wangxinze/Verilog_data · Datasets at Hugging Face

module_content stringlengths 18 1.05M
module mig_7series_v2_3_ddr_phy_wrlvl # ( parameter TCQ = 100, parameter DQS_CNT_WIDTH = 3, parameter DQ_WIDTH = 64, parameter DQS_WIDTH = 2, parameter DRAM_WIDTH = 8, parameter RANKS = 1, parameter nCK_PER_CLK = 4, parameter CLK_PERIOD = 4, parameter SIM_CAL_OPTION = "NONE" ) ( input clk, input rst, input phy_ctl_ready, input wr_level_start, input wl_sm_start, input wrlvl_final, input wrlvl_byte_redo, input [DQS_CNT_WIDTH:0] wrcal_cnt, input early1_data, input early2_data, input [DQS_CNT_WIDTH:0] oclkdelay_calib_cnt, input oclkdelay_calib_done, input [(DQ_WIDTH)-1:0] rd_data_rise0, output reg wrlvl_byte_done, output reg dqs_po_dec_done /* synthesis syn_maxfan = 2 /, output phy_ctl_rdy_dly, output reg wr_level_done / synthesis syn_maxfan = 2 /, // to phy_init for cs logic output wrlvl_rank_done, output done_dqs_tap_inc, output [DQS_CNT_WIDTH:0] po_stg2_wl_cnt, // Fine delay line used only during write leveling // Inc/dec Phaser_Out fine delay line output reg dqs_po_stg2_f_incdec, // Enable Phaser_Out fine delay inc/dec output reg dqs_po_en_stg2_f, // Coarse delay line used during write leveling // only if 64 taps of fine delay line were not // sufficient to detect a 0->1 transition // Inc Phaser_Out coarse delay line output reg dqs_wl_po_stg2_c_incdec, // Enable Phaser_Out coarse delay inc/dec output reg dqs_wl_po_en_stg2_c, // Read Phaser_Out delay value input [8:0] po_counter_read_val, // output reg dqs_wl_po_stg2_load, // output reg [8:0] dqs_wl_po_stg2_reg_l, // CK edge undetected output reg wrlvl_err, output reg [3DQS_WIDTH-1:0] wl_po_coarse_cnt, output reg [6DQS_WIDTH-1:0] wl_po_fine_cnt, // Debug ports output [5:0] dbg_wl_tap_cnt, output dbg_wl_edge_detect_valid, output [(DQS_WIDTH)-1:0] dbg_rd_data_edge_detect, output [DQS_CNT_WIDTH:0] dbg_dqs_count, output [4:0] dbg_wl_state, output [6DQS_WIDTH-1:0] dbg_wrlvl_fine_tap_cnt, output [3DQS_WIDTH-1:0] dbg_wrlvl_coarse_tap_cnt, output [255:0] dbg_phy_wrlvl ); localparam WL_IDLE = 5'h0; localparam WL_INIT = 5'h1; localparam WL_INIT_FINE_INC = 5'h2; localparam WL_INIT_FINE_INC_WAIT1= 5'h3; localparam WL_INIT_FINE_INC_WAIT = 5'h4; localparam WL_INIT_FINE_DEC = 5'h5; localparam WL_INIT_FINE_DEC_WAIT = 5'h6; localparam WL_FINE_INC = 5'h7; localparam WL_WAIT = 5'h8; localparam WL_EDGE_CHECK = 5'h9; localparam WL_DQS_CHECK = 5'hA; localparam WL_DQS_CNT = 5'hB; localparam WL_2RANK_TAP_DEC = 5'hC; localparam WL_2RANK_DQS_CNT = 5'hD; localparam WL_FINE_DEC = 5'hE; localparam WL_FINE_DEC_WAIT = 5'hF; localparam WL_CORSE_INC = 5'h10; localparam WL_CORSE_INC_WAIT = 5'h11; localparam WL_CORSE_INC_WAIT1 = 5'h12; localparam WL_CORSE_INC_WAIT2 = 5'h13; localparam WL_CORSE_DEC = 5'h14; localparam WL_CORSE_DEC_WAIT = 5'h15; localparam WL_CORSE_DEC_WAIT1 = 5'h16; localparam WL_FINE_INC_WAIT = 5'h17; localparam WL_2RANK_FINAL_TAP = 5'h18; localparam WL_INIT_FINE_DEC_WAIT1= 5'h19; localparam WL_FINE_DEC_WAIT1 = 5'h1A; localparam WL_CORSE_INC_WAIT_TMP = 5'h1B; localparam COARSE_TAPS = 7; localparam FAST_CAL_FINE = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 45 : 48; localparam FAST_CAL_COARSE = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 1 : 2; localparam REDO_COARSE = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 2 : 5; integer i, j, k, l, p, q, r, s, t, m, n, u, v, w, x,y; reg phy_ctl_ready_r1; reg phy_ctl_ready_r2; reg phy_ctl_ready_r3; reg phy_ctl_ready_r4; reg phy_ctl_ready_r5; reg phy_ctl_ready_r6; ( max_fanout = 50 ) reg [DQS_CNT_WIDTH:0] dqs_count_r; reg [1:0] rank_cnt_r; reg [DQS_WIDTH-1:0] rd_data_rise_wl_r; reg [DQS_WIDTH-1:0] rd_data_previous_r; reg [DQS_WIDTH-1:0] rd_data_edge_detect_r; reg wr_level_done_r; reg wrlvl_rank_done_r; reg wr_level_start_r; reg [4:0] wl_state_r, wl_state_r1; reg inhibit_edge_detect_r; reg wl_edge_detect_valid_r; reg [5:0] wl_tap_count_r; reg [5:0] fine_dec_cnt; reg [5:0] fine_inc[0:DQS_WIDTH-1]; // DQS_WIDTH number of counters 6-bit each reg [2:0] corse_dec[0:DQS_WIDTH-1]; reg [2:0] corse_inc[0:DQS_WIDTH-1]; reg dq_cnt_inc; reg [3:0] stable_cnt; reg flag_ck_negedge; //reg past_negedge; reg flag_init; reg [2:0] corse_cnt[0:DQS_WIDTH-1]; reg [3DQS_WIDTH-1:0] corse_cnt_dbg; reg [2:0] wl_corse_cnt[0:RANKS-1][0:DQS_WIDTH-1]; //reg [3DQS_WIDTH-1:0] coarse_tap_inc; reg [2:0] final_coarse_tap[0:DQS_WIDTH-1]; reg [5:0] add_smallest[0:DQS_WIDTH-1]; reg [5:0] add_largest[0:DQS_WIDTH-1]; //reg [6DQS_WIDTH-1:0] fine_tap_inc; //reg [6DQS_WIDTH-1:0] fine_tap_dec; reg wr_level_done_r1; reg wr_level_done_r2; reg wr_level_done_r3; reg wr_level_done_r4; reg wr_level_done_r5; reg [5:0] wl_dqs_tap_count_r[0:RANKS-1][0:DQS_WIDTH-1]; reg [5:0] smallest[0:DQS_WIDTH-1]; reg [5:0] largest[0:DQS_WIDTH-1]; reg [5:0] final_val[0:DQS_WIDTH-1]; reg [5:0] po_dec_cnt[0:DQS_WIDTH-1]; reg done_dqs_dec; reg [8:0] po_rdval_cnt; reg po_cnt_dec; reg po_dec_done; reg dual_rnk_dec; wire [DQS_CNT_WIDTH+2:0] dqs_count_w; reg [5:0] fast_cal_fine_cnt; reg [2:0] fast_cal_coarse_cnt; reg wrlvl_byte_redo_r; reg [2:0] wrlvl_redo_corse_inc; reg wrlvl_final_r; reg final_corse_dec; wire [DQS_CNT_WIDTH+2:0] oclk_count_w; reg wrlvl_tap_done_r ; reg [3:0] wait_cnt; reg [3:0] incdec_wait_cnt; // Debug ports assign dbg_wl_edge_detect_valid = wl_edge_detect_valid_r; assign dbg_rd_data_edge_detect = rd_data_edge_detect_r; assign dbg_wl_tap_cnt = wl_tap_count_r; assign dbg_dqs_count = dqs_count_r; assign dbg_wl_state = wl_state_r; assign dbg_wrlvl_fine_tap_cnt = wl_po_fine_cnt; assign dbg_wrlvl_coarse_tap_cnt = wl_po_coarse_cnt; always @() begin for (v = 0; v < DQS_WIDTH; v = v + 1) corse_cnt_dbg[3v+:3] = corse_cnt[v]; end assign dbg_phy_wrlvl[0+:27] = corse_cnt_dbg; assign dbg_phy_wrlvl[27+:5] = wl_state_r; assign dbg_phy_wrlvl[32+:4] = dqs_count_r; assign dbg_phy_wrlvl[36+:9] = rd_data_rise_wl_r; assign dbg_phy_wrlvl[45+:9] = rd_data_previous_r; assign dbg_phy_wrlvl[54+:4] = stable_cnt; assign dbg_phy_wrlvl[58] = 'd0; assign dbg_phy_wrlvl[59] = flag_ck_negedge; assign dbg_phy_wrlvl [60] = wl_edge_detect_valid_r; assign dbg_phy_wrlvl [61+:6] = wl_tap_count_r; assign dbg_phy_wrlvl [67+:9] = rd_data_edge_detect_r; assign dbg_phy_wrlvl [76+:54] = wl_po_fine_cnt; assign dbg_phy_wrlvl [130+:27] = wl_po_coarse_cnt; //*********************************************************************** // DQS count to hard PHY during write leveling using Phaser_OUT Stage2 delay //************************************************************************ assign po_stg2_wl_cnt = dqs_count_r; assign wrlvl_rank_done = wrlvl_rank_done_r; assign done_dqs_tap_inc = done_dqs_dec; assign phy_ctl_rdy_dly = phy_ctl_ready_r6; always @(posedge clk) begin phy_ctl_ready_r1 <= #TCQ phy_ctl_ready; phy_ctl_ready_r2 <= #TCQ phy_ctl_ready_r1; phy_ctl_ready_r3 <= #TCQ phy_ctl_ready_r2; phy_ctl_ready_r4 <= #TCQ phy_ctl_ready_r3; phy_ctl_ready_r5 <= #TCQ phy_ctl_ready_r4; phy_ctl_ready_r6 <= #TCQ phy_ctl_ready_r5; wrlvl_byte_redo_r <= #TCQ wrlvl_byte_redo; wrlvl_final_r <= #TCQ wrlvl_final; if ((wrlvl_byte_redo && ~wrlvl_byte_redo_r) \|\| (wrlvl_final && ~wrlvl_final_r)) wr_level_done <= #TCQ 1'b0; else wr_level_done <= #TCQ done_dqs_dec; end // Status signal that will be asserted once the first // pass of write leveling is done. always @(posedge clk) begin if(rst) begin wrlvl_tap_done_r <= #TCQ 1'b0 ; end else begin if(wrlvl_tap_done_r == 1'b0) begin if(oclkdelay_calib_done) begin wrlvl_tap_done_r <= #TCQ 1'b1 ; end end end end always @(posedge clk) begin if (rst \|\| po_cnt_dec) wait_cnt <= #TCQ 'd8; else if (phy_ctl_ready_r6 && (wait_cnt > 'd0)) wait_cnt <= #TCQ wait_cnt - 1; end always @(posedge clk) begin if (rst) begin po_rdval_cnt <= #TCQ 'd0; end else if (phy_ctl_ready_r5 && ~phy_ctl_ready_r6) begin po_rdval_cnt <= #TCQ po_counter_read_val; end else if (po_rdval_cnt > 'd0) begin if (po_cnt_dec) po_rdval_cnt <= #TCQ po_rdval_cnt - 1; else po_rdval_cnt <= #TCQ po_rdval_cnt; end else if (po_rdval_cnt == 'd0) begin po_rdval_cnt <= #TCQ po_rdval_cnt; end end always @(posedge clk) begin if (rst \|\| (po_rdval_cnt == 'd0)) po_cnt_dec <= #TCQ 1'b0; else if (phy_ctl_ready_r6 && (po_rdval_cnt > 'd0) && (wait_cnt == 'd1)) po_cnt_dec <= #TCQ 1'b1; else po_cnt_dec <= #TCQ 1'b0; end always @(posedge clk) begin if (rst) po_dec_done <= #TCQ 1'b0; else if (((po_cnt_dec == 'd1) && (po_rdval_cnt == 'd1)) \|\| (phy_ctl_ready_r6 && (po_rdval_cnt == 'd0))) begin po_dec_done <= #TCQ 1'b1; end end always @(posedge clk) begin dqs_po_dec_done <= #TCQ po_dec_done; wr_level_done_r1 <= #TCQ wr_level_done_r; wr_level_done_r2 <= #TCQ wr_level_done_r1; wr_level_done_r3 <= #TCQ wr_level_done_r2; wr_level_done_r4 <= #TCQ wr_level_done_r3; wr_level_done_r5 <= #TCQ wr_level_done_r4; for (l = 0; l < DQS_WIDTH; l = l + 1) begin wl_po_coarse_cnt[3l+:3] <= #TCQ final_coarse_tap[l]; if ((RANKS == 1) \|\| ~oclkdelay_calib_done) wl_po_fine_cnt[6l+:6] <= #TCQ smallest[l]; else wl_po_fine_cnt[6l+:6] <= #TCQ final_val[l]; end end generate if (RANKS == 2) begin: dual_rank always @(posedge clk) begin if (rst \|\| (wrlvl_byte_redo && ~wrlvl_byte_redo_r) \|\| (wrlvl_final && ~wrlvl_final_r)) done_dqs_dec <= #TCQ 1'b0; else if ((SIM_CAL_OPTION == "FAST_CAL") \|\| ~oclkdelay_calib_done) done_dqs_dec <= #TCQ wr_level_done_r; else if (wr_level_done_r5 && (wl_state_r == WL_IDLE)) done_dqs_dec <= #TCQ 1'b1; end end else begin: single_rank always @(posedge clk) begin if (rst \|\| (wrlvl_byte_redo && ~wrlvl_byte_redo_r) \|\| (wrlvl_final && ~wrlvl_final_r)) done_dqs_dec <= #TCQ 1'b0; else if (~oclkdelay_calib_done) done_dqs_dec <= #TCQ wr_level_done_r; else if (wr_level_done_r3 && ~wr_level_done_r4) done_dqs_dec <= #TCQ 1'b1; end end endgenerate always @(posedge clk) if (rst \|\| (wrlvl_byte_redo && ~wrlvl_byte_redo_r)) wrlvl_byte_done <= #TCQ 1'b0; else if (wrlvl_byte_redo && wr_level_done_r3 && ~wr_level_done_r4) wrlvl_byte_done <= #TCQ 1'b1; // Storing DQS tap values at the end of each DQS write leveling always @(posedge clk) begin if (rst) begin for (k = 0; k < RANKS; k = k + 1) begin: rst_wl_dqs_tap_count_loop for (n = 0; n < DQS_WIDTH; n = n + 1) begin wl_corse_cnt[k][n] <= #TCQ 'b0; wl_dqs_tap_count_r[k][n] <= #TCQ 'b0; end end end else if ((wl_state_r == WL_DQS_CNT) \| (wl_state_r == WL_WAIT) \| (wl_state_r == WL_FINE_DEC_WAIT1) \| (wl_state_r == WL_2RANK_TAP_DEC)) begin wl_dqs_tap_count_r[rank_cnt_r][dqs_count_r] <= #TCQ wl_tap_count_r; wl_corse_cnt[rank_cnt_r][dqs_count_r] <= #TCQ corse_cnt[dqs_count_r]; end else if ((SIM_CAL_OPTION == "FAST_CAL") & (wl_state_r == WL_DQS_CHECK)) begin for (p = 0; p < RANKS; p = p +1) begin: dqs_tap_rank_cnt for(q = 0; q < DQS_WIDTH; q = q +1) begin: dqs_tap_dqs_cnt wl_dqs_tap_count_r[p][q] <= #TCQ wl_tap_count_r; wl_corse_cnt[p][q] <= #TCQ corse_cnt[0]; end end end end // Convert coarse delay to fine taps in case of unequal number of coarse // taps between ranks. Assuming a difference of 1 coarse tap counts // between ranks. A common fine and coarse tap value must be used for both ranks // because Phaser_Out has only one rank register. // Coarse tap1 = period(ps)93/360 = 34 fine taps // Other coarse taps = period(ps)103/360 = 38 fine taps generate genvar cnt; if (RANKS == 2) begin // Dual rank for(cnt = 0; cnt < DQS_WIDTH; cnt = cnt +1) begin: coarse_dqs_cnt always @(posedge clk) begin if (rst) begin //coarse_tap_inc[3cnt+:3] <= #TCQ 'b0; add_smallest[cnt] <= #TCQ 'd0; add_largest[cnt] <= #TCQ 'd0; final_coarse_tap[cnt] <= #TCQ 'd0; end else if (wr_level_done_r1 & ~wr_level_done_r2) begin if (~oclkdelay_calib_done) begin for(y = 0 ; y < DQS_WIDTH; y = y+1) begin final_coarse_tap[y] <= #TCQ wl_corse_cnt[0][y]; add_smallest[y] <= #TCQ 'd0; add_largest[y] <= #TCQ 'd0; end end else if (wl_corse_cnt[0][cnt] == wl_corse_cnt[1][cnt]) begin // Both ranks have use the same number of coarse delay taps. // No conversion of coarse tap to fine taps required. //coarse_tap_inc[3cnt+:3] <= #TCQ wl_corse_cnt[1][3cnt+:3]; final_coarse_tap[cnt] <= #TCQ wl_corse_cnt[1][cnt]; add_smallest[cnt] <= #TCQ 'd0; add_largest[cnt] <= #TCQ 'd0; end else if (wl_corse_cnt[0][cnt] < wl_corse_cnt[1][cnt]) begin // Rank 0 uses fewer coarse delay taps than rank1. // conversion of coarse tap to fine taps required for rank1. // The final coarse count will the smaller value. //coarse_tap_inc[3cnt+:3] <= #TCQ wl_corse_cnt[1][3cnt+:3] - 1; final_coarse_tap[cnt] <= #TCQ wl_corse_cnt[1][cnt] - 1; if (\|wl_corse_cnt[0][cnt]) // Coarse tap 2 or higher being converted to fine taps // This will be added to 'largest' value in final_val // computation add_largest[cnt] <= #TCQ 'd38; else // Coarse tap 1 being converted to fine taps // This will be added to 'largest' value in final_val // computation add_largest[cnt] <= #TCQ 'd34; end else if (wl_corse_cnt[0][cnt] > wl_corse_cnt[1][cnt]) begin // This may be an unlikely scenario in a real system. // Rank 0 uses more coarse delay taps than rank1. // conversion of coarse tap to fine taps required. //coarse_tap_inc[3cnt+:3] <= #TCQ 'd0; final_coarse_tap[cnt] <= #TCQ wl_corse_cnt[1][cnt]; if (\|wl_corse_cnt[1][cnt]) // Coarse tap 2 or higher being converted to fine taps // This will be added to 'smallest' value in final_val // computation add_smallest[cnt] <= #TCQ 'd38; else // Coarse tap 1 being converted to fine taps // This will be added to 'smallest' value in // final_val computation add_smallest[cnt] <= #TCQ 'd34; end end end end end else begin // Single rank always @(posedge clk) begin //coarse_tap_inc <= #TCQ 'd0; for(w = 0; w < DQS_WIDTH; w = w + 1) begin final_coarse_tap[w] <= #TCQ wl_corse_cnt[0][w]; add_smallest[w] <= #TCQ 'd0; add_largest[w] <= #TCQ 'd0; end end end endgenerate // Determine delay value for DQS in multirank system // Assuming delay value is the smallest for rank 0 DQS // and largest delay value for rank 4 DQS // Set to smallest + ((largest-smallest)/2) always @(posedge clk) begin if (rst) begin for(x = 0; x < DQS_WIDTH; x = x +1) begin smallest[x] <= #TCQ 'b0; largest[x] <= #TCQ 'b0; end end else if ((wl_state_r == WL_DQS_CNT) & wrlvl_byte_redo) begin smallest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[0][dqs_count_r]; largest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[0][dqs_count_r]; end else if ((wl_state_r == WL_DQS_CNT) \| (wl_state_r == WL_2RANK_TAP_DEC)) begin smallest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[0][dqs_count_r]; largest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[RANKS-1][dqs_count_r]; end else if (((SIM_CAL_OPTION == "FAST_CAL") \| (~oclkdelay_calib_done & ~wrlvl_byte_redo)) & wr_level_done_r1 & ~wr_level_done_r2) begin for(i = 0; i < DQS_WIDTH; i = i +1) begin: smallest_dqs smallest[i] <= #TCQ wl_dqs_tap_count_r[0][i]; largest[i] <= #TCQ wl_dqs_tap_count_r[0][i]; end end end // final_val to be used for all DQSs in all ranks genvar wr_i; generate for (wr_i = 0; wr_i < DQS_WIDTH; wr_i = wr_i +1) begin: gen_final_tap always @(posedge clk) begin if (rst) final_val[wr_i] <= #TCQ 'b0; else if (wr_level_done_r2 && ~wr_level_done_r3) begin if (~oclkdelay_calib_done) final_val[wr_i] <= #TCQ (smallest[wr_i] + add_smallest[wr_i]); else if ((smallest[wr_i] + add_smallest[wr_i]) < (largest[wr_i] + add_largest[wr_i])) final_val[wr_i] <= #TCQ ((smallest[wr_i] + add_smallest[wr_i]) + (((largest[wr_i] + add_largest[wr_i]) - (smallest[wr_i] + add_smallest[wr_i]))/2)); else if ((smallest[wr_i] + add_smallest[wr_i]) > (largest[wr_i] + add_largest[wr_i])) final_val[wr_i] <= #TCQ ((largest[wr_i] + add_largest[wr_i]) + (((smallest[wr_i] + add_smallest[wr_i]) - (largest[wr_i] + add_largest[wr_i]))/2)); else if ((smallest[wr_i] + add_smallest[wr_i]) == (largest[wr_i] + add_largest[wr_i])) final_val[wr_i] <= #TCQ (largest[wr_i] + add_largest[wr_i]); end end end endgenerate // // fine tap inc/dec value for all DQSs in all ranks // genvar dqs_i; // generate // for (dqs_i = 0; dqs_i < DQS_WIDTH; dqs_i = dqs_i +1) begin: gen_fine_tap // always @(posedge clk) begin // if (rst) // fine_tap_inc[6dqs_i+:6] <= #TCQ 'd0; // //fine_tap_dec[6dqs_i+:6] <= #TCQ 'd0; // else if (wr_level_done_r3 && ~wr_level_done_r4) begin // fine_tap_inc[6dqs_i+:6] <= #TCQ final_val[6dqs_i+:6]; // //fine_tap_dec[6dqs_i+:6] <= #TCQ 'd0; // end // end // endgenerate // Inc/Dec Phaser_Out stage 2 fine delay line always @(posedge clk) begin if (rst) begin // Fine delay line used only during write leveling dqs_po_stg2_f_incdec <= #TCQ 1'b0; dqs_po_en_stg2_f <= #TCQ 1'b0; // Dec Phaser_Out fine delay (1)before write leveling, // (2)if no 0 to 1 transition detected with 63 fine delay taps, or // (3)dual rank case where fine taps for the first rank need to be 0 end else if (po_cnt_dec \|\| (wl_state_r == WL_INIT_FINE_DEC) \|\| (wl_state_r == WL_FINE_DEC)) begin dqs_po_stg2_f_incdec <= #TCQ 1'b0; dqs_po_en_stg2_f <= #TCQ 1'b1; // Inc Phaser_Out fine delay during write leveling end else if ((wl_state_r == WL_INIT_FINE_INC) \|\| (wl_state_r == WL_FINE_INC)) begin dqs_po_stg2_f_incdec <= #TCQ 1'b1; dqs_po_en_stg2_f <= #TCQ 1'b1; end else begin dqs_po_stg2_f_incdec <= #TCQ 1'b0; dqs_po_en_stg2_f <= #TCQ 1'b0; end end // Inc Phaser_Out stage 2 Coarse delay line always @(posedge clk) begin if (rst) begin // Coarse delay line used during write leveling // only if no 0->1 transition undetected with 64 // fine delay line taps dqs_wl_po_stg2_c_incdec <= #TCQ 1'b0; dqs_wl_po_en_stg2_c <= #TCQ 1'b0; end else if (wl_state_r == WL_CORSE_INC) begin // Inc Phaser_Out coarse delay during write leveling dqs_wl_po_stg2_c_incdec <= #TCQ 1'b1; dqs_wl_po_en_stg2_c <= #TCQ 1'b1; end else begin dqs_wl_po_stg2_c_incdec <= #TCQ 1'b0; dqs_wl_po_en_stg2_c <= #TCQ 1'b0; end end // only storing the rise data for checking. The data comming back during // write leveling will be a static value. Just checking for rise data is // enough. genvar rd_i; generate for(rd_i = 0; rd_i < DQS_WIDTH; rd_i = rd_i +1)begin: gen_rd always @(posedge clk) rd_data_rise_wl_r[rd_i] <= #TCQ \|rd_data_rise0[(rd_iDRAM_WIDTH)+DRAM_WIDTH-1:rd_iDRAM_WIDTH]; end endgenerate // storing the previous data for checking later. always @(posedge clk)begin if ((wl_state_r == WL_INIT) \|\| //(wl_state_r == WL_INIT_FINE_INC_WAIT) \|\| //(wl_state_r == WL_INIT_FINE_INC_WAIT1) \|\| ((wl_state_r1 == WL_INIT_FINE_INC_WAIT) & (wl_state_r == WL_INIT_FINE_INC)) \|\| (wl_state_r == WL_FINE_DEC) \|\| (wl_state_r == WL_FINE_DEC_WAIT1) \|\| (wl_state_r == WL_FINE_DEC_WAIT) \|\| (wl_state_r == WL_CORSE_INC) \|\| (wl_state_r == WL_CORSE_INC_WAIT) \|\| (wl_state_r == WL_CORSE_INC_WAIT_TMP) \|\| (wl_state_r == WL_CORSE_INC_WAIT1) \|\| (wl_state_r == WL_CORSE_INC_WAIT2) \|\| ((wl_state_r == WL_EDGE_CHECK) & (wl_edge_detect_valid_r))) rd_data_previous_r <= #TCQ rd_data_rise_wl_r; end // changed stable count from 3 to 7 because of fine tap resolution always @(posedge clk)begin if (rst \| (wl_state_r == WL_DQS_CNT) \| (wl_state_r == WL_2RANK_TAP_DEC) \| (wl_state_r == WL_FINE_DEC) \| (rd_data_previous_r[dqs_count_r] != rd_data_rise_wl_r[dqs_count_r]) \| (wl_state_r1 == WL_INIT_FINE_DEC)) stable_cnt <= #TCQ 'd0; else if ((wl_tap_count_r > 6'd0) & (((wl_state_r == WL_EDGE_CHECK) & (wl_edge_detect_valid_r)) \| ((wl_state_r1 == WL_INIT_FINE_INC_WAIT) & (wl_state_r == WL_INIT_FINE_INC)))) begin if ((rd_data_previous_r[dqs_count_r] == rd_data_rise_wl_r[dqs_count_r]) & (stable_cnt < 'd14)) stable_cnt <= #TCQ stable_cnt + 1; end end // Signal to ensure that flag_ck_negedge does not incorrectly assert // when DQS is very close to CK rising edge //always @(posedge clk) begin // if (rst \| (wl_state_r == WL_DQS_CNT) \| // (wl_state_r == WL_DQS_CHECK) \| wr_level_done_r) // past_negedge <= #TCQ 1'b0; // else if (~flag_ck_negedge && ~rd_data_previous_r[dqs_count_r] && // (stable_cnt == 'd0) && ((wl_state_r == WL_CORSE_INC_WAIT1) \| // (wl_state_r == WL_CORSE_INC_WAIT2))) // past_negedge <= #TCQ 1'b1; //end // Flag to indicate negedge of CK detected and ignore 0->1 transitions // in this region always @(posedge clk)begin if (rst \| (wl_state_r == WL_DQS_CNT) \| (wl_state_r == WL_DQS_CHECK) \| wr_level_done_r \| (wl_state_r1 == WL_INIT_FINE_DEC)) flag_ck_negedge <= #TCQ 1'd0; else if ((rd_data_previous_r[dqs_count_r] && ((stable_cnt > 'd0) \| (wl_state_r == WL_FINE_DEC) \| (wl_state_r == WL_FINE_DEC_WAIT) \| (wl_state_r == WL_FINE_DEC_WAIT1))) \| (wl_state_r == WL_CORSE_INC)) flag_ck_negedge <= #TCQ 1'd1; else if (~rd_data_previous_r[dqs_count_r] && (stable_cnt == 'd14)) //&& flag_ck_negedge) flag_ck_negedge <= #TCQ 1'd0; end // Flag to inhibit rd_data_edge_detect_r before stable DQ always @(posedge clk) begin if (rst) flag_init <= #TCQ 1'b1; else if ((wl_state_r == WL_WAIT) && ((wl_state_r1 == WL_INIT_FINE_INC_WAIT) \|\| (wl_state_r1 == WL_INIT_FINE_DEC_WAIT))) flag_init <= #TCQ 1'b0; end //checking for transition from 0 to 1 always @(posedge clk)begin if (rst \| flag_ck_negedge \| flag_init \| (wl_tap_count_r < 'd1) \| inhibit_edge_detect_r) rd_data_edge_detect_r <= #TCQ {DQS_WIDTH{1'b0}}; else if (rd_data_edge_detect_r[dqs_count_r] == 1'b1) begin if ((wl_state_r == WL_FINE_DEC) \|\| (wl_state_r == WL_FINE_DEC_WAIT) \|\| (wl_state_r == WL_FINE_DEC_WAIT1) \|\| (wl_state_r == WL_CORSE_INC) \|\| (wl_state_r == WL_CORSE_INC_WAIT) \|\| (wl_state_r == WL_CORSE_INC_WAIT_TMP) \|\| (wl_state_r == WL_CORSE_INC_WAIT1) \|\| (wl_state_r == WL_CORSE_INC_WAIT2)) rd_data_edge_detect_r <= #TCQ {DQS_WIDTH{1'b0}}; else rd_data_edge_detect_r <= #TCQ rd_data_edge_detect_r; end else if (rd_data_previous_r[dqs_count_r] && (stable_cnt < 'd14)) rd_data_edge_detect_r <= #TCQ {DQS_WIDTH{1'b0}}; else rd_data_edge_detect_r <= #TCQ (~rd_data_previous_r & rd_data_rise_wl_r); end // registring the write level start signal always@(posedge clk) begin wr_level_start_r <= #TCQ wr_level_start; end // Assign dqs_count_r to dqs_count_w to perform the shift operation // instead of multiply operation assign dqs_count_w = {2'b00, dqs_count_r}; assign oclk_count_w = {2'b00, oclkdelay_calib_cnt}; always @(posedge clk) begin if (rst) incdec_wait_cnt <= #TCQ 'd0; else if ((wl_state_r == WL_FINE_DEC_WAIT1) \|\| (wl_state_r == WL_INIT_FINE_DEC_WAIT1) \|\| (wl_state_r == WL_CORSE_INC_WAIT_TMP)) incdec_wait_cnt <= #TCQ incdec_wait_cnt + 1; else incdec_wait_cnt <= #TCQ 'd0; end // state machine to initiate the write leveling sequence // The state machine operates on one byte at a time. // It will increment the delays to the DQS OSERDES // and sample the DQ from the memory. When it detects // a transition from 1 to 0 then the write leveling is considered // done. always @(posedge clk) begin if(rst)begin wrlvl_err <= #TCQ 1'b0; wr_level_done_r <= #TCQ 1'b0; wrlvl_rank_done_r <= #TCQ 1'b0; dqs_count_r <= #TCQ {DQS_CNT_WIDTH+1{1'b0}}; dq_cnt_inc <= #TCQ 1'b1; rank_cnt_r <= #TCQ 2'b00; wl_state_r <= #TCQ WL_IDLE; wl_state_r1 <= #TCQ WL_IDLE; inhibit_edge_detect_r <= #TCQ 1'b1; wl_edge_detect_valid_r <= #TCQ 1'b0; wl_tap_count_r <= #TCQ 6'd0; fine_dec_cnt <= #TCQ 6'd0; for (r = 0; r < DQS_WIDTH; r = r + 1) begin fine_inc[r] <= #TCQ 6'b0; corse_dec[r] <= #TCQ 3'b0; corse_inc[r] <= #TCQ 3'b0; corse_cnt[r] <= #TCQ 3'b0; end dual_rnk_dec <= #TCQ 1'b0; fast_cal_fine_cnt <= #TCQ FAST_CAL_FINE; fast_cal_coarse_cnt <= #TCQ FAST_CAL_COARSE; final_corse_dec <= #TCQ 1'b0; //zero_tran_r <= #TCQ 1'b0; wrlvl_redo_corse_inc <= #TCQ 'd0; end else begin wl_state_r1 <= #TCQ wl_state_r; case (wl_state_r) WL_IDLE: begin wrlvl_rank_done_r <= #TCQ 1'd0; inhibit_edge_detect_r <= #TCQ 1'b1; if (wrlvl_byte_redo && ~wrlvl_byte_redo_r) begin wr_level_done_r <= #TCQ 1'b0; dqs_count_r <= #TCQ wrcal_cnt; corse_cnt[wrcal_cnt] <= #TCQ final_coarse_tap[wrcal_cnt]; wl_tap_count_r <= #TCQ smallest[wrcal_cnt]; if (early1_data && (((final_coarse_tap[wrcal_cnt] < 'd6) && (CLK_PERIOD/nCK_PER_CLK <= 2500)) \|\| ((final_coarse_tap[wrcal_cnt] < 'd3) && (CLK_PERIOD/nCK_PER_CLK > 2500)))) wrlvl_redo_corse_inc <= #TCQ REDO_COARSE; else if (early2_data && (final_coarse_tap[wrcal_cnt] < 'd2)) wrlvl_redo_corse_inc <= #TCQ 3'd6; else begin wl_state_r <= #TCQ WL_IDLE; wrlvl_err <= #TCQ 1'b1; end end else if (wrlvl_final && ~wrlvl_final_r) begin wr_level_done_r <= #TCQ 1'b0; dqs_count_r <= #TCQ 'd0; end // verilint STARC-2.2.3.3 off if(!wr_level_done_r & wr_level_start_r & wl_sm_start) begin if (SIM_CAL_OPTION == "FAST_CAL") wl_state_r <= #TCQ WL_FINE_INC; else wl_state_r <= #TCQ WL_INIT; end end // verilint STARC-2.2.3.3 on WL_INIT: begin wl_edge_detect_valid_r <= #TCQ 1'b0; inhibit_edge_detect_r <= #TCQ 1'b1; wrlvl_rank_done_r <= #TCQ 1'd0; //zero_tran_r <= #TCQ 1'b0; if (wrlvl_final) corse_cnt[dqs_count_w ] <= #TCQ final_coarse_tap[dqs_count_w ]; if (wrlvl_byte_redo) begin if (\|wl_tap_count_r) begin wl_state_r <= #TCQ WL_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; end else if ((corse_cnt[dqs_count_w] + wrlvl_redo_corse_inc) <= 'd7) wl_state_r <= #TCQ WL_CORSE_INC; else begin wl_state_r <= #TCQ WL_IDLE; wrlvl_err <= #TCQ 1'b1; end end else if(wl_sm_start) wl_state_r <= #TCQ WL_INIT_FINE_INC; end // Initially Phaser_Out fine delay taps incremented // until stable_cnt=14. A stable_cnt of 14 indicates // that rd_data_rise_wl_r=rd_data_previous_r for 14 fine // tap increments. This is done to inhibit false 0->1 // edge detection when DQS is initially aligned to the // negedge of CK WL_INIT_FINE_INC: begin wl_state_r <= #TCQ WL_INIT_FINE_INC_WAIT1; wl_tap_count_r <= #TCQ wl_tap_count_r + 1'b1; final_corse_dec <= #TCQ 1'b0; end WL_INIT_FINE_INC_WAIT1: begin if (wl_sm_start) wl_state_r <= #TCQ WL_INIT_FINE_INC_WAIT; end // Case1: stable value of rd_data_previous_r=0 then // proceed to 0->1 edge detection. // Case2: stable value of rd_data_previous_r=1 then // decrement fine taps to '0' and proceed to 0->1 // edge detection. Need to decrement in this case to // make sure a valid 0->1 transition was not left // undetected. WL_INIT_FINE_INC_WAIT: begin if (wl_sm_start) begin if (stable_cnt < 'd14) wl_state_r <= #TCQ WL_INIT_FINE_INC; else if (~rd_data_previous_r[dqs_count_r]) begin wl_state_r <= #TCQ WL_WAIT; inhibit_edge_detect_r <= #TCQ 1'b0; end else begin wl_state_r <= #TCQ WL_INIT_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; end end end // Case2: stable value of rd_data_previous_r=1 then // decrement fine taps to '0' and proceed to 0->1 // edge detection. Need to decrement in this case to // make sure a valid 0->1 transition was not left // undetected. WL_INIT_FINE_DEC: begin wl_tap_count_r <= #TCQ 'd0; wl_state_r <= #TCQ WL_INIT_FINE_DEC_WAIT1; if (fine_dec_cnt > 6'd0) fine_dec_cnt <= #TCQ fine_dec_cnt - 1; else fine_dec_cnt <= #TCQ fine_dec_cnt; end WL_INIT_FINE_DEC_WAIT1: begin if (incdec_wait_cnt == 'd8) wl_state_r <= #TCQ WL_INIT_FINE_DEC_WAIT; end WL_INIT_FINE_DEC_WAIT: begin if (fine_dec_cnt > 6'd0) begin wl_state_r <= #TCQ WL_INIT_FINE_DEC; inhibit_edge_detect_r <= #TCQ 1'b1; end else begin wl_state_r <= #TCQ WL_WAIT; inhibit_edge_detect_r <= #TCQ 1'b0; end end // Inc DQS Phaser_Out Stage2 Fine Delay line WL_FINE_INC: begin wl_edge_detect_valid_r <= #TCQ 1'b0; if (SIM_CAL_OPTION == "FAST_CAL") begin wl_state_r <= #TCQ WL_FINE_INC_WAIT; if (fast_cal_fine_cnt > 'd0) fast_cal_fine_cnt <= #TCQ fast_cal_fine_cnt - 1; else fast_cal_fine_cnt <= #TCQ fast_cal_fine_cnt; end else if (wr_level_done_r5) begin wl_tap_count_r <= #TCQ 'd0; wl_state_r <= #TCQ WL_FINE_INC_WAIT; if (\|fine_inc[dqs_count_w]) fine_inc[dqs_count_w] <= #TCQ fine_inc[dqs_count_w] - 1; end else begin wl_state_r <= #TCQ WL_WAIT; wl_tap_count_r <= #TCQ wl_tap_count_r + 1'b1; end end WL_FINE_INC_WAIT: begin if (SIM_CAL_OPTION == "FAST_CAL") begin if (fast_cal_fine_cnt > 'd0) wl_state_r <= #TCQ WL_FINE_INC; else if (fast_cal_coarse_cnt > 'd0) wl_state_r <= #TCQ WL_CORSE_INC; else wl_state_r <= #TCQ WL_DQS_CNT; end else if (\|fine_inc[dqs_count_w]) wl_state_r <= #TCQ WL_FINE_INC; else if (dqs_count_r == (DQS_WIDTH-1)) wl_state_r <= #TCQ WL_IDLE; else begin wl_state_r <= #TCQ WL_2RANK_FINAL_TAP; dqs_count_r <= #TCQ dqs_count_r + 1; end end WL_FINE_DEC: begin wl_edge_detect_valid_r <= #TCQ 1'b0; wl_tap_count_r <= #TCQ 'd0; wl_state_r <= #TCQ WL_FINE_DEC_WAIT1; if (fine_dec_cnt > 6'd0) fine_dec_cnt <= #TCQ fine_dec_cnt - 1; else fine_dec_cnt <= #TCQ fine_dec_cnt; end WL_FINE_DEC_WAIT1: begin if (incdec_wait_cnt == 'd8) wl_state_r <= #TCQ WL_FINE_DEC_WAIT; end WL_FINE_DEC_WAIT: begin if (fine_dec_cnt > 6'd0) wl_state_r <= #TCQ WL_FINE_DEC; //else if (zero_tran_r) // wl_state_r <= #TCQ WL_DQS_CNT; else if (dual_rnk_dec) begin if (\|corse_dec[dqs_count_r]) wl_state_r <= #TCQ WL_CORSE_DEC; else wl_state_r <= #TCQ WL_2RANK_DQS_CNT; end else if (wrlvl_byte_redo) begin if ((corse_cnt[dqs_count_w] + wrlvl_redo_corse_inc) <= 'd7) wl_state_r <= #TCQ WL_CORSE_INC; else begin wl_state_r <= #TCQ WL_IDLE; wrlvl_err <= #TCQ 1'b1; end end else wl_state_r <= #TCQ WL_CORSE_INC; end WL_CORSE_DEC: begin wl_state_r <= #TCQ WL_CORSE_DEC_WAIT; dual_rnk_dec <= #TCQ 1'b0; if (\|corse_dec[dqs_count_r]) corse_dec[dqs_count_r] <= #TCQ corse_dec[dqs_count_r] - 1; else corse_dec[dqs_count_r] <= #TCQ corse_dec[dqs_count_r]; end WL_CORSE_DEC_WAIT: begin if (wl_sm_start) begin //if (\|corse_dec[dqs_count_r]) // wl_state_r <= #TCQ WL_CORSE_DEC; if (\|corse_dec[dqs_count_r]) wl_state_r <= #TCQ WL_CORSE_DEC_WAIT1; else wl_state_r <= #TCQ WL_2RANK_DQS_CNT; end end WL_CORSE_DEC_WAIT1: begin if (wl_sm_start) wl_state_r <= #TCQ WL_CORSE_DEC; end WL_CORSE_INC: begin wl_state_r <= #TCQ WL_CORSE_INC_WAIT_TMP; if (SIM_CAL_OPTION == "FAST_CAL") begin if (fast_cal_coarse_cnt > 'd0) fast_cal_coarse_cnt <= #TCQ fast_cal_coarse_cnt - 1; else fast_cal_coarse_cnt <= #TCQ fast_cal_coarse_cnt; end else if (wrlvl_byte_redo) begin corse_cnt[dqs_count_w] <= #TCQ corse_cnt[dqs_count_w] + 1; if (\|wrlvl_redo_corse_inc) wrlvl_redo_corse_inc <= #TCQ wrlvl_redo_corse_inc - 1; end else if (~wr_level_done_r5) corse_cnt[dqs_count_r] <= #TCQ corse_cnt[dqs_count_r] + 1; else if (\|corse_inc[dqs_count_w]) corse_inc[dqs_count_w] <= #TCQ corse_inc[dqs_count_w] - 1; end WL_CORSE_INC_WAIT_TMP: begin if (incdec_wait_cnt == 'd8) wl_state_r <= #TCQ WL_CORSE_INC_WAIT; end WL_CORSE_INC_WAIT: begin if (SIM_CAL_OPTION == "FAST_CAL") begin if (fast_cal_coarse_cnt > 'd0) wl_state_r <= #TCQ WL_CORSE_INC; else wl_state_r <= #TCQ WL_DQS_CNT; end else if (wrlvl_byte_redo) begin if (\|wrlvl_redo_corse_inc) wl_state_r <= #TCQ WL_CORSE_INC; else begin wl_state_r <= #TCQ WL_INIT_FINE_INC; inhibit_edge_detect_r <= #TCQ 1'b1; end end else if (~wr_level_done_r5 && wl_sm_start) wl_state_r <= #TCQ WL_CORSE_INC_WAIT1; else if (wr_level_done_r5) begin if (\|corse_inc[dqs_count_r]) wl_state_r <= #TCQ WL_CORSE_INC; else if (\|fine_inc[dqs_count_w]) wl_state_r <= #TCQ WL_FINE_INC; else if (dqs_count_r == (DQS_WIDTH-1)) wl_state_r <= #TCQ WL_IDLE; else begin wl_state_r <= #TCQ WL_2RANK_FINAL_TAP; dqs_count_r <= #TCQ dqs_count_r + 1; end end end WL_CORSE_INC_WAIT1: begin if (wl_sm_start) wl_state_r <= #TCQ WL_CORSE_INC_WAIT2; end WL_CORSE_INC_WAIT2: begin if (wl_sm_start) wl_state_r <= #TCQ WL_WAIT; end WL_WAIT: begin if (wl_sm_start) wl_state_r <= #TCQ WL_EDGE_CHECK; end WL_EDGE_CHECK: begin // Look for the edge if (wl_edge_detect_valid_r == 1'b0) begin wl_state_r <= #TCQ WL_WAIT; wl_edge_detect_valid_r <= #TCQ 1'b1; end // 0->1 transition detected with DQS else if(rd_data_edge_detect_r[dqs_count_r] && wl_edge_detect_valid_r) begin wl_tap_count_r <= #TCQ wl_tap_count_r; if ((SIM_CAL_OPTION == "FAST_CAL") \|\| (RANKS < 2) \|\| ~oclkdelay_calib_done) wl_state_r <= #TCQ WL_DQS_CNT; else wl_state_r <= #TCQ WL_2RANK_TAP_DEC; end // For initial writes check only upto 56 taps. Reserving the // remaining taps for OCLK calibration. else if((~wrlvl_tap_done_r) && (wl_tap_count_r > 6'd55)) begin if (corse_cnt[dqs_count_r] < COARSE_TAPS) begin wl_state_r <= #TCQ WL_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; end else begin wrlvl_err <= #TCQ 1'b1; wl_state_r <= #TCQ WL_IDLE; end end else begin if (wl_tap_count_r < 6'd56) //for reuse wrlvl for complex ocal wl_state_r <= #TCQ WL_FINE_INC; else if (corse_cnt[dqs_count_r] < COARSE_TAPS) begin wl_state_r <= #TCQ WL_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; end else begin wrlvl_err <= #TCQ 1'b1; wl_state_r <= #TCQ WL_IDLE; end end end WL_2RANK_TAP_DEC: begin wl_state_r <= #TCQ WL_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; for (m = 0; m < DQS_WIDTH; m = m + 1) corse_dec[m] <= #TCQ corse_cnt[m]; wl_edge_detect_valid_r <= #TCQ 1'b0; dual_rnk_dec <= #TCQ 1'b1; end WL_DQS_CNT: begin if ((SIM_CAL_OPTION == "FAST_CAL") \|\| (dqs_count_r == (DQS_WIDTH-1)) \|\| wrlvl_byte_redo) begin dqs_count_r <= #TCQ dqs_count_r; dq_cnt_inc <= #TCQ 1'b0; end else begin dqs_count_r <= #TCQ dqs_count_r + 1'b1; dq_cnt_inc <= #TCQ 1'b1; end wl_state_r <= #TCQ WL_DQS_CHECK; wl_edge_detect_valid_r <= #TCQ 1'b0; end WL_2RANK_DQS_CNT: begin if ((SIM_CAL_OPTION == "FAST_CAL") \|\| (dqs_count_r == (DQS_WIDTH-1))) begin dqs_count_r <= #TCQ dqs_count_r; dq_cnt_inc <= #TCQ 1'b0; end else begin dqs_count_r <= #TCQ dqs_count_r + 1'b1; dq_cnt_inc <= #TCQ 1'b1; end wl_state_r <= #TCQ WL_DQS_CHECK; wl_edge_detect_valid_r <= #TCQ 1'b0; dual_rnk_dec <= #TCQ 1'b0; end WL_DQS_CHECK: begin // check if all DQS have been calibrated wl_tap_count_r <= #TCQ 'd0; if (dq_cnt_inc == 1'b0)begin wrlvl_rank_done_r <= #TCQ 1'd1; for (t = 0; t < DQS_WIDTH; t = t + 1) corse_cnt[t] <= #TCQ 3'b0; if ((SIM_CAL_OPTION == "FAST_CAL") \|\| (RANKS < 2) \|\| ~oclkdelay_calib_done) begin wl_state_r <= #TCQ WL_IDLE; if (wrlvl_byte_redo) dqs_count_r <= #TCQ dqs_count_r; else dqs_count_r <= #TCQ 'd0; end else if (rank_cnt_r == RANKS-1) begin dqs_count_r <= #TCQ dqs_count_r; if (RANKS > 1) wl_state_r <= #TCQ WL_2RANK_FINAL_TAP; else wl_state_r <= #TCQ WL_IDLE; end else begin wl_state_r <= #TCQ WL_INIT; dqs_count_r <= #TCQ 'd0; end if ((SIM_CAL_OPTION == "FAST_CAL") \|\| (rank_cnt_r == RANKS-1)) begin wr_level_done_r <= #TCQ 1'd1; rank_cnt_r <= #TCQ 2'b00; end else begin wr_level_done_r <= #TCQ 1'd0; rank_cnt_r <= #TCQ rank_cnt_r + 1'b1; end end else wl_state_r <= #TCQ WL_INIT; end WL_2RANK_FINAL_TAP: begin if (wr_level_done_r4 && ~wr_level_done_r5) begin for(u = 0; u < DQS_WIDTH; u = u + 1) begin corse_inc[u] <= #TCQ final_coarse_tap[u]; fine_inc[u] <= #TCQ final_val[u]; end dqs_count_r <= #TCQ 'd0; end else if (wr_level_done_r5) begin if (\|corse_inc[dqs_count_r]) wl_state_r <= #TCQ WL_CORSE_INC; else if (\|fine_inc[dqs_count_w]) wl_state_r <= #TCQ WL_FINE_INC; end end endcase end end // always @ (posedge clk) endmodule
module mig_7series_v2_3_ecc_dec_fix #( parameter TCQ = 100, parameter PAYLOAD_WIDTH = 64, parameter CODE_WIDTH = 72, parameter DATA_WIDTH = 64, parameter DQ_WIDTH = 72, parameter ECC_WIDTH = 8, parameter nCK_PER_CLK = 4 ) ( /AUTOARG/ // Outputs rd_data, ecc_single, ecc_multiple, // Inputs clk, rst, h_rows, phy_rddata, correct_en, ecc_status_valid ); input clk; input rst; // Compute syndromes. input [CODE_WIDTHECC_WIDTH-1:0] h_rows; input [2nCK_PER_CLKDQ_WIDTH-1:0] phy_rddata; wire [2nCK_PER_CLKECC_WIDTH-1:0] syndrome_ns; genvar k; genvar m; generate for (k=0; k<2nCK_PER_CLK; k=k+1) begin : ecc_word for (m=0; m<ECC_WIDTH; m=m+1) begin : ecc_bit assign syndrome_ns[kECC_WIDTH+m] = ^(phy_rddata[kDQ_WIDTH+:CODE_WIDTH] & h_rows[mCODE_WIDTH+:CODE_WIDTH]); end end endgenerate reg [2nCK_PER_CLKECC_WIDTH-1:0] syndrome_r; always @(posedge clk) syndrome_r <= #TCQ syndrome_ns; // Extract payload bits from raw DRAM bits and register. wire [2nCK_PER_CLKPAYLOAD_WIDTH-1:0] ecc_rddata_ns; genvar i; generate for (i=0; i<2nCK_PER_CLK; i=i+1) begin : extract_payload assign ecc_rddata_ns[iPAYLOAD_WIDTH+:PAYLOAD_WIDTH] = phy_rddata[iDQ_WIDTH+:PAYLOAD_WIDTH]; end endgenerate reg [2nCK_PER_CLKPAYLOAD_WIDTH-1:0] ecc_rddata_r; always @(posedge clk) ecc_rddata_r <= #TCQ ecc_rddata_ns; // Regenerate h_matrix from h_rows leaving out the identity part // since we're not going to correct the ECC bits themselves. genvar n; genvar p; wire [ECC_WIDTH-1:0] h_matrix [DATA_WIDTH-1:0]; generate for (n=0; n<DATA_WIDTH; n=n+1) begin : h_col for (p=0; p<ECC_WIDTH; p=p+1) begin : h_bit assign h_matrix [n][p] = h_rows [pCODE_WIDTH+n]; end end endgenerate // Compute flip bits. wire [2nCK_PER_CLKDATA_WIDTH-1:0] flip_bits; genvar q; genvar r; generate for (q=0; q<2nCK_PER_CLK; q=q+1) begin : flip_word for (r=0; r<DATA_WIDTH; r=r+1) begin : flip_bit assign flip_bits[qDATA_WIDTH+r] = h_matrix[r] == syndrome_r[qECC_WIDTH+:ECC_WIDTH]; end end endgenerate // Correct data. output reg [2nCK_PER_CLKPAYLOAD_WIDTH-1:0] rd_data; input correct_en; integer s; always @(/AS/correct_en or ecc_rddata_r or flip_bits) for (s=0; s<2nCK_PER_CLK; s=s+1) if (correct_en) rd_data[sPAYLOAD_WIDTH+:DATA_WIDTH] = ecc_rddata_r[sPAYLOAD_WIDTH+:DATA_WIDTH] ^ flip_bits[sDATA_WIDTH+:DATA_WIDTH]; else rd_data[sPAYLOAD_WIDTH+:DATA_WIDTH] = ecc_rddata_r[sPAYLOAD_WIDTH+:DATA_WIDTH]; // Copy raw payload bits if ECC_TEST is ON. localparam RAW_BIT_WIDTH = PAYLOAD_WIDTH - DATA_WIDTH; genvar t; generate if (RAW_BIT_WIDTH > 0) for (t=0; t<2nCK_PER_CLK; t=t+1) begin : copy_raw_bits always @(/AS/ecc_rddata_r) rd_data[(t+1)PAYLOAD_WIDTH-1-:RAW_BIT_WIDTH] = ecc_rddata_r[(t+1)PAYLOAD_WIDTH-1-:RAW_BIT_WIDTH]; end endgenerate // Generate status information. input ecc_status_valid; output wire [2nCK_PER_CLK-1:0] ecc_single; output wire [2nCK_PER_CLK-1:0] ecc_multiple; genvar v; generate for (v=0; v<2nCK_PER_CLK; v=v+1) begin : compute_status wire zero = ~\|syndrome_r[vECC_WIDTH+:ECC_WIDTH]; wire odd = ^syndrome_r[vECC_WIDTH+:ECC_WIDTH]; assign ecc_single[v] = ecc_status_valid && ~zero && odd; assign ecc_multiple[v] = ecc_status_valid && ~zero && ~odd; end endgenerate endmodule
module mig_7series_v2_3_ecc_dec_fix #( parameter TCQ = 100, parameter PAYLOAD_WIDTH = 64, parameter CODE_WIDTH = 72, parameter DATA_WIDTH = 64, parameter DQ_WIDTH = 72, parameter ECC_WIDTH = 8, parameter nCK_PER_CLK = 4 ) ( /AUTOARG/ // Outputs rd_data, ecc_single, ecc_multiple, // Inputs clk, rst, h_rows, phy_rddata, correct_en, ecc_status_valid ); input clk; input rst; // Compute syndromes. input [CODE_WIDTHECC_WIDTH-1:0] h_rows; input [2nCK_PER_CLKDQ_WIDTH-1:0] phy_rddata; wire [2nCK_PER_CLKECC_WIDTH-1:0] syndrome_ns; genvar k; genvar m; generate for (k=0; k<2nCK_PER_CLK; k=k+1) begin : ecc_word for (m=0; m<ECC_WIDTH; m=m+1) begin : ecc_bit assign syndrome_ns[kECC_WIDTH+m] = ^(phy_rddata[kDQ_WIDTH+:CODE_WIDTH] & h_rows[mCODE_WIDTH+:CODE_WIDTH]); end end endgenerate reg [2nCK_PER_CLKECC_WIDTH-1:0] syndrome_r; always @(posedge clk) syndrome_r <= #TCQ syndrome_ns; // Extract payload bits from raw DRAM bits and register. wire [2nCK_PER_CLKPAYLOAD_WIDTH-1:0] ecc_rddata_ns; genvar i; generate for (i=0; i<2nCK_PER_CLK; i=i+1) begin : extract_payload assign ecc_rddata_ns[iPAYLOAD_WIDTH+:PAYLOAD_WIDTH] = phy_rddata[iDQ_WIDTH+:PAYLOAD_WIDTH]; end endgenerate reg [2nCK_PER_CLKPAYLOAD_WIDTH-1:0] ecc_rddata_r; always @(posedge clk) ecc_rddata_r <= #TCQ ecc_rddata_ns; // Regenerate h_matrix from h_rows leaving out the identity part // since we're not going to correct the ECC bits themselves. genvar n; genvar p; wire [ECC_WIDTH-1:0] h_matrix [DATA_WIDTH-1:0]; generate for (n=0; n<DATA_WIDTH; n=n+1) begin : h_col for (p=0; p<ECC_WIDTH; p=p+1) begin : h_bit assign h_matrix [n][p] = h_rows [pCODE_WIDTH+n]; end end endgenerate // Compute flip bits. wire [2nCK_PER_CLKDATA_WIDTH-1:0] flip_bits; genvar q; genvar r; generate for (q=0; q<2nCK_PER_CLK; q=q+1) begin : flip_word for (r=0; r<DATA_WIDTH; r=r+1) begin : flip_bit assign flip_bits[qDATA_WIDTH+r] = h_matrix[r] == syndrome_r[qECC_WIDTH+:ECC_WIDTH]; end end endgenerate // Correct data. output reg [2nCK_PER_CLKPAYLOAD_WIDTH-1:0] rd_data; input correct_en; integer s; always @(/AS/correct_en or ecc_rddata_r or flip_bits) for (s=0; s<2nCK_PER_CLK; s=s+1) if (correct_en) rd_data[sPAYLOAD_WIDTH+:DATA_WIDTH] = ecc_rddata_r[sPAYLOAD_WIDTH+:DATA_WIDTH] ^ flip_bits[sDATA_WIDTH+:DATA_WIDTH]; else rd_data[sPAYLOAD_WIDTH+:DATA_WIDTH] = ecc_rddata_r[sPAYLOAD_WIDTH+:DATA_WIDTH]; // Copy raw payload bits if ECC_TEST is ON. localparam RAW_BIT_WIDTH = PAYLOAD_WIDTH - DATA_WIDTH; genvar t; generate if (RAW_BIT_WIDTH > 0) for (t=0; t<2nCK_PER_CLK; t=t+1) begin : copy_raw_bits always @(/AS/ecc_rddata_r) rd_data[(t+1)PAYLOAD_WIDTH-1-:RAW_BIT_WIDTH] = ecc_rddata_r[(t+1)PAYLOAD_WIDTH-1-:RAW_BIT_WIDTH]; end endgenerate // Generate status information. input ecc_status_valid; output wire [2nCK_PER_CLK-1:0] ecc_single; output wire [2nCK_PER_CLK-1:0] ecc_multiple; genvar v; generate for (v=0; v<2nCK_PER_CLK; v=v+1) begin : compute_status wire zero = ~\|syndrome_r[vECC_WIDTH+:ECC_WIDTH]; wire odd = ^syndrome_r[vECC_WIDTH+:ECC_WIDTH]; assign ecc_single[v] = ecc_status_valid && ~zero && odd; assign ecc_multiple[v] = ecc_status_valid && ~zero && ~odd; end endgenerate endmodule
module mig_7series_v2_3_ecc_dec_fix #( parameter TCQ = 100, parameter PAYLOAD_WIDTH = 64, parameter CODE_WIDTH = 72, parameter DATA_WIDTH = 64, parameter DQ_WIDTH = 72, parameter ECC_WIDTH = 8, parameter nCK_PER_CLK = 4 ) ( /AUTOARG/ // Outputs rd_data, ecc_single, ecc_multiple, // Inputs clk, rst, h_rows, phy_rddata, correct_en, ecc_status_valid ); input clk; input rst; // Compute syndromes. input [CODE_WIDTHECC_WIDTH-1:0] h_rows; input [2nCK_PER_CLKDQ_WIDTH-1:0] phy_rddata; wire [2nCK_PER_CLKECC_WIDTH-1:0] syndrome_ns; genvar k; genvar m; generate for (k=0; k<2nCK_PER_CLK; k=k+1) begin : ecc_word for (m=0; m<ECC_WIDTH; m=m+1) begin : ecc_bit assign syndrome_ns[kECC_WIDTH+m] = ^(phy_rddata[kDQ_WIDTH+:CODE_WIDTH] & h_rows[mCODE_WIDTH+:CODE_WIDTH]); end end endgenerate reg [2nCK_PER_CLKECC_WIDTH-1:0] syndrome_r; always @(posedge clk) syndrome_r <= #TCQ syndrome_ns; // Extract payload bits from raw DRAM bits and register. wire [2nCK_PER_CLKPAYLOAD_WIDTH-1:0] ecc_rddata_ns; genvar i; generate for (i=0; i<2nCK_PER_CLK; i=i+1) begin : extract_payload assign ecc_rddata_ns[iPAYLOAD_WIDTH+:PAYLOAD_WIDTH] = phy_rddata[iDQ_WIDTH+:PAYLOAD_WIDTH]; end endgenerate reg [2nCK_PER_CLKPAYLOAD_WIDTH-1:0] ecc_rddata_r; always @(posedge clk) ecc_rddata_r <= #TCQ ecc_rddata_ns; // Regenerate h_matrix from h_rows leaving out the identity part // since we're not going to correct the ECC bits themselves. genvar n; genvar p; wire [ECC_WIDTH-1:0] h_matrix [DATA_WIDTH-1:0]; generate for (n=0; n<DATA_WIDTH; n=n+1) begin : h_col for (p=0; p<ECC_WIDTH; p=p+1) begin : h_bit assign h_matrix [n][p] = h_rows [pCODE_WIDTH+n]; end end endgenerate // Compute flip bits. wire [2nCK_PER_CLKDATA_WIDTH-1:0] flip_bits; genvar q; genvar r; generate for (q=0; q<2nCK_PER_CLK; q=q+1) begin : flip_word for (r=0; r<DATA_WIDTH; r=r+1) begin : flip_bit assign flip_bits[qDATA_WIDTH+r] = h_matrix[r] == syndrome_r[qECC_WIDTH+:ECC_WIDTH]; end end endgenerate // Correct data. output reg [2nCK_PER_CLKPAYLOAD_WIDTH-1:0] rd_data; input correct_en; integer s; always @(/AS/correct_en or ecc_rddata_r or flip_bits) for (s=0; s<2nCK_PER_CLK; s=s+1) if (correct_en) rd_data[sPAYLOAD_WIDTH+:DATA_WIDTH] = ecc_rddata_r[sPAYLOAD_WIDTH+:DATA_WIDTH] ^ flip_bits[sDATA_WIDTH+:DATA_WIDTH]; else rd_data[sPAYLOAD_WIDTH+:DATA_WIDTH] = ecc_rddata_r[sPAYLOAD_WIDTH+:DATA_WIDTH]; // Copy raw payload bits if ECC_TEST is ON. localparam RAW_BIT_WIDTH = PAYLOAD_WIDTH - DATA_WIDTH; genvar t; generate if (RAW_BIT_WIDTH > 0) for (t=0; t<2nCK_PER_CLK; t=t+1) begin : copy_raw_bits always @(/AS/ecc_rddata_r) rd_data[(t+1)PAYLOAD_WIDTH-1-:RAW_BIT_WIDTH] = ecc_rddata_r[(t+1)PAYLOAD_WIDTH-1-:RAW_BIT_WIDTH]; end endgenerate // Generate status information. input ecc_status_valid; output wire [2nCK_PER_CLK-1:0] ecc_single; output wire [2nCK_PER_CLK-1:0] ecc_multiple; genvar v; generate for (v=0; v<2nCK_PER_CLK; v=v+1) begin : compute_status wire zero = ~\|syndrome_r[vECC_WIDTH+:ECC_WIDTH]; wire odd = ^syndrome_r[vECC_WIDTH+:ECC_WIDTH]; assign ecc_single[v] = ecc_status_valid && ~zero && odd; assign ecc_multiple[v] = ecc_status_valid && ~zero && ~odd; end endgenerate endmodule
module mig_7series_v2_3_ddr_phy_ocd_po_cntlr # (parameter DQS_CNT_WIDTH = 3, parameter DQS_WIDTH = 8, parameter nCK_PER_CLK = 4, parameter TCQ = 100) (/AUTOARG/ // Outputs scan_done, ocal_num_samples_done_r, oclkdelay_center_calib_start, oclkdelay_center_calib_done, oclk_center_write_resume, ocd2stg2_inc, ocd2stg2_dec, ocd2stg3_inc, ocd2stg3_dec, stg3, simp_stg3_final, cmplx_stg3_final, simp_stg3_final_sel, ninety_offsets, scanning_right, ocd_ktap_left, ocd_ktap_right, ocd_edge_detect_rdy, taps_set, use_noise_window, ocal_scan_win_not_found, // Inputs clk, rst, reset_scan, oclkdelay_init_val, lim2ocal_stg3_right_lim, lim2ocal_stg3_left_lim, complex_oclkdelay_calib_start, po_counter_read_val, oclkdelay_calib_cnt, mmcm_edge_detect_done, mmcm_lbclk_edge_aligned, poc_backup, phy_rddata_en_3, zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty, z2f, f2z, o2f, f2o, scan_right, samp_done, wl_po_fine_cnt_sel, po_rdy ); input clk; input rst; input reset_scan; reg scan_done_r; output scan_done; assign scan_done = scan_done_r; output [5:0] simp_stg3_final_sel; reg cmplx_samples_done_ns, cmplx_samples_done_r; always @(posedge clk) cmplx_samples_done_r <= #TCQ cmplx_samples_done_ns; output ocal_num_samples_done_r; assign ocal_num_samples_done_r = cmplx_samples_done_r; // Write Level signals during OCLKDELAY calibration input [5:0] oclkdelay_init_val; input [5:0] lim2ocal_stg3_right_lim; input [5:0] lim2ocal_stg3_left_lim; input complex_oclkdelay_calib_start; reg oclkdelay_center_calib_start_ns, oclkdelay_center_calib_start_r; always @(posedge clk) oclkdelay_center_calib_start_r <= #TCQ oclkdelay_center_calib_start_ns; output oclkdelay_center_calib_start; assign oclkdelay_center_calib_start = oclkdelay_center_calib_start_r; reg oclkdelay_center_calib_done_ns, oclkdelay_center_calib_done_r; always @(posedge clk) oclkdelay_center_calib_done_r <= #TCQ oclkdelay_center_calib_done_ns; output oclkdelay_center_calib_done; assign oclkdelay_center_calib_done = oclkdelay_center_calib_done_r; reg oclk_center_write_resume_ns, oclk_center_write_resume_r; always @(posedge clk) oclk_center_write_resume_r <= #TCQ oclk_center_write_resume_ns; output oclk_center_write_resume; assign oclk_center_write_resume = oclk_center_write_resume_r; reg ocd2stg2_inc_r, ocd2stg2_dec_r, ocd2stg3_inc_r, ocd2stg3_dec_r; output ocd2stg2_inc, ocd2stg2_dec, ocd2stg3_inc, ocd2stg3_dec; assign ocd2stg2_inc = ocd2stg2_inc_r; assign ocd2stg2_dec = ocd2stg2_dec_r; assign ocd2stg3_inc = ocd2stg3_inc_r; assign ocd2stg3_dec = ocd2stg3_dec_r; // Remember, two stage 2 steps for every stg 3 step. And we need a sign bit. reg [8:0] stg2_ns, stg2_r; always @(posedge clk) stg2_r <= #TCQ stg2_ns; reg [5:0] stg3_ns, stg3_r; always @(posedge clk) stg3_r <= #TCQ stg3_ns; output [5:0] stg3; assign stg3 = stg3_r; input [5:0] wl_po_fine_cnt_sel; input [8:0] po_counter_read_val; reg [5:0] po_counter_read_val_r; always @(posedge clk) po_counter_read_val_r <= #TCQ po_counter_read_val[5:0]; reg [DQS_WIDTH6-1:0] simp_stg3_final_ns, simp_stg3_final_r, cmplx_stg3_final_ns, cmplx_stg3_final_r; always @(posedge clk) simp_stg3_final_r <= #TCQ simp_stg3_final_ns; always @(posedge clk) cmplx_stg3_final_r <= #TCQ cmplx_stg3_final_ns; output [DQS_WIDTH6-1:0] simp_stg3_final, cmplx_stg3_final; assign simp_stg3_final = simp_stg3_final_r; assign cmplx_stg3_final = cmplx_stg3_final_r; input [DQS_CNT_WIDTH:0] oclkdelay_calib_cnt; wire [DQS_WIDTH6-1:0] simp_stg3_final_shft = simp_stg3_final_r >> oclkdelay_calib_cnt 6; assign simp_stg3_final_sel = simp_stg3_final_shft[5:0]; wire [5:0] stg3_init = complex_oclkdelay_calib_start ? simp_stg3_final_sel : oclkdelay_init_val; wire signed [8:0] stg2_steps = stg3_r > stg3_init ? -9'sd2 * $signed({3'b0, (stg3_r - stg3_init)}) : 9'sd2 * $signed({3'b0, (stg3_init - stg3_r)}); wire signed [8:0] stg2_target_ns = $signed({3'b0, wl_po_fine_cnt_sel}) + stg2_steps; reg signed [8:0] stg2_target_r; always @ (posedge clk) stg2_target_r <= #TCQ stg2_target_ns; reg [5:0] stg2_final_ns, stg2_final_r; always @(posedge clk) stg2_final_r <= #TCQ stg2_final_ns; always @() stg2_final_ns = stg2_target_r[8] == 1'b1 ? 6'd0 : stg2_target_r > 9'd63 ? 6'd63 : stg2_target_r[5:0]; wire final_stg2_inc = stg2_final_r > po_counter_read_val_r; wire final_stg2_dec = stg2_final_r < po_counter_read_val_r; wire left_lim = stg3_r == lim2ocal_stg3_left_lim; wire right_lim = stg3_r == lim2ocal_stg3_right_lim; reg [1:0] ninety_offsets_ns, ninety_offsets_r; always @(posedge clk) ninety_offsets_r <= #TCQ ninety_offsets_ns; output [1:0] ninety_offsets; assign ninety_offsets = ninety_offsets_r; reg scanning_right_ns, scanning_right_r; always @(posedge clk) scanning_right_r <= #TCQ scanning_right_ns; output scanning_right; assign scanning_right = scanning_right_r; reg ocd_ktap_left_ns, ocd_ktap_left_r, ocd_ktap_right_ns, ocd_ktap_right_r; always @(posedge clk) ocd_ktap_left_r <= #TCQ ocd_ktap_left_ns; always @(posedge clk) ocd_ktap_right_r <= #TCQ ocd_ktap_right_ns; output ocd_ktap_left, ocd_ktap_right; assign ocd_ktap_left = ocd_ktap_left_r; assign ocd_ktap_right = ocd_ktap_right_r; reg ocd_edge_detect_rdy_ns, ocd_edge_detect_rdy_r; always @(posedge clk) ocd_edge_detect_rdy_r <= #TCQ ocd_edge_detect_rdy_ns; output ocd_edge_detect_rdy; assign ocd_edge_detect_rdy = ocd_edge_detect_rdy_r; input mmcm_edge_detect_done; input mmcm_lbclk_edge_aligned; input poc_backup; reg poc_backup_ns, poc_backup_r; always @(posedge clk) poc_backup_r <= #TCQ poc_backup_ns; reg taps_set_r; output taps_set; assign taps_set = taps_set_r; input phy_rddata_en_3; input [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty; input z2f, f2z, o2f, f2o; wire zero = f2z && z2f; wire noise = z2f && f2o; wire oneeighty = f2o && o2f; reg win_not_found; reg [1:0] ninety_offsets_final; reg [5:0] left, right, current_edge; always @() begin left = lim2ocal_stg3_left_lim; right = lim2ocal_stg3_right_lim; ninety_offsets_final = 2'd0; win_not_found = 1'b0; if (zero) begin left = fuzz2zero; right = zero2fuzz; end else if (noise) begin left = zero2fuzz; right = fuzz2oneeighty; ninety_offsets_final = 2'd1; end else if (oneeighty) begin left = fuzz2oneeighty; right = oneeighty2fuzz; ninety_offsets_final = 2'd2; end else if (z2f) begin right = zero2fuzz; end else if (f2o) begin left = fuzz2oneeighty; ninety_offsets_final = 2'd2; end else if (f2z) begin left = fuzz2zero; end else win_not_found = 1'b1; current_edge = ocd_ktap_left_r ? left : right; end // always @ begin output use_noise_window; assign use_noise_window = ninety_offsets == 2'd1; reg ocal_scan_win_not_found_ns, ocal_scan_win_not_found_r; always @(posedge clk) ocal_scan_win_not_found_r <= #TCQ ocal_scan_win_not_found_ns; output ocal_scan_win_not_found; assign ocal_scan_win_not_found = ocal_scan_win_not_found_r; wire inc_po_ns = current_edge > stg3_r; wire dec_po_ns = current_edge < stg3_r; reg inc_po_r, dec_po_r; always @(posedge clk) inc_po_r <= #TCQ inc_po_ns; always @(posedge clk) dec_po_r <= #TCQ dec_po_ns; input scan_right; wire left_stop = left_lim \|\| scan_right; wire right_stop = right_lim \|\| o2f; reg [4:0] resume_wait_ns, resume_wait_r; always @(posedge clk) resume_wait_r <= #TCQ resume_wait_ns; wire resume_wait = \|resume_wait_r; reg po_done_ns, po_done_r; always @(posedge clk) po_done_r <= #TCQ po_done_ns; input samp_done; input po_rdy; reg up_ns, up_r; always @(posedge clk) up_r <= #TCQ up_ns; reg [1:0] two_ns, two_r; always @(posedge clk) two_r <= #TCQ two_ns; /* wire stg2_zero = ~\|stg2_r; wire [8:0] stg2_2_zero = stg2_r[8] ? 9'd0 : stg2_r > 9'd63 ? 9'd63 : stg2_r; / reg [3:0] sm_ns, sm_r; always @(posedge clk) sm_r <= #TCQ sm_ns; ( dont_touch = "true" ) reg phy_rddata_en_3_second_ns, phy_rddata_en_3_second_r; always @(posedge clk) phy_rddata_en_3_second_r <= #TCQ phy_rddata_en_3_second_ns; always @() phy_rddata_en_3_second_ns = ~reset_scan && (phy_rddata_en_3 ? ~phy_rddata_en_3_second_r : phy_rddata_en_3_second_r); (* dont_touch = "true" ) wire use_samp_done = nCK_PER_CLK == 2 ? phy_rddata_en_3 && phy_rddata_en_3_second_r : phy_rddata_en_3; reg po_center_wait; reg po_slew; reg po_finish_scan; always @() begin // Default next state assignments. cmplx_samples_done_ns = cmplx_samples_done_r; cmplx_stg3_final_ns = cmplx_stg3_final_r; scanning_right_ns = scanning_right_r; ninety_offsets_ns = ninety_offsets_r; ocal_scan_win_not_found_ns = ocal_scan_win_not_found_r; ocd_edge_detect_rdy_ns = ocd_edge_detect_rdy_r; ocd_ktap_left_ns = ocd_ktap_left_r; ocd_ktap_right_ns = ocd_ktap_right_r; ocd2stg2_inc_r = 1'b0; ocd2stg2_dec_r = 1'b0; ocd2stg3_inc_r = 1'b0; ocd2stg3_dec_r = 1'b0; oclkdelay_center_calib_start_ns = oclkdelay_center_calib_start_r; oclkdelay_center_calib_done_ns = 1'b0; oclk_center_write_resume_ns = oclk_center_write_resume_r; po_center_wait = 1'b0; po_done_ns = po_done_r; po_finish_scan = 1'b0; po_slew = 1'b0; poc_backup_ns = poc_backup_r; scan_done_r = 1'b0; simp_stg3_final_ns = simp_stg3_final_r; sm_ns = sm_r; taps_set_r = 1'b0; up_ns = up_r; stg2_ns = stg2_r; stg3_ns = stg3_r; two_ns = two_r; resume_wait_ns = resume_wait_r; if (rst == 1'b1) begin // RESET next states cmplx_samples_done_ns = 1'b0; ocal_scan_win_not_found_ns = 1'b0; ocd_ktap_left_ns = 1'b0; ocd_ktap_right_ns = 1'b0; ocd_edge_detect_rdy_ns = 1'b0; oclk_center_write_resume_ns = 1'b0; oclkdelay_center_calib_start_ns = 1'b0; po_done_ns = 1'b1; resume_wait_ns = 5'd0; sm_ns = /AK("READY")/4'd0; end else // State based actions and next states. case (sm_r) /AL("READY")/4'd0:begin poc_backup_ns = 1'b0; stg2_ns = {3'b0, wl_po_fine_cnt_sel}; stg3_ns = stg3_init; scanning_right_ns = 1'b0; if (complex_oclkdelay_calib_start) cmplx_samples_done_ns = 1'b1; if (!reset_scan && ~resume_wait) begin cmplx_samples_done_ns = 1'b0; ocal_scan_win_not_found_ns = 1'b0; taps_set_r = 1'b1; sm_ns = /AK("SAMPLING")/4'd1; end end /AL("SAMPLING")/4'd1:begin if (samp_done && use_samp_done) begin if (complex_oclkdelay_calib_start) cmplx_samples_done_ns = 1'b1; scanning_right_ns = scanning_right_r \|\| left_stop; if (right_stop && scanning_right_r) begin oclkdelay_center_calib_start_ns = 1'b1; ocd_ktap_left_ns = 1'b1; ocal_scan_win_not_found_ns = win_not_found; sm_ns = /AK("SLEW_PO")/4'd3; end else begin if (scanning_right_ns) ocd2stg3_inc_r = 1'b1; else ocd2stg3_dec_r = 1'b1; sm_ns = /AK("PO_WAIT")/4'd2; end end end /AL("PO_WAIT")/4'd2:begin if (po_done_r && ~resume_wait) begin taps_set_r = 1'b1; sm_ns = /AK("SAMPLING")/4'd1; cmplx_samples_done_ns = 1'b0; end end /AL("SLEW_PO")/4'd3:begin po_slew = 1'b1; ninety_offsets_ns = \|ninety_offsets_final ? 2'b01 : 2'b00; if (~resume_wait) begin if (po_done_r) begin if (inc_po_r) ocd2stg3_inc_r = 1'b1; else if (dec_po_r) ocd2stg3_dec_r = 1'b1; else if (~resume_wait) begin cmplx_samples_done_ns = 1'b0; sm_ns = /AK("ALIGN_EDGES")/4'd4; oclk_center_write_resume_ns = 1'b1; end end // if (po_done) end end // case: 3'd3 /AL("ALIGN_EDGES")/4'd4: if (~resume_wait) begin if (mmcm_edge_detect_done) begin ocd_edge_detect_rdy_ns = 1'b0; if (ocd_ktap_left_r) begin ocd_ktap_left_ns = 1'b0; ocd_ktap_right_ns = 1'b1; oclk_center_write_resume_ns = 1'b0; sm_ns = /AK("SLEW_PO")/4'd3; end else if (ocd_ktap_right_r) begin ocd_ktap_right_ns = 1'b0; sm_ns = /AK("WAIT_ONE")/4'd5; end else if (~mmcm_lbclk_edge_aligned) begin sm_ns = /AK("DQS_STOP_WAIT")/4'd6; oclk_center_write_resume_ns = 1'b0; end else begin if (ninety_offsets_r != ninety_offsets_final && ocd_edge_detect_rdy_r) begin ninety_offsets_ns = ninety_offsets_r + 2'b01; sm_ns = /AK("WAIT_ONE")/4'd5; end else begin oclk_center_write_resume_ns = 1'b0; poc_backup_ns = poc_backup; // stg2_ns = stg2_2_zero; sm_ns = /AK("FINISH_SCAN")/4'd8; end end // else: !if(~mmcm_lbclk_edge_aligned) end else ocd_edge_detect_rdy_ns = 1'b1; end // if (~resume_wait) /AL("WAIT_ONE")/4'd5: sm_ns = /AK("ALIGN_EDGES")/4'd4; /AL("DQS_STOP_WAIT")/4'd6: if (~resume_wait) begin ocd2stg3_dec_r = 1'b1; sm_ns = /AK("CENTER_PO_WAIT")/4'd7; end /AL("CENTER_PO_WAIT")/4'd7: begin po_center_wait = 1'b1; // Kludge to get around limitation of the AUTOs symbols. if (po_done_r) begin sm_ns = /AK("ALIGN_EDGES")/4'd4; oclk_center_write_resume_ns = 1'b1; end end /AL("FINISH_SCAN")/4'd8: begin po_finish_scan = 1'b1; if (resume_wait_r == 5'd1) begin if (~poc_backup_r) begin oclkdelay_center_calib_done_ns = 1'b1; oclkdelay_center_calib_start_ns = 1'b0; end end if (~resume_wait) begin if (po_rdy) if (poc_backup_r) begin ocd2stg3_inc_r = 1'b1; poc_backup_ns = 1'b0; end else if (~final_stg2_inc && ~final_stg2_dec) begin if (complex_oclkdelay_calib_start) cmplx_stg3_final_ns[oclkdelay_calib_cnt6+:6] = stg3_r; else simp_stg3_final_ns[oclkdelay_calib_cnt6+:6] = stg3_r; sm_ns = /AK("READY")/4'd0; scan_done_r = 1'b1; end else begin ocd2stg2_inc_r = final_stg2_inc; ocd2stg2_dec_r = final_stg2_dec; end end // if (~resume_wait) end // case: 4'd8 endcase // case (sm_r) if (ocd2stg3_inc_r) begin stg3_ns = stg3_r + 6'h1; up_ns = 1'b0; end if (ocd2stg3_dec_r) begin stg3_ns = stg3_r - 6'h1; up_ns = 1'b1; end if (ocd2stg3_inc_r \|\| ocd2stg3_dec_r) begin po_done_ns = 1'b0; two_ns = 2'b00; end if (~po_done_r) if (po_rdy) if (two_r == 2'b10 \|\| po_center_wait \|\| po_slew \|\| po_finish_scan) po_done_ns = 1'b1; else begin two_ns = two_r + 2'b1; if (up_r) begin stg2_ns = stg2_r + 9'b1; if (stg2_r >= 9'd0 && stg2_r < 9'd63) ocd2stg2_inc_r = 1'b1; end else begin stg2_ns = stg2_r - 9'b1; if (stg2_r > 9'd0 && stg2_r <= 9'd63) ocd2stg2_dec_r = 1'b1; end end // else: !if(two_r == 2'b10) if (ocd_ktap_left_ns && ~ocd_ktap_left_r) resume_wait_ns = 5'b1; else if (oclk_center_write_resume_ns ^ oclk_center_write_resume_r) resume_wait_ns = 5'd15; else if (cmplx_samples_done_ns & ~cmplx_samples_done_r \|\| complex_oclkdelay_calib_start & reset_scan \|\| poc_backup_r & ocd2stg3_inc_r) resume_wait_ns = 5'd31; else if (\|resume_wait_r) resume_wait_ns = resume_wait_r - 5'd1; end // always @ begin endmodule
module mig_7series_v2_3_ddr_phy_ocd_po_cntlr # (parameter DQS_CNT_WIDTH = 3, parameter DQS_WIDTH = 8, parameter nCK_PER_CLK = 4, parameter TCQ = 100) (/AUTOARG/ // Outputs scan_done, ocal_num_samples_done_r, oclkdelay_center_calib_start, oclkdelay_center_calib_done, oclk_center_write_resume, ocd2stg2_inc, ocd2stg2_dec, ocd2stg3_inc, ocd2stg3_dec, stg3, simp_stg3_final, cmplx_stg3_final, simp_stg3_final_sel, ninety_offsets, scanning_right, ocd_ktap_left, ocd_ktap_right, ocd_edge_detect_rdy, taps_set, use_noise_window, ocal_scan_win_not_found, // Inputs clk, rst, reset_scan, oclkdelay_init_val, lim2ocal_stg3_right_lim, lim2ocal_stg3_left_lim, complex_oclkdelay_calib_start, po_counter_read_val, oclkdelay_calib_cnt, mmcm_edge_detect_done, mmcm_lbclk_edge_aligned, poc_backup, phy_rddata_en_3, zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty, z2f, f2z, o2f, f2o, scan_right, samp_done, wl_po_fine_cnt_sel, po_rdy ); input clk; input rst; input reset_scan; reg scan_done_r; output scan_done; assign scan_done = scan_done_r; output [5:0] simp_stg3_final_sel; reg cmplx_samples_done_ns, cmplx_samples_done_r; always @(posedge clk) cmplx_samples_done_r <= #TCQ cmplx_samples_done_ns; output ocal_num_samples_done_r; assign ocal_num_samples_done_r = cmplx_samples_done_r; // Write Level signals during OCLKDELAY calibration input [5:0] oclkdelay_init_val; input [5:0] lim2ocal_stg3_right_lim; input [5:0] lim2ocal_stg3_left_lim; input complex_oclkdelay_calib_start; reg oclkdelay_center_calib_start_ns, oclkdelay_center_calib_start_r; always @(posedge clk) oclkdelay_center_calib_start_r <= #TCQ oclkdelay_center_calib_start_ns; output oclkdelay_center_calib_start; assign oclkdelay_center_calib_start = oclkdelay_center_calib_start_r; reg oclkdelay_center_calib_done_ns, oclkdelay_center_calib_done_r; always @(posedge clk) oclkdelay_center_calib_done_r <= #TCQ oclkdelay_center_calib_done_ns; output oclkdelay_center_calib_done; assign oclkdelay_center_calib_done = oclkdelay_center_calib_done_r; reg oclk_center_write_resume_ns, oclk_center_write_resume_r; always @(posedge clk) oclk_center_write_resume_r <= #TCQ oclk_center_write_resume_ns; output oclk_center_write_resume; assign oclk_center_write_resume = oclk_center_write_resume_r; reg ocd2stg2_inc_r, ocd2stg2_dec_r, ocd2stg3_inc_r, ocd2stg3_dec_r; output ocd2stg2_inc, ocd2stg2_dec, ocd2stg3_inc, ocd2stg3_dec; assign ocd2stg2_inc = ocd2stg2_inc_r; assign ocd2stg2_dec = ocd2stg2_dec_r; assign ocd2stg3_inc = ocd2stg3_inc_r; assign ocd2stg3_dec = ocd2stg3_dec_r; // Remember, two stage 2 steps for every stg 3 step. And we need a sign bit. reg [8:0] stg2_ns, stg2_r; always @(posedge clk) stg2_r <= #TCQ stg2_ns; reg [5:0] stg3_ns, stg3_r; always @(posedge clk) stg3_r <= #TCQ stg3_ns; output [5:0] stg3; assign stg3 = stg3_r; input [5:0] wl_po_fine_cnt_sel; input [8:0] po_counter_read_val; reg [5:0] po_counter_read_val_r; always @(posedge clk) po_counter_read_val_r <= #TCQ po_counter_read_val[5:0]; reg [DQS_WIDTH6-1:0] simp_stg3_final_ns, simp_stg3_final_r, cmplx_stg3_final_ns, cmplx_stg3_final_r; always @(posedge clk) simp_stg3_final_r <= #TCQ simp_stg3_final_ns; always @(posedge clk) cmplx_stg3_final_r <= #TCQ cmplx_stg3_final_ns; output [DQS_WIDTH6-1:0] simp_stg3_final, cmplx_stg3_final; assign simp_stg3_final = simp_stg3_final_r; assign cmplx_stg3_final = cmplx_stg3_final_r; input [DQS_CNT_WIDTH:0] oclkdelay_calib_cnt; wire [DQS_WIDTH6-1:0] simp_stg3_final_shft = simp_stg3_final_r >> oclkdelay_calib_cnt 6; assign simp_stg3_final_sel = simp_stg3_final_shft[5:0]; wire [5:0] stg3_init = complex_oclkdelay_calib_start ? simp_stg3_final_sel : oclkdelay_init_val; wire signed [8:0] stg2_steps = stg3_r > stg3_init ? -9'sd2 * $signed({3'b0, (stg3_r - stg3_init)}) : 9'sd2 * $signed({3'b0, (stg3_init - stg3_r)}); wire signed [8:0] stg2_target_ns = $signed({3'b0, wl_po_fine_cnt_sel}) + stg2_steps; reg signed [8:0] stg2_target_r; always @ (posedge clk) stg2_target_r <= #TCQ stg2_target_ns; reg [5:0] stg2_final_ns, stg2_final_r; always @(posedge clk) stg2_final_r <= #TCQ stg2_final_ns; always @() stg2_final_ns = stg2_target_r[8] == 1'b1 ? 6'd0 : stg2_target_r > 9'd63 ? 6'd63 : stg2_target_r[5:0]; wire final_stg2_inc = stg2_final_r > po_counter_read_val_r; wire final_stg2_dec = stg2_final_r < po_counter_read_val_r; wire left_lim = stg3_r == lim2ocal_stg3_left_lim; wire right_lim = stg3_r == lim2ocal_stg3_right_lim; reg [1:0] ninety_offsets_ns, ninety_offsets_r; always @(posedge clk) ninety_offsets_r <= #TCQ ninety_offsets_ns; output [1:0] ninety_offsets; assign ninety_offsets = ninety_offsets_r; reg scanning_right_ns, scanning_right_r; always @(posedge clk) scanning_right_r <= #TCQ scanning_right_ns; output scanning_right; assign scanning_right = scanning_right_r; reg ocd_ktap_left_ns, ocd_ktap_left_r, ocd_ktap_right_ns, ocd_ktap_right_r; always @(posedge clk) ocd_ktap_left_r <= #TCQ ocd_ktap_left_ns; always @(posedge clk) ocd_ktap_right_r <= #TCQ ocd_ktap_right_ns; output ocd_ktap_left, ocd_ktap_right; assign ocd_ktap_left = ocd_ktap_left_r; assign ocd_ktap_right = ocd_ktap_right_r; reg ocd_edge_detect_rdy_ns, ocd_edge_detect_rdy_r; always @(posedge clk) ocd_edge_detect_rdy_r <= #TCQ ocd_edge_detect_rdy_ns; output ocd_edge_detect_rdy; assign ocd_edge_detect_rdy = ocd_edge_detect_rdy_r; input mmcm_edge_detect_done; input mmcm_lbclk_edge_aligned; input poc_backup; reg poc_backup_ns, poc_backup_r; always @(posedge clk) poc_backup_r <= #TCQ poc_backup_ns; reg taps_set_r; output taps_set; assign taps_set = taps_set_r; input phy_rddata_en_3; input [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty; input z2f, f2z, o2f, f2o; wire zero = f2z && z2f; wire noise = z2f && f2o; wire oneeighty = f2o && o2f; reg win_not_found; reg [1:0] ninety_offsets_final; reg [5:0] left, right, current_edge; always @() begin left = lim2ocal_stg3_left_lim; right = lim2ocal_stg3_right_lim; ninety_offsets_final = 2'd0; win_not_found = 1'b0; if (zero) begin left = fuzz2zero; right = zero2fuzz; end else if (noise) begin left = zero2fuzz; right = fuzz2oneeighty; ninety_offsets_final = 2'd1; end else if (oneeighty) begin left = fuzz2oneeighty; right = oneeighty2fuzz; ninety_offsets_final = 2'd2; end else if (z2f) begin right = zero2fuzz; end else if (f2o) begin left = fuzz2oneeighty; ninety_offsets_final = 2'd2; end else if (f2z) begin left = fuzz2zero; end else win_not_found = 1'b1; current_edge = ocd_ktap_left_r ? left : right; end // always @ begin output use_noise_window; assign use_noise_window = ninety_offsets == 2'd1; reg ocal_scan_win_not_found_ns, ocal_scan_win_not_found_r; always @(posedge clk) ocal_scan_win_not_found_r <= #TCQ ocal_scan_win_not_found_ns; output ocal_scan_win_not_found; assign ocal_scan_win_not_found = ocal_scan_win_not_found_r; wire inc_po_ns = current_edge > stg3_r; wire dec_po_ns = current_edge < stg3_r; reg inc_po_r, dec_po_r; always @(posedge clk) inc_po_r <= #TCQ inc_po_ns; always @(posedge clk) dec_po_r <= #TCQ dec_po_ns; input scan_right; wire left_stop = left_lim \|\| scan_right; wire right_stop = right_lim \|\| o2f; reg [4:0] resume_wait_ns, resume_wait_r; always @(posedge clk) resume_wait_r <= #TCQ resume_wait_ns; wire resume_wait = \|resume_wait_r; reg po_done_ns, po_done_r; always @(posedge clk) po_done_r <= #TCQ po_done_ns; input samp_done; input po_rdy; reg up_ns, up_r; always @(posedge clk) up_r <= #TCQ up_ns; reg [1:0] two_ns, two_r; always @(posedge clk) two_r <= #TCQ two_ns; /* wire stg2_zero = ~\|stg2_r; wire [8:0] stg2_2_zero = stg2_r[8] ? 9'd0 : stg2_r > 9'd63 ? 9'd63 : stg2_r; / reg [3:0] sm_ns, sm_r; always @(posedge clk) sm_r <= #TCQ sm_ns; ( dont_touch = "true" ) reg phy_rddata_en_3_second_ns, phy_rddata_en_3_second_r; always @(posedge clk) phy_rddata_en_3_second_r <= #TCQ phy_rddata_en_3_second_ns; always @() phy_rddata_en_3_second_ns = ~reset_scan && (phy_rddata_en_3 ? ~phy_rddata_en_3_second_r : phy_rddata_en_3_second_r); (* dont_touch = "true" ) wire use_samp_done = nCK_PER_CLK == 2 ? phy_rddata_en_3 && phy_rddata_en_3_second_r : phy_rddata_en_3; reg po_center_wait; reg po_slew; reg po_finish_scan; always @() begin // Default next state assignments. cmplx_samples_done_ns = cmplx_samples_done_r; cmplx_stg3_final_ns = cmplx_stg3_final_r; scanning_right_ns = scanning_right_r; ninety_offsets_ns = ninety_offsets_r; ocal_scan_win_not_found_ns = ocal_scan_win_not_found_r; ocd_edge_detect_rdy_ns = ocd_edge_detect_rdy_r; ocd_ktap_left_ns = ocd_ktap_left_r; ocd_ktap_right_ns = ocd_ktap_right_r; ocd2stg2_inc_r = 1'b0; ocd2stg2_dec_r = 1'b0; ocd2stg3_inc_r = 1'b0; ocd2stg3_dec_r = 1'b0; oclkdelay_center_calib_start_ns = oclkdelay_center_calib_start_r; oclkdelay_center_calib_done_ns = 1'b0; oclk_center_write_resume_ns = oclk_center_write_resume_r; po_center_wait = 1'b0; po_done_ns = po_done_r; po_finish_scan = 1'b0; po_slew = 1'b0; poc_backup_ns = poc_backup_r; scan_done_r = 1'b0; simp_stg3_final_ns = simp_stg3_final_r; sm_ns = sm_r; taps_set_r = 1'b0; up_ns = up_r; stg2_ns = stg2_r; stg3_ns = stg3_r; two_ns = two_r; resume_wait_ns = resume_wait_r; if (rst == 1'b1) begin // RESET next states cmplx_samples_done_ns = 1'b0; ocal_scan_win_not_found_ns = 1'b0; ocd_ktap_left_ns = 1'b0; ocd_ktap_right_ns = 1'b0; ocd_edge_detect_rdy_ns = 1'b0; oclk_center_write_resume_ns = 1'b0; oclkdelay_center_calib_start_ns = 1'b0; po_done_ns = 1'b1; resume_wait_ns = 5'd0; sm_ns = /AK("READY")/4'd0; end else // State based actions and next states. case (sm_r) /AL("READY")/4'd0:begin poc_backup_ns = 1'b0; stg2_ns = {3'b0, wl_po_fine_cnt_sel}; stg3_ns = stg3_init; scanning_right_ns = 1'b0; if (complex_oclkdelay_calib_start) cmplx_samples_done_ns = 1'b1; if (!reset_scan && ~resume_wait) begin cmplx_samples_done_ns = 1'b0; ocal_scan_win_not_found_ns = 1'b0; taps_set_r = 1'b1; sm_ns = /AK("SAMPLING")/4'd1; end end /AL("SAMPLING")/4'd1:begin if (samp_done && use_samp_done) begin if (complex_oclkdelay_calib_start) cmplx_samples_done_ns = 1'b1; scanning_right_ns = scanning_right_r \|\| left_stop; if (right_stop && scanning_right_r) begin oclkdelay_center_calib_start_ns = 1'b1; ocd_ktap_left_ns = 1'b1; ocal_scan_win_not_found_ns = win_not_found; sm_ns = /AK("SLEW_PO")/4'd3; end else begin if (scanning_right_ns) ocd2stg3_inc_r = 1'b1; else ocd2stg3_dec_r = 1'b1; sm_ns = /AK("PO_WAIT")/4'd2; end end end /AL("PO_WAIT")/4'd2:begin if (po_done_r && ~resume_wait) begin taps_set_r = 1'b1; sm_ns = /AK("SAMPLING")/4'd1; cmplx_samples_done_ns = 1'b0; end end /AL("SLEW_PO")/4'd3:begin po_slew = 1'b1; ninety_offsets_ns = \|ninety_offsets_final ? 2'b01 : 2'b00; if (~resume_wait) begin if (po_done_r) begin if (inc_po_r) ocd2stg3_inc_r = 1'b1; else if (dec_po_r) ocd2stg3_dec_r = 1'b1; else if (~resume_wait) begin cmplx_samples_done_ns = 1'b0; sm_ns = /AK("ALIGN_EDGES")/4'd4; oclk_center_write_resume_ns = 1'b1; end end // if (po_done) end end // case: 3'd3 /AL("ALIGN_EDGES")/4'd4: if (~resume_wait) begin if (mmcm_edge_detect_done) begin ocd_edge_detect_rdy_ns = 1'b0; if (ocd_ktap_left_r) begin ocd_ktap_left_ns = 1'b0; ocd_ktap_right_ns = 1'b1; oclk_center_write_resume_ns = 1'b0; sm_ns = /AK("SLEW_PO")/4'd3; end else if (ocd_ktap_right_r) begin ocd_ktap_right_ns = 1'b0; sm_ns = /AK("WAIT_ONE")/4'd5; end else if (~mmcm_lbclk_edge_aligned) begin sm_ns = /AK("DQS_STOP_WAIT")/4'd6; oclk_center_write_resume_ns = 1'b0; end else begin if (ninety_offsets_r != ninety_offsets_final && ocd_edge_detect_rdy_r) begin ninety_offsets_ns = ninety_offsets_r + 2'b01; sm_ns = /AK("WAIT_ONE")/4'd5; end else begin oclk_center_write_resume_ns = 1'b0; poc_backup_ns = poc_backup; // stg2_ns = stg2_2_zero; sm_ns = /AK("FINISH_SCAN")/4'd8; end end // else: !if(~mmcm_lbclk_edge_aligned) end else ocd_edge_detect_rdy_ns = 1'b1; end // if (~resume_wait) /AL("WAIT_ONE")/4'd5: sm_ns = /AK("ALIGN_EDGES")/4'd4; /AL("DQS_STOP_WAIT")/4'd6: if (~resume_wait) begin ocd2stg3_dec_r = 1'b1; sm_ns = /AK("CENTER_PO_WAIT")/4'd7; end /AL("CENTER_PO_WAIT")/4'd7: begin po_center_wait = 1'b1; // Kludge to get around limitation of the AUTOs symbols. if (po_done_r) begin sm_ns = /AK("ALIGN_EDGES")/4'd4; oclk_center_write_resume_ns = 1'b1; end end /AL("FINISH_SCAN")/4'd8: begin po_finish_scan = 1'b1; if (resume_wait_r == 5'd1) begin if (~poc_backup_r) begin oclkdelay_center_calib_done_ns = 1'b1; oclkdelay_center_calib_start_ns = 1'b0; end end if (~resume_wait) begin if (po_rdy) if (poc_backup_r) begin ocd2stg3_inc_r = 1'b1; poc_backup_ns = 1'b0; end else if (~final_stg2_inc && ~final_stg2_dec) begin if (complex_oclkdelay_calib_start) cmplx_stg3_final_ns[oclkdelay_calib_cnt6+:6] = stg3_r; else simp_stg3_final_ns[oclkdelay_calib_cnt6+:6] = stg3_r; sm_ns = /AK("READY")/4'd0; scan_done_r = 1'b1; end else begin ocd2stg2_inc_r = final_stg2_inc; ocd2stg2_dec_r = final_stg2_dec; end end // if (~resume_wait) end // case: 4'd8 endcase // case (sm_r) if (ocd2stg3_inc_r) begin stg3_ns = stg3_r + 6'h1; up_ns = 1'b0; end if (ocd2stg3_dec_r) begin stg3_ns = stg3_r - 6'h1; up_ns = 1'b1; end if (ocd2stg3_inc_r \|\| ocd2stg3_dec_r) begin po_done_ns = 1'b0; two_ns = 2'b00; end if (~po_done_r) if (po_rdy) if (two_r == 2'b10 \|\| po_center_wait \|\| po_slew \|\| po_finish_scan) po_done_ns = 1'b1; else begin two_ns = two_r + 2'b1; if (up_r) begin stg2_ns = stg2_r + 9'b1; if (stg2_r >= 9'd0 && stg2_r < 9'd63) ocd2stg2_inc_r = 1'b1; end else begin stg2_ns = stg2_r - 9'b1; if (stg2_r > 9'd0 && stg2_r <= 9'd63) ocd2stg2_dec_r = 1'b1; end end // else: !if(two_r == 2'b10) if (ocd_ktap_left_ns && ~ocd_ktap_left_r) resume_wait_ns = 5'b1; else if (oclk_center_write_resume_ns ^ oclk_center_write_resume_r) resume_wait_ns = 5'd15; else if (cmplx_samples_done_ns & ~cmplx_samples_done_r \|\| complex_oclkdelay_calib_start & reset_scan \|\| poc_backup_r & ocd2stg3_inc_r) resume_wait_ns = 5'd31; else if (\|resume_wait_r) resume_wait_ns = resume_wait_r - 5'd1; end // always @ begin endmodule
module mig_7series_v2_3_ddr_phy_ocd_po_cntlr # (parameter DQS_CNT_WIDTH = 3, parameter DQS_WIDTH = 8, parameter nCK_PER_CLK = 4, parameter TCQ = 100) (/AUTOARG/ // Outputs scan_done, ocal_num_samples_done_r, oclkdelay_center_calib_start, oclkdelay_center_calib_done, oclk_center_write_resume, ocd2stg2_inc, ocd2stg2_dec, ocd2stg3_inc, ocd2stg3_dec, stg3, simp_stg3_final, cmplx_stg3_final, simp_stg3_final_sel, ninety_offsets, scanning_right, ocd_ktap_left, ocd_ktap_right, ocd_edge_detect_rdy, taps_set, use_noise_window, ocal_scan_win_not_found, // Inputs clk, rst, reset_scan, oclkdelay_init_val, lim2ocal_stg3_right_lim, lim2ocal_stg3_left_lim, complex_oclkdelay_calib_start, po_counter_read_val, oclkdelay_calib_cnt, mmcm_edge_detect_done, mmcm_lbclk_edge_aligned, poc_backup, phy_rddata_en_3, zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty, z2f, f2z, o2f, f2o, scan_right, samp_done, wl_po_fine_cnt_sel, po_rdy ); input clk; input rst; input reset_scan; reg scan_done_r; output scan_done; assign scan_done = scan_done_r; output [5:0] simp_stg3_final_sel; reg cmplx_samples_done_ns, cmplx_samples_done_r; always @(posedge clk) cmplx_samples_done_r <= #TCQ cmplx_samples_done_ns; output ocal_num_samples_done_r; assign ocal_num_samples_done_r = cmplx_samples_done_r; // Write Level signals during OCLKDELAY calibration input [5:0] oclkdelay_init_val; input [5:0] lim2ocal_stg3_right_lim; input [5:0] lim2ocal_stg3_left_lim; input complex_oclkdelay_calib_start; reg oclkdelay_center_calib_start_ns, oclkdelay_center_calib_start_r; always @(posedge clk) oclkdelay_center_calib_start_r <= #TCQ oclkdelay_center_calib_start_ns; output oclkdelay_center_calib_start; assign oclkdelay_center_calib_start = oclkdelay_center_calib_start_r; reg oclkdelay_center_calib_done_ns, oclkdelay_center_calib_done_r; always @(posedge clk) oclkdelay_center_calib_done_r <= #TCQ oclkdelay_center_calib_done_ns; output oclkdelay_center_calib_done; assign oclkdelay_center_calib_done = oclkdelay_center_calib_done_r; reg oclk_center_write_resume_ns, oclk_center_write_resume_r; always @(posedge clk) oclk_center_write_resume_r <= #TCQ oclk_center_write_resume_ns; output oclk_center_write_resume; assign oclk_center_write_resume = oclk_center_write_resume_r; reg ocd2stg2_inc_r, ocd2stg2_dec_r, ocd2stg3_inc_r, ocd2stg3_dec_r; output ocd2stg2_inc, ocd2stg2_dec, ocd2stg3_inc, ocd2stg3_dec; assign ocd2stg2_inc = ocd2stg2_inc_r; assign ocd2stg2_dec = ocd2stg2_dec_r; assign ocd2stg3_inc = ocd2stg3_inc_r; assign ocd2stg3_dec = ocd2stg3_dec_r; // Remember, two stage 2 steps for every stg 3 step. And we need a sign bit. reg [8:0] stg2_ns, stg2_r; always @(posedge clk) stg2_r <= #TCQ stg2_ns; reg [5:0] stg3_ns, stg3_r; always @(posedge clk) stg3_r <= #TCQ stg3_ns; output [5:0] stg3; assign stg3 = stg3_r; input [5:0] wl_po_fine_cnt_sel; input [8:0] po_counter_read_val; reg [5:0] po_counter_read_val_r; always @(posedge clk) po_counter_read_val_r <= #TCQ po_counter_read_val[5:0]; reg [DQS_WIDTH6-1:0] simp_stg3_final_ns, simp_stg3_final_r, cmplx_stg3_final_ns, cmplx_stg3_final_r; always @(posedge clk) simp_stg3_final_r <= #TCQ simp_stg3_final_ns; always @(posedge clk) cmplx_stg3_final_r <= #TCQ cmplx_stg3_final_ns; output [DQS_WIDTH6-1:0] simp_stg3_final, cmplx_stg3_final; assign simp_stg3_final = simp_stg3_final_r; assign cmplx_stg3_final = cmplx_stg3_final_r; input [DQS_CNT_WIDTH:0] oclkdelay_calib_cnt; wire [DQS_WIDTH6-1:0] simp_stg3_final_shft = simp_stg3_final_r >> oclkdelay_calib_cnt 6; assign simp_stg3_final_sel = simp_stg3_final_shft[5:0]; wire [5:0] stg3_init = complex_oclkdelay_calib_start ? simp_stg3_final_sel : oclkdelay_init_val; wire signed [8:0] stg2_steps = stg3_r > stg3_init ? -9'sd2 * $signed({3'b0, (stg3_r - stg3_init)}) : 9'sd2 * $signed({3'b0, (stg3_init - stg3_r)}); wire signed [8:0] stg2_target_ns = $signed({3'b0, wl_po_fine_cnt_sel}) + stg2_steps; reg signed [8:0] stg2_target_r; always @ (posedge clk) stg2_target_r <= #TCQ stg2_target_ns; reg [5:0] stg2_final_ns, stg2_final_r; always @(posedge clk) stg2_final_r <= #TCQ stg2_final_ns; always @() stg2_final_ns = stg2_target_r[8] == 1'b1 ? 6'd0 : stg2_target_r > 9'd63 ? 6'd63 : stg2_target_r[5:0]; wire final_stg2_inc = stg2_final_r > po_counter_read_val_r; wire final_stg2_dec = stg2_final_r < po_counter_read_val_r; wire left_lim = stg3_r == lim2ocal_stg3_left_lim; wire right_lim = stg3_r == lim2ocal_stg3_right_lim; reg [1:0] ninety_offsets_ns, ninety_offsets_r; always @(posedge clk) ninety_offsets_r <= #TCQ ninety_offsets_ns; output [1:0] ninety_offsets; assign ninety_offsets = ninety_offsets_r; reg scanning_right_ns, scanning_right_r; always @(posedge clk) scanning_right_r <= #TCQ scanning_right_ns; output scanning_right; assign scanning_right = scanning_right_r; reg ocd_ktap_left_ns, ocd_ktap_left_r, ocd_ktap_right_ns, ocd_ktap_right_r; always @(posedge clk) ocd_ktap_left_r <= #TCQ ocd_ktap_left_ns; always @(posedge clk) ocd_ktap_right_r <= #TCQ ocd_ktap_right_ns; output ocd_ktap_left, ocd_ktap_right; assign ocd_ktap_left = ocd_ktap_left_r; assign ocd_ktap_right = ocd_ktap_right_r; reg ocd_edge_detect_rdy_ns, ocd_edge_detect_rdy_r; always @(posedge clk) ocd_edge_detect_rdy_r <= #TCQ ocd_edge_detect_rdy_ns; output ocd_edge_detect_rdy; assign ocd_edge_detect_rdy = ocd_edge_detect_rdy_r; input mmcm_edge_detect_done; input mmcm_lbclk_edge_aligned; input poc_backup; reg poc_backup_ns, poc_backup_r; always @(posedge clk) poc_backup_r <= #TCQ poc_backup_ns; reg taps_set_r; output taps_set; assign taps_set = taps_set_r; input phy_rddata_en_3; input [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty; input z2f, f2z, o2f, f2o; wire zero = f2z && z2f; wire noise = z2f && f2o; wire oneeighty = f2o && o2f; reg win_not_found; reg [1:0] ninety_offsets_final; reg [5:0] left, right, current_edge; always @() begin left = lim2ocal_stg3_left_lim; right = lim2ocal_stg3_right_lim; ninety_offsets_final = 2'd0; win_not_found = 1'b0; if (zero) begin left = fuzz2zero; right = zero2fuzz; end else if (noise) begin left = zero2fuzz; right = fuzz2oneeighty; ninety_offsets_final = 2'd1; end else if (oneeighty) begin left = fuzz2oneeighty; right = oneeighty2fuzz; ninety_offsets_final = 2'd2; end else if (z2f) begin right = zero2fuzz; end else if (f2o) begin left = fuzz2oneeighty; ninety_offsets_final = 2'd2; end else if (f2z) begin left = fuzz2zero; end else win_not_found = 1'b1; current_edge = ocd_ktap_left_r ? left : right; end // always @ begin output use_noise_window; assign use_noise_window = ninety_offsets == 2'd1; reg ocal_scan_win_not_found_ns, ocal_scan_win_not_found_r; always @(posedge clk) ocal_scan_win_not_found_r <= #TCQ ocal_scan_win_not_found_ns; output ocal_scan_win_not_found; assign ocal_scan_win_not_found = ocal_scan_win_not_found_r; wire inc_po_ns = current_edge > stg3_r; wire dec_po_ns = current_edge < stg3_r; reg inc_po_r, dec_po_r; always @(posedge clk) inc_po_r <= #TCQ inc_po_ns; always @(posedge clk) dec_po_r <= #TCQ dec_po_ns; input scan_right; wire left_stop = left_lim \|\| scan_right; wire right_stop = right_lim \|\| o2f; reg [4:0] resume_wait_ns, resume_wait_r; always @(posedge clk) resume_wait_r <= #TCQ resume_wait_ns; wire resume_wait = \|resume_wait_r; reg po_done_ns, po_done_r; always @(posedge clk) po_done_r <= #TCQ po_done_ns; input samp_done; input po_rdy; reg up_ns, up_r; always @(posedge clk) up_r <= #TCQ up_ns; reg [1:0] two_ns, two_r; always @(posedge clk) two_r <= #TCQ two_ns; /* wire stg2_zero = ~\|stg2_r; wire [8:0] stg2_2_zero = stg2_r[8] ? 9'd0 : stg2_r > 9'd63 ? 9'd63 : stg2_r; / reg [3:0] sm_ns, sm_r; always @(posedge clk) sm_r <= #TCQ sm_ns; ( dont_touch = "true" ) reg phy_rddata_en_3_second_ns, phy_rddata_en_3_second_r; always @(posedge clk) phy_rddata_en_3_second_r <= #TCQ phy_rddata_en_3_second_ns; always @() phy_rddata_en_3_second_ns = ~reset_scan && (phy_rddata_en_3 ? ~phy_rddata_en_3_second_r : phy_rddata_en_3_second_r); (* dont_touch = "true" ) wire use_samp_done = nCK_PER_CLK == 2 ? phy_rddata_en_3 && phy_rddata_en_3_second_r : phy_rddata_en_3; reg po_center_wait; reg po_slew; reg po_finish_scan; always @() begin // Default next state assignments. cmplx_samples_done_ns = cmplx_samples_done_r; cmplx_stg3_final_ns = cmplx_stg3_final_r; scanning_right_ns = scanning_right_r; ninety_offsets_ns = ninety_offsets_r; ocal_scan_win_not_found_ns = ocal_scan_win_not_found_r; ocd_edge_detect_rdy_ns = ocd_edge_detect_rdy_r; ocd_ktap_left_ns = ocd_ktap_left_r; ocd_ktap_right_ns = ocd_ktap_right_r; ocd2stg2_inc_r = 1'b0; ocd2stg2_dec_r = 1'b0; ocd2stg3_inc_r = 1'b0; ocd2stg3_dec_r = 1'b0; oclkdelay_center_calib_start_ns = oclkdelay_center_calib_start_r; oclkdelay_center_calib_done_ns = 1'b0; oclk_center_write_resume_ns = oclk_center_write_resume_r; po_center_wait = 1'b0; po_done_ns = po_done_r; po_finish_scan = 1'b0; po_slew = 1'b0; poc_backup_ns = poc_backup_r; scan_done_r = 1'b0; simp_stg3_final_ns = simp_stg3_final_r; sm_ns = sm_r; taps_set_r = 1'b0; up_ns = up_r; stg2_ns = stg2_r; stg3_ns = stg3_r; two_ns = two_r; resume_wait_ns = resume_wait_r; if (rst == 1'b1) begin // RESET next states cmplx_samples_done_ns = 1'b0; ocal_scan_win_not_found_ns = 1'b0; ocd_ktap_left_ns = 1'b0; ocd_ktap_right_ns = 1'b0; ocd_edge_detect_rdy_ns = 1'b0; oclk_center_write_resume_ns = 1'b0; oclkdelay_center_calib_start_ns = 1'b0; po_done_ns = 1'b1; resume_wait_ns = 5'd0; sm_ns = /AK("READY")/4'd0; end else // State based actions and next states. case (sm_r) /AL("READY")/4'd0:begin poc_backup_ns = 1'b0; stg2_ns = {3'b0, wl_po_fine_cnt_sel}; stg3_ns = stg3_init; scanning_right_ns = 1'b0; if (complex_oclkdelay_calib_start) cmplx_samples_done_ns = 1'b1; if (!reset_scan && ~resume_wait) begin cmplx_samples_done_ns = 1'b0; ocal_scan_win_not_found_ns = 1'b0; taps_set_r = 1'b1; sm_ns = /AK("SAMPLING")/4'd1; end end /AL("SAMPLING")/4'd1:begin if (samp_done && use_samp_done) begin if (complex_oclkdelay_calib_start) cmplx_samples_done_ns = 1'b1; scanning_right_ns = scanning_right_r \|\| left_stop; if (right_stop && scanning_right_r) begin oclkdelay_center_calib_start_ns = 1'b1; ocd_ktap_left_ns = 1'b1; ocal_scan_win_not_found_ns = win_not_found; sm_ns = /AK("SLEW_PO")/4'd3; end else begin if (scanning_right_ns) ocd2stg3_inc_r = 1'b1; else ocd2stg3_dec_r = 1'b1; sm_ns = /AK("PO_WAIT")/4'd2; end end end /AL("PO_WAIT")/4'd2:begin if (po_done_r && ~resume_wait) begin taps_set_r = 1'b1; sm_ns = /AK("SAMPLING")/4'd1; cmplx_samples_done_ns = 1'b0; end end /AL("SLEW_PO")/4'd3:begin po_slew = 1'b1; ninety_offsets_ns = \|ninety_offsets_final ? 2'b01 : 2'b00; if (~resume_wait) begin if (po_done_r) begin if (inc_po_r) ocd2stg3_inc_r = 1'b1; else if (dec_po_r) ocd2stg3_dec_r = 1'b1; else if (~resume_wait) begin cmplx_samples_done_ns = 1'b0; sm_ns = /AK("ALIGN_EDGES")/4'd4; oclk_center_write_resume_ns = 1'b1; end end // if (po_done) end end // case: 3'd3 /AL("ALIGN_EDGES")/4'd4: if (~resume_wait) begin if (mmcm_edge_detect_done) begin ocd_edge_detect_rdy_ns = 1'b0; if (ocd_ktap_left_r) begin ocd_ktap_left_ns = 1'b0; ocd_ktap_right_ns = 1'b1; oclk_center_write_resume_ns = 1'b0; sm_ns = /AK("SLEW_PO")/4'd3; end else if (ocd_ktap_right_r) begin ocd_ktap_right_ns = 1'b0; sm_ns = /AK("WAIT_ONE")/4'd5; end else if (~mmcm_lbclk_edge_aligned) begin sm_ns = /AK("DQS_STOP_WAIT")/4'd6; oclk_center_write_resume_ns = 1'b0; end else begin if (ninety_offsets_r != ninety_offsets_final && ocd_edge_detect_rdy_r) begin ninety_offsets_ns = ninety_offsets_r + 2'b01; sm_ns = /AK("WAIT_ONE")/4'd5; end else begin oclk_center_write_resume_ns = 1'b0; poc_backup_ns = poc_backup; // stg2_ns = stg2_2_zero; sm_ns = /AK("FINISH_SCAN")/4'd8; end end // else: !if(~mmcm_lbclk_edge_aligned) end else ocd_edge_detect_rdy_ns = 1'b1; end // if (~resume_wait) /AL("WAIT_ONE")/4'd5: sm_ns = /AK("ALIGN_EDGES")/4'd4; /AL("DQS_STOP_WAIT")/4'd6: if (~resume_wait) begin ocd2stg3_dec_r = 1'b1; sm_ns = /AK("CENTER_PO_WAIT")/4'd7; end /AL("CENTER_PO_WAIT")/4'd7: begin po_center_wait = 1'b1; // Kludge to get around limitation of the AUTOs symbols. if (po_done_r) begin sm_ns = /AK("ALIGN_EDGES")/4'd4; oclk_center_write_resume_ns = 1'b1; end end /AL("FINISH_SCAN")/4'd8: begin po_finish_scan = 1'b1; if (resume_wait_r == 5'd1) begin if (~poc_backup_r) begin oclkdelay_center_calib_done_ns = 1'b1; oclkdelay_center_calib_start_ns = 1'b0; end end if (~resume_wait) begin if (po_rdy) if (poc_backup_r) begin ocd2stg3_inc_r = 1'b1; poc_backup_ns = 1'b0; end else if (~final_stg2_inc && ~final_stg2_dec) begin if (complex_oclkdelay_calib_start) cmplx_stg3_final_ns[oclkdelay_calib_cnt6+:6] = stg3_r; else simp_stg3_final_ns[oclkdelay_calib_cnt6+:6] = stg3_r; sm_ns = /AK("READY")/4'd0; scan_done_r = 1'b1; end else begin ocd2stg2_inc_r = final_stg2_inc; ocd2stg2_dec_r = final_stg2_dec; end end // if (~resume_wait) end // case: 4'd8 endcase // case (sm_r) if (ocd2stg3_inc_r) begin stg3_ns = stg3_r + 6'h1; up_ns = 1'b0; end if (ocd2stg3_dec_r) begin stg3_ns = stg3_r - 6'h1; up_ns = 1'b1; end if (ocd2stg3_inc_r \|\| ocd2stg3_dec_r) begin po_done_ns = 1'b0; two_ns = 2'b00; end if (~po_done_r) if (po_rdy) if (two_r == 2'b10 \|\| po_center_wait \|\| po_slew \|\| po_finish_scan) po_done_ns = 1'b1; else begin two_ns = two_r + 2'b1; if (up_r) begin stg2_ns = stg2_r + 9'b1; if (stg2_r >= 9'd0 && stg2_r < 9'd63) ocd2stg2_inc_r = 1'b1; end else begin stg2_ns = stg2_r - 9'b1; if (stg2_r > 9'd0 && stg2_r <= 9'd63) ocd2stg2_dec_r = 1'b1; end end // else: !if(two_r == 2'b10) if (ocd_ktap_left_ns && ~ocd_ktap_left_r) resume_wait_ns = 5'b1; else if (oclk_center_write_resume_ns ^ oclk_center_write_resume_r) resume_wait_ns = 5'd15; else if (cmplx_samples_done_ns & ~cmplx_samples_done_r \|\| complex_oclkdelay_calib_start & reset_scan \|\| poc_backup_r & ocd2stg3_inc_r) resume_wait_ns = 5'd31; else if (\|resume_wait_r) resume_wait_ns = resume_wait_r - 5'd1; end // always @ begin endmodule
