI_ARLEN_7_GND_8_o_equal_1_o_7_Q (
.I0 ( S_AXI_ARLEN[7]),
.I1 ( S_AXI_ARLEN[6]),
.I2 ( S_AXI_ARLEN[5]),
.I3 ( S_AXI_ARLEN[4]),
.I4 ( S_AXI_ARLEN[3]),
.I5 ( N01),
.O ( S_AXI_ARLEN_7_GND_8_o_equal_1_o)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000007))
Mmux_gaxi_full_sm_outstanding_read_c1_SW0 (
.I0 ( S_AXI_ARVALID),
.I1 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I2 ( 1'b0),
.I3 ( 1'b0),
.I4 ( 1'b0),
.I5 ( 1'b0),
.O ( N2)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0020000002200200))
Mmux_gaxi_full_sm_outstanding_read_c1 (
.I0 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I1 ( S_AXI_RREADY),
.I2 ( present_state_FSM_FFd1_13),
.I3 ( present_state_FSM_FFd2_14),
.I4 ( gaxi_full_sm_outstanding_read_r_15),
.I5 ( N2),
.O ( gaxi_full_sm_outstanding_read_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000004555))
Mmux_gaxi_full_sm_ar_ready_c12 (
.I0 ( S_AXI_ARVALID),
.I1 ( S_AXI_RREADY),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I4 ( 1'b0),
.I5 ( 1'b0),
.O ( Mmux_gaxi_full_sm_ar_ready_c11)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000EF))
Mmux_S_AXI_R_LAST11_SW0 (
.I0 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I1 ( S_AXI_RREADY),
.I2 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I3 ( 1'b0),
.I4 ( 1'b0),
.I5 ( 1'b0),
.O ( N4)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hFCAAFC0A00AA000A))
Mmux_S_AXI_R_LAST11 (
.I0 ( S_AXI_ARVALID),
.I1 ( gaxi_full_sm_outstanding_read_r_15),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( present_state_FSM_FFd1_13),
.I4 ( N4),
.I5 ( S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o),
.O ( gaxi_full_sm_r_valid_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000AAAAAA08))
S_AXI_MUX_SEL1 (
.I0 (present_state_FSM_FFd1_13),
.I1 (NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I2 (S_AXI_RREADY),
.I3 (present_state_FSM_FFd2_14),
.I4 (gaxi_full_sm_outstanding_read_r_15),
.I5 (1'b0),
.O (S_AXI_MUX_SEL)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hF3F3F755A2A2A200))
Mmux_S_AXI_RD_EN11 (
.I0 ( present_state_FSM_FFd1_13),
.I1 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I2 ( S_AXI_RREADY),
.I3 ( gaxi_full_sm_outstanding_read_r_15),
.I4 ( present_state_FSM_FFd2_14),
.I5 ( S_AXI_ARVALID),
.O ( S_AXI_RD_EN)
);
beh_vlog_muxf7_v8_2 present_state_FSM_FFd1_In3 (
.I0 ( N8),
.I1 ( N9),
.S ( present_state_FSM_FFd1_13),
.O ( present_state_FSM_FFd1_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h000000005410F4F0))
present_state_FSM_FFd1_In3_F (
.I0 ( S_AXI_RREADY),
.I1 ( present_state_FSM_FFd2_14),
.I2 ( S_AXI_ARVALID),
.I3 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I4 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I5 ( 1'b0),
.O ( N8)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000072FF7272))
present_state_FSM_FFd1_In3_G (
.I0 ( present_state_FSM_FFd2_14),
.I1 ( S_AXI_R_LAST_INT),
.I2 ( gaxi_full_sm_outstanding_read_r_15),
.I3 ( S_AXI_RREADY),
.I4 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I5 ( 1'b0),
.O ( N9)
);
beh_vlog_muxf7_v8_2 Mmux_gaxi_full_sm_ar_ready_c14 (
.I0 ( N10),
.I1 ( N11),
.S ( present_state_FSM_FFd1_13),
.O ( gaxi_full_sm_ar_ready_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000FFFF88A8))
Mmux_gaxi_full_sm_ar_ready_c14_F (
.I0 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I1 ( S_AXI_RREADY),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I4 ( Mmux_gaxi_full_sm_ar_ready_c11),
.I5 ( 1'b0),
.O ( N10)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h000000008D008D8D))
Mmux_gaxi_full_sm_ar_ready_c14_G (
.I0 ( present_state_FSM_FFd2_14),
.I1 ( S_AXI_R_LAST_INT),
.I2 ( gaxi_full_sm_outstanding_read_r_15),
.I3 ( S_AXI_RREADY),
.I4 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I5 ( 1'b0),
.O ( N11)
);
beh_vlog_muxf7_v8_2 Mmux_S_AXI_R_LAST1 (
.I0 ( N12),
.I1 ( N13),
.S ( present_state_FSM_FFd1_13),
.O ( NlwRenamedSig_OI_S_AXI_R_LAST)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000088088888))
Mmux_S_AXI_R_LAST1_F (
.I0 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I1 ( S_AXI_ARVALID),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( S_AXI_RREADY),
.I4 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I5 ( 1'b0),
.O ( N12)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000E400E4E4))
Mmux_S_AXI_R_LAST1_G (
.I0 ( present_state_FSM_FFd2_14),
.I1 ( gaxi_full_sm_outstanding_read_r_15),
.I2 ( S_AXI_R_LAST_INT),
.I3 ( S_AXI_RREADY),
.I4 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I5 ( 1'b0),
.O ( N13)
);
endmodule |
module blk_mem_axi_write_wrapper_beh_v8_2
# (
// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0, // 0: Native Interface; 1: AXI Interface
parameter C_AXI_TYPE = 0, // 0: AXI Lite; 1: AXI Full;
parameter C_AXI_SLAVE_TYPE = 0, // 0: MEMORY SLAVE; 1: PERIPHERAL SLAVE;
parameter C_MEMORY_TYPE = 0, // 0: SP-RAM, 1: SDP-RAM; 2: TDP-RAM; 3: DP-ROM;
parameter C_WRITE_DEPTH_A = 0,
parameter C_AXI_AWADDR_WIDTH = 32,
parameter C_ADDRA_WIDTH = 12,
parameter C_AXI_WDATA_WIDTH = 32,
parameter C_HAS_AXI_ID = 0,
parameter C_AXI_ID_WIDTH = 4,
// AXI OUTSTANDING WRITES
parameter C_AXI_OS_WR = 2
)
(
// AXI Global Signals
input S_ACLK,
input S_ARESETN,
// AXI Full/Lite Slave Write Channel (write side)
input [C_AXI_ID_WIDTH-1:0] S_AXI_AWID,
input [C_AXI_AWADDR_WIDTH-1:0] S_AXI_AWADDR,
input [8-1:0] S_AXI_AWLEN,
input [2:0] S_AXI_AWSIZE,
input [1:0] S_AXI_AWBURST,
input S_AXI_AWVALID,
output S_AXI_AWREADY,
input S_AXI_WVALID,
output S_AXI_WREADY,
output reg [C_AXI_ID_WIDTH-1:0] S_AXI_BID = 0,
output S_AXI_BVALID,
input S_AXI_BREADY,
// Signals for BMG interface
output [C_ADDRA_WIDTH-1:0] S_AXI_AWADDR_OUT,
output S_AXI_WR_EN
);
localparam FLOP_DELAY = 100; // 100 ps
localparam C_RANGE = ((C_AXI_WDATA_WIDTH == 8)?0:
((C_AXI_WDATA_WIDTH==16)?1:
((C_AXI_WDATA_WIDTH==32)?2:
((C_AXI_WDATA_WIDTH==64)?3:
((C_AXI_WDATA_WIDTH==128)?4:
((C_AXI_WDATA_WIDTH==256)?5:0))))));
wire bvalid_c ;
reg bready_timeout_c = 0;
wire [1:0] bvalid_rd_cnt_c;
reg bvalid_r = 0;
reg [2:0] bvalid_count_r = 0;
reg [((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?
C_AXI_AWADDR_WIDTH:C_ADDRA_WIDTH)-1:0] awaddr_reg = 0;
reg [1:0] bvalid_wr_cnt_r = 0;
reg [1:0] bvalid_rd_cnt_r = 0;
wire w_last_c ;
wire addr_en_c ;
wire incr_addr_c ;
wire aw_ready_r ;
wire dec_alen_c ;
reg bvalid_d1_c = 0;
reg [7:0] awlen_cntr_r = 0;
reg [7:0] awlen_int = 0;
reg [1:0] awburst_int = 0;
integer total_bytes = 0;
integer wrap_boundary = 0;
integer wrap_base_addr = 0;
integer num_of_bytes_c = 0;
integer num_of_bytes_r = 0;
// Array to store BIDs
reg [C_AXI_ID_WIDTH-1:0] axi_bid_array[3:0] ;
wire S_AXI_BVALID_axi_wr_fsm;
//-------------------------------------
//AXI WRITE FSM COMPONENT INSTANTIATION
//-------------------------------------
write_netlist_v8_2 #(.C_AXI_TYPE(C_AXI_TYPE)) axi_wr_fsm
(
.S_ACLK(S_ACLK),
.S_ARESETN(S_ARESETN),
.S_AXI_AWVALID(S_AXI_AWVALID),
.aw_ready_r(aw_ready_r),
.S_AXI_WVALID(S_AXI_WVALID),
.S_AXI_WREADY(S_AXI_WREADY),
.S_AXI_BREADY(S_AXI_BREADY),
.S_AXI_WR_EN(S_AXI_WR_EN),
.w_last_c(w_last_c),
.bready_timeout_c(bready_timeout_c),
.addr_en_c(addr_en_c),
.incr_addr_c(incr_addr_c),
.bvalid_c(bvalid_c),
.S_AXI_BVALID (S_AXI_BVALID_axi_wr_fsm)
);
//Wrap Address boundary calculation
always@(*) begin
num_of_bytes_c = 2**((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_AWSIZE:0);
total_bytes = (num_of_bytes_r)*(awlen_int+1);
wrap_base_addr = ((awaddr_reg)/((total_bytes==0)?1:total_bytes))*(total_bytes);
wrap_boundary = wrap_base_addr+total_bytes;
end
//-------------------------------------------------------------------------
// BMG address generation
//-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
awaddr_reg <= 0;
num_of_bytes_r <= 0;
awburst_int <= 0;
end else begin
if (addr_en_c == 1'b1) begin
awaddr_reg <= #FLOP_DELAY S_AXI_AWADDR ;
num_of_bytes_r <= num_of_bytes_c;
awburst_int <= ((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_AWBURST:2'b01);
end else if (incr_addr_c == 1'b1) begin
if (awburst_int == 2'b10) begin
if(awaddr_reg == (wrap_boundary-num_of_bytes_r)) begin
awaddr_reg <= wrap_base_addr;
end else begin
awaddr_reg <= awaddr_reg + num_of_bytes_r;
end
end else if (awburst_int == 2'b01 || awburst_int == 2'b11) begin
awaddr_reg <= awaddr_reg + num_of_bytes_r;
end
end
end
end
assign S_AXI_AWADDR_OUT = ((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?
awaddr_reg[C_AXI_AWADDR_WIDTH-1:C_RANGE]:awaddr_reg);
//-------------------------------------------------------------------------
// AXI wlast generation
//-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
awlen_cntr_r <= 0;
awlen_int <= 0;
end else begin
if (addr_en_c == 1'b1) begin
awlen_int <= #FLOP_DELAY (C_AXI_TYPE == 0?0:S_AXI_AWLEN) ;
awlen_cntr_r <= #FLOP_DELAY (C_AXI_TYPE == 0?0:S_AXI_AWLEN) ;
end else if (dec_alen_c == 1'b1) begin
awlen_cntr_r <= #FLOP_DELAY awlen_cntr_r - 1 ;
end
end
end
assign w_last_c = (awlen_cntr_r == 0 && S_AXI_WVALID == 1'b1)?1'b1:1'b0;
assign dec_alen_c = (incr_addr_c | w_last_c);
//-------------------------------------------------------------------------
// Generation of bvalid counter for outstanding transactions
//-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
bvalid_count_r <= 0;
end else begin
// bvalid_count_r generation
if (bvalid_c == 1'b1 && bvalid_r == 1'b1 && S_AXI_BREADY == 1'b1) begin
bvalid_count_r <= #FLOP_DELAY bvalid_count_r ;
end else if (bvalid_c == 1'b1) begin
bvalid_count_r <= #FLOP_DELAY bvalid_count_r + 1 ;
end else if (bvalid_r == 1'b1 && S_AXI_BREADY == 1'b1 && bvalid_count_r != 0) begin
bvalid_count_r <= #FLOP_DELAY bvalid_count_r - 1 ;
end
end
end
//-------------------------------------------------------------------------
// Generation of bvalid when BID is used
//-------------------------------------------------------------------------
generate if (C_HAS_AXI_ID == 1) begin:gaxi_bvalid_id_r
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
bvalid_r <= 0;
bvalid_d1_c <= 0;
end else begin
// Delay the generation o bvalid_r for generation for BID
bvalid_d1_c <= bvalid_c;
//external bvalid signal generation
if (bvalid_d1_c == 1'b1) begin
bvalid_r <= #FLOP_DELAY 1'b1 ;
end else if (bvalid_count_r <= 1 && S_AXI_BREADY == 1'b1) begin
bvalid_r <= #FLOP_DELAY 0 ;
end
end
end
end
endgenerate
//-------------------------------------------------------------------------
// Generation of bvalid when BID is not used
//-------------------------------------------------------------------------
generate if(C_HAS_AXI_ID == 0) begin:gaxi_bvalid_noid_r
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
bvalid_r <= 0;
end else begin
//external bvalid signal generation
if (bvalid_c == 1'b1) begin
bvalid_r <= #FLOP_DELAY 1'b1 ;
end else if (bvalid_count_r <= 1 && S_AXI_BREADY == 1'b1) begin
bvalid_r <= #FLOP_DELAY 0 ;
end
end
end
end
endgenerate
//-------------------------------------------------------------------------
// Generation of Bready timeout
//-------------------------------------------------------------------------
always @(bvalid_count_r) begin
// bready_timeout_c generation
if(bvalid_count_r == C_AXI_OS_WR-1) begin
bready_timeout_c <= 1'b1;
end else begin
bready_timeout_c <= 1'b0;
end
end
//-------------------------------------------------------------------------
// Generation of BID
//-------------------------------------------------------------------------
generate if(C_HAS_AXI_ID == 1) begin:gaxi_bid_gen
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
bvalid_wr_cnt_r <= 0;
bvalid_rd_cnt_r <= 0;
end else begin
// STORE AWID IN AN ARRAY
if(bvalid_c == 1'b1) begin
bvalid_wr_cnt_r <= bvalid_wr_cnt_r + 1;
end
// generate BID FROM AWID ARRAY
bvalid_rd_cnt_r <= #FLOP_DELAY bvalid_rd_cnt_c ;
S_AXI_BID <= axi_bid_array[bvalid_rd_cnt_c];
end
end
assign bvalid_rd_cnt_c = (bvalid_r == 1'b1 && S_AXI_BREADY == 1'b1)?bvalid_rd_cnt_r+1:bvalid_rd_cnt_r;
//-------------------------------------------------------------------------
// Storing AWID for generation of BID
//-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if(S_ARESETN == 1'b1) begin
axi_bid_array[0] = 0;
axi_bid_array[1] = 0;
axi_bid_array[2] = 0;
axi_bid_array[3] = 0;
end else if(aw_ready_r == 1'b1 && S_AXI_AWVALID == 1'b1) begin
axi_bid_array[bvalid_wr_cnt_r] <= S_AXI_AWID;
end
end
end
endgenerate
assign S_AXI_BVALID = bvalid_r;
assign S_AXI_AWREADY = aw_ready_r;
endmodule |
module blk_mem_axi_read_wrapper_beh_v8_2
# (
//// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0,
parameter C_AXI_TYPE = 0,
parameter C_AXI_SLAVE_TYPE = 0,
parameter C_MEMORY_TYPE = 0,
parameter C_WRITE_WIDTH_A = 4,
parameter C_WRITE_DEPTH_A = 32,
parameter C_ADDRA_WIDTH = 12,
parameter C_AXI_PIPELINE_STAGES = 0,
parameter C_AXI_ARADDR_WIDTH = 12,
parameter C_HAS_AXI_ID = 0,
parameter C_AXI_ID_WIDTH = 4,
parameter C_ADDRB_WIDTH = 12
)
(
//// AXI Global Signals
input S_ACLK,
input S_ARESETN,
//// AXI Full/Lite Slave Read (Read side)
input [C_AXI_ARADDR_WIDTH-1:0] S_AXI_ARADDR,
input [7:0] S_AXI_ARLEN,
input [2:0] S_AXI_ARSIZE,
input [1:0] S_AXI_ARBURST,
input S_AXI_ARVALID,
output S_AXI_ARREADY,
output S_AXI_RLAST,
output S_AXI_RVALID,
input S_AXI_RREADY,
input [C_AXI_ID_WIDTH-1:0] S_AXI_ARID,
output reg [C_AXI_ID_WIDTH-1:0] S_AXI_RID = 0,
//// AXI Full/Lite Read Address Signals to BRAM
output [C_ADDRB_WIDTH-1:0] S_AXI_ARADDR_OUT,
output S_AXI_RD_EN
);
localparam FLOP_DELAY = 100; // 100 ps
localparam C_RANGE = ((C_WRITE_WIDTH_A == 8)?0:
((C_WRITE_WIDTH_A==16)?1:
((C_WRITE_WIDTH_A==32)?2:
((C_WRITE_WIDTH_A==64)?3:
((C_WRITE_WIDTH_A==128)?4:
((C_WRITE_WIDTH_A==256)?5:0))))));
reg [C_AXI_ID_WIDTH-1:0] ar_id_r=0;
wire addr_en_c;
wire rd_en_c;
wire incr_addr_c;
wire single_trans_c;
wire dec_alen_c;
wire mux_sel_c;
wire r_last_c;
wire r_last_int_c;
wire [C_ADDRB_WIDTH-1 : 0] araddr_out;
reg [7:0] arlen_int_r=0;
reg [7:0] arlen_cntr=8'h01;
reg [1:0] arburst_int_c=0;
reg [1:0] arburst_int_r=0;
reg [((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?
C_AXI_ARADDR_WIDTH:C_ADDRA_WIDTH)-1:0] araddr_reg =0;
integer num_of_bytes_c = 0;
integer total_bytes = 0;
integer num_of_bytes_r = 0;
integer wrap_base_addr_r = 0;
integer wrap_boundary_r = 0;
reg [7:0] arlen_int_c=0;
integer total_bytes_c = 0;
integer wrap_base_addr_c = 0;
integer wrap_boundary_c = 0;
assign dec_alen_c = incr_addr_c | r_last_int_c;
read_netlist_v8_2
#(.C_AXI_TYPE (1),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH))
axi_read_fsm (
.S_AXI_INCR_ADDR(incr_addr_c),
.S_AXI_ADDR_EN(addr_en_c),
.S_AXI_SINGLE_TRANS(single_trans_c),
.S_AXI_MUX_SEL(mux_sel_c),
.S_AXI_R_LAST(r_last_c),
.S_AXI_R_LAST_INT(r_last_int_c),
//// AXI Global Signals
.S_ACLK(S_ACLK),
.S_ARESETN(S_ARESETN),
//// AXI Full/Lite Slave Read (Read side)
.S_AXI_ARLEN(S_AXI_ARLEN),
.S_AXI_ARVALID(S_AXI_ARVALID),
.S_AXI_ARREADY(S_AXI_ARREADY),
.S_AXI_RLAST(S_AXI_RLAST),
.S_AXI_RVALID(S_AXI_RVALID),
.S_AXI_RREADY(S_AXI_RREADY),
//// AXI Full/Lite Read Address Signals to BRAM
.S_AXI_RD_EN(rd_en_c)
);
always@(*) begin
num_of_bytes_c = 2**((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_ARSIZE:0);
total_bytes = (num_of_bytes_r)*(arlen_int_r+1);
wrap_base_addr_r = ((araddr_reg)/(total_bytes==0?1:total_bytes))*(total_bytes);
wrap_boundary_r = wrap_base_addr_r+total_bytes;
//////// combinatorial from interface
arlen_int_c = (C_AXI_TYPE == 0?0:S_AXI_ARLEN);
total_bytes_c = (num_of_bytes_c)*(arlen_int_c+1);
wrap_base_addr_c = ((S_AXI_ARADDR)/(total_bytes_c==0?1:total_bytes_c))*(total_bytes_c);
wrap_boundary_c = wrap_base_addr_c+total_bytes_c;
arburst_int_c = ((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_ARBURST:1);
end
////-------------------------------------------------------------------------
//// BMG address generation
////-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
araddr_reg <= 0;
arburst_int_r <= 0;
num_of_bytes_r <= 0;
end else begin
if (incr_addr_c == 1'b1 && addr_en_c == 1'b1 && single_trans_c == 1'b0) begin
arburst_int_r <= arburst_int_c;
num_of_bytes_r <= num_of_bytes_c;
if (arburst_int_c == 2'b10) begin
if(S_AXI_ARADDR == (wrap_boundary_c-num_of_bytes_c)) begin
araddr_reg <= wrap_base_addr_c;
end else begin
araddr_reg <= S_AXI_ARADDR + num_of_bytes_c;
end
end else if (arburst_int_c == 2'b01 || arburst_int_c == 2'b11) begin
araddr_reg <= S_AXI_ARADDR + num_of_bytes_c;
end
end else if (addr_en_c == 1'b1) begin
araddr_reg <= S_AXI_ARADDR;
num_of_bytes_r <= num_of_bytes_c;
arburst_int_r <= arburst_int_c;
end else if (incr_addr_c == 1'b1) begin
if (arburst_int_r == 2'b10) begin
if(araddr_reg == (wrap_boundary_r-num_of_bytes_r)) begin
araddr_reg <= wrap_base_addr_r;
end else begin
araddr_reg <= araddr_reg + num_of_bytes_r;
end
end else if (arburst_int_r == 2'b01 || arburst_int_r == 2'b11) begin
araddr_reg <= araddr_reg + num_of_bytes_r;
end
end
end
end
assign araddr_out = ((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?araddr_reg[C_AXI_ARADDR_WIDTH-1:C_RANGE]:araddr_reg);
////-----------------------------------------------------------------------
//// Counter to generate r_last_int_c from registered ARLEN - AXI FULL FSM
////-----------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
arlen_cntr <= 8'h01;
arlen_int_r <= 0;
end else begin
if (addr_en_c == 1'b1 && dec_alen_c == 1'b1 && single_trans_c == 1'b0) begin
arlen_int_r <= (C_AXI_TYPE == 0?0:S_AXI_ARLEN) ;
arlen_cntr <= S_AXI_ARLEN - 1'b1;
end else if (addr_en_c == 1'b1) begin
arlen_int_r <= (C_AXI_TYPE == 0?0:S_AXI_ARLEN) ;
arlen_cntr <= (C_AXI_TYPE == 0?0:S_AXI_ARLEN) ;
end else if (dec_alen_c == 1'b1) begin
arlen_cntr <= arlen_cntr - 1'b1 ;
end
else begin
arlen_cntr <= arlen_cntr;
end
end
end
assign r_last_int_c = (arlen_cntr == 0 && S_AXI_RREADY == 1'b1)?1'b1:1'b0;
////------------------------------------------------------------------------
//// AXI FULL FSM
//// Mux Selection of ARADDR
//// ARADDR is driven out from the read fsm based on the mux_sel_c
//// Based on mux_sel either ARADDR is given out or the latched ARADDR is
//// given out to BRAM
////------------------------------------------------------------------------
assign S_AXI_ARADDR_OUT = (mux_sel_c == 1'b0)?((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_ARADDR[C_AXI_ARADDR_WIDTH-1:C_RANGE]:S_AXI_ARADDR):araddr_out;
////------------------------------------------------------------------------
//// Assign output signals - AXI FULL FSM
////------------------------------------------------------------------------
assign S_AXI_RD_EN = rd_en_c;
generate if (C_HAS_AXI_ID == 1) begin:gaxi_bvalid_id_r
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
S_AXI_RID <= 0;
ar_id_r <= 0;
end else begin
if (addr_en_c == 1'b1 && rd_en_c == 1'b1) begin
S_AXI_RID <= S_AXI_ARID;
ar_id_r <= S_AXI_ARID;
end else if (addr_en_c == 1'b1 && rd_en_c == 1'b0) begin
ar_id_r <= S_AXI_ARID;
end else if (rd_en_c == 1'b1) begin
S_AXI_RID <= ar_id_r;
end
end
end
end
endgenerate
endmodule |
module blk_mem_axi_regs_fwd_v8_2
#(parameter C_DATA_WIDTH = 8
)(
input ACLK,
input ARESET,
input S_VALID,
output S_READY,
input [C_DATA_WIDTH-1:0] S_PAYLOAD_DATA,
output M_VALID,
input M_READY,
output reg [C_DATA_WIDTH-1:0] M_PAYLOAD_DATA
);
reg [C_DATA_WIDTH-1:0] STORAGE_DATA;
wire S_READY_I;
reg M_VALID_I;
reg [1:0] ARESET_D;
//assign local signal to its output signal
assign S_READY = S_READY_I;
assign M_VALID = M_VALID_I;
always @(posedge ACLK) begin
ARESET_D <= {ARESET_D[0], ARESET};
end
//Save payload data whenever we have a transaction on the slave side
always @(posedge ACLK or ARESET) begin
if (ARESET == 1'b1) begin
STORAGE_DATA <= 0;
end else begin
if(S_VALID == 1'b1 && S_READY_I == 1'b1 ) begin
STORAGE_DATA <= S_PAYLOAD_DATA;
end
end
end
always @(posedge ACLK) begin
M_PAYLOAD_DATA = STORAGE_DATA;
end
//M_Valid set to high when we have a completed transfer on slave side
//Is removed on a M_READY except if we have a new transfer on the slave side
always @(posedge ACLK or ARESET_D) begin
if (ARESET_D != 2'b00) begin
M_VALID_I <= 1'b0;
end else begin
if (S_VALID == 1'b1) begin
//Always set M_VALID_I when slave side is valid
M_VALID_I <= 1'b1;
end else if (M_READY == 1'b1 ) begin
//Clear (or keep) when no slave side is valid but master side is ready
M_VALID_I <= 1'b0;
end
end
end
//Slave Ready is either when Master side drives M_READY or we have space in our storage data
assign S_READY_I = (M_READY || (!M_VALID_I)) && !(|(ARESET_D));
endmodule |
module BLK_MEM_GEN_v8_2_output_stage
#(parameter C_FAMILY = "virtex7",
parameter C_XDEVICEFAMILY = "virtex7",
parameter C_RST_TYPE = "SYNC",
parameter C_HAS_RST = 0,
parameter C_RSTRAM = 0,
parameter C_RST_PRIORITY = "CE",
parameter C_INIT_VAL = "0",
parameter C_HAS_EN = 0,
parameter C_HAS_REGCE = 0,
parameter C_DATA_WIDTH = 32,
parameter C_ADDRB_WIDTH = 10,
parameter C_HAS_MEM_OUTPUT_REGS = 0,
parameter C_USE_SOFTECC = 0,
parameter C_USE_ECC = 0,
parameter NUM_STAGES = 1,
parameter C_EN_ECC_PIPE = 0,
parameter FLOP_DELAY = 100
)
(
input CLK,
input RST,
input EN,
input REGCE,
input [C_DATA_WIDTH-1:0] DIN_I,
output reg [C_DATA_WIDTH-1:0] DOUT,
input SBITERR_IN_I,
input DBITERR_IN_I,
output reg SBITERR,
output reg DBITERR,
input [C_ADDRB_WIDTH-1:0] RDADDRECC_IN_I,
input ECCPIPECE,
output reg [C_ADDRB_WIDTH-1:0] RDADDRECC
);
//******************************
// Port and Generic Definitions
//******************************
//////////////////////////////////////////////////////////////////////////
// Generic Definitions
//////////////////////////////////////////////////////////////////////////
// C_FAMILY,C_XDEVICEFAMILY: Designates architecture targeted. The following
// options are available - "spartan3", "spartan6",
// "virtex4", "virtex5", "virtex6" and "virtex6l".
// C_RST_TYPE : Type of reset - Synchronous or Asynchronous
// C_HAS_RST : Determines the presence of the RST port
// C_RSTRAM : Determines if special reset behavior is used
// C_RST_PRIORITY : Determines the priority between CE and SR
// C_INIT_VAL : Initialization value
// C_HAS_EN : Determines the presence of the EN port
// C_HAS_REGCE : Determines the presence of the REGCE port
// C_DATA_WIDTH : Memory write/read width
// C_ADDRB_WIDTH : Width of the ADDRB input port
// C_HAS_MEM_OUTPUT_REGS : Designates the use of a register at the output
// of the RAM primitive
// C_USE_SOFTECC : Determines if the Soft ECC feature is used or
// not. Only applicable Spartan-6
// C_USE_ECC : Determines if the ECC feature is used or
// not. Only applicable for V5 and V6
// NUM_STAGES : Determines the number of output stages
// FLOP_DELAY : Constant delay for register assignments
//////////////////////////////////////////////////////////////////////////
// Port Definitions
//////////////////////////////////////////////////////////////////////////
// CLK : Clock to synchronize all read and write operations
// RST : Reset input to reset memory outputs to a user-defined
// reset state
// EN : Enable all read and write operations
// REGCE : Register Clock Enable to control each pipeline output
// register stages
// DIN : Data input to the Output stage.
// DOUT : Final Data output
// SBITERR_IN : SBITERR input signal to the Output stage.
// SBITERR : Final SBITERR Output signal.
// DBITERR_IN : DBITERR input signal to the Output stage.
// DBITERR : Final DBITERR Output signal.
// RDADDRECC_IN : RDADDRECC input signal to the Output stage.
// RDADDRECC : Final RDADDRECC Output signal.
//////////////////////////////////////////////////////////////////////////
// Fix for CR-509792
localparam REG_STAGES = (NUM_STAGES < 2) ? 1 : NUM_STAGES-1;
// Declare the pipeline registers
// (includes mem output reg, mux pipeline stages, and mux output reg)
reg [C_DATA_WIDTH*REG_STAGES-1:0] out_regs;
reg [C_ADDRB_WIDTH*REG_STAGES-1:0] rdaddrecc_regs;
reg [REG_STAGES-1:0] sbiterr_regs;
reg [REG_STAGES-1:0] dbiterr_regs;
reg [C_DATA_WIDTH*8-1:0] init_str = C_INIT_VAL;
reg [C_DATA_WIDTH-1:0] init_val ;
//*********************************************
// Wire off optional inputs based on parameters
//*********************************************
wire en_i;
wire regce_i;
wire rst_i;
// Internal signals
reg [C_DATA_WIDTH-1:0] DIN;
reg [C_ADDRB_WIDTH-1:0] RDADDRECC_IN;
reg SBITERR_IN;
reg DBITERR_IN;
// Internal enable for output registers is tied to user EN or '1' depending
// on parameters
assign en_i = (C_HAS_EN==0 || EN);
// Internal register enable for output registers is tied to user REGCE, EN or
// '1' depending on parameters
// For V4 ECC, REGCE is always 1
// Virtex-4 ECC Not Yet Supported
assign regce_i = ((C_HAS_REGCE==1) && REGCE) ||
((C_HAS_REGCE==0) && (C_HAS_EN==0 || EN));
//Internal SRR is tied to user RST or '0' depending on parameters
assign rst_i = (C_HAS_RST==1) && RST;
//****************************************************
// Power on: load up the output registers and latches
//****************************************************
initial begin
if (!($sscanf(init_str, "%h", init_val))) begin
init_val = 0;
end
DOUT = init_val;
RDADDRECC = 0;
SBITERR = 1'b0;
DBITERR = 1'b0;
DIN = {(C_DATA_WIDTH){1'b0}};
RDADDRECC_IN = 0;
SBITERR_IN = 0;
DBITERR_IN = 0;
// This will be one wider than need, but 0 is an error
out_regs = {(REG_STAGES+1){init_val}};
rdaddrecc_regs = 0;
sbiterr_regs = {(REG_STAGES+1){1'b0}};
dbiterr_regs = {(REG_STAGES+1){1'b0}};
end
//***********************************************
// NUM_STAGES = 0 (No output registers. RAM only)
//***********************************************
generate if (NUM_STAGES == 0) begin : zero_stages
always @* begin
DOUT = DIN;
RDADDRECC = RDADDRECC_IN;
SBITERR = SBITERR_IN;
DBITERR = DBITERR_IN;
end
end
endgenerate
generate if (C_EN_ECC_PIPE == 0) begin : no_ecc_pipe_reg
always @* begin
DIN = DIN_I;
SBITERR_IN = SBITERR_IN_I;
DBITERR_IN = DBITERR_IN_I;
RDADDRECC_IN = RDADDRECC_IN_I;
end
end
endgenerate
generate if (C_EN_ECC_PIPE == 1) begin : with_ecc_pipe_reg
always @(posedge CLK) begin
if(ECCPIPECE == 1) begin
DIN <= #FLOP_DELAY DIN_I;
SBITERR_IN <= #FLOP_DELAY SBITERR_IN_I;
DBITERR_IN <= #FLOP_DELAY DBITERR_IN_I;
RDADDRECC_IN <= #FLOP_DELAY RDADDRECC_IN_I;
end
end
end
endgenerate
//***********************************************
// NUM_STAGES = 1
// (Mem Output Reg only or Mux Output Reg only)
//***********************************************
// Possible valid combinations:
// Note: C_HAS_MUX_OUTPUT_REGS_*=0 when (C_RSTRAM_*=1)
// +-----------------------------------------+
// | C_RSTRAM_* | Reset Behavior |
// +----------------+------------------------+
// | 0 | Normal Behavior |
// +----------------+------------------------+
// | 1 | Special Behavior |
// +----------------+------------------------+
//
// Normal = REGCE gates reset, as in the case of all families except S3ADSP.
// Special = EN gates reset, as in the case of S3ADSP.
generate if (NUM_STAGES == 1 &&
(C_RSTRAM == 0 || (C_RSTRAM == 1 && (C_XDEVICEFAMILY != "spartan3adsp" && C_XDEVICEFAMILY != "aspartan3adsp" )) ||
C_HAS_MEM_OUTPUT_REGS == 0 || C_HAS_RST == 0))
begin : one_stages_norm
always @(posedge CLK) begin
if (C_RST_PRIORITY == "CE") begin //REGCE has priority
if (regce_i && rst_i) begin
DOUT <= #FLOP_DELAY init_val;
RDADDRECC <= #FLOP_DELAY 0;
SBITERR <= #FLOP_DELAY 1'b0;
DBITERR <= #FLOP_DELAY 1'b0;
end else if (regce_i) begin
DOUT <= #FLOP_DELAY DIN;
RDADDRECC <= #FLOP_DELAY RDADDRECC_IN;
SBITERR <= #FLOP_DELAY SBITERR_IN;
DBITERR <= #FLOP_DELAY DBITERR_IN;
end //Output signal assignments
end else begin //RST has priority
if (rst_i) begin
DOUT <= #FLOP_DELAY init_val;
RDADDRECC <= #FLOP_DELAY RDADDRECC_IN;
SBITERR <= #FLOP_DELAY 1'b0;
DBITERR <= #FLOP_DELAY 1'b0;
end else if (regce_i) begin
DOUT <= #FLOP_DELAY DIN;
RDADDRECC <= #FLOP_DELAY RDADDRECC_IN;
SBITERR <= #FLOP_DELAY SBITERR_IN;
DBITERR <= #FLOP_DELAY DBITERR_IN;
end //Output signal assignments
end //end Priority conditions
end //end RST Type conditions
end //end one_stages_norm generate statement
endgenerate
// Special Reset Behavior for S3ADSP
generate if (NUM_STAGES == 1 && C_RSTRAM == 1 && (C_XDEVICEFAMILY =="spartan3adsp" || C_XDEVICEFAMILY =="aspartan3adsp"))
begin : one_stage_splbhv
always @(posedge CLK) begin
if (en_i && rst_i) begin
DOUT <= #FLOP_DELAY init_val;
end else if (regce_i && !rst_i) begin
DOUT <= #FLOP_DELAY DIN;
end //Output signal assignments
end //end CLK
end //end one_stage_splbhv generate statement
endgenerate
//************************************************************
// NUM_STAGES > 1
// Mem Output Reg + Mux Output Reg
// or
// Mem Output Reg + Mux Pipeline Stages (>0) + Mux Output Reg
// or
// Mux Pipeline Stages (>0) + Mux Output Reg
//*************************************************************
generate if (NUM_STAGES > 1) begin : multi_stage
//Asynchronous Reset
always @(posedge CLK) begin
if (C_RST_PRIORITY == "CE") begin //REGCE has priority
if (regce_i && rst_i) begin
DOUT <= #FLOP_DELAY init_val;
RDADDRECC <= #FLOP_DELAY 0;
SBITERR <= #FLOP_DELAY 1'b0;
DBITERR <= #FLOP_DELAY 1'b0;
end else if (regce_i) begin
DOUT <= #FLOP_DELAY
out_regs[C_DATA_WIDTH*(NUM_STAGES-2)+:C_DATA_WIDTH];
RDADDRECC <= #FLOP_DELAY rdaddrecc_regs[C_ADDRB_WIDTH*(NUM_STAGES-2)+:C_ADDRB_WIDTH];
SBITERR <= #FLOP_DELAY sbiterr_regs[NUM_STAGES-2];
DBITERR <= #FLOP_DELAY dbiterr_regs[NUM_STAGES-2];
end //Output signal assignments
end else begin //RST has priority
if (rst_i) begin
DOUT <= #FLOP_DELAY init_val;
RDADDRECC <= #FLOP_DELAY 0;
SBITERR <= #FLOP_DELAY 1'b0;
DBITERR <= #FLOP_DELAY 1'b0;
end else if (regce_i) begin
DOUT <= #FLOP_DELAY
out_regs[C_DATA_WIDTH*(NUM_STAGES-2)+:C_DATA_WIDTH];
RDADDRECC <= #FLOP_DELAY rdaddrecc_regs[C_ADDRB_WIDTH*(NUM_STAGES-2)+:C_ADDRB_WIDTH];
SBITERR <= #FLOP_DELAY sbiterr_regs[NUM_STAGES-2];
DBITERR <= #FLOP_DELAY dbiterr_regs[NUM_STAGES-2];
end //Output signal assignments
end //end Priority conditions
// Shift the data through the output stages
if (en_i) begin
out_regs <= #FLOP_DELAY (out_regs << C_DATA_WIDTH) | DIN;
rdaddrecc_regs <= #FLOP_DELAY (rdaddrecc_regs << C_ADDRB_WIDTH) | RDADDRECC_IN;
sbiterr_regs <= #FLOP_DELAY (sbiterr_regs << 1) | SBITERR_IN;
dbiterr_regs <= #FLOP_DELAY (dbiterr_regs << 1) | DBITERR_IN;
end
end //end CLK
end //end multi_stage generate statement
endgenerate
endmodule |
module BLK_MEM_GEN_v8_2_softecc_output_reg_stage
#(parameter C_DATA_WIDTH = 32,
parameter C_ADDRB_WIDTH = 10,
parameter C_HAS_SOFTECC_OUTPUT_REGS_B= 0,
parameter C_USE_SOFTECC = 0,
parameter FLOP_DELAY = 100
)
(
input CLK,
input [C_DATA_WIDTH-1:0] DIN,
output reg [C_DATA_WIDTH-1:0] DOUT,
input SBITERR_IN,
input DBITERR_IN,
output reg SBITERR,
output reg DBITERR,
input [C_ADDRB_WIDTH-1:0] RDADDRECC_IN,
output reg [C_ADDRB_WIDTH-1:0] RDADDRECC
);
//******************************
// Port and Generic Definitions
//******************************
//////////////////////////////////////////////////////////////////////////
// Generic Definitions
//////////////////////////////////////////////////////////////////////////
// C_DATA_WIDTH : Memory write/read width
// C_ADDRB_WIDTH : Width of the ADDRB input port
// C_HAS_SOFTECC_OUTPUT_REGS_B : Designates the use of a register at the output
// of the RAM primitive
// C_USE_SOFTECC : Determines if the Soft ECC feature is used or
// not. Only applicable Spartan-6
// FLOP_DELAY : Constant delay for register assignments
//////////////////////////////////////////////////////////////////////////
// Port Definitions
//////////////////////////////////////////////////////////////////////////
// CLK : Clock to synchronize all read and write operations
// DIN : Data input to the Output stage.
// DOUT : Final Data output
// SBITERR_IN : SBITERR input signal to the Output stage.
// SBITERR : Final SBITERR Output signal.
// DBITERR_IN : DBITERR input signal to the Output stage.
// DBITERR : Final DBITERR Output signal.
// RDADDRECC_IN : RDADDRECC input signal to the Output stage.
// RDADDRECC : Final RDADDRECC Output signal.
//////////////////////////////////////////////////////////////////////////
reg [C_DATA_WIDTH-1:0] dout_i = 0;
reg sbiterr_i = 0;
reg dbiterr_i = 0;
reg [C_ADDRB_WIDTH-1:0] rdaddrecc_i = 0;
//***********************************************
// NO OUTPUT REGISTERS.
//***********************************************
generate if (C_HAS_SOFTECC_OUTPUT_REGS_B==0) begin : no_output_stage
always @* begin
DOUT = DIN;
RDADDRECC = RDADDRECC_IN;
SBITERR = SBITERR_IN;
DBITERR = DBITERR_IN;
end
end
endgenerate
//***********************************************
// WITH OUTPUT REGISTERS.
//***********************************************
generate if (C_HAS_SOFTECC_OUTPUT_REGS_B==1) begin : has_output_stage
always @(posedge CLK) begin
dout_i <= #FLOP_DELAY DIN;
rdaddrecc_i <= #FLOP_DELAY RDADDRECC_IN;
sbiterr_i <= #FLOP_DELAY SBITERR_IN;
dbiterr_i <= #FLOP_DELAY DBITERR_IN;
end
always @* begin
DOUT = dout_i;
RDADDRECC = rdaddrecc_i;
SBITERR = sbiterr_i;
DBITERR = dbiterr_i;
end //end always
end //end in_or_out_stage generate statement
endgenerate
endmodule |
module
//***************************************************************
// Port A
assign rsta_outp_stage = RSTA & (~SLEEP);
BLK_MEM_GEN_v8_2_output_stage
#(.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_RST_TYPE ("SYNC"),
.C_HAS_RST (C_HAS_RSTA),
.C_RSTRAM (C_RSTRAM_A),
.C_RST_PRIORITY (C_RST_PRIORITY_A),
.C_INIT_VAL (C_INITA_VAL),
.C_HAS_EN (C_HAS_ENA),
.C_HAS_REGCE (C_HAS_REGCEA),
.C_DATA_WIDTH (C_READ_WIDTH_A),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_MEM_OUTPUT_REGS (C_HAS_MEM_OUTPUT_REGS_A),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.NUM_STAGES (NUM_OUTPUT_STAGES_A),
.C_EN_ECC_PIPE (0),
.FLOP_DELAY (FLOP_DELAY))
reg_a
(.CLK (CLKA),
.RST (rsta_outp_stage),//(RSTA),
.EN (ENA),
.REGCE (REGCEA),
.DIN_I (memory_out_a),
.DOUT (DOUTA),
.SBITERR_IN_I (1'b0),
.DBITERR_IN_I (1'b0),
.SBITERR (),
.DBITERR (),
.RDADDRECC_IN_I ({C_ADDRB_WIDTH{1'b0}}),
.ECCPIPECE (1'b0),
.RDADDRECC ()
);
assign rstb_outp_stage = RSTB & (~SLEEP);
// Port B
BLK_MEM_GEN_v8_2_output_stage
#(.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_RST_TYPE ("SYNC"),
.C_HAS_RST (C_HAS_RSTB),
.C_RSTRAM (C_RSTRAM_B),
.C_RST_PRIORITY (C_RST_PRIORITY_B),
.C_INIT_VAL (C_INITB_VAL),
.C_HAS_EN (C_HAS_ENB),
.C_HAS_REGCE (C_HAS_REGCEB),
.C_DATA_WIDTH (C_READ_WIDTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_MEM_OUTPUT_REGS (C_HAS_MEM_OUTPUT_REGS_B),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.NUM_STAGES (NUM_OUTPUT_STAGES_B),
.C_EN_ECC_PIPE (C_EN_ECC_PIPE),
.FLOP_DELAY (FLOP_DELAY))
reg_b
(.CLK (CLKB),
.RST (rstb_outp_stage),//(RSTB),
.EN (ENB),
.REGCE (REGCEB),
.DIN_I (memory_out_b),
.DOUT (dout_i),
.SBITERR_IN_I (sbiterr_in),
.DBITERR_IN_I (dbiterr_in),
.SBITERR (sbiterr_i),
.DBITERR (dbiterr_i),
.RDADDRECC_IN_I (rdaddrecc_in),
.ECCPIPECE (ECCPIPECE),
.RDADDRECC (rdaddrecc_i)
);
//***************************************************************
// Instantiate the Input and Output register stages
//***************************************************************
BLK_MEM_GEN_v8_2_softecc_output_reg_stage
#(.C_DATA_WIDTH (C_READ_WIDTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_SOFTECC_OUTPUT_REGS_B (C_HAS_SOFTECC_OUTPUT_REGS_B),
.C_USE_SOFTECC (C_USE_SOFTECC),
.FLOP_DELAY (FLOP_DELAY))
has_softecc_output_reg_stage
(.CLK (CLKB),
.DIN (dout_i),
.DOUT (DOUTB),
.SBITERR_IN (sbiterr_i),
.DBITERR_IN (dbiterr_i),
.SBITERR (sbiterr_sdp),
.DBITERR (dbiterr_sdp),
.RDADDRECC_IN (rdaddrecc_i),
.RDADDRECC (rdaddrecc_sdp)
);
//****************************************************
// Synchronous collision checks
//****************************************************
// CR 780544 : To make verilog model's collison warnings in consistant with
// vhdl model, the non-blocking assignments are replaced with blocking
// assignments.
generate if (!C_DISABLE_WARN_BHV_COLL && C_COMMON_CLK) begin : sync_coll
always @(posedge CLKA) begin
// Possible collision if both are enabled and the addresses match
if (ena_i && enb_i) begin
if (wea_i || web_i) begin
is_collision = collision_check(ADDRA, wea_i, ADDRB, web_i);
end else begin
is_collision = 0;
end
end else begin
is_collision = 0;
end
// If the write port is in READ_FIRST mode, there is no collision
if (C_WRITE_MODE_A=="READ_FIRST" && wea_i && !web_i) begin
is_collision = 0;
end
if (C_WRITE_MODE_B=="READ_FIRST" && web_i && !wea_i) begin
is_collision = 0;
end
// Only flag if one of the accesses is a write
if (is_collision && (wea_i || web_i)) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A %0s address: %0h, B %0s address: %0h\n",
wea_i ? "write" : "read", ADDRA,
web_i ? "write" : "read", ADDRB);
end
end
//****************************************************
// Asynchronous collision checks
//****************************************************
end else if (!C_DISABLE_WARN_BHV_COLL && !C_COMMON_CLK) begin : async_coll
// Delay A and B addresses in order to mimic setup/hold times
wire [C_ADDRA_WIDTH-1:0] #COLL_DELAY addra_delay = ADDRA;
wire [0:0] #COLL_DELAY wea_delay = wea_i;
wire #COLL_DELAY ena_delay = ena_i;
wire [C_ADDRB_WIDTH-1:0] #COLL_DELAY addrb_delay = ADDRB;
wire [0:0] #COLL_DELAY web_delay = web_i;
wire #COLL_DELAY enb_delay = enb_i;
// Do the checks w/rt A
always @(posedge CLKA) begin
// Possible collision if both are enabled and the addresses match
if (ena_i && enb_i) begin
if (wea_i || web_i) begin
is_collision_a = collision_check(ADDRA, wea_i, ADDRB, web_i);
end else begin
is_collision_a = 0;
end
end else begin
is_collision_a = 0;
end
if (ena_i && enb_delay) begin
if(wea_i || web_delay) begin
is_collision_delay_a = collision_check(ADDRA, wea_i, addrb_delay,
web_delay);
end else begin
is_collision_delay_a = 0;
end
end else begin
is_collision_delay_a = 0;
end
// Only flag if B access is a write
if (is_collision_a && web_i) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A %0s address: %0h, B write address: %0h\n",
wea_i ? "write" : "read", ADDRA, ADDRB);
end else if (is_collision_delay_a && web_delay) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A %0s address: %0h, B write address: %0h\n",
wea_i ? "write" : "read", ADDRA, addrb_delay);
end
end
// Do the checks w/rt B
always @(posedge CLKB) begin
// Possible collision if both are enabled and the addresses match
if (ena_i && enb_i) begin
if (wea_i || web_i) begin
is_collision_b = collision_check(ADDRA, wea_i, ADDRB, web_i);
end else begin
is_collision_b = 0;
end
end else begin
is_collision_b = 0;
end
if (ena_delay && enb_i) begin
if (wea_delay || web_i) begin
is_collision_delay_b = collision_check(addra_delay, wea_delay, ADDRB,
web_i);
end else begin
is_collision_delay_b = 0;
end
end else begin
is_collision_delay_b = 0;
end
// Only flag if A access is a write
if (is_collision_b && wea_i) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A write address: %0h, B %s address: %0h\n",
ADDRA, web_i ? "write" : "read", ADDRB);
end else if (is_collision_delay_b && wea_delay) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A write address: %0h, B %s address: %0h\n",
addra_delay, web_i ? "write" : "read", ADDRB);
end
end
end
endgenerate
endmodule |
module blk_mem_gen_v8_2
#(parameter C_CORENAME = "blk_mem_gen_v8_2",
parameter C_FAMILY = "virtex7",
parameter C_XDEVICEFAMILY = "virtex7",
parameter C_ELABORATION_DIR = "",
parameter C_INTERFACE_TYPE = 0,
parameter C_USE_BRAM_BLOCK = 0,
parameter C_CTRL_ECC_ALGO = "NONE",
parameter C_ENABLE_32BIT_ADDRESS = 0,
parameter C_AXI_TYPE = 0,
parameter C_AXI_SLAVE_TYPE = 0,
parameter C_HAS_AXI_ID = 0,
parameter C_AXI_ID_WIDTH = 4,
parameter C_MEM_TYPE = 2,
parameter C_BYTE_SIZE = 9,
parameter C_ALGORITHM = 1,
parameter C_PRIM_TYPE = 3,
parameter C_LOAD_INIT_FILE = 0,
parameter C_INIT_FILE_NAME = "",
parameter C_INIT_FILE = "",
parameter C_USE_DEFAULT_DATA = 0,
parameter C_DEFAULT_DATA = "0",
//parameter C_RST_TYPE = "SYNC",
parameter C_HAS_RSTA = 0,
parameter C_RST_PRIORITY_A = "CE",
parameter C_RSTRAM_A = 0,
parameter C_INITA_VAL = "0",
parameter C_HAS_ENA = 1,
parameter C_HAS_REGCEA = 0,
parameter C_USE_BYTE_WEA = 0,
parameter C_WEA_WIDTH = 1,
parameter C_WRITE_MODE_A = "WRITE_FIRST",
parameter C_WRITE_WIDTH_A = 32,
parameter C_READ_WIDTH_A = 32,
parameter C_WRITE_DEPTH_A = 64,
parameter C_READ_DEPTH_A = 64,
parameter C_ADDRA_WIDTH = 5,
parameter C_HAS_RSTB = 0,
parameter C_RST_PRIORITY_B = "CE",
parameter C_RSTRAM_B = 0,
parameter C_INITB_VAL = "",
parameter C_HAS_ENB = 1,
parameter C_HAS_REGCEB = 0,
parameter C_USE_BYTE_WEB = 0,
parameter C_WEB_WIDTH = 1,
parameter C_WRITE_MODE_B = "WRITE_FIRST",
parameter C_WRITE_WIDTH_B = 32,
parameter C_READ_WIDTH_B = 32,
parameter C_WRITE_DEPTH_B = 64,
parameter C_READ_DEPTH_B = 64,
parameter C_ADDRB_WIDTH = 5,
parameter C_HAS_MEM_OUTPUT_REGS_A = 0,
parameter C_HAS_MEM_OUTPUT_REGS_B = 0,
parameter C_HAS_MUX_OUTPUT_REGS_A = 0,
parameter C_HAS_MUX_OUTPUT_REGS_B = 0,
parameter C_HAS_SOFTECC_INPUT_REGS_A = 0,
parameter C_HAS_SOFTECC_OUTPUT_REGS_B= 0,
parameter C_MUX_PIPELINE_STAGES = 0,
parameter C_USE_SOFTECC = 0,
parameter C_USE_ECC = 0,
parameter C_EN_ECC_PIPE = 0,
parameter C_HAS_INJECTERR = 0,
parameter C_SIM_COLLISION_CHECK = "NONE",
parameter C_COMMON_CLK = 1,
parameter C_DISABLE_WARN_BHV_COLL = 0,
parameter C_EN_SLEEP_PIN = 0,
parameter C_USE_URAM = 0,
parameter C_EN_RDADDRA_CHG = 0,
parameter C_EN_RDADDRB_CHG = 0,
parameter C_EN_DEEPSLEEP_PIN = 0,
parameter C_EN_SHUTDOWN_PIN = 0,
parameter C_DISABLE_WARN_BHV_RANGE = 0,
parameter C_COUNT_36K_BRAM = "",
parameter C_COUNT_18K_BRAM = "",
parameter C_EST_POWER_SUMMARY = ""
)
(input clka,
input rsta,
input ena,
input regcea,
input [C_WEA_WIDTH-1:0] wea,
input [C_ADDRA_WIDTH-1:0] addra,
input [C_WRITE_WIDTH_A-1:0] dina,
output [C_READ_WIDTH_A-1:0] douta,
input clkb,
input rstb,
input enb,
input regceb,
input [C_WEB_WIDTH-1:0] web,
input [C_ADDRB_WIDTH-1:0] addrb,
input [C_WRITE_WIDTH_B-1:0] dinb,
output [C_READ_WIDTH_B-1:0] doutb,
input injectsbiterr,
input injectdbiterr,
output sbiterr,
output dbiterr,
output [C_ADDRB_WIDTH-1:0] rdaddrecc,
input eccpipece,
input sleep,
input deepsleep,
input shutdown,
//AXI BMG Input and Output Port Declarations
//AXI Global Signals
input s_aclk,
input s_aresetn,
//AXI Full/lite slave write (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_awid,
input [31:0] s_axi_awaddr,
input [7:0] s_axi_awlen,
input [2:0] s_axi_awsize,
input [1:0] s_axi_awburst,
input s_axi_awvalid,
output s_axi_awready,
input [C_WRITE_WIDTH_A-1:0] s_axi_wdata,
input [C_WEA_WIDTH-1:0] s_axi_wstrb,
input s_axi_wlast,
input s_axi_wvalid,
output s_axi_wready,
output [C_AXI_ID_WIDTH-1:0] s_axi_bid,
output [1:0] s_axi_bresp,
output s_axi_bvalid,
input s_axi_bready,
//AXI Full/lite slave read (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_arid,
input [31:0] s_axi_araddr,
input [7:0] s_axi_arlen,
input [2:0] s_axi_arsize,
input [1:0] s_axi_arburst,
input s_axi_arvalid,
output s_axi_arready,
output [C_AXI_ID_WIDTH-1:0] s_axi_rid,
output [C_WRITE_WIDTH_B-1:0] s_axi_rdata,
output [1:0] s_axi_rresp,
output s_axi_rlast,
output s_axi_rvalid,
input s_axi_rready,
//AXI Full/lite sideband signals
input s_axi_injectsbiterr,
input s_axi_injectdbiterr,
output s_axi_sbiterr,
output s_axi_dbiterr,
output [C_ADDRB_WIDTH-1:0] s_axi_rdaddrecc
);
//******************************
// Port and Generic Definitions
//******************************
//////////////////////////////////////////////////////////////////////////
// Generic Definitions
//////////////////////////////////////////////////////////////////////////
// C_CORENAME : Instance name of the Block Memory Generator core
// C_FAMILY,C_XDEVICEFAMILY: Designates architecture targeted. The following
// options are available - "spartan3", "spartan6",
// "virtex4", "virtex5", "virtex6" and "virtex6l".