module axi_crossbar_v2_1_crossbar # ( parameter C_FAMILY = "none", parameter integer C_NUM_SLAVE_SLOTS = 1, parameter integer C_NUM_MASTER_SLOTS = 1, parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_PROTOCOL = 0, parameter [C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64-1:0] C_M_AXI_BASE_ADDR = {C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64{1'b1}}, parameter [C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64-1:0] C_M_AXI_HIGH_ADDR = {C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS64-1:0] C_S_AXI_BASE_ID = {C_NUM_SLAVE_SLOTS64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS64-1:0] C_S_AXI_HIGH_ID = {C_NUM_SLAVE_SLOTS64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_THREAD_ID_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_AWUSER_WIDTH = 1, parameter integer C_AXI_ARUSER_WIDTH = 1, parameter integer C_AXI_WUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_BUSER_WIDTH = 1, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_WRITE = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_READ = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_WRITE = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_READ = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_WRITE_CONNECTIVITY = {C_NUM_MASTER_SLOTS32{1'b1}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_READ_CONNECTIVITY = {C_NUM_MASTER_SLOTS32{1'b1}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_SINGLE_THREAD = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_WRITE_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_READ_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_WRITE_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_READ_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_ARB_PRIORITY = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_SECURE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_ERR_MODE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE = 0, parameter [(C_NUM_MASTER_SLOTS+1)32-1:0] C_W_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [(C_NUM_MASTER_SLOTS+1)32-1:0] C_R_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_W_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_R_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESETN, // Slave Interface Write Address Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_AWID, input wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR, input wire [C_NUM_SLAVE_SLOTS8-1:0] S_AXI_AWLEN, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_AWSIZE, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_AWBURST, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_AWLOCK, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWCACHE, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_AWPROT, // input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWREGION, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWQOS, input wire [C_NUM_SLAVE_SLOTSC_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWREADY, // Slave Interface Write Data Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_WID, input wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH-1:0] S_AXI_WDATA, input wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WLAST, input wire [C_NUM_SLAVE_SLOTSC_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WREADY, // Slave Interface Write Response Ports output wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_BID, output wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_BRESP, output wire [C_NUM_SLAVE_SLOTSC_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BREADY, // Slave Interface Read Address Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_ARID, input wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR, input wire [C_NUM_SLAVE_SLOTS8-1:0] S_AXI_ARLEN, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_ARSIZE, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_ARBURST, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_ARLOCK, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARCACHE, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_ARPROT, // input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARREGION, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARQOS, input wire [C_NUM_SLAVE_SLOTSC_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARREADY, // Slave Interface Read Data Ports output wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_RID, output wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH-1:0] S_AXI_RDATA, output wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_RRESP, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RLAST, output wire [C_NUM_SLAVE_SLOTSC_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RREADY, // Master Interface Write Address Port output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_AWID, output wire [C_NUM_MASTER_SLOTSC_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR, output wire [C_NUM_MASTER_SLOTS8-1:0] M_AXI_AWLEN, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_AWSIZE, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_AWBURST, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_AWLOCK, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWCACHE, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_AWPROT, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWREGION, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWQOS, output wire [C_NUM_MASTER_SLOTSC_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWREADY, // Master Interface Write Data Ports output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_WID, output wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH-1:0] M_AXI_WDATA, output wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WLAST, output wire [C_NUM_MASTER_SLOTSC_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WREADY, // Master Interface Write Response Ports input wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_BID, input wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_BRESP, input wire [C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BREADY, // Master Interface Read Address Port output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_ARID, output wire [C_NUM_MASTER_SLOTSC_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR, output wire [C_NUM_MASTER_SLOTS8-1:0] M_AXI_ARLEN, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_ARSIZE, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_ARBURST, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_ARLOCK, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARCACHE, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_ARPROT, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARREGION, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARQOS, output wire [C_NUM_MASTER_SLOTSC_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARREADY, // Master Interface Read Data Ports input wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_RID, input wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH-1:0] M_AXI_RDATA, input wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_RRESP, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RLAST, input wire [C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RREADY ); localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_NUM_MASTER_SLOTS_LOG = f_ceil_log2(C_NUM_MASTER_SLOTS); localparam integer P_NUM_SLAVE_SLOTS_LOG = f_ceil_log2((C_NUM_SLAVE_SLOTS>1) ? C_NUM_SLAVE_SLOTS : 2); localparam integer P_AXI_WID_WIDTH = (C_AXI_PROTOCOL == P_AXI3) ? C_AXI_ID_WIDTH : 1; localparam integer P_ST_AWMESG_WIDTH = 2+4+4 + C_AXI_AWUSER_WIDTH; localparam integer P_AA_AWMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_AWMESG_WIDTH; localparam integer P_ST_ARMESG_WIDTH = 2+4+4 + C_AXI_ARUSER_WIDTH; localparam integer P_AA_ARMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_ARMESG_WIDTH; localparam integer P_ST_BMESG_WIDTH = 2 + C_AXI_BUSER_WIDTH; localparam integer P_ST_RMESG_WIDTH = 2 + C_AXI_RUSER_WIDTH + C_AXI_DATA_WIDTH; localparam integer P_WR_WMESG_WIDTH = C_AXI_DATA_WIDTH + C_AXI_DATA_WIDTH/8 + C_AXI_WUSER_WIDTH + P_AXI_WID_WIDTH; localparam [31:0] P_BYPASS = 32'h00000000; localparam [31:0] P_FWD_REV = 32'h00000001; localparam [31:0] P_SIMPLE = 32'h00000007; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_READ = {1'b1, C_M_AXI_SUPPORTS_READ[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_WRITE = {1'b1, C_M_AXI_SUPPORTS_WRITE[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_WRITE_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_WRITE_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS32]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_READ_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_READ_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS32]}; localparam [C_NUM_SLAVE_SLOTS32-1:0] P_S_AXI_WRITE_CONNECTIVITY = f_si_write_connectivity(0); localparam [C_NUM_SLAVE_SLOTS32-1:0] P_S_AXI_READ_CONNECTIVITY = f_si_read_connectivity(0); localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_READ_ISSUING = {32'h00000001, C_M_AXI_READ_ISSUING[0+:C_NUM_MASTER_SLOTS32]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_WRITE_ISSUING = {32'h00000001, C_M_AXI_WRITE_ISSUING[0+:C_NUM_MASTER_SLOTS32]}; localparam P_DECERR = 2'b11; //--------------------------------------------------------------------------- // Functions //--------------------------------------------------------------------------- // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // Isolate thread bits of input S_ID and add to BASE_ID (RNG00) to form MI-side ID value // only for end-point SI-slots function [C_AXI_ID_WIDTH-1:0] f_extend_ID ( input [C_AXI_ID_WIDTH-1:0] s_id, input integer slot ); begin f_extend_ID = C_S_AXI_BASE_ID[slot64+:C_AXI_ID_WIDTH] \| (s_id & (C_S_AXI_BASE_ID[slot64+:C_AXI_ID_WIDTH] ^ C_S_AXI_HIGH_ID[slot64+:C_AXI_ID_WIDTH])); end endfunction // Write connectivity array transposed function [C_NUM_SLAVE_SLOTS32-1:0] f_si_write_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot32+mi_slot] = C_M_AXI_WRITE_CONNECTIVITY[mi_slot32+si_slot]; end end f_si_write_connectivity = result; end endfunction // Read connectivity array transposed function [C_NUM_SLAVE_SLOTS32-1:0] f_si_read_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot32+mi_slot] = C_M_AXI_READ_CONNECTIVITY[mi_slot32+si_slot]; end end f_si_read_connectivity = result; end endfunction genvar gen_si_slot; genvar gen_mi_slot; wire [C_NUM_SLAVE_SLOTSP_ST_AWMESG_WIDTH-1:0] si_st_awmesg ; wire [C_NUM_SLAVE_SLOTSP_ST_AWMESG_WIDTH-1:0] st_tmp_awmesg ; wire [C_NUM_SLAVE_SLOTSP_AA_AWMESG_WIDTH-1:0] tmp_aa_awmesg ; wire [P_AA_AWMESG_WIDTH-1:0] aa_mi_awmesg ; wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] st_aa_awid ; wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] st_aa_awaddr ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_awlen ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_awsize ; wire [C_NUM_SLAVE_SLOTS2-1:0] st_aa_awlock ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_awprot ; wire [C_NUM_SLAVE_SLOTS4-1:0] st_aa_awregion ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_awerror ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_awtarget_enc ; wire [P_NUM_SLAVE_SLOTS_LOG1-1:0] aa_wm_awgrant_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_awvalid_qual ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_ss_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_ss_awready ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_wr_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_wr_awready ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_aa_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_aa_awready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] sa_wm_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] sa_wm_awready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awready ; wire aa_sa_awvalid ; wire aa_sa_awready ; wire aa_mi_arready ; wire mi_awvalid_en ; wire sa_wm_awvalid_en ; wire sa_wm_awready_mux ; wire [C_NUM_SLAVE_SLOTSP_ST_ARMESG_WIDTH-1:0] si_st_armesg ; wire [C_NUM_SLAVE_SLOTSP_ST_ARMESG_WIDTH-1:0] st_tmp_armesg ; wire [C_NUM_SLAVE_SLOTSP_AA_ARMESG_WIDTH-1:0] tmp_aa_armesg ; wire [P_AA_ARMESG_WIDTH-1:0] aa_mi_armesg ; wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] st_aa_arid ; wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] st_aa_araddr ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_arlen ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_arsize ; wire [C_NUM_SLAVE_SLOTS2-1:0] st_aa_arlock ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_arprot ; wire [C_NUM_SLAVE_SLOTS4-1:0] st_aa_arregion ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_arerror ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_artarget_hot ; wire [C_NUM_SLAVE_SLOTS(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_artarget_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_artarget_hot ; wire [P_NUM_SLAVE_SLOTS_LOG1-1:0] aa_mi_argrant_enc ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arvalid_qual ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_arvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_arready ; wire aa_mi_arvalid ; wire mi_awready_mux ; wire [C_NUM_SLAVE_SLOTSP_ST_BMESG_WIDTH-1:0] st_si_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)P_ST_BMESG_WIDTH-1:0] st_mr_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] st_mr_bid ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] st_mr_bresp ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_BUSER_WIDTH-1:0] st_mr_buser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_mr_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)P_NUM_SLAVE_SLOTS_LOG-1:0] debug_bid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] bid_match ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_bid ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] mi_bresp ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_BUSER_WIDTH-1:0] mi_buser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] bready_carry ; wire [C_NUM_SLAVE_SLOTSP_ST_RMESG_WIDTH-1:0] st_si_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)P_ST_RMESG_WIDTH-1:0] st_mr_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] st_mr_rid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] st_mr_rdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_RUSER_WIDTH-1:0] st_mr_ruser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rlast ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] st_mr_rresp ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_mr_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)P_NUM_SLAVE_SLOTS_LOG-1:0] debug_rid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] rid_match ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_rid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] mi_rdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_RUSER_WIDTH-1:0] mi_ruser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rlast ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] mi_rresp ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] rready_carry ; wire [C_NUM_SLAVE_SLOTSP_WR_WMESG_WIDTH-1:0] si_wr_wmesg ; wire [C_NUM_SLAVE_SLOTSP_WR_WMESG_WIDTH-1:0] wr_wm_wmesg ; wire [C_NUM_SLAVE_SLOTS1-1:0] wr_wm_wlast ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wvalid ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wready ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wready ; wire [(C_NUM_MASTER_SLOTS+1)P_WR_WMESG_WIDTH-1:0] wm_mr_wmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] wm_mr_wdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH/8-1:0] wm_mr_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] wm_mr_wid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_WUSER_WIDTH-1:0] wm_mr_wuser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wlast ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wready ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] mi_wdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH/8-1:0] mi_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_WUSER_WIDTH-1:0] mi_wuser ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_wid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wlast ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] w_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] w_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] r_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] r_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awmaxissuing ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_armaxissuing ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] w_issuing_cnt ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] r_issuing_cnt ; reg [8-1:0] debug_aw_trans_seq_i ; reg [8-1:0] debug_ar_trans_seq_i ; wire [(C_NUM_MASTER_SLOTS+1)8-1:0] debug_w_trans_seq_i ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] debug_w_beat_cnt_i ; reg aresetn_d = 1'b0; // Reset delay register always @(posedge ACLK) begin if (~ARESETN) begin aresetn_d <= 1'b0; end else begin aresetn_d <= ARESETN; end end wire reset; assign reset = ~aresetn_d; generate for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_slave_slots if (C_S_AXI_SUPPORTS_READ[gen_si_slot]) begin : gen_si_read axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (read channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_READ), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_READ_ACCEPTANCE[gen_si_slot32+:32]), .C_ACCEPTANCE_LOG (C_R_ACCEPT_WIDTH[gen_si_slot32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_ARMESG_WIDTH), .C_RMESG_WIDTH (P_ST_RMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_READ_CONNECTIVITY[gen_si_slot32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_ar ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_ARID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_ARADDR[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_ARLEN[gen_si_slot8+:8]), .S_ASIZE (S_AXI_ARSIZE[gen_si_slot3+:3]), .S_ABURST (S_AXI_ARBURST[gen_si_slot2+:2]), .S_ALOCK (S_AXI_ARLOCK[gen_si_slot2+:2]), .S_APROT (S_AXI_ARPROT[gen_si_slot3+:3]), // .S_AREGION (S_AXI_ARREGION[gen_si_slot4+:4]), .S_AMESG (si_st_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .S_AVALID (S_AXI_ARVALID[gen_si_slot]), .S_AREADY (S_AXI_ARREADY[gen_si_slot]), .M_AID (st_aa_arid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_araddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_arlen[gen_si_slot8+:8]), .M_ASIZE (st_aa_arsize[gen_si_slot3+:3]), .M_ALOCK (st_aa_arlock[gen_si_slot2+:2]), .M_APROT (st_aa_arprot[gen_si_slot3+:3]), .M_AREGION (st_aa_arregion[gen_si_slot4+:4]), .M_AMESG (st_tmp_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .M_ATARGET_HOT (st_aa_artarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_artarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_arerror[gen_si_slot8+:8]), .M_AVALID_QUAL (st_aa_arvalid_qual[gen_si_slot]), .M_AVALID (st_aa_arvalid[gen_si_slot]), .M_AREADY (st_aa_arready[gen_si_slot]), .S_RID (S_AXI_RID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH]), .S_RLAST (S_AXI_RLAST[gen_si_slot]), .S_RVALID (S_AXI_RVALID[gen_si_slot]), .S_RREADY (S_AXI_RREADY[gen_si_slot]), .M_RID (st_mr_rid), .M_RLAST (st_mr_rlast), .M_RMESG (st_mr_rmesg), .M_RVALID (st_mr_rvalid), .M_RREADY (st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_rid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_ar_trans_seq_i : 8'h0) ); assign si_st_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH] = { S_AXI_ARUSER[gen_si_slotC_AXI_ARUSER_WIDTH+:C_AXI_ARUSER_WIDTH], S_AXI_ARQOS[gen_si_slot4+:4], S_AXI_ARCACHE[gen_si_slot4+:4], S_AXI_ARBURST[gen_si_slot2+:2] }; assign tmp_aa_armesg[gen_si_slotP_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = { st_tmp_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH], st_aa_arregion[gen_si_slot4+:4], st_aa_arprot[gen_si_slot3+:3], st_aa_arlock[gen_si_slot2+:2], st_aa_arsize[gen_si_slot3+:3], st_aa_arlen[gen_si_slot8+:8], st_aa_araddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_arid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_RRESP[gen_si_slot2+:2] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+:2]; assign S_AXI_RUSER[gen_si_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+2 +: C_AXI_RUSER_WIDTH]; assign S_AXI_RDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+2+C_AXI_RUSER_WIDTH +: C_AXI_DATA_WIDTH]; end else begin : gen_no_si_read assign S_AXI_ARREADY[gen_si_slot] = 1'b0; assign st_aa_arvalid[gen_si_slot] = 1'b0; assign st_aa_arvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_armesg[gen_si_slotP_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = 0; assign S_AXI_RID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_RRESP[gen_si_slot2+:2] = 0; assign S_AXI_RUSER[gen_si_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign S_AXI_RDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign S_AXI_RVALID[gen_si_slot] = 1'b0; assign S_AXI_RLAST[gen_si_slot] = 1'b0; assign st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_artarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_read if (C_S_AXI_SUPPORTS_WRITE[gen_si_slot]) begin : gen_si_write axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (write channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_WRITE), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_WRITE_ACCEPTANCE[gen_si_slot32+:32]), .C_ACCEPTANCE_LOG (C_W_ACCEPT_WIDTH[gen_si_slot32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_AWMESG_WIDTH), .C_RMESG_WIDTH (P_ST_BMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_WRITE_CONNECTIVITY[gen_si_slot32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_aw ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_AWID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_AWADDR[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_AWLEN[gen_si_slot8+:8]), .S_ASIZE (S_AXI_AWSIZE[gen_si_slot3+:3]), .S_ABURST (S_AXI_AWBURST[gen_si_slot2+:2]), .S_ALOCK (S_AXI_AWLOCK[gen_si_slot2+:2]), .S_APROT (S_AXI_AWPROT[gen_si_slot3+:3]), // .S_AREGION (S_AXI_AWREGION[gen_si_slot4+:4]), .S_AMESG (si_st_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .S_AVALID (S_AXI_AWVALID[gen_si_slot]), .S_AREADY (S_AXI_AWREADY[gen_si_slot]), .M_AID (st_aa_awid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_awaddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_awlen[gen_si_slot8+:8]), .M_ASIZE (st_aa_awsize[gen_si_slot3+:3]), .M_ALOCK (st_aa_awlock[gen_si_slot2+:2]), .M_APROT (st_aa_awprot[gen_si_slot3+:3]), .M_AREGION (st_aa_awregion[gen_si_slot4+:4]), .M_AMESG (st_tmp_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .M_ATARGET_HOT (st_aa_awtarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_awtarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_awerror[gen_si_slot8+:8]), .M_AVALID_QUAL (st_aa_awvalid_qual[gen_si_slot]), .M_AVALID (st_ss_awvalid[gen_si_slot]), .M_AREADY (st_ss_awready[gen_si_slot]), .S_RID (S_AXI_BID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH]), .S_RLAST (), .S_RVALID (S_AXI_BVALID[gen_si_slot]), .S_RREADY (S_AXI_BREADY[gen_si_slot]), .M_RID (st_mr_bid), .M_RLAST ({(C_NUM_MASTER_SLOTS+1){1'b1}}), .M_RMESG (st_mr_bmesg), .M_RVALID (st_mr_bvalid), .M_RREADY (st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_bid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_aw_trans_seq_i : 8'h0) ); // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign si_st_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH] = { S_AXI_AWUSER[gen_si_slotC_AXI_AWUSER_WIDTH+:C_AXI_AWUSER_WIDTH], S_AXI_AWQOS[gen_si_slot4+:4], S_AXI_AWCACHE[gen_si_slot4+:4], S_AXI_AWBURST[gen_si_slot2+:2] }; assign tmp_aa_awmesg[gen_si_slotP_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = { st_tmp_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH], st_aa_awregion[gen_si_slot4+:4], st_aa_awprot[gen_si_slot3+:3], st_aa_awlock[gen_si_slot2+:2], st_aa_awsize[gen_si_slot3+:3], st_aa_awlen[gen_si_slot8+:8], st_aa_awaddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_awid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_BRESP[gen_si_slot2+:2] = st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+:2]; assign S_AXI_BUSER[gen_si_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+2 +: C_AXI_BUSER_WIDTH]; // AW SI-transactor transfer completes upon completion of both W-router address acceptance (command push) and AW arbitration axi_crossbar_v2_1_splitter # // "SS": Splitter from SI-Transactor (write channel) ( .C_NUM_M (2) ) splitter_aw_si ( .ACLK (ACLK), .ARESET (reset), .S_VALID (st_ss_awvalid[gen_si_slot]), .S_READY (st_ss_awready[gen_si_slot]), .M_VALID ({ss_wr_awvalid[gen_si_slot], ss_aa_awvalid[gen_si_slot]}), .M_READY ({ss_wr_awready[gen_si_slot], ss_aa_awready[gen_si_slot]}) ); axi_crossbar_v2_1_wdata_router # // "WR": Write data Router ( .C_FAMILY (C_FAMILY), .C_NUM_MASTER_SLOTS (C_NUM_MASTER_SLOTS+1), .C_SELECT_WIDTH (P_NUM_MASTER_SLOTS_LOG+1), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ACCEPT_WIDTH[gen_si_slot32+:6]) ) wdata_router_w ( .ACLK (ACLK), .ARESET (reset), // Write transfer input from the current SI-slot .S_WMESG (si_wr_wmesg[gen_si_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .S_WLAST (S_AXI_WLAST[gen_si_slot]), .S_WVALID (S_AXI_WVALID[gen_si_slot]), .S_WREADY (S_AXI_WREADY[gen_si_slot]), // Vector of write transfer outputs to each MI-slot's W-mux .M_WMESG (wr_wm_wmesg[gen_si_slot(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH]), .M_WLAST (wr_wm_wlast[gen_si_slot]), .M_WVALID (wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_WREADY (wr_tmp_wready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), // AW command push from local SI-slot .S_ASELECT (st_aa_awtarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), // Target MI-slot .S_AVALID (ss_wr_awvalid[gen_si_slot]), .S_AREADY (ss_wr_awready[gen_si_slot]) ); assign si_wr_wmesg[gen_si_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH] = { ((C_AXI_PROTOCOL == P_AXI3) ? f_extend_ID(S_AXI_WID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot) : 1'b0), S_AXI_WUSER[gen_si_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH], S_AXI_WSTRB[gen_si_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8], S_AXI_WDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] }; end else begin : gen_no_si_write assign S_AXI_AWREADY[gen_si_slot] = 1'b0; assign ss_aa_awvalid[gen_si_slot] = 1'b0; assign st_aa_awvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_awmesg[gen_si_slotP_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = 0; assign S_AXI_BID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_BRESP[gen_si_slot2+:2] = 0; assign S_AXI_BUSER[gen_si_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign S_AXI_BVALID[gen_si_slot] = 1'b0; assign st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign S_AXI_WREADY[gen_si_slot] = 1'b0; assign wr_wm_wmesg[gen_si_slot(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH] = 0; assign wr_wm_wlast[gen_si_slot] = 1'b0; assign wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_awtarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_write end // gen_slave_slots for (gen_mi_slot=0; gen_mi_slot<C_NUM_MASTER_SLOTS+1; gen_mi_slot=gen_mi_slot+1) begin : gen_master_slots if (P_M_AXI_SUPPORTS_READ[gen_mi_slot]) begin : gen_mi_read if (C_NUM_SLAVE_SLOTS>1) begin : gen_rid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_READ_CONNECTIVITY[gen_mi_slot32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) rid_decoder_inst ( .ADDR (st_mr_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_rid_target_i[gen_mi_slotP_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (rid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_rid_decoder assign tmp_mr_rid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign rid_match[gen_mi_slot] = 1'b1; end assign st_mr_rmesg[gen_mi_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = { st_mr_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH], st_mr_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH], st_mr_rresp[gen_mi_slot2+:2] }; end else begin : gen_no_mi_read assign tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign rid_match[gen_mi_slot] = 1'b0; assign st_mr_rmesg[gen_mi_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = 0; end // gen_mi_read if (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]) begin : gen_mi_write if (C_NUM_SLAVE_SLOTS>1) begin : gen_bid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_WRITE_CONNECTIVITY[gen_mi_slot32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) bid_decoder_inst ( .ADDR (st_mr_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_bid_target_i[gen_mi_slotP_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (bid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_bid_decoder assign tmp_mr_bid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign bid_match[gen_mi_slot] = 1'b1; end axi_crossbar_v2_1_wdata_mux # // "WM": Write data Mux, per MI-slot (incl error-handler) ( .C_FAMILY (C_FAMILY), .C_NUM_SLAVE_SLOTS (C_NUM_SLAVE_SLOTS), .C_SELECT_WIDTH (P_NUM_SLAVE_SLOTS_LOG), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]) ) wdata_mux_w ( .ACLK (ACLK), .ARESET (reset), // Vector of write transfer inputs from each SI-slot's W-router .S_WMESG (wr_wm_wmesg), .S_WLAST (wr_wm_wlast), .S_WVALID (tmp_wm_wvalid[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .S_WREADY (tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), // Write transfer output to the current MI-slot .M_WMESG (wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .M_WLAST (wm_mr_wlast[gen_mi_slot]), .M_WVALID (wm_mr_wvalid[gen_mi_slot]), .M_WREADY (wm_mr_wready[gen_mi_slot]), // AW command push from AW arbiter output .S_ASELECT (aa_wm_awgrant_enc), // SI-slot selected by arbiter .S_AVALID (sa_wm_awvalid[gen_mi_slot]), .S_AREADY (sa_wm_awready[gen_mi_slot]) ); if (C_DEBUG) begin : gen_debug_w // DEBUG WRITE BEAT COUNTER always @(posedge ACLK) begin if (reset) begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= 0; end else begin if (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot]) begin if (mi_wlast[gen_mi_slot]) begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= 0; end else begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= debug_w_beat_cnt_i[gen_mi_slot8+:8] + 1; end end end end // clocked process // DEBUG W-CHANNEL TRANSACTION SEQUENCE QUEUE axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]), .C_USE_FULL (0) ) debug_w_seq_fifo ( .ACLK (ACLK), .ARESET (reset), .S_MESG (debug_aw_trans_seq_i), .S_VALID (sa_wm_awvalid[gen_mi_slot]), .S_READY (), .M_MESG (debug_w_trans_seq_i[gen_mi_slot8+:8]), .M_VALID (), .M_READY (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot] & mi_wlast[gen_mi_slot]) ); end // gen_debug_w assign wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH +: C_AXI_DATA_WIDTH]; assign wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH +: C_AXI_DATA_WIDTH/8]; assign wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+C_AXI_DATA_WIDTH/8 +: C_AXI_WUSER_WIDTH]; assign wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+(C_AXI_DATA_WIDTH/8)+C_AXI_WUSER_WIDTH +: P_AXI_WID_WIDTH]; assign st_mr_bmesg[gen_mi_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = { st_mr_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH], st_mr_bresp[gen_mi_slot2+:2] }; end else begin : gen_no_mi_write assign tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign bid_match[gen_mi_slot] = 1'b0; assign wm_mr_wvalid[gen_mi_slot] = 0; assign wm_mr_wlast[gen_mi_slot] = 0; assign wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = 0; assign wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = 0; assign wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign st_mr_bmesg[gen_mi_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = 0; assign tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign sa_wm_awready[gen_mi_slot] = 0; end // gen_mi_write for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_trans_si // Transpose handshakes from W-router (SxM) to W-mux (MxS). assign tmp_wm_wvalid[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot] = wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; assign wr_tmp_wready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; // Transpose response enables from ID decoders (MxS) to si_transactors (SxM). assign st_tmp_bid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; assign st_tmp_rid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; end // gen_trans_si assign bready_carry[gen_mi_slot] = st_tmp_bready[gen_mi_slot]; assign rready_carry[gen_mi_slot] = st_tmp_rready[gen_mi_slot]; for (gen_si_slot=1; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_resp_carry_si assign bready_carry[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_BREADY if ... bready_carry[(gen_si_slot-1)(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] \| // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates BREADY for that MI-slot. assign rready_carry[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_RREADY if ... rready_carry[(gen_si_slot-1)(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] \| // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates RREADY for that MI-slot. end // gen_resp_carry_si assign w_cmd_push[gen_mi_slot] = mi_awvalid[gen_mi_slot] && mi_awready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_push[gen_mi_slot] = mi_arvalid[gen_mi_slot] && mi_arready[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; assign w_cmd_pop[gen_mi_slot] = st_mr_bvalid[gen_mi_slot] && st_mr_bready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_pop[gen_mi_slot] = st_mr_rvalid[gen_mi_slot] && st_mr_rready[gen_mi_slot] && st_mr_rlast[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; // Disqualify arbitration of SI-slot if targeted MI-slot has reached its issuing limit. assign mi_awmaxissuing[gen_mi_slot] = (w_issuing_cnt[gen_mi_slot8 +: (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] == P_M_AXI_WRITE_ISSUING[gen_mi_slot32 +: (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)]) & ~w_cmd_pop[gen_mi_slot]; assign mi_armaxissuing[gen_mi_slot] = (r_issuing_cnt[gen_mi_slot8 +: (C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] == P_M_AXI_READ_ISSUING[gen_mi_slot32 +: (C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)]) & ~r_cmd_pop[gen_mi_slot]; always @(posedge ACLK) begin if (reset) begin w_issuing_cnt[gen_mi_slot8+:8] <= 0; // Some high-order bits remain constant 0 r_issuing_cnt[gen_mi_slot8+:8] <= 0; // Some high-order bits remain constant 0 end else begin if (w_cmd_push[gen_mi_slot] && ~w_cmd_pop[gen_mi_slot]) begin w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] + 1; end else if (w_cmd_pop[gen_mi_slot] && ~w_cmd_push[gen_mi_slot] && (\|w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)])) begin w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] - 1; end if (r_cmd_push[gen_mi_slot] && ~r_cmd_pop[gen_mi_slot]) begin r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] + 1; end else if (r_cmd_pop[gen_mi_slot] && ~r_cmd_push[gen_mi_slot] && (\|r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)])) begin r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] - 1; end end end // Clocked process // Reg-slice must break combinatorial path from M_BID and M_RID inputs to M_BREADY and M_RREADY outputs. // (See m_rready_i and m_resp_en combinatorial assignments in si_transactor.) // Reg-slice incurs +1 latency, but no bubble-cycles. axi_register_slice_v2_1_axi_register_slice # // "MR": MI-side R/B-channel Reg-slice, per MI-slot (pass-through if only 1 SI-slot configured) ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL ((C_AXI_PROTOCOL == P_AXI3) ? P_AXI3 : P_AXI4), .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (1), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (C_AXI_SUPPORTS_USER_SIGNALS), .C_AXI_AWUSER_WIDTH (1), .C_AXI_ARUSER_WIDTH (1), .C_AXI_WUSER_WIDTH (C_AXI_WUSER_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_REG_CONFIG_AW (P_BYPASS), .C_REG_CONFIG_AR (P_BYPASS), .C_REG_CONFIG_W (P_BYPASS), .C_REG_CONFIG_R (P_M_AXI_SUPPORTS_READ[gen_mi_slot] ? P_FWD_REV : P_BYPASS), .C_REG_CONFIG_B (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot] ? P_SIMPLE : P_BYPASS) ) reg_slice_mi ( .aresetn (ARESETN), .aclk (ACLK), .s_axi_awid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_awaddr ({1{1'b0}}), .s_axi_awlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_awsize ({3{1'b0}}), .s_axi_awburst ({2{1'b0}}), .s_axi_awlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_awcache ({4{1'b0}}), .s_axi_awprot ({3{1'b0}}), .s_axi_awregion ({4{1'b0}}), .s_axi_awqos ({4{1'b0}}), .s_axi_awuser ({1{1'b0}}), .s_axi_awvalid ({1{1'b0}}), .s_axi_awready (), .s_axi_wid (wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .s_axi_wdata (wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .s_axi_wstrb (wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .s_axi_wlast (wm_mr_wlast[gen_mi_slot]), .s_axi_wuser (wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .s_axi_wvalid (wm_mr_wvalid[gen_mi_slot]), .s_axi_wready (wm_mr_wready[gen_mi_slot]), .s_axi_bid (st_mr_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_bresp (st_mr_bresp[gen_mi_slot2+:2] ), .s_axi_buser (st_mr_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .s_axi_bvalid (st_mr_bvalid[gen_mi_slot1+:1] ), .s_axi_bready (st_mr_bready[gen_mi_slot1+:1] ), .s_axi_arid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_araddr ({1{1'b0}}), .s_axi_arlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_arsize ({3{1'b0}}), .s_axi_arburst ({2{1'b0}}), .s_axi_arlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_arcache ({4{1'b0}}), .s_axi_arprot ({3{1'b0}}), .s_axi_arregion ({4{1'b0}}), .s_axi_arqos ({4{1'b0}}), .s_axi_aruser ({1{1'b0}}), .s_axi_arvalid ({1{1'b0}}), .s_axi_arready (), .s_axi_rid (st_mr_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_rdata (st_mr_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .s_axi_rresp (st_mr_rresp[gen_mi_slot2+:2] ), .s_axi_rlast (st_mr_rlast[gen_mi_slot1+:1] ), .s_axi_ruser (st_mr_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .s_axi_rvalid (st_mr_rvalid[gen_mi_slot1+:1] ), .s_axi_rready (st_mr_rready[gen_mi_slot1+:1] ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready ({1{1'b0}}), .m_axi_wid (mi_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .m_axi_wdata (mi_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .m_axi_wstrb (mi_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .m_axi_wlast (mi_wlast[gen_mi_slot]), .m_axi_wuser (mi_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .m_axi_wvalid (mi_wvalid[gen_mi_slot]), .m_axi_wready (mi_wready[gen_mi_slot]), .m_axi_bid (mi_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_bresp (mi_bresp[gen_mi_slot2+:2] ), .m_axi_buser (mi_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .m_axi_bvalid (mi_bvalid[gen_mi_slot1+:1] ), .m_axi_bready (mi_bready[gen_mi_slot1+:1] ), .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready ({1{1'b0}}), .m_axi_rid (mi_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_rdata (mi_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .m_axi_rresp (mi_rresp[gen_mi_slot2+:2] ), .m_axi_rlast (mi_rlast[gen_mi_slot1+:1] ), .m_axi_ruser (mi_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .m_axi_rvalid (mi_rvalid[gen_mi_slot1+:1] ), .m_axi_rready (mi_rready[gen_mi_slot1+:1] ) ); end // gen_master_slots (Next gen_mi_slot) // Highest row of ready_carry contains accumulated OR across all SI-slots, for each MI-slot. assign st_mr_bready = bready_carry[(C_NUM_SLAVE_SLOTS-1)(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; assign st_mr_rready = rready_carry[(C_NUM_SLAVE_SLOTS-1)(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; // Assign MI-side B, R and W channel ports (exclude error handler signals). assign mi_bid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] = M_AXI_BID; assign mi_bvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_BVALID; assign mi_bresp[0+:C_NUM_MASTER_SLOTS2] = M_AXI_BRESP; assign mi_buser[0+:C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH] = M_AXI_BUSER; assign M_AXI_BREADY = mi_bready[0+:C_NUM_MASTER_SLOTS]; assign mi_rid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] = M_AXI_RID; assign mi_rlast[0+:C_NUM_MASTER_SLOTS] = M_AXI_RLAST; assign mi_rvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_RVALID; assign mi_rresp[0+:C_NUM_MASTER_SLOTS2] = M_AXI_RRESP; assign mi_ruser[0+:C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH] = M_AXI_RUSER; assign mi_rdata[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH] = M_AXI_RDATA; assign M_AXI_RREADY = mi_rready[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WLAST = mi_wlast[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WVALID = mi_wvalid[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WUSER = mi_wuser[0+:C_NUM_MASTER_SLOTSC_AXI_WUSER_WIDTH]; assign M_AXI_WID = (C_AXI_PROTOCOL == P_AXI3) ? mi_wid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] : 0; assign M_AXI_WDATA = mi_wdata[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH]; assign M_AXI_WSTRB = mi_wstrb[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH/8]; assign mi_wready[0+:C_NUM_MASTER_SLOTS] = M_AXI_WREADY; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AW channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_AWMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_aw ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AW command request inputs .S_MESG (tmp_aa_awmesg), .S_TARGET_HOT (st_aa_awtarget_hot), .S_VALID (ss_aa_awvalid), .S_VALID_QUAL (st_aa_awvalid_qual), .S_READY (ss_aa_awready), // Granted AW command output .M_MESG (aa_mi_awmesg), .M_TARGET_HOT (aa_mi_awtarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_wm_awgrant_enc), // SI-slot index of granted command .M_VALID (aa_sa_awvalid), .M_READY (aa_sa_awready), .ISSUING_LIMIT (mi_awmaxissuing) ); // Broadcast AW transfer payload to all MI-slots assign M_AXI_AWID = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_AWADDR = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_AWLEN = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_AWSIZE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_AWLOCK = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_AWPROT = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_AWREGION = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_AWBURST = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_AWCACHE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_AWQOS = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_AWUSER = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_AWUSER_WIDTH]}}; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AR channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_ARMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_ar ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AR command request inputs .S_MESG (tmp_aa_armesg), .S_TARGET_HOT (st_aa_artarget_hot), .S_VALID_QUAL (st_aa_arvalid_qual), .S_VALID (st_aa_arvalid), .S_READY (st_aa_arready), // Granted AR command output .M_MESG (aa_mi_armesg), .M_TARGET_HOT (aa_mi_artarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_mi_argrant_enc), .M_VALID (aa_mi_arvalid), // SI-slot index of granted command .M_READY (aa_mi_arready), .ISSUING_LIMIT (mi_armaxissuing) ); if (C_DEBUG) begin : gen_debug_trans_seq // DEBUG WRITE TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_aw_trans_seq_i <= 1; end else begin if (aa_sa_awvalid && aa_sa_awready) begin debug_aw_trans_seq_i <= debug_aw_trans_seq_i + 1; end end end // DEBUG READ TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_ar_trans_seq_i <= 1; end else begin if (aa_mi_arvalid && aa_mi_arready) begin debug_ar_trans_seq_i <= debug_ar_trans_seq_i + 1; end end end end // gen_debug_trans_seq // Broadcast AR transfer payload to all MI-slots assign M_AXI_ARID = {C_NUM_MASTER_SLOTS{aa_mi_armesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_ARADDR = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_ARLEN = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_ARSIZE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_ARLOCK = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_ARPROT = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_ARREGION = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_ARBURST = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_ARCACHE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_ARQOS = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_ARUSER = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_ARUSER_WIDTH]}}; // AW arbiter command transfer completes upon completion of both M-side AW-channel transfer and W-mux address acceptance (command push). axi_crossbar_v2_1_splitter # // "SA": Splitter for Write Addr Arbiter ( .C_NUM_M (2) ) splitter_aw_mi ( .ACLK (ACLK), .ARESET (reset), .S_VALID (aa_sa_awvalid), .S_READY (aa_sa_awready), .M_VALID ({mi_awvalid_en, sa_wm_awvalid_en}), .M_READY ({mi_awready_mux, sa_wm_awready_mux}) ); assign mi_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{mi_awvalid_en}}; assign mi_awready_mux = \|(aa_mi_awtarget_hot & mi_awready); assign M_AXI_AWVALID = mi_awvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_awready[0+:C_NUM_MASTER_SLOTS] = M_AXI_AWREADY; assign sa_wm_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{sa_wm_awvalid_en}}; assign sa_wm_awready_mux = \|(aa_mi_awtarget_hot & sa_wm_awready); assign mi_arvalid = aa_mi_artarget_hot & {C_NUM_MASTER_SLOTS+1{aa_mi_arvalid}}; assign aa_mi_arready = \|(aa_mi_artarget_hot & mi_arready); assign M_AXI_ARVALID = mi_arvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_arready[0+:C_NUM_MASTER_SLOTS] = M_AXI_ARREADY; // MI-slot # C_NUM_MASTER_SLOTS is the error handler if (C_RANGE_CHECK) begin : gen_decerr_slave axi_crossbar_v2_1_decerr_slave # ( .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_RESP (P_DECERR) ) decerr_slave_inst ( .S_AXI_ACLK (ACLK), .S_AXI_ARESET (reset), .S_AXI_AWID (aa_mi_awmesg[0+:C_AXI_ID_WIDTH]), .S_AXI_AWVALID (mi_awvalid[C_NUM_MASTER_SLOTS]), .S_AXI_AWREADY (mi_awready[C_NUM_MASTER_SLOTS]), .S_AXI_WLAST (mi_wlast[C_NUM_MASTER_SLOTS]), .S_AXI_WVALID (mi_wvalid[C_NUM_MASTER_SLOTS]), .S_AXI_WREADY (mi_wready[C_NUM_MASTER_SLOTS]), .S_AXI_BID (mi_bid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_BRESP (mi_bresp[C_NUM_MASTER_SLOTS2+:2]), .S_AXI_BUSER (mi_buser[C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH]), .S_AXI_BVALID (mi_bvalid[C_NUM_MASTER_SLOTS]), .S_AXI_BREADY (mi_bready[C_NUM_MASTER_SLOTS]), .S_AXI_ARID (aa_mi_armesg[0+:C_AXI_ID_WIDTH]), .S_AXI_ARLEN (aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]), .S_AXI_ARVALID (mi_arvalid[C_NUM_MASTER_SLOTS]), .S_AXI_ARREADY (mi_arready[C_NUM_MASTER_SLOTS]), .S_AXI_RID (mi_rid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_RDATA (mi_rdata[C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .S_AXI_RRESP (mi_rresp[C_NUM_MASTER_SLOTS2+:2]), .S_AXI_RUSER (mi_ruser[C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH]), .S_AXI_RLAST (mi_rlast[C_NUM_MASTER_SLOTS]), .S_AXI_RVALID (mi_rvalid[C_NUM_MASTER_SLOTS]), .S_AXI_RREADY (mi_rready[C_NUM_MASTER_SLOTS]) ); end else begin : gen_no_decerr_slave assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_wready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_arready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_bid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_bresp[C_NUM_MASTER_SLOTS2+:2] = 0; assign mi_buser[C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign mi_bvalid[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_rdata[C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign mi_rresp[C_NUM_MASTER_SLOTS2+:2] = 0; assign mi_ruser[C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign mi_rlast[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rvalid[C_NUM_MASTER_SLOTS] = 1'b0; end // gen_decerr_slave endgenerate endmodule
module axi_crossbar_v2_1_crossbar # ( parameter C_FAMILY = "none", parameter integer C_NUM_SLAVE_SLOTS = 1, parameter integer C_NUM_MASTER_SLOTS = 1, parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_PROTOCOL = 0, parameter [C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64-1:0] C_M_AXI_BASE_ADDR = {C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64{1'b1}}, parameter [C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64-1:0] C_M_AXI_HIGH_ADDR = {C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS64-1:0] C_S_AXI_BASE_ID = {C_NUM_SLAVE_SLOTS64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS64-1:0] C_S_AXI_HIGH_ID = {C_NUM_SLAVE_SLOTS64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_THREAD_ID_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_AWUSER_WIDTH = 1, parameter integer C_AXI_ARUSER_WIDTH = 1, parameter integer C_AXI_WUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_BUSER_WIDTH = 1, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_WRITE = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_READ = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_WRITE = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_READ = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_WRITE_CONNECTIVITY = {C_NUM_MASTER_SLOTS32{1'b1}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_READ_CONNECTIVITY = {C_NUM_MASTER_SLOTS32{1'b1}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_SINGLE_THREAD = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_WRITE_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_READ_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_WRITE_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_READ_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_ARB_PRIORITY = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_SECURE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_ERR_MODE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE = 0, parameter [(C_NUM_MASTER_SLOTS+1)32-1:0] C_W_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [(C_NUM_MASTER_SLOTS+1)32-1:0] C_R_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_W_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_R_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESETN, // Slave Interface Write Address Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_AWID, input wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR, input wire [C_NUM_SLAVE_SLOTS8-1:0] S_AXI_AWLEN, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_AWSIZE, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_AWBURST, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_AWLOCK, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWCACHE, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_AWPROT, // input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWREGION, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWQOS, input wire [C_NUM_SLAVE_SLOTSC_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWREADY, // Slave Interface Write Data Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_WID, input wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH-1:0] S_AXI_WDATA, input wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WLAST, input wire [C_NUM_SLAVE_SLOTSC_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WREADY, // Slave Interface Write Response Ports output wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_BID, output wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_BRESP, output wire [C_NUM_SLAVE_SLOTSC_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BREADY, // Slave Interface Read Address Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_ARID, input wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR, input wire [C_NUM_SLAVE_SLOTS8-1:0] S_AXI_ARLEN, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_ARSIZE, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_ARBURST, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_ARLOCK, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARCACHE, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_ARPROT, // input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARREGION, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARQOS, input wire [C_NUM_SLAVE_SLOTSC_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARREADY, // Slave Interface Read Data Ports output wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_RID, output wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH-1:0] S_AXI_RDATA, output wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_RRESP, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RLAST, output wire [C_NUM_SLAVE_SLOTSC_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RREADY, // Master Interface Write Address Port output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_AWID, output wire [C_NUM_MASTER_SLOTSC_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR, output wire [C_NUM_MASTER_SLOTS8-1:0] M_AXI_AWLEN, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_AWSIZE, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_AWBURST, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_AWLOCK, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWCACHE, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_AWPROT, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWREGION, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWQOS, output wire [C_NUM_MASTER_SLOTSC_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWREADY, // Master Interface Write Data Ports output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_WID, output wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH-1:0] M_AXI_WDATA, output wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WLAST, output wire [C_NUM_MASTER_SLOTSC_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WREADY, // Master Interface Write Response Ports input wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_BID, input wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_BRESP, input wire [C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BREADY, // Master Interface Read Address Port output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_ARID, output wire [C_NUM_MASTER_SLOTSC_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR, output wire [C_NUM_MASTER_SLOTS8-1:0] M_AXI_ARLEN, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_ARSIZE, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_ARBURST, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_ARLOCK, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARCACHE, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_ARPROT, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARREGION, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARQOS, output wire [C_NUM_MASTER_SLOTSC_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARREADY, // Master Interface Read Data Ports input wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_RID, input wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH-1:0] M_AXI_RDATA, input wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_RRESP, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RLAST, input wire [C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RREADY ); localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_NUM_MASTER_SLOTS_LOG = f_ceil_log2(C_NUM_MASTER_SLOTS); localparam integer P_NUM_SLAVE_SLOTS_LOG = f_ceil_log2((C_NUM_SLAVE_SLOTS>1) ? C_NUM_SLAVE_SLOTS : 2); localparam integer P_AXI_WID_WIDTH = (C_AXI_PROTOCOL == P_AXI3) ? C_AXI_ID_WIDTH : 1; localparam integer P_ST_AWMESG_WIDTH = 2+4+4 + C_AXI_AWUSER_WIDTH; localparam integer P_AA_AWMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_AWMESG_WIDTH; localparam integer P_ST_ARMESG_WIDTH = 2+4+4 + C_AXI_ARUSER_WIDTH; localparam integer P_AA_ARMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_ARMESG_WIDTH; localparam integer P_ST_BMESG_WIDTH = 2 + C_AXI_BUSER_WIDTH; localparam integer P_ST_RMESG_WIDTH = 2 + C_AXI_RUSER_WIDTH + C_AXI_DATA_WIDTH; localparam integer P_WR_WMESG_WIDTH = C_AXI_DATA_WIDTH + C_AXI_DATA_WIDTH/8 + C_AXI_WUSER_WIDTH + P_AXI_WID_WIDTH; localparam [31:0] P_BYPASS = 32'h00000000; localparam [31:0] P_FWD_REV = 32'h00000001; localparam [31:0] P_SIMPLE = 32'h00000007; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_READ = {1'b1, C_M_AXI_SUPPORTS_READ[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_WRITE = {1'b1, C_M_AXI_SUPPORTS_WRITE[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_WRITE_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_WRITE_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS32]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_READ_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_READ_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS32]}; localparam [C_NUM_SLAVE_SLOTS32-1:0] P_S_AXI_WRITE_CONNECTIVITY = f_si_write_connectivity(0); localparam [C_NUM_SLAVE_SLOTS32-1:0] P_S_AXI_READ_CONNECTIVITY = f_si_read_connectivity(0); localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_READ_ISSUING = {32'h00000001, C_M_AXI_READ_ISSUING[0+:C_NUM_MASTER_SLOTS32]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_WRITE_ISSUING = {32'h00000001, C_M_AXI_WRITE_ISSUING[0+:C_NUM_MASTER_SLOTS32]}; localparam P_DECERR = 2'b11; //--------------------------------------------------------------------------- // Functions //--------------------------------------------------------------------------- // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // Isolate thread bits of input S_ID and add to BASE_ID (RNG00) to form MI-side ID value // only for end-point SI-slots function [C_AXI_ID_WIDTH-1:0] f_extend_ID ( input [C_AXI_ID_WIDTH-1:0] s_id, input integer slot ); begin f_extend_ID = C_S_AXI_BASE_ID[slot64+:C_AXI_ID_WIDTH] \| (s_id & (C_S_AXI_BASE_ID[slot64+:C_AXI_ID_WIDTH] ^ C_S_AXI_HIGH_ID[slot64+:C_AXI_ID_WIDTH])); end endfunction // Write connectivity array transposed function [C_NUM_SLAVE_SLOTS32-1:0] f_si_write_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot32+mi_slot] = C_M_AXI_WRITE_CONNECTIVITY[mi_slot32+si_slot]; end end f_si_write_connectivity = result; end endfunction // Read connectivity array transposed function [C_NUM_SLAVE_SLOTS32-1:0] f_si_read_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot32+mi_slot] = C_M_AXI_READ_CONNECTIVITY[mi_slot32+si_slot]; end end f_si_read_connectivity = result; end endfunction genvar gen_si_slot; genvar gen_mi_slot; wire [C_NUM_SLAVE_SLOTSP_ST_AWMESG_WIDTH-1:0] si_st_awmesg ; wire [C_NUM_SLAVE_SLOTSP_ST_AWMESG_WIDTH-1:0] st_tmp_awmesg ; wire [C_NUM_SLAVE_SLOTSP_AA_AWMESG_WIDTH-1:0] tmp_aa_awmesg ; wire [P_AA_AWMESG_WIDTH-1:0] aa_mi_awmesg ; wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] st_aa_awid ; wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] st_aa_awaddr ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_awlen ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_awsize ; wire [C_NUM_SLAVE_SLOTS2-1:0] st_aa_awlock ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_awprot ; wire [C_NUM_SLAVE_SLOTS4-1:0] st_aa_awregion ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_awerror ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_awtarget_enc ; wire [P_NUM_SLAVE_SLOTS_LOG1-1:0] aa_wm_awgrant_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_awvalid_qual ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_ss_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_ss_awready ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_wr_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_wr_awready ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_aa_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_aa_awready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] sa_wm_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] sa_wm_awready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awready ; wire aa_sa_awvalid ; wire aa_sa_awready ; wire aa_mi_arready ; wire mi_awvalid_en ; wire sa_wm_awvalid_en ; wire sa_wm_awready_mux ; wire [C_NUM_SLAVE_SLOTSP_ST_ARMESG_WIDTH-1:0] si_st_armesg ; wire [C_NUM_SLAVE_SLOTSP_ST_ARMESG_WIDTH-1:0] st_tmp_armesg ; wire [C_NUM_SLAVE_SLOTSP_AA_ARMESG_WIDTH-1:0] tmp_aa_armesg ; wire [P_AA_ARMESG_WIDTH-1:0] aa_mi_armesg ; wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] st_aa_arid ; wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] st_aa_araddr ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_arlen ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_arsize ; wire [C_NUM_SLAVE_SLOTS2-1:0] st_aa_arlock ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_arprot ; wire [C_NUM_SLAVE_SLOTS4-1:0] st_aa_arregion ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_arerror ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_artarget_hot ; wire [C_NUM_SLAVE_SLOTS(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_artarget_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_artarget_hot ; wire [P_NUM_SLAVE_SLOTS_LOG1-1:0] aa_mi_argrant_enc ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arvalid_qual ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_arvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_arready ; wire aa_mi_arvalid ; wire mi_awready_mux ; wire [C_NUM_SLAVE_SLOTSP_ST_BMESG_WIDTH-1:0] st_si_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)P_ST_BMESG_WIDTH-1:0] st_mr_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] st_mr_bid ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] st_mr_bresp ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_BUSER_WIDTH-1:0] st_mr_buser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_mr_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)P_NUM_SLAVE_SLOTS_LOG-1:0] debug_bid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] bid_match ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_bid ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] mi_bresp ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_BUSER_WIDTH-1:0] mi_buser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] bready_carry ; wire [C_NUM_SLAVE_SLOTSP_ST_RMESG_WIDTH-1:0] st_si_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)P_ST_RMESG_WIDTH-1:0] st_mr_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] st_mr_rid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] st_mr_rdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_RUSER_WIDTH-1:0] st_mr_ruser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rlast ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] st_mr_rresp ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_mr_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)P_NUM_SLAVE_SLOTS_LOG-1:0] debug_rid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] rid_match ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_rid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] mi_rdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_RUSER_WIDTH-1:0] mi_ruser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rlast ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] mi_rresp ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] rready_carry ; wire [C_NUM_SLAVE_SLOTSP_WR_WMESG_WIDTH-1:0] si_wr_wmesg ; wire [C_NUM_SLAVE_SLOTSP_WR_WMESG_WIDTH-1:0] wr_wm_wmesg ; wire [C_NUM_SLAVE_SLOTS1-1:0] wr_wm_wlast ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wvalid ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wready ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wready ; wire [(C_NUM_MASTER_SLOTS+1)P_WR_WMESG_WIDTH-1:0] wm_mr_wmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] wm_mr_wdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH/8-1:0] wm_mr_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] wm_mr_wid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_WUSER_WIDTH-1:0] wm_mr_wuser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wlast ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wready ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] mi_wdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH/8-1:0] mi_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_WUSER_WIDTH-1:0] mi_wuser ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_wid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wlast ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] w_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] w_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] r_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] r_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awmaxissuing ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_armaxissuing ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] w_issuing_cnt ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] r_issuing_cnt ; reg [8-1:0] debug_aw_trans_seq_i ; reg [8-1:0] debug_ar_trans_seq_i ; wire [(C_NUM_MASTER_SLOTS+1)8-1:0] debug_w_trans_seq_i ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] debug_w_beat_cnt_i ; reg aresetn_d = 1'b0; // Reset delay register always @(posedge ACLK) begin if (~ARESETN) begin aresetn_d <= 1'b0; end else begin aresetn_d <= ARESETN; end end wire reset; assign reset = ~aresetn_d; generate for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_slave_slots if (C_S_AXI_SUPPORTS_READ[gen_si_slot]) begin : gen_si_read axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (read channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_READ), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_READ_ACCEPTANCE[gen_si_slot32+:32]), .C_ACCEPTANCE_LOG (C_R_ACCEPT_WIDTH[gen_si_slot32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_ARMESG_WIDTH), .C_RMESG_WIDTH (P_ST_RMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_READ_CONNECTIVITY[gen_si_slot32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_ar ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_ARID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_ARADDR[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_ARLEN[gen_si_slot8+:8]), .S_ASIZE (S_AXI_ARSIZE[gen_si_slot3+:3]), .S_ABURST (S_AXI_ARBURST[gen_si_slot2+:2]), .S_ALOCK (S_AXI_ARLOCK[gen_si_slot2+:2]), .S_APROT (S_AXI_ARPROT[gen_si_slot3+:3]), // .S_AREGION (S_AXI_ARREGION[gen_si_slot4+:4]), .S_AMESG (si_st_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .S_AVALID (S_AXI_ARVALID[gen_si_slot]), .S_AREADY (S_AXI_ARREADY[gen_si_slot]), .M_AID (st_aa_arid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_araddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_arlen[gen_si_slot8+:8]), .M_ASIZE (st_aa_arsize[gen_si_slot3+:3]), .M_ALOCK (st_aa_arlock[gen_si_slot2+:2]), .M_APROT (st_aa_arprot[gen_si_slot3+:3]), .M_AREGION (st_aa_arregion[gen_si_slot4+:4]), .M_AMESG (st_tmp_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .M_ATARGET_HOT (st_aa_artarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_artarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_arerror[gen_si_slot8+:8]), .M_AVALID_QUAL (st_aa_arvalid_qual[gen_si_slot]), .M_AVALID (st_aa_arvalid[gen_si_slot]), .M_AREADY (st_aa_arready[gen_si_slot]), .S_RID (S_AXI_RID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH]), .S_RLAST (S_AXI_RLAST[gen_si_slot]), .S_RVALID (S_AXI_RVALID[gen_si_slot]), .S_RREADY (S_AXI_RREADY[gen_si_slot]), .M_RID (st_mr_rid), .M_RLAST (st_mr_rlast), .M_RMESG (st_mr_rmesg), .M_RVALID (st_mr_rvalid), .M_RREADY (st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_rid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_ar_trans_seq_i : 8'h0) ); assign si_st_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH] = { S_AXI_ARUSER[gen_si_slotC_AXI_ARUSER_WIDTH+:C_AXI_ARUSER_WIDTH], S_AXI_ARQOS[gen_si_slot4+:4], S_AXI_ARCACHE[gen_si_slot4+:4], S_AXI_ARBURST[gen_si_slot2+:2] }; assign tmp_aa_armesg[gen_si_slotP_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = { st_tmp_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH], st_aa_arregion[gen_si_slot4+:4], st_aa_arprot[gen_si_slot3+:3], st_aa_arlock[gen_si_slot2+:2], st_aa_arsize[gen_si_slot3+:3], st_aa_arlen[gen_si_slot8+:8], st_aa_araddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_arid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_RRESP[gen_si_slot2+:2] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+:2]; assign S_AXI_RUSER[gen_si_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+2 +: C_AXI_RUSER_WIDTH]; assign S_AXI_RDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+2+C_AXI_RUSER_WIDTH +: C_AXI_DATA_WIDTH]; end else begin : gen_no_si_read assign S_AXI_ARREADY[gen_si_slot] = 1'b0; assign st_aa_arvalid[gen_si_slot] = 1'b0; assign st_aa_arvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_armesg[gen_si_slotP_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = 0; assign S_AXI_RID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_RRESP[gen_si_slot2+:2] = 0; assign S_AXI_RUSER[gen_si_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign S_AXI_RDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign S_AXI_RVALID[gen_si_slot] = 1'b0; assign S_AXI_RLAST[gen_si_slot] = 1'b0; assign st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_artarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_read if (C_S_AXI_SUPPORTS_WRITE[gen_si_slot]) begin : gen_si_write axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (write channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_WRITE), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_WRITE_ACCEPTANCE[gen_si_slot32+:32]), .C_ACCEPTANCE_LOG (C_W_ACCEPT_WIDTH[gen_si_slot32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_AWMESG_WIDTH), .C_RMESG_WIDTH (P_ST_BMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_WRITE_CONNECTIVITY[gen_si_slot32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_aw ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_AWID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_AWADDR[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_AWLEN[gen_si_slot8+:8]), .S_ASIZE (S_AXI_AWSIZE[gen_si_slot3+:3]), .S_ABURST (S_AXI_AWBURST[gen_si_slot2+:2]), .S_ALOCK (S_AXI_AWLOCK[gen_si_slot2+:2]), .S_APROT (S_AXI_AWPROT[gen_si_slot3+:3]), // .S_AREGION (S_AXI_AWREGION[gen_si_slot4+:4]), .S_AMESG (si_st_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .S_AVALID (S_AXI_AWVALID[gen_si_slot]), .S_AREADY (S_AXI_AWREADY[gen_si_slot]), .M_AID (st_aa_awid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_awaddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_awlen[gen_si_slot8+:8]), .M_ASIZE (st_aa_awsize[gen_si_slot3+:3]), .M_ALOCK (st_aa_awlock[gen_si_slot2+:2]), .M_APROT (st_aa_awprot[gen_si_slot3+:3]), .M_AREGION (st_aa_awregion[gen_si_slot4+:4]), .M_AMESG (st_tmp_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .M_ATARGET_HOT (st_aa_awtarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_awtarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_awerror[gen_si_slot8+:8]), .M_AVALID_QUAL (st_aa_awvalid_qual[gen_si_slot]), .M_AVALID (st_ss_awvalid[gen_si_slot]), .M_AREADY (st_ss_awready[gen_si_slot]), .S_RID (S_AXI_BID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH]), .S_RLAST (), .S_RVALID (S_AXI_BVALID[gen_si_slot]), .S_RREADY (S_AXI_BREADY[gen_si_slot]), .M_RID (st_mr_bid), .M_RLAST ({(C_NUM_MASTER_SLOTS+1){1'b1}}), .M_RMESG (st_mr_bmesg), .M_RVALID (st_mr_bvalid), .M_RREADY (st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_bid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_aw_trans_seq_i : 8'h0) ); // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign si_st_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH] = { S_AXI_AWUSER[gen_si_slotC_AXI_AWUSER_WIDTH+:C_AXI_AWUSER_WIDTH], S_AXI_AWQOS[gen_si_slot4+:4], S_AXI_AWCACHE[gen_si_slot4+:4], S_AXI_AWBURST[gen_si_slot2+:2] }; assign tmp_aa_awmesg[gen_si_slotP_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = { st_tmp_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH], st_aa_awregion[gen_si_slot4+:4], st_aa_awprot[gen_si_slot3+:3], st_aa_awlock[gen_si_slot2+:2], st_aa_awsize[gen_si_slot3+:3], st_aa_awlen[gen_si_slot8+:8], st_aa_awaddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_awid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_BRESP[gen_si_slot2+:2] = st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+:2]; assign S_AXI_BUSER[gen_si_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+2 +: C_AXI_BUSER_WIDTH]; // AW SI-transactor transfer completes upon completion of both W-router address acceptance (command push) and AW arbitration axi_crossbar_v2_1_splitter # // "SS": Splitter from SI-Transactor (write channel) ( .C_NUM_M (2) ) splitter_aw_si ( .ACLK (ACLK), .ARESET (reset), .S_VALID (st_ss_awvalid[gen_si_slot]), .S_READY (st_ss_awready[gen_si_slot]), .M_VALID ({ss_wr_awvalid[gen_si_slot], ss_aa_awvalid[gen_si_slot]}), .M_READY ({ss_wr_awready[gen_si_slot], ss_aa_awready[gen_si_slot]}) ); axi_crossbar_v2_1_wdata_router # // "WR": Write data Router ( .C_FAMILY (C_FAMILY), .C_NUM_MASTER_SLOTS (C_NUM_MASTER_SLOTS+1), .C_SELECT_WIDTH (P_NUM_MASTER_SLOTS_LOG+1), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ACCEPT_WIDTH[gen_si_slot32+:6]) ) wdata_router_w ( .ACLK (ACLK), .ARESET (reset), // Write transfer input from the current SI-slot .S_WMESG (si_wr_wmesg[gen_si_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .S_WLAST (S_AXI_WLAST[gen_si_slot]), .S_WVALID (S_AXI_WVALID[gen_si_slot]), .S_WREADY (S_AXI_WREADY[gen_si_slot]), // Vector of write transfer outputs to each MI-slot's W-mux .M_WMESG (wr_wm_wmesg[gen_si_slot(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH]), .M_WLAST (wr_wm_wlast[gen_si_slot]), .M_WVALID (wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_WREADY (wr_tmp_wready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), // AW command push from local SI-slot .S_ASELECT (st_aa_awtarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), // Target MI-slot .S_AVALID (ss_wr_awvalid[gen_si_slot]), .S_AREADY (ss_wr_awready[gen_si_slot]) ); assign si_wr_wmesg[gen_si_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH] = { ((C_AXI_PROTOCOL == P_AXI3) ? f_extend_ID(S_AXI_WID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot) : 1'b0), S_AXI_WUSER[gen_si_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH], S_AXI_WSTRB[gen_si_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8], S_AXI_WDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] }; end else begin : gen_no_si_write assign S_AXI_AWREADY[gen_si_slot] = 1'b0; assign ss_aa_awvalid[gen_si_slot] = 1'b0; assign st_aa_awvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_awmesg[gen_si_slotP_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = 0; assign S_AXI_BID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_BRESP[gen_si_slot2+:2] = 0; assign S_AXI_BUSER[gen_si_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign S_AXI_BVALID[gen_si_slot] = 1'b0; assign st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign S_AXI_WREADY[gen_si_slot] = 1'b0; assign wr_wm_wmesg[gen_si_slot(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH] = 0; assign wr_wm_wlast[gen_si_slot] = 1'b0; assign wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_awtarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_write end // gen_slave_slots for (gen_mi_slot=0; gen_mi_slot<C_NUM_MASTER_SLOTS+1; gen_mi_slot=gen_mi_slot+1) begin : gen_master_slots if (P_M_AXI_SUPPORTS_READ[gen_mi_slot]) begin : gen_mi_read if (C_NUM_SLAVE_SLOTS>1) begin : gen_rid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_READ_CONNECTIVITY[gen_mi_slot32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) rid_decoder_inst ( .ADDR (st_mr_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_rid_target_i[gen_mi_slotP_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (rid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_rid_decoder assign tmp_mr_rid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign rid_match[gen_mi_slot] = 1'b1; end assign st_mr_rmesg[gen_mi_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = { st_mr_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH], st_mr_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH], st_mr_rresp[gen_mi_slot2+:2] }; end else begin : gen_no_mi_read assign tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign rid_match[gen_mi_slot] = 1'b0; assign st_mr_rmesg[gen_mi_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = 0; end // gen_mi_read if (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]) begin : gen_mi_write if (C_NUM_SLAVE_SLOTS>1) begin : gen_bid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_WRITE_CONNECTIVITY[gen_mi_slot32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) bid_decoder_inst ( .ADDR (st_mr_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_bid_target_i[gen_mi_slotP_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (bid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_bid_decoder assign tmp_mr_bid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign bid_match[gen_mi_slot] = 1'b1; end axi_crossbar_v2_1_wdata_mux # // "WM": Write data Mux, per MI-slot (incl error-handler) ( .C_FAMILY (C_FAMILY), .C_NUM_SLAVE_SLOTS (C_NUM_SLAVE_SLOTS), .C_SELECT_WIDTH (P_NUM_SLAVE_SLOTS_LOG), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]) ) wdata_mux_w ( .ACLK (ACLK), .ARESET (reset), // Vector of write transfer inputs from each SI-slot's W-router .S_WMESG (wr_wm_wmesg), .S_WLAST (wr_wm_wlast), .S_WVALID (tmp_wm_wvalid[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .S_WREADY (tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), // Write transfer output to the current MI-slot .M_WMESG (wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .M_WLAST (wm_mr_wlast[gen_mi_slot]), .M_WVALID (wm_mr_wvalid[gen_mi_slot]), .M_WREADY (wm_mr_wready[gen_mi_slot]), // AW command push from AW arbiter output .S_ASELECT (aa_wm_awgrant_enc), // SI-slot selected by arbiter .S_AVALID (sa_wm_awvalid[gen_mi_slot]), .S_AREADY (sa_wm_awready[gen_mi_slot]) ); if (C_DEBUG) begin : gen_debug_w // DEBUG WRITE BEAT COUNTER always @(posedge ACLK) begin if (reset) begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= 0; end else begin if (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot]) begin if (mi_wlast[gen_mi_slot]) begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= 0; end else begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= debug_w_beat_cnt_i[gen_mi_slot8+:8] + 1; end end end end // clocked process // DEBUG W-CHANNEL TRANSACTION SEQUENCE QUEUE axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]), .C_USE_FULL (0) ) debug_w_seq_fifo ( .ACLK (ACLK), .ARESET (reset), .S_MESG (debug_aw_trans_seq_i), .S_VALID (sa_wm_awvalid[gen_mi_slot]), .S_READY (), .M_MESG (debug_w_trans_seq_i[gen_mi_slot8+:8]), .M_VALID (), .M_READY (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot] & mi_wlast[gen_mi_slot]) ); end // gen_debug_w assign wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH +: C_AXI_DATA_WIDTH]; assign wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH +: C_AXI_DATA_WIDTH/8]; assign wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+C_AXI_DATA_WIDTH/8 +: C_AXI_WUSER_WIDTH]; assign wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+(C_AXI_DATA_WIDTH/8)+C_AXI_WUSER_WIDTH +: P_AXI_WID_WIDTH]; assign st_mr_bmesg[gen_mi_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = { st_mr_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH], st_mr_bresp[gen_mi_slot2+:2] }; end else begin : gen_no_mi_write assign tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign bid_match[gen_mi_slot] = 1'b0; assign wm_mr_wvalid[gen_mi_slot] = 0; assign wm_mr_wlast[gen_mi_slot] = 0; assign wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = 0; assign wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = 0; assign wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign st_mr_bmesg[gen_mi_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = 0; assign tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign sa_wm_awready[gen_mi_slot] = 0; end // gen_mi_write for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_trans_si // Transpose handshakes from W-router (SxM) to W-mux (MxS). assign tmp_wm_wvalid[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot] = wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; assign wr_tmp_wready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; // Transpose response enables from ID decoders (MxS) to si_transactors (SxM). assign st_tmp_bid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; assign st_tmp_rid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; end // gen_trans_si assign bready_carry[gen_mi_slot] = st_tmp_bready[gen_mi_slot]; assign rready_carry[gen_mi_slot] = st_tmp_rready[gen_mi_slot]; for (gen_si_slot=1; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_resp_carry_si assign bready_carry[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_BREADY if ... bready_carry[(gen_si_slot-1)(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] \| // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates BREADY for that MI-slot. assign rready_carry[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_RREADY if ... rready_carry[(gen_si_slot-1)(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] \| // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates RREADY for that MI-slot. end // gen_resp_carry_si assign w_cmd_push[gen_mi_slot] = mi_awvalid[gen_mi_slot] && mi_awready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_push[gen_mi_slot] = mi_arvalid[gen_mi_slot] && mi_arready[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; assign w_cmd_pop[gen_mi_slot] = st_mr_bvalid[gen_mi_slot] && st_mr_bready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_pop[gen_mi_slot] = st_mr_rvalid[gen_mi_slot] && st_mr_rready[gen_mi_slot] && st_mr_rlast[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; // Disqualify arbitration of SI-slot if targeted MI-slot has reached its issuing limit. assign mi_awmaxissuing[gen_mi_slot] = (w_issuing_cnt[gen_mi_slot8 +: (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] == P_M_AXI_WRITE_ISSUING[gen_mi_slot32 +: (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)]) & ~w_cmd_pop[gen_mi_slot]; assign mi_armaxissuing[gen_mi_slot] = (r_issuing_cnt[gen_mi_slot8 +: (C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] == P_M_AXI_READ_ISSUING[gen_mi_slot32 +: (C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)]) & ~r_cmd_pop[gen_mi_slot]; always @(posedge ACLK) begin if (reset) begin w_issuing_cnt[gen_mi_slot8+:8] <= 0; // Some high-order bits remain constant 0 r_issuing_cnt[gen_mi_slot8+:8] <= 0; // Some high-order bits remain constant 0 end else begin if (w_cmd_push[gen_mi_slot] && ~w_cmd_pop[gen_mi_slot]) begin w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] + 1; end else if (w_cmd_pop[gen_mi_slot] && ~w_cmd_push[gen_mi_slot] && (\|w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)])) begin w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] - 1; end if (r_cmd_push[gen_mi_slot] && ~r_cmd_pop[gen_mi_slot]) begin r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] + 1; end else if (r_cmd_pop[gen_mi_slot] && ~r_cmd_push[gen_mi_slot] && (\|r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)])) begin r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] - 1; end end end // Clocked process // Reg-slice must break combinatorial path from M_BID and M_RID inputs to M_BREADY and M_RREADY outputs. // (See m_rready_i and m_resp_en combinatorial assignments in si_transactor.) // Reg-slice incurs +1 latency, but no bubble-cycles. axi_register_slice_v2_1_axi_register_slice # // "MR": MI-side R/B-channel Reg-slice, per MI-slot (pass-through if only 1 SI-slot configured) ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL ((C_AXI_PROTOCOL == P_AXI3) ? P_AXI3 : P_AXI4), .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (1), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (C_AXI_SUPPORTS_USER_SIGNALS), .C_AXI_AWUSER_WIDTH (1), .C_AXI_ARUSER_WIDTH (1), .C_AXI_WUSER_WIDTH (C_AXI_WUSER_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_REG_CONFIG_AW (P_BYPASS), .C_REG_CONFIG_AR (P_BYPASS), .C_REG_CONFIG_W (P_BYPASS), .C_REG_CONFIG_R (P_M_AXI_SUPPORTS_READ[gen_mi_slot] ? P_FWD_REV : P_BYPASS), .C_REG_CONFIG_B (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot] ? P_SIMPLE : P_BYPASS) ) reg_slice_mi ( .aresetn (ARESETN), .aclk (ACLK), .s_axi_awid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_awaddr ({1{1'b0}}), .s_axi_awlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_awsize ({3{1'b0}}), .s_axi_awburst ({2{1'b0}}), .s_axi_awlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_awcache ({4{1'b0}}), .s_axi_awprot ({3{1'b0}}), .s_axi_awregion ({4{1'b0}}), .s_axi_awqos ({4{1'b0}}), .s_axi_awuser ({1{1'b0}}), .s_axi_awvalid ({1{1'b0}}), .s_axi_awready (), .s_axi_wid (wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .s_axi_wdata (wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .s_axi_wstrb (wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .s_axi_wlast (wm_mr_wlast[gen_mi_slot]), .s_axi_wuser (wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .s_axi_wvalid (wm_mr_wvalid[gen_mi_slot]), .s_axi_wready (wm_mr_wready[gen_mi_slot]), .s_axi_bid (st_mr_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_bresp (st_mr_bresp[gen_mi_slot2+:2] ), .s_axi_buser (st_mr_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .s_axi_bvalid (st_mr_bvalid[gen_mi_slot1+:1] ), .s_axi_bready (st_mr_bready[gen_mi_slot1+:1] ), .s_axi_arid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_araddr ({1{1'b0}}), .s_axi_arlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_arsize ({3{1'b0}}), .s_axi_arburst ({2{1'b0}}), .s_axi_arlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_arcache ({4{1'b0}}), .s_axi_arprot ({3{1'b0}}), .s_axi_arregion ({4{1'b0}}), .s_axi_arqos ({4{1'b0}}), .s_axi_aruser ({1{1'b0}}), .s_axi_arvalid ({1{1'b0}}), .s_axi_arready (), .s_axi_rid (st_mr_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_rdata (st_mr_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .s_axi_rresp (st_mr_rresp[gen_mi_slot2+:2] ), .s_axi_rlast (st_mr_rlast[gen_mi_slot1+:1] ), .s_axi_ruser (st_mr_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .s_axi_rvalid (st_mr_rvalid[gen_mi_slot1+:1] ), .s_axi_rready (st_mr_rready[gen_mi_slot1+:1] ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready ({1{1'b0}}), .m_axi_wid (mi_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .m_axi_wdata (mi_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .m_axi_wstrb (mi_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .m_axi_wlast (mi_wlast[gen_mi_slot]), .m_axi_wuser (mi_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .m_axi_wvalid (mi_wvalid[gen_mi_slot]), .m_axi_wready (mi_wready[gen_mi_slot]), .m_axi_bid (mi_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_bresp (mi_bresp[gen_mi_slot2+:2] ), .m_axi_buser (mi_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .m_axi_bvalid (mi_bvalid[gen_mi_slot1+:1] ), .m_axi_bready (mi_bready[gen_mi_slot1+:1] ), .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready ({1{1'b0}}), .m_axi_rid (mi_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_rdata (mi_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .m_axi_rresp (mi_rresp[gen_mi_slot2+:2] ), .m_axi_rlast (mi_rlast[gen_mi_slot1+:1] ), .m_axi_ruser (mi_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .m_axi_rvalid (mi_rvalid[gen_mi_slot1+:1] ), .m_axi_rready (mi_rready[gen_mi_slot1+:1] ) ); end // gen_master_slots (Next gen_mi_slot) // Highest row of ready_carry contains accumulated OR across all SI-slots, for each MI-slot. assign st_mr_bready = bready_carry[(C_NUM_SLAVE_SLOTS-1)(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; assign st_mr_rready = rready_carry[(C_NUM_SLAVE_SLOTS-1)(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; // Assign MI-side B, R and W channel ports (exclude error handler signals). assign mi_bid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] = M_AXI_BID; assign mi_bvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_BVALID; assign mi_bresp[0+:C_NUM_MASTER_SLOTS2] = M_AXI_BRESP; assign mi_buser[0+:C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH] = M_AXI_BUSER; assign M_AXI_BREADY = mi_bready[0+:C_NUM_MASTER_SLOTS]; assign mi_rid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] = M_AXI_RID; assign mi_rlast[0+:C_NUM_MASTER_SLOTS] = M_AXI_RLAST; assign mi_rvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_RVALID; assign mi_rresp[0+:C_NUM_MASTER_SLOTS2] = M_AXI_RRESP; assign mi_ruser[0+:C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH] = M_AXI_RUSER; assign mi_rdata[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH] = M_AXI_RDATA; assign M_AXI_RREADY = mi_rready[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WLAST = mi_wlast[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WVALID = mi_wvalid[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WUSER = mi_wuser[0+:C_NUM_MASTER_SLOTSC_AXI_WUSER_WIDTH]; assign M_AXI_WID = (C_AXI_PROTOCOL == P_AXI3) ? mi_wid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] : 0; assign M_AXI_WDATA = mi_wdata[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH]; assign M_AXI_WSTRB = mi_wstrb[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH/8]; assign mi_wready[0+:C_NUM_MASTER_SLOTS] = M_AXI_WREADY; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AW channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_AWMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_aw ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AW command request inputs .S_MESG (tmp_aa_awmesg), .S_TARGET_HOT (st_aa_awtarget_hot), .S_VALID (ss_aa_awvalid), .S_VALID_QUAL (st_aa_awvalid_qual), .S_READY (ss_aa_awready), // Granted AW command output .M_MESG (aa_mi_awmesg), .M_TARGET_HOT (aa_mi_awtarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_wm_awgrant_enc), // SI-slot index of granted command .M_VALID (aa_sa_awvalid), .M_READY (aa_sa_awready), .ISSUING_LIMIT (mi_awmaxissuing) ); // Broadcast AW transfer payload to all MI-slots assign M_AXI_AWID = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_AWADDR = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_AWLEN = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_AWSIZE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_AWLOCK = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_AWPROT = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_AWREGION = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_AWBURST = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_AWCACHE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_AWQOS = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_AWUSER = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_AWUSER_WIDTH]}}; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AR channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_ARMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_ar ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AR command request inputs .S_MESG (tmp_aa_armesg), .S_TARGET_HOT (st_aa_artarget_hot), .S_VALID_QUAL (st_aa_arvalid_qual), .S_VALID (st_aa_arvalid), .S_READY (st_aa_arready), // Granted AR command output .M_MESG (aa_mi_armesg), .M_TARGET_HOT (aa_mi_artarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_mi_argrant_enc), .M_VALID (aa_mi_arvalid), // SI-slot index of granted command .M_READY (aa_mi_arready), .ISSUING_LIMIT (mi_armaxissuing) ); if (C_DEBUG) begin : gen_debug_trans_seq // DEBUG WRITE TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_aw_trans_seq_i <= 1; end else begin if (aa_sa_awvalid && aa_sa_awready) begin debug_aw_trans_seq_i <= debug_aw_trans_seq_i + 1; end end end // DEBUG READ TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_ar_trans_seq_i <= 1; end else begin if (aa_mi_arvalid && aa_mi_arready) begin debug_ar_trans_seq_i <= debug_ar_trans_seq_i + 1; end end end end // gen_debug_trans_seq // Broadcast AR transfer payload to all MI-slots assign M_AXI_ARID = {C_NUM_MASTER_SLOTS{aa_mi_armesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_ARADDR = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_ARLEN = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_ARSIZE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_ARLOCK = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_ARPROT = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_ARREGION = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_ARBURST = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_ARCACHE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_ARQOS = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_ARUSER = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_ARUSER_WIDTH]}}; // AW arbiter command transfer completes upon completion of both M-side AW-channel transfer and W-mux address acceptance (command push). axi_crossbar_v2_1_splitter # // "SA": Splitter for Write Addr Arbiter ( .C_NUM_M (2) ) splitter_aw_mi ( .ACLK (ACLK), .ARESET (reset), .S_VALID (aa_sa_awvalid), .S_READY (aa_sa_awready), .M_VALID ({mi_awvalid_en, sa_wm_awvalid_en}), .M_READY ({mi_awready_mux, sa_wm_awready_mux}) ); assign mi_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{mi_awvalid_en}}; assign mi_awready_mux = \|(aa_mi_awtarget_hot & mi_awready); assign M_AXI_AWVALID = mi_awvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_awready[0+:C_NUM_MASTER_SLOTS] = M_AXI_AWREADY; assign sa_wm_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{sa_wm_awvalid_en}}; assign sa_wm_awready_mux = \|(aa_mi_awtarget_hot & sa_wm_awready); assign mi_arvalid = aa_mi_artarget_hot & {C_NUM_MASTER_SLOTS+1{aa_mi_arvalid}}; assign aa_mi_arready = \|(aa_mi_artarget_hot & mi_arready); assign M_AXI_ARVALID = mi_arvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_arready[0+:C_NUM_MASTER_SLOTS] = M_AXI_ARREADY; // MI-slot # C_NUM_MASTER_SLOTS is the error handler if (C_RANGE_CHECK) begin : gen_decerr_slave axi_crossbar_v2_1_decerr_slave # ( .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_RESP (P_DECERR) ) decerr_slave_inst ( .S_AXI_ACLK (ACLK), .S_AXI_ARESET (reset), .S_AXI_AWID (aa_mi_awmesg[0+:C_AXI_ID_WIDTH]), .S_AXI_AWVALID (mi_awvalid[C_NUM_MASTER_SLOTS]), .S_AXI_AWREADY (mi_awready[C_NUM_MASTER_SLOTS]), .S_AXI_WLAST (mi_wlast[C_NUM_MASTER_SLOTS]), .S_AXI_WVALID (mi_wvalid[C_NUM_MASTER_SLOTS]), .S_AXI_WREADY (mi_wready[C_NUM_MASTER_SLOTS]), .S_AXI_BID (mi_bid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_BRESP (mi_bresp[C_NUM_MASTER_SLOTS2+:2]), .S_AXI_BUSER (mi_buser[C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH]), .S_AXI_BVALID (mi_bvalid[C_NUM_MASTER_SLOTS]), .S_AXI_BREADY (mi_bready[C_NUM_MASTER_SLOTS]), .S_AXI_ARID (aa_mi_armesg[0+:C_AXI_ID_WIDTH]), .S_AXI_ARLEN (aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]), .S_AXI_ARVALID (mi_arvalid[C_NUM_MASTER_SLOTS]), .S_AXI_ARREADY (mi_arready[C_NUM_MASTER_SLOTS]), .S_AXI_RID (mi_rid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_RDATA (mi_rdata[C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .S_AXI_RRESP (mi_rresp[C_NUM_MASTER_SLOTS2+:2]), .S_AXI_RUSER (mi_ruser[C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH]), .S_AXI_RLAST (mi_rlast[C_NUM_MASTER_SLOTS]), .S_AXI_RVALID (mi_rvalid[C_NUM_MASTER_SLOTS]), .S_AXI_RREADY (mi_rready[C_NUM_MASTER_SLOTS]) ); end else begin : gen_no_decerr_slave assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_wready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_arready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_bid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_bresp[C_NUM_MASTER_SLOTS2+:2] = 0; assign mi_buser[C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign mi_bvalid[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_rdata[C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign mi_rresp[C_NUM_MASTER_SLOTS2+:2] = 0; assign mi_ruser[C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign mi_rlast[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rvalid[C_NUM_MASTER_SLOTS] = 1'b0; end // gen_decerr_slave endgenerate endmodule
module axi_crossbar_v2_1_crossbar # ( parameter C_FAMILY = "none", parameter integer C_NUM_SLAVE_SLOTS = 1, parameter integer C_NUM_MASTER_SLOTS = 1, parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_PROTOCOL = 0, parameter [C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64-1:0] C_M_AXI_BASE_ADDR = {C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64{1'b1}}, parameter [C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64-1:0] C_M_AXI_HIGH_ADDR = {C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS64-1:0] C_S_AXI_BASE_ID = {C_NUM_SLAVE_SLOTS64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS64-1:0] C_S_AXI_HIGH_ID = {C_NUM_SLAVE_SLOTS64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_THREAD_ID_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_AWUSER_WIDTH = 1, parameter integer C_AXI_ARUSER_WIDTH = 1, parameter integer C_AXI_WUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_BUSER_WIDTH = 1, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_WRITE = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_READ = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_WRITE = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_READ = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_WRITE_CONNECTIVITY = {C_NUM_MASTER_SLOTS32{1'b1}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_READ_CONNECTIVITY = {C_NUM_MASTER_SLOTS32{1'b1}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_SINGLE_THREAD = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_WRITE_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_READ_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_WRITE_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_READ_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_ARB_PRIORITY = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_SECURE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_ERR_MODE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE = 0, parameter [(C_NUM_MASTER_SLOTS+1)32-1:0] C_W_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [(C_NUM_MASTER_SLOTS+1)32-1:0] C_R_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_W_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_R_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESETN, // Slave Interface Write Address Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_AWID, input wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR, input wire [C_NUM_SLAVE_SLOTS8-1:0] S_AXI_AWLEN, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_AWSIZE, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_AWBURST, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_AWLOCK, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWCACHE, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_AWPROT, // input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWREGION, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWQOS, input wire [C_NUM_SLAVE_SLOTSC_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWREADY, // Slave Interface Write Data Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_WID, input wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH-1:0] S_AXI_WDATA, input wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WLAST, input wire [C_NUM_SLAVE_SLOTSC_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WREADY, // Slave Interface Write Response Ports output wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_BID, output wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_BRESP, output wire [C_NUM_SLAVE_SLOTSC_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BREADY, // Slave Interface Read Address Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_ARID, input wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR, input wire [C_NUM_SLAVE_SLOTS8-1:0] S_AXI_ARLEN, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_ARSIZE, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_ARBURST, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_ARLOCK, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARCACHE, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_ARPROT, // input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARREGION, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARQOS, input wire [C_NUM_SLAVE_SLOTSC_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARREADY, // Slave Interface Read Data Ports output wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_RID, output wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH-1:0] S_AXI_RDATA, output wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_RRESP, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RLAST, output wire [C_NUM_SLAVE_SLOTSC_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RREADY, // Master Interface Write Address Port output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_AWID, output wire [C_NUM_MASTER_SLOTSC_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR, output wire [C_NUM_MASTER_SLOTS8-1:0] M_AXI_AWLEN, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_AWSIZE, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_AWBURST, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_AWLOCK, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWCACHE, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_AWPROT, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWREGION, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWQOS, output wire [C_NUM_MASTER_SLOTSC_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWREADY, // Master Interface Write Data Ports output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_WID, output wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH-1:0] M_AXI_WDATA, output wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WLAST, output wire [C_NUM_MASTER_SLOTSC_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WREADY, // Master Interface Write Response Ports input wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_BID, input wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_BRESP, input wire [C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BREADY, // Master Interface Read Address Port output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_ARID, output wire [C_NUM_MASTER_SLOTSC_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR, output wire [C_NUM_MASTER_SLOTS8-1:0] M_AXI_ARLEN, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_ARSIZE, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_ARBURST, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_ARLOCK, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARCACHE, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_ARPROT, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARREGION, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARQOS, output wire [C_NUM_MASTER_SLOTSC_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARREADY, // Master Interface Read Data Ports input wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_RID, input wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH-1:0] M_AXI_RDATA, input wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_RRESP, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RLAST, input wire [C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RREADY ); localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_NUM_MASTER_SLOTS_LOG = f_ceil_log2(C_NUM_MASTER_SLOTS); localparam integer P_NUM_SLAVE_SLOTS_LOG = f_ceil_log2((C_NUM_SLAVE_SLOTS>1) ? C_NUM_SLAVE_SLOTS : 2); localparam integer P_AXI_WID_WIDTH = (C_AXI_PROTOCOL == P_AXI3) ? C_AXI_ID_WIDTH : 1; localparam integer P_ST_AWMESG_WIDTH = 2+4+4 + C_AXI_AWUSER_WIDTH; localparam integer P_AA_AWMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_AWMESG_WIDTH; localparam integer P_ST_ARMESG_WIDTH = 2+4+4 + C_AXI_ARUSER_WIDTH; localparam integer P_AA_ARMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_ARMESG_WIDTH; localparam integer P_ST_BMESG_WIDTH = 2 + C_AXI_BUSER_WIDTH; localparam integer P_ST_RMESG_WIDTH = 2 + C_AXI_RUSER_WIDTH + C_AXI_DATA_WIDTH; localparam integer P_WR_WMESG_WIDTH = C_AXI_DATA_WIDTH + C_AXI_DATA_WIDTH/8 + C_AXI_WUSER_WIDTH + P_AXI_WID_WIDTH; localparam [31:0] P_BYPASS = 32'h00000000; localparam [31:0] P_FWD_REV = 32'h00000001; localparam [31:0] P_SIMPLE = 32'h00000007; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_READ = {1'b1, C_M_AXI_SUPPORTS_READ[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_WRITE = {1'b1, C_M_AXI_SUPPORTS_WRITE[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_WRITE_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_WRITE_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS32]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_READ_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_READ_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS32]}; localparam [C_NUM_SLAVE_SLOTS32-1:0] P_S_AXI_WRITE_CONNECTIVITY = f_si_write_connectivity(0); localparam [C_NUM_SLAVE_SLOTS32-1:0] P_S_AXI_READ_CONNECTIVITY = f_si_read_connectivity(0); localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_READ_ISSUING = {32'h00000001, C_M_AXI_READ_ISSUING[0+:C_NUM_MASTER_SLOTS32]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_WRITE_ISSUING = {32'h00000001, C_M_AXI_WRITE_ISSUING[0+:C_NUM_MASTER_SLOTS32]}; localparam P_DECERR = 2'b11; //--------------------------------------------------------------------------- // Functions //--------------------------------------------------------------------------- // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // Isolate thread bits of input S_ID and add to BASE_ID (RNG00) to form MI-side ID value // only for end-point SI-slots function [C_AXI_ID_WIDTH-1:0] f_extend_ID ( input [C_AXI_ID_WIDTH-1:0] s_id, input integer slot ); begin f_extend_ID = C_S_AXI_BASE_ID[slot64+:C_AXI_ID_WIDTH] \| (s_id & (C_S_AXI_BASE_ID[slot64+:C_AXI_ID_WIDTH] ^ C_S_AXI_HIGH_ID[slot64+:C_AXI_ID_WIDTH])); end endfunction // Write connectivity array transposed function [C_NUM_SLAVE_SLOTS32-1:0] f_si_write_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot32+mi_slot] = C_M_AXI_WRITE_CONNECTIVITY[mi_slot32+si_slot]; end end f_si_write_connectivity = result; end endfunction // Read connectivity array transposed function [C_NUM_SLAVE_SLOTS32-1:0] f_si_read_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot32+mi_slot] = C_M_AXI_READ_CONNECTIVITY[mi_slot32+si_slot]; end end f_si_read_connectivity = result; end endfunction genvar gen_si_slot; genvar gen_mi_slot; wire [C_NUM_SLAVE_SLOTSP_ST_AWMESG_WIDTH-1:0] si_st_awmesg ; wire [C_NUM_SLAVE_SLOTSP_ST_AWMESG_WIDTH-1:0] st_tmp_awmesg ; wire [C_NUM_SLAVE_SLOTSP_AA_AWMESG_WIDTH-1:0] tmp_aa_awmesg ; wire [P_AA_AWMESG_WIDTH-1:0] aa_mi_awmesg ; wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] st_aa_awid ; wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] st_aa_awaddr ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_awlen ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_awsize ; wire [C_NUM_SLAVE_SLOTS2-1:0] st_aa_awlock ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_awprot ; wire [C_NUM_SLAVE_SLOTS4-1:0] st_aa_awregion ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_awerror ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_awtarget_enc ; wire [P_NUM_SLAVE_SLOTS_LOG1-1:0] aa_wm_awgrant_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_awvalid_qual ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_ss_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_ss_awready ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_wr_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_wr_awready ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_aa_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_aa_awready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] sa_wm_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] sa_wm_awready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awready ; wire aa_sa_awvalid ; wire aa_sa_awready ; wire aa_mi_arready ; wire mi_awvalid_en ; wire sa_wm_awvalid_en ; wire sa_wm_awready_mux ; wire [C_NUM_SLAVE_SLOTSP_ST_ARMESG_WIDTH-1:0] si_st_armesg ; wire [C_NUM_SLAVE_SLOTSP_ST_ARMESG_WIDTH-1:0] st_tmp_armesg ; wire [C_NUM_SLAVE_SLOTSP_AA_ARMESG_WIDTH-1:0] tmp_aa_armesg ; wire [P_AA_ARMESG_WIDTH-1:0] aa_mi_armesg ; wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] st_aa_arid ; wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] st_aa_araddr ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_arlen ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_arsize ; wire [C_NUM_SLAVE_SLOTS2-1:0] st_aa_arlock ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_arprot ; wire [C_NUM_SLAVE_SLOTS4-1:0] st_aa_arregion ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_arerror ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_artarget_hot ; wire [C_NUM_SLAVE_SLOTS(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_artarget_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_artarget_hot ; wire [P_NUM_SLAVE_SLOTS_LOG1-1:0] aa_mi_argrant_enc ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arvalid_qual ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_arvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_arready ; wire aa_mi_arvalid ; wire mi_awready_mux ; wire [C_NUM_SLAVE_SLOTSP_ST_BMESG_WIDTH-1:0] st_si_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)P_ST_BMESG_WIDTH-1:0] st_mr_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] st_mr_bid ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] st_mr_bresp ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_BUSER_WIDTH-1:0] st_mr_buser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_mr_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)P_NUM_SLAVE_SLOTS_LOG-1:0] debug_bid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] bid_match ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_bid ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] mi_bresp ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_BUSER_WIDTH-1:0] mi_buser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] bready_carry ; wire [C_NUM_SLAVE_SLOTSP_ST_RMESG_WIDTH-1:0] st_si_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)P_ST_RMESG_WIDTH-1:0] st_mr_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] st_mr_rid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] st_mr_rdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_RUSER_WIDTH-1:0] st_mr_ruser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rlast ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] st_mr_rresp ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_mr_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)P_NUM_SLAVE_SLOTS_LOG-1:0] debug_rid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] rid_match ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_rid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] mi_rdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_RUSER_WIDTH-1:0] mi_ruser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rlast ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] mi_rresp ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] rready_carry ; wire [C_NUM_SLAVE_SLOTSP_WR_WMESG_WIDTH-1:0] si_wr_wmesg ; wire [C_NUM_SLAVE_SLOTSP_WR_WMESG_WIDTH-1:0] wr_wm_wmesg ; wire [C_NUM_SLAVE_SLOTS1-1:0] wr_wm_wlast ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wvalid ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wready ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wready ; wire [(C_NUM_MASTER_SLOTS+1)P_WR_WMESG_WIDTH-1:0] wm_mr_wmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] wm_mr_wdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH/8-1:0] wm_mr_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] wm_mr_wid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_WUSER_WIDTH-1:0] wm_mr_wuser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wlast ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wready ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] mi_wdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH/8-1:0] mi_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_WUSER_WIDTH-1:0] mi_wuser ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_wid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wlast ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] w_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] w_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] r_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] r_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awmaxissuing ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_armaxissuing ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] w_issuing_cnt ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] r_issuing_cnt ; reg [8-1:0] debug_aw_trans_seq_i ; reg [8-1:0] debug_ar_trans_seq_i ; wire [(C_NUM_MASTER_SLOTS+1)8-1:0] debug_w_trans_seq_i ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] debug_w_beat_cnt_i ; reg aresetn_d = 1'b0; // Reset delay register always @(posedge ACLK) begin if (~ARESETN) begin aresetn_d <= 1'b0; end else begin aresetn_d <= ARESETN; end end wire reset; assign reset = ~aresetn_d; generate for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_slave_slots if (C_S_AXI_SUPPORTS_READ[gen_si_slot]) begin : gen_si_read axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (read channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_READ), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_READ_ACCEPTANCE[gen_si_slot32+:32]), .C_ACCEPTANCE_LOG (C_R_ACCEPT_WIDTH[gen_si_slot32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_ARMESG_WIDTH), .C_RMESG_WIDTH (P_ST_RMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_READ_CONNECTIVITY[gen_si_slot32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_ar ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_ARID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_ARADDR[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_ARLEN[gen_si_slot8+:8]), .S_ASIZE (S_AXI_ARSIZE[gen_si_slot3+:3]), .S_ABURST (S_AXI_ARBURST[gen_si_slot2+:2]), .S_ALOCK (S_AXI_ARLOCK[gen_si_slot2+:2]), .S_APROT (S_AXI_ARPROT[gen_si_slot3+:3]), // .S_AREGION (S_AXI_ARREGION[gen_si_slot4+:4]), .S_AMESG (si_st_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .S_AVALID (S_AXI_ARVALID[gen_si_slot]), .S_AREADY (S_AXI_ARREADY[gen_si_slot]), .M_AID (st_aa_arid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_araddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_arlen[gen_si_slot8+:8]), .M_ASIZE (st_aa_arsize[gen_si_slot3+:3]), .M_ALOCK (st_aa_arlock[gen_si_slot2+:2]), .M_APROT (st_aa_arprot[gen_si_slot3+:3]), .M_AREGION (st_aa_arregion[gen_si_slot4+:4]), .M_AMESG (st_tmp_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .M_ATARGET_HOT (st_aa_artarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_artarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_arerror[gen_si_slot8+:8]), .M_AVALID_QUAL (st_aa_arvalid_qual[gen_si_slot]), .M_AVALID (st_aa_arvalid[gen_si_slot]), .M_AREADY (st_aa_arready[gen_si_slot]), .S_RID (S_AXI_RID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH]), .S_RLAST (S_AXI_RLAST[gen_si_slot]), .S_RVALID (S_AXI_RVALID[gen_si_slot]), .S_RREADY (S_AXI_RREADY[gen_si_slot]), .M_RID (st_mr_rid), .M_RLAST (st_mr_rlast), .M_RMESG (st_mr_rmesg), .M_RVALID (st_mr_rvalid), .M_RREADY (st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_rid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_ar_trans_seq_i : 8'h0) ); assign si_st_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH] = { S_AXI_ARUSER[gen_si_slotC_AXI_ARUSER_WIDTH+:C_AXI_ARUSER_WIDTH], S_AXI_ARQOS[gen_si_slot4+:4], S_AXI_ARCACHE[gen_si_slot4+:4], S_AXI_ARBURST[gen_si_slot2+:2] }; assign tmp_aa_armesg[gen_si_slotP_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = { st_tmp_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH], st_aa_arregion[gen_si_slot4+:4], st_aa_arprot[gen_si_slot3+:3], st_aa_arlock[gen_si_slot2+:2], st_aa_arsize[gen_si_slot3+:3], st_aa_arlen[gen_si_slot8+:8], st_aa_araddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_arid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_RRESP[gen_si_slot2+:2] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+:2]; assign S_AXI_RUSER[gen_si_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+2 +: C_AXI_RUSER_WIDTH]; assign S_AXI_RDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+2+C_AXI_RUSER_WIDTH +: C_AXI_DATA_WIDTH]; end else begin : gen_no_si_read assign S_AXI_ARREADY[gen_si_slot] = 1'b0; assign st_aa_arvalid[gen_si_slot] = 1'b0; assign st_aa_arvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_armesg[gen_si_slotP_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = 0; assign S_AXI_RID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_RRESP[gen_si_slot2+:2] = 0; assign S_AXI_RUSER[gen_si_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign S_AXI_RDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign S_AXI_RVALID[gen_si_slot] = 1'b0; assign S_AXI_RLAST[gen_si_slot] = 1'b0; assign st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_artarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_read if (C_S_AXI_SUPPORTS_WRITE[gen_si_slot]) begin : gen_si_write axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (write channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_WRITE), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_WRITE_ACCEPTANCE[gen_si_slot32+:32]), .C_ACCEPTANCE_LOG (C_W_ACCEPT_WIDTH[gen_si_slot32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_AWMESG_WIDTH), .C_RMESG_WIDTH (P_ST_BMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_WRITE_CONNECTIVITY[gen_si_slot32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_aw ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_AWID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_AWADDR[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_AWLEN[gen_si_slot8+:8]), .S_ASIZE (S_AXI_AWSIZE[gen_si_slot3+:3]), .S_ABURST (S_AXI_AWBURST[gen_si_slot2+:2]), .S_ALOCK (S_AXI_AWLOCK[gen_si_slot2+:2]), .S_APROT (S_AXI_AWPROT[gen_si_slot3+:3]), // .S_AREGION (S_AXI_AWREGION[gen_si_slot4+:4]), .S_AMESG (si_st_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .S_AVALID (S_AXI_AWVALID[gen_si_slot]), .S_AREADY (S_AXI_AWREADY[gen_si_slot]), .M_AID (st_aa_awid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_awaddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_awlen[gen_si_slot8+:8]), .M_ASIZE (st_aa_awsize[gen_si_slot3+:3]), .M_ALOCK (st_aa_awlock[gen_si_slot2+:2]), .M_APROT (st_aa_awprot[gen_si_slot3+:3]), .M_AREGION (st_aa_awregion[gen_si_slot4+:4]), .M_AMESG (st_tmp_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .M_ATARGET_HOT (st_aa_awtarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_awtarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_awerror[gen_si_slot8+:8]), .M_AVALID_QUAL (st_aa_awvalid_qual[gen_si_slot]), .M_AVALID (st_ss_awvalid[gen_si_slot]), .M_AREADY (st_ss_awready[gen_si_slot]), .S_RID (S_AXI_BID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH]), .S_RLAST (), .S_RVALID (S_AXI_BVALID[gen_si_slot]), .S_RREADY (S_AXI_BREADY[gen_si_slot]), .M_RID (st_mr_bid), .M_RLAST ({(C_NUM_MASTER_SLOTS+1){1'b1}}), .M_RMESG (st_mr_bmesg), .M_RVALID (st_mr_bvalid), .M_RREADY (st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_bid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_aw_trans_seq_i : 8'h0) ); // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign si_st_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH] = { S_AXI_AWUSER[gen_si_slotC_AXI_AWUSER_WIDTH+:C_AXI_AWUSER_WIDTH], S_AXI_AWQOS[gen_si_slot4+:4], S_AXI_AWCACHE[gen_si_slot4+:4], S_AXI_AWBURST[gen_si_slot2+:2] }; assign tmp_aa_awmesg[gen_si_slotP_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = { st_tmp_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH], st_aa_awregion[gen_si_slot4+:4], st_aa_awprot[gen_si_slot3+:3], st_aa_awlock[gen_si_slot2+:2], st_aa_awsize[gen_si_slot3+:3], st_aa_awlen[gen_si_slot8+:8], st_aa_awaddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_awid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_BRESP[gen_si_slot2+:2] = st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+:2]; assign S_AXI_BUSER[gen_si_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+2 +: C_AXI_BUSER_WIDTH]; // AW SI-transactor transfer completes upon completion of both W-router address acceptance (command push) and AW arbitration axi_crossbar_v2_1_splitter # // "SS": Splitter from SI-Transactor (write channel) ( .C_NUM_M (2) ) splitter_aw_si ( .ACLK (ACLK), .ARESET (reset), .S_VALID (st_ss_awvalid[gen_si_slot]), .S_READY (st_ss_awready[gen_si_slot]), .M_VALID ({ss_wr_awvalid[gen_si_slot], ss_aa_awvalid[gen_si_slot]}), .M_READY ({ss_wr_awready[gen_si_slot], ss_aa_awready[gen_si_slot]}) ); axi_crossbar_v2_1_wdata_router # // "WR": Write data Router ( .C_FAMILY (C_FAMILY), .C_NUM_MASTER_SLOTS (C_NUM_MASTER_SLOTS+1), .C_SELECT_WIDTH (P_NUM_MASTER_SLOTS_LOG+1), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ACCEPT_WIDTH[gen_si_slot32+:6]) ) wdata_router_w ( .ACLK (ACLK), .ARESET (reset), // Write transfer input from the current SI-slot .S_WMESG (si_wr_wmesg[gen_si_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .S_WLAST (S_AXI_WLAST[gen_si_slot]), .S_WVALID (S_AXI_WVALID[gen_si_slot]), .S_WREADY (S_AXI_WREADY[gen_si_slot]), // Vector of write transfer outputs to each MI-slot's W-mux .M_WMESG (wr_wm_wmesg[gen_si_slot(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH]), .M_WLAST (wr_wm_wlast[gen_si_slot]), .M_WVALID (wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_WREADY (wr_tmp_wready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), // AW command push from local SI-slot .S_ASELECT (st_aa_awtarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), // Target MI-slot .S_AVALID (ss_wr_awvalid[gen_si_slot]), .S_AREADY (ss_wr_awready[gen_si_slot]) ); assign si_wr_wmesg[gen_si_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH] = { ((C_AXI_PROTOCOL == P_AXI3) ? f_extend_ID(S_AXI_WID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot) : 1'b0), S_AXI_WUSER[gen_si_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH], S_AXI_WSTRB[gen_si_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8], S_AXI_WDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] }; end else begin : gen_no_si_write assign S_AXI_AWREADY[gen_si_slot] = 1'b0; assign ss_aa_awvalid[gen_si_slot] = 1'b0; assign st_aa_awvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_awmesg[gen_si_slotP_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = 0; assign S_AXI_BID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_BRESP[gen_si_slot2+:2] = 0; assign S_AXI_BUSER[gen_si_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign S_AXI_BVALID[gen_si_slot] = 1'b0; assign st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign S_AXI_WREADY[gen_si_slot] = 1'b0; assign wr_wm_wmesg[gen_si_slot(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH] = 0; assign wr_wm_wlast[gen_si_slot] = 1'b0; assign wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_awtarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_write end // gen_slave_slots for (gen_mi_slot=0; gen_mi_slot<C_NUM_MASTER_SLOTS+1; gen_mi_slot=gen_mi_slot+1) begin : gen_master_slots if (P_M_AXI_SUPPORTS_READ[gen_mi_slot]) begin : gen_mi_read if (C_NUM_SLAVE_SLOTS>1) begin : gen_rid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_READ_CONNECTIVITY[gen_mi_slot32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) rid_decoder_inst ( .ADDR (st_mr_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_rid_target_i[gen_mi_slotP_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (rid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_rid_decoder assign tmp_mr_rid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign rid_match[gen_mi_slot] = 1'b1; end assign st_mr_rmesg[gen_mi_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = { st_mr_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH], st_mr_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH], st_mr_rresp[gen_mi_slot2+:2] }; end else begin : gen_no_mi_read assign tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign rid_match[gen_mi_slot] = 1'b0; assign st_mr_rmesg[gen_mi_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = 0; end // gen_mi_read if (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]) begin : gen_mi_write if (C_NUM_SLAVE_SLOTS>1) begin : gen_bid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_WRITE_CONNECTIVITY[gen_mi_slot32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) bid_decoder_inst ( .ADDR (st_mr_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_bid_target_i[gen_mi_slotP_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (bid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_bid_decoder assign tmp_mr_bid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign bid_match[gen_mi_slot] = 1'b1; end axi_crossbar_v2_1_wdata_mux # // "WM": Write data Mux, per MI-slot (incl error-handler) ( .C_FAMILY (C_FAMILY), .C_NUM_SLAVE_SLOTS (C_NUM_SLAVE_SLOTS), .C_SELECT_WIDTH (P_NUM_SLAVE_SLOTS_LOG), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]) ) wdata_mux_w ( .ACLK (ACLK), .ARESET (reset), // Vector of write transfer inputs from each SI-slot's W-router .S_WMESG (wr_wm_wmesg), .S_WLAST (wr_wm_wlast), .S_WVALID (tmp_wm_wvalid[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .S_WREADY (tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), // Write transfer output to the current MI-slot .M_WMESG (wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .M_WLAST (wm_mr_wlast[gen_mi_slot]), .M_WVALID (wm_mr_wvalid[gen_mi_slot]), .M_WREADY (wm_mr_wready[gen_mi_slot]), // AW command push from AW arbiter output .S_ASELECT (aa_wm_awgrant_enc), // SI-slot selected by arbiter .S_AVALID (sa_wm_awvalid[gen_mi_slot]), .S_AREADY (sa_wm_awready[gen_mi_slot]) ); if (C_DEBUG) begin : gen_debug_w // DEBUG WRITE BEAT COUNTER always @(posedge ACLK) begin if (reset) begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= 0; end else begin if (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot]) begin if (mi_wlast[gen_mi_slot]) begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= 0; end else begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= debug_w_beat_cnt_i[gen_mi_slot8+:8] + 1; end end end end // clocked process // DEBUG W-CHANNEL TRANSACTION SEQUENCE QUEUE axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]), .C_USE_FULL (0) ) debug_w_seq_fifo ( .ACLK (ACLK), .ARESET (reset), .S_MESG (debug_aw_trans_seq_i), .S_VALID (sa_wm_awvalid[gen_mi_slot]), .S_READY (), .M_MESG (debug_w_trans_seq_i[gen_mi_slot8+:8]), .M_VALID (), .M_READY (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot] & mi_wlast[gen_mi_slot]) ); end // gen_debug_w assign wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH +: C_AXI_DATA_WIDTH]; assign wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH +: C_AXI_DATA_WIDTH/8]; assign wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+C_AXI_DATA_WIDTH/8 +: C_AXI_WUSER_WIDTH]; assign wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+(C_AXI_DATA_WIDTH/8)+C_AXI_WUSER_WIDTH +: P_AXI_WID_WIDTH]; assign st_mr_bmesg[gen_mi_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = { st_mr_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH], st_mr_bresp[gen_mi_slot2+:2] }; end else begin : gen_no_mi_write assign tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign bid_match[gen_mi_slot] = 1'b0; assign wm_mr_wvalid[gen_mi_slot] = 0; assign wm_mr_wlast[gen_mi_slot] = 0; assign wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = 0; assign wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = 0; assign wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign st_mr_bmesg[gen_mi_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = 0; assign tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign sa_wm_awready[gen_mi_slot] = 0; end // gen_mi_write for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_trans_si // Transpose handshakes from W-router (SxM) to W-mux (MxS). assign tmp_wm_wvalid[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot] = wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; assign wr_tmp_wready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; // Transpose response enables from ID decoders (MxS) to si_transactors (SxM). assign st_tmp_bid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; assign st_tmp_rid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; end // gen_trans_si assign bready_carry[gen_mi_slot] = st_tmp_bready[gen_mi_slot]; assign rready_carry[gen_mi_slot] = st_tmp_rready[gen_mi_slot]; for (gen_si_slot=1; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_resp_carry_si assign bready_carry[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_BREADY if ... bready_carry[(gen_si_slot-1)(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] \| // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates BREADY for that MI-slot. assign rready_carry[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_RREADY if ... rready_carry[(gen_si_slot-1)(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] \| // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates RREADY for that MI-slot. end // gen_resp_carry_si assign w_cmd_push[gen_mi_slot] = mi_awvalid[gen_mi_slot] && mi_awready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_push[gen_mi_slot] = mi_arvalid[gen_mi_slot] && mi_arready[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; assign w_cmd_pop[gen_mi_slot] = st_mr_bvalid[gen_mi_slot] && st_mr_bready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_pop[gen_mi_slot] = st_mr_rvalid[gen_mi_slot] && st_mr_rready[gen_mi_slot] && st_mr_rlast[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; // Disqualify arbitration of SI-slot if targeted MI-slot has reached its issuing limit. assign mi_awmaxissuing[gen_mi_slot] = (w_issuing_cnt[gen_mi_slot8 +: (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] == P_M_AXI_WRITE_ISSUING[gen_mi_slot32 +: (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)]) & ~w_cmd_pop[gen_mi_slot]; assign mi_armaxissuing[gen_mi_slot] = (r_issuing_cnt[gen_mi_slot8 +: (C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] == P_M_AXI_READ_ISSUING[gen_mi_slot32 +: (C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)]) & ~r_cmd_pop[gen_mi_slot]; always @(posedge ACLK) begin if (reset) begin w_issuing_cnt[gen_mi_slot8+:8] <= 0; // Some high-order bits remain constant 0 r_issuing_cnt[gen_mi_slot8+:8] <= 0; // Some high-order bits remain constant 0 end else begin if (w_cmd_push[gen_mi_slot] && ~w_cmd_pop[gen_mi_slot]) begin w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] + 1; end else if (w_cmd_pop[gen_mi_slot] && ~w_cmd_push[gen_mi_slot] && (\|w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)])) begin w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] - 1; end if (r_cmd_push[gen_mi_slot] && ~r_cmd_pop[gen_mi_slot]) begin r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] + 1; end else if (r_cmd_pop[gen_mi_slot] && ~r_cmd_push[gen_mi_slot] && (\|r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)])) begin r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] - 1; end end end // Clocked process // Reg-slice must break combinatorial path from M_BID and M_RID inputs to M_BREADY and M_RREADY outputs. // (See m_rready_i and m_resp_en combinatorial assignments in si_transactor.) // Reg-slice incurs +1 latency, but no bubble-cycles. axi_register_slice_v2_1_axi_register_slice # // "MR": MI-side R/B-channel Reg-slice, per MI-slot (pass-through if only 1 SI-slot configured) ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL ((C_AXI_PROTOCOL == P_AXI3) ? P_AXI3 : P_AXI4), .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (1), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (C_AXI_SUPPORTS_USER_SIGNALS), .C_AXI_AWUSER_WIDTH (1), .C_AXI_ARUSER_WIDTH (1), .C_AXI_WUSER_WIDTH (C_AXI_WUSER_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_REG_CONFIG_AW (P_BYPASS), .C_REG_CONFIG_AR (P_BYPASS), .C_REG_CONFIG_W (P_BYPASS), .C_REG_CONFIG_R (P_M_AXI_SUPPORTS_READ[gen_mi_slot] ? P_FWD_REV : P_BYPASS), .C_REG_CONFIG_B (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot] ? P_SIMPLE : P_BYPASS) ) reg_slice_mi ( .aresetn (ARESETN), .aclk (ACLK), .s_axi_awid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_awaddr ({1{1'b0}}), .s_axi_awlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_awsize ({3{1'b0}}), .s_axi_awburst ({2{1'b0}}), .s_axi_awlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_awcache ({4{1'b0}}), .s_axi_awprot ({3{1'b0}}), .s_axi_awregion ({4{1'b0}}), .s_axi_awqos ({4{1'b0}}), .s_axi_awuser ({1{1'b0}}), .s_axi_awvalid ({1{1'b0}}), .s_axi_awready (), .s_axi_wid (wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .s_axi_wdata (wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .s_axi_wstrb (wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .s_axi_wlast (wm_mr_wlast[gen_mi_slot]), .s_axi_wuser (wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .s_axi_wvalid (wm_mr_wvalid[gen_mi_slot]), .s_axi_wready (wm_mr_wready[gen_mi_slot]), .s_axi_bid (st_mr_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_bresp (st_mr_bresp[gen_mi_slot2+:2] ), .s_axi_buser (st_mr_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .s_axi_bvalid (st_mr_bvalid[gen_mi_slot1+:1] ), .s_axi_bready (st_mr_bready[gen_mi_slot1+:1] ), .s_axi_arid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_araddr ({1{1'b0}}), .s_axi_arlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_arsize ({3{1'b0}}), .s_axi_arburst ({2{1'b0}}), .s_axi_arlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_arcache ({4{1'b0}}), .s_axi_arprot ({3{1'b0}}), .s_axi_arregion ({4{1'b0}}), .s_axi_arqos ({4{1'b0}}), .s_axi_aruser ({1{1'b0}}), .s_axi_arvalid ({1{1'b0}}), .s_axi_arready (), .s_axi_rid (st_mr_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_rdata (st_mr_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .s_axi_rresp (st_mr_rresp[gen_mi_slot2+:2] ), .s_axi_rlast (st_mr_rlast[gen_mi_slot1+:1] ), .s_axi_ruser (st_mr_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .s_axi_rvalid (st_mr_rvalid[gen_mi_slot1+:1] ), .s_axi_rready (st_mr_rready[gen_mi_slot1+:1] ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready ({1{1'b0}}), .m_axi_wid (mi_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .m_axi_wdata (mi_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .m_axi_wstrb (mi_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .m_axi_wlast (mi_wlast[gen_mi_slot]), .m_axi_wuser (mi_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .m_axi_wvalid (mi_wvalid[gen_mi_slot]), .m_axi_wready (mi_wready[gen_mi_slot]), .m_axi_bid (mi_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_bresp (mi_bresp[gen_mi_slot2+:2] ), .m_axi_buser (mi_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .m_axi_bvalid (mi_bvalid[gen_mi_slot1+:1] ), .m_axi_bready (mi_bready[gen_mi_slot1+:1] ), .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready ({1{1'b0}}), .m_axi_rid (mi_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_rdata (mi_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .m_axi_rresp (mi_rresp[gen_mi_slot2+:2] ), .m_axi_rlast (mi_rlast[gen_mi_slot1+:1] ), .m_axi_ruser (mi_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .m_axi_rvalid (mi_rvalid[gen_mi_slot1+:1] ), .m_axi_rready (mi_rready[gen_mi_slot1+:1] ) ); end // gen_master_slots (Next gen_mi_slot) // Highest row of ready_carry contains accumulated OR across all SI-slots, for each MI-slot. assign st_mr_bready = bready_carry[(C_NUM_SLAVE_SLOTS-1)(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; assign st_mr_rready = rready_carry[(C_NUM_SLAVE_SLOTS-1)(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; // Assign MI-side B, R and W channel ports (exclude error handler signals). assign mi_bid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] = M_AXI_BID; assign mi_bvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_BVALID; assign mi_bresp[0+:C_NUM_MASTER_SLOTS2] = M_AXI_BRESP; assign mi_buser[0+:C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH] = M_AXI_BUSER; assign M_AXI_BREADY = mi_bready[0+:C_NUM_MASTER_SLOTS]; assign mi_rid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] = M_AXI_RID; assign mi_rlast[0+:C_NUM_MASTER_SLOTS] = M_AXI_RLAST; assign mi_rvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_RVALID; assign mi_rresp[0+:C_NUM_MASTER_SLOTS2] = M_AXI_RRESP; assign mi_ruser[0+:C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH] = M_AXI_RUSER; assign mi_rdata[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH] = M_AXI_RDATA; assign M_AXI_RREADY = mi_rready[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WLAST = mi_wlast[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WVALID = mi_wvalid[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WUSER = mi_wuser[0+:C_NUM_MASTER_SLOTSC_AXI_WUSER_WIDTH]; assign M_AXI_WID = (C_AXI_PROTOCOL == P_AXI3) ? mi_wid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] : 0; assign M_AXI_WDATA = mi_wdata[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH]; assign M_AXI_WSTRB = mi_wstrb[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH/8]; assign mi_wready[0+:C_NUM_MASTER_SLOTS] = M_AXI_WREADY; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AW channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_AWMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_aw ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AW command request inputs .S_MESG (tmp_aa_awmesg), .S_TARGET_HOT (st_aa_awtarget_hot), .S_VALID (ss_aa_awvalid), .S_VALID_QUAL (st_aa_awvalid_qual), .S_READY (ss_aa_awready), // Granted AW command output .M_MESG (aa_mi_awmesg), .M_TARGET_HOT (aa_mi_awtarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_wm_awgrant_enc), // SI-slot index of granted command .M_VALID (aa_sa_awvalid), .M_READY (aa_sa_awready), .ISSUING_LIMIT (mi_awmaxissuing) ); // Broadcast AW transfer payload to all MI-slots assign M_AXI_AWID = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_AWADDR = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_AWLEN = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_AWSIZE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_AWLOCK = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_AWPROT = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_AWREGION = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_AWBURST = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_AWCACHE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_AWQOS = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_AWUSER = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_AWUSER_WIDTH]}}; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AR channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_ARMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_ar ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AR command request inputs .S_MESG (tmp_aa_armesg), .S_TARGET_HOT (st_aa_artarget_hot), .S_VALID_QUAL (st_aa_arvalid_qual), .S_VALID (st_aa_arvalid), .S_READY (st_aa_arready), // Granted AR command output .M_MESG (aa_mi_armesg), .M_TARGET_HOT (aa_mi_artarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_mi_argrant_enc), .M_VALID (aa_mi_arvalid), // SI-slot index of granted command .M_READY (aa_mi_arready), .ISSUING_LIMIT (mi_armaxissuing) ); if (C_DEBUG) begin : gen_debug_trans_seq // DEBUG WRITE TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_aw_trans_seq_i <= 1; end else begin if (aa_sa_awvalid && aa_sa_awready) begin debug_aw_trans_seq_i <= debug_aw_trans_seq_i + 1; end end end // DEBUG READ TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_ar_trans_seq_i <= 1; end else begin if (aa_mi_arvalid && aa_mi_arready) begin debug_ar_trans_seq_i <= debug_ar_trans_seq_i + 1; end end end end // gen_debug_trans_seq // Broadcast AR transfer payload to all MI-slots assign M_AXI_ARID = {C_NUM_MASTER_SLOTS{aa_mi_armesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_ARADDR = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_ARLEN = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_ARSIZE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_ARLOCK = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_ARPROT = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_ARREGION = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_ARBURST = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_ARCACHE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_ARQOS = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_ARUSER = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_ARUSER_WIDTH]}}; // AW arbiter command transfer completes upon completion of both M-side AW-channel transfer and W-mux address acceptance (command push). axi_crossbar_v2_1_splitter # // "SA": Splitter for Write Addr Arbiter ( .C_NUM_M (2) ) splitter_aw_mi ( .ACLK (ACLK), .ARESET (reset), .S_VALID (aa_sa_awvalid), .S_READY (aa_sa_awready), .M_VALID ({mi_awvalid_en, sa_wm_awvalid_en}), .M_READY ({mi_awready_mux, sa_wm_awready_mux}) ); assign mi_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{mi_awvalid_en}}; assign mi_awready_mux = \|(aa_mi_awtarget_hot & mi_awready); assign M_AXI_AWVALID = mi_awvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_awready[0+:C_NUM_MASTER_SLOTS] = M_AXI_AWREADY; assign sa_wm_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{sa_wm_awvalid_en}}; assign sa_wm_awready_mux = \|(aa_mi_awtarget_hot & sa_wm_awready); assign mi_arvalid = aa_mi_artarget_hot & {C_NUM_MASTER_SLOTS+1{aa_mi_arvalid}}; assign aa_mi_arready = \|(aa_mi_artarget_hot & mi_arready); assign M_AXI_ARVALID = mi_arvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_arready[0+:C_NUM_MASTER_SLOTS] = M_AXI_ARREADY; // MI-slot # C_NUM_MASTER_SLOTS is the error handler if (C_RANGE_CHECK) begin : gen_decerr_slave axi_crossbar_v2_1_decerr_slave # ( .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_RESP (P_DECERR) ) decerr_slave_inst ( .S_AXI_ACLK (ACLK), .S_AXI_ARESET (reset), .S_AXI_AWID (aa_mi_awmesg[0+:C_AXI_ID_WIDTH]), .S_AXI_AWVALID (mi_awvalid[C_NUM_MASTER_SLOTS]), .S_AXI_AWREADY (mi_awready[C_NUM_MASTER_SLOTS]), .S_AXI_WLAST (mi_wlast[C_NUM_MASTER_SLOTS]), .S_AXI_WVALID (mi_wvalid[C_NUM_MASTER_SLOTS]), .S_AXI_WREADY (mi_wready[C_NUM_MASTER_SLOTS]), .S_AXI_BID (mi_bid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_BRESP (mi_bresp[C_NUM_MASTER_SLOTS2+:2]), .S_AXI_BUSER (mi_buser[C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH]), .S_AXI_BVALID (mi_bvalid[C_NUM_MASTER_SLOTS]), .S_AXI_BREADY (mi_bready[C_NUM_MASTER_SLOTS]), .S_AXI_ARID (aa_mi_armesg[0+:C_AXI_ID_WIDTH]), .S_AXI_ARLEN (aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]), .S_AXI_ARVALID (mi_arvalid[C_NUM_MASTER_SLOTS]), .S_AXI_ARREADY (mi_arready[C_NUM_MASTER_SLOTS]), .S_AXI_RID (mi_rid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_RDATA (mi_rdata[C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .S_AXI_RRESP (mi_rresp[C_NUM_MASTER_SLOTS2+:2]), .S_AXI_RUSER (mi_ruser[C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH]), .S_AXI_RLAST (mi_rlast[C_NUM_MASTER_SLOTS]), .S_AXI_RVALID (mi_rvalid[C_NUM_MASTER_SLOTS]), .S_AXI_RREADY (mi_rready[C_NUM_MASTER_SLOTS]) ); end else begin : gen_no_decerr_slave assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_wready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_arready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_bid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_bresp[C_NUM_MASTER_SLOTS2+:2] = 0; assign mi_buser[C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign mi_bvalid[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_rdata[C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign mi_rresp[C_NUM_MASTER_SLOTS2+:2] = 0; assign mi_ruser[C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign mi_rlast[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rvalid[C_NUM_MASTER_SLOTS] = 1'b0; end // gen_decerr_slave endgenerate endmodule
module Mux_Array #(parameter SWR=26, parameter EWR=5) ( input wire clk, input wire rst, input wire load_i, input wire [SWR-1:0] Data_i, input wire FSM_left_right_i, input wire [EWR-1:0] Shift_Value_i, input wire bit_shift_i, output wire [SWR-1:0] Data_o ); //// wire [SWR-1:0] Data_array[EWR+1:0]; //////////////////7 genvar k;//Level ///////////////////77777 Rotate_Mux_Array #(.SWR(SWR)) first_rotate( .Data_i(Data_i), .select_i(FSM_left_right_i), .Data_o(Data_array [0][SWR-1:0]) ); generate for (k=0; k < 3; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+1]) ); end endgenerate RegisterAdd #(.W(SWR)) Mid_Reg( .clk(clk), .rst(rst), .load(1'b1), .D(Data_array[3]), .Q(Data_array[4]) ); generate for (k=3; k < EWR; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k+1]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+2]) ); end endgenerate Rotate_Mux_Array #(.SWR(SWR)) last_rotate( .Data_i(Data_array[EWR+1]), .select_i(FSM_left_right_i), .Data_o(Data_o) ); endmodule
module Mux_Array #(parameter SWR=26, parameter EWR=5) ( input wire clk, input wire rst, input wire load_i, input wire [SWR-1:0] Data_i, input wire FSM_left_right_i, input wire [EWR-1:0] Shift_Value_i, input wire bit_shift_i, output wire [SWR-1:0] Data_o ); //// wire [SWR-1:0] Data_array[EWR+1:0]; //////////////////7 genvar k;//Level ///////////////////77777 Rotate_Mux_Array #(.SWR(SWR)) first_rotate( .Data_i(Data_i), .select_i(FSM_left_right_i), .Data_o(Data_array [0][SWR-1:0]) ); generate for (k=0; k < 3; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+1]) ); end endgenerate RegisterAdd #(.W(SWR)) Mid_Reg( .clk(clk), .rst(rst), .load(1'b1), .D(Data_array[3]), .Q(Data_array[4]) ); generate for (k=3; k < EWR; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k+1]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+2]) ); end endgenerate Rotate_Mux_Array #(.SWR(SWR)) last_rotate( .Data_i(Data_array[EWR+1]), .select_i(FSM_left_right_i), .Data_o(Data_o) ); endmodule
module Mux_Array #(parameter SWR=26, parameter EWR=5) ( input wire clk, input wire rst, input wire load_i, input wire [SWR-1:0] Data_i, input wire FSM_left_right_i, input wire [EWR-1:0] Shift_Value_i, input wire bit_shift_i, output wire [SWR-1:0] Data_o ); //// wire [SWR-1:0] Data_array[EWR+1:0]; //////////////////7 genvar k;//Level ///////////////////77777 Rotate_Mux_Array #(.SWR(SWR)) first_rotate( .Data_i(Data_i), .select_i(FSM_left_right_i), .Data_o(Data_array [0][SWR-1:0]) ); generate for (k=0; k < 3; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+1]) ); end endgenerate RegisterAdd #(.W(SWR)) Mid_Reg( .clk(clk), .rst(rst), .load(1'b1), .D(Data_array[3]), .Q(Data_array[4]) ); generate for (k=3; k < EWR; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k+1]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+2]) ); end endgenerate Rotate_Mux_Array #(.SWR(SWR)) last_rotate( .Data_i(Data_array[EWR+1]), .select_i(FSM_left_right_i), .Data_o(Data_o) ); endmodule
module Mux_Array #(parameter SWR=26, parameter EWR=5) ( input wire clk, input wire rst, input wire load_i, input wire [SWR-1:0] Data_i, input wire FSM_left_right_i, input wire [EWR-1:0] Shift_Value_i, input wire bit_shift_i, output wire [SWR-1:0] Data_o ); //// wire [SWR-1:0] Data_array[EWR+1:0]; //////////////////7 genvar k;//Level ///////////////////77777 Rotate_Mux_Array #(.SWR(SWR)) first_rotate( .Data_i(Data_i), .select_i(FSM_left_right_i), .Data_o(Data_array [0][SWR-1:0]) ); generate for (k=0; k < 3; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+1]) ); end endgenerate RegisterAdd #(.W(SWR)) Mid_Reg( .clk(clk), .rst(rst), .load(1'b1), .D(Data_array[3]), .Q(Data_array[4]) ); generate for (k=3; k < EWR; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k+1]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+2]) ); end endgenerate Rotate_Mux_Array #(.SWR(SWR)) last_rotate( .Data_i(Data_array[EWR+1]), .select_i(FSM_left_right_i), .Data_o(Data_o) ); endmodule
module Mux_Array #(parameter SWR=26, parameter EWR=5) ( input wire clk, input wire rst, input wire load_i, input wire [SWR-1:0] Data_i, input wire FSM_left_right_i, input wire [EWR-1:0] Shift_Value_i, input wire bit_shift_i, output wire [SWR-1:0] Data_o ); //// wire [SWR-1:0] Data_array[EWR+1:0]; //////////////////7 genvar k;//Level ///////////////////77777 Rotate_Mux_Array #(.SWR(SWR)) first_rotate( .Data_i(Data_i), .select_i(FSM_left_right_i), .Data_o(Data_array [0][SWR-1:0]) ); generate for (k=0; k < 3; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+1]) ); end endgenerate RegisterAdd #(.W(SWR)) Mid_Reg( .clk(clk), .rst(rst), .load(1'b1), .D(Data_array[3]), .Q(Data_array[4]) ); generate for (k=3; k < EWR; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k+1]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+2]) ); end endgenerate Rotate_Mux_Array #(.SWR(SWR)) last_rotate( .Data_i(Data_array[EWR+1]), .select_i(FSM_left_right_i), .Data_o(Data_o) ); endmodule
module processing_system7_bfm_v2_0_5_intr_wr_mem( sw_clk, rstn, full, WR_DATA_ACK_OCM, WR_DATA_ACK_DDR, WR_ADDR, WR_DATA, WR_BYTES, WR_QOS, WR_DATA_VALID_OCM, WR_DATA_VALID_DDR ); `include "processing_system7_bfm_v2_0_5_local_params.v" /* local parameters for interconnect wr fifo model */ input sw_clk, rstn; output full; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output reg WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output reg [max_burst_bits-1:0] WR_DATA; output reg [addr_width-1:0] WR_ADDR; output reg [max_burst_bytes_width:0] WR_BYTES; output reg [axi_qos_width-1:0] WR_QOS; reg [intr_cnt_width-1:0] wr_ptr = 0, rd_ptr = 0; reg [wr_fifo_data_bits-1:0] wr_fifo [0:intr_max_outstanding-1]; wire empty; assign empty = (wr_ptr === rd_ptr)?1'b1: 1'b0; assign full = ((wr_ptr[intr_cnt_width-1]!== rd_ptr[intr_cnt_width-1]) && (wr_ptr[intr_cnt_width-2:0] === rd_ptr[intr_cnt_width-2:0]))?1'b1 :1'b0; parameter SEND_DATA = 0, WAIT_ACK = 1; reg state; task automatic write_mem; input [wr_fifo_data_bits-1:0] data; begin wr_fifo[wr_ptr[intr_cnt_width-2:0]] = data; if(wr_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) wr_ptr[intr_cnt_width-2:0] = 0; else wr_ptr = wr_ptr + 1; end endtask always@(negedge rstn or posedge sw_clk) begin if(!rstn) begin wr_ptr = 0; rd_ptr = 0; WR_DATA_VALID_DDR = 1'b0; WR_DATA_VALID_OCM = 1'b0; WR_QOS = 0; state = SEND_DATA; end else begin case(state) SEND_DATA :begin state = SEND_DATA; WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; if(!empty) begin WR_DATA = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_data_msb : wr_data_lsb]; WR_ADDR = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb]; WR_BYTES = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_bytes_msb : wr_bytes_lsb]; WR_QOS = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_qos_msb : wr_qos_lsb]; state = WAIT_ACK; case(decode_address(wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb])) OCM_MEM : WR_DATA_VALID_OCM = 1; DDR_MEM : WR_DATA_VALID_DDR = 1; default : state = SEND_DATA; endcase if(rd_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) begin rd_ptr[intr_cnt_width-2:0] = 0; end else begin rd_ptr = rd_ptr+1; end end end WAIT_ACK :begin state = WAIT_ACK; if(WR_DATA_ACK_OCM \| WR_DATA_ACK_DDR) begin WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; state = SEND_DATA; end end endcase end end endmodule
module processing_system7_bfm_v2_0_5_intr_wr_mem( sw_clk, rstn, full, WR_DATA_ACK_OCM, WR_DATA_ACK_DDR, WR_ADDR, WR_DATA, WR_BYTES, WR_QOS, WR_DATA_VALID_OCM, WR_DATA_VALID_DDR ); `include "processing_system7_bfm_v2_0_5_local_params.v" /* local parameters for interconnect wr fifo model */ input sw_clk, rstn; output full; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output reg WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output reg [max_burst_bits-1:0] WR_DATA; output reg [addr_width-1:0] WR_ADDR; output reg [max_burst_bytes_width:0] WR_BYTES; output reg [axi_qos_width-1:0] WR_QOS; reg [intr_cnt_width-1:0] wr_ptr = 0, rd_ptr = 0; reg [wr_fifo_data_bits-1:0] wr_fifo [0:intr_max_outstanding-1]; wire empty; assign empty = (wr_ptr === rd_ptr)?1'b1: 1'b0; assign full = ((wr_ptr[intr_cnt_width-1]!== rd_ptr[intr_cnt_width-1]) && (wr_ptr[intr_cnt_width-2:0] === rd_ptr[intr_cnt_width-2:0]))?1'b1 :1'b0; parameter SEND_DATA = 0, WAIT_ACK = 1; reg state; task automatic write_mem; input [wr_fifo_data_bits-1:0] data; begin wr_fifo[wr_ptr[intr_cnt_width-2:0]] = data; if(wr_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) wr_ptr[intr_cnt_width-2:0] = 0; else wr_ptr = wr_ptr + 1; end endtask always@(negedge rstn or posedge sw_clk) begin if(!rstn) begin wr_ptr = 0; rd_ptr = 0; WR_DATA_VALID_DDR = 1'b0; WR_DATA_VALID_OCM = 1'b0; WR_QOS = 0; state = SEND_DATA; end else begin case(state) SEND_DATA :begin state = SEND_DATA; WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; if(!empty) begin WR_DATA = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_data_msb : wr_data_lsb]; WR_ADDR = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb]; WR_BYTES = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_bytes_msb : wr_bytes_lsb]; WR_QOS = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_qos_msb : wr_qos_lsb]; state = WAIT_ACK; case(decode_address(wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb])) OCM_MEM : WR_DATA_VALID_OCM = 1; DDR_MEM : WR_DATA_VALID_DDR = 1; default : state = SEND_DATA; endcase if(rd_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) begin rd_ptr[intr_cnt_width-2:0] = 0; end else begin rd_ptr = rd_ptr+1; end end end WAIT_ACK :begin state = WAIT_ACK; if(WR_DATA_ACK_OCM \| WR_DATA_ACK_DDR) begin WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; state = SEND_DATA; end end endcase end end endmodule
module processing_system7_bfm_v2_0_5_intr_wr_mem( sw_clk, rstn, full, WR_DATA_ACK_OCM, WR_DATA_ACK_DDR, WR_ADDR, WR_DATA, WR_BYTES, WR_QOS, WR_DATA_VALID_OCM, WR_DATA_VALID_DDR ); `include "processing_system7_bfm_v2_0_5_local_params.v" /* local parameters for interconnect wr fifo model */ input sw_clk, rstn; output full; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output reg WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output reg [max_burst_bits-1:0] WR_DATA; output reg [addr_width-1:0] WR_ADDR; output reg [max_burst_bytes_width:0] WR_BYTES; output reg [axi_qos_width-1:0] WR_QOS; reg [intr_cnt_width-1:0] wr_ptr = 0, rd_ptr = 0; reg [wr_fifo_data_bits-1:0] wr_fifo [0:intr_max_outstanding-1]; wire empty; assign empty = (wr_ptr === rd_ptr)?1'b1: 1'b0; assign full = ((wr_ptr[intr_cnt_width-1]!== rd_ptr[intr_cnt_width-1]) && (wr_ptr[intr_cnt_width-2:0] === rd_ptr[intr_cnt_width-2:0]))?1'b1 :1'b0; parameter SEND_DATA = 0, WAIT_ACK = 1; reg state; task automatic write_mem; input [wr_fifo_data_bits-1:0] data; begin wr_fifo[wr_ptr[intr_cnt_width-2:0]] = data; if(wr_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) wr_ptr[intr_cnt_width-2:0] = 0; else wr_ptr = wr_ptr + 1; end endtask always@(negedge rstn or posedge sw_clk) begin if(!rstn) begin wr_ptr = 0; rd_ptr = 0; WR_DATA_VALID_DDR = 1'b0; WR_DATA_VALID_OCM = 1'b0; WR_QOS = 0; state = SEND_DATA; end else begin case(state) SEND_DATA :begin state = SEND_DATA; WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; if(!empty) begin WR_DATA = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_data_msb : wr_data_lsb]; WR_ADDR = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb]; WR_BYTES = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_bytes_msb : wr_bytes_lsb]; WR_QOS = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_qos_msb : wr_qos_lsb]; state = WAIT_ACK; case(decode_address(wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb])) OCM_MEM : WR_DATA_VALID_OCM = 1; DDR_MEM : WR_DATA_VALID_DDR = 1; default : state = SEND_DATA; endcase if(rd_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) begin rd_ptr[intr_cnt_width-2:0] = 0; end else begin rd_ptr = rd_ptr+1; end end end WAIT_ACK :begin state = WAIT_ACK; if(WR_DATA_ACK_OCM \| WR_DATA_ACK_DDR) begin WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; state = SEND_DATA; end end endcase end end endmodule
module processing_system7_bfm_v2_0_5_intr_wr_mem( sw_clk, rstn, full, WR_DATA_ACK_OCM, WR_DATA_ACK_DDR, WR_ADDR, WR_DATA, WR_BYTES, WR_QOS, WR_DATA_VALID_OCM, WR_DATA_VALID_DDR ); `include "processing_system7_bfm_v2_0_5_local_params.v" /* local parameters for interconnect wr fifo model */ input sw_clk, rstn; output full; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output reg WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output reg [max_burst_bits-1:0] WR_DATA; output reg [addr_width-1:0] WR_ADDR; output reg [max_burst_bytes_width:0] WR_BYTES; output reg [axi_qos_width-1:0] WR_QOS; reg [intr_cnt_width-1:0] wr_ptr = 0, rd_ptr = 0; reg [wr_fifo_data_bits-1:0] wr_fifo [0:intr_max_outstanding-1]; wire empty; assign empty = (wr_ptr === rd_ptr)?1'b1: 1'b0; assign full = ((wr_ptr[intr_cnt_width-1]!== rd_ptr[intr_cnt_width-1]) && (wr_ptr[intr_cnt_width-2:0] === rd_ptr[intr_cnt_width-2:0]))?1'b1 :1'b0; parameter SEND_DATA = 0, WAIT_ACK = 1; reg state; task automatic write_mem; input [wr_fifo_data_bits-1:0] data; begin wr_fifo[wr_ptr[intr_cnt_width-2:0]] = data; if(wr_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) wr_ptr[intr_cnt_width-2:0] = 0; else wr_ptr = wr_ptr + 1; end endtask always@(negedge rstn or posedge sw_clk) begin if(!rstn) begin wr_ptr = 0; rd_ptr = 0; WR_DATA_VALID_DDR = 1'b0; WR_DATA_VALID_OCM = 1'b0; WR_QOS = 0; state = SEND_DATA; end else begin case(state) SEND_DATA :begin state = SEND_DATA; WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; if(!empty) begin WR_DATA = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_data_msb : wr_data_lsb]; WR_ADDR = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb]; WR_BYTES = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_bytes_msb : wr_bytes_lsb]; WR_QOS = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_qos_msb : wr_qos_lsb]; state = WAIT_ACK; case(decode_address(wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb])) OCM_MEM : WR_DATA_VALID_OCM = 1; DDR_MEM : WR_DATA_VALID_DDR = 1; default : state = SEND_DATA; endcase if(rd_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) begin rd_ptr[intr_cnt_width-2:0] = 0; end else begin rd_ptr = rd_ptr+1; end end end WAIT_ACK :begin state = WAIT_ACK; if(WR_DATA_ACK_OCM \| WR_DATA_ACK_DDR) begin WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; state = SEND_DATA; end end endcase end end endmodule
module axi_crossbar_v2_1_addr_arbiter # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 1, parameter integer C_NUM_S_LOG = 1, parameter integer C_NUM_M = 1, parameter integer C_MESG_WIDTH = 1, parameter [C_NUM_S32-1:0] C_ARB_PRIORITY = {C_NUM_S{32'h00000000}} // Arbitration priority among each SI slot. // Higher values indicate higher priority. // Format: C_NUM_SLAVE_SLOTS{Bit32}; // Range: 'h0-'hF. ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_SC_MESG_WIDTH-1:0] S_MESG, input wire [C_NUM_SC_NUM_M-1:0] S_TARGET_HOT, input wire [C_NUM_S-1:0] S_VALID, input wire [C_NUM_S-1:0] S_VALID_QUAL, output wire [C_NUM_S-1:0] S_READY, // Master Ports output wire [C_MESG_WIDTH-1:0] M_MESG, output wire [C_NUM_M-1:0] M_TARGET_HOT, output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, output wire M_VALID, input wire M_READY, // Sideband input input wire [C_NUM_M-1:0] ISSUING_LIMIT ); // Generates a mask for all input slots that are priority based function [C_NUM_S-1:0] f_prio_mask ( input integer null_arg ); reg [C_NUM_S-1:0] mask; integer i; begin mask = 0; for (i=0; i < C_NUM_S; i=i+1) begin mask[i] = (C_ARB_PRIORITY[i32+:32] != 0); end f_prio_mask = mask; end endfunction // Convert 16-bit one-hot to 4-bit binary function [3:0] f_hot2enc ( input [15:0] one_hot ); begin f_hot2enc[0] = \|(one_hot & 16'b1010101010101010); f_hot2enc[1] = \|(one_hot & 16'b1100110011001100); f_hot2enc[2] = \|(one_hot & 16'b1111000011110000); f_hot2enc[3] = \|(one_hot & 16'b1111111100000000); end endfunction localparam [C_NUM_S-1:0] P_PRIO_MASK = f_prio_mask(0); reg m_valid_i; reg [C_NUM_S-1:0] s_ready_i; reg [C_NUM_S-1:0] qual_reg; reg [C_NUM_S-1:0] grant_hot; reg [C_NUM_S-1:0] last_rr_hot; reg any_grant; reg any_prio; reg found_prio; reg [C_NUM_S-1:0] which_prio_hot; reg [C_NUM_S-1:0] next_prio_hot; reg [C_NUM_S_LOG-1:0] which_prio_enc; reg [C_NUM_S_LOG-1:0] next_prio_enc; reg [4:0] current_highest; wire [C_NUM_S-1:0] valid_rr; reg [15:0] next_rr_hot; reg [C_NUM_S_LOG-1:0] next_rr_enc; reg [C_NUM_SC_NUM_S-1:0] carry_rr; reg [C_NUM_SC_NUM_S-1:0] mask_rr; reg found_rr; wire [C_NUM_S-1:0] next_hot; wire [C_NUM_S_LOG-1:0] next_enc; reg prio_stall; integer i; wire [C_NUM_S-1:0] valid_qual_i; reg [C_NUM_S_LOG-1:0] m_grant_enc_i; reg [C_NUM_M-1:0] m_target_hot_i; wire [C_NUM_M-1:0] m_target_hot_mux; reg [C_MESG_WIDTH-1:0] m_mesg_i; wire [C_MESG_WIDTH-1:0] m_mesg_mux; genvar gen_si; assign M_VALID = m_valid_i; assign S_READY = s_ready_i; assign M_GRANT_ENC = m_grant_enc_i; assign M_MESG = m_mesg_i; assign M_TARGET_HOT = m_target_hot_i; generate if (C_NUM_S>1) begin : gen_arbiter always @(posedge ACLK) begin if (ARESET) begin qual_reg <= 0; end else begin qual_reg <= valid_qual_i \| ~S_VALID; // Don't disqualify when bus not VALID (valid_qual_i would be garbage) end end for (gen_si=0; gen_si<C_NUM_S; gen_si=gen_si+1) begin : gen_req_qual assign valid_qual_i[gen_si] = S_VALID_QUAL[gen_si] & (\|(S_TARGET_HOT[gen_siC_NUM_M+:C_NUM_M] & ~ISSUING_LIMIT)); end ///////////////////////////////////////////////////////////////////////////// // Grant a new request when there is none still pending. // If no qualified requests found, de-assert M_VALID. ///////////////////////////////////////////////////////////////////////////// assign next_hot = found_prio ? next_prio_hot : next_rr_hot; assign next_enc = found_prio ? next_prio_enc : next_rr_enc; always @(posedge ACLK) begin if (ARESET) begin m_valid_i <= 0; s_ready_i <= 0; grant_hot <= 0; any_grant <= 1'b0; m_grant_enc_i <= 0; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; m_target_hot_i <= 0; end else begin s_ready_i <= 0; if (m_valid_i) begin // Stall 1 cycle after each master-side completion. if (M_READY) begin // Master-side completion m_valid_i <= 1'b0; grant_hot <= 0; any_grant <= 1'b0; end end else if (any_grant) begin m_valid_i <= 1'b1; s_ready_i <= grant_hot; // Assert S_AW/READY for 1 cycle to complete SI address transfer (regardless of M_AREADY) end else begin if ((found_prio \| found_rr) & ~prio_stall) begin // Waste 1 cycle and re-arbitrate if target of highest prio hit issuing limit in previous cycle (valid_qual_i). if (\|(next_hot & valid_qual_i)) begin grant_hot <= next_hot; m_grant_enc_i <= next_enc; any_grant <= 1'b1; if (~found_prio) begin last_rr_hot <= next_rr_hot; end m_target_hot_i <= m_target_hot_mux; end end end end end ///////////////////////////////////////////////////////////////////////////// // Fixed Priority arbiter // Selects next request to grant from among inputs with PRIO > 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ begin : ALG_PRIO integer ip; any_prio = 1'b0; prio_stall = 1'b0; which_prio_hot = 0; which_prio_enc = 0; current_highest = 0; for (ip=0; ip < C_NUM_S; ip=ip+1) begin // Disqualify slot if target hit issuing limit (pass to lower prio slot). if (P_PRIO_MASK[ip] & S_VALID[ip] & qual_reg[ip]) begin if ({1'b0, C_ARB_PRIORITY[ip32+:4]} > current_highest) begin current_highest[0+:4] = C_ARB_PRIORITY[ip32+:4]; // Stall 1 cycle when highest prio is recovering from SI-side handshake. // (Do not allow lower-prio slot to win arbitration.) if (s_ready_i[ip]) begin any_prio = 1'b0; prio_stall = 1'b1; which_prio_hot = 0; which_prio_enc = 0; end else begin any_prio = 1'b1; which_prio_hot = 1'b1 << ip; which_prio_enc = ip; end end end end found_prio = any_prio; next_prio_hot = which_prio_hot; next_prio_enc = which_prio_enc; end ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// // Disqualify slot if target hit issuing limit 2 or more cycles earlier (pass to next RR slot). // Disqualify for 1 cycle a slot that is recovering from SI-side handshake (s_ready_i), // and allow arbitration to pass to any other RR requester. assign valid_rr = ~P_PRIO_MASK & S_VALID & ~s_ready_i & qual_reg; always @ * begin : ALG_RR integer ir, jr, nr; next_rr_hot = 0; for (ir=0;ir<C_NUM_S;ir=ir+1) begin nr = (ir>0) ? (ir-1) : (C_NUM_S-1); carry_rr[irC_NUM_S] = last_rr_hot[nr]; mask_rr[irC_NUM_S] = ~valid_rr[nr]; for (jr=1;jr<C_NUM_S;jr=jr+1) begin nr = (ir-jr > 0) ? (ir-jr-1) : (C_NUM_S+ir-jr-1); carry_rr[irC_NUM_S+jr] = carry_rr[irC_NUM_S+jr-1] \| (last_rr_hot[nr] & mask_rr[irC_NUM_S+jr-1]); if (jr < C_NUM_S-1) begin mask_rr[irC_NUM_S+jr] = mask_rr[irC_NUM_S+jr-1] & ~valid_rr[nr]; end end next_rr_hot[ir] = valid_rr[ir] & carry_rr[(ir+1)C_NUM_S-1]; end next_rr_enc = f_hot2enc(next_rr_hot); found_rr = \|(next_rr_hot); end generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY ("rtl"), .C_RATIO (C_NUM_S), .C_SEL_WIDTH (C_NUM_S_LOG), .C_DATA_WIDTH (C_MESG_WIDTH) ) mux_mesg ( .S (m_grant_enc_i), .A (S_MESG), .O (m_mesg_mux), .OE (1'b1) ); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY ("rtl"), .C_RATIO (C_NUM_S), .C_SEL_WIDTH (C_NUM_S_LOG), .C_DATA_WIDTH (C_NUM_M) ) si_amesg_mux_inst ( .S (next_enc), .A (S_TARGET_HOT), .O (m_target_hot_mux), .OE (1'b1) ); always @(posedge ACLK) begin if (ARESET) begin m_mesg_i <= 0; end else if (~m_valid_i) begin m_mesg_i <= m_mesg_mux; end end end else begin : gen_no_arbiter assign valid_qual_i = S_VALID_QUAL & \|(S_TARGET_HOT & ~ISSUING_LIMIT); always @ (posedge ACLK) begin if (ARESET) begin m_valid_i <= 1'b0; s_ready_i <= 1'b0; m_grant_enc_i <= 0; end else begin s_ready_i <= 1'b0; if (m_valid_i) begin if (M_READY) begin m_valid_i <= 1'b0; end end else if (S_VALID[0] & valid_qual_i[0] & ~s_ready_i) begin m_valid_i <= 1'b1; s_ready_i <= 1'b1; m_target_hot_i <= S_TARGET_HOT; end end end always @(posedge ACLK) begin if (ARESET) begin m_mesg_i <= 0; end else if (~m_valid_i) begin m_mesg_i <= S_MESG; end end end // gen_arbiter endgenerate endmodule
module axi_crossbar_v2_1_addr_arbiter # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 1, parameter integer C_NUM_S_LOG = 1, parameter integer C_NUM_M = 1, parameter integer C_MESG_WIDTH = 1, parameter [C_NUM_S32-1:0] C_ARB_PRIORITY = {C_NUM_S{32'h00000000}} // Arbitration priority among each SI slot. // Higher values indicate higher priority. // Format: C_NUM_SLAVE_SLOTS{Bit32}; // Range: 'h0-'hF. ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_SC_MESG_WIDTH-1:0] S_MESG, input wire [C_NUM_SC_NUM_M-1:0] S_TARGET_HOT, input wire [C_NUM_S-1:0] S_VALID, input wire [C_NUM_S-1:0] S_VALID_QUAL, output wire [C_NUM_S-1:0] S_READY, // Master Ports output wire [C_MESG_WIDTH-1:0] M_MESG, output wire [C_NUM_M-1:0] M_TARGET_HOT, output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, output wire M_VALID, input wire M_READY, // Sideband input input wire [C_NUM_M-1:0] ISSUING_LIMIT ); // Generates a mask for all input slots that are priority based function [C_NUM_S-1:0] f_prio_mask ( input integer null_arg ); reg [C_NUM_S-1:0] mask; integer i; begin mask = 0; for (i=0; i < C_NUM_S; i=i+1) begin mask[i] = (C_ARB_PRIORITY[i32+:32] != 0); end f_prio_mask = mask; end endfunction // Convert 16-bit one-hot to 4-bit binary function [3:0] f_hot2enc ( input [15:0] one_hot ); begin f_hot2enc[0] = \|(one_hot & 16'b1010101010101010); f_hot2enc[1] = \|(one_hot & 16'b1100110011001100); f_hot2enc[2] = \|(one_hot & 16'b1111000011110000); f_hot2enc[3] = \|(one_hot & 16'b1111111100000000); end endfunction localparam [C_NUM_S-1:0] P_PRIO_MASK = f_prio_mask(0); reg m_valid_i; reg [C_NUM_S-1:0] s_ready_i; reg [C_NUM_S-1:0] qual_reg; reg [C_NUM_S-1:0] grant_hot; reg [C_NUM_S-1:0] last_rr_hot; reg any_grant; reg any_prio; reg found_prio; reg [C_NUM_S-1:0] which_prio_hot; reg [C_NUM_S-1:0] next_prio_hot; reg [C_NUM_S_LOG-1:0] which_prio_enc; reg [C_NUM_S_LOG-1:0] next_prio_enc; reg [4:0] current_highest; wire [C_NUM_S-1:0] valid_rr; reg [15:0] next_rr_hot; reg [C_NUM_S_LOG-1:0] next_rr_enc; reg [C_NUM_SC_NUM_S-1:0] carry_rr; reg [C_NUM_SC_NUM_S-1:0] mask_rr; reg found_rr; wire [C_NUM_S-1:0] next_hot; wire [C_NUM_S_LOG-1:0] next_enc; reg prio_stall; integer i; wire [C_NUM_S-1:0] valid_qual_i; reg [C_NUM_S_LOG-1:0] m_grant_enc_i; reg [C_NUM_M-1:0] m_target_hot_i; wire [C_NUM_M-1:0] m_target_hot_mux; reg [C_MESG_WIDTH-1:0] m_mesg_i; wire [C_MESG_WIDTH-1:0] m_mesg_mux; genvar gen_si; assign M_VALID = m_valid_i; assign S_READY = s_ready_i; assign M_GRANT_ENC = m_grant_enc_i; assign M_MESG = m_mesg_i; assign M_TARGET_HOT = m_target_hot_i; generate if (C_NUM_S>1) begin : gen_arbiter always @(posedge ACLK) begin if (ARESET) begin qual_reg <= 0; end else begin qual_reg <= valid_qual_i \| ~S_VALID; // Don't disqualify when bus not VALID (valid_qual_i would be garbage) end end for (gen_si=0; gen_si<C_NUM_S; gen_si=gen_si+1) begin : gen_req_qual assign valid_qual_i[gen_si] = S_VALID_QUAL[gen_si] & (\|(S_TARGET_HOT[gen_siC_NUM_M+:C_NUM_M] & ~ISSUING_LIMIT)); end ///////////////////////////////////////////////////////////////////////////// // Grant a new request when there is none still pending. // If no qualified requests found, de-assert M_VALID. ///////////////////////////////////////////////////////////////////////////// assign next_hot = found_prio ? next_prio_hot : next_rr_hot; assign next_enc = found_prio ? next_prio_enc : next_rr_enc; always @(posedge ACLK) begin if (ARESET) begin m_valid_i <= 0; s_ready_i <= 0; grant_hot <= 0; any_grant <= 1'b0; m_grant_enc_i <= 0; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; m_target_hot_i <= 0; end else begin s_ready_i <= 0; if (m_valid_i) begin // Stall 1 cycle after each master-side completion. if (M_READY) begin // Master-side completion m_valid_i <= 1'b0; grant_hot <= 0; any_grant <= 1'b0; end end else if (any_grant) begin m_valid_i <= 1'b1; s_ready_i <= grant_hot; // Assert S_AW/READY for 1 cycle to complete SI address transfer (regardless of M_AREADY) end else begin if ((found_prio \| found_rr) & ~prio_stall) begin // Waste 1 cycle and re-arbitrate if target of highest prio hit issuing limit in previous cycle (valid_qual_i). if (\|(next_hot & valid_qual_i)) begin grant_hot <= next_hot; m_grant_enc_i <= next_enc; any_grant <= 1'b1; if (~found_prio) begin last_rr_hot <= next_rr_hot; end m_target_hot_i <= m_target_hot_mux; end end end end end ///////////////////////////////////////////////////////////////////////////// // Fixed Priority arbiter // Selects next request to grant from among inputs with PRIO > 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ begin : ALG_PRIO integer ip; any_prio = 1'b0; prio_stall = 1'b0; which_prio_hot = 0; which_prio_enc = 0; current_highest = 0; for (ip=0; ip < C_NUM_S; ip=ip+1) begin // Disqualify slot if target hit issuing limit (pass to lower prio slot). if (P_PRIO_MASK[ip] & S_VALID[ip] & qual_reg[ip]) begin if ({1'b0, C_ARB_PRIORITY[ip32+:4]} > current_highest) begin current_highest[0+:4] = C_ARB_PRIORITY[ip32+:4]; // Stall 1 cycle when highest prio is recovering from SI-side handshake. // (Do not allow lower-prio slot to win arbitration.) if (s_ready_i[ip]) begin any_prio = 1'b0; prio_stall = 1'b1; which_prio_hot = 0; which_prio_enc = 0; end else begin any_prio = 1'b1; which_prio_hot = 1'b1 << ip; which_prio_enc = ip; end end end end found_prio = any_prio; next_prio_hot = which_prio_hot; next_prio_enc = which_prio_enc; end ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// // Disqualify slot if target hit issuing limit 2 or more cycles earlier (pass to next RR slot). // Disqualify for 1 cycle a slot that is recovering from SI-side handshake (s_ready_i), // and allow arbitration to pass to any other RR requester. assign valid_rr = ~P_PRIO_MASK & S_VALID & ~s_ready_i & qual_reg; always @ * begin : ALG_RR integer ir, jr, nr; next_rr_hot = 0; for (ir=0;ir<C_NUM_S;ir=ir+1) begin nr = (ir>0) ? (ir-1) : (C_NUM_S-1); carry_rr[irC_NUM_S] = last_rr_hot[nr]; mask_rr[irC_NUM_S] = ~valid_rr[nr]; for (jr=1;jr<C_NUM_S;jr=jr+1) begin nr = (ir-jr > 0) ? (ir-jr-1) : (C_NUM_S+ir-jr-1); carry_rr[irC_NUM_S+jr] = carry_rr[irC_NUM_S+jr-1] \| (last_rr_hot[nr] & mask_rr[irC_NUM_S+jr-1]); if (jr < C_NUM_S-1) begin mask_rr[irC_NUM_S+jr] = mask_rr[irC_NUM_S+jr-1] & ~valid_rr[nr]; end end next_rr_hot[ir] = valid_rr[ir] & carry_rr[(ir+1)C_NUM_S-1]; end next_rr_enc = f_hot2enc(next_rr_hot); found_rr = \|(next_rr_hot); end generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY ("rtl"), .C_RATIO (C_NUM_S), .C_SEL_WIDTH (C_NUM_S_LOG), .C_DATA_WIDTH (C_MESG_WIDTH) ) mux_mesg ( .S (m_grant_enc_i), .A (S_MESG), .O (m_mesg_mux), .OE (1'b1) ); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY ("rtl"), .C_RATIO (C_NUM_S), .C_SEL_WIDTH (C_NUM_S_LOG), .C_DATA_WIDTH (C_NUM_M) ) si_amesg_mux_inst ( .S (next_enc), .A (S_TARGET_HOT), .O (m_target_hot_mux), .OE (1'b1) ); always @(posedge ACLK) begin if (ARESET) begin m_mesg_i <= 0; end else if (~m_valid_i) begin m_mesg_i <= m_mesg_mux; end end end else begin : gen_no_arbiter assign valid_qual_i = S_VALID_QUAL & \|(S_TARGET_HOT & ~ISSUING_LIMIT); always @ (posedge ACLK) begin if (ARESET) begin m_valid_i <= 1'b0; s_ready_i <= 1'b0; m_grant_enc_i <= 0; end else begin s_ready_i <= 1'b0; if (m_valid_i) begin if (M_READY) begin m_valid_i <= 1'b0; end end else if (S_VALID[0] & valid_qual_i[0] & ~s_ready_i) begin m_valid_i <= 1'b1; s_ready_i <= 1'b1; m_target_hot_i <= S_TARGET_HOT; end end end always @(posedge ACLK) begin if (ARESET) begin m_mesg_i <= 0; end else if (~m_valid_i) begin m_mesg_i <= S_MESG; end end end // gen_arbiter endgenerate endmodule
module processing_system7_bfm_v2_0_5_intr_rd_mem( sw_clk, rstn, full, empty, req, invalid_rd_req, rd_info, RD_DATA_OCM, RD_DATA_DDR, RD_DATA_VALID_OCM, RD_DATA_VALID_DDR ); `include "processing_system7_bfm_v2_0_5_local_params.v" input sw_clk, rstn; output full, empty; input RD_DATA_VALID_DDR, RD_DATA_VALID_OCM; input [max_burst_bits-1:0] RD_DATA_DDR, RD_DATA_OCM; input req, invalid_rd_req; input [rd_info_bits-1:0] rd_info; reg [intr_cnt_width-1:0] wr_ptr = 0, rd_ptr = 0; reg [rd_afi_fifo_bits-1:0] rd_fifo [0:intr_max_outstanding-1]; // Data, addr, size, burst, len, RID, RRESP, valid bytes wire full, empty; assign empty = (wr_ptr === rd_ptr)?1'b1: 1'b0; assign full = ((wr_ptr[intr_cnt_width-1]!== rd_ptr[intr_cnt_width-1]) && (wr_ptr[intr_cnt_width-2:0] === rd_ptr[intr_cnt_width-2:0]))?1'b1 :1'b0; /* read from the fifo / task read_mem; output [rd_afi_fifo_bits-1:0] data; begin data = rd_fifo[rd_ptr[intr_cnt_width-1:0]]; if(rd_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) rd_ptr[intr_cnt_width-2:0] = 0; else rd_ptr = rd_ptr + 1; end endtask reg state; reg invalid_rd; / write in the fifo */ always@(negedge rstn or posedge sw_clk) begin if(!rstn) begin wr_ptr = 0; rd_ptr = 0; state = 0; invalid_rd = 0; end else begin case (state) 0 : begin state = 0; invalid_rd = 0; if(req)begin state = 1; invalid_rd = invalid_rd_req; end end 1 : begin state = 1; if(RD_DATA_VALID_OCM \| RD_DATA_VALID_DDR \| invalid_rd) begin if(RD_DATA_VALID_DDR) rd_fifo[wr_ptr[intr_cnt_width-2:0]] = {RD_DATA_DDR,rd_info}; else if(RD_DATA_VALID_OCM) rd_fifo[wr_ptr[intr_cnt_width-2:0]] = {RD_DATA_OCM,rd_info}; else rd_fifo[wr_ptr[intr_cnt_width-2:0]] = rd_info; if(wr_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) wr_ptr[intr_cnt_width-2:0] = 0; else wr_ptr = wr_ptr + 1; state = 0; invalid_rd = 0; end end endcase end end endmodule
module axi_crossbar_v2_1_splitter # ( parameter integer C_NUM_M = 2 // Number of master ports = [2:16] ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Port input wire S_VALID, output wire S_READY, // Master Ports output wire [C_NUM_M-1:0] M_VALID, input wire [C_NUM_M-1:0] M_READY ); reg [C_NUM_M-1:0] m_ready_d; wire s_ready_i; wire [C_NUM_M-1:0] m_valid_i; always @(posedge ACLK) begin if (ARESET \| s_ready_i) m_ready_d <= {C_NUM_M{1'b0}}; else m_ready_d <= m_ready_d \| (m_valid_i & M_READY); end assign s_ready_i = &(m_ready_d \| M_READY); assign m_valid_i = {C_NUM_M{S_VALID}} & ~m_ready_d; assign M_VALID = m_valid_i; assign S_READY = s_ready_i; endmodule
module debounce_switch #( parameter WIDTH=1, // width of the input and output signals parameter N=3, // length of shift register parameter RATE=125000 // clock division factor )( input wire clk, input wire rst, input wire [WIDTH-1:0] in, output wire [WIDTH-1:0] out ); reg [23:0] cnt_reg = 24'd0; reg [N-1:0] debounce_reg[WIDTH-1:0]; reg [WIDTH-1:0] state; /* * The synchronized output is the state register */ assign out = state; integer k; always @(posedge clk or posedge rst) begin if (rst) begin cnt_reg <= 0; state <= 0; for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= 0; end end else begin if (cnt_reg < RATE) begin cnt_reg <= cnt_reg + 24'd1; end else begin cnt_reg <= 24'd0; end if (cnt_reg == 24'd0) begin for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]}; end end for (k = 0; k < WIDTH; k = k + 1) begin if (\|debounce_reg[k] == 0) begin state[k] <= 0; end else if (&debounce_reg[k] == 1) begin state[k] <= 1; end else begin state[k] <= state[k]; end end end end endmodule
module debounce_switch #( parameter WIDTH=1, // width of the input and output signals parameter N=3, // length of shift register parameter RATE=125000 // clock division factor )( input wire clk, input wire rst, input wire [WIDTH-1:0] in, output wire [WIDTH-1:0] out ); reg [23:0] cnt_reg = 24'd0; reg [N-1:0] debounce_reg[WIDTH-1:0]; reg [WIDTH-1:0] state; /* * The synchronized output is the state register */ assign out = state; integer k; always @(posedge clk or posedge rst) begin if (rst) begin cnt_reg <= 0; state <= 0; for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= 0; end end else begin if (cnt_reg < RATE) begin cnt_reg <= cnt_reg + 24'd1; end else begin cnt_reg <= 24'd0; end if (cnt_reg == 24'd0) begin for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]}; end end for (k = 0; k < WIDTH; k = k + 1) begin if (\|debounce_reg[k] == 0) begin state[k] <= 0; end else if (&debounce_reg[k] == 1) begin state[k] <= 1; end else begin state[k] <= state[k]; end end end end endmodule
module debounce_switch #( parameter WIDTH=1, // width of the input and output signals parameter N=3, // length of shift register parameter RATE=125000 // clock division factor )( input wire clk, input wire rst, input wire [WIDTH-1:0] in, output wire [WIDTH-1:0] out ); reg [23:0] cnt_reg = 24'd0; reg [N-1:0] debounce_reg[WIDTH-1:0]; reg [WIDTH-1:0] state; /* * The synchronized output is the state register */ assign out = state; integer k; always @(posedge clk or posedge rst) begin if (rst) begin cnt_reg <= 0; state <= 0; for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= 0; end end else begin if (cnt_reg < RATE) begin cnt_reg <= cnt_reg + 24'd1; end else begin cnt_reg <= 24'd0; end if (cnt_reg == 24'd0) begin for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]}; end end for (k = 0; k < WIDTH; k = k + 1) begin if (\|debounce_reg[k] == 0) begin state[k] <= 0; end else if (&debounce_reg[k] == 1) begin state[k] <= 1; end else begin state[k] <= state[k]; end end end end endmodule
module debounce_switch #( parameter WIDTH=1, // width of the input and output signals parameter N=3, // length of shift register parameter RATE=125000 // clock division factor )( input wire clk, input wire rst, input wire [WIDTH-1:0] in, output wire [WIDTH-1:0] out ); reg [23:0] cnt_reg = 24'd0; reg [N-1:0] debounce_reg[WIDTH-1:0]; reg [WIDTH-1:0] state; /* * The synchronized output is the state register */ assign out = state; integer k; always @(posedge clk or posedge rst) begin if (rst) begin cnt_reg <= 0; state <= 0; for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= 0; end end else begin if (cnt_reg < RATE) begin cnt_reg <= cnt_reg + 24'd1; end else begin cnt_reg <= 24'd0; end if (cnt_reg == 24'd0) begin for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]}; end end for (k = 0; k < WIDTH; k = k + 1) begin if (\|debounce_reg[k] == 0) begin state[k] <= 0; end else if (&debounce_reg[k] == 1) begin state[k] <= 1; end else begin state[k] <= state[k]; end end end end endmodule
module processing_system7_bfm_v2_0_5_gen_clock( ps_clk, sw_clk, fclk_clk3, fclk_clk2, fclk_clk1, fclk_clk0 ); input ps_clk; output sw_clk; output fclk_clk3; output fclk_clk2; output fclk_clk1; output fclk_clk0; parameter freq_clk3 = 50; parameter freq_clk2 = 50; parameter freq_clk1 = 50; parameter freq_clk0 = 50; reg clk0 = 1'b0; reg clk1 = 1'b0; reg clk2 = 1'b0; reg clk3 = 1'b0; reg sw_clk = 1'b0; assign fclk_clk0 = clk0; assign fclk_clk1 = clk1; assign fclk_clk2 = clk2; assign fclk_clk3 = clk3; real clk3_p = (1000.00/freq_clk3)/2; real clk2_p = (1000.00/freq_clk2)/2; real clk1_p = (1000.00/freq_clk1)/2; real clk0_p = (1000.00/freq_clk0)/2; always #(clk3_p) clk3 = !clk3; always #(clk2_p) clk2 = !clk2; always #(clk1_p) clk1 = !clk1; always #(clk0_p) clk0 = !clk0; always #(0.5) sw_clk = !sw_clk; endmodule
module processing_system7_bfm_v2_0_5_gen_clock( ps_clk, sw_clk, fclk_clk3, fclk_clk2, fclk_clk1, fclk_clk0 ); input ps_clk; output sw_clk; output fclk_clk3; output fclk_clk2; output fclk_clk1; output fclk_clk0; parameter freq_clk3 = 50; parameter freq_clk2 = 50; parameter freq_clk1 = 50; parameter freq_clk0 = 50; reg clk0 = 1'b0; reg clk1 = 1'b0; reg clk2 = 1'b0; reg clk3 = 1'b0; reg sw_clk = 1'b0; assign fclk_clk0 = clk0; assign fclk_clk1 = clk1; assign fclk_clk2 = clk2; assign fclk_clk3 = clk3; real clk3_p = (1000.00/freq_clk3)/2; real clk2_p = (1000.00/freq_clk2)/2; real clk1_p = (1000.00/freq_clk1)/2; real clk0_p = (1000.00/freq_clk0)/2; always #(clk3_p) clk3 = !clk3; always #(clk2_p) clk2 = !clk2; always #(clk1_p) clk1 = !clk1; always #(clk0_p) clk0 = !clk0; always #(0.5) sw_clk = !sw_clk; endmodule
module processing_system7_bfm_v2_0_5_ocmc( rstn, sw_clk, /* Goes to port 0 of OCM / ocm_wr_ack_port0, ocm_wr_dv_port0, ocm_rd_req_port0, ocm_rd_dv_port0, ocm_wr_addr_port0, ocm_wr_data_port0, ocm_wr_bytes_port0, ocm_rd_addr_port0, ocm_rd_data_port0, ocm_rd_bytes_port0, ocm_wr_qos_port0, ocm_rd_qos_port0, / Goes to port 1 of OCM */ ocm_wr_ack_port1, ocm_wr_dv_port1, ocm_rd_req_port1, ocm_rd_dv_port1, ocm_wr_addr_port1, ocm_wr_data_port1, ocm_wr_bytes_port1, ocm_rd_addr_port1, ocm_rd_data_port1, ocm_rd_bytes_port1, ocm_wr_qos_port1, ocm_rd_qos_port1 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; output ocm_wr_ack_port0; input ocm_wr_dv_port0; input ocm_rd_req_port0; output ocm_rd_dv_port0; input[addr_width-1:0] ocm_wr_addr_port0; input[max_burst_bits-1:0] ocm_wr_data_port0; input[max_burst_bytes_width:0] ocm_wr_bytes_port0; input[addr_width-1:0] ocm_rd_addr_port0; output[max_burst_bits-1:0] ocm_rd_data_port0; input[max_burst_bytes_width:0] ocm_rd_bytes_port0; input [axi_qos_width-1:0] ocm_wr_qos_port0; input [axi_qos_width-1:0] ocm_rd_qos_port0; output ocm_wr_ack_port1; input ocm_wr_dv_port1; input ocm_rd_req_port1; output ocm_rd_dv_port1; input[addr_width-1:0] ocm_wr_addr_port1; input[max_burst_bits-1:0] ocm_wr_data_port1; input[max_burst_bytes_width:0] ocm_wr_bytes_port1; input[addr_width-1:0] ocm_rd_addr_port1; output[max_burst_bits-1:0] ocm_rd_data_port1; input[max_burst_bytes_width:0] ocm_rd_bytes_port1; input[axi_qos_width-1:0] ocm_wr_qos_port1; input[axi_qos_width-1:0] ocm_rd_qos_port1; wire [axi_qos_width-1:0] wr_qos; wire wr_req; wire [max_burst_bits-1:0] wr_data; wire [addr_width-1:0] wr_addr; wire [max_burst_bytes_width:0] wr_bytes; reg wr_ack; wire [axi_qos_width-1:0] rd_qos; reg [max_burst_bits-1:0] rd_data; wire [addr_width-1:0] rd_addr; wire [max_burst_bytes_width:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_wr ocm_write_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_wr_qos_port0), .qos2(ocm_wr_qos_port1), .prt_dv1(ocm_wr_dv_port0), .prt_dv2(ocm_wr_dv_port1), .prt_data1(ocm_wr_data_port0), .prt_data2(ocm_wr_data_port1), .prt_addr1(ocm_wr_addr_port0), .prt_addr2(ocm_wr_addr_port1), .prt_bytes1(ocm_wr_bytes_port0), .prt_bytes2(ocm_wr_bytes_port1), .prt_ack1(ocm_wr_ack_port0), .prt_ack2(ocm_wr_ack_port1), .prt_qos(wr_qos), .prt_req(wr_req), .prt_data(wr_data), .prt_addr(wr_addr), .prt_bytes(wr_bytes), .prt_ack(wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ocm_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_rd_qos_port0), .qos2(ocm_rd_qos_port1), .prt_req1(ocm_rd_req_port0), .prt_req2(ocm_rd_req_port1), .prt_data1(ocm_rd_data_port0), .prt_data2(ocm_rd_data_port1), .prt_addr1(ocm_rd_addr_port0), .prt_addr2(ocm_rd_addr_port1), .prt_bytes1(ocm_rd_bytes_port0), .prt_bytes2(ocm_rd_bytes_port1), .prt_dv1(ocm_rd_dv_port0), .prt_dv2(ocm_rd_dv_port1), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_ocm_mem ocm(); reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin wr_ack <= 0; rd_dv <= 0; state <= 2'd0; end else begin case(state) 0:begin state <= 0; wr_ack <= 0; rd_dv <= 0; if(wr_req) begin ocm.write_mem(wr_data , wr_addr, wr_bytes); wr_ack <= 1; state <= 1; end if(rd_req) begin ocm.read_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin wr_ack <= 0; rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule
module processing_system7_bfm_v2_0_5_ocmc( rstn, sw_clk, /* Goes to port 0 of OCM / ocm_wr_ack_port0, ocm_wr_dv_port0, ocm_rd_req_port0, ocm_rd_dv_port0, ocm_wr_addr_port0, ocm_wr_data_port0, ocm_wr_bytes_port0, ocm_rd_addr_port0, ocm_rd_data_port0, ocm_rd_bytes_port0, ocm_wr_qos_port0, ocm_rd_qos_port0, / Goes to port 1 of OCM */ ocm_wr_ack_port1, ocm_wr_dv_port1, ocm_rd_req_port1, ocm_rd_dv_port1, ocm_wr_addr_port1, ocm_wr_data_port1, ocm_wr_bytes_port1, ocm_rd_addr_port1, ocm_rd_data_port1, ocm_rd_bytes_port1, ocm_wr_qos_port1, ocm_rd_qos_port1 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; output ocm_wr_ack_port0; input ocm_wr_dv_port0; input ocm_rd_req_port0; output ocm_rd_dv_port0; input[addr_width-1:0] ocm_wr_addr_port0; input[max_burst_bits-1:0] ocm_wr_data_port0; input[max_burst_bytes_width:0] ocm_wr_bytes_port0; input[addr_width-1:0] ocm_rd_addr_port0; output[max_burst_bits-1:0] ocm_rd_data_port0; input[max_burst_bytes_width:0] ocm_rd_bytes_port0; input [axi_qos_width-1:0] ocm_wr_qos_port0; input [axi_qos_width-1:0] ocm_rd_qos_port0; output ocm_wr_ack_port1; input ocm_wr_dv_port1; input ocm_rd_req_port1; output ocm_rd_dv_port1; input[addr_width-1:0] ocm_wr_addr_port1; input[max_burst_bits-1:0] ocm_wr_data_port1; input[max_burst_bytes_width:0] ocm_wr_bytes_port1; input[addr_width-1:0] ocm_rd_addr_port1; output[max_burst_bits-1:0] ocm_rd_data_port1; input[max_burst_bytes_width:0] ocm_rd_bytes_port1; input[axi_qos_width-1:0] ocm_wr_qos_port1; input[axi_qos_width-1:0] ocm_rd_qos_port1; wire [axi_qos_width-1:0] wr_qos; wire wr_req; wire [max_burst_bits-1:0] wr_data; wire [addr_width-1:0] wr_addr; wire [max_burst_bytes_width:0] wr_bytes; reg wr_ack; wire [axi_qos_width-1:0] rd_qos; reg [max_burst_bits-1:0] rd_data; wire [addr_width-1:0] rd_addr; wire [max_burst_bytes_width:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_wr ocm_write_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_wr_qos_port0), .qos2(ocm_wr_qos_port1), .prt_dv1(ocm_wr_dv_port0), .prt_dv2(ocm_wr_dv_port1), .prt_data1(ocm_wr_data_port0), .prt_data2(ocm_wr_data_port1), .prt_addr1(ocm_wr_addr_port0), .prt_addr2(ocm_wr_addr_port1), .prt_bytes1(ocm_wr_bytes_port0), .prt_bytes2(ocm_wr_bytes_port1), .prt_ack1(ocm_wr_ack_port0), .prt_ack2(ocm_wr_ack_port1), .prt_qos(wr_qos), .prt_req(wr_req), .prt_data(wr_data), .prt_addr(wr_addr), .prt_bytes(wr_bytes), .prt_ack(wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ocm_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_rd_qos_port0), .qos2(ocm_rd_qos_port1), .prt_req1(ocm_rd_req_port0), .prt_req2(ocm_rd_req_port1), .prt_data1(ocm_rd_data_port0), .prt_data2(ocm_rd_data_port1), .prt_addr1(ocm_rd_addr_port0), .prt_addr2(ocm_rd_addr_port1), .prt_bytes1(ocm_rd_bytes_port0), .prt_bytes2(ocm_rd_bytes_port1), .prt_dv1(ocm_rd_dv_port0), .prt_dv2(ocm_rd_dv_port1), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_ocm_mem ocm(); reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin wr_ack <= 0; rd_dv <= 0; state <= 2'd0; end else begin case(state) 0:begin state <= 0; wr_ack <= 0; rd_dv <= 0; if(wr_req) begin ocm.write_mem(wr_data , wr_addr, wr_bytes); wr_ack <= 1; state <= 1; end if(rd_req) begin ocm.read_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin wr_ack <= 0; rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule
module processing_system7_bfm_v2_0_5_ocmc( rstn, sw_clk, /* Goes to port 0 of OCM / ocm_wr_ack_port0, ocm_wr_dv_port0, ocm_rd_req_port0, ocm_rd_dv_port0, ocm_wr_addr_port0, ocm_wr_data_port0, ocm_wr_bytes_port0, ocm_rd_addr_port0, ocm_rd_data_port0, ocm_rd_bytes_port0, ocm_wr_qos_port0, ocm_rd_qos_port0, / Goes to port 1 of OCM */ ocm_wr_ack_port1, ocm_wr_dv_port1, ocm_rd_req_port1, ocm_rd_dv_port1, ocm_wr_addr_port1, ocm_wr_data_port1, ocm_wr_bytes_port1, ocm_rd_addr_port1, ocm_rd_data_port1, ocm_rd_bytes_port1, ocm_wr_qos_port1, ocm_rd_qos_port1 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; output ocm_wr_ack_port0; input ocm_wr_dv_port0; input ocm_rd_req_port0; output ocm_rd_dv_port0; input[addr_width-1:0] ocm_wr_addr_port0; input[max_burst_bits-1:0] ocm_wr_data_port0; input[max_burst_bytes_width:0] ocm_wr_bytes_port0; input[addr_width-1:0] ocm_rd_addr_port0; output[max_burst_bits-1:0] ocm_rd_data_port0; input[max_burst_bytes_width:0] ocm_rd_bytes_port0; input [axi_qos_width-1:0] ocm_wr_qos_port0; input [axi_qos_width-1:0] ocm_rd_qos_port0; output ocm_wr_ack_port1; input ocm_wr_dv_port1; input ocm_rd_req_port1; output ocm_rd_dv_port1; input[addr_width-1:0] ocm_wr_addr_port1; input[max_burst_bits-1:0] ocm_wr_data_port1; input[max_burst_bytes_width:0] ocm_wr_bytes_port1; input[addr_width-1:0] ocm_rd_addr_port1; output[max_burst_bits-1:0] ocm_rd_data_port1; input[max_burst_bytes_width:0] ocm_rd_bytes_port1; input[axi_qos_width-1:0] ocm_wr_qos_port1; input[axi_qos_width-1:0] ocm_rd_qos_port1; wire [axi_qos_width-1:0] wr_qos; wire wr_req; wire [max_burst_bits-1:0] wr_data; wire [addr_width-1:0] wr_addr; wire [max_burst_bytes_width:0] wr_bytes; reg wr_ack; wire [axi_qos_width-1:0] rd_qos; reg [max_burst_bits-1:0] rd_data; wire [addr_width-1:0] rd_addr; wire [max_burst_bytes_width:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_wr ocm_write_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_wr_qos_port0), .qos2(ocm_wr_qos_port1), .prt_dv1(ocm_wr_dv_port0), .prt_dv2(ocm_wr_dv_port1), .prt_data1(ocm_wr_data_port0), .prt_data2(ocm_wr_data_port1), .prt_addr1(ocm_wr_addr_port0), .prt_addr2(ocm_wr_addr_port1), .prt_bytes1(ocm_wr_bytes_port0), .prt_bytes2(ocm_wr_bytes_port1), .prt_ack1(ocm_wr_ack_port0), .prt_ack2(ocm_wr_ack_port1), .prt_qos(wr_qos), .prt_req(wr_req), .prt_data(wr_data), .prt_addr(wr_addr), .prt_bytes(wr_bytes), .prt_ack(wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ocm_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_rd_qos_port0), .qos2(ocm_rd_qos_port1), .prt_req1(ocm_rd_req_port0), .prt_req2(ocm_rd_req_port1), .prt_data1(ocm_rd_data_port0), .prt_data2(ocm_rd_data_port1), .prt_addr1(ocm_rd_addr_port0), .prt_addr2(ocm_rd_addr_port1), .prt_bytes1(ocm_rd_bytes_port0), .prt_bytes2(ocm_rd_bytes_port1), .prt_dv1(ocm_rd_dv_port0), .prt_dv2(ocm_rd_dv_port1), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_ocm_mem ocm(); reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin wr_ack <= 0; rd_dv <= 0; state <= 2'd0; end else begin case(state) 0:begin state <= 0; wr_ack <= 0; rd_dv <= 0; if(wr_req) begin ocm.write_mem(wr_data , wr_addr, wr_bytes); wr_ack <= 1; state <= 1; end if(rd_req) begin ocm.read_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin wr_ack <= 0; rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule
module processing_system7_bfm_v2_0_5_fmsw_gp( sw_clk, rstn, w_qos_gp0, r_qos_gp0, wr_ack_ocm_gp0, wr_ack_ddr_gp0, wr_data_gp0, wr_addr_gp0, wr_bytes_gp0, wr_dv_ocm_gp0, wr_dv_ddr_gp0, rd_req_ocm_gp0, rd_req_ddr_gp0, rd_req_reg_gp0, rd_addr_gp0, rd_bytes_gp0, rd_data_ocm_gp0, rd_data_ddr_gp0, rd_data_reg_gp0, rd_dv_ocm_gp0, rd_dv_ddr_gp0, rd_dv_reg_gp0, w_qos_gp1, r_qos_gp1, wr_ack_ocm_gp1, wr_ack_ddr_gp1, wr_data_gp1, wr_addr_gp1, wr_bytes_gp1, wr_dv_ocm_gp1, wr_dv_ddr_gp1, rd_req_ocm_gp1, rd_req_ddr_gp1, rd_req_reg_gp1, rd_addr_gp1, rd_bytes_gp1, rd_data_ocm_gp1, rd_data_ddr_gp1, rd_data_reg_gp1, rd_dv_ocm_gp1, rd_dv_ddr_gp1, rd_dv_reg_gp1, ocm_wr_ack, ocm_wr_dv, ocm_rd_req, ocm_rd_dv, ddr_wr_ack, ddr_wr_dv, ddr_rd_req, ddr_rd_dv, reg_rd_req, reg_rd_dv, ocm_wr_qos, ddr_wr_qos, ocm_rd_qos, ddr_rd_qos, reg_rd_qos, ocm_wr_addr, ocm_wr_data, ocm_wr_bytes, ocm_rd_addr, ocm_rd_data, ocm_rd_bytes, ddr_wr_addr, ddr_wr_data, ddr_wr_bytes, ddr_rd_addr, ddr_rd_data, ddr_rd_bytes, reg_rd_addr, reg_rd_data, reg_rd_bytes ); `include "processing_system7_bfm_v2_0_5_local_params.v" input sw_clk; input rstn; input [axi_qos_width-1:0]w_qos_gp0; input [axi_qos_width-1:0]r_qos_gp0; input [axi_qos_width-1:0]w_qos_gp1; input [axi_qos_width-1:0]r_qos_gp1; output [axi_qos_width-1:0]ocm_wr_qos; output [axi_qos_width-1:0]ocm_rd_qos; output [axi_qos_width-1:0]ddr_wr_qos; output [axi_qos_width-1:0]ddr_rd_qos; output [axi_qos_width-1:0]reg_rd_qos; output wr_ack_ocm_gp0; output wr_ack_ddr_gp0; input [max_burst_bits-1:0] wr_data_gp0; input [addr_width-1:0] wr_addr_gp0; input [max_burst_bytes_width:0] wr_bytes_gp0; output wr_dv_ocm_gp0; output wr_dv_ddr_gp0; input rd_req_ocm_gp0; input rd_req_ddr_gp0; input rd_req_reg_gp0; input [addr_width-1:0] rd_addr_gp0; input [max_burst_bytes_width:0] rd_bytes_gp0; output [max_burst_bits-1:0] rd_data_ocm_gp0; output [max_burst_bits-1:0] rd_data_ddr_gp0; output [max_burst_bits-1:0] rd_data_reg_gp0; output rd_dv_ocm_gp0; output rd_dv_ddr_gp0; output rd_dv_reg_gp0; output wr_ack_ocm_gp1; output wr_ack_ddr_gp1; input [max_burst_bits-1:0] wr_data_gp1; input [addr_width-1:0] wr_addr_gp1; input [max_burst_bytes_width:0] wr_bytes_gp1; output wr_dv_ocm_gp1; output wr_dv_ddr_gp1; input rd_req_ocm_gp1; input rd_req_ddr_gp1; input rd_req_reg_gp1; input [addr_width-1:0] rd_addr_gp1; input [max_burst_bytes_width:0] rd_bytes_gp1; output [max_burst_bits-1:0] rd_data_ocm_gp1; output [max_burst_bits-1:0] rd_data_ddr_gp1; output [max_burst_bits-1:0] rd_data_reg_gp1; output rd_dv_ocm_gp1; output rd_dv_ddr_gp1; output rd_dv_reg_gp1; input ocm_wr_ack; output ocm_wr_dv; output [addr_width-1:0]ocm_wr_addr; output [max_burst_bits-1:0]ocm_wr_data; output [max_burst_bytes_width:0]ocm_wr_bytes; input ocm_rd_dv; input [max_burst_bits-1:0] ocm_rd_data; output ocm_rd_req; output [addr_width-1:0] ocm_rd_addr; output [max_burst_bytes_width:0] ocm_rd_bytes; input ddr_wr_ack; output ddr_wr_dv; output [addr_width-1:0]ddr_wr_addr; output [max_burst_bits-1:0]ddr_wr_data; output [max_burst_bytes_width:0]ddr_wr_bytes; input ddr_rd_dv; input [max_burst_bits-1:0] ddr_rd_data; output ddr_rd_req; output [addr_width-1:0] ddr_rd_addr; output [max_burst_bytes_width:0] ddr_rd_bytes; input reg_rd_dv; input [max_burst_bits-1:0] reg_rd_data; output reg_rd_req; output [addr_width-1:0] reg_rd_addr; output [max_burst_bytes_width:0] reg_rd_bytes; processing_system7_bfm_v2_0_5_arb_wr ocm_gp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_gp0), .qos2(w_qos_gp1), .prt_dv1(wr_dv_ocm_gp0), .prt_dv2(wr_dv_ocm_gp1), .prt_data1(wr_data_gp0), .prt_data2(wr_data_gp1), .prt_addr1(wr_addr_gp0), .prt_addr2(wr_addr_gp1), .prt_bytes1(wr_bytes_gp0), .prt_bytes2(wr_bytes_gp1), .prt_ack1(wr_ack_ocm_gp0), .prt_ack2(wr_ack_ocm_gp1), .prt_req(ocm_wr_dv), .prt_qos(ocm_wr_qos), .prt_data(ocm_wr_data), .prt_addr(ocm_wr_addr), .prt_bytes(ocm_wr_bytes), .prt_ack(ocm_wr_ack) ); processing_system7_bfm_v2_0_5_arb_wr ddr_gp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_gp0), .qos2(w_qos_gp1), .prt_dv1(wr_dv_ddr_gp0), .prt_dv2(wr_dv_ddr_gp1), .prt_data1(wr_data_gp0), .prt_data2(wr_data_gp1), .prt_addr1(wr_addr_gp0), .prt_addr2(wr_addr_gp1), .prt_bytes1(wr_bytes_gp0), .prt_bytes2(wr_bytes_gp1), .prt_ack1(wr_ack_ddr_gp0), .prt_ack2(wr_ack_ddr_gp1), .prt_req(ddr_wr_dv), .prt_qos(ddr_wr_qos), .prt_data(ddr_wr_data), .prt_addr(ddr_wr_addr), .prt_bytes(ddr_wr_bytes), .prt_ack(ddr_wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ocm_gp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_gp0), .qos2(r_qos_gp1), .prt_req1(rd_req_ocm_gp0), .prt_req2(rd_req_ocm_gp1), .prt_data1(rd_data_ocm_gp0), .prt_data2(rd_data_ocm_gp1), .prt_addr1(rd_addr_gp0), .prt_addr2(rd_addr_gp1), .prt_bytes1(rd_bytes_gp0), .prt_bytes2(rd_bytes_gp1), .prt_dv1(rd_dv_ocm_gp0), .prt_dv2(rd_dv_ocm_gp1), .prt_req(ocm_rd_req), .prt_qos(ocm_rd_qos), .prt_data(ocm_rd_data), .prt_addr(ocm_rd_addr), .prt_bytes(ocm_rd_bytes), .prt_dv(ocm_rd_dv) ); processing_system7_bfm_v2_0_5_arb_rd ddr_gp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_gp0), .qos2(r_qos_gp1), .prt_req1(rd_req_ddr_gp0), .prt_req2(rd_req_ddr_gp1), .prt_data1(rd_data_ddr_gp0), .prt_data2(rd_data_ddr_gp1), .prt_addr1(rd_addr_gp0), .prt_addr2(rd_addr_gp1), .prt_bytes1(rd_bytes_gp0), .prt_bytes2(rd_bytes_gp1), .prt_dv1(rd_dv_ddr_gp0), .prt_dv2(rd_dv_ddr_gp1), .prt_req(ddr_rd_req), .prt_qos(ddr_rd_qos), .prt_data(ddr_rd_data), .prt_addr(ddr_rd_addr), .prt_bytes(ddr_rd_bytes), .prt_dv(ddr_rd_dv) ); processing_system7_bfm_v2_0_5_arb_rd reg_gp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_gp0), .qos2(r_qos_gp1), .prt_req1(rd_req_reg_gp0), .prt_req2(rd_req_reg_gp1), .prt_data1(rd_data_reg_gp0), .prt_data2(rd_data_reg_gp1), .prt_addr1(rd_addr_gp0), .prt_addr2(rd_addr_gp1), .prt_bytes1(rd_bytes_gp0), .prt_bytes2(rd_bytes_gp1), .prt_dv1(rd_dv_reg_gp0), .prt_dv2(rd_dv_reg_gp1), .prt_req(reg_rd_req), .prt_qos(reg_rd_qos), .prt_data(reg_rd_data), .prt_addr(reg_rd_addr), .prt_bytes(reg_rd_bytes), .prt_dv(reg_rd_dv) ); endmodule
module processing_system7_bfm_v2_0_5_fmsw_gp( sw_clk, rstn, w_qos_gp0, r_qos_gp0, wr_ack_ocm_gp0, wr_ack_ddr_gp0, wr_data_gp0, wr_addr_gp0, wr_bytes_gp0, wr_dv_ocm_gp0, wr_dv_ddr_gp0, rd_req_ocm_gp0, rd_req_ddr_gp0, rd_req_reg_gp0, rd_addr_gp0, rd_bytes_gp0, rd_data_ocm_gp0, rd_data_ddr_gp0, rd_data_reg_gp0, rd_dv_ocm_gp0, rd_dv_ddr_gp0, rd_dv_reg_gp0, w_qos_gp1, r_qos_gp1, wr_ack_ocm_gp1, wr_ack_ddr_gp1, wr_data_gp1, wr_addr_gp1, wr_bytes_gp1, wr_dv_ocm_gp1, wr_dv_ddr_gp1, rd_req_ocm_gp1, rd_req_ddr_gp1, rd_req_reg_gp1, rd_addr_gp1, rd_bytes_gp1, rd_data_ocm_gp1, rd_data_ddr_gp1, rd_data_reg_gp1, rd_dv_ocm_gp1, rd_dv_ddr_gp1, rd_dv_reg_gp1, ocm_wr_ack, ocm_wr_dv, ocm_rd_req, ocm_rd_dv, ddr_wr_ack, ddr_wr_dv, ddr_rd_req, ddr_rd_dv, reg_rd_req, reg_rd_dv, ocm_wr_qos, ddr_wr_qos, ocm_rd_qos, ddr_rd_qos, reg_rd_qos, ocm_wr_addr, ocm_wr_data, ocm_wr_bytes, ocm_rd_addr, ocm_rd_data, ocm_rd_bytes, ddr_wr_addr, ddr_wr_data, ddr_wr_bytes, ddr_rd_addr, ddr_rd_data, ddr_rd_bytes, reg_rd_addr, reg_rd_data, reg_rd_bytes ); `include "processing_system7_bfm_v2_0_5_local_params.v" input sw_clk; input rstn; input [axi_qos_width-1:0]w_qos_gp0; input [axi_qos_width-1:0]r_qos_gp0; input [axi_qos_width-1:0]w_qos_gp1; input [axi_qos_width-1:0]r_qos_gp1; output [axi_qos_width-1:0]ocm_wr_qos; output [axi_qos_width-1:0]ocm_rd_qos; output [axi_qos_width-1:0]ddr_wr_qos; output [axi_qos_width-1:0]ddr_rd_qos; output [axi_qos_width-1:0]reg_rd_qos; output wr_ack_ocm_gp0; output wr_ack_ddr_gp0; input [max_burst_bits-1:0] wr_data_gp0; input [addr_width-1:0] wr_addr_gp0; input [max_burst_bytes_width:0] wr_bytes_gp0; output wr_dv_ocm_gp0; output wr_dv_ddr_gp0; input rd_req_ocm_gp0; input rd_req_ddr_gp0; input rd_req_reg_gp0; input [addr_width-1:0] rd_addr_gp0; input [max_burst_bytes_width:0] rd_bytes_gp0; output [max_burst_bits-1:0] rd_data_ocm_gp0; output [max_burst_bits-1:0] rd_data_ddr_gp0; output [max_burst_bits-1:0] rd_data_reg_gp0; output rd_dv_ocm_gp0; output rd_dv_ddr_gp0; output rd_dv_reg_gp0; output wr_ack_ocm_gp1; output wr_ack_ddr_gp1; input [max_burst_bits-1:0] wr_data_gp1; input [addr_width-1:0] wr_addr_gp1; input [max_burst_bytes_width:0] wr_bytes_gp1; output wr_dv_ocm_gp1; output wr_dv_ddr_gp1; input rd_req_ocm_gp1; input rd_req_ddr_gp1; input rd_req_reg_gp1; input [addr_width-1:0] rd_addr_gp1; input [max_burst_bytes_width:0] rd_bytes_gp1; output [max_burst_bits-1:0] rd_data_ocm_gp1; output [max_burst_bits-1:0] rd_data_ddr_gp1; output [max_burst_bits-1:0] rd_data_reg_gp1; output rd_dv_ocm_gp1; output rd_dv_ddr_gp1; output rd_dv_reg_gp1; input ocm_wr_ack; output ocm_wr_dv; output [addr_width-1:0]ocm_wr_addr; output [max_burst_bits-1:0]ocm_wr_data; output [max_burst_bytes_width:0]ocm_wr_bytes; input ocm_rd_dv; input [max_burst_bits-1:0] ocm_rd_data; output ocm_rd_req; output [addr_width-1:0] ocm_rd_addr; output [max_burst_bytes_width:0] ocm_rd_bytes; input ddr_wr_ack; output ddr_wr_dv; output [addr_width-1:0]ddr_wr_addr; output [max_burst_bits-1:0]ddr_wr_data; output [max_burst_bytes_width:0]ddr_wr_bytes; input ddr_rd_dv; input [max_burst_bits-1:0] ddr_rd_data; output ddr_rd_req; output [addr_width-1:0] ddr_rd_addr; output [max_burst_bytes_width:0] ddr_rd_bytes; input reg_rd_dv; input [max_burst_bits-1:0] reg_rd_data; output reg_rd_req; output [addr_width-1:0] reg_rd_addr; output [max_burst_bytes_width:0] reg_rd_bytes; processing_system7_bfm_v2_0_5_arb_wr ocm_gp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_gp0), .qos2(w_qos_gp1), .prt_dv1(wr_dv_ocm_gp0), .prt_dv2(wr_dv_ocm_gp1), .prt_data1(wr_data_gp0), .prt_data2(wr_data_gp1), .prt_addr1(wr_addr_gp0), .prt_addr2(wr_addr_gp1), .prt_bytes1(wr_bytes_gp0), .prt_bytes2(wr_bytes_gp1), .prt_ack1(wr_ack_ocm_gp0), .prt_ack2(wr_ack_ocm_gp1), .prt_req(ocm_wr_dv), .prt_qos(ocm_wr_qos), .prt_data(ocm_wr_data), .prt_addr(ocm_wr_addr), .prt_bytes(ocm_wr_bytes), .prt_ack(ocm_wr_ack) ); processing_system7_bfm_v2_0_5_arb_wr ddr_gp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_gp0), .qos2(w_qos_gp1), .prt_dv1(wr_dv_ddr_gp0), .prt_dv2(wr_dv_ddr_gp1), .prt_data1(wr_data_gp0), .prt_data2(wr_data_gp1), .prt_addr1(wr_addr_gp0), .prt_addr2(wr_addr_gp1), .prt_bytes1(wr_bytes_gp0), .prt_bytes2(wr_bytes_gp1), .prt_ack1(wr_ack_ddr_gp0), .prt_ack2(wr_ack_ddr_gp1), .prt_req(ddr_wr_dv), .prt_qos(ddr_wr_qos), .prt_data(ddr_wr_data), .prt_addr(ddr_wr_addr), .prt_bytes(ddr_wr_bytes), .prt_ack(ddr_wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ocm_gp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_gp0), .qos2(r_qos_gp1), .prt_req1(rd_req_ocm_gp0), .prt_req2(rd_req_ocm_gp1), .prt_data1(rd_data_ocm_gp0), .prt_data2(rd_data_ocm_gp1), .prt_addr1(rd_addr_gp0), .prt_addr2(rd_addr_gp1), .prt_bytes1(rd_bytes_gp0), .prt_bytes2(rd_bytes_gp1), .prt_dv1(rd_dv_ocm_gp0), .prt_dv2(rd_dv_ocm_gp1), .prt_req(ocm_rd_req), .prt_qos(ocm_rd_qos), .prt_data(ocm_rd_data), .prt_addr(ocm_rd_addr), .prt_bytes(ocm_rd_bytes), .prt_dv(ocm_rd_dv) ); processing_system7_bfm_v2_0_5_arb_rd ddr_gp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_gp0), .qos2(r_qos_gp1), .prt_req1(rd_req_ddr_gp0), .prt_req2(rd_req_ddr_gp1), .prt_data1(rd_data_ddr_gp0), .prt_data2(rd_data_ddr_gp1), .prt_addr1(rd_addr_gp0), .prt_addr2(rd_addr_gp1), .prt_bytes1(rd_bytes_gp0), .prt_bytes2(rd_bytes_gp1), .prt_dv1(rd_dv_ddr_gp0), .prt_dv2(rd_dv_ddr_gp1), .prt_req(ddr_rd_req), .prt_qos(ddr_rd_qos), .prt_data(ddr_rd_data), .prt_addr(ddr_rd_addr), .prt_bytes(ddr_rd_bytes), .prt_dv(ddr_rd_dv) ); processing_system7_bfm_v2_0_5_arb_rd reg_gp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_gp0), .qos2(r_qos_gp1), .prt_req1(rd_req_reg_gp0), .prt_req2(rd_req_reg_gp1), .prt_data1(rd_data_reg_gp0), .prt_data2(rd_data_reg_gp1), .prt_addr1(rd_addr_gp0), .prt_addr2(rd_addr_gp1), .prt_bytes1(rd_bytes_gp0), .prt_bytes2(rd_bytes_gp1), .prt_dv1(rd_dv_reg_gp0), .prt_dv2(rd_dv_reg_gp1), .prt_req(reg_rd_req), .prt_qos(reg_rd_qos), .prt_data(reg_rd_data), .prt_addr(reg_rd_addr), .prt_bytes(reg_rd_bytes), .prt_dv(reg_rd_dv) ); endmodule
module processing_system7_bfm_v2_0_5_arb_hp0_1( sw_clk, rstn, w_qos_hp0, r_qos_hp0, w_qos_hp1, r_qos_hp1, wr_ack_ddr_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, rd_req_ddr_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_dv_ddr_hp0, wr_ack_ddr_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, rd_req_ddr_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_dv_ddr_hp1, ddr_wr_ack, ddr_wr_dv, ddr_rd_req, ddr_rd_dv, ddr_rd_qos, ddr_wr_qos, ddr_wr_addr, ddr_wr_data, ddr_wr_bytes, ddr_rd_addr, ddr_rd_data, ddr_rd_bytes ); `include "processing_system7_bfm_v2_0_5_local_params.v" input sw_clk; input rstn; input [axi_qos_width-1:0] w_qos_hp0; input [axi_qos_width-1:0] r_qos_hp0; input [axi_qos_width-1:0] w_qos_hp1; input [axi_qos_width-1:0] r_qos_hp1; input [axi_qos_width-1:0] ddr_rd_qos; input [axi_qos_width-1:0] ddr_wr_qos; output wr_ack_ddr_hp0; input [max_burst_bits-1:0] wr_data_hp0; input [addr_width-1:0] wr_addr_hp0; input [max_burst_bytes_width:0] wr_bytes_hp0; output wr_dv_ddr_hp0; input rd_req_ddr_hp0; input [addr_width-1:0] rd_addr_hp0; input [max_burst_bytes_width:0] rd_bytes_hp0; output [max_burst_bits-1:0] rd_data_ddr_hp0; output rd_dv_ddr_hp0; output wr_ack_ddr_hp1; input [max_burst_bits-1:0] wr_data_hp1; input [addr_width-1:0] wr_addr_hp1; input [max_burst_bytes_width:0] wr_bytes_hp1; output wr_dv_ddr_hp1; input rd_req_ddr_hp1; input [addr_width-1:0] rd_addr_hp1; input [max_burst_bytes_width:0] rd_bytes_hp1; output [max_burst_bits-1:0] rd_data_ddr_hp1; output rd_dv_ddr_hp1; input ddr_wr_ack; output ddr_wr_dv; output [addr_width-1:0]ddr_wr_addr; output [max_burst_bits-1:0]ddr_wr_data; output [max_burst_bytes_width:0]ddr_wr_bytes; input ddr_rd_dv; input [max_burst_bits-1:0] ddr_rd_data; output ddr_rd_req; output [addr_width-1:0] ddr_rd_addr; output [max_burst_bytes_width:0] ddr_rd_bytes; processing_system7_bfm_v2_0_5_arb_wr ddr_hp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_hp0), .qos2(w_qos_hp1), .prt_dv1(wr_dv_ddr_hp0), .prt_dv2(wr_dv_ddr_hp1), .prt_data1(wr_data_hp0), .prt_data2(wr_data_hp1), .prt_addr1(wr_addr_hp0), .prt_addr2(wr_addr_hp1), .prt_bytes1(wr_bytes_hp0), .prt_bytes2(wr_bytes_hp1), .prt_ack1(wr_ack_ddr_hp0), .prt_ack2(wr_ack_ddr_hp1), .prt_req(ddr_wr_dv), .prt_qos(ddr_wr_qos), .prt_data(ddr_wr_data), .prt_addr(ddr_wr_addr), .prt_bytes(ddr_wr_bytes), .prt_ack(ddr_wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ddr_hp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_hp0), .qos2(r_qos_hp1), .prt_req1(rd_req_ddr_hp0), .prt_req2(rd_req_ddr_hp1), .prt_data1(rd_data_ddr_hp0), .prt_data2(rd_data_ddr_hp1), .prt_addr1(rd_addr_hp0), .prt_addr2(rd_addr_hp1), .prt_bytes1(rd_bytes_hp0), .prt_bytes2(rd_bytes_hp1), .prt_dv1(rd_dv_ddr_hp0), .prt_dv2(rd_dv_ddr_hp1), .prt_qos(ddr_rd_qos), .prt_req(ddr_rd_req), .prt_data(ddr_rd_data), .prt_addr(ddr_rd_addr), .prt_bytes(ddr_rd_bytes), .prt_dv(ddr_rd_dv) ); endmodule
module processing_system7_bfm_v2_0_5_arb_hp0_1( sw_clk, rstn, w_qos_hp0, r_qos_hp0, w_qos_hp1, r_qos_hp1, wr_ack_ddr_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, rd_req_ddr_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_dv_ddr_hp0, wr_ack_ddr_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, rd_req_ddr_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_dv_ddr_hp1, ddr_wr_ack, ddr_wr_dv, ddr_rd_req, ddr_rd_dv, ddr_rd_qos, ddr_wr_qos, ddr_wr_addr, ddr_wr_data, ddr_wr_bytes, ddr_rd_addr, ddr_rd_data, ddr_rd_bytes ); `include "processing_system7_bfm_v2_0_5_local_params.v" input sw_clk; input rstn; input [axi_qos_width-1:0] w_qos_hp0; input [axi_qos_width-1:0] r_qos_hp0; input [axi_qos_width-1:0] w_qos_hp1; input [axi_qos_width-1:0] r_qos_hp1; input [axi_qos_width-1:0] ddr_rd_qos; input [axi_qos_width-1:0] ddr_wr_qos; output wr_ack_ddr_hp0; input [max_burst_bits-1:0] wr_data_hp0; input [addr_width-1:0] wr_addr_hp0; input [max_burst_bytes_width:0] wr_bytes_hp0; output wr_dv_ddr_hp0; input rd_req_ddr_hp0; input [addr_width-1:0] rd_addr_hp0; input [max_burst_bytes_width:0] rd_bytes_hp0; output [max_burst_bits-1:0] rd_data_ddr_hp0; output rd_dv_ddr_hp0; output wr_ack_ddr_hp1; input [max_burst_bits-1:0] wr_data_hp1; input [addr_width-1:0] wr_addr_hp1; input [max_burst_bytes_width:0] wr_bytes_hp1; output wr_dv_ddr_hp1; input rd_req_ddr_hp1; input [addr_width-1:0] rd_addr_hp1; input [max_burst_bytes_width:0] rd_bytes_hp1; output [max_burst_bits-1:0] rd_data_ddr_hp1; output rd_dv_ddr_hp1; input ddr_wr_ack; output ddr_wr_dv; output [addr_width-1:0]ddr_wr_addr; output [max_burst_bits-1:0]ddr_wr_data; output [max_burst_bytes_width:0]ddr_wr_bytes; input ddr_rd_dv; input [max_burst_bits-1:0] ddr_rd_data; output ddr_rd_req; output [addr_width-1:0] ddr_rd_addr; output [max_burst_bytes_width:0] ddr_rd_bytes; processing_system7_bfm_v2_0_5_arb_wr ddr_hp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_hp0), .qos2(w_qos_hp1), .prt_dv1(wr_dv_ddr_hp0), .prt_dv2(wr_dv_ddr_hp1), .prt_data1(wr_data_hp0), .prt_data2(wr_data_hp1), .prt_addr1(wr_addr_hp0), .prt_addr2(wr_addr_hp1), .prt_bytes1(wr_bytes_hp0), .prt_bytes2(wr_bytes_hp1), .prt_ack1(wr_ack_ddr_hp0), .prt_ack2(wr_ack_ddr_hp1), .prt_req(ddr_wr_dv), .prt_qos(ddr_wr_qos), .prt_data(ddr_wr_data), .prt_addr(ddr_wr_addr), .prt_bytes(ddr_wr_bytes), .prt_ack(ddr_wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ddr_hp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_hp0), .qos2(r_qos_hp1), .prt_req1(rd_req_ddr_hp0), .prt_req2(rd_req_ddr_hp1), .prt_data1(rd_data_ddr_hp0), .prt_data2(rd_data_ddr_hp1), .prt_addr1(rd_addr_hp0), .prt_addr2(rd_addr_hp1), .prt_bytes1(rd_bytes_hp0), .prt_bytes2(rd_bytes_hp1), .prt_dv1(rd_dv_ddr_hp0), .prt_dv2(rd_dv_ddr_hp1), .prt_qos(ddr_rd_qos), .prt_req(ddr_rd_req), .prt_data(ddr_rd_data), .prt_addr(ddr_rd_addr), .prt_bytes(ddr_rd_bytes), .prt_dv(ddr_rd_dv) ); endmodule
module processing_system7_bfm_v2_0_5_arb_hp0_1( sw_clk, rstn, w_qos_hp0, r_qos_hp0, w_qos_hp1, r_qos_hp1, wr_ack_ddr_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, rd_req_ddr_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_dv_ddr_hp0, wr_ack_ddr_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, rd_req_ddr_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_dv_ddr_hp1, ddr_wr_ack, ddr_wr_dv, ddr_rd_req, ddr_rd_dv, ddr_rd_qos, ddr_wr_qos, ddr_wr_addr, ddr_wr_data, ddr_wr_bytes, ddr_rd_addr, ddr_rd_data, ddr_rd_bytes ); `include "processing_system7_bfm_v2_0_5_local_params.v" input sw_clk; input rstn; input [axi_qos_width-1:0] w_qos_hp0; input [axi_qos_width-1:0] r_qos_hp0; input [axi_qos_width-1:0] w_qos_hp1; input [axi_qos_width-1:0] r_qos_hp1; input [axi_qos_width-1:0] ddr_rd_qos; input [axi_qos_width-1:0] ddr_wr_qos; output wr_ack_ddr_hp0; input [max_burst_bits-1:0] wr_data_hp0; input [addr_width-1:0] wr_addr_hp0; input [max_burst_bytes_width:0] wr_bytes_hp0; output wr_dv_ddr_hp0; input rd_req_ddr_hp0; input [addr_width-1:0] rd_addr_hp0; input [max_burst_bytes_width:0] rd_bytes_hp0; output [max_burst_bits-1:0] rd_data_ddr_hp0; output rd_dv_ddr_hp0; output wr_ack_ddr_hp1; input [max_burst_bits-1:0] wr_data_hp1; input [addr_width-1:0] wr_addr_hp1; input [max_burst_bytes_width:0] wr_bytes_hp1; output wr_dv_ddr_hp1; input rd_req_ddr_hp1; input [addr_width-1:0] rd_addr_hp1; input [max_burst_bytes_width:0] rd_bytes_hp1; output [max_burst_bits-1:0] rd_data_ddr_hp1; output rd_dv_ddr_hp1; input ddr_wr_ack; output ddr_wr_dv; output [addr_width-1:0]ddr_wr_addr; output [max_burst_bits-1:0]ddr_wr_data; output [max_burst_bytes_width:0]ddr_wr_bytes; input ddr_rd_dv; input [max_burst_bits-1:0] ddr_rd_data; output ddr_rd_req; output [addr_width-1:0] ddr_rd_addr; output [max_burst_bytes_width:0] ddr_rd_bytes; processing_system7_bfm_v2_0_5_arb_wr ddr_hp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_hp0), .qos2(w_qos_hp1), .prt_dv1(wr_dv_ddr_hp0), .prt_dv2(wr_dv_ddr_hp1), .prt_data1(wr_data_hp0), .prt_data2(wr_data_hp1), .prt_addr1(wr_addr_hp0), .prt_addr2(wr_addr_hp1), .prt_bytes1(wr_bytes_hp0), .prt_bytes2(wr_bytes_hp1), .prt_ack1(wr_ack_ddr_hp0), .prt_ack2(wr_ack_ddr_hp1), .prt_req(ddr_wr_dv), .prt_qos(ddr_wr_qos), .prt_data(ddr_wr_data), .prt_addr(ddr_wr_addr), .prt_bytes(ddr_wr_bytes), .prt_ack(ddr_wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ddr_hp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_hp0), .qos2(r_qos_hp1), .prt_req1(rd_req_ddr_hp0), .prt_req2(rd_req_ddr_hp1), .prt_data1(rd_data_ddr_hp0), .prt_data2(rd_data_ddr_hp1), .prt_addr1(rd_addr_hp0), .prt_addr2(rd_addr_hp1), .prt_bytes1(rd_bytes_hp0), .prt_bytes2(rd_bytes_hp1), .prt_dv1(rd_dv_ddr_hp0), .prt_dv2(rd_dv_ddr_hp1), .prt_qos(ddr_rd_qos), .prt_req(ddr_rd_req), .prt_data(ddr_rd_data), .prt_addr(ddr_rd_addr), .prt_bytes(ddr_rd_bytes), .prt_dv(ddr_rd_dv) ); endmodule
module axi_crossbar_v2_1_decerr_slave # ( parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_BUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_PROTOCOL = 0, parameter integer C_RESP = 2'b11 ) ( input wire S_AXI_ACLK, input wire S_AXI_ARESET, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_AWID, input wire S_AXI_AWVALID, output wire S_AXI_AWREADY, input wire S_AXI_WLAST, input wire S_AXI_WVALID, output wire S_AXI_WREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_BID, output wire [1:0] S_AXI_BRESP, output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire S_AXI_BVALID, input wire S_AXI_BREADY, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_ARID, input wire [7:0] S_AXI_ARLEN, input wire S_AXI_ARVALID, output wire S_AXI_ARREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_RID, output wire [(C_AXI_DATA_WIDTH-1):0] S_AXI_RDATA, output wire [1:0] S_AXI_RRESP, output wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire S_AXI_RLAST, output wire S_AXI_RVALID, input wire S_AXI_RREADY ); reg s_axi_awready_i; reg s_axi_wready_i; reg s_axi_bvalid_i; reg s_axi_arready_i; reg s_axi_rvalid_i; localparam P_WRITE_IDLE = 2'b00; localparam P_WRITE_DATA = 2'b01; localparam P_WRITE_RESP = 2'b10; localparam P_READ_IDLE = 1'b0; localparam P_READ_DATA = 1'b1; localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; assign S_AXI_BRESP = C_RESP; assign S_AXI_RRESP = C_RESP; assign S_AXI_RDATA = {C_AXI_DATA_WIDTH{1'b0}}; assign S_AXI_BUSER = {C_AXI_BUSER_WIDTH{1'b0}}; assign S_AXI_RUSER = {C_AXI_RUSER_WIDTH{1'b0}}; assign S_AXI_AWREADY = s_axi_awready_i; assign S_AXI_WREADY = s_axi_wready_i; assign S_AXI_BVALID = s_axi_bvalid_i; assign S_AXI_ARREADY = s_axi_arready_i; assign S_AXI_RVALID = s_axi_rvalid_i; generate if (C_AXI_PROTOCOL == P_AXILITE) begin : gen_axilite assign S_AXI_RLAST = 1'b1; assign S_AXI_BID = 0; assign S_AXI_RID = 0; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; end else begin if (s_axi_bvalid_i) begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; end end else if (S_AXI_AWVALID & S_AXI_WVALID) begin if (s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; end else begin s_axi_awready_i <= 1'b1; s_axi_wready_i <= 1'b1; end end end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; end else begin if (s_axi_rvalid_i) begin if (S_AXI_RREADY) begin s_axi_rvalid_i <= 1'b0; end end else if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b1; end else begin s_axi_arready_i <= 1'b1; end end end end else begin : gen_axi reg s_axi_rlast_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_bid_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_rid_i; reg [7:0] read_cnt; reg [1:0] write_cs; reg [0:0] read_cs; assign S_AXI_RLAST = s_axi_rlast_i; assign S_AXI_BID = s_axi_bid_i; assign S_AXI_RID = s_axi_rid_i; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin write_cs <= P_WRITE_IDLE; s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; s_axi_bid_i <= 0; end else begin case (write_cs) P_WRITE_IDLE: begin if (S_AXI_AWVALID & s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_bid_i <= S_AXI_AWID; s_axi_wready_i <= 1'b1; write_cs <= P_WRITE_DATA; end else begin s_axi_awready_i <= 1'b1; end end P_WRITE_DATA: begin if (S_AXI_WVALID & S_AXI_WLAST) begin s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; write_cs <= P_WRITE_RESP; end end P_WRITE_RESP: begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; s_axi_awready_i <= 1'b1; write_cs <= P_WRITE_IDLE; end end endcase end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin read_cs <= P_READ_IDLE; s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_rid_i <= 0; read_cnt <= 0; end else begin case (read_cs) P_READ_IDLE: begin if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rid_i <= S_AXI_ARID; read_cnt <= S_AXI_ARLEN; s_axi_rvalid_i <= 1'b1; if (S_AXI_ARLEN == 0) begin s_axi_rlast_i <= 1'b1; end else begin s_axi_rlast_i <= 1'b0; end read_cs <= P_READ_DATA; end else begin s_axi_arready_i <= 1'b1; end end P_READ_DATA: begin if (S_AXI_RREADY) begin if (read_cnt == 0) begin s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_arready_i <= 1'b1; read_cs <= P_READ_IDLE; end else begin if (read_cnt == 1) begin s_axi_rlast_i <= 1'b1; end read_cnt <= read_cnt - 1; end end end endcase end end end endgenerate endmodule