// C_MEM_TYPE : Designates memory type.
// It can be
// 0 - Single Port Memory
// 1 - Simple Dual Port Memory
// 2 - True Dual Port Memory
// 3 - Single Port Read Only Memory
// 4 - Dual Port Read Only Memory
// C_BYTE_SIZE : Size of a byte (8 or 9 bits)
// C_ALGORITHM : Designates the algorithm method used
// for constructing the memory.
// It can be Fixed_Primitives, Minimum_Area or
// Low_Power
// C_PRIM_TYPE : Designates the user selected primitive used to
// construct the memory.
//
// C_LOAD_INIT_FILE : Designates the use of an initialization file to
// initialize memory contents.
// C_INIT_FILE_NAME : Memory initialization file name.
// C_USE_DEFAULT_DATA : Designates whether to fill remaining
// initialization space with default data
// C_DEFAULT_DATA : Default value of all memory locations
// not initialized by the memory
// initialization file.
// C_RST_TYPE : Type of reset - Synchronous or Asynchronous
// C_HAS_RSTA : Determines the presence of the RSTA port
// C_RST_PRIORITY_A : Determines the priority between CE and SR for
// Port A.
// C_RSTRAM_A : Determines if special reset behavior is used for
// Port A
// C_INITA_VAL : The initialization value for Port A
// C_HAS_ENA : Determines the presence of the ENA port
// C_HAS_REGCEA : Determines the presence of the REGCEA port
// C_USE_BYTE_WEA : Determines if the Byte Write is used or not.
// C_WEA_WIDTH : The width of the WEA port
// C_WRITE_MODE_A : Configurable write mode for Port A. It can be
// WRITE_FIRST, READ_FIRST or NO_CHANGE.
// C_WRITE_WIDTH_A : Memory write width for Port A.
// C_READ_WIDTH_A : Memory read width for Port A.
// C_WRITE_DEPTH_A : Memory write depth for Port A.
// C_READ_DEPTH_A : Memory read depth for Port A.
// C_ADDRA_WIDTH : Width of the ADDRA input port
// C_HAS_RSTB : Determines the presence of the RSTB port
// C_RST_PRIORITY_B : Determines the priority between CE and SR for
// Port B.
// C_RSTRAM_B : Determines if special reset behavior is used for
// Port B
// C_INITB_VAL : The initialization value for Port B
// C_HAS_ENB : Determines the presence of the ENB port
// C_HAS_REGCEB : Determines the presence of the REGCEB port
// C_USE_BYTE_WEB : Determines if the Byte Write is used or not.
// C_WEB_WIDTH : The width of the WEB port
// C_WRITE_MODE_B : Configurable write mode for Port B. It can be
// WRITE_FIRST, READ_FIRST or NO_CHANGE.
// C_WRITE_WIDTH_B : Memory write width for Port B.
// C_READ_WIDTH_B : Memory read width for Port B.
// C_WRITE_DEPTH_B : Memory write depth for Port B.
// C_READ_DEPTH_B : Memory read depth for Port B.
// C_ADDRB_WIDTH : Width of the ADDRB input port
// C_HAS_MEM_OUTPUT_REGS_A : Designates the use of a register at the output
// of the RAM primitive for Port A.
// C_HAS_MEM_OUTPUT_REGS_B : Designates the use of a register at the output
// of the RAM primitive for Port B.
// C_HAS_MUX_OUTPUT_REGS_A : Designates the use of a register at the output
// of the MUX for Port A.
// C_HAS_MUX_OUTPUT_REGS_B : Designates the use of a register at the output
// of the MUX for Port B.
// C_HAS_SOFTECC_INPUT_REGS_A :
// C_HAS_SOFTECC_OUTPUT_REGS_B :
// C_MUX_PIPELINE_STAGES : Designates the number of pipeline stages in
// between the muxes.
// C_USE_SOFTECC : Determines if the Soft ECC feature is used or
// not. Only applicable Spartan-6
// C_USE_ECC : Determines if the ECC feature is used or
// not. Only applicable for V5 and V6
// C_HAS_INJECTERR : Determines if the error injection pins
// are present or not. If the ECC feature
// is not used, this value is defaulted to
// 0, else the following are the allowed
// values:
// 0 : No INJECTSBITERR or INJECTDBITERR pins
// 1 : Only INJECTSBITERR pin exists
// 2 : Only INJECTDBITERR pin exists
// 3 : Both INJECTSBITERR and INJECTDBITERR pins exist
// C_SIM_COLLISION_CHECK : Controls the disabling of Unisim model collision
// warnings. It can be "ALL", "NONE",
// "Warnings_Only" or "Generate_X_Only".
// C_COMMON_CLK : Determins if the core has a single CLK input.
// C_DISABLE_WARN_BHV_COLL : Controls the Behavioral Model Collision warnings
// C_DISABLE_WARN_BHV_RANGE: Controls the Behavioral Model Out of Range
// warnings
//////////////////////////////////////////////////////////////////////////
// Port Definitions
//////////////////////////////////////////////////////////////////////////
// CLKA : Clock to synchronize all read and write operations of Port A.
// RSTA : Reset input to reset memory outputs to a user-defined
// reset state for Port A.
// ENA : Enable all read and write operations of Port A.
// REGCEA : Register Clock Enable to control each pipeline output
// register stages for Port A.
// WEA : Write Enable to enable all write operations of Port A.
// ADDRA : Address of Port A.
// DINA : Data input of Port A.
// DOUTA : Data output of Port A.
// CLKB : Clock to synchronize all read and write operations of Port B.
// RSTB : Reset input to reset memory outputs to a user-defined
// reset state for Port B.
// ENB : Enable all read and write operations of Port B.
// REGCEB : Register Clock Enable to control each pipeline output
// register stages for Port B.
// WEB : Write Enable to enable all write operations of Port B.
// ADDRB : Address of Port B.
// DINB : Data input of Port B.
// DOUTB : Data output of Port B.
// INJECTSBITERR : Single Bit ECC Error Injection Pin.
// INJECTDBITERR : Double Bit ECC Error Injection Pin.
// SBITERR : Output signal indicating that a Single Bit ECC Error has been
// detected and corrected.
// DBITERR : Output signal indicating that a Double Bit ECC Error has been
// detected.
// RDADDRECC : Read Address Output signal indicating address at which an
// ECC error has occurred.
//////////////////////////////////////////////////////////////////////////
wire SBITERR;
wire DBITERR;
wire S_AXI_AWREADY;
wire S_AXI_WREADY;
wire S_AXI_BVALID;
wire S_AXI_ARREADY;
wire S_AXI_RLAST;
wire S_AXI_RVALID;
wire S_AXI_SBITERR;
wire S_AXI_DBITERR;
wire [C_WEA_WIDTH-1:0] WEA = wea;
wire [C_ADDRA_WIDTH-1:0] ADDRA = addra;
wire [C_WRITE_WIDTH_A-1:0] DINA = dina;
wire [C_READ_WIDTH_A-1:0] DOUTA;
wire [C_WEB_WIDTH-1:0] WEB = web;
wire [C_ADDRB_WIDTH-1:0] ADDRB = addrb;
wire [C_WRITE_WIDTH_B-1:0] DINB = dinb;
wire [C_READ_WIDTH_B-1:0] DOUTB;
wire [C_ADDRB_WIDTH-1:0] RDADDRECC;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID = s_axi_awid;
wire [31:0] S_AXI_AWADDR = s_axi_awaddr;
wire [7:0] S_AXI_AWLEN = s_axi_awlen;
wire [2:0] S_AXI_AWSIZE = s_axi_awsize;
wire [1:0] S_AXI_AWBURST = s_axi_awburst;
wire [C_WRITE_WIDTH_A-1:0] S_AXI_WDATA = s_axi_wdata;
wire [C_WEA_WIDTH-1:0] S_AXI_WSTRB = s_axi_wstrb;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID;
wire [1:0] S_AXI_BRESP;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_ARID = s_axi_arid;
wire [31:0] S_AXI_ARADDR = s_axi_araddr;
wire [7:0] S_AXI_ARLEN = s_axi_arlen;
wire [2:0] S_AXI_ARSIZE = s_axi_arsize;
wire [1:0] S_AXI_ARBURST = s_axi_arburst;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID;
wire [C_WRITE_WIDTH_B-1:0] S_AXI_RDATA;
wire [1:0] S_AXI_RRESP;
wire [C_ADDRB_WIDTH-1:0] S_AXI_RDADDRECC;
// Added to fix the simulation warning #CR731605
wire [C_WEB_WIDTH-1:0] WEB_parameterized = 0;
wire ECCPIPECE;
wire SLEEP;
assign CLKA = clka;
assign RSTA = rsta;
assign ENA = ena;
assign REGCEA = regcea;
assign CLKB = clkb;
assign RSTB = rstb;
assign ENB = enb;
assign REGCEB = regceb;
assign INJECTSBITERR = injectsbiterr;
assign INJECTDBITERR = injectdbiterr;
assign ECCPIPECE = eccpipece;
assign SLEEP = sleep;
assign sbiterr = SBITERR;
assign dbiterr = DBITERR;
assign S_ACLK = s_aclk;
assign S_ARESETN = s_aresetn;
assign S_AXI_AWVALID = s_axi_awvalid;
assign s_axi_awready = S_AXI_AWREADY;
assign S_AXI_WLAST = s_axi_wlast;
assign S_AXI_WVALID = s_axi_wvalid;
assign s_axi_wready = S_AXI_WREADY;
assign s_axi_bvalid = S_AXI_BVALID;
assign S_AXI_BREADY = s_axi_bready;
assign S_AXI_ARVALID = s_axi_arvalid;
assign s_axi_arready = S_AXI_ARREADY;
assign s_axi_rlast = S_AXI_RLAST;
assign s_axi_rvalid = S_AXI_RVALID;
assign S_AXI_RREADY = s_axi_rready;
assign S_AXI_INJECTSBITERR = s_axi_injectsbiterr;
assign S_AXI_INJECTDBITERR = s_axi_injectdbiterr;
assign s_axi_sbiterr = S_AXI_SBITERR;
assign s_axi_dbiterr = S_AXI_DBITERR;
assign doutb = DOUTB;
assign douta = DOUTA;
assign rdaddrecc = RDADDRECC;
assign s_axi_bid = S_AXI_BID;
assign s_axi_bresp = S_AXI_BRESP;
assign s_axi_rid = S_AXI_RID;
assign s_axi_rdata = S_AXI_RDATA;
assign s_axi_rresp = S_AXI_RRESP;
assign s_axi_rdaddrecc = S_AXI_RDADDRECC;
localparam FLOP_DELAY = 100; // 100 ps
reg injectsbiterr_in;
reg injectdbiterr_in;
reg rsta_in;
reg ena_in;
reg regcea_in;
reg [C_WEA_WIDTH-1:0] wea_in;
reg [C_ADDRA_WIDTH-1:0] addra_in;
reg [C_WRITE_WIDTH_A-1:0] dina_in;
wire [C_ADDRA_WIDTH-1:0] s_axi_awaddr_out_c;
wire [C_ADDRB_WIDTH-1:0] s_axi_araddr_out_c;
wire s_axi_wr_en_c;
wire s_axi_rd_en_c;
wire s_aresetn_a_c;
wire [7:0] s_axi_arlen_c ;
wire [C_AXI_ID_WIDTH-1 : 0] s_axi_rid_c;
wire [C_WRITE_WIDTH_B-1 : 0] s_axi_rdata_c;
wire [1:0] s_axi_rresp_c;
wire s_axi_rlast_c;
wire s_axi_rvalid_c;
wire s_axi_rready_c;
wire regceb_c;
localparam C_AXI_PAYLOAD = (C_HAS_MUX_OUTPUT_REGS_B == 1)?C_WRITE_WIDTH_B+C_AXI_ID_WIDTH+3:C_AXI_ID_WIDTH+3;
wire [C_AXI_PAYLOAD-1 : 0] s_axi_payload_c;
wire [C_AXI_PAYLOAD-1 : 0] m_axi_payload_c;
//**************
// log2roundup
//**************
function integer log2roundup (input integer data_value);
integer width;
integer cnt;
begin
width = 0;
if (data_value > 1) begin
for(cnt=1 ; cnt < data_value ; cnt = cnt * 2) begin
width = width + 1;
end //loop
end //if
log2roundup = width;
end //log2roundup
endfunction
//**************
// log2int
//**************
function integer log2int (input integer data_value);
integer width;
integer cnt;
begin
width = 0;
cnt= data_value;
for(cnt=data_value ; cnt >1 ; cnt = cnt / 2) begin
width = width + 1;
end //loop
log2int = width;
end //log2int
endfunction
//**************************************************************************
// FUNCTION : divroundup
// Returns the ceiling value of the division
// Data_value - the quantity to be divided, dividend
// Divisor - the value to divide the data_value by
//**************************************************************************
function integer divroundup (input integer data_value,input integer divisor);
integer div;
begin
div = data_value/divisor;
if ((data_value % divisor) != 0) begin
div = div+1;
end //if
divroundup = div;
end //if
endfunction
localparam AXI_FULL_MEMORY_SLAVE = ((C_AXI_SLAVE_TYPE == 0 && C_AXI_TYPE == 1)?1:0);
localparam C_AXI_ADDR_WIDTH_MSB = C_ADDRA_WIDTH+log2roundup(C_WRITE_WIDTH_A/8);
localparam C_AXI_ADDR_WIDTH = C_AXI_ADDR_WIDTH_MSB;
//Data Width Number of LSB address bits to be discarded
//1 to 16 1
//17 to 32 2
//33 to 64 3
//65 to 128 4
//129 to 256 5
//257 to 512 6
//513 to 1024 7
// The following two constants determine this.
localparam LOWER_BOUND_VAL = (log2roundup(divroundup(C_WRITE_WIDTH_A,8) == 0))?0:(log2roundup(divroundup(C_WRITE_WIDTH_A,8)));
localparam C_AXI_ADDR_WIDTH_LSB = ((AXI_FULL_MEMORY_SLAVE == 1)?0:LOWER_BOUND_VAL);
localparam C_AXI_OS_WR = 2;
//***********************************************
// INPUT REGISTERS.
//***********************************************
generate if (C_HAS_SOFTECC_INPUT_REGS_A==0) begin : no_softecc_input_reg_stage
always @* begin
injectsbiterr_in = INJECTSBITERR;
injectdbiterr_in = INJECTDBITERR;
rsta_in = RSTA;
ena_in = ENA;
regcea_in = REGCEA;
wea_in = WEA;
addra_in = ADDRA;
dina_in = DINA;
end //end always
end //end no_softecc_input_reg_stage
endgenerate
generate if (C_HAS_SOFTECC_INPUT_REGS_A==1) begin : has_softecc_input_reg_stage
always @(posedge CLKA) begin
injectsbiterr_in <= #FLOP_DELAY INJECTSBITERR;
injectdbiterr_in <= #FLOP_DELAY INJECTDBITERR;
rsta_in <= #FLOP_DELAY RSTA;
ena_in <= #FLOP_DELAY ENA;
regcea_in <= #FLOP_DELAY REGCEA;
wea_in <= #FLOP_DELAY WEA;
addra_in <= #FLOP_DELAY ADDRA;
dina_in <= #FLOP_DELAY DINA;
end //end always
end //end input_reg_stages generate statement
endgenerate
generate if ((C_INTERFACE_TYPE == 0) && (C_ENABLE_32BIT_ADDRESS == 0)) begin : native_mem_module
BLK_MEM_GEN_v8_2_mem_module
#(.C_CORENAME (C_CORENAME),
.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_MEM_TYPE (C_MEM_TYPE),
.C_BYTE_SIZE (C_BYTE_SIZE),
.C_ALGORITHM (C_ALGORITHM),
.C_USE_BRAM_BLOCK (C_USE_BRAM_BLOCK),
.C_PRIM_TYPE (C_PRIM_TYPE),
.C_LOAD_INIT_FILE (C_LOAD_INIT_FILE),
.C_INIT_FILE_NAME (C_INIT_FILE_NAME),
.C_INIT_FILE (C_INIT_FILE),
.C_USE_DEFAULT_DATA (C_USE_DEFAULT_DATA),
.C_DEFAULT_DATA (C_DEFAULT_DATA),
.C_RST_TYPE ("SYNC"),
.C_HAS_RSTA (C_HAS_RSTA),
.C_RST_PRIORITY_A (C_RST_PRIORITY_A),
.C_RSTRAM_A (C_RSTRAM_A),
.C_INITA_VAL (C_INITA_VAL),
.C_HAS_ENA (C_HAS_ENA),
.C_HAS_REGCEA (C_HAS_REGCEA),
.C_USE_BYTE_WEA (C_USE_BYTE_WEA),
.C_WEA_WIDTH (C_WEA_WIDTH),
.C_WRITE_MODE_A (C_WRITE_MODE_A),
.C_WRITE_WIDTH_A (C_WRITE_WIDTH_A),
.C_READ_WIDTH_A (C_READ_WIDTH_A),
.C_WRITE_DEPTH_A (C_WRITE_DEPTH_A),
.C_READ_DEPTH_A (C_READ_DEPTH_A),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH),
.C_HAS_RSTB (C_HAS_RSTB),
.C_RST_PRIORITY_B (C_RST_PRIORITY_B),
.C_RSTRAM_B (C_RSTRAM_B),
.C_INITB_VAL (C_INITB_VAL),
.C_HAS_ENB (C_HAS_ENB),
.C_HAS_REGCEB (C_HAS_REGCEB),
.C_USE_BYTE_WEB (C_USE_BYTE_WEB),
.C_WEB_WIDTH (C_WEB_WIDTH),
.C_WRITE_MODE_B (C_WRITE_MODE_B),
.C_WRITE_WIDTH_B (C_WRITE_WIDTH_B),
.C_READ_WIDTH_B (C_READ_WIDTH_B),
.C_WRITE_DEPTH_B (C_WRITE_DEPTH_B),
.C_READ_DEPTH_B (C_READ_DEPTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_MEM_OUTPUT_REGS_A (C_HAS_MEM_OUTPUT_REGS_A),
.C_HAS_MEM_OUTPUT_REGS_B (C_HAS_MEM_OUTPUT_REGS_B),
.C_HAS_MUX_OUTPUT_REGS_A (C_HAS_MUX_OUTPUT_REGS_A),
.C_HAS_MUX_OUTPUT_REGS_B (C_HAS_MUX_OUTPUT_REGS_B),
.C_HAS_SOFTECC_INPUT_REGS_A (C_HAS_SOFTECC_INPUT_REGS_A),
.C_HAS_SOFTECC_OUTPUT_REGS_B (C_HAS_SOFTECC_OUTPUT_REGS_B),
.C_MUX_PIPELINE_STAGES (C_MUX_PIPELINE_STAGES),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.C_HAS_INJECTERR (C_HAS_INJECTERR),
.C_SIM_COLLISION_CHECK (C_SIM_COLLISION_CHECK),
.C_COMMON_CLK (C_COMMON_CLK),
.FLOP_DELAY (FLOP_DELAY),
.C_DISABLE_WARN_BHV_COLL (C_DISABLE_WARN_BHV_COLL),
.C_EN_ECC_PIPE (C_EN_ECC_PIPE),
.C_DISABLE_WARN_BHV_RANGE (C_DISABLE_WARN_BHV_RANGE))
blk_mem_gen_v8_2_inst
(.CLKA (CLKA),
.RSTA (rsta_in),
.ENA (ena_in),
.REGCEA (regcea_in),
.WEA (wea_in),
.ADDRA (addra_in),
.DINA (dina_in),
.DOUTA (DOUTA),
.CLKB (CLKB),
.RSTB (RSTB),
.ENB (ENB),
.REGCEB (REGCEB),
.WEB (WEB),
.ADDRB (ADDRB),
.DINB (DINB),
.DOUTB (DOUTB),
.INJECTSBITERR (injectsbiterr_in),
.INJECTDBITERR (injectdbiterr_in),
.ECCPIPECE (ECCPIPECE),
.SLEEP (SLEEP),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.RDADDRECC (RDADDRECC)
);
end
endgenerate
generate if((C_INTERFACE_TYPE == 0) && (C_ENABLE_32BIT_ADDRESS == 1)) begin : native_mem_mapped_module
localparam C_ADDRA_WIDTH_ACTUAL = log2roundup(C_WRITE_DEPTH_A);
localparam C_ADDRB_WIDTH_ACTUAL = log2roundup(C_WRITE_DEPTH_B);
localparam C_ADDRA_WIDTH_MSB = C_ADDRA_WIDTH_ACTUAL+log2int(C_WRITE_WIDTH_A/8);
localparam C_ADDRB_WIDTH_MSB = C_ADDRB_WIDTH_ACTUAL+log2int(C_WRITE_WIDTH_B/8);
// localparam C_ADDRA_WIDTH_MSB = C_ADDRA_WIDTH_ACTUAL+log2roundup(C_WRITE_WIDTH_A/8);
// localparam C_ADDRB_WIDTH_MSB = C_ADDRB_WIDTH_ACTUAL+log2roundup(C_WRITE_WIDTH_B/8);
localparam C_MEM_MAP_ADDRA_WIDTH_MSB = C_ADDRA_WIDTH_MSB;
localparam C_MEM_MAP_ADDRB_WIDTH_MSB = C_ADDRB_WIDTH_MSB;
// Data Width Number of LSB address bits to be discarded
// 1 to 16 1
// 17 to 32 2
// 33 to 64 3
// 65 to 128 4
// 129 to 256 5
// 257 to 512 6
// 513 to 1024 7
// The following two constants determine this.
localparam MEM_MAP_LOWER_BOUND_VAL_A = (log2int(divroundup(C_WRITE_WIDTH_A,8)==0)) ? 0:(log2int(divroundup(C_WRITE_WIDTH_A,8)));
localparam MEM_MAP_LOWER_BOUND_VAL_B = (log2int(divroundup(C_WRITE_WIDTH_A,8)==0)) ? 0:(log2int(divroundup(C_WRITE_WIDTH_A,8)));
localparam C_MEM_MAP_ADDRA_WIDTH_LSB = MEM_MAP_LOWER_BOUND_VAL_A;
localparam C_MEM_MAP_ADDRB_WIDTH_LSB = MEM_MAP_LOWER_BOUND_VAL_B;
wire [C_ADDRB_WIDTH_ACTUAL-1 :0] rdaddrecc_i;
wire [C_ADDRB_WIDTH-1:C_MEM_MAP_ADDRB_WIDTH_MSB] msb_zero_i;
wire [C_MEM_MAP_ADDRB_WIDTH_LSB-1:0] lsb_zero_i;
assign msb_zero_i = 0;
assign lsb_zero_i = 0;
assign RDADDRECC = {msb_zero_i,rdaddrecc_i,lsb_zero_i};
BLK_MEM_GEN_v8_2_mem_module
#(.C_CORENAME (C_CORENAME),
.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_MEM_TYPE (C_MEM_TYPE),
.C_BYTE_SIZE (C_BYTE_SIZE),
.C_USE_BRAM_BLOCK (C_USE_BRAM_BLOCK),
.C_ALGORITHM (C_ALGORITHM),
.C_PRIM_TYPE (C_PRIM_TYPE),
.C_LOAD_INIT_FILE (C_LOAD_INIT_FILE),
.C_INIT_FILE_NAME (C_INIT_FILE_NAME),
.C_INIT_FILE (C_INIT_FILE),
.C_USE_DEFAULT_DATA (C_USE_DEFAULT_DATA),
.C_DEFAULT_DATA (C_DEFAULT_DATA),
.C_RST_TYPE ("SYNC"),
.C_HAS_RSTA (C_HAS_RSTA),
.C_RST_PRIORITY_A (C_RST_PRIORITY_A),
.C_RSTRAM_A (C_RSTRAM_A),
.C_INITA_VAL (C_INITA_VAL),
.C_HAS_ENA (C_HAS_ENA),
.C_HAS_REGCEA (C_HAS_REGCEA),
.C_USE_BYTE_WEA (C_USE_BYTE_WEA),
.C_WEA_WIDTH (C_WEA_WIDTH),
.C_WRITE_MODE_A (C_WRITE_MODE_A),
.C_WRITE_WIDTH_A (C_WRITE_WIDTH_A),
.C_READ_WIDTH_A (C_READ_WIDTH_A),
.C_WRITE_DEPTH_A (C_WRITE_DEPTH_A),
.C_READ_DEPTH_A (C_READ_DEPTH_A),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH_ACTUAL),
.C_HAS_RSTB (C_HAS_RSTB),
.C_RST_PRIORITY_B (C_RST_PRIORITY_B),
.C_RSTRAM_B (C_RSTRAM_B),
.C_INITB_VAL (C_INITB_VAL),
.C_HAS_ENB (C_HAS_ENB),
.C_HAS_REGCEB (C_HAS_REGCEB),
.C_USE_BYTE_WEB (C_USE_BYTE_WEB),
.C_WEB_WIDTH (C_WEB_WIDTH),
.C_WRITE_MODE_B (C_WRITE_MODE_B),
.C_WRITE_WIDTH_B (C_WRITE_WIDTH_B),
.C_READ_WIDTH_B (C_READ_WIDTH_B),
.C_WRITE_DEPTH_B (C_WRITE_DEPTH_B),
.C_READ_DEPTH_B (C_READ_DEPTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH_ACTUAL),
.C_HAS_MEM_OUTPUT_REGS_A (C_HAS_MEM_OUTPUT_REGS_A),
.C_HAS_MEM_OUTPUT_REGS_B (C_HAS_MEM_OUTPUT_REGS_B),
.C_HAS_MUX_OUTPUT_REGS_A (C_HAS_MUX_OUTPUT_REGS_A),
.C_HAS_MUX_OUTPUT_REGS_B (C_HAS_MUX_OUTPUT_REGS_B),
.C_HAS_SOFTECC_INPUT_REGS_A (C_HAS_SOFTECC_INPUT_REGS_A),
.C_HAS_SOFTECC_OUTPUT_REGS_B (C_HAS_SOFTECC_OUTPUT_REGS_B),
.C_MUX_PIPELINE_STAGES (C_MUX_PIPELINE_STAGES),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.C_HAS_INJECTERR (C_HAS_INJECTERR),
.C_SIM_COLLISION_CHECK (C_SIM_COLLISION_CHECK),
.C_COMMON_CLK (C_COMMON_CLK),
.FLOP_DELAY (FLOP_DELAY),
.C_DISABLE_WARN_BHV_COLL (C_DISABLE_WARN_BHV_COLL),
.C_EN_ECC_PIPE (C_EN_ECC_PIPE),
.C_DISABLE_WARN_BHV_RANGE (C_DISABLE_WARN_BHV_RANGE))
blk_mem_gen_v8_2_inst
(.CLKA (CLKA),
.RSTA (rsta_in),
.ENA (ena_in),
.REGCEA (regcea_in),
.WEA (wea_in),
.ADDRA (addra_in[C_MEM_MAP_ADDRA_WIDTH_MSB-1:C_MEM_MAP_ADDRA_WIDTH_LSB]),
.DINA (dina_in),
.DOUTA (DOUTA),
.CLKB (CLKB),
.RSTB (RSTB),
.ENB (ENB),
.REGCEB (REGCEB),
.WEB (WEB),
.ADDRB (ADDRB[C_MEM_MAP_ADDRB_WIDTH_MSB-1:C_MEM_MAP_ADDRB_WIDTH_LSB]),
.DINB (DINB),
.DOUTB (DOUTB),
.INJECTSBITERR (injectsbiterr_in),
.INJECTDBITERR (injectdbiterr_in),
.ECCPIPECE (ECCPIPECE),
.SLEEP (SLEEP),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.RDADDRECC (rdaddrecc_i)
);
end
endgenerate
generate if (C_HAS_MEM_OUTPUT_REGS_B == 0 && C_HAS_MUX_OUTPUT_REGS_B == 0 ) begin : no_regs
assign S_AXI_RDATA = s_axi_rdata_c;
assign S_AXI_RLAST = s_axi_rlast_c;
assign S_AXI_RVALID = s_axi_rvalid_c;
assign S_AXI_RID = s_axi_rid_c;
assign S_AXI_RRESP = s_axi_rresp_c;
assign s_axi_rready_c = S_AXI_RREADY;
end
endgenerate
generate if (C_HAS_MEM_OUTPUT_REGS_B == 1) begin : has_regceb
assign regceb_c = s_axi_rvalid_c && s_axi_rready_c;
end
endgenerate
generate if (C_HAS_MEM_OUTPUT_REGS_B == 0) begin : no_regceb
assign regceb_c = REGCEB;
end
endgenerate
generate if (C_HAS_MUX_OUTPUT_REGS_B == 1) begin : only_core_op_regs
assign s_axi_payload_c = {s_axi_rid_c,s_axi_rdata_c,s_axi_rresp_c,s_axi_rlast_c};
assign S_AXI_RID = m_axi_payload_c[C_AXI_PAYLOAD-1 : C_AXI_PAYLOAD-C_AXI_ID_WIDTH];
assign S_AXI_RDATA = m_axi_payload_c[C_AXI_PAYLOAD-C_AXI_ID_WIDTH-1 : C_AXI_PAYLOAD-C_AXI_ID_WIDTH-C_WRITE_WIDTH_B];
assign S_AXI_RRESP = m_axi_payload_c[2:1];
assign S_AXI_RLAST = m_axi_payload_c[0];
end
endgenerate
generate if (C_HAS_MEM_OUTPUT_REGS_B == 1) begin : only_emb_op_regs
assign s_axi_payload_c = {s_axi_rid_c,s_axi_rresp_c,s_axi_rlast_c};
assign S_AXI_RDATA = s_axi_rdata_c;
assign S_AXI_RID = m_axi_payload_c[C_AXI_PAYLOAD-1 : C_AXI_PAYLOAD-C_AXI_ID_WIDTH];
assign S_AXI_RRESP = m_axi_payload_c[2:1];
assign S_AXI_RLAST = m_axi_payload_c[0];
end
endgenerate
generate if (C_HAS_MUX_OUTPUT_REGS_B == 1 || C_HAS_MEM_OUTPUT_REGS_B == 1) begin : has_regs_fwd
blk_mem_axi_regs_fwd_v8_2
#(.C_DATA_WIDTH (C_AXI_PAYLOAD))
axi_regs_inst (
.ACLK (S_ACLK),
.ARESET (s_aresetn_a_c),
.S_VALID (s_axi_rvalid_c),
.S_READY (s_axi_rready_c),
.S_PAYLOAD_DATA (s_axi_payload_c),
.M_VALID (S_AXI_RVALID),
.M_READY (S_AXI_RREADY),
.M_PAYLOAD_DATA (m_axi_payload_c)
);
end
endgenerate
generate if (C_INTERFACE_TYPE == 1) begin : axi_mem_module
assign s_aresetn_a_c = !S_ARESETN;
assign S_AXI_BRESP = 2'b00;
assign s_axi_rresp_c = 2'b00;
assign s_axi_arlen_c = (C_AXI_TYPE == 1)?S_AXI_ARLEN:8'h0;
blk_mem_axi_write_wrapper_beh_v8_2
#(.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_AXI_SLAVE_TYPE (C_AXI_SLAVE_TYPE),
.C_MEMORY_TYPE (C_MEM_TYPE),
.C_WRITE_DEPTH_A (C_WRITE_DEPTH_A),
.C_AXI_AWADDR_WIDTH ((AXI_FULL_MEMORY_SLAVE == 1)?C_AXI_ADDR_WIDTH:C_AXI_ADDR_WIDTH-C_AXI_ADDR_WIDTH_LSB),
.C_HAS_AXI_ID (C_HAS_AXI_ID),
.C_AXI_ID_WIDTH (C_AXI_ID_WIDTH),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH),
.C_AXI_WDATA_WIDTH (C_WRITE_WIDTH_A),
.C_AXI_OS_WR (C_AXI_OS_WR))
axi_wr_fsm (
// AXI Global Signals
.S_ACLK (S_ACLK),
.S_ARESETN (s_aresetn_a_c),
// AXI Full/Lite Slave Write interface
.S_AXI_AWADDR (S_AXI_AWADDR[C_AXI_ADDR_WIDTH_MSB-1:C_AXI_ADDR_WIDTH_LSB]),
.S_AXI_AWLEN (S_AXI_AWLEN),
.S_AXI_AWID (S_AXI_AWID),
.S_AXI_AWSIZE (S_AXI_AWSIZE),
.S_AXI_AWBURST (S_AXI_AWBURST),
.S_AXI_AWVALID (S_AXI_AWVALID),
.S_AXI_AWREADY (S_AXI_AWREADY),
.S_AXI_WVALID (S_AXI_WVALID),
.S_AXI_WREADY (S_AXI_WREADY),
.S_AXI_BVALID (S_AXI_BVALID),
.S_AXI_BREADY (S_AXI_BREADY),
.S_AXI_BID (S_AXI_BID),
// Signals for BRAM interfac(
.S_AXI_AWADDR_OUT (s_axi_awaddr_out_c),
.S_AXI_WR_EN (s_axi_wr_en_c)
);
blk_mem_axi_read_wrapper_beh_v8_2
#(.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_AXI_SLAVE_TYPE (C_AXI_SLAVE_TYPE),
.C_MEMORY_TYPE (C_MEM_TYPE),
.C_WRITE_WIDTH_A (C_WRITE_WIDTH_A),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH),
.C_AXI_PIPELINE_STAGES (1),
.C_AXI_ARADDR_WIDTH ((AXI_FULL_MEMORY_SLAVE == 1)?C_AXI_ADDR_WIDTH:C_AXI_ADDR_WIDTH-C_AXI_ADDR_WIDTH_LSB),
.C_HAS_AXI_ID (C_HAS_AXI_ID),
.C_AXI_ID_WIDTH (C_AXI_ID_WIDTH),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH))
axi_rd_sm(
//AXI Global Signals
.S_ACLK (S_ACLK),
.S_ARESETN (s_aresetn_a_c),
//AXI Full/Lite Read Side
.S_AXI_ARADDR (S_AXI_ARADDR[C_AXI_ADDR_WIDTH_MSB-1:C_AXI_ADDR_WIDTH_LSB]),
.S_AXI_ARLEN (s_axi_arlen_c),
.S_AXI_ARSIZE (S_AXI_ARSIZE),
.S_AXI_ARBURST (S_AXI_ARBURST),
.S_AXI_ARVALID (S_AXI_ARVALID),
.S_AXI_ARREADY (S_AXI_ARREADY),
.S_AXI_RLAST (s_axi_rlast_c),
.S_AXI_RVALID (s_axi_rvalid_c),
.S_AXI_RREADY (s_axi_rready_c),
.S_AXI_ARID (S_AXI_ARID),
.S_AXI_RID (s_axi_rid_c),
//AXI Full/Lite Read FSM Outputs
.S_AXI_ARADDR_OUT (s_axi_araddr_out_c),
.S_AXI_RD_EN (s_axi_rd_en_c)
);
BLK_MEM_GEN_v8_2_mem_module
#(.C_CORENAME (C_CORENAME),
.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_MEM_TYPE (C_MEM_TYPE),
.C_BYTE_SIZE (C_BYTE_SIZE),
.C_USE_BRAM_BLOCK (C_USE_BRAM_BLOCK),
.C_ALGORITHM (C_ALGORITHM),
.C_PRIM_TYPE (C_PRIM_TYPE),
.C_LOAD_INIT_FILE (C_LOAD_INIT_FILE),
.C_INIT_FILE_NAME (C_INIT_FILE_NAME),
.C_INIT_FILE (C_INIT_FILE),
.C_USE_DEFAULT_DATA (C_USE_DEFAULT_DATA),
.C_DEFAULT_DATA (C_DEFAULT_DATA),
.C_RST_TYPE ("SYNC"),
.C_HAS_RSTA (C_HAS_RSTA),
.C_RST_PRIORITY_A (C_RST_PRIORITY_A),
.C_RSTRAM_A (C_RSTRAM_A),
.C_INITA_VAL (C_INITA_VAL),
.C_HAS_ENA (1),
.C_HAS_REGCEA (C_HAS_REGCEA),
.C_USE_BYTE_WEA (1),
.C_WEA_WIDTH (C_WEA_WIDTH),
.C_WRITE_MODE_A (C_WRITE_MODE_A),
.C_WRITE_WIDTH_A (C_WRITE_WIDTH_A),
.C_READ_WIDTH_A (C_READ_WIDTH_A),
.C_WRITE_DEPTH_A (C_WRITE_DEPTH_A),
.C_READ_DEPTH_A (C_READ_DEPTH_A),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH),
.C_HAS_RSTB (C_HAS_RSTB),
.C_RST_PRIORITY_B (C_RST_PRIORITY_B),
.C_RSTRAM_B (C_RSTRAM_B),
.C_INITB_VAL (C_INITB_VAL),
.C_HAS_ENB (1),
.C_HAS_REGCEB (C_HAS_MEM_OUTPUT_REGS_B),
.C_USE_BYTE_WEB (1),
.C_WEB_WIDTH (C_WEB_WIDTH),
.C_WRITE_MODE_B (C_WRITE_MODE_B),
.C_WRITE_WIDTH_B (C_WRITE_WIDTH_B),
.C_READ_WIDTH_B (C_READ_WIDTH_B),
.C_WRITE_DEPTH_B (C_WRITE_DEPTH_B),
.C_READ_DEPTH_B (C_READ_DEPTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_MEM_OUTPUT_REGS_A (0),
.C_HAS_MEM_OUTPUT_REGS_B (C_HAS_MEM_OUTPUT_REGS_B),
.C_HAS_MUX_OUTPUT_REGS_A (0),
.C_HAS_MUX_OUTPUT_REGS_B (0),
.C_HAS_SOFTECC_INPUT_REGS_A (C_HAS_SOFTECC_INPUT_REGS_A),
.C_HAS_SOFTECC_OUTPUT_REGS_B (C_HAS_SOFTECC_OUTPUT_REGS_B),
.C_MUX_PIPELINE_STAGES (C_MUX_PIPELINE_STAGES),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.C_HAS_INJECTERR (C_HAS_INJECTERR),
.C_SIM_COLLISION_CHECK (C_SIM_COLLISION_CHECK),
.C_COMMON_CLK (C_COMMON_CLK),
.FLOP_DELAY (FLOP_DELAY),
.C_DISABLE_WARN_BHV_COLL (C_DISABLE_WARN_BHV_COLL),
.C_EN_ECC_PIPE (0),
.C_DISABLE_WARN_BHV_RANGE (C_DISABLE_WARN_BHV_RANGE))
blk_mem_gen_v8_2_inst
(.CLKA (S_ACLK),
.RSTA (s_aresetn_a_c),
.ENA (s_axi_wr_en_c),
.REGCEA (regcea_in),
.WEA (S_AXI_WSTRB),
.ADDRA (s_axi_awaddr_out_c),
.DINA (S_AXI_WDATA),
.DOUTA (DOUTA),
.CLKB (S_ACLK),
.RSTB (s_aresetn_a_c),
.ENB (s_axi_rd_en_c),
.REGCEB (regceb_c),
.WEB (WEB_parameterized),
.ADDRB (s_axi_araddr_out_c),
.DINB (DINB),
.DOUTB (s_axi_rdata_c),
.INJECTSBITERR (injectsbiterr_in),
.INJECTDBITERR (injectdbiterr_in),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.ECCPIPECE (1'b0),
.SLEEP (1'b0),
.RDADDRECC (RDADDRECC)
);
end
endgenerate
endmodule |
module STATE_LOGIC_v8_2 (O, I0, I1, I2, I3, I4, I5);
parameter INIT = 64'h0000000000000000;
input I0, I1, I2, I3, I4, I5;
output O;
reg O;
reg tmp;
always @( I5 or I4 or I3 or I2 or I1 or I0 ) begin
tmp = I0 ^ I1 ^ I2 ^ I3 ^ I4 ^ I5;
if ( tmp == 0 || tmp == 1)
O = INIT[{I5, I4, I3, I2, I1, I0}];
end
endmodule |
module beh_vlog_muxf7_v8_2 (O, I0, I1, S);
output O;
reg O;
input I0, I1, S;
always @(I0 or I1 or S)
if (S)
O = I1;
else
O = I0;
endmodule |
module beh_vlog_ff_clr_v8_2 (Q, C, CLR, D);
parameter INIT = 0;
localparam FLOP_DELAY = 100;
output Q;
input C, CLR, D;
reg Q;
initial Q= 1'b0;
always @(posedge C )
if (CLR)
Q<= 1'b0;
else
Q<= #FLOP_DELAY D;
endmodule |
module beh_vlog_ff_pre_v8_2 (Q, C, D, PRE);
parameter INIT = 0;
localparam FLOP_DELAY = 100;
output Q;
input C, D, PRE;
reg Q;
initial Q= 1'b0;
always @(posedge C )
if (PRE)
Q <= 1'b1;
else
Q <= #FLOP_DELAY D;
endmodule |
module beh_vlog_ff_ce_clr_v8_2 (Q, C, CE, CLR, D);
parameter INIT = 0;
localparam FLOP_DELAY = 100;
output Q;
input C, CE, CLR, D;
reg Q;
initial Q= 1'b0;
always @(posedge C )
if (CLR)
Q <= 1'b0;
else if (CE)
Q <= #FLOP_DELAY D;
endmodule |
module write_netlist_v8_2
#(
parameter C_AXI_TYPE = 0
)
(
S_ACLK, S_ARESETN, S_AXI_AWVALID, S_AXI_WVALID, S_AXI_BREADY,
w_last_c, bready_timeout_c, aw_ready_r, S_AXI_WREADY, S_AXI_BVALID,
S_AXI_WR_EN, addr_en_c, incr_addr_c, bvalid_c
);
input S_ACLK;
input S_ARESETN;
input S_AXI_AWVALID;
input S_AXI_WVALID;
input S_AXI_BREADY;
input w_last_c;
input bready_timeout_c;
output aw_ready_r;
output S_AXI_WREADY;
output S_AXI_BVALID;
output S_AXI_WR_EN;
output addr_en_c;
output incr_addr_c;
output bvalid_c;
//-------------------------------------------------------------------------
//AXI LITE
//-------------------------------------------------------------------------
generate if (C_AXI_TYPE == 0 ) begin : gbeh_axi_lite_sm
wire w_ready_r_7;
wire w_ready_c;
wire aw_ready_c;
wire NlwRenamedSignal_bvalid_c;
wire NlwRenamedSignal_incr_addr_c;
wire present_state_FSM_FFd3_13;
wire present_state_FSM_FFd2_14;
wire present_state_FSM_FFd1_15;
wire present_state_FSM_FFd4_16;
wire present_state_FSM_FFd4_In;
wire present_state_FSM_FFd3_In;
wire present_state_FSM_FFd2_In;
wire present_state_FSM_FFd1_In;
wire present_state_FSM_FFd4_In1_21;
wire [0:0] Mmux_aw_ready_c ;
begin
assign
S_AXI_WREADY = w_ready_r_7,
S_AXI_BVALID = NlwRenamedSignal_incr_addr_c,
S_AXI_WR_EN = NlwRenamedSignal_bvalid_c,
incr_addr_c = NlwRenamedSignal_incr_addr_c,
bvalid_c = NlwRenamedSignal_bvalid_c;
assign NlwRenamedSignal_incr_addr_c = 1'b0;
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
aw_ready_r_2 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( aw_ready_c),
.Q ( aw_ready_r)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
w_ready_r (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( w_ready_c),
.Q ( w_ready_r_7)
);
beh_vlog_ff_pre_v8_2 #(
.INIT (1'b1))
present_state_FSM_FFd4 (
.C ( S_ACLK),
.D ( present_state_FSM_FFd4_In),
.PRE ( S_ARESETN),
.Q ( present_state_FSM_FFd4_16)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd3 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd3_In),
.Q ( present_state_FSM_FFd3_13)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd2 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd2_In),
.Q ( present_state_FSM_FFd2_14)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd1 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd1_In),
.Q ( present_state_FSM_FFd1_15)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000055554440))
present_state_FSM_FFd3_In1 (
.I0 ( S_AXI_WVALID),
.I1 ( S_AXI_AWVALID),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( present_state_FSM_FFd4_16),
.I4 ( present_state_FSM_FFd3_13),
.I5 (1'b0),
.O ( present_state_FSM_FFd3_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000088880800))
present_state_FSM_FFd2_In1 (
.I0 ( S_AXI_AWVALID),
.I1 ( S_AXI_WVALID),
.I2 ( bready_timeout_c),
.I3 ( present_state_FSM_FFd2_14),
.I4 ( present_state_FSM_FFd4_16),
.I5 (1'b0),
.O ( present_state_FSM_FFd2_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000AAAA2000))
Mmux_addr_en_c_0_1 (
.I0 ( S_AXI_AWVALID),
.I1 ( bready_timeout_c),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( S_AXI_WVALID),
.I4 ( present_state_FSM_FFd4_16),
.I5 (1'b0),
.O ( addr_en_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hF5F07570F5F05500))
Mmux_w_ready_c_0_1 (
.I0 ( S_AXI_WVALID),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd3_13),
.I4 ( present_state_FSM_FFd4_16),
.I5 ( present_state_FSM_FFd2_14),
.O ( w_ready_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h88808880FFFF8880))
present_state_FSM_FFd1_In1 (
.I0 ( S_AXI_WVALID),
.I1 ( bready_timeout_c),
.I2 ( present_state_FSM_FFd3_13),
.I3 ( present_state_FSM_FFd2_14),
.I4 ( present_state_FSM_FFd1_15),
.I5 ( S_AXI_BREADY),
.O ( present_state_FSM_FFd1_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000A8))
Mmux_S_AXI_WR_EN_0_1 (
.I0 ( S_AXI_WVALID),
.I1 ( present_state_FSM_FFd2_14),
.I2 ( present_state_FSM_FFd3_13),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( NlwRenamedSignal_bvalid_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h2F0F27072F0F2200))
present_state_FSM_FFd4_In1 (
.I0 ( S_AXI_WVALID),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd3_13),
.I4 ( present_state_FSM_FFd4_16),
.I5 ( present_state_FSM_FFd2_14),
.O ( present_state_FSM_FFd4_In1_21)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000F8))
present_state_FSM_FFd4_In2 (
.I0 ( present_state_FSM_FFd1_15),
.I1 ( S_AXI_BREADY),
.I2 ( present_state_FSM_FFd4_In1_21),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( present_state_FSM_FFd4_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h7535753575305500))
Mmux_aw_ready_c_0_1 (
.I0 ( S_AXI_AWVALID),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_WVALID),
.I3 ( present_state_FSM_FFd4_16),
.I4 ( present_state_FSM_FFd3_13),
.I5 ( present_state_FSM_FFd2_14),
.O ( Mmux_aw_ready_c[0])
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000F8))
Mmux_aw_ready_c_0_2 (
.I0 ( present_state_FSM_FFd1_15),
.I1 ( S_AXI_BREADY),
.I2 ( Mmux_aw_ready_c[0]),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( aw_ready_c)
);
end
end
endgenerate
//---------------------------------------------------------------------
// AXI FULL
//---------------------------------------------------------------------
generate if (C_AXI_TYPE == 1 ) begin : gbeh_axi_full_sm
wire w_ready_r_8;
wire w_ready_c;
wire aw_ready_c;
wire NlwRenamedSig_OI_bvalid_c;
wire present_state_FSM_FFd1_16;
wire present_state_FSM_FFd4_17;
wire present_state_FSM_FFd3_18;
wire present_state_FSM_FFd2_19;
wire present_state_FSM_FFd4_In;
wire present_state_FSM_FFd3_In;
wire present_state_FSM_FFd2_In;
wire present_state_FSM_FFd1_In;
wire present_state_FSM_FFd2_In1_24;
wire present_state_FSM_FFd4_In1_25;
wire N2;
wire N4;
begin
assign
S_AXI_WREADY = w_ready_r_8,
bvalid_c = NlwRenamedSig_OI_bvalid_c,
S_AXI_BVALID = 1'b0;
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
aw_ready_r_2
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( aw_ready_c),
.Q ( aw_ready_r)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
w_ready_r
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( w_ready_c),
.Q ( w_ready_r_8)
);
beh_vlog_ff_pre_v8_2 #(
.INIT (1'b1))
present_state_FSM_FFd4
(
.C ( S_ACLK),
.D ( present_state_FSM_FFd4_In),
.PRE ( S_ARESETN),
.Q ( present_state_FSM_FFd4_17)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd3
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd3_In),
.Q ( present_state_FSM_FFd3_18)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd2
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd2_In),
.Q ( present_state_FSM_FFd2_19)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd1
(
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd1_In),
.Q ( present_state_FSM_FFd1_16)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000005540))
present_state_FSM_FFd3_In1
(
.I0 ( S_AXI_WVALID),
.I1 ( present_state_FSM_FFd4_17),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd3_18),
.I4 (1'b0),
.I5 (1'b0),
.O ( present_state_FSM_FFd3_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hBF3FBB33AF0FAA00))
Mmux_aw_ready_c_0_2
(
.I0 ( S_AXI_BREADY),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd1_16),
.I4 ( present_state_FSM_FFd4_17),
.I5 ( NlwRenamedSig_OI_bvalid_c),
.O ( aw_ready_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hAAAAAAAA20000000))
Mmux_addr_en_c_0_1
(
.I0 ( S_AXI_AWVALID),
.I1 ( bready_timeout_c),
.I2 ( present_state_FSM_FFd2_19),
.I3 ( S_AXI_WVALID),
.I4 ( w_last_c),
.I5 ( present_state_FSM_FFd4_17),
.O ( addr_en_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000A8))
Mmux_S_AXI_WR_EN_0_1
(
.I0 ( S_AXI_WVALID),
.I1 ( present_state_FSM_FFd2_19),
.I2 ( present_state_FSM_FFd3_18),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( S_AXI_WR_EN)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000002220))
Mmux_incr_addr_c_0_1
(
.I0 ( S_AXI_WVALID),
.I1 ( w_last_c),
.I2 ( present_state_FSM_FFd2_19),
.I3 ( present_state_FSM_FFd3_18),
.I4 (1'b0),
.I5 (1'b0),
.O ( incr_addr_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000008880))
Mmux_aw_ready_c_0_11
(
.I0 ( S_AXI_WVALID),
.I1 ( w_last_c),
.I2 ( present_state_FSM_FFd2_19),
.I3 ( present_state_FSM_FFd3_18),
.I4 (1'b0),
.I5 (1'b0),
.O ( NlwRenamedSig_OI_bvalid_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h000000000000D5C0))
present_state_FSM_FFd2_In1
(
.I0 ( w_last_c),
.I1 ( S_AXI_AWVALID),
.I2 ( present_state_FSM_FFd4_17),
.I3 ( present_state_FSM_FFd3_18),
.I4 (1'b0),
.I5 (1'b0),
.O ( present_state_FSM_FFd2_In1_24)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hFFFFAAAA08AAAAAA))
present_state_FSM_FFd2_In2
(
.I0 ( present_state_FSM_FFd2_19),
.I1 ( S_AXI_AWVALID),
.I2 ( bready_timeout_c),
.I3 ( w_last_c),
.I4 ( S_AXI_WVALID),