module axi_crossbar_v2_1_decerr_slave # ( parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_BUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_PROTOCOL = 0, parameter integer C_RESP = 2'b11 ) ( input wire S_AXI_ACLK, input wire S_AXI_ARESET, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_AWID, input wire S_AXI_AWVALID, output wire S_AXI_AWREADY, input wire S_AXI_WLAST, input wire S_AXI_WVALID, output wire S_AXI_WREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_BID, output wire [1:0] S_AXI_BRESP, output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire S_AXI_BVALID, input wire S_AXI_BREADY, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_ARID, input wire [7:0] S_AXI_ARLEN, input wire S_AXI_ARVALID, output wire S_AXI_ARREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_RID, output wire [(C_AXI_DATA_WIDTH-1):0] S_AXI_RDATA, output wire [1:0] S_AXI_RRESP, output wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire S_AXI_RLAST, output wire S_AXI_RVALID, input wire S_AXI_RREADY ); reg s_axi_awready_i; reg s_axi_wready_i; reg s_axi_bvalid_i; reg s_axi_arready_i; reg s_axi_rvalid_i; localparam P_WRITE_IDLE = 2'b00; localparam P_WRITE_DATA = 2'b01; localparam P_WRITE_RESP = 2'b10; localparam P_READ_IDLE = 1'b0; localparam P_READ_DATA = 1'b1; localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; assign S_AXI_BRESP = C_RESP; assign S_AXI_RRESP = C_RESP; assign S_AXI_RDATA = {C_AXI_DATA_WIDTH{1'b0}}; assign S_AXI_BUSER = {C_AXI_BUSER_WIDTH{1'b0}}; assign S_AXI_RUSER = {C_AXI_RUSER_WIDTH{1'b0}}; assign S_AXI_AWREADY = s_axi_awready_i; assign S_AXI_WREADY = s_axi_wready_i; assign S_AXI_BVALID = s_axi_bvalid_i; assign S_AXI_ARREADY = s_axi_arready_i; assign S_AXI_RVALID = s_axi_rvalid_i; generate if (C_AXI_PROTOCOL == P_AXILITE) begin : gen_axilite assign S_AXI_RLAST = 1'b1; assign S_AXI_BID = 0; assign S_AXI_RID = 0; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; end else begin if (s_axi_bvalid_i) begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; end end else if (S_AXI_AWVALID & S_AXI_WVALID) begin if (s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; end else begin s_axi_awready_i <= 1'b1; s_axi_wready_i <= 1'b1; end end end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; end else begin if (s_axi_rvalid_i) begin if (S_AXI_RREADY) begin s_axi_rvalid_i <= 1'b0; end end else if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b1; end else begin s_axi_arready_i <= 1'b1; end end end end else begin : gen_axi reg s_axi_rlast_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_bid_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_rid_i; reg [7:0] read_cnt; reg [1:0] write_cs; reg [0:0] read_cs; assign S_AXI_RLAST = s_axi_rlast_i; assign S_AXI_BID = s_axi_bid_i; assign S_AXI_RID = s_axi_rid_i; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin write_cs <= P_WRITE_IDLE; s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; s_axi_bid_i <= 0; end else begin case (write_cs) P_WRITE_IDLE: begin if (S_AXI_AWVALID & s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_bid_i <= S_AXI_AWID; s_axi_wready_i <= 1'b1; write_cs <= P_WRITE_DATA; end else begin s_axi_awready_i <= 1'b1; end end P_WRITE_DATA: begin if (S_AXI_WVALID & S_AXI_WLAST) begin s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; write_cs <= P_WRITE_RESP; end end P_WRITE_RESP: begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; s_axi_awready_i <= 1'b1; write_cs <= P_WRITE_IDLE; end end endcase end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin read_cs <= P_READ_IDLE; s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_rid_i <= 0; read_cnt <= 0; end else begin case (read_cs) P_READ_IDLE: begin if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rid_i <= S_AXI_ARID; read_cnt <= S_AXI_ARLEN; s_axi_rvalid_i <= 1'b1; if (S_AXI_ARLEN == 0) begin s_axi_rlast_i <= 1'b1; end else begin s_axi_rlast_i <= 1'b0; end read_cs <= P_READ_DATA; end else begin s_axi_arready_i <= 1'b1; end end P_READ_DATA: begin if (S_AXI_RREADY) begin if (read_cnt == 0) begin s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_arready_i <= 1'b1; read_cs <= P_READ_IDLE; end else begin if (read_cnt == 1) begin s_axi_rlast_i <= 1'b1; end read_cnt <= read_cnt - 1; end end end endcase end end end endgenerate endmodule
module axi_crossbar_v2_1_decerr_slave # ( parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_BUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_PROTOCOL = 0, parameter integer C_RESP = 2'b11 ) ( input wire S_AXI_ACLK, input wire S_AXI_ARESET, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_AWID, input wire S_AXI_AWVALID, output wire S_AXI_AWREADY, input wire S_AXI_WLAST, input wire S_AXI_WVALID, output wire S_AXI_WREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_BID, output wire [1:0] S_AXI_BRESP, output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire S_AXI_BVALID, input wire S_AXI_BREADY, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_ARID, input wire [7:0] S_AXI_ARLEN, input wire S_AXI_ARVALID, output wire S_AXI_ARREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_RID, output wire [(C_AXI_DATA_WIDTH-1):0] S_AXI_RDATA, output wire [1:0] S_AXI_RRESP, output wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire S_AXI_RLAST, output wire S_AXI_RVALID, input wire S_AXI_RREADY ); reg s_axi_awready_i; reg s_axi_wready_i; reg s_axi_bvalid_i; reg s_axi_arready_i; reg s_axi_rvalid_i; localparam P_WRITE_IDLE = 2'b00; localparam P_WRITE_DATA = 2'b01; localparam P_WRITE_RESP = 2'b10; localparam P_READ_IDLE = 1'b0; localparam P_READ_DATA = 1'b1; localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; assign S_AXI_BRESP = C_RESP; assign S_AXI_RRESP = C_RESP; assign S_AXI_RDATA = {C_AXI_DATA_WIDTH{1'b0}}; assign S_AXI_BUSER = {C_AXI_BUSER_WIDTH{1'b0}}; assign S_AXI_RUSER = {C_AXI_RUSER_WIDTH{1'b0}}; assign S_AXI_AWREADY = s_axi_awready_i; assign S_AXI_WREADY = s_axi_wready_i; assign S_AXI_BVALID = s_axi_bvalid_i; assign S_AXI_ARREADY = s_axi_arready_i; assign S_AXI_RVALID = s_axi_rvalid_i; generate if (C_AXI_PROTOCOL == P_AXILITE) begin : gen_axilite assign S_AXI_RLAST = 1'b1; assign S_AXI_BID = 0; assign S_AXI_RID = 0; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; end else begin if (s_axi_bvalid_i) begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; end end else if (S_AXI_AWVALID & S_AXI_WVALID) begin if (s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; end else begin s_axi_awready_i <= 1'b1; s_axi_wready_i <= 1'b1; end end end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; end else begin if (s_axi_rvalid_i) begin if (S_AXI_RREADY) begin s_axi_rvalid_i <= 1'b0; end end else if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b1; end else begin s_axi_arready_i <= 1'b1; end end end end else begin : gen_axi reg s_axi_rlast_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_bid_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_rid_i; reg [7:0] read_cnt; reg [1:0] write_cs; reg [0:0] read_cs; assign S_AXI_RLAST = s_axi_rlast_i; assign S_AXI_BID = s_axi_bid_i; assign S_AXI_RID = s_axi_rid_i; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin write_cs <= P_WRITE_IDLE; s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; s_axi_bid_i <= 0; end else begin case (write_cs) P_WRITE_IDLE: begin if (S_AXI_AWVALID & s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_bid_i <= S_AXI_AWID; s_axi_wready_i <= 1'b1; write_cs <= P_WRITE_DATA; end else begin s_axi_awready_i <= 1'b1; end end P_WRITE_DATA: begin if (S_AXI_WVALID & S_AXI_WLAST) begin s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; write_cs <= P_WRITE_RESP; end end P_WRITE_RESP: begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; s_axi_awready_i <= 1'b1; write_cs <= P_WRITE_IDLE; end end endcase end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin read_cs <= P_READ_IDLE; s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_rid_i <= 0; read_cnt <= 0; end else begin case (read_cs) P_READ_IDLE: begin if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rid_i <= S_AXI_ARID; read_cnt <= S_AXI_ARLEN; s_axi_rvalid_i <= 1'b1; if (S_AXI_ARLEN == 0) begin s_axi_rlast_i <= 1'b1; end else begin s_axi_rlast_i <= 1'b0; end read_cs <= P_READ_DATA; end else begin s_axi_arready_i <= 1'b1; end end P_READ_DATA: begin if (S_AXI_RREADY) begin if (read_cnt == 0) begin s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_arready_i <= 1'b1; read_cs <= P_READ_IDLE; end else begin if (read_cnt == 1) begin s_axi_rlast_i <= 1'b1; end read_cnt <= read_cnt - 1; end end end endcase end end end endgenerate endmodule
module axi_crossbar_v2_1_decerr_slave # ( parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_BUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_PROTOCOL = 0, parameter integer C_RESP = 2'b11 ) ( input wire S_AXI_ACLK, input wire S_AXI_ARESET, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_AWID, input wire S_AXI_AWVALID, output wire S_AXI_AWREADY, input wire S_AXI_WLAST, input wire S_AXI_WVALID, output wire S_AXI_WREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_BID, output wire [1:0] S_AXI_BRESP, output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire S_AXI_BVALID, input wire S_AXI_BREADY, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_ARID, input wire [7:0] S_AXI_ARLEN, input wire S_AXI_ARVALID, output wire S_AXI_ARREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_RID, output wire [(C_AXI_DATA_WIDTH-1):0] S_AXI_RDATA, output wire [1:0] S_AXI_RRESP, output wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire S_AXI_RLAST, output wire S_AXI_RVALID, input wire S_AXI_RREADY ); reg s_axi_awready_i; reg s_axi_wready_i; reg s_axi_bvalid_i; reg s_axi_arready_i; reg s_axi_rvalid_i; localparam P_WRITE_IDLE = 2'b00; localparam P_WRITE_DATA = 2'b01; localparam P_WRITE_RESP = 2'b10; localparam P_READ_IDLE = 1'b0; localparam P_READ_DATA = 1'b1; localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; assign S_AXI_BRESP = C_RESP; assign S_AXI_RRESP = C_RESP; assign S_AXI_RDATA = {C_AXI_DATA_WIDTH{1'b0}}; assign S_AXI_BUSER = {C_AXI_BUSER_WIDTH{1'b0}}; assign S_AXI_RUSER = {C_AXI_RUSER_WIDTH{1'b0}}; assign S_AXI_AWREADY = s_axi_awready_i; assign S_AXI_WREADY = s_axi_wready_i; assign S_AXI_BVALID = s_axi_bvalid_i; assign S_AXI_ARREADY = s_axi_arready_i; assign S_AXI_RVALID = s_axi_rvalid_i; generate if (C_AXI_PROTOCOL == P_AXILITE) begin : gen_axilite assign S_AXI_RLAST = 1'b1; assign S_AXI_BID = 0; assign S_AXI_RID = 0; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; end else begin if (s_axi_bvalid_i) begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; end end else if (S_AXI_AWVALID & S_AXI_WVALID) begin if (s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; end else begin s_axi_awready_i <= 1'b1; s_axi_wready_i <= 1'b1; end end end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; end else begin if (s_axi_rvalid_i) begin if (S_AXI_RREADY) begin s_axi_rvalid_i <= 1'b0; end end else if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b1; end else begin s_axi_arready_i <= 1'b1; end end end end else begin : gen_axi reg s_axi_rlast_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_bid_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_rid_i; reg [7:0] read_cnt; reg [1:0] write_cs; reg [0:0] read_cs; assign S_AXI_RLAST = s_axi_rlast_i; assign S_AXI_BID = s_axi_bid_i; assign S_AXI_RID = s_axi_rid_i; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin write_cs <= P_WRITE_IDLE; s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; s_axi_bid_i <= 0; end else begin case (write_cs) P_WRITE_IDLE: begin if (S_AXI_AWVALID & s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_bid_i <= S_AXI_AWID; s_axi_wready_i <= 1'b1; write_cs <= P_WRITE_DATA; end else begin s_axi_awready_i <= 1'b1; end end P_WRITE_DATA: begin if (S_AXI_WVALID & S_AXI_WLAST) begin s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; write_cs <= P_WRITE_RESP; end end P_WRITE_RESP: begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; s_axi_awready_i <= 1'b1; write_cs <= P_WRITE_IDLE; end end endcase end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin read_cs <= P_READ_IDLE; s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_rid_i <= 0; read_cnt <= 0; end else begin case (read_cs) P_READ_IDLE: begin if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rid_i <= S_AXI_ARID; read_cnt <= S_AXI_ARLEN; s_axi_rvalid_i <= 1'b1; if (S_AXI_ARLEN == 0) begin s_axi_rlast_i <= 1'b1; end else begin s_axi_rlast_i <= 1'b0; end read_cs <= P_READ_DATA; end else begin s_axi_arready_i <= 1'b1; end end P_READ_DATA: begin if (S_AXI_RREADY) begin if (read_cnt == 0) begin s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_arready_i <= 1'b1; read_cs <= P_READ_IDLE; end else begin if (read_cnt == 1) begin s_axi_rlast_i <= 1'b1; end read_cnt <= read_cnt - 1; end end end endcase end end end endgenerate endmodule
module axi_crossbar_v2_1_si_transactor # ( parameter C_FAMILY = "none", parameter integer C_SI = 0, // SI-slot number of current instance. parameter integer C_DIR = 0, // Direction: 0 = Write; 1 = Read. parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_NUM_M = 2, parameter integer C_NUM_M_LOG = 1, parameter integer C_ACCEPTANCE = 1, // Acceptance limit of this SI-slot. parameter integer C_ACCEPTANCE_LOG = 0, // Width of acceptance counter for this SI-slot. parameter integer C_ID_WIDTH = 1, parameter integer C_THREAD_ID_WIDTH = 0, parameter integer C_ADDR_WIDTH = 32, parameter integer C_AMESG_WIDTH = 1, // Used for AW or AR channel payload, depending on instantiation. parameter integer C_RMESG_WIDTH = 1, // Used for B or R channel payload, depending on instantiation. parameter [C_ID_WIDTH-1:0] C_BASE_ID = {C_ID_WIDTH{1'b0}}, parameter [C_ID_WIDTH-1:0] C_HIGH_ID = {C_ID_WIDTH{1'b0}}, parameter [C_NUM_MC_NUM_ADDR_RANGES64-1:0] C_BASE_ADDR = {C_NUM_MC_NUM_ADDR_RANGES64{1'b1}}, parameter [C_NUM_MC_NUM_ADDR_RANGES64-1:0] C_HIGH_ADDR = {C_NUM_MC_NUM_ADDR_RANGES64{1'b0}}, parameter integer C_SINGLE_THREAD = 0, parameter [C_NUM_M-1:0] C_TARGET_QUAL = {C_NUM_M{1'b1}}, parameter [C_NUM_M32-1:0] C_M_AXI_SECURE = {C_NUM_M{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE =0, parameter [C_NUM_M32-1:0] C_ERR_MODE = {C_NUM_M{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Address Channel Interface Ports input wire [C_ID_WIDTH-1:0] S_AID, input wire [C_ADDR_WIDTH-1:0] S_AADDR, input wire [8-1:0] S_ALEN, input wire [3-1:0] S_ASIZE, input wire [2-1:0] S_ABURST, input wire [2-1:0] S_ALOCK, input wire [3-1:0] S_APROT, // input wire [4-1:0] S_AREGION, input wire [C_AMESG_WIDTH-1:0] S_AMESG, input wire S_AVALID, output wire S_AREADY, // Master Address Channel Interface Ports output wire [C_ID_WIDTH-1:0] M_AID, output wire [C_ADDR_WIDTH-1:0] M_AADDR, output wire [8-1:0] M_ALEN, output wire [3-1:0] M_ASIZE, output wire [2-1:0] M_ALOCK, output wire [3-1:0] M_APROT, output wire [4-1:0] M_AREGION, output wire [C_AMESG_WIDTH-1:0] M_AMESG, output wire [(C_NUM_M+1)-1:0] M_ATARGET_HOT, output wire [(C_NUM_M_LOG+1)-1:0] M_ATARGET_ENC, output wire [7:0] M_AERROR, output wire M_AVALID_QUAL, output wire M_AVALID, input wire M_AREADY, // Slave Response Channel Interface Ports output wire [C_ID_WIDTH-1:0] S_RID, output wire [C_RMESG_WIDTH-1:0] S_RMESG, output wire S_RLAST, output wire S_RVALID, input wire S_RREADY, // Master Response Channel Interface Ports input wire [(C_NUM_M+1)C_ID_WIDTH-1:0] M_RID, input wire [(C_NUM_M+1)C_RMESG_WIDTH-1:0] M_RMESG, input wire [(C_NUM_M+1)-1:0] M_RLAST, input wire [(C_NUM_M+1)-1:0] M_RVALID, output wire [(C_NUM_M+1)-1:0] M_RREADY, input wire [(C_NUM_M+1)-1:0] M_RTARGET, // Does response ID from each MI-slot target this SI slot? input wire [8-1:0] DEBUG_A_TRANS_SEQ ); localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_RMUX_MESG_WIDTH = C_ID_WIDTH + C_RMESG_WIDTH + 1; localparam [31:0] P_AXILITE_ERRMODE = 32'h00000001; localparam integer P_NONSECURE_BIT = 1; localparam integer P_NUM_M_LOG_M1 = C_NUM_M_LOG ? C_NUM_M_LOG : 1; localparam [C_NUM_M-1:0] P_M_AXILITE = f_m_axilite(0); // Mask of AxiLite MI-slots localparam [1:0] P_FIXED = 2'b00; localparam integer P_NUM_M_DE_LOG = f_ceil_log2(C_NUM_M+1); localparam integer P_THREAD_ID_WIDTH_M1 = (C_THREAD_ID_WIDTH > 0) ? C_THREAD_ID_WIDTH : 1; localparam integer P_NUM_ID_VAL = 2C_THREAD_ID_WIDTH; localparam integer P_NUM_THREADS = (P_NUM_ID_VAL < C_ACCEPTANCE) ? P_NUM_ID_VAL : C_ACCEPTANCE; localparam [C_NUM_M-1:0] P_M_SECURE_MASK = f_bit32to1_mi(C_M_AXI_SECURE); // Mask of secure MI-slots // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // AxiLite protocol flag vector function [C_NUM_M-1:0] f_m_axilite ( input integer null_arg ); integer mi; begin for (mi=0; mi<C_NUM_M; mi=mi+1) begin f_m_axilite[mi] = (C_ERR_MODE[mi32+:32] == P_AXILITE_ERRMODE); end end endfunction // Convert Bit32 vector of range [0,1] to Bit1 vector on MI function [C_NUM_M-1:0] f_bit32to1_mi (input [C_NUM_M32-1:0] vec32); integer mi; begin for (mi=0; mi<C_NUM_M; mi=mi+1) begin f_bit32to1_mi[mi] = vec32[mi32]; end end endfunction wire [C_NUM_M-1:0] target_mi_hot; wire [P_NUM_M_LOG_M1-1:0] target_mi_enc; wire [(C_NUM_M+1)-1:0] m_atarget_hot_i; wire [(P_NUM_M_DE_LOG)-1:0] m_atarget_enc_i; wire match; wire [3:0] target_region; wire [3:0] m_aregion_i; wire m_avalid_i; wire s_aready_i; wire any_error; wire s_rvalid_i; wire [C_ID_WIDTH-1:0] s_rid_i; wire s_rlast_i; wire [P_RMUX_MESG_WIDTH-1:0] si_rmux_mesg; wire [(C_NUM_M+1)P_RMUX_MESG_WIDTH-1:0] mi_rmux_mesg; wire [(C_NUM_M+1)-1:0] m_rvalid_qual; wire [(C_NUM_M+1)-1:0] m_rready_arb; wire [(C_NUM_M+1)-1:0] m_rready_i; wire target_secure; wire target_axilite; wire m_avalid_qual_i; wire [7:0] m_aerror_i; genvar gen_mi; genvar gen_thread; generate if (C_ADDR_DECODE) begin : gen_addr_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_M), .C_NUM_TARGETS_LOG (P_NUM_M_LOG_M1), .C_NUM_RANGES (C_NUM_ADDR_RANGES), .C_ADDR_WIDTH (C_ADDR_WIDTH), .C_TARGET_ENC (1), .C_TARGET_HOT (1), .C_REGION_ENC (1), .C_BASE_ADDR (C_BASE_ADDR), .C_HIGH_ADDR (C_HIGH_ADDR), .C_TARGET_QUAL (C_TARGET_QUAL), .C_RESOLUTION (2) ) addr_decoder_inst ( .ADDR (S_AADDR), .TARGET_HOT (target_mi_hot), .TARGET_ENC (target_mi_enc), .MATCH (match), .REGION (target_region) ); end else begin : gen_no_addr_decoder assign target_mi_hot = 1; assign target_mi_enc = 0; assign match = 1'b1; assign target_region = 4'b0000; end endgenerate assign target_secure = \|(target_mi_hot & P_M_SECURE_MASK); assign target_axilite = \|(target_mi_hot & P_M_AXILITE); assign any_error = C_RANGE_CHECK && (m_aerror_i != 0); // DECERR if error-detection enabled and any error condition. assign m_aerror_i[0] = ~match; // Invalid target address assign m_aerror_i[1] = target_secure && S_APROT[P_NONSECURE_BIT]; // TrustZone violation assign m_aerror_i[2] = target_axilite && ((S_ALEN != 0) \|\| (S_ASIZE[1:0] == 2'b11) \|\| (S_ASIZE[2] == 1'b1)); // AxiLite access violation assign m_aerror_i[7:3] = 5'b00000; // Reserved assign M_ATARGET_HOT = m_atarget_hot_i; assign m_atarget_hot_i = (any_error ? {1'b1, {C_NUM_M{1'b0}}} : {1'b0, target_mi_hot}); assign m_atarget_enc_i = (any_error ? C_NUM_M : target_mi_enc); assign M_AVALID = m_avalid_i; assign m_avalid_i = S_AVALID; assign M_AVALID_QUAL = m_avalid_qual_i; assign S_AREADY = s_aready_i; assign s_aready_i = M_AREADY; assign M_AERROR = m_aerror_i; assign M_ATARGET_ENC = m_atarget_enc_i; assign m_aregion_i = any_error ? 4'b0000 : (C_ADDR_DECODE != 0) ? target_region : 4'b0000; // assign m_aregion_i = any_error ? 4'b0000 : (C_ADDR_DECODE != 0) ? target_region : S_AREGION; assign M_AREGION = m_aregion_i; assign M_AID = S_AID; assign M_AADDR = S_AADDR; assign M_ALEN = S_ALEN; assign M_ASIZE = S_ASIZE; assign M_ALOCK = S_ALOCK; assign M_APROT = S_APROT; assign M_AMESG = S_AMESG; assign S_RVALID = s_rvalid_i; assign M_RREADY = m_rready_i; assign s_rid_i = si_rmux_mesg[0+:C_ID_WIDTH]; assign S_RMESG = si_rmux_mesg[C_ID_WIDTH+:C_RMESG_WIDTH]; assign s_rlast_i = si_rmux_mesg[C_ID_WIDTH+C_RMESG_WIDTH+:1]; assign S_RID = s_rid_i; assign S_RLAST = s_rlast_i; assign m_rvalid_qual = M_RVALID & M_RTARGET; assign m_rready_i = m_rready_arb & M_RTARGET; generate for (gen_mi=0; gen_mi<(C_NUM_M+1); gen_mi=gen_mi+1) begin : gen_rmesg_mi // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign mi_rmux_mesg[gen_miP_RMUX_MESG_WIDTH+:P_RMUX_MESG_WIDTH] = { M_RLAST[gen_mi], M_RMESG[gen_miC_RMESG_WIDTH+:C_RMESG_WIDTH], M_RID[gen_miC_ID_WIDTH+:C_ID_WIDTH] }; end // gen_rmesg_mi if (C_ACCEPTANCE == 1) begin : gen_single_issue wire cmd_push; wire cmd_pop; reg [(C_NUM_M+1)-1:0] active_target_hot; reg [P_NUM_M_DE_LOG-1:0] active_target_enc; reg accept_cnt; reg [8-1:0] debug_r_beat_cnt_i; wire [8-1:0] debug_r_trans_seq_i; assign cmd_push = M_AREADY; assign cmd_pop = s_rvalid_i && S_RREADY && s_rlast_i; // Pop command queue if end of read burst assign m_avalid_qual_i = ~accept_cnt \| cmd_pop; // Ready for arbitration if no outstanding transaction or transaction being completed always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 1'b0; active_target_enc <= 0; active_target_hot <= 0; end else begin if (cmd_push) begin active_target_enc <= m_atarget_enc_i; active_target_hot <= m_atarget_hot_i; accept_cnt <= 1'b1; end else if (cmd_pop) begin accept_cnt <= 1'b0; end end end // Clocked process assign m_rready_arb = active_target_hot & {(C_NUM_M+1){S_RREADY}}; assign s_rvalid_i = \|(active_target_hot & m_rvalid_qual); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_single_issue ( .S (active_target_enc), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); if (C_DEBUG) begin : gen_debug_r_single_issue // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i && S_RREADY) begin if (s_rlast_i) begin debug_r_beat_cnt_i <= 0; end else begin debug_r_beat_cnt_i <= debug_r_beat_cnt_i + 1; end end end else begin debug_r_beat_cnt_i <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_single_issue ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push), .S_READY (), .M_MESG (debug_r_trans_seq_i), .M_VALID (), .M_READY (cmd_pop) ); end // gen_debug_r end else if (C_SINGLE_THREAD \|\| (P_NUM_ID_VAL==1)) begin : gen_single_thread wire s_avalid_en; wire cmd_push; wire cmd_pop; reg [C_ID_WIDTH-1:0] active_id; reg [(C_NUM_M+1)-1:0] active_target_hot; reg [P_NUM_M_DE_LOG-1:0] active_target_enc; reg [4-1:0] active_region; reg [(C_ACCEPTANCE_LOG+1)-1:0] accept_cnt; reg [8-1:0] debug_r_beat_cnt_i; wire [8-1:0] debug_r_trans_seq_i; wire accept_limit ; // Implement single-region-per-ID cyclic dependency avoidance method. assign s_avalid_en = // This transaction is qualified to request arbitration if ... (accept_cnt == 0) \|\| // Either there are no outstanding transactions, or ... (((P_NUM_ID_VAL==1) \|\| (S_AID[P_THREAD_ID_WIDTH_M1-1:0] == active_id[P_THREAD_ID_WIDTH_M1-1:0])) && // the current transaction ID matches the previous, and ... (active_target_enc == m_atarget_enc_i) && // all outstanding transactions are to the same target MI ... (active_region == m_aregion_i)); // and to the same REGION. assign cmd_push = M_AREADY; assign cmd_pop = s_rvalid_i && S_RREADY && s_rlast_i; // Pop command queue if end of read burst assign accept_limit = (accept_cnt == C_ACCEPTANCE) & ~cmd_pop; // Allow next push if a transaction is currently being completed assign m_avalid_qual_i = s_avalid_en & ~accept_limit; always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 0; active_id <= 0; active_target_enc <= 0; active_target_hot <= 0; active_region <= 0; end else begin if (cmd_push) begin active_id <= S_AID[P_THREAD_ID_WIDTH_M1-1:0]; active_target_enc <= m_atarget_enc_i; active_target_hot <= m_atarget_hot_i; active_region <= m_aregion_i; if (~cmd_pop) begin accept_cnt <= accept_cnt + 1; end end else begin if (cmd_pop & (accept_cnt != 0)) begin accept_cnt <= accept_cnt - 1; end end end end // Clocked process assign m_rready_arb = active_target_hot & {(C_NUM_M+1){S_RREADY}}; assign s_rvalid_i = \|(active_target_hot & m_rvalid_qual); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_single_thread ( .S (active_target_enc), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); if (C_DEBUG) begin : gen_debug_r_single_thread // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i && S_RREADY) begin if (s_rlast_i) begin debug_r_beat_cnt_i <= 0; end else begin debug_r_beat_cnt_i <= debug_r_beat_cnt_i + 1; end end end else begin debug_r_beat_cnt_i <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_single_thread ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push), .S_READY (), .M_MESG (debug_r_trans_seq_i), .M_VALID (), .M_READY (cmd_pop) ); end // gen_debug_r end else begin : gen_multi_thread wire [(P_NUM_M_DE_LOG)-1:0] resp_select; reg [(C_ACCEPTANCE_LOG+1)-1:0] accept_cnt; wire [P_NUM_THREADS-1:0] s_avalid_en; wire [P_NUM_THREADS-1:0] thread_valid; wire [P_NUM_THREADS-1:0] aid_match; wire [P_NUM_THREADS-1:0] rid_match; wire [P_NUM_THREADS-1:0] cmd_push; wire [P_NUM_THREADS-1:0] cmd_pop; wire [P_NUM_THREADS:0] accum_push; reg [P_NUM_THREADSC_ID_WIDTH-1:0] active_id; reg [P_NUM_THREADS8-1:0] active_target; reg [P_NUM_THREADS8-1:0] active_region; reg [P_NUM_THREADS8-1:0] active_cnt; reg [P_NUM_THREADS8-1:0] debug_r_beat_cnt_i; wire [P_NUM_THREADS8-1:0] debug_r_trans_seq_i; wire any_aid_match; wire any_rid_match; wire accept_limit; wire any_push; wire any_pop; axi_crossbar_v2_1_arbiter_resp # // Multi-thread response arbiter ( .C_FAMILY (C_FAMILY), .C_NUM_S (C_NUM_M+1), .C_NUM_S_LOG (P_NUM_M_DE_LOG), .C_GRANT_ENC (1), .C_GRANT_HOT (0) ) arbiter_resp_inst ( .ACLK (ACLK), .ARESET (ARESET), .S_VALID (m_rvalid_qual), .S_READY (m_rready_arb), .M_GRANT_HOT (), .M_GRANT_ENC (resp_select), .M_VALID (s_rvalid_i), .M_READY (S_RREADY) ); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_multi_thread ( .S (resp_select), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); assign any_push = M_AREADY; assign any_pop = s_rvalid_i & S_RREADY & s_rlast_i; assign accept_limit = (accept_cnt == C_ACCEPTANCE) & ~any_pop; // Allow next push if a transaction is currently being completed assign m_avalid_qual_i = (&s_avalid_en) & ~accept_limit; // The current request is qualified for arbitration when it is qualified against all outstanding transaction threads. assign any_aid_match = \|aid_match; assign any_rid_match = \|rid_match; assign accum_push[0] = 1'b0; always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 0; end else begin if (any_push & ~any_pop) begin accept_cnt <= accept_cnt + 1; end else if (any_pop & ~any_push & (accept_cnt != 0)) begin accept_cnt <= accept_cnt - 1; end end end // Clocked process for (gen_thread=0; gen_thread<P_NUM_THREADS; gen_thread=gen_thread+1) begin : gen_thread_loop assign thread_valid[gen_thread] = (active_cnt[gen_thread8 +: C_ACCEPTANCE_LOG+1] != 0); assign aid_match[gen_thread] = // The currect thread is active for the requested transaction if thread_valid[gen_thread] && // this thread slot is not vacant, and ((S_AID[P_THREAD_ID_WIDTH_M1-1:0]) == active_id[gen_threadC_ID_WIDTH+:P_THREAD_ID_WIDTH_M1]); // the requested ID matches the active ID for this thread. assign s_avalid_en[gen_thread] = // The current request is qualified against this thread slot if (~aid_match[gen_thread]) \|\| // This thread slot is not active for the requested ID, or ((m_atarget_enc_i == active_target[gen_thread8+:P_NUM_M_DE_LOG]) && // this outstanding transaction was to the same target and (m_aregion_i == active_region[gen_thread8+:4])); // to the same region. // cmd_push points to the position of either the active thread for the requested ID or the lowest vacant thread slot. assign accum_push[gen_thread+1] = accum_push[gen_thread] \| ~thread_valid[gen_thread]; assign cmd_push[gen_thread] = any_push & (aid_match[gen_thread] \| ((~any_aid_match) & ~thread_valid[gen_thread] & ~accum_push[gen_thread])); // cmd_pop points to the position of the active thread that matches the current RID. assign rid_match[gen_thread] = thread_valid[gen_thread] & ((s_rid_i[P_THREAD_ID_WIDTH_M1-1:0]) == active_id[gen_threadC_ID_WIDTH+:P_THREAD_ID_WIDTH_M1]); assign cmd_pop[gen_thread] = any_pop & rid_match[gen_thread]; always @(posedge ACLK) begin if (ARESET) begin active_id[gen_threadC_ID_WIDTH+:C_ID_WIDTH] <= 0; active_target[gen_thread8+:8] <= 0; active_region[gen_thread8+:8] <= 0; active_cnt[gen_thread8+:8] <= 0; end else begin if (cmd_push[gen_thread]) begin active_id[gen_threadC_ID_WIDTH+:P_THREAD_ID_WIDTH_M1] <= S_AID[P_THREAD_ID_WIDTH_M1-1:0]; active_target[gen_thread8+:P_NUM_M_DE_LOG] <= m_atarget_enc_i; active_region[gen_thread8+:4] <= m_aregion_i; if (~cmd_pop[gen_thread]) begin active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] <= active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] + 1; end end else if (cmd_pop[gen_thread]) begin active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] <= active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] - 1; end end end // Clocked process if (C_DEBUG) begin : gen_debug_r_multi_thread // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i[gen_thread8+:8] <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i & S_RREADY & rid_match[gen_thread]) begin if (s_rlast_i) begin debug_r_beat_cnt_i[gen_thread8+:8] <= 0; end else begin debug_r_beat_cnt_i[gen_thread8+:8] <= debug_r_beat_cnt_i[gen_thread8+:8] + 1; end end end else begin debug_r_beat_cnt_i[gen_thread8+:8] <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_multi_thread ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push[gen_thread]), .S_READY (), .M_MESG (debug_r_trans_seq_i[gen_thread*8+:8]), .M_VALID (), .M_READY (cmd_pop[gen_thread]) ); end // gen_debug_r_multi_thread end // Next gen_thread_loop end // thread control endgenerate endmodule
module axi_crossbar_v2_1_si_transactor # ( parameter C_FAMILY = "none", parameter integer C_SI = 0, // SI-slot number of current instance. parameter integer C_DIR = 0, // Direction: 0 = Write; 1 = Read. parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_NUM_M = 2, parameter integer C_NUM_M_LOG = 1, parameter integer C_ACCEPTANCE = 1, // Acceptance limit of this SI-slot. parameter integer C_ACCEPTANCE_LOG = 0, // Width of acceptance counter for this SI-slot. parameter integer C_ID_WIDTH = 1, parameter integer C_THREAD_ID_WIDTH = 0, parameter integer C_ADDR_WIDTH = 32, parameter integer C_AMESG_WIDTH = 1, // Used for AW or AR channel payload, depending on instantiation. parameter integer C_RMESG_WIDTH = 1, // Used for B or R channel payload, depending on instantiation. parameter [C_ID_WIDTH-1:0] C_BASE_ID = {C_ID_WIDTH{1'b0}}, parameter [C_ID_WIDTH-1:0] C_HIGH_ID = {C_ID_WIDTH{1'b0}}, parameter [C_NUM_MC_NUM_ADDR_RANGES64-1:0] C_BASE_ADDR = {C_NUM_MC_NUM_ADDR_RANGES64{1'b1}}, parameter [C_NUM_MC_NUM_ADDR_RANGES64-1:0] C_HIGH_ADDR = {C_NUM_MC_NUM_ADDR_RANGES64{1'b0}}, parameter integer C_SINGLE_THREAD = 0, parameter [C_NUM_M-1:0] C_TARGET_QUAL = {C_NUM_M{1'b1}}, parameter [C_NUM_M32-1:0] C_M_AXI_SECURE = {C_NUM_M{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE =0, parameter [C_NUM_M32-1:0] C_ERR_MODE = {C_NUM_M{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Address Channel Interface Ports input wire [C_ID_WIDTH-1:0] S_AID, input wire [C_ADDR_WIDTH-1:0] S_AADDR, input wire [8-1:0] S_ALEN, input wire [3-1:0] S_ASIZE, input wire [2-1:0] S_ABURST, input wire [2-1:0] S_ALOCK, input wire [3-1:0] S_APROT, // input wire [4-1:0] S_AREGION, input wire [C_AMESG_WIDTH-1:0] S_AMESG, input wire S_AVALID, output wire S_AREADY, // Master Address Channel Interface Ports output wire [C_ID_WIDTH-1:0] M_AID, output wire [C_ADDR_WIDTH-1:0] M_AADDR, output wire [8-1:0] M_ALEN, output wire [3-1:0] M_ASIZE, output wire [2-1:0] M_ALOCK, output wire [3-1:0] M_APROT, output wire [4-1:0] M_AREGION, output wire [C_AMESG_WIDTH-1:0] M_AMESG, output wire [(C_NUM_M+1)-1:0] M_ATARGET_HOT, output wire [(C_NUM_M_LOG+1)-1:0] M_ATARGET_ENC, output wire [7:0] M_AERROR, output wire M_AVALID_QUAL, output wire M_AVALID, input wire M_AREADY, // Slave Response Channel Interface Ports output wire [C_ID_WIDTH-1:0] S_RID, output wire [C_RMESG_WIDTH-1:0] S_RMESG, output wire S_RLAST, output wire S_RVALID, input wire S_RREADY, // Master Response Channel Interface Ports input wire [(C_NUM_M+1)C_ID_WIDTH-1:0] M_RID, input wire [(C_NUM_M+1)C_RMESG_WIDTH-1:0] M_RMESG, input wire [(C_NUM_M+1)-1:0] M_RLAST, input wire [(C_NUM_M+1)-1:0] M_RVALID, output wire [(C_NUM_M+1)-1:0] M_RREADY, input wire [(C_NUM_M+1)-1:0] M_RTARGET, // Does response ID from each MI-slot target this SI slot? input wire [8-1:0] DEBUG_A_TRANS_SEQ ); localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_RMUX_MESG_WIDTH = C_ID_WIDTH + C_RMESG_WIDTH + 1; localparam [31:0] P_AXILITE_ERRMODE = 32'h00000001; localparam integer P_NONSECURE_BIT = 1; localparam integer P_NUM_M_LOG_M1 = C_NUM_M_LOG ? C_NUM_M_LOG : 1; localparam [C_NUM_M-1:0] P_M_AXILITE = f_m_axilite(0); // Mask of AxiLite MI-slots localparam [1:0] P_FIXED = 2'b00; localparam integer P_NUM_M_DE_LOG = f_ceil_log2(C_NUM_M+1); localparam integer P_THREAD_ID_WIDTH_M1 = (C_THREAD_ID_WIDTH > 0) ? C_THREAD_ID_WIDTH : 1; localparam integer P_NUM_ID_VAL = 2C_THREAD_ID_WIDTH; localparam integer P_NUM_THREADS = (P_NUM_ID_VAL < C_ACCEPTANCE) ? P_NUM_ID_VAL : C_ACCEPTANCE; localparam [C_NUM_M-1:0] P_M_SECURE_MASK = f_bit32to1_mi(C_M_AXI_SECURE); // Mask of secure MI-slots // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // AxiLite protocol flag vector function [C_NUM_M-1:0] f_m_axilite ( input integer null_arg ); integer mi; begin for (mi=0; mi<C_NUM_M; mi=mi+1) begin f_m_axilite[mi] = (C_ERR_MODE[mi32+:32] == P_AXILITE_ERRMODE); end end endfunction // Convert Bit32 vector of range [0,1] to Bit1 vector on MI function [C_NUM_M-1:0] f_bit32to1_mi (input [C_NUM_M32-1:0] vec32); integer mi; begin for (mi=0; mi<C_NUM_M; mi=mi+1) begin f_bit32to1_mi[mi] = vec32[mi32]; end end endfunction wire [C_NUM_M-1:0] target_mi_hot; wire [P_NUM_M_LOG_M1-1:0] target_mi_enc; wire [(C_NUM_M+1)-1:0] m_atarget_hot_i; wire [(P_NUM_M_DE_LOG)-1:0] m_atarget_enc_i; wire match; wire [3:0] target_region; wire [3:0] m_aregion_i; wire m_avalid_i; wire s_aready_i; wire any_error; wire s_rvalid_i; wire [C_ID_WIDTH-1:0] s_rid_i; wire s_rlast_i; wire [P_RMUX_MESG_WIDTH-1:0] si_rmux_mesg; wire [(C_NUM_M+1)P_RMUX_MESG_WIDTH-1:0] mi_rmux_mesg; wire [(C_NUM_M+1)-1:0] m_rvalid_qual; wire [(C_NUM_M+1)-1:0] m_rready_arb; wire [(C_NUM_M+1)-1:0] m_rready_i; wire target_secure; wire target_axilite; wire m_avalid_qual_i; wire [7:0] m_aerror_i; genvar gen_mi; genvar gen_thread; generate if (C_ADDR_DECODE) begin : gen_addr_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_M), .C_NUM_TARGETS_LOG (P_NUM_M_LOG_M1), .C_NUM_RANGES (C_NUM_ADDR_RANGES), .C_ADDR_WIDTH (C_ADDR_WIDTH), .C_TARGET_ENC (1), .C_TARGET_HOT (1), .C_REGION_ENC (1), .C_BASE_ADDR (C_BASE_ADDR), .C_HIGH_ADDR (C_HIGH_ADDR), .C_TARGET_QUAL (C_TARGET_QUAL), .C_RESOLUTION (2) ) addr_decoder_inst ( .ADDR (S_AADDR), .TARGET_HOT (target_mi_hot), .TARGET_ENC (target_mi_enc), .MATCH (match), .REGION (target_region) ); end else begin : gen_no_addr_decoder assign target_mi_hot = 1; assign target_mi_enc = 0; assign match = 1'b1; assign target_region = 4'b0000; end endgenerate assign target_secure = \|(target_mi_hot & P_M_SECURE_MASK); assign target_axilite = \|(target_mi_hot & P_M_AXILITE); assign any_error = C_RANGE_CHECK && (m_aerror_i != 0); // DECERR if error-detection enabled and any error condition. assign m_aerror_i[0] = ~match; // Invalid target address assign m_aerror_i[1] = target_secure && S_APROT[P_NONSECURE_BIT]; // TrustZone violation assign m_aerror_i[2] = target_axilite && ((S_ALEN != 0) \|\| (S_ASIZE[1:0] == 2'b11) \|\| (S_ASIZE[2] == 1'b1)); // AxiLite access violation assign m_aerror_i[7:3] = 5'b00000; // Reserved assign M_ATARGET_HOT = m_atarget_hot_i; assign m_atarget_hot_i = (any_error ? {1'b1, {C_NUM_M{1'b0}}} : {1'b0, target_mi_hot}); assign m_atarget_enc_i = (any_error ? C_NUM_M : target_mi_enc); assign M_AVALID = m_avalid_i; assign m_avalid_i = S_AVALID; assign M_AVALID_QUAL = m_avalid_qual_i; assign S_AREADY = s_aready_i; assign s_aready_i = M_AREADY; assign M_AERROR = m_aerror_i; assign M_ATARGET_ENC = m_atarget_enc_i; assign m_aregion_i = any_error ? 4'b0000 : (C_ADDR_DECODE != 0) ? target_region : 4'b0000; // assign m_aregion_i = any_error ? 4'b0000 : (C_ADDR_DECODE != 0) ? target_region : S_AREGION; assign M_AREGION = m_aregion_i; assign M_AID = S_AID; assign M_AADDR = S_AADDR; assign M_ALEN = S_ALEN; assign M_ASIZE = S_ASIZE; assign M_ALOCK = S_ALOCK; assign M_APROT = S_APROT; assign M_AMESG = S_AMESG; assign S_RVALID = s_rvalid_i; assign M_RREADY = m_rready_i; assign s_rid_i = si_rmux_mesg[0+:C_ID_WIDTH]; assign S_RMESG = si_rmux_mesg[C_ID_WIDTH+:C_RMESG_WIDTH]; assign s_rlast_i = si_rmux_mesg[C_ID_WIDTH+C_RMESG_WIDTH+:1]; assign S_RID = s_rid_i; assign S_RLAST = s_rlast_i; assign m_rvalid_qual = M_RVALID & M_RTARGET; assign m_rready_i = m_rready_arb & M_RTARGET; generate for (gen_mi=0; gen_mi<(C_NUM_M+1); gen_mi=gen_mi+1) begin : gen_rmesg_mi // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign mi_rmux_mesg[gen_miP_RMUX_MESG_WIDTH+:P_RMUX_MESG_WIDTH] = { M_RLAST[gen_mi], M_RMESG[gen_miC_RMESG_WIDTH+:C_RMESG_WIDTH], M_RID[gen_miC_ID_WIDTH+:C_ID_WIDTH] }; end // gen_rmesg_mi if (C_ACCEPTANCE == 1) begin : gen_single_issue wire cmd_push; wire cmd_pop; reg [(C_NUM_M+1)-1:0] active_target_hot; reg [P_NUM_M_DE_LOG-1:0] active_target_enc; reg accept_cnt; reg [8-1:0] debug_r_beat_cnt_i; wire [8-1:0] debug_r_trans_seq_i; assign cmd_push = M_AREADY; assign cmd_pop = s_rvalid_i && S_RREADY && s_rlast_i; // Pop command queue if end of read burst assign m_avalid_qual_i = ~accept_cnt \| cmd_pop; // Ready for arbitration if no outstanding transaction or transaction being completed always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 1'b0; active_target_enc <= 0; active_target_hot <= 0; end else begin if (cmd_push) begin active_target_enc <= m_atarget_enc_i; active_target_hot <= m_atarget_hot_i; accept_cnt <= 1'b1; end else if (cmd_pop) begin accept_cnt <= 1'b0; end end end // Clocked process assign m_rready_arb = active_target_hot & {(C_NUM_M+1){S_RREADY}}; assign s_rvalid_i = \|(active_target_hot & m_rvalid_qual); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_single_issue ( .S (active_target_enc), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); if (C_DEBUG) begin : gen_debug_r_single_issue // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i && S_RREADY) begin if (s_rlast_i) begin debug_r_beat_cnt_i <= 0; end else begin debug_r_beat_cnt_i <= debug_r_beat_cnt_i + 1; end end end else begin debug_r_beat_cnt_i <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_single_issue ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push), .S_READY (), .M_MESG (debug_r_trans_seq_i), .M_VALID (), .M_READY (cmd_pop) ); end // gen_debug_r end else if (C_SINGLE_THREAD \|\| (P_NUM_ID_VAL==1)) begin : gen_single_thread wire s_avalid_en; wire cmd_push; wire cmd_pop; reg [C_ID_WIDTH-1:0] active_id; reg [(C_NUM_M+1)-1:0] active_target_hot; reg [P_NUM_M_DE_LOG-1:0] active_target_enc; reg [4-1:0] active_region; reg [(C_ACCEPTANCE_LOG+1)-1:0] accept_cnt; reg [8-1:0] debug_r_beat_cnt_i; wire [8-1:0] debug_r_trans_seq_i; wire accept_limit ; // Implement single-region-per-ID cyclic dependency avoidance method. assign s_avalid_en = // This transaction is qualified to request arbitration if ... (accept_cnt == 0) \|\| // Either there are no outstanding transactions, or ... (((P_NUM_ID_VAL==1) \|\| (S_AID[P_THREAD_ID_WIDTH_M1-1:0] == active_id[P_THREAD_ID_WIDTH_M1-1:0])) && // the current transaction ID matches the previous, and ... (active_target_enc == m_atarget_enc_i) && // all outstanding transactions are to the same target MI ... (active_region == m_aregion_i)); // and to the same REGION. assign cmd_push = M_AREADY; assign cmd_pop = s_rvalid_i && S_RREADY && s_rlast_i; // Pop command queue if end of read burst assign accept_limit = (accept_cnt == C_ACCEPTANCE) & ~cmd_pop; // Allow next push if a transaction is currently being completed assign m_avalid_qual_i = s_avalid_en & ~accept_limit; always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 0; active_id <= 0; active_target_enc <= 0; active_target_hot <= 0; active_region <= 0; end else begin if (cmd_push) begin active_id <= S_AID[P_THREAD_ID_WIDTH_M1-1:0]; active_target_enc <= m_atarget_enc_i; active_target_hot <= m_atarget_hot_i; active_region <= m_aregion_i; if (~cmd_pop) begin accept_cnt <= accept_cnt + 1; end end else begin if (cmd_pop & (accept_cnt != 0)) begin accept_cnt <= accept_cnt - 1; end end end end // Clocked process assign m_rready_arb = active_target_hot & {(C_NUM_M+1){S_RREADY}}; assign s_rvalid_i = \|(active_target_hot & m_rvalid_qual); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_single_thread ( .S (active_target_enc), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); if (C_DEBUG) begin : gen_debug_r_single_thread // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i && S_RREADY) begin if (s_rlast_i) begin debug_r_beat_cnt_i <= 0; end else begin debug_r_beat_cnt_i <= debug_r_beat_cnt_i + 1; end end end else begin debug_r_beat_cnt_i <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_single_thread ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push), .S_READY (), .M_MESG (debug_r_trans_seq_i), .M_VALID (), .M_READY (cmd_pop) ); end // gen_debug_r end else begin : gen_multi_thread wire [(P_NUM_M_DE_LOG)-1:0] resp_select; reg [(C_ACCEPTANCE_LOG+1)-1:0] accept_cnt; wire [P_NUM_THREADS-1:0] s_avalid_en; wire [P_NUM_THREADS-1:0] thread_valid; wire [P_NUM_THREADS-1:0] aid_match; wire [P_NUM_THREADS-1:0] rid_match; wire [P_NUM_THREADS-1:0] cmd_push; wire [P_NUM_THREADS-1:0] cmd_pop; wire [P_NUM_THREADS:0] accum_push; reg [P_NUM_THREADSC_ID_WIDTH-1:0] active_id; reg [P_NUM_THREADS8-1:0] active_target; reg [P_NUM_THREADS8-1:0] active_region; reg [P_NUM_THREADS8-1:0] active_cnt; reg [P_NUM_THREADS8-1:0] debug_r_beat_cnt_i; wire [P_NUM_THREADS8-1:0] debug_r_trans_seq_i; wire any_aid_match; wire any_rid_match; wire accept_limit; wire any_push; wire any_pop; axi_crossbar_v2_1_arbiter_resp # // Multi-thread response arbiter ( .C_FAMILY (C_FAMILY), .C_NUM_S (C_NUM_M+1), .C_NUM_S_LOG (P_NUM_M_DE_LOG), .C_GRANT_ENC (1), .C_GRANT_HOT (0) ) arbiter_resp_inst ( .ACLK (ACLK), .ARESET (ARESET), .S_VALID (m_rvalid_qual), .S_READY (m_rready_arb), .M_GRANT_HOT (), .M_GRANT_ENC (resp_select), .M_VALID (s_rvalid_i), .M_READY (S_RREADY) ); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_multi_thread ( .S (resp_select), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); assign any_push = M_AREADY; assign any_pop = s_rvalid_i & S_RREADY & s_rlast_i; assign accept_limit = (accept_cnt == C_ACCEPTANCE) & ~any_pop; // Allow next push if a transaction is currently being completed assign m_avalid_qual_i = (&s_avalid_en) & ~accept_limit; // The current request is qualified for arbitration when it is qualified against all outstanding transaction threads. assign any_aid_match = \|aid_match; assign any_rid_match = \|rid_match; assign accum_push[0] = 1'b0; always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 0; end else begin if (any_push & ~any_pop) begin accept_cnt <= accept_cnt + 1; end else if (any_pop & ~any_push & (accept_cnt != 0)) begin accept_cnt <= accept_cnt - 1; end end end // Clocked process for (gen_thread=0; gen_thread<P_NUM_THREADS; gen_thread=gen_thread+1) begin : gen_thread_loop assign thread_valid[gen_thread] = (active_cnt[gen_thread8 +: C_ACCEPTANCE_LOG+1] != 0); assign aid_match[gen_thread] = // The currect thread is active for the requested transaction if thread_valid[gen_thread] && // this thread slot is not vacant, and ((S_AID[P_THREAD_ID_WIDTH_M1-1:0]) == active_id[gen_threadC_ID_WIDTH+:P_THREAD_ID_WIDTH_M1]); // the requested ID matches the active ID for this thread. assign s_avalid_en[gen_thread] = // The current request is qualified against this thread slot if (~aid_match[gen_thread]) \|\| // This thread slot is not active for the requested ID, or ((m_atarget_enc_i == active_target[gen_thread8+:P_NUM_M_DE_LOG]) && // this outstanding transaction was to the same target and (m_aregion_i == active_region[gen_thread8+:4])); // to the same region. // cmd_push points to the position of either the active thread for the requested ID or the lowest vacant thread slot. assign accum_push[gen_thread+1] = accum_push[gen_thread] \| ~thread_valid[gen_thread]; assign cmd_push[gen_thread] = any_push & (aid_match[gen_thread] \| ((~any_aid_match) & ~thread_valid[gen_thread] & ~accum_push[gen_thread])); // cmd_pop points to the position of the active thread that matches the current RID. assign rid_match[gen_thread] = thread_valid[gen_thread] & ((s_rid_i[P_THREAD_ID_WIDTH_M1-1:0]) == active_id[gen_threadC_ID_WIDTH+:P_THREAD_ID_WIDTH_M1]); assign cmd_pop[gen_thread] = any_pop & rid_match[gen_thread]; always @(posedge ACLK) begin if (ARESET) begin active_id[gen_threadC_ID_WIDTH+:C_ID_WIDTH] <= 0; active_target[gen_thread8+:8] <= 0; active_region[gen_thread8+:8] <= 0; active_cnt[gen_thread8+:8] <= 0; end else begin if (cmd_push[gen_thread]) begin active_id[gen_threadC_ID_WIDTH+:P_THREAD_ID_WIDTH_M1] <= S_AID[P_THREAD_ID_WIDTH_M1-1:0]; active_target[gen_thread8+:P_NUM_M_DE_LOG] <= m_atarget_enc_i; active_region[gen_thread8+:4] <= m_aregion_i; if (~cmd_pop[gen_thread]) begin active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] <= active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] + 1; end end else if (cmd_pop[gen_thread]) begin active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] <= active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] - 1; end end end // Clocked process if (C_DEBUG) begin : gen_debug_r_multi_thread // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i[gen_thread8+:8] <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i & S_RREADY & rid_match[gen_thread]) begin if (s_rlast_i) begin debug_r_beat_cnt_i[gen_thread8+:8] <= 0; end else begin debug_r_beat_cnt_i[gen_thread8+:8] <= debug_r_beat_cnt_i[gen_thread8+:8] + 1; end end end else begin debug_r_beat_cnt_i[gen_thread8+:8] <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_multi_thread ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push[gen_thread]), .S_READY (), .M_MESG (debug_r_trans_seq_i[gen_thread*8+:8]), .M_VALID (), .M_READY (cmd_pop[gen_thread]) ); end // gen_debug_r_multi_thread end // Next gen_thread_loop end // thread control endgenerate endmodule
module axi_crossbar_v2_1_si_transactor # ( parameter C_FAMILY = "none", parameter integer C_SI = 0, // SI-slot number of current instance. parameter integer C_DIR = 0, // Direction: 0 = Write; 1 = Read. parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_NUM_M = 2, parameter integer C_NUM_M_LOG = 1, parameter integer C_ACCEPTANCE = 1, // Acceptance limit of this SI-slot. parameter integer C_ACCEPTANCE_LOG = 0, // Width of acceptance counter for this SI-slot. parameter integer C_ID_WIDTH = 1, parameter integer C_THREAD_ID_WIDTH = 0, parameter integer C_ADDR_WIDTH = 32, parameter integer C_AMESG_WIDTH = 1, // Used for AW or AR channel payload, depending on instantiation. parameter integer C_RMESG_WIDTH = 1, // Used for B or R channel payload, depending on instantiation. parameter [C_ID_WIDTH-1:0] C_BASE_ID = {C_ID_WIDTH{1'b0}}, parameter [C_ID_WIDTH-1:0] C_HIGH_ID = {C_ID_WIDTH{1'b0}}, parameter [C_NUM_MC_NUM_ADDR_RANGES64-1:0] C_BASE_ADDR = {C_NUM_MC_NUM_ADDR_RANGES64{1'b1}}, parameter [C_NUM_MC_NUM_ADDR_RANGES64-1:0] C_HIGH_ADDR = {C_NUM_MC_NUM_ADDR_RANGES64{1'b0}}, parameter integer C_SINGLE_THREAD = 0, parameter [C_NUM_M-1:0] C_TARGET_QUAL = {C_NUM_M{1'b1}}, parameter [C_NUM_M32-1:0] C_M_AXI_SECURE = {C_NUM_M{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE =0, parameter [C_NUM_M32-1:0] C_ERR_MODE = {C_NUM_M{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Address Channel Interface Ports input wire [C_ID_WIDTH-1:0] S_AID, input wire [C_ADDR_WIDTH-1:0] S_AADDR, input wire [8-1:0] S_ALEN, input wire [3-1:0] S_ASIZE, input wire [2-1:0] S_ABURST, input wire [2-1:0] S_ALOCK, input wire [3-1:0] S_APROT, // input wire [4-1:0] S_AREGION, input wire [C_AMESG_WIDTH-1:0] S_AMESG, input wire S_AVALID, output wire S_AREADY, // Master Address Channel Interface Ports output wire [C_ID_WIDTH-1:0] M_AID, output wire [C_ADDR_WIDTH-1:0] M_AADDR, output wire [8-1:0] M_ALEN, output wire [3-1:0] M_ASIZE, output wire [2-1:0] M_ALOCK, output wire [3-1:0] M_APROT, output wire [4-1:0] M_AREGION, output wire [C_AMESG_WIDTH-1:0] M_AMESG, output wire [(C_NUM_M+1)-1:0] M_ATARGET_HOT, output wire [(C_NUM_M_LOG+1)-1:0] M_ATARGET_ENC, output wire [7:0] M_AERROR, output wire M_AVALID_QUAL, output wire M_AVALID, input wire M_AREADY, // Slave Response Channel Interface Ports output wire [C_ID_WIDTH-1:0] S_RID, output wire [C_RMESG_WIDTH-1:0] S_RMESG, output wire S_RLAST, output wire S_RVALID, input wire S_RREADY, // Master Response Channel Interface Ports input wire [(C_NUM_M+1)C_ID_WIDTH-1:0] M_RID, input wire [(C_NUM_M+1)C_RMESG_WIDTH-1:0] M_RMESG, input wire [(C_NUM_M+1)-1:0] M_RLAST, input wire [(C_NUM_M+1)-1:0] M_RVALID, output wire [(C_NUM_M+1)-1:0] M_RREADY, input wire [(C_NUM_M+1)-1:0] M_RTARGET, // Does response ID from each MI-slot target this SI slot? input wire [8-1:0] DEBUG_A_TRANS_SEQ ); localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_RMUX_MESG_WIDTH = C_ID_WIDTH + C_RMESG_WIDTH + 1; localparam [31:0] P_AXILITE_ERRMODE = 32'h00000001; localparam integer P_NONSECURE_BIT = 1; localparam integer P_NUM_M_LOG_M1 = C_NUM_M_LOG ? C_NUM_M_LOG : 1; localparam [C_NUM_M-1:0] P_M_AXILITE = f_m_axilite(0); // Mask of AxiLite MI-slots localparam [1:0] P_FIXED = 2'b00; localparam integer P_NUM_M_DE_LOG = f_ceil_log2(C_NUM_M+1); localparam integer P_THREAD_ID_WIDTH_M1 = (C_THREAD_ID_WIDTH > 0) ? C_THREAD_ID_WIDTH : 1; localparam integer P_NUM_ID_VAL = 2C_THREAD_ID_WIDTH; localparam integer P_NUM_THREADS = (P_NUM_ID_VAL < C_ACCEPTANCE) ? P_NUM_ID_VAL : C_ACCEPTANCE; localparam [C_NUM_M-1:0] P_M_SECURE_MASK = f_bit32to1_mi(C_M_AXI_SECURE); // Mask of secure MI-slots // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // AxiLite protocol flag vector function [C_NUM_M-1:0] f_m_axilite ( input integer null_arg ); integer mi; begin for (mi=0; mi<C_NUM_M; mi=mi+1) begin f_m_axilite[mi] = (C_ERR_MODE[mi32+:32] == P_AXILITE_ERRMODE); end end endfunction // Convert Bit32 vector of range [0,1] to Bit1 vector on MI function [C_NUM_M-1:0] f_bit32to1_mi (input [C_NUM_M32-1:0] vec32); integer mi; begin for (mi=0; mi<C_NUM_M; mi=mi+1) begin f_bit32to1_mi[mi] = vec32[mi32]; end end endfunction wire [C_NUM_M-1:0] target_mi_hot; wire [P_NUM_M_LOG_M1-1:0] target_mi_enc; wire [(C_NUM_M+1)-1:0] m_atarget_hot_i; wire [(P_NUM_M_DE_LOG)-1:0] m_atarget_enc_i; wire match; wire [3:0] target_region; wire [3:0] m_aregion_i; wire m_avalid_i; wire s_aready_i; wire any_error; wire s_rvalid_i; wire [C_ID_WIDTH-1:0] s_rid_i; wire s_rlast_i; wire [P_RMUX_MESG_WIDTH-1:0] si_rmux_mesg; wire [(C_NUM_M+1)P_RMUX_MESG_WIDTH-1:0] mi_rmux_mesg; wire [(C_NUM_M+1)-1:0] m_rvalid_qual; wire [(C_NUM_M+1)-1:0] m_rready_arb; wire [(C_NUM_M+1)-1:0] m_rready_i; wire target_secure; wire target_axilite; wire m_avalid_qual_i; wire [7:0] m_aerror_i; genvar gen_mi; genvar gen_thread; generate if (C_ADDR_DECODE) begin : gen_addr_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_M), .C_NUM_TARGETS_LOG (P_NUM_M_LOG_M1), .C_NUM_RANGES (C_NUM_ADDR_RANGES), .C_ADDR_WIDTH (C_ADDR_WIDTH), .C_TARGET_ENC (1), .C_TARGET_HOT (1), .C_REGION_ENC (1), .C_BASE_ADDR (C_BASE_ADDR), .C_HIGH_ADDR (C_HIGH_ADDR), .C_TARGET_QUAL (C_TARGET_QUAL), .C_RESOLUTION (2) ) addr_decoder_inst ( .ADDR (S_AADDR), .TARGET_HOT (target_mi_hot), .TARGET_ENC (target_mi_enc), .MATCH (match), .REGION (target_region) ); end else begin : gen_no_addr_decoder assign target_mi_hot = 1; assign target_mi_enc = 0; assign match = 1'b1; assign target_region = 4'b0000; end endgenerate assign target_secure = \|(target_mi_hot & P_M_SECURE_MASK); assign target_axilite = \|(target_mi_hot & P_M_AXILITE); assign any_error = C_RANGE_CHECK && (m_aerror_i != 0); // DECERR if error-detection enabled and any error condition. assign m_aerror_i[0] = ~match; // Invalid target address assign m_aerror_i[1] = target_secure && S_APROT[P_NONSECURE_BIT]; // TrustZone violation assign m_aerror_i[2] = target_axilite && ((S_ALEN != 0) \|\| (S_ASIZE[1:0] == 2'b11) \|\| (S_ASIZE[2] == 1'b1)); // AxiLite access violation assign m_aerror_i[7:3] = 5'b00000; // Reserved assign M_ATARGET_HOT = m_atarget_hot_i; assign m_atarget_hot_i = (any_error ? {1'b1, {C_NUM_M{1'b0}}} : {1'b0, target_mi_hot}); assign m_atarget_enc_i = (any_error ? C_NUM_M : target_mi_enc); assign M_AVALID = m_avalid_i; assign m_avalid_i = S_AVALID; assign M_AVALID_QUAL = m_avalid_qual_i; assign S_AREADY = s_aready_i; assign s_aready_i = M_AREADY; assign M_AERROR = m_aerror_i; assign M_ATARGET_ENC = m_atarget_enc_i; assign m_aregion_i = any_error ? 4'b0000 : (C_ADDR_DECODE != 0) ? target_region : 4'b0000; // assign m_aregion_i = any_error ? 4'b0000 : (C_ADDR_DECODE != 0) ? target_region : S_AREGION; assign M_AREGION = m_aregion_i; assign M_AID = S_AID; assign M_AADDR = S_AADDR; assign M_ALEN = S_ALEN; assign M_ASIZE = S_ASIZE; assign M_ALOCK = S_ALOCK; assign M_APROT = S_APROT; assign M_AMESG = S_AMESG; assign S_RVALID = s_rvalid_i; assign M_RREADY = m_rready_i; assign s_rid_i = si_rmux_mesg[0+:C_ID_WIDTH]; assign S_RMESG = si_rmux_mesg[C_ID_WIDTH+:C_RMESG_WIDTH]; assign s_rlast_i = si_rmux_mesg[C_ID_WIDTH+C_RMESG_WIDTH+:1]; assign S_RID = s_rid_i; assign S_RLAST = s_rlast_i; assign m_rvalid_qual = M_RVALID & M_RTARGET; assign m_rready_i = m_rready_arb & M_RTARGET; generate for (gen_mi=0; gen_mi<(C_NUM_M+1); gen_mi=gen_mi+1) begin : gen_rmesg_mi // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign mi_rmux_mesg[gen_miP_RMUX_MESG_WIDTH+:P_RMUX_MESG_WIDTH] = { M_RLAST[gen_mi], M_RMESG[gen_miC_RMESG_WIDTH+:C_RMESG_WIDTH], M_RID[gen_miC_ID_WIDTH+:C_ID_WIDTH] }; end // gen_rmesg_mi if (C_ACCEPTANCE == 1) begin : gen_single_issue wire cmd_push; wire cmd_pop; reg [(C_NUM_M+1)-1:0] active_target_hot; reg [P_NUM_M_DE_LOG-1:0] active_target_enc; reg accept_cnt; reg [8-1:0] debug_r_beat_cnt_i; wire [8-1:0] debug_r_trans_seq_i; assign cmd_push = M_AREADY; assign cmd_pop = s_rvalid_i && S_RREADY && s_rlast_i; // Pop command queue if end of read burst assign m_avalid_qual_i = ~accept_cnt \| cmd_pop; // Ready for arbitration if no outstanding transaction or transaction being completed always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 1'b0; active_target_enc <= 0; active_target_hot <= 0; end else begin if (cmd_push) begin active_target_enc <= m_atarget_enc_i; active_target_hot <= m_atarget_hot_i; accept_cnt <= 1'b1; end else if (cmd_pop) begin accept_cnt <= 1'b0; end end end // Clocked process assign m_rready_arb = active_target_hot & {(C_NUM_M+1){S_RREADY}}; assign s_rvalid_i = \|(active_target_hot & m_rvalid_qual); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_single_issue ( .S (active_target_enc), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); if (C_DEBUG) begin : gen_debug_r_single_issue // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i && S_RREADY) begin if (s_rlast_i) begin debug_r_beat_cnt_i <= 0; end else begin debug_r_beat_cnt_i <= debug_r_beat_cnt_i + 1; end end end else begin debug_r_beat_cnt_i <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_single_issue ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push), .S_READY (), .M_MESG (debug_r_trans_seq_i), .M_VALID (), .M_READY (cmd_pop) ); end // gen_debug_r end else if (C_SINGLE_THREAD \|\| (P_NUM_ID_VAL==1)) begin : gen_single_thread wire s_avalid_en; wire cmd_push; wire cmd_pop; reg [C_ID_WIDTH-1:0] active_id; reg [(C_NUM_M+1)-1:0] active_target_hot; reg [P_NUM_M_DE_LOG-1:0] active_target_enc; reg [4-1:0] active_region; reg [(C_ACCEPTANCE_LOG+1)-1:0] accept_cnt; reg [8-1:0] debug_r_beat_cnt_i; wire [8-1:0] debug_r_trans_seq_i; wire accept_limit ; // Implement single-region-per-ID cyclic dependency avoidance method. assign s_avalid_en = // This transaction is qualified to request arbitration if ... (accept_cnt == 0) \|\| // Either there are no outstanding transactions, or ... (((P_NUM_ID_VAL==1) \|\| (S_AID[P_THREAD_ID_WIDTH_M1-1:0] == active_id[P_THREAD_ID_WIDTH_M1-1:0])) && // the current transaction ID matches the previous, and ... (active_target_enc == m_atarget_enc_i) && // all outstanding transactions are to the same target MI ... (active_region == m_aregion_i)); // and to the same REGION. assign cmd_push = M_AREADY; assign cmd_pop = s_rvalid_i && S_RREADY && s_rlast_i; // Pop command queue if end of read burst assign accept_limit = (accept_cnt == C_ACCEPTANCE) & ~cmd_pop; // Allow next push if a transaction is currently being completed assign m_avalid_qual_i = s_avalid_en & ~accept_limit; always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 0; active_id <= 0; active_target_enc <= 0; active_target_hot <= 0; active_region <= 0; end else begin if (cmd_push) begin active_id <= S_AID[P_THREAD_ID_WIDTH_M1-1:0]; active_target_enc <= m_atarget_enc_i; active_target_hot <= m_atarget_hot_i; active_region <= m_aregion_i; if (~cmd_pop) begin accept_cnt <= accept_cnt + 1; end end else begin if (cmd_pop & (accept_cnt != 0)) begin accept_cnt <= accept_cnt - 1; end end end end // Clocked process assign m_rready_arb = active_target_hot & {(C_NUM_M+1){S_RREADY}}; assign s_rvalid_i = \|(active_target_hot & m_rvalid_qual); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_single_thread ( .S (active_target_enc), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); if (C_DEBUG) begin : gen_debug_r_single_thread // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i && S_RREADY) begin if (s_rlast_i) begin debug_r_beat_cnt_i <= 0; end else begin debug_r_beat_cnt_i <= debug_r_beat_cnt_i + 1; end end end else begin debug_r_beat_cnt_i <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_single_thread ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push), .S_READY (), .M_MESG (debug_r_trans_seq_i), .M_VALID (), .M_READY (cmd_pop) ); end // gen_debug_r end else begin : gen_multi_thread wire [(P_NUM_M_DE_LOG)-1:0] resp_select; reg [(C_ACCEPTANCE_LOG+1)-1:0] accept_cnt; wire [P_NUM_THREADS-1:0] s_avalid_en; wire [P_NUM_THREADS-1:0] thread_valid; wire [P_NUM_THREADS-1:0] aid_match; wire [P_NUM_THREADS-1:0] rid_match; wire [P_NUM_THREADS-1:0] cmd_push; wire [P_NUM_THREADS-1:0] cmd_pop; wire [P_NUM_THREADS:0] accum_push; reg [P_NUM_THREADSC_ID_WIDTH-1:0] active_id; reg [P_NUM_THREADS8-1:0] active_target; reg [P_NUM_THREADS8-1:0] active_region; reg [P_NUM_THREADS8-1:0] active_cnt; reg [P_NUM_THREADS8-1:0] debug_r_beat_cnt_i; wire [P_NUM_THREADS8-1:0] debug_r_trans_seq_i; wire any_aid_match; wire any_rid_match; wire accept_limit; wire any_push; wire any_pop; axi_crossbar_v2_1_arbiter_resp # // Multi-thread response arbiter ( .C_FAMILY (C_FAMILY), .C_NUM_S (C_NUM_M+1), .C_NUM_S_LOG (P_NUM_M_DE_LOG), .C_GRANT_ENC (1), .C_GRANT_HOT (0) ) arbiter_resp_inst ( .ACLK (ACLK), .ARESET (ARESET), .S_VALID (m_rvalid_qual), .S_READY (m_rready_arb), .M_GRANT_HOT (), .M_GRANT_ENC (resp_select), .M_VALID (s_rvalid_i), .M_READY (S_RREADY) ); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_multi_thread ( .S (resp_select), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); assign any_push = M_AREADY; assign any_pop = s_rvalid_i & S_RREADY & s_rlast_i; assign accept_limit = (accept_cnt == C_ACCEPTANCE) & ~any_pop; // Allow next push if a transaction is currently being completed assign m_avalid_qual_i = (&s_avalid_en) & ~accept_limit; // The current request is qualified for arbitration when it is qualified against all outstanding transaction threads. assign any_aid_match = \|aid_match; assign any_rid_match = \|rid_match; assign accum_push[0] = 1'b0; always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 0; end else begin if (any_push & ~any_pop) begin accept_cnt <= accept_cnt + 1; end else if (any_pop & ~any_push & (accept_cnt != 0)) begin accept_cnt <= accept_cnt - 1; end end end // Clocked process for (gen_thread=0; gen_thread<P_NUM_THREADS; gen_thread=gen_thread+1) begin : gen_thread_loop assign thread_valid[gen_thread] = (active_cnt[gen_thread8 +: C_ACCEPTANCE_LOG+1] != 0); assign aid_match[gen_thread] = // The currect thread is active for the requested transaction if thread_valid[gen_thread] && // this thread slot is not vacant, and ((S_AID[P_THREAD_ID_WIDTH_M1-1:0]) == active_id[gen_threadC_ID_WIDTH+:P_THREAD_ID_WIDTH_M1]); // the requested ID matches the active ID for this thread. assign s_avalid_en[gen_thread] = // The current request is qualified against this thread slot if (~aid_match[gen_thread]) \|\| // This thread slot is not active for the requested ID, or ((m_atarget_enc_i == active_target[gen_thread8+:P_NUM_M_DE_LOG]) && // this outstanding transaction was to the same target and (m_aregion_i == active_region[gen_thread8+:4])); // to the same region. // cmd_push points to the position of either the active thread for the requested ID or the lowest vacant thread slot. assign accum_push[gen_thread+1] = accum_push[gen_thread] \| ~thread_valid[gen_thread]; assign cmd_push[gen_thread] = any_push & (aid_match[gen_thread] \| ((~any_aid_match) & ~thread_valid[gen_thread] & ~accum_push[gen_thread])); // cmd_pop points to the position of the active thread that matches the current RID. assign rid_match[gen_thread] = thread_valid[gen_thread] & ((s_rid_i[P_THREAD_ID_WIDTH_M1-1:0]) == active_id[gen_threadC_ID_WIDTH+:P_THREAD_ID_WIDTH_M1]); assign cmd_pop[gen_thread] = any_pop & rid_match[gen_thread]; always @(posedge ACLK) begin if (ARESET) begin active_id[gen_threadC_ID_WIDTH+:C_ID_WIDTH] <= 0; active_target[gen_thread8+:8] <= 0; active_region[gen_thread8+:8] <= 0; active_cnt[gen_thread8+:8] <= 0; end else begin if (cmd_push[gen_thread]) begin active_id[gen_threadC_ID_WIDTH+:P_THREAD_ID_WIDTH_M1] <= S_AID[P_THREAD_ID_WIDTH_M1-1:0]; active_target[gen_thread8+:P_NUM_M_DE_LOG] <= m_atarget_enc_i; active_region[gen_thread8+:4] <= m_aregion_i; if (~cmd_pop[gen_thread]) begin active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] <= active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] + 1; end end else if (cmd_pop[gen_thread]) begin active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] <= active_cnt[gen_thread8+:C_ACCEPTANCE_LOG+1] - 1; end end end // Clocked process if (C_DEBUG) begin : gen_debug_r_multi_thread // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i[gen_thread8+:8] <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i & S_RREADY & rid_match[gen_thread]) begin if (s_rlast_i) begin debug_r_beat_cnt_i[gen_thread8+:8] <= 0; end else begin debug_r_beat_cnt_i[gen_thread8+:8] <= debug_r_beat_cnt_i[gen_thread8+:8] + 1; end end end else begin debug_r_beat_cnt_i[gen_thread8+:8] <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_multi_thread ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push[gen_thread]), .S_READY (), .M_MESG (debug_r_trans_seq_i[gen_thread*8+:8]), .M_VALID (), .M_READY (cmd_pop[gen_thread]) ); end // gen_debug_r_multi_thread end // Next gen_thread_loop end // thread control endgenerate endmodule
module processing_system7_bfm_v2_0_5_interconnect_model ( rstn, sw_clk, w_qos_gp0, w_qos_gp1, w_qos_hp0, w_qos_hp1, w_qos_hp2, w_qos_hp3, r_qos_gp0, r_qos_gp1, r_qos_hp0, r_qos_hp1, r_qos_hp2, r_qos_hp3, wr_ack_ddr_gp0, wr_ack_ocm_gp0, wr_data_gp0, wr_addr_gp0, wr_bytes_gp0, wr_dv_ddr_gp0, wr_dv_ocm_gp0, rd_req_ddr_gp0, rd_req_ocm_gp0, rd_req_reg_gp0, rd_addr_gp0, rd_bytes_gp0, rd_data_ddr_gp0, rd_data_ocm_gp0, rd_data_reg_gp0, rd_dv_ddr_gp0, rd_dv_ocm_gp0, rd_dv_reg_gp0, wr_ack_ddr_gp1, wr_ack_ocm_gp1, wr_data_gp1, wr_addr_gp1, wr_bytes_gp1, wr_dv_ddr_gp1, wr_dv_ocm_gp1, rd_req_ddr_gp1, rd_req_ocm_gp1, rd_req_reg_gp1, rd_addr_gp1, rd_bytes_gp1, rd_data_ddr_gp1, rd_data_ocm_gp1, rd_data_reg_gp1, rd_dv_ddr_gp1, rd_dv_ocm_gp1, rd_dv_reg_gp1, wr_ack_ddr_hp0, wr_ack_ocm_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, wr_dv_ocm_hp0, rd_req_ddr_hp0, rd_req_ocm_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_data_ocm_hp0, rd_dv_ddr_hp0, rd_dv_ocm_hp0, wr_ack_ddr_hp1, wr_ack_ocm_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, wr_dv_ocm_hp1, rd_req_ddr_hp1, rd_req_ocm_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_data_ocm_hp1, rd_dv_ddr_hp1, rd_dv_ocm_hp1, wr_ack_ddr_hp2, wr_ack_ocm_hp2, wr_data_hp2, wr_addr_hp2, wr_bytes_hp2, wr_dv_ddr_hp2, wr_dv_ocm_hp2, rd_req_ddr_hp2, rd_req_ocm_hp2, rd_addr_hp2, rd_bytes_hp2, rd_data_ddr_hp2, rd_data_ocm_hp2, rd_dv_ddr_hp2, rd_dv_ocm_hp2, wr_ack_ddr_hp3, wr_ack_ocm_hp3, wr_data_hp3, wr_addr_hp3, wr_bytes_hp3, wr_dv_ddr_hp3, wr_dv_ocm_hp3, rd_req_ddr_hp3, rd_req_ocm_hp3, rd_addr_hp3, rd_bytes_hp3, rd_data_ddr_hp3, rd_data_ocm_hp3, rd_dv_ddr_hp3, rd_dv_ocm_hp3, /* Goes to port 1 of DDR / ddr_wr_ack_port1, ddr_wr_dv_port1, ddr_rd_req_port1, ddr_rd_dv_port1, ddr_wr_addr_port1, ddr_wr_data_port1, ddr_wr_bytes_port1, ddr_rd_addr_port1, ddr_rd_data_port1, ddr_rd_bytes_port1, ddr_wr_qos_port1, ddr_rd_qos_port1, / Goes to port2 of DDR / ddr_wr_ack_port2, ddr_wr_dv_port2, ddr_rd_req_port2, ddr_rd_dv_port2, ddr_wr_addr_port2, ddr_wr_data_port2, ddr_wr_bytes_port2, ddr_rd_addr_port2, ddr_rd_data_port2, ddr_rd_bytes_port2, ddr_wr_qos_port2, ddr_rd_qos_port2, / Goes to port3 of DDR / ddr_wr_ack_port3, ddr_wr_dv_port3, ddr_rd_req_port3, ddr_rd_dv_port3, ddr_wr_addr_port3, ddr_wr_data_port3, ddr_wr_bytes_port3, ddr_rd_addr_port3, ddr_rd_data_port3, ddr_rd_bytes_port3, ddr_wr_qos_port3, ddr_rd_qos_port3, / Goes to port1 of OCM / ocm_wr_qos_port1, ocm_rd_qos_port1, ocm_wr_dv_port1, ocm_wr_data_port1, ocm_wr_addr_port1, ocm_wr_bytes_port1, ocm_wr_ack_port1, ocm_rd_req_port1, ocm_rd_data_port1, ocm_rd_addr_port1, ocm_rd_bytes_port1, ocm_rd_dv_port1, / Goes to port1 for RegMap / reg_rd_qos_port1, reg_rd_req_port1, reg_rd_data_port1, reg_rd_addr_port1, reg_rd_bytes_port1, reg_rd_dv_port1 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; input [axi_qos_width-1:0] w_qos_gp0; input [axi_qos_width-1:0] w_qos_gp1; input [axi_qos_width-1:0] w_qos_hp0; input [axi_qos_width-1:0] w_qos_hp1; input [axi_qos_width-1:0] w_qos_hp2; input [axi_qos_width-1:0] w_qos_hp3; input [axi_qos_width-1:0] r_qos_gp0; input [axi_qos_width-1:0] r_qos_gp1; input [axi_qos_width-1:0] r_qos_hp0; input [axi_qos_width-1:0] r_qos_hp1; input [axi_qos_width-1:0] r_qos_hp2; input [axi_qos_width-1:0] r_qos_hp3; output [axi_qos_width-1:0] ocm_wr_qos_port1; output [axi_qos_width-1:0] ocm_rd_qos_port1; output wr_ack_ddr_gp0; output wr_ack_ocm_gp0; input[max_burst_bits-1:0] wr_data_gp0; input[addr_width-1:0] wr_addr_gp0; input[max_burst_bytes_width:0] wr_bytes_gp0; input wr_dv_ddr_gp0; input wr_dv_ocm_gp0; input rd_req_ddr_gp0; input rd_req_ocm_gp0; input rd_req_reg_gp0; input[addr_width-1:0] rd_addr_gp0; input[max_burst_bytes_width:0] rd_bytes_gp0; output[max_burst_bits-1:0] rd_data_ddr_gp0; output[max_burst_bits-1:0] rd_data_ocm_gp0; output[max_burst_bits-1:0] rd_data_reg_gp0; output rd_dv_ddr_gp0; output rd_dv_ocm_gp0; output rd_dv_reg_gp0; output wr_ack_ddr_gp1; output wr_ack_ocm_gp1; input[max_burst_bits-1:0] wr_data_gp1; input[addr_width-1:0] wr_addr_gp1; input[max_burst_bytes_width:0] wr_bytes_gp1; input wr_dv_ddr_gp1; input wr_dv_ocm_gp1; input rd_req_ddr_gp1; input rd_req_ocm_gp1; input rd_req_reg_gp1; input[addr_width-1:0] rd_addr_gp1; input[max_burst_bytes_width:0] rd_bytes_gp1; output[max_burst_bits-1:0] rd_data_ddr_gp1; output[max_burst_bits-1:0] rd_data_ocm_gp1; output[max_burst_bits-1:0] rd_data_reg_gp1; output rd_dv_ddr_gp1; output rd_dv_ocm_gp1; output rd_dv_reg_gp1; output wr_ack_ddr_hp0; output wr_ack_ocm_hp0; input[max_burst_bits-1:0] wr_data_hp0; input[addr_width-1:0] wr_addr_hp0; input[max_burst_bytes_width:0] wr_bytes_hp0; input wr_dv_ddr_hp0; input wr_dv_ocm_hp0; input rd_req_ddr_hp0; input rd_req_ocm_hp0; input[addr_width-1:0] rd_addr_hp0; input[max_burst_bytes_width:0] rd_bytes_hp0; output[max_burst_bits-1:0] rd_data_ddr_hp0; output[max_burst_bits-1:0] rd_data_ocm_hp0; output rd_dv_ddr_hp0; output rd_dv_ocm_hp0; output wr_ack_ddr_hp1; output wr_ack_ocm_hp1; input[max_burst_bits-1:0] wr_data_hp1; input[addr_width-1:0] wr_addr_hp1; input[max_burst_bytes_width:0] wr_bytes_hp1; input wr_dv_ddr_hp1; input wr_dv_ocm_hp1; input rd_req_ddr_hp1; input rd_req_ocm_hp1; input[addr_width-1:0] rd_addr_hp1; input[max_burst_bytes_width:0] rd_bytes_hp1; output[max_burst_bits-1:0] rd_data_ddr_hp1; output[max_burst_bits-1:0] rd_data_ocm_hp1; output rd_dv_ddr_hp1; output rd_dv_ocm_hp1; output wr_ack_ddr_hp2; output wr_ack_ocm_hp2; input[max_burst_bits-1:0] wr_data_hp2; input[addr_width-1:0] wr_addr_hp2; input[max_burst_bytes_width:0] wr_bytes_hp2; input wr_dv_ddr_hp2; input wr_dv_ocm_hp2; input rd_req_ddr_hp2; input rd_req_ocm_hp2; input[addr_width-1:0] rd_addr_hp2; input[max_burst_bytes_width:0] rd_bytes_hp2; output[max_burst_bits-1:0] rd_data_ddr_hp2; output[max_burst_bits-1:0] rd_data_ocm_hp2; output rd_dv_ddr_hp2; output rd_dv_ocm_hp2; output wr_ack_ddr_hp3; output wr_ack_ocm_hp3; input[max_burst_bits-1:0] wr_data_hp3; input[addr_width-1:0] wr_addr_hp3; input[max_burst_bytes_width:0] wr_bytes_hp3; input wr_dv_ddr_hp3; input wr_dv_ocm_hp3; input rd_req_ddr_hp3; input rd_req_ocm_hp3; input[addr_width-1:0] rd_addr_hp3; input[max_burst_bytes_width:0] rd_bytes_hp3; output[max_burst_bits-1:0] rd_data_ddr_hp3; output[max_burst_bits-1:0] rd_data_ocm_hp3; output rd_dv_ddr_hp3; output rd_dv_ocm_hp3; / Goes to port 1 of DDR / input ddr_wr_ack_port1; output ddr_wr_dv_port1; output ddr_rd_req_port1; input ddr_rd_dv_port1; output[addr_width-1:0] ddr_wr_addr_port1; output[max_burst_bits-1:0] ddr_wr_data_port1; output[max_burst_bytes_width:0] ddr_wr_bytes_port1; output[addr_width-1:0] ddr_rd_addr_port1; input[max_burst_bits-1:0] ddr_rd_data_port1; output[max_burst_bytes_width:0] ddr_rd_bytes_port1; output [axi_qos_width-1:0] ddr_wr_qos_port1; output [axi_qos_width-1:0] ddr_rd_qos_port1; / Goes to port2 of DDR / input ddr_wr_ack_port2; output ddr_wr_dv_port2; output ddr_rd_req_port2; input ddr_rd_dv_port2; output[addr_width-1:0] ddr_wr_addr_port2; output[max_burst_bits-1:0] ddr_wr_data_port2; output[max_burst_bytes_width:0] ddr_wr_bytes_port2; output[addr_width-1:0] ddr_rd_addr_port2; input[max_burst_bits-1:0] ddr_rd_data_port2; output[max_burst_bytes_width:0] ddr_rd_bytes_port2; output [axi_qos_width-1:0] ddr_wr_qos_port2; output [axi_qos_width-1:0] ddr_rd_qos_port2; / Goes to port3 of DDR / input ddr_wr_ack_port3; output ddr_wr_dv_port3; output ddr_rd_req_port3; input ddr_rd_dv_port3; output[addr_width-1:0] ddr_wr_addr_port3; output[max_burst_bits-1:0] ddr_wr_data_port3; output[max_burst_bytes_width:0] ddr_wr_bytes_port3; output[addr_width-1:0] ddr_rd_addr_port3; input[max_burst_bits-1:0] ddr_rd_data_port3; output[max_burst_bytes_width:0] ddr_rd_bytes_port3; output [axi_qos_width-1:0] ddr_wr_qos_port3; output [axi_qos_width-1:0] ddr_rd_qos_port3; / Goes to port1 of OCM / input ocm_wr_ack_port1; output ocm_wr_dv_port1; output ocm_rd_req_port1; input ocm_rd_dv_port1; output[max_burst_bits-1:0] ocm_wr_data_port1; output[addr_width-1:0] ocm_wr_addr_port1; output[max_burst_bytes_width:0] ocm_wr_bytes_port1; input[max_burst_bits-1:0] ocm_rd_data_port1; output[addr_width-1:0] ocm_rd_addr_port1; output[max_burst_bytes_width:0] ocm_rd_bytes_port1; / Goes to port1 of REG */ output [axi_qos_width-1:0] reg_rd_qos_port1; output reg_rd_req_port1; input reg_rd_dv_port1; input[max_burst_bits-1:0] reg_rd_data_port1; output[addr_width-1:0] reg_rd_addr_port1; output[max_burst_bytes_width:0] reg_rd_bytes_port1; wire ocm_wr_dv_osw0; wire ocm_wr_dv_osw1; wire[max_burst_bits-1:0] ocm_wr_data_osw0; wire[max_burst_bits-1:0] ocm_wr_data_osw1; wire[addr_width-1:0] ocm_wr_addr_osw0; wire[addr_width-1:0] ocm_wr_addr_osw1; wire[max_burst_bytes_width:0] ocm_wr_bytes_osw0; wire[max_burst_bytes_width:0] ocm_wr_bytes_osw1; wire ocm_wr_ack_osw0; wire ocm_wr_ack_osw1; wire ocm_rd_req_osw0; wire ocm_rd_req_osw1; wire[max_burst_bits-1:0] ocm_rd_data_osw0; wire[max_burst_bits-1:0] ocm_rd_data_osw1; wire[addr_width-1:0] ocm_rd_addr_osw0; wire[addr_width-1:0] ocm_rd_addr_osw1; wire[max_burst_bytes_width:0] ocm_rd_bytes_osw0; wire[max_burst_bytes_width:0] ocm_rd_bytes_osw1; wire ocm_rd_dv_osw0; wire ocm_rd_dv_osw1; wire [axi_qos_width-1:0] ocm_wr_qos_osw0; wire [axi_qos_width-1:0] ocm_wr_qos_osw1; wire [axi_qos_width-1:0] ocm_rd_qos_osw0; wire [axi_qos_width-1:0] ocm_rd_qos_osw1; processing_system7_bfm_v2_0_5_fmsw_gp fmsw ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_gp0(w_qos_gp0), .r_qos_gp0(r_qos_gp0), .wr_ack_ocm_gp0(wr_ack_ocm_gp0), .wr_ack_ddr_gp0(wr_ack_ddr_gp0), .wr_data_gp0(wr_data_gp0), .wr_addr_gp0(wr_addr_gp0), .wr_bytes_gp0(wr_bytes_gp0), .wr_dv_ocm_gp0(wr_dv_ocm_gp0), .wr_dv_ddr_gp0(wr_dv_ddr_gp0), .rd_req_ocm_gp0(rd_req_ocm_gp0), .rd_req_ddr_gp0(rd_req_ddr_gp0), .rd_req_reg_gp0(rd_req_reg_gp0), .rd_addr_gp0(rd_addr_gp0), .rd_bytes_gp0(rd_bytes_gp0), .rd_data_ddr_gp0(rd_data_ddr_gp0), .rd_data_ocm_gp0(rd_data_ocm_gp0), .rd_data_reg_gp0(rd_data_reg_gp0), .rd_dv_ocm_gp0(rd_dv_ocm_gp0), .rd_dv_ddr_gp0(rd_dv_ddr_gp0), .rd_dv_reg_gp0(rd_dv_reg_gp0), .w_qos_gp1(w_qos_gp1), .r_qos_gp1(r_qos_gp1), .wr_ack_ocm_gp1(wr_ack_ocm_gp1), .wr_ack_ddr_gp1(wr_ack_ddr_gp1), .wr_data_gp1(wr_data_gp1), .wr_addr_gp1(wr_addr_gp1), .wr_bytes_gp1(wr_bytes_gp1), .wr_dv_ocm_gp1(wr_dv_ocm_gp1), .wr_dv_ddr_gp1(wr_dv_ddr_gp1), .rd_req_ocm_gp1(rd_req_ocm_gp1), .rd_req_ddr_gp1(rd_req_ddr_gp1), .rd_req_reg_gp1(rd_req_reg_gp1), .rd_addr_gp1(rd_addr_gp1), .rd_bytes_gp1(rd_bytes_gp1), .rd_data_ddr_gp1(rd_data_ddr_gp1), .rd_data_ocm_gp1(rd_data_ocm_gp1), .rd_data_reg_gp1(rd_data_reg_gp1), .rd_dv_ocm_gp1(rd_dv_ocm_gp1), .rd_dv_ddr_gp1(rd_dv_ddr_gp1), .rd_dv_reg_gp1(rd_dv_reg_gp1), .ocm_wr_ack (ocm_wr_ack_osw0), .ocm_wr_dv (ocm_wr_dv_osw0), .ocm_rd_req (ocm_rd_req_osw0), .ocm_rd_dv (ocm_rd_dv_osw0), .ocm_wr_addr(ocm_wr_addr_osw0), .ocm_wr_data(ocm_wr_data_osw0), .ocm_wr_bytes(ocm_wr_bytes_osw0), .ocm_rd_addr(ocm_rd_addr_osw0), .ocm_rd_data(ocm_rd_data_osw0), .ocm_rd_bytes(ocm_rd_bytes_osw0), .ocm_wr_qos(ocm_wr_qos_osw0), .ocm_rd_qos(ocm_rd_qos_osw0), .ddr_wr_qos(ddr_wr_qos_port1), .ddr_rd_qos(ddr_rd_qos_port1), .reg_rd_qos(reg_rd_qos_port1), .ddr_wr_ack(ddr_wr_ack_port1), .ddr_wr_dv(ddr_wr_dv_port1), .ddr_rd_req(ddr_rd_req_port1), .ddr_rd_dv(ddr_rd_dv_port1), .ddr_wr_addr(ddr_wr_addr_port1), .ddr_wr_data(ddr_wr_data_port1), .ddr_wr_bytes(ddr_wr_bytes_port1), .ddr_rd_addr(ddr_rd_addr_port1), .ddr_rd_data(ddr_rd_data_port1), .ddr_rd_bytes(ddr_rd_bytes_port1), .reg_rd_req(reg_rd_req_port1), .reg_rd_dv(reg_rd_dv_port1), .reg_rd_addr(reg_rd_addr_port1), .reg_rd_data(reg_rd_data_port1), .reg_rd_bytes(reg_rd_bytes_port1) ); processing_system7_bfm_v2_0_5_ssw_hp ssw( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp0(w_qos_hp0), .r_qos_hp0(r_qos_hp0), .w_qos_hp1(w_qos_hp1), .r_qos_hp1(r_qos_hp1), .w_qos_hp2(w_qos_hp2), .r_qos_hp2(r_qos_hp2), .w_qos_hp3(w_qos_hp3), .r_qos_hp3(r_qos_hp3), .wr_ack_ddr_hp0(wr_ack_ddr_hp0), .wr_data_hp0(wr_data_hp0), .wr_addr_hp0(wr_addr_hp0), .wr_bytes_hp0(wr_bytes_hp0), .wr_dv_ddr_hp0(wr_dv_ddr_hp0), .rd_req_ddr_hp0(rd_req_ddr_hp0), .rd_addr_hp0(rd_addr_hp0), .rd_bytes_hp0(rd_bytes_hp0), .rd_data_ddr_hp0(rd_data_ddr_hp0), .rd_data_ocm_hp0(rd_data_ocm_hp0), .rd_dv_ddr_hp0(rd_dv_ddr_hp0), .wr_ack_ocm_hp0(wr_ack_ocm_hp0), .wr_dv_ocm_hp0(wr_dv_ocm_hp0), .rd_req_ocm_hp0(rd_req_ocm_hp0), .rd_dv_ocm_hp0(rd_dv_ocm_hp0), .wr_ack_ddr_hp1(wr_ack_ddr_hp1), .wr_data_hp1(wr_data_hp1), .wr_addr_hp1(wr_addr_hp1), .wr_bytes_hp1(wr_bytes_hp1), .wr_dv_ddr_hp1(wr_dv_ddr_hp1), .rd_req_ddr_hp1(rd_req_ddr_hp1), .rd_addr_hp1(rd_addr_hp1), .rd_bytes_hp1(rd_bytes_hp1), .rd_data_ddr_hp1(rd_data_ddr_hp1), .rd_data_ocm_hp1(rd_data_ocm_hp1), .rd_dv_ddr_hp1(rd_dv_ddr_hp1), .wr_ack_ocm_hp1(wr_ack_ocm_hp1), .wr_dv_ocm_hp1(wr_dv_ocm_hp1), .rd_req_ocm_hp1(rd_req_ocm_hp1), .rd_dv_ocm_hp1(rd_dv_ocm_hp1), .wr_ack_ddr_hp2(wr_ack_ddr_hp2), .wr_data_hp2(wr_data_hp2), .wr_addr_hp2(wr_addr_hp2), .wr_bytes_hp2(wr_bytes_hp2), .wr_dv_ddr_hp2(wr_dv_ddr_hp2), .rd_req_ddr_hp2(rd_req_ddr_hp2), .rd_addr_hp2(rd_addr_hp2), .rd_bytes_hp2(rd_bytes_hp2), .rd_data_ddr_hp2(rd_data_ddr_hp2), .rd_data_ocm_hp2(rd_data_ocm_hp2), .rd_dv_ddr_hp2(rd_dv_ddr_hp2), .wr_ack_ocm_hp2(wr_ack_ocm_hp2), .wr_dv_ocm_hp2(wr_dv_ocm_hp2), .rd_req_ocm_hp2(rd_req_ocm_hp2), .rd_dv_ocm_hp2(rd_dv_ocm_hp2), .wr_ack_ddr_hp3(wr_ack_ddr_hp3), .wr_data_hp3(wr_data_hp3), .wr_addr_hp3(wr_addr_hp3), .wr_bytes_hp3(wr_bytes_hp3), .wr_dv_ddr_hp3(wr_dv_ddr_hp3), .rd_req_ddr_hp3(rd_req_ddr_hp3), .rd_addr_hp3(rd_addr_hp3), .rd_bytes_hp3(rd_bytes_hp3), .rd_data_ddr_hp3(rd_data_ddr_hp3), .rd_data_ocm_hp3(rd_data_ocm_hp3), .rd_dv_ddr_hp3(rd_dv_ddr_hp3), .wr_ack_ocm_hp3(wr_ack_ocm_hp3), .wr_dv_ocm_hp3(wr_dv_ocm_hp3), .rd_req_ocm_hp3(rd_req_ocm_hp3), .rd_dv_ocm_hp3(rd_dv_ocm_hp3), .ddr_wr_ack0(ddr_wr_ack_port2), .ddr_wr_dv0(ddr_wr_dv_port2), .ddr_rd_req0(ddr_rd_req_port2), .ddr_rd_dv0(ddr_rd_dv_port2), .ddr_wr_addr0(ddr_wr_addr_port2), .ddr_wr_data0(ddr_wr_data_port2), .ddr_wr_bytes0(ddr_wr_bytes_port2), .ddr_rd_addr0(ddr_rd_addr_port2), .ddr_rd_data0(ddr_rd_data_port2), .ddr_rd_bytes0(ddr_rd_bytes_port2), .ddr_wr_qos0(ddr_wr_qos_port2), .ddr_rd_qos0(ddr_rd_qos_port2), .ddr_wr_ack1(ddr_wr_ack_port3), .ddr_wr_dv1(ddr_wr_dv_port3), .ddr_rd_req1(ddr_rd_req_port3), .ddr_rd_dv1(ddr_rd_dv_port3), .ddr_wr_addr1(ddr_wr_addr_port3), .ddr_wr_data1(ddr_wr_data_port3), .ddr_wr_bytes1(ddr_wr_bytes_port3), .ddr_rd_addr1(ddr_rd_addr_port3), .ddr_rd_data1(ddr_rd_data_port3), .ddr_rd_bytes1(ddr_rd_bytes_port3), .ddr_wr_qos1(ddr_wr_qos_port3), .ddr_rd_qos1(ddr_rd_qos_port3), .ocm_wr_qos(ocm_wr_qos_osw1), .ocm_rd_qos(ocm_rd_qos_osw1), .ocm_wr_ack (ocm_wr_ack_osw1), .ocm_wr_dv (ocm_wr_dv_osw1), .ocm_rd_req (ocm_rd_req_osw1), .ocm_rd_dv (ocm_rd_dv_osw1), .ocm_wr_addr(ocm_wr_addr_osw1), .ocm_wr_data(ocm_wr_data_osw1), .ocm_wr_bytes(ocm_wr_bytes_osw1), .ocm_rd_addr(ocm_rd_addr_osw1), .ocm_rd_data(ocm_rd_data_osw1), .ocm_rd_bytes(ocm_rd_bytes_osw1) ); processing_system7_bfm_v2_0_5_arb_wr osw_wr ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_wr_qos_osw0), /// chk .qos2(ocm_wr_qos_osw1), /// chk .prt_dv1(ocm_wr_dv_osw0), .prt_dv2(ocm_wr_dv_osw1), .prt_data1(ocm_wr_data_osw0), .prt_data2(ocm_wr_data_osw1), .prt_addr1(ocm_wr_addr_osw0), .prt_addr2(ocm_wr_addr_osw1), .prt_bytes1(ocm_wr_bytes_osw0), .prt_bytes2(ocm_wr_bytes_osw1), .prt_ack1(ocm_wr_ack_osw0), .prt_ack2(ocm_wr_ack_osw1), .prt_req(ocm_wr_dv_port1), .prt_qos(ocm_wr_qos_port1), .prt_data(ocm_wr_data_port1), .prt_addr(ocm_wr_addr_port1), .prt_bytes(ocm_wr_bytes_port1), .prt_ack(ocm_wr_ack_port1) ); processing_system7_bfm_v2_0_5_arb_rd osw_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_rd_qos_osw0), // chk .qos2(ocm_rd_qos_osw1), // chk .prt_req1(ocm_rd_req_osw0), .prt_req2(ocm_rd_req_osw1), .prt_data1(ocm_rd_data_osw0), .prt_data2(ocm_rd_data_osw1), .prt_addr1(ocm_rd_addr_osw0), .prt_addr2(ocm_rd_addr_osw1), .prt_bytes1(ocm_rd_bytes_osw0), .prt_bytes2(ocm_rd_bytes_osw1), .prt_dv1(ocm_rd_dv_osw0), .prt_dv2(ocm_rd_dv_osw1), .prt_req(ocm_rd_req_port1), .prt_qos(ocm_rd_qos_port1), .prt_data(ocm_rd_data_port1), .prt_addr(ocm_rd_addr_port1), .prt_bytes(ocm_rd_bytes_port1), .prt_dv(ocm_rd_dv_port1) ); endmodule
module processing_system7_bfm_v2_0_5_interconnect_model ( rstn, sw_clk, w_qos_gp0, w_qos_gp1, w_qos_hp0, w_qos_hp1, w_qos_hp2, w_qos_hp3, r_qos_gp0, r_qos_gp1, r_qos_hp0, r_qos_hp1, r_qos_hp2, r_qos_hp3, wr_ack_ddr_gp0, wr_ack_ocm_gp0, wr_data_gp0, wr_addr_gp0, wr_bytes_gp0, wr_dv_ddr_gp0, wr_dv_ocm_gp0, rd_req_ddr_gp0, rd_req_ocm_gp0, rd_req_reg_gp0, rd_addr_gp0, rd_bytes_gp0, rd_data_ddr_gp0, rd_data_ocm_gp0, rd_data_reg_gp0, rd_dv_ddr_gp0, rd_dv_ocm_gp0, rd_dv_reg_gp0, wr_ack_ddr_gp1, wr_ack_ocm_gp1, wr_data_gp1, wr_addr_gp1, wr_bytes_gp1, wr_dv_ddr_gp1, wr_dv_ocm_gp1, rd_req_ddr_gp1, rd_req_ocm_gp1, rd_req_reg_gp1, rd_addr_gp1, rd_bytes_gp1, rd_data_ddr_gp1, rd_data_ocm_gp1, rd_data_reg_gp1, rd_dv_ddr_gp1, rd_dv_ocm_gp1, rd_dv_reg_gp1, wr_ack_ddr_hp0, wr_ack_ocm_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, wr_dv_ocm_hp0, rd_req_ddr_hp0, rd_req_ocm_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_data_ocm_hp0, rd_dv_ddr_hp0, rd_dv_ocm_hp0, wr_ack_ddr_hp1, wr_ack_ocm_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, wr_dv_ocm_hp1, rd_req_ddr_hp1, rd_req_ocm_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_data_ocm_hp1, rd_dv_ddr_hp1, rd_dv_ocm_hp1, wr_ack_ddr_hp2, wr_ack_ocm_hp2, wr_data_hp2, wr_addr_hp2, wr_bytes_hp2, wr_dv_ddr_hp2, wr_dv_ocm_hp2, rd_req_ddr_hp2, rd_req_ocm_hp2, rd_addr_hp2, rd_bytes_hp2, rd_data_ddr_hp2, rd_data_ocm_hp2, rd_dv_ddr_hp2, rd_dv_ocm_hp2, wr_ack_ddr_hp3, wr_ack_ocm_hp3, wr_data_hp3, wr_addr_hp3, wr_bytes_hp3, wr_dv_ddr_hp3, wr_dv_ocm_hp3, rd_req_ddr_hp3, rd_req_ocm_hp3, rd_addr_hp3, rd_bytes_hp3, rd_data_ddr_hp3, rd_data_ocm_hp3, rd_dv_ddr_hp3, rd_dv_ocm_hp3, /* Goes to port 1 of DDR / ddr_wr_ack_port1, ddr_wr_dv_port1, ddr_rd_req_port1, ddr_rd_dv_port1, ddr_wr_addr_port1, ddr_wr_data_port1, ddr_wr_bytes_port1, ddr_rd_addr_port1, ddr_rd_data_port1, ddr_rd_bytes_port1, ddr_wr_qos_port1, ddr_rd_qos_port1, / Goes to port2 of DDR / ddr_wr_ack_port2, ddr_wr_dv_port2, ddr_rd_req_port2, ddr_rd_dv_port2, ddr_wr_addr_port2, ddr_wr_data_port2, ddr_wr_bytes_port2, ddr_rd_addr_port2, ddr_rd_data_port2, ddr_rd_bytes_port2, ddr_wr_qos_port2, ddr_rd_qos_port2, / Goes to port3 of DDR / ddr_wr_ack_port3, ddr_wr_dv_port3, ddr_rd_req_port3, ddr_rd_dv_port3, ddr_wr_addr_port3, ddr_wr_data_port3, ddr_wr_bytes_port3, ddr_rd_addr_port3, ddr_rd_data_port3, ddr_rd_bytes_port3, ddr_wr_qos_port3, ddr_rd_qos_port3, / Goes to port1 of OCM / ocm_wr_qos_port1, ocm_rd_qos_port1, ocm_wr_dv_port1, ocm_wr_data_port1, ocm_wr_addr_port1, ocm_wr_bytes_port1, ocm_wr_ack_port1, ocm_rd_req_port1, ocm_rd_data_port1, ocm_rd_addr_port1, ocm_rd_bytes_port1, ocm_rd_dv_port1, / Goes to port1 for RegMap / reg_rd_qos_port1, reg_rd_req_port1, reg_rd_data_port1, reg_rd_addr_port1, reg_rd_bytes_port1, reg_rd_dv_port1 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; input [axi_qos_width-1:0] w_qos_gp0; input [axi_qos_width-1:0] w_qos_gp1; input [axi_qos_width-1:0] w_qos_hp0; input [axi_qos_width-1:0] w_qos_hp1; input [axi_qos_width-1:0] w_qos_hp2; input [axi_qos_width-1:0] w_qos_hp3; input [axi_qos_width-1:0] r_qos_gp0; input [axi_qos_width-1:0] r_qos_gp1; input [axi_qos_width-1:0] r_qos_hp0; input [axi_qos_width-1:0] r_qos_hp1; input [axi_qos_width-1:0] r_qos_hp2; input [axi_qos_width-1:0] r_qos_hp3; output [axi_qos_width-1:0] ocm_wr_qos_port1; output [axi_qos_width-1:0] ocm_rd_qos_port1; output wr_ack_ddr_gp0; output wr_ack_ocm_gp0; input[max_burst_bits-1:0] wr_data_gp0; input[addr_width-1:0] wr_addr_gp0; input[max_burst_bytes_width:0] wr_bytes_gp0; input wr_dv_ddr_gp0; input wr_dv_ocm_gp0; input rd_req_ddr_gp0; input rd_req_ocm_gp0; input rd_req_reg_gp0; input[addr_width-1:0] rd_addr_gp0; input[max_burst_bytes_width:0] rd_bytes_gp0; output[max_burst_bits-1:0] rd_data_ddr_gp0; output[max_burst_bits-1:0] rd_data_ocm_gp0; output[max_burst_bits-1:0] rd_data_reg_gp0; output rd_dv_ddr_gp0; output rd_dv_ocm_gp0; output rd_dv_reg_gp0; output wr_ack_ddr_gp1; output wr_ack_ocm_gp1; input[max_burst_bits-1:0] wr_data_gp1; input[addr_width-1:0] wr_addr_gp1; input[max_burst_bytes_width:0] wr_bytes_gp1; input wr_dv_ddr_gp1; input wr_dv_ocm_gp1; input rd_req_ddr_gp1; input rd_req_ocm_gp1; input rd_req_reg_gp1; input[addr_width-1:0] rd_addr_gp1; input[max_burst_bytes_width:0] rd_bytes_gp1; output[max_burst_bits-1:0] rd_data_ddr_gp1; output[max_burst_bits-1:0] rd_data_ocm_gp1; output[max_burst_bits-1:0] rd_data_reg_gp1; output rd_dv_ddr_gp1; output rd_dv_ocm_gp1; output rd_dv_reg_gp1; output wr_ack_ddr_hp0; output wr_ack_ocm_hp0; input[max_burst_bits-1:0] wr_data_hp0; input[addr_width-1:0] wr_addr_hp0; input[max_burst_bytes_width:0] wr_bytes_hp0; input wr_dv_ddr_hp0; input wr_dv_ocm_hp0; input rd_req_ddr_hp0; input rd_req_ocm_hp0; input[addr_width-1:0] rd_addr_hp0; input[max_burst_bytes_width:0] rd_bytes_hp0; output[max_burst_bits-1:0] rd_data_ddr_hp0; output[max_burst_bits-1:0] rd_data_ocm_hp0; output rd_dv_ddr_hp0; output rd_dv_ocm_hp0; output wr_ack_ddr_hp1; output wr_ack_ocm_hp1; input[max_burst_bits-1:0] wr_data_hp1; input[addr_width-1:0] wr_addr_hp1; input[max_burst_bytes_width:0] wr_bytes_hp1; input wr_dv_ddr_hp1; input wr_dv_ocm_hp1; input rd_req_ddr_hp1; input rd_req_ocm_hp1; input[addr_width-1:0] rd_addr_hp1; input[max_burst_bytes_width:0] rd_bytes_hp1; output[max_burst_bits-1:0] rd_data_ddr_hp1; output[max_burst_bits-1:0] rd_data_ocm_hp1; output rd_dv_ddr_hp1; output rd_dv_ocm_hp1; output wr_ack_ddr_hp2; output wr_ack_ocm_hp2; input[max_burst_bits-1:0] wr_data_hp2; input[addr_width-1:0] wr_addr_hp2; input[max_burst_bytes_width:0] wr_bytes_hp2; input wr_dv_ddr_hp2; input wr_dv_ocm_hp2; input rd_req_ddr_hp2; input rd_req_ocm_hp2; input[addr_width-1:0] rd_addr_hp2; input[max_burst_bytes_width:0] rd_bytes_hp2; output[max_burst_bits-1:0] rd_data_ddr_hp2; output[max_burst_bits-1:0] rd_data_ocm_hp2; output rd_dv_ddr_hp2; output rd_dv_ocm_hp2; output wr_ack_ddr_hp3; output wr_ack_ocm_hp3; input[max_burst_bits-1:0] wr_data_hp3; input[addr_width-1:0] wr_addr_hp3; input[max_burst_bytes_width:0] wr_bytes_hp3; input wr_dv_ddr_hp3; input wr_dv_ocm_hp3; input rd_req_ddr_hp3; input rd_req_ocm_hp3; input[addr_width-1:0] rd_addr_hp3; input[max_burst_bytes_width:0] rd_bytes_hp3; output[max_burst_bits-1:0] rd_data_ddr_hp3; output[max_burst_bits-1:0] rd_data_ocm_hp3; output rd_dv_ddr_hp3; output rd_dv_ocm_hp3; / Goes to port 1 of DDR / input ddr_wr_ack_port1; output ddr_wr_dv_port1; output ddr_rd_req_port1; input ddr_rd_dv_port1; output[addr_width-1:0] ddr_wr_addr_port1; output[max_burst_bits-1:0] ddr_wr_data_port1; output[max_burst_bytes_width:0] ddr_wr_bytes_port1; output[addr_width-1:0] ddr_rd_addr_port1; input[max_burst_bits-1:0] ddr_rd_data_port1; output[max_burst_bytes_width:0] ddr_rd_bytes_port1; output [axi_qos_width-1:0] ddr_wr_qos_port1; output [axi_qos_width-1:0] ddr_rd_qos_port1; / Goes to port2 of DDR / input ddr_wr_ack_port2; output ddr_wr_dv_port2; output ddr_rd_req_port2; input ddr_rd_dv_port2; output[addr_width-1:0] ddr_wr_addr_port2; output[max_burst_bits-1:0] ddr_wr_data_port2; output[max_burst_bytes_width:0] ddr_wr_bytes_port2; output[addr_width-1:0] ddr_rd_addr_port2; input[max_burst_bits-1:0] ddr_rd_data_port2; output[max_burst_bytes_width:0] ddr_rd_bytes_port2; output [axi_qos_width-1:0] ddr_wr_qos_port2; output [axi_qos_width-1:0] ddr_rd_qos_port2; / Goes to port3 of DDR / input ddr_wr_ack_port3; output ddr_wr_dv_port3; output ddr_rd_req_port3; input ddr_rd_dv_port3; output[addr_width-1:0] ddr_wr_addr_port3; output[max_burst_bits-1:0] ddr_wr_data_port3; output[max_burst_bytes_width:0] ddr_wr_bytes_port3; output[addr_width-1:0] ddr_rd_addr_port3; input[max_burst_bits-1:0] ddr_rd_data_port3; output[max_burst_bytes_width:0] ddr_rd_bytes_port3; output [axi_qos_width-1:0] ddr_wr_qos_port3; output [axi_qos_width-1:0] ddr_rd_qos_port3; / Goes to port1 of OCM / input ocm_wr_ack_port1; output ocm_wr_dv_port1; output ocm_rd_req_port1; input ocm_rd_dv_port1; output[max_burst_bits-1:0] ocm_wr_data_port1; output[addr_width-1:0] ocm_wr_addr_port1; output[max_burst_bytes_width:0] ocm_wr_bytes_port1; input[max_burst_bits-1:0] ocm_rd_data_port1; output[addr_width-1:0] ocm_rd_addr_port1; output[max_burst_bytes_width:0] ocm_rd_bytes_port1; / Goes to port1 of REG */ output [axi_qos_width-1:0] reg_rd_qos_port1; output reg_rd_req_port1; input reg_rd_dv_port1; input[max_burst_bits-1:0] reg_rd_data_port1; output[addr_width-1:0] reg_rd_addr_port1; output[max_burst_bytes_width:0] reg_rd_bytes_port1; wire ocm_wr_dv_osw0; wire ocm_wr_dv_osw1; wire[max_burst_bits-1:0] ocm_wr_data_osw0; wire[max_burst_bits-1:0] ocm_wr_data_osw1; wire[addr_width-1:0] ocm_wr_addr_osw0; wire[addr_width-1:0] ocm_wr_addr_osw1; wire[max_burst_bytes_width:0] ocm_wr_bytes_osw0; wire[max_burst_bytes_width:0] ocm_wr_bytes_osw1; wire ocm_wr_ack_osw0; wire ocm_wr_ack_osw1; wire ocm_rd_req_osw0; wire ocm_rd_req_osw1; wire[max_burst_bits-1:0] ocm_rd_data_osw0; wire[max_burst_bits-1:0] ocm_rd_data_osw1; wire[addr_width-1:0] ocm_rd_addr_osw0; wire[addr_width-1:0] ocm_rd_addr_osw1; wire[max_burst_bytes_width:0] ocm_rd_bytes_osw0; wire[max_burst_bytes_width:0] ocm_rd_bytes_osw1; wire ocm_rd_dv_osw0; wire ocm_rd_dv_osw1; wire [axi_qos_width-1:0] ocm_wr_qos_osw0; wire [axi_qos_width-1:0] ocm_wr_qos_osw1; wire [axi_qos_width-1:0] ocm_rd_qos_osw0; wire [axi_qos_width-1:0] ocm_rd_qos_osw1; processing_system7_bfm_v2_0_5_fmsw_gp fmsw ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_gp0(w_qos_gp0), .r_qos_gp0(r_qos_gp0), .wr_ack_ocm_gp0(wr_ack_ocm_gp0), .wr_ack_ddr_gp0(wr_ack_ddr_gp0), .wr_data_gp0(wr_data_gp0), .wr_addr_gp0(wr_addr_gp0), .wr_bytes_gp0(wr_bytes_gp0), .wr_dv_ocm_gp0(wr_dv_ocm_gp0), .wr_dv_ddr_gp0(wr_dv_ddr_gp0), .rd_req_ocm_gp0(rd_req_ocm_gp0), .rd_req_ddr_gp0(rd_req_ddr_gp0), .rd_req_reg_gp0(rd_req_reg_gp0), .rd_addr_gp0(rd_addr_gp0), .rd_bytes_gp0(rd_bytes_gp0), .rd_data_ddr_gp0(rd_data_ddr_gp0), .rd_data_ocm_gp0(rd_data_ocm_gp0), .rd_data_reg_gp0(rd_data_reg_gp0), .rd_dv_ocm_gp0(rd_dv_ocm_gp0), .rd_dv_ddr_gp0(rd_dv_ddr_gp0), .rd_dv_reg_gp0(rd_dv_reg_gp0), .w_qos_gp1(w_qos_gp1), .r_qos_gp1(r_qos_gp1), .wr_ack_ocm_gp1(wr_ack_ocm_gp1), .wr_ack_ddr_gp1(wr_ack_ddr_gp1), .wr_data_gp1(wr_data_gp1), .wr_addr_gp1(wr_addr_gp1), .wr_bytes_gp1(wr_bytes_gp1), .wr_dv_ocm_gp1(wr_dv_ocm_gp1), .wr_dv_ddr_gp1(wr_dv_ddr_gp1), .rd_req_ocm_gp1(rd_req_ocm_gp1), .rd_req_ddr_gp1(rd_req_ddr_gp1), .rd_req_reg_gp1(rd_req_reg_gp1), .rd_addr_gp1(rd_addr_gp1), .rd_bytes_gp1(rd_bytes_gp1), .rd_data_ddr_gp1(rd_data_ddr_gp1), .rd_data_ocm_gp1(rd_data_ocm_gp1), .rd_data_reg_gp1(rd_data_reg_gp1), .rd_dv_ocm_gp1(rd_dv_ocm_gp1), .rd_dv_ddr_gp1(rd_dv_ddr_gp1), .rd_dv_reg_gp1(rd_dv_reg_gp1), .ocm_wr_ack (ocm_wr_ack_osw0), .ocm_wr_dv (ocm_wr_dv_osw0), .ocm_rd_req (ocm_rd_req_osw0), .ocm_rd_dv (ocm_rd_dv_osw0), .ocm_wr_addr(ocm_wr_addr_osw0), .ocm_wr_data(ocm_wr_data_osw0), .ocm_wr_bytes(ocm_wr_bytes_osw0), .ocm_rd_addr(ocm_rd_addr_osw0), .ocm_rd_data(ocm_rd_data_osw0), .ocm_rd_bytes(ocm_rd_bytes_osw0), .ocm_wr_qos(ocm_wr_qos_osw0), .ocm_rd_qos(ocm_rd_qos_osw0), .ddr_wr_qos(ddr_wr_qos_port1), .ddr_rd_qos(ddr_rd_qos_port1), .reg_rd_qos(reg_rd_qos_port1), .ddr_wr_ack(ddr_wr_ack_port1), .ddr_wr_dv(ddr_wr_dv_port1), .ddr_rd_req(ddr_rd_req_port1), .ddr_rd_dv(ddr_rd_dv_port1), .ddr_wr_addr(ddr_wr_addr_port1), .ddr_wr_data(ddr_wr_data_port1), .ddr_wr_bytes(ddr_wr_bytes_port1), .ddr_rd_addr(ddr_rd_addr_port1), .ddr_rd_data(ddr_rd_data_port1), .ddr_rd_bytes(ddr_rd_bytes_port1), .reg_rd_req(reg_rd_req_port1), .reg_rd_dv(reg_rd_dv_port1), .reg_rd_addr(reg_rd_addr_port1), .reg_rd_data(reg_rd_data_port1), .reg_rd_bytes(reg_rd_bytes_port1) ); processing_system7_bfm_v2_0_5_ssw_hp ssw( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp0(w_qos_hp0), .r_qos_hp0(r_qos_hp0), .w_qos_hp1(w_qos_hp1), .r_qos_hp1(r_qos_hp1), .w_qos_hp2(w_qos_hp2), .r_qos_hp2(r_qos_hp2), .w_qos_hp3(w_qos_hp3), .r_qos_hp3(r_qos_hp3), .wr_ack_ddr_hp0(wr_ack_ddr_hp0), .wr_data_hp0(wr_data_hp0), .wr_addr_hp0(wr_addr_hp0), .wr_bytes_hp0(wr_bytes_hp0), .wr_dv_ddr_hp0(wr_dv_ddr_hp0), .rd_req_ddr_hp0(rd_req_ddr_hp0), .rd_addr_hp0(rd_addr_hp0), .rd_bytes_hp0(rd_bytes_hp0), .rd_data_ddr_hp0(rd_data_ddr_hp0), .rd_data_ocm_hp0(rd_data_ocm_hp0), .rd_dv_ddr_hp0(rd_dv_ddr_hp0), .wr_ack_ocm_hp0(wr_ack_ocm_hp0), .wr_dv_ocm_hp0(wr_dv_ocm_hp0), .rd_req_ocm_hp0(rd_req_ocm_hp0), .rd_dv_ocm_hp0(rd_dv_ocm_hp0), .wr_ack_ddr_hp1(wr_ack_ddr_hp1), .wr_data_hp1(wr_data_hp1), .wr_addr_hp1(wr_addr_hp1), .wr_bytes_hp1(wr_bytes_hp1), .wr_dv_ddr_hp1(wr_dv_ddr_hp1), .rd_req_ddr_hp1(rd_req_ddr_hp1), .rd_addr_hp1(rd_addr_hp1), .rd_bytes_hp1(rd_bytes_hp1), .rd_data_ddr_hp1(rd_data_ddr_hp1), .rd_data_ocm_hp1(rd_data_ocm_hp1), .rd_dv_ddr_hp1(rd_dv_ddr_hp1), .wr_ack_ocm_hp1(wr_ack_ocm_hp1), .wr_dv_ocm_hp1(wr_dv_ocm_hp1), .rd_req_ocm_hp1(rd_req_ocm_hp1), .rd_dv_ocm_hp1(rd_dv_ocm_hp1), .wr_ack_ddr_hp2(wr_ack_ddr_hp2), .wr_data_hp2(wr_data_hp2), .wr_addr_hp2(wr_addr_hp2), .wr_bytes_hp2(wr_bytes_hp2), .wr_dv_ddr_hp2(wr_dv_ddr_hp2), .rd_req_ddr_hp2(rd_req_ddr_hp2), .rd_addr_hp2(rd_addr_hp2), .rd_bytes_hp2(rd_bytes_hp2), .rd_data_ddr_hp2(rd_data_ddr_hp2), .rd_data_ocm_hp2(rd_data_ocm_hp2), .rd_dv_ddr_hp2(rd_dv_ddr_hp2), .wr_ack_ocm_hp2(wr_ack_ocm_hp2), .wr_dv_ocm_hp2(wr_dv_ocm_hp2), .rd_req_ocm_hp2(rd_req_ocm_hp2), .rd_dv_ocm_hp2(rd_dv_ocm_hp2), .wr_ack_ddr_hp3(wr_ack_ddr_hp3), .wr_data_hp3(wr_data_hp3), .wr_addr_hp3(wr_addr_hp3), .wr_bytes_hp3(wr_bytes_hp3), .wr_dv_ddr_hp3(wr_dv_ddr_hp3), .rd_req_ddr_hp3(rd_req_ddr_hp3), .rd_addr_hp3(rd_addr_hp3), .rd_bytes_hp3(rd_bytes_hp3), .rd_data_ddr_hp3(rd_data_ddr_hp3), .rd_data_ocm_hp3(rd_data_ocm_hp3), .rd_dv_ddr_hp3(rd_dv_ddr_hp3), .wr_ack_ocm_hp3(wr_ack_ocm_hp3), .wr_dv_ocm_hp3(wr_dv_ocm_hp3), .rd_req_ocm_hp3(rd_req_ocm_hp3), .rd_dv_ocm_hp3(rd_dv_ocm_hp3), .ddr_wr_ack0(ddr_wr_ack_port2), .ddr_wr_dv0(ddr_wr_dv_port2), .ddr_rd_req0(ddr_rd_req_port2), .ddr_rd_dv0(ddr_rd_dv_port2), .ddr_wr_addr0(ddr_wr_addr_port2), .ddr_wr_data0(ddr_wr_data_port2), .ddr_wr_bytes0(ddr_wr_bytes_port2), .ddr_rd_addr0(ddr_rd_addr_port2), .ddr_rd_data0(ddr_rd_data_port2), .ddr_rd_bytes0(ddr_rd_bytes_port2), .ddr_wr_qos0(ddr_wr_qos_port2), .ddr_rd_qos0(ddr_rd_qos_port2), .ddr_wr_ack1(ddr_wr_ack_port3), .ddr_wr_dv1(ddr_wr_dv_port3), .ddr_rd_req1(ddr_rd_req_port3), .ddr_rd_dv1(ddr_rd_dv_port3), .ddr_wr_addr1(ddr_wr_addr_port3), .ddr_wr_data1(ddr_wr_data_port3), .ddr_wr_bytes1(ddr_wr_bytes_port3), .ddr_rd_addr1(ddr_rd_addr_port3), .ddr_rd_data1(ddr_rd_data_port3), .ddr_rd_bytes1(ddr_rd_bytes_port3), .ddr_wr_qos1(ddr_wr_qos_port3), .ddr_rd_qos1(ddr_rd_qos_port3), .ocm_wr_qos(ocm_wr_qos_osw1), .ocm_rd_qos(ocm_rd_qos_osw1), .ocm_wr_ack (ocm_wr_ack_osw1), .ocm_wr_dv (ocm_wr_dv_osw1), .ocm_rd_req (ocm_rd_req_osw1), .ocm_rd_dv (ocm_rd_dv_osw1), .ocm_wr_addr(ocm_wr_addr_osw1), .ocm_wr_data(ocm_wr_data_osw1), .ocm_wr_bytes(ocm_wr_bytes_osw1), .ocm_rd_addr(ocm_rd_addr_osw1), .ocm_rd_data(ocm_rd_data_osw1), .ocm_rd_bytes(ocm_rd_bytes_osw1) ); processing_system7_bfm_v2_0_5_arb_wr osw_wr ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_wr_qos_osw0), /// chk .qos2(ocm_wr_qos_osw1), /// chk .prt_dv1(ocm_wr_dv_osw0), .prt_dv2(ocm_wr_dv_osw1), .prt_data1(ocm_wr_data_osw0), .prt_data2(ocm_wr_data_osw1), .prt_addr1(ocm_wr_addr_osw0), .prt_addr2(ocm_wr_addr_osw1), .prt_bytes1(ocm_wr_bytes_osw0), .prt_bytes2(ocm_wr_bytes_osw1), .prt_ack1(ocm_wr_ack_osw0), .prt_ack2(ocm_wr_ack_osw1), .prt_req(ocm_wr_dv_port1), .prt_qos(ocm_wr_qos_port1), .prt_data(ocm_wr_data_port1), .prt_addr(ocm_wr_addr_port1), .prt_bytes(ocm_wr_bytes_port1), .prt_ack(ocm_wr_ack_port1) ); processing_system7_bfm_v2_0_5_arb_rd osw_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_rd_qos_osw0), // chk .qos2(ocm_rd_qos_osw1), // chk .prt_req1(ocm_rd_req_osw0), .prt_req2(ocm_rd_req_osw1), .prt_data1(ocm_rd_data_osw0), .prt_data2(ocm_rd_data_osw1), .prt_addr1(ocm_rd_addr_osw0), .prt_addr2(ocm_rd_addr_osw1), .prt_bytes1(ocm_rd_bytes_osw0), .prt_bytes2(ocm_rd_bytes_osw1), .prt_dv1(ocm_rd_dv_osw0), .prt_dv2(ocm_rd_dv_osw1), .prt_req(ocm_rd_req_port1), .prt_qos(ocm_rd_qos_port1), .prt_data(ocm_rd_data_port1), .prt_addr(ocm_rd_addr_port1), .prt_bytes(ocm_rd_bytes_port1), .prt_dv(ocm_rd_dv_port1) ); endmodule