.I5 ( present_state_FSM_FFd2_In1_24),
.O ( present_state_FSM_FFd2_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00C0004000C00000))
present_state_FSM_FFd4_In1
(
.I0 ( S_AXI_AWVALID),
.I1 ( w_last_c),
.I2 ( S_AXI_WVALID),
.I3 ( bready_timeout_c),
.I4 ( present_state_FSM_FFd3_18),
.I5 ( present_state_FSM_FFd2_19),
.O ( present_state_FSM_FFd4_In1_25)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000FFFF88F8))
present_state_FSM_FFd4_In2
(
.I0 ( present_state_FSM_FFd1_16),
.I1 ( S_AXI_BREADY),
.I2 ( present_state_FSM_FFd4_17),
.I3 ( S_AXI_AWVALID),
.I4 ( present_state_FSM_FFd4_In1_25),
.I5 (1'b0),
.O ( present_state_FSM_FFd4_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000007))
Mmux_w_ready_c_0_SW0
(
.I0 ( w_last_c),
.I1 ( S_AXI_WVALID),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( N2)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hFABAFABAFAAAF000))
Mmux_w_ready_c_0_Q
(
.I0 ( N2),
.I1 ( bready_timeout_c),
.I2 ( S_AXI_AWVALID),
.I3 ( present_state_FSM_FFd4_17),
.I4 ( present_state_FSM_FFd3_18),
.I5 ( present_state_FSM_FFd2_19),
.O ( w_ready_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000008))
Mmux_aw_ready_c_0_11_SW0
(
.I0 ( bready_timeout_c),
.I1 ( S_AXI_WVALID),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O ( N4)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h88808880FFFF8880))
present_state_FSM_FFd1_In1
(
.I0 ( w_last_c),
.I1 ( N4),
.I2 ( present_state_FSM_FFd2_19),
.I3 ( present_state_FSM_FFd3_18),
.I4 ( present_state_FSM_FFd1_16),
.I5 ( S_AXI_BREADY),
.O ( present_state_FSM_FFd1_In)
);
end
end
endgenerate
endmodule |
module read_netlist_v8_2 #(
parameter C_AXI_TYPE = 1,
parameter C_ADDRB_WIDTH = 12
) ( S_AXI_R_LAST_INT, S_ACLK, S_ARESETN, S_AXI_ARVALID,
S_AXI_RREADY,S_AXI_INCR_ADDR,S_AXI_ADDR_EN,
S_AXI_SINGLE_TRANS,S_AXI_MUX_SEL, S_AXI_R_LAST, S_AXI_ARREADY,
S_AXI_RLAST, S_AXI_RVALID, S_AXI_RD_EN, S_AXI_ARLEN);
input S_AXI_R_LAST_INT;
input S_ACLK;
input S_ARESETN;
input S_AXI_ARVALID;
input S_AXI_RREADY;
output S_AXI_INCR_ADDR;
output S_AXI_ADDR_EN;
output S_AXI_SINGLE_TRANS;
output S_AXI_MUX_SEL;
output S_AXI_R_LAST;
output S_AXI_ARREADY;
output S_AXI_RLAST;
output S_AXI_RVALID;
output S_AXI_RD_EN;
input [7:0] S_AXI_ARLEN;
wire present_state_FSM_FFd1_13 ;
wire present_state_FSM_FFd2_14 ;
wire gaxi_full_sm_outstanding_read_r_15 ;
wire gaxi_full_sm_ar_ready_r_16 ;
wire gaxi_full_sm_r_last_r_17 ;
wire NlwRenamedSig_OI_gaxi_full_sm_r_valid_r ;
wire gaxi_full_sm_r_valid_c ;
wire S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o ;
wire gaxi_full_sm_ar_ready_c ;
wire gaxi_full_sm_outstanding_read_c ;
wire NlwRenamedSig_OI_S_AXI_R_LAST ;
wire S_AXI_ARLEN_7_GND_8_o_equal_1_o ;
wire present_state_FSM_FFd2_In ;
wire present_state_FSM_FFd1_In ;
wire Mmux_S_AXI_R_LAST13 ;
wire N01 ;
wire N2 ;
wire Mmux_gaxi_full_sm_ar_ready_c11 ;
wire N4 ;
wire N8 ;
wire N9 ;
wire N10 ;
wire N11 ;
wire N12 ;
wire N13 ;
assign
S_AXI_R_LAST = NlwRenamedSig_OI_S_AXI_R_LAST,
S_AXI_ARREADY = gaxi_full_sm_ar_ready_r_16,
S_AXI_RLAST = gaxi_full_sm_r_last_r_17,
S_AXI_RVALID = NlwRenamedSig_OI_gaxi_full_sm_r_valid_r;
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
gaxi_full_sm_outstanding_read_r (
.C (S_ACLK),
.CLR(S_ARESETN),
.D(gaxi_full_sm_outstanding_read_c),
.Q(gaxi_full_sm_outstanding_read_r_15)
);
beh_vlog_ff_ce_clr_v8_2 #(
.INIT (1'b0))
gaxi_full_sm_r_valid_r (
.C (S_ACLK),
.CE (S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o),
.CLR (S_ARESETN),
.D (gaxi_full_sm_r_valid_c),
.Q (NlwRenamedSig_OI_gaxi_full_sm_r_valid_r)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
gaxi_full_sm_ar_ready_r (
.C (S_ACLK),
.CLR (S_ARESETN),
.D (gaxi_full_sm_ar_ready_c),
.Q (gaxi_full_sm_ar_ready_r_16)
);
beh_vlog_ff_ce_clr_v8_2 #(
.INIT(1'b0))
gaxi_full_sm_r_last_r (
.C (S_ACLK),
.CE (S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o),
.CLR (S_ARESETN),
.D (NlwRenamedSig_OI_S_AXI_R_LAST),
.Q (gaxi_full_sm_r_last_r_17)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd2 (
.C ( S_ACLK),
.CLR ( S_ARESETN),
.D ( present_state_FSM_FFd2_In),
.Q ( present_state_FSM_FFd2_14)
);
beh_vlog_ff_clr_v8_2 #(
.INIT (1'b0))
present_state_FSM_FFd1 (
.C (S_ACLK),
.CLR (S_ARESETN),
.D (present_state_FSM_FFd1_In),
.Q (present_state_FSM_FFd1_13)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h000000000000000B))
S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o1 (
.I0 ( S_AXI_RREADY),
.I1 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O (S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000008))
Mmux_S_AXI_SINGLE_TRANS11 (
.I0 (S_AXI_ARVALID),
.I1 (S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O (S_AXI_SINGLE_TRANS)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000004))
Mmux_S_AXI_ADDR_EN11 (
.I0 (present_state_FSM_FFd1_13),
.I1 (S_AXI_ARVALID),
.I2 (1'b0),
.I3 (1'b0),
.I4 (1'b0),
.I5 (1'b0),
.O (S_AXI_ADDR_EN)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hECEE2022EEEE2022))
present_state_FSM_FFd2_In1 (
.I0 ( S_AXI_ARVALID),
.I1 ( present_state_FSM_FFd1_13),
.I2 ( S_AXI_RREADY),
.I3 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I4 ( present_state_FSM_FFd2_14),
.I5 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.O ( present_state_FSM_FFd2_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000044440444))
Mmux_S_AXI_R_LAST131 (
.I0 ( present_state_FSM_FFd1_13),
.I1 ( S_AXI_ARVALID),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I4 ( S_AXI_RREADY),
.I5 (1'b0),
.O ( Mmux_S_AXI_R_LAST13)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h4000FFFF40004000))
Mmux_S_AXI_INCR_ADDR11 (
.I0 ( S_AXI_R_LAST_INT),
.I1 ( S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( present_state_FSM_FFd1_13),
.I4 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I5 ( Mmux_S_AXI_R_LAST13),
.O ( S_AXI_INCR_ADDR)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000FE))
S_AXI_ARLEN_7_GND_8_o_equal_1_o_7_SW0 (
.I0 ( S_AXI_ARLEN[2]),
.I1 ( S_AXI_ARLEN[1]),
.I2 ( S_AXI_ARLEN[0]),
.I3 ( 1'b0),
.I4 ( 1'b0),
.I5 ( 1'b0),
.O ( N01)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000001))
S_AXI_ARLEN_7_GND_8_o_equal_1_o_7_Q (
.I0 ( S_AXI_ARLEN[7]),
.I1 ( S_AXI_ARLEN[6]),
.I2 ( S_AXI_ARLEN[5]),
.I3 ( S_AXI_ARLEN[4]),
.I4 ( S_AXI_ARLEN[3]),
.I5 ( N01),
.O ( S_AXI_ARLEN_7_GND_8_o_equal_1_o)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000000007))
Mmux_gaxi_full_sm_outstanding_read_c1_SW0 (
.I0 ( S_AXI_ARVALID),
.I1 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I2 ( 1'b0),
.I3 ( 1'b0),
.I4 ( 1'b0),
.I5 ( 1'b0),
.O ( N2)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0020000002200200))
Mmux_gaxi_full_sm_outstanding_read_c1 (
.I0 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I1 ( S_AXI_RREADY),
.I2 ( present_state_FSM_FFd1_13),
.I3 ( present_state_FSM_FFd2_14),
.I4 ( gaxi_full_sm_outstanding_read_r_15),
.I5 ( N2),
.O ( gaxi_full_sm_outstanding_read_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000000004555))
Mmux_gaxi_full_sm_ar_ready_c12 (
.I0 ( S_AXI_ARVALID),
.I1 ( S_AXI_RREADY),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I4 ( 1'b0),
.I5 ( 1'b0),
.O ( Mmux_gaxi_full_sm_ar_ready_c11)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000000000EF))
Mmux_S_AXI_R_LAST11_SW0 (
.I0 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I1 ( S_AXI_RREADY),
.I2 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I3 ( 1'b0),
.I4 ( 1'b0),
.I5 ( 1'b0),
.O ( N4)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hFCAAFC0A00AA000A))
Mmux_S_AXI_R_LAST11 (
.I0 ( S_AXI_ARVALID),
.I1 ( gaxi_full_sm_outstanding_read_r_15),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( present_state_FSM_FFd1_13),
.I4 ( N4),
.I5 ( S_AXI_RREADY_gaxi_full_sm_r_valid_r_OR_9_o),
.O ( gaxi_full_sm_r_valid_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000AAAAAA08))
S_AXI_MUX_SEL1 (
.I0 (present_state_FSM_FFd1_13),
.I1 (NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I2 (S_AXI_RREADY),
.I3 (present_state_FSM_FFd2_14),
.I4 (gaxi_full_sm_outstanding_read_r_15),
.I5 (1'b0),
.O (S_AXI_MUX_SEL)
);
STATE_LOGIC_v8_2 #(
.INIT (64'hF3F3F755A2A2A200))
Mmux_S_AXI_RD_EN11 (
.I0 ( present_state_FSM_FFd1_13),
.I1 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I2 ( S_AXI_RREADY),
.I3 ( gaxi_full_sm_outstanding_read_r_15),
.I4 ( present_state_FSM_FFd2_14),
.I5 ( S_AXI_ARVALID),
.O ( S_AXI_RD_EN)
);
beh_vlog_muxf7_v8_2 present_state_FSM_FFd1_In3 (
.I0 ( N8),
.I1 ( N9),
.S ( present_state_FSM_FFd1_13),
.O ( present_state_FSM_FFd1_In)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h000000005410F4F0))
present_state_FSM_FFd1_In3_F (
.I0 ( S_AXI_RREADY),
.I1 ( present_state_FSM_FFd2_14),
.I2 ( S_AXI_ARVALID),
.I3 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I4 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I5 ( 1'b0),
.O ( N8)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000072FF7272))
present_state_FSM_FFd1_In3_G (
.I0 ( present_state_FSM_FFd2_14),
.I1 ( S_AXI_R_LAST_INT),
.I2 ( gaxi_full_sm_outstanding_read_r_15),
.I3 ( S_AXI_RREADY),
.I4 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I5 ( 1'b0),
.O ( N9)
);
beh_vlog_muxf7_v8_2 Mmux_gaxi_full_sm_ar_ready_c14 (
.I0 ( N10),
.I1 ( N11),
.S ( present_state_FSM_FFd1_13),
.O ( gaxi_full_sm_ar_ready_c)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000FFFF88A8))
Mmux_gaxi_full_sm_ar_ready_c14_F (
.I0 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I1 ( S_AXI_RREADY),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I4 ( Mmux_gaxi_full_sm_ar_ready_c11),
.I5 ( 1'b0),
.O ( N10)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h000000008D008D8D))
Mmux_gaxi_full_sm_ar_ready_c14_G (
.I0 ( present_state_FSM_FFd2_14),
.I1 ( S_AXI_R_LAST_INT),
.I2 ( gaxi_full_sm_outstanding_read_r_15),
.I3 ( S_AXI_RREADY),
.I4 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I5 ( 1'b0),
.O ( N11)
);
beh_vlog_muxf7_v8_2 Mmux_S_AXI_R_LAST1 (
.I0 ( N12),
.I1 ( N13),
.S ( present_state_FSM_FFd1_13),
.O ( NlwRenamedSig_OI_S_AXI_R_LAST)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h0000000088088888))
Mmux_S_AXI_R_LAST1_F (
.I0 ( S_AXI_ARLEN_7_GND_8_o_equal_1_o),
.I1 ( S_AXI_ARVALID),
.I2 ( present_state_FSM_FFd2_14),
.I3 ( S_AXI_RREADY),
.I4 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I5 ( 1'b0),
.O ( N12)
);
STATE_LOGIC_v8_2 #(
.INIT (64'h00000000E400E4E4))
Mmux_S_AXI_R_LAST1_G (
.I0 ( present_state_FSM_FFd2_14),
.I1 ( gaxi_full_sm_outstanding_read_r_15),
.I2 ( S_AXI_R_LAST_INT),
.I3 ( S_AXI_RREADY),
.I4 ( NlwRenamedSig_OI_gaxi_full_sm_r_valid_r),
.I5 ( 1'b0),
.O ( N13)
);
endmodule |
module blk_mem_axi_write_wrapper_beh_v8_2
# (
// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0, // 0: Native Interface; 1: AXI Interface
parameter C_AXI_TYPE = 0, // 0: AXI Lite; 1: AXI Full;
parameter C_AXI_SLAVE_TYPE = 0, // 0: MEMORY SLAVE; 1: PERIPHERAL SLAVE;
parameter C_MEMORY_TYPE = 0, // 0: SP-RAM, 1: SDP-RAM; 2: TDP-RAM; 3: DP-ROM;
parameter C_WRITE_DEPTH_A = 0,
parameter C_AXI_AWADDR_WIDTH = 32,
parameter C_ADDRA_WIDTH = 12,
parameter C_AXI_WDATA_WIDTH = 32,
parameter C_HAS_AXI_ID = 0,
parameter C_AXI_ID_WIDTH = 4,
// AXI OUTSTANDING WRITES
parameter C_AXI_OS_WR = 2
)
(
// AXI Global Signals
input S_ACLK,
input S_ARESETN,
// AXI Full/Lite Slave Write Channel (write side)
input [C_AXI_ID_WIDTH-1:0] S_AXI_AWID,
input [C_AXI_AWADDR_WIDTH-1:0] S_AXI_AWADDR,
input [8-1:0] S_AXI_AWLEN,
input [2:0] S_AXI_AWSIZE,
input [1:0] S_AXI_AWBURST,
input S_AXI_AWVALID,
output S_AXI_AWREADY,
input S_AXI_WVALID,
output S_AXI_WREADY,
output reg [C_AXI_ID_WIDTH-1:0] S_AXI_BID = 0,
output S_AXI_BVALID,
input S_AXI_BREADY,
// Signals for BMG interface
output [C_ADDRA_WIDTH-1:0] S_AXI_AWADDR_OUT,
output S_AXI_WR_EN
);
localparam FLOP_DELAY = 100; // 100 ps
localparam C_RANGE = ((C_AXI_WDATA_WIDTH == 8)?0:
((C_AXI_WDATA_WIDTH==16)?1:
((C_AXI_WDATA_WIDTH==32)?2:
((C_AXI_WDATA_WIDTH==64)?3:
((C_AXI_WDATA_WIDTH==128)?4:
((C_AXI_WDATA_WIDTH==256)?5:0))))));
wire bvalid_c ;
reg bready_timeout_c = 0;
wire [1:0] bvalid_rd_cnt_c;
reg bvalid_r = 0;
reg [2:0] bvalid_count_r = 0;
reg [((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?
C_AXI_AWADDR_WIDTH:C_ADDRA_WIDTH)-1:0] awaddr_reg = 0;
reg [1:0] bvalid_wr_cnt_r = 0;
reg [1:0] bvalid_rd_cnt_r = 0;
wire w_last_c ;
wire addr_en_c ;
wire incr_addr_c ;
wire aw_ready_r ;
wire dec_alen_c ;
reg bvalid_d1_c = 0;
reg [7:0] awlen_cntr_r = 0;
reg [7:0] awlen_int = 0;
reg [1:0] awburst_int = 0;
integer total_bytes = 0;
integer wrap_boundary = 0;
integer wrap_base_addr = 0;
integer num_of_bytes_c = 0;
integer num_of_bytes_r = 0;
// Array to store BIDs
reg [C_AXI_ID_WIDTH-1:0] axi_bid_array[3:0] ;
wire S_AXI_BVALID_axi_wr_fsm;
//-------------------------------------
//AXI WRITE FSM COMPONENT INSTANTIATION
//-------------------------------------
write_netlist_v8_2 #(.C_AXI_TYPE(C_AXI_TYPE)) axi_wr_fsm
(
.S_ACLK(S_ACLK),
.S_ARESETN(S_ARESETN),
.S_AXI_AWVALID(S_AXI_AWVALID),
.aw_ready_r(aw_ready_r),
.S_AXI_WVALID(S_AXI_WVALID),
.S_AXI_WREADY(S_AXI_WREADY),
.S_AXI_BREADY(S_AXI_BREADY),
.S_AXI_WR_EN(S_AXI_WR_EN),
.w_last_c(w_last_c),
.bready_timeout_c(bready_timeout_c),
.addr_en_c(addr_en_c),
.incr_addr_c(incr_addr_c),
.bvalid_c(bvalid_c),
.S_AXI_BVALID (S_AXI_BVALID_axi_wr_fsm)
);
//Wrap Address boundary calculation
always@(*) begin
num_of_bytes_c = 2**((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_AWSIZE:0);
total_bytes = (num_of_bytes_r)*(awlen_int+1);
wrap_base_addr = ((awaddr_reg)/((total_bytes==0)?1:total_bytes))*(total_bytes);
wrap_boundary = wrap_base_addr+total_bytes;
end
//-------------------------------------------------------------------------
// BMG address generation
//-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
awaddr_reg <= 0;
num_of_bytes_r <= 0;
awburst_int <= 0;
end else begin
if (addr_en_c == 1'b1) begin
awaddr_reg <= #FLOP_DELAY S_AXI_AWADDR ;
num_of_bytes_r <= num_of_bytes_c;
awburst_int <= ((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_AWBURST:2'b01);
end else if (incr_addr_c == 1'b1) begin
if (awburst_int == 2'b10) begin
if(awaddr_reg == (wrap_boundary-num_of_bytes_r)) begin
awaddr_reg <= wrap_base_addr;
end else begin
awaddr_reg <= awaddr_reg + num_of_bytes_r;
end
end else if (awburst_int == 2'b01 || awburst_int == 2'b11) begin
awaddr_reg <= awaddr_reg + num_of_bytes_r;
end
end
end
end
assign S_AXI_AWADDR_OUT = ((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?
awaddr_reg[C_AXI_AWADDR_WIDTH-1:C_RANGE]:awaddr_reg);
//-------------------------------------------------------------------------
// AXI wlast generation
//-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
awlen_cntr_r <= 0;
awlen_int <= 0;
end else begin
if (addr_en_c == 1'b1) begin
awlen_int <= #FLOP_DELAY (C_AXI_TYPE == 0?0:S_AXI_AWLEN) ;
awlen_cntr_r <= #FLOP_DELAY (C_AXI_TYPE == 0?0:S_AXI_AWLEN) ;
end else if (dec_alen_c == 1'b1) begin
awlen_cntr_r <= #FLOP_DELAY awlen_cntr_r - 1 ;
end
end
end
assign w_last_c = (awlen_cntr_r == 0 && S_AXI_WVALID == 1'b1)?1'b1:1'b0;
assign dec_alen_c = (incr_addr_c | w_last_c);
//-------------------------------------------------------------------------
// Generation of bvalid counter for outstanding transactions
//-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
bvalid_count_r <= 0;
end else begin
// bvalid_count_r generation
if (bvalid_c == 1'b1 && bvalid_r == 1'b1 && S_AXI_BREADY == 1'b1) begin
bvalid_count_r <= #FLOP_DELAY bvalid_count_r ;
end else if (bvalid_c == 1'b1) begin
bvalid_count_r <= #FLOP_DELAY bvalid_count_r + 1 ;
end else if (bvalid_r == 1'b1 && S_AXI_BREADY == 1'b1 && bvalid_count_r != 0) begin
bvalid_count_r <= #FLOP_DELAY bvalid_count_r - 1 ;
end
end
end
//-------------------------------------------------------------------------
// Generation of bvalid when BID is used
//-------------------------------------------------------------------------
generate if (C_HAS_AXI_ID == 1) begin:gaxi_bvalid_id_r
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
bvalid_r <= 0;
bvalid_d1_c <= 0;
end else begin
// Delay the generation o bvalid_r for generation for BID
bvalid_d1_c <= bvalid_c;
//external bvalid signal generation
if (bvalid_d1_c == 1'b1) begin
bvalid_r <= #FLOP_DELAY 1'b1 ;
end else if (bvalid_count_r <= 1 && S_AXI_BREADY == 1'b1) begin
bvalid_r <= #FLOP_DELAY 0 ;
end
end
end
end
endgenerate
//-------------------------------------------------------------------------
// Generation of bvalid when BID is not used
//-------------------------------------------------------------------------
generate if(C_HAS_AXI_ID == 0) begin:gaxi_bvalid_noid_r
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
bvalid_r <= 0;
end else begin
//external bvalid signal generation
if (bvalid_c == 1'b1) begin
bvalid_r <= #FLOP_DELAY 1'b1 ;
end else if (bvalid_count_r <= 1 && S_AXI_BREADY == 1'b1) begin
bvalid_r <= #FLOP_DELAY 0 ;
end
end
end
end
endgenerate
//-------------------------------------------------------------------------
// Generation of Bready timeout
//-------------------------------------------------------------------------
always @(bvalid_count_r) begin
// bready_timeout_c generation
if(bvalid_count_r == C_AXI_OS_WR-1) begin
bready_timeout_c <= 1'b1;
end else begin
bready_timeout_c <= 1'b0;
end
end
//-------------------------------------------------------------------------
// Generation of BID
//-------------------------------------------------------------------------
generate if(C_HAS_AXI_ID == 1) begin:gaxi_bid_gen
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
bvalid_wr_cnt_r <= 0;
bvalid_rd_cnt_r <= 0;
end else begin
// STORE AWID IN AN ARRAY
if(bvalid_c == 1'b1) begin
bvalid_wr_cnt_r <= bvalid_wr_cnt_r + 1;
end
// generate BID FROM AWID ARRAY
bvalid_rd_cnt_r <= #FLOP_DELAY bvalid_rd_cnt_c ;
S_AXI_BID <= axi_bid_array[bvalid_rd_cnt_c];
end
end
assign bvalid_rd_cnt_c = (bvalid_r == 1'b1 && S_AXI_BREADY == 1'b1)?bvalid_rd_cnt_r+1:bvalid_rd_cnt_r;
//-------------------------------------------------------------------------
// Storing AWID for generation of BID
//-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if(S_ARESETN == 1'b1) begin
axi_bid_array[0] = 0;
axi_bid_array[1] = 0;
axi_bid_array[2] = 0;
axi_bid_array[3] = 0;
end else if(aw_ready_r == 1'b1 && S_AXI_AWVALID == 1'b1) begin
axi_bid_array[bvalid_wr_cnt_r] <= S_AXI_AWID;
end
end
end
endgenerate
assign S_AXI_BVALID = bvalid_r;
assign S_AXI_AWREADY = aw_ready_r;
endmodule |
module blk_mem_axi_read_wrapper_beh_v8_2
# (
//// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0,
parameter C_AXI_TYPE = 0,
parameter C_AXI_SLAVE_TYPE = 0,
parameter C_MEMORY_TYPE = 0,
parameter C_WRITE_WIDTH_A = 4,
parameter C_WRITE_DEPTH_A = 32,
parameter C_ADDRA_WIDTH = 12,
parameter C_AXI_PIPELINE_STAGES = 0,
parameter C_AXI_ARADDR_WIDTH = 12,
parameter C_HAS_AXI_ID = 0,
parameter C_AXI_ID_WIDTH = 4,
parameter C_ADDRB_WIDTH = 12
)
(
//// AXI Global Signals
input S_ACLK,
input S_ARESETN,
//// AXI Full/Lite Slave Read (Read side)
input [C_AXI_ARADDR_WIDTH-1:0] S_AXI_ARADDR,
input [7:0] S_AXI_ARLEN,
input [2:0] S_AXI_ARSIZE,
input [1:0] S_AXI_ARBURST,
input S_AXI_ARVALID,
output S_AXI_ARREADY,
output S_AXI_RLAST,
output S_AXI_RVALID,
input S_AXI_RREADY,
input [C_AXI_ID_WIDTH-1:0] S_AXI_ARID,
output reg [C_AXI_ID_WIDTH-1:0] S_AXI_RID = 0,
//// AXI Full/Lite Read Address Signals to BRAM
output [C_ADDRB_WIDTH-1:0] S_AXI_ARADDR_OUT,
output S_AXI_RD_EN
);
localparam FLOP_DELAY = 100; // 100 ps
localparam C_RANGE = ((C_WRITE_WIDTH_A == 8)?0:
((C_WRITE_WIDTH_A==16)?1:
((C_WRITE_WIDTH_A==32)?2:
((C_WRITE_WIDTH_A==64)?3:
((C_WRITE_WIDTH_A==128)?4:
((C_WRITE_WIDTH_A==256)?5:0))))));
reg [C_AXI_ID_WIDTH-1:0] ar_id_r=0;
wire addr_en_c;
wire rd_en_c;
wire incr_addr_c;
wire single_trans_c;
wire dec_alen_c;
wire mux_sel_c;
wire r_last_c;
wire r_last_int_c;
wire [C_ADDRB_WIDTH-1 : 0] araddr_out;
reg [7:0] arlen_int_r=0;
reg [7:0] arlen_cntr=8'h01;
reg [1:0] arburst_int_c=0;
reg [1:0] arburst_int_r=0;
reg [((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?
C_AXI_ARADDR_WIDTH:C_ADDRA_WIDTH)-1:0] araddr_reg =0;
integer num_of_bytes_c = 0;
integer total_bytes = 0;
integer num_of_bytes_r = 0;
integer wrap_base_addr_r = 0;
integer wrap_boundary_r = 0;
reg [7:0] arlen_int_c=0;
integer total_bytes_c = 0;
integer wrap_base_addr_c = 0;
integer wrap_boundary_c = 0;
assign dec_alen_c = incr_addr_c | r_last_int_c;
read_netlist_v8_2
#(.C_AXI_TYPE (1),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH))
axi_read_fsm (
.S_AXI_INCR_ADDR(incr_addr_c),
.S_AXI_ADDR_EN(addr_en_c),
.S_AXI_SINGLE_TRANS(single_trans_c),
.S_AXI_MUX_SEL(mux_sel_c),
.S_AXI_R_LAST(r_last_c),
.S_AXI_R_LAST_INT(r_last_int_c),
//// AXI Global Signals
.S_ACLK(S_ACLK),
.S_ARESETN(S_ARESETN),
//// AXI Full/Lite Slave Read (Read side)
.S_AXI_ARLEN(S_AXI_ARLEN),
.S_AXI_ARVALID(S_AXI_ARVALID),
.S_AXI_ARREADY(S_AXI_ARREADY),
.S_AXI_RLAST(S_AXI_RLAST),
.S_AXI_RVALID(S_AXI_RVALID),
.S_AXI_RREADY(S_AXI_RREADY),
//// AXI Full/Lite Read Address Signals to BRAM
.S_AXI_RD_EN(rd_en_c)
);
always@(*) begin
num_of_bytes_c = 2**((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_ARSIZE:0);
total_bytes = (num_of_bytes_r)*(arlen_int_r+1);
wrap_base_addr_r = ((araddr_reg)/(total_bytes==0?1:total_bytes))*(total_bytes);
wrap_boundary_r = wrap_base_addr_r+total_bytes;
//////// combinatorial from interface
arlen_int_c = (C_AXI_TYPE == 0?0:S_AXI_ARLEN);
total_bytes_c = (num_of_bytes_c)*(arlen_int_c+1);
wrap_base_addr_c = ((S_AXI_ARADDR)/(total_bytes_c==0?1:total_bytes_c))*(total_bytes_c);
wrap_boundary_c = wrap_base_addr_c+total_bytes_c;
arburst_int_c = ((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_ARBURST:1);
end
////-------------------------------------------------------------------------
//// BMG address generation
////-------------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
araddr_reg <= 0;
arburst_int_r <= 0;
num_of_bytes_r <= 0;
end else begin
if (incr_addr_c == 1'b1 && addr_en_c == 1'b1 && single_trans_c == 1'b0) begin
arburst_int_r <= arburst_int_c;
num_of_bytes_r <= num_of_bytes_c;
if (arburst_int_c == 2'b10) begin
if(S_AXI_ARADDR == (wrap_boundary_c-num_of_bytes_c)) begin
araddr_reg <= wrap_base_addr_c;
end else begin
araddr_reg <= S_AXI_ARADDR + num_of_bytes_c;
end
end else if (arburst_int_c == 2'b01 || arburst_int_c == 2'b11) begin
araddr_reg <= S_AXI_ARADDR + num_of_bytes_c;
end
end else if (addr_en_c == 1'b1) begin
araddr_reg <= S_AXI_ARADDR;
num_of_bytes_r <= num_of_bytes_c;
arburst_int_r <= arburst_int_c;
end else if (incr_addr_c == 1'b1) begin
if (arburst_int_r == 2'b10) begin
if(araddr_reg == (wrap_boundary_r-num_of_bytes_r)) begin
araddr_reg <= wrap_base_addr_r;
end else begin
araddr_reg <= araddr_reg + num_of_bytes_r;
end
end else if (arburst_int_r == 2'b01 || arburst_int_r == 2'b11) begin
araddr_reg <= araddr_reg + num_of_bytes_r;
end
end
end
end
assign araddr_out = ((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?araddr_reg[C_AXI_ARADDR_WIDTH-1:C_RANGE]:araddr_reg);
////-----------------------------------------------------------------------
//// Counter to generate r_last_int_c from registered ARLEN - AXI FULL FSM
////-----------------------------------------------------------------------
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
arlen_cntr <= 8'h01;
arlen_int_r <= 0;
end else begin
if (addr_en_c == 1'b1 && dec_alen_c == 1'b1 && single_trans_c == 1'b0) begin
arlen_int_r <= (C_AXI_TYPE == 0?0:S_AXI_ARLEN) ;
arlen_cntr <= S_AXI_ARLEN - 1'b1;
end else if (addr_en_c == 1'b1) begin
arlen_int_r <= (C_AXI_TYPE == 0?0:S_AXI_ARLEN) ;
arlen_cntr <= (C_AXI_TYPE == 0?0:S_AXI_ARLEN) ;
end else if (dec_alen_c == 1'b1) begin
arlen_cntr <= arlen_cntr - 1'b1 ;
end
else begin
arlen_cntr <= arlen_cntr;
end
end
end
assign r_last_int_c = (arlen_cntr == 0 && S_AXI_RREADY == 1'b1)?1'b1:1'b0;
////------------------------------------------------------------------------
//// AXI FULL FSM
//// Mux Selection of ARADDR
//// ARADDR is driven out from the read fsm based on the mux_sel_c
//// Based on mux_sel either ARADDR is given out or the latched ARADDR is
//// given out to BRAM
////------------------------------------------------------------------------
assign S_AXI_ARADDR_OUT = (mux_sel_c == 1'b0)?((C_AXI_TYPE == 1 && C_AXI_SLAVE_TYPE == 0)?S_AXI_ARADDR[C_AXI_ARADDR_WIDTH-1:C_RANGE]:S_AXI_ARADDR):araddr_out;
////------------------------------------------------------------------------
//// Assign output signals - AXI FULL FSM
////------------------------------------------------------------------------
assign S_AXI_RD_EN = rd_en_c;
generate if (C_HAS_AXI_ID == 1) begin:gaxi_bvalid_id_r
always @(posedge S_ACLK or S_ARESETN) begin
if (S_ARESETN == 1'b1) begin
S_AXI_RID <= 0;
ar_id_r <= 0;
end else begin
if (addr_en_c == 1'b1 && rd_en_c == 1'b1) begin
S_AXI_RID <= S_AXI_ARID;
ar_id_r <= S_AXI_ARID;
end else if (addr_en_c == 1'b1 && rd_en_c == 1'b0) begin
ar_id_r <= S_AXI_ARID;
end else if (rd_en_c == 1'b1) begin
S_AXI_RID <= ar_id_r;
end
end
end
end
endgenerate
endmodule |
module blk_mem_axi_regs_fwd_v8_2
#(parameter C_DATA_WIDTH = 8
)(
input ACLK,
input ARESET,
input S_VALID,
output S_READY,
input [C_DATA_WIDTH-1:0] S_PAYLOAD_DATA,
output M_VALID,
input M_READY,
output reg [C_DATA_WIDTH-1:0] M_PAYLOAD_DATA
);
reg [C_DATA_WIDTH-1:0] STORAGE_DATA;
wire S_READY_I;
reg M_VALID_I;
reg [1:0] ARESET_D;
//assign local signal to its output signal
assign S_READY = S_READY_I;
assign M_VALID = M_VALID_I;
always @(posedge ACLK) begin
ARESET_D <= {ARESET_D[0], ARESET};
end
//Save payload data whenever we have a transaction on the slave side
always @(posedge ACLK or ARESET) begin
if (ARESET == 1'b1) begin
STORAGE_DATA <= 0;
end else begin
if(S_VALID == 1'b1 && S_READY_I == 1'b1 ) begin
STORAGE_DATA <= S_PAYLOAD_DATA;
end
end
end
always @(posedge ACLK) begin
M_PAYLOAD_DATA = STORAGE_DATA;
end
//M_Valid set to high when we have a completed transfer on slave side
//Is removed on a M_READY except if we have a new transfer on the slave side
always @(posedge ACLK or ARESET_D) begin
if (ARESET_D != 2'b00) begin
M_VALID_I <= 1'b0;
end else begin
if (S_VALID == 1'b1) begin
//Always set M_VALID_I when slave side is valid
M_VALID_I <= 1'b1;
end else if (M_READY == 1'b1 ) begin
//Clear (or keep) when no slave side is valid but master side is ready
M_VALID_I <= 1'b0;
end
end
end
//Slave Ready is either when Master side drives M_READY or we have space in our storage data
assign S_READY_I = (M_READY || (!M_VALID_I)) && !(|(ARESET_D));
endmodule |
module BLK_MEM_GEN_v8_2_output_stage
#(parameter C_FAMILY = "virtex7",
parameter C_XDEVICEFAMILY = "virtex7",
parameter C_RST_TYPE = "SYNC",
parameter C_HAS_RST = 0,
parameter C_RSTRAM = 0,
parameter C_RST_PRIORITY = "CE",
parameter C_INIT_VAL = "0",
parameter C_HAS_EN = 0,
parameter C_HAS_REGCE = 0,
parameter C_DATA_WIDTH = 32,
parameter C_ADDRB_WIDTH = 10,
parameter C_HAS_MEM_OUTPUT_REGS = 0,
parameter C_USE_SOFTECC = 0,
parameter C_USE_ECC = 0,
parameter NUM_STAGES = 1,
parameter C_EN_ECC_PIPE = 0,
parameter FLOP_DELAY = 100
)
(
input CLK,
input RST,
input EN,
input REGCE,
input [C_DATA_WIDTH-1:0] DIN_I,
output reg [C_DATA_WIDTH-1:0] DOUT,
input SBITERR_IN_I,
input DBITERR_IN_I,
output reg SBITERR,
output reg DBITERR,
input [C_ADDRB_WIDTH-1:0] RDADDRECC_IN_I,
input ECCPIPECE,
output reg [C_ADDRB_WIDTH-1:0] RDADDRECC
);
//******************************
// Port and Generic Definitions
//******************************
//////////////////////////////////////////////////////////////////////////
// Generic Definitions
//////////////////////////////////////////////////////////////////////////
// C_FAMILY,C_XDEVICEFAMILY: Designates architecture targeted. The following
// options are available - "spartan3", "spartan6",
// "virtex4", "virtex5", "virtex6" and "virtex6l".
// C_RST_TYPE : Type of reset - Synchronous or Asynchronous
// C_HAS_RST : Determines the presence of the RST port
// C_RSTRAM : Determines if special reset behavior is used
// C_RST_PRIORITY : Determines the priority between CE and SR
// C_INIT_VAL : Initialization value
// C_HAS_EN : Determines the presence of the EN port
// C_HAS_REGCE : Determines the presence of the REGCE port
// C_DATA_WIDTH : Memory write/read width
// C_ADDRB_WIDTH : Width of the ADDRB input port
// C_HAS_MEM_OUTPUT_REGS : Designates the use of a register at the output
// of the RAM primitive
// C_USE_SOFTECC : Determines if the Soft ECC feature is used or
// not. Only applicable Spartan-6
// C_USE_ECC : Determines if the ECC feature is used or
// not. Only applicable for V5 and V6
// NUM_STAGES : Determines the number of output stages
// FLOP_DELAY : Constant delay for register assignments
//////////////////////////////////////////////////////////////////////////
// Port Definitions
//////////////////////////////////////////////////////////////////////////
// CLK : Clock to synchronize all read and write operations
// RST : Reset input to reset memory outputs to a user-defined
// reset state
// EN : Enable all read and write operations
// REGCE : Register Clock Enable to control each pipeline output
// register stages
// DIN : Data input to the Output stage.
// DOUT : Final Data output
// SBITERR_IN : SBITERR input signal to the Output stage.
// SBITERR : Final SBITERR Output signal.
// DBITERR_IN : DBITERR input signal to the Output stage.
// DBITERR : Final DBITERR Output signal.
// RDADDRECC_IN : RDADDRECC input signal to the Output stage.
// RDADDRECC : Final RDADDRECC Output signal.
//////////////////////////////////////////////////////////////////////////
// Fix for CR-509792
localparam REG_STAGES = (NUM_STAGES < 2) ? 1 : NUM_STAGES-1;
// Declare the pipeline registers
// (includes mem output reg, mux pipeline stages, and mux output reg)
reg [C_DATA_WIDTH*REG_STAGES-1:0] out_regs;
reg [C_ADDRB_WIDTH*REG_STAGES-1:0] rdaddrecc_regs;
reg [REG_STAGES-1:0] sbiterr_regs;
reg [REG_STAGES-1:0] dbiterr_regs;
reg [C_DATA_WIDTH*8-1:0] init_str = C_INIT_VAL;
reg [C_DATA_WIDTH-1:0] init_val ;
//*********************************************
// Wire off optional inputs based on parameters
//*********************************************
wire en_i;
wire regce_i;
wire rst_i;
// Internal signals
reg [C_DATA_WIDTH-1:0] DIN;
reg [C_ADDRB_WIDTH-1:0] RDADDRECC_IN;
reg SBITERR_IN;
reg DBITERR_IN;
// Internal enable for output registers is tied to user EN or '1' depending
// on parameters
assign en_i = (C_HAS_EN==0 || EN);
// Internal register enable for output registers is tied to user REGCE, EN or
// '1' depending on parameters
// For V4 ECC, REGCE is always 1
// Virtex-4 ECC Not Yet Supported
assign regce_i = ((C_HAS_REGCE==1) && REGCE) ||
((C_HAS_REGCE==0) && (C_HAS_EN==0 || EN));
//Internal SRR is tied to user RST or '0' depending on parameters
assign rst_i = (C_HAS_RST==1) && RST;
//****************************************************
// Power on: load up the output registers and latches
//****************************************************
initial begin
if (!($sscanf(init_str, "%h", init_val))) begin
init_val = 0;
end
DOUT = init_val;
RDADDRECC = 0;
SBITERR = 1'b0;
DBITERR = 1'b0;
DIN = {(C_DATA_WIDTH){1'b0}};
RDADDRECC_IN = 0;
SBITERR_IN = 0;
DBITERR_IN = 0;
// This will be one wider than need, but 0 is an error
out_regs = {(REG_STAGES+1){init_val}};
rdaddrecc_regs = 0;
sbiterr_regs = {(REG_STAGES+1){1'b0}};
dbiterr_regs = {(REG_STAGES+1){1'b0}};
end
//***********************************************
// NUM_STAGES = 0 (No output registers. RAM only)
//***********************************************
generate if (NUM_STAGES == 0) begin : zero_stages
always @* begin
DOUT = DIN;
RDADDRECC = RDADDRECC_IN;
SBITERR = SBITERR_IN;
DBITERR = DBITERR_IN;
end
end
endgenerate
generate if (C_EN_ECC_PIPE == 0) begin : no_ecc_pipe_reg
always @* begin
DIN = DIN_I;
SBITERR_IN = SBITERR_IN_I;
DBITERR_IN = DBITERR_IN_I;
RDADDRECC_IN = RDADDRECC_IN_I;
end
end
endgenerate
generate if (C_EN_ECC_PIPE == 1) begin : with_ecc_pipe_reg
always @(posedge CLK) begin
if(ECCPIPECE == 1) begin
DIN <= #FLOP_DELAY DIN_I;
SBITERR_IN <= #FLOP_DELAY SBITERR_IN_I;
DBITERR_IN <= #FLOP_DELAY DBITERR_IN_I;
RDADDRECC_IN <= #FLOP_DELAY RDADDRECC_IN_I;
end
end
end
endgenerate
//***********************************************
// NUM_STAGES = 1
// (Mem Output Reg only or Mux Output Reg only)
//***********************************************
// Possible valid combinations:
// Note: C_HAS_MUX_OUTPUT_REGS_*=0 when (C_RSTRAM_*=1)
// +-----------------------------------------+
// | C_RSTRAM_* | Reset Behavior |
// +----------------+------------------------+
// | 0 | Normal Behavior |
// +----------------+------------------------+
// | 1 | Special Behavior |
// +----------------+------------------------+
//
// Normal = REGCE gates reset, as in the case of all families except S3ADSP.
// Special = EN gates reset, as in the case of S3ADSP.
generate if (NUM_STAGES == 1 &&
(C_RSTRAM == 0 || (C_RSTRAM == 1 && (C_XDEVICEFAMILY != "spartan3adsp" && C_XDEVICEFAMILY != "aspartan3adsp" )) ||
C_HAS_MEM_OUTPUT_REGS == 0 || C_HAS_RST == 0))
begin : one_stages_norm
always @(posedge CLK) begin
if (C_RST_PRIORITY == "CE") begin //REGCE has priority
if (regce_i && rst_i) begin
DOUT <= #FLOP_DELAY init_val;
RDADDRECC <= #FLOP_DELAY 0;
SBITERR <= #FLOP_DELAY 1'b0;
DBITERR <= #FLOP_DELAY 1'b0;
end else if (regce_i) begin
DOUT <= #FLOP_DELAY DIN;
RDADDRECC <= #FLOP_DELAY RDADDRECC_IN;
SBITERR <= #FLOP_DELAY SBITERR_IN;
DBITERR <= #FLOP_DELAY DBITERR_IN;
end //Output signal assignments
end else begin //RST has priority
if (rst_i) begin
DOUT <= #FLOP_DELAY init_val;
RDADDRECC <= #FLOP_DELAY RDADDRECC_IN;
SBITERR <= #FLOP_DELAY 1'b0;
DBITERR <= #FLOP_DELAY 1'b0;
end else if (regce_i) begin
DOUT <= #FLOP_DELAY DIN;
RDADDRECC <= #FLOP_DELAY RDADDRECC_IN;
SBITERR <= #FLOP_DELAY SBITERR_IN;
DBITERR <= #FLOP_DELAY DBITERR_IN;
end //Output signal assignments
end //end Priority conditions
end //end RST Type conditions
end //end one_stages_norm generate statement
endgenerate
// Special Reset Behavior for S3ADSP
generate if (NUM_STAGES == 1 && C_RSTRAM == 1 && (C_XDEVICEFAMILY =="spartan3adsp" || C_XDEVICEFAMILY =="aspartan3adsp"))
begin : one_stage_splbhv
always @(posedge CLK) begin
if (en_i && rst_i) begin
DOUT <= #FLOP_DELAY init_val;
end else if (regce_i && !rst_i) begin
DOUT <= #FLOP_DELAY DIN;
end //Output signal assignments
end //end CLK
end //end one_stage_splbhv generate statement
endgenerate
//************************************************************
// NUM_STAGES > 1
// Mem Output Reg + Mux Output Reg
// or
// Mem Output Reg + Mux Pipeline Stages (>0) + Mux Output Reg
// or
// Mux Pipeline Stages (>0) + Mux Output Reg
//*************************************************************
generate if (NUM_STAGES > 1) begin : multi_stage
//Asynchronous Reset
always @(posedge CLK) begin
if (C_RST_PRIORITY == "CE") begin //REGCE has priority
if (regce_i && rst_i) begin
DOUT <= #FLOP_DELAY init_val;
RDADDRECC <= #FLOP_DELAY 0;
SBITERR <= #FLOP_DELAY 1'b0;
DBITERR <= #FLOP_DELAY 1'b0;
end else if (regce_i) begin
DOUT <= #FLOP_DELAY
out_regs[C_DATA_WIDTH*(NUM_STAGES-2)+:C_DATA_WIDTH];
RDADDRECC <= #FLOP_DELAY rdaddrecc_regs[C_ADDRB_WIDTH*(NUM_STAGES-2)+:C_ADDRB_WIDTH];
SBITERR <= #FLOP_DELAY sbiterr_regs[NUM_STAGES-2];
DBITERR <= #FLOP_DELAY dbiterr_regs[NUM_STAGES-2];
end //Output signal assignments
end else begin //RST has priority
if (rst_i) begin
DOUT <= #FLOP_DELAY init_val;
RDADDRECC <= #FLOP_DELAY 0;
SBITERR <= #FLOP_DELAY 1'b0;
DBITERR <= #FLOP_DELAY 1'b0;
end else if (regce_i) begin
DOUT <= #FLOP_DELAY
out_regs[C_DATA_WIDTH*(NUM_STAGES-2)+:C_DATA_WIDTH];
RDADDRECC <= #FLOP_DELAY rdaddrecc_regs[C_ADDRB_WIDTH*(NUM_STAGES-2)+:C_ADDRB_WIDTH];
SBITERR <= #FLOP_DELAY sbiterr_regs[NUM_STAGES-2];
DBITERR <= #FLOP_DELAY dbiterr_regs[NUM_STAGES-2];
end //Output signal assignments
end //end Priority conditions
// Shift the data through the output stages
if (en_i) begin
out_regs <= #FLOP_DELAY (out_regs << C_DATA_WIDTH) | DIN;
rdaddrecc_regs <= #FLOP_DELAY (rdaddrecc_regs << C_ADDRB_WIDTH) | RDADDRECC_IN;
sbiterr_regs <= #FLOP_DELAY (sbiterr_regs << 1) | SBITERR_IN;
dbiterr_regs <= #FLOP_DELAY (dbiterr_regs << 1) | DBITERR_IN;
end
end //end CLK
end //end multi_stage generate statement
endgenerate
endmodule |
module BLK_MEM_GEN_v8_2_softecc_output_reg_stage
#(parameter C_DATA_WIDTH = 32,
parameter C_ADDRB_WIDTH = 10,
parameter C_HAS_SOFTECC_OUTPUT_REGS_B= 0,
parameter C_USE_SOFTECC = 0,
parameter FLOP_DELAY = 100
)
(
input CLK,
input [C_DATA_WIDTH-1:0] DIN,
output reg [C_DATA_WIDTH-1:0] DOUT,
input SBITERR_IN,
input DBITERR_IN,
output reg SBITERR,
output reg DBITERR,
input [C_ADDRB_WIDTH-1:0] RDADDRECC_IN,
output reg [C_ADDRB_WIDTH-1:0] RDADDRECC
);
//******************************
// Port and Generic Definitions
//******************************
//////////////////////////////////////////////////////////////////////////
// Generic Definitions
//////////////////////////////////////////////////////////////////////////
// C_DATA_WIDTH : Memory write/read width
// C_ADDRB_WIDTH : Width of the ADDRB input port
// C_HAS_SOFTECC_OUTPUT_REGS_B : Designates the use of a register at the output
// of the RAM primitive
// C_USE_SOFTECC : Determines if the Soft ECC feature is used or
// not. Only applicable Spartan-6
// FLOP_DELAY : Constant delay for register assignments
//////////////////////////////////////////////////////////////////////////
// Port Definitions
//////////////////////////////////////////////////////////////////////////
// CLK : Clock to synchronize all read and write operations
// DIN : Data input to the Output stage.
// DOUT : Final Data output
// SBITERR_IN : SBITERR input signal to the Output stage.
// SBITERR : Final SBITERR Output signal.
// DBITERR_IN : DBITERR input signal to the Output stage.
// DBITERR : Final DBITERR Output signal.
// RDADDRECC_IN : RDADDRECC input signal to the Output stage.
// RDADDRECC : Final RDADDRECC Output signal.
//////////////////////////////////////////////////////////////////////////
reg [C_DATA_WIDTH-1:0] dout_i = 0;
reg sbiterr_i = 0;
reg dbiterr_i = 0;
reg [C_ADDRB_WIDTH-1:0] rdaddrecc_i = 0;
//***********************************************
// NO OUTPUT REGISTERS.
//***********************************************
generate if (C_HAS_SOFTECC_OUTPUT_REGS_B==0) begin : no_output_stage
always @* begin
DOUT = DIN;
RDADDRECC = RDADDRECC_IN;
SBITERR = SBITERR_IN;
DBITERR = DBITERR_IN;
end
end
endgenerate
//***********************************************
// WITH OUTPUT REGISTERS.