module processing_system7_bfm_v2_0_5_interconnect_model ( rstn, sw_clk, w_qos_gp0, w_qos_gp1, w_qos_hp0, w_qos_hp1, w_qos_hp2, w_qos_hp3, r_qos_gp0, r_qos_gp1, r_qos_hp0, r_qos_hp1, r_qos_hp2, r_qos_hp3, wr_ack_ddr_gp0, wr_ack_ocm_gp0, wr_data_gp0, wr_addr_gp0, wr_bytes_gp0, wr_dv_ddr_gp0, wr_dv_ocm_gp0, rd_req_ddr_gp0, rd_req_ocm_gp0, rd_req_reg_gp0, rd_addr_gp0, rd_bytes_gp0, rd_data_ddr_gp0, rd_data_ocm_gp0, rd_data_reg_gp0, rd_dv_ddr_gp0, rd_dv_ocm_gp0, rd_dv_reg_gp0, wr_ack_ddr_gp1, wr_ack_ocm_gp1, wr_data_gp1, wr_addr_gp1, wr_bytes_gp1, wr_dv_ddr_gp1, wr_dv_ocm_gp1, rd_req_ddr_gp1, rd_req_ocm_gp1, rd_req_reg_gp1, rd_addr_gp1, rd_bytes_gp1, rd_data_ddr_gp1, rd_data_ocm_gp1, rd_data_reg_gp1, rd_dv_ddr_gp1, rd_dv_ocm_gp1, rd_dv_reg_gp1, wr_ack_ddr_hp0, wr_ack_ocm_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, wr_dv_ocm_hp0, rd_req_ddr_hp0, rd_req_ocm_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_data_ocm_hp0, rd_dv_ddr_hp0, rd_dv_ocm_hp0, wr_ack_ddr_hp1, wr_ack_ocm_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, wr_dv_ocm_hp1, rd_req_ddr_hp1, rd_req_ocm_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_data_ocm_hp1, rd_dv_ddr_hp1, rd_dv_ocm_hp1, wr_ack_ddr_hp2, wr_ack_ocm_hp2, wr_data_hp2, wr_addr_hp2, wr_bytes_hp2, wr_dv_ddr_hp2, wr_dv_ocm_hp2, rd_req_ddr_hp2, rd_req_ocm_hp2, rd_addr_hp2, rd_bytes_hp2, rd_data_ddr_hp2, rd_data_ocm_hp2, rd_dv_ddr_hp2, rd_dv_ocm_hp2, wr_ack_ddr_hp3, wr_ack_ocm_hp3, wr_data_hp3, wr_addr_hp3, wr_bytes_hp3, wr_dv_ddr_hp3, wr_dv_ocm_hp3, rd_req_ddr_hp3, rd_req_ocm_hp3, rd_addr_hp3, rd_bytes_hp3, rd_data_ddr_hp3, rd_data_ocm_hp3, rd_dv_ddr_hp3, rd_dv_ocm_hp3, /* Goes to port 1 of DDR / ddr_wr_ack_port1, ddr_wr_dv_port1, ddr_rd_req_port1, ddr_rd_dv_port1, ddr_wr_addr_port1, ddr_wr_data_port1, ddr_wr_bytes_port1, ddr_rd_addr_port1, ddr_rd_data_port1, ddr_rd_bytes_port1, ddr_wr_qos_port1, ddr_rd_qos_port1, / Goes to port2 of DDR / ddr_wr_ack_port2, ddr_wr_dv_port2, ddr_rd_req_port2, ddr_rd_dv_port2, ddr_wr_addr_port2, ddr_wr_data_port2, ddr_wr_bytes_port2, ddr_rd_addr_port2, ddr_rd_data_port2, ddr_rd_bytes_port2, ddr_wr_qos_port2, ddr_rd_qos_port2, / Goes to port3 of DDR / ddr_wr_ack_port3, ddr_wr_dv_port3, ddr_rd_req_port3, ddr_rd_dv_port3, ddr_wr_addr_port3, ddr_wr_data_port3, ddr_wr_bytes_port3, ddr_rd_addr_port3, ddr_rd_data_port3, ddr_rd_bytes_port3, ddr_wr_qos_port3, ddr_rd_qos_port3, / Goes to port1 of OCM / ocm_wr_qos_port1, ocm_rd_qos_port1, ocm_wr_dv_port1, ocm_wr_data_port1, ocm_wr_addr_port1, ocm_wr_bytes_port1, ocm_wr_ack_port1, ocm_rd_req_port1, ocm_rd_data_port1, ocm_rd_addr_port1, ocm_rd_bytes_port1, ocm_rd_dv_port1, / Goes to port1 for RegMap / reg_rd_qos_port1, reg_rd_req_port1, reg_rd_data_port1, reg_rd_addr_port1, reg_rd_bytes_port1, reg_rd_dv_port1 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; input [axi_qos_width-1:0] w_qos_gp0; input [axi_qos_width-1:0] w_qos_gp1; input [axi_qos_width-1:0] w_qos_hp0; input [axi_qos_width-1:0] w_qos_hp1; input [axi_qos_width-1:0] w_qos_hp2; input [axi_qos_width-1:0] w_qos_hp3; input [axi_qos_width-1:0] r_qos_gp0; input [axi_qos_width-1:0] r_qos_gp1; input [axi_qos_width-1:0] r_qos_hp0; input [axi_qos_width-1:0] r_qos_hp1; input [axi_qos_width-1:0] r_qos_hp2; input [axi_qos_width-1:0] r_qos_hp3; output [axi_qos_width-1:0] ocm_wr_qos_port1; output [axi_qos_width-1:0] ocm_rd_qos_port1; output wr_ack_ddr_gp0; output wr_ack_ocm_gp0; input[max_burst_bits-1:0] wr_data_gp0; input[addr_width-1:0] wr_addr_gp0; input[max_burst_bytes_width:0] wr_bytes_gp0; input wr_dv_ddr_gp0; input wr_dv_ocm_gp0; input rd_req_ddr_gp0; input rd_req_ocm_gp0; input rd_req_reg_gp0; input[addr_width-1:0] rd_addr_gp0; input[max_burst_bytes_width:0] rd_bytes_gp0; output[max_burst_bits-1:0] rd_data_ddr_gp0; output[max_burst_bits-1:0] rd_data_ocm_gp0; output[max_burst_bits-1:0] rd_data_reg_gp0; output rd_dv_ddr_gp0; output rd_dv_ocm_gp0; output rd_dv_reg_gp0; output wr_ack_ddr_gp1; output wr_ack_ocm_gp1; input[max_burst_bits-1:0] wr_data_gp1; input[addr_width-1:0] wr_addr_gp1; input[max_burst_bytes_width:0] wr_bytes_gp1; input wr_dv_ddr_gp1; input wr_dv_ocm_gp1; input rd_req_ddr_gp1; input rd_req_ocm_gp1; input rd_req_reg_gp1; input[addr_width-1:0] rd_addr_gp1; input[max_burst_bytes_width:0] rd_bytes_gp1; output[max_burst_bits-1:0] rd_data_ddr_gp1; output[max_burst_bits-1:0] rd_data_ocm_gp1; output[max_burst_bits-1:0] rd_data_reg_gp1; output rd_dv_ddr_gp1; output rd_dv_ocm_gp1; output rd_dv_reg_gp1; output wr_ack_ddr_hp0; output wr_ack_ocm_hp0; input[max_burst_bits-1:0] wr_data_hp0; input[addr_width-1:0] wr_addr_hp0; input[max_burst_bytes_width:0] wr_bytes_hp0; input wr_dv_ddr_hp0; input wr_dv_ocm_hp0; input rd_req_ddr_hp0; input rd_req_ocm_hp0; input[addr_width-1:0] rd_addr_hp0; input[max_burst_bytes_width:0] rd_bytes_hp0; output[max_burst_bits-1:0] rd_data_ddr_hp0; output[max_burst_bits-1:0] rd_data_ocm_hp0; output rd_dv_ddr_hp0; output rd_dv_ocm_hp0; output wr_ack_ddr_hp1; output wr_ack_ocm_hp1; input[max_burst_bits-1:0] wr_data_hp1; input[addr_width-1:0] wr_addr_hp1; input[max_burst_bytes_width:0] wr_bytes_hp1; input wr_dv_ddr_hp1; input wr_dv_ocm_hp1; input rd_req_ddr_hp1; input rd_req_ocm_hp1; input[addr_width-1:0] rd_addr_hp1; input[max_burst_bytes_width:0] rd_bytes_hp1; output[max_burst_bits-1:0] rd_data_ddr_hp1; output[max_burst_bits-1:0] rd_data_ocm_hp1; output rd_dv_ddr_hp1; output rd_dv_ocm_hp1; output wr_ack_ddr_hp2; output wr_ack_ocm_hp2; input[max_burst_bits-1:0] wr_data_hp2; input[addr_width-1:0] wr_addr_hp2; input[max_burst_bytes_width:0] wr_bytes_hp2; input wr_dv_ddr_hp2; input wr_dv_ocm_hp2; input rd_req_ddr_hp2; input rd_req_ocm_hp2; input[addr_width-1:0] rd_addr_hp2; input[max_burst_bytes_width:0] rd_bytes_hp2; output[max_burst_bits-1:0] rd_data_ddr_hp2; output[max_burst_bits-1:0] rd_data_ocm_hp2; output rd_dv_ddr_hp2; output rd_dv_ocm_hp2; output wr_ack_ddr_hp3; output wr_ack_ocm_hp3; input[max_burst_bits-1:0] wr_data_hp3; input[addr_width-1:0] wr_addr_hp3; input[max_burst_bytes_width:0] wr_bytes_hp3; input wr_dv_ddr_hp3; input wr_dv_ocm_hp3; input rd_req_ddr_hp3; input rd_req_ocm_hp3; input[addr_width-1:0] rd_addr_hp3; input[max_burst_bytes_width:0] rd_bytes_hp3; output[max_burst_bits-1:0] rd_data_ddr_hp3; output[max_burst_bits-1:0] rd_data_ocm_hp3; output rd_dv_ddr_hp3; output rd_dv_ocm_hp3; / Goes to port 1 of DDR / input ddr_wr_ack_port1; output ddr_wr_dv_port1; output ddr_rd_req_port1; input ddr_rd_dv_port1; output[addr_width-1:0] ddr_wr_addr_port1; output[max_burst_bits-1:0] ddr_wr_data_port1; output[max_burst_bytes_width:0] ddr_wr_bytes_port1; output[addr_width-1:0] ddr_rd_addr_port1; input[max_burst_bits-1:0] ddr_rd_data_port1; output[max_burst_bytes_width:0] ddr_rd_bytes_port1; output [axi_qos_width-1:0] ddr_wr_qos_port1; output [axi_qos_width-1:0] ddr_rd_qos_port1; / Goes to port2 of DDR / input ddr_wr_ack_port2; output ddr_wr_dv_port2; output ddr_rd_req_port2; input ddr_rd_dv_port2; output[addr_width-1:0] ddr_wr_addr_port2; output[max_burst_bits-1:0] ddr_wr_data_port2; output[max_burst_bytes_width:0] ddr_wr_bytes_port2; output[addr_width-1:0] ddr_rd_addr_port2; input[max_burst_bits-1:0] ddr_rd_data_port2; output[max_burst_bytes_width:0] ddr_rd_bytes_port2; output [axi_qos_width-1:0] ddr_wr_qos_port2; output [axi_qos_width-1:0] ddr_rd_qos_port2; / Goes to port3 of DDR / input ddr_wr_ack_port3; output ddr_wr_dv_port3; output ddr_rd_req_port3; input ddr_rd_dv_port3; output[addr_width-1:0] ddr_wr_addr_port3; output[max_burst_bits-1:0] ddr_wr_data_port3; output[max_burst_bytes_width:0] ddr_wr_bytes_port3; output[addr_width-1:0] ddr_rd_addr_port3; input[max_burst_bits-1:0] ddr_rd_data_port3; output[max_burst_bytes_width:0] ddr_rd_bytes_port3; output [axi_qos_width-1:0] ddr_wr_qos_port3; output [axi_qos_width-1:0] ddr_rd_qos_port3; / Goes to port1 of OCM / input ocm_wr_ack_port1; output ocm_wr_dv_port1; output ocm_rd_req_port1; input ocm_rd_dv_port1; output[max_burst_bits-1:0] ocm_wr_data_port1; output[addr_width-1:0] ocm_wr_addr_port1; output[max_burst_bytes_width:0] ocm_wr_bytes_port1; input[max_burst_bits-1:0] ocm_rd_data_port1; output[addr_width-1:0] ocm_rd_addr_port1; output[max_burst_bytes_width:0] ocm_rd_bytes_port1; / Goes to port1 of REG */ output [axi_qos_width-1:0] reg_rd_qos_port1; output reg_rd_req_port1; input reg_rd_dv_port1; input[max_burst_bits-1:0] reg_rd_data_port1; output[addr_width-1:0] reg_rd_addr_port1; output[max_burst_bytes_width:0] reg_rd_bytes_port1; wire ocm_wr_dv_osw0; wire ocm_wr_dv_osw1; wire[max_burst_bits-1:0] ocm_wr_data_osw0; wire[max_burst_bits-1:0] ocm_wr_data_osw1; wire[addr_width-1:0] ocm_wr_addr_osw0; wire[addr_width-1:0] ocm_wr_addr_osw1; wire[max_burst_bytes_width:0] ocm_wr_bytes_osw0; wire[max_burst_bytes_width:0] ocm_wr_bytes_osw1; wire ocm_wr_ack_osw0; wire ocm_wr_ack_osw1; wire ocm_rd_req_osw0; wire ocm_rd_req_osw1; wire[max_burst_bits-1:0] ocm_rd_data_osw0; wire[max_burst_bits-1:0] ocm_rd_data_osw1; wire[addr_width-1:0] ocm_rd_addr_osw0; wire[addr_width-1:0] ocm_rd_addr_osw1; wire[max_burst_bytes_width:0] ocm_rd_bytes_osw0; wire[max_burst_bytes_width:0] ocm_rd_bytes_osw1; wire ocm_rd_dv_osw0; wire ocm_rd_dv_osw1; wire [axi_qos_width-1:0] ocm_wr_qos_osw0; wire [axi_qos_width-1:0] ocm_wr_qos_osw1; wire [axi_qos_width-1:0] ocm_rd_qos_osw0; wire [axi_qos_width-1:0] ocm_rd_qos_osw1; processing_system7_bfm_v2_0_5_fmsw_gp fmsw ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_gp0(w_qos_gp0), .r_qos_gp0(r_qos_gp0), .wr_ack_ocm_gp0(wr_ack_ocm_gp0), .wr_ack_ddr_gp0(wr_ack_ddr_gp0), .wr_data_gp0(wr_data_gp0), .wr_addr_gp0(wr_addr_gp0), .wr_bytes_gp0(wr_bytes_gp0), .wr_dv_ocm_gp0(wr_dv_ocm_gp0), .wr_dv_ddr_gp0(wr_dv_ddr_gp0), .rd_req_ocm_gp0(rd_req_ocm_gp0), .rd_req_ddr_gp0(rd_req_ddr_gp0), .rd_req_reg_gp0(rd_req_reg_gp0), .rd_addr_gp0(rd_addr_gp0), .rd_bytes_gp0(rd_bytes_gp0), .rd_data_ddr_gp0(rd_data_ddr_gp0), .rd_data_ocm_gp0(rd_data_ocm_gp0), .rd_data_reg_gp0(rd_data_reg_gp0), .rd_dv_ocm_gp0(rd_dv_ocm_gp0), .rd_dv_ddr_gp0(rd_dv_ddr_gp0), .rd_dv_reg_gp0(rd_dv_reg_gp0), .w_qos_gp1(w_qos_gp1), .r_qos_gp1(r_qos_gp1), .wr_ack_ocm_gp1(wr_ack_ocm_gp1), .wr_ack_ddr_gp1(wr_ack_ddr_gp1), .wr_data_gp1(wr_data_gp1), .wr_addr_gp1(wr_addr_gp1), .wr_bytes_gp1(wr_bytes_gp1), .wr_dv_ocm_gp1(wr_dv_ocm_gp1), .wr_dv_ddr_gp1(wr_dv_ddr_gp1), .rd_req_ocm_gp1(rd_req_ocm_gp1), .rd_req_ddr_gp1(rd_req_ddr_gp1), .rd_req_reg_gp1(rd_req_reg_gp1), .rd_addr_gp1(rd_addr_gp1), .rd_bytes_gp1(rd_bytes_gp1), .rd_data_ddr_gp1(rd_data_ddr_gp1), .rd_data_ocm_gp1(rd_data_ocm_gp1), .rd_data_reg_gp1(rd_data_reg_gp1), .rd_dv_ocm_gp1(rd_dv_ocm_gp1), .rd_dv_ddr_gp1(rd_dv_ddr_gp1), .rd_dv_reg_gp1(rd_dv_reg_gp1), .ocm_wr_ack (ocm_wr_ack_osw0), .ocm_wr_dv (ocm_wr_dv_osw0), .ocm_rd_req (ocm_rd_req_osw0), .ocm_rd_dv (ocm_rd_dv_osw0), .ocm_wr_addr(ocm_wr_addr_osw0), .ocm_wr_data(ocm_wr_data_osw0), .ocm_wr_bytes(ocm_wr_bytes_osw0), .ocm_rd_addr(ocm_rd_addr_osw0), .ocm_rd_data(ocm_rd_data_osw0), .ocm_rd_bytes(ocm_rd_bytes_osw0), .ocm_wr_qos(ocm_wr_qos_osw0), .ocm_rd_qos(ocm_rd_qos_osw0), .ddr_wr_qos(ddr_wr_qos_port1), .ddr_rd_qos(ddr_rd_qos_port1), .reg_rd_qos(reg_rd_qos_port1), .ddr_wr_ack(ddr_wr_ack_port1), .ddr_wr_dv(ddr_wr_dv_port1), .ddr_rd_req(ddr_rd_req_port1), .ddr_rd_dv(ddr_rd_dv_port1), .ddr_wr_addr(ddr_wr_addr_port1), .ddr_wr_data(ddr_wr_data_port1), .ddr_wr_bytes(ddr_wr_bytes_port1), .ddr_rd_addr(ddr_rd_addr_port1), .ddr_rd_data(ddr_rd_data_port1), .ddr_rd_bytes(ddr_rd_bytes_port1), .reg_rd_req(reg_rd_req_port1), .reg_rd_dv(reg_rd_dv_port1), .reg_rd_addr(reg_rd_addr_port1), .reg_rd_data(reg_rd_data_port1), .reg_rd_bytes(reg_rd_bytes_port1) ); processing_system7_bfm_v2_0_5_ssw_hp ssw( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp0(w_qos_hp0), .r_qos_hp0(r_qos_hp0), .w_qos_hp1(w_qos_hp1), .r_qos_hp1(r_qos_hp1), .w_qos_hp2(w_qos_hp2), .r_qos_hp2(r_qos_hp2), .w_qos_hp3(w_qos_hp3), .r_qos_hp3(r_qos_hp3), .wr_ack_ddr_hp0(wr_ack_ddr_hp0), .wr_data_hp0(wr_data_hp0), .wr_addr_hp0(wr_addr_hp0), .wr_bytes_hp0(wr_bytes_hp0), .wr_dv_ddr_hp0(wr_dv_ddr_hp0), .rd_req_ddr_hp0(rd_req_ddr_hp0), .rd_addr_hp0(rd_addr_hp0), .rd_bytes_hp0(rd_bytes_hp0), .rd_data_ddr_hp0(rd_data_ddr_hp0), .rd_data_ocm_hp0(rd_data_ocm_hp0), .rd_dv_ddr_hp0(rd_dv_ddr_hp0), .wr_ack_ocm_hp0(wr_ack_ocm_hp0), .wr_dv_ocm_hp0(wr_dv_ocm_hp0), .rd_req_ocm_hp0(rd_req_ocm_hp0), .rd_dv_ocm_hp0(rd_dv_ocm_hp0), .wr_ack_ddr_hp1(wr_ack_ddr_hp1), .wr_data_hp1(wr_data_hp1), .wr_addr_hp1(wr_addr_hp1), .wr_bytes_hp1(wr_bytes_hp1), .wr_dv_ddr_hp1(wr_dv_ddr_hp1), .rd_req_ddr_hp1(rd_req_ddr_hp1), .rd_addr_hp1(rd_addr_hp1), .rd_bytes_hp1(rd_bytes_hp1), .rd_data_ddr_hp1(rd_data_ddr_hp1), .rd_data_ocm_hp1(rd_data_ocm_hp1), .rd_dv_ddr_hp1(rd_dv_ddr_hp1), .wr_ack_ocm_hp1(wr_ack_ocm_hp1), .wr_dv_ocm_hp1(wr_dv_ocm_hp1), .rd_req_ocm_hp1(rd_req_ocm_hp1), .rd_dv_ocm_hp1(rd_dv_ocm_hp1), .wr_ack_ddr_hp2(wr_ack_ddr_hp2), .wr_data_hp2(wr_data_hp2), .wr_addr_hp2(wr_addr_hp2), .wr_bytes_hp2(wr_bytes_hp2), .wr_dv_ddr_hp2(wr_dv_ddr_hp2), .rd_req_ddr_hp2(rd_req_ddr_hp2), .rd_addr_hp2(rd_addr_hp2), .rd_bytes_hp2(rd_bytes_hp2), .rd_data_ddr_hp2(rd_data_ddr_hp2), .rd_data_ocm_hp2(rd_data_ocm_hp2), .rd_dv_ddr_hp2(rd_dv_ddr_hp2), .wr_ack_ocm_hp2(wr_ack_ocm_hp2), .wr_dv_ocm_hp2(wr_dv_ocm_hp2), .rd_req_ocm_hp2(rd_req_ocm_hp2), .rd_dv_ocm_hp2(rd_dv_ocm_hp2), .wr_ack_ddr_hp3(wr_ack_ddr_hp3), .wr_data_hp3(wr_data_hp3), .wr_addr_hp3(wr_addr_hp3), .wr_bytes_hp3(wr_bytes_hp3), .wr_dv_ddr_hp3(wr_dv_ddr_hp3), .rd_req_ddr_hp3(rd_req_ddr_hp3), .rd_addr_hp3(rd_addr_hp3), .rd_bytes_hp3(rd_bytes_hp3), .rd_data_ddr_hp3(rd_data_ddr_hp3), .rd_data_ocm_hp3(rd_data_ocm_hp3), .rd_dv_ddr_hp3(rd_dv_ddr_hp3), .wr_ack_ocm_hp3(wr_ack_ocm_hp3), .wr_dv_ocm_hp3(wr_dv_ocm_hp3), .rd_req_ocm_hp3(rd_req_ocm_hp3), .rd_dv_ocm_hp3(rd_dv_ocm_hp3), .ddr_wr_ack0(ddr_wr_ack_port2), .ddr_wr_dv0(ddr_wr_dv_port2), .ddr_rd_req0(ddr_rd_req_port2), .ddr_rd_dv0(ddr_rd_dv_port2), .ddr_wr_addr0(ddr_wr_addr_port2), .ddr_wr_data0(ddr_wr_data_port2), .ddr_wr_bytes0(ddr_wr_bytes_port2), .ddr_rd_addr0(ddr_rd_addr_port2), .ddr_rd_data0(ddr_rd_data_port2), .ddr_rd_bytes0(ddr_rd_bytes_port2), .ddr_wr_qos0(ddr_wr_qos_port2), .ddr_rd_qos0(ddr_rd_qos_port2), .ddr_wr_ack1(ddr_wr_ack_port3), .ddr_wr_dv1(ddr_wr_dv_port3), .ddr_rd_req1(ddr_rd_req_port3), .ddr_rd_dv1(ddr_rd_dv_port3), .ddr_wr_addr1(ddr_wr_addr_port3), .ddr_wr_data1(ddr_wr_data_port3), .ddr_wr_bytes1(ddr_wr_bytes_port3), .ddr_rd_addr1(ddr_rd_addr_port3), .ddr_rd_data1(ddr_rd_data_port3), .ddr_rd_bytes1(ddr_rd_bytes_port3), .ddr_wr_qos1(ddr_wr_qos_port3), .ddr_rd_qos1(ddr_rd_qos_port3), .ocm_wr_qos(ocm_wr_qos_osw1), .ocm_rd_qos(ocm_rd_qos_osw1), .ocm_wr_ack (ocm_wr_ack_osw1), .ocm_wr_dv (ocm_wr_dv_osw1), .ocm_rd_req (ocm_rd_req_osw1), .ocm_rd_dv (ocm_rd_dv_osw1), .ocm_wr_addr(ocm_wr_addr_osw1), .ocm_wr_data(ocm_wr_data_osw1), .ocm_wr_bytes(ocm_wr_bytes_osw1), .ocm_rd_addr(ocm_rd_addr_osw1), .ocm_rd_data(ocm_rd_data_osw1), .ocm_rd_bytes(ocm_rd_bytes_osw1) ); processing_system7_bfm_v2_0_5_arb_wr osw_wr ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_wr_qos_osw0), /// chk .qos2(ocm_wr_qos_osw1), /// chk .prt_dv1(ocm_wr_dv_osw0), .prt_dv2(ocm_wr_dv_osw1), .prt_data1(ocm_wr_data_osw0), .prt_data2(ocm_wr_data_osw1), .prt_addr1(ocm_wr_addr_osw0), .prt_addr2(ocm_wr_addr_osw1), .prt_bytes1(ocm_wr_bytes_osw0), .prt_bytes2(ocm_wr_bytes_osw1), .prt_ack1(ocm_wr_ack_osw0), .prt_ack2(ocm_wr_ack_osw1), .prt_req(ocm_wr_dv_port1), .prt_qos(ocm_wr_qos_port1), .prt_data(ocm_wr_data_port1), .prt_addr(ocm_wr_addr_port1), .prt_bytes(ocm_wr_bytes_port1), .prt_ack(ocm_wr_ack_port1) ); processing_system7_bfm_v2_0_5_arb_rd osw_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_rd_qos_osw0), // chk .qos2(ocm_rd_qos_osw1), // chk .prt_req1(ocm_rd_req_osw0), .prt_req2(ocm_rd_req_osw1), .prt_data1(ocm_rd_data_osw0), .prt_data2(ocm_rd_data_osw1), .prt_addr1(ocm_rd_addr_osw0), .prt_addr2(ocm_rd_addr_osw1), .prt_bytes1(ocm_rd_bytes_osw0), .prt_bytes2(ocm_rd_bytes_osw1), .prt_dv1(ocm_rd_dv_osw0), .prt_dv2(ocm_rd_dv_osw1), .prt_req(ocm_rd_req_port1), .prt_qos(ocm_rd_qos_port1), .prt_data(ocm_rd_data_port1), .prt_addr(ocm_rd_addr_port1), .prt_bytes(ocm_rd_bytes_port1), .prt_dv(ocm_rd_dv_port1) ); endmodule
module processing_system7_bfm_v2_0_5_arb_wr_4( rstn, sw_clk, qos1, qos2, qos3, qos4, prt_dv1, prt_dv2, prt_dv3, prt_dv4, prt_data1, prt_data2, prt_data3, prt_data4, prt_addr1, prt_addr2, prt_addr3, prt_addr4, prt_bytes1, prt_bytes2, prt_bytes3, prt_bytes4, prt_ack1, prt_ack2, prt_ack3, prt_ack4, prt_qos, prt_req, prt_data, prt_addr, prt_bytes, prt_ack ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2,qos3,qos4; input [max_burst_bits-1:0] prt_data1,prt_data2,prt_data3,prt_data4; input [addr_width-1:0] prt_addr1,prt_addr2,prt_addr3,prt_addr4; input [max_burst_bytes_width:0] prt_bytes1,prt_bytes2,prt_bytes3,prt_bytes4; input prt_dv1, prt_dv2,prt_dv3, prt_dv4, prt_ack; output reg prt_ack1,prt_ack2,prt_ack3,prt_ack4,prt_req; output reg [max_burst_bits-1:0] prt_data; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; output reg [axi_qos_width-1:0] prt_qos; parameter wait_req = 3'b000, serv_req1 = 3'b001, serv_req2 = 3'b010, serv_req3 = 3'b011, serv_req4 = 4'b100,wait_ack_low = 3'b101; reg [2:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; prt_req = 0; if(prt_dv1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_dv2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_dv4) begin prt_req = 1; prt_qos = qos4; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; state = serv_req4; end end serv_req1:begin state = serv_req1; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; if(prt_ack)begin prt_ack1 = 1'b1; //state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv2) begin state = serv_req2; prt_qos = qos2; prt_req = 1; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_dv4) begin prt_req = 1; prt_qos = qos4; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; state = serv_req4; end end end serv_req2:begin state = serv_req2; prt_ack1 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; if(prt_ack)begin prt_ack2 = 1'b1; //state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv3) begin state = serv_req3; prt_qos = qos3; prt_req = 1; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_dv4) begin state = serv_req4; prt_req = 1; prt_qos = qos4; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_dv1) begin prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req3:begin state = serv_req3; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack4 = 1'b0; if(prt_ack)begin prt_ack3 = 1'b1; // state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv4) begin state = serv_req4; prt_qos = qos4; prt_req = 1; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_dv1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_dv2) begin prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end end end serv_req4:begin state = serv_req4; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; if(prt_ack)begin prt_ack4 = 1'b1; //state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_dv2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv3) begin prt_req = 1; prt_qos = qos3; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; state = serv_req3; end end end wait_ack_low:begin state = wait_ack_low; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; if(!prt_ack) state = wait_req; end endcase end /// if else end /// always endmodule
module processing_system7_bfm_v2_0_5_arb_wr_4( rstn, sw_clk, qos1, qos2, qos3, qos4, prt_dv1, prt_dv2, prt_dv3, prt_dv4, prt_data1, prt_data2, prt_data3, prt_data4, prt_addr1, prt_addr2, prt_addr3, prt_addr4, prt_bytes1, prt_bytes2, prt_bytes3, prt_bytes4, prt_ack1, prt_ack2, prt_ack3, prt_ack4, prt_qos, prt_req, prt_data, prt_addr, prt_bytes, prt_ack ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2,qos3,qos4; input [max_burst_bits-1:0] prt_data1,prt_data2,prt_data3,prt_data4; input [addr_width-1:0] prt_addr1,prt_addr2,prt_addr3,prt_addr4; input [max_burst_bytes_width:0] prt_bytes1,prt_bytes2,prt_bytes3,prt_bytes4; input prt_dv1, prt_dv2,prt_dv3, prt_dv4, prt_ack; output reg prt_ack1,prt_ack2,prt_ack3,prt_ack4,prt_req; output reg [max_burst_bits-1:0] prt_data; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; output reg [axi_qos_width-1:0] prt_qos; parameter wait_req = 3'b000, serv_req1 = 3'b001, serv_req2 = 3'b010, serv_req3 = 3'b011, serv_req4 = 4'b100,wait_ack_low = 3'b101; reg [2:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; prt_req = 0; if(prt_dv1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_dv2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_dv4) begin prt_req = 1; prt_qos = qos4; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; state = serv_req4; end end serv_req1:begin state = serv_req1; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; if(prt_ack)begin prt_ack1 = 1'b1; //state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv2) begin state = serv_req2; prt_qos = qos2; prt_req = 1; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_dv4) begin prt_req = 1; prt_qos = qos4; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; state = serv_req4; end end end serv_req2:begin state = serv_req2; prt_ack1 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; if(prt_ack)begin prt_ack2 = 1'b1; //state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv3) begin state = serv_req3; prt_qos = qos3; prt_req = 1; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_dv4) begin state = serv_req4; prt_req = 1; prt_qos = qos4; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_dv1) begin prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req3:begin state = serv_req3; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack4 = 1'b0; if(prt_ack)begin prt_ack3 = 1'b1; // state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv4) begin state = serv_req4; prt_qos = qos4; prt_req = 1; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_dv1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_dv2) begin prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end end end serv_req4:begin state = serv_req4; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; if(prt_ack)begin prt_ack4 = 1'b1; //state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_dv2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv3) begin prt_req = 1; prt_qos = qos3; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; state = serv_req3; end end end wait_ack_low:begin state = wait_ack_low; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; if(!prt_ack) state = wait_req; end endcase end /// if else end /// always endmodule
module processing_system7_bfm_v2_0_5_gen_reset( por_rst_n, sys_rst_n, rst_out_n, m_axi_gp0_clk, m_axi_gp1_clk, s_axi_gp0_clk, s_axi_gp1_clk, s_axi_hp0_clk, s_axi_hp1_clk, s_axi_hp2_clk, s_axi_hp3_clk, s_axi_acp_clk, m_axi_gp0_rstn, m_axi_gp1_rstn, s_axi_gp0_rstn, s_axi_gp1_rstn, s_axi_hp0_rstn, s_axi_hp1_rstn, s_axi_hp2_rstn, s_axi_hp3_rstn, s_axi_acp_rstn, fclk_reset3_n, fclk_reset2_n, fclk_reset1_n, fclk_reset0_n, fpga_acp_reset_n, fpga_gp_m0_reset_n, fpga_gp_m1_reset_n, fpga_gp_s0_reset_n, fpga_gp_s1_reset_n, fpga_hp_s0_reset_n, fpga_hp_s1_reset_n, fpga_hp_s2_reset_n, fpga_hp_s3_reset_n ); input por_rst_n; input sys_rst_n; input m_axi_gp0_clk; input m_axi_gp1_clk; input s_axi_gp0_clk; input s_axi_gp1_clk; input s_axi_hp0_clk; input s_axi_hp1_clk; input s_axi_hp2_clk; input s_axi_hp3_clk; input s_axi_acp_clk; output reg m_axi_gp0_rstn; output reg m_axi_gp1_rstn; output reg s_axi_gp0_rstn; output reg s_axi_gp1_rstn; output reg s_axi_hp0_rstn; output reg s_axi_hp1_rstn; output reg s_axi_hp2_rstn; output reg s_axi_hp3_rstn; output reg s_axi_acp_rstn; output rst_out_n; output fclk_reset3_n; output fclk_reset2_n; output fclk_reset1_n; output fclk_reset0_n; output fpga_acp_reset_n; output fpga_gp_m0_reset_n; output fpga_gp_m1_reset_n; output fpga_gp_s0_reset_n; output fpga_gp_s1_reset_n; output fpga_hp_s0_reset_n; output fpga_hp_s1_reset_n; output fpga_hp_s2_reset_n; output fpga_hp_s3_reset_n; reg [31:0] fabric_rst_n; reg r_m_axi_gp0_rstn; reg r_m_axi_gp1_rstn; reg r_s_axi_gp0_rstn; reg r_s_axi_gp1_rstn; reg r_s_axi_hp0_rstn; reg r_s_axi_hp1_rstn; reg r_s_axi_hp2_rstn; reg r_s_axi_hp3_rstn; reg r_s_axi_acp_rstn; assign rst_out_n = por_rst_n & sys_rst_n; assign fclk_reset0_n = !fabric_rst_n[0]; assign fclk_reset1_n = !fabric_rst_n[1]; assign fclk_reset2_n = !fabric_rst_n[2]; assign fclk_reset3_n = !fabric_rst_n[3]; assign fpga_acp_reset_n = !fabric_rst_n[24]; assign fpga_hp_s3_reset_n = !fabric_rst_n[23]; assign fpga_hp_s2_reset_n = !fabric_rst_n[22]; assign fpga_hp_s1_reset_n = !fabric_rst_n[21]; assign fpga_hp_s0_reset_n = !fabric_rst_n[20]; assign fpga_gp_s1_reset_n = !fabric_rst_n[17]; assign fpga_gp_s0_reset_n = !fabric_rst_n[16]; assign fpga_gp_m1_reset_n = !fabric_rst_n[13]; assign fpga_gp_m0_reset_n = !fabric_rst_n[12]; task fpga_soft_reset; input[31:0] reset_ctrl; begin fabric_rst_n[0] = reset_ctrl[0]; fabric_rst_n[1] = reset_ctrl[1]; fabric_rst_n[2] = reset_ctrl[2]; fabric_rst_n[3] = reset_ctrl[3]; fabric_rst_n[12] = reset_ctrl[12]; fabric_rst_n[13] = reset_ctrl[13]; fabric_rst_n[16] = reset_ctrl[16]; fabric_rst_n[17] = reset_ctrl[17]; fabric_rst_n[20] = reset_ctrl[20]; fabric_rst_n[21] = reset_ctrl[21]; fabric_rst_n[22] = reset_ctrl[22]; fabric_rst_n[23] = reset_ctrl[23]; fabric_rst_n[24] = reset_ctrl[24]; end endtask always@(negedge por_rst_n or negedge sys_rst_n) fabric_rst_n = 32'h01f3_300f; always@(posedge m_axi_gp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) m_axi_gp0_rstn = 1'b0; else m_axi_gp0_rstn = 1'b1; end always@(posedge m_axi_gp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) m_axi_gp1_rstn = 1'b0; else m_axi_gp1_rstn = 1'b1; end always@(posedge s_axi_gp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_gp0_rstn = 1'b0; else s_axi_gp0_rstn = 1'b1; end always@(posedge s_axi_gp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_gp1_rstn = 1'b0; else s_axi_gp1_rstn = 1'b1; end always@(posedge s_axi_hp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp0_rstn = 1'b0; else s_axi_hp0_rstn = 1'b1; end always@(posedge s_axi_hp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp1_rstn = 1'b0; else s_axi_hp1_rstn = 1'b1; end always@(posedge s_axi_hp2_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp2_rstn = 1'b0; else s_axi_hp2_rstn = 1'b1; end always@(posedge s_axi_hp3_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp3_rstn = 1'b0; else s_axi_hp3_rstn = 1'b1; end always@(posedge s_axi_acp_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_acp_rstn = 1'b0; else s_axi_acp_rstn = 1'b1; end always@(*) begin if ((por_rst_n!= 1'b0) && (por_rst_n!= 1'b1) && (sys_rst_n != 1'b0) && (sys_rst_n != 1'b1)) begin $display(" Error:processing_system7_bfm_v2_0_5_gen_reset. PS_PORB and PS_SRSTB must be driven to known state"); $finish(); end end endmodule
module processing_system7_bfm_v2_0_5_gen_reset( por_rst_n, sys_rst_n, rst_out_n, m_axi_gp0_clk, m_axi_gp1_clk, s_axi_gp0_clk, s_axi_gp1_clk, s_axi_hp0_clk, s_axi_hp1_clk, s_axi_hp2_clk, s_axi_hp3_clk, s_axi_acp_clk, m_axi_gp0_rstn, m_axi_gp1_rstn, s_axi_gp0_rstn, s_axi_gp1_rstn, s_axi_hp0_rstn, s_axi_hp1_rstn, s_axi_hp2_rstn, s_axi_hp3_rstn, s_axi_acp_rstn, fclk_reset3_n, fclk_reset2_n, fclk_reset1_n, fclk_reset0_n, fpga_acp_reset_n, fpga_gp_m0_reset_n, fpga_gp_m1_reset_n, fpga_gp_s0_reset_n, fpga_gp_s1_reset_n, fpga_hp_s0_reset_n, fpga_hp_s1_reset_n, fpga_hp_s2_reset_n, fpga_hp_s3_reset_n ); input por_rst_n; input sys_rst_n; input m_axi_gp0_clk; input m_axi_gp1_clk; input s_axi_gp0_clk; input s_axi_gp1_clk; input s_axi_hp0_clk; input s_axi_hp1_clk; input s_axi_hp2_clk; input s_axi_hp3_clk; input s_axi_acp_clk; output reg m_axi_gp0_rstn; output reg m_axi_gp1_rstn; output reg s_axi_gp0_rstn; output reg s_axi_gp1_rstn; output reg s_axi_hp0_rstn; output reg s_axi_hp1_rstn; output reg s_axi_hp2_rstn; output reg s_axi_hp3_rstn; output reg s_axi_acp_rstn; output rst_out_n; output fclk_reset3_n; output fclk_reset2_n; output fclk_reset1_n; output fclk_reset0_n; output fpga_acp_reset_n; output fpga_gp_m0_reset_n; output fpga_gp_m1_reset_n; output fpga_gp_s0_reset_n; output fpga_gp_s1_reset_n; output fpga_hp_s0_reset_n; output fpga_hp_s1_reset_n; output fpga_hp_s2_reset_n; output fpga_hp_s3_reset_n; reg [31:0] fabric_rst_n; reg r_m_axi_gp0_rstn; reg r_m_axi_gp1_rstn; reg r_s_axi_gp0_rstn; reg r_s_axi_gp1_rstn; reg r_s_axi_hp0_rstn; reg r_s_axi_hp1_rstn; reg r_s_axi_hp2_rstn; reg r_s_axi_hp3_rstn; reg r_s_axi_acp_rstn; assign rst_out_n = por_rst_n & sys_rst_n; assign fclk_reset0_n = !fabric_rst_n[0]; assign fclk_reset1_n = !fabric_rst_n[1]; assign fclk_reset2_n = !fabric_rst_n[2]; assign fclk_reset3_n = !fabric_rst_n[3]; assign fpga_acp_reset_n = !fabric_rst_n[24]; assign fpga_hp_s3_reset_n = !fabric_rst_n[23]; assign fpga_hp_s2_reset_n = !fabric_rst_n[22]; assign fpga_hp_s1_reset_n = !fabric_rst_n[21]; assign fpga_hp_s0_reset_n = !fabric_rst_n[20]; assign fpga_gp_s1_reset_n = !fabric_rst_n[17]; assign fpga_gp_s0_reset_n = !fabric_rst_n[16]; assign fpga_gp_m1_reset_n = !fabric_rst_n[13]; assign fpga_gp_m0_reset_n = !fabric_rst_n[12]; task fpga_soft_reset; input[31:0] reset_ctrl; begin fabric_rst_n[0] = reset_ctrl[0]; fabric_rst_n[1] = reset_ctrl[1]; fabric_rst_n[2] = reset_ctrl[2]; fabric_rst_n[3] = reset_ctrl[3]; fabric_rst_n[12] = reset_ctrl[12]; fabric_rst_n[13] = reset_ctrl[13]; fabric_rst_n[16] = reset_ctrl[16]; fabric_rst_n[17] = reset_ctrl[17]; fabric_rst_n[20] = reset_ctrl[20]; fabric_rst_n[21] = reset_ctrl[21]; fabric_rst_n[22] = reset_ctrl[22]; fabric_rst_n[23] = reset_ctrl[23]; fabric_rst_n[24] = reset_ctrl[24]; end endtask always@(negedge por_rst_n or negedge sys_rst_n) fabric_rst_n = 32'h01f3_300f; always@(posedge m_axi_gp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) m_axi_gp0_rstn = 1'b0; else m_axi_gp0_rstn = 1'b1; end always@(posedge m_axi_gp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) m_axi_gp1_rstn = 1'b0; else m_axi_gp1_rstn = 1'b1; end always@(posedge s_axi_gp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_gp0_rstn = 1'b0; else s_axi_gp0_rstn = 1'b1; end always@(posedge s_axi_gp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_gp1_rstn = 1'b0; else s_axi_gp1_rstn = 1'b1; end always@(posedge s_axi_hp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp0_rstn = 1'b0; else s_axi_hp0_rstn = 1'b1; end always@(posedge s_axi_hp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp1_rstn = 1'b0; else s_axi_hp1_rstn = 1'b1; end always@(posedge s_axi_hp2_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp2_rstn = 1'b0; else s_axi_hp2_rstn = 1'b1; end always@(posedge s_axi_hp3_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp3_rstn = 1'b0; else s_axi_hp3_rstn = 1'b1; end always@(posedge s_axi_acp_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_acp_rstn = 1'b0; else s_axi_acp_rstn = 1'b1; end always@(*) begin if ((por_rst_n!= 1'b0) && (por_rst_n!= 1'b1) && (sys_rst_n != 1'b0) && (sys_rst_n != 1'b1)) begin $display(" Error:processing_system7_bfm_v2_0_5_gen_reset. PS_PORB and PS_SRSTB must be driven to known state"); $finish(); end end endmodule
module processing_system7_bfm_v2_0_5_gen_reset( por_rst_n, sys_rst_n, rst_out_n, m_axi_gp0_clk, m_axi_gp1_clk, s_axi_gp0_clk, s_axi_gp1_clk, s_axi_hp0_clk, s_axi_hp1_clk, s_axi_hp2_clk, s_axi_hp3_clk, s_axi_acp_clk, m_axi_gp0_rstn, m_axi_gp1_rstn, s_axi_gp0_rstn, s_axi_gp1_rstn, s_axi_hp0_rstn, s_axi_hp1_rstn, s_axi_hp2_rstn, s_axi_hp3_rstn, s_axi_acp_rstn, fclk_reset3_n, fclk_reset2_n, fclk_reset1_n, fclk_reset0_n, fpga_acp_reset_n, fpga_gp_m0_reset_n, fpga_gp_m1_reset_n, fpga_gp_s0_reset_n, fpga_gp_s1_reset_n, fpga_hp_s0_reset_n, fpga_hp_s1_reset_n, fpga_hp_s2_reset_n, fpga_hp_s3_reset_n ); input por_rst_n; input sys_rst_n; input m_axi_gp0_clk; input m_axi_gp1_clk; input s_axi_gp0_clk; input s_axi_gp1_clk; input s_axi_hp0_clk; input s_axi_hp1_clk; input s_axi_hp2_clk; input s_axi_hp3_clk; input s_axi_acp_clk; output reg m_axi_gp0_rstn; output reg m_axi_gp1_rstn; output reg s_axi_gp0_rstn; output reg s_axi_gp1_rstn; output reg s_axi_hp0_rstn; output reg s_axi_hp1_rstn; output reg s_axi_hp2_rstn; output reg s_axi_hp3_rstn; output reg s_axi_acp_rstn; output rst_out_n; output fclk_reset3_n; output fclk_reset2_n; output fclk_reset1_n; output fclk_reset0_n; output fpga_acp_reset_n; output fpga_gp_m0_reset_n; output fpga_gp_m1_reset_n; output fpga_gp_s0_reset_n; output fpga_gp_s1_reset_n; output fpga_hp_s0_reset_n; output fpga_hp_s1_reset_n; output fpga_hp_s2_reset_n; output fpga_hp_s3_reset_n; reg [31:0] fabric_rst_n; reg r_m_axi_gp0_rstn; reg r_m_axi_gp1_rstn; reg r_s_axi_gp0_rstn; reg r_s_axi_gp1_rstn; reg r_s_axi_hp0_rstn; reg r_s_axi_hp1_rstn; reg r_s_axi_hp2_rstn; reg r_s_axi_hp3_rstn; reg r_s_axi_acp_rstn; assign rst_out_n = por_rst_n & sys_rst_n; assign fclk_reset0_n = !fabric_rst_n[0]; assign fclk_reset1_n = !fabric_rst_n[1]; assign fclk_reset2_n = !fabric_rst_n[2]; assign fclk_reset3_n = !fabric_rst_n[3]; assign fpga_acp_reset_n = !fabric_rst_n[24]; assign fpga_hp_s3_reset_n = !fabric_rst_n[23]; assign fpga_hp_s2_reset_n = !fabric_rst_n[22]; assign fpga_hp_s1_reset_n = !fabric_rst_n[21]; assign fpga_hp_s0_reset_n = !fabric_rst_n[20]; assign fpga_gp_s1_reset_n = !fabric_rst_n[17]; assign fpga_gp_s0_reset_n = !fabric_rst_n[16]; assign fpga_gp_m1_reset_n = !fabric_rst_n[13]; assign fpga_gp_m0_reset_n = !fabric_rst_n[12]; task fpga_soft_reset; input[31:0] reset_ctrl; begin fabric_rst_n[0] = reset_ctrl[0]; fabric_rst_n[1] = reset_ctrl[1]; fabric_rst_n[2] = reset_ctrl[2]; fabric_rst_n[3] = reset_ctrl[3]; fabric_rst_n[12] = reset_ctrl[12]; fabric_rst_n[13] = reset_ctrl[13]; fabric_rst_n[16] = reset_ctrl[16]; fabric_rst_n[17] = reset_ctrl[17]; fabric_rst_n[20] = reset_ctrl[20]; fabric_rst_n[21] = reset_ctrl[21]; fabric_rst_n[22] = reset_ctrl[22]; fabric_rst_n[23] = reset_ctrl[23]; fabric_rst_n[24] = reset_ctrl[24]; end endtask always@(negedge por_rst_n or negedge sys_rst_n) fabric_rst_n = 32'h01f3_300f; always@(posedge m_axi_gp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) m_axi_gp0_rstn = 1'b0; else m_axi_gp0_rstn = 1'b1; end always@(posedge m_axi_gp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) m_axi_gp1_rstn = 1'b0; else m_axi_gp1_rstn = 1'b1; end always@(posedge s_axi_gp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_gp0_rstn = 1'b0; else s_axi_gp0_rstn = 1'b1; end always@(posedge s_axi_gp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_gp1_rstn = 1'b0; else s_axi_gp1_rstn = 1'b1; end always@(posedge s_axi_hp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp0_rstn = 1'b0; else s_axi_hp0_rstn = 1'b1; end always@(posedge s_axi_hp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp1_rstn = 1'b0; else s_axi_hp1_rstn = 1'b1; end always@(posedge s_axi_hp2_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp2_rstn = 1'b0; else s_axi_hp2_rstn = 1'b1; end always@(posedge s_axi_hp3_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp3_rstn = 1'b0; else s_axi_hp3_rstn = 1'b1; end always@(posedge s_axi_acp_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_acp_rstn = 1'b0; else s_axi_acp_rstn = 1'b1; end always@(*) begin if ((por_rst_n!= 1'b0) && (por_rst_n!= 1'b1) && (sys_rst_n != 1'b0) && (sys_rst_n != 1'b1)) begin $display(" Error:processing_system7_bfm_v2_0_5_gen_reset. PS_PORB and PS_SRSTB must be driven to known state"); $finish(); end end endmodule
module axi_crossbar_v2_1_addr_arbiter_sasd # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 1, parameter integer C_NUM_S_LOG = 1, parameter integer C_AMESG_WIDTH = 1, parameter C_GRANT_ENC = 0, parameter [C_NUM_S32-1:0] C_ARB_PRIORITY = {C_NUM_S{32'h00000000}} // Arbitration priority among each SI slot. // Higher values indicate higher priority. // Format: C_NUM_SLAVE_SLOTS{Bit32}; // Range: 'h0-'hF. ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_SC_AMESG_WIDTH-1:0] S_AWMESG, input wire [C_NUM_SC_AMESG_WIDTH-1:0] S_ARMESG, input wire [C_NUM_S-1:0] S_AWVALID, output wire [C_NUM_S-1:0] S_AWREADY, input wire [C_NUM_S-1:0] S_ARVALID, output wire [C_NUM_S-1:0] S_ARREADY, // Master Ports output wire [C_AMESG_WIDTH-1:0] M_AMESG, output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, output wire [C_NUM_S-1:0] M_GRANT_HOT, output wire M_GRANT_RNW, output wire M_GRANT_ANY, output wire M_AWVALID, input wire M_AWREADY, output wire M_ARVALID, input wire M_ARREADY ); // Generates a mask for all input slots that are priority based function [C_NUM_S-1:0] f_prio_mask ( input integer null_arg ); reg [C_NUM_S-1:0] mask; integer i; begin mask = 0; for (i=0; i < C_NUM_S; i=i+1) begin mask[i] = (C_ARB_PRIORITY[i32+:32] != 0); end f_prio_mask = mask; end endfunction // Convert 16-bit one-hot to 4-bit binary function [3:0] f_hot2enc ( input [15:0] one_hot ); begin f_hot2enc[0] = \|(one_hot & 16'b1010101010101010); f_hot2enc[1] = \|(one_hot & 16'b1100110011001100); f_hot2enc[2] = \|(one_hot & 16'b1111000011110000); f_hot2enc[3] = \|(one_hot & 16'b1111111100000000); end endfunction localparam [C_NUM_S-1:0] P_PRIO_MASK = f_prio_mask(0); reg m_valid_i; reg [C_NUM_S-1:0] s_ready_i; reg [C_NUM_S-1:0] s_awvalid_reg; reg [C_NUM_S-1:0] s_arvalid_reg; wire [15:0] s_avalid; wire m_aready; wire [C_NUM_S-1:0] rnw; reg grant_rnw; reg [C_NUM_S_LOG-1:0] m_grant_enc_i; reg [C_NUM_S-1:0] m_grant_hot_i; reg [C_NUM_S-1:0] last_rr_hot; reg any_grant; reg any_prio; reg [C_NUM_S-1:0] which_prio_hot; reg [C_NUM_S_LOG-1:0] which_prio_enc; reg [4:0] current_highest; reg [15:0] next_prio_hot; reg [C_NUM_S_LOG-1:0] next_prio_enc; reg found_prio; wire [C_NUM_S-1:0] valid_rr; reg [15:0] next_rr_hot; reg [C_NUM_S_LOG-1:0] next_rr_enc; reg [C_NUM_SC_NUM_S-1:0] carry_rr; reg [C_NUM_SC_NUM_S-1:0] mask_rr; reg found_rr; wire [C_NUM_S-1:0] next_hot; wire [C_NUM_S_LOG-1:0] next_enc; integer i; wire [C_AMESG_WIDTH-1:0] amesg_mux; reg [C_AMESG_WIDTH-1:0] m_amesg_i; wire [C_NUM_SC_AMESG_WIDTH-1:0] s_amesg; genvar gen_si; always @(posedge ACLK) begin if (ARESET) begin s_awvalid_reg <= 0; s_arvalid_reg <= 0; end else if (\|s_ready_i) begin s_awvalid_reg <= 0; s_arvalid_reg <= 0; end else begin s_arvalid_reg <= S_ARVALID & ~s_awvalid_reg; s_awvalid_reg <= S_AWVALID & ~s_arvalid_reg & (~S_ARVALID \| s_awvalid_reg); end end assign s_avalid = S_AWVALID \| S_ARVALID; assign M_AWVALID = m_valid_i & ~grant_rnw; assign M_ARVALID = m_valid_i & grant_rnw; assign S_AWREADY = s_ready_i & {C_NUM_S{~grant_rnw}}; assign S_ARREADY = s_ready_i & {C_NUM_S{grant_rnw}}; assign M_GRANT_ENC = C_GRANT_ENC ? m_grant_enc_i : 0; assign M_GRANT_HOT = m_grant_hot_i; assign M_GRANT_RNW = grant_rnw; assign rnw = S_ARVALID & ~s_awvalid_reg; assign M_AMESG = m_amesg_i; assign m_aready = grant_rnw ? M_ARREADY : M_AWREADY; generate for (gen_si=0; gen_si<C_NUM_S; gen_si=gen_si+1) begin : gen_mesg_mux assign s_amesg[C_AMESG_WIDTHgen_si +: C_AMESG_WIDTH] = rnw[gen_si] ? S_ARMESG[C_AMESG_WIDTHgen_si +: C_AMESG_WIDTH] : S_AWMESG[C_AMESG_WIDTHgen_si +: C_AMESG_WIDTH]; end // gen_mesg_mux if (C_NUM_S>1) begin : gen_arbiter ///////////////////////////////////////////////////////////////////////////// // Grant a new request when there is none still pending. // If no qualified requests found, de-assert M_VALID. ///////////////////////////////////////////////////////////////////////////// assign M_GRANT_ANY = any_grant; assign next_hot = found_prio ? next_prio_hot : next_rr_hot; assign next_enc = found_prio ? next_prio_enc : next_rr_enc; always @(posedge ACLK) begin if (ARESET) begin m_valid_i <= 0; s_ready_i <= 0; m_grant_hot_i <= 0; m_grant_enc_i <= 0; any_grant <= 1'b0; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; grant_rnw <= 1'b0; end else begin s_ready_i <= 0; if (m_valid_i) begin // Stall 1 cycle after each master-side completion. if (m_aready) begin // Master-side completion m_valid_i <= 1'b0; m_grant_hot_i <= 0; any_grant <= 1'b0; end end else if (any_grant) begin m_valid_i <= 1'b1; s_ready_i <= m_grant_hot_i; // Assert S_AW/READY for 1 cycle to complete SI address transfer end else begin if (found_prio \| found_rr) begin m_grant_hot_i <= next_hot; m_grant_enc_i <= next_enc; any_grant <= 1'b1; grant_rnw <= \|(rnw & next_hot); if (~found_prio) begin last_rr_hot <= next_rr_hot; end end end end end ///////////////////////////////////////////////////////////////////////////// // Fixed Priority arbiter // Selects next request to grant from among inputs with PRIO > 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ * begin : ALG_PRIO integer ip; any_prio = 1'b0; which_prio_hot = 0; which_prio_enc = 0; current_highest = 0; for (ip=0; ip < C_NUM_S; ip=ip+1) begin if (P_PRIO_MASK[ip] & ({1'b0, C_ARB_PRIORITY[ip32+:4]} > current_highest)) begin if (s_avalid[ip]) begin current_highest[0+:4] = C_ARB_PRIORITY[ip32+:4]; any_prio = 1'b1; which_prio_hot = 1'b1 << ip; which_prio_enc = ip; end end end found_prio = any_prio; next_prio_hot = which_prio_hot; next_prio_enc = which_prio_enc; end ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// assign valid_rr = ~P_PRIO_MASK & s_avalid; always @ * begin : ALG_RR integer ir, jr, nr; next_rr_hot = 0; for (ir=0;ir<C_NUM_S;ir=ir+1) begin nr = (ir>0) ? (ir-1) : (C_NUM_S-1); carry_rr[irC_NUM_S] = last_rr_hot[nr]; mask_rr[irC_NUM_S] = ~valid_rr[nr]; for (jr=1;jr<C_NUM_S;jr=jr+1) begin nr = (ir-jr > 0) ? (ir-jr-1) : (C_NUM_S+ir-jr-1); carry_rr[irC_NUM_S+jr] = carry_rr[irC_NUM_S+jr-1] \| (last_rr_hot[nr] & mask_rr[irC_NUM_S+jr-1]); if (jr < C_NUM_S-1) begin mask_rr[irC_NUM_S+jr] = mask_rr[irC_NUM_S+jr-1] & ~valid_rr[nr]; end end next_rr_hot[ir] = valid_rr[ir] & carry_rr[(ir+1)C_NUM_S-1]; end next_rr_enc = f_hot2enc(next_rr_hot); found_rr = \|(next_rr_hot); end generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY ("rtl"), .C_RATIO (C_NUM_S), .C_SEL_WIDTH (C_NUM_S_LOG), .C_DATA_WIDTH (C_AMESG_WIDTH) ) si_amesg_mux_inst ( .S (next_enc), .A (s_amesg), .O (amesg_mux), .OE (1'b1) ); always @(posedge ACLK) begin if (ARESET) begin m_amesg_i <= 0; end else if (~any_grant) begin m_amesg_i <= amesg_mux; end end end else begin : gen_no_arbiter assign M_GRANT_ANY = m_grant_hot_i; always @ (posedge ACLK) begin if (ARESET) begin m_valid_i <= 1'b0; s_ready_i <= 1'b0; m_grant_enc_i <= 0; m_grant_hot_i <= 1'b0; grant_rnw <= 1'b0; end else begin s_ready_i <= 1'b0; if (m_valid_i) begin if (m_aready) begin m_valid_i <= 1'b0; m_grant_hot_i <= 1'b0; end end else if (m_grant_hot_i) begin m_valid_i <= 1'b1; s_ready_i[0] <= 1'b1; // Assert S_AW/READY for 1 cycle to complete SI address transfer end else if (s_avalid[0]) begin m_grant_hot_i <= 1'b1; grant_rnw <= rnw[0]; end end end always @ (posedge ACLK) begin if (ARESET) begin m_amesg_i <= 0; end else if (~m_grant_hot_i) begin m_amesg_i <= s_amesg; end end end // gen_arbiter endgenerate endmodule
module processing_system7_bfm_v2_0_5_arb_wr( rstn, sw_clk, qos1, qos2, prt_dv1, prt_dv2, prt_data1, prt_data2, prt_addr1, prt_addr2, prt_bytes1, prt_bytes2, prt_ack1, prt_ack2, prt_qos, prt_req, prt_data, prt_addr, prt_bytes, prt_ack ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2; input [max_burst_bits-1:0] prt_data1,prt_data2; input [addr_width-1:0] prt_addr1,prt_addr2; input [max_burst_bytes_width:0] prt_bytes1,prt_bytes2; input prt_dv1, prt_dv2, prt_ack; output reg prt_ack1,prt_ack2,prt_req; output reg [max_burst_bits-1:0] prt_data; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; output reg [axi_qos_width-1:0] prt_qos; parameter wait_req = 2'b00, serv_req1 = 2'b01, serv_req2 = 2'b10,wait_ack_low = 2'b11; reg [1:0] state,temp_state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_req = 1'b0; if(prt_dv1 && !prt_dv2) begin state = serv_req1; prt_req = 1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; prt_qos = qos1; end else if(!prt_dv1 && prt_dv2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv1 && prt_dv2) begin if(qos1 > qos2) begin prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else if(qos1 < qos2) begin prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end else begin prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req1:begin state = serv_req1; prt_ack2 = 1'b0; if(prt_ack) begin prt_ack1 = 1'b1; prt_req = 0; if(prt_dv2) begin prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end else begin // state = wait_req; state = wait_ack_low; end end end serv_req2:begin state = serv_req2; prt_ack1 = 1'b0; if(prt_ack) begin prt_ack2 = 1'b1; prt_req = 0; if(prt_dv1) begin prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else begin state = wait_ack_low; // state = wait_req; end end end wait_ack_low:begin prt_ack1 = 1'b0; prt_ack2 = 1'b0; state = wait_ack_low; if(!prt_ack) state = wait_req; end endcase end /// if else end /// always endmodule
module / / Internal counters that are used as Read/Write pointers to the fifo's that store all the transaction info on all channles. This parameter is used to define the width of these pointers --> depending on Maximum outstanding transactions supported. 1-bit extra width than the no.of.bits needed to represent the outstanding transactions Extra bit helps in generating the empty and full flags / parameter int_cntr_width = clogb2(max_outstanding_transactions)+1; / RESP data / parameter rsp_fifo_bits = axi_rsp_width+id_bus_width; parameter rsp_lsb = 0; parameter rsp_msb = axi_rsp_width-1; parameter rsp_id_lsb = rsp_msb + 1; parameter rsp_id_msb = rsp_id_lsb + id_bus_width-1; input S_RESETN; output S_ARREADY; output S_AWREADY; output S_BVALID; output S_RLAST; output S_RVALID; output S_WREADY; output [axi_rsp_width-1:0] S_BRESP; output [axi_rsp_width-1:0] S_RRESP; output [data_bus_width-1:0] S_RDATA; output [id_bus_width-1:0] S_BID; output [id_bus_width-1:0] S_RID; input S_ACLK; input S_ARVALID; input S_AWVALID; input S_BREADY; input S_RREADY; input S_WLAST; input S_WVALID; input [axi_brst_type_width-1:0] S_ARBURST; input [axi_lock_width-1:0] S_ARLOCK; input [axi_size_width-1:0] S_ARSIZE; input [axi_brst_type_width-1:0] S_AWBURST; input [axi_lock_width-1:0] S_AWLOCK; input [axi_size_width-1:0] S_AWSIZE; input [axi_prot_width-1:0] S_ARPROT; input [axi_prot_width-1:0] S_AWPROT; input [address_bus_width-1:0] S_ARADDR; input [address_bus_width-1:0] S_AWADDR; input [data_bus_width-1:0] S_WDATA; input [axi_cache_width-1:0] S_ARCACHE; input [axi_cache_width-1:0] S_ARLEN; input [axi_qos_width-1:0] S_ARQOS; input [axi_cache_width-1:0] S_AWCACHE; input [axi_len_width-1:0] S_AWLEN; input [axi_qos_width-1:0] S_AWQOS; input [(data_bus_width/8)-1:0] S_WSTRB; input [id_bus_width-1:0] S_ARID; input [id_bus_width-1:0] S_AWID; input [id_bus_width-1:0] S_WID; input SW_CLK; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output [max_burst_bits-1:0] WR_DATA; output [addr_width-1:0] WR_ADDR; output [max_transfer_bytes_width:0] WR_BYTES; output reg RD_REQ_OCM, RD_REQ_DDR; output reg [addr_width-1:0] RD_ADDR; input [max_burst_bits-1:0] RD_DATA_DDR,RD_DATA_OCM; output reg[max_transfer_bytes_width:0] RD_BYTES; input RD_DATA_VALID_OCM,RD_DATA_VALID_DDR; output [axi_qos_width-1:0] WR_QOS; output reg [axi_qos_width-1:0] RD_QOS; input S_RDISSUECAP1_EN; input S_WRISSUECAP1_EN; output [7:0] S_RCOUNT; output [7:0] S_WCOUNT; output [2:0] S_RACOUNT; output [5:0] S_WACOUNT; wire net_ARVALID; wire net_AWVALID; wire net_WVALID; real s_aclk_period; cdn_axi3_slave_bfm #(slave_name, data_bus_width, address_bus_width, id_bus_width, slave_base_address, (slave_high_address- slave_base_address), max_outstanding_transactions, 0, ///MEMORY_MODEL_MODE, exclusive_access_supported) slave (.ACLK (S_ACLK), .ARESETn (S_RESETN), /// confirm this // Write Address Channel .AWID (S_AWID), .AWADDR (S_AWADDR), .AWLEN (S_AWLEN), .AWSIZE (S_AWSIZE), .AWBURST (S_AWBURST), .AWLOCK (S_AWLOCK), .AWCACHE (S_AWCACHE), .AWPROT (S_AWPROT), .AWVALID (net_AWVALID), .AWREADY (S_AWREADY), // Write Data Channel Signals. .WID (S_WID), .WDATA (S_WDATA), .WSTRB (S_WSTRB), .WLAST (S_WLAST), .WVALID (net_WVALID), .WREADY (S_WREADY), // Write Response Channel Signals. .BID (S_BID), .BRESP (S_BRESP), .BVALID (S_BVALID), .BREADY (S_BREADY), // Read Address Channel Signals. .ARID (S_ARID), .ARADDR (S_ARADDR), .ARLEN (S_ARLEN), .ARSIZE (S_ARSIZE), .ARBURST (S_ARBURST), .ARLOCK (S_ARLOCK), .ARCACHE (S_ARCACHE), .ARPROT (S_ARPROT), .ARVALID (net_ARVALID), .ARREADY (S_ARREADY), // Read Data Channel Signals. .RID (S_RID), .RDATA (S_RDATA), .RRESP (S_RRESP), .RLAST (S_RLAST), .RVALID (S_RVALID), .RREADY (S_RREADY)); wire wr_intr_fifo_full; reg temp_wr_intr_fifo_full; / Interconnect WR_FIFO model instance / processing_system7_bfm_v2_0_5_intr_wr_mem wr_intr_fifo(SW_CLK, S_RESETN, wr_intr_fifo_full, WR_DATA_ACK_OCM, WR_DATA_ACK_DDR, WR_ADDR, WR_DATA, WR_BYTES, WR_QOS, WR_DATA_VALID_OCM, WR_DATA_VALID_DDR); / Register the async 'full' signal to S_ACLK clock / always@(posedge S_ACLK) temp_wr_intr_fifo_full = wr_intr_fifo_full; / Latency type and Debug/Error Control / reg[1:0] latency_type = RANDOM_CASE; reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1'b1; / Internal nets/regs for calling slave BFM API's/ reg [wr_afi_fifo_data_bits-1:0] wr_fifo [0:max_outstanding_transactions-1]; reg [int_cntr_width-1:0] wr_fifo_wr_ptr = 0, wr_fifo_rd_ptr = 0; wire wr_fifo_empty; / Store the awvalid receive time --- necessary for calculating the bresp latency / reg [7:0] aw_time_cnt = 0,bresp_time_cnt = 0; real awvalid_receive_time[0:max_outstanding_transactions]; // store the time when a new awvalid is received reg awvalid_flag[0:max_outstanding_transactions]; // store the time when a new awvalid is received / Address Write Channel handshake/ reg[int_cntr_width-1:0] aw_cnt = 0;// / various FIFOs for storing the ADDR channel info / reg [axi_size_width-1:0] awsize [0:max_outstanding_transactions-1]; reg [axi_prot_width-1:0] awprot [0:max_outstanding_transactions-1]; reg [axi_lock_width-1:0] awlock [0:max_outstanding_transactions-1]; reg [axi_cache_width-1:0] awcache [0:max_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] awbrst [0:max_outstanding_transactions-1]; reg [axi_len_width-1:0] awlen [0:max_outstanding_transactions-1]; reg aw_flag [0:max_outstanding_transactions-1]; reg [addr_width-1:0] awaddr [0:max_outstanding_transactions-1]; reg [id_bus_width-1:0] awid [0:max_outstanding_transactions-1]; reg [axi_qos_width-1:0] awqos [0:max_outstanding_transactions-1]; wire aw_fifo_full; // indicates awvalid_fifo is full (max outstanding transactions reached) / internal fifos to store burst write data, ID & strobes/ reg [(data_bus_widthaxi_burst_len)-1:0] burst_data [0:max_outstanding_transactions-1]; reg [max_burst_bytes_width:0] burst_valid_bytes [0:max_outstanding_transactions-1]; /// total valid bytes received in a complete burst transfer reg wlast_flag [0:max_outstanding_transactions-1]; // flag to indicate WLAST received wire wd_fifo_full; /* Write Data Channel and Write Response handshake signals/ reg [int_cntr_width-1:0] wd_cnt = 0; reg [(data_bus_widthaxi_burst_len)-1:0] aligned_wr_data; reg [addr_width-1:0] aligned_wr_addr; reg [max_burst_bytes_width:0] valid_data_bytes; reg [int_cntr_width-1:0] wr_bresp_cnt = 0; reg [axi_rsp_width-1:0] bresp; reg [rsp_fifo_bits-1:0] fifo_bresp [0:max_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_bresp; reg [int_cntr_width-1:0] rd_bresp_cnt = 0; integer wr_latency_count; reg wr_delayed; wire bresp_fifo_empty; /* keep track of count values / reg[7:0] wcount; reg[5:0] wacount; / Qos/ reg [axi_qos_width-1:0] ar_qos, aw_qos; initial begin if(DEBUG_INFO) begin if(enable_this_port) $display("[%0d] : %0s : %0s : Port is ENABLED.",$time, DISP_INFO, slave_name); else $display("[%0d] : %0s : %0s : Port is DISABLED.",$time, DISP_INFO, slave_name); end end /--------------------------------------------------------------------------------/ / Store the Clock cycle time period / always@(S_RESETN) begin if(S_RESETN) begin @(posedge S_ACLK); s_aclk_period = $time; @(posedge S_ACLK); s_aclk_period = $time - s_aclk_period; end end /--------------------------------------------------------------------------------/ initial slave.set_disable_reset_value_checks(1); initial begin repeat(2) @(posedge S_ACLK); if(!enable_this_port) begin slave.set_channel_level_info(0); slave.set_function_level_info(0); end slave.RESPONSE_TIMEOUT = 0; end /--------------------------------------------------------------------------------/ / Set Latency type to be used / task set_latency_type; input[1:0] lat; begin if(enable_this_port) latency_type = lat; else begin //if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'Latency Profile' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / Set ARQoS to be used / task set_arqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) ar_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'ARQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / Set AWQoS to be used / task set_awqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) aw_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'AWQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / get the wr latency number / function [31:0] get_wr_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : get_wr_lat_number = afi_wr_min; AVG_CASE : get_wr_lat_number = afi_wr_avg; WORST_CASE : get_wr_lat_number = afi_wr_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : get_wr_lat_number = ($random()%10+ afi_wr_min); 2'b01 : get_wr_lat_number = ($random()%40+ afi_wr_avg); default : get_wr_lat_number = ($random()%60+ afi_wr_max); endcase end endcase end endfunction /--------------------------------------------------------------------------------/ / get the rd latency number / function [31:0] get_rd_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : get_rd_lat_number = afi_rd_min; AVG_CASE : get_rd_lat_number = afi_rd_avg; WORST_CASE : get_rd_lat_number = afi_rd_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : get_rd_lat_number = ($random()%10+ afi_rd_min); 2'b01 : get_rd_lat_number = ($random()%40+ afi_rd_avg); default : get_rd_lat_number = ($random()%60+ afi_rd_max); endcase end endcase end endfunction /--------------------------------------------------------------------------------/ / Check for any WRITE/READs when this port is disabled / always@(S_AWVALID or S_WVALID or S_ARVALID) begin if((S_AWVALID \| S_WVALID \| S_ARVALID) && !enable_this_port) begin $display("[%0d] : %0s : %0s : Port is disabled. AXI transaction is initiated on this port ...\nSimulation will halt ..",$time, DISP_ERR, slave_name); $stop; end end /--------------------------------------------------------------------------------/ assign net_ARVALID = enable_this_port ? S_ARVALID : 1'b0; assign net_AWVALID = enable_this_port ? S_AWVALID : 1'b0; assign net_WVALID = enable_this_port ? S_WVALID : 1'b0; assign wr_fifo_empty = (wr_fifo_wr_ptr === wr_fifo_rd_ptr)?1'b1: 1'b0; assign bresp_fifo_empty = (wr_bresp_cnt === rd_bresp_cnt)?1'b1:1'b0; assign bresp_fifo_full = ((wr_bresp_cnt[int_cntr_width-1] !== rd_bresp_cnt[int_cntr_width-1]) && (wr_bresp_cnt[int_cntr_width-2:0] === rd_bresp_cnt[int_cntr_width-2:0]))?1'b1:1'b0; assign S_WCOUNT = wcount; assign S_WACOUNT = wacount; // FIFO_STATUS (only if AFI port) 1- full function automatic wrfifo_full ; input [axi_len_width:0] fifo_space_exp; integer fifo_space_left; begin fifo_space_left = afi_fifo_locations - wcount; if(fifo_space_left < fifo_space_exp) wrfifo_full = 1; else wrfifo_full = 0; end endfunction /--------------------------------------------------------------------------------/ / Store the awvalid receive time --- necessary for calculating the bresp latency / always@(negedge S_RESETN or S_AWID or S_AWADDR or S_AWVALID ) begin if(!S_RESETN) aw_time_cnt = 0; else begin if(S_AWVALID) begin awvalid_receive_time[aw_time_cnt] = $time; awvalid_flag[aw_time_cnt] = 1'b1; aw_time_cnt = aw_time_cnt + 1; end end // else end /// always /--------------------------------------------------------------------------------/ always@(posedge S_ACLK) begin if(net_AWVALID && S_AWREADY) begin if(S_AWQOS === 0) awqos[aw_cnt[int_cntr_width-2:0]] = aw_qos; else awqos[aw_cnt[int_cntr_width-2:0]] = S_AWQOS; end end / Address Write Channel handshake/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin aw_cnt = 0; wacount = 0; end else begin if(S_AWVALID && !wrfifo_full(S_AWLEN+1)) begin slave.RECEIVE_WRITE_ADDRESS(0, id_invalid, awaddr[aw_cnt[int_cntr_width-2:0]], awlen[aw_cnt[int_cntr_width-2:0]], awsize[aw_cnt[int_cntr_width-2:0]], awbrst[aw_cnt[int_cntr_width-2:0]], awlock[aw_cnt[int_cntr_width-2:0]], awcache[aw_cnt[int_cntr_width-2:0]], awprot[aw_cnt[int_cntr_width-2:0]], awid[aw_cnt[int_cntr_width-2:0]]); /// sampled valid ID. aw_flag[aw_cnt[int_cntr_width-2:0]] = 1'b1; aw_cnt = aw_cnt + 1; wacount = wacount + 1; end // if (!aw_fifo_full) end /// if else end /// always /--------------------------------------------------------------------------------/ / Write Data Channel Handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wd_cnt = 0; end else begin if(aw_flag[wd_cnt[int_cntr_width-2:0]]) begin if(S_WVALID && !wrfifo_full(awlen[wd_cnt[int_cntr_width-2:0]] + 1)) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_cntr_width-2:0]]); wlast_flag[wd_cnt[int_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; end end else begin if(!wrfifo_full(axi_burst_len+1) && S_WVALID) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_cntr_width-2:0]]); wlast_flag[wd_cnt[int_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; end end /// if end /// else end /// always /--------------------------------------------------------------------------------/ / Align the wrap data for write transaction / task automatic get_wrap_aligned_wr_data; output [(data_bus_widthaxi_burst_len)-1:0] aligned_data; output [addr_width-1:0] start_addr; /// aligned start address input [addr_width-1:0] addr; input [(data_bus_widthaxi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [(data_bus_widthaxi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; wrp_data = wrp_data << ((data_bus_widthaxi_burst_len) - (v_bytes8)); while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data << 8; temp_data[7:0] = wrp_data[(data_bus_widthaxi_burst_len)-1 : (data_bus_widthaxi_burst_len)-8]; wrp_data = wrp_data << 8; wrp_bytes = wrp_bytes - 1; end wrp_bytes = addr - start_addr; wrp_data = b_data << (wrp_bytes8); aligned_data = (temp_data \| wrp_data); end endtask /--------------------------------------------------------------------------------/ / Calculate the Response for each read/write transaction / function [axi_rsp_width-1:0] calculate_resp; input [addr_width-1:0] awaddr; input [axi_prot_width-1:0] awprot; reg [axi_rsp_width-1:0] rsp; begin rsp = AXI_OK; / Address Decode / if(decode_address(awaddr) === INVALID_MEM_TYPE) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Invalid location(0x%0h) ",$time, DISP_ERR, slave_name, awaddr); end else if(decode_address(awaddr) === REG_MEM) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Register Map(0x%0h) is not allowed through this port.",$time, DISP_ERR, slave_name, awaddr); end if(secure_access_enabled && awprot[1]) rsp = AXI_DEC_ERR; // decode error calculate_resp = rsp; end endfunction /--------------------------------------------------------------------------------/ reg[max_burst_bits-1:0] temp_wr_data; / Store the Write response for each write transaction / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_fifo_wr_ptr = 0; wcount = 0; end else begin enable_write_bresp = aw_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] && wlast_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]]; / calculate bresp only when AWVALID && WLAST is received / if(enable_write_bresp) begin aw_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] = 0; wlast_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] = 0; bresp = calculate_resp(awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]], awprot[wr_fifo_wr_ptr[int_cntr_width-2:0]]); / Fill AFI_WR_data FIFO / if(bresp === AXI_OK ) begin if(awbrst[wr_fifo_wr_ptr[int_cntr_width-2:0]]=== AXI_WRAP) begin /// wrap type? then align the data get_wrap_aligned_wr_data(aligned_wr_data, aligned_wr_addr, awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]], burst_data[wr_fifo_wr_ptr[int_cntr_width-2:0]],burst_valid_bytes[wr_fifo_wr_ptr[int_cntr_width-2:0]]); /// gives wrapped start address end else begin aligned_wr_data = burst_data[wr_fifo_wr_ptr[int_cntr_width-2:0]]; aligned_wr_addr = awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]] ; end valid_data_bytes = burst_valid_bytes[wr_fifo_wr_ptr[int_cntr_width-2:0]]; end else valid_data_bytes = 0; temp_wr_data = aligned_wr_data; wr_fifo[wr_fifo_wr_ptr[int_cntr_width-2:0]] = {awqos[wr_fifo_wr_ptr[int_cntr_width-2:0]], awlen[wr_fifo_wr_ptr[int_cntr_width-2:0]], awid[wr_fifo_wr_ptr[int_cntr_width-2:0]], bresp, temp_wr_data, aligned_wr_addr, valid_data_bytes}; wcount = wcount + awlen[wr_fifo_wr_ptr[int_cntr_width-2:0]]+1; wr_fifo_wr_ptr = wr_fifo_wr_ptr + 1; end end // else end // always /--------------------------------------------------------------------------------/ / Send Write Response Channel handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin rd_bresp_cnt = 0; wr_latency_count = get_wr_lat_number(1); wr_delayed = 0; bresp_time_cnt = 0; end else begin wr_delayed = 1'b0; if(awvalid_flag[bresp_time_cnt] && (($time - awvalid_receive_time[bresp_time_cnt])/s_aclk_period >= wr_latency_count)) wr_delayed = 1; if(!bresp_fifo_empty && wr_delayed) begin slave.SEND_WRITE_RESPONSE(fifo_bresp[rd_bresp_cnt[int_cntr_width-2:0]][rsp_id_msb : rsp_id_lsb], // ID fifo_bresp[rd_bresp_cnt[int_cntr_width-2:0]][rsp_msb : rsp_lsb] // Response ); wr_delayed = 0; awvalid_flag[bresp_time_cnt] = 1'b0; bresp_time_cnt = bresp_time_cnt+1; rd_bresp_cnt = rd_bresp_cnt + 1; wr_latency_count = get_wr_lat_number(1); end end // else end//always /--------------------------------------------------------------------------------/ / Write Response Channel handshake / reg wr_int_state; / Reading from the wr_fifo and sending to Interconnect fifo/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_int_state = 1'b0; wr_bresp_cnt = 0; wr_fifo_rd_ptr = 0; end else begin case(wr_int_state) 1'b0 : begin wr_int_state = 1'b0; if(!temp_wr_intr_fifo_full && !bresp_fifo_full && !wr_fifo_empty) begin wr_intr_fifo.write_mem({wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_qos_msb:wr_afi_qos_lsb], wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_data_msb:wr_afi_bytes_lsb]}); /// qos, data, address and valid_bytes wr_int_state = 1'b1; / start filling the write response fifo at the same time / fifo_bresp[wr_bresp_cnt[int_cntr_width-2:0]] = wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_id_msb:wr_afi_rsp_lsb]; // ID and Resp wcount = wcount - (wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_ln_msb:wr_afi_ln_lsb] + 1); /// burst length wacount = wacount - 1; wr_fifo_rd_ptr = wr_fifo_rd_ptr + 1; wr_bresp_cnt = wr_bresp_cnt+1; end end 1'b1 : begin wr_int_state = 0; end endcase end end /--------------------------------------------------------------------------------/ /-------------------------------- WRITE HANDSHAKE END ----------------------------------------/ /-------------------------------- READ HANDSHAKE ---------------------------------------------/ / READ CHANNELS / / Store the arvalid receive time --- necessary for calculating latency in sending the rresp latency / reg [7:0] ar_time_cnt = 0,rresp_time_cnt = 0; real arvalid_receive_time[0:max_outstanding_transactions]; // store the time when a new arvalid is received reg arvalid_flag[0:max_outstanding_transactions]; // store the time when a new arvalid is received reg [int_cntr_width-1:0] ar_cnt = 0;// counter for arvalid info / various FIFOs for storing the ADDR channel info / reg [axi_size_width-1:0] arsize [0:max_outstanding_transactions-1]; reg [axi_prot_width-1:0] arprot [0:max_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] arbrst [0:max_outstanding_transactions-1]; reg [axi_len_width-1:0] arlen [0:max_outstanding_transactions-1]; reg [axi_cache_width-1:0] arcache [0:max_outstanding_transactions-1]; reg [axi_lock_width-1:0] arlock [0:max_outstanding_transactions-1]; reg ar_flag [0:max_outstanding_transactions-1]; reg [addr_width-1:0] araddr [0:max_outstanding_transactions-1]; reg [id_bus_width-1:0] arid [0:max_outstanding_transactions-1]; reg [axi_qos_width-1:0] arqos [0:max_outstanding_transactions-1]; wire ar_fifo_full; // indicates arvalid_fifo is full (max outstanding transactions reached) reg [int_cntr_width-1:0] wr_rresp_cnt = 0; reg [axi_rsp_width-1:0] rresp; reg [rsp_fifo_bits-1:0] fifo_rresp [0:max_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_rresp; / Send Read Response & Data Channel handshake / integer rd_latency_count; reg rd_delayed; reg [rd_afi_fifo_bits-1:0] read_fifo[0:max_outstanding_transactions-1]; /// Read Burst Data, addr, size, burst, len, RID, RRESP, valid_bytes reg [int_cntr_width-1:0] rd_fifo_wr_ptr = 0, rd_fifo_rd_ptr = 0; wire read_fifo_full; reg [7:0] rcount; reg [2:0] racount; wire rd_intr_fifo_full, rd_intr_fifo_empty; wire read_fifo_empty; / signals to communicate with interconnect RD_FIFO model / reg rd_req, invalid_rd_req; / REad control Info 56:25 : Address (32) 24:22 : Size (3) 21:20 : BRST (2) 19:16 : LEN (4) 15:10 : RID (6) 9:8 : RRSP (2) 7:0 : byte cnt (8) / reg [rd_info_bits-1:0] read_control_info; reg [(data_bus_widthaxi_burst_len)-1:0] aligned_rd_data; reg temp_rd_intr_fifo_empty; processing_system7_bfm_v2_0_5_intr_rd_mem rd_intr_fifo(SW_CLK, S_RESETN, rd_intr_fifo_full, rd_intr_fifo_empty, rd_req, invalid_rd_req, read_control_info , RD_DATA_OCM, RD_DATA_DDR, RD_DATA_VALID_OCM, RD_DATA_VALID_DDR); assign read_fifo_empty = (rd_fifo_wr_ptr === rd_fifo_rd_ptr)?1'b1: 1'b0; assign S_RCOUNT = rcount; assign S_RACOUNT = racount; /* Register the asynch signal empty coming from Interconnect READ FIFO / always@(posedge S_ACLK) temp_rd_intr_fifo_empty = rd_intr_fifo_empty; // FIFO_STATUS (only if AFI port) 1- full function automatic rdfifo_full ; input [axi_len_width:0] fifo_space_exp; integer fifo_space_left; begin fifo_space_left = afi_fifo_locations - rcount; if(fifo_space_left < fifo_space_exp) rdfifo_full = 1; else rdfifo_full = 0; end endfunction / Store the arvalid receive time --- necessary for calculating the bresp latency / always@(negedge S_RESETN or S_ARID or S_ARADDR or S_ARVALID ) begin if(!S_RESETN) ar_time_cnt = 0; else begin if(S_ARVALID) begin arvalid_receive_time[ar_time_cnt] = $time; arvalid_flag[ar_time_cnt] = 1'b1; ar_time_cnt = ar_time_cnt + 1; end end // else end /// always /--------------------------------------------------------------------------------/ always@(posedge S_ACLK) begin if(net_ARVALID && S_ARREADY) begin if(S_ARQOS === 0) arqos[aw_cnt[int_cntr_width-2:0]] = ar_qos; else arqos[aw_cnt[int_cntr_width-2:0]] = S_ARQOS; end end / Address Read Channel handshake/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin ar_cnt = 0; racount = 0; end else begin if(S_ARVALID && !rdfifo_full(S_ARLEN+1)) begin /// if AFI read fifo is not full slave.RECEIVE_READ_ADDRESS(0, id_invalid, araddr[ar_cnt[int_cntr_width-2:0]], arlen[ar_cnt[int_cntr_width-2:0]], arsize[ar_cnt[int_cntr_width-2:0]], arbrst[ar_cnt[int_cntr_width-2:0]], arlock[ar_cnt[int_cntr_width-2:0]], arcache[ar_cnt[int_cntr_width-2:0]], arprot[ar_cnt[int_cntr_width-2:0]], arid[ar_cnt[int_cntr_width-2:0]]); /// sampled valid ID. ar_flag[ar_cnt[int_cntr_width-2:0]] = 1'b1; ar_cnt = ar_cnt+1; racount = racount + 1; end /// if(!ar_fifo_full) end /// if else end /// always/ /--------------------------------------------------------------------------------/ /* Align Wrap data for read transaction/ task automatic get_wrap_aligned_rd_data; output [(data_bus_widthaxi_burst_len)-1:0] aligned_data; input [addr_width-1:0] addr; input [(data_bus_widthaxi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [addr_width-1:0] start_addr; reg [(data_bus_widthaxi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data >> 8; temp_data[(data_bus_widthaxi_burst_len)-1 : (data_bus_widthaxi_burst_len)-8] = wrp_data[7:0]; wrp_data = wrp_data >> 8; wrp_bytes = wrp_bytes - 1; end temp_data = temp_data >> ((data_bus_widthaxi_burst_len) - (v_bytes8)); wrp_bytes = addr - start_addr; wrp_data = b_data >> (wrp_bytes8); aligned_data = (temp_data \| wrp_data); end endtask /--------------------------------------------------------------------------------/ parameter RD_DATA_REQ = 1'b0, WAIT_RD_VALID = 1'b1; reg rd_fifo_state; reg [addr_width-1:0] temp_read_address; reg [max_burst_bytes_width:0] temp_rd_valid_bytes; / get the data from memory && also calculate the rresp/ always@(negedge S_RESETN or posedge SW_CLK) begin if(!S_RESETN)begin wr_rresp_cnt =0; rd_fifo_state = RD_DATA_REQ; temp_rd_valid_bytes = 0; temp_read_address = 0; RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; rd_req = 0; invalid_rd_req= 0; RD_QOS = 0; end else begin case(rd_fifo_state) RD_DATA_REQ : begin rd_fifo_state = RD_DATA_REQ; RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; invalid_rd_req = 0; if(ar_flag[wr_rresp_cnt[int_cntr_width-2:0]] && !rd_intr_fifo_full) begin /// check the rd_fifo_bytes, interconnect fifo full condition ar_flag[wr_rresp_cnt[int_cntr_width-2:0]] = 0; rresp = calculate_resp(araddr[wr_rresp_cnt[int_cntr_width-2:0]],arprot[wr_rresp_cnt[int_cntr_width-2:0]]); temp_rd_valid_bytes = (arlen[wr_rresp_cnt[int_cntr_width-2:0]]+1)(2*arsize[wr_rresp_cnt[int_cntr_width-2:0]]);//data_bus_width/8; if(arbrst[wr_rresp_cnt[int_cntr_width-2:0]] === AXI_WRAP) /// wrap begin temp_read_address = (araddr[wr_rresp_cnt[int_cntr_width-2:0]]/temp_rd_valid_bytes) temp_rd_valid_bytes; else temp_read_address = araddr[wr_rresp_cnt[int_cntr_width-2:0]]; if(rresp === AXI_OK) begin case(decode_address(temp_read_address))//decode_address(araddr[wr_rresp_cnt[int_cntr_width-2:0]]); OCM_MEM : RD_REQ_OCM = 1; DDR_MEM : RD_REQ_DDR = 1; default : invalid_rd_req = 1; endcase end else invalid_rd_req = 1; RD_ADDR = temp_read_address; ///araddr[wr_rresp_cnt[int_cntr_width-2:0]]; RD_BYTES = temp_rd_valid_bytes; RD_QOS = arqos[wr_rresp_cnt[int_cntr_width-2:0]]; rd_fifo_state = WAIT_RD_VALID; rd_req = 1; racount = racount - 1; read_control_info = {araddr[wr_rresp_cnt[int_cntr_width-2:0]], arsize[wr_rresp_cnt[int_cntr_width-2:0]], arbrst[wr_rresp_cnt[int_cntr_width-2:0]], arlen[wr_rresp_cnt[int_cntr_width-2:0]], arid[wr_rresp_cnt[int_cntr_width-2:0]], rresp, temp_rd_valid_bytes }; wr_rresp_cnt = wr_rresp_cnt + 1; end end WAIT_RD_VALID : begin rd_fifo_state = WAIT_RD_VALID; rd_req = 0; if(RD_DATA_VALID_OCM \| RD_DATA_VALID_DDR \| invalid_rd_req) begin ///temp_dec == 2'b11) begin RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; invalid_rd_req = 0; rd_fifo_state = RD_DATA_REQ; end end endcase end /// else end /// always /--------------------------------------------------------------------------------/ /* thread to fill in the AFI RD_FIFO / reg[rd_afi_fifo_bits-1:0] temp_rd_data;//Read Burst Data, addr, size, burst, len, RID, RRESP, valid bytes reg tmp_state; always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_wr_ptr = 0; rcount = 0; tmp_state = 0; end else begin case(tmp_state) 0 : begin tmp_state = 0; if(!temp_rd_intr_fifo_empty) begin rd_intr_fifo.read_mem(temp_rd_data); tmp_state = 1; end end 1 : begin tmp_state = 1; if(!rdfifo_full(temp_rd_data[rd_afi_ln_msb:rd_afi_ln_lsb]+1)) begin read_fifo[rd_fifo_wr_ptr[int_cntr_width-2:0]] = temp_rd_data; rd_fifo_wr_ptr = rd_fifo_wr_ptr + 1; rcount = rcount + temp_rd_data[rd_afi_ln_msb:rd_afi_ln_lsb]+1; /// Burst length tmp_state = 0; end end endcase end end /--------------------------------------------------------------------------------/ reg[max_burst_bytes_width:0] rd_v_b; reg[rd_afi_fifo_bits-1:0] tmp_fifo_rd; /// Data, addr, size, burst, len, RID, RRESP,valid_bytes reg[(data_bus_widthaxi_burst_len)-1:0] temp_read_data; reg[(axi_rsp_widthaxi_burst_len)-1:0] temp_read_rsp; / Read Data Channel handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_rd_ptr = 0; rd_latency_count = get_rd_lat_number(1); rd_delayed = 0; rresp_time_cnt = 0; rd_v_b = 0; end else begin if(arvalid_flag[rresp_time_cnt] && ((($time - arvalid_receive_time[rresp_time_cnt])/s_aclk_period) >= rd_latency_count)) begin rd_delayed = 1; end if(!read_fifo_empty && rd_delayed)begin rd_delayed = 0; arvalid_flag[rresp_time_cnt] = 1'b0; tmp_fifo_rd = read_fifo[rd_fifo_rd_ptr[int_cntr_width-2:0]]; rd_v_b = (tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb]+1)(2*tmp_fifo_rd[rd_afi_siz_msb : rd_afi_siz_lsb]); temp_read_data = tmp_fifo_rd[rd_afi_data_msb : rd_afi_data_lsb]; if(tmp_fifo_rd[rd_afi_brst_msb : rd_afi_brst_lsb] === AXI_WRAP) begin get_wrap_aligned_rd_data(aligned_rd_data, tmp_fifo_rd[rd_afi_addr_msb : rd_afi_addr_lsb], tmp_fifo_rd[rd_afi_data_msb : rd_afi_data_lsb], rd_v_b); temp_read_data = aligned_rd_data; end temp_read_rsp = 0; repeat(axi_burst_len) begin temp_read_rsp = temp_read_rsp >> axi_rsp_width; temp_read_rsp[(axi_rsp_widthaxi_burst_len)-1:(axi_rsp_width*axi_burst_len)-axi_rsp_width] = tmp_fifo_rd[rd_afi_rsp_msb : rd_afi_rsp_lsb]; end slave.SEND_READ_BURST_RESP_CTRL(tmp_fifo_rd[rd_afi_id_msb : rd_afi_id_lsb], tmp_fifo_rd[rd_afi_addr_msb : rd_afi_addr_lsb], tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb], tmp_fifo_rd[rd_afi_siz_msb : rd_afi_siz_lsb], tmp_fifo_rd[rd_afi_brst_msb : rd_afi_brst_lsb], temp_read_data, temp_read_rsp); rcount = rcount - (tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb]+ 1) ; rresp_time_cnt = rresp_time_cnt+1; rd_latency_count = get_rd_lat_number(1); rd_fifo_rd_ptr = rd_fifo_rd_ptr+1; end end /// else end /// always endmodule
module / / Internal counters that are used as Read/Write pointers to the fifo's that store all the transaction info on all channles. This parameter is used to define the width of these pointers --> depending on Maximum outstanding transactions supported. 1-bit extra width than the no.of.bits needed to represent the outstanding transactions Extra bit helps in generating the empty and full flags / parameter int_cntr_width = clogb2(max_outstanding_transactions)+1; / RESP data / parameter rsp_fifo_bits = axi_rsp_width+id_bus_width; parameter rsp_lsb = 0; parameter rsp_msb = axi_rsp_width-1; parameter rsp_id_lsb = rsp_msb + 1; parameter rsp_id_msb = rsp_id_lsb + id_bus_width-1; input S_RESETN; output S_ARREADY; output S_AWREADY; output S_BVALID; output S_RLAST; output S_RVALID; output S_WREADY; output [axi_rsp_width-1:0] S_BRESP; output [axi_rsp_width-1:0] S_RRESP; output [data_bus_width-1:0] S_RDATA; output [id_bus_width-1:0] S_BID; output [id_bus_width-1:0] S_RID; input S_ACLK; input S_ARVALID; input S_AWVALID; input S_BREADY; input S_RREADY; input S_WLAST; input S_WVALID; input [axi_brst_type_width-1:0] S_ARBURST; input [axi_lock_width-1:0] S_ARLOCK; input [axi_size_width-1:0] S_ARSIZE; input [axi_brst_type_width-1:0] S_AWBURST; input [axi_lock_width-1:0] S_AWLOCK; input [axi_size_width-1:0] S_AWSIZE; input [axi_prot_width-1:0] S_ARPROT; input [axi_prot_width-1:0] S_AWPROT; input [address_bus_width-1:0] S_ARADDR; input [address_bus_width-1:0] S_AWADDR; input [data_bus_width-1:0] S_WDATA; input [axi_cache_width-1:0] S_ARCACHE; input [axi_cache_width-1:0] S_ARLEN; input [axi_qos_width-1:0] S_ARQOS; input [axi_cache_width-1:0] S_AWCACHE; input [axi_len_width-1:0] S_AWLEN; input [axi_qos_width-1:0] S_AWQOS; input [(data_bus_width/8)-1:0] S_WSTRB; input [id_bus_width-1:0] S_ARID; input [id_bus_width-1:0] S_AWID; input [id_bus_width-1:0] S_WID; input SW_CLK; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output [max_burst_bits-1:0] WR_DATA; output [addr_width-1:0] WR_ADDR; output [max_transfer_bytes_width:0] WR_BYTES; output reg RD_REQ_OCM, RD_REQ_DDR; output reg [addr_width-1:0] RD_ADDR; input [max_burst_bits-1:0] RD_DATA_DDR,RD_DATA_OCM; output reg[max_transfer_bytes_width:0] RD_BYTES; input RD_DATA_VALID_OCM,RD_DATA_VALID_DDR; output [axi_qos_width-1:0] WR_QOS; output reg [axi_qos_width-1:0] RD_QOS; input S_RDISSUECAP1_EN; input S_WRISSUECAP1_EN; output [7:0] S_RCOUNT; output [7:0] S_WCOUNT; output [2:0] S_RACOUNT; output [5:0] S_WACOUNT; wire net_ARVALID; wire net_AWVALID; wire net_WVALID; real s_aclk_period; cdn_axi3_slave_bfm #(slave_name, data_bus_width, address_bus_width, id_bus_width, slave_base_address, (slave_high_address- slave_base_address), max_outstanding_transactions, 0, ///MEMORY_MODEL_MODE, exclusive_access_supported) slave (.ACLK (S_ACLK), .ARESETn (S_RESETN), /// confirm this // Write Address Channel .AWID (S_AWID), .AWADDR (S_AWADDR), .AWLEN (S_AWLEN), .AWSIZE (S_AWSIZE), .AWBURST (S_AWBURST), .AWLOCK (S_AWLOCK), .AWCACHE (S_AWCACHE), .AWPROT (S_AWPROT), .AWVALID (net_AWVALID), .AWREADY (S_AWREADY), // Write Data Channel Signals. .WID (S_WID), .WDATA (S_WDATA), .WSTRB (S_WSTRB), .WLAST (S_WLAST), .WVALID (net_WVALID), .WREADY (S_WREADY), // Write Response Channel Signals. .BID (S_BID), .BRESP (S_BRESP), .BVALID (S_BVALID), .BREADY (S_BREADY), // Read Address Channel Signals. .ARID (S_ARID), .ARADDR (S_ARADDR), .ARLEN (S_ARLEN), .ARSIZE (S_ARSIZE), .ARBURST (S_ARBURST), .ARLOCK (S_ARLOCK), .ARCACHE (S_ARCACHE), .ARPROT (S_ARPROT), .ARVALID (net_ARVALID), .ARREADY (S_ARREADY), // Read Data Channel Signals. .RID (S_RID), .RDATA (S_RDATA), .RRESP (S_RRESP), .RLAST (S_RLAST), .RVALID (S_RVALID), .RREADY (S_RREADY)); wire wr_intr_fifo_full; reg temp_wr_intr_fifo_full; / Interconnect WR_FIFO model instance / processing_system7_bfm_v2_0_5_intr_wr_mem wr_intr_fifo(SW_CLK, S_RESETN, wr_intr_fifo_full, WR_DATA_ACK_OCM, WR_DATA_ACK_DDR, WR_ADDR, WR_DATA, WR_BYTES, WR_QOS, WR_DATA_VALID_OCM, WR_DATA_VALID_DDR); / Register the async 'full' signal to S_ACLK clock / always@(posedge S_ACLK) temp_wr_intr_fifo_full = wr_intr_fifo_full; / Latency type and Debug/Error Control / reg[1:0] latency_type = RANDOM_CASE; reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1'b1; / Internal nets/regs for calling slave BFM API's/ reg [wr_afi_fifo_data_bits-1:0] wr_fifo [0:max_outstanding_transactions-1]; reg [int_cntr_width-1:0] wr_fifo_wr_ptr = 0, wr_fifo_rd_ptr = 0; wire wr_fifo_empty; / Store the awvalid receive time --- necessary for calculating the bresp latency / reg [7:0] aw_time_cnt = 0,bresp_time_cnt = 0; real awvalid_receive_time[0:max_outstanding_transactions]; // store the time when a new awvalid is received reg awvalid_flag[0:max_outstanding_transactions]; // store the time when a new awvalid is received / Address Write Channel handshake/ reg[int_cntr_width-1:0] aw_cnt = 0;// / various FIFOs for storing the ADDR channel info / reg [axi_size_width-1:0] awsize [0:max_outstanding_transactions-1]; reg [axi_prot_width-1:0] awprot [0:max_outstanding_transactions-1]; reg [axi_lock_width-1:0] awlock [0:max_outstanding_transactions-1]; reg [axi_cache_width-1:0] awcache [0:max_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] awbrst [0:max_outstanding_transactions-1]; reg [axi_len_width-1:0] awlen [0:max_outstanding_transactions-1]; reg aw_flag [0:max_outstanding_transactions-1]; reg [addr_width-1:0] awaddr [0:max_outstanding_transactions-1]; reg [id_bus_width-1:0] awid [0:max_outstanding_transactions-1]; reg [axi_qos_width-1:0] awqos [0:max_outstanding_transactions-1]; wire aw_fifo_full; // indicates awvalid_fifo is full (max outstanding transactions reached) / internal fifos to store burst write data, ID & strobes/ reg [(data_bus_widthaxi_burst_len)-1:0] burst_data [0:max_outstanding_transactions-1]; reg [max_burst_bytes_width:0] burst_valid_bytes [0:max_outstanding_transactions-1]; /// total valid bytes received in a complete burst transfer reg wlast_flag [0:max_outstanding_transactions-1]; // flag to indicate WLAST received wire wd_fifo_full; /* Write Data Channel and Write Response handshake signals/ reg [int_cntr_width-1:0] wd_cnt = 0; reg [(data_bus_widthaxi_burst_len)-1:0] aligned_wr_data; reg [addr_width-1:0] aligned_wr_addr; reg [max_burst_bytes_width:0] valid_data_bytes; reg [int_cntr_width-1:0] wr_bresp_cnt = 0; reg [axi_rsp_width-1:0] bresp; reg [rsp_fifo_bits-1:0] fifo_bresp [0:max_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_bresp; reg [int_cntr_width-1:0] rd_bresp_cnt = 0; integer wr_latency_count; reg wr_delayed; wire bresp_fifo_empty; /* keep track of count values / reg[7:0] wcount; reg[5:0] wacount; / Qos/ reg [axi_qos_width-1:0] ar_qos, aw_qos; initial begin if(DEBUG_INFO) begin if(enable_this_port) $display("[%0d] : %0s : %0s : Port is ENABLED.",$time, DISP_INFO, slave_name); else $display("[%0d] : %0s : %0s : Port is DISABLED.",$time, DISP_INFO, slave_name); end end /--------------------------------------------------------------------------------/ / Store the Clock cycle time period / always@(S_RESETN) begin if(S_RESETN) begin @(posedge S_ACLK); s_aclk_period = $time; @(posedge S_ACLK); s_aclk_period = $time - s_aclk_period; end end /--------------------------------------------------------------------------------/ initial slave.set_disable_reset_value_checks(1); initial begin repeat(2) @(posedge S_ACLK); if(!enable_this_port) begin slave.set_channel_level_info(0); slave.set_function_level_info(0); end slave.RESPONSE_TIMEOUT = 0; end /--------------------------------------------------------------------------------/ / Set Latency type to be used / task set_latency_type; input[1:0] lat; begin if(enable_this_port) latency_type = lat; else begin //if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'Latency Profile' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / Set ARQoS to be used / task set_arqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) ar_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'ARQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / Set AWQoS to be used / task set_awqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) aw_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'AWQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / get the wr latency number / function [31:0] get_wr_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : get_wr_lat_number = afi_wr_min; AVG_CASE : get_wr_lat_number = afi_wr_avg; WORST_CASE : get_wr_lat_number = afi_wr_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : get_wr_lat_number = ($random()%10+ afi_wr_min); 2'b01 : get_wr_lat_number = ($random()%40+ afi_wr_avg); default : get_wr_lat_number = ($random()%60+ afi_wr_max); endcase end endcase end endfunction /--------------------------------------------------------------------------------/ / get the rd latency number / function [31:0] get_rd_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : get_rd_lat_number = afi_rd_min; AVG_CASE : get_rd_lat_number = afi_rd_avg; WORST_CASE : get_rd_lat_number = afi_rd_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : get_rd_lat_number = ($random()%10+ afi_rd_min); 2'b01 : get_rd_lat_number = ($random()%40+ afi_rd_avg); default : get_rd_lat_number = ($random()%60+ afi_rd_max); endcase end endcase end endfunction /--------------------------------------------------------------------------------/ / Check for any WRITE/READs when this port is disabled / always@(S_AWVALID or S_WVALID or S_ARVALID) begin if((S_AWVALID \| S_WVALID \| S_ARVALID) && !enable_this_port) begin $display("[%0d] : %0s : %0s : Port is disabled. AXI transaction is initiated on this port ...\nSimulation will halt ..",$time, DISP_ERR, slave_name); $stop; end end /--------------------------------------------------------------------------------/ assign net_ARVALID = enable_this_port ? S_ARVALID : 1'b0; assign net_AWVALID = enable_this_port ? S_AWVALID : 1'b0; assign net_WVALID = enable_this_port ? S_WVALID : 1'b0; assign wr_fifo_empty = (wr_fifo_wr_ptr === wr_fifo_rd_ptr)?1'b1: 1'b0; assign bresp_fifo_empty = (wr_bresp_cnt === rd_bresp_cnt)?1'b1:1'b0; assign bresp_fifo_full = ((wr_bresp_cnt[int_cntr_width-1] !== rd_bresp_cnt[int_cntr_width-1]) && (wr_bresp_cnt[int_cntr_width-2:0] === rd_bresp_cnt[int_cntr_width-2:0]))?1'b1:1'b0; assign S_WCOUNT = wcount; assign S_WACOUNT = wacount; // FIFO_STATUS (only if AFI port) 1- full function automatic wrfifo_full ; input [axi_len_width:0] fifo_space_exp; integer fifo_space_left; begin fifo_space_left = afi_fifo_locations - wcount; if(fifo_space_left < fifo_space_exp) wrfifo_full = 1; else wrfifo_full = 0; end endfunction /--------------------------------------------------------------------------------/ / Store the awvalid receive time --- necessary for calculating the bresp latency / always@(negedge S_RESETN or S_AWID or S_AWADDR or S_AWVALID ) begin if(!S_RESETN) aw_time_cnt = 0; else begin if(S_AWVALID) begin awvalid_receive_time[aw_time_cnt] = $time; awvalid_flag[aw_time_cnt] = 1'b1; aw_time_cnt = aw_time_cnt + 1; end end // else end /// always /--------------------------------------------------------------------------------/ always@(posedge S_ACLK) begin if(net_AWVALID && S_AWREADY) begin if(S_AWQOS === 0) awqos[aw_cnt[int_cntr_width-2:0]] = aw_qos; else awqos[aw_cnt[int_cntr_width-2:0]] = S_AWQOS; end end / Address Write Channel handshake/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin aw_cnt = 0; wacount = 0; end else begin if(S_AWVALID && !wrfifo_full(S_AWLEN+1)) begin slave.RECEIVE_WRITE_ADDRESS(0, id_invalid, awaddr[aw_cnt[int_cntr_width-2:0]], awlen[aw_cnt[int_cntr_width-2:0]], awsize[aw_cnt[int_cntr_width-2:0]], awbrst[aw_cnt[int_cntr_width-2:0]], awlock[aw_cnt[int_cntr_width-2:0]], awcache[aw_cnt[int_cntr_width-2:0]], awprot[aw_cnt[int_cntr_width-2:0]], awid[aw_cnt[int_cntr_width-2:0]]); /// sampled valid ID. aw_flag[aw_cnt[int_cntr_width-2:0]] = 1'b1; aw_cnt = aw_cnt + 1; wacount = wacount + 1; end // if (!aw_fifo_full) end /// if else end /// always /--------------------------------------------------------------------------------/ / Write Data Channel Handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wd_cnt = 0; end else begin if(aw_flag[wd_cnt[int_cntr_width-2:0]]) begin if(S_WVALID && !wrfifo_full(awlen[wd_cnt[int_cntr_width-2:0]] + 1)) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_cntr_width-2:0]]); wlast_flag[wd_cnt[int_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; end end else begin if(!wrfifo_full(axi_burst_len+1) && S_WVALID) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_cntr_width-2:0]]); wlast_flag[wd_cnt[int_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; end end /// if end /// else end /// always /--------------------------------------------------------------------------------/ / Align the wrap data for write transaction / task automatic get_wrap_aligned_wr_data; output [(data_bus_widthaxi_burst_len)-1:0] aligned_data; output [addr_width-1:0] start_addr; /// aligned start address input [addr_width-1:0] addr; input [(data_bus_widthaxi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [(data_bus_widthaxi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; wrp_data = wrp_data << ((data_bus_widthaxi_burst_len) - (v_bytes8)); while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data << 8; temp_data[7:0] = wrp_data[(data_bus_widthaxi_burst_len)-1 : (data_bus_widthaxi_burst_len)-8]; wrp_data = wrp_data << 8; wrp_bytes = wrp_bytes - 1; end wrp_bytes = addr - start_addr; wrp_data = b_data << (wrp_bytes8); aligned_data = (temp_data \| wrp_data); end endtask /--------------------------------------------------------------------------------/ / Calculate the Response for each read/write transaction / function [axi_rsp_width-1:0] calculate_resp; input [addr_width-1:0] awaddr; input [axi_prot_width-1:0] awprot; reg [axi_rsp_width-1:0] rsp; begin rsp = AXI_OK; / Address Decode / if(decode_address(awaddr) === INVALID_MEM_TYPE) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Invalid location(0x%0h) ",$time, DISP_ERR, slave_name, awaddr); end else if(decode_address(awaddr) === REG_MEM) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Register Map(0x%0h) is not allowed through this port.",$time, DISP_ERR, slave_name, awaddr); end if(secure_access_enabled && awprot[1]) rsp = AXI_DEC_ERR; // decode error calculate_resp = rsp; end endfunction /--------------------------------------------------------------------------------/ reg[max_burst_bits-1:0] temp_wr_data; / Store the Write response for each write transaction / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_fifo_wr_ptr = 0; wcount = 0; end else begin enable_write_bresp = aw_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] && wlast_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]]; / calculate bresp only when AWVALID && WLAST is received / if(enable_write_bresp) begin aw_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] = 0; wlast_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] = 0; bresp = calculate_resp(awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]], awprot[wr_fifo_wr_ptr[int_cntr_width-2:0]]); / Fill AFI_WR_data FIFO / if(bresp === AXI_OK ) begin if(awbrst[wr_fifo_wr_ptr[int_cntr_width-2:0]]=== AXI_WRAP) begin /// wrap type? then align the data get_wrap_aligned_wr_data(aligned_wr_data, aligned_wr_addr, awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]], burst_data[wr_fifo_wr_ptr[int_cntr_width-2:0]],burst_valid_bytes[wr_fifo_wr_ptr[int_cntr_width-2:0]]); /// gives wrapped start address end else begin aligned_wr_data = burst_data[wr_fifo_wr_ptr[int_cntr_width-2:0]]; aligned_wr_addr = awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]] ; end valid_data_bytes = burst_valid_bytes[wr_fifo_wr_ptr[int_cntr_width-2:0]]; end else valid_data_bytes = 0; temp_wr_data = aligned_wr_data; wr_fifo[wr_fifo_wr_ptr[int_cntr_width-2:0]] = {awqos[wr_fifo_wr_ptr[int_cntr_width-2:0]], awlen[wr_fifo_wr_ptr[int_cntr_width-2:0]], awid[wr_fifo_wr_ptr[int_cntr_width-2:0]], bresp, temp_wr_data, aligned_wr_addr, valid_data_bytes}; wcount = wcount + awlen[wr_fifo_wr_ptr[int_cntr_width-2:0]]+1; wr_fifo_wr_ptr = wr_fifo_wr_ptr + 1; end end // else end // always /--------------------------------------------------------------------------------/ / Send Write Response Channel handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin rd_bresp_cnt = 0; wr_latency_count = get_wr_lat_number(1); wr_delayed = 0; bresp_time_cnt = 0; end else begin wr_delayed = 1'b0; if(awvalid_flag[bresp_time_cnt] && (($time - awvalid_receive_time[bresp_time_cnt])/s_aclk_period >= wr_latency_count)) wr_delayed = 1; if(!bresp_fifo_empty && wr_delayed) begin slave.SEND_WRITE_RESPONSE(fifo_bresp[rd_bresp_cnt[int_cntr_width-2:0]][rsp_id_msb : rsp_id_lsb], // ID fifo_bresp[rd_bresp_cnt[int_cntr_width-2:0]][rsp_msb : rsp_lsb] // Response ); wr_delayed = 0; awvalid_flag[bresp_time_cnt] = 1'b0; bresp_time_cnt = bresp_time_cnt+1; rd_bresp_cnt = rd_bresp_cnt + 1; wr_latency_count = get_wr_lat_number(1); end end // else end//always /--------------------------------------------------------------------------------/ / Write Response Channel handshake / reg wr_int_state; / Reading from the wr_fifo and sending to Interconnect fifo/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_int_state = 1'b0; wr_bresp_cnt = 0; wr_fifo_rd_ptr = 0; end else begin case(wr_int_state) 1'b0 : begin wr_int_state = 1'b0; if(!temp_wr_intr_fifo_full && !bresp_fifo_full && !wr_fifo_empty) begin wr_intr_fifo.write_mem({wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_qos_msb:wr_afi_qos_lsb], wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_data_msb:wr_afi_bytes_lsb]}); /// qos, data, address and valid_bytes wr_int_state = 1'b1; / start filling the write response fifo at the same time / fifo_bresp[wr_bresp_cnt[int_cntr_width-2:0]] = wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_id_msb:wr_afi_rsp_lsb]; // ID and Resp wcount = wcount - (wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_ln_msb:wr_afi_ln_lsb] + 1); /// burst length wacount = wacount - 1; wr_fifo_rd_ptr = wr_fifo_rd_ptr + 1; wr_bresp_cnt = wr_bresp_cnt+1; end end 1'b1 : begin wr_int_state = 0; end endcase end end /--------------------------------------------------------------------------------/ /-------------------------------- WRITE HANDSHAKE END ----------------------------------------/ /-------------------------------- READ HANDSHAKE ---------------------------------------------/ / READ CHANNELS / / Store the arvalid receive time --- necessary for calculating latency in sending the rresp latency / reg [7:0] ar_time_cnt = 0,rresp_time_cnt = 0; real arvalid_receive_time[0:max_outstanding_transactions]; // store the time when a new arvalid is received reg arvalid_flag[0:max_outstanding_transactions]; // store the time when a new arvalid is received reg [int_cntr_width-1:0] ar_cnt = 0;// counter for arvalid info / various FIFOs for storing the ADDR channel info / reg [axi_size_width-1:0] arsize [0:max_outstanding_transactions-1]; reg [axi_prot_width-1:0] arprot [0:max_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] arbrst [0:max_outstanding_transactions-1]; reg [axi_len_width-1:0] arlen [0:max_outstanding_transactions-1]; reg [axi_cache_width-1:0] arcache [0:max_outstanding_transactions-1]; reg [axi_lock_width-1:0] arlock [0:max_outstanding_transactions-1]; reg ar_flag [0:max_outstanding_transactions-1]; reg [addr_width-1:0] araddr [0:max_outstanding_transactions-1]; reg [id_bus_width-1:0] arid [0:max_outstanding_transactions-1]; reg [axi_qos_width-1:0] arqos [0:max_outstanding_transactions-1]; wire ar_fifo_full; // indicates arvalid_fifo is full (max outstanding transactions reached) reg [int_cntr_width-1:0] wr_rresp_cnt = 0; reg [axi_rsp_width-1:0] rresp; reg [rsp_fifo_bits-1:0] fifo_rresp [0:max_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_rresp; / Send Read Response & Data Channel handshake / integer rd_latency_count; reg rd_delayed; reg [rd_afi_fifo_bits-1:0] read_fifo[0:max_outstanding_transactions-1]; /// Read Burst Data, addr, size, burst, len, RID, RRESP, valid_bytes reg [int_cntr_width-1:0] rd_fifo_wr_ptr = 0, rd_fifo_rd_ptr = 0; wire read_fifo_full; reg [7:0] rcount; reg [2:0] racount; wire rd_intr_fifo_full, rd_intr_fifo_empty; wire read_fifo_empty; / signals to communicate with interconnect RD_FIFO model / reg rd_req, invalid_rd_req; / REad control Info 56:25 : Address (32) 24:22 : Size (3) 21:20 : BRST (2) 19:16 : LEN (4) 15:10 : RID (6) 9:8 : RRSP (2) 7:0 : byte cnt (8) / reg [rd_info_bits-1:0] read_control_info; reg [(data_bus_widthaxi_burst_len)-1:0] aligned_rd_data; reg temp_rd_intr_fifo_empty; processing_system7_bfm_v2_0_5_intr_rd_mem rd_intr_fifo(SW_CLK, S_RESETN, rd_intr_fifo_full, rd_intr_fifo_empty, rd_req, invalid_rd_req, read_control_info , RD_DATA_OCM, RD_DATA_DDR, RD_DATA_VALID_OCM, RD_DATA_VALID_DDR); assign read_fifo_empty = (rd_fifo_wr_ptr === rd_fifo_rd_ptr)?1'b1: 1'b0; assign S_RCOUNT = rcount; assign S_RACOUNT = racount; /* Register the asynch signal empty coming from Interconnect READ FIFO / always@(posedge S_ACLK) temp_rd_intr_fifo_empty = rd_intr_fifo_empty; // FIFO_STATUS (only if AFI port) 1- full function automatic rdfifo_full ; input [axi_len_width:0] fifo_space_exp; integer fifo_space_left; begin fifo_space_left = afi_fifo_locations - rcount; if(fifo_space_left < fifo_space_exp) rdfifo_full = 1; else rdfifo_full = 0; end endfunction / Store the arvalid receive time --- necessary for calculating the bresp latency / always@(negedge S_RESETN or S_ARID or S_ARADDR or S_ARVALID ) begin if(!S_RESETN) ar_time_cnt = 0; else begin if(S_ARVALID) begin arvalid_receive_time[ar_time_cnt] = $time; arvalid_flag[ar_time_cnt] = 1'b1; ar_time_cnt = ar_time_cnt + 1; end end // else end /// always /--------------------------------------------------------------------------------/ always@(posedge S_ACLK) begin if(net_ARVALID && S_ARREADY) begin if(S_ARQOS === 0) arqos[aw_cnt[int_cntr_width-2:0]] = ar_qos; else arqos[aw_cnt[int_cntr_width-2:0]] = S_ARQOS; end end / Address Read Channel handshake/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin ar_cnt = 0; racount = 0; end else begin if(S_ARVALID && !rdfifo_full(S_ARLEN+1)) begin /// if AFI read fifo is not full slave.RECEIVE_READ_ADDRESS(0, id_invalid, araddr[ar_cnt[int_cntr_width-2:0]], arlen[ar_cnt[int_cntr_width-2:0]], arsize[ar_cnt[int_cntr_width-2:0]], arbrst[ar_cnt[int_cntr_width-2:0]], arlock[ar_cnt[int_cntr_width-2:0]], arcache[ar_cnt[int_cntr_width-2:0]], arprot[ar_cnt[int_cntr_width-2:0]], arid[ar_cnt[int_cntr_width-2:0]]); /// sampled valid ID. ar_flag[ar_cnt[int_cntr_width-2:0]] = 1'b1; ar_cnt = ar_cnt+1; racount = racount + 1; end /// if(!ar_fifo_full) end /// if else end /// always/ /--------------------------------------------------------------------------------/ /* Align Wrap data for read transaction/ task automatic get_wrap_aligned_rd_data; output [(data_bus_widthaxi_burst_len)-1:0] aligned_data; input [addr_width-1:0] addr; input [(data_bus_widthaxi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [addr_width-1:0] start_addr; reg [(data_bus_widthaxi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data >> 8; temp_data[(data_bus_widthaxi_burst_len)-1 : (data_bus_widthaxi_burst_len)-8] = wrp_data[7:0]; wrp_data = wrp_data >> 8; wrp_bytes = wrp_bytes - 1; end temp_data = temp_data >> ((data_bus_widthaxi_burst_len) - (v_bytes8)); wrp_bytes = addr - start_addr; wrp_data = b_data >> (wrp_bytes8); aligned_data = (temp_data \| wrp_data); end endtask /--------------------------------------------------------------------------------/ parameter RD_DATA_REQ = 1'b0, WAIT_RD_VALID = 1'b1; reg rd_fifo_state; reg [addr_width-1:0] temp_read_address; reg [max_burst_bytes_width:0] temp_rd_valid_bytes; / get the data from memory && also calculate the rresp/ always@(negedge S_RESETN or posedge SW_CLK) begin if(!S_RESETN)begin wr_rresp_cnt =0; rd_fifo_state = RD_DATA_REQ; temp_rd_valid_bytes = 0; temp_read_address = 0; RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; rd_req = 0; invalid_rd_req= 0; RD_QOS = 0; end else begin case(rd_fifo_state) RD_DATA_REQ : begin rd_fifo_state = RD_DATA_REQ; RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; invalid_rd_req = 0; if(ar_flag[wr_rresp_cnt[int_cntr_width-2:0]] && !rd_intr_fifo_full) begin /// check the rd_fifo_bytes, interconnect fifo full condition ar_flag[wr_rresp_cnt[int_cntr_width-2:0]] = 0; rresp = calculate_resp(araddr[wr_rresp_cnt[int_cntr_width-2:0]],arprot[wr_rresp_cnt[int_cntr_width-2:0]]); temp_rd_valid_bytes = (arlen[wr_rresp_cnt[int_cntr_width-2:0]]+1)(2*arsize[wr_rresp_cnt[int_cntr_width-2:0]]);//data_bus_width/8; if(arbrst[wr_rresp_cnt[int_cntr_width-2:0]] === AXI_WRAP) /// wrap begin temp_read_address = (araddr[wr_rresp_cnt[int_cntr_width-2:0]]/temp_rd_valid_bytes) temp_rd_valid_bytes; else temp_read_address = araddr[wr_rresp_cnt[int_cntr_width-2:0]]; if(rresp === AXI_OK) begin case(decode_address(temp_read_address))//decode_address(araddr[wr_rresp_cnt[int_cntr_width-2:0]]); OCM_MEM : RD_REQ_OCM = 1; DDR_MEM : RD_REQ_DDR = 1; default : invalid_rd_req = 1; endcase end else invalid_rd_req = 1; RD_ADDR = temp_read_address; ///araddr[wr_rresp_cnt[int_cntr_width-2:0]]; RD_BYTES = temp_rd_valid_bytes; RD_QOS = arqos[wr_rresp_cnt[int_cntr_width-2:0]]; rd_fifo_state = WAIT_RD_VALID; rd_req = 1; racount = racount - 1; read_control_info = {araddr[wr_rresp_cnt[int_cntr_width-2:0]], arsize[wr_rresp_cnt[int_cntr_width-2:0]], arbrst[wr_rresp_cnt[int_cntr_width-2:0]], arlen[wr_rresp_cnt[int_cntr_width-2:0]], arid[wr_rresp_cnt[int_cntr_width-2:0]], rresp, temp_rd_valid_bytes }; wr_rresp_cnt = wr_rresp_cnt + 1; end end WAIT_RD_VALID : begin rd_fifo_state = WAIT_RD_VALID; rd_req = 0; if(RD_DATA_VALID_OCM \| RD_DATA_VALID_DDR \| invalid_rd_req) begin ///temp_dec == 2'b11) begin RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; invalid_rd_req = 0; rd_fifo_state = RD_DATA_REQ; end end endcase end /// else end /// always /--------------------------------------------------------------------------------/ /* thread to fill in the AFI RD_FIFO / reg[rd_afi_fifo_bits-1:0] temp_rd_data;//Read Burst Data, addr, size, burst, len, RID, RRESP, valid bytes reg tmp_state; always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_wr_ptr = 0; rcount = 0; tmp_state = 0; end else begin case(tmp_state) 0 : begin tmp_state = 0; if(!temp_rd_intr_fifo_empty) begin rd_intr_fifo.read_mem(temp_rd_data); tmp_state = 1; end end 1 : begin tmp_state = 1; if(!rdfifo_full(temp_rd_data[rd_afi_ln_msb:rd_afi_ln_lsb]+1)) begin read_fifo[rd_fifo_wr_ptr[int_cntr_width-2:0]] = temp_rd_data; rd_fifo_wr_ptr = rd_fifo_wr_ptr + 1; rcount = rcount + temp_rd_data[rd_afi_ln_msb:rd_afi_ln_lsb]+1; /// Burst length tmp_state = 0; end end endcase end end /--------------------------------------------------------------------------------/ reg[max_burst_bytes_width:0] rd_v_b; reg[rd_afi_fifo_bits-1:0] tmp_fifo_rd; /// Data, addr, size, burst, len, RID, RRESP,valid_bytes reg[(data_bus_widthaxi_burst_len)-1:0] temp_read_data; reg[(axi_rsp_widthaxi_burst_len)-1:0] temp_read_rsp; / Read Data Channel handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_rd_ptr = 0; rd_latency_count = get_rd_lat_number(1); rd_delayed = 0; rresp_time_cnt = 0; rd_v_b = 0; end else begin if(arvalid_flag[rresp_time_cnt] && ((($time - arvalid_receive_time[rresp_time_cnt])/s_aclk_period) >= rd_latency_count)) begin rd_delayed = 1; end if(!read_fifo_empty && rd_delayed)begin rd_delayed = 0; arvalid_flag[rresp_time_cnt] = 1'b0; tmp_fifo_rd = read_fifo[rd_fifo_rd_ptr[int_cntr_width-2:0]]; rd_v_b = (tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb]+1)(2*tmp_fifo_rd[rd_afi_siz_msb : rd_afi_siz_lsb]); temp_read_data = tmp_fifo_rd[rd_afi_data_msb : rd_afi_data_lsb]; if(tmp_fifo_rd[rd_afi_brst_msb : rd_afi_brst_lsb] === AXI_WRAP) begin get_wrap_aligned_rd_data(aligned_rd_data, tmp_fifo_rd[rd_afi_addr_msb : rd_afi_addr_lsb], tmp_fifo_rd[rd_afi_data_msb : rd_afi_data_lsb], rd_v_b); temp_read_data = aligned_rd_data; end temp_read_rsp = 0; repeat(axi_burst_len) begin temp_read_rsp = temp_read_rsp >> axi_rsp_width; temp_read_rsp[(axi_rsp_widthaxi_burst_len)-1:(axi_rsp_width*axi_burst_len)-axi_rsp_width] = tmp_fifo_rd[rd_afi_rsp_msb : rd_afi_rsp_lsb]; end slave.SEND_READ_BURST_RESP_CTRL(tmp_fifo_rd[rd_afi_id_msb : rd_afi_id_lsb], tmp_fifo_rd[rd_afi_addr_msb : rd_afi_addr_lsb], tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb], tmp_fifo_rd[rd_afi_siz_msb : rd_afi_siz_lsb], tmp_fifo_rd[rd_afi_brst_msb : rd_afi_brst_lsb], temp_read_data, temp_read_rsp); rcount = rcount - (tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb]+ 1) ; rresp_time_cnt = rresp_time_cnt+1; rd_latency_count = get_rd_lat_number(1); rd_fifo_rd_ptr = rd_fifo_rd_ptr+1; end end /// else end /// always endmodule