//***********************************************
generate if (C_HAS_SOFTECC_OUTPUT_REGS_B==1) begin : has_output_stage
always @(posedge CLK) begin
dout_i <= #FLOP_DELAY DIN;
rdaddrecc_i <= #FLOP_DELAY RDADDRECC_IN;
sbiterr_i <= #FLOP_DELAY SBITERR_IN;
dbiterr_i <= #FLOP_DELAY DBITERR_IN;
end
always @* begin
DOUT = dout_i;
RDADDRECC = rdaddrecc_i;
SBITERR = sbiterr_i;
DBITERR = dbiterr_i;
end //end always
end //end in_or_out_stage generate statement
endgenerate
endmodule |
module
//***************************************************************
// Port A
assign rsta_outp_stage = RSTA & (~SLEEP);
BLK_MEM_GEN_v8_2_output_stage
#(.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_RST_TYPE ("SYNC"),
.C_HAS_RST (C_HAS_RSTA),
.C_RSTRAM (C_RSTRAM_A),
.C_RST_PRIORITY (C_RST_PRIORITY_A),
.C_INIT_VAL (C_INITA_VAL),
.C_HAS_EN (C_HAS_ENA),
.C_HAS_REGCE (C_HAS_REGCEA),
.C_DATA_WIDTH (C_READ_WIDTH_A),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_MEM_OUTPUT_REGS (C_HAS_MEM_OUTPUT_REGS_A),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.NUM_STAGES (NUM_OUTPUT_STAGES_A),
.C_EN_ECC_PIPE (0),
.FLOP_DELAY (FLOP_DELAY))
reg_a
(.CLK (CLKA),
.RST (rsta_outp_stage),//(RSTA),
.EN (ENA),
.REGCE (REGCEA),
.DIN_I (memory_out_a),
.DOUT (DOUTA),
.SBITERR_IN_I (1'b0),
.DBITERR_IN_I (1'b0),
.SBITERR (),
.DBITERR (),
.RDADDRECC_IN_I ({C_ADDRB_WIDTH{1'b0}}),
.ECCPIPECE (1'b0),
.RDADDRECC ()
);
assign rstb_outp_stage = RSTB & (~SLEEP);
// Port B
BLK_MEM_GEN_v8_2_output_stage
#(.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_RST_TYPE ("SYNC"),
.C_HAS_RST (C_HAS_RSTB),
.C_RSTRAM (C_RSTRAM_B),
.C_RST_PRIORITY (C_RST_PRIORITY_B),
.C_INIT_VAL (C_INITB_VAL),
.C_HAS_EN (C_HAS_ENB),
.C_HAS_REGCE (C_HAS_REGCEB),
.C_DATA_WIDTH (C_READ_WIDTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_MEM_OUTPUT_REGS (C_HAS_MEM_OUTPUT_REGS_B),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.NUM_STAGES (NUM_OUTPUT_STAGES_B),
.C_EN_ECC_PIPE (C_EN_ECC_PIPE),
.FLOP_DELAY (FLOP_DELAY))
reg_b
(.CLK (CLKB),
.RST (rstb_outp_stage),//(RSTB),
.EN (ENB),
.REGCE (REGCEB),
.DIN_I (memory_out_b),
.DOUT (dout_i),
.SBITERR_IN_I (sbiterr_in),
.DBITERR_IN_I (dbiterr_in),
.SBITERR (sbiterr_i),
.DBITERR (dbiterr_i),
.RDADDRECC_IN_I (rdaddrecc_in),
.ECCPIPECE (ECCPIPECE),
.RDADDRECC (rdaddrecc_i)
);
//***************************************************************
// Instantiate the Input and Output register stages
//***************************************************************
BLK_MEM_GEN_v8_2_softecc_output_reg_stage
#(.C_DATA_WIDTH (C_READ_WIDTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_SOFTECC_OUTPUT_REGS_B (C_HAS_SOFTECC_OUTPUT_REGS_B),
.C_USE_SOFTECC (C_USE_SOFTECC),
.FLOP_DELAY (FLOP_DELAY))
has_softecc_output_reg_stage
(.CLK (CLKB),
.DIN (dout_i),
.DOUT (DOUTB),
.SBITERR_IN (sbiterr_i),
.DBITERR_IN (dbiterr_i),
.SBITERR (sbiterr_sdp),
.DBITERR (dbiterr_sdp),
.RDADDRECC_IN (rdaddrecc_i),
.RDADDRECC (rdaddrecc_sdp)
);
//****************************************************
// Synchronous collision checks
//****************************************************
// CR 780544 : To make verilog model's collison warnings in consistant with
// vhdl model, the non-blocking assignments are replaced with blocking
// assignments.
generate if (!C_DISABLE_WARN_BHV_COLL && C_COMMON_CLK) begin : sync_coll
always @(posedge CLKA) begin
// Possible collision if both are enabled and the addresses match
if (ena_i && enb_i) begin
if (wea_i || web_i) begin
is_collision = collision_check(ADDRA, wea_i, ADDRB, web_i);
end else begin
is_collision = 0;
end
end else begin
is_collision = 0;
end
// If the write port is in READ_FIRST mode, there is no collision
if (C_WRITE_MODE_A=="READ_FIRST" && wea_i && !web_i) begin
is_collision = 0;
end
if (C_WRITE_MODE_B=="READ_FIRST" && web_i && !wea_i) begin
is_collision = 0;
end
// Only flag if one of the accesses is a write
if (is_collision && (wea_i || web_i)) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A %0s address: %0h, B %0s address: %0h\n",
wea_i ? "write" : "read", ADDRA,
web_i ? "write" : "read", ADDRB);
end
end
//****************************************************
// Asynchronous collision checks
//****************************************************
end else if (!C_DISABLE_WARN_BHV_COLL && !C_COMMON_CLK) begin : async_coll
// Delay A and B addresses in order to mimic setup/hold times
wire [C_ADDRA_WIDTH-1:0] #COLL_DELAY addra_delay = ADDRA;
wire [0:0] #COLL_DELAY wea_delay = wea_i;
wire #COLL_DELAY ena_delay = ena_i;
wire [C_ADDRB_WIDTH-1:0] #COLL_DELAY addrb_delay = ADDRB;
wire [0:0] #COLL_DELAY web_delay = web_i;
wire #COLL_DELAY enb_delay = enb_i;
// Do the checks w/rt A
always @(posedge CLKA) begin
// Possible collision if both are enabled and the addresses match
if (ena_i && enb_i) begin
if (wea_i || web_i) begin
is_collision_a = collision_check(ADDRA, wea_i, ADDRB, web_i);
end else begin
is_collision_a = 0;
end
end else begin
is_collision_a = 0;
end
if (ena_i && enb_delay) begin
if(wea_i || web_delay) begin
is_collision_delay_a = collision_check(ADDRA, wea_i, addrb_delay,
web_delay);
end else begin
is_collision_delay_a = 0;
end
end else begin
is_collision_delay_a = 0;
end
// Only flag if B access is a write
if (is_collision_a && web_i) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A %0s address: %0h, B write address: %0h\n",
wea_i ? "write" : "read", ADDRA, ADDRB);
end else if (is_collision_delay_a && web_delay) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A %0s address: %0h, B write address: %0h\n",
wea_i ? "write" : "read", ADDRA, addrb_delay);
end
end
// Do the checks w/rt B
always @(posedge CLKB) begin
// Possible collision if both are enabled and the addresses match
if (ena_i && enb_i) begin
if (wea_i || web_i) begin
is_collision_b = collision_check(ADDRA, wea_i, ADDRB, web_i);
end else begin
is_collision_b = 0;
end
end else begin
is_collision_b = 0;
end
if (ena_delay && enb_i) begin
if (wea_delay || web_i) begin
is_collision_delay_b = collision_check(addra_delay, wea_delay, ADDRB,
web_i);
end else begin
is_collision_delay_b = 0;
end
end else begin
is_collision_delay_b = 0;
end
// Only flag if A access is a write
if (is_collision_b && wea_i) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A write address: %0h, B %s address: %0h\n",
ADDRA, web_i ? "write" : "read", ADDRB);
end else if (is_collision_delay_b && wea_delay) begin
$fwrite(COLLFILE, "%0s collision detected at time: %0d, ",
C_CORENAME, $time);
$fwrite(COLLFILE, "A write address: %0h, B %s address: %0h\n",
addra_delay, web_i ? "write" : "read", ADDRB);
end
end
end
endgenerate
endmodule |
module blk_mem_gen_v8_2
#(parameter C_CORENAME = "blk_mem_gen_v8_2",
parameter C_FAMILY = "virtex7",
parameter C_XDEVICEFAMILY = "virtex7",
parameter C_ELABORATION_DIR = "",
parameter C_INTERFACE_TYPE = 0,
parameter C_USE_BRAM_BLOCK = 0,
parameter C_CTRL_ECC_ALGO = "NONE",
parameter C_ENABLE_32BIT_ADDRESS = 0,
parameter C_AXI_TYPE = 0,
parameter C_AXI_SLAVE_TYPE = 0,
parameter C_HAS_AXI_ID = 0,
parameter C_AXI_ID_WIDTH = 4,
parameter C_MEM_TYPE = 2,
parameter C_BYTE_SIZE = 9,
parameter C_ALGORITHM = 1,
parameter C_PRIM_TYPE = 3,
parameter C_LOAD_INIT_FILE = 0,
parameter C_INIT_FILE_NAME = "",
parameter C_INIT_FILE = "",
parameter C_USE_DEFAULT_DATA = 0,
parameter C_DEFAULT_DATA = "0",
//parameter C_RST_TYPE = "SYNC",
parameter C_HAS_RSTA = 0,
parameter C_RST_PRIORITY_A = "CE",
parameter C_RSTRAM_A = 0,
parameter C_INITA_VAL = "0",
parameter C_HAS_ENA = 1,
parameter C_HAS_REGCEA = 0,
parameter C_USE_BYTE_WEA = 0,
parameter C_WEA_WIDTH = 1,
parameter C_WRITE_MODE_A = "WRITE_FIRST",
parameter C_WRITE_WIDTH_A = 32,
parameter C_READ_WIDTH_A = 32,
parameter C_WRITE_DEPTH_A = 64,
parameter C_READ_DEPTH_A = 64,
parameter C_ADDRA_WIDTH = 5,
parameter C_HAS_RSTB = 0,
parameter C_RST_PRIORITY_B = "CE",
parameter C_RSTRAM_B = 0,
parameter C_INITB_VAL = "",
parameter C_HAS_ENB = 1,
parameter C_HAS_REGCEB = 0,
parameter C_USE_BYTE_WEB = 0,
parameter C_WEB_WIDTH = 1,
parameter C_WRITE_MODE_B = "WRITE_FIRST",
parameter C_WRITE_WIDTH_B = 32,
parameter C_READ_WIDTH_B = 32,
parameter C_WRITE_DEPTH_B = 64,
parameter C_READ_DEPTH_B = 64,
parameter C_ADDRB_WIDTH = 5,
parameter C_HAS_MEM_OUTPUT_REGS_A = 0,
parameter C_HAS_MEM_OUTPUT_REGS_B = 0,
parameter C_HAS_MUX_OUTPUT_REGS_A = 0,
parameter C_HAS_MUX_OUTPUT_REGS_B = 0,
parameter C_HAS_SOFTECC_INPUT_REGS_A = 0,
parameter C_HAS_SOFTECC_OUTPUT_REGS_B= 0,
parameter C_MUX_PIPELINE_STAGES = 0,
parameter C_USE_SOFTECC = 0,
parameter C_USE_ECC = 0,
parameter C_EN_ECC_PIPE = 0,
parameter C_HAS_INJECTERR = 0,
parameter C_SIM_COLLISION_CHECK = "NONE",
parameter C_COMMON_CLK = 1,
parameter C_DISABLE_WARN_BHV_COLL = 0,
parameter C_EN_SLEEP_PIN = 0,
parameter C_USE_URAM = 0,
parameter C_EN_RDADDRA_CHG = 0,
parameter C_EN_RDADDRB_CHG = 0,
parameter C_EN_DEEPSLEEP_PIN = 0,
parameter C_EN_SHUTDOWN_PIN = 0,
parameter C_DISABLE_WARN_BHV_RANGE = 0,
parameter C_COUNT_36K_BRAM = "",
parameter C_COUNT_18K_BRAM = "",
parameter C_EST_POWER_SUMMARY = ""
)
(input clka,
input rsta,
input ena,
input regcea,
input [C_WEA_WIDTH-1:0] wea,
input [C_ADDRA_WIDTH-1:0] addra,
input [C_WRITE_WIDTH_A-1:0] dina,
output [C_READ_WIDTH_A-1:0] douta,
input clkb,
input rstb,
input enb,
input regceb,
input [C_WEB_WIDTH-1:0] web,
input [C_ADDRB_WIDTH-1:0] addrb,
input [C_WRITE_WIDTH_B-1:0] dinb,
output [C_READ_WIDTH_B-1:0] doutb,
input injectsbiterr,
input injectdbiterr,
output sbiterr,
output dbiterr,
output [C_ADDRB_WIDTH-1:0] rdaddrecc,
input eccpipece,
input sleep,
input deepsleep,
input shutdown,
//AXI BMG Input and Output Port Declarations
//AXI Global Signals
input s_aclk,
input s_aresetn,
//AXI Full/lite slave write (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_awid,
input [31:0] s_axi_awaddr,
input [7:0] s_axi_awlen,
input [2:0] s_axi_awsize,
input [1:0] s_axi_awburst,
input s_axi_awvalid,
output s_axi_awready,
input [C_WRITE_WIDTH_A-1:0] s_axi_wdata,
input [C_WEA_WIDTH-1:0] s_axi_wstrb,
input s_axi_wlast,
input s_axi_wvalid,
output s_axi_wready,
output [C_AXI_ID_WIDTH-1:0] s_axi_bid,
output [1:0] s_axi_bresp,
output s_axi_bvalid,
input s_axi_bready,
//AXI Full/lite slave read (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_arid,
input [31:0] s_axi_araddr,
input [7:0] s_axi_arlen,
input [2:0] s_axi_arsize,
input [1:0] s_axi_arburst,
input s_axi_arvalid,
output s_axi_arready,
output [C_AXI_ID_WIDTH-1:0] s_axi_rid,
output [C_WRITE_WIDTH_B-1:0] s_axi_rdata,
output [1:0] s_axi_rresp,
output s_axi_rlast,
output s_axi_rvalid,
input s_axi_rready,
//AXI Full/lite sideband signals
input s_axi_injectsbiterr,
input s_axi_injectdbiterr,
output s_axi_sbiterr,
output s_axi_dbiterr,
output [C_ADDRB_WIDTH-1:0] s_axi_rdaddrecc
);
//******************************
// Port and Generic Definitions
//******************************
//////////////////////////////////////////////////////////////////////////
// Generic Definitions
//////////////////////////////////////////////////////////////////////////
// C_CORENAME : Instance name of the Block Memory Generator core
// C_FAMILY,C_XDEVICEFAMILY: Designates architecture targeted. The following
// options are available - "spartan3", "spartan6",
// "virtex4", "virtex5", "virtex6" and "virtex6l".
// C_MEM_TYPE : Designates memory type.
// It can be
// 0 - Single Port Memory
// 1 - Simple Dual Port Memory
// 2 - True Dual Port Memory
// 3 - Single Port Read Only Memory
// 4 - Dual Port Read Only Memory
// C_BYTE_SIZE : Size of a byte (8 or 9 bits)
// C_ALGORITHM : Designates the algorithm method used
// for constructing the memory.
// It can be Fixed_Primitives, Minimum_Area or
// Low_Power
// C_PRIM_TYPE : Designates the user selected primitive used to
// construct the memory.
//
// C_LOAD_INIT_FILE : Designates the use of an initialization file to
// initialize memory contents.
// C_INIT_FILE_NAME : Memory initialization file name.
// C_USE_DEFAULT_DATA : Designates whether to fill remaining
// initialization space with default data
// C_DEFAULT_DATA : Default value of all memory locations
// not initialized by the memory
// initialization file.
// C_RST_TYPE : Type of reset - Synchronous or Asynchronous
// C_HAS_RSTA : Determines the presence of the RSTA port
// C_RST_PRIORITY_A : Determines the priority between CE and SR for
// Port A.
// C_RSTRAM_A : Determines if special reset behavior is used for
// Port A
// C_INITA_VAL : The initialization value for Port A
// C_HAS_ENA : Determines the presence of the ENA port
// C_HAS_REGCEA : Determines the presence of the REGCEA port
// C_USE_BYTE_WEA : Determines if the Byte Write is used or not.
// C_WEA_WIDTH : The width of the WEA port
// C_WRITE_MODE_A : Configurable write mode for Port A. It can be
// WRITE_FIRST, READ_FIRST or NO_CHANGE.
// C_WRITE_WIDTH_A : Memory write width for Port A.
// C_READ_WIDTH_A : Memory read width for Port A.
// C_WRITE_DEPTH_A : Memory write depth for Port A.
// C_READ_DEPTH_A : Memory read depth for Port A.
// C_ADDRA_WIDTH : Width of the ADDRA input port
// C_HAS_RSTB : Determines the presence of the RSTB port
// C_RST_PRIORITY_B : Determines the priority between CE and SR for
// Port B.
// C_RSTRAM_B : Determines if special reset behavior is used for
// Port B
// C_INITB_VAL : The initialization value for Port B
// C_HAS_ENB : Determines the presence of the ENB port
// C_HAS_REGCEB : Determines the presence of the REGCEB port
// C_USE_BYTE_WEB : Determines if the Byte Write is used or not.
// C_WEB_WIDTH : The width of the WEB port
// C_WRITE_MODE_B : Configurable write mode for Port B. It can be
// WRITE_FIRST, READ_FIRST or NO_CHANGE.
// C_WRITE_WIDTH_B : Memory write width for Port B.
// C_READ_WIDTH_B : Memory read width for Port B.
// C_WRITE_DEPTH_B : Memory write depth for Port B.
// C_READ_DEPTH_B : Memory read depth for Port B.
// C_ADDRB_WIDTH : Width of the ADDRB input port
// C_HAS_MEM_OUTPUT_REGS_A : Designates the use of a register at the output
// of the RAM primitive for Port A.
// C_HAS_MEM_OUTPUT_REGS_B : Designates the use of a register at the output
// of the RAM primitive for Port B.
// C_HAS_MUX_OUTPUT_REGS_A : Designates the use of a register at the output
// of the MUX for Port A.
// C_HAS_MUX_OUTPUT_REGS_B : Designates the use of a register at the output
// of the MUX for Port B.
// C_HAS_SOFTECC_INPUT_REGS_A :
// C_HAS_SOFTECC_OUTPUT_REGS_B :
// C_MUX_PIPELINE_STAGES : Designates the number of pipeline stages in
// between the muxes.
// C_USE_SOFTECC : Determines if the Soft ECC feature is used or
// not. Only applicable Spartan-6
// C_USE_ECC : Determines if the ECC feature is used or
// not. Only applicable for V5 and V6
// C_HAS_INJECTERR : Determines if the error injection pins
// are present or not. If the ECC feature
// is not used, this value is defaulted to
// 0, else the following are the allowed
// values:
// 0 : No INJECTSBITERR or INJECTDBITERR pins
// 1 : Only INJECTSBITERR pin exists
// 2 : Only INJECTDBITERR pin exists
// 3 : Both INJECTSBITERR and INJECTDBITERR pins exist
// C_SIM_COLLISION_CHECK : Controls the disabling of Unisim model collision
// warnings. It can be "ALL", "NONE",
// "Warnings_Only" or "Generate_X_Only".
// C_COMMON_CLK : Determins if the core has a single CLK input.
// C_DISABLE_WARN_BHV_COLL : Controls the Behavioral Model Collision warnings
// C_DISABLE_WARN_BHV_RANGE: Controls the Behavioral Model Out of Range
// warnings
//////////////////////////////////////////////////////////////////////////
// Port Definitions
//////////////////////////////////////////////////////////////////////////
// CLKA : Clock to synchronize all read and write operations of Port A.
// RSTA : Reset input to reset memory outputs to a user-defined
// reset state for Port A.
// ENA : Enable all read and write operations of Port A.
// REGCEA : Register Clock Enable to control each pipeline output
// register stages for Port A.
// WEA : Write Enable to enable all write operations of Port A.
// ADDRA : Address of Port A.
// DINA : Data input of Port A.
// DOUTA : Data output of Port A.
// CLKB : Clock to synchronize all read and write operations of Port B.
// RSTB : Reset input to reset memory outputs to a user-defined
// reset state for Port B.
// ENB : Enable all read and write operations of Port B.
// REGCEB : Register Clock Enable to control each pipeline output
// register stages for Port B.
// WEB : Write Enable to enable all write operations of Port B.
// ADDRB : Address of Port B.
// DINB : Data input of Port B.
// DOUTB : Data output of Port B.
// INJECTSBITERR : Single Bit ECC Error Injection Pin.
// INJECTDBITERR : Double Bit ECC Error Injection Pin.
// SBITERR : Output signal indicating that a Single Bit ECC Error has been
// detected and corrected.
// DBITERR : Output signal indicating that a Double Bit ECC Error has been
// detected.
// RDADDRECC : Read Address Output signal indicating address at which an
// ECC error has occurred.
//////////////////////////////////////////////////////////////////////////
wire SBITERR;
wire DBITERR;
wire S_AXI_AWREADY;
wire S_AXI_WREADY;
wire S_AXI_BVALID;
wire S_AXI_ARREADY;
wire S_AXI_RLAST;
wire S_AXI_RVALID;
wire S_AXI_SBITERR;
wire S_AXI_DBITERR;
wire [C_WEA_WIDTH-1:0] WEA = wea;
wire [C_ADDRA_WIDTH-1:0] ADDRA = addra;
wire [C_WRITE_WIDTH_A-1:0] DINA = dina;
wire [C_READ_WIDTH_A-1:0] DOUTA;
wire [C_WEB_WIDTH-1:0] WEB = web;
wire [C_ADDRB_WIDTH-1:0] ADDRB = addrb;
wire [C_WRITE_WIDTH_B-1:0] DINB = dinb;
wire [C_READ_WIDTH_B-1:0] DOUTB;
wire [C_ADDRB_WIDTH-1:0] RDADDRECC;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID = s_axi_awid;
wire [31:0] S_AXI_AWADDR = s_axi_awaddr;
wire [7:0] S_AXI_AWLEN = s_axi_awlen;
wire [2:0] S_AXI_AWSIZE = s_axi_awsize;
wire [1:0] S_AXI_AWBURST = s_axi_awburst;
wire [C_WRITE_WIDTH_A-1:0] S_AXI_WDATA = s_axi_wdata;
wire [C_WEA_WIDTH-1:0] S_AXI_WSTRB = s_axi_wstrb;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID;
wire [1:0] S_AXI_BRESP;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_ARID = s_axi_arid;
wire [31:0] S_AXI_ARADDR = s_axi_araddr;
wire [7:0] S_AXI_ARLEN = s_axi_arlen;
wire [2:0] S_AXI_ARSIZE = s_axi_arsize;
wire [1:0] S_AXI_ARBURST = s_axi_arburst;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID;
wire [C_WRITE_WIDTH_B-1:0] S_AXI_RDATA;
wire [1:0] S_AXI_RRESP;
wire [C_ADDRB_WIDTH-1:0] S_AXI_RDADDRECC;
// Added to fix the simulation warning #CR731605
wire [C_WEB_WIDTH-1:0] WEB_parameterized = 0;
wire ECCPIPECE;
wire SLEEP;
assign CLKA = clka;
assign RSTA = rsta;
assign ENA = ena;
assign REGCEA = regcea;
assign CLKB = clkb;
assign RSTB = rstb;
assign ENB = enb;
assign REGCEB = regceb;
assign INJECTSBITERR = injectsbiterr;
assign INJECTDBITERR = injectdbiterr;
assign ECCPIPECE = eccpipece;
assign SLEEP = sleep;
assign sbiterr = SBITERR;
assign dbiterr = DBITERR;
assign S_ACLK = s_aclk;
assign S_ARESETN = s_aresetn;
assign S_AXI_AWVALID = s_axi_awvalid;
assign s_axi_awready = S_AXI_AWREADY;
assign S_AXI_WLAST = s_axi_wlast;
assign S_AXI_WVALID = s_axi_wvalid;
assign s_axi_wready = S_AXI_WREADY;
assign s_axi_bvalid = S_AXI_BVALID;
assign S_AXI_BREADY = s_axi_bready;
assign S_AXI_ARVALID = s_axi_arvalid;
assign s_axi_arready = S_AXI_ARREADY;
assign s_axi_rlast = S_AXI_RLAST;
assign s_axi_rvalid = S_AXI_RVALID;
assign S_AXI_RREADY = s_axi_rready;
assign S_AXI_INJECTSBITERR = s_axi_injectsbiterr;
assign S_AXI_INJECTDBITERR = s_axi_injectdbiterr;
assign s_axi_sbiterr = S_AXI_SBITERR;
assign s_axi_dbiterr = S_AXI_DBITERR;
assign doutb = DOUTB;
assign douta = DOUTA;
assign rdaddrecc = RDADDRECC;
assign s_axi_bid = S_AXI_BID;
assign s_axi_bresp = S_AXI_BRESP;
assign s_axi_rid = S_AXI_RID;
assign s_axi_rdata = S_AXI_RDATA;
assign s_axi_rresp = S_AXI_RRESP;
assign s_axi_rdaddrecc = S_AXI_RDADDRECC;
localparam FLOP_DELAY = 100; // 100 ps
reg injectsbiterr_in;
reg injectdbiterr_in;
reg rsta_in;
reg ena_in;
reg regcea_in;
reg [C_WEA_WIDTH-1:0] wea_in;
reg [C_ADDRA_WIDTH-1:0] addra_in;
reg [C_WRITE_WIDTH_A-1:0] dina_in;
wire [C_ADDRA_WIDTH-1:0] s_axi_awaddr_out_c;
wire [C_ADDRB_WIDTH-1:0] s_axi_araddr_out_c;
wire s_axi_wr_en_c;
wire s_axi_rd_en_c;
wire s_aresetn_a_c;
wire [7:0] s_axi_arlen_c ;
wire [C_AXI_ID_WIDTH-1 : 0] s_axi_rid_c;
wire [C_WRITE_WIDTH_B-1 : 0] s_axi_rdata_c;
wire [1:0] s_axi_rresp_c;
wire s_axi_rlast_c;
wire s_axi_rvalid_c;
wire s_axi_rready_c;
wire regceb_c;
localparam C_AXI_PAYLOAD = (C_HAS_MUX_OUTPUT_REGS_B == 1)?C_WRITE_WIDTH_B+C_AXI_ID_WIDTH+3:C_AXI_ID_WIDTH+3;
wire [C_AXI_PAYLOAD-1 : 0] s_axi_payload_c;
wire [C_AXI_PAYLOAD-1 : 0] m_axi_payload_c;
//**************
// log2roundup
//**************
function integer log2roundup (input integer data_value);
integer width;
integer cnt;
begin
width = 0;
if (data_value > 1) begin
for(cnt=1 ; cnt < data_value ; cnt = cnt * 2) begin
width = width + 1;
end //loop
end //if
log2roundup = width;
end //log2roundup
endfunction
//**************
// log2int
//**************
function integer log2int (input integer data_value);
integer width;
integer cnt;
begin
width = 0;
cnt= data_value;
for(cnt=data_value ; cnt >1 ; cnt = cnt / 2) begin
width = width + 1;
end //loop
log2int = width;
end //log2int
endfunction
//**************************************************************************
// FUNCTION : divroundup
// Returns the ceiling value of the division
// Data_value - the quantity to be divided, dividend
// Divisor - the value to divide the data_value by
//**************************************************************************
function integer divroundup (input integer data_value,input integer divisor);
integer div;
begin
div = data_value/divisor;
if ((data_value % divisor) != 0) begin
div = div+1;
end //if
divroundup = div;
end //if
endfunction
localparam AXI_FULL_MEMORY_SLAVE = ((C_AXI_SLAVE_TYPE == 0 && C_AXI_TYPE == 1)?1:0);
localparam C_AXI_ADDR_WIDTH_MSB = C_ADDRA_WIDTH+log2roundup(C_WRITE_WIDTH_A/8);
localparam C_AXI_ADDR_WIDTH = C_AXI_ADDR_WIDTH_MSB;
//Data Width Number of LSB address bits to be discarded
//1 to 16 1
//17 to 32 2
//33 to 64 3
//65 to 128 4
//129 to 256 5
//257 to 512 6
//513 to 1024 7
// The following two constants determine this.
localparam LOWER_BOUND_VAL = (log2roundup(divroundup(C_WRITE_WIDTH_A,8) == 0))?0:(log2roundup(divroundup(C_WRITE_WIDTH_A,8)));
localparam C_AXI_ADDR_WIDTH_LSB = ((AXI_FULL_MEMORY_SLAVE == 1)?0:LOWER_BOUND_VAL);
localparam C_AXI_OS_WR = 2;
//***********************************************
// INPUT REGISTERS.