module / / Internal counters that are used as Read/Write pointers to the fifo's that store all the transaction info on all channles. This parameter is used to define the width of these pointers --> depending on Maximum outstanding transactions supported. 1-bit extra width than the no.of.bits needed to represent the outstanding transactions Extra bit helps in generating the empty and full flags / parameter int_cntr_width = clogb2(max_outstanding_transactions)+1; / RESP data / parameter rsp_fifo_bits = axi_rsp_width+id_bus_width; parameter rsp_lsb = 0; parameter rsp_msb = axi_rsp_width-1; parameter rsp_id_lsb = rsp_msb + 1; parameter rsp_id_msb = rsp_id_lsb + id_bus_width-1; input S_RESETN; output S_ARREADY; output S_AWREADY; output S_BVALID; output S_RLAST; output S_RVALID; output S_WREADY; output [axi_rsp_width-1:0] S_BRESP; output [axi_rsp_width-1:0] S_RRESP; output [data_bus_width-1:0] S_RDATA; output [id_bus_width-1:0] S_BID; output [id_bus_width-1:0] S_RID; input S_ACLK; input S_ARVALID; input S_AWVALID; input S_BREADY; input S_RREADY; input S_WLAST; input S_WVALID; input [axi_brst_type_width-1:0] S_ARBURST; input [axi_lock_width-1:0] S_ARLOCK; input [axi_size_width-1:0] S_ARSIZE; input [axi_brst_type_width-1:0] S_AWBURST; input [axi_lock_width-1:0] S_AWLOCK; input [axi_size_width-1:0] S_AWSIZE; input [axi_prot_width-1:0] S_ARPROT; input [axi_prot_width-1:0] S_AWPROT; input [address_bus_width-1:0] S_ARADDR; input [address_bus_width-1:0] S_AWADDR; input [data_bus_width-1:0] S_WDATA; input [axi_cache_width-1:0] S_ARCACHE; input [axi_cache_width-1:0] S_ARLEN; input [axi_qos_width-1:0] S_ARQOS; input [axi_cache_width-1:0] S_AWCACHE; input [axi_len_width-1:0] S_AWLEN; input [axi_qos_width-1:0] S_AWQOS; input [(data_bus_width/8)-1:0] S_WSTRB; input [id_bus_width-1:0] S_ARID; input [id_bus_width-1:0] S_AWID; input [id_bus_width-1:0] S_WID; input SW_CLK; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output [max_burst_bits-1:0] WR_DATA; output [addr_width-1:0] WR_ADDR; output [max_transfer_bytes_width:0] WR_BYTES; output reg RD_REQ_OCM, RD_REQ_DDR; output reg [addr_width-1:0] RD_ADDR; input [max_burst_bits-1:0] RD_DATA_DDR,RD_DATA_OCM; output reg[max_transfer_bytes_width:0] RD_BYTES; input RD_DATA_VALID_OCM,RD_DATA_VALID_DDR; output [axi_qos_width-1:0] WR_QOS; output reg [axi_qos_width-1:0] RD_QOS; input S_RDISSUECAP1_EN; input S_WRISSUECAP1_EN; output [7:0] S_RCOUNT; output [7:0] S_WCOUNT; output [2:0] S_RACOUNT; output [5:0] S_WACOUNT; wire net_ARVALID; wire net_AWVALID; wire net_WVALID; real s_aclk_period; cdn_axi3_slave_bfm #(slave_name, data_bus_width, address_bus_width, id_bus_width, slave_base_address, (slave_high_address- slave_base_address), max_outstanding_transactions, 0, ///MEMORY_MODEL_MODE, exclusive_access_supported) slave (.ACLK (S_ACLK), .ARESETn (S_RESETN), /// confirm this // Write Address Channel .AWID (S_AWID), .AWADDR (S_AWADDR), .AWLEN (S_AWLEN), .AWSIZE (S_AWSIZE), .AWBURST (S_AWBURST), .AWLOCK (S_AWLOCK), .AWCACHE (S_AWCACHE), .AWPROT (S_AWPROT), .AWVALID (net_AWVALID), .AWREADY (S_AWREADY), // Write Data Channel Signals. .WID (S_WID), .WDATA (S_WDATA), .WSTRB (S_WSTRB), .WLAST (S_WLAST), .WVALID (net_WVALID), .WREADY (S_WREADY), // Write Response Channel Signals. .BID (S_BID), .BRESP (S_BRESP), .BVALID (S_BVALID), .BREADY (S_BREADY), // Read Address Channel Signals. .ARID (S_ARID), .ARADDR (S_ARADDR), .ARLEN (S_ARLEN), .ARSIZE (S_ARSIZE), .ARBURST (S_ARBURST), .ARLOCK (S_ARLOCK), .ARCACHE (S_ARCACHE), .ARPROT (S_ARPROT), .ARVALID (net_ARVALID), .ARREADY (S_ARREADY), // Read Data Channel Signals. .RID (S_RID), .RDATA (S_RDATA), .RRESP (S_RRESP), .RLAST (S_RLAST), .RVALID (S_RVALID), .RREADY (S_RREADY)); wire wr_intr_fifo_full; reg temp_wr_intr_fifo_full; / Interconnect WR_FIFO model instance / processing_system7_bfm_v2_0_5_intr_wr_mem wr_intr_fifo(SW_CLK, S_RESETN, wr_intr_fifo_full, WR_DATA_ACK_OCM, WR_DATA_ACK_DDR, WR_ADDR, WR_DATA, WR_BYTES, WR_QOS, WR_DATA_VALID_OCM, WR_DATA_VALID_DDR); / Register the async 'full' signal to S_ACLK clock / always@(posedge S_ACLK) temp_wr_intr_fifo_full = wr_intr_fifo_full; / Latency type and Debug/Error Control / reg[1:0] latency_type = RANDOM_CASE; reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1'b1; / Internal nets/regs for calling slave BFM API's/ reg [wr_afi_fifo_data_bits-1:0] wr_fifo [0:max_outstanding_transactions-1]; reg [int_cntr_width-1:0] wr_fifo_wr_ptr = 0, wr_fifo_rd_ptr = 0; wire wr_fifo_empty; / Store the awvalid receive time --- necessary for calculating the bresp latency / reg [7:0] aw_time_cnt = 0,bresp_time_cnt = 0; real awvalid_receive_time[0:max_outstanding_transactions]; // store the time when a new awvalid is received reg awvalid_flag[0:max_outstanding_transactions]; // store the time when a new awvalid is received / Address Write Channel handshake/ reg[int_cntr_width-1:0] aw_cnt = 0;// / various FIFOs for storing the ADDR channel info / reg [axi_size_width-1:0] awsize [0:max_outstanding_transactions-1]; reg [axi_prot_width-1:0] awprot [0:max_outstanding_transactions-1]; reg [axi_lock_width-1:0] awlock [0:max_outstanding_transactions-1]; reg [axi_cache_width-1:0] awcache [0:max_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] awbrst [0:max_outstanding_transactions-1]; reg [axi_len_width-1:0] awlen [0:max_outstanding_transactions-1]; reg aw_flag [0:max_outstanding_transactions-1]; reg [addr_width-1:0] awaddr [0:max_outstanding_transactions-1]; reg [id_bus_width-1:0] awid [0:max_outstanding_transactions-1]; reg [axi_qos_width-1:0] awqos [0:max_outstanding_transactions-1]; wire aw_fifo_full; // indicates awvalid_fifo is full (max outstanding transactions reached) / internal fifos to store burst write data, ID & strobes/ reg [(data_bus_widthaxi_burst_len)-1:0] burst_data [0:max_outstanding_transactions-1]; reg [max_burst_bytes_width:0] burst_valid_bytes [0:max_outstanding_transactions-1]; /// total valid bytes received in a complete burst transfer reg wlast_flag [0:max_outstanding_transactions-1]; // flag to indicate WLAST received wire wd_fifo_full; /* Write Data Channel and Write Response handshake signals/ reg [int_cntr_width-1:0] wd_cnt = 0; reg [(data_bus_widthaxi_burst_len)-1:0] aligned_wr_data; reg [addr_width-1:0] aligned_wr_addr; reg [max_burst_bytes_width:0] valid_data_bytes; reg [int_cntr_width-1:0] wr_bresp_cnt = 0; reg [axi_rsp_width-1:0] bresp; reg [rsp_fifo_bits-1:0] fifo_bresp [0:max_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_bresp; reg [int_cntr_width-1:0] rd_bresp_cnt = 0; integer wr_latency_count; reg wr_delayed; wire bresp_fifo_empty; /* keep track of count values / reg[7:0] wcount; reg[5:0] wacount; / Qos/ reg [axi_qos_width-1:0] ar_qos, aw_qos; initial begin if(DEBUG_INFO) begin if(enable_this_port) $display("[%0d] : %0s : %0s : Port is ENABLED.",$time, DISP_INFO, slave_name); else $display("[%0d] : %0s : %0s : Port is DISABLED.",$time, DISP_INFO, slave_name); end end /--------------------------------------------------------------------------------/ / Store the Clock cycle time period / always@(S_RESETN) begin if(S_RESETN) begin @(posedge S_ACLK); s_aclk_period = $time; @(posedge S_ACLK); s_aclk_period = $time - s_aclk_period; end end /--------------------------------------------------------------------------------/ initial slave.set_disable_reset_value_checks(1); initial begin repeat(2) @(posedge S_ACLK); if(!enable_this_port) begin slave.set_channel_level_info(0); slave.set_function_level_info(0); end slave.RESPONSE_TIMEOUT = 0; end /--------------------------------------------------------------------------------/ / Set Latency type to be used / task set_latency_type; input[1:0] lat; begin if(enable_this_port) latency_type = lat; else begin //if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'Latency Profile' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / Set ARQoS to be used / task set_arqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) ar_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'ARQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / Set AWQoS to be used / task set_awqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) aw_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'AWQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / get the wr latency number / function [31:0] get_wr_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : get_wr_lat_number = afi_wr_min; AVG_CASE : get_wr_lat_number = afi_wr_avg; WORST_CASE : get_wr_lat_number = afi_wr_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : get_wr_lat_number = ($random()%10+ afi_wr_min); 2'b01 : get_wr_lat_number = ($random()%40+ afi_wr_avg); default : get_wr_lat_number = ($random()%60+ afi_wr_max); endcase end endcase end endfunction /--------------------------------------------------------------------------------/ / get the rd latency number / function [31:0] get_rd_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : get_rd_lat_number = afi_rd_min; AVG_CASE : get_rd_lat_number = afi_rd_avg; WORST_CASE : get_rd_lat_number = afi_rd_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : get_rd_lat_number = ($random()%10+ afi_rd_min); 2'b01 : get_rd_lat_number = ($random()%40+ afi_rd_avg); default : get_rd_lat_number = ($random()%60+ afi_rd_max); endcase end endcase end endfunction /--------------------------------------------------------------------------------/ / Check for any WRITE/READs when this port is disabled / always@(S_AWVALID or S_WVALID or S_ARVALID) begin if((S_AWVALID \| S_WVALID \| S_ARVALID) && !enable_this_port) begin $display("[%0d] : %0s : %0s : Port is disabled. AXI transaction is initiated on this port ...\nSimulation will halt ..",$time, DISP_ERR, slave_name); $stop; end end /--------------------------------------------------------------------------------/ assign net_ARVALID = enable_this_port ? S_ARVALID : 1'b0; assign net_AWVALID = enable_this_port ? S_AWVALID : 1'b0; assign net_WVALID = enable_this_port ? S_WVALID : 1'b0; assign wr_fifo_empty = (wr_fifo_wr_ptr === wr_fifo_rd_ptr)?1'b1: 1'b0; assign bresp_fifo_empty = (wr_bresp_cnt === rd_bresp_cnt)?1'b1:1'b0; assign bresp_fifo_full = ((wr_bresp_cnt[int_cntr_width-1] !== rd_bresp_cnt[int_cntr_width-1]) && (wr_bresp_cnt[int_cntr_width-2:0] === rd_bresp_cnt[int_cntr_width-2:0]))?1'b1:1'b0; assign S_WCOUNT = wcount; assign S_WACOUNT = wacount; // FIFO_STATUS (only if AFI port) 1- full function automatic wrfifo_full ; input [axi_len_width:0] fifo_space_exp; integer fifo_space_left; begin fifo_space_left = afi_fifo_locations - wcount; if(fifo_space_left < fifo_space_exp) wrfifo_full = 1; else wrfifo_full = 0; end endfunction /--------------------------------------------------------------------------------/ / Store the awvalid receive time --- necessary for calculating the bresp latency / always@(negedge S_RESETN or S_AWID or S_AWADDR or S_AWVALID ) begin if(!S_RESETN) aw_time_cnt = 0; else begin if(S_AWVALID) begin awvalid_receive_time[aw_time_cnt] = $time; awvalid_flag[aw_time_cnt] = 1'b1; aw_time_cnt = aw_time_cnt + 1; end end // else end /// always /--------------------------------------------------------------------------------/ always@(posedge S_ACLK) begin if(net_AWVALID && S_AWREADY) begin if(S_AWQOS === 0) awqos[aw_cnt[int_cntr_width-2:0]] = aw_qos; else awqos[aw_cnt[int_cntr_width-2:0]] = S_AWQOS; end end / Address Write Channel handshake/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin aw_cnt = 0; wacount = 0; end else begin if(S_AWVALID && !wrfifo_full(S_AWLEN+1)) begin slave.RECEIVE_WRITE_ADDRESS(0, id_invalid, awaddr[aw_cnt[int_cntr_width-2:0]], awlen[aw_cnt[int_cntr_width-2:0]], awsize[aw_cnt[int_cntr_width-2:0]], awbrst[aw_cnt[int_cntr_width-2:0]], awlock[aw_cnt[int_cntr_width-2:0]], awcache[aw_cnt[int_cntr_width-2:0]], awprot[aw_cnt[int_cntr_width-2:0]], awid[aw_cnt[int_cntr_width-2:0]]); /// sampled valid ID. aw_flag[aw_cnt[int_cntr_width-2:0]] = 1'b1; aw_cnt = aw_cnt + 1; wacount = wacount + 1; end // if (!aw_fifo_full) end /// if else end /// always /--------------------------------------------------------------------------------/ / Write Data Channel Handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wd_cnt = 0; end else begin if(aw_flag[wd_cnt[int_cntr_width-2:0]]) begin if(S_WVALID && !wrfifo_full(awlen[wd_cnt[int_cntr_width-2:0]] + 1)) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_cntr_width-2:0]]); wlast_flag[wd_cnt[int_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; end end else begin if(!wrfifo_full(axi_burst_len+1) && S_WVALID) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_cntr_width-2:0]]); wlast_flag[wd_cnt[int_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; end end /// if end /// else end /// always /--------------------------------------------------------------------------------/ / Align the wrap data for write transaction / task automatic get_wrap_aligned_wr_data; output [(data_bus_widthaxi_burst_len)-1:0] aligned_data; output [addr_width-1:0] start_addr; /// aligned start address input [addr_width-1:0] addr; input [(data_bus_widthaxi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [(data_bus_widthaxi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; wrp_data = wrp_data << ((data_bus_widthaxi_burst_len) - (v_bytes8)); while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data << 8; temp_data[7:0] = wrp_data[(data_bus_widthaxi_burst_len)-1 : (data_bus_widthaxi_burst_len)-8]; wrp_data = wrp_data << 8; wrp_bytes = wrp_bytes - 1; end wrp_bytes = addr - start_addr; wrp_data = b_data << (wrp_bytes8); aligned_data = (temp_data \| wrp_data); end endtask /--------------------------------------------------------------------------------/ / Calculate the Response for each read/write transaction / function [axi_rsp_width-1:0] calculate_resp; input [addr_width-1:0] awaddr; input [axi_prot_width-1:0] awprot; reg [axi_rsp_width-1:0] rsp; begin rsp = AXI_OK; / Address Decode / if(decode_address(awaddr) === INVALID_MEM_TYPE) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Invalid location(0x%0h) ",$time, DISP_ERR, slave_name, awaddr); end else if(decode_address(awaddr) === REG_MEM) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Register Map(0x%0h) is not allowed through this port.",$time, DISP_ERR, slave_name, awaddr); end if(secure_access_enabled && awprot[1]) rsp = AXI_DEC_ERR; // decode error calculate_resp = rsp; end endfunction /--------------------------------------------------------------------------------/ reg[max_burst_bits-1:0] temp_wr_data; / Store the Write response for each write transaction / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_fifo_wr_ptr = 0; wcount = 0; end else begin enable_write_bresp = aw_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] && wlast_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]]; / calculate bresp only when AWVALID && WLAST is received / if(enable_write_bresp) begin aw_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] = 0; wlast_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] = 0; bresp = calculate_resp(awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]], awprot[wr_fifo_wr_ptr[int_cntr_width-2:0]]); / Fill AFI_WR_data FIFO / if(bresp === AXI_OK ) begin if(awbrst[wr_fifo_wr_ptr[int_cntr_width-2:0]]=== AXI_WRAP) begin /// wrap type? then align the data get_wrap_aligned_wr_data(aligned_wr_data, aligned_wr_addr, awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]], burst_data[wr_fifo_wr_ptr[int_cntr_width-2:0]],burst_valid_bytes[wr_fifo_wr_ptr[int_cntr_width-2:0]]); /// gives wrapped start address end else begin aligned_wr_data = burst_data[wr_fifo_wr_ptr[int_cntr_width-2:0]]; aligned_wr_addr = awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]] ; end valid_data_bytes = burst_valid_bytes[wr_fifo_wr_ptr[int_cntr_width-2:0]]; end else valid_data_bytes = 0; temp_wr_data = aligned_wr_data; wr_fifo[wr_fifo_wr_ptr[int_cntr_width-2:0]] = {awqos[wr_fifo_wr_ptr[int_cntr_width-2:0]], awlen[wr_fifo_wr_ptr[int_cntr_width-2:0]], awid[wr_fifo_wr_ptr[int_cntr_width-2:0]], bresp, temp_wr_data, aligned_wr_addr, valid_data_bytes}; wcount = wcount + awlen[wr_fifo_wr_ptr[int_cntr_width-2:0]]+1; wr_fifo_wr_ptr = wr_fifo_wr_ptr + 1; end end // else end // always /--------------------------------------------------------------------------------/ / Send Write Response Channel handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin rd_bresp_cnt = 0; wr_latency_count = get_wr_lat_number(1); wr_delayed = 0; bresp_time_cnt = 0; end else begin wr_delayed = 1'b0; if(awvalid_flag[bresp_time_cnt] && (($time - awvalid_receive_time[bresp_time_cnt])/s_aclk_period >= wr_latency_count)) wr_delayed = 1; if(!bresp_fifo_empty && wr_delayed) begin slave.SEND_WRITE_RESPONSE(fifo_bresp[rd_bresp_cnt[int_cntr_width-2:0]][rsp_id_msb : rsp_id_lsb], // ID fifo_bresp[rd_bresp_cnt[int_cntr_width-2:0]][rsp_msb : rsp_lsb] // Response ); wr_delayed = 0; awvalid_flag[bresp_time_cnt] = 1'b0; bresp_time_cnt = bresp_time_cnt+1; rd_bresp_cnt = rd_bresp_cnt + 1; wr_latency_count = get_wr_lat_number(1); end end // else end//always /--------------------------------------------------------------------------------/ / Write Response Channel handshake / reg wr_int_state; / Reading from the wr_fifo and sending to Interconnect fifo/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_int_state = 1'b0; wr_bresp_cnt = 0; wr_fifo_rd_ptr = 0; end else begin case(wr_int_state) 1'b0 : begin wr_int_state = 1'b0; if(!temp_wr_intr_fifo_full && !bresp_fifo_full && !wr_fifo_empty) begin wr_intr_fifo.write_mem({wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_qos_msb:wr_afi_qos_lsb], wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_data_msb:wr_afi_bytes_lsb]}); /// qos, data, address and valid_bytes wr_int_state = 1'b1; / start filling the write response fifo at the same time / fifo_bresp[wr_bresp_cnt[int_cntr_width-2:0]] = wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_id_msb:wr_afi_rsp_lsb]; // ID and Resp wcount = wcount - (wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_ln_msb:wr_afi_ln_lsb] + 1); /// burst length wacount = wacount - 1; wr_fifo_rd_ptr = wr_fifo_rd_ptr + 1; wr_bresp_cnt = wr_bresp_cnt+1; end end 1'b1 : begin wr_int_state = 0; end endcase end end /--------------------------------------------------------------------------------/ /-------------------------------- WRITE HANDSHAKE END ----------------------------------------/ /-------------------------------- READ HANDSHAKE ---------------------------------------------/ / READ CHANNELS / / Store the arvalid receive time --- necessary for calculating latency in sending the rresp latency / reg [7:0] ar_time_cnt = 0,rresp_time_cnt = 0; real arvalid_receive_time[0:max_outstanding_transactions]; // store the time when a new arvalid is received reg arvalid_flag[0:max_outstanding_transactions]; // store the time when a new arvalid is received reg [int_cntr_width-1:0] ar_cnt = 0;// counter for arvalid info / various FIFOs for storing the ADDR channel info / reg [axi_size_width-1:0] arsize [0:max_outstanding_transactions-1]; reg [axi_prot_width-1:0] arprot [0:max_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] arbrst [0:max_outstanding_transactions-1]; reg [axi_len_width-1:0] arlen [0:max_outstanding_transactions-1]; reg [axi_cache_width-1:0] arcache [0:max_outstanding_transactions-1]; reg [axi_lock_width-1:0] arlock [0:max_outstanding_transactions-1]; reg ar_flag [0:max_outstanding_transactions-1]; reg [addr_width-1:0] araddr [0:max_outstanding_transactions-1]; reg [id_bus_width-1:0] arid [0:max_outstanding_transactions-1]; reg [axi_qos_width-1:0] arqos [0:max_outstanding_transactions-1]; wire ar_fifo_full; // indicates arvalid_fifo is full (max outstanding transactions reached) reg [int_cntr_width-1:0] wr_rresp_cnt = 0; reg [axi_rsp_width-1:0] rresp; reg [rsp_fifo_bits-1:0] fifo_rresp [0:max_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_rresp; / Send Read Response & Data Channel handshake / integer rd_latency_count; reg rd_delayed; reg [rd_afi_fifo_bits-1:0] read_fifo[0:max_outstanding_transactions-1]; /// Read Burst Data, addr, size, burst, len, RID, RRESP, valid_bytes reg [int_cntr_width-1:0] rd_fifo_wr_ptr = 0, rd_fifo_rd_ptr = 0; wire read_fifo_full; reg [7:0] rcount; reg [2:0] racount; wire rd_intr_fifo_full, rd_intr_fifo_empty; wire read_fifo_empty; / signals to communicate with interconnect RD_FIFO model / reg rd_req, invalid_rd_req; / REad control Info 56:25 : Address (32) 24:22 : Size (3) 21:20 : BRST (2) 19:16 : LEN (4) 15:10 : RID (6) 9:8 : RRSP (2) 7:0 : byte cnt (8) / reg [rd_info_bits-1:0] read_control_info; reg [(data_bus_widthaxi_burst_len)-1:0] aligned_rd_data; reg temp_rd_intr_fifo_empty; processing_system7_bfm_v2_0_5_intr_rd_mem rd_intr_fifo(SW_CLK, S_RESETN, rd_intr_fifo_full, rd_intr_fifo_empty, rd_req, invalid_rd_req, read_control_info , RD_DATA_OCM, RD_DATA_DDR, RD_DATA_VALID_OCM, RD_DATA_VALID_DDR); assign read_fifo_empty = (rd_fifo_wr_ptr === rd_fifo_rd_ptr)?1'b1: 1'b0; assign S_RCOUNT = rcount; assign S_RACOUNT = racount; /* Register the asynch signal empty coming from Interconnect READ FIFO / always@(posedge S_ACLK) temp_rd_intr_fifo_empty = rd_intr_fifo_empty; // FIFO_STATUS (only if AFI port) 1- full function automatic rdfifo_full ; input [axi_len_width:0] fifo_space_exp; integer fifo_space_left; begin fifo_space_left = afi_fifo_locations - rcount; if(fifo_space_left < fifo_space_exp) rdfifo_full = 1; else rdfifo_full = 0; end endfunction / Store the arvalid receive time --- necessary for calculating the bresp latency / always@(negedge S_RESETN or S_ARID or S_ARADDR or S_ARVALID ) begin if(!S_RESETN) ar_time_cnt = 0; else begin if(S_ARVALID) begin arvalid_receive_time[ar_time_cnt] = $time; arvalid_flag[ar_time_cnt] = 1'b1; ar_time_cnt = ar_time_cnt + 1; end end // else end /// always /--------------------------------------------------------------------------------/ always@(posedge S_ACLK) begin if(net_ARVALID && S_ARREADY) begin if(S_ARQOS === 0) arqos[aw_cnt[int_cntr_width-2:0]] = ar_qos; else arqos[aw_cnt[int_cntr_width-2:0]] = S_ARQOS; end end / Address Read Channel handshake/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin ar_cnt = 0; racount = 0; end else begin if(S_ARVALID && !rdfifo_full(S_ARLEN+1)) begin /// if AFI read fifo is not full slave.RECEIVE_READ_ADDRESS(0, id_invalid, araddr[ar_cnt[int_cntr_width-2:0]], arlen[ar_cnt[int_cntr_width-2:0]], arsize[ar_cnt[int_cntr_width-2:0]], arbrst[ar_cnt[int_cntr_width-2:0]], arlock[ar_cnt[int_cntr_width-2:0]], arcache[ar_cnt[int_cntr_width-2:0]], arprot[ar_cnt[int_cntr_width-2:0]], arid[ar_cnt[int_cntr_width-2:0]]); /// sampled valid ID. ar_flag[ar_cnt[int_cntr_width-2:0]] = 1'b1; ar_cnt = ar_cnt+1; racount = racount + 1; end /// if(!ar_fifo_full) end /// if else end /// always/ /--------------------------------------------------------------------------------/ /* Align Wrap data for read transaction/ task automatic get_wrap_aligned_rd_data; output [(data_bus_widthaxi_burst_len)-1:0] aligned_data; input [addr_width-1:0] addr; input [(data_bus_widthaxi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [addr_width-1:0] start_addr; reg [(data_bus_widthaxi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data >> 8; temp_data[(data_bus_widthaxi_burst_len)-1 : (data_bus_widthaxi_burst_len)-8] = wrp_data[7:0]; wrp_data = wrp_data >> 8; wrp_bytes = wrp_bytes - 1; end temp_data = temp_data >> ((data_bus_widthaxi_burst_len) - (v_bytes8)); wrp_bytes = addr - start_addr; wrp_data = b_data >> (wrp_bytes8); aligned_data = (temp_data \| wrp_data); end endtask /--------------------------------------------------------------------------------/ parameter RD_DATA_REQ = 1'b0, WAIT_RD_VALID = 1'b1; reg rd_fifo_state; reg [addr_width-1:0] temp_read_address; reg [max_burst_bytes_width:0] temp_rd_valid_bytes; / get the data from memory && also calculate the rresp/ always@(negedge S_RESETN or posedge SW_CLK) begin if(!S_RESETN)begin wr_rresp_cnt =0; rd_fifo_state = RD_DATA_REQ; temp_rd_valid_bytes = 0; temp_read_address = 0; RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; rd_req = 0; invalid_rd_req= 0; RD_QOS = 0; end else begin case(rd_fifo_state) RD_DATA_REQ : begin rd_fifo_state = RD_DATA_REQ; RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; invalid_rd_req = 0; if(ar_flag[wr_rresp_cnt[int_cntr_width-2:0]] && !rd_intr_fifo_full) begin /// check the rd_fifo_bytes, interconnect fifo full condition ar_flag[wr_rresp_cnt[int_cntr_width-2:0]] = 0; rresp = calculate_resp(araddr[wr_rresp_cnt[int_cntr_width-2:0]],arprot[wr_rresp_cnt[int_cntr_width-2:0]]); temp_rd_valid_bytes = (arlen[wr_rresp_cnt[int_cntr_width-2:0]]+1)(2*arsize[wr_rresp_cnt[int_cntr_width-2:0]]);//data_bus_width/8; if(arbrst[wr_rresp_cnt[int_cntr_width-2:0]] === AXI_WRAP) /// wrap begin temp_read_address = (araddr[wr_rresp_cnt[int_cntr_width-2:0]]/temp_rd_valid_bytes) temp_rd_valid_bytes; else temp_read_address = araddr[wr_rresp_cnt[int_cntr_width-2:0]]; if(rresp === AXI_OK) begin case(decode_address(temp_read_address))//decode_address(araddr[wr_rresp_cnt[int_cntr_width-2:0]]); OCM_MEM : RD_REQ_OCM = 1; DDR_MEM : RD_REQ_DDR = 1; default : invalid_rd_req = 1; endcase end else invalid_rd_req = 1; RD_ADDR = temp_read_address; ///araddr[wr_rresp_cnt[int_cntr_width-2:0]]; RD_BYTES = temp_rd_valid_bytes; RD_QOS = arqos[wr_rresp_cnt[int_cntr_width-2:0]]; rd_fifo_state = WAIT_RD_VALID; rd_req = 1; racount = racount - 1; read_control_info = {araddr[wr_rresp_cnt[int_cntr_width-2:0]], arsize[wr_rresp_cnt[int_cntr_width-2:0]], arbrst[wr_rresp_cnt[int_cntr_width-2:0]], arlen[wr_rresp_cnt[int_cntr_width-2:0]], arid[wr_rresp_cnt[int_cntr_width-2:0]], rresp, temp_rd_valid_bytes }; wr_rresp_cnt = wr_rresp_cnt + 1; end end WAIT_RD_VALID : begin rd_fifo_state = WAIT_RD_VALID; rd_req = 0; if(RD_DATA_VALID_OCM \| RD_DATA_VALID_DDR \| invalid_rd_req) begin ///temp_dec == 2'b11) begin RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; invalid_rd_req = 0; rd_fifo_state = RD_DATA_REQ; end end endcase end /// else end /// always /--------------------------------------------------------------------------------/ /* thread to fill in the AFI RD_FIFO / reg[rd_afi_fifo_bits-1:0] temp_rd_data;//Read Burst Data, addr, size, burst, len, RID, RRESP, valid bytes reg tmp_state; always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_wr_ptr = 0; rcount = 0; tmp_state = 0; end else begin case(tmp_state) 0 : begin tmp_state = 0; if(!temp_rd_intr_fifo_empty) begin rd_intr_fifo.read_mem(temp_rd_data); tmp_state = 1; end end 1 : begin tmp_state = 1; if(!rdfifo_full(temp_rd_data[rd_afi_ln_msb:rd_afi_ln_lsb]+1)) begin read_fifo[rd_fifo_wr_ptr[int_cntr_width-2:0]] = temp_rd_data; rd_fifo_wr_ptr = rd_fifo_wr_ptr + 1; rcount = rcount + temp_rd_data[rd_afi_ln_msb:rd_afi_ln_lsb]+1; /// Burst length tmp_state = 0; end end endcase end end /--------------------------------------------------------------------------------/ reg[max_burst_bytes_width:0] rd_v_b; reg[rd_afi_fifo_bits-1:0] tmp_fifo_rd; /// Data, addr, size, burst, len, RID, RRESP,valid_bytes reg[(data_bus_widthaxi_burst_len)-1:0] temp_read_data; reg[(axi_rsp_widthaxi_burst_len)-1:0] temp_read_rsp; / Read Data Channel handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_rd_ptr = 0; rd_latency_count = get_rd_lat_number(1); rd_delayed = 0; rresp_time_cnt = 0; rd_v_b = 0; end else begin if(arvalid_flag[rresp_time_cnt] && ((($time - arvalid_receive_time[rresp_time_cnt])/s_aclk_period) >= rd_latency_count)) begin rd_delayed = 1; end if(!read_fifo_empty && rd_delayed)begin rd_delayed = 0; arvalid_flag[rresp_time_cnt] = 1'b0; tmp_fifo_rd = read_fifo[rd_fifo_rd_ptr[int_cntr_width-2:0]]; rd_v_b = (tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb]+1)(2*tmp_fifo_rd[rd_afi_siz_msb : rd_afi_siz_lsb]); temp_read_data = tmp_fifo_rd[rd_afi_data_msb : rd_afi_data_lsb]; if(tmp_fifo_rd[rd_afi_brst_msb : rd_afi_brst_lsb] === AXI_WRAP) begin get_wrap_aligned_rd_data(aligned_rd_data, tmp_fifo_rd[rd_afi_addr_msb : rd_afi_addr_lsb], tmp_fifo_rd[rd_afi_data_msb : rd_afi_data_lsb], rd_v_b); temp_read_data = aligned_rd_data; end temp_read_rsp = 0; repeat(axi_burst_len) begin temp_read_rsp = temp_read_rsp >> axi_rsp_width; temp_read_rsp[(axi_rsp_widthaxi_burst_len)-1:(axi_rsp_width*axi_burst_len)-axi_rsp_width] = tmp_fifo_rd[rd_afi_rsp_msb : rd_afi_rsp_lsb]; end slave.SEND_READ_BURST_RESP_CTRL(tmp_fifo_rd[rd_afi_id_msb : rd_afi_id_lsb], tmp_fifo_rd[rd_afi_addr_msb : rd_afi_addr_lsb], tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb], tmp_fifo_rd[rd_afi_siz_msb : rd_afi_siz_lsb], tmp_fifo_rd[rd_afi_brst_msb : rd_afi_brst_lsb], temp_read_data, temp_read_rsp); rcount = rcount - (tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb]+ 1) ; rresp_time_cnt = rresp_time_cnt+1; rd_latency_count = get_rd_lat_number(1); rd_fifo_rd_ptr = rd_fifo_rd_ptr+1; end end /// else end /// always endmodule
module processing_system7_bfm_v2_0_5_regc( rstn, sw_clk, /* Goes to port 0 of REG / reg_rd_req_port0, reg_rd_dv_port0, reg_rd_addr_port0, reg_rd_data_port0, reg_rd_bytes_port0, reg_rd_qos_port0, / Goes to port 1 of REG */ reg_rd_req_port1, reg_rd_dv_port1, reg_rd_addr_port1, reg_rd_data_port1, reg_rd_bytes_port1, reg_rd_qos_port1 ); input rstn; input sw_clk; input reg_rd_req_port0; output reg_rd_dv_port0; input[31:0] reg_rd_addr_port0; output[1023:0] reg_rd_data_port0; input[7:0] reg_rd_bytes_port0; input [3:0] reg_rd_qos_port0; input reg_rd_req_port1; output reg_rd_dv_port1; input[31:0] reg_rd_addr_port1; output[1023:0] reg_rd_data_port1; input[7:0] reg_rd_bytes_port1; input[3:0] reg_rd_qos_port1; wire [3:0] rd_qos; reg [1023:0] rd_data; wire [31:0] rd_addr; wire [7:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_rd reg_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(reg_rd_qos_port0), .qos2(reg_rd_qos_port1), .prt_req1(reg_rd_req_port0), .prt_req2(reg_rd_req_port1), .prt_data1(reg_rd_data_port0), .prt_data2(reg_rd_data_port1), .prt_addr1(reg_rd_addr_port0), .prt_addr2(reg_rd_addr_port1), .prt_bytes1(reg_rd_bytes_port0), .prt_bytes2(reg_rd_bytes_port1), .prt_dv1(reg_rd_dv_port0), .prt_dv2(reg_rd_dv_port1), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_reg_map regm(); reg state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin rd_dv <= 0; state <= 0; end else begin case(state) 0:begin state <= 0; rd_dv <= 0; if(rd_req) begin regm.read_reg_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule
module processing_system7_bfm_v2_0_5_regc( rstn, sw_clk, /* Goes to port 0 of REG / reg_rd_req_port0, reg_rd_dv_port0, reg_rd_addr_port0, reg_rd_data_port0, reg_rd_bytes_port0, reg_rd_qos_port0, / Goes to port 1 of REG */ reg_rd_req_port1, reg_rd_dv_port1, reg_rd_addr_port1, reg_rd_data_port1, reg_rd_bytes_port1, reg_rd_qos_port1 ); input rstn; input sw_clk; input reg_rd_req_port0; output reg_rd_dv_port0; input[31:0] reg_rd_addr_port0; output[1023:0] reg_rd_data_port0; input[7:0] reg_rd_bytes_port0; input [3:0] reg_rd_qos_port0; input reg_rd_req_port1; output reg_rd_dv_port1; input[31:0] reg_rd_addr_port1; output[1023:0] reg_rd_data_port1; input[7:0] reg_rd_bytes_port1; input[3:0] reg_rd_qos_port1; wire [3:0] rd_qos; reg [1023:0] rd_data; wire [31:0] rd_addr; wire [7:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_rd reg_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(reg_rd_qos_port0), .qos2(reg_rd_qos_port1), .prt_req1(reg_rd_req_port0), .prt_req2(reg_rd_req_port1), .prt_data1(reg_rd_data_port0), .prt_data2(reg_rd_data_port1), .prt_addr1(reg_rd_addr_port0), .prt_addr2(reg_rd_addr_port1), .prt_bytes1(reg_rd_bytes_port0), .prt_bytes2(reg_rd_bytes_port1), .prt_dv1(reg_rd_dv_port0), .prt_dv2(reg_rd_dv_port1), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_reg_map regm(); reg state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin rd_dv <= 0; state <= 0; end else begin case(state) 0:begin state <= 0; rd_dv <= 0; if(rd_req) begin regm.read_reg_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule
module processing_system7_bfm_v2_0_5_arb_rd_4( rstn, sw_clk, qos1, qos2, qos3, qos4, prt_req1, prt_req2, prt_req3, prt_req4, prt_data1, prt_data2, prt_data3, prt_data4, prt_addr1, prt_addr2, prt_addr3, prt_addr4, prt_bytes1, prt_bytes2, prt_bytes3, prt_bytes4, prt_dv1, prt_dv2, prt_dv3, prt_dv4, prt_qos, prt_req, prt_data, prt_addr, prt_bytes, prt_dv ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2,qos3,qos4; input prt_req1, prt_req2,prt_req3, prt_req4, prt_dv; output reg [max_burst_bits-1:0] prt_data1,prt_data2,prt_data3,prt_data4; input [addr_width-1:0] prt_addr1,prt_addr2,prt_addr3,prt_addr4; input [max_burst_bytes_width:0] prt_bytes1,prt_bytes2,prt_bytes3,prt_bytes4; output reg prt_dv1,prt_dv2,prt_dv3,prt_dv4,prt_req; input [max_burst_bits-1:0] prt_data; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; output reg [axi_qos_width-1:0] prt_qos; parameter wait_req = 3'b000, serv_req1 = 3'b001, serv_req2 = 3'b010, serv_req3 = 3'b011, serv_req4 = 3'b100, wait_dv_low=3'b101; reg [2:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; prt_req = 1'b0; if(prt_req1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_req4) begin prt_req = 1; prt_addr = prt_addr4; prt_qos = qos4; prt_bytes = prt_bytes4; state = serv_req4; end end serv_req1:begin state = serv_req1; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; if(prt_dv)begin prt_dv1 = 1'b1; prt_data1 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req2) begin state = serv_req2; prt_qos = qos2; prt_req = 1; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req3) begin state = serv_req3; prt_qos = qos3; prt_req = 1; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_req4) begin prt_req = 1; prt_qos = qos4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; state = serv_req4; end end end serv_req2:begin state = serv_req2; prt_dv1 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; if(prt_dv)begin prt_dv2 = 1'b1; prt_data2 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_req4) begin state = serv_req4; prt_req = 1; prt_qos = qos4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_req1) begin prt_req = 1; prt_addr = prt_addr1; prt_qos = qos1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req3:begin state = serv_req3; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv4 = 1'b0; if(prt_dv)begin prt_dv3 = 1'b1; prt_data3 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req4) begin state = serv_req4; prt_qos = qos4; prt_req = 1; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_req1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_req2) begin prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end end end serv_req4:begin state = serv_req4; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; if(prt_dv)begin prt_dv4 = 1'b1; prt_data4 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req1) begin state = serv_req1; prt_qos = qos1; prt_req = 1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req3) begin prt_req = 1; prt_addr = prt_addr3; prt_qos = qos3; prt_bytes = prt_bytes3; state = serv_req3; end end end wait_dv_low:begin state = wait_dv_low; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; if(!prt_dv) state = wait_req; end endcase end /// if else end /// always endmodule
module processing_system7_bfm_v2_0_5_arb_rd_4( rstn, sw_clk, qos1, qos2, qos3, qos4, prt_req1, prt_req2, prt_req3, prt_req4, prt_data1, prt_data2, prt_data3, prt_data4, prt_addr1, prt_addr2, prt_addr3, prt_addr4, prt_bytes1, prt_bytes2, prt_bytes3, prt_bytes4, prt_dv1, prt_dv2, prt_dv3, prt_dv4, prt_qos, prt_req, prt_data, prt_addr, prt_bytes, prt_dv ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2,qos3,qos4; input prt_req1, prt_req2,prt_req3, prt_req4, prt_dv; output reg [max_burst_bits-1:0] prt_data1,prt_data2,prt_data3,prt_data4; input [addr_width-1:0] prt_addr1,prt_addr2,prt_addr3,prt_addr4; input [max_burst_bytes_width:0] prt_bytes1,prt_bytes2,prt_bytes3,prt_bytes4; output reg prt_dv1,prt_dv2,prt_dv3,prt_dv4,prt_req; input [max_burst_bits-1:0] prt_data; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; output reg [axi_qos_width-1:0] prt_qos; parameter wait_req = 3'b000, serv_req1 = 3'b001, serv_req2 = 3'b010, serv_req3 = 3'b011, serv_req4 = 3'b100, wait_dv_low=3'b101; reg [2:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; prt_req = 1'b0; if(prt_req1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_req4) begin prt_req = 1; prt_addr = prt_addr4; prt_qos = qos4; prt_bytes = prt_bytes4; state = serv_req4; end end serv_req1:begin state = serv_req1; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; if(prt_dv)begin prt_dv1 = 1'b1; prt_data1 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req2) begin state = serv_req2; prt_qos = qos2; prt_req = 1; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req3) begin state = serv_req3; prt_qos = qos3; prt_req = 1; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_req4) begin prt_req = 1; prt_qos = qos4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; state = serv_req4; end end end serv_req2:begin state = serv_req2; prt_dv1 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; if(prt_dv)begin prt_dv2 = 1'b1; prt_data2 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_req4) begin state = serv_req4; prt_req = 1; prt_qos = qos4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_req1) begin prt_req = 1; prt_addr = prt_addr1; prt_qos = qos1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req3:begin state = serv_req3; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv4 = 1'b0; if(prt_dv)begin prt_dv3 = 1'b1; prt_data3 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req4) begin state = serv_req4; prt_qos = qos4; prt_req = 1; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_req1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_req2) begin prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end end end serv_req4:begin state = serv_req4; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; if(prt_dv)begin prt_dv4 = 1'b1; prt_data4 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req1) begin state = serv_req1; prt_qos = qos1; prt_req = 1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req3) begin prt_req = 1; prt_addr = prt_addr3; prt_qos = qos3; prt_bytes = prt_bytes3; state = serv_req3; end end end wait_dv_low:begin state = wait_dv_low; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; if(!prt_dv) state = wait_req; end endcase end /// if else end /// always endmodule
module processing_system7_bfm_v2_0_5_ssw_hp( sw_clk, rstn, w_qos_hp0, r_qos_hp0, w_qos_hp1, r_qos_hp1, w_qos_hp2, r_qos_hp2, w_qos_hp3, r_qos_hp3, wr_ack_ddr_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, rd_req_ddr_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_dv_ddr_hp0, rd_data_ocm_hp0, wr_ack_ocm_hp0, wr_dv_ocm_hp0, rd_req_ocm_hp0, rd_dv_ocm_hp0, wr_ack_ddr_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, rd_req_ddr_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_data_ocm_hp1, rd_dv_ddr_hp1, wr_ack_ocm_hp1, wr_dv_ocm_hp1, rd_req_ocm_hp1, rd_dv_ocm_hp1, wr_ack_ddr_hp2, wr_data_hp2, wr_addr_hp2, wr_bytes_hp2, wr_dv_ddr_hp2, rd_req_ddr_hp2, rd_addr_hp2, rd_bytes_hp2, rd_data_ddr_hp2, rd_data_ocm_hp2, rd_dv_ddr_hp2, wr_ack_ocm_hp2, wr_dv_ocm_hp2, rd_req_ocm_hp2, rd_dv_ocm_hp2, wr_ack_ddr_hp3, wr_data_hp3, wr_addr_hp3, wr_bytes_hp3, wr_dv_ddr_hp3, rd_req_ddr_hp3, rd_addr_hp3, rd_bytes_hp3, rd_data_ocm_hp3, rd_data_ddr_hp3, rd_dv_ddr_hp3, wr_ack_ocm_hp3, wr_dv_ocm_hp3, rd_req_ocm_hp3, rd_dv_ocm_hp3, ddr_wr_ack0, ddr_wr_dv0, ddr_rd_req0, ddr_rd_dv0, ddr_rd_qos0, ddr_wr_qos0, ddr_wr_addr0, ddr_wr_data0, ddr_wr_bytes0, ddr_rd_addr0, ddr_rd_data0, ddr_rd_bytes0, ddr_wr_ack1, ddr_wr_dv1, ddr_rd_req1, ddr_rd_dv1, ddr_rd_qos1, ddr_wr_qos1, ddr_wr_addr1, ddr_wr_data1, ddr_wr_bytes1, ddr_rd_addr1, ddr_rd_data1, ddr_rd_bytes1, ocm_wr_ack, ocm_wr_dv, ocm_rd_req, ocm_rd_dv, ocm_wr_qos, ocm_rd_qos, ocm_wr_addr, ocm_wr_data, ocm_wr_bytes, ocm_rd_addr, ocm_rd_data, ocm_rd_bytes ); input sw_clk; input rstn; input [3:0] w_qos_hp0; input [3:0] r_qos_hp0; input [3:0] w_qos_hp1; input [3:0] r_qos_hp1; input [3:0] w_qos_hp2; input [3:0] r_qos_hp2; input [3:0] w_qos_hp3; input [3:0] r_qos_hp3; output [3:0] ddr_rd_qos0; output [3:0] ddr_wr_qos0; output [3:0] ddr_rd_qos1; output [3:0] ddr_wr_qos1; output [3:0] ocm_wr_qos; output [3:0] ocm_rd_qos; output wr_ack_ddr_hp0; input [1023:0] wr_data_hp0; input [31:0] wr_addr_hp0; input [7:0] wr_bytes_hp0; output wr_dv_ddr_hp0; input rd_req_ddr_hp0; input [31:0] rd_addr_hp0; input [7:0] rd_bytes_hp0; output [1023:0] rd_data_ddr_hp0; output rd_dv_ddr_hp0; output wr_ack_ddr_hp1; input [1023:0] wr_data_hp1; input [31:0] wr_addr_hp1; input [7:0] wr_bytes_hp1; output wr_dv_ddr_hp1; input rd_req_ddr_hp1; input [31:0] rd_addr_hp1; input [7:0] rd_bytes_hp1; output [1023:0] rd_data_ddr_hp1; output rd_dv_ddr_hp1; output wr_ack_ddr_hp2; input [1023:0] wr_data_hp2; input [31:0] wr_addr_hp2; input [7:0] wr_bytes_hp2; output wr_dv_ddr_hp2; input rd_req_ddr_hp2; input [31:0] rd_addr_hp2; input [7:0] rd_bytes_hp2; output [1023:0] rd_data_ddr_hp2; output rd_dv_ddr_hp2; output wr_ack_ddr_hp3; input [1023:0] wr_data_hp3; input [31:0] wr_addr_hp3; input [7:0] wr_bytes_hp3; output wr_dv_ddr_hp3; input rd_req_ddr_hp3; input [31:0] rd_addr_hp3; input [7:0] rd_bytes_hp3; output [1023:0] rd_data_ddr_hp3; output rd_dv_ddr_hp3; input ddr_wr_ack0; output ddr_wr_dv0; output [31:0]ddr_wr_addr0; output [1023:0]ddr_wr_data0; output [7:0]ddr_wr_bytes0; input ddr_rd_dv0; input [1023:0] ddr_rd_data0; output ddr_rd_req0; output [31:0] ddr_rd_addr0; output [7:0] ddr_rd_bytes0; input ddr_wr_ack1; output ddr_wr_dv1; output [31:0]ddr_wr_addr1; output [1023:0]ddr_wr_data1; output [7:0]ddr_wr_bytes1; input ddr_rd_dv1; input [1023:0] ddr_rd_data1; output ddr_rd_req1; output [31:0] ddr_rd_addr1; output [7:0] ddr_rd_bytes1; output wr_ack_ocm_hp0; input wr_dv_ocm_hp0; input rd_req_ocm_hp0; output rd_dv_ocm_hp0; output [1023:0] rd_data_ocm_hp0; output wr_ack_ocm_hp1; input wr_dv_ocm_hp1; input rd_req_ocm_hp1; output rd_dv_ocm_hp1; output [1023:0] rd_data_ocm_hp1; output wr_ack_ocm_hp2; input wr_dv_ocm_hp2; input rd_req_ocm_hp2; output rd_dv_ocm_hp2; output [1023:0] rd_data_ocm_hp2; output wr_ack_ocm_hp3; input wr_dv_ocm_hp3; input rd_req_ocm_hp3; output rd_dv_ocm_hp3; output [1023:0] rd_data_ocm_hp3; input ocm_wr_ack; output ocm_wr_dv; output [31:0]ocm_wr_addr; output [1023:0]ocm_wr_data; output [7:0]ocm_wr_bytes; input ocm_rd_dv; input [1023:0] ocm_rd_data; output ocm_rd_req; output [31:0] ocm_rd_addr; output [7:0] ocm_rd_bytes; /* FOR DDR / processing_system7_bfm_v2_0_5_arb_hp0_1 ddr_hp01 ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp0(w_qos_hp0), .r_qos_hp0(r_qos_hp0), .w_qos_hp1(w_qos_hp1), .r_qos_hp1(r_qos_hp1), .wr_ack_ddr_hp0(wr_ack_ddr_hp0), .wr_data_hp0(wr_data_hp0), .wr_addr_hp0(wr_addr_hp0), .wr_bytes_hp0(wr_bytes_hp0), .wr_dv_ddr_hp0(wr_dv_ddr_hp0), .rd_req_ddr_hp0(rd_req_ddr_hp0), .rd_addr_hp0(rd_addr_hp0), .rd_bytes_hp0(rd_bytes_hp0), .rd_data_ddr_hp0(rd_data_ddr_hp0), .rd_dv_ddr_hp0(rd_dv_ddr_hp0), .wr_ack_ddr_hp1(wr_ack_ddr_hp1), .wr_data_hp1(wr_data_hp1), .wr_addr_hp1(wr_addr_hp1), .wr_bytes_hp1(wr_bytes_hp1), .wr_dv_ddr_hp1(wr_dv_ddr_hp1), .rd_req_ddr_hp1(rd_req_ddr_hp1), .rd_addr_hp1(rd_addr_hp1), .rd_bytes_hp1(rd_bytes_hp1), .rd_data_ddr_hp1(rd_data_ddr_hp1), .rd_dv_ddr_hp1(rd_dv_ddr_hp1), .ddr_wr_ack(ddr_wr_ack0), .ddr_wr_dv(ddr_wr_dv0), .ddr_rd_req(ddr_rd_req0), .ddr_rd_dv(ddr_rd_dv0), .ddr_rd_qos(ddr_rd_qos0), .ddr_wr_qos(ddr_wr_qos0), .ddr_wr_addr(ddr_wr_addr0), .ddr_wr_data(ddr_wr_data0), .ddr_wr_bytes(ddr_wr_bytes0), .ddr_rd_addr(ddr_rd_addr0), .ddr_rd_data(ddr_rd_data0), .ddr_rd_bytes(ddr_rd_bytes0) ); / FOR DDR / processing_system7_bfm_v2_0_5_arb_hp2_3 ddr_hp23 ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp2(w_qos_hp2), .r_qos_hp2(r_qos_hp2), .w_qos_hp3(w_qos_hp3), .r_qos_hp3(r_qos_hp3), .wr_ack_ddr_hp2(wr_ack_ddr_hp2), .wr_data_hp2(wr_data_hp2), .wr_addr_hp2(wr_addr_hp2), .wr_bytes_hp2(wr_bytes_hp2), .wr_dv_ddr_hp2(wr_dv_ddr_hp2), .rd_req_ddr_hp2(rd_req_ddr_hp2), .rd_addr_hp2(rd_addr_hp2), .rd_bytes_hp2(rd_bytes_hp2), .rd_data_ddr_hp2(rd_data_ddr_hp2), .rd_dv_ddr_hp2(rd_dv_ddr_hp2), .wr_ack_ddr_hp3(wr_ack_ddr_hp3), .wr_data_hp3(wr_data_hp3), .wr_addr_hp3(wr_addr_hp3), .wr_bytes_hp3(wr_bytes_hp3), .wr_dv_ddr_hp3(wr_dv_ddr_hp3), .rd_req_ddr_hp3(rd_req_ddr_hp3), .rd_addr_hp3(rd_addr_hp3), .rd_bytes_hp3(rd_bytes_hp3), .rd_data_ddr_hp3(rd_data_ddr_hp3), .rd_dv_ddr_hp3(rd_dv_ddr_hp3), .ddr_wr_ack(ddr_wr_ack1), .ddr_wr_dv(ddr_wr_dv1), .ddr_rd_req(ddr_rd_req1), .ddr_rd_dv(ddr_rd_dv1), .ddr_rd_qos(ddr_rd_qos1), .ddr_wr_qos(ddr_wr_qos1), .ddr_wr_addr(ddr_wr_addr1), .ddr_wr_data(ddr_wr_data1), .ddr_wr_bytes(ddr_wr_bytes1), .ddr_rd_addr(ddr_rd_addr1), .ddr_rd_data(ddr_rd_data1), .ddr_rd_bytes(ddr_rd_bytes1) ); / FOR OCM_WR / processing_system7_bfm_v2_0_5_arb_wr_4 ocm_wr_hp( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_hp0), .qos2(w_qos_hp1), .qos3(w_qos_hp2), .qos4(w_qos_hp3), .prt_dv1(wr_dv_ocm_hp0), .prt_dv2(wr_dv_ocm_hp1), .prt_dv3(wr_dv_ocm_hp2), .prt_dv4(wr_dv_ocm_hp3), .prt_data1(wr_data_hp0), .prt_data2(wr_data_hp1), .prt_data3(wr_data_hp2), .prt_data4(wr_data_hp3), .prt_addr1(wr_addr_hp0), .prt_addr2(wr_addr_hp1), .prt_addr3(wr_addr_hp2), .prt_addr4(wr_addr_hp3), .prt_bytes1(wr_bytes_hp0), .prt_bytes2(wr_bytes_hp1), .prt_bytes3(wr_bytes_hp2), .prt_bytes4(wr_bytes_hp3), .prt_ack1(wr_ack_ocm_hp0), .prt_ack2(wr_ack_ocm_hp1), .prt_ack3(wr_ack_ocm_hp2), .prt_ack4(wr_ack_ocm_hp3), .prt_qos(ocm_wr_qos), .prt_req(ocm_wr_dv), .prt_data(ocm_wr_data), .prt_addr(ocm_wr_addr), .prt_bytes(ocm_wr_bytes), .prt_ack(ocm_wr_ack) ); / FOR OCM_RD */ processing_system7_bfm_v2_0_5_arb_rd_4 ocm_rd_hp( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_hp0), .qos2(r_qos_hp1), .qos3(r_qos_hp2), .qos4(r_qos_hp3), .prt_req1(rd_req_ocm_hp0), .prt_req2(rd_req_ocm_hp1), .prt_req3(rd_req_ocm_hp2), .prt_req4(rd_req_ocm_hp3), .prt_data1(rd_data_ocm_hp0), .prt_data2(rd_data_ocm_hp1), .prt_data3(rd_data_ocm_hp2), .prt_data4(rd_data_ocm_hp3), .prt_addr1(rd_addr_hp0), .prt_addr2(rd_addr_hp1), .prt_addr3(rd_addr_hp2), .prt_addr4(rd_addr_hp3), .prt_bytes1(rd_bytes_hp0), .prt_bytes2(rd_bytes_hp1), .prt_bytes3(rd_bytes_hp2), .prt_bytes4(rd_bytes_hp3), .prt_dv1(rd_dv_ocm_hp0), .prt_dv2(rd_dv_ocm_hp1), .prt_dv3(rd_dv_ocm_hp2), .prt_dv4(rd_dv_ocm_hp3), .prt_qos(ocm_rd_qos), .prt_req(ocm_rd_req), .prt_data(ocm_rd_data), .prt_addr(ocm_rd_addr), .prt_bytes(ocm_rd_bytes), .prt_dv(ocm_rd_dv) ); endmodule
module processing_system7_bfm_v2_0_5_ssw_hp( sw_clk, rstn, w_qos_hp0, r_qos_hp0, w_qos_hp1, r_qos_hp1, w_qos_hp2, r_qos_hp2, w_qos_hp3, r_qos_hp3, wr_ack_ddr_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, rd_req_ddr_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_dv_ddr_hp0, rd_data_ocm_hp0, wr_ack_ocm_hp0, wr_dv_ocm_hp0, rd_req_ocm_hp0, rd_dv_ocm_hp0, wr_ack_ddr_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, rd_req_ddr_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_data_ocm_hp1, rd_dv_ddr_hp1, wr_ack_ocm_hp1, wr_dv_ocm_hp1, rd_req_ocm_hp1, rd_dv_ocm_hp1, wr_ack_ddr_hp2, wr_data_hp2, wr_addr_hp2, wr_bytes_hp2, wr_dv_ddr_hp2, rd_req_ddr_hp2, rd_addr_hp2, rd_bytes_hp2, rd_data_ddr_hp2, rd_data_ocm_hp2, rd_dv_ddr_hp2, wr_ack_ocm_hp2, wr_dv_ocm_hp2, rd_req_ocm_hp2, rd_dv_ocm_hp2, wr_ack_ddr_hp3, wr_data_hp3, wr_addr_hp3, wr_bytes_hp3, wr_dv_ddr_hp3, rd_req_ddr_hp3, rd_addr_hp3, rd_bytes_hp3, rd_data_ocm_hp3, rd_data_ddr_hp3, rd_dv_ddr_hp3, wr_ack_ocm_hp3, wr_dv_ocm_hp3, rd_req_ocm_hp3, rd_dv_ocm_hp3, ddr_wr_ack0, ddr_wr_dv0, ddr_rd_req0, ddr_rd_dv0, ddr_rd_qos0, ddr_wr_qos0, ddr_wr_addr0, ddr_wr_data0, ddr_wr_bytes0, ddr_rd_addr0, ddr_rd_data0, ddr_rd_bytes0, ddr_wr_ack1, ddr_wr_dv1, ddr_rd_req1, ddr_rd_dv1, ddr_rd_qos1, ddr_wr_qos1, ddr_wr_addr1, ddr_wr_data1, ddr_wr_bytes1, ddr_rd_addr1, ddr_rd_data1, ddr_rd_bytes1, ocm_wr_ack, ocm_wr_dv, ocm_rd_req, ocm_rd_dv, ocm_wr_qos, ocm_rd_qos, ocm_wr_addr, ocm_wr_data, ocm_wr_bytes, ocm_rd_addr, ocm_rd_data, ocm_rd_bytes ); input sw_clk; input rstn; input [3:0] w_qos_hp0; input [3:0] r_qos_hp0; input [3:0] w_qos_hp1; input [3:0] r_qos_hp1; input [3:0] w_qos_hp2; input [3:0] r_qos_hp2; input [3:0] w_qos_hp3; input [3:0] r_qos_hp3; output [3:0] ddr_rd_qos0; output [3:0] ddr_wr_qos0; output [3:0] ddr_rd_qos1; output [3:0] ddr_wr_qos1; output [3:0] ocm_wr_qos; output [3:0] ocm_rd_qos; output wr_ack_ddr_hp0; input [1023:0] wr_data_hp0; input [31:0] wr_addr_hp0; input [7:0] wr_bytes_hp0; output wr_dv_ddr_hp0; input rd_req_ddr_hp0; input [31:0] rd_addr_hp0; input [7:0] rd_bytes_hp0; output [1023:0] rd_data_ddr_hp0; output rd_dv_ddr_hp0; output wr_ack_ddr_hp1; input [1023:0] wr_data_hp1; input [31:0] wr_addr_hp1; input [7:0] wr_bytes_hp1; output wr_dv_ddr_hp1; input rd_req_ddr_hp1; input [31:0] rd_addr_hp1; input [7:0] rd_bytes_hp1; output [1023:0] rd_data_ddr_hp1; output rd_dv_ddr_hp1; output wr_ack_ddr_hp2; input [1023:0] wr_data_hp2; input [31:0] wr_addr_hp2; input [7:0] wr_bytes_hp2; output wr_dv_ddr_hp2; input rd_req_ddr_hp2; input [31:0] rd_addr_hp2; input [7:0] rd_bytes_hp2; output [1023:0] rd_data_ddr_hp2; output rd_dv_ddr_hp2; output wr_ack_ddr_hp3; input [1023:0] wr_data_hp3; input [31:0] wr_addr_hp3; input [7:0] wr_bytes_hp3; output wr_dv_ddr_hp3; input rd_req_ddr_hp3; input [31:0] rd_addr_hp3; input [7:0] rd_bytes_hp3; output [1023:0] rd_data_ddr_hp3; output rd_dv_ddr_hp3; input ddr_wr_ack0; output ddr_wr_dv0; output [31:0]ddr_wr_addr0; output [1023:0]ddr_wr_data0; output [7:0]ddr_wr_bytes0; input ddr_rd_dv0; input [1023:0] ddr_rd_data0; output ddr_rd_req0; output [31:0] ddr_rd_addr0; output [7:0] ddr_rd_bytes0; input ddr_wr_ack1; output ddr_wr_dv1; output [31:0]ddr_wr_addr1; output [1023:0]ddr_wr_data1; output [7:0]ddr_wr_bytes1; input ddr_rd_dv1; input [1023:0] ddr_rd_data1; output ddr_rd_req1; output [31:0] ddr_rd_addr1; output [7:0] ddr_rd_bytes1; output wr_ack_ocm_hp0; input wr_dv_ocm_hp0; input rd_req_ocm_hp0; output rd_dv_ocm_hp0; output [1023:0] rd_data_ocm_hp0; output wr_ack_ocm_hp1; input wr_dv_ocm_hp1; input rd_req_ocm_hp1; output rd_dv_ocm_hp1; output [1023:0] rd_data_ocm_hp1; output wr_ack_ocm_hp2; input wr_dv_ocm_hp2; input rd_req_ocm_hp2; output rd_dv_ocm_hp2; output [1023:0] rd_data_ocm_hp2; output wr_ack_ocm_hp3; input wr_dv_ocm_hp3; input rd_req_ocm_hp3; output rd_dv_ocm_hp3; output [1023:0] rd_data_ocm_hp3; input ocm_wr_ack; output ocm_wr_dv; output [31:0]ocm_wr_addr; output [1023:0]ocm_wr_data; output [7:0]ocm_wr_bytes; input ocm_rd_dv; input [1023:0] ocm_rd_data; output ocm_rd_req; output [31:0] ocm_rd_addr; output [7:0] ocm_rd_bytes; /* FOR DDR / processing_system7_bfm_v2_0_5_arb_hp0_1 ddr_hp01 ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp0(w_qos_hp0), .r_qos_hp0(r_qos_hp0), .w_qos_hp1(w_qos_hp1), .r_qos_hp1(r_qos_hp1), .wr_ack_ddr_hp0(wr_ack_ddr_hp0), .wr_data_hp0(wr_data_hp0), .wr_addr_hp0(wr_addr_hp0), .wr_bytes_hp0(wr_bytes_hp0), .wr_dv_ddr_hp0(wr_dv_ddr_hp0), .rd_req_ddr_hp0(rd_req_ddr_hp0), .rd_addr_hp0(rd_addr_hp0), .rd_bytes_hp0(rd_bytes_hp0), .rd_data_ddr_hp0(rd_data_ddr_hp0), .rd_dv_ddr_hp0(rd_dv_ddr_hp0), .wr_ack_ddr_hp1(wr_ack_ddr_hp1), .wr_data_hp1(wr_data_hp1), .wr_addr_hp1(wr_addr_hp1), .wr_bytes_hp1(wr_bytes_hp1), .wr_dv_ddr_hp1(wr_dv_ddr_hp1), .rd_req_ddr_hp1(rd_req_ddr_hp1), .rd_addr_hp1(rd_addr_hp1), .rd_bytes_hp1(rd_bytes_hp1), .rd_data_ddr_hp1(rd_data_ddr_hp1), .rd_dv_ddr_hp1(rd_dv_ddr_hp1), .ddr_wr_ack(ddr_wr_ack0), .ddr_wr_dv(ddr_wr_dv0), .ddr_rd_req(ddr_rd_req0), .ddr_rd_dv(ddr_rd_dv0), .ddr_rd_qos(ddr_rd_qos0), .ddr_wr_qos(ddr_wr_qos0), .ddr_wr_addr(ddr_wr_addr0), .ddr_wr_data(ddr_wr_data0), .ddr_wr_bytes(ddr_wr_bytes0), .ddr_rd_addr(ddr_rd_addr0), .ddr_rd_data(ddr_rd_data0), .ddr_rd_bytes(ddr_rd_bytes0) ); / FOR DDR / processing_system7_bfm_v2_0_5_arb_hp2_3 ddr_hp23 ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp2(w_qos_hp2), .r_qos_hp2(r_qos_hp2), .w_qos_hp3(w_qos_hp3), .r_qos_hp3(r_qos_hp3), .wr_ack_ddr_hp2(wr_ack_ddr_hp2), .wr_data_hp2(wr_data_hp2), .wr_addr_hp2(wr_addr_hp2), .wr_bytes_hp2(wr_bytes_hp2), .wr_dv_ddr_hp2(wr_dv_ddr_hp2), .rd_req_ddr_hp2(rd_req_ddr_hp2), .rd_addr_hp2(rd_addr_hp2), .rd_bytes_hp2(rd_bytes_hp2), .rd_data_ddr_hp2(rd_data_ddr_hp2), .rd_dv_ddr_hp2(rd_dv_ddr_hp2), .wr_ack_ddr_hp3(wr_ack_ddr_hp3), .wr_data_hp3(wr_data_hp3), .wr_addr_hp3(wr_addr_hp3), .wr_bytes_hp3(wr_bytes_hp3), .wr_dv_ddr_hp3(wr_dv_ddr_hp3), .rd_req_ddr_hp3(rd_req_ddr_hp3), .rd_addr_hp3(rd_addr_hp3), .rd_bytes_hp3(rd_bytes_hp3), .rd_data_ddr_hp3(rd_data_ddr_hp3), .rd_dv_ddr_hp3(rd_dv_ddr_hp3), .ddr_wr_ack(ddr_wr_ack1), .ddr_wr_dv(ddr_wr_dv1), .ddr_rd_req(ddr_rd_req1), .ddr_rd_dv(ddr_rd_dv1), .ddr_rd_qos(ddr_rd_qos1), .ddr_wr_qos(ddr_wr_qos1), .ddr_wr_addr(ddr_wr_addr1), .ddr_wr_data(ddr_wr_data1), .ddr_wr_bytes(ddr_wr_bytes1), .ddr_rd_addr(ddr_rd_addr1), .ddr_rd_data(ddr_rd_data1), .ddr_rd_bytes(ddr_rd_bytes1) ); / FOR OCM_WR / processing_system7_bfm_v2_0_5_arb_wr_4 ocm_wr_hp( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_hp0), .qos2(w_qos_hp1), .qos3(w_qos_hp2), .qos4(w_qos_hp3), .prt_dv1(wr_dv_ocm_hp0), .prt_dv2(wr_dv_ocm_hp1), .prt_dv3(wr_dv_ocm_hp2), .prt_dv4(wr_dv_ocm_hp3), .prt_data1(wr_data_hp0), .prt_data2(wr_data_hp1), .prt_data3(wr_data_hp2), .prt_data4(wr_data_hp3), .prt_addr1(wr_addr_hp0), .prt_addr2(wr_addr_hp1), .prt_addr3(wr_addr_hp2), .prt_addr4(wr_addr_hp3), .prt_bytes1(wr_bytes_hp0), .prt_bytes2(wr_bytes_hp1), .prt_bytes3(wr_bytes_hp2), .prt_bytes4(wr_bytes_hp3), .prt_ack1(wr_ack_ocm_hp0), .prt_ack2(wr_ack_ocm_hp1), .prt_ack3(wr_ack_ocm_hp2), .prt_ack4(wr_ack_ocm_hp3), .prt_qos(ocm_wr_qos), .prt_req(ocm_wr_dv), .prt_data(ocm_wr_data), .prt_addr(ocm_wr_addr), .prt_bytes(ocm_wr_bytes), .prt_ack(ocm_wr_ack) ); / FOR OCM_RD */ processing_system7_bfm_v2_0_5_arb_rd_4 ocm_rd_hp( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_hp0), .qos2(r_qos_hp1), .qos3(r_qos_hp2), .qos4(r_qos_hp3), .prt_req1(rd_req_ocm_hp0), .prt_req2(rd_req_ocm_hp1), .prt_req3(rd_req_ocm_hp2), .prt_req4(rd_req_ocm_hp3), .prt_data1(rd_data_ocm_hp0), .prt_data2(rd_data_ocm_hp1), .prt_data3(rd_data_ocm_hp2), .prt_data4(rd_data_ocm_hp3), .prt_addr1(rd_addr_hp0), .prt_addr2(rd_addr_hp1), .prt_addr3(rd_addr_hp2), .prt_addr4(rd_addr_hp3), .prt_bytes1(rd_bytes_hp0), .prt_bytes2(rd_bytes_hp1), .prt_bytes3(rd_bytes_hp2), .prt_bytes4(rd_bytes_hp3), .prt_dv1(rd_dv_ocm_hp0), .prt_dv2(rd_dv_ocm_hp1), .prt_dv3(rd_dv_ocm_hp2), .prt_dv4(rd_dv_ocm_hp3), .prt_qos(ocm_rd_qos), .prt_req(ocm_rd_req), .prt_data(ocm_rd_data), .prt_addr(ocm_rd_addr), .prt_bytes(ocm_rd_bytes), .prt_dv(ocm_rd_dv) ); endmodule
module processing_system7_bfm_v2_0_5_reg_map(); `include "processing_system7_bfm_v2_0_5_local_params.v" /* Register definitions / `include "processing_system7_bfm_v2_0_5_reg_params.v" parameter mem_size = 32'h2000_0000; ///as the memory is implemented 4 byte wide parameter xsim_mem_size = 32'h1000_0000; ///as the memory is implemented 4 byte wide 256 MB `ifdef XSIM_ISIM reg [data_width-1:0] reg_mem0 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] reg_mem1 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem parameter addr_offset_bits = 26; `else reg /sparse/ [data_width-1:0] reg_mem [0:(mem_size/mem_width)-1]; // 512 MB needed for reg space parameter addr_offset_bits = 27; `endif / preload reset_values from file / task automatic pre_load_rst_values; input dummy; begin `include "processing_system7_bfm_v2_0_5_reg_init.v" / This file has list of set_reset_data() calls to set the reset value for each register/ end endtask / writes the reset data into the reg memory / task automatic set_reset_data; input [addr_width-1:0] address; input [data_width-1:0] data; reg [addr_width-1:0] addr; begin addr = address >> 2; `ifdef XSIM_ISIM case(addr[addr_width-1:addr_offset_bits]) 14 : reg_mem0[addr[addr_offset_bits-1:0]] = data; 15 : reg_mem1[addr[addr_offset_bits-1:0]] = data; endcase `else reg_mem[addr[addr_offset_bits-1:0]] = data; `endif end endtask / writes the data into the reg memory / task automatic set_data; input [addr_width-1:0] addr; input [data_width-1:0] data; begin `ifdef XSIM_ISIM case(addr[addr_width-1:addr_offset_bits]) 6'h0E : reg_mem0[addr[addr_offset_bits-1:0]] = data; 6'h0F : reg_mem1[addr[addr_offset_bits-1:0]] = data; endcase `else reg_mem[addr[addr_offset_bits-1:0]] = data; `endif end endtask / get the read data from reg mem / task automatic get_data; input [addr_width-1:0] addr; output [data_width-1:0] data; begin `ifdef XSIM_ISIM case(addr[addr_width-1:addr_offset_bits]) 6'h0E : data = reg_mem0[addr[addr_offset_bits-1:0]]; 6'h0F : data = reg_mem1[addr[addr_offset_bits-1:0]]; endcase `else data = reg_mem[addr[addr_offset_bits-1:0]]; `endif end endtask / read chunk of registers / task read_reg_mem; output[max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; integer i; reg [addr_width-1:0] addr; reg [data_width-1:0] temp_rd_data; reg [max_burst_bits-1:0] temp_data; integer bytes_left; begin addr = start_addr >> shft_addr_bits; bytes_left = no_of_bytes; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Reading Register Map starting address (0x%0h) -> %0d bytes",$time, DISP_INT_INFO, start_addr,no_of_bytes ); `endif / Get first data ... if unaligned address / get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits- data_width]); if(no_of_bytes < mem_width ) begin repeat(max_burst_bytes - mem_width) temp_data = temp_data >> 8; end else begin bytes_left = bytes_left - mem_width; addr = addr+1; / Got first data / while (bytes_left > (mem_width-1) ) begin temp_data = temp_data >> data_width; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); addr = addr+1; bytes_left = bytes_left - mem_width; end / Get last valid data in the burst/ get_data(addr,temp_rd_data); while(bytes_left > 0) begin temp_data = temp_data >> 8; temp_data[max_burst_bits-1 : max_burst_bits-8] = temp_rd_data[7:0]; temp_rd_data = temp_rd_data >> 8; bytes_left = bytes_left - 1; end / align to the brst_byte length */ repeat(max_burst_bytes - no_of_bytes) temp_data = temp_data >> 8; end data = temp_data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Reading Register Map starting address (0x%0h), Data returned(0x%0h)",$time, DISP_INT_INFO, start_addr, data ); `endif end endtask initial begin pre_load_rst_values(1); end endmodule
module processing_system7_bfm_v2_0_5_processing_system7_bfm ( CAN0_PHY_TX, CAN0_PHY_RX, CAN1_PHY_TX, CAN1_PHY_RX, ENET0_GMII_TX_EN, ENET0_GMII_TX_ER, ENET0_MDIO_MDC, ENET0_MDIO_O, ENET0_MDIO_T, ENET0_PTP_DELAY_REQ_RX, ENET0_PTP_DELAY_REQ_TX, ENET0_PTP_PDELAY_REQ_RX, ENET0_PTP_PDELAY_REQ_TX, ENET0_PTP_PDELAY_RESP_RX, ENET0_PTP_PDELAY_RESP_TX, ENET0_PTP_SYNC_FRAME_RX, ENET0_PTP_SYNC_FRAME_TX, ENET0_SOF_RX, ENET0_SOF_TX, ENET0_GMII_TXD, ENET0_GMII_COL, ENET0_GMII_CRS, ENET0_EXT_INTIN, ENET0_GMII_RX_CLK, ENET0_GMII_RX_DV, ENET0_GMII_RX_ER, ENET0_GMII_TX_CLK, ENET0_MDIO_I, ENET0_GMII_RXD, ENET1_GMII_TX_EN, ENET1_GMII_TX_ER, ENET1_MDIO_MDC, ENET1_MDIO_O, ENET1_MDIO_T, ENET1_PTP_DELAY_REQ_RX, ENET1_PTP_DELAY_REQ_TX, ENET1_PTP_PDELAY_REQ_RX, ENET1_PTP_PDELAY_REQ_TX, ENET1_PTP_PDELAY_RESP_RX, ENET1_PTP_PDELAY_RESP_TX, ENET1_PTP_SYNC_FRAME_RX, ENET1_PTP_SYNC_FRAME_TX, ENET1_SOF_RX, ENET1_SOF_TX, ENET1_GMII_TXD, ENET1_GMII_COL, ENET1_GMII_CRS, ENET1_EXT_INTIN, ENET1_GMII_RX_CLK, ENET1_GMII_RX_DV, ENET1_GMII_RX_ER, ENET1_GMII_TX_CLK, ENET1_MDIO_I, ENET1_GMII_RXD, GPIO_I, GPIO_O, GPIO_T, I2C0_SDA_I, I2C0_SDA_O, I2C0_SDA_T, I2C0_SCL_I, I2C0_SCL_O, I2C0_SCL_T, I2C1_SDA_I, I2C1_SDA_O, I2C1_SDA_T, I2C1_SCL_I, I2C1_SCL_O, I2C1_SCL_T, PJTAG_TCK, PJTAG_TMS, PJTAG_TD_I, PJTAG_TD_T, PJTAG_TD_O, SDIO0_CLK, SDIO0_CLK_FB, SDIO0_CMD_O, SDIO0_CMD_I, SDIO0_CMD_T, SDIO0_DATA_I, SDIO0_DATA_O, SDIO0_DATA_T, SDIO0_LED, SDIO0_CDN, SDIO0_WP, SDIO0_BUSPOW, SDIO0_BUSVOLT, SDIO1_CLK, SDIO1_CLK_FB, SDIO1_CMD_O, SDIO1_CMD_I, SDIO1_CMD_T, SDIO1_DATA_I, SDIO1_DATA_O, SDIO1_DATA_T, SDIO1_LED, SDIO1_CDN, SDIO1_WP, SDIO1_BUSPOW, SDIO1_BUSVOLT, SPI0_SCLK_I, SPI0_SCLK_O, SPI0_SCLK_T, SPI0_MOSI_I, SPI0_MOSI_O, SPI0_MOSI_T, SPI0_MISO_I, SPI0_MISO_O, SPI0_MISO_T, SPI0_SS_I, SPI0_SS_O, SPI0_SS1_O, SPI0_SS2_O, SPI0_SS_T, SPI1_SCLK_I, SPI1_SCLK_O, SPI1_SCLK_T, SPI1_MOSI_I, SPI1_MOSI_O, SPI1_MOSI_T, SPI1_MISO_I, SPI1_MISO_O, SPI1_MISO_T, SPI1_SS_I, SPI1_SS_O, SPI1_SS1_O, SPI1_SS2_O, SPI1_SS_T, UART0_DTRN, UART0_RTSN, UART0_TX, UART0_CTSN, UART0_DCDN, UART0_DSRN, UART0_RIN, UART0_RX, UART1_DTRN, UART1_RTSN, UART1_TX, UART1_CTSN, UART1_DCDN, UART1_DSRN, UART1_RIN, UART1_RX, TTC0_WAVE0_OUT, TTC0_WAVE1_OUT, TTC0_WAVE2_OUT, TTC0_CLK0_IN, TTC0_CLK1_IN, TTC0_CLK2_IN, TTC1_WAVE0_OUT, TTC1_WAVE1_OUT, TTC1_WAVE2_OUT, TTC1_CLK0_IN, TTC1_CLK1_IN, TTC1_CLK2_IN, WDT_CLK_IN, WDT_RST_OUT, TRACE_CLK, TRACE_CTL, TRACE_DATA, USB0_PORT_INDCTL, USB1_PORT_INDCTL, USB0_VBUS_PWRSELECT, USB1_VBUS_PWRSELECT, USB0_VBUS_PWRFAULT, USB1_VBUS_PWRFAULT, SRAM_INTIN, M_AXI_GP0_ARVALID, M_AXI_GP0_AWVALID, M_AXI_GP0_BREADY, M_AXI_GP0_RREADY, M_AXI_GP0_WLAST, M_AXI_GP0_WVALID, M_AXI_GP0_ARID, M_AXI_GP0_AWID, M_AXI_GP0_WID, M_AXI_GP0_ARBURST, M_AXI_GP0_ARLOCK, M_AXI_GP0_ARSIZE, M_AXI_GP0_AWBURST, M_AXI_GP0_AWLOCK, M_AXI_GP0_AWSIZE, M_AXI_GP0_ARPROT, M_AXI_GP0_AWPROT, M_AXI_GP0_ARADDR, M_AXI_GP0_AWADDR, M_AXI_GP0_WDATA, M_AXI_GP0_ARCACHE, M_AXI_GP0_ARLEN, M_AXI_GP0_ARQOS, M_AXI_GP0_AWCACHE, M_AXI_GP0_AWLEN, M_AXI_GP0_AWQOS, M_AXI_GP0_WSTRB, M_AXI_GP0_ACLK, M_AXI_GP0_ARREADY, M_AXI_GP0_AWREADY, M_AXI_GP0_BVALID, M_AXI_GP0_RLAST, M_AXI_GP0_RVALID, M_AXI_GP0_WREADY, M_AXI_GP0_BID, M_AXI_GP0_RID, M_AXI_GP0_BRESP, M_AXI_GP0_RRESP, M_AXI_GP0_RDATA, M_AXI_GP1_ARVALID, M_AXI_GP1_AWVALID, M_AXI_GP1_BREADY, M_AXI_GP1_RREADY, M_AXI_GP1_WLAST, M_AXI_GP1_WVALID, M_AXI_GP1_ARID, M_AXI_GP1_AWID, M_AXI_GP1_WID, M_AXI_GP1_ARBURST, M_AXI_GP1_ARLOCK, M_AXI_GP1_ARSIZE, M_AXI_GP1_AWBURST, M_AXI_GP1_AWLOCK, M_AXI_GP1_AWSIZE, M_AXI_GP1_ARPROT, M_AXI_GP1_AWPROT, M_AXI_GP1_ARADDR, M_AXI_GP1_AWADDR, M_AXI_GP1_WDATA, M_AXI_GP1_ARCACHE, M_AXI_GP1_ARLEN, M_AXI_GP1_ARQOS, M_AXI_GP1_AWCACHE, M_AXI_GP1_AWLEN, M_AXI_GP1_AWQOS, M_AXI_GP1_WSTRB, M_AXI_GP1_ACLK, M_AXI_GP1_ARREADY, M_AXI_GP1_AWREADY, M_AXI_GP1_BVALID, M_AXI_GP1_RLAST, M_AXI_GP1_RVALID, M_AXI_GP1_WREADY, M_AXI_GP1_BID, M_AXI_GP1_RID, M_AXI_GP1_BRESP, M_AXI_GP1_RRESP, M_AXI_GP1_RDATA, S_AXI_GP0_ARREADY, S_AXI_GP0_AWREADY, S_AXI_GP0_BVALID, S_AXI_GP0_RLAST, S_AXI_GP0_RVALID, S_AXI_GP0_WREADY, S_AXI_GP0_BRESP, S_AXI_GP0_RRESP, S_AXI_GP0_RDATA, S_AXI_GP0_BID, S_AXI_GP0_RID, S_AXI_GP0_ACLK, S_AXI_GP0_ARVALID, S_AXI_GP0_AWVALID, S_AXI_GP0_BREADY, S_AXI_GP0_RREADY, S_AXI_GP0_WLAST, S_AXI_GP0_WVALID, S_AXI_GP0_ARBURST, S_AXI_GP0_ARLOCK, S_AXI_GP0_ARSIZE, S_AXI_GP0_AWBURST, S_AXI_GP0_AWLOCK, S_AXI_GP0_AWSIZE, S_AXI_GP0_ARPROT, S_AXI_GP0_AWPROT, S_AXI_GP0_ARADDR, S_AXI_GP0_AWADDR, S_AXI_GP0_WDATA, S_AXI_GP0_ARCACHE, S_AXI_GP0_ARLEN, S_AXI_GP0_ARQOS, S_AXI_GP0_AWCACHE, S_AXI_GP0_AWLEN, S_AXI_GP0_AWQOS, S_AXI_GP0_WSTRB, S_AXI_GP0_ARID, S_AXI_GP0_AWID, S_AXI_GP0_WID, S_AXI_GP1_ARREADY, S_AXI_GP1_AWREADY, S_AXI_GP1_BVALID, S_AXI_GP1_RLAST, S_AXI_GP1_RVALID, S_AXI_GP1_WREADY, S_AXI_GP1_BRESP, S_AXI_GP1_RRESP, S_AXI_GP1_RDATA, S_AXI_GP1_BID, S_AXI_GP1_RID, S_AXI_GP1_ACLK, S_AXI_GP1_ARVALID, S_AXI_GP1_AWVALID, S_AXI_GP1_BREADY, S_AXI_GP1_RREADY, S_AXI_GP1_WLAST, S_AXI_GP1_WVALID, S_AXI_GP1_ARBURST, S_AXI_GP1_ARLOCK, S_AXI_GP1_ARSIZE, S_AXI_GP1_AWBURST, S_AXI_GP1_AWLOCK, S_AXI_GP1_AWSIZE, S_AXI_GP1_ARPROT, S_AXI_GP1_AWPROT, S_AXI_GP1_ARADDR, S_AXI_GP1_AWADDR, S_AXI_GP1_WDATA, S_AXI_GP1_ARCACHE, S_AXI_GP1_ARLEN, S_AXI_GP1_ARQOS, S_AXI_GP1_AWCACHE, S_AXI_GP1_AWLEN, S_AXI_GP1_AWQOS, S_AXI_GP1_WSTRB, S_AXI_GP1_ARID, S_AXI_GP1_AWID, S_AXI_GP1_WID, S_AXI_ACP_AWREADY, S_AXI_ACP_ARREADY, S_AXI_ACP_BVALID, S_AXI_ACP_RLAST, S_AXI_ACP_RVALID, S_AXI_ACP_WREADY, S_AXI_ACP_BRESP, S_AXI_ACP_RRESP, S_AXI_ACP_BID, S_AXI_ACP_RID, S_AXI_ACP_RDATA, S_AXI_ACP_ACLK, S_AXI_ACP_ARVALID, S_AXI_ACP_AWVALID, S_AXI_ACP_BREADY, S_AXI_ACP_RREADY, S_AXI_ACP_WLAST, S_AXI_ACP_WVALID, S_AXI_ACP_ARID, S_AXI_ACP_ARPROT, S_AXI_ACP_AWID, S_AXI_ACP_AWPROT, S_AXI_ACP_WID, S_AXI_ACP_ARADDR, S_AXI_ACP_AWADDR, S_AXI_ACP_ARCACHE, S_AXI_ACP_ARLEN, S_AXI_ACP_ARQOS, S_AXI_ACP_AWCACHE, S_AXI_ACP_AWLEN, S_AXI_ACP_AWQOS, S_AXI_ACP_ARBURST, S_AXI_ACP_ARLOCK, S_AXI_ACP_ARSIZE, S_AXI_ACP_AWBURST, S_AXI_ACP_AWLOCK, S_AXI_ACP_AWSIZE, S_AXI_ACP_ARUSER, S_AXI_ACP_AWUSER, S_AXI_ACP_WDATA, S_AXI_ACP_WSTRB, S_AXI_HP0_ARREADY, S_AXI_HP0_AWREADY, S_AXI_HP0_BVALID, S_AXI_HP0_RLAST, S_AXI_HP0_RVALID, S_AXI_HP0_WREADY, S_AXI_HP0_BRESP, S_AXI_HP0_RRESP, S_AXI_HP0_BID, S_AXI_HP0_RID, S_AXI_HP0_RDATA, S_AXI_HP0_RCOUNT, S_AXI_HP0_WCOUNT, S_AXI_HP0_RACOUNT, S_AXI_HP0_WACOUNT, S_AXI_HP0_ACLK, S_AXI_HP0_ARVALID, S_AXI_HP0_AWVALID, S_AXI_HP0_BREADY, S_AXI_HP0_RDISSUECAP1_EN, S_AXI_HP0_RREADY, S_AXI_HP0_WLAST, S_AXI_HP0_WRISSUECAP1_EN, S_AXI_HP0_WVALID, S_AXI_HP0_ARBURST, S_AXI_HP0_ARLOCK, S_AXI_HP0_ARSIZE, S_AXI_HP0_AWBURST, S_AXI_HP0_AWLOCK, S_AXI_HP0_AWSIZE, S_AXI_HP0_ARPROT, S_AXI_HP0_AWPROT, S_AXI_HP0_ARADDR, S_AXI_HP0_AWADDR, S_AXI_HP0_ARCACHE, S_AXI_HP0_ARLEN, S_AXI_HP0_ARQOS, S_AXI_HP0_AWCACHE, S_AXI_HP0_AWLEN, S_AXI_HP0_AWQOS, S_AXI_HP0_ARID, S_AXI_HP0_AWID, S_AXI_HP0_WID, S_AXI_HP0_WDATA, S_AXI_HP0_WSTRB, S_AXI_HP1_ARREADY, S_AXI_HP1_AWREADY, S_AXI_HP1_BVALID, S_AXI_HP1_RLAST, S_AXI_HP1_RVALID, S_AXI_HP1_WREADY, S_AXI_HP1_BRESP, S_AXI_HP1_RRESP, S_AXI_HP1_BID, S_AXI_HP1_RID, S_AXI_HP1_RDATA, S_AXI_HP1_RCOUNT, S_AXI_HP1_WCOUNT, S_AXI_HP1_RACOUNT, S_AXI_HP1_WACOUNT, S_AXI_HP1_ACLK, S_AXI_HP1_ARVALID, S_AXI_HP1_AWVALID, S_AXI_HP1_BREADY, S_AXI_HP1_RDISSUECAP1_EN, S_AXI_HP1_RREADY, S_AXI_HP1_WLAST, S_AXI_HP1_WRISSUECAP1_EN, S_AXI_HP1_WVALID, S_AXI_HP1_ARBURST, S_AXI_HP1_ARLOCK, S_AXI_HP1_ARSIZE, S_AXI_HP1_AWBURST, S_AXI_HP1_AWLOCK, S_AXI_HP1_AWSIZE, S_AXI_HP1_ARPROT, S_AXI_HP1_AWPROT, S_AXI_HP1_ARADDR, S_AXI_HP1_AWADDR, S_AXI_HP1_ARCACHE, S_AXI_HP1_ARLEN, S_AXI_HP1_ARQOS, S_AXI_HP1_AWCACHE, S_AXI_HP1_AWLEN, S_AXI_HP1_AWQOS, S_AXI_HP1_ARID, S_AXI_HP1_AWID, S_AXI_HP1_WID, S_AXI_HP1_WDATA, S_AXI_HP1_WSTRB, S_AXI_HP2_ARREADY, S_AXI_HP2_AWREADY, S_AXI_HP2_BVALID, S_AXI_HP2_RLAST, S_AXI_HP2_RVALID, S_AXI_HP2_WREADY, S_AXI_HP2_BRESP, S_AXI_HP2_RRESP, S_AXI_HP2_BID, S_AXI_HP2_RID, S_AXI_HP2_RDATA, S_AXI_HP2_RCOUNT, S_AXI_HP2_WCOUNT, S_AXI_HP2_RACOUNT, S_AXI_HP2_WACOUNT, S_AXI_HP2_ACLK, S_AXI_HP2_ARVALID, S_AXI_HP2_AWVALID, S_AXI_HP2_BREADY, S_AXI_HP2_RDISSUECAP1_EN, S_AXI_HP2_RREADY, S_AXI_HP2_WLAST, S_AXI_HP2_WRISSUECAP1_EN, S_AXI_HP2_WVALID, S_AXI_HP2_ARBURST, S_AXI_HP2_ARLOCK, S_AXI_HP2_ARSIZE, S_AXI_HP2_AWBURST, S_AXI_HP2_AWLOCK, S_AXI_HP2_AWSIZE, S_AXI_HP2_ARPROT, S_AXI_HP2_AWPROT, S_AXI_HP2_ARADDR, S_AXI_HP2_AWADDR, S_AXI_HP2_ARCACHE, S_AXI_HP2_ARLEN, S_AXI_HP2_ARQOS, S_AXI_HP2_AWCACHE, S_AXI_HP2_AWLEN, S_AXI_HP2_AWQOS, S_AXI_HP2_ARID, S_AXI_HP2_AWID, S_AXI_HP2_WID, S_AXI_HP2_WDATA, S_AXI_HP2_WSTRB, S_AXI_HP3_ARREADY, S_AXI_HP3_AWREADY, S_AXI_HP3_BVALID, S_AXI_HP3_RLAST, S_AXI_HP3_RVALID, S_AXI_HP3_WREADY, S_AXI_HP3_BRESP, S_AXI_HP3_RRESP, S_AXI_HP3_BID, S_AXI_HP3_RID, S_AXI_HP3_RDATA, S_AXI_HP3_RCOUNT, S_AXI_HP3_WCOUNT, S_AXI_HP3_RACOUNT, S_AXI_HP3_WACOUNT, S_AXI_HP3_ACLK, S_AXI_HP3_ARVALID, S_AXI_HP3_AWVALID, S_AXI_HP3_BREADY, S_AXI_HP3_RDISSUECAP1_EN, S_AXI_HP3_RREADY, S_AXI_HP3_WLAST, S_AXI_HP3_WRISSUECAP1_EN, S_AXI_HP3_WVALID, S_AXI_HP3_ARBURST, S_AXI_HP3_ARLOCK, S_AXI_HP3_ARSIZE, S_AXI_HP3_AWBURST, S_AXI_HP3_AWLOCK, S_AXI_HP3_AWSIZE, S_AXI_HP3_ARPROT, S_AXI_HP3_AWPROT, S_AXI_HP3_ARADDR, S_AXI_HP3_AWADDR, S_AXI_HP3_ARCACHE, S_AXI_HP3_ARLEN, S_AXI_HP3_ARQOS, S_AXI_HP3_AWCACHE, S_AXI_HP3_AWLEN, S_AXI_HP3_AWQOS, S_AXI_HP3_ARID, S_AXI_HP3_AWID, S_AXI_HP3_WID, S_AXI_HP3_WDATA, S_AXI_HP3_WSTRB, DMA0_DATYPE, DMA0_DAVALID, DMA0_DRREADY, DMA0_ACLK, DMA0_DAREADY, DMA0_DRLAST, DMA0_DRVALID, DMA0_DRTYPE, DMA1_DATYPE, DMA1_DAVALID, DMA1_DRREADY, DMA1_ACLK, DMA1_DAREADY, DMA1_DRLAST, DMA1_DRVALID, DMA1_DRTYPE, DMA2_DATYPE, DMA2_DAVALID, DMA2_DRREADY, DMA2_ACLK, DMA2_DAREADY, DMA2_DRLAST, DMA2_DRVALID, DMA3_DRVALID, DMA3_DATYPE, DMA3_DAVALID, DMA3_DRREADY, DMA3_ACLK, DMA3_DAREADY, DMA3_DRLAST, DMA2_DRTYPE, DMA3_DRTYPE, FTMD_TRACEIN_DATA, FTMD_TRACEIN_VALID, FTMD_TRACEIN_CLK, FTMD_TRACEIN_ATID, FTMT_F2P_TRIG, FTMT_F2P_TRIGACK, FTMT_F2P_DEBUG, FTMT_P2F_TRIGACK, FTMT_P2F_TRIG, FTMT_P2F_DEBUG, FCLK_CLK3, FCLK_CLK2, FCLK_CLK1, FCLK_CLK0, FCLK_CLKTRIG3_N, FCLK_CLKTRIG2_N, FCLK_CLKTRIG1_N, FCLK_CLKTRIG0_N, FCLK_RESET3_N, FCLK_RESET2_N, FCLK_RESET1_N, FCLK_RESET0_N, FPGA_IDLE_N, DDR_ARB, IRQ_F2P, Core0_nFIQ, Core0_nIRQ, Core1_nFIQ, Core1_nIRQ, EVENT_EVENTO, EVENT_STANDBYWFE, EVENT_STANDBYWFI, EVENT_EVENTI, MIO, DDR_Clk, DDR_Clk_n, DDR_CKE, DDR_CS_n, DDR_RAS_n, DDR_CAS_n, DDR_WEB, DDR_BankAddr, DDR_Addr, DDR_ODT, DDR_DRSTB, DDR_DQ, DDR_DM, DDR_DQS, DDR_DQS_n, DDR_VRN, DDR_VRP, PS_SRSTB, PS_CLK, PS_PORB, IRQ_P2F_DMAC_ABORT, IRQ_P2F_DMAC0, IRQ_P2F_DMAC1, IRQ_P2F_DMAC2, IRQ_P2F_DMAC3, IRQ_P2F_DMAC4, IRQ_P2F_DMAC5, IRQ_P2F_DMAC6, IRQ_P2F_DMAC7, IRQ_P2F_SMC, IRQ_P2F_QSPI, IRQ_P2F_CTI, IRQ_P2F_GPIO, IRQ_P2F_USB0, IRQ_P2F_ENET0, IRQ_P2F_ENET_WAKE0, IRQ_P2F_SDIO0, IRQ_P2F_I2C0, IRQ_P2F_SPI0, IRQ_P2F_UART0, IRQ_P2F_CAN0, IRQ_P2F_USB1, IRQ_P2F_ENET1, IRQ_P2F_ENET_WAKE1, IRQ_P2F_SDIO1, IRQ_P2F_I2C1, IRQ_P2F_SPI1, IRQ_P2F_UART1, IRQ_P2F_CAN1 ); /* parameters for gen_clk / parameter C_FCLK_CLK0_FREQ = 50; parameter C_FCLK_CLK1_FREQ = 50; parameter C_FCLK_CLK3_FREQ = 50; parameter C_FCLK_CLK2_FREQ = 50; parameter C_HIGH_OCM_EN = 0; / parameters for HP ports / parameter C_USE_S_AXI_HP0 = 0; parameter C_USE_S_AXI_HP1 = 0; parameter C_USE_S_AXI_HP2 = 0; parameter C_USE_S_AXI_HP3 = 0; parameter C_S_AXI_HP0_DATA_WIDTH = 32; parameter C_S_AXI_HP1_DATA_WIDTH = 32; parameter C_S_AXI_HP2_DATA_WIDTH = 32; parameter C_S_AXI_HP3_DATA_WIDTH = 32; parameter C_M_AXI_GP0_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP1_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP0_ENABLE_STATIC_REMAP = 0; parameter C_M_AXI_GP1_ENABLE_STATIC_REMAP = 0; / Do we need these parameter C_S_AXI_HP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP2_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP3_ENABLE_HIGHOCM = 0; / parameter C_S_AXI_HP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP2_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP3_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP2_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP3_HIGHADDR = 32'hFFFF_FFFF; / parameters for GP and ACP ports / parameter C_USE_M_AXI_GP0 = 0; parameter C_USE_M_AXI_GP1 = 0; parameter C_USE_S_AXI_GP0 = 1; parameter C_USE_S_AXI_GP1 = 1; / Do we need this? parameter C_M_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_M_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_ACP_ENABLE_HIGHOCM = 0;/ parameter C_S_AXI_GP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_GP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_USE_S_AXI_ACP = 1; parameter C_S_AXI_ACP_BASEADDR = 32'h0000_0000; parameter C_S_AXI_ACP_HIGHADDR = 32'hFFFF_FFFF; `include "processing_system7_bfm_v2_0_5_local_params.v" output CAN0_PHY_TX; input CAN0_PHY_RX; output CAN1_PHY_TX; input CAN1_PHY_RX; output ENET0_GMII_TX_EN; output ENET0_GMII_TX_ER; output ENET0_MDIO_MDC; output ENET0_MDIO_O; output ENET0_MDIO_T; output ENET0_PTP_DELAY_REQ_RX; output ENET0_PTP_DELAY_REQ_TX; output ENET0_PTP_PDELAY_REQ_RX; output ENET0_PTP_PDELAY_REQ_TX; output ENET0_PTP_PDELAY_RESP_RX; output ENET0_PTP_PDELAY_RESP_TX; output ENET0_PTP_SYNC_FRAME_RX; output ENET0_PTP_SYNC_FRAME_TX; output ENET0_SOF_RX; output ENET0_SOF_TX; output [7:0] ENET0_GMII_TXD; input ENET0_GMII_COL; input ENET0_GMII_CRS; input ENET0_EXT_INTIN; input ENET0_GMII_RX_CLK; input ENET0_GMII_RX_DV; input ENET0_GMII_RX_ER; input ENET0_GMII_TX_CLK; input ENET0_MDIO_I; input [7:0] ENET0_GMII_RXD; output ENET1_GMII_TX_EN; output ENET1_GMII_TX_ER; output ENET1_MDIO_MDC; output ENET1_MDIO_O; output ENET1_MDIO_T; output ENET1_PTP_DELAY_REQ_RX; output ENET1_PTP_DELAY_REQ_TX; output ENET1_PTP_PDELAY_REQ_RX; output ENET1_PTP_PDELAY_REQ_TX; output ENET1_PTP_PDELAY_RESP_RX; output ENET1_PTP_PDELAY_RESP_TX; output ENET1_PTP_SYNC_FRAME_RX; output ENET1_PTP_SYNC_FRAME_TX; output ENET1_SOF_RX; output ENET1_SOF_TX; output [7:0] ENET1_GMII_TXD; input ENET1_GMII_COL; input ENET1_GMII_CRS; input ENET1_EXT_INTIN; input ENET1_GMII_RX_CLK; input ENET1_GMII_RX_DV; input ENET1_GMII_RX_ER; input ENET1_GMII_TX_CLK; input ENET1_MDIO_I; input [7:0] ENET1_GMII_RXD; input [63:0] GPIO_I; output [63:0] GPIO_O; output [63:0] GPIO_T; input I2C0_SDA_I; output I2C0_SDA_O; output I2C0_SDA_T; input I2C0_SCL_I; output I2C0_SCL_O; output I2C0_SCL_T; input I2C1_SDA_I; output I2C1_SDA_O; output I2C1_SDA_T; input I2C1_SCL_I; output I2C1_SCL_O; output I2C1_SCL_T; input PJTAG_TCK; input PJTAG_TMS; input PJTAG_TD_I; output PJTAG_TD_T; output PJTAG_TD_O; output SDIO0_CLK; input SDIO0_CLK_FB; output SDIO0_CMD_O; input SDIO0_CMD_I; output SDIO0_CMD_T; input [3:0] SDIO0_DATA_I; output [3:0] SDIO0_DATA_O; output [3:0] SDIO0_DATA_T; output SDIO0_LED; input SDIO0_CDN; input SDIO0_WP; output SDIO0_BUSPOW; output [2:0] SDIO0_BUSVOLT; output SDIO1_CLK; input SDIO1_CLK_FB; output SDIO1_CMD_O; input SDIO1_CMD_I; output SDIO1_CMD_T; input [3:0] SDIO1_DATA_I; output [3:0] SDIO1_DATA_O; output [3:0] SDIO1_DATA_T; output SDIO1_LED; input SDIO1_CDN; input SDIO1_WP; output SDIO1_BUSPOW; output [2:0] SDIO1_BUSVOLT; input SPI0_SCLK_I; output SPI0_SCLK_O; output SPI0_SCLK_T; input SPI0_MOSI_I; output SPI0_MOSI_O; output SPI0_MOSI_T; input SPI0_MISO_I; output SPI0_MISO_O; output SPI0_MISO_T; input SPI0_SS_I; output SPI0_SS_O; output SPI0_SS1_O; output SPI0_SS2_O; output SPI0_SS_T; input SPI1_SCLK_I; output SPI1_SCLK_O; output SPI1_SCLK_T; input SPI1_MOSI_I; output SPI1_MOSI_O; output SPI1_MOSI_T; input SPI1_MISO_I; output SPI1_MISO_O; output SPI1_MISO_T; input SPI1_SS_I; output SPI1_SS_O; output SPI1_SS1_O; output SPI1_SS2_O; output SPI1_SS_T; output UART0_DTRN; output UART0_RTSN; output UART0_TX; input UART0_CTSN; input UART0_DCDN; input UART0_DSRN; input UART0_RIN; input UART0_RX; output UART1_DTRN; output UART1_RTSN; output UART1_TX; input UART1_CTSN; input UART1_DCDN; input UART1_DSRN; input UART1_RIN; input UART1_RX; output TTC0_WAVE0_OUT; output TTC0_WAVE1_OUT; output TTC0_WAVE2_OUT; input TTC0_CLK0_IN; input TTC0_CLK1_IN; input TTC0_CLK2_IN; output TTC1_WAVE0_OUT; output TTC1_WAVE1_OUT; output TTC1_WAVE2_OUT; input TTC1_CLK0_IN; input TTC1_CLK1_IN; input TTC1_CLK2_IN; input WDT_CLK_IN; output WDT_RST_OUT; input TRACE_CLK; output TRACE_CTL; output [31:0] TRACE_DATA; output [1:0] USB0_PORT_INDCTL; output [1:0] USB1_PORT_INDCTL; output USB0_VBUS_PWRSELECT; output USB1_VBUS_PWRSELECT; input USB0_VBUS_PWRFAULT; input USB1_VBUS_PWRFAULT; input SRAM_INTIN; output M_AXI_GP0_ARVALID; output M_AXI_GP0_AWVALID; output M_AXI_GP0_BREADY; output M_AXI_GP0_RREADY; output M_AXI_GP0_WLAST; output M_AXI_GP0_WVALID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_ARID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_AWID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_WID; output [1:0] M_AXI_GP0_ARBURST; output [1:0] M_AXI_GP0_ARLOCK; output [2:0] M_AXI_GP0_ARSIZE; output [1:0] M_AXI_GP0_AWBURST; output [1:0] M_AXI_GP0_AWLOCK; output [2:0] M_AXI_GP0_AWSIZE; output [2:0] M_AXI_GP0_ARPROT; output [2:0] M_AXI_GP0_AWPROT; output [31:0] M_AXI_GP0_ARADDR; output [31:0] M_AXI_GP0_AWADDR; output [31:0] M_AXI_GP0_WDATA; output [3:0] M_AXI_GP0_ARCACHE; output [3:0] M_AXI_GP0_ARLEN; output [3:0] M_AXI_GP0_ARQOS; output [3:0] M_AXI_GP0_AWCACHE; output [3:0] M_AXI_GP0_AWLEN; output [3:0] M_AXI_GP0_AWQOS; output [3:0] M_AXI_GP0_WSTRB; input M_AXI_GP0_ACLK; input M_AXI_GP0_ARREADY; input M_AXI_GP0_AWREADY; input M_AXI_GP0_BVALID; input M_AXI_GP0_RLAST; input M_AXI_GP0_RVALID; input M_AXI_GP0_WREADY; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_BID; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_RID; input [1:0] M_AXI_GP0_BRESP; input [1:0] M_AXI_GP0_RRESP; input [31:0] M_AXI_GP0_RDATA; output M_AXI_GP1_ARVALID; output M_AXI_GP1_AWVALID; output M_AXI_GP1_BREADY; output M_AXI_GP1_RREADY; output M_AXI_GP1_WLAST; output M_AXI_GP1_WVALID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_ARID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_AWID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_WID; output [1:0] M_AXI_GP1_ARBURST; output [1:0] M_AXI_GP1_ARLOCK; output [2:0] M_AXI_GP1_ARSIZE; output [1:0] M_AXI_GP1_AWBURST; output [1:0] M_AXI_GP1_AWLOCK; output [2:0] M_AXI_GP1_AWSIZE; output [2:0] M_AXI_GP1_ARPROT; output [2:0] M_AXI_GP1_AWPROT; output [31:0] M_AXI_GP1_ARADDR; output [31:0] M_AXI_GP1_AWADDR; output [31:0] M_AXI_GP1_WDATA; output [3:0] M_AXI_GP1_ARCACHE; output [3:0] M_AXI_GP1_ARLEN; output [3:0] M_AXI_GP1_ARQOS; output [3:0] M_AXI_GP1_AWCACHE; output [3:0] M_AXI_GP1_AWLEN; output [3:0] M_AXI_GP1_AWQOS; output [3:0] M_AXI_GP1_WSTRB; input M_AXI_GP1_ACLK; input M_AXI_GP1_ARREADY; input M_AXI_GP1_AWREADY; input M_AXI_GP1_BVALID; input M_AXI_GP1_RLAST; input M_AXI_GP1_RVALID; input M_AXI_GP1_WREADY; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_BID; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_RID; input [1:0] M_AXI_GP1_BRESP; input [1:0] M_AXI_GP1_RRESP; input [31:0] M_AXI_GP1_RDATA; output S_AXI_GP0_ARREADY; output S_AXI_GP0_AWREADY; output S_AXI_GP0_BVALID; output S_AXI_GP0_RLAST; output S_AXI_GP0_RVALID; output S_AXI_GP0_WREADY; output [1:0] S_AXI_GP0_BRESP; output [1:0] S_AXI_GP0_RRESP; output [31:0] S_AXI_GP0_RDATA; output [5:0] S_AXI_GP0_BID; output [5:0] S_AXI_GP0_RID; input S_AXI_GP0_ACLK; input S_AXI_GP0_ARVALID; input S_AXI_GP0_AWVALID; input S_AXI_GP0_BREADY; input S_AXI_GP0_RREADY; input S_AXI_GP0_WLAST; input S_AXI_GP0_WVALID; input [1:0] S_AXI_GP0_ARBURST; input [1:0] S_AXI_GP0_ARLOCK; input [2:0] S_AXI_GP0_ARSIZE; input [1:0] S_AXI_GP0_AWBURST; input [1:0] S_AXI_GP0_AWLOCK; input [2:0] S_AXI_GP0_AWSIZE; input [2:0] S_AXI_GP0_ARPROT; input [2:0] S_AXI_GP0_AWPROT; input [31:0] S_AXI_GP0_ARADDR; input [31:0] S_AXI_GP0_AWADDR; input [31:0] S_AXI_GP0_WDATA; input [3:0] S_AXI_GP0_ARCACHE; input [3:0] S_AXI_GP0_ARLEN; input [3:0] S_AXI_GP0_ARQOS; input [3:0] S_AXI_GP0_AWCACHE; input [3:0] S_AXI_GP0_AWLEN; input [3:0] S_AXI_GP0_AWQOS; input [3:0] S_AXI_GP0_WSTRB; input [5:0] S_AXI_GP0_ARID; input [5:0] S_AXI_GP0_AWID; input [5:0] S_AXI_GP0_WID; output S_AXI_GP1_ARREADY; output S_AXI_GP1_AWREADY; output S_AXI_GP1_BVALID; output S_AXI_GP1_RLAST; output S_AXI_GP1_RVALID; output S_AXI_GP1_WREADY; output [1:0] S_AXI_GP1_BRESP; output [1:0] S_AXI_GP1_RRESP; output [31:0] S_AXI_GP1_RDATA; output [5:0] S_AXI_GP1_BID; output [5:0] S_AXI_GP1_RID; input S_AXI_GP1_ACLK; input S_AXI_GP1_ARVALID; input S_AXI_GP1_AWVALID; input S_AXI_GP1_BREADY; input S_AXI_GP1_RREADY; input S_AXI_GP1_WLAST; input S_AXI_GP1_WVALID; input [1:0] S_AXI_GP1_ARBURST; input [1:0] S_AXI_GP1_ARLOCK; input [2:0] S_AXI_GP1_ARSIZE; input [1:0] S_AXI_GP1_AWBURST; input [1:0] S_AXI_GP1_AWLOCK; input [2:0] S_AXI_GP1_AWSIZE; input [2:0] S_AXI_GP1_ARPROT; input [2:0] S_AXI_GP1_AWPROT; input [31:0] S_AXI_GP1_ARADDR; input [31:0] S_AXI_GP1_AWADDR; input [31:0] S_AXI_GP1_WDATA; input [3:0] S_AXI_GP1_ARCACHE; input [3:0] S_AXI_GP1_ARLEN; input [3:0] S_AXI_GP1_ARQOS; input [3:0] S_AXI_GP1_AWCACHE; input [3:0] S_AXI_GP1_AWLEN; input [3:0] S_AXI_GP1_AWQOS; input [3:0] S_AXI_GP1_WSTRB; input [5:0] S_AXI_GP1_ARID; input [5:0] S_AXI_GP1_AWID; input [5:0] S_AXI_GP1_WID; output S_AXI_ACP_AWREADY; output S_AXI_ACP_ARREADY; output S_AXI_ACP_BVALID; output S_AXI_ACP_RLAST; output S_AXI_ACP_RVALID; output S_AXI_ACP_WREADY; output [1:0] S_AXI_ACP_BRESP; output [1:0] S_AXI_ACP_RRESP; output [2:0] S_AXI_ACP_BID; output [2:0] S_AXI_ACP_RID; output [63:0] S_AXI_ACP_RDATA; input S_AXI_ACP_ACLK; input S_AXI_ACP_ARVALID; input S_AXI_ACP_AWVALID; input S_AXI_ACP_BREADY; input S_AXI_ACP_RREADY; input S_AXI_ACP_WLAST; input S_AXI_ACP_WVALID; input [2:0] S_AXI_ACP_ARID; input [2:0] S_AXI_ACP_ARPROT; input [2:0] S_AXI_ACP_AWID; input [2:0] S_AXI_ACP_AWPROT; input [2:0] S_AXI_ACP_WID; input [31:0] S_AXI_ACP_ARADDR; input [31:0] S_AXI_ACP_AWADDR; input [3:0] S_AXI_ACP_ARCACHE; input [3:0] S_AXI_ACP_ARLEN; input [3:0] S_AXI_ACP_ARQOS; input [3:0] S_AXI_ACP_AWCACHE; input [3:0] S_AXI_ACP_AWLEN; input [3:0] S_AXI_ACP_AWQOS; input [1:0] S_AXI_ACP_ARBURST; input [1:0] S_AXI_ACP_ARLOCK; input [2:0] S_AXI_ACP_ARSIZE; input [1:0] S_AXI_ACP_AWBURST; input [1:0] S_AXI_ACP_AWLOCK; input [2:0] S_AXI_ACP_AWSIZE; input [4:0] S_AXI_ACP_ARUSER; input [4:0] S_AXI_ACP_AWUSER; input [63:0] S_AXI_ACP_WDATA; input [7:0] S_AXI_ACP_WSTRB; output S_AXI_HP0_ARREADY; output S_AXI_HP0_AWREADY; output S_AXI_HP0_BVALID; output S_AXI_HP0_RLAST; output S_AXI_HP0_RVALID; output S_AXI_HP0_WREADY; output [1:0] S_AXI_HP0_BRESP; output [1:0] S_AXI_HP0_RRESP; output [5:0] S_AXI_HP0_BID; output [5:0] S_AXI_HP0_RID; output [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_RDATA; output [7:0] S_AXI_HP0_RCOUNT; output [7:0] S_AXI_HP0_WCOUNT; output [2:0] S_AXI_HP0_RACOUNT; output [5:0] S_AXI_HP0_WACOUNT; input S_AXI_HP0_ACLK; input S_AXI_HP0_ARVALID; input S_AXI_HP0_AWVALID; input S_AXI_HP0_BREADY; input S_AXI_HP0_RDISSUECAP1_EN; input S_AXI_HP0_RREADY; input S_AXI_HP0_WLAST; input S_AXI_HP0_WRISSUECAP1_EN; input S_AXI_HP0_WVALID; input [1:0] S_AXI_HP0_ARBURST; input [1:0] S_AXI_HP0_ARLOCK; input [2:0] S_AXI_HP0_ARSIZE; input [1:0] S_AXI_HP0_AWBURST; input [1:0] S_AXI_HP0_AWLOCK; input [2:0] S_AXI_HP0_AWSIZE; input [2:0] S_AXI_HP0_ARPROT; input [2:0] S_AXI_HP0_AWPROT; input [31:0] S_AXI_HP0_ARADDR; input [31:0] S_AXI_HP0_AWADDR; input [3:0] S_AXI_HP0_ARCACHE; input [3:0] S_AXI_HP0_ARLEN; input [3:0] S_AXI_HP0_ARQOS; input [3:0] S_AXI_HP0_AWCACHE; input [3:0] S_AXI_HP0_AWLEN; input [3:0] S_AXI_HP0_AWQOS; input [5:0] S_AXI_HP0_ARID; input [5:0] S_AXI_HP0_AWID; input [5:0] S_AXI_HP0_WID; input [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_WDATA; input [C_S_AXI_HP0_DATA_WIDTH/8-1:0] S_AXI_HP0_WSTRB; output S_AXI_HP1_ARREADY; output S_AXI_HP1_AWREADY; output S_AXI_HP1_BVALID; output S_AXI_HP1_RLAST; output S_AXI_HP1_RVALID; output S_AXI_HP1_WREADY; output [1:0] S_AXI_HP1_BRESP; output [1:0] S_AXI_HP1_RRESP; output [5:0] S_AXI_HP1_BID; output [5:0] S_AXI_HP1_RID; output [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_RDATA; output [7:0] S_AXI_HP1_RCOUNT; output [7:0] S_AXI_HP1_WCOUNT; output [2:0] S_AXI_HP1_RACOUNT; output [5:0] S_AXI_HP1_WACOUNT; input S_AXI_HP1_ACLK; input S_AXI_HP1_ARVALID; input S_AXI_HP1_AWVALID; input S_AXI_HP1_BREADY; input S_AXI_HP1_RDISSUECAP1_EN; input S_AXI_HP1_RREADY; input S_AXI_HP1_WLAST; input S_AXI_HP1_WRISSUECAP1_EN; input S_AXI_HP1_WVALID; input [1:0] S_AXI_HP1_ARBURST; input [1:0] S_AXI_HP1_ARLOCK; input [2:0] S_AXI_HP1_ARSIZE; input [1:0] S_AXI_HP1_AWBURST; input [1:0] S_AXI_HP1_AWLOCK; input [2:0] S_AXI_HP1_AWSIZE; input [2:0] S_AXI_HP1_ARPROT; input [2:0] S_AXI_HP1_AWPROT; input [31:0] S_AXI_HP1_ARADDR; input [31:0] S_AXI_HP1_AWADDR; input [3:0] S_AXI_HP1_ARCACHE; input [3:0] S_AXI_HP1_ARLEN; input [3:0] S_AXI_HP1_ARQOS; input [3:0] S_AXI_HP1_AWCACHE; input [3:0] S_AXI_HP1_AWLEN; input [3:0] S_AXI_HP1_AWQOS; input [5:0] S_AXI_HP1_ARID; input [5:0] S_AXI_HP1_AWID; input [5:0] S_AXI_HP1_WID; input [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_WDATA; input [C_S_AXI_HP1_DATA_WIDTH/8-1:0] S_AXI_HP1_WSTRB; output S_AXI_HP2_ARREADY; output S_AXI_HP2_AWREADY; output S_AXI_HP2_BVALID; output S_AXI_HP2_RLAST; output S_AXI_HP2_RVALID; output S_AXI_HP2_WREADY; output [1:0] S_AXI_HP2_BRESP; output [1:0] S_AXI_HP2_RRESP; output [5:0] S_AXI_HP2_BID; output [5:0] S_AXI_HP2_RID; output [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_RDATA; output [7:0] S_AXI_HP2_RCOUNT; output [7:0] S_AXI_HP2_WCOUNT; output [2:0] S_AXI_HP2_RACOUNT; output [5:0] S_AXI_HP2_WACOUNT; input S_AXI_HP2_ACLK; input S_AXI_HP2_ARVALID; input S_AXI_HP2_AWVALID; input S_AXI_HP2_BREADY; input S_AXI_HP2_RDISSUECAP1_EN; input S_AXI_HP2_RREADY; input S_AXI_HP2_WLAST; input S_AXI_HP2_WRISSUECAP1_EN; input S_AXI_HP2_WVALID; input [1:0] S_AXI_HP2_ARBURST; input [1:0] S_AXI_HP2_ARLOCK; input [2:0] S_AXI_HP2_ARSIZE; input [1:0] S_AXI_HP2_AWBURST; input [1:0] S_AXI_HP2_AWLOCK; input [2:0] S_AXI_HP2_AWSIZE; input [2:0] S_AXI_HP2_ARPROT; input [2:0] S_AXI_HP2_AWPROT; input [31:0] S_AXI_HP2_ARADDR; input [31:0] S_AXI_HP2_AWADDR; input [3:0] S_AXI_HP2_ARCACHE; input [3:0] S_AXI_HP2_ARLEN; input [3:0] S_AXI_HP2_ARQOS; input [3:0] S_AXI_HP2_AWCACHE; input [3:0] S_AXI_HP2_AWLEN; input [3:0] S_AXI_HP2_AWQOS; input [5:0] S_AXI_HP2_ARID; input [5:0] S_AXI_HP2_AWID; input [5:0] S_AXI_HP2_WID; input [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_WDATA; input [C_S_AXI_HP2_DATA_WIDTH/8-1:0] S_AXI_HP2_WSTRB; output S_AXI_HP3_ARREADY; output S_AXI_HP3_AWREADY; output S_AXI_HP3_BVALID; output S_AXI_HP3_RLAST; output S_AXI_HP3_RVALID; output S_AXI_HP3_WREADY; output [1:0] S_AXI_HP3_BRESP; output [1:0] S_AXI_HP3_RRESP; output [5:0] S_AXI_HP3_BID; output [5:0] S_AXI_HP3_RID; output [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_RDATA; output [7:0] S_AXI_HP3_RCOUNT; output [7:0] S_AXI_HP3_WCOUNT; output [2:0] S_AXI_HP3_RACOUNT; output [5:0] S_AXI_HP3_WACOUNT; input S_AXI_HP3_ACLK; input S_AXI_HP3_ARVALID; input S_AXI_HP3_AWVALID; input S_AXI_HP3_BREADY; input S_AXI_HP3_RDISSUECAP1_EN; input S_AXI_HP3_RREADY; input S_AXI_HP3_WLAST; input S_AXI_HP3_WRISSUECAP1_EN; input S_AXI_HP3_WVALID; input [1:0] S_AXI_HP3_ARBURST; input [1:0] S_AXI_HP3_ARLOCK; input [2:0] S_AXI_HP3_ARSIZE; input [1:0] S_AXI_HP3_AWBURST; input [1:0] S_AXI_HP3_AWLOCK; input [2:0] S_AXI_HP3_AWSIZE; input [2:0] S_AXI_HP3_ARPROT; input [2:0] S_AXI_HP3_AWPROT; input [31:0] S_AXI_HP3_ARADDR; input [31:0] S_AXI_HP3_AWADDR; input [3:0] S_AXI_HP3_ARCACHE; input [3:0] S_AXI_HP3_ARLEN; input [3:0] S_AXI_HP3_ARQOS; input [3:0] S_AXI_HP3_AWCACHE; input [3:0] S_AXI_HP3_AWLEN; input [3:0] S_AXI_HP3_AWQOS; input [5:0] S_AXI_HP3_ARID; input [5:0] S_AXI_HP3_AWID; input [5:0] S_AXI_HP3_WID; input [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_WDATA; input [C_S_AXI_HP3_DATA_WIDTH/8-1:0] S_AXI_HP3_WSTRB; output [1:0] DMA0_DATYPE; output DMA0_DAVALID; output DMA0_DRREADY; input DMA0_ACLK; input DMA0_DAREADY; input DMA0_DRLAST; input DMA0_DRVALID; input [1:0] DMA0_DRTYPE; output [1:0] DMA1_DATYPE; output DMA1_DAVALID; output DMA1_DRREADY; input DMA1_ACLK; input DMA1_DAREADY; input DMA1_DRLAST; input DMA1_DRVALID; input [1:0] DMA1_DRTYPE; output [1:0] DMA2_DATYPE; output DMA2_DAVALID; output DMA2_DRREADY; input DMA2_ACLK; input DMA2_DAREADY; input DMA2_DRLAST; input DMA2_DRVALID; input DMA3_DRVALID; output [1:0] DMA3_DATYPE; output DMA3_DAVALID; output DMA3_DRREADY; input DMA3_ACLK; input DMA3_DAREADY; input DMA3_DRLAST; input [1:0] DMA2_DRTYPE; input [1:0] DMA3_DRTYPE; input [31:0] FTMD_TRACEIN_DATA; input FTMD_TRACEIN_VALID; input FTMD_TRACEIN_CLK; input [3:0] FTMD_TRACEIN_ATID; input [3:0] FTMT_F2P_TRIG; output [3:0] FTMT_F2P_TRIGACK; input [31:0] FTMT_F2P_DEBUG; input [3:0] FTMT_P2F_TRIGACK; output [3:0] FTMT_P2F_TRIG; output [31:0] FTMT_P2F_DEBUG; output FCLK_CLK3; output FCLK_CLK2; output FCLK_CLK1; output FCLK_CLK0; input FCLK_CLKTRIG3_N; input FCLK_CLKTRIG2_N; input FCLK_CLKTRIG1_N; input FCLK_CLKTRIG0_N; output FCLK_RESET3_N; output FCLK_RESET2_N; output FCLK_RESET1_N; output FCLK_RESET0_N; input FPGA_IDLE_N; input [3:0] DDR_ARB; input [irq_width-1:0] IRQ_F2P; input Core0_nFIQ; input Core0_nIRQ; input Core1_nFIQ; input Core1_nIRQ; output EVENT_EVENTO; output [1:0] EVENT_STANDBYWFE; output [1:0] EVENT_STANDBYWFI; input EVENT_EVENTI; inout [53:0] MIO; inout DDR_Clk; inout DDR_Clk_n; inout DDR_CKE; inout DDR_CS_n; inout DDR_RAS_n; inout DDR_CAS_n; output DDR_WEB; inout [2:0] DDR_BankAddr; inout [14:0] DDR_Addr; inout DDR_ODT; inout DDR_DRSTB; inout [31:0] DDR_DQ; inout [3:0] DDR_DM; inout [3:0] DDR_DQS; inout [3:0] DDR_DQS_n; inout DDR_VRN; inout DDR_VRP; / Reset Input & Clock Input / input PS_SRSTB; input PS_CLK; input PS_PORB; output IRQ_P2F_DMAC_ABORT; output IRQ_P2F_DMAC0; output IRQ_P2F_DMAC1; output IRQ_P2F_DMAC2; output IRQ_P2F_DMAC3; output IRQ_P2F_DMAC4; output IRQ_P2F_DMAC5; output IRQ_P2F_DMAC6; output IRQ_P2F_DMAC7; output IRQ_P2F_SMC; output IRQ_P2F_QSPI; output IRQ_P2F_CTI; output IRQ_P2F_GPIO; output IRQ_P2F_USB0; output IRQ_P2F_ENET0; output IRQ_P2F_ENET_WAKE0; output IRQ_P2F_SDIO0; output IRQ_P2F_I2C0; output IRQ_P2F_SPI0; output IRQ_P2F_UART0; output IRQ_P2F_CAN0; output IRQ_P2F_USB1; output IRQ_P2F_ENET1; output IRQ_P2F_ENET_WAKE1; output IRQ_P2F_SDIO1; output IRQ_P2F_I2C1; output IRQ_P2F_SPI1; output IRQ_P2F_UART1; output IRQ_P2F_CAN1; / Internal wires/nets used for connectivity / wire net_rstn; wire net_sw_clk; wire net_ocm_clk; wire net_arbiter_clk; wire net_axi_mgp0_rstn; wire net_axi_mgp1_rstn; wire net_axi_gp0_rstn; wire net_axi_gp1_rstn; wire net_axi_hp0_rstn; wire net_axi_hp1_rstn; wire net_axi_hp2_rstn; wire net_axi_hp3_rstn; wire net_axi_acp_rstn; wire [4:0] net_axi_acp_awuser; wire [4:0] net_axi_acp_aruser; / Dummy / assign net_axi_acp_awuser = S_AXI_ACP_AWUSER; assign net_axi_acp_aruser = S_AXI_ACP_ARUSER; / Global variables / reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1; / local variable acting as semaphore for wait_mem_update and wait_reg_update task / reg mem_update_key = 1; reg reg_update_key_0 = 1; reg reg_update_key_1 = 1; / assignments and semantic checks for unused ports / `include "processing_system7_bfm_v2_0_5_unused_ports.v" / include api definition / `include "processing_system7_bfm_v2_0_5_apis.v" / Reset Generator / processing_system7_bfm_v2_0_5_gen_reset gen_rst(.por_rst_n(PS_PORB), .sys_rst_n(PS_SRSTB), .rst_out_n(net_rstn), .m_axi_gp0_clk(M_AXI_GP0_ACLK), .m_axi_gp1_clk(M_AXI_GP1_ACLK), .s_axi_gp0_clk(S_AXI_GP0_ACLK), .s_axi_gp1_clk(S_AXI_GP1_ACLK), .s_axi_hp0_clk(S_AXI_HP0_ACLK), .s_axi_hp1_clk(S_AXI_HP1_ACLK), .s_axi_hp2_clk(S_AXI_HP2_ACLK), .s_axi_hp3_clk(S_AXI_HP3_ACLK), .s_axi_acp_clk(S_AXI_ACP_ACLK), .m_axi_gp0_rstn(net_axi_mgp0_rstn), .m_axi_gp1_rstn(net_axi_mgp1_rstn), .s_axi_gp0_rstn(net_axi_gp0_rstn), .s_axi_gp1_rstn(net_axi_gp1_rstn), .s_axi_hp0_rstn(net_axi_hp0_rstn), .s_axi_hp1_rstn(net_axi_hp1_rstn), .s_axi_hp2_rstn(net_axi_hp2_rstn), .s_axi_hp3_rstn(net_axi_hp3_rstn), .s_axi_acp_rstn(net_axi_acp_rstn), .fclk_reset3_n(FCLK_RESET3_N), .fclk_reset2_n(FCLK_RESET2_N), .fclk_reset1_n(FCLK_RESET1_N), .fclk_reset0_n(FCLK_RESET0_N), .fpga_acp_reset_n(), ////S_AXI_ACP_ARESETN), (These are removed from Zynq IP) .fpga_gp_m0_reset_n(), ////M_AXI_GP0_ARESETN), .fpga_gp_m1_reset_n(), ////M_AXI_GP1_ARESETN), .fpga_gp_s0_reset_n(), ////S_AXI_GP0_ARESETN), .fpga_gp_s1_reset_n(), ////S_AXI_GP1_ARESETN), .fpga_hp_s0_reset_n(), ////S_AXI_HP0_ARESETN), .fpga_hp_s1_reset_n(), ////S_AXI_HP1_ARESETN), .fpga_hp_s2_reset_n(), ////S_AXI_HP2_ARESETN), .fpga_hp_s3_reset_n() ////S_AXI_HP3_ARESETN) ); / Clock Generator / processing_system7_bfm_v2_0_5_gen_clock #(C_FCLK_CLK3_FREQ, C_FCLK_CLK2_FREQ, C_FCLK_CLK1_FREQ, C_FCLK_CLK0_FREQ) gen_clk(.ps_clk(PS_CLK), .sw_clk(net_sw_clk), .fclk_clk3(FCLK_CLK3), .fclk_clk2(FCLK_CLK2), .fclk_clk1(FCLK_CLK1), .fclk_clk0(FCLK_CLK0) ); wire net_wr_ack_ocm_gp0, net_wr_ack_ddr_gp0, net_wr_ack_ocm_gp1, net_wr_ack_ddr_gp1; wire net_wr_dv_ocm_gp0, net_wr_dv_ddr_gp0, net_wr_dv_ocm_gp1, net_wr_dv_ddr_gp1; wire [max_burst_bits-1:0] net_wr_data_gp0, net_wr_data_gp1; wire [addr_width-1:0] net_wr_addr_gp0, net_wr_addr_gp1; wire [max_burst_bytes_width:0] net_wr_bytes_gp0, net_wr_bytes_gp1; wire [axi_qos_width-1:0] net_wr_qos_gp0, net_wr_qos_gp1; wire net_rd_req_ddr_gp0, net_rd_req_ddr_gp1; wire net_rd_req_ocm_gp0, net_rd_req_ocm_gp1; wire net_rd_req_reg_gp0, net_rd_req_reg_gp1; wire [addr_width-1:0] net_rd_addr_gp0, net_rd_addr_gp1; wire [max_burst_bytes_width:0] net_rd_bytes_gp0, net_rd_bytes_gp1; wire [max_burst_bits-1:0] net_rd_data_ddr_gp0, net_rd_data_ddr_gp1; wire [max_burst_bits-1:0] net_rd_data_ocm_gp0, net_rd_data_ocm_gp1; wire [max_burst_bits-1:0] net_rd_data_reg_gp0, net_rd_data_reg_gp1; wire net_rd_dv_ddr_gp0, net_rd_dv_ddr_gp1; wire net_rd_dv_ocm_gp0, net_rd_dv_ocm_gp1; wire net_rd_dv_reg_gp0, net_rd_dv_reg_gp1; wire [axi_qos_width-1:0] net_rd_qos_gp0, net_rd_qos_gp1; wire net_wr_ack_ddr_hp0, net_wr_ack_ddr_hp1, net_wr_ack_ddr_hp2, net_wr_ack_ddr_hp3; wire net_wr_ack_ocm_hp0, net_wr_ack_ocm_hp1, net_wr_ack_ocm_hp2, net_wr_ack_ocm_hp3; wire net_wr_dv_ddr_hp0, net_wr_dv_ddr_hp1, net_wr_dv_ddr_hp2, net_wr_dv_ddr_hp3; wire net_wr_dv_ocm_hp0, net_wr_dv_ocm_hp1, net_wr_dv_ocm_hp2, net_wr_dv_ocm_hp3; wire [max_burst_bits-1:0] net_wr_data_hp0, net_wr_data_hp1, net_wr_data_hp2, net_wr_data_hp3; wire [addr_width-1:0] net_wr_addr_hp0, net_wr_addr_hp1, net_wr_addr_hp2, net_wr_addr_hp3; wire [max_burst_bytes_width:0] net_wr_bytes_hp0, net_wr_bytes_hp1, net_wr_bytes_hp2, net_wr_bytes_hp3; wire [axi_qos_width-1:0] net_wr_qos_hp0, net_wr_qos_hp1, net_wr_qos_hp2, net_wr_qos_hp3; wire net_rd_req_ddr_hp0, net_rd_req_ddr_hp1, net_rd_req_ddr_hp2, net_rd_req_ddr_hp3; wire net_rd_req_ocm_hp0, net_rd_req_ocm_hp1, net_rd_req_ocm_hp2, net_rd_req_ocm_hp3; wire [addr_width-1:0] net_rd_addr_hp0, net_rd_addr_hp1, net_rd_addr_hp2, net_rd_addr_hp3; wire [max_burst_bytes_width:0] net_rd_bytes_hp0, net_rd_bytes_hp1, net_rd_bytes_hp2, net_rd_bytes_hp3; wire [max_burst_bits-1:0] net_rd_data_ddr_hp0, net_rd_data_ddr_hp1, net_rd_data_ddr_hp2, net_rd_data_ddr_hp3; wire [max_burst_bits-1:0] net_rd_data_ocm_hp0, net_rd_data_ocm_hp1, net_rd_data_ocm_hp2, net_rd_data_ocm_hp3; wire net_rd_dv_ddr_hp0, net_rd_dv_ddr_hp1, net_rd_dv_ddr_hp2, net_rd_dv_ddr_hp3; wire net_rd_dv_ocm_hp0, net_rd_dv_ocm_hp1, net_rd_dv_ocm_hp2, net_rd_dv_ocm_hp3; wire [axi_qos_width-1:0] net_rd_qos_hp0, net_rd_qos_hp1, net_rd_qos_hp2, net_rd_qos_hp3; wire net_wr_ack_ddr_acp,net_wr_ack_ocm_acp; wire net_wr_dv_ddr_acp,net_wr_dv_ocm_acp; wire [max_burst_bits-1:0] net_wr_data_acp; wire [addr_width-1:0] net_wr_addr_acp; wire [max_burst_bytes_width:0] net_wr_bytes_acp; wire [axi_qos_width-1:0] net_wr_qos_acp; wire net_rd_req_ddr_acp, net_rd_req_ocm_acp; wire [addr_width-1:0] net_rd_addr_acp; wire [max_burst_bytes_width:0] net_rd_bytes_acp; wire [max_burst_bits-1:0] net_rd_data_ddr_acp; wire [max_burst_bits-1:0] net_rd_data_ocm_acp; wire net_rd_dv_ddr_acp,net_rd_dv_ocm_acp; wire [axi_qos_width-1:0] net_rd_qos_acp; wire ocm_wr_ack_port0; wire ocm_wr_dv_port0; wire ocm_rd_req_port0; wire ocm_rd_dv_port0; wire [addr_width-1:0] ocm_wr_addr_port0; wire [max_burst_bits-1:0] ocm_wr_data_port0; wire [max_burst_bytes_width:0] ocm_wr_bytes_port0; wire [addr_width-1:0] ocm_rd_addr_port0; wire [max_burst_bits-1:0] ocm_rd_data_port0; wire [max_burst_bytes_width:0] ocm_rd_bytes_port0; wire [axi_qos_width-1:0] ocm_wr_qos_port0; wire [axi_qos_width-1:0] ocm_rd_qos_port0; wire ocm_wr_ack_port1; wire ocm_wr_dv_port1; wire ocm_rd_req_port1; wire ocm_rd_dv_port1; wire [addr_width-1:0] ocm_wr_addr_port1; wire [max_burst_bits-1:0] ocm_wr_data_port1; wire [max_burst_bytes_width:0] ocm_wr_bytes_port1; wire [addr_width-1:0] ocm_rd_addr_port1; wire [max_burst_bits-1:0] ocm_rd_data_port1; wire [max_burst_bytes_width:0] ocm_rd_bytes_port1; wire [axi_qos_width-1:0] ocm_wr_qos_port1; wire [axi_qos_width-1:0] ocm_rd_qos_port1; wire ddr_wr_ack_port0; wire ddr_wr_dv_port0; wire ddr_rd_req_port0; wire ddr_rd_dv_port0; wire[addr_width-1:0] ddr_wr_addr_port0; wire[max_burst_bits-1:0] ddr_wr_data_port0; wire[max_burst_bytes_width:0] ddr_wr_bytes_port0; wire[addr_width-1:0] ddr_rd_addr_port0; wire[max_burst_bits-1:0] ddr_rd_data_port0; wire[max_burst_bytes_width:0] ddr_rd_bytes_port0; wire [axi_qos_width-1:0] ddr_wr_qos_port0; wire [axi_qos_width-1:0] ddr_rd_qos_port0; wire ddr_wr_ack_port1; wire ddr_wr_dv_port1; wire ddr_rd_req_port1; wire ddr_rd_dv_port1; wire[addr_width-1:0] ddr_wr_addr_port1; wire[max_burst_bits-1:0] ddr_wr_data_port1; wire[max_burst_bytes_width:0] ddr_wr_bytes_port1; wire[addr_width-1:0] ddr_rd_addr_port1; wire[max_burst_bits-1:0] ddr_rd_data_port1; wire[max_burst_bytes_width:0] ddr_rd_bytes_port1; wire[axi_qos_width-1:0] ddr_wr_qos_port1; wire[axi_qos_width-1:0] ddr_rd_qos_port1; wire ddr_wr_ack_port2; wire ddr_wr_dv_port2; wire ddr_rd_req_port2; wire ddr_rd_dv_port2; wire[addr_width-1:0] ddr_wr_addr_port2; wire[max_burst_bits-1:0] ddr_wr_data_port2; wire[max_burst_bytes_width:0] ddr_wr_bytes_port2; wire[addr_width-1:0] ddr_rd_addr_port2; wire[max_burst_bits-1:0] ddr_rd_data_port2; wire[max_burst_bytes_width:0] ddr_rd_bytes_port2; wire[axi_qos_width-1:0] ddr_wr_qos_port2; wire[axi_qos_width-1:0] ddr_rd_qos_port2; wire ddr_wr_ack_port3; wire ddr_wr_dv_port3; wire ddr_rd_req_port3; wire ddr_rd_dv_port3; wire[addr_width-1:0] ddr_wr_addr_port3; wire[max_burst_bits-1:0] ddr_wr_data_port3; wire[max_burst_bytes_width:0] ddr_wr_bytes_port3; wire[addr_width-1:0] ddr_rd_addr_port3; wire[max_burst_bits-1:0] ddr_rd_data_port3; wire[max_burst_bytes_width:0] ddr_rd_bytes_port3; wire[axi_qos_width-1:0] ddr_wr_qos_port3; wire[axi_qos_width-1:0] ddr_rd_qos_port3; wire reg_rd_req_port0; wire reg_rd_dv_port0; wire[addr_width-1:0] reg_rd_addr_port0; wire[max_burst_bits-1:0] reg_rd_data_port0; wire[max_burst_bytes_width:0] reg_rd_bytes_port0; wire [axi_qos_width-1:0] reg_rd_qos_port0; wire reg_rd_req_port1; wire reg_rd_dv_port1; wire[addr_width-1:0] reg_rd_addr_port1; wire[max_burst_bits-1:0] reg_rd_data_port1; wire[max_burst_bytes_width:0] reg_rd_bytes_port1; wire [axi_qos_width-1:0] reg_rd_qos_port1; wire [11:0] M_AXI_GP0_AWID_FULL; wire [11:0] M_AXI_GP0_WID_FULL; wire [11:0] M_AXI_GP0_ARID_FULL; wire [11:0] M_AXI_GP0_BID_FULL; wire [11:0] M_AXI_GP0_RID_FULL; wire [11:0] M_AXI_GP1_AWID_FULL; wire [11:0] M_AXI_GP1_WID_FULL; wire [11:0] M_AXI_GP1_ARID_FULL; wire [11:0] M_AXI_GP1_BID_FULL; wire [11:0] M_AXI_GP1_RID_FULL; function [5:0] compress_id; input [11:0] id; begin compress_id = id[5:0]; end endfunction function [11:0] uncompress_id; input [5:0] id; begin uncompress_id = {6'b110000, id[5:0]}; end endfunction assign M_AXI_GP0_AWID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_AWID_FULL) : M_AXI_GP0_AWID_FULL; assign M_AXI_GP0_WID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_WID_FULL) : M_AXI_GP0_WID_FULL; assign M_AXI_GP0_ARID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_ARID_FULL) : M_AXI_GP0_ARID_FULL; assign M_AXI_GP0_BID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_BID) : M_AXI_GP0_BID; assign M_AXI_GP0_RID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_RID) : M_AXI_GP0_RID; assign M_AXI_GP1_AWID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_AWID_FULL) : M_AXI_GP1_AWID_FULL; assign M_AXI_GP1_WID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_WID_FULL) : M_AXI_GP1_WID_FULL; assign M_AXI_GP1_ARID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_ARID_FULL) : M_AXI_GP1_ARID_FULL; assign M_AXI_GP1_BID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_BID) : M_AXI_GP1_BID; assign M_AXI_GP1_RID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_RID) : M_AXI_GP1_RID; processing_system7_bfm_v2_0_5_interconnect_model icm ( .rstn(net_rstn), .sw_clk(net_sw_clk), .w_qos_gp0(net_wr_qos_gp0), .w_qos_gp1(net_wr_qos_gp1), .w_qos_hp0(net_wr_qos_hp0), .w_qos_hp1(net_wr_qos_hp1), .w_qos_hp2(net_wr_qos_hp2), .w_qos_hp3(net_wr_qos_hp3), .r_qos_gp0(net_rd_qos_gp0), .r_qos_gp1(net_rd_qos_gp1), .r_qos_hp0(net_rd_qos_hp0), .r_qos_hp1(net_rd_qos_hp1), .r_qos_hp2(net_rd_qos_hp2), .r_qos_hp3(net_rd_qos_hp3), / GP Slave ports access / .wr_ack_ddr_gp0(net_wr_ack_ddr_gp0), .wr_ack_ocm_gp0(net_wr_ack_ocm_gp0), .wr_data_gp0(net_wr_data_gp0), .wr_addr_gp0(net_wr_addr_gp0), .wr_bytes_gp0(net_wr_bytes_gp0), .wr_dv_ddr_gp0(net_wr_dv_ddr_gp0), .wr_dv_ocm_gp0(net_wr_dv_ocm_gp0), .rd_req_ddr_gp0(net_rd_req_ddr_gp0), .rd_req_ocm_gp0(net_rd_req_ocm_gp0), .rd_req_reg_gp0(net_rd_req_reg_gp0), .rd_addr_gp0(net_rd_addr_gp0), .rd_bytes_gp0(net_rd_bytes_gp0), .rd_data_ddr_gp0(net_rd_data_ddr_gp0), .rd_data_ocm_gp0(net_rd_data_ocm_gp0), .rd_data_reg_gp0(net_rd_data_reg_gp0), .rd_dv_ddr_gp0(net_rd_dv_ddr_gp0), .rd_dv_ocm_gp0(net_rd_dv_ocm_gp0), .rd_dv_reg_gp0(net_rd_dv_reg_gp0), .wr_ack_ddr_gp1(net_wr_ack_ddr_gp1), .wr_ack_ocm_gp1(net_wr_ack_ocm_gp1), .wr_data_gp1(net_wr_data_gp1), .wr_addr_gp1(net_wr_addr_gp1), .wr_bytes_gp1(net_wr_bytes_gp1), .wr_dv_ddr_gp1(net_wr_dv_ddr_gp1), .wr_dv_ocm_gp1(net_wr_dv_ocm_gp1), .rd_req_ddr_gp1(net_rd_req_ddr_gp1), .rd_req_ocm_gp1(net_rd_req_ocm_gp1), .rd_req_reg_gp1(net_rd_req_reg_gp1), .rd_addr_gp1(net_rd_addr_gp1), .rd_bytes_gp1(net_rd_bytes_gp1), .rd_data_ddr_gp1(net_rd_data_ddr_gp1), .rd_data_ocm_gp1(net_rd_data_ocm_gp1), .rd_data_reg_gp1(net_rd_data_reg_gp1), .rd_dv_ddr_gp1(net_rd_dv_ddr_gp1), .rd_dv_ocm_gp1(net_rd_dv_ocm_gp1), .rd_dv_reg_gp1(net_rd_dv_reg_gp1), / HP Slave ports access / .wr_ack_ddr_hp0(net_wr_ack_ddr_hp0), .wr_ack_ocm_hp0(net_wr_ack_ocm_hp0), .wr_data_hp0(net_wr_data_hp0), .wr_addr_hp0(net_wr_addr_hp0), .wr_bytes_hp0(net_wr_bytes_hp0), .wr_dv_ddr_hp0(net_wr_dv_ddr_hp0), .wr_dv_ocm_hp0(net_wr_dv_ocm_hp0), .rd_req_ddr_hp0(net_rd_req_ddr_hp0), .rd_req_ocm_hp0(net_rd_req_ocm_hp0), .rd_addr_hp0(net_rd_addr_hp0), .rd_bytes_hp0(net_rd_bytes_hp0), .rd_data_ddr_hp0(net_rd_data_ddr_hp0), .rd_data_ocm_hp0(net_rd_data_ocm_hp0), .rd_dv_ddr_hp0(net_rd_dv_ddr_hp0), .rd_dv_ocm_hp0(net_rd_dv_ocm_hp0), .wr_ack_ddr_hp1(net_wr_ack_ddr_hp1), .wr_ack_ocm_hp1(net_wr_ack_ocm_hp1), .wr_data_hp1(net_wr_data_hp1), .wr_addr_hp1(net_wr_addr_hp1), .wr_bytes_hp1(net_wr_bytes_hp1), .wr_dv_ddr_hp1(net_wr_dv_ddr_hp1), .wr_dv_ocm_hp1(net_wr_dv_ocm_hp1), .rd_req_ddr_hp1(net_rd_req_ddr_hp1), .rd_req_ocm_hp1(net_rd_req_ocm_hp1), .rd_addr_hp1(net_rd_addr_hp1), .rd_bytes_hp1(net_rd_bytes_hp1), .rd_data_ddr_hp1(net_rd_data_ddr_hp1), .rd_data_ocm_hp1(net_rd_data_ocm_hp1), .rd_dv_ocm_hp1(net_rd_dv_ocm_hp1), .rd_dv_ddr_hp1(net_rd_dv_ddr_hp1), .wr_ack_ddr_hp2(net_wr_ack_ddr_hp2), .wr_ack_ocm_hp2(net_wr_ack_ocm_hp2), .wr_data_hp2(net_wr_data_hp2), .wr_addr_hp2(net_wr_addr_hp2), .wr_bytes_hp2(net_wr_bytes_hp2), .wr_dv_ocm_hp2(net_wr_dv_ocm_hp2), .wr_dv_ddr_hp2(net_wr_dv_ddr_hp2), .rd_req_ddr_hp2(net_rd_req_ddr_hp2), .rd_req_ocm_hp2(net_rd_req_ocm_hp2), .rd_addr_hp2(net_rd_addr_hp2), .rd_bytes_hp2(net_rd_bytes_hp2), .rd_data_ddr_hp2(net_rd_data_ddr_hp2), .rd_data_ocm_hp2(net_rd_data_ocm_hp2), .rd_dv_ddr_hp2(net_rd_dv_ddr_hp2), .rd_dv_ocm_hp2(net_rd_dv_ocm_hp2), .wr_ack_ocm_hp3(net_wr_ack_ocm_hp3), .wr_ack_ddr_hp3(net_wr_ack_ddr_hp3), .wr_data_hp3(net_wr_data_hp3), .wr_addr_hp3(net_wr_addr_hp3), .wr_bytes_hp3(net_wr_bytes_hp3), .wr_dv_ddr_hp3(net_wr_dv_ddr_hp3), .wr_dv_ocm_hp3(net_wr_dv_ocm_hp3), .rd_req_ddr_hp3(net_rd_req_ddr_hp3), .rd_req_ocm_hp3(net_rd_req_ocm_hp3), .rd_addr_hp3(net_rd_addr_hp3), .rd_bytes_hp3(net_rd_bytes_hp3), .rd_data_ddr_hp3(net_rd_data_ddr_hp3), .rd_data_ocm_hp3(net_rd_data_ocm_hp3), .rd_dv_ddr_hp3(net_rd_dv_ddr_hp3), .rd_dv_ocm_hp3(net_rd_dv_ocm_hp3), / Goes to port 1 of DDR / .ddr_wr_ack_port1(ddr_wr_ack_port1), .ddr_wr_dv_port1(ddr_wr_dv_port1), .ddr_rd_req_port1(ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1(ddr_wr_qos_port1), .ddr_rd_qos_port1(ddr_rd_qos_port1), / Goes to port2 of DDR / .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), / Goes to port3 of DDR / .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3), / Goes to port 0 of OCM / .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1), / Goes to port 0 of REG / .reg_rd_qos_port1 (reg_rd_qos_port1) , .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1) ); processing_system7_bfm_v2_0_5_ddrc ddrc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of DDR / .ddr_wr_ack_port0 (ddr_wr_ack_port0), .ddr_wr_dv_port0 (ddr_wr_dv_port0), .ddr_rd_req_port0 (ddr_rd_req_port0), .ddr_rd_dv_port0 (ddr_rd_dv_port0), .ddr_wr_addr_port0(net_wr_addr_acp), .ddr_wr_data_port0(net_wr_data_acp), .ddr_wr_bytes_port0(net_wr_bytes_acp), .ddr_rd_addr_port0(net_rd_addr_acp), .ddr_rd_bytes_port0(net_rd_bytes_acp), .ddr_rd_data_port0(ddr_rd_data_port0), .ddr_wr_qos_port0 (net_wr_qos_acp), .ddr_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of DDR / .ddr_wr_ack_port1 (ddr_wr_ack_port1), .ddr_wr_dv_port1 (ddr_wr_dv_port1), .ddr_rd_req_port1 (ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1 (ddr_wr_qos_port1), .ddr_rd_qos_port1 (ddr_rd_qos_port1), / Goes to port2 of DDR / .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), / Goes to port3 of DDR / .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3) ); processing_system7_bfm_v2_0_5_ocmc ocmc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of OCM / .ocm_wr_ack_port0 (ocm_wr_ack_port0), .ocm_wr_dv_port0 (ocm_wr_dv_port0), .ocm_rd_req_port0 (ocm_rd_req_port0), .ocm_rd_dv_port0 (ocm_rd_dv_port0), .ocm_wr_addr_port0(net_wr_addr_acp), .ocm_wr_data_port0(net_wr_data_acp), .ocm_wr_bytes_port0(net_wr_bytes_acp), .ocm_rd_addr_port0(net_rd_addr_acp), .ocm_rd_bytes_port0(net_rd_bytes_acp), .ocm_rd_data_port0(ocm_rd_data_port0), .ocm_wr_qos_port0 (net_wr_qos_acp), .ocm_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of OCM / .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1) ); processing_system7_bfm_v2_0_5_regc regc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of REG / .reg_rd_req_port0 (reg_rd_req_port0), .reg_rd_dv_port0 (reg_rd_dv_port0), .reg_rd_addr_port0(net_rd_addr_acp), .reg_rd_bytes_port0(net_rd_bytes_acp), .reg_rd_data_port0(reg_rd_data_port0), .reg_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of REG / .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1), .reg_rd_qos_port1(reg_rd_qos_port1) ); / include axi_gp port instantiations / `include "processing_system7_bfm_v2_0_5_axi_gp.v" / include axi_hp port instantiations / `include "processing_system7_bfm_v2_0_5_axi_hp.v" / include axi_acp port instantiations */ `include "processing_system7_bfm_v2_0_5_axi_acp.v" endmodule