//***********************************************
generate if (C_HAS_SOFTECC_INPUT_REGS_A==0) begin : no_softecc_input_reg_stage
always @* begin
injectsbiterr_in = INJECTSBITERR;
injectdbiterr_in = INJECTDBITERR;
rsta_in = RSTA;
ena_in = ENA;
regcea_in = REGCEA;
wea_in = WEA;
addra_in = ADDRA;
dina_in = DINA;
end //end always
end //end no_softecc_input_reg_stage
endgenerate
generate if (C_HAS_SOFTECC_INPUT_REGS_A==1) begin : has_softecc_input_reg_stage
always @(posedge CLKA) begin
injectsbiterr_in <= #FLOP_DELAY INJECTSBITERR;
injectdbiterr_in <= #FLOP_DELAY INJECTDBITERR;
rsta_in <= #FLOP_DELAY RSTA;
ena_in <= #FLOP_DELAY ENA;
regcea_in <= #FLOP_DELAY REGCEA;
wea_in <= #FLOP_DELAY WEA;
addra_in <= #FLOP_DELAY ADDRA;
dina_in <= #FLOP_DELAY DINA;
end //end always
end //end input_reg_stages generate statement
endgenerate
generate if ((C_INTERFACE_TYPE == 0) && (C_ENABLE_32BIT_ADDRESS == 0)) begin : native_mem_module
BLK_MEM_GEN_v8_2_mem_module
#(.C_CORENAME (C_CORENAME),
.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_MEM_TYPE (C_MEM_TYPE),
.C_BYTE_SIZE (C_BYTE_SIZE),
.C_ALGORITHM (C_ALGORITHM),
.C_USE_BRAM_BLOCK (C_USE_BRAM_BLOCK),
.C_PRIM_TYPE (C_PRIM_TYPE),
.C_LOAD_INIT_FILE (C_LOAD_INIT_FILE),
.C_INIT_FILE_NAME (C_INIT_FILE_NAME),
.C_INIT_FILE (C_INIT_FILE),
.C_USE_DEFAULT_DATA (C_USE_DEFAULT_DATA),
.C_DEFAULT_DATA (C_DEFAULT_DATA),
.C_RST_TYPE ("SYNC"),
.C_HAS_RSTA (C_HAS_RSTA),
.C_RST_PRIORITY_A (C_RST_PRIORITY_A),
.C_RSTRAM_A (C_RSTRAM_A),
.C_INITA_VAL (C_INITA_VAL),
.C_HAS_ENA (C_HAS_ENA),
.C_HAS_REGCEA (C_HAS_REGCEA),
.C_USE_BYTE_WEA (C_USE_BYTE_WEA),
.C_WEA_WIDTH (C_WEA_WIDTH),
.C_WRITE_MODE_A (C_WRITE_MODE_A),
.C_WRITE_WIDTH_A (C_WRITE_WIDTH_A),
.C_READ_WIDTH_A (C_READ_WIDTH_A),
.C_WRITE_DEPTH_A (C_WRITE_DEPTH_A),
.C_READ_DEPTH_A (C_READ_DEPTH_A),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH),
.C_HAS_RSTB (C_HAS_RSTB),
.C_RST_PRIORITY_B (C_RST_PRIORITY_B),
.C_RSTRAM_B (C_RSTRAM_B),
.C_INITB_VAL (C_INITB_VAL),
.C_HAS_ENB (C_HAS_ENB),
.C_HAS_REGCEB (C_HAS_REGCEB),
.C_USE_BYTE_WEB (C_USE_BYTE_WEB),
.C_WEB_WIDTH (C_WEB_WIDTH),
.C_WRITE_MODE_B (C_WRITE_MODE_B),
.C_WRITE_WIDTH_B (C_WRITE_WIDTH_B),
.C_READ_WIDTH_B (C_READ_WIDTH_B),
.C_WRITE_DEPTH_B (C_WRITE_DEPTH_B),
.C_READ_DEPTH_B (C_READ_DEPTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_MEM_OUTPUT_REGS_A (C_HAS_MEM_OUTPUT_REGS_A),
.C_HAS_MEM_OUTPUT_REGS_B (C_HAS_MEM_OUTPUT_REGS_B),
.C_HAS_MUX_OUTPUT_REGS_A (C_HAS_MUX_OUTPUT_REGS_A),
.C_HAS_MUX_OUTPUT_REGS_B (C_HAS_MUX_OUTPUT_REGS_B),
.C_HAS_SOFTECC_INPUT_REGS_A (C_HAS_SOFTECC_INPUT_REGS_A),
.C_HAS_SOFTECC_OUTPUT_REGS_B (C_HAS_SOFTECC_OUTPUT_REGS_B),
.C_MUX_PIPELINE_STAGES (C_MUX_PIPELINE_STAGES),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.C_HAS_INJECTERR (C_HAS_INJECTERR),
.C_SIM_COLLISION_CHECK (C_SIM_COLLISION_CHECK),
.C_COMMON_CLK (C_COMMON_CLK),
.FLOP_DELAY (FLOP_DELAY),
.C_DISABLE_WARN_BHV_COLL (C_DISABLE_WARN_BHV_COLL),
.C_EN_ECC_PIPE (C_EN_ECC_PIPE),
.C_DISABLE_WARN_BHV_RANGE (C_DISABLE_WARN_BHV_RANGE))
blk_mem_gen_v8_2_inst
(.CLKA (CLKA),
.RSTA (rsta_in),
.ENA (ena_in),
.REGCEA (regcea_in),
.WEA (wea_in),
.ADDRA (addra_in),
.DINA (dina_in),
.DOUTA (DOUTA),
.CLKB (CLKB),
.RSTB (RSTB),
.ENB (ENB),
.REGCEB (REGCEB),
.WEB (WEB),
.ADDRB (ADDRB),
.DINB (DINB),
.DOUTB (DOUTB),
.INJECTSBITERR (injectsbiterr_in),
.INJECTDBITERR (injectdbiterr_in),
.ECCPIPECE (ECCPIPECE),
.SLEEP (SLEEP),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.RDADDRECC (RDADDRECC)
);
end
endgenerate
generate if((C_INTERFACE_TYPE == 0) && (C_ENABLE_32BIT_ADDRESS == 1)) begin : native_mem_mapped_module
localparam C_ADDRA_WIDTH_ACTUAL = log2roundup(C_WRITE_DEPTH_A);
localparam C_ADDRB_WIDTH_ACTUAL = log2roundup(C_WRITE_DEPTH_B);
localparam C_ADDRA_WIDTH_MSB = C_ADDRA_WIDTH_ACTUAL+log2int(C_WRITE_WIDTH_A/8);
localparam C_ADDRB_WIDTH_MSB = C_ADDRB_WIDTH_ACTUAL+log2int(C_WRITE_WIDTH_B/8);
// localparam C_ADDRA_WIDTH_MSB = C_ADDRA_WIDTH_ACTUAL+log2roundup(C_WRITE_WIDTH_A/8);
// localparam C_ADDRB_WIDTH_MSB = C_ADDRB_WIDTH_ACTUAL+log2roundup(C_WRITE_WIDTH_B/8);
localparam C_MEM_MAP_ADDRA_WIDTH_MSB = C_ADDRA_WIDTH_MSB;
localparam C_MEM_MAP_ADDRB_WIDTH_MSB = C_ADDRB_WIDTH_MSB;
// Data Width Number of LSB address bits to be discarded
// 1 to 16 1
// 17 to 32 2
// 33 to 64 3
// 65 to 128 4
// 129 to 256 5
// 257 to 512 6
// 513 to 1024 7
// The following two constants determine this.
localparam MEM_MAP_LOWER_BOUND_VAL_A = (log2int(divroundup(C_WRITE_WIDTH_A,8)==0)) ? 0:(log2int(divroundup(C_WRITE_WIDTH_A,8)));
localparam MEM_MAP_LOWER_BOUND_VAL_B = (log2int(divroundup(C_WRITE_WIDTH_A,8)==0)) ? 0:(log2int(divroundup(C_WRITE_WIDTH_A,8)));
localparam C_MEM_MAP_ADDRA_WIDTH_LSB = MEM_MAP_LOWER_BOUND_VAL_A;
localparam C_MEM_MAP_ADDRB_WIDTH_LSB = MEM_MAP_LOWER_BOUND_VAL_B;
wire [C_ADDRB_WIDTH_ACTUAL-1 :0] rdaddrecc_i;
wire [C_ADDRB_WIDTH-1:C_MEM_MAP_ADDRB_WIDTH_MSB] msb_zero_i;
wire [C_MEM_MAP_ADDRB_WIDTH_LSB-1:0] lsb_zero_i;
assign msb_zero_i = 0;
assign lsb_zero_i = 0;
assign RDADDRECC = {msb_zero_i,rdaddrecc_i,lsb_zero_i};
BLK_MEM_GEN_v8_2_mem_module
#(.C_CORENAME (C_CORENAME),
.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_MEM_TYPE (C_MEM_TYPE),
.C_BYTE_SIZE (C_BYTE_SIZE),
.C_USE_BRAM_BLOCK (C_USE_BRAM_BLOCK),
.C_ALGORITHM (C_ALGORITHM),
.C_PRIM_TYPE (C_PRIM_TYPE),
.C_LOAD_INIT_FILE (C_LOAD_INIT_FILE),
.C_INIT_FILE_NAME (C_INIT_FILE_NAME),
.C_INIT_FILE (C_INIT_FILE),
.C_USE_DEFAULT_DATA (C_USE_DEFAULT_DATA),
.C_DEFAULT_DATA (C_DEFAULT_DATA),
.C_RST_TYPE ("SYNC"),
.C_HAS_RSTA (C_HAS_RSTA),
.C_RST_PRIORITY_A (C_RST_PRIORITY_A),
.C_RSTRAM_A (C_RSTRAM_A),
.C_INITA_VAL (C_INITA_VAL),
.C_HAS_ENA (C_HAS_ENA),
.C_HAS_REGCEA (C_HAS_REGCEA),
.C_USE_BYTE_WEA (C_USE_BYTE_WEA),
.C_WEA_WIDTH (C_WEA_WIDTH),
.C_WRITE_MODE_A (C_WRITE_MODE_A),
.C_WRITE_WIDTH_A (C_WRITE_WIDTH_A),
.C_READ_WIDTH_A (C_READ_WIDTH_A),
.C_WRITE_DEPTH_A (C_WRITE_DEPTH_A),
.C_READ_DEPTH_A (C_READ_DEPTH_A),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH_ACTUAL),
.C_HAS_RSTB (C_HAS_RSTB),
.C_RST_PRIORITY_B (C_RST_PRIORITY_B),
.C_RSTRAM_B (C_RSTRAM_B),
.C_INITB_VAL (C_INITB_VAL),
.C_HAS_ENB (C_HAS_ENB),
.C_HAS_REGCEB (C_HAS_REGCEB),
.C_USE_BYTE_WEB (C_USE_BYTE_WEB),
.C_WEB_WIDTH (C_WEB_WIDTH),
.C_WRITE_MODE_B (C_WRITE_MODE_B),
.C_WRITE_WIDTH_B (C_WRITE_WIDTH_B),
.C_READ_WIDTH_B (C_READ_WIDTH_B),
.C_WRITE_DEPTH_B (C_WRITE_DEPTH_B),
.C_READ_DEPTH_B (C_READ_DEPTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH_ACTUAL),
.C_HAS_MEM_OUTPUT_REGS_A (C_HAS_MEM_OUTPUT_REGS_A),
.C_HAS_MEM_OUTPUT_REGS_B (C_HAS_MEM_OUTPUT_REGS_B),
.C_HAS_MUX_OUTPUT_REGS_A (C_HAS_MUX_OUTPUT_REGS_A),
.C_HAS_MUX_OUTPUT_REGS_B (C_HAS_MUX_OUTPUT_REGS_B),
.C_HAS_SOFTECC_INPUT_REGS_A (C_HAS_SOFTECC_INPUT_REGS_A),
.C_HAS_SOFTECC_OUTPUT_REGS_B (C_HAS_SOFTECC_OUTPUT_REGS_B),
.C_MUX_PIPELINE_STAGES (C_MUX_PIPELINE_STAGES),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.C_HAS_INJECTERR (C_HAS_INJECTERR),
.C_SIM_COLLISION_CHECK (C_SIM_COLLISION_CHECK),
.C_COMMON_CLK (C_COMMON_CLK),
.FLOP_DELAY (FLOP_DELAY),
.C_DISABLE_WARN_BHV_COLL (C_DISABLE_WARN_BHV_COLL),
.C_EN_ECC_PIPE (C_EN_ECC_PIPE),
.C_DISABLE_WARN_BHV_RANGE (C_DISABLE_WARN_BHV_RANGE))
blk_mem_gen_v8_2_inst
(.CLKA (CLKA),
.RSTA (rsta_in),
.ENA (ena_in),
.REGCEA (regcea_in),
.WEA (wea_in),
.ADDRA (addra_in[C_MEM_MAP_ADDRA_WIDTH_MSB-1:C_MEM_MAP_ADDRA_WIDTH_LSB]),
.DINA (dina_in),
.DOUTA (DOUTA),
.CLKB (CLKB),
.RSTB (RSTB),
.ENB (ENB),
.REGCEB (REGCEB),
.WEB (WEB),
.ADDRB (ADDRB[C_MEM_MAP_ADDRB_WIDTH_MSB-1:C_MEM_MAP_ADDRB_WIDTH_LSB]),
.DINB (DINB),
.DOUTB (DOUTB),
.INJECTSBITERR (injectsbiterr_in),
.INJECTDBITERR (injectdbiterr_in),
.ECCPIPECE (ECCPIPECE),
.SLEEP (SLEEP),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.RDADDRECC (rdaddrecc_i)
);
end
endgenerate
generate if (C_HAS_MEM_OUTPUT_REGS_B == 0 && C_HAS_MUX_OUTPUT_REGS_B == 0 ) begin : no_regs
assign S_AXI_RDATA = s_axi_rdata_c;
assign S_AXI_RLAST = s_axi_rlast_c;
assign S_AXI_RVALID = s_axi_rvalid_c;
assign S_AXI_RID = s_axi_rid_c;
assign S_AXI_RRESP = s_axi_rresp_c;
assign s_axi_rready_c = S_AXI_RREADY;
end
endgenerate
generate if (C_HAS_MEM_OUTPUT_REGS_B == 1) begin : has_regceb
assign regceb_c = s_axi_rvalid_c && s_axi_rready_c;
end
endgenerate
generate if (C_HAS_MEM_OUTPUT_REGS_B == 0) begin : no_regceb
assign regceb_c = REGCEB;
end
endgenerate
generate if (C_HAS_MUX_OUTPUT_REGS_B == 1) begin : only_core_op_regs
assign s_axi_payload_c = {s_axi_rid_c,s_axi_rdata_c,s_axi_rresp_c,s_axi_rlast_c};
assign S_AXI_RID = m_axi_payload_c[C_AXI_PAYLOAD-1 : C_AXI_PAYLOAD-C_AXI_ID_WIDTH];
assign S_AXI_RDATA = m_axi_payload_c[C_AXI_PAYLOAD-C_AXI_ID_WIDTH-1 : C_AXI_PAYLOAD-C_AXI_ID_WIDTH-C_WRITE_WIDTH_B];
assign S_AXI_RRESP = m_axi_payload_c[2:1];
assign S_AXI_RLAST = m_axi_payload_c[0];
end
endgenerate
generate if (C_HAS_MEM_OUTPUT_REGS_B == 1) begin : only_emb_op_regs
assign s_axi_payload_c = {s_axi_rid_c,s_axi_rresp_c,s_axi_rlast_c};
assign S_AXI_RDATA = s_axi_rdata_c;
assign S_AXI_RID = m_axi_payload_c[C_AXI_PAYLOAD-1 : C_AXI_PAYLOAD-C_AXI_ID_WIDTH];
assign S_AXI_RRESP = m_axi_payload_c[2:1];
assign S_AXI_RLAST = m_axi_payload_c[0];
end
endgenerate
generate if (C_HAS_MUX_OUTPUT_REGS_B == 1 || C_HAS_MEM_OUTPUT_REGS_B == 1) begin : has_regs_fwd
blk_mem_axi_regs_fwd_v8_2
#(.C_DATA_WIDTH (C_AXI_PAYLOAD))
axi_regs_inst (
.ACLK (S_ACLK),
.ARESET (s_aresetn_a_c),
.S_VALID (s_axi_rvalid_c),
.S_READY (s_axi_rready_c),
.S_PAYLOAD_DATA (s_axi_payload_c),
.M_VALID (S_AXI_RVALID),
.M_READY (S_AXI_RREADY),
.M_PAYLOAD_DATA (m_axi_payload_c)
);
end
endgenerate
generate if (C_INTERFACE_TYPE == 1) begin : axi_mem_module
assign s_aresetn_a_c = !S_ARESETN;
assign S_AXI_BRESP = 2'b00;
assign s_axi_rresp_c = 2'b00;
assign s_axi_arlen_c = (C_AXI_TYPE == 1)?S_AXI_ARLEN:8'h0;
blk_mem_axi_write_wrapper_beh_v8_2
#(.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_AXI_SLAVE_TYPE (C_AXI_SLAVE_TYPE),
.C_MEMORY_TYPE (C_MEM_TYPE),
.C_WRITE_DEPTH_A (C_WRITE_DEPTH_A),
.C_AXI_AWADDR_WIDTH ((AXI_FULL_MEMORY_SLAVE == 1)?C_AXI_ADDR_WIDTH:C_AXI_ADDR_WIDTH-C_AXI_ADDR_WIDTH_LSB),
.C_HAS_AXI_ID (C_HAS_AXI_ID),
.C_AXI_ID_WIDTH (C_AXI_ID_WIDTH),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH),
.C_AXI_WDATA_WIDTH (C_WRITE_WIDTH_A),
.C_AXI_OS_WR (C_AXI_OS_WR))
axi_wr_fsm (
// AXI Global Signals
.S_ACLK (S_ACLK),
.S_ARESETN (s_aresetn_a_c),
// AXI Full/Lite Slave Write interface
.S_AXI_AWADDR (S_AXI_AWADDR[C_AXI_ADDR_WIDTH_MSB-1:C_AXI_ADDR_WIDTH_LSB]),
.S_AXI_AWLEN (S_AXI_AWLEN),
.S_AXI_AWID (S_AXI_AWID),
.S_AXI_AWSIZE (S_AXI_AWSIZE),
.S_AXI_AWBURST (S_AXI_AWBURST),
.S_AXI_AWVALID (S_AXI_AWVALID),
.S_AXI_AWREADY (S_AXI_AWREADY),
.S_AXI_WVALID (S_AXI_WVALID),
.S_AXI_WREADY (S_AXI_WREADY),
.S_AXI_BVALID (S_AXI_BVALID),
.S_AXI_BREADY (S_AXI_BREADY),
.S_AXI_BID (S_AXI_BID),
// Signals for BRAM interfac(
.S_AXI_AWADDR_OUT (s_axi_awaddr_out_c),
.S_AXI_WR_EN (s_axi_wr_en_c)
);
blk_mem_axi_read_wrapper_beh_v8_2
#(.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_AXI_SLAVE_TYPE (C_AXI_SLAVE_TYPE),
.C_MEMORY_TYPE (C_MEM_TYPE),
.C_WRITE_WIDTH_A (C_WRITE_WIDTH_A),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH),
.C_AXI_PIPELINE_STAGES (1),
.C_AXI_ARADDR_WIDTH ((AXI_FULL_MEMORY_SLAVE == 1)?C_AXI_ADDR_WIDTH:C_AXI_ADDR_WIDTH-C_AXI_ADDR_WIDTH_LSB),
.C_HAS_AXI_ID (C_HAS_AXI_ID),
.C_AXI_ID_WIDTH (C_AXI_ID_WIDTH),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH))
axi_rd_sm(
//AXI Global Signals
.S_ACLK (S_ACLK),
.S_ARESETN (s_aresetn_a_c),
//AXI Full/Lite Read Side
.S_AXI_ARADDR (S_AXI_ARADDR[C_AXI_ADDR_WIDTH_MSB-1:C_AXI_ADDR_WIDTH_LSB]),
.S_AXI_ARLEN (s_axi_arlen_c),
.S_AXI_ARSIZE (S_AXI_ARSIZE),
.S_AXI_ARBURST (S_AXI_ARBURST),
.S_AXI_ARVALID (S_AXI_ARVALID),
.S_AXI_ARREADY (S_AXI_ARREADY),
.S_AXI_RLAST (s_axi_rlast_c),
.S_AXI_RVALID (s_axi_rvalid_c),
.S_AXI_RREADY (s_axi_rready_c),
.S_AXI_ARID (S_AXI_ARID),
.S_AXI_RID (s_axi_rid_c),
//AXI Full/Lite Read FSM Outputs
.S_AXI_ARADDR_OUT (s_axi_araddr_out_c),
.S_AXI_RD_EN (s_axi_rd_en_c)
);
BLK_MEM_GEN_v8_2_mem_module
#(.C_CORENAME (C_CORENAME),
.C_FAMILY (C_FAMILY),
.C_XDEVICEFAMILY (C_XDEVICEFAMILY),
.C_MEM_TYPE (C_MEM_TYPE),
.C_BYTE_SIZE (C_BYTE_SIZE),
.C_USE_BRAM_BLOCK (C_USE_BRAM_BLOCK),
.C_ALGORITHM (C_ALGORITHM),
.C_PRIM_TYPE (C_PRIM_TYPE),
.C_LOAD_INIT_FILE (C_LOAD_INIT_FILE),
.C_INIT_FILE_NAME (C_INIT_FILE_NAME),
.C_INIT_FILE (C_INIT_FILE),
.C_USE_DEFAULT_DATA (C_USE_DEFAULT_DATA),
.C_DEFAULT_DATA (C_DEFAULT_DATA),
.C_RST_TYPE ("SYNC"),
.C_HAS_RSTA (C_HAS_RSTA),
.C_RST_PRIORITY_A (C_RST_PRIORITY_A),
.C_RSTRAM_A (C_RSTRAM_A),
.C_INITA_VAL (C_INITA_VAL),
.C_HAS_ENA (1),
.C_HAS_REGCEA (C_HAS_REGCEA),
.C_USE_BYTE_WEA (1),
.C_WEA_WIDTH (C_WEA_WIDTH),
.C_WRITE_MODE_A (C_WRITE_MODE_A),
.C_WRITE_WIDTH_A (C_WRITE_WIDTH_A),
.C_READ_WIDTH_A (C_READ_WIDTH_A),
.C_WRITE_DEPTH_A (C_WRITE_DEPTH_A),
.C_READ_DEPTH_A (C_READ_DEPTH_A),
.C_ADDRA_WIDTH (C_ADDRA_WIDTH),
.C_HAS_RSTB (C_HAS_RSTB),
.C_RST_PRIORITY_B (C_RST_PRIORITY_B),
.C_RSTRAM_B (C_RSTRAM_B),
.C_INITB_VAL (C_INITB_VAL),
.C_HAS_ENB (1),
.C_HAS_REGCEB (C_HAS_MEM_OUTPUT_REGS_B),
.C_USE_BYTE_WEB (1),
.C_WEB_WIDTH (C_WEB_WIDTH),
.C_WRITE_MODE_B (C_WRITE_MODE_B),
.C_WRITE_WIDTH_B (C_WRITE_WIDTH_B),
.C_READ_WIDTH_B (C_READ_WIDTH_B),
.C_WRITE_DEPTH_B (C_WRITE_DEPTH_B),
.C_READ_DEPTH_B (C_READ_DEPTH_B),
.C_ADDRB_WIDTH (C_ADDRB_WIDTH),
.C_HAS_MEM_OUTPUT_REGS_A (0),
.C_HAS_MEM_OUTPUT_REGS_B (C_HAS_MEM_OUTPUT_REGS_B),
.C_HAS_MUX_OUTPUT_REGS_A (0),
.C_HAS_MUX_OUTPUT_REGS_B (0),
.C_HAS_SOFTECC_INPUT_REGS_A (C_HAS_SOFTECC_INPUT_REGS_A),
.C_HAS_SOFTECC_OUTPUT_REGS_B (C_HAS_SOFTECC_OUTPUT_REGS_B),
.C_MUX_PIPELINE_STAGES (C_MUX_PIPELINE_STAGES),
.C_USE_SOFTECC (C_USE_SOFTECC),
.C_USE_ECC (C_USE_ECC),
.C_HAS_INJECTERR (C_HAS_INJECTERR),
.C_SIM_COLLISION_CHECK (C_SIM_COLLISION_CHECK),
.C_COMMON_CLK (C_COMMON_CLK),
.FLOP_DELAY (FLOP_DELAY),
.C_DISABLE_WARN_BHV_COLL (C_DISABLE_WARN_BHV_COLL),
.C_EN_ECC_PIPE (0),
.C_DISABLE_WARN_BHV_RANGE (C_DISABLE_WARN_BHV_RANGE))
blk_mem_gen_v8_2_inst
(.CLKA (S_ACLK),
.RSTA (s_aresetn_a_c),
.ENA (s_axi_wr_en_c),
.REGCEA (regcea_in),
.WEA (S_AXI_WSTRB),
.ADDRA (s_axi_awaddr_out_c),
.DINA (S_AXI_WDATA),
.DOUTA (DOUTA),
.CLKB (S_ACLK),
.RSTB (s_aresetn_a_c),
.ENB (s_axi_rd_en_c),
.REGCEB (regceb_c),
.WEB (WEB_parameterized),
.ADDRB (s_axi_araddr_out_c),
.DINB (DINB),
.DOUTB (s_axi_rdata_c),
.INJECTSBITERR (injectsbiterr_in),
.INJECTDBITERR (injectdbiterr_in),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.ECCPIPECE (1'b0),
.SLEEP (1'b0),
.RDADDRECC (RDADDRECC)
);
end
endgenerate
endmodule |
module STATE_LOGIC_v8_2 (O, I0, I1, I2, I3, I4, I5);
parameter INIT = 64'h0000000000000000;
input I0, I1, I2, I3, I4, I5;
output O;
reg O;
reg tmp;
always @( I5 or I4 or I3 or I2 or I1 or I0 ) begin
tmp = I0 ^ I1 ^ I2 ^ I3 ^ I4 ^ I5;
if ( tmp == 0 || tmp == 1)
O = INIT[{I5, I4, I3, I2, I1, I0}];
end
endmodule |
module beh_vlog_muxf7_v8_2 (O, I0, I1, S);
output O;
reg O;
input I0, I1, S;
always @(I0 or I1 or S)
if (S)
O = I1;
else
O = I0;
endmodule |
module beh_vlog_ff_clr_v8_2 (Q, C, CLR, D);
parameter INIT = 0;
localparam FLOP_DELAY = 100;
output Q;
input C, CLR, D;
reg Q;
initial Q= 1'b0;
always @(posedge C )
if (CLR)
Q<= 1'b0;
else
Q<= #FLOP_DELAY D;
endmodule |
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