module processing_system7_bfm_v2_0_5_processing_system7_bfm ( CAN0_PHY_TX, CAN0_PHY_RX, CAN1_PHY_TX, CAN1_PHY_RX, ENET0_GMII_TX_EN, ENET0_GMII_TX_ER, ENET0_MDIO_MDC, ENET0_MDIO_O, ENET0_MDIO_T, ENET0_PTP_DELAY_REQ_RX, ENET0_PTP_DELAY_REQ_TX, ENET0_PTP_PDELAY_REQ_RX, ENET0_PTP_PDELAY_REQ_TX, ENET0_PTP_PDELAY_RESP_RX, ENET0_PTP_PDELAY_RESP_TX, ENET0_PTP_SYNC_FRAME_RX, ENET0_PTP_SYNC_FRAME_TX, ENET0_SOF_RX, ENET0_SOF_TX, ENET0_GMII_TXD, ENET0_GMII_COL, ENET0_GMII_CRS, ENET0_EXT_INTIN, ENET0_GMII_RX_CLK, ENET0_GMII_RX_DV, ENET0_GMII_RX_ER, ENET0_GMII_TX_CLK, ENET0_MDIO_I, ENET0_GMII_RXD, ENET1_GMII_TX_EN, ENET1_GMII_TX_ER, ENET1_MDIO_MDC, ENET1_MDIO_O, ENET1_MDIO_T, ENET1_PTP_DELAY_REQ_RX, ENET1_PTP_DELAY_REQ_TX, ENET1_PTP_PDELAY_REQ_RX, ENET1_PTP_PDELAY_REQ_TX, ENET1_PTP_PDELAY_RESP_RX, ENET1_PTP_PDELAY_RESP_TX, ENET1_PTP_SYNC_FRAME_RX, ENET1_PTP_SYNC_FRAME_TX, ENET1_SOF_RX, ENET1_SOF_TX, ENET1_GMII_TXD, ENET1_GMII_COL, ENET1_GMII_CRS, ENET1_EXT_INTIN, ENET1_GMII_RX_CLK, ENET1_GMII_RX_DV, ENET1_GMII_RX_ER, ENET1_GMII_TX_CLK, ENET1_MDIO_I, ENET1_GMII_RXD, GPIO_I, GPIO_O, GPIO_T, I2C0_SDA_I, I2C0_SDA_O, I2C0_SDA_T, I2C0_SCL_I, I2C0_SCL_O, I2C0_SCL_T, I2C1_SDA_I, I2C1_SDA_O, I2C1_SDA_T, I2C1_SCL_I, I2C1_SCL_O, I2C1_SCL_T, PJTAG_TCK, PJTAG_TMS, PJTAG_TD_I, PJTAG_TD_T, PJTAG_TD_O, SDIO0_CLK, SDIO0_CLK_FB, SDIO0_CMD_O, SDIO0_CMD_I, SDIO0_CMD_T, SDIO0_DATA_I, SDIO0_DATA_O, SDIO0_DATA_T, SDIO0_LED, SDIO0_CDN, SDIO0_WP, SDIO0_BUSPOW, SDIO0_BUSVOLT, SDIO1_CLK, SDIO1_CLK_FB, SDIO1_CMD_O, SDIO1_CMD_I, SDIO1_CMD_T, SDIO1_DATA_I, SDIO1_DATA_O, SDIO1_DATA_T, SDIO1_LED, SDIO1_CDN, SDIO1_WP, SDIO1_BUSPOW, SDIO1_BUSVOLT, SPI0_SCLK_I, SPI0_SCLK_O, SPI0_SCLK_T, SPI0_MOSI_I, SPI0_MOSI_O, SPI0_MOSI_T, SPI0_MISO_I, SPI0_MISO_O, SPI0_MISO_T, SPI0_SS_I, SPI0_SS_O, SPI0_SS1_O, SPI0_SS2_O, SPI0_SS_T, SPI1_SCLK_I, SPI1_SCLK_O, SPI1_SCLK_T, SPI1_MOSI_I, SPI1_MOSI_O, SPI1_MOSI_T, SPI1_MISO_I, SPI1_MISO_O, SPI1_MISO_T, SPI1_SS_I, SPI1_SS_O, SPI1_SS1_O, SPI1_SS2_O, SPI1_SS_T, UART0_DTRN, UART0_RTSN, UART0_TX, UART0_CTSN, UART0_DCDN, UART0_DSRN, UART0_RIN, UART0_RX, UART1_DTRN, UART1_RTSN, UART1_TX, UART1_CTSN, UART1_DCDN, UART1_DSRN, UART1_RIN, UART1_RX, TTC0_WAVE0_OUT, TTC0_WAVE1_OUT, TTC0_WAVE2_OUT, TTC0_CLK0_IN, TTC0_CLK1_IN, TTC0_CLK2_IN, TTC1_WAVE0_OUT, TTC1_WAVE1_OUT, TTC1_WAVE2_OUT, TTC1_CLK0_IN, TTC1_CLK1_IN, TTC1_CLK2_IN, WDT_CLK_IN, WDT_RST_OUT, TRACE_CLK, TRACE_CTL, TRACE_DATA, USB0_PORT_INDCTL, USB1_PORT_INDCTL, USB0_VBUS_PWRSELECT, USB1_VBUS_PWRSELECT, USB0_VBUS_PWRFAULT, USB1_VBUS_PWRFAULT, SRAM_INTIN, M_AXI_GP0_ARVALID, M_AXI_GP0_AWVALID, M_AXI_GP0_BREADY, M_AXI_GP0_RREADY, M_AXI_GP0_WLAST, M_AXI_GP0_WVALID, M_AXI_GP0_ARID, M_AXI_GP0_AWID, M_AXI_GP0_WID, M_AXI_GP0_ARBURST, M_AXI_GP0_ARLOCK, M_AXI_GP0_ARSIZE, M_AXI_GP0_AWBURST, M_AXI_GP0_AWLOCK, M_AXI_GP0_AWSIZE, M_AXI_GP0_ARPROT, M_AXI_GP0_AWPROT, M_AXI_GP0_ARADDR, M_AXI_GP0_AWADDR, M_AXI_GP0_WDATA, M_AXI_GP0_ARCACHE, M_AXI_GP0_ARLEN, M_AXI_GP0_ARQOS, M_AXI_GP0_AWCACHE, M_AXI_GP0_AWLEN, M_AXI_GP0_AWQOS, M_AXI_GP0_WSTRB, M_AXI_GP0_ACLK, M_AXI_GP0_ARREADY, M_AXI_GP0_AWREADY, M_AXI_GP0_BVALID, M_AXI_GP0_RLAST, M_AXI_GP0_RVALID, M_AXI_GP0_WREADY, M_AXI_GP0_BID, M_AXI_GP0_RID, M_AXI_GP0_BRESP, M_AXI_GP0_RRESP, M_AXI_GP0_RDATA, M_AXI_GP1_ARVALID, M_AXI_GP1_AWVALID, M_AXI_GP1_BREADY, M_AXI_GP1_RREADY, M_AXI_GP1_WLAST, M_AXI_GP1_WVALID, M_AXI_GP1_ARID, M_AXI_GP1_AWID, M_AXI_GP1_WID, M_AXI_GP1_ARBURST, M_AXI_GP1_ARLOCK, M_AXI_GP1_ARSIZE, M_AXI_GP1_AWBURST, M_AXI_GP1_AWLOCK, M_AXI_GP1_AWSIZE, M_AXI_GP1_ARPROT, M_AXI_GP1_AWPROT, M_AXI_GP1_ARADDR, M_AXI_GP1_AWADDR, M_AXI_GP1_WDATA, M_AXI_GP1_ARCACHE, M_AXI_GP1_ARLEN, M_AXI_GP1_ARQOS, M_AXI_GP1_AWCACHE, M_AXI_GP1_AWLEN, M_AXI_GP1_AWQOS, M_AXI_GP1_WSTRB, M_AXI_GP1_ACLK, M_AXI_GP1_ARREADY, M_AXI_GP1_AWREADY, M_AXI_GP1_BVALID, M_AXI_GP1_RLAST, M_AXI_GP1_RVALID, M_AXI_GP1_WREADY, M_AXI_GP1_BID, M_AXI_GP1_RID, M_AXI_GP1_BRESP, M_AXI_GP1_RRESP, M_AXI_GP1_RDATA, S_AXI_GP0_ARREADY, S_AXI_GP0_AWREADY, S_AXI_GP0_BVALID, S_AXI_GP0_RLAST, S_AXI_GP0_RVALID, S_AXI_GP0_WREADY, S_AXI_GP0_BRESP, S_AXI_GP0_RRESP, S_AXI_GP0_RDATA, S_AXI_GP0_BID, S_AXI_GP0_RID, S_AXI_GP0_ACLK, S_AXI_GP0_ARVALID, S_AXI_GP0_AWVALID, S_AXI_GP0_BREADY, S_AXI_GP0_RREADY, S_AXI_GP0_WLAST, S_AXI_GP0_WVALID, S_AXI_GP0_ARBURST, S_AXI_GP0_ARLOCK, S_AXI_GP0_ARSIZE, S_AXI_GP0_AWBURST, S_AXI_GP0_AWLOCK, S_AXI_GP0_AWSIZE, S_AXI_GP0_ARPROT, S_AXI_GP0_AWPROT, S_AXI_GP0_ARADDR, S_AXI_GP0_AWADDR, S_AXI_GP0_WDATA, S_AXI_GP0_ARCACHE, S_AXI_GP0_ARLEN, S_AXI_GP0_ARQOS, S_AXI_GP0_AWCACHE, S_AXI_GP0_AWLEN, S_AXI_GP0_AWQOS, S_AXI_GP0_WSTRB, S_AXI_GP0_ARID, S_AXI_GP0_AWID, S_AXI_GP0_WID, S_AXI_GP1_ARREADY, S_AXI_GP1_AWREADY, S_AXI_GP1_BVALID, S_AXI_GP1_RLAST, S_AXI_GP1_RVALID, S_AXI_GP1_WREADY, S_AXI_GP1_BRESP, S_AXI_GP1_RRESP, S_AXI_GP1_RDATA, S_AXI_GP1_BID, S_AXI_GP1_RID, S_AXI_GP1_ACLK, S_AXI_GP1_ARVALID, S_AXI_GP1_AWVALID, S_AXI_GP1_BREADY, S_AXI_GP1_RREADY, S_AXI_GP1_WLAST, S_AXI_GP1_WVALID, S_AXI_GP1_ARBURST, S_AXI_GP1_ARLOCK, S_AXI_GP1_ARSIZE, S_AXI_GP1_AWBURST, S_AXI_GP1_AWLOCK, S_AXI_GP1_AWSIZE, S_AXI_GP1_ARPROT, S_AXI_GP1_AWPROT, S_AXI_GP1_ARADDR, S_AXI_GP1_AWADDR, S_AXI_GP1_WDATA, S_AXI_GP1_ARCACHE, S_AXI_GP1_ARLEN, S_AXI_GP1_ARQOS, S_AXI_GP1_AWCACHE, S_AXI_GP1_AWLEN, S_AXI_GP1_AWQOS, S_AXI_GP1_WSTRB, S_AXI_GP1_ARID, S_AXI_GP1_AWID, S_AXI_GP1_WID, S_AXI_ACP_AWREADY, S_AXI_ACP_ARREADY, S_AXI_ACP_BVALID, S_AXI_ACP_RLAST, S_AXI_ACP_RVALID, S_AXI_ACP_WREADY, S_AXI_ACP_BRESP, S_AXI_ACP_RRESP, S_AXI_ACP_BID, S_AXI_ACP_RID, S_AXI_ACP_RDATA, S_AXI_ACP_ACLK, S_AXI_ACP_ARVALID, S_AXI_ACP_AWVALID, S_AXI_ACP_BREADY, S_AXI_ACP_RREADY, S_AXI_ACP_WLAST, S_AXI_ACP_WVALID, S_AXI_ACP_ARID, S_AXI_ACP_ARPROT, S_AXI_ACP_AWID, S_AXI_ACP_AWPROT, S_AXI_ACP_WID, S_AXI_ACP_ARADDR, S_AXI_ACP_AWADDR, S_AXI_ACP_ARCACHE, S_AXI_ACP_ARLEN, S_AXI_ACP_ARQOS, S_AXI_ACP_AWCACHE, S_AXI_ACP_AWLEN, S_AXI_ACP_AWQOS, S_AXI_ACP_ARBURST, S_AXI_ACP_ARLOCK, S_AXI_ACP_ARSIZE, S_AXI_ACP_AWBURST, S_AXI_ACP_AWLOCK, S_AXI_ACP_AWSIZE, S_AXI_ACP_ARUSER, S_AXI_ACP_AWUSER, S_AXI_ACP_WDATA, S_AXI_ACP_WSTRB, S_AXI_HP0_ARREADY, S_AXI_HP0_AWREADY, S_AXI_HP0_BVALID, S_AXI_HP0_RLAST, S_AXI_HP0_RVALID, S_AXI_HP0_WREADY, S_AXI_HP0_BRESP, S_AXI_HP0_RRESP, S_AXI_HP0_BID, S_AXI_HP0_RID, S_AXI_HP0_RDATA, S_AXI_HP0_RCOUNT, S_AXI_HP0_WCOUNT, S_AXI_HP0_RACOUNT, S_AXI_HP0_WACOUNT, S_AXI_HP0_ACLK, S_AXI_HP0_ARVALID, S_AXI_HP0_AWVALID, S_AXI_HP0_BREADY, S_AXI_HP0_RDISSUECAP1_EN, S_AXI_HP0_RREADY, S_AXI_HP0_WLAST, S_AXI_HP0_WRISSUECAP1_EN, S_AXI_HP0_WVALID, S_AXI_HP0_ARBURST, S_AXI_HP0_ARLOCK, S_AXI_HP0_ARSIZE, S_AXI_HP0_AWBURST, S_AXI_HP0_AWLOCK, S_AXI_HP0_AWSIZE, S_AXI_HP0_ARPROT, S_AXI_HP0_AWPROT, S_AXI_HP0_ARADDR, S_AXI_HP0_AWADDR, S_AXI_HP0_ARCACHE, S_AXI_HP0_ARLEN, S_AXI_HP0_ARQOS, S_AXI_HP0_AWCACHE, S_AXI_HP0_AWLEN, S_AXI_HP0_AWQOS, S_AXI_HP0_ARID, S_AXI_HP0_AWID, S_AXI_HP0_WID, S_AXI_HP0_WDATA, S_AXI_HP0_WSTRB, S_AXI_HP1_ARREADY, S_AXI_HP1_AWREADY, S_AXI_HP1_BVALID, S_AXI_HP1_RLAST, S_AXI_HP1_RVALID, S_AXI_HP1_WREADY, S_AXI_HP1_BRESP, S_AXI_HP1_RRESP, S_AXI_HP1_BID, S_AXI_HP1_RID, S_AXI_HP1_RDATA, S_AXI_HP1_RCOUNT, S_AXI_HP1_WCOUNT, S_AXI_HP1_RACOUNT, S_AXI_HP1_WACOUNT, S_AXI_HP1_ACLK, S_AXI_HP1_ARVALID, S_AXI_HP1_AWVALID, S_AXI_HP1_BREADY, S_AXI_HP1_RDISSUECAP1_EN, S_AXI_HP1_RREADY, S_AXI_HP1_WLAST, S_AXI_HP1_WRISSUECAP1_EN, S_AXI_HP1_WVALID, S_AXI_HP1_ARBURST, S_AXI_HP1_ARLOCK, S_AXI_HP1_ARSIZE, S_AXI_HP1_AWBURST, S_AXI_HP1_AWLOCK, S_AXI_HP1_AWSIZE, S_AXI_HP1_ARPROT, S_AXI_HP1_AWPROT, S_AXI_HP1_ARADDR, S_AXI_HP1_AWADDR, S_AXI_HP1_ARCACHE, S_AXI_HP1_ARLEN, S_AXI_HP1_ARQOS, S_AXI_HP1_AWCACHE, S_AXI_HP1_AWLEN, S_AXI_HP1_AWQOS, S_AXI_HP1_ARID, S_AXI_HP1_AWID, S_AXI_HP1_WID, S_AXI_HP1_WDATA, S_AXI_HP1_WSTRB, S_AXI_HP2_ARREADY, S_AXI_HP2_AWREADY, S_AXI_HP2_BVALID, S_AXI_HP2_RLAST, S_AXI_HP2_RVALID, S_AXI_HP2_WREADY, S_AXI_HP2_BRESP, S_AXI_HP2_RRESP, S_AXI_HP2_BID, S_AXI_HP2_RID, S_AXI_HP2_RDATA, S_AXI_HP2_RCOUNT, S_AXI_HP2_WCOUNT, S_AXI_HP2_RACOUNT, S_AXI_HP2_WACOUNT, S_AXI_HP2_ACLK, S_AXI_HP2_ARVALID, S_AXI_HP2_AWVALID, S_AXI_HP2_BREADY, S_AXI_HP2_RDISSUECAP1_EN, S_AXI_HP2_RREADY, S_AXI_HP2_WLAST, S_AXI_HP2_WRISSUECAP1_EN, S_AXI_HP2_WVALID, S_AXI_HP2_ARBURST, S_AXI_HP2_ARLOCK, S_AXI_HP2_ARSIZE, S_AXI_HP2_AWBURST, S_AXI_HP2_AWLOCK, S_AXI_HP2_AWSIZE, S_AXI_HP2_ARPROT, S_AXI_HP2_AWPROT, S_AXI_HP2_ARADDR, S_AXI_HP2_AWADDR, S_AXI_HP2_ARCACHE, S_AXI_HP2_ARLEN, S_AXI_HP2_ARQOS, S_AXI_HP2_AWCACHE, S_AXI_HP2_AWLEN, S_AXI_HP2_AWQOS, S_AXI_HP2_ARID, S_AXI_HP2_AWID, S_AXI_HP2_WID, S_AXI_HP2_WDATA, S_AXI_HP2_WSTRB, S_AXI_HP3_ARREADY, S_AXI_HP3_AWREADY, S_AXI_HP3_BVALID, S_AXI_HP3_RLAST, S_AXI_HP3_RVALID, S_AXI_HP3_WREADY, S_AXI_HP3_BRESP, S_AXI_HP3_RRESP, S_AXI_HP3_BID, S_AXI_HP3_RID, S_AXI_HP3_RDATA, S_AXI_HP3_RCOUNT, S_AXI_HP3_WCOUNT, S_AXI_HP3_RACOUNT, S_AXI_HP3_WACOUNT, S_AXI_HP3_ACLK, S_AXI_HP3_ARVALID, S_AXI_HP3_AWVALID, S_AXI_HP3_BREADY, S_AXI_HP3_RDISSUECAP1_EN, S_AXI_HP3_RREADY, S_AXI_HP3_WLAST, S_AXI_HP3_WRISSUECAP1_EN, S_AXI_HP3_WVALID, S_AXI_HP3_ARBURST, S_AXI_HP3_ARLOCK, S_AXI_HP3_ARSIZE, S_AXI_HP3_AWBURST, S_AXI_HP3_AWLOCK, S_AXI_HP3_AWSIZE, S_AXI_HP3_ARPROT, S_AXI_HP3_AWPROT, S_AXI_HP3_ARADDR, S_AXI_HP3_AWADDR, S_AXI_HP3_ARCACHE, S_AXI_HP3_ARLEN, S_AXI_HP3_ARQOS, S_AXI_HP3_AWCACHE, S_AXI_HP3_AWLEN, S_AXI_HP3_AWQOS, S_AXI_HP3_ARID, S_AXI_HP3_AWID, S_AXI_HP3_WID, S_AXI_HP3_WDATA, S_AXI_HP3_WSTRB, DMA0_DATYPE, DMA0_DAVALID, DMA0_DRREADY, DMA0_ACLK, DMA0_DAREADY, DMA0_DRLAST, DMA0_DRVALID, DMA0_DRTYPE, DMA1_DATYPE, DMA1_DAVALID, DMA1_DRREADY, DMA1_ACLK, DMA1_DAREADY, DMA1_DRLAST, DMA1_DRVALID, DMA1_DRTYPE, DMA2_DATYPE, DMA2_DAVALID, DMA2_DRREADY, DMA2_ACLK, DMA2_DAREADY, DMA2_DRLAST, DMA2_DRVALID, DMA3_DRVALID, DMA3_DATYPE, DMA3_DAVALID, DMA3_DRREADY, DMA3_ACLK, DMA3_DAREADY, DMA3_DRLAST, DMA2_DRTYPE, DMA3_DRTYPE, FTMD_TRACEIN_DATA, FTMD_TRACEIN_VALID, FTMD_TRACEIN_CLK, FTMD_TRACEIN_ATID, FTMT_F2P_TRIG, FTMT_F2P_TRIGACK, FTMT_F2P_DEBUG, FTMT_P2F_TRIGACK, FTMT_P2F_TRIG, FTMT_P2F_DEBUG, FCLK_CLK3, FCLK_CLK2, FCLK_CLK1, FCLK_CLK0, FCLK_CLKTRIG3_N, FCLK_CLKTRIG2_N, FCLK_CLKTRIG1_N, FCLK_CLKTRIG0_N, FCLK_RESET3_N, FCLK_RESET2_N, FCLK_RESET1_N, FCLK_RESET0_N, FPGA_IDLE_N, DDR_ARB, IRQ_F2P, Core0_nFIQ, Core0_nIRQ, Core1_nFIQ, Core1_nIRQ, EVENT_EVENTO, EVENT_STANDBYWFE, EVENT_STANDBYWFI, EVENT_EVENTI, MIO, DDR_Clk, DDR_Clk_n, DDR_CKE, DDR_CS_n, DDR_RAS_n, DDR_CAS_n, DDR_WEB, DDR_BankAddr, DDR_Addr, DDR_ODT, DDR_DRSTB, DDR_DQ, DDR_DM, DDR_DQS, DDR_DQS_n, DDR_VRN, DDR_VRP, PS_SRSTB, PS_CLK, PS_PORB, IRQ_P2F_DMAC_ABORT, IRQ_P2F_DMAC0, IRQ_P2F_DMAC1, IRQ_P2F_DMAC2, IRQ_P2F_DMAC3, IRQ_P2F_DMAC4, IRQ_P2F_DMAC5, IRQ_P2F_DMAC6, IRQ_P2F_DMAC7, IRQ_P2F_SMC, IRQ_P2F_QSPI, IRQ_P2F_CTI, IRQ_P2F_GPIO, IRQ_P2F_USB0, IRQ_P2F_ENET0, IRQ_P2F_ENET_WAKE0, IRQ_P2F_SDIO0, IRQ_P2F_I2C0, IRQ_P2F_SPI0, IRQ_P2F_UART0, IRQ_P2F_CAN0, IRQ_P2F_USB1, IRQ_P2F_ENET1, IRQ_P2F_ENET_WAKE1, IRQ_P2F_SDIO1, IRQ_P2F_I2C1, IRQ_P2F_SPI1, IRQ_P2F_UART1, IRQ_P2F_CAN1 ); /* parameters for gen_clk / parameter C_FCLK_CLK0_FREQ = 50; parameter C_FCLK_CLK1_FREQ = 50; parameter C_FCLK_CLK3_FREQ = 50; parameter C_FCLK_CLK2_FREQ = 50; parameter C_HIGH_OCM_EN = 0; / parameters for HP ports / parameter C_USE_S_AXI_HP0 = 0; parameter C_USE_S_AXI_HP1 = 0; parameter C_USE_S_AXI_HP2 = 0; parameter C_USE_S_AXI_HP3 = 0; parameter C_S_AXI_HP0_DATA_WIDTH = 32; parameter C_S_AXI_HP1_DATA_WIDTH = 32; parameter C_S_AXI_HP2_DATA_WIDTH = 32; parameter C_S_AXI_HP3_DATA_WIDTH = 32; parameter C_M_AXI_GP0_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP1_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP0_ENABLE_STATIC_REMAP = 0; parameter C_M_AXI_GP1_ENABLE_STATIC_REMAP = 0; / Do we need these parameter C_S_AXI_HP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP2_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP3_ENABLE_HIGHOCM = 0; / parameter C_S_AXI_HP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP2_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP3_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP2_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP3_HIGHADDR = 32'hFFFF_FFFF; / parameters for GP and ACP ports / parameter C_USE_M_AXI_GP0 = 0; parameter C_USE_M_AXI_GP1 = 0; parameter C_USE_S_AXI_GP0 = 1; parameter C_USE_S_AXI_GP1 = 1; / Do we need this? parameter C_M_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_M_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_ACP_ENABLE_HIGHOCM = 0;/ parameter C_S_AXI_GP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_GP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_USE_S_AXI_ACP = 1; parameter C_S_AXI_ACP_BASEADDR = 32'h0000_0000; parameter C_S_AXI_ACP_HIGHADDR = 32'hFFFF_FFFF; `include "processing_system7_bfm_v2_0_5_local_params.v" output CAN0_PHY_TX; input CAN0_PHY_RX; output CAN1_PHY_TX; input CAN1_PHY_RX; output ENET0_GMII_TX_EN; output ENET0_GMII_TX_ER; output ENET0_MDIO_MDC; output ENET0_MDIO_O; output ENET0_MDIO_T; output ENET0_PTP_DELAY_REQ_RX; output ENET0_PTP_DELAY_REQ_TX; output ENET0_PTP_PDELAY_REQ_RX; output ENET0_PTP_PDELAY_REQ_TX; output ENET0_PTP_PDELAY_RESP_RX; output ENET0_PTP_PDELAY_RESP_TX; output ENET0_PTP_SYNC_FRAME_RX; output ENET0_PTP_SYNC_FRAME_TX; output ENET0_SOF_RX; output ENET0_SOF_TX; output [7:0] ENET0_GMII_TXD; input ENET0_GMII_COL; input ENET0_GMII_CRS; input ENET0_EXT_INTIN; input ENET0_GMII_RX_CLK; input ENET0_GMII_RX_DV; input ENET0_GMII_RX_ER; input ENET0_GMII_TX_CLK; input ENET0_MDIO_I; input [7:0] ENET0_GMII_RXD; output ENET1_GMII_TX_EN; output ENET1_GMII_TX_ER; output ENET1_MDIO_MDC; output ENET1_MDIO_O; output ENET1_MDIO_T; output ENET1_PTP_DELAY_REQ_RX; output ENET1_PTP_DELAY_REQ_TX; output ENET1_PTP_PDELAY_REQ_RX; output ENET1_PTP_PDELAY_REQ_TX; output ENET1_PTP_PDELAY_RESP_RX; output ENET1_PTP_PDELAY_RESP_TX; output ENET1_PTP_SYNC_FRAME_RX; output ENET1_PTP_SYNC_FRAME_TX; output ENET1_SOF_RX; output ENET1_SOF_TX; output [7:0] ENET1_GMII_TXD; input ENET1_GMII_COL; input ENET1_GMII_CRS; input ENET1_EXT_INTIN; input ENET1_GMII_RX_CLK; input ENET1_GMII_RX_DV; input ENET1_GMII_RX_ER; input ENET1_GMII_TX_CLK; input ENET1_MDIO_I; input [7:0] ENET1_GMII_RXD; input [63:0] GPIO_I; output [63:0] GPIO_O; output [63:0] GPIO_T; input I2C0_SDA_I; output I2C0_SDA_O; output I2C0_SDA_T; input I2C0_SCL_I; output I2C0_SCL_O; output I2C0_SCL_T; input I2C1_SDA_I; output I2C1_SDA_O; output I2C1_SDA_T; input I2C1_SCL_I; output I2C1_SCL_O; output I2C1_SCL_T; input PJTAG_TCK; input PJTAG_TMS; input PJTAG_TD_I; output PJTAG_TD_T; output PJTAG_TD_O; output SDIO0_CLK; input SDIO0_CLK_FB; output SDIO0_CMD_O; input SDIO0_CMD_I; output SDIO0_CMD_T; input [3:0] SDIO0_DATA_I; output [3:0] SDIO0_DATA_O; output [3:0] SDIO0_DATA_T; output SDIO0_LED; input SDIO0_CDN; input SDIO0_WP; output SDIO0_BUSPOW; output [2:0] SDIO0_BUSVOLT; output SDIO1_CLK; input SDIO1_CLK_FB; output SDIO1_CMD_O; input SDIO1_CMD_I; output SDIO1_CMD_T; input [3:0] SDIO1_DATA_I; output [3:0] SDIO1_DATA_O; output [3:0] SDIO1_DATA_T; output SDIO1_LED; input SDIO1_CDN; input SDIO1_WP; output SDIO1_BUSPOW; output [2:0] SDIO1_BUSVOLT; input SPI0_SCLK_I; output SPI0_SCLK_O; output SPI0_SCLK_T; input SPI0_MOSI_I; output SPI0_MOSI_O; output SPI0_MOSI_T; input SPI0_MISO_I; output SPI0_MISO_O; output SPI0_MISO_T; input SPI0_SS_I; output SPI0_SS_O; output SPI0_SS1_O; output SPI0_SS2_O; output SPI0_SS_T; input SPI1_SCLK_I; output SPI1_SCLK_O; output SPI1_SCLK_T; input SPI1_MOSI_I; output SPI1_MOSI_O; output SPI1_MOSI_T; input SPI1_MISO_I; output SPI1_MISO_O; output SPI1_MISO_T; input SPI1_SS_I; output SPI1_SS_O; output SPI1_SS1_O; output SPI1_SS2_O; output SPI1_SS_T; output UART0_DTRN; output UART0_RTSN; output UART0_TX; input UART0_CTSN; input UART0_DCDN; input UART0_DSRN; input UART0_RIN; input UART0_RX; output UART1_DTRN; output UART1_RTSN; output UART1_TX; input UART1_CTSN; input UART1_DCDN; input UART1_DSRN; input UART1_RIN; input UART1_RX; output TTC0_WAVE0_OUT; output TTC0_WAVE1_OUT; output TTC0_WAVE2_OUT; input TTC0_CLK0_IN; input TTC0_CLK1_IN; input TTC0_CLK2_IN; output TTC1_WAVE0_OUT; output TTC1_WAVE1_OUT; output TTC1_WAVE2_OUT; input TTC1_CLK0_IN; input TTC1_CLK1_IN; input TTC1_CLK2_IN; input WDT_CLK_IN; output WDT_RST_OUT; input TRACE_CLK; output TRACE_CTL; output [31:0] TRACE_DATA; output [1:0] USB0_PORT_INDCTL; output [1:0] USB1_PORT_INDCTL; output USB0_VBUS_PWRSELECT; output USB1_VBUS_PWRSELECT; input USB0_VBUS_PWRFAULT; input USB1_VBUS_PWRFAULT; input SRAM_INTIN; output M_AXI_GP0_ARVALID; output M_AXI_GP0_AWVALID; output M_AXI_GP0_BREADY; output M_AXI_GP0_RREADY; output M_AXI_GP0_WLAST; output M_AXI_GP0_WVALID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_ARID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_AWID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_WID; output [1:0] M_AXI_GP0_ARBURST; output [1:0] M_AXI_GP0_ARLOCK; output [2:0] M_AXI_GP0_ARSIZE; output [1:0] M_AXI_GP0_AWBURST; output [1:0] M_AXI_GP0_AWLOCK; output [2:0] M_AXI_GP0_AWSIZE; output [2:0] M_AXI_GP0_ARPROT; output [2:0] M_AXI_GP0_AWPROT; output [31:0] M_AXI_GP0_ARADDR; output [31:0] M_AXI_GP0_AWADDR; output [31:0] M_AXI_GP0_WDATA; output [3:0] M_AXI_GP0_ARCACHE; output [3:0] M_AXI_GP0_ARLEN; output [3:0] M_AXI_GP0_ARQOS; output [3:0] M_AXI_GP0_AWCACHE; output [3:0] M_AXI_GP0_AWLEN; output [3:0] M_AXI_GP0_AWQOS; output [3:0] M_AXI_GP0_WSTRB; input M_AXI_GP0_ACLK; input M_AXI_GP0_ARREADY; input M_AXI_GP0_AWREADY; input M_AXI_GP0_BVALID; input M_AXI_GP0_RLAST; input M_AXI_GP0_RVALID; input M_AXI_GP0_WREADY; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_BID; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_RID; input [1:0] M_AXI_GP0_BRESP; input [1:0] M_AXI_GP0_RRESP; input [31:0] M_AXI_GP0_RDATA; output M_AXI_GP1_ARVALID; output M_AXI_GP1_AWVALID; output M_AXI_GP1_BREADY; output M_AXI_GP1_RREADY; output M_AXI_GP1_WLAST; output M_AXI_GP1_WVALID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_ARID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_AWID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_WID; output [1:0] M_AXI_GP1_ARBURST; output [1:0] M_AXI_GP1_ARLOCK; output [2:0] M_AXI_GP1_ARSIZE; output [1:0] M_AXI_GP1_AWBURST; output [1:0] M_AXI_GP1_AWLOCK; output [2:0] M_AXI_GP1_AWSIZE; output [2:0] M_AXI_GP1_ARPROT; output [2:0] M_AXI_GP1_AWPROT; output [31:0] M_AXI_GP1_ARADDR; output [31:0] M_AXI_GP1_AWADDR; output [31:0] M_AXI_GP1_WDATA; output [3:0] M_AXI_GP1_ARCACHE; output [3:0] M_AXI_GP1_ARLEN; output [3:0] M_AXI_GP1_ARQOS; output [3:0] M_AXI_GP1_AWCACHE; output [3:0] M_AXI_GP1_AWLEN; output [3:0] M_AXI_GP1_AWQOS; output [3:0] M_AXI_GP1_WSTRB; input M_AXI_GP1_ACLK; input M_AXI_GP1_ARREADY; input M_AXI_GP1_AWREADY; input M_AXI_GP1_BVALID; input M_AXI_GP1_RLAST; input M_AXI_GP1_RVALID; input M_AXI_GP1_WREADY; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_BID; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_RID; input [1:0] M_AXI_GP1_BRESP; input [1:0] M_AXI_GP1_RRESP; input [31:0] M_AXI_GP1_RDATA; output S_AXI_GP0_ARREADY; output S_AXI_GP0_AWREADY; output S_AXI_GP0_BVALID; output S_AXI_GP0_RLAST; output S_AXI_GP0_RVALID; output S_AXI_GP0_WREADY; output [1:0] S_AXI_GP0_BRESP; output [1:0] S_AXI_GP0_RRESP; output [31:0] S_AXI_GP0_RDATA; output [5:0] S_AXI_GP0_BID; output [5:0] S_AXI_GP0_RID; input S_AXI_GP0_ACLK; input S_AXI_GP0_ARVALID; input S_AXI_GP0_AWVALID; input S_AXI_GP0_BREADY; input S_AXI_GP0_RREADY; input S_AXI_GP0_WLAST; input S_AXI_GP0_WVALID; input [1:0] S_AXI_GP0_ARBURST; input [1:0] S_AXI_GP0_ARLOCK; input [2:0] S_AXI_GP0_ARSIZE; input [1:0] S_AXI_GP0_AWBURST; input [1:0] S_AXI_GP0_AWLOCK; input [2:0] S_AXI_GP0_AWSIZE; input [2:0] S_AXI_GP0_ARPROT; input [2:0] S_AXI_GP0_AWPROT; input [31:0] S_AXI_GP0_ARADDR; input [31:0] S_AXI_GP0_AWADDR; input [31:0] S_AXI_GP0_WDATA; input [3:0] S_AXI_GP0_ARCACHE; input [3:0] S_AXI_GP0_ARLEN; input [3:0] S_AXI_GP0_ARQOS; input [3:0] S_AXI_GP0_AWCACHE; input [3:0] S_AXI_GP0_AWLEN; input [3:0] S_AXI_GP0_AWQOS; input [3:0] S_AXI_GP0_WSTRB; input [5:0] S_AXI_GP0_ARID; input [5:0] S_AXI_GP0_AWID; input [5:0] S_AXI_GP0_WID; output S_AXI_GP1_ARREADY; output S_AXI_GP1_AWREADY; output S_AXI_GP1_BVALID; output S_AXI_GP1_RLAST; output S_AXI_GP1_RVALID; output S_AXI_GP1_WREADY; output [1:0] S_AXI_GP1_BRESP; output [1:0] S_AXI_GP1_RRESP; output [31:0] S_AXI_GP1_RDATA; output [5:0] S_AXI_GP1_BID; output [5:0] S_AXI_GP1_RID; input S_AXI_GP1_ACLK; input S_AXI_GP1_ARVALID; input S_AXI_GP1_AWVALID; input S_AXI_GP1_BREADY; input S_AXI_GP1_RREADY; input S_AXI_GP1_WLAST; input S_AXI_GP1_WVALID; input [1:0] S_AXI_GP1_ARBURST; input [1:0] S_AXI_GP1_ARLOCK; input [2:0] S_AXI_GP1_ARSIZE; input [1:0] S_AXI_GP1_AWBURST; input [1:0] S_AXI_GP1_AWLOCK; input [2:0] S_AXI_GP1_AWSIZE; input [2:0] S_AXI_GP1_ARPROT; input [2:0] S_AXI_GP1_AWPROT; input [31:0] S_AXI_GP1_ARADDR; input [31:0] S_AXI_GP1_AWADDR; input [31:0] S_AXI_GP1_WDATA; input [3:0] S_AXI_GP1_ARCACHE; input [3:0] S_AXI_GP1_ARLEN; input [3:0] S_AXI_GP1_ARQOS; input [3:0] S_AXI_GP1_AWCACHE; input [3:0] S_AXI_GP1_AWLEN; input [3:0] S_AXI_GP1_AWQOS; input [3:0] S_AXI_GP1_WSTRB; input [5:0] S_AXI_GP1_ARID; input [5:0] S_AXI_GP1_AWID; input [5:0] S_AXI_GP1_WID; output S_AXI_ACP_AWREADY; output S_AXI_ACP_ARREADY; output S_AXI_ACP_BVALID; output S_AXI_ACP_RLAST; output S_AXI_ACP_RVALID; output S_AXI_ACP_WREADY; output [1:0] S_AXI_ACP_BRESP; output [1:0] S_AXI_ACP_RRESP; output [2:0] S_AXI_ACP_BID; output [2:0] S_AXI_ACP_RID; output [63:0] S_AXI_ACP_RDATA; input S_AXI_ACP_ACLK; input S_AXI_ACP_ARVALID; input S_AXI_ACP_AWVALID; input S_AXI_ACP_BREADY; input S_AXI_ACP_RREADY; input S_AXI_ACP_WLAST; input S_AXI_ACP_WVALID; input [2:0] S_AXI_ACP_ARID; input [2:0] S_AXI_ACP_ARPROT; input [2:0] S_AXI_ACP_AWID; input [2:0] S_AXI_ACP_AWPROT; input [2:0] S_AXI_ACP_WID; input [31:0] S_AXI_ACP_ARADDR; input [31:0] S_AXI_ACP_AWADDR; input [3:0] S_AXI_ACP_ARCACHE; input [3:0] S_AXI_ACP_ARLEN; input [3:0] S_AXI_ACP_ARQOS; input [3:0] S_AXI_ACP_AWCACHE; input [3:0] S_AXI_ACP_AWLEN; input [3:0] S_AXI_ACP_AWQOS; input [1:0] S_AXI_ACP_ARBURST; input [1:0] S_AXI_ACP_ARLOCK; input [2:0] S_AXI_ACP_ARSIZE; input [1:0] S_AXI_ACP_AWBURST; input [1:0] S_AXI_ACP_AWLOCK; input [2:0] S_AXI_ACP_AWSIZE; input [4:0] S_AXI_ACP_ARUSER; input [4:0] S_AXI_ACP_AWUSER; input [63:0] S_AXI_ACP_WDATA; input [7:0] S_AXI_ACP_WSTRB; output S_AXI_HP0_ARREADY; output S_AXI_HP0_AWREADY; output S_AXI_HP0_BVALID; output S_AXI_HP0_RLAST; output S_AXI_HP0_RVALID; output S_AXI_HP0_WREADY; output [1:0] S_AXI_HP0_BRESP; output [1:0] S_AXI_HP0_RRESP; output [5:0] S_AXI_HP0_BID; output [5:0] S_AXI_HP0_RID; output [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_RDATA; output [7:0] S_AXI_HP0_RCOUNT; output [7:0] S_AXI_HP0_WCOUNT; output [2:0] S_AXI_HP0_RACOUNT; output [5:0] S_AXI_HP0_WACOUNT; input S_AXI_HP0_ACLK; input S_AXI_HP0_ARVALID; input S_AXI_HP0_AWVALID; input S_AXI_HP0_BREADY; input S_AXI_HP0_RDISSUECAP1_EN; input S_AXI_HP0_RREADY; input S_AXI_HP0_WLAST; input S_AXI_HP0_WRISSUECAP1_EN; input S_AXI_HP0_WVALID; input [1:0] S_AXI_HP0_ARBURST; input [1:0] S_AXI_HP0_ARLOCK; input [2:0] S_AXI_HP0_ARSIZE; input [1:0] S_AXI_HP0_AWBURST; input [1:0] S_AXI_HP0_AWLOCK; input [2:0] S_AXI_HP0_AWSIZE; input [2:0] S_AXI_HP0_ARPROT; input [2:0] S_AXI_HP0_AWPROT; input [31:0] S_AXI_HP0_ARADDR; input [31:0] S_AXI_HP0_AWADDR; input [3:0] S_AXI_HP0_ARCACHE; input [3:0] S_AXI_HP0_ARLEN; input [3:0] S_AXI_HP0_ARQOS; input [3:0] S_AXI_HP0_AWCACHE; input [3:0] S_AXI_HP0_AWLEN; input [3:0] S_AXI_HP0_AWQOS; input [5:0] S_AXI_HP0_ARID; input [5:0] S_AXI_HP0_AWID; input [5:0] S_AXI_HP0_WID; input [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_WDATA; input [C_S_AXI_HP0_DATA_WIDTH/8-1:0] S_AXI_HP0_WSTRB; output S_AXI_HP1_ARREADY; output S_AXI_HP1_AWREADY; output S_AXI_HP1_BVALID; output S_AXI_HP1_RLAST; output S_AXI_HP1_RVALID; output S_AXI_HP1_WREADY; output [1:0] S_AXI_HP1_BRESP; output [1:0] S_AXI_HP1_RRESP; output [5:0] S_AXI_HP1_BID; output [5:0] S_AXI_HP1_RID; output [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_RDATA; output [7:0] S_AXI_HP1_RCOUNT; output [7:0] S_AXI_HP1_WCOUNT; output [2:0] S_AXI_HP1_RACOUNT; output [5:0] S_AXI_HP1_WACOUNT; input S_AXI_HP1_ACLK; input S_AXI_HP1_ARVALID; input S_AXI_HP1_AWVALID; input S_AXI_HP1_BREADY; input S_AXI_HP1_RDISSUECAP1_EN; input S_AXI_HP1_RREADY; input S_AXI_HP1_WLAST; input S_AXI_HP1_WRISSUECAP1_EN; input S_AXI_HP1_WVALID; input [1:0] S_AXI_HP1_ARBURST; input [1:0] S_AXI_HP1_ARLOCK; input [2:0] S_AXI_HP1_ARSIZE; input [1:0] S_AXI_HP1_AWBURST; input [1:0] S_AXI_HP1_AWLOCK; input [2:0] S_AXI_HP1_AWSIZE; input [2:0] S_AXI_HP1_ARPROT; input [2:0] S_AXI_HP1_AWPROT; input [31:0] S_AXI_HP1_ARADDR; input [31:0] S_AXI_HP1_AWADDR; input [3:0] S_AXI_HP1_ARCACHE; input [3:0] S_AXI_HP1_ARLEN; input [3:0] S_AXI_HP1_ARQOS; input [3:0] S_AXI_HP1_AWCACHE; input [3:0] S_AXI_HP1_AWLEN; input [3:0] S_AXI_HP1_AWQOS; input [5:0] S_AXI_HP1_ARID; input [5:0] S_AXI_HP1_AWID; input [5:0] S_AXI_HP1_WID; input [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_WDATA; input [C_S_AXI_HP1_DATA_WIDTH/8-1:0] S_AXI_HP1_WSTRB; output S_AXI_HP2_ARREADY; output S_AXI_HP2_AWREADY; output S_AXI_HP2_BVALID; output S_AXI_HP2_RLAST; output S_AXI_HP2_RVALID; output S_AXI_HP2_WREADY; output [1:0] S_AXI_HP2_BRESP; output [1:0] S_AXI_HP2_RRESP; output [5:0] S_AXI_HP2_BID; output [5:0] S_AXI_HP2_RID; output [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_RDATA; output [7:0] S_AXI_HP2_RCOUNT; output [7:0] S_AXI_HP2_WCOUNT; output [2:0] S_AXI_HP2_RACOUNT; output [5:0] S_AXI_HP2_WACOUNT; input S_AXI_HP2_ACLK; input S_AXI_HP2_ARVALID; input S_AXI_HP2_AWVALID; input S_AXI_HP2_BREADY; input S_AXI_HP2_RDISSUECAP1_EN; input S_AXI_HP2_RREADY; input S_AXI_HP2_WLAST; input S_AXI_HP2_WRISSUECAP1_EN; input S_AXI_HP2_WVALID; input [1:0] S_AXI_HP2_ARBURST; input [1:0] S_AXI_HP2_ARLOCK; input [2:0] S_AXI_HP2_ARSIZE; input [1:0] S_AXI_HP2_AWBURST; input [1:0] S_AXI_HP2_AWLOCK; input [2:0] S_AXI_HP2_AWSIZE; input [2:0] S_AXI_HP2_ARPROT; input [2:0] S_AXI_HP2_AWPROT; input [31:0] S_AXI_HP2_ARADDR; input [31:0] S_AXI_HP2_AWADDR; input [3:0] S_AXI_HP2_ARCACHE; input [3:0] S_AXI_HP2_ARLEN; input [3:0] S_AXI_HP2_ARQOS; input [3:0] S_AXI_HP2_AWCACHE; input [3:0] S_AXI_HP2_AWLEN; input [3:0] S_AXI_HP2_AWQOS; input [5:0] S_AXI_HP2_ARID; input [5:0] S_AXI_HP2_AWID; input [5:0] S_AXI_HP2_WID; input [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_WDATA; input [C_S_AXI_HP2_DATA_WIDTH/8-1:0] S_AXI_HP2_WSTRB; output S_AXI_HP3_ARREADY; output S_AXI_HP3_AWREADY; output S_AXI_HP3_BVALID; output S_AXI_HP3_RLAST; output S_AXI_HP3_RVALID; output S_AXI_HP3_WREADY; output [1:0] S_AXI_HP3_BRESP; output [1:0] S_AXI_HP3_RRESP; output [5:0] S_AXI_HP3_BID; output [5:0] S_AXI_HP3_RID; output [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_RDATA; output [7:0] S_AXI_HP3_RCOUNT; output [7:0] S_AXI_HP3_WCOUNT; output [2:0] S_AXI_HP3_RACOUNT; output [5:0] S_AXI_HP3_WACOUNT; input S_AXI_HP3_ACLK; input S_AXI_HP3_ARVALID; input S_AXI_HP3_AWVALID; input S_AXI_HP3_BREADY; input S_AXI_HP3_RDISSUECAP1_EN; input S_AXI_HP3_RREADY; input S_AXI_HP3_WLAST; input S_AXI_HP3_WRISSUECAP1_EN; input S_AXI_HP3_WVALID; input [1:0] S_AXI_HP3_ARBURST; input [1:0] S_AXI_HP3_ARLOCK; input [2:0] S_AXI_HP3_ARSIZE; input [1:0] S_AXI_HP3_AWBURST; input [1:0] S_AXI_HP3_AWLOCK; input [2:0] S_AXI_HP3_AWSIZE; input [2:0] S_AXI_HP3_ARPROT; input [2:0] S_AXI_HP3_AWPROT; input [31:0] S_AXI_HP3_ARADDR; input [31:0] S_AXI_HP3_AWADDR; input [3:0] S_AXI_HP3_ARCACHE; input [3:0] S_AXI_HP3_ARLEN; input [3:0] S_AXI_HP3_ARQOS; input [3:0] S_AXI_HP3_AWCACHE; input [3:0] S_AXI_HP3_AWLEN; input [3:0] S_AXI_HP3_AWQOS; input [5:0] S_AXI_HP3_ARID; input [5:0] S_AXI_HP3_AWID; input [5:0] S_AXI_HP3_WID; input [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_WDATA; input [C_S_AXI_HP3_DATA_WIDTH/8-1:0] S_AXI_HP3_WSTRB; output [1:0] DMA0_DATYPE; output DMA0_DAVALID; output DMA0_DRREADY; input DMA0_ACLK; input DMA0_DAREADY; input DMA0_DRLAST; input DMA0_DRVALID; input [1:0] DMA0_DRTYPE; output [1:0] DMA1_DATYPE; output DMA1_DAVALID; output DMA1_DRREADY; input DMA1_ACLK; input DMA1_DAREADY; input DMA1_DRLAST; input DMA1_DRVALID; input [1:0] DMA1_DRTYPE; output [1:0] DMA2_DATYPE; output DMA2_DAVALID; output DMA2_DRREADY; input DMA2_ACLK; input DMA2_DAREADY; input DMA2_DRLAST; input DMA2_DRVALID; input DMA3_DRVALID; output [1:0] DMA3_DATYPE; output DMA3_DAVALID; output DMA3_DRREADY; input DMA3_ACLK; input DMA3_DAREADY; input DMA3_DRLAST; input [1:0] DMA2_DRTYPE; input [1:0] DMA3_DRTYPE; input [31:0] FTMD_TRACEIN_DATA; input FTMD_TRACEIN_VALID; input FTMD_TRACEIN_CLK; input [3:0] FTMD_TRACEIN_ATID; input [3:0] FTMT_F2P_TRIG; output [3:0] FTMT_F2P_TRIGACK; input [31:0] FTMT_F2P_DEBUG; input [3:0] FTMT_P2F_TRIGACK; output [3:0] FTMT_P2F_TRIG; output [31:0] FTMT_P2F_DEBUG; output FCLK_CLK3; output FCLK_CLK2; output FCLK_CLK1; output FCLK_CLK0; input FCLK_CLKTRIG3_N; input FCLK_CLKTRIG2_N; input FCLK_CLKTRIG1_N; input FCLK_CLKTRIG0_N; output FCLK_RESET3_N; output FCLK_RESET2_N; output FCLK_RESET1_N; output FCLK_RESET0_N; input FPGA_IDLE_N; input [3:0] DDR_ARB; input [irq_width-1:0] IRQ_F2P; input Core0_nFIQ; input Core0_nIRQ; input Core1_nFIQ; input Core1_nIRQ; output EVENT_EVENTO; output [1:0] EVENT_STANDBYWFE; output [1:0] EVENT_STANDBYWFI; input EVENT_EVENTI; inout [53:0] MIO; inout DDR_Clk; inout DDR_Clk_n; inout DDR_CKE; inout DDR_CS_n; inout DDR_RAS_n; inout DDR_CAS_n; output DDR_WEB; inout [2:0] DDR_BankAddr; inout [14:0] DDR_Addr; inout DDR_ODT; inout DDR_DRSTB; inout [31:0] DDR_DQ; inout [3:0] DDR_DM; inout [3:0] DDR_DQS; inout [3:0] DDR_DQS_n; inout DDR_VRN; inout DDR_VRP; / Reset Input & Clock Input / input PS_SRSTB; input PS_CLK; input PS_PORB; output IRQ_P2F_DMAC_ABORT; output IRQ_P2F_DMAC0; output IRQ_P2F_DMAC1; output IRQ_P2F_DMAC2; output IRQ_P2F_DMAC3; output IRQ_P2F_DMAC4; output IRQ_P2F_DMAC5; output IRQ_P2F_DMAC6; output IRQ_P2F_DMAC7; output IRQ_P2F_SMC; output IRQ_P2F_QSPI; output IRQ_P2F_CTI; output IRQ_P2F_GPIO; output IRQ_P2F_USB0; output IRQ_P2F_ENET0; output IRQ_P2F_ENET_WAKE0; output IRQ_P2F_SDIO0; output IRQ_P2F_I2C0; output IRQ_P2F_SPI0; output IRQ_P2F_UART0; output IRQ_P2F_CAN0; output IRQ_P2F_USB1; output IRQ_P2F_ENET1; output IRQ_P2F_ENET_WAKE1; output IRQ_P2F_SDIO1; output IRQ_P2F_I2C1; output IRQ_P2F_SPI1; output IRQ_P2F_UART1; output IRQ_P2F_CAN1; / Internal wires/nets used for connectivity / wire net_rstn; wire net_sw_clk; wire net_ocm_clk; wire net_arbiter_clk; wire net_axi_mgp0_rstn; wire net_axi_mgp1_rstn; wire net_axi_gp0_rstn; wire net_axi_gp1_rstn; wire net_axi_hp0_rstn; wire net_axi_hp1_rstn; wire net_axi_hp2_rstn; wire net_axi_hp3_rstn; wire net_axi_acp_rstn; wire [4:0] net_axi_acp_awuser; wire [4:0] net_axi_acp_aruser; / Dummy / assign net_axi_acp_awuser = S_AXI_ACP_AWUSER; assign net_axi_acp_aruser = S_AXI_ACP_ARUSER; / Global variables / reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1; / local variable acting as semaphore for wait_mem_update and wait_reg_update task / reg mem_update_key = 1; reg reg_update_key_0 = 1; reg reg_update_key_1 = 1; / assignments and semantic checks for unused ports / `include "processing_system7_bfm_v2_0_5_unused_ports.v" / include api definition / `include "processing_system7_bfm_v2_0_5_apis.v" / Reset Generator / processing_system7_bfm_v2_0_5_gen_reset gen_rst(.por_rst_n(PS_PORB), .sys_rst_n(PS_SRSTB), .rst_out_n(net_rstn), .m_axi_gp0_clk(M_AXI_GP0_ACLK), .m_axi_gp1_clk(M_AXI_GP1_ACLK), .s_axi_gp0_clk(S_AXI_GP0_ACLK), .s_axi_gp1_clk(S_AXI_GP1_ACLK), .s_axi_hp0_clk(S_AXI_HP0_ACLK), .s_axi_hp1_clk(S_AXI_HP1_ACLK), .s_axi_hp2_clk(S_AXI_HP2_ACLK), .s_axi_hp3_clk(S_AXI_HP3_ACLK), .s_axi_acp_clk(S_AXI_ACP_ACLK), .m_axi_gp0_rstn(net_axi_mgp0_rstn), .m_axi_gp1_rstn(net_axi_mgp1_rstn), .s_axi_gp0_rstn(net_axi_gp0_rstn), .s_axi_gp1_rstn(net_axi_gp1_rstn), .s_axi_hp0_rstn(net_axi_hp0_rstn), .s_axi_hp1_rstn(net_axi_hp1_rstn), .s_axi_hp2_rstn(net_axi_hp2_rstn), .s_axi_hp3_rstn(net_axi_hp3_rstn), .s_axi_acp_rstn(net_axi_acp_rstn), .fclk_reset3_n(FCLK_RESET3_N), .fclk_reset2_n(FCLK_RESET2_N), .fclk_reset1_n(FCLK_RESET1_N), .fclk_reset0_n(FCLK_RESET0_N), .fpga_acp_reset_n(), ////S_AXI_ACP_ARESETN), (These are removed from Zynq IP) .fpga_gp_m0_reset_n(), ////M_AXI_GP0_ARESETN), .fpga_gp_m1_reset_n(), ////M_AXI_GP1_ARESETN), .fpga_gp_s0_reset_n(), ////S_AXI_GP0_ARESETN), .fpga_gp_s1_reset_n(), ////S_AXI_GP1_ARESETN), .fpga_hp_s0_reset_n(), ////S_AXI_HP0_ARESETN), .fpga_hp_s1_reset_n(), ////S_AXI_HP1_ARESETN), .fpga_hp_s2_reset_n(), ////S_AXI_HP2_ARESETN), .fpga_hp_s3_reset_n() ////S_AXI_HP3_ARESETN) ); / Clock Generator / processing_system7_bfm_v2_0_5_gen_clock #(C_FCLK_CLK3_FREQ, C_FCLK_CLK2_FREQ, C_FCLK_CLK1_FREQ, C_FCLK_CLK0_FREQ) gen_clk(.ps_clk(PS_CLK), .sw_clk(net_sw_clk), .fclk_clk3(FCLK_CLK3), .fclk_clk2(FCLK_CLK2), .fclk_clk1(FCLK_CLK1), .fclk_clk0(FCLK_CLK0) ); wire net_wr_ack_ocm_gp0, net_wr_ack_ddr_gp0, net_wr_ack_ocm_gp1, net_wr_ack_ddr_gp1; wire net_wr_dv_ocm_gp0, net_wr_dv_ddr_gp0, net_wr_dv_ocm_gp1, net_wr_dv_ddr_gp1; wire [max_burst_bits-1:0] net_wr_data_gp0, net_wr_data_gp1; wire [addr_width-1:0] net_wr_addr_gp0, net_wr_addr_gp1; wire [max_burst_bytes_width:0] net_wr_bytes_gp0, net_wr_bytes_gp1; wire [axi_qos_width-1:0] net_wr_qos_gp0, net_wr_qos_gp1; wire net_rd_req_ddr_gp0, net_rd_req_ddr_gp1; wire net_rd_req_ocm_gp0, net_rd_req_ocm_gp1; wire net_rd_req_reg_gp0, net_rd_req_reg_gp1; wire [addr_width-1:0] net_rd_addr_gp0, net_rd_addr_gp1; wire [max_burst_bytes_width:0] net_rd_bytes_gp0, net_rd_bytes_gp1; wire [max_burst_bits-1:0] net_rd_data_ddr_gp0, net_rd_data_ddr_gp1; wire [max_burst_bits-1:0] net_rd_data_ocm_gp0, net_rd_data_ocm_gp1; wire [max_burst_bits-1:0] net_rd_data_reg_gp0, net_rd_data_reg_gp1; wire net_rd_dv_ddr_gp0, net_rd_dv_ddr_gp1; wire net_rd_dv_ocm_gp0, net_rd_dv_ocm_gp1; wire net_rd_dv_reg_gp0, net_rd_dv_reg_gp1; wire [axi_qos_width-1:0] net_rd_qos_gp0, net_rd_qos_gp1; wire net_wr_ack_ddr_hp0, net_wr_ack_ddr_hp1, net_wr_ack_ddr_hp2, net_wr_ack_ddr_hp3; wire net_wr_ack_ocm_hp0, net_wr_ack_ocm_hp1, net_wr_ack_ocm_hp2, net_wr_ack_ocm_hp3; wire net_wr_dv_ddr_hp0, net_wr_dv_ddr_hp1, net_wr_dv_ddr_hp2, net_wr_dv_ddr_hp3; wire net_wr_dv_ocm_hp0, net_wr_dv_ocm_hp1, net_wr_dv_ocm_hp2, net_wr_dv_ocm_hp3; wire [max_burst_bits-1:0] net_wr_data_hp0, net_wr_data_hp1, net_wr_data_hp2, net_wr_data_hp3; wire [addr_width-1:0] net_wr_addr_hp0, net_wr_addr_hp1, net_wr_addr_hp2, net_wr_addr_hp3; wire [max_burst_bytes_width:0] net_wr_bytes_hp0, net_wr_bytes_hp1, net_wr_bytes_hp2, net_wr_bytes_hp3; wire [axi_qos_width-1:0] net_wr_qos_hp0, net_wr_qos_hp1, net_wr_qos_hp2, net_wr_qos_hp3; wire net_rd_req_ddr_hp0, net_rd_req_ddr_hp1, net_rd_req_ddr_hp2, net_rd_req_ddr_hp3; wire net_rd_req_ocm_hp0, net_rd_req_ocm_hp1, net_rd_req_ocm_hp2, net_rd_req_ocm_hp3; wire [addr_width-1:0] net_rd_addr_hp0, net_rd_addr_hp1, net_rd_addr_hp2, net_rd_addr_hp3; wire [max_burst_bytes_width:0] net_rd_bytes_hp0, net_rd_bytes_hp1, net_rd_bytes_hp2, net_rd_bytes_hp3; wire [max_burst_bits-1:0] net_rd_data_ddr_hp0, net_rd_data_ddr_hp1, net_rd_data_ddr_hp2, net_rd_data_ddr_hp3; wire [max_burst_bits-1:0] net_rd_data_ocm_hp0, net_rd_data_ocm_hp1, net_rd_data_ocm_hp2, net_rd_data_ocm_hp3; wire net_rd_dv_ddr_hp0, net_rd_dv_ddr_hp1, net_rd_dv_ddr_hp2, net_rd_dv_ddr_hp3; wire net_rd_dv_ocm_hp0, net_rd_dv_ocm_hp1, net_rd_dv_ocm_hp2, net_rd_dv_ocm_hp3; wire [axi_qos_width-1:0] net_rd_qos_hp0, net_rd_qos_hp1, net_rd_qos_hp2, net_rd_qos_hp3; wire net_wr_ack_ddr_acp,net_wr_ack_ocm_acp; wire net_wr_dv_ddr_acp,net_wr_dv_ocm_acp; wire [max_burst_bits-1:0] net_wr_data_acp; wire [addr_width-1:0] net_wr_addr_acp; wire [max_burst_bytes_width:0] net_wr_bytes_acp; wire [axi_qos_width-1:0] net_wr_qos_acp; wire net_rd_req_ddr_acp, net_rd_req_ocm_acp; wire [addr_width-1:0] net_rd_addr_acp; wire [max_burst_bytes_width:0] net_rd_bytes_acp; wire [max_burst_bits-1:0] net_rd_data_ddr_acp; wire [max_burst_bits-1:0] net_rd_data_ocm_acp; wire net_rd_dv_ddr_acp,net_rd_dv_ocm_acp; wire [axi_qos_width-1:0] net_rd_qos_acp; wire ocm_wr_ack_port0; wire ocm_wr_dv_port0; wire ocm_rd_req_port0; wire ocm_rd_dv_port0; wire [addr_width-1:0] ocm_wr_addr_port0; wire [max_burst_bits-1:0] ocm_wr_data_port0; wire [max_burst_bytes_width:0] ocm_wr_bytes_port0; wire [addr_width-1:0] ocm_rd_addr_port0; wire [max_burst_bits-1:0] ocm_rd_data_port0; wire [max_burst_bytes_width:0] ocm_rd_bytes_port0; wire [axi_qos_width-1:0] ocm_wr_qos_port0; wire [axi_qos_width-1:0] ocm_rd_qos_port0; wire ocm_wr_ack_port1; wire ocm_wr_dv_port1; wire ocm_rd_req_port1; wire ocm_rd_dv_port1; wire [addr_width-1:0] ocm_wr_addr_port1; wire [max_burst_bits-1:0] ocm_wr_data_port1; wire [max_burst_bytes_width:0] ocm_wr_bytes_port1; wire [addr_width-1:0] ocm_rd_addr_port1; wire [max_burst_bits-1:0] ocm_rd_data_port1; wire [max_burst_bytes_width:0] ocm_rd_bytes_port1; wire [axi_qos_width-1:0] ocm_wr_qos_port1; wire [axi_qos_width-1:0] ocm_rd_qos_port1; wire ddr_wr_ack_port0; wire ddr_wr_dv_port0; wire ddr_rd_req_port0; wire ddr_rd_dv_port0; wire[addr_width-1:0] ddr_wr_addr_port0; wire[max_burst_bits-1:0] ddr_wr_data_port0; wire[max_burst_bytes_width:0] ddr_wr_bytes_port0; wire[addr_width-1:0] ddr_rd_addr_port0; wire[max_burst_bits-1:0] ddr_rd_data_port0; wire[max_burst_bytes_width:0] ddr_rd_bytes_port0; wire [axi_qos_width-1:0] ddr_wr_qos_port0; wire [axi_qos_width-1:0] ddr_rd_qos_port0; wire ddr_wr_ack_port1; wire ddr_wr_dv_port1; wire ddr_rd_req_port1; wire ddr_rd_dv_port1; wire[addr_width-1:0] ddr_wr_addr_port1; wire[max_burst_bits-1:0] ddr_wr_data_port1; wire[max_burst_bytes_width:0] ddr_wr_bytes_port1; wire[addr_width-1:0] ddr_rd_addr_port1; wire[max_burst_bits-1:0] ddr_rd_data_port1; wire[max_burst_bytes_width:0] ddr_rd_bytes_port1; wire[axi_qos_width-1:0] ddr_wr_qos_port1; wire[axi_qos_width-1:0] ddr_rd_qos_port1; wire ddr_wr_ack_port2; wire ddr_wr_dv_port2; wire ddr_rd_req_port2; wire ddr_rd_dv_port2; wire[addr_width-1:0] ddr_wr_addr_port2; wire[max_burst_bits-1:0] ddr_wr_data_port2; wire[max_burst_bytes_width:0] ddr_wr_bytes_port2; wire[addr_width-1:0] ddr_rd_addr_port2; wire[max_burst_bits-1:0] ddr_rd_data_port2; wire[max_burst_bytes_width:0] ddr_rd_bytes_port2; wire[axi_qos_width-1:0] ddr_wr_qos_port2; wire[axi_qos_width-1:0] ddr_rd_qos_port2; wire ddr_wr_ack_port3; wire ddr_wr_dv_port3; wire ddr_rd_req_port3; wire ddr_rd_dv_port3; wire[addr_width-1:0] ddr_wr_addr_port3; wire[max_burst_bits-1:0] ddr_wr_data_port3; wire[max_burst_bytes_width:0] ddr_wr_bytes_port3; wire[addr_width-1:0] ddr_rd_addr_port3; wire[max_burst_bits-1:0] ddr_rd_data_port3; wire[max_burst_bytes_width:0] ddr_rd_bytes_port3; wire[axi_qos_width-1:0] ddr_wr_qos_port3; wire[axi_qos_width-1:0] ddr_rd_qos_port3; wire reg_rd_req_port0; wire reg_rd_dv_port0; wire[addr_width-1:0] reg_rd_addr_port0; wire[max_burst_bits-1:0] reg_rd_data_port0; wire[max_burst_bytes_width:0] reg_rd_bytes_port0; wire [axi_qos_width-1:0] reg_rd_qos_port0; wire reg_rd_req_port1; wire reg_rd_dv_port1; wire[addr_width-1:0] reg_rd_addr_port1; wire[max_burst_bits-1:0] reg_rd_data_port1; wire[max_burst_bytes_width:0] reg_rd_bytes_port1; wire [axi_qos_width-1:0] reg_rd_qos_port1; wire [11:0] M_AXI_GP0_AWID_FULL; wire [11:0] M_AXI_GP0_WID_FULL; wire [11:0] M_AXI_GP0_ARID_FULL; wire [11:0] M_AXI_GP0_BID_FULL; wire [11:0] M_AXI_GP0_RID_FULL; wire [11:0] M_AXI_GP1_AWID_FULL; wire [11:0] M_AXI_GP1_WID_FULL; wire [11:0] M_AXI_GP1_ARID_FULL; wire [11:0] M_AXI_GP1_BID_FULL; wire [11:0] M_AXI_GP1_RID_FULL; function [5:0] compress_id; input [11:0] id; begin compress_id = id[5:0]; end endfunction function [11:0] uncompress_id; input [5:0] id; begin uncompress_id = {6'b110000, id[5:0]}; end endfunction assign M_AXI_GP0_AWID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_AWID_FULL) : M_AXI_GP0_AWID_FULL; assign M_AXI_GP0_WID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_WID_FULL) : M_AXI_GP0_WID_FULL; assign M_AXI_GP0_ARID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_ARID_FULL) : M_AXI_GP0_ARID_FULL; assign M_AXI_GP0_BID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_BID) : M_AXI_GP0_BID; assign M_AXI_GP0_RID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_RID) : M_AXI_GP0_RID; assign M_AXI_GP1_AWID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_AWID_FULL) : M_AXI_GP1_AWID_FULL; assign M_AXI_GP1_WID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_WID_FULL) : M_AXI_GP1_WID_FULL; assign M_AXI_GP1_ARID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_ARID_FULL) : M_AXI_GP1_ARID_FULL; assign M_AXI_GP1_BID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_BID) : M_AXI_GP1_BID; assign M_AXI_GP1_RID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_RID) : M_AXI_GP1_RID; processing_system7_bfm_v2_0_5_interconnect_model icm ( .rstn(net_rstn), .sw_clk(net_sw_clk), .w_qos_gp0(net_wr_qos_gp0), .w_qos_gp1(net_wr_qos_gp1), .w_qos_hp0(net_wr_qos_hp0), .w_qos_hp1(net_wr_qos_hp1), .w_qos_hp2(net_wr_qos_hp2), .w_qos_hp3(net_wr_qos_hp3), .r_qos_gp0(net_rd_qos_gp0), .r_qos_gp1(net_rd_qos_gp1), .r_qos_hp0(net_rd_qos_hp0), .r_qos_hp1(net_rd_qos_hp1), .r_qos_hp2(net_rd_qos_hp2), .r_qos_hp3(net_rd_qos_hp3), / GP Slave ports access / .wr_ack_ddr_gp0(net_wr_ack_ddr_gp0), .wr_ack_ocm_gp0(net_wr_ack_ocm_gp0), .wr_data_gp0(net_wr_data_gp0), .wr_addr_gp0(net_wr_addr_gp0), .wr_bytes_gp0(net_wr_bytes_gp0), .wr_dv_ddr_gp0(net_wr_dv_ddr_gp0), .wr_dv_ocm_gp0(net_wr_dv_ocm_gp0), .rd_req_ddr_gp0(net_rd_req_ddr_gp0), .rd_req_ocm_gp0(net_rd_req_ocm_gp0), .rd_req_reg_gp0(net_rd_req_reg_gp0), .rd_addr_gp0(net_rd_addr_gp0), .rd_bytes_gp0(net_rd_bytes_gp0), .rd_data_ddr_gp0(net_rd_data_ddr_gp0), .rd_data_ocm_gp0(net_rd_data_ocm_gp0), .rd_data_reg_gp0(net_rd_data_reg_gp0), .rd_dv_ddr_gp0(net_rd_dv_ddr_gp0), .rd_dv_ocm_gp0(net_rd_dv_ocm_gp0), .rd_dv_reg_gp0(net_rd_dv_reg_gp0), .wr_ack_ddr_gp1(net_wr_ack_ddr_gp1), .wr_ack_ocm_gp1(net_wr_ack_ocm_gp1), .wr_data_gp1(net_wr_data_gp1), .wr_addr_gp1(net_wr_addr_gp1), .wr_bytes_gp1(net_wr_bytes_gp1), .wr_dv_ddr_gp1(net_wr_dv_ddr_gp1), .wr_dv_ocm_gp1(net_wr_dv_ocm_gp1), .rd_req_ddr_gp1(net_rd_req_ddr_gp1), .rd_req_ocm_gp1(net_rd_req_ocm_gp1), .rd_req_reg_gp1(net_rd_req_reg_gp1), .rd_addr_gp1(net_rd_addr_gp1), .rd_bytes_gp1(net_rd_bytes_gp1), .rd_data_ddr_gp1(net_rd_data_ddr_gp1), .rd_data_ocm_gp1(net_rd_data_ocm_gp1), .rd_data_reg_gp1(net_rd_data_reg_gp1), .rd_dv_ddr_gp1(net_rd_dv_ddr_gp1), .rd_dv_ocm_gp1(net_rd_dv_ocm_gp1), .rd_dv_reg_gp1(net_rd_dv_reg_gp1), / HP Slave ports access / .wr_ack_ddr_hp0(net_wr_ack_ddr_hp0), .wr_ack_ocm_hp0(net_wr_ack_ocm_hp0), .wr_data_hp0(net_wr_data_hp0), .wr_addr_hp0(net_wr_addr_hp0), .wr_bytes_hp0(net_wr_bytes_hp0), .wr_dv_ddr_hp0(net_wr_dv_ddr_hp0), .wr_dv_ocm_hp0(net_wr_dv_ocm_hp0), .rd_req_ddr_hp0(net_rd_req_ddr_hp0), .rd_req_ocm_hp0(net_rd_req_ocm_hp0), .rd_addr_hp0(net_rd_addr_hp0), .rd_bytes_hp0(net_rd_bytes_hp0), .rd_data_ddr_hp0(net_rd_data_ddr_hp0), .rd_data_ocm_hp0(net_rd_data_ocm_hp0), .rd_dv_ddr_hp0(net_rd_dv_ddr_hp0), .rd_dv_ocm_hp0(net_rd_dv_ocm_hp0), .wr_ack_ddr_hp1(net_wr_ack_ddr_hp1), .wr_ack_ocm_hp1(net_wr_ack_ocm_hp1), .wr_data_hp1(net_wr_data_hp1), .wr_addr_hp1(net_wr_addr_hp1), .wr_bytes_hp1(net_wr_bytes_hp1), .wr_dv_ddr_hp1(net_wr_dv_ddr_hp1), .wr_dv_ocm_hp1(net_wr_dv_ocm_hp1), .rd_req_ddr_hp1(net_rd_req_ddr_hp1), .rd_req_ocm_hp1(net_rd_req_ocm_hp1), .rd_addr_hp1(net_rd_addr_hp1), .rd_bytes_hp1(net_rd_bytes_hp1), .rd_data_ddr_hp1(net_rd_data_ddr_hp1), .rd_data_ocm_hp1(net_rd_data_ocm_hp1), .rd_dv_ocm_hp1(net_rd_dv_ocm_hp1), .rd_dv_ddr_hp1(net_rd_dv_ddr_hp1), .wr_ack_ddr_hp2(net_wr_ack_ddr_hp2), .wr_ack_ocm_hp2(net_wr_ack_ocm_hp2), .wr_data_hp2(net_wr_data_hp2), .wr_addr_hp2(net_wr_addr_hp2), .wr_bytes_hp2(net_wr_bytes_hp2), .wr_dv_ocm_hp2(net_wr_dv_ocm_hp2), .wr_dv_ddr_hp2(net_wr_dv_ddr_hp2), .rd_req_ddr_hp2(net_rd_req_ddr_hp2), .rd_req_ocm_hp2(net_rd_req_ocm_hp2), .rd_addr_hp2(net_rd_addr_hp2), .rd_bytes_hp2(net_rd_bytes_hp2), .rd_data_ddr_hp2(net_rd_data_ddr_hp2), .rd_data_ocm_hp2(net_rd_data_ocm_hp2), .rd_dv_ddr_hp2(net_rd_dv_ddr_hp2), .rd_dv_ocm_hp2(net_rd_dv_ocm_hp2), .wr_ack_ocm_hp3(net_wr_ack_ocm_hp3), .wr_ack_ddr_hp3(net_wr_ack_ddr_hp3), .wr_data_hp3(net_wr_data_hp3), .wr_addr_hp3(net_wr_addr_hp3), .wr_bytes_hp3(net_wr_bytes_hp3), .wr_dv_ddr_hp3(net_wr_dv_ddr_hp3), .wr_dv_ocm_hp3(net_wr_dv_ocm_hp3), .rd_req_ddr_hp3(net_rd_req_ddr_hp3), .rd_req_ocm_hp3(net_rd_req_ocm_hp3), .rd_addr_hp3(net_rd_addr_hp3), .rd_bytes_hp3(net_rd_bytes_hp3), .rd_data_ddr_hp3(net_rd_data_ddr_hp3), .rd_data_ocm_hp3(net_rd_data_ocm_hp3), .rd_dv_ddr_hp3(net_rd_dv_ddr_hp3), .rd_dv_ocm_hp3(net_rd_dv_ocm_hp3), / Goes to port 1 of DDR / .ddr_wr_ack_port1(ddr_wr_ack_port1), .ddr_wr_dv_port1(ddr_wr_dv_port1), .ddr_rd_req_port1(ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1(ddr_wr_qos_port1), .ddr_rd_qos_port1(ddr_rd_qos_port1), / Goes to port2 of DDR / .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), / Goes to port3 of DDR / .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3), / Goes to port 0 of OCM / .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1), / Goes to port 0 of REG / .reg_rd_qos_port1 (reg_rd_qos_port1) , .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1) ); processing_system7_bfm_v2_0_5_ddrc ddrc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of DDR / .ddr_wr_ack_port0 (ddr_wr_ack_port0), .ddr_wr_dv_port0 (ddr_wr_dv_port0), .ddr_rd_req_port0 (ddr_rd_req_port0), .ddr_rd_dv_port0 (ddr_rd_dv_port0), .ddr_wr_addr_port0(net_wr_addr_acp), .ddr_wr_data_port0(net_wr_data_acp), .ddr_wr_bytes_port0(net_wr_bytes_acp), .ddr_rd_addr_port0(net_rd_addr_acp), .ddr_rd_bytes_port0(net_rd_bytes_acp), .ddr_rd_data_port0(ddr_rd_data_port0), .ddr_wr_qos_port0 (net_wr_qos_acp), .ddr_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of DDR / .ddr_wr_ack_port1 (ddr_wr_ack_port1), .ddr_wr_dv_port1 (ddr_wr_dv_port1), .ddr_rd_req_port1 (ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1 (ddr_wr_qos_port1), .ddr_rd_qos_port1 (ddr_rd_qos_port1), / Goes to port2 of DDR / .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), / Goes to port3 of DDR / .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3) ); processing_system7_bfm_v2_0_5_ocmc ocmc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of OCM / .ocm_wr_ack_port0 (ocm_wr_ack_port0), .ocm_wr_dv_port0 (ocm_wr_dv_port0), .ocm_rd_req_port0 (ocm_rd_req_port0), .ocm_rd_dv_port0 (ocm_rd_dv_port0), .ocm_wr_addr_port0(net_wr_addr_acp), .ocm_wr_data_port0(net_wr_data_acp), .ocm_wr_bytes_port0(net_wr_bytes_acp), .ocm_rd_addr_port0(net_rd_addr_acp), .ocm_rd_bytes_port0(net_rd_bytes_acp), .ocm_rd_data_port0(ocm_rd_data_port0), .ocm_wr_qos_port0 (net_wr_qos_acp), .ocm_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of OCM / .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1) ); processing_system7_bfm_v2_0_5_regc regc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of REG / .reg_rd_req_port0 (reg_rd_req_port0), .reg_rd_dv_port0 (reg_rd_dv_port0), .reg_rd_addr_port0(net_rd_addr_acp), .reg_rd_bytes_port0(net_rd_bytes_acp), .reg_rd_data_port0(reg_rd_data_port0), .reg_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of REG / .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1), .reg_rd_qos_port1(reg_rd_qos_port1) ); / include axi_gp port instantiations / `include "processing_system7_bfm_v2_0_5_axi_gp.v" / include axi_hp port instantiations / `include "processing_system7_bfm_v2_0_5_axi_hp.v" / include axi_acp port instantiations */ `include "processing_system7_bfm_v2_0_5_axi_acp.v" endmodule
module processing_system7_bfm_v2_0_5_processing_system7_bfm ( CAN0_PHY_TX, CAN0_PHY_RX, CAN1_PHY_TX, CAN1_PHY_RX, ENET0_GMII_TX_EN, ENET0_GMII_TX_ER, ENET0_MDIO_MDC, ENET0_MDIO_O, ENET0_MDIO_T, ENET0_PTP_DELAY_REQ_RX, ENET0_PTP_DELAY_REQ_TX, ENET0_PTP_PDELAY_REQ_RX, ENET0_PTP_PDELAY_REQ_TX, ENET0_PTP_PDELAY_RESP_RX, ENET0_PTP_PDELAY_RESP_TX, ENET0_PTP_SYNC_FRAME_RX, ENET0_PTP_SYNC_FRAME_TX, ENET0_SOF_RX, ENET0_SOF_TX, ENET0_GMII_TXD, ENET0_GMII_COL, ENET0_GMII_CRS, ENET0_EXT_INTIN, ENET0_GMII_RX_CLK, ENET0_GMII_RX_DV, ENET0_GMII_RX_ER, ENET0_GMII_TX_CLK, ENET0_MDIO_I, ENET0_GMII_RXD, ENET1_GMII_TX_EN, ENET1_GMII_TX_ER, ENET1_MDIO_MDC, ENET1_MDIO_O, ENET1_MDIO_T, ENET1_PTP_DELAY_REQ_RX, ENET1_PTP_DELAY_REQ_TX, ENET1_PTP_PDELAY_REQ_RX, ENET1_PTP_PDELAY_REQ_TX, ENET1_PTP_PDELAY_RESP_RX, ENET1_PTP_PDELAY_RESP_TX, ENET1_PTP_SYNC_FRAME_RX, ENET1_PTP_SYNC_FRAME_TX, ENET1_SOF_RX, ENET1_SOF_TX, ENET1_GMII_TXD, ENET1_GMII_COL, ENET1_GMII_CRS, ENET1_EXT_INTIN, ENET1_GMII_RX_CLK, ENET1_GMII_RX_DV, ENET1_GMII_RX_ER, ENET1_GMII_TX_CLK, ENET1_MDIO_I, ENET1_GMII_RXD, GPIO_I, GPIO_O, GPIO_T, I2C0_SDA_I, I2C0_SDA_O, I2C0_SDA_T, I2C0_SCL_I, I2C0_SCL_O, I2C0_SCL_T, I2C1_SDA_I, I2C1_SDA_O, I2C1_SDA_T, I2C1_SCL_I, I2C1_SCL_O, I2C1_SCL_T, PJTAG_TCK, PJTAG_TMS, PJTAG_TD_I, PJTAG_TD_T, PJTAG_TD_O, SDIO0_CLK, SDIO0_CLK_FB, SDIO0_CMD_O, SDIO0_CMD_I, SDIO0_CMD_T, SDIO0_DATA_I, SDIO0_DATA_O, SDIO0_DATA_T, SDIO0_LED, SDIO0_CDN, SDIO0_WP, SDIO0_BUSPOW, SDIO0_BUSVOLT, SDIO1_CLK, SDIO1_CLK_FB, SDIO1_CMD_O, SDIO1_CMD_I, SDIO1_CMD_T, SDIO1_DATA_I, SDIO1_DATA_O, SDIO1_DATA_T, SDIO1_LED, SDIO1_CDN, SDIO1_WP, SDIO1_BUSPOW, SDIO1_BUSVOLT, SPI0_SCLK_I, SPI0_SCLK_O, SPI0_SCLK_T, SPI0_MOSI_I, SPI0_MOSI_O, SPI0_MOSI_T, SPI0_MISO_I, SPI0_MISO_O, SPI0_MISO_T, SPI0_SS_I, SPI0_SS_O, SPI0_SS1_O, SPI0_SS2_O, SPI0_SS_T, SPI1_SCLK_I, SPI1_SCLK_O, SPI1_SCLK_T, SPI1_MOSI_I, SPI1_MOSI_O, SPI1_MOSI_T, SPI1_MISO_I, SPI1_MISO_O, SPI1_MISO_T, SPI1_SS_I, SPI1_SS_O, SPI1_SS1_O, SPI1_SS2_O, SPI1_SS_T, UART0_DTRN, UART0_RTSN, UART0_TX, UART0_CTSN, UART0_DCDN, UART0_DSRN, UART0_RIN, UART0_RX, UART1_DTRN, UART1_RTSN, UART1_TX, UART1_CTSN, UART1_DCDN, UART1_DSRN, UART1_RIN, UART1_RX, TTC0_WAVE0_OUT, TTC0_WAVE1_OUT, TTC0_WAVE2_OUT, TTC0_CLK0_IN, TTC0_CLK1_IN, TTC0_CLK2_IN, TTC1_WAVE0_OUT, TTC1_WAVE1_OUT, TTC1_WAVE2_OUT, TTC1_CLK0_IN, TTC1_CLK1_IN, TTC1_CLK2_IN, WDT_CLK_IN, WDT_RST_OUT, TRACE_CLK, TRACE_CTL, TRACE_DATA, USB0_PORT_INDCTL, USB1_PORT_INDCTL, USB0_VBUS_PWRSELECT, USB1_VBUS_PWRSELECT, USB0_VBUS_PWRFAULT, USB1_VBUS_PWRFAULT, SRAM_INTIN, M_AXI_GP0_ARVALID, M_AXI_GP0_AWVALID, M_AXI_GP0_BREADY, M_AXI_GP0_RREADY, M_AXI_GP0_WLAST, M_AXI_GP0_WVALID, M_AXI_GP0_ARID, M_AXI_GP0_AWID, M_AXI_GP0_WID, M_AXI_GP0_ARBURST, M_AXI_GP0_ARLOCK, M_AXI_GP0_ARSIZE, M_AXI_GP0_AWBURST, M_AXI_GP0_AWLOCK, M_AXI_GP0_AWSIZE, M_AXI_GP0_ARPROT, M_AXI_GP0_AWPROT, M_AXI_GP0_ARADDR, M_AXI_GP0_AWADDR, M_AXI_GP0_WDATA, M_AXI_GP0_ARCACHE, M_AXI_GP0_ARLEN, M_AXI_GP0_ARQOS, M_AXI_GP0_AWCACHE, M_AXI_GP0_AWLEN, M_AXI_GP0_AWQOS, M_AXI_GP0_WSTRB, M_AXI_GP0_ACLK, M_AXI_GP0_ARREADY, M_AXI_GP0_AWREADY, M_AXI_GP0_BVALID, M_AXI_GP0_RLAST, M_AXI_GP0_RVALID, M_AXI_GP0_WREADY, M_AXI_GP0_BID, M_AXI_GP0_RID, M_AXI_GP0_BRESP, M_AXI_GP0_RRESP, M_AXI_GP0_RDATA, M_AXI_GP1_ARVALID, M_AXI_GP1_AWVALID, M_AXI_GP1_BREADY, M_AXI_GP1_RREADY, M_AXI_GP1_WLAST, M_AXI_GP1_WVALID, M_AXI_GP1_ARID, M_AXI_GP1_AWID, M_AXI_GP1_WID, M_AXI_GP1_ARBURST, M_AXI_GP1_ARLOCK, M_AXI_GP1_ARSIZE, M_AXI_GP1_AWBURST, M_AXI_GP1_AWLOCK, M_AXI_GP1_AWSIZE, M_AXI_GP1_ARPROT, M_AXI_GP1_AWPROT, M_AXI_GP1_ARADDR, M_AXI_GP1_AWADDR, M_AXI_GP1_WDATA, M_AXI_GP1_ARCACHE, M_AXI_GP1_ARLEN, M_AXI_GP1_ARQOS, M_AXI_GP1_AWCACHE, M_AXI_GP1_AWLEN, M_AXI_GP1_AWQOS, M_AXI_GP1_WSTRB, M_AXI_GP1_ACLK, M_AXI_GP1_ARREADY, M_AXI_GP1_AWREADY, M_AXI_GP1_BVALID, M_AXI_GP1_RLAST, M_AXI_GP1_RVALID, M_AXI_GP1_WREADY, M_AXI_GP1_BID, M_AXI_GP1_RID, M_AXI_GP1_BRESP, M_AXI_GP1_RRESP, M_AXI_GP1_RDATA, S_AXI_GP0_ARREADY, S_AXI_GP0_AWREADY, S_AXI_GP0_BVALID, S_AXI_GP0_RLAST, S_AXI_GP0_RVALID, S_AXI_GP0_WREADY, S_AXI_GP0_BRESP, S_AXI_GP0_RRESP, S_AXI_GP0_RDATA, S_AXI_GP0_BID, S_AXI_GP0_RID, S_AXI_GP0_ACLK, S_AXI_GP0_ARVALID, S_AXI_GP0_AWVALID, S_AXI_GP0_BREADY, S_AXI_GP0_RREADY, S_AXI_GP0_WLAST, S_AXI_GP0_WVALID, S_AXI_GP0_ARBURST, S_AXI_GP0_ARLOCK, S_AXI_GP0_ARSIZE, S_AXI_GP0_AWBURST, S_AXI_GP0_AWLOCK, S_AXI_GP0_AWSIZE, S_AXI_GP0_ARPROT, S_AXI_GP0_AWPROT, S_AXI_GP0_ARADDR, S_AXI_GP0_AWADDR, S_AXI_GP0_WDATA, S_AXI_GP0_ARCACHE, S_AXI_GP0_ARLEN, S_AXI_GP0_ARQOS, S_AXI_GP0_AWCACHE, S_AXI_GP0_AWLEN, S_AXI_GP0_AWQOS, S_AXI_GP0_WSTRB, S_AXI_GP0_ARID, S_AXI_GP0_AWID, S_AXI_GP0_WID, S_AXI_GP1_ARREADY, S_AXI_GP1_AWREADY, S_AXI_GP1_BVALID, S_AXI_GP1_RLAST, S_AXI_GP1_RVALID, S_AXI_GP1_WREADY, S_AXI_GP1_BRESP, S_AXI_GP1_RRESP, S_AXI_GP1_RDATA, S_AXI_GP1_BID, S_AXI_GP1_RID, S_AXI_GP1_ACLK, S_AXI_GP1_ARVALID, S_AXI_GP1_AWVALID, S_AXI_GP1_BREADY, S_AXI_GP1_RREADY, S_AXI_GP1_WLAST, S_AXI_GP1_WVALID, S_AXI_GP1_ARBURST, S_AXI_GP1_ARLOCK, S_AXI_GP1_ARSIZE, S_AXI_GP1_AWBURST, S_AXI_GP1_AWLOCK, S_AXI_GP1_AWSIZE, S_AXI_GP1_ARPROT, S_AXI_GP1_AWPROT, S_AXI_GP1_ARADDR, S_AXI_GP1_AWADDR, S_AXI_GP1_WDATA, S_AXI_GP1_ARCACHE, S_AXI_GP1_ARLEN, S_AXI_GP1_ARQOS, S_AXI_GP1_AWCACHE, S_AXI_GP1_AWLEN, S_AXI_GP1_AWQOS, S_AXI_GP1_WSTRB, S_AXI_GP1_ARID, S_AXI_GP1_AWID, S_AXI_GP1_WID, S_AXI_ACP_AWREADY, S_AXI_ACP_ARREADY, S_AXI_ACP_BVALID, S_AXI_ACP_RLAST, S_AXI_ACP_RVALID, S_AXI_ACP_WREADY, S_AXI_ACP_BRESP, S_AXI_ACP_RRESP, S_AXI_ACP_BID, S_AXI_ACP_RID, S_AXI_ACP_RDATA, S_AXI_ACP_ACLK, S_AXI_ACP_ARVALID, S_AXI_ACP_AWVALID, S_AXI_ACP_BREADY, S_AXI_ACP_RREADY, S_AXI_ACP_WLAST, S_AXI_ACP_WVALID, S_AXI_ACP_ARID, S_AXI_ACP_ARPROT, S_AXI_ACP_AWID, S_AXI_ACP_AWPROT, S_AXI_ACP_WID, S_AXI_ACP_ARADDR, S_AXI_ACP_AWADDR, S_AXI_ACP_ARCACHE, S_AXI_ACP_ARLEN, S_AXI_ACP_ARQOS, S_AXI_ACP_AWCACHE, S_AXI_ACP_AWLEN, S_AXI_ACP_AWQOS, S_AXI_ACP_ARBURST, S_AXI_ACP_ARLOCK, S_AXI_ACP_ARSIZE, S_AXI_ACP_AWBURST, S_AXI_ACP_AWLOCK, S_AXI_ACP_AWSIZE, S_AXI_ACP_ARUSER, S_AXI_ACP_AWUSER, S_AXI_ACP_WDATA, S_AXI_ACP_WSTRB, S_AXI_HP0_ARREADY, S_AXI_HP0_AWREADY, S_AXI_HP0_BVALID, S_AXI_HP0_RLAST, S_AXI_HP0_RVALID, S_AXI_HP0_WREADY, S_AXI_HP0_BRESP, S_AXI_HP0_RRESP, S_AXI_HP0_BID, S_AXI_HP0_RID, S_AXI_HP0_RDATA, S_AXI_HP0_RCOUNT, S_AXI_HP0_WCOUNT, S_AXI_HP0_RACOUNT, S_AXI_HP0_WACOUNT, S_AXI_HP0_ACLK, S_AXI_HP0_ARVALID, S_AXI_HP0_AWVALID, S_AXI_HP0_BREADY, S_AXI_HP0_RDISSUECAP1_EN, S_AXI_HP0_RREADY, S_AXI_HP0_WLAST, S_AXI_HP0_WRISSUECAP1_EN, S_AXI_HP0_WVALID, S_AXI_HP0_ARBURST, S_AXI_HP0_ARLOCK, S_AXI_HP0_ARSIZE, S_AXI_HP0_AWBURST, S_AXI_HP0_AWLOCK, S_AXI_HP0_AWSIZE, S_AXI_HP0_ARPROT, S_AXI_HP0_AWPROT, S_AXI_HP0_ARADDR, S_AXI_HP0_AWADDR, S_AXI_HP0_ARCACHE, S_AXI_HP0_ARLEN, S_AXI_HP0_ARQOS, S_AXI_HP0_AWCACHE, S_AXI_HP0_AWLEN, S_AXI_HP0_AWQOS, S_AXI_HP0_ARID, S_AXI_HP0_AWID, S_AXI_HP0_WID, S_AXI_HP0_WDATA, S_AXI_HP0_WSTRB, S_AXI_HP1_ARREADY, S_AXI_HP1_AWREADY, S_AXI_HP1_BVALID, S_AXI_HP1_RLAST, S_AXI_HP1_RVALID, S_AXI_HP1_WREADY, S_AXI_HP1_BRESP, S_AXI_HP1_RRESP, S_AXI_HP1_BID, S_AXI_HP1_RID, S_AXI_HP1_RDATA, S_AXI_HP1_RCOUNT, S_AXI_HP1_WCOUNT, S_AXI_HP1_RACOUNT, S_AXI_HP1_WACOUNT, S_AXI_HP1_ACLK, S_AXI_HP1_ARVALID, S_AXI_HP1_AWVALID, S_AXI_HP1_BREADY, S_AXI_HP1_RDISSUECAP1_EN, S_AXI_HP1_RREADY, S_AXI_HP1_WLAST, S_AXI_HP1_WRISSUECAP1_EN, S_AXI_HP1_WVALID, S_AXI_HP1_ARBURST, S_AXI_HP1_ARLOCK, S_AXI_HP1_ARSIZE, S_AXI_HP1_AWBURST, S_AXI_HP1_AWLOCK, S_AXI_HP1_AWSIZE, S_AXI_HP1_ARPROT, S_AXI_HP1_AWPROT, S_AXI_HP1_ARADDR, S_AXI_HP1_AWADDR, S_AXI_HP1_ARCACHE, S_AXI_HP1_ARLEN, S_AXI_HP1_ARQOS, S_AXI_HP1_AWCACHE, S_AXI_HP1_AWLEN, S_AXI_HP1_AWQOS, S_AXI_HP1_ARID, S_AXI_HP1_AWID, S_AXI_HP1_WID, S_AXI_HP1_WDATA, S_AXI_HP1_WSTRB, S_AXI_HP2_ARREADY, S_AXI_HP2_AWREADY, S_AXI_HP2_BVALID, S_AXI_HP2_RLAST, S_AXI_HP2_RVALID, S_AXI_HP2_WREADY, S_AXI_HP2_BRESP, S_AXI_HP2_RRESP, S_AXI_HP2_BID, S_AXI_HP2_RID, S_AXI_HP2_RDATA, S_AXI_HP2_RCOUNT, S_AXI_HP2_WCOUNT, S_AXI_HP2_RACOUNT, S_AXI_HP2_WACOUNT, S_AXI_HP2_ACLK, S_AXI_HP2_ARVALID, S_AXI_HP2_AWVALID, S_AXI_HP2_BREADY, S_AXI_HP2_RDISSUECAP1_EN, S_AXI_HP2_RREADY, S_AXI_HP2_WLAST, S_AXI_HP2_WRISSUECAP1_EN, S_AXI_HP2_WVALID, S_AXI_HP2_ARBURST, S_AXI_HP2_ARLOCK, S_AXI_HP2_ARSIZE, S_AXI_HP2_AWBURST, S_AXI_HP2_AWLOCK, S_AXI_HP2_AWSIZE, S_AXI_HP2_ARPROT, S_AXI_HP2_AWPROT, S_AXI_HP2_ARADDR, S_AXI_HP2_AWADDR, S_AXI_HP2_ARCACHE, S_AXI_HP2_ARLEN, S_AXI_HP2_ARQOS, S_AXI_HP2_AWCACHE, S_AXI_HP2_AWLEN, S_AXI_HP2_AWQOS, S_AXI_HP2_ARID, S_AXI_HP2_AWID, S_AXI_HP2_WID, S_AXI_HP2_WDATA, S_AXI_HP2_WSTRB, S_AXI_HP3_ARREADY, S_AXI_HP3_AWREADY, S_AXI_HP3_BVALID, S_AXI_HP3_RLAST, S_AXI_HP3_RVALID, S_AXI_HP3_WREADY, S_AXI_HP3_BRESP, S_AXI_HP3_RRESP, S_AXI_HP3_BID, S_AXI_HP3_RID, S_AXI_HP3_RDATA, S_AXI_HP3_RCOUNT, S_AXI_HP3_WCOUNT, S_AXI_HP3_RACOUNT, S_AXI_HP3_WACOUNT, S_AXI_HP3_ACLK, S_AXI_HP3_ARVALID, S_AXI_HP3_AWVALID, S_AXI_HP3_BREADY, S_AXI_HP3_RDISSUECAP1_EN, S_AXI_HP3_RREADY, S_AXI_HP3_WLAST, S_AXI_HP3_WRISSUECAP1_EN, S_AXI_HP3_WVALID, S_AXI_HP3_ARBURST, S_AXI_HP3_ARLOCK, S_AXI_HP3_ARSIZE, S_AXI_HP3_AWBURST, S_AXI_HP3_AWLOCK, S_AXI_HP3_AWSIZE, S_AXI_HP3_ARPROT, S_AXI_HP3_AWPROT, S_AXI_HP3_ARADDR, S_AXI_HP3_AWADDR, S_AXI_HP3_ARCACHE, S_AXI_HP3_ARLEN, S_AXI_HP3_ARQOS, S_AXI_HP3_AWCACHE, S_AXI_HP3_AWLEN, S_AXI_HP3_AWQOS, S_AXI_HP3_ARID, S_AXI_HP3_AWID, S_AXI_HP3_WID, S_AXI_HP3_WDATA, S_AXI_HP3_WSTRB, DMA0_DATYPE, DMA0_DAVALID, DMA0_DRREADY, DMA0_ACLK, DMA0_DAREADY, DMA0_DRLAST, DMA0_DRVALID, DMA0_DRTYPE, DMA1_DATYPE, DMA1_DAVALID, DMA1_DRREADY, DMA1_ACLK, DMA1_DAREADY, DMA1_DRLAST, DMA1_DRVALID, DMA1_DRTYPE, DMA2_DATYPE, DMA2_DAVALID, DMA2_DRREADY, DMA2_ACLK, DMA2_DAREADY, DMA2_DRLAST, DMA2_DRVALID, DMA3_DRVALID, DMA3_DATYPE, DMA3_DAVALID, DMA3_DRREADY, DMA3_ACLK, DMA3_DAREADY, DMA3_DRLAST, DMA2_DRTYPE, DMA3_DRTYPE, FTMD_TRACEIN_DATA, FTMD_TRACEIN_VALID, FTMD_TRACEIN_CLK, FTMD_TRACEIN_ATID, FTMT_F2P_TRIG, FTMT_F2P_TRIGACK, FTMT_F2P_DEBUG, FTMT_P2F_TRIGACK, FTMT_P2F_TRIG, FTMT_P2F_DEBUG, FCLK_CLK3, FCLK_CLK2, FCLK_CLK1, FCLK_CLK0, FCLK_CLKTRIG3_N, FCLK_CLKTRIG2_N, FCLK_CLKTRIG1_N, FCLK_CLKTRIG0_N, FCLK_RESET3_N, FCLK_RESET2_N, FCLK_RESET1_N, FCLK_RESET0_N, FPGA_IDLE_N, DDR_ARB, IRQ_F2P, Core0_nFIQ, Core0_nIRQ, Core1_nFIQ, Core1_nIRQ, EVENT_EVENTO, EVENT_STANDBYWFE, EVENT_STANDBYWFI, EVENT_EVENTI, MIO, DDR_Clk, DDR_Clk_n, DDR_CKE, DDR_CS_n, DDR_RAS_n, DDR_CAS_n, DDR_WEB, DDR_BankAddr, DDR_Addr, DDR_ODT, DDR_DRSTB, DDR_DQ, DDR_DM, DDR_DQS, DDR_DQS_n, DDR_VRN, DDR_VRP, PS_SRSTB, PS_CLK, PS_PORB, IRQ_P2F_DMAC_ABORT, IRQ_P2F_DMAC0, IRQ_P2F_DMAC1, IRQ_P2F_DMAC2, IRQ_P2F_DMAC3, IRQ_P2F_DMAC4, IRQ_P2F_DMAC5, IRQ_P2F_DMAC6, IRQ_P2F_DMAC7, IRQ_P2F_SMC, IRQ_P2F_QSPI, IRQ_P2F_CTI, IRQ_P2F_GPIO, IRQ_P2F_USB0, IRQ_P2F_ENET0, IRQ_P2F_ENET_WAKE0, IRQ_P2F_SDIO0, IRQ_P2F_I2C0, IRQ_P2F_SPI0, IRQ_P2F_UART0, IRQ_P2F_CAN0, IRQ_P2F_USB1, IRQ_P2F_ENET1, IRQ_P2F_ENET_WAKE1, IRQ_P2F_SDIO1, IRQ_P2F_I2C1, IRQ_P2F_SPI1, IRQ_P2F_UART1, IRQ_P2F_CAN1 ); /* parameters for gen_clk / parameter C_FCLK_CLK0_FREQ = 50; parameter C_FCLK_CLK1_FREQ = 50; parameter C_FCLK_CLK3_FREQ = 50; parameter C_FCLK_CLK2_FREQ = 50; parameter C_HIGH_OCM_EN = 0; / parameters for HP ports / parameter C_USE_S_AXI_HP0 = 0; parameter C_USE_S_AXI_HP1 = 0; parameter C_USE_S_AXI_HP2 = 0; parameter C_USE_S_AXI_HP3 = 0; parameter C_S_AXI_HP0_DATA_WIDTH = 32; parameter C_S_AXI_HP1_DATA_WIDTH = 32; parameter C_S_AXI_HP2_DATA_WIDTH = 32; parameter C_S_AXI_HP3_DATA_WIDTH = 32; parameter C_M_AXI_GP0_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP1_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP0_ENABLE_STATIC_REMAP = 0; parameter C_M_AXI_GP1_ENABLE_STATIC_REMAP = 0; / Do we need these parameter C_S_AXI_HP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP2_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP3_ENABLE_HIGHOCM = 0; / parameter C_S_AXI_HP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP2_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP3_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP2_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP3_HIGHADDR = 32'hFFFF_FFFF; / parameters for GP and ACP ports / parameter C_USE_M_AXI_GP0 = 0; parameter C_USE_M_AXI_GP1 = 0; parameter C_USE_S_AXI_GP0 = 1; parameter C_USE_S_AXI_GP1 = 1; / Do we need this? parameter C_M_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_M_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_ACP_ENABLE_HIGHOCM = 0;/ parameter C_S_AXI_GP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_GP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_USE_S_AXI_ACP = 1; parameter C_S_AXI_ACP_BASEADDR = 32'h0000_0000; parameter C_S_AXI_ACP_HIGHADDR = 32'hFFFF_FFFF; `include "processing_system7_bfm_v2_0_5_local_params.v" output CAN0_PHY_TX; input CAN0_PHY_RX; output CAN1_PHY_TX; input CAN1_PHY_RX; output ENET0_GMII_TX_EN; output ENET0_GMII_TX_ER; output ENET0_MDIO_MDC; output ENET0_MDIO_O; output ENET0_MDIO_T; output ENET0_PTP_DELAY_REQ_RX; output ENET0_PTP_DELAY_REQ_TX; output ENET0_PTP_PDELAY_REQ_RX; output ENET0_PTP_PDELAY_REQ_TX; output ENET0_PTP_PDELAY_RESP_RX; output ENET0_PTP_PDELAY_RESP_TX; output ENET0_PTP_SYNC_FRAME_RX; output ENET0_PTP_SYNC_FRAME_TX; output ENET0_SOF_RX; output ENET0_SOF_TX; output [7:0] ENET0_GMII_TXD; input ENET0_GMII_COL; input ENET0_GMII_CRS; input ENET0_EXT_INTIN; input ENET0_GMII_RX_CLK; input ENET0_GMII_RX_DV; input ENET0_GMII_RX_ER; input ENET0_GMII_TX_CLK; input ENET0_MDIO_I; input [7:0] ENET0_GMII_RXD; output ENET1_GMII_TX_EN; output ENET1_GMII_TX_ER; output ENET1_MDIO_MDC; output ENET1_MDIO_O; output ENET1_MDIO_T; output ENET1_PTP_DELAY_REQ_RX; output ENET1_PTP_DELAY_REQ_TX; output ENET1_PTP_PDELAY_REQ_RX; output ENET1_PTP_PDELAY_REQ_TX; output ENET1_PTP_PDELAY_RESP_RX; output ENET1_PTP_PDELAY_RESP_TX; output ENET1_PTP_SYNC_FRAME_RX; output ENET1_PTP_SYNC_FRAME_TX; output ENET1_SOF_RX; output ENET1_SOF_TX; output [7:0] ENET1_GMII_TXD; input ENET1_GMII_COL; input ENET1_GMII_CRS; input ENET1_EXT_INTIN; input ENET1_GMII_RX_CLK; input ENET1_GMII_RX_DV; input ENET1_GMII_RX_ER; input ENET1_GMII_TX_CLK; input ENET1_MDIO_I; input [7:0] ENET1_GMII_RXD; input [63:0] GPIO_I; output [63:0] GPIO_O; output [63:0] GPIO_T; input I2C0_SDA_I; output I2C0_SDA_O; output I2C0_SDA_T; input I2C0_SCL_I; output I2C0_SCL_O; output I2C0_SCL_T; input I2C1_SDA_I; output I2C1_SDA_O; output I2C1_SDA_T; input I2C1_SCL_I; output I2C1_SCL_O; output I2C1_SCL_T; input PJTAG_TCK; input PJTAG_TMS; input PJTAG_TD_I; output PJTAG_TD_T; output PJTAG_TD_O; output SDIO0_CLK; input SDIO0_CLK_FB; output SDIO0_CMD_O; input SDIO0_CMD_I; output SDIO0_CMD_T; input [3:0] SDIO0_DATA_I; output [3:0] SDIO0_DATA_O; output [3:0] SDIO0_DATA_T; output SDIO0_LED; input SDIO0_CDN; input SDIO0_WP; output SDIO0_BUSPOW; output [2:0] SDIO0_BUSVOLT; output SDIO1_CLK; input SDIO1_CLK_FB; output SDIO1_CMD_O; input SDIO1_CMD_I; output SDIO1_CMD_T; input [3:0] SDIO1_DATA_I; output [3:0] SDIO1_DATA_O; output [3:0] SDIO1_DATA_T; output SDIO1_LED; input SDIO1_CDN; input SDIO1_WP; output SDIO1_BUSPOW; output [2:0] SDIO1_BUSVOLT; input SPI0_SCLK_I; output SPI0_SCLK_O; output SPI0_SCLK_T; input SPI0_MOSI_I; output SPI0_MOSI_O; output SPI0_MOSI_T; input SPI0_MISO_I; output SPI0_MISO_O; output SPI0_MISO_T; input SPI0_SS_I; output SPI0_SS_O; output SPI0_SS1_O; output SPI0_SS2_O; output SPI0_SS_T; input SPI1_SCLK_I; output SPI1_SCLK_O; output SPI1_SCLK_T; input SPI1_MOSI_I; output SPI1_MOSI_O; output SPI1_MOSI_T; input SPI1_MISO_I; output SPI1_MISO_O; output SPI1_MISO_T; input SPI1_SS_I; output SPI1_SS_O; output SPI1_SS1_O; output SPI1_SS2_O; output SPI1_SS_T; output UART0_DTRN; output UART0_RTSN; output UART0_TX; input UART0_CTSN; input UART0_DCDN; input UART0_DSRN; input UART0_RIN; input UART0_RX; output UART1_DTRN; output UART1_RTSN; output UART1_TX; input UART1_CTSN; input UART1_DCDN; input UART1_DSRN; input UART1_RIN; input UART1_RX; output TTC0_WAVE0_OUT; output TTC0_WAVE1_OUT; output TTC0_WAVE2_OUT; input TTC0_CLK0_IN; input TTC0_CLK1_IN; input TTC0_CLK2_IN; output TTC1_WAVE0_OUT; output TTC1_WAVE1_OUT; output TTC1_WAVE2_OUT; input TTC1_CLK0_IN; input TTC1_CLK1_IN; input TTC1_CLK2_IN; input WDT_CLK_IN; output WDT_RST_OUT; input TRACE_CLK; output TRACE_CTL; output [31:0] TRACE_DATA; output [1:0] USB0_PORT_INDCTL; output [1:0] USB1_PORT_INDCTL; output USB0_VBUS_PWRSELECT; output USB1_VBUS_PWRSELECT; input USB0_VBUS_PWRFAULT; input USB1_VBUS_PWRFAULT; input SRAM_INTIN; output M_AXI_GP0_ARVALID; output M_AXI_GP0_AWVALID; output M_AXI_GP0_BREADY; output M_AXI_GP0_RREADY; output M_AXI_GP0_WLAST; output M_AXI_GP0_WVALID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_ARID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_AWID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_WID; output [1:0] M_AXI_GP0_ARBURST; output [1:0] M_AXI_GP0_ARLOCK; output [2:0] M_AXI_GP0_ARSIZE; output [1:0] M_AXI_GP0_AWBURST; output [1:0] M_AXI_GP0_AWLOCK; output [2:0] M_AXI_GP0_AWSIZE; output [2:0] M_AXI_GP0_ARPROT; output [2:0] M_AXI_GP0_AWPROT; output [31:0] M_AXI_GP0_ARADDR; output [31:0] M_AXI_GP0_AWADDR; output [31:0] M_AXI_GP0_WDATA; output [3:0] M_AXI_GP0_ARCACHE; output [3:0] M_AXI_GP0_ARLEN; output [3:0] M_AXI_GP0_ARQOS; output [3:0] M_AXI_GP0_AWCACHE; output [3:0] M_AXI_GP0_AWLEN; output [3:0] M_AXI_GP0_AWQOS; output [3:0] M_AXI_GP0_WSTRB; input M_AXI_GP0_ACLK; input M_AXI_GP0_ARREADY; input M_AXI_GP0_AWREADY; input M_AXI_GP0_BVALID; input M_AXI_GP0_RLAST; input M_AXI_GP0_RVALID; input M_AXI_GP0_WREADY; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_BID; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_RID; input [1:0] M_AXI_GP0_BRESP; input [1:0] M_AXI_GP0_RRESP; input [31:0] M_AXI_GP0_RDATA; output M_AXI_GP1_ARVALID; output M_AXI_GP1_AWVALID; output M_AXI_GP1_BREADY; output M_AXI_GP1_RREADY; output M_AXI_GP1_WLAST; output M_AXI_GP1_WVALID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_ARID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_AWID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_WID; output [1:0] M_AXI_GP1_ARBURST; output [1:0] M_AXI_GP1_ARLOCK; output [2:0] M_AXI_GP1_ARSIZE; output [1:0] M_AXI_GP1_AWBURST; output [1:0] M_AXI_GP1_AWLOCK; output [2:0] M_AXI_GP1_AWSIZE; output [2:0] M_AXI_GP1_ARPROT; output [2:0] M_AXI_GP1_AWPROT; output [31:0] M_AXI_GP1_ARADDR; output [31:0] M_AXI_GP1_AWADDR; output [31:0] M_AXI_GP1_WDATA; output [3:0] M_AXI_GP1_ARCACHE; output [3:0] M_AXI_GP1_ARLEN; output [3:0] M_AXI_GP1_ARQOS; output [3:0] M_AXI_GP1_AWCACHE; output [3:0] M_AXI_GP1_AWLEN; output [3:0] M_AXI_GP1_AWQOS; output [3:0] M_AXI_GP1_WSTRB; input M_AXI_GP1_ACLK; input M_AXI_GP1_ARREADY; input M_AXI_GP1_AWREADY; input M_AXI_GP1_BVALID; input M_AXI_GP1_RLAST; input M_AXI_GP1_RVALID; input M_AXI_GP1_WREADY; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_BID; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_RID; input [1:0] M_AXI_GP1_BRESP; input [1:0] M_AXI_GP1_RRESP; input [31:0] M_AXI_GP1_RDATA; output S_AXI_GP0_ARREADY; output S_AXI_GP0_AWREADY; output S_AXI_GP0_BVALID; output S_AXI_GP0_RLAST; output S_AXI_GP0_RVALID; output S_AXI_GP0_WREADY; output [1:0] S_AXI_GP0_BRESP; output [1:0] S_AXI_GP0_RRESP; output [31:0] S_AXI_GP0_RDATA; output [5:0] S_AXI_GP0_BID; output [5:0] S_AXI_GP0_RID; input S_AXI_GP0_ACLK; input S_AXI_GP0_ARVALID; input S_AXI_GP0_AWVALID; input S_AXI_GP0_BREADY; input S_AXI_GP0_RREADY; input S_AXI_GP0_WLAST; input S_AXI_GP0_WVALID; input [1:0] S_AXI_GP0_ARBURST; input [1:0] S_AXI_GP0_ARLOCK; input [2:0] S_AXI_GP0_ARSIZE; input [1:0] S_AXI_GP0_AWBURST; input [1:0] S_AXI_GP0_AWLOCK; input [2:0] S_AXI_GP0_AWSIZE; input [2:0] S_AXI_GP0_ARPROT; input [2:0] S_AXI_GP0_AWPROT; input [31:0] S_AXI_GP0_ARADDR; input [31:0] S_AXI_GP0_AWADDR; input [31:0] S_AXI_GP0_WDATA; input [3:0] S_AXI_GP0_ARCACHE; input [3:0] S_AXI_GP0_ARLEN; input [3:0] S_AXI_GP0_ARQOS; input [3:0] S_AXI_GP0_AWCACHE; input [3:0] S_AXI_GP0_AWLEN; input [3:0] S_AXI_GP0_AWQOS; input [3:0] S_AXI_GP0_WSTRB; input [5:0] S_AXI_GP0_ARID; input [5:0] S_AXI_GP0_AWID; input [5:0] S_AXI_GP0_WID; output S_AXI_GP1_ARREADY; output S_AXI_GP1_AWREADY; output S_AXI_GP1_BVALID; output S_AXI_GP1_RLAST; output S_AXI_GP1_RVALID; output S_AXI_GP1_WREADY; output [1:0] S_AXI_GP1_BRESP; output [1:0] S_AXI_GP1_RRESP; output [31:0] S_AXI_GP1_RDATA; output [5:0] S_AXI_GP1_BID; output [5:0] S_AXI_GP1_RID; input S_AXI_GP1_ACLK; input S_AXI_GP1_ARVALID; input S_AXI_GP1_AWVALID; input S_AXI_GP1_BREADY; input S_AXI_GP1_RREADY; input S_AXI_GP1_WLAST; input S_AXI_GP1_WVALID; input [1:0] S_AXI_GP1_ARBURST; input [1:0] S_AXI_GP1_ARLOCK; input [2:0] S_AXI_GP1_ARSIZE; input [1:0] S_AXI_GP1_AWBURST; input [1:0] S_AXI_GP1_AWLOCK; input [2:0] S_AXI_GP1_AWSIZE; input [2:0] S_AXI_GP1_ARPROT; input [2:0] S_AXI_GP1_AWPROT; input [31:0] S_AXI_GP1_ARADDR; input [31:0] S_AXI_GP1_AWADDR; input [31:0] S_AXI_GP1_WDATA; input [3:0] S_AXI_GP1_ARCACHE; input [3:0] S_AXI_GP1_ARLEN; input [3:0] S_AXI_GP1_ARQOS; input [3:0] S_AXI_GP1_AWCACHE; input [3:0] S_AXI_GP1_AWLEN; input [3:0] S_AXI_GP1_AWQOS; input [3:0] S_AXI_GP1_WSTRB; input [5:0] S_AXI_GP1_ARID; input [5:0] S_AXI_GP1_AWID; input [5:0] S_AXI_GP1_WID; output S_AXI_ACP_AWREADY; output S_AXI_ACP_ARREADY; output S_AXI_ACP_BVALID; output S_AXI_ACP_RLAST; output S_AXI_ACP_RVALID; output S_AXI_ACP_WREADY; output [1:0] S_AXI_ACP_BRESP; output [1:0] S_AXI_ACP_RRESP; output [2:0] S_AXI_ACP_BID; output [2:0] S_AXI_ACP_RID; output [63:0] S_AXI_ACP_RDATA; input S_AXI_ACP_ACLK; input S_AXI_ACP_ARVALID; input S_AXI_ACP_AWVALID; input S_AXI_ACP_BREADY; input S_AXI_ACP_RREADY; input S_AXI_ACP_WLAST; input S_AXI_ACP_WVALID; input [2:0] S_AXI_ACP_ARID; input [2:0] S_AXI_ACP_ARPROT; input [2:0] S_AXI_ACP_AWID; input [2:0] S_AXI_ACP_AWPROT; input [2:0] S_AXI_ACP_WID; input [31:0] S_AXI_ACP_ARADDR; input [31:0] S_AXI_ACP_AWADDR; input [3:0] S_AXI_ACP_ARCACHE; input [3:0] S_AXI_ACP_ARLEN; input [3:0] S_AXI_ACP_ARQOS; input [3:0] S_AXI_ACP_AWCACHE; input [3:0] S_AXI_ACP_AWLEN; input [3:0] S_AXI_ACP_AWQOS; input [1:0] S_AXI_ACP_ARBURST; input [1:0] S_AXI_ACP_ARLOCK; input [2:0] S_AXI_ACP_ARSIZE; input [1:0] S_AXI_ACP_AWBURST; input [1:0] S_AXI_ACP_AWLOCK; input [2:0] S_AXI_ACP_AWSIZE; input [4:0] S_AXI_ACP_ARUSER; input [4:0] S_AXI_ACP_AWUSER; input [63:0] S_AXI_ACP_WDATA; input [7:0] S_AXI_ACP_WSTRB; output S_AXI_HP0_ARREADY; output S_AXI_HP0_AWREADY; output S_AXI_HP0_BVALID; output S_AXI_HP0_RLAST; output S_AXI_HP0_RVALID; output S_AXI_HP0_WREADY; output [1:0] S_AXI_HP0_BRESP; output [1:0] S_AXI_HP0_RRESP; output [5:0] S_AXI_HP0_BID; output [5:0] S_AXI_HP0_RID; output [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_RDATA; output [7:0] S_AXI_HP0_RCOUNT; output [7:0] S_AXI_HP0_WCOUNT; output [2:0] S_AXI_HP0_RACOUNT; output [5:0] S_AXI_HP0_WACOUNT; input S_AXI_HP0_ACLK; input S_AXI_HP0_ARVALID; input S_AXI_HP0_AWVALID; input S_AXI_HP0_BREADY; input S_AXI_HP0_RDISSUECAP1_EN; input S_AXI_HP0_RREADY; input S_AXI_HP0_WLAST; input S_AXI_HP0_WRISSUECAP1_EN; input S_AXI_HP0_WVALID; input [1:0] S_AXI_HP0_ARBURST; input [1:0] S_AXI_HP0_ARLOCK; input [2:0] S_AXI_HP0_ARSIZE; input [1:0] S_AXI_HP0_AWBURST; input [1:0] S_AXI_HP0_AWLOCK; input [2:0] S_AXI_HP0_AWSIZE; input [2:0] S_AXI_HP0_ARPROT; input [2:0] S_AXI_HP0_AWPROT; input [31:0] S_AXI_HP0_ARADDR; input [31:0] S_AXI_HP0_AWADDR; input [3:0] S_AXI_HP0_ARCACHE; input [3:0] S_AXI_HP0_ARLEN; input [3:0] S_AXI_HP0_ARQOS; input [3:0] S_AXI_HP0_AWCACHE; input [3:0] S_AXI_HP0_AWLEN; input [3:0] S_AXI_HP0_AWQOS; input [5:0] S_AXI_HP0_ARID; input [5:0] S_AXI_HP0_AWID; input [5:0] S_AXI_HP0_WID; input [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_WDATA; input [C_S_AXI_HP0_DATA_WIDTH/8-1:0] S_AXI_HP0_WSTRB; output S_AXI_HP1_ARREADY; output S_AXI_HP1_AWREADY; output S_AXI_HP1_BVALID; output S_AXI_HP1_RLAST; output S_AXI_HP1_RVALID; output S_AXI_HP1_WREADY; output [1:0] S_AXI_HP1_BRESP; output [1:0] S_AXI_HP1_RRESP; output [5:0] S_AXI_HP1_BID; output [5:0] S_AXI_HP1_RID; output [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_RDATA; output [7:0] S_AXI_HP1_RCOUNT; output [7:0] S_AXI_HP1_WCOUNT; output [2:0] S_AXI_HP1_RACOUNT; output [5:0] S_AXI_HP1_WACOUNT; input S_AXI_HP1_ACLK; input S_AXI_HP1_ARVALID; input S_AXI_HP1_AWVALID; input S_AXI_HP1_BREADY; input S_AXI_HP1_RDISSUECAP1_EN; input S_AXI_HP1_RREADY; input S_AXI_HP1_WLAST; input S_AXI_HP1_WRISSUECAP1_EN; input S_AXI_HP1_WVALID; input [1:0] S_AXI_HP1_ARBURST; input [1:0] S_AXI_HP1_ARLOCK; input [2:0] S_AXI_HP1_ARSIZE; input [1:0] S_AXI_HP1_AWBURST; input [1:0] S_AXI_HP1_AWLOCK; input [2:0] S_AXI_HP1_AWSIZE; input [2:0] S_AXI_HP1_ARPROT; input [2:0] S_AXI_HP1_AWPROT; input [31:0] S_AXI_HP1_ARADDR; input [31:0] S_AXI_HP1_AWADDR; input [3:0] S_AXI_HP1_ARCACHE; input [3:0] S_AXI_HP1_ARLEN; input [3:0] S_AXI_HP1_ARQOS; input [3:0] S_AXI_HP1_AWCACHE; input [3:0] S_AXI_HP1_AWLEN; input [3:0] S_AXI_HP1_AWQOS; input [5:0] S_AXI_HP1_ARID; input [5:0] S_AXI_HP1_AWID; input [5:0] S_AXI_HP1_WID; input [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_WDATA; input [C_S_AXI_HP1_DATA_WIDTH/8-1:0] S_AXI_HP1_WSTRB; output S_AXI_HP2_ARREADY; output S_AXI_HP2_AWREADY; output S_AXI_HP2_BVALID; output S_AXI_HP2_RLAST; output S_AXI_HP2_RVALID; output S_AXI_HP2_WREADY; output [1:0] S_AXI_HP2_BRESP; output [1:0] S_AXI_HP2_RRESP; output [5:0] S_AXI_HP2_BID; output [5:0] S_AXI_HP2_RID; output [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_RDATA; output [7:0] S_AXI_HP2_RCOUNT; output [7:0] S_AXI_HP2_WCOUNT; output [2:0] S_AXI_HP2_RACOUNT; output [5:0] S_AXI_HP2_WACOUNT; input S_AXI_HP2_ACLK; input S_AXI_HP2_ARVALID; input S_AXI_HP2_AWVALID; input S_AXI_HP2_BREADY; input S_AXI_HP2_RDISSUECAP1_EN; input S_AXI_HP2_RREADY; input S_AXI_HP2_WLAST; input S_AXI_HP2_WRISSUECAP1_EN; input S_AXI_HP2_WVALID; input [1:0] S_AXI_HP2_ARBURST; input [1:0] S_AXI_HP2_ARLOCK; input [2:0] S_AXI_HP2_ARSIZE; input [1:0] S_AXI_HP2_AWBURST; input [1:0] S_AXI_HP2_AWLOCK; input [2:0] S_AXI_HP2_AWSIZE; input [2:0] S_AXI_HP2_ARPROT; input [2:0] S_AXI_HP2_AWPROT; input [31:0] S_AXI_HP2_ARADDR; input [31:0] S_AXI_HP2_AWADDR; input [3:0] S_AXI_HP2_ARCACHE; input [3:0] S_AXI_HP2_ARLEN; input [3:0] S_AXI_HP2_ARQOS; input [3:0] S_AXI_HP2_AWCACHE; input [3:0] S_AXI_HP2_AWLEN; input [3:0] S_AXI_HP2_AWQOS; input [5:0] S_AXI_HP2_ARID; input [5:0] S_AXI_HP2_AWID; input [5:0] S_AXI_HP2_WID; input [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_WDATA; input [C_S_AXI_HP2_DATA_WIDTH/8-1:0] S_AXI_HP2_WSTRB; output S_AXI_HP3_ARREADY; output S_AXI_HP3_AWREADY; output S_AXI_HP3_BVALID; output S_AXI_HP3_RLAST; output S_AXI_HP3_RVALID; output S_AXI_HP3_WREADY; output [1:0] S_AXI_HP3_BRESP; output [1:0] S_AXI_HP3_RRESP; output [5:0] S_AXI_HP3_BID; output [5:0] S_AXI_HP3_RID; output [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_RDATA; output [7:0] S_AXI_HP3_RCOUNT; output [7:0] S_AXI_HP3_WCOUNT; output [2:0] S_AXI_HP3_RACOUNT; output [5:0] S_AXI_HP3_WACOUNT; input S_AXI_HP3_ACLK; input S_AXI_HP3_ARVALID; input S_AXI_HP3_AWVALID; input S_AXI_HP3_BREADY; input S_AXI_HP3_RDISSUECAP1_EN; input S_AXI_HP3_RREADY; input S_AXI_HP3_WLAST; input S_AXI_HP3_WRISSUECAP1_EN; input S_AXI_HP3_WVALID; input [1:0] S_AXI_HP3_ARBURST; input [1:0] S_AXI_HP3_ARLOCK; input [2:0] S_AXI_HP3_ARSIZE; input [1:0] S_AXI_HP3_AWBURST; input [1:0] S_AXI_HP3_AWLOCK; input [2:0] S_AXI_HP3_AWSIZE; input [2:0] S_AXI_HP3_ARPROT; input [2:0] S_AXI_HP3_AWPROT; input [31:0] S_AXI_HP3_ARADDR; input [31:0] S_AXI_HP3_AWADDR; input [3:0] S_AXI_HP3_ARCACHE; input [3:0] S_AXI_HP3_ARLEN; input [3:0] S_AXI_HP3_ARQOS; input [3:0] S_AXI_HP3_AWCACHE; input [3:0] S_AXI_HP3_AWLEN; input [3:0] S_AXI_HP3_AWQOS; input [5:0] S_AXI_HP3_ARID; input [5:0] S_AXI_HP3_AWID; input [5:0] S_AXI_HP3_WID; input [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_WDATA; input [C_S_AXI_HP3_DATA_WIDTH/8-1:0] S_AXI_HP3_WSTRB; output [1:0] DMA0_DATYPE; output DMA0_DAVALID; output DMA0_DRREADY; input DMA0_ACLK; input DMA0_DAREADY; input DMA0_DRLAST; input DMA0_DRVALID; input [1:0] DMA0_DRTYPE; output [1:0] DMA1_DATYPE; output DMA1_DAVALID; output DMA1_DRREADY; input DMA1_ACLK; input DMA1_DAREADY; input DMA1_DRLAST; input DMA1_DRVALID; input [1:0] DMA1_DRTYPE; output [1:0] DMA2_DATYPE; output DMA2_DAVALID; output DMA2_DRREADY; input DMA2_ACLK; input DMA2_DAREADY; input DMA2_DRLAST; input DMA2_DRVALID; input DMA3_DRVALID; output [1:0] DMA3_DATYPE; output DMA3_DAVALID; output DMA3_DRREADY; input DMA3_ACLK; input DMA3_DAREADY; input DMA3_DRLAST; input [1:0] DMA2_DRTYPE; input [1:0] DMA3_DRTYPE; input [31:0] FTMD_TRACEIN_DATA; input FTMD_TRACEIN_VALID; input FTMD_TRACEIN_CLK; input [3:0] FTMD_TRACEIN_ATID; input [3:0] FTMT_F2P_TRIG; output [3:0] FTMT_F2P_TRIGACK; input [31:0] FTMT_F2P_DEBUG; input [3:0] FTMT_P2F_TRIGACK; output [3:0] FTMT_P2F_TRIG; output [31:0] FTMT_P2F_DEBUG; output FCLK_CLK3; output FCLK_CLK2; output FCLK_CLK1; output FCLK_CLK0; input FCLK_CLKTRIG3_N; input FCLK_CLKTRIG2_N; input FCLK_CLKTRIG1_N; input FCLK_CLKTRIG0_N; output FCLK_RESET3_N; output FCLK_RESET2_N; output FCLK_RESET1_N; output FCLK_RESET0_N; input FPGA_IDLE_N; input [3:0] DDR_ARB; input [irq_width-1:0] IRQ_F2P; input Core0_nFIQ; input Core0_nIRQ; input Core1_nFIQ; input Core1_nIRQ; output EVENT_EVENTO; output [1:0] EVENT_STANDBYWFE; output [1:0] EVENT_STANDBYWFI; input EVENT_EVENTI; inout [53:0] MIO; inout DDR_Clk; inout DDR_Clk_n; inout DDR_CKE; inout DDR_CS_n; inout DDR_RAS_n; inout DDR_CAS_n; output DDR_WEB; inout [2:0] DDR_BankAddr; inout [14:0] DDR_Addr; inout DDR_ODT; inout DDR_DRSTB; inout [31:0] DDR_DQ; inout [3:0] DDR_DM; inout [3:0] DDR_DQS; inout [3:0] DDR_DQS_n; inout DDR_VRN; inout DDR_VRP; / Reset Input & Clock Input / input PS_SRSTB; input PS_CLK; input PS_PORB; output IRQ_P2F_DMAC_ABORT; output IRQ_P2F_DMAC0; output IRQ_P2F_DMAC1; output IRQ_P2F_DMAC2; output IRQ_P2F_DMAC3; output IRQ_P2F_DMAC4; output IRQ_P2F_DMAC5; output IRQ_P2F_DMAC6; output IRQ_P2F_DMAC7; output IRQ_P2F_SMC; output IRQ_P2F_QSPI; output IRQ_P2F_CTI; output IRQ_P2F_GPIO; output IRQ_P2F_USB0; output IRQ_P2F_ENET0; output IRQ_P2F_ENET_WAKE0; output IRQ_P2F_SDIO0; output IRQ_P2F_I2C0; output IRQ_P2F_SPI0; output IRQ_P2F_UART0; output IRQ_P2F_CAN0; output IRQ_P2F_USB1; output IRQ_P2F_ENET1; output IRQ_P2F_ENET_WAKE1; output IRQ_P2F_SDIO1; output IRQ_P2F_I2C1; output IRQ_P2F_SPI1; output IRQ_P2F_UART1; output IRQ_P2F_CAN1; / Internal wires/nets used for connectivity / wire net_rstn; wire net_sw_clk; wire net_ocm_clk; wire net_arbiter_clk; wire net_axi_mgp0_rstn; wire net_axi_mgp1_rstn; wire net_axi_gp0_rstn; wire net_axi_gp1_rstn; wire net_axi_hp0_rstn; wire net_axi_hp1_rstn; wire net_axi_hp2_rstn; wire net_axi_hp3_rstn; wire net_axi_acp_rstn; wire [4:0] net_axi_acp_awuser; wire [4:0] net_axi_acp_aruser; / Dummy / assign net_axi_acp_awuser = S_AXI_ACP_AWUSER; assign net_axi_acp_aruser = S_AXI_ACP_ARUSER; / Global variables / reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1; / local variable acting as semaphore for wait_mem_update and wait_reg_update task / reg mem_update_key = 1; reg reg_update_key_0 = 1; reg reg_update_key_1 = 1; / assignments and semantic checks for unused ports / `include "processing_system7_bfm_v2_0_5_unused_ports.v" / include api definition / `include "processing_system7_bfm_v2_0_5_apis.v" / Reset Generator / processing_system7_bfm_v2_0_5_gen_reset gen_rst(.por_rst_n(PS_PORB), .sys_rst_n(PS_SRSTB), .rst_out_n(net_rstn), .m_axi_gp0_clk(M_AXI_GP0_ACLK), .m_axi_gp1_clk(M_AXI_GP1_ACLK), .s_axi_gp0_clk(S_AXI_GP0_ACLK), .s_axi_gp1_clk(S_AXI_GP1_ACLK), .s_axi_hp0_clk(S_AXI_HP0_ACLK), .s_axi_hp1_clk(S_AXI_HP1_ACLK), .s_axi_hp2_clk(S_AXI_HP2_ACLK), .s_axi_hp3_clk(S_AXI_HP3_ACLK), .s_axi_acp_clk(S_AXI_ACP_ACLK), .m_axi_gp0_rstn(net_axi_mgp0_rstn), .m_axi_gp1_rstn(net_axi_mgp1_rstn), .s_axi_gp0_rstn(net_axi_gp0_rstn), .s_axi_gp1_rstn(net_axi_gp1_rstn), .s_axi_hp0_rstn(net_axi_hp0_rstn), .s_axi_hp1_rstn(net_axi_hp1_rstn), .s_axi_hp2_rstn(net_axi_hp2_rstn), .s_axi_hp3_rstn(net_axi_hp3_rstn), .s_axi_acp_rstn(net_axi_acp_rstn), .fclk_reset3_n(FCLK_RESET3_N), .fclk_reset2_n(FCLK_RESET2_N), .fclk_reset1_n(FCLK_RESET1_N), .fclk_reset0_n(FCLK_RESET0_N), .fpga_acp_reset_n(), ////S_AXI_ACP_ARESETN), (These are removed from Zynq IP) .fpga_gp_m0_reset_n(), ////M_AXI_GP0_ARESETN), .fpga_gp_m1_reset_n(), ////M_AXI_GP1_ARESETN), .fpga_gp_s0_reset_n(), ////S_AXI_GP0_ARESETN), .fpga_gp_s1_reset_n(), ////S_AXI_GP1_ARESETN), .fpga_hp_s0_reset_n(), ////S_AXI_HP0_ARESETN), .fpga_hp_s1_reset_n(), ////S_AXI_HP1_ARESETN), .fpga_hp_s2_reset_n(), ////S_AXI_HP2_ARESETN), .fpga_hp_s3_reset_n() ////S_AXI_HP3_ARESETN) ); / Clock Generator / processing_system7_bfm_v2_0_5_gen_clock #(C_FCLK_CLK3_FREQ, C_FCLK_CLK2_FREQ, C_FCLK_CLK1_FREQ, C_FCLK_CLK0_FREQ) gen_clk(.ps_clk(PS_CLK), .sw_clk(net_sw_clk), .fclk_clk3(FCLK_CLK3), .fclk_clk2(FCLK_CLK2), .fclk_clk1(FCLK_CLK1), .fclk_clk0(FCLK_CLK0) ); wire net_wr_ack_ocm_gp0, net_wr_ack_ddr_gp0, net_wr_ack_ocm_gp1, net_wr_ack_ddr_gp1; wire net_wr_dv_ocm_gp0, net_wr_dv_ddr_gp0, net_wr_dv_ocm_gp1, net_wr_dv_ddr_gp1; wire [max_burst_bits-1:0] net_wr_data_gp0, net_wr_data_gp1; wire [addr_width-1:0] net_wr_addr_gp0, net_wr_addr_gp1; wire [max_burst_bytes_width:0] net_wr_bytes_gp0, net_wr_bytes_gp1; wire [axi_qos_width-1:0] net_wr_qos_gp0, net_wr_qos_gp1; wire net_rd_req_ddr_gp0, net_rd_req_ddr_gp1; wire net_rd_req_ocm_gp0, net_rd_req_ocm_gp1; wire net_rd_req_reg_gp0, net_rd_req_reg_gp1; wire [addr_width-1:0] net_rd_addr_gp0, net_rd_addr_gp1; wire [max_burst_bytes_width:0] net_rd_bytes_gp0, net_rd_bytes_gp1; wire [max_burst_bits-1:0] net_rd_data_ddr_gp0, net_rd_data_ddr_gp1; wire [max_burst_bits-1:0] net_rd_data_ocm_gp0, net_rd_data_ocm_gp1; wire [max_burst_bits-1:0] net_rd_data_reg_gp0, net_rd_data_reg_gp1; wire net_rd_dv_ddr_gp0, net_rd_dv_ddr_gp1; wire net_rd_dv_ocm_gp0, net_rd_dv_ocm_gp1; wire net_rd_dv_reg_gp0, net_rd_dv_reg_gp1; wire [axi_qos_width-1:0] net_rd_qos_gp0, net_rd_qos_gp1; wire net_wr_ack_ddr_hp0, net_wr_ack_ddr_hp1, net_wr_ack_ddr_hp2, net_wr_ack_ddr_hp3; wire net_wr_ack_ocm_hp0, net_wr_ack_ocm_hp1, net_wr_ack_ocm_hp2, net_wr_ack_ocm_hp3; wire net_wr_dv_ddr_hp0, net_wr_dv_ddr_hp1, net_wr_dv_ddr_hp2, net_wr_dv_ddr_hp3; wire net_wr_dv_ocm_hp0, net_wr_dv_ocm_hp1, net_wr_dv_ocm_hp2, net_wr_dv_ocm_hp3; wire [max_burst_bits-1:0] net_wr_data_hp0, net_wr_data_hp1, net_wr_data_hp2, net_wr_data_hp3; wire [addr_width-1:0] net_wr_addr_hp0, net_wr_addr_hp1, net_wr_addr_hp2, net_wr_addr_hp3; wire [max_burst_bytes_width:0] net_wr_bytes_hp0, net_wr_bytes_hp1, net_wr_bytes_hp2, net_wr_bytes_hp3; wire [axi_qos_width-1:0] net_wr_qos_hp0, net_wr_qos_hp1, net_wr_qos_hp2, net_wr_qos_hp3; wire net_rd_req_ddr_hp0, net_rd_req_ddr_hp1, net_rd_req_ddr_hp2, net_rd_req_ddr_hp3; wire net_rd_req_ocm_hp0, net_rd_req_ocm_hp1, net_rd_req_ocm_hp2, net_rd_req_ocm_hp3; wire [addr_width-1:0] net_rd_addr_hp0, net_rd_addr_hp1, net_rd_addr_hp2, net_rd_addr_hp3; wire [max_burst_bytes_width:0] net_rd_bytes_hp0, net_rd_bytes_hp1, net_rd_bytes_hp2, net_rd_bytes_hp3; wire [max_burst_bits-1:0] net_rd_data_ddr_hp0, net_rd_data_ddr_hp1, net_rd_data_ddr_hp2, net_rd_data_ddr_hp3; wire [max_burst_bits-1:0] net_rd_data_ocm_hp0, net_rd_data_ocm_hp1, net_rd_data_ocm_hp2, net_rd_data_ocm_hp3; wire net_rd_dv_ddr_hp0, net_rd_dv_ddr_hp1, net_rd_dv_ddr_hp2, net_rd_dv_ddr_hp3; wire net_rd_dv_ocm_hp0, net_rd_dv_ocm_hp1, net_rd_dv_ocm_hp2, net_rd_dv_ocm_hp3; wire [axi_qos_width-1:0] net_rd_qos_hp0, net_rd_qos_hp1, net_rd_qos_hp2, net_rd_qos_hp3; wire net_wr_ack_ddr_acp,net_wr_ack_ocm_acp; wire net_wr_dv_ddr_acp,net_wr_dv_ocm_acp; wire [max_burst_bits-1:0] net_wr_data_acp; wire [addr_width-1:0] net_wr_addr_acp; wire [max_burst_bytes_width:0] net_wr_bytes_acp; wire [axi_qos_width-1:0] net_wr_qos_acp; wire net_rd_req_ddr_acp, net_rd_req_ocm_acp; wire [addr_width-1:0] net_rd_addr_acp; wire [max_burst_bytes_width:0] net_rd_bytes_acp; wire [max_burst_bits-1:0] net_rd_data_ddr_acp; wire [max_burst_bits-1:0] net_rd_data_ocm_acp; wire net_rd_dv_ddr_acp,net_rd_dv_ocm_acp; wire [axi_qos_width-1:0] net_rd_qos_acp; wire ocm_wr_ack_port0; wire ocm_wr_dv_port0; wire ocm_rd_req_port0; wire ocm_rd_dv_port0; wire [addr_width-1:0] ocm_wr_addr_port0; wire [max_burst_bits-1:0] ocm_wr_data_port0; wire [max_burst_bytes_width:0] ocm_wr_bytes_port0; wire [addr_width-1:0] ocm_rd_addr_port0; wire [max_burst_bits-1:0] ocm_rd_data_port0; wire [max_burst_bytes_width:0] ocm_rd_bytes_port0; wire [axi_qos_width-1:0] ocm_wr_qos_port0; wire [axi_qos_width-1:0] ocm_rd_qos_port0; wire ocm_wr_ack_port1; wire ocm_wr_dv_port1; wire ocm_rd_req_port1; wire ocm_rd_dv_port1; wire [addr_width-1:0] ocm_wr_addr_port1; wire [max_burst_bits-1:0] ocm_wr_data_port1; wire [max_burst_bytes_width:0] ocm_wr_bytes_port1; wire [addr_width-1:0] ocm_rd_addr_port1; wire [max_burst_bits-1:0] ocm_rd_data_port1; wire [max_burst_bytes_width:0] ocm_rd_bytes_port1; wire [axi_qos_width-1:0] ocm_wr_qos_port1; wire [axi_qos_width-1:0] ocm_rd_qos_port1; wire ddr_wr_ack_port0; wire ddr_wr_dv_port0; wire ddr_rd_req_port0; wire ddr_rd_dv_port0; wire[addr_width-1:0] ddr_wr_addr_port0; wire[max_burst_bits-1:0] ddr_wr_data_port0; wire[max_burst_bytes_width:0] ddr_wr_bytes_port0; wire[addr_width-1:0] ddr_rd_addr_port0; wire[max_burst_bits-1:0] ddr_rd_data_port0; wire[max_burst_bytes_width:0] ddr_rd_bytes_port0; wire [axi_qos_width-1:0] ddr_wr_qos_port0; wire [axi_qos_width-1:0] ddr_rd_qos_port0; wire ddr_wr_ack_port1; wire ddr_wr_dv_port1; wire ddr_rd_req_port1; wire ddr_rd_dv_port1; wire[addr_width-1:0] ddr_wr_addr_port1; wire[max_burst_bits-1:0] ddr_wr_data_port1; wire[max_burst_bytes_width:0] ddr_wr_bytes_port1; wire[addr_width-1:0] ddr_rd_addr_port1; wire[max_burst_bits-1:0] ddr_rd_data_port1; wire[max_burst_bytes_width:0] ddr_rd_bytes_port1; wire[axi_qos_width-1:0] ddr_wr_qos_port1; wire[axi_qos_width-1:0] ddr_rd_qos_port1; wire ddr_wr_ack_port2; wire ddr_wr_dv_port2; wire ddr_rd_req_port2; wire ddr_rd_dv_port2; wire[addr_width-1:0] ddr_wr_addr_port2; wire[max_burst_bits-1:0] ddr_wr_data_port2; wire[max_burst_bytes_width:0] ddr_wr_bytes_port2; wire[addr_width-1:0] ddr_rd_addr_port2; wire[max_burst_bits-1:0] ddr_rd_data_port2; wire[max_burst_bytes_width:0] ddr_rd_bytes_port2; wire[axi_qos_width-1:0] ddr_wr_qos_port2; wire[axi_qos_width-1:0] ddr_rd_qos_port2; wire ddr_wr_ack_port3; wire ddr_wr_dv_port3; wire ddr_rd_req_port3; wire ddr_rd_dv_port3; wire[addr_width-1:0] ddr_wr_addr_port3; wire[max_burst_bits-1:0] ddr_wr_data_port3; wire[max_burst_bytes_width:0] ddr_wr_bytes_port3; wire[addr_width-1:0] ddr_rd_addr_port3; wire[max_burst_bits-1:0] ddr_rd_data_port3; wire[max_burst_bytes_width:0] ddr_rd_bytes_port3; wire[axi_qos_width-1:0] ddr_wr_qos_port3; wire[axi_qos_width-1:0] ddr_rd_qos_port3; wire reg_rd_req_port0; wire reg_rd_dv_port0; wire[addr_width-1:0] reg_rd_addr_port0; wire[max_burst_bits-1:0] reg_rd_data_port0; wire[max_burst_bytes_width:0] reg_rd_bytes_port0; wire [axi_qos_width-1:0] reg_rd_qos_port0; wire reg_rd_req_port1; wire reg_rd_dv_port1; wire[addr_width-1:0] reg_rd_addr_port1; wire[max_burst_bits-1:0] reg_rd_data_port1; wire[max_burst_bytes_width:0] reg_rd_bytes_port1; wire [axi_qos_width-1:0] reg_rd_qos_port1; wire [11:0] M_AXI_GP0_AWID_FULL; wire [11:0] M_AXI_GP0_WID_FULL; wire [11:0] M_AXI_GP0_ARID_FULL; wire [11:0] M_AXI_GP0_BID_FULL; wire [11:0] M_AXI_GP0_RID_FULL; wire [11:0] M_AXI_GP1_AWID_FULL; wire [11:0] M_AXI_GP1_WID_FULL; wire [11:0] M_AXI_GP1_ARID_FULL; wire [11:0] M_AXI_GP1_BID_FULL; wire [11:0] M_AXI_GP1_RID_FULL; function [5:0] compress_id; input [11:0] id; begin compress_id = id[5:0]; end endfunction function [11:0] uncompress_id; input [5:0] id; begin uncompress_id = {6'b110000, id[5:0]}; end endfunction assign M_AXI_GP0_AWID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_AWID_FULL) : M_AXI_GP0_AWID_FULL; assign M_AXI_GP0_WID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_WID_FULL) : M_AXI_GP0_WID_FULL; assign M_AXI_GP0_ARID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_ARID_FULL) : M_AXI_GP0_ARID_FULL; assign M_AXI_GP0_BID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_BID) : M_AXI_GP0_BID; assign M_AXI_GP0_RID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_RID) : M_AXI_GP0_RID; assign M_AXI_GP1_AWID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_AWID_FULL) : M_AXI_GP1_AWID_FULL; assign M_AXI_GP1_WID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_WID_FULL) : M_AXI_GP1_WID_FULL; assign M_AXI_GP1_ARID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_ARID_FULL) : M_AXI_GP1_ARID_FULL; assign M_AXI_GP1_BID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_BID) : M_AXI_GP1_BID; assign M_AXI_GP1_RID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_RID) : M_AXI_GP1_RID; processing_system7_bfm_v2_0_5_interconnect_model icm ( .rstn(net_rstn), .sw_clk(net_sw_clk), .w_qos_gp0(net_wr_qos_gp0), .w_qos_gp1(net_wr_qos_gp1), .w_qos_hp0(net_wr_qos_hp0), .w_qos_hp1(net_wr_qos_hp1), .w_qos_hp2(net_wr_qos_hp2), .w_qos_hp3(net_wr_qos_hp3), .r_qos_gp0(net_rd_qos_gp0), .r_qos_gp1(net_rd_qos_gp1), .r_qos_hp0(net_rd_qos_hp0), .r_qos_hp1(net_rd_qos_hp1), .r_qos_hp2(net_rd_qos_hp2), .r_qos_hp3(net_rd_qos_hp3), / GP Slave ports access / .wr_ack_ddr_gp0(net_wr_ack_ddr_gp0), .wr_ack_ocm_gp0(net_wr_ack_ocm_gp0), .wr_data_gp0(net_wr_data_gp0), .wr_addr_gp0(net_wr_addr_gp0), .wr_bytes_gp0(net_wr_bytes_gp0), .wr_dv_ddr_gp0(net_wr_dv_ddr_gp0), .wr_dv_ocm_gp0(net_wr_dv_ocm_gp0), .rd_req_ddr_gp0(net_rd_req_ddr_gp0), .rd_req_ocm_gp0(net_rd_req_ocm_gp0), .rd_req_reg_gp0(net_rd_req_reg_gp0), .rd_addr_gp0(net_rd_addr_gp0), .rd_bytes_gp0(net_rd_bytes_gp0), .rd_data_ddr_gp0(net_rd_data_ddr_gp0), .rd_data_ocm_gp0(net_rd_data_ocm_gp0), .rd_data_reg_gp0(net_rd_data_reg_gp0), .rd_dv_ddr_gp0(net_rd_dv_ddr_gp0), .rd_dv_ocm_gp0(net_rd_dv_ocm_gp0), .rd_dv_reg_gp0(net_rd_dv_reg_gp0), .wr_ack_ddr_gp1(net_wr_ack_ddr_gp1), .wr_ack_ocm_gp1(net_wr_ack_ocm_gp1), .wr_data_gp1(net_wr_data_gp1), .wr_addr_gp1(net_wr_addr_gp1), .wr_bytes_gp1(net_wr_bytes_gp1), .wr_dv_ddr_gp1(net_wr_dv_ddr_gp1), .wr_dv_ocm_gp1(net_wr_dv_ocm_gp1), .rd_req_ddr_gp1(net_rd_req_ddr_gp1), .rd_req_ocm_gp1(net_rd_req_ocm_gp1), .rd_req_reg_gp1(net_rd_req_reg_gp1), .rd_addr_gp1(net_rd_addr_gp1), .rd_bytes_gp1(net_rd_bytes_gp1), .rd_data_ddr_gp1(net_rd_data_ddr_gp1), .rd_data_ocm_gp1(net_rd_data_ocm_gp1), .rd_data_reg_gp1(net_rd_data_reg_gp1), .rd_dv_ddr_gp1(net_rd_dv_ddr_gp1), .rd_dv_ocm_gp1(net_rd_dv_ocm_gp1), .rd_dv_reg_gp1(net_rd_dv_reg_gp1), / HP Slave ports access / .wr_ack_ddr_hp0(net_wr_ack_ddr_hp0), .wr_ack_ocm_hp0(net_wr_ack_ocm_hp0), .wr_data_hp0(net_wr_data_hp0), .wr_addr_hp0(net_wr_addr_hp0), .wr_bytes_hp0(net_wr_bytes_hp0), .wr_dv_ddr_hp0(net_wr_dv_ddr_hp0), .wr_dv_ocm_hp0(net_wr_dv_ocm_hp0), .rd_req_ddr_hp0(net_rd_req_ddr_hp0), .rd_req_ocm_hp0(net_rd_req_ocm_hp0), .rd_addr_hp0(net_rd_addr_hp0), .rd_bytes_hp0(net_rd_bytes_hp0), .rd_data_ddr_hp0(net_rd_data_ddr_hp0), .rd_data_ocm_hp0(net_rd_data_ocm_hp0), .rd_dv_ddr_hp0(net_rd_dv_ddr_hp0), .rd_dv_ocm_hp0(net_rd_dv_ocm_hp0), .wr_ack_ddr_hp1(net_wr_ack_ddr_hp1), .wr_ack_ocm_hp1(net_wr_ack_ocm_hp1), .wr_data_hp1(net_wr_data_hp1), .wr_addr_hp1(net_wr_addr_hp1), .wr_bytes_hp1(net_wr_bytes_hp1), .wr_dv_ddr_hp1(net_wr_dv_ddr_hp1), .wr_dv_ocm_hp1(net_wr_dv_ocm_hp1), .rd_req_ddr_hp1(net_rd_req_ddr_hp1), .rd_req_ocm_hp1(net_rd_req_ocm_hp1), .rd_addr_hp1(net_rd_addr_hp1), .rd_bytes_hp1(net_rd_bytes_hp1), .rd_data_ddr_hp1(net_rd_data_ddr_hp1), .rd_data_ocm_hp1(net_rd_data_ocm_hp1), .rd_dv_ocm_hp1(net_rd_dv_ocm_hp1), .rd_dv_ddr_hp1(net_rd_dv_ddr_hp1), .wr_ack_ddr_hp2(net_wr_ack_ddr_hp2), .wr_ack_ocm_hp2(net_wr_ack_ocm_hp2), .wr_data_hp2(net_wr_data_hp2), .wr_addr_hp2(net_wr_addr_hp2), .wr_bytes_hp2(net_wr_bytes_hp2), .wr_dv_ocm_hp2(net_wr_dv_ocm_hp2), .wr_dv_ddr_hp2(net_wr_dv_ddr_hp2), .rd_req_ddr_hp2(net_rd_req_ddr_hp2), .rd_req_ocm_hp2(net_rd_req_ocm_hp2), .rd_addr_hp2(net_rd_addr_hp2), .rd_bytes_hp2(net_rd_bytes_hp2), .rd_data_ddr_hp2(net_rd_data_ddr_hp2), .rd_data_ocm_hp2(net_rd_data_ocm_hp2), .rd_dv_ddr_hp2(net_rd_dv_ddr_hp2), .rd_dv_ocm_hp2(net_rd_dv_ocm_hp2), .wr_ack_ocm_hp3(net_wr_ack_ocm_hp3), .wr_ack_ddr_hp3(net_wr_ack_ddr_hp3), .wr_data_hp3(net_wr_data_hp3), .wr_addr_hp3(net_wr_addr_hp3), .wr_bytes_hp3(net_wr_bytes_hp3), .wr_dv_ddr_hp3(net_wr_dv_ddr_hp3), .wr_dv_ocm_hp3(net_wr_dv_ocm_hp3), .rd_req_ddr_hp3(net_rd_req_ddr_hp3), .rd_req_ocm_hp3(net_rd_req_ocm_hp3), .rd_addr_hp3(net_rd_addr_hp3), .rd_bytes_hp3(net_rd_bytes_hp3), .rd_data_ddr_hp3(net_rd_data_ddr_hp3), .rd_data_ocm_hp3(net_rd_data_ocm_hp3), .rd_dv_ddr_hp3(net_rd_dv_ddr_hp3), .rd_dv_ocm_hp3(net_rd_dv_ocm_hp3), / Goes to port 1 of DDR / .ddr_wr_ack_port1(ddr_wr_ack_port1), .ddr_wr_dv_port1(ddr_wr_dv_port1), .ddr_rd_req_port1(ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1(ddr_wr_qos_port1), .ddr_rd_qos_port1(ddr_rd_qos_port1), / Goes to port2 of DDR / .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), / Goes to port3 of DDR / .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3), / Goes to port 0 of OCM / .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1), / Goes to port 0 of REG / .reg_rd_qos_port1 (reg_rd_qos_port1) , .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1) ); processing_system7_bfm_v2_0_5_ddrc ddrc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of DDR / .ddr_wr_ack_port0 (ddr_wr_ack_port0), .ddr_wr_dv_port0 (ddr_wr_dv_port0), .ddr_rd_req_port0 (ddr_rd_req_port0), .ddr_rd_dv_port0 (ddr_rd_dv_port0), .ddr_wr_addr_port0(net_wr_addr_acp), .ddr_wr_data_port0(net_wr_data_acp), .ddr_wr_bytes_port0(net_wr_bytes_acp), .ddr_rd_addr_port0(net_rd_addr_acp), .ddr_rd_bytes_port0(net_rd_bytes_acp), .ddr_rd_data_port0(ddr_rd_data_port0), .ddr_wr_qos_port0 (net_wr_qos_acp), .ddr_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of DDR / .ddr_wr_ack_port1 (ddr_wr_ack_port1), .ddr_wr_dv_port1 (ddr_wr_dv_port1), .ddr_rd_req_port1 (ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1 (ddr_wr_qos_port1), .ddr_rd_qos_port1 (ddr_rd_qos_port1), / Goes to port2 of DDR / .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), / Goes to port3 of DDR / .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3) ); processing_system7_bfm_v2_0_5_ocmc ocmc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of OCM / .ocm_wr_ack_port0 (ocm_wr_ack_port0), .ocm_wr_dv_port0 (ocm_wr_dv_port0), .ocm_rd_req_port0 (ocm_rd_req_port0), .ocm_rd_dv_port0 (ocm_rd_dv_port0), .ocm_wr_addr_port0(net_wr_addr_acp), .ocm_wr_data_port0(net_wr_data_acp), .ocm_wr_bytes_port0(net_wr_bytes_acp), .ocm_rd_addr_port0(net_rd_addr_acp), .ocm_rd_bytes_port0(net_rd_bytes_acp), .ocm_rd_data_port0(ocm_rd_data_port0), .ocm_wr_qos_port0 (net_wr_qos_acp), .ocm_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of OCM / .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1) ); processing_system7_bfm_v2_0_5_regc regc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of REG / .reg_rd_req_port0 (reg_rd_req_port0), .reg_rd_dv_port0 (reg_rd_dv_port0), .reg_rd_addr_port0(net_rd_addr_acp), .reg_rd_bytes_port0(net_rd_bytes_acp), .reg_rd_data_port0(reg_rd_data_port0), .reg_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of REG / .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1), .reg_rd_qos_port1(reg_rd_qos_port1) ); / include axi_gp port instantiations / `include "processing_system7_bfm_v2_0_5_axi_gp.v" / include axi_hp port instantiations / `include "processing_system7_bfm_v2_0_5_axi_hp.v" / include axi_acp port instantiations */ `include "processing_system7_bfm_v2_0_5_axi_acp.v" endmodule
module processing_system7_bfm_v2_0_5_processing_system7_bfm ( CAN0_PHY_TX, CAN0_PHY_RX, CAN1_PHY_TX, CAN1_PHY_RX, ENET0_GMII_TX_EN, ENET0_GMII_TX_ER, ENET0_MDIO_MDC, ENET0_MDIO_O, ENET0_MDIO_T, ENET0_PTP_DELAY_REQ_RX, ENET0_PTP_DELAY_REQ_TX, ENET0_PTP_PDELAY_REQ_RX, ENET0_PTP_PDELAY_REQ_TX, ENET0_PTP_PDELAY_RESP_RX, ENET0_PTP_PDELAY_RESP_TX, ENET0_PTP_SYNC_FRAME_RX, ENET0_PTP_SYNC_FRAME_TX, ENET0_SOF_RX, ENET0_SOF_TX, ENET0_GMII_TXD, ENET0_GMII_COL, ENET0_GMII_CRS, ENET0_EXT_INTIN, ENET0_GMII_RX_CLK, ENET0_GMII_RX_DV, ENET0_GMII_RX_ER, ENET0_GMII_TX_CLK, ENET0_MDIO_I, ENET0_GMII_RXD, ENET1_GMII_TX_EN, ENET1_GMII_TX_ER, ENET1_MDIO_MDC, ENET1_MDIO_O, ENET1_MDIO_T, ENET1_PTP_DELAY_REQ_RX, ENET1_PTP_DELAY_REQ_TX, ENET1_PTP_PDELAY_REQ_RX, ENET1_PTP_PDELAY_REQ_TX, ENET1_PTP_PDELAY_RESP_RX, ENET1_PTP_PDELAY_RESP_TX, ENET1_PTP_SYNC_FRAME_RX, ENET1_PTP_SYNC_FRAME_TX, ENET1_SOF_RX, ENET1_SOF_TX, ENET1_GMII_TXD, ENET1_GMII_COL, ENET1_GMII_CRS, ENET1_EXT_INTIN, ENET1_GMII_RX_CLK, ENET1_GMII_RX_DV, ENET1_GMII_RX_ER, ENET1_GMII_TX_CLK, ENET1_MDIO_I, ENET1_GMII_RXD, GPIO_I, GPIO_O, GPIO_T, I2C0_SDA_I, I2C0_SDA_O, I2C0_SDA_T, I2C0_SCL_I, I2C0_SCL_O, I2C0_SCL_T, I2C1_SDA_I, I2C1_SDA_O, I2C1_SDA_T, I2C1_SCL_I, I2C1_SCL_O, I2C1_SCL_T, PJTAG_TCK, PJTAG_TMS, PJTAG_TD_I, PJTAG_TD_T, PJTAG_TD_O, SDIO0_CLK, SDIO0_CLK_FB, SDIO0_CMD_O, SDIO0_CMD_I, SDIO0_CMD_T, SDIO0_DATA_I, SDIO0_DATA_O, SDIO0_DATA_T, SDIO0_LED, SDIO0_CDN, SDIO0_WP, SDIO0_BUSPOW, SDIO0_BUSVOLT, SDIO1_CLK, SDIO1_CLK_FB, SDIO1_CMD_O, SDIO1_CMD_I, SDIO1_CMD_T, SDIO1_DATA_I, SDIO1_DATA_O, SDIO1_DATA_T, SDIO1_LED, SDIO1_CDN, SDIO1_WP, SDIO1_BUSPOW, SDIO1_BUSVOLT, SPI0_SCLK_I, SPI0_SCLK_O, SPI0_SCLK_T, SPI0_MOSI_I, SPI0_MOSI_O, SPI0_MOSI_T, SPI0_MISO_I, SPI0_MISO_O, SPI0_MISO_T, SPI0_SS_I, SPI0_SS_O, SPI0_SS1_O, SPI0_SS2_O, SPI0_SS_T, SPI1_SCLK_I, SPI1_SCLK_O, SPI1_SCLK_T, SPI1_MOSI_I, SPI1_MOSI_O, SPI1_MOSI_T, SPI1_MISO_I, SPI1_MISO_O, SPI1_MISO_T, SPI1_SS_I, SPI1_SS_O, SPI1_SS1_O, SPI1_SS2_O, SPI1_SS_T, UART0_DTRN, UART0_RTSN, UART0_TX, UART0_CTSN, UART0_DCDN, UART0_DSRN, UART0_RIN, UART0_RX, UART1_DTRN, UART1_RTSN, UART1_TX, UART1_CTSN, UART1_DCDN, UART1_DSRN, UART1_RIN, UART1_RX, TTC0_WAVE0_OUT, TTC0_WAVE1_OUT, TTC0_WAVE2_OUT, TTC0_CLK0_IN, TTC0_CLK1_IN, TTC0_CLK2_IN, TTC1_WAVE0_OUT, TTC1_WAVE1_OUT, TTC1_WAVE2_OUT, TTC1_CLK0_IN, TTC1_CLK1_IN, TTC1_CLK2_IN, WDT_CLK_IN, WDT_RST_OUT, TRACE_CLK, TRACE_CTL, TRACE_DATA, USB0_PORT_INDCTL, USB1_PORT_INDCTL, USB0_VBUS_PWRSELECT, USB1_VBUS_PWRSELECT, USB0_VBUS_PWRFAULT, USB1_VBUS_PWRFAULT, SRAM_INTIN, M_AXI_GP0_ARVALID, M_AXI_GP0_AWVALID, M_AXI_GP0_BREADY, M_AXI_GP0_RREADY, M_AXI_GP0_WLAST, M_AXI_GP0_WVALID, M_AXI_GP0_ARID, M_AXI_GP0_AWID, M_AXI_GP0_WID, M_AXI_GP0_ARBURST, M_AXI_GP0_ARLOCK, M_AXI_GP0_ARSIZE, M_AXI_GP0_AWBURST, M_AXI_GP0_AWLOCK, M_AXI_GP0_AWSIZE, M_AXI_GP0_ARPROT, M_AXI_GP0_AWPROT, M_AXI_GP0_ARADDR, M_AXI_GP0_AWADDR, M_AXI_GP0_WDATA, M_AXI_GP0_ARCACHE, M_AXI_GP0_ARLEN, M_AXI_GP0_ARQOS, M_AXI_GP0_AWCACHE, M_AXI_GP0_AWLEN, M_AXI_GP0_AWQOS, M_AXI_GP0_WSTRB, M_AXI_GP0_ACLK, M_AXI_GP0_ARREADY, M_AXI_GP0_AWREADY, M_AXI_GP0_BVALID, M_AXI_GP0_RLAST, M_AXI_GP0_RVALID, M_AXI_GP0_WREADY, M_AXI_GP0_BID, M_AXI_GP0_RID, M_AXI_GP0_BRESP, M_AXI_GP0_RRESP, M_AXI_GP0_RDATA, M_AXI_GP1_ARVALID, M_AXI_GP1_AWVALID, M_AXI_GP1_BREADY, M_AXI_GP1_RREADY, M_AXI_GP1_WLAST, M_AXI_GP1_WVALID, M_AXI_GP1_ARID, M_AXI_GP1_AWID, M_AXI_GP1_WID, M_AXI_GP1_ARBURST, M_AXI_GP1_ARLOCK, M_AXI_GP1_ARSIZE, M_AXI_GP1_AWBURST, M_AXI_GP1_AWLOCK, M_AXI_GP1_AWSIZE, M_AXI_GP1_ARPROT, M_AXI_GP1_AWPROT, M_AXI_GP1_ARADDR, M_AXI_GP1_AWADDR, M_AXI_GP1_WDATA, M_AXI_GP1_ARCACHE, M_AXI_GP1_ARLEN, M_AXI_GP1_ARQOS, M_AXI_GP1_AWCACHE, M_AXI_GP1_AWLEN, M_AXI_GP1_AWQOS, M_AXI_GP1_WSTRB, M_AXI_GP1_ACLK, M_AXI_GP1_ARREADY, M_AXI_GP1_AWREADY, M_AXI_GP1_BVALID, M_AXI_GP1_RLAST, M_AXI_GP1_RVALID, M_AXI_GP1_WREADY, M_AXI_GP1_BID, M_AXI_GP1_RID, M_AXI_GP1_BRESP, M_AXI_GP1_RRESP, M_AXI_GP1_RDATA, S_AXI_GP0_ARREADY, S_AXI_GP0_AWREADY, S_AXI_GP0_BVALID, S_AXI_GP0_RLAST, S_AXI_GP0_RVALID, S_AXI_GP0_WREADY, S_AXI_GP0_BRESP, S_AXI_GP0_RRESP, S_AXI_GP0_RDATA, S_AXI_GP0_BID, S_AXI_GP0_RID, S_AXI_GP0_ACLK, S_AXI_GP0_ARVALID, S_AXI_GP0_AWVALID, S_AXI_GP0_BREADY, S_AXI_GP0_RREADY, S_AXI_GP0_WLAST, S_AXI_GP0_WVALID, S_AXI_GP0_ARBURST, S_AXI_GP0_ARLOCK, S_AXI_GP0_ARSIZE, S_AXI_GP0_AWBURST, S_AXI_GP0_AWLOCK, S_AXI_GP0_AWSIZE, S_AXI_GP0_ARPROT, S_AXI_GP0_AWPROT, S_AXI_GP0_ARADDR, S_AXI_GP0_AWADDR, S_AXI_GP0_WDATA, S_AXI_GP0_ARCACHE, S_AXI_GP0_ARLEN, S_AXI_GP0_ARQOS, S_AXI_GP0_AWCACHE, S_AXI_GP0_AWLEN, S_AXI_GP0_AWQOS, S_AXI_GP0_WSTRB, S_AXI_GP0_ARID, S_AXI_GP0_AWID, S_AXI_GP0_WID, S_AXI_GP1_ARREADY, S_AXI_GP1_AWREADY, S_AXI_GP1_BVALID, S_AXI_GP1_RLAST, S_AXI_GP1_RVALID, S_AXI_GP1_WREADY, S_AXI_GP1_BRESP, S_AXI_GP1_RRESP, S_AXI_GP1_RDATA, S_AXI_GP1_BID, S_AXI_GP1_RID, S_AXI_GP1_ACLK, S_AXI_GP1_ARVALID, S_AXI_GP1_AWVALID, S_AXI_GP1_BREADY, S_AXI_GP1_RREADY, S_AXI_GP1_WLAST, S_AXI_GP1_WVALID, S_AXI_GP1_ARBURST, S_AXI_GP1_ARLOCK, S_AXI_GP1_ARSIZE, S_AXI_GP1_AWBURST, S_AXI_GP1_AWLOCK, S_AXI_GP1_AWSIZE, S_AXI_GP1_ARPROT, S_AXI_GP1_AWPROT, S_AXI_GP1_ARADDR, S_AXI_GP1_AWADDR, S_AXI_GP1_WDATA, S_AXI_GP1_ARCACHE, S_AXI_GP1_ARLEN, S_AXI_GP1_ARQOS, S_AXI_GP1_AWCACHE, S_AXI_GP1_AWLEN, S_AXI_GP1_AWQOS, S_AXI_GP1_WSTRB, S_AXI_GP1_ARID, S_AXI_GP1_AWID, S_AXI_GP1_WID, S_AXI_ACP_AWREADY, S_AXI_ACP_ARREADY, S_AXI_ACP_BVALID, S_AXI_ACP_RLAST, S_AXI_ACP_RVALID, S_AXI_ACP_WREADY, S_AXI_ACP_BRESP, S_AXI_ACP_RRESP, S_AXI_ACP_BID, S_AXI_ACP_RID, S_AXI_ACP_RDATA, S_AXI_ACP_ACLK, S_AXI_ACP_ARVALID, S_AXI_ACP_AWVALID, S_AXI_ACP_BREADY, S_AXI_ACP_RREADY, S_AXI_ACP_WLAST, S_AXI_ACP_WVALID, S_AXI_ACP_ARID, S_AXI_ACP_ARPROT, S_AXI_ACP_AWID, S_AXI_ACP_AWPROT, S_AXI_ACP_WID, S_AXI_ACP_ARADDR, S_AXI_ACP_AWADDR, S_AXI_ACP_ARCACHE, S_AXI_ACP_ARLEN, S_AXI_ACP_ARQOS, S_AXI_ACP_AWCACHE, S_AXI_ACP_AWLEN, S_AXI_ACP_AWQOS, S_AXI_ACP_ARBURST, S_AXI_ACP_ARLOCK, S_AXI_ACP_ARSIZE, S_AXI_ACP_AWBURST, S_AXI_ACP_AWLOCK, S_AXI_ACP_AWSIZE, S_AXI_ACP_ARUSER, S_AXI_ACP_AWUSER, S_AXI_ACP_WDATA, S_AXI_ACP_WSTRB, S_AXI_HP0_ARREADY, S_AXI_HP0_AWREADY, S_AXI_HP0_BVALID, S_AXI_HP0_RLAST, S_AXI_HP0_RVALID, S_AXI_HP0_WREADY, S_AXI_HP0_BRESP, S_AXI_HP0_RRESP, S_AXI_HP0_BID, S_AXI_HP0_RID, S_AXI_HP0_RDATA, S_AXI_HP0_RCOUNT, S_AXI_HP0_WCOUNT, S_AXI_HP0_RACOUNT, S_AXI_HP0_WACOUNT, S_AXI_HP0_ACLK, S_AXI_HP0_ARVALID, S_AXI_HP0_AWVALID, S_AXI_HP0_BREADY, S_AXI_HP0_RDISSUECAP1_EN, S_AXI_HP0_RREADY, S_AXI_HP0_WLAST, S_AXI_HP0_WRISSUECAP1_EN, S_AXI_HP0_WVALID, S_AXI_HP0_ARBURST, S_AXI_HP0_ARLOCK, S_AXI_HP0_ARSIZE, S_AXI_HP0_AWBURST, S_AXI_HP0_AWLOCK, S_AXI_HP0_AWSIZE, S_AXI_HP0_ARPROT, S_AXI_HP0_AWPROT, S_AXI_HP0_ARADDR, S_AXI_HP0_AWADDR, S_AXI_HP0_ARCACHE, S_AXI_HP0_ARLEN, S_AXI_HP0_ARQOS, S_AXI_HP0_AWCACHE, S_AXI_HP0_AWLEN, S_AXI_HP0_AWQOS, S_AXI_HP0_ARID, S_AXI_HP0_AWID, S_AXI_HP0_WID, S_AXI_HP0_WDATA, S_AXI_HP0_WSTRB, S_AXI_HP1_ARREADY, S_AXI_HP1_AWREADY, S_AXI_HP1_BVALID, S_AXI_HP1_RLAST, S_AXI_HP1_RVALID, S_AXI_HP1_WREADY, S_AXI_HP1_BRESP, S_AXI_HP1_RRESP, S_AXI_HP1_BID, S_AXI_HP1_RID, S_AXI_HP1_RDATA, S_AXI_HP1_RCOUNT, S_AXI_HP1_WCOUNT, S_AXI_HP1_RACOUNT, S_AXI_HP1_WACOUNT, S_AXI_HP1_ACLK, S_AXI_HP1_ARVALID, S_AXI_HP1_AWVALID, S_AXI_HP1_BREADY, S_AXI_HP1_RDISSUECAP1_EN, S_AXI_HP1_RREADY, S_AXI_HP1_WLAST, S_AXI_HP1_WRISSUECAP1_EN, S_AXI_HP1_WVALID, S_AXI_HP1_ARBURST, S_AXI_HP1_ARLOCK, S_AXI_HP1_ARSIZE, S_AXI_HP1_AWBURST, S_AXI_HP1_AWLOCK, S_AXI_HP1_AWSIZE, S_AXI_HP1_ARPROT, S_AXI_HP1_AWPROT, S_AXI_HP1_ARADDR, S_AXI_HP1_AWADDR, S_AXI_HP1_ARCACHE, S_AXI_HP1_ARLEN, S_AXI_HP1_ARQOS, S_AXI_HP1_AWCACHE, S_AXI_HP1_AWLEN, S_AXI_HP1_AWQOS, S_AXI_HP1_ARID, S_AXI_HP1_AWID, S_AXI_HP1_WID, S_AXI_HP1_WDATA, S_AXI_HP1_WSTRB, S_AXI_HP2_ARREADY, S_AXI_HP2_AWREADY, S_AXI_HP2_BVALID, S_AXI_HP2_RLAST, S_AXI_HP2_RVALID, S_AXI_HP2_WREADY, S_AXI_HP2_BRESP, S_AXI_HP2_RRESP, S_AXI_HP2_BID, S_AXI_HP2_RID, S_AXI_HP2_RDATA, S_AXI_HP2_RCOUNT, S_AXI_HP2_WCOUNT, S_AXI_HP2_RACOUNT, S_AXI_HP2_WACOUNT, S_AXI_HP2_ACLK, S_AXI_HP2_ARVALID, S_AXI_HP2_AWVALID, S_AXI_HP2_BREADY, S_AXI_HP2_RDISSUECAP1_EN, S_AXI_HP2_RREADY, S_AXI_HP2_WLAST, S_AXI_HP2_WRISSUECAP1_EN, S_AXI_HP2_WVALID, S_AXI_HP2_ARBURST, S_AXI_HP2_ARLOCK, S_AXI_HP2_ARSIZE, S_AXI_HP2_AWBURST, S_AXI_HP2_AWLOCK, S_AXI_HP2_AWSIZE, S_AXI_HP2_ARPROT, S_AXI_HP2_AWPROT, S_AXI_HP2_ARADDR, S_AXI_HP2_AWADDR, S_AXI_HP2_ARCACHE, S_AXI_HP2_ARLEN, S_AXI_HP2_ARQOS, S_AXI_HP2_AWCACHE, S_AXI_HP2_AWLEN, S_AXI_HP2_AWQOS, S_AXI_HP2_ARID, S_AXI_HP2_AWID, S_AXI_HP2_WID, S_AXI_HP2_WDATA, S_AXI_HP2_WSTRB, S_AXI_HP3_ARREADY, S_AXI_HP3_AWREADY, S_AXI_HP3_BVALID, S_AXI_HP3_RLAST, S_AXI_HP3_RVALID, S_AXI_HP3_WREADY, S_AXI_HP3_BRESP, S_AXI_HP3_RRESP, S_AXI_HP3_BID, S_AXI_HP3_RID, S_AXI_HP3_RDATA, S_AXI_HP3_RCOUNT, S_AXI_HP3_WCOUNT, S_AXI_HP3_RACOUNT, S_AXI_HP3_WACOUNT, S_AXI_HP3_ACLK, S_AXI_HP3_ARVALID, S_AXI_HP3_AWVALID, S_AXI_HP3_BREADY, S_AXI_HP3_RDISSUECAP1_EN, S_AXI_HP3_RREADY, S_AXI_HP3_WLAST, S_AXI_HP3_WRISSUECAP1_EN, S_AXI_HP3_WVALID, S_AXI_HP3_ARBURST, S_AXI_HP3_ARLOCK, S_AXI_HP3_ARSIZE, S_AXI_HP3_AWBURST, S_AXI_HP3_AWLOCK, S_AXI_HP3_AWSIZE, S_AXI_HP3_ARPROT, S_AXI_HP3_AWPROT, S_AXI_HP3_ARADDR, S_AXI_HP3_AWADDR, S_AXI_HP3_ARCACHE, S_AXI_HP3_ARLEN, S_AXI_HP3_ARQOS, S_AXI_HP3_AWCACHE, S_AXI_HP3_AWLEN, S_AXI_HP3_AWQOS, S_AXI_HP3_ARID, S_AXI_HP3_AWID, S_AXI_HP3_WID, S_AXI_HP3_WDATA, S_AXI_HP3_WSTRB, DMA0_DATYPE, DMA0_DAVALID, DMA0_DRREADY, DMA0_ACLK, DMA0_DAREADY, DMA0_DRLAST, DMA0_DRVALID, DMA0_DRTYPE, DMA1_DATYPE, DMA1_DAVALID, DMA1_DRREADY, DMA1_ACLK, DMA1_DAREADY, DMA1_DRLAST, DMA1_DRVALID, DMA1_DRTYPE, DMA2_DATYPE, DMA2_DAVALID, DMA2_DRREADY, DMA2_ACLK, DMA2_DAREADY, DMA2_DRLAST, DMA2_DRVALID, DMA3_DRVALID, DMA3_DATYPE, DMA3_DAVALID, DMA3_DRREADY, DMA3_ACLK, DMA3_DAREADY, DMA3_DRLAST, DMA2_DRTYPE, DMA3_DRTYPE, FTMD_TRACEIN_DATA, FTMD_TRACEIN_VALID, FTMD_TRACEIN_CLK, FTMD_TRACEIN_ATID, FTMT_F2P_TRIG, FTMT_F2P_TRIGACK, FTMT_F2P_DEBUG, FTMT_P2F_TRIGACK, FTMT_P2F_TRIG, FTMT_P2F_DEBUG, FCLK_CLK3, FCLK_CLK2, FCLK_CLK1, FCLK_CLK0, FCLK_CLKTRIG3_N, FCLK_CLKTRIG2_N, FCLK_CLKTRIG1_N, FCLK_CLKTRIG0_N, FCLK_RESET3_N, FCLK_RESET2_N, FCLK_RESET1_N, FCLK_RESET0_N, FPGA_IDLE_N, DDR_ARB, IRQ_F2P, Core0_nFIQ, Core0_nIRQ, Core1_nFIQ, Core1_nIRQ, EVENT_EVENTO, EVENT_STANDBYWFE, EVENT_STANDBYWFI, EVENT_EVENTI, MIO, DDR_Clk, DDR_Clk_n, DDR_CKE, DDR_CS_n, DDR_RAS_n, DDR_CAS_n, DDR_WEB, DDR_BankAddr, DDR_Addr, DDR_ODT, DDR_DRSTB, DDR_DQ, DDR_DM, DDR_DQS, DDR_DQS_n, DDR_VRN, DDR_VRP, PS_SRSTB, PS_CLK, PS_PORB, IRQ_P2F_DMAC_ABORT, IRQ_P2F_DMAC0, IRQ_P2F_DMAC1, IRQ_P2F_DMAC2, IRQ_P2F_DMAC3, IRQ_P2F_DMAC4, IRQ_P2F_DMAC5, IRQ_P2F_DMAC6, IRQ_P2F_DMAC7, IRQ_P2F_SMC, IRQ_P2F_QSPI, IRQ_P2F_CTI, IRQ_P2F_GPIO, IRQ_P2F_USB0, IRQ_P2F_ENET0, IRQ_P2F_ENET_WAKE0, IRQ_P2F_SDIO0, IRQ_P2F_I2C0, IRQ_P2F_SPI0, IRQ_P2F_UART0, IRQ_P2F_CAN0, IRQ_P2F_USB1, IRQ_P2F_ENET1, IRQ_P2F_ENET_WAKE1, IRQ_P2F_SDIO1, IRQ_P2F_I2C1, IRQ_P2F_SPI1, IRQ_P2F_UART1, IRQ_P2F_CAN1 ); /* parameters for gen_clk / parameter C_FCLK_CLK0_FREQ = 50; parameter C_FCLK_CLK1_FREQ = 50; parameter C_FCLK_CLK3_FREQ = 50; parameter C_FCLK_CLK2_FREQ = 50; parameter C_HIGH_OCM_EN = 0; / parameters for HP ports / parameter C_USE_S_AXI_HP0 = 0; parameter C_USE_S_AXI_HP1 = 0; parameter C_USE_S_AXI_HP2 = 0; parameter C_USE_S_AXI_HP3 = 0; parameter C_S_AXI_HP0_DATA_WIDTH = 32; parameter C_S_AXI_HP1_DATA_WIDTH = 32; parameter C_S_AXI_HP2_DATA_WIDTH = 32; parameter C_S_AXI_HP3_DATA_WIDTH = 32; parameter C_M_AXI_GP0_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP1_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP0_ENABLE_STATIC_REMAP = 0; parameter C_M_AXI_GP1_ENABLE_STATIC_REMAP = 0; / Do we need these parameter C_S_AXI_HP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP2_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP3_ENABLE_HIGHOCM = 0; / parameter C_S_AXI_HP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP2_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP3_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP2_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP3_HIGHADDR = 32'hFFFF_FFFF; / parameters for GP and ACP ports / parameter C_USE_M_AXI_GP0 = 0; parameter C_USE_M_AXI_GP1 = 0; parameter C_USE_S_AXI_GP0 = 1; parameter C_USE_S_AXI_GP1 = 1; / Do we need this? parameter C_M_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_M_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_ACP_ENABLE_HIGHOCM = 0;/ parameter C_S_AXI_GP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_GP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_USE_S_AXI_ACP = 1; parameter C_S_AXI_ACP_BASEADDR = 32'h0000_0000; parameter C_S_AXI_ACP_HIGHADDR = 32'hFFFF_FFFF; `include "processing_system7_bfm_v2_0_5_local_params.v" output CAN0_PHY_TX; input CAN0_PHY_RX; output CAN1_PHY_TX; input CAN1_PHY_RX; output ENET0_GMII_TX_EN; output ENET0_GMII_TX_ER; output ENET0_MDIO_MDC; output ENET0_MDIO_O; output ENET0_MDIO_T; output ENET0_PTP_DELAY_REQ_RX; output ENET0_PTP_DELAY_REQ_TX; output ENET0_PTP_PDELAY_REQ_RX; output ENET0_PTP_PDELAY_REQ_TX; output ENET0_PTP_PDELAY_RESP_RX; output ENET0_PTP_PDELAY_RESP_TX; output ENET0_PTP_SYNC_FRAME_RX; output ENET0_PTP_SYNC_FRAME_TX; output ENET0_SOF_RX; output ENET0_SOF_TX; output [7:0] ENET0_GMII_TXD; input ENET0_GMII_COL; input ENET0_GMII_CRS; input ENET0_EXT_INTIN; input ENET0_GMII_RX_CLK; input ENET0_GMII_RX_DV; input ENET0_GMII_RX_ER; input ENET0_GMII_TX_CLK; input ENET0_MDIO_I; input [7:0] ENET0_GMII_RXD; output ENET1_GMII_TX_EN; output ENET1_GMII_TX_ER; output ENET1_MDIO_MDC; output ENET1_MDIO_O; output ENET1_MDIO_T; output ENET1_PTP_DELAY_REQ_RX; output ENET1_PTP_DELAY_REQ_TX; output ENET1_PTP_PDELAY_REQ_RX; output ENET1_PTP_PDELAY_REQ_TX; output ENET1_PTP_PDELAY_RESP_RX; output ENET1_PTP_PDELAY_RESP_TX; output ENET1_PTP_SYNC_FRAME_RX; output ENET1_PTP_SYNC_FRAME_TX; output ENET1_SOF_RX; output ENET1_SOF_TX; output [7:0] ENET1_GMII_TXD; input ENET1_GMII_COL; input ENET1_GMII_CRS; input ENET1_EXT_INTIN; input ENET1_GMII_RX_CLK; input ENET1_GMII_RX_DV; input ENET1_GMII_RX_ER; input ENET1_GMII_TX_CLK; input ENET1_MDIO_I; input [7:0] ENET1_GMII_RXD; input [63:0] GPIO_I; output [63:0] GPIO_O; output [63:0] GPIO_T; input I2C0_SDA_I; output I2C0_SDA_O; output I2C0_SDA_T; input I2C0_SCL_I; output I2C0_SCL_O; output I2C0_SCL_T; input I2C1_SDA_I; output I2C1_SDA_O; output I2C1_SDA_T; input I2C1_SCL_I; output I2C1_SCL_O; output I2C1_SCL_T; input PJTAG_TCK; input PJTAG_TMS; input PJTAG_TD_I; output PJTAG_TD_T; output PJTAG_TD_O; output SDIO0_CLK; input SDIO0_CLK_FB; output SDIO0_CMD_O; input SDIO0_CMD_I; output SDIO0_CMD_T; input [3:0] SDIO0_DATA_I; output [3:0] SDIO0_DATA_O; output [3:0] SDIO0_DATA_T; output SDIO0_LED; input SDIO0_CDN; input SDIO0_WP; output SDIO0_BUSPOW; output [2:0] SDIO0_BUSVOLT; output SDIO1_CLK; input SDIO1_CLK_FB; output SDIO1_CMD_O; input SDIO1_CMD_I; output SDIO1_CMD_T; input [3:0] SDIO1_DATA_I; output [3:0] SDIO1_DATA_O; output [3:0] SDIO1_DATA_T; output SDIO1_LED; input SDIO1_CDN; input SDIO1_WP; output SDIO1_BUSPOW; output [2:0] SDIO1_BUSVOLT; input SPI0_SCLK_I; output SPI0_SCLK_O; output SPI0_SCLK_T; input SPI0_MOSI_I; output SPI0_MOSI_O; output SPI0_MOSI_T; input SPI0_MISO_I; output SPI0_MISO_O; output SPI0_MISO_T; input SPI0_SS_I; output SPI0_SS_O; output SPI0_SS1_O; output SPI0_SS2_O; output SPI0_SS_T; input SPI1_SCLK_I; output SPI1_SCLK_O; output SPI1_SCLK_T; input SPI1_MOSI_I; output SPI1_MOSI_O; output SPI1_MOSI_T; input SPI1_MISO_I; output SPI1_MISO_O; output SPI1_MISO_T; input SPI1_SS_I; output SPI1_SS_O; output SPI1_SS1_O; output SPI1_SS2_O; output SPI1_SS_T; output UART0_DTRN; output UART0_RTSN; output UART0_TX; input UART0_CTSN; input UART0_DCDN; input UART0_DSRN; input UART0_RIN; input UART0_RX; output UART1_DTRN; output UART1_RTSN; output UART1_TX; input UART1_CTSN; input UART1_DCDN; input UART1_DSRN; input UART1_RIN; input UART1_RX; output TTC0_WAVE0_OUT; output TTC0_WAVE1_OUT; output TTC0_WAVE2_OUT; input TTC0_CLK0_IN; input TTC0_CLK1_IN; input TTC0_CLK2_IN; output TTC1_WAVE0_OUT; output TTC1_WAVE1_OUT; output TTC1_WAVE2_OUT; input TTC1_CLK0_IN; input TTC1_CLK1_IN; input TTC1_CLK2_IN; input WDT_CLK_IN; output WDT_RST_OUT; input TRACE_CLK; output TRACE_CTL; output [31:0] TRACE_DATA; output [1:0] USB0_PORT_INDCTL; output [1:0] USB1_PORT_INDCTL; output USB0_VBUS_PWRSELECT; output USB1_VBUS_PWRSELECT; input USB0_VBUS_PWRFAULT; input USB1_VBUS_PWRFAULT; input SRAM_INTIN; output M_AXI_GP0_ARVALID; output M_AXI_GP0_AWVALID; output M_AXI_GP0_BREADY; output M_AXI_GP0_RREADY; output M_AXI_GP0_WLAST; output M_AXI_GP0_WVALID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_ARID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_AWID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_WID; output [1:0] M_AXI_GP0_ARBURST; output [1:0] M_AXI_GP0_ARLOCK; output [2:0] M_AXI_GP0_ARSIZE; output [1:0] M_AXI_GP0_AWBURST; output [1:0] M_AXI_GP0_AWLOCK; output [2:0] M_AXI_GP0_AWSIZE; output [2:0] M_AXI_GP0_ARPROT; output [2:0] M_AXI_GP0_AWPROT; output [31:0] M_AXI_GP0_ARADDR; output [31:0] M_AXI_GP0_AWADDR; output [31:0] M_AXI_GP0_WDATA; output [3:0] M_AXI_GP0_ARCACHE; output [3:0] M_AXI_GP0_ARLEN; output [3:0] M_AXI_GP0_ARQOS; output [3:0] M_AXI_GP0_AWCACHE; output [3:0] M_AXI_GP0_AWLEN; output [3:0] M_AXI_GP0_AWQOS; output [3:0] M_AXI_GP0_WSTRB; input M_AXI_GP0_ACLK; input M_AXI_GP0_ARREADY; input M_AXI_GP0_AWREADY; input M_AXI_GP0_BVALID; input M_AXI_GP0_RLAST; input M_AXI_GP0_RVALID; input M_AXI_GP0_WREADY; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_BID; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_RID; input [1:0] M_AXI_GP0_BRESP; input [1:0] M_AXI_GP0_RRESP; input [31:0] M_AXI_GP0_RDATA; output M_AXI_GP1_ARVALID; output M_AXI_GP1_AWVALID; output M_AXI_GP1_BREADY; output M_AXI_GP1_RREADY; output M_AXI_GP1_WLAST; output M_AXI_GP1_WVALID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_ARID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_AWID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_WID; output [1:0] M_AXI_GP1_ARBURST; output [1:0] M_AXI_GP1_ARLOCK; output [2:0] M_AXI_GP1_ARSIZE; output [1:0] M_AXI_GP1_AWBURST; output [1:0] M_AXI_GP1_AWLOCK; output [2:0] M_AXI_GP1_AWSIZE; output [2:0] M_AXI_GP1_ARPROT; output [2:0] M_AXI_GP1_AWPROT; output [31:0] M_AXI_GP1_ARADDR; output [31:0] M_AXI_GP1_AWADDR; output [31:0] M_AXI_GP1_WDATA; output [3:0] M_AXI_GP1_ARCACHE; output [3:0] M_AXI_GP1_ARLEN; output [3:0] M_AXI_GP1_ARQOS; output [3:0] M_AXI_GP1_AWCACHE; output [3:0] M_AXI_GP1_AWLEN; output [3:0] M_AXI_GP1_AWQOS; output [3:0] M_AXI_GP1_WSTRB; input M_AXI_GP1_ACLK; input M_AXI_GP1_ARREADY; input M_AXI_GP1_AWREADY; input M_AXI_GP1_BVALID; input M_AXI_GP1_RLAST; input M_AXI_GP1_RVALID; input M_AXI_GP1_WREADY; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_BID; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_RID; input [1:0] M_AXI_GP1_BRESP; input [1:0] M_AXI_GP1_RRESP; input [31:0] M_AXI_GP1_RDATA; output S_AXI_GP0_ARREADY; output S_AXI_GP0_AWREADY; output S_AXI_GP0_BVALID; output S_AXI_GP0_RLAST; output S_AXI_GP0_RVALID; output S_AXI_GP0_WREADY; output [1:0] S_AXI_GP0_BRESP; output [1:0] S_AXI_GP0_RRESP; output [31:0] S_AXI_GP0_RDATA; output [5:0] S_AXI_GP0_BID; output [5:0] S_AXI_GP0_RID; input S_AXI_GP0_ACLK; input S_AXI_GP0_ARVALID; input S_AXI_GP0_AWVALID; input S_AXI_GP0_BREADY; input S_AXI_GP0_RREADY; input S_AXI_GP0_WLAST; input S_AXI_GP0_WVALID; input [1:0] S_AXI_GP0_ARBURST; input [1:0] S_AXI_GP0_ARLOCK; input [2:0] S_AXI_GP0_ARSIZE; input [1:0] S_AXI_GP0_AWBURST; input [1:0] S_AXI_GP0_AWLOCK; input [2:0] S_AXI_GP0_AWSIZE; input [2:0] S_AXI_GP0_ARPROT; input [2:0] S_AXI_GP0_AWPROT; input [31:0] S_AXI_GP0_ARADDR; input [31:0] S_AXI_GP0_AWADDR; input [31:0] S_AXI_GP0_WDATA; input [3:0] S_AXI_GP0_ARCACHE; input [3:0] S_AXI_GP0_ARLEN; input [3:0] S_AXI_GP0_ARQOS; input [3:0] S_AXI_GP0_AWCACHE; input [3:0] S_AXI_GP0_AWLEN; input [3:0] S_AXI_GP0_AWQOS; input [3:0] S_AXI_GP0_WSTRB; input [5:0] S_AXI_GP0_ARID; input [5:0] S_AXI_GP0_AWID; input [5:0] S_AXI_GP0_WID; output S_AXI_GP1_ARREADY; output S_AXI_GP1_AWREADY; output S_AXI_GP1_BVALID; output S_AXI_GP1_RLAST; output S_AXI_GP1_RVALID; output S_AXI_GP1_WREADY; output [1:0] S_AXI_GP1_BRESP; output [1:0] S_AXI_GP1_RRESP; output [31:0] S_AXI_GP1_RDATA; output [5:0] S_AXI_GP1_BID; output [5:0] S_AXI_GP1_RID; input S_AXI_GP1_ACLK; input S_AXI_GP1_ARVALID; input S_AXI_GP1_AWVALID; input S_AXI_GP1_BREADY; input S_AXI_GP1_RREADY; input S_AXI_GP1_WLAST; input S_AXI_GP1_WVALID; input [1:0] S_AXI_GP1_ARBURST; input [1:0] S_AXI_GP1_ARLOCK; input [2:0] S_AXI_GP1_ARSIZE; input [1:0] S_AXI_GP1_AWBURST; input [1:0] S_AXI_GP1_AWLOCK; input [2:0] S_AXI_GP1_AWSIZE; input [2:0] S_AXI_GP1_ARPROT; input [2:0] S_AXI_GP1_AWPROT; input [31:0] S_AXI_GP1_ARADDR; input [31:0] S_AXI_GP1_AWADDR; input [31:0] S_AXI_GP1_WDATA; input [3:0] S_AXI_GP1_ARCACHE; input [3:0] S_AXI_GP1_ARLEN; input [3:0] S_AXI_GP1_ARQOS; input [3:0] S_AXI_GP1_AWCACHE; input [3:0] S_AXI_GP1_AWLEN; input [3:0] S_AXI_GP1_AWQOS; input [3:0] S_AXI_GP1_WSTRB; input [5:0] S_AXI_GP1_ARID; input [5:0] S_AXI_GP1_AWID; input [5:0] S_AXI_GP1_WID; output S_AXI_ACP_AWREADY; output S_AXI_ACP_ARREADY; output S_AXI_ACP_BVALID; output S_AXI_ACP_RLAST; output S_AXI_ACP_RVALID; output S_AXI_ACP_WREADY; output [1:0] S_AXI_ACP_BRESP; output [1:0] S_AXI_ACP_RRESP; output [2:0] S_AXI_ACP_BID; output [2:0] S_AXI_ACP_RID; output [63:0] S_AXI_ACP_RDATA; input S_AXI_ACP_ACLK; input S_AXI_ACP_ARVALID; input S_AXI_ACP_AWVALID; input S_AXI_ACP_BREADY; input S_AXI_ACP_RREADY; input S_AXI_ACP_WLAST; input S_AXI_ACP_WVALID; input [2:0] S_AXI_ACP_ARID; input [2:0] S_AXI_ACP_ARPROT; input [2:0] S_AXI_ACP_AWID; input [2:0] S_AXI_ACP_AWPROT; input [2:0] S_AXI_ACP_WID; input [31:0] S_AXI_ACP_ARADDR; input [31:0] S_AXI_ACP_AWADDR; input [3:0] S_AXI_ACP_ARCACHE; input [3:0] S_AXI_ACP_ARLEN; input [3:0] S_AXI_ACP_ARQOS; input [3:0] S_AXI_ACP_AWCACHE; input [3:0] S_AXI_ACP_AWLEN; input [3:0] S_AXI_ACP_AWQOS; input [1:0] S_AXI_ACP_ARBURST; input [1:0] S_AXI_ACP_ARLOCK; input [2:0] S_AXI_ACP_ARSIZE; input [1:0] S_AXI_ACP_AWBURST; input [1:0] S_AXI_ACP_AWLOCK; input [2:0] S_AXI_ACP_AWSIZE; input [4:0] S_AXI_ACP_ARUSER; input [4:0] S_AXI_ACP_AWUSER; input [63:0] S_AXI_ACP_WDATA; input [7:0] S_AXI_ACP_WSTRB; output S_AXI_HP0_ARREADY; output S_AXI_HP0_AWREADY; output S_AXI_HP0_BVALID; output S_AXI_HP0_RLAST; output S_AXI_HP0_RVALID; output S_AXI_HP0_WREADY; output [1:0] S_AXI_HP0_BRESP; output [1:0] S_AXI_HP0_RRESP; output [5:0] S_AXI_HP0_BID; output [5:0] S_AXI_HP0_RID; output [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_RDATA; output [7:0] S_AXI_HP0_RCOUNT; output [7:0] S_AXI_HP0_WCOUNT; output [2:0] S_AXI_HP0_RACOUNT; output [5:0] S_AXI_HP0_WACOUNT; input S_AXI_HP0_ACLK; input S_AXI_HP0_ARVALID; input S_AXI_HP0_AWVALID; input S_AXI_HP0_BREADY; input S_AXI_HP0_RDISSUECAP1_EN; input S_AXI_HP0_RREADY; input S_AXI_HP0_WLAST; input S_AXI_HP0_WRISSUECAP1_EN; input S_AXI_HP0_WVALID; input [1:0] S_AXI_HP0_ARBURST; input [1:0] S_AXI_HP0_ARLOCK; input [2:0] S_AXI_HP0_ARSIZE; input [1:0] S_AXI_HP0_AWBURST; input [1:0] S_AXI_HP0_AWLOCK; input [2:0] S_AXI_HP0_AWSIZE; input [2:0] S_AXI_HP0_ARPROT; input [2:0] S_AXI_HP0_AWPROT; input [31:0] S_AXI_HP0_ARADDR; input [31:0] S_AXI_HP0_AWADDR; input [3:0] S_AXI_HP0_ARCACHE; input [3:0] S_AXI_HP0_ARLEN; input [3:0] S_AXI_HP0_ARQOS; input [3:0] S_AXI_HP0_AWCACHE; input [3:0] S_AXI_HP0_AWLEN; input [3:0] S_AXI_HP0_AWQOS; input [5:0] S_AXI_HP0_ARID; input [5:0] S_AXI_HP0_AWID; input [5:0] S_AXI_HP0_WID; input [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_WDATA; input [C_S_AXI_HP0_DATA_WIDTH/8-1:0] S_AXI_HP0_WSTRB; output S_AXI_HP1_ARREADY; output S_AXI_HP1_AWREADY; output S_AXI_HP1_BVALID; output S_AXI_HP1_RLAST; output S_AXI_HP1_RVALID; output S_AXI_HP1_WREADY; output [1:0] S_AXI_HP1_BRESP; output [1:0] S_AXI_HP1_RRESP; output [5:0] S_AXI_HP1_BID; output [5:0] S_AXI_HP1_RID; output [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_RDATA; output [7:0] S_AXI_HP1_RCOUNT; output [7:0] S_AXI_HP1_WCOUNT; output [2:0] S_AXI_HP1_RACOUNT; output [5:0] S_AXI_HP1_WACOUNT; input S_AXI_HP1_ACLK; input S_AXI_HP1_ARVALID; input S_AXI_HP1_AWVALID; input S_AXI_HP1_BREADY; input S_AXI_HP1_RDISSUECAP1_EN; input S_AXI_HP1_RREADY; input S_AXI_HP1_WLAST; input S_AXI_HP1_WRISSUECAP1_EN; input S_AXI_HP1_WVALID; input [1:0] S_AXI_HP1_ARBURST; input [1:0] S_AXI_HP1_ARLOCK; input [2:0] S_AXI_HP1_ARSIZE; input [1:0] S_AXI_HP1_AWBURST; input [1:0] S_AXI_HP1_AWLOCK; input [2:0] S_AXI_HP1_AWSIZE; input [2:0] S_AXI_HP1_ARPROT; input [2:0] S_AXI_HP1_AWPROT; input [31:0] S_AXI_HP1_ARADDR; input [31:0] S_AXI_HP1_AWADDR; input [3:0] S_AXI_HP1_ARCACHE; input [3:0] S_AXI_HP1_ARLEN; input [3:0] S_AXI_HP1_ARQOS; input [3:0] S_AXI_HP1_AWCACHE; input [3:0] S_AXI_HP1_AWLEN; input [3:0] S_AXI_HP1_AWQOS; input [5:0] S_AXI_HP1_ARID; input [5:0] S_AXI_HP1_AWID; input [5:0] S_AXI_HP1_WID; input [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_WDATA; input [C_S_AXI_HP1_DATA_WIDTH/8-1:0] S_AXI_HP1_WSTRB; output S_AXI_HP2_ARREADY; output S_AXI_HP2_AWREADY; output S_AXI_HP2_BVALID; output S_AXI_HP2_RLAST; output S_AXI_HP2_RVALID; output S_AXI_HP2_WREADY; output [1:0] S_AXI_HP2_BRESP; output [1:0] S_AXI_HP2_RRESP; output [5:0] S_AXI_HP2_BID; output [5:0] S_AXI_HP2_RID; output [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_RDATA; output [7:0] S_AXI_HP2_RCOUNT; output [7:0] S_AXI_HP2_WCOUNT; output [2:0] S_AXI_HP2_RACOUNT; output [5:0] S_AXI_HP2_WACOUNT; input S_AXI_HP2_ACLK; input S_AXI_HP2_ARVALID; input S_AXI_HP2_AWVALID; input S_AXI_HP2_BREADY; input S_AXI_HP2_RDISSUECAP1_EN; input S_AXI_HP2_RREADY; input S_AXI_HP2_WLAST; input S_AXI_HP2_WRISSUECAP1_EN; input S_AXI_HP2_WVALID; input [1:0] S_AXI_HP2_ARBURST; input [1:0] S_AXI_HP2_ARLOCK; input [2:0] S_AXI_HP2_ARSIZE; input [1:0] S_AXI_HP2_AWBURST; input [1:0] S_AXI_HP2_AWLOCK; input [2:0] S_AXI_HP2_AWSIZE; input [2:0] S_AXI_HP2_ARPROT; input [2:0] S_AXI_HP2_AWPROT; input [31:0] S_AXI_HP2_ARADDR; input [31:0] S_AXI_HP2_AWADDR; input [3:0] S_AXI_HP2_ARCACHE; input [3:0] S_AXI_HP2_ARLEN; input [3:0] S_AXI_HP2_ARQOS; input [3:0] S_AXI_HP2_AWCACHE; input [3:0] S_AXI_HP2_AWLEN; input [3:0] S_AXI_HP2_AWQOS; input [5:0] S_AXI_HP2_ARID; input [5:0] S_AXI_HP2_AWID; input [5:0] S_AXI_HP2_WID; input [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_WDATA; input [C_S_AXI_HP2_DATA_WIDTH/8-1:0] S_AXI_HP2_WSTRB; output S_AXI_HP3_ARREADY; output S_AXI_HP3_AWREADY; output S_AXI_HP3_BVALID; output S_AXI_HP3_RLAST; output S_AXI_HP3_RVALID; output S_AXI_HP3_WREADY; output [1:0] S_AXI_HP3_BRESP; output [1:0] S_AXI_HP3_RRESP; output [5:0] S_AXI_HP3_BID; output [5:0] S_AXI_HP3_RID; output [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_RDATA; output [7:0] S_AXI_HP3_RCOUNT; output [7:0] S_AXI_HP3_WCOUNT; output [2:0] S_AXI_HP3_RACOUNT; output [5:0] S_AXI_HP3_WACOUNT; input S_AXI_HP3_ACLK; input S_AXI_HP3_ARVALID; input S_AXI_HP3_AWVALID; input S_AXI_HP3_BREADY; input S_AXI_HP3_RDISSUECAP1_EN; input S_AXI_HP3_RREADY; input S_AXI_HP3_WLAST; input S_AXI_HP3_WRISSUECAP1_EN; input S_AXI_HP3_WVALID; input [1:0] S_AXI_HP3_ARBURST; input [1:0] S_AXI_HP3_ARLOCK; input [2:0] S_AXI_HP3_ARSIZE; input [1:0] S_AXI_HP3_AWBURST; input [1:0] S_AXI_HP3_AWLOCK; input [2:0] S_AXI_HP3_AWSIZE; input [2:0] S_AXI_HP3_ARPROT; input [2:0] S_AXI_HP3_AWPROT; input [31:0] S_AXI_HP3_ARADDR; input [31:0] S_AXI_HP3_AWADDR; input [3:0] S_AXI_HP3_ARCACHE; input [3:0] S_AXI_HP3_ARLEN; input [3:0] S_AXI_HP3_ARQOS; input [3:0] S_AXI_HP3_AWCACHE; input [3:0] S_AXI_HP3_AWLEN; input [3:0] S_AXI_HP3_AWQOS; input [5:0] S_AXI_HP3_ARID; input [5:0] S_AXI_HP3_AWID; input [5:0] S_AXI_HP3_WID; input [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_WDATA; input [C_S_AXI_HP3_DATA_WIDTH/8-1:0] S_AXI_HP3_WSTRB; output [1:0] DMA0_DATYPE; output DMA0_DAVALID; output DMA0_DRREADY; input DMA0_ACLK; input DMA0_DAREADY; input DMA0_DRLAST; input DMA0_DRVALID; input [1:0] DMA0_DRTYPE; output [1:0] DMA1_DATYPE; output DMA1_DAVALID; output DMA1_DRREADY; input DMA1_ACLK; input DMA1_DAREADY; input DMA1_DRLAST; input DMA1_DRVALID; input [1:0] DMA1_DRTYPE; output [1:0] DMA2_DATYPE; output DMA2_DAVALID; output DMA2_DRREADY; input DMA2_ACLK; input DMA2_DAREADY; input DMA2_DRLAST; input DMA2_DRVALID; input DMA3_DRVALID; output [1:0] DMA3_DATYPE; output DMA3_DAVALID; output DMA3_DRREADY; input DMA3_ACLK; input DMA3_DAREADY; input DMA3_DRLAST; input [1:0] DMA2_DRTYPE; input [1:0] DMA3_DRTYPE; input [31:0] FTMD_TRACEIN_DATA; input FTMD_TRACEIN_VALID; input FTMD_TRACEIN_CLK; input [3:0] FTMD_TRACEIN_ATID; input [3:0] FTMT_F2P_TRIG; output [3:0] FTMT_F2P_TRIGACK; input [31:0] FTMT_F2P_DEBUG; input [3:0] FTMT_P2F_TRIGACK; output [3:0] FTMT_P2F_TRIG; output [31:0] FTMT_P2F_DEBUG; output FCLK_CLK3; output FCLK_CLK2; output FCLK_CLK1; output FCLK_CLK0; input FCLK_CLKTRIG3_N; input FCLK_CLKTRIG2_N; input FCLK_CLKTRIG1_N; input FCLK_CLKTRIG0_N; output FCLK_RESET3_N; output FCLK_RESET2_N; output FCLK_RESET1_N; output FCLK_RESET0_N; input FPGA_IDLE_N; input [3:0] DDR_ARB; input [irq_width-1:0] IRQ_F2P; input Core0_nFIQ; input Core0_nIRQ; input Core1_nFIQ; input Core1_nIRQ; output EVENT_EVENTO; output [1:0] EVENT_STANDBYWFE; output [1:0] EVENT_STANDBYWFI; input EVENT_EVENTI; inout [53:0] MIO; inout DDR_Clk; inout DDR_Clk_n; inout DDR_CKE; inout DDR_CS_n; inout DDR_RAS_n; inout DDR_CAS_n; output DDR_WEB; inout [2:0] DDR_BankAddr; inout [14:0] DDR_Addr; inout DDR_ODT; inout DDR_DRSTB; inout [31:0] DDR_DQ; inout [3:0] DDR_DM; inout [3:0] DDR_DQS; inout [3:0] DDR_DQS_n; inout DDR_VRN; inout DDR_VRP; / Reset Input & Clock Input / input PS_SRSTB; input PS_CLK; input PS_PORB; output IRQ_P2F_DMAC_ABORT; output IRQ_P2F_DMAC0; output IRQ_P2F_DMAC1; output IRQ_P2F_DMAC2; output IRQ_P2F_DMAC3; output IRQ_P2F_DMAC4; output IRQ_P2F_DMAC5; output IRQ_P2F_DMAC6; output IRQ_P2F_DMAC7; output IRQ_P2F_SMC; output IRQ_P2F_QSPI; output IRQ_P2F_CTI; output IRQ_P2F_GPIO; output IRQ_P2F_USB0; output IRQ_P2F_ENET0; output IRQ_P2F_ENET_WAKE0; output IRQ_P2F_SDIO0; output IRQ_P2F_I2C0; output IRQ_P2F_SPI0; output IRQ_P2F_UART0; output IRQ_P2F_CAN0; output IRQ_P2F_USB1; output IRQ_P2F_ENET1; output IRQ_P2F_ENET_WAKE1; output IRQ_P2F_SDIO1; output IRQ_P2F_I2C1; output IRQ_P2F_SPI1; output IRQ_P2F_UART1; output IRQ_P2F_CAN1; / Internal wires/nets used for connectivity / wire net_rstn; wire net_sw_clk; wire net_ocm_clk; wire net_arbiter_clk; wire net_axi_mgp0_rstn; wire net_axi_mgp1_rstn; wire net_axi_gp0_rstn; wire net_axi_gp1_rstn; wire net_axi_hp0_rstn; wire net_axi_hp1_rstn; wire net_axi_hp2_rstn; wire net_axi_hp3_rstn; wire net_axi_acp_rstn; wire [4:0] net_axi_acp_awuser; wire [4:0] net_axi_acp_aruser; / Dummy / assign net_axi_acp_awuser = S_AXI_ACP_AWUSER; assign net_axi_acp_aruser = S_AXI_ACP_ARUSER; / Global variables / reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1; / local variable acting as semaphore for wait_mem_update and wait_reg_update task / reg mem_update_key = 1; reg reg_update_key_0 = 1; reg reg_update_key_1 = 1; / assignments and semantic checks for unused ports / `include "processing_system7_bfm_v2_0_5_unused_ports.v" / include api definition / `include "processing_system7_bfm_v2_0_5_apis.v" / Reset Generator / processing_system7_bfm_v2_0_5_gen_reset gen_rst(.por_rst_n(PS_PORB), .sys_rst_n(PS_SRSTB), .rst_out_n(net_rstn), .m_axi_gp0_clk(M_AXI_GP0_ACLK), .m_axi_gp1_clk(M_AXI_GP1_ACLK), .s_axi_gp0_clk(S_AXI_GP0_ACLK), .s_axi_gp1_clk(S_AXI_GP1_ACLK), .s_axi_hp0_clk(S_AXI_HP0_ACLK), .s_axi_hp1_clk(S_AXI_HP1_ACLK), .s_axi_hp2_clk(S_AXI_HP2_ACLK), .s_axi_hp3_clk(S_AXI_HP3_ACLK), .s_axi_acp_clk(S_AXI_ACP_ACLK), .m_axi_gp0_rstn(net_axi_mgp0_rstn), .m_axi_gp1_rstn(net_axi_mgp1_rstn), .s_axi_gp0_rstn(net_axi_gp0_rstn), .s_axi_gp1_rstn(net_axi_gp1_rstn), .s_axi_hp0_rstn(net_axi_hp0_rstn), .s_axi_hp1_rstn(net_axi_hp1_rstn), .s_axi_hp2_rstn(net_axi_hp2_rstn), .s_axi_hp3_rstn(net_axi_hp3_rstn), .s_axi_acp_rstn(net_axi_acp_rstn), .fclk_reset3_n(FCLK_RESET3_N), .fclk_reset2_n(FCLK_RESET2_N), .fclk_reset1_n(FCLK_RESET1_N), .fclk_reset0_n(FCLK_RESET0_N), .fpga_acp_reset_n(), ////S_AXI_ACP_ARESETN), (These are removed from Zynq IP) .fpga_gp_m0_reset_n(), ////M_AXI_GP0_ARESETN), .fpga_gp_m1_reset_n(), ////M_AXI_GP1_ARESETN), .fpga_gp_s0_reset_n(), ////S_AXI_GP0_ARESETN), .fpga_gp_s1_reset_n(), ////S_AXI_GP1_ARESETN), .fpga_hp_s0_reset_n(), ////S_AXI_HP0_ARESETN), .fpga_hp_s1_reset_n(), ////S_AXI_HP1_ARESETN), .fpga_hp_s2_reset_n(), ////S_AXI_HP2_ARESETN), .fpga_hp_s3_reset_n() ////S_AXI_HP3_ARESETN) ); / Clock Generator / processing_system7_bfm_v2_0_5_gen_clock #(C_FCLK_CLK3_FREQ, C_FCLK_CLK2_FREQ, C_FCLK_CLK1_FREQ, C_FCLK_CLK0_FREQ) gen_clk(.ps_clk(PS_CLK), .sw_clk(net_sw_clk), .fclk_clk3(FCLK_CLK3), .fclk_clk2(FCLK_CLK2), .fclk_clk1(FCLK_CLK1), .fclk_clk0(FCLK_CLK0) ); wire net_wr_ack_ocm_gp0, net_wr_ack_ddr_gp0, net_wr_ack_ocm_gp1, net_wr_ack_ddr_gp1; wire net_wr_dv_ocm_gp0, net_wr_dv_ddr_gp0, net_wr_dv_ocm_gp1, net_wr_dv_ddr_gp1; wire [max_burst_bits-1:0] net_wr_data_gp0, net_wr_data_gp1; wire [addr_width-1:0] net_wr_addr_gp0, net_wr_addr_gp1; wire [max_burst_bytes_width:0] net_wr_bytes_gp0, net_wr_bytes_gp1; wire [axi_qos_width-1:0] net_wr_qos_gp0, net_wr_qos_gp1; wire net_rd_req_ddr_gp0, net_rd_req_ddr_gp1; wire net_rd_req_ocm_gp0, net_rd_req_ocm_gp1; wire net_rd_req_reg_gp0, net_rd_req_reg_gp1; wire [addr_width-1:0] net_rd_addr_gp0, net_rd_addr_gp1; wire [max_burst_bytes_width:0] net_rd_bytes_gp0, net_rd_bytes_gp1; wire [max_burst_bits-1:0] net_rd_data_ddr_gp0, net_rd_data_ddr_gp1; wire [max_burst_bits-1:0] net_rd_data_ocm_gp0, net_rd_data_ocm_gp1; wire [max_burst_bits-1:0] net_rd_data_reg_gp0, net_rd_data_reg_gp1; wire net_rd_dv_ddr_gp0, net_rd_dv_ddr_gp1; wire net_rd_dv_ocm_gp0, net_rd_dv_ocm_gp1; wire net_rd_dv_reg_gp0, net_rd_dv_reg_gp1; wire [axi_qos_width-1:0] net_rd_qos_gp0, net_rd_qos_gp1; wire net_wr_ack_ddr_hp0, net_wr_ack_ddr_hp1, net_wr_ack_ddr_hp2, net_wr_ack_ddr_hp3; wire net_wr_ack_ocm_hp0, net_wr_ack_ocm_hp1, net_wr_ack_ocm_hp2, net_wr_ack_ocm_hp3; wire net_wr_dv_ddr_hp0, net_wr_dv_ddr_hp1, net_wr_dv_ddr_hp2, net_wr_dv_ddr_hp3; wire net_wr_dv_ocm_hp0, net_wr_dv_ocm_hp1, net_wr_dv_ocm_hp2, net_wr_dv_ocm_hp3; wire [max_burst_bits-1:0] net_wr_data_hp0, net_wr_data_hp1, net_wr_data_hp2, net_wr_data_hp3; wire [addr_width-1:0] net_wr_addr_hp0, net_wr_addr_hp1, net_wr_addr_hp2, net_wr_addr_hp3; wire [max_burst_bytes_width:0] net_wr_bytes_hp0, net_wr_bytes_hp1, net_wr_bytes_hp2, net_wr_bytes_hp3; wire [axi_qos_width-1:0] net_wr_qos_hp0, net_wr_qos_hp1, net_wr_qos_hp2, net_wr_qos_hp3; wire net_rd_req_ddr_hp0, net_rd_req_ddr_hp1, net_rd_req_ddr_hp2, net_rd_req_ddr_hp3; wire net_rd_req_ocm_hp0, net_rd_req_ocm_hp1, net_rd_req_ocm_hp2, net_rd_req_ocm_hp3; wire [addr_width-1:0] net_rd_addr_hp0, net_rd_addr_hp1, net_rd_addr_hp2, net_rd_addr_hp3; wire [max_burst_bytes_width:0] net_rd_bytes_hp0, net_rd_bytes_hp1, net_rd_bytes_hp2, net_rd_bytes_hp3; wire [max_burst_bits-1:0] net_rd_data_ddr_hp0, net_rd_data_ddr_hp1, net_rd_data_ddr_hp2, net_rd_data_ddr_hp3; wire [max_burst_bits-1:0] net_rd_data_ocm_hp0, net_rd_data_ocm_hp1, net_rd_data_ocm_hp2, net_rd_data_ocm_hp3; wire net_rd_dv_ddr_hp0, net_rd_dv_ddr_hp1, net_rd_dv_ddr_hp2, net_rd_dv_ddr_hp3; wire net_rd_dv_ocm_hp0, net_rd_dv_ocm_hp1, net_rd_dv_ocm_hp2, net_rd_dv_ocm_hp3; wire [axi_qos_width-1:0] net_rd_qos_hp0, net_rd_qos_hp1, net_rd_qos_hp2, net_rd_qos_hp3; wire net_wr_ack_ddr_acp,net_wr_ack_ocm_acp; wire net_wr_dv_ddr_acp,net_wr_dv_ocm_acp; wire [max_burst_bits-1:0] net_wr_data_acp; wire [addr_width-1:0] net_wr_addr_acp; wire [max_burst_bytes_width:0] net_wr_bytes_acp; wire [axi_qos_width-1:0] net_wr_qos_acp; wire net_rd_req_ddr_acp, net_rd_req_ocm_acp; wire [addr_width-1:0] net_rd_addr_acp; wire [max_burst_bytes_width:0] net_rd_bytes_acp; wire [max_burst_bits-1:0] net_rd_data_ddr_acp; wire [max_burst_bits-1:0] net_rd_data_ocm_acp; wire net_rd_dv_ddr_acp,net_rd_dv_ocm_acp; wire [axi_qos_width-1:0] net_rd_qos_acp; wire ocm_wr_ack_port0; wire ocm_wr_dv_port0; wire ocm_rd_req_port0; wire ocm_rd_dv_port0; wire [addr_width-1:0] ocm_wr_addr_port0; wire [max_burst_bits-1:0] ocm_wr_data_port0; wire [max_burst_bytes_width:0] ocm_wr_bytes_port0; wire [addr_width-1:0] ocm_rd_addr_port0; wire [max_burst_bits-1:0] ocm_rd_data_port0; wire [max_burst_bytes_width:0] ocm_rd_bytes_port0; wire [axi_qos_width-1:0] ocm_wr_qos_port0; wire [axi_qos_width-1:0] ocm_rd_qos_port0; wire ocm_wr_ack_port1; wire ocm_wr_dv_port1; wire ocm_rd_req_port1; wire ocm_rd_dv_port1; wire [addr_width-1:0] ocm_wr_addr_port1; wire [max_burst_bits-1:0] ocm_wr_data_port1; wire [max_burst_bytes_width:0] ocm_wr_bytes_port1; wire [addr_width-1:0] ocm_rd_addr_port1; wire [max_burst_bits-1:0] ocm_rd_data_port1; wire [max_burst_bytes_width:0] ocm_rd_bytes_port1; wire [axi_qos_width-1:0] ocm_wr_qos_port1; wire [axi_qos_width-1:0] ocm_rd_qos_port1; wire ddr_wr_ack_port0; wire ddr_wr_dv_port0; wire ddr_rd_req_port0; wire ddr_rd_dv_port0; wire[addr_width-1:0] ddr_wr_addr_port0; wire[max_burst_bits-1:0] ddr_wr_data_port0; wire[max_burst_bytes_width:0] ddr_wr_bytes_port0; wire[addr_width-1:0] ddr_rd_addr_port0; wire[max_burst_bits-1:0] ddr_rd_data_port0; wire[max_burst_bytes_width:0] ddr_rd_bytes_port0; wire [axi_qos_width-1:0] ddr_wr_qos_port0; wire [axi_qos_width-1:0] ddr_rd_qos_port0; wire ddr_wr_ack_port1; wire ddr_wr_dv_port1; wire ddr_rd_req_port1; wire ddr_rd_dv_port1; wire[addr_width-1:0] ddr_wr_addr_port1; wire[max_burst_bits-1:0] ddr_wr_data_port1; wire[max_burst_bytes_width:0] ddr_wr_bytes_port1; wire[addr_width-1:0] ddr_rd_addr_port1; wire[max_burst_bits-1:0] ddr_rd_data_port1; wire[max_burst_bytes_width:0] ddr_rd_bytes_port1; wire[axi_qos_width-1:0] ddr_wr_qos_port1; wire[axi_qos_width-1:0] ddr_rd_qos_port1; wire ddr_wr_ack_port2; wire ddr_wr_dv_port2; wire ddr_rd_req_port2; wire ddr_rd_dv_port2; wire[addr_width-1:0] ddr_wr_addr_port2; wire[max_burst_bits-1:0] ddr_wr_data_port2; wire[max_burst_bytes_width:0] ddr_wr_bytes_port2; wire[addr_width-1:0] ddr_rd_addr_port2; wire[max_burst_bits-1:0] ddr_rd_data_port2; wire[max_burst_bytes_width:0] ddr_rd_bytes_port2; wire[axi_qos_width-1:0] ddr_wr_qos_port2; wire[axi_qos_width-1:0] ddr_rd_qos_port2; wire ddr_wr_ack_port3; wire ddr_wr_dv_port3; wire ddr_rd_req_port3; wire ddr_rd_dv_port3; wire[addr_width-1:0] ddr_wr_addr_port3; wire[max_burst_bits-1:0] ddr_wr_data_port3; wire[max_burst_bytes_width:0] ddr_wr_bytes_port3; wire[addr_width-1:0] ddr_rd_addr_port3; wire[max_burst_bits-1:0] ddr_rd_data_port3; wire[max_burst_bytes_width:0] ddr_rd_bytes_port3; wire[axi_qos_width-1:0] ddr_wr_qos_port3; wire[axi_qos_width-1:0] ddr_rd_qos_port3; wire reg_rd_req_port0; wire reg_rd_dv_port0; wire[addr_width-1:0] reg_rd_addr_port0; wire[max_burst_bits-1:0] reg_rd_data_port0; wire[max_burst_bytes_width:0] reg_rd_bytes_port0; wire [axi_qos_width-1:0] reg_rd_qos_port0; wire reg_rd_req_port1; wire reg_rd_dv_port1; wire[addr_width-1:0] reg_rd_addr_port1; wire[max_burst_bits-1:0] reg_rd_data_port1; wire[max_burst_bytes_width:0] reg_rd_bytes_port1; wire [axi_qos_width-1:0] reg_rd_qos_port1; wire [11:0] M_AXI_GP0_AWID_FULL; wire [11:0] M_AXI_GP0_WID_FULL; wire [11:0] M_AXI_GP0_ARID_FULL; wire [11:0] M_AXI_GP0_BID_FULL; wire [11:0] M_AXI_GP0_RID_FULL; wire [11:0] M_AXI_GP1_AWID_FULL; wire [11:0] M_AXI_GP1_WID_FULL; wire [11:0] M_AXI_GP1_ARID_FULL; wire [11:0] M_AXI_GP1_BID_FULL; wire [11:0] M_AXI_GP1_RID_FULL; function [5:0] compress_id; input [11:0] id; begin compress_id = id[5:0]; end endfunction function [11:0] uncompress_id; input [5:0] id; begin uncompress_id = {6'b110000, id[5:0]}; end endfunction assign M_AXI_GP0_AWID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_AWID_FULL) : M_AXI_GP0_AWID_FULL; assign M_AXI_GP0_WID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_WID_FULL) : M_AXI_GP0_WID_FULL; assign M_AXI_GP0_ARID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_ARID_FULL) : M_AXI_GP0_ARID_FULL; assign M_AXI_GP0_BID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_BID) : M_AXI_GP0_BID; assign M_AXI_GP0_RID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_RID) : M_AXI_GP0_RID; assign M_AXI_GP1_AWID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_AWID_FULL) : M_AXI_GP1_AWID_FULL; assign M_AXI_GP1_WID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_WID_FULL) : M_AXI_GP1_WID_FULL; assign M_AXI_GP1_ARID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_ARID_FULL) : M_AXI_GP1_ARID_FULL; assign M_AXI_GP1_BID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_BID) : M_AXI_GP1_BID; assign M_AXI_GP1_RID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_RID) : M_AXI_GP1_RID; processing_system7_bfm_v2_0_5_interconnect_model icm ( .rstn(net_rstn), .sw_clk(net_sw_clk), .w_qos_gp0(net_wr_qos_gp0), .w_qos_gp1(net_wr_qos_gp1), .w_qos_hp0(net_wr_qos_hp0), .w_qos_hp1(net_wr_qos_hp1), .w_qos_hp2(net_wr_qos_hp2), .w_qos_hp3(net_wr_qos_hp3), .r_qos_gp0(net_rd_qos_gp0), .r_qos_gp1(net_rd_qos_gp1), .r_qos_hp0(net_rd_qos_hp0), .r_qos_hp1(net_rd_qos_hp1), .r_qos_hp2(net_rd_qos_hp2), .r_qos_hp3(net_rd_qos_hp3), / GP Slave ports access / .wr_ack_ddr_gp0(net_wr_ack_ddr_gp0), .wr_ack_ocm_gp0(net_wr_ack_ocm_gp0), .wr_data_gp0(net_wr_data_gp0), .wr_addr_gp0(net_wr_addr_gp0), .wr_bytes_gp0(net_wr_bytes_gp0), .wr_dv_ddr_gp0(net_wr_dv_ddr_gp0), .wr_dv_ocm_gp0(net_wr_dv_ocm_gp0), .rd_req_ddr_gp0(net_rd_req_ddr_gp0), .rd_req_ocm_gp0(net_rd_req_ocm_gp0), .rd_req_reg_gp0(net_rd_req_reg_gp0), .rd_addr_gp0(net_rd_addr_gp0), .rd_bytes_gp0(net_rd_bytes_gp0), .rd_data_ddr_gp0(net_rd_data_ddr_gp0), .rd_data_ocm_gp0(net_rd_data_ocm_gp0), .rd_data_reg_gp0(net_rd_data_reg_gp0), .rd_dv_ddr_gp0(net_rd_dv_ddr_gp0), .rd_dv_ocm_gp0(net_rd_dv_ocm_gp0), .rd_dv_reg_gp0(net_rd_dv_reg_gp0), .wr_ack_ddr_gp1(net_wr_ack_ddr_gp1), .wr_ack_ocm_gp1(net_wr_ack_ocm_gp1), .wr_data_gp1(net_wr_data_gp1), .wr_addr_gp1(net_wr_addr_gp1), .wr_bytes_gp1(net_wr_bytes_gp1), .wr_dv_ddr_gp1(net_wr_dv_ddr_gp1), .wr_dv_ocm_gp1(net_wr_dv_ocm_gp1), .rd_req_ddr_gp1(net_rd_req_ddr_gp1), .rd_req_ocm_gp1(net_rd_req_ocm_gp1), .rd_req_reg_gp1(net_rd_req_reg_gp1), .rd_addr_gp1(net_rd_addr_gp1), .rd_bytes_gp1(net_rd_bytes_gp1), .rd_data_ddr_gp1(net_rd_data_ddr_gp1), .rd_data_ocm_gp1(net_rd_data_ocm_gp1), .rd_data_reg_gp1(net_rd_data_reg_gp1), .rd_dv_ddr_gp1(net_rd_dv_ddr_gp1), .rd_dv_ocm_gp1(net_rd_dv_ocm_gp1), .rd_dv_reg_gp1(net_rd_dv_reg_gp1), / HP Slave ports access / .wr_ack_ddr_hp0(net_wr_ack_ddr_hp0), .wr_ack_ocm_hp0(net_wr_ack_ocm_hp0), .wr_data_hp0(net_wr_data_hp0), .wr_addr_hp0(net_wr_addr_hp0), .wr_bytes_hp0(net_wr_bytes_hp0), .wr_dv_ddr_hp0(net_wr_dv_ddr_hp0), .wr_dv_ocm_hp0(net_wr_dv_ocm_hp0), .rd_req_ddr_hp0(net_rd_req_ddr_hp0), .rd_req_ocm_hp0(net_rd_req_ocm_hp0), .rd_addr_hp0(net_rd_addr_hp0), .rd_bytes_hp0(net_rd_bytes_hp0), .rd_data_ddr_hp0(net_rd_data_ddr_hp0), .rd_data_ocm_hp0(net_rd_data_ocm_hp0), .rd_dv_ddr_hp0(net_rd_dv_ddr_hp0), .rd_dv_ocm_hp0(net_rd_dv_ocm_hp0), .wr_ack_ddr_hp1(net_wr_ack_ddr_hp1), .wr_ack_ocm_hp1(net_wr_ack_ocm_hp1), .wr_data_hp1(net_wr_data_hp1), .wr_addr_hp1(net_wr_addr_hp1), .wr_bytes_hp1(net_wr_bytes_hp1), .wr_dv_ddr_hp1(net_wr_dv_ddr_hp1), .wr_dv_ocm_hp1(net_wr_dv_ocm_hp1), .rd_req_ddr_hp1(net_rd_req_ddr_hp1), .rd_req_ocm_hp1(net_rd_req_ocm_hp1), .rd_addr_hp1(net_rd_addr_hp1), .rd_bytes_hp1(net_rd_bytes_hp1), .rd_data_ddr_hp1(net_rd_data_ddr_hp1), .rd_data_ocm_hp1(net_rd_data_ocm_hp1), .rd_dv_ocm_hp1(net_rd_dv_ocm_hp1), .rd_dv_ddr_hp1(net_rd_dv_ddr_hp1), .wr_ack_ddr_hp2(net_wr_ack_ddr_hp2), .wr_ack_ocm_hp2(net_wr_ack_ocm_hp2), .wr_data_hp2(net_wr_data_hp2), .wr_addr_hp2(net_wr_addr_hp2), .wr_bytes_hp2(net_wr_bytes_hp2), .wr_dv_ocm_hp2(net_wr_dv_ocm_hp2), .wr_dv_ddr_hp2(net_wr_dv_ddr_hp2), .rd_req_ddr_hp2(net_rd_req_ddr_hp2), .rd_req_ocm_hp2(net_rd_req_ocm_hp2), .rd_addr_hp2(net_rd_addr_hp2), .rd_bytes_hp2(net_rd_bytes_hp2), .rd_data_ddr_hp2(net_rd_data_ddr_hp2), .rd_data_ocm_hp2(net_rd_data_ocm_hp2), .rd_dv_ddr_hp2(net_rd_dv_ddr_hp2), .rd_dv_ocm_hp2(net_rd_dv_ocm_hp2), .wr_ack_ocm_hp3(net_wr_ack_ocm_hp3), .wr_ack_ddr_hp3(net_wr_ack_ddr_hp3), .wr_data_hp3(net_wr_data_hp3), .wr_addr_hp3(net_wr_addr_hp3), .wr_bytes_hp3(net_wr_bytes_hp3), .wr_dv_ddr_hp3(net_wr_dv_ddr_hp3), .wr_dv_ocm_hp3(net_wr_dv_ocm_hp3), .rd_req_ddr_hp3(net_rd_req_ddr_hp3), .rd_req_ocm_hp3(net_rd_req_ocm_hp3), .rd_addr_hp3(net_rd_addr_hp3), .rd_bytes_hp3(net_rd_bytes_hp3), .rd_data_ddr_hp3(net_rd_data_ddr_hp3), .rd_data_ocm_hp3(net_rd_data_ocm_hp3), .rd_dv_ddr_hp3(net_rd_dv_ddr_hp3), .rd_dv_ocm_hp3(net_rd_dv_ocm_hp3), / Goes to port 1 of DDR / .ddr_wr_ack_port1(ddr_wr_ack_port1), .ddr_wr_dv_port1(ddr_wr_dv_port1), .ddr_rd_req_port1(ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1(ddr_wr_qos_port1), .ddr_rd_qos_port1(ddr_rd_qos_port1), / Goes to port2 of DDR / .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), / Goes to port3 of DDR / .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3), / Goes to port 0 of OCM / .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1), / Goes to port 0 of REG / .reg_rd_qos_port1 (reg_rd_qos_port1) , .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1) ); processing_system7_bfm_v2_0_5_ddrc ddrc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of DDR / .ddr_wr_ack_port0 (ddr_wr_ack_port0), .ddr_wr_dv_port0 (ddr_wr_dv_port0), .ddr_rd_req_port0 (ddr_rd_req_port0), .ddr_rd_dv_port0 (ddr_rd_dv_port0), .ddr_wr_addr_port0(net_wr_addr_acp), .ddr_wr_data_port0(net_wr_data_acp), .ddr_wr_bytes_port0(net_wr_bytes_acp), .ddr_rd_addr_port0(net_rd_addr_acp), .ddr_rd_bytes_port0(net_rd_bytes_acp), .ddr_rd_data_port0(ddr_rd_data_port0), .ddr_wr_qos_port0 (net_wr_qos_acp), .ddr_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of DDR / .ddr_wr_ack_port1 (ddr_wr_ack_port1), .ddr_wr_dv_port1 (ddr_wr_dv_port1), .ddr_rd_req_port1 (ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1 (ddr_wr_qos_port1), .ddr_rd_qos_port1 (ddr_rd_qos_port1), / Goes to port2 of DDR / .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), / Goes to port3 of DDR / .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3) ); processing_system7_bfm_v2_0_5_ocmc ocmc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of OCM / .ocm_wr_ack_port0 (ocm_wr_ack_port0), .ocm_wr_dv_port0 (ocm_wr_dv_port0), .ocm_rd_req_port0 (ocm_rd_req_port0), .ocm_rd_dv_port0 (ocm_rd_dv_port0), .ocm_wr_addr_port0(net_wr_addr_acp), .ocm_wr_data_port0(net_wr_data_acp), .ocm_wr_bytes_port0(net_wr_bytes_acp), .ocm_rd_addr_port0(net_rd_addr_acp), .ocm_rd_bytes_port0(net_rd_bytes_acp), .ocm_rd_data_port0(ocm_rd_data_port0), .ocm_wr_qos_port0 (net_wr_qos_acp), .ocm_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of OCM / .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1) ); processing_system7_bfm_v2_0_5_regc regc ( .rstn(net_rstn), .sw_clk(net_sw_clk), / Goes to port 0 of REG / .reg_rd_req_port0 (reg_rd_req_port0), .reg_rd_dv_port0 (reg_rd_dv_port0), .reg_rd_addr_port0(net_rd_addr_acp), .reg_rd_bytes_port0(net_rd_bytes_acp), .reg_rd_data_port0(reg_rd_data_port0), .reg_rd_qos_port0 (net_rd_qos_acp), / Goes to port 1 of REG / .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1), .reg_rd_qos_port1(reg_rd_qos_port1) ); / include axi_gp port instantiations / `include "processing_system7_bfm_v2_0_5_axi_gp.v" / include axi_hp port instantiations / `include "processing_system7_bfm_v2_0_5_axi_hp.v" / include axi_acp port instantiations */ `include "processing_system7_bfm_v2_0_5_axi_acp.v" endmodule
module processing_system7_bfm_v2_0_5_ddrc( rstn, sw_clk, /* Goes to port 0 of DDR / ddr_wr_ack_port0, ddr_wr_dv_port0, ddr_rd_req_port0, ddr_rd_dv_port0, ddr_wr_addr_port0, ddr_wr_data_port0, ddr_wr_bytes_port0, ddr_rd_addr_port0, ddr_rd_data_port0, ddr_rd_bytes_port0, ddr_wr_qos_port0, ddr_rd_qos_port0, / Goes to port 1 of DDR / ddr_wr_ack_port1, ddr_wr_dv_port1, ddr_rd_req_port1, ddr_rd_dv_port1, ddr_wr_addr_port1, ddr_wr_data_port1, ddr_wr_bytes_port1, ddr_rd_addr_port1, ddr_rd_data_port1, ddr_rd_bytes_port1, ddr_wr_qos_port1, ddr_rd_qos_port1, / Goes to port2 of DDR / ddr_wr_ack_port2, ddr_wr_dv_port2, ddr_rd_req_port2, ddr_rd_dv_port2, ddr_wr_addr_port2, ddr_wr_data_port2, ddr_wr_bytes_port2, ddr_rd_addr_port2, ddr_rd_data_port2, ddr_rd_bytes_port2, ddr_wr_qos_port2, ddr_rd_qos_port2, / Goes to port3 of DDR */ ddr_wr_ack_port3, ddr_wr_dv_port3, ddr_rd_req_port3, ddr_rd_dv_port3, ddr_wr_addr_port3, ddr_wr_data_port3, ddr_wr_bytes_port3, ddr_rd_addr_port3, ddr_rd_data_port3, ddr_rd_bytes_port3, ddr_wr_qos_port3, ddr_rd_qos_port3 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; output ddr_wr_ack_port0; input ddr_wr_dv_port0; input ddr_rd_req_port0; output ddr_rd_dv_port0; input[addr_width-1:0] ddr_wr_addr_port0; input[max_burst_bits-1:0] ddr_wr_data_port0; input[max_burst_bytes_width:0] ddr_wr_bytes_port0; input[addr_width-1:0] ddr_rd_addr_port0; output[max_burst_bits-1:0] ddr_rd_data_port0; input[max_burst_bytes_width:0] ddr_rd_bytes_port0; input [axi_qos_width-1:0] ddr_wr_qos_port0; input [axi_qos_width-1:0] ddr_rd_qos_port0; output ddr_wr_ack_port1; input ddr_wr_dv_port1; input ddr_rd_req_port1; output ddr_rd_dv_port1; input[addr_width-1:0] ddr_wr_addr_port1; input[max_burst_bits-1:0] ddr_wr_data_port1; input[max_burst_bytes_width:0] ddr_wr_bytes_port1; input[addr_width-1:0] ddr_rd_addr_port1; output[max_burst_bits-1:0] ddr_rd_data_port1; input[max_burst_bytes_width:0] ddr_rd_bytes_port1; input[axi_qos_width-1:0] ddr_wr_qos_port1; input[axi_qos_width-1:0] ddr_rd_qos_port1; output ddr_wr_ack_port2; input ddr_wr_dv_port2; input ddr_rd_req_port2; output ddr_rd_dv_port2; input[addr_width-1:0] ddr_wr_addr_port2; input[max_burst_bits-1:0] ddr_wr_data_port2; input[max_burst_bytes_width:0] ddr_wr_bytes_port2; input[addr_width-1:0] ddr_rd_addr_port2; output[max_burst_bits-1:0] ddr_rd_data_port2; input[max_burst_bytes_width:0] ddr_rd_bytes_port2; input[axi_qos_width-1:0] ddr_wr_qos_port2; input[axi_qos_width-1:0] ddr_rd_qos_port2; output ddr_wr_ack_port3; input ddr_wr_dv_port3; input ddr_rd_req_port3; output ddr_rd_dv_port3; input[addr_width-1:0] ddr_wr_addr_port3; input[max_burst_bits-1:0] ddr_wr_data_port3; input[max_burst_bytes_width:0] ddr_wr_bytes_port3; input[addr_width-1:0] ddr_rd_addr_port3; output[max_burst_bits-1:0] ddr_rd_data_port3; input[max_burst_bytes_width:0] ddr_rd_bytes_port3; input[axi_qos_width-1:0] ddr_wr_qos_port3; input[axi_qos_width-1:0] ddr_rd_qos_port3; wire [axi_qos_width-1:0] wr_qos; wire wr_req; wire [max_burst_bits-1:0] wr_data; wire [addr_width-1:0] wr_addr; wire [max_burst_bytes_width:0] wr_bytes; reg wr_ack; wire [axi_qos_width-1:0] rd_qos; reg [max_burst_bits-1:0] rd_data; wire [addr_width-1:0] rd_addr; wire [max_burst_bytes_width:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_wr_4 ddr_write_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_wr_qos_port0), .qos2(ddr_wr_qos_port1), .qos3(ddr_wr_qos_port2), .qos4(ddr_wr_qos_port3), .prt_dv1(ddr_wr_dv_port0), .prt_dv2(ddr_wr_dv_port1), .prt_dv3(ddr_wr_dv_port2), .prt_dv4(ddr_wr_dv_port3), .prt_data1(ddr_wr_data_port0), .prt_data2(ddr_wr_data_port1), .prt_data3(ddr_wr_data_port2), .prt_data4(ddr_wr_data_port3), .prt_addr1(ddr_wr_addr_port0), .prt_addr2(ddr_wr_addr_port1), .prt_addr3(ddr_wr_addr_port2), .prt_addr4(ddr_wr_addr_port3), .prt_bytes1(ddr_wr_bytes_port0), .prt_bytes2(ddr_wr_bytes_port1), .prt_bytes3(ddr_wr_bytes_port2), .prt_bytes4(ddr_wr_bytes_port3), .prt_ack1(ddr_wr_ack_port0), .prt_ack2(ddr_wr_ack_port1), .prt_ack3(ddr_wr_ack_port2), .prt_ack4(ddr_wr_ack_port3), .prt_qos(wr_qos), .prt_req(wr_req), .prt_data(wr_data), .prt_addr(wr_addr), .prt_bytes(wr_bytes), .prt_ack(wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd_4 ddr_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_rd_qos_port0), .qos2(ddr_rd_qos_port1), .qos3(ddr_rd_qos_port2), .qos4(ddr_rd_qos_port3), .prt_req1(ddr_rd_req_port0), .prt_req2(ddr_rd_req_port1), .prt_req3(ddr_rd_req_port2), .prt_req4(ddr_rd_req_port3), .prt_data1(ddr_rd_data_port0), .prt_data2(ddr_rd_data_port1), .prt_data3(ddr_rd_data_port2), .prt_data4(ddr_rd_data_port3), .prt_addr1(ddr_rd_addr_port0), .prt_addr2(ddr_rd_addr_port1), .prt_addr3(ddr_rd_addr_port2), .prt_addr4(ddr_rd_addr_port3), .prt_bytes1(ddr_rd_bytes_port0), .prt_bytes2(ddr_rd_bytes_port1), .prt_bytes3(ddr_rd_bytes_port2), .prt_bytes4(ddr_rd_bytes_port3), .prt_dv1(ddr_rd_dv_port0), .prt_dv2(ddr_rd_dv_port1), .prt_dv3(ddr_rd_dv_port2), .prt_dv4(ddr_rd_dv_port3), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_sparse_mem ddr(); reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin wr_ack <= 0; rd_dv <= 0; state <= 2'd0; end else begin case(state) 0:begin state <= 0; wr_ack <= 0; rd_dv <= 0; if(wr_req) begin ddr.write_mem(wr_data , wr_addr, wr_bytes); wr_ack <= 1; state <= 1; end if(rd_req) begin ddr.read_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin wr_ack <= 0; rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule
module processing_system7_bfm_v2_0_5_ddrc( rstn, sw_clk, /* Goes to port 0 of DDR / ddr_wr_ack_port0, ddr_wr_dv_port0, ddr_rd_req_port0, ddr_rd_dv_port0, ddr_wr_addr_port0, ddr_wr_data_port0, ddr_wr_bytes_port0, ddr_rd_addr_port0, ddr_rd_data_port0, ddr_rd_bytes_port0, ddr_wr_qos_port0, ddr_rd_qos_port0, / Goes to port 1 of DDR / ddr_wr_ack_port1, ddr_wr_dv_port1, ddr_rd_req_port1, ddr_rd_dv_port1, ddr_wr_addr_port1, ddr_wr_data_port1, ddr_wr_bytes_port1, ddr_rd_addr_port1, ddr_rd_data_port1, ddr_rd_bytes_port1, ddr_wr_qos_port1, ddr_rd_qos_port1, / Goes to port2 of DDR / ddr_wr_ack_port2, ddr_wr_dv_port2, ddr_rd_req_port2, ddr_rd_dv_port2, ddr_wr_addr_port2, ddr_wr_data_port2, ddr_wr_bytes_port2, ddr_rd_addr_port2, ddr_rd_data_port2, ddr_rd_bytes_port2, ddr_wr_qos_port2, ddr_rd_qos_port2, / Goes to port3 of DDR */ ddr_wr_ack_port3, ddr_wr_dv_port3, ddr_rd_req_port3, ddr_rd_dv_port3, ddr_wr_addr_port3, ddr_wr_data_port3, ddr_wr_bytes_port3, ddr_rd_addr_port3, ddr_rd_data_port3, ddr_rd_bytes_port3, ddr_wr_qos_port3, ddr_rd_qos_port3 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; output ddr_wr_ack_port0; input ddr_wr_dv_port0; input ddr_rd_req_port0; output ddr_rd_dv_port0; input[addr_width-1:0] ddr_wr_addr_port0; input[max_burst_bits-1:0] ddr_wr_data_port0; input[max_burst_bytes_width:0] ddr_wr_bytes_port0; input[addr_width-1:0] ddr_rd_addr_port0; output[max_burst_bits-1:0] ddr_rd_data_port0; input[max_burst_bytes_width:0] ddr_rd_bytes_port0; input [axi_qos_width-1:0] ddr_wr_qos_port0; input [axi_qos_width-1:0] ddr_rd_qos_port0; output ddr_wr_ack_port1; input ddr_wr_dv_port1; input ddr_rd_req_port1; output ddr_rd_dv_port1; input[addr_width-1:0] ddr_wr_addr_port1; input[max_burst_bits-1:0] ddr_wr_data_port1; input[max_burst_bytes_width:0] ddr_wr_bytes_port1; input[addr_width-1:0] ddr_rd_addr_port1; output[max_burst_bits-1:0] ddr_rd_data_port1; input[max_burst_bytes_width:0] ddr_rd_bytes_port1; input[axi_qos_width-1:0] ddr_wr_qos_port1; input[axi_qos_width-1:0] ddr_rd_qos_port1; output ddr_wr_ack_port2; input ddr_wr_dv_port2; input ddr_rd_req_port2; output ddr_rd_dv_port2; input[addr_width-1:0] ddr_wr_addr_port2; input[max_burst_bits-1:0] ddr_wr_data_port2; input[max_burst_bytes_width:0] ddr_wr_bytes_port2; input[addr_width-1:0] ddr_rd_addr_port2; output[max_burst_bits-1:0] ddr_rd_data_port2; input[max_burst_bytes_width:0] ddr_rd_bytes_port2; input[axi_qos_width-1:0] ddr_wr_qos_port2; input[axi_qos_width-1:0] ddr_rd_qos_port2; output ddr_wr_ack_port3; input ddr_wr_dv_port3; input ddr_rd_req_port3; output ddr_rd_dv_port3; input[addr_width-1:0] ddr_wr_addr_port3; input[max_burst_bits-1:0] ddr_wr_data_port3; input[max_burst_bytes_width:0] ddr_wr_bytes_port3; input[addr_width-1:0] ddr_rd_addr_port3; output[max_burst_bits-1:0] ddr_rd_data_port3; input[max_burst_bytes_width:0] ddr_rd_bytes_port3; input[axi_qos_width-1:0] ddr_wr_qos_port3; input[axi_qos_width-1:0] ddr_rd_qos_port3; wire [axi_qos_width-1:0] wr_qos; wire wr_req; wire [max_burst_bits-1:0] wr_data; wire [addr_width-1:0] wr_addr; wire [max_burst_bytes_width:0] wr_bytes; reg wr_ack; wire [axi_qos_width-1:0] rd_qos; reg [max_burst_bits-1:0] rd_data; wire [addr_width-1:0] rd_addr; wire [max_burst_bytes_width:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_wr_4 ddr_write_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_wr_qos_port0), .qos2(ddr_wr_qos_port1), .qos3(ddr_wr_qos_port2), .qos4(ddr_wr_qos_port3), .prt_dv1(ddr_wr_dv_port0), .prt_dv2(ddr_wr_dv_port1), .prt_dv3(ddr_wr_dv_port2), .prt_dv4(ddr_wr_dv_port3), .prt_data1(ddr_wr_data_port0), .prt_data2(ddr_wr_data_port1), .prt_data3(ddr_wr_data_port2), .prt_data4(ddr_wr_data_port3), .prt_addr1(ddr_wr_addr_port0), .prt_addr2(ddr_wr_addr_port1), .prt_addr3(ddr_wr_addr_port2), .prt_addr4(ddr_wr_addr_port3), .prt_bytes1(ddr_wr_bytes_port0), .prt_bytes2(ddr_wr_bytes_port1), .prt_bytes3(ddr_wr_bytes_port2), .prt_bytes4(ddr_wr_bytes_port3), .prt_ack1(ddr_wr_ack_port0), .prt_ack2(ddr_wr_ack_port1), .prt_ack3(ddr_wr_ack_port2), .prt_ack4(ddr_wr_ack_port3), .prt_qos(wr_qos), .prt_req(wr_req), .prt_data(wr_data), .prt_addr(wr_addr), .prt_bytes(wr_bytes), .prt_ack(wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd_4 ddr_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_rd_qos_port0), .qos2(ddr_rd_qos_port1), .qos3(ddr_rd_qos_port2), .qos4(ddr_rd_qos_port3), .prt_req1(ddr_rd_req_port0), .prt_req2(ddr_rd_req_port1), .prt_req3(ddr_rd_req_port2), .prt_req4(ddr_rd_req_port3), .prt_data1(ddr_rd_data_port0), .prt_data2(ddr_rd_data_port1), .prt_data3(ddr_rd_data_port2), .prt_data4(ddr_rd_data_port3), .prt_addr1(ddr_rd_addr_port0), .prt_addr2(ddr_rd_addr_port1), .prt_addr3(ddr_rd_addr_port2), .prt_addr4(ddr_rd_addr_port3), .prt_bytes1(ddr_rd_bytes_port0), .prt_bytes2(ddr_rd_bytes_port1), .prt_bytes3(ddr_rd_bytes_port2), .prt_bytes4(ddr_rd_bytes_port3), .prt_dv1(ddr_rd_dv_port0), .prt_dv2(ddr_rd_dv_port1), .prt_dv3(ddr_rd_dv_port2), .prt_dv4(ddr_rd_dv_port3), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_sparse_mem ddr(); reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin wr_ack <= 0; rd_dv <= 0; state <= 2'd0; end else begin case(state) 0:begin state <= 0; wr_ack <= 0; rd_dv <= 0; if(wr_req) begin ddr.write_mem(wr_data , wr_addr, wr_bytes); wr_ack <= 1; state <= 1; end if(rd_req) begin ddr.read_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin wr_ack <= 0; rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule
module processing_system7_bfm_v2_0_5_ddrc( rstn, sw_clk, /* Goes to port 0 of DDR / ddr_wr_ack_port0, ddr_wr_dv_port0, ddr_rd_req_port0, ddr_rd_dv_port0, ddr_wr_addr_port0, ddr_wr_data_port0, ddr_wr_bytes_port0, ddr_rd_addr_port0, ddr_rd_data_port0, ddr_rd_bytes_port0, ddr_wr_qos_port0, ddr_rd_qos_port0, / Goes to port 1 of DDR / ddr_wr_ack_port1, ddr_wr_dv_port1, ddr_rd_req_port1, ddr_rd_dv_port1, ddr_wr_addr_port1, ddr_wr_data_port1, ddr_wr_bytes_port1, ddr_rd_addr_port1, ddr_rd_data_port1, ddr_rd_bytes_port1, ddr_wr_qos_port1, ddr_rd_qos_port1, / Goes to port2 of DDR / ddr_wr_ack_port2, ddr_wr_dv_port2, ddr_rd_req_port2, ddr_rd_dv_port2, ddr_wr_addr_port2, ddr_wr_data_port2, ddr_wr_bytes_port2, ddr_rd_addr_port2, ddr_rd_data_port2, ddr_rd_bytes_port2, ddr_wr_qos_port2, ddr_rd_qos_port2, / Goes to port3 of DDR */ ddr_wr_ack_port3, ddr_wr_dv_port3, ddr_rd_req_port3, ddr_rd_dv_port3, ddr_wr_addr_port3, ddr_wr_data_port3, ddr_wr_bytes_port3, ddr_rd_addr_port3, ddr_rd_data_port3, ddr_rd_bytes_port3, ddr_wr_qos_port3, ddr_rd_qos_port3 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; output ddr_wr_ack_port0; input ddr_wr_dv_port0; input ddr_rd_req_port0; output ddr_rd_dv_port0; input[addr_width-1:0] ddr_wr_addr_port0; input[max_burst_bits-1:0] ddr_wr_data_port0; input[max_burst_bytes_width:0] ddr_wr_bytes_port0; input[addr_width-1:0] ddr_rd_addr_port0; output[max_burst_bits-1:0] ddr_rd_data_port0; input[max_burst_bytes_width:0] ddr_rd_bytes_port0; input [axi_qos_width-1:0] ddr_wr_qos_port0; input [axi_qos_width-1:0] ddr_rd_qos_port0; output ddr_wr_ack_port1; input ddr_wr_dv_port1; input ddr_rd_req_port1; output ddr_rd_dv_port1; input[addr_width-1:0] ddr_wr_addr_port1; input[max_burst_bits-1:0] ddr_wr_data_port1; input[max_burst_bytes_width:0] ddr_wr_bytes_port1; input[addr_width-1:0] ddr_rd_addr_port1; output[max_burst_bits-1:0] ddr_rd_data_port1; input[max_burst_bytes_width:0] ddr_rd_bytes_port1; input[axi_qos_width-1:0] ddr_wr_qos_port1; input[axi_qos_width-1:0] ddr_rd_qos_port1; output ddr_wr_ack_port2; input ddr_wr_dv_port2; input ddr_rd_req_port2; output ddr_rd_dv_port2; input[addr_width-1:0] ddr_wr_addr_port2; input[max_burst_bits-1:0] ddr_wr_data_port2; input[max_burst_bytes_width:0] ddr_wr_bytes_port2; input[addr_width-1:0] ddr_rd_addr_port2; output[max_burst_bits-1:0] ddr_rd_data_port2; input[max_burst_bytes_width:0] ddr_rd_bytes_port2; input[axi_qos_width-1:0] ddr_wr_qos_port2; input[axi_qos_width-1:0] ddr_rd_qos_port2; output ddr_wr_ack_port3; input ddr_wr_dv_port3; input ddr_rd_req_port3; output ddr_rd_dv_port3; input[addr_width-1:0] ddr_wr_addr_port3; input[max_burst_bits-1:0] ddr_wr_data_port3; input[max_burst_bytes_width:0] ddr_wr_bytes_port3; input[addr_width-1:0] ddr_rd_addr_port3; output[max_burst_bits-1:0] ddr_rd_data_port3; input[max_burst_bytes_width:0] ddr_rd_bytes_port3; input[axi_qos_width-1:0] ddr_wr_qos_port3; input[axi_qos_width-1:0] ddr_rd_qos_port3; wire [axi_qos_width-1:0] wr_qos; wire wr_req; wire [max_burst_bits-1:0] wr_data; wire [addr_width-1:0] wr_addr; wire [max_burst_bytes_width:0] wr_bytes; reg wr_ack; wire [axi_qos_width-1:0] rd_qos; reg [max_burst_bits-1:0] rd_data; wire [addr_width-1:0] rd_addr; wire [max_burst_bytes_width:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_wr_4 ddr_write_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_wr_qos_port0), .qos2(ddr_wr_qos_port1), .qos3(ddr_wr_qos_port2), .qos4(ddr_wr_qos_port3), .prt_dv1(ddr_wr_dv_port0), .prt_dv2(ddr_wr_dv_port1), .prt_dv3(ddr_wr_dv_port2), .prt_dv4(ddr_wr_dv_port3), .prt_data1(ddr_wr_data_port0), .prt_data2(ddr_wr_data_port1), .prt_data3(ddr_wr_data_port2), .prt_data4(ddr_wr_data_port3), .prt_addr1(ddr_wr_addr_port0), .prt_addr2(ddr_wr_addr_port1), .prt_addr3(ddr_wr_addr_port2), .prt_addr4(ddr_wr_addr_port3), .prt_bytes1(ddr_wr_bytes_port0), .prt_bytes2(ddr_wr_bytes_port1), .prt_bytes3(ddr_wr_bytes_port2), .prt_bytes4(ddr_wr_bytes_port3), .prt_ack1(ddr_wr_ack_port0), .prt_ack2(ddr_wr_ack_port1), .prt_ack3(ddr_wr_ack_port2), .prt_ack4(ddr_wr_ack_port3), .prt_qos(wr_qos), .prt_req(wr_req), .prt_data(wr_data), .prt_addr(wr_addr), .prt_bytes(wr_bytes), .prt_ack(wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd_4 ddr_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_rd_qos_port0), .qos2(ddr_rd_qos_port1), .qos3(ddr_rd_qos_port2), .qos4(ddr_rd_qos_port3), .prt_req1(ddr_rd_req_port0), .prt_req2(ddr_rd_req_port1), .prt_req3(ddr_rd_req_port2), .prt_req4(ddr_rd_req_port3), .prt_data1(ddr_rd_data_port0), .prt_data2(ddr_rd_data_port1), .prt_data3(ddr_rd_data_port2), .prt_data4(ddr_rd_data_port3), .prt_addr1(ddr_rd_addr_port0), .prt_addr2(ddr_rd_addr_port1), .prt_addr3(ddr_rd_addr_port2), .prt_addr4(ddr_rd_addr_port3), .prt_bytes1(ddr_rd_bytes_port0), .prt_bytes2(ddr_rd_bytes_port1), .prt_bytes3(ddr_rd_bytes_port2), .prt_bytes4(ddr_rd_bytes_port3), .prt_dv1(ddr_rd_dv_port0), .prt_dv2(ddr_rd_dv_port1), .prt_dv3(ddr_rd_dv_port2), .prt_dv4(ddr_rd_dv_port3), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_sparse_mem ddr(); reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin wr_ack <= 0; rd_dv <= 0; state <= 2'd0; end else begin case(state) 0:begin state <= 0; wr_ack <= 0; rd_dv <= 0; if(wr_req) begin ddr.write_mem(wr_data , wr_addr, wr_bytes); wr_ack <= 1; state <= 1; end if(rd_req) begin ddr.read_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin wr_ack <= 0; rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule
module processing_system7_bfm_v2_0_5_ddrc( rstn, sw_clk, /* Goes to port 0 of DDR / ddr_wr_ack_port0, ddr_wr_dv_port0, ddr_rd_req_port0, ddr_rd_dv_port0, ddr_wr_addr_port0, ddr_wr_data_port0, ddr_wr_bytes_port0, ddr_rd_addr_port0, ddr_rd_data_port0, ddr_rd_bytes_port0, ddr_wr_qos_port0, ddr_rd_qos_port0, / Goes to port 1 of DDR / ddr_wr_ack_port1, ddr_wr_dv_port1, ddr_rd_req_port1, ddr_rd_dv_port1, ddr_wr_addr_port1, ddr_wr_data_port1, ddr_wr_bytes_port1, ddr_rd_addr_port1, ddr_rd_data_port1, ddr_rd_bytes_port1, ddr_wr_qos_port1, ddr_rd_qos_port1, / Goes to port2 of DDR / ddr_wr_ack_port2, ddr_wr_dv_port2, ddr_rd_req_port2, ddr_rd_dv_port2, ddr_wr_addr_port2, ddr_wr_data_port2, ddr_wr_bytes_port2, ddr_rd_addr_port2, ddr_rd_data_port2, ddr_rd_bytes_port2, ddr_wr_qos_port2, ddr_rd_qos_port2, / Goes to port3 of DDR */ ddr_wr_ack_port3, ddr_wr_dv_port3, ddr_rd_req_port3, ddr_rd_dv_port3, ddr_wr_addr_port3, ddr_wr_data_port3, ddr_wr_bytes_port3, ddr_rd_addr_port3, ddr_rd_data_port3, ddr_rd_bytes_port3, ddr_wr_qos_port3, ddr_rd_qos_port3 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; output ddr_wr_ack_port0; input ddr_wr_dv_port0; input ddr_rd_req_port0; output ddr_rd_dv_port0; input[addr_width-1:0] ddr_wr_addr_port0; input[max_burst_bits-1:0] ddr_wr_data_port0; input[max_burst_bytes_width:0] ddr_wr_bytes_port0; input[addr_width-1:0] ddr_rd_addr_port0; output[max_burst_bits-1:0] ddr_rd_data_port0; input[max_burst_bytes_width:0] ddr_rd_bytes_port0; input [axi_qos_width-1:0] ddr_wr_qos_port0; input [axi_qos_width-1:0] ddr_rd_qos_port0; output ddr_wr_ack_port1; input ddr_wr_dv_port1; input ddr_rd_req_port1; output ddr_rd_dv_port1; input[addr_width-1:0] ddr_wr_addr_port1; input[max_burst_bits-1:0] ddr_wr_data_port1; input[max_burst_bytes_width:0] ddr_wr_bytes_port1; input[addr_width-1:0] ddr_rd_addr_port1; output[max_burst_bits-1:0] ddr_rd_data_port1; input[max_burst_bytes_width:0] ddr_rd_bytes_port1; input[axi_qos_width-1:0] ddr_wr_qos_port1; input[axi_qos_width-1:0] ddr_rd_qos_port1; output ddr_wr_ack_port2; input ddr_wr_dv_port2; input ddr_rd_req_port2; output ddr_rd_dv_port2; input[addr_width-1:0] ddr_wr_addr_port2; input[max_burst_bits-1:0] ddr_wr_data_port2; input[max_burst_bytes_width:0] ddr_wr_bytes_port2; input[addr_width-1:0] ddr_rd_addr_port2; output[max_burst_bits-1:0] ddr_rd_data_port2; input[max_burst_bytes_width:0] ddr_rd_bytes_port2; input[axi_qos_width-1:0] ddr_wr_qos_port2; input[axi_qos_width-1:0] ddr_rd_qos_port2; output ddr_wr_ack_port3; input ddr_wr_dv_port3; input ddr_rd_req_port3; output ddr_rd_dv_port3; input[addr_width-1:0] ddr_wr_addr_port3; input[max_burst_bits-1:0] ddr_wr_data_port3; input[max_burst_bytes_width:0] ddr_wr_bytes_port3; input[addr_width-1:0] ddr_rd_addr_port3; output[max_burst_bits-1:0] ddr_rd_data_port3; input[max_burst_bytes_width:0] ddr_rd_bytes_port3; input[axi_qos_width-1:0] ddr_wr_qos_port3; input[axi_qos_width-1:0] ddr_rd_qos_port3; wire [axi_qos_width-1:0] wr_qos; wire wr_req; wire [max_burst_bits-1:0] wr_data; wire [addr_width-1:0] wr_addr; wire [max_burst_bytes_width:0] wr_bytes; reg wr_ack; wire [axi_qos_width-1:0] rd_qos; reg [max_burst_bits-1:0] rd_data; wire [addr_width-1:0] rd_addr; wire [max_burst_bytes_width:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_wr_4 ddr_write_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_wr_qos_port0), .qos2(ddr_wr_qos_port1), .qos3(ddr_wr_qos_port2), .qos4(ddr_wr_qos_port3), .prt_dv1(ddr_wr_dv_port0), .prt_dv2(ddr_wr_dv_port1), .prt_dv3(ddr_wr_dv_port2), .prt_dv4(ddr_wr_dv_port3), .prt_data1(ddr_wr_data_port0), .prt_data2(ddr_wr_data_port1), .prt_data3(ddr_wr_data_port2), .prt_data4(ddr_wr_data_port3), .prt_addr1(ddr_wr_addr_port0), .prt_addr2(ddr_wr_addr_port1), .prt_addr3(ddr_wr_addr_port2), .prt_addr4(ddr_wr_addr_port3), .prt_bytes1(ddr_wr_bytes_port0), .prt_bytes2(ddr_wr_bytes_port1), .prt_bytes3(ddr_wr_bytes_port2), .prt_bytes4(ddr_wr_bytes_port3), .prt_ack1(ddr_wr_ack_port0), .prt_ack2(ddr_wr_ack_port1), .prt_ack3(ddr_wr_ack_port2), .prt_ack4(ddr_wr_ack_port3), .prt_qos(wr_qos), .prt_req(wr_req), .prt_data(wr_data), .prt_addr(wr_addr), .prt_bytes(wr_bytes), .prt_ack(wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd_4 ddr_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_rd_qos_port0), .qos2(ddr_rd_qos_port1), .qos3(ddr_rd_qos_port2), .qos4(ddr_rd_qos_port3), .prt_req1(ddr_rd_req_port0), .prt_req2(ddr_rd_req_port1), .prt_req3(ddr_rd_req_port2), .prt_req4(ddr_rd_req_port3), .prt_data1(ddr_rd_data_port0), .prt_data2(ddr_rd_data_port1), .prt_data3(ddr_rd_data_port2), .prt_data4(ddr_rd_data_port3), .prt_addr1(ddr_rd_addr_port0), .prt_addr2(ddr_rd_addr_port1), .prt_addr3(ddr_rd_addr_port2), .prt_addr4(ddr_rd_addr_port3), .prt_bytes1(ddr_rd_bytes_port0), .prt_bytes2(ddr_rd_bytes_port1), .prt_bytes3(ddr_rd_bytes_port2), .prt_bytes4(ddr_rd_bytes_port3), .prt_dv1(ddr_rd_dv_port0), .prt_dv2(ddr_rd_dv_port1), .prt_dv3(ddr_rd_dv_port2), .prt_dv4(ddr_rd_dv_port3), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_sparse_mem ddr(); reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin wr_ack <= 0; rd_dv <= 0; state <= 2'd0; end else begin case(state) 0:begin state <= 0; wr_ack <= 0; rd_dv <= 0; if(wr_req) begin ddr.write_mem(wr_data , wr_addr, wr_bytes); wr_ack <= 1; state <= 1; end if(rd_req) begin ddr.read_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin wr_ack <= 0; rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule
module processing_system7_bfm_v2_0_5_arb_rd( rstn, sw_clk, qos1, qos2, prt_req1, prt_req2, prt_bytes1, prt_bytes2, prt_addr1, prt_addr2, prt_data1, prt_data2, prt_dv1, prt_dv2, prt_req, prt_qos, prt_addr, prt_bytes, prt_data, prt_dv ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2; input prt_req1, prt_req2; input [addr_width-1:0] prt_addr1, prt_addr2; input [max_burst_bytes_width:0] prt_bytes1, prt_bytes2; output reg prt_dv1, prt_dv2; output reg [max_burst_bits-1:0] prt_data1,prt_data2; output reg prt_req; output reg [axi_qos_width-1:0] prt_qos; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; input [max_burst_bits-1:0] prt_data; input prt_dv; parameter wait_req = 2'b00, serv_req1 = 2'b01, serv_req2 = 2'b10,wait_dv_low = 2'b11; reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_req = 0; if(prt_req1 && !prt_req2) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(!prt_req1 && prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req1 && prt_req2) begin if(qos1 > qos2) begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else if(qos1 < qos2) begin prt_req = 1; prt_addr = prt_addr2; prt_qos = qos2; prt_bytes = prt_bytes2; state = serv_req2; end else begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req1:begin state = serv_req1; prt_dv2 = 1'b0; if(prt_dv) begin prt_dv1 = 1'b1; prt_data1 = prt_data; prt_req = 0; if(prt_req2) begin prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end else begin state = wait_dv_low; //state = wait_req; end end end serv_req2:begin state = serv_req2; prt_dv1 = 1'b0; if(prt_dv) begin prt_dv2 = 1'b1; prt_data2 = prt_data; prt_req = 0; if(prt_req1) begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else begin state = wait_dv_low; //state = wait_req; end end end wait_dv_low:begin prt_dv1 = 1'b0; prt_dv2 = 1'b0; state = wait_dv_low; if(!prt_dv) state = wait_req; end endcase end /// if else end /// always endmodule
module processing_system7_bfm_v2_0_5_arb_rd( rstn, sw_clk, qos1, qos2, prt_req1, prt_req2, prt_bytes1, prt_bytes2, prt_addr1, prt_addr2, prt_data1, prt_data2, prt_dv1, prt_dv2, prt_req, prt_qos, prt_addr, prt_bytes, prt_data, prt_dv ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2; input prt_req1, prt_req2; input [addr_width-1:0] prt_addr1, prt_addr2; input [max_burst_bytes_width:0] prt_bytes1, prt_bytes2; output reg prt_dv1, prt_dv2; output reg [max_burst_bits-1:0] prt_data1,prt_data2; output reg prt_req; output reg [axi_qos_width-1:0] prt_qos; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; input [max_burst_bits-1:0] prt_data; input prt_dv; parameter wait_req = 2'b00, serv_req1 = 2'b01, serv_req2 = 2'b10,wait_dv_low = 2'b11; reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_req = 0; if(prt_req1 && !prt_req2) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(!prt_req1 && prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req1 && prt_req2) begin if(qos1 > qos2) begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else if(qos1 < qos2) begin prt_req = 1; prt_addr = prt_addr2; prt_qos = qos2; prt_bytes = prt_bytes2; state = serv_req2; end else begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req1:begin state = serv_req1; prt_dv2 = 1'b0; if(prt_dv) begin prt_dv1 = 1'b1; prt_data1 = prt_data; prt_req = 0; if(prt_req2) begin prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end else begin state = wait_dv_low; //state = wait_req; end end end serv_req2:begin state = serv_req2; prt_dv1 = 1'b0; if(prt_dv) begin prt_dv2 = 1'b1; prt_data2 = prt_data; prt_req = 0; if(prt_req1) begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else begin state = wait_dv_low; //state = wait_req; end end end wait_dv_low:begin prt_dv1 = 1'b0; prt_dv2 = 1'b0; state = wait_dv_low; if(!prt_dv) state = wait_req; end endcase end /// if else end /// always endmodule
module processing_system7_bfm_v2_0_5_arb_rd( rstn, sw_clk, qos1, qos2, prt_req1, prt_req2, prt_bytes1, prt_bytes2, prt_addr1, prt_addr2, prt_data1, prt_data2, prt_dv1, prt_dv2, prt_req, prt_qos, prt_addr, prt_bytes, prt_data, prt_dv ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2; input prt_req1, prt_req2; input [addr_width-1:0] prt_addr1, prt_addr2; input [max_burst_bytes_width:0] prt_bytes1, prt_bytes2; output reg prt_dv1, prt_dv2; output reg [max_burst_bits-1:0] prt_data1,prt_data2; output reg prt_req; output reg [axi_qos_width-1:0] prt_qos; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; input [max_burst_bits-1:0] prt_data; input prt_dv; parameter wait_req = 2'b00, serv_req1 = 2'b01, serv_req2 = 2'b10,wait_dv_low = 2'b11; reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_req = 0; if(prt_req1 && !prt_req2) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(!prt_req1 && prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req1 && prt_req2) begin if(qos1 > qos2) begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else if(qos1 < qos2) begin prt_req = 1; prt_addr = prt_addr2; prt_qos = qos2; prt_bytes = prt_bytes2; state = serv_req2; end else begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req1:begin state = serv_req1; prt_dv2 = 1'b0; if(prt_dv) begin prt_dv1 = 1'b1; prt_data1 = prt_data; prt_req = 0; if(prt_req2) begin prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end else begin state = wait_dv_low; //state = wait_req; end end end serv_req2:begin state = serv_req2; prt_dv1 = 1'b0; if(prt_dv) begin prt_dv2 = 1'b1; prt_data2 = prt_data; prt_req = 0; if(prt_req1) begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else begin state = wait_dv_low; //state = wait_req; end end end wait_dv_low:begin prt_dv1 = 1'b0; prt_dv2 = 1'b0; state = wait_dv_low; if(!prt_dv) state = wait_req; end endcase end /// if else end /// always endmodule
module axi_crossbar_v2_1_arbiter_resp # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 4, // Number of requesting Slave ports = [2:16] parameter integer C_NUM_S_LOG = 2, // Log2(C_NUM_S) parameter integer C_GRANT_ENC = 0, // Enable encoded grant output parameter integer C_GRANT_HOT = 1 // Enable 1-hot grant output ) ( // Global Inputs input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_S-1:0] S_VALID, // Request from each slave output wire [C_NUM_S-1:0] S_READY, // Grant response to each slave // Master Ports output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, // Granted slave index (encoded) output wire [C_NUM_S-1:0] M_GRANT_HOT, // Granted slave index (1-hot) output wire M_VALID, // Grant event input wire M_READY ); // Generates a binary coded from onehotone encoded function [4:0] f_hot2enc ( input [16:0] one_hot ); begin f_hot2enc[0] = \|(one_hot & 17'b01010101010101010); f_hot2enc[1] = \|(one_hot & 17'b01100110011001100); f_hot2enc[2] = \|(one_hot & 17'b01111000011110000); f_hot2enc[3] = \|(one_hot & 17'b01111111100000000); f_hot2enc[4] = \|(one_hot & 17'b10000000000000000); end endfunction (* use_clock_enable = "yes" ) reg [C_NUM_S-1:0] chosen; wire [C_NUM_S-1:0] grant_hot; wire master_selected; wire active_master; wire need_arbitration; wire m_valid_i; wire [C_NUM_S-1:0] s_ready_i; wire access_done; reg [C_NUM_S-1:0] last_rr_hot; wire [C_NUM_S-1:0] valid_rr; reg [C_NUM_S-1:0] next_rr_hot; reg [C_NUM_SC_NUM_S-1:0] carry_rr; reg [C_NUM_SC_NUM_S-1:0] mask_rr; integer i; integer j; integer n; ///////////////////////////////////////////////////////////////////////////// // // Implementation of the arbiter outputs independant of arbitration // ///////////////////////////////////////////////////////////////////////////// // Mask the current requests with the chosen master assign grant_hot = chosen & S_VALID; // See if we have a selected master assign master_selected = \|grant_hot[0+:C_NUM_S]; // See if we have current requests assign active_master = \|S_VALID; // Access is completed assign access_done = m_valid_i & M_READY; // Need to handle if we drive S_ready combinatorial and without an IDLE state // Drive S_READY on the master who has been chosen when we get a M_READY assign s_ready_i = {C_NUM_S{M_READY}} & grant_hot[0+:C_NUM_S]; // Drive M_VALID if we have a selected master assign m_valid_i = master_selected; // If we have request and not a selected master, we need to arbitrate a new chosen assign need_arbitration = (active_master & ~master_selected) \| access_done; // need internal signals of the output signals assign M_VALID = m_valid_i; assign S_READY = s_ready_i; ///////////////////////////////////////////////////////////////////////////// // Assign conditional onehot target output signal. assign M_GRANT_HOT = (C_GRANT_HOT == 1) ? grant_hot[0+:C_NUM_S] : {C_NUM_S{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Assign conditional encoded target output signal. assign M_GRANT_ENC = (C_GRANT_ENC == 1) ? f_hot2enc(grant_hot) : {C_NUM_S_LOG{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Select a new chosen when we need to arbitrate // If we don't have a new chosen, keep the old one since it's a good chance // that it will do another request always @(posedge ACLK) begin if (ARESET) begin chosen <= {C_NUM_S{1'b0}}; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; end else if (need_arbitration) begin chosen <= next_rr_hot; if (\|next_rr_hot) last_rr_hot <= next_rr_hot; end end assign valid_rr = S_VALID; ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ begin next_rr_hot = 0; for (i=0;i<C_NUM_S;i=i+1) begin n = (i>0) ? (i-1) : (C_NUM_S-1); carry_rr[iC_NUM_S] = last_rr_hot[n]; mask_rr[iC_NUM_S] = ~valid_rr[n]; for (j=1;j<C_NUM_S;j=j+1) begin n = (i-j > 0) ? (i-j-1) : (C_NUM_S+i-j-1); carry_rr[iC_NUM_S+j] = carry_rr[iC_NUM_S+j-1] \| (last_rr_hot[n] & mask_rr[iC_NUM_S+j-1]); if (j < C_NUM_S-1) begin mask_rr[iC_NUM_S+j] = mask_rr[iC_NUM_S+j-1] & ~valid_rr[n]; end end next_rr_hot[i] = valid_rr[i] & carry_rr[(i+1)C_NUM_S-1]; end end endmodule
module axi_crossbar_v2_1_arbiter_resp # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 4, // Number of requesting Slave ports = [2:16] parameter integer C_NUM_S_LOG = 2, // Log2(C_NUM_S) parameter integer C_GRANT_ENC = 0, // Enable encoded grant output parameter integer C_GRANT_HOT = 1 // Enable 1-hot grant output ) ( // Global Inputs input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_S-1:0] S_VALID, // Request from each slave output wire [C_NUM_S-1:0] S_READY, // Grant response to each slave // Master Ports output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, // Granted slave index (encoded) output wire [C_NUM_S-1:0] M_GRANT_HOT, // Granted slave index (1-hot) output wire M_VALID, // Grant event input wire M_READY ); // Generates a binary coded from onehotone encoded function [4:0] f_hot2enc ( input [16:0] one_hot ); begin f_hot2enc[0] = \|(one_hot & 17'b01010101010101010); f_hot2enc[1] = \|(one_hot & 17'b01100110011001100); f_hot2enc[2] = \|(one_hot & 17'b01111000011110000); f_hot2enc[3] = \|(one_hot & 17'b01111111100000000); f_hot2enc[4] = \|(one_hot & 17'b10000000000000000); end endfunction (* use_clock_enable = "yes" ) reg [C_NUM_S-1:0] chosen; wire [C_NUM_S-1:0] grant_hot; wire master_selected; wire active_master; wire need_arbitration; wire m_valid_i; wire [C_NUM_S-1:0] s_ready_i; wire access_done; reg [C_NUM_S-1:0] last_rr_hot; wire [C_NUM_S-1:0] valid_rr; reg [C_NUM_S-1:0] next_rr_hot; reg [C_NUM_SC_NUM_S-1:0] carry_rr; reg [C_NUM_SC_NUM_S-1:0] mask_rr; integer i; integer j; integer n; ///////////////////////////////////////////////////////////////////////////// // // Implementation of the arbiter outputs independant of arbitration // ///////////////////////////////////////////////////////////////////////////// // Mask the current requests with the chosen master assign grant_hot = chosen & S_VALID; // See if we have a selected master assign master_selected = \|grant_hot[0+:C_NUM_S]; // See if we have current requests assign active_master = \|S_VALID; // Access is completed assign access_done = m_valid_i & M_READY; // Need to handle if we drive S_ready combinatorial and without an IDLE state // Drive S_READY on the master who has been chosen when we get a M_READY assign s_ready_i = {C_NUM_S{M_READY}} & grant_hot[0+:C_NUM_S]; // Drive M_VALID if we have a selected master assign m_valid_i = master_selected; // If we have request and not a selected master, we need to arbitrate a new chosen assign need_arbitration = (active_master & ~master_selected) \| access_done; // need internal signals of the output signals assign M_VALID = m_valid_i; assign S_READY = s_ready_i; ///////////////////////////////////////////////////////////////////////////// // Assign conditional onehot target output signal. assign M_GRANT_HOT = (C_GRANT_HOT == 1) ? grant_hot[0+:C_NUM_S] : {C_NUM_S{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Assign conditional encoded target output signal. assign M_GRANT_ENC = (C_GRANT_ENC == 1) ? f_hot2enc(grant_hot) : {C_NUM_S_LOG{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Select a new chosen when we need to arbitrate // If we don't have a new chosen, keep the old one since it's a good chance // that it will do another request always @(posedge ACLK) begin if (ARESET) begin chosen <= {C_NUM_S{1'b0}}; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; end else if (need_arbitration) begin chosen <= next_rr_hot; if (\|next_rr_hot) last_rr_hot <= next_rr_hot; end end assign valid_rr = S_VALID; ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ begin next_rr_hot = 0; for (i=0;i<C_NUM_S;i=i+1) begin n = (i>0) ? (i-1) : (C_NUM_S-1); carry_rr[iC_NUM_S] = last_rr_hot[n]; mask_rr[iC_NUM_S] = ~valid_rr[n]; for (j=1;j<C_NUM_S;j=j+1) begin n = (i-j > 0) ? (i-j-1) : (C_NUM_S+i-j-1); carry_rr[iC_NUM_S+j] = carry_rr[iC_NUM_S+j-1] \| (last_rr_hot[n] & mask_rr[iC_NUM_S+j-1]); if (j < C_NUM_S-1) begin mask_rr[iC_NUM_S+j] = mask_rr[iC_NUM_S+j-1] & ~valid_rr[n]; end end next_rr_hot[i] = valid_rr[i] & carry_rr[(i+1)C_NUM_S-1]; end end endmodule
module axi_crossbar_v2_1_arbiter_resp # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 4, // Number of requesting Slave ports = [2:16] parameter integer C_NUM_S_LOG = 2, // Log2(C_NUM_S) parameter integer C_GRANT_ENC = 0, // Enable encoded grant output parameter integer C_GRANT_HOT = 1 // Enable 1-hot grant output ) ( // Global Inputs input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_S-1:0] S_VALID, // Request from each slave output wire [C_NUM_S-1:0] S_READY, // Grant response to each slave // Master Ports output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, // Granted slave index (encoded) output wire [C_NUM_S-1:0] M_GRANT_HOT, // Granted slave index (1-hot) output wire M_VALID, // Grant event input wire M_READY ); // Generates a binary coded from onehotone encoded function [4:0] f_hot2enc ( input [16:0] one_hot ); begin f_hot2enc[0] = \|(one_hot & 17'b01010101010101010); f_hot2enc[1] = \|(one_hot & 17'b01100110011001100); f_hot2enc[2] = \|(one_hot & 17'b01111000011110000); f_hot2enc[3] = \|(one_hot & 17'b01111111100000000); f_hot2enc[4] = \|(one_hot & 17'b10000000000000000); end endfunction (* use_clock_enable = "yes" ) reg [C_NUM_S-1:0] chosen; wire [C_NUM_S-1:0] grant_hot; wire master_selected; wire active_master; wire need_arbitration; wire m_valid_i; wire [C_NUM_S-1:0] s_ready_i; wire access_done; reg [C_NUM_S-1:0] last_rr_hot; wire [C_NUM_S-1:0] valid_rr; reg [C_NUM_S-1:0] next_rr_hot; reg [C_NUM_SC_NUM_S-1:0] carry_rr; reg [C_NUM_SC_NUM_S-1:0] mask_rr; integer i; integer j; integer n; ///////////////////////////////////////////////////////////////////////////// // // Implementation of the arbiter outputs independant of arbitration // ///////////////////////////////////////////////////////////////////////////// // Mask the current requests with the chosen master assign grant_hot = chosen & S_VALID; // See if we have a selected master assign master_selected = \|grant_hot[0+:C_NUM_S]; // See if we have current requests assign active_master = \|S_VALID; // Access is completed assign access_done = m_valid_i & M_READY; // Need to handle if we drive S_ready combinatorial and without an IDLE state // Drive S_READY on the master who has been chosen when we get a M_READY assign s_ready_i = {C_NUM_S{M_READY}} & grant_hot[0+:C_NUM_S]; // Drive M_VALID if we have a selected master assign m_valid_i = master_selected; // If we have request and not a selected master, we need to arbitrate a new chosen assign need_arbitration = (active_master & ~master_selected) \| access_done; // need internal signals of the output signals assign M_VALID = m_valid_i; assign S_READY = s_ready_i; ///////////////////////////////////////////////////////////////////////////// // Assign conditional onehot target output signal. assign M_GRANT_HOT = (C_GRANT_HOT == 1) ? grant_hot[0+:C_NUM_S] : {C_NUM_S{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Assign conditional encoded target output signal. assign M_GRANT_ENC = (C_GRANT_ENC == 1) ? f_hot2enc(grant_hot) : {C_NUM_S_LOG{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Select a new chosen when we need to arbitrate // If we don't have a new chosen, keep the old one since it's a good chance // that it will do another request always @(posedge ACLK) begin if (ARESET) begin chosen <= {C_NUM_S{1'b0}}; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; end else if (need_arbitration) begin chosen <= next_rr_hot; if (\|next_rr_hot) last_rr_hot <= next_rr_hot; end end assign valid_rr = S_VALID; ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ begin next_rr_hot = 0; for (i=0;i<C_NUM_S;i=i+1) begin n = (i>0) ? (i-1) : (C_NUM_S-1); carry_rr[iC_NUM_S] = last_rr_hot[n]; mask_rr[iC_NUM_S] = ~valid_rr[n]; for (j=1;j<C_NUM_S;j=j+1) begin n = (i-j > 0) ? (i-j-1) : (C_NUM_S+i-j-1); carry_rr[iC_NUM_S+j] = carry_rr[iC_NUM_S+j-1] \| (last_rr_hot[n] & mask_rr[iC_NUM_S+j-1]); if (j < C_NUM_S-1) begin mask_rr[iC_NUM_S+j] = mask_rr[iC_NUM_S+j-1] & ~valid_rr[n]; end end next_rr_hot[i] = valid_rr[i] & carry_rr[(i+1)C_NUM_S-1]; end end endmodule
module axi_crossbar_v2_1_arbiter_resp # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 4, // Number of requesting Slave ports = [2:16] parameter integer C_NUM_S_LOG = 2, // Log2(C_NUM_S) parameter integer C_GRANT_ENC = 0, // Enable encoded grant output parameter integer C_GRANT_HOT = 1 // Enable 1-hot grant output ) ( // Global Inputs input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_S-1:0] S_VALID, // Request from each slave output wire [C_NUM_S-1:0] S_READY, // Grant response to each slave // Master Ports output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, // Granted slave index (encoded) output wire [C_NUM_S-1:0] M_GRANT_HOT, // Granted slave index (1-hot) output wire M_VALID, // Grant event input wire M_READY ); // Generates a binary coded from onehotone encoded function [4:0] f_hot2enc ( input [16:0] one_hot ); begin f_hot2enc[0] = \|(one_hot & 17'b01010101010101010); f_hot2enc[1] = \|(one_hot & 17'b01100110011001100); f_hot2enc[2] = \|(one_hot & 17'b01111000011110000); f_hot2enc[3] = \|(one_hot & 17'b01111111100000000); f_hot2enc[4] = \|(one_hot & 17'b10000000000000000); end endfunction (* use_clock_enable = "yes" ) reg [C_NUM_S-1:0] chosen; wire [C_NUM_S-1:0] grant_hot; wire master_selected; wire active_master; wire need_arbitration; wire m_valid_i; wire [C_NUM_S-1:0] s_ready_i; wire access_done; reg [C_NUM_S-1:0] last_rr_hot; wire [C_NUM_S-1:0] valid_rr; reg [C_NUM_S-1:0] next_rr_hot; reg [C_NUM_SC_NUM_S-1:0] carry_rr; reg [C_NUM_SC_NUM_S-1:0] mask_rr; integer i; integer j; integer n; ///////////////////////////////////////////////////////////////////////////// // // Implementation of the arbiter outputs independant of arbitration // ///////////////////////////////////////////////////////////////////////////// // Mask the current requests with the chosen master assign grant_hot = chosen & S_VALID; // See if we have a selected master assign master_selected = \|grant_hot[0+:C_NUM_S]; // See if we have current requests assign active_master = \|S_VALID; // Access is completed assign access_done = m_valid_i & M_READY; // Need to handle if we drive S_ready combinatorial and without an IDLE state // Drive S_READY on the master who has been chosen when we get a M_READY assign s_ready_i = {C_NUM_S{M_READY}} & grant_hot[0+:C_NUM_S]; // Drive M_VALID if we have a selected master assign m_valid_i = master_selected; // If we have request and not a selected master, we need to arbitrate a new chosen assign need_arbitration = (active_master & ~master_selected) \| access_done; // need internal signals of the output signals assign M_VALID = m_valid_i; assign S_READY = s_ready_i; ///////////////////////////////////////////////////////////////////////////// // Assign conditional onehot target output signal. assign M_GRANT_HOT = (C_GRANT_HOT == 1) ? grant_hot[0+:C_NUM_S] : {C_NUM_S{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Assign conditional encoded target output signal. assign M_GRANT_ENC = (C_GRANT_ENC == 1) ? f_hot2enc(grant_hot) : {C_NUM_S_LOG{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Select a new chosen when we need to arbitrate // If we don't have a new chosen, keep the old one since it's a good chance // that it will do another request always @(posedge ACLK) begin if (ARESET) begin chosen <= {C_NUM_S{1'b0}}; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; end else if (need_arbitration) begin chosen <= next_rr_hot; if (\|next_rr_hot) last_rr_hot <= next_rr_hot; end end assign valid_rr = S_VALID; ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ begin next_rr_hot = 0; for (i=0;i<C_NUM_S;i=i+1) begin n = (i>0) ? (i-1) : (C_NUM_S-1); carry_rr[iC_NUM_S] = last_rr_hot[n]; mask_rr[iC_NUM_S] = ~valid_rr[n]; for (j=1;j<C_NUM_S;j=j+1) begin n = (i-j > 0) ? (i-j-1) : (C_NUM_S+i-j-1); carry_rr[iC_NUM_S+j] = carry_rr[iC_NUM_S+j-1] \| (last_rr_hot[n] & mask_rr[iC_NUM_S+j-1]); if (j < C_NUM_S-1) begin mask_rr[iC_NUM_S+j] = mask_rr[iC_NUM_S+j-1] & ~valid_rr[n]; end end next_rr_hot[i] = valid_rr[i] & carry_rr[(i+1)C_NUM_S-1]; end end endmodule
module axi_crossbar_v2_1_arbiter_resp # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 4, // Number of requesting Slave ports = [2:16] parameter integer C_NUM_S_LOG = 2, // Log2(C_NUM_S) parameter integer C_GRANT_ENC = 0, // Enable encoded grant output parameter integer C_GRANT_HOT = 1 // Enable 1-hot grant output ) ( // Global Inputs input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_S-1:0] S_VALID, // Request from each slave output wire [C_NUM_S-1:0] S_READY, // Grant response to each slave // Master Ports output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, // Granted slave index (encoded) output wire [C_NUM_S-1:0] M_GRANT_HOT, // Granted slave index (1-hot) output wire M_VALID, // Grant event input wire M_READY ); // Generates a binary coded from onehotone encoded function [4:0] f_hot2enc ( input [16:0] one_hot ); begin f_hot2enc[0] = \|(one_hot & 17'b01010101010101010); f_hot2enc[1] = \|(one_hot & 17'b01100110011001100); f_hot2enc[2] = \|(one_hot & 17'b01111000011110000); f_hot2enc[3] = \|(one_hot & 17'b01111111100000000); f_hot2enc[4] = \|(one_hot & 17'b10000000000000000); end endfunction (* use_clock_enable = "yes" ) reg [C_NUM_S-1:0] chosen; wire [C_NUM_S-1:0] grant_hot; wire master_selected; wire active_master; wire need_arbitration; wire m_valid_i; wire [C_NUM_S-1:0] s_ready_i; wire access_done; reg [C_NUM_S-1:0] last_rr_hot; wire [C_NUM_S-1:0] valid_rr; reg [C_NUM_S-1:0] next_rr_hot; reg [C_NUM_SC_NUM_S-1:0] carry_rr; reg [C_NUM_SC_NUM_S-1:0] mask_rr; integer i; integer j; integer n; ///////////////////////////////////////////////////////////////////////////// // // Implementation of the arbiter outputs independant of arbitration // ///////////////////////////////////////////////////////////////////////////// // Mask the current requests with the chosen master assign grant_hot = chosen & S_VALID; // See if we have a selected master assign master_selected = \|grant_hot[0+:C_NUM_S]; // See if we have current requests assign active_master = \|S_VALID; // Access is completed assign access_done = m_valid_i & M_READY; // Need to handle if we drive S_ready combinatorial and without an IDLE state // Drive S_READY on the master who has been chosen when we get a M_READY assign s_ready_i = {C_NUM_S{M_READY}} & grant_hot[0+:C_NUM_S]; // Drive M_VALID if we have a selected master assign m_valid_i = master_selected; // If we have request and not a selected master, we need to arbitrate a new chosen assign need_arbitration = (active_master & ~master_selected) \| access_done; // need internal signals of the output signals assign M_VALID = m_valid_i; assign S_READY = s_ready_i; ///////////////////////////////////////////////////////////////////////////// // Assign conditional onehot target output signal. assign M_GRANT_HOT = (C_GRANT_HOT == 1) ? grant_hot[0+:C_NUM_S] : {C_NUM_S{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Assign conditional encoded target output signal. assign M_GRANT_ENC = (C_GRANT_ENC == 1) ? f_hot2enc(grant_hot) : {C_NUM_S_LOG{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Select a new chosen when we need to arbitrate // If we don't have a new chosen, keep the old one since it's a good chance // that it will do another request always @(posedge ACLK) begin if (ARESET) begin chosen <= {C_NUM_S{1'b0}}; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; end else if (need_arbitration) begin chosen <= next_rr_hot; if (\|next_rr_hot) last_rr_hot <= next_rr_hot; end end assign valid_rr = S_VALID; ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ begin next_rr_hot = 0; for (i=0;i<C_NUM_S;i=i+1) begin n = (i>0) ? (i-1) : (C_NUM_S-1); carry_rr[iC_NUM_S] = last_rr_hot[n]; mask_rr[iC_NUM_S] = ~valid_rr[n]; for (j=1;j<C_NUM_S;j=j+1) begin n = (i-j > 0) ? (i-j-1) : (C_NUM_S+i-j-1); carry_rr[iC_NUM_S+j] = carry_rr[iC_NUM_S+j-1] \| (last_rr_hot[n] & mask_rr[iC_NUM_S+j-1]); if (j < C_NUM_S-1) begin mask_rr[iC_NUM_S+j] = mask_rr[iC_NUM_S+j-1] & ~valid_rr[n]; end end next_rr_hot[i] = valid_rr[i] & carry_rr[(i+1)C_NUM_S-1]; end end endmodule
module processing_system7_bfm_v2_0_5_ocm_mem(); `include "processing_system7_bfm_v2_0_5_local_params.v" parameter mem_size = 32'h4_0000; /// 256 KB parameter mem_addr_width = clogb2(mem_size/mem_width); reg [data_width-1:0] ocm_memory [0:(mem_size/mem_width)-1]; /// 256 KB memory /* preload memory from file / task automatic pre_load_mem_from_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; $readmemh(file_name,ocm_memory,start_addr>>shft_addr_bits); endtask /* preload memory with some random data / task automatic pre_load_mem; input [1:0] data_type; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer i; reg [mem_addr_width-1:0] addr; begin addr = start_addr >> shft_addr_bits; for (i = 0; i < no_of_bytes; i = i + mem_width) begin case(data_type) ALL_RANDOM : ocm_memory[addr] = $random; ALL_ZEROS : ocm_memory[addr] = 32'h0000_0000; ALL_ONES : ocm_memory[addr] = 32'hFFFF_FFFF; default : ocm_memory[addr] = $random; endcase addr = addr+1; end end endtask / Write memory / task write_mem; input [max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; reg [mem_addr_width-1:0] addr; reg [max_burst_bits-1 :0] wr_temp_data; reg [data_width-1:0] pre_pad_data,post_pad_data,temp_data; integer bytes_left; integer pre_pad_bytes; integer post_pad_bytes; begin addr = start_addr >> shft_addr_bits; wr_temp_data = data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Writing OCM Memory starting address (0x%0h) with %0d bytes.\n Data (0x%0h)",$time, DISP_INT_INFO, start_addr, no_of_bytes, data); `endif temp_data = wr_temp_data[data_width-1:0]; bytes_left = no_of_bytes; / when the no. of bytes to be updated is less than mem_width / if(bytes_left < mem_width) begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin temp_data = ocm_memory[addr]; pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; end bytes_left = bytes_left + pre_pad_bytes; end / This is needed for post padding the data .../ post_pad_bytes = mem_width - bytes_left; post_pad_data = ocm_memory[addr]; repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end ocm_memory[addr] = temp_data; end else begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin temp_data = ocm_memory[addr]; pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; bytes_left = bytes_left -1; end end else begin wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end / first data word end / ocm_memory[addr] = temp_data; addr = addr + 1; while(bytes_left > (mem_width-1) ) begin /// for unaliged address necessary to check for mem_wd-1 , accordingly we have to pad post bytes. ocm_memory[addr] = wr_temp_data[data_width-1:0]; addr = addr+1; wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end post_pad_data = ocm_memory[addr]; post_pad_bytes = mem_width - bytes_left; / This is needed for last transfer in unaliged burst / if(bytes_left > 0) begin temp_data = wr_temp_data[data_width-1:0]; repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end ocm_memory[addr] = temp_data; end end `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Writing OCM Memory starting address (0x%0h)",$time, DISP_INT_INFO, start_addr ); `endif end endtask / read_memory / task read_mem; output[max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; integer i; reg [mem_addr_width-1:0] addr; reg [data_width-1:0] temp_rd_data; reg [max_burst_bits-1:0] temp_data; integer pre_bytes; integer bytes_left; begin addr = start_addr >> shft_addr_bits; pre_bytes = start_addr[shft_addr_bits-1:0]; bytes_left = no_of_bytes; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Reading OCM Memory starting address (0x%0h) -> %0d bytes",$time, DISP_INT_INFO, start_addr,no_of_bytes ); `endif / Get first data ... if unaligned address / temp_data[max_burst_bits-1 : max_burst_bits-data_width] = ocm_memory[addr]; if(no_of_bytes < mem_width ) begin temp_data = temp_data >> (pre_bytes 8); repeat(max_burst_bytes - mem_width) temp_data = temp_data >> 8; end else begin bytes_left = bytes_left - (mem_width - pre_bytes); addr = addr+1; /* Got first data / while (bytes_left > (mem_width-1) ) begin temp_data = temp_data >> data_width; temp_data[max_burst_bits-1 : max_burst_bits-data_width] = ocm_memory[addr]; addr = addr+1; bytes_left = bytes_left - mem_width; end / Get last valid data in the burst/ temp_rd_data = ocm_memory[addr]; while(bytes_left > 0) begin temp_data = temp_data >> 8; temp_data[max_burst_bits-1 : max_burst_bits-8] = temp_rd_data[7:0]; temp_rd_data = temp_rd_data >> 8; bytes_left = bytes_left - 1; end / align to the brst_byte length / repeat(max_burst_bytes - no_of_bytes) temp_data = temp_data >> 8; end data = temp_data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Reading OCM Memory starting address (0x%0h), Data returned(0x%0h)",$time, DISP_INT_INFO, start_addr, data ); `endif end endtask / backdoor read to memory / task peek_mem_to_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer rd_fd; integer bytes; reg [addr_width-1:0] addr; reg [data_width-1:0] rd_data; begin rd_fd = $fopen(file_name,"w"); bytes = no_of_bytes; addr = start_addr >> shft_addr_bits; while (bytes > 0) begin rd_data = ocm_memory[addr]; $fdisplayh(rd_fd,rd_data); bytes = bytes - 4; addr = addr + 1; end end endtask endmodule
module processing_system7_bfm_v2_0_5_sparse_mem(); `include "processing_system7_bfm_v2_0_5_local_params.v" parameter mem_size = 32'h4000_0000; /// 1GB mem size parameter xsim_mem_size = 32'h1000_0000; ///256 MB mem size (x4 for XSIM/ISIM) `ifdef XSIM_ISIM reg [data_width-1:0] ddr_mem0 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem1 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem2 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem3 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem `else reg /sparse/ [data_width-1:0] ddr_mem [0:(mem_size/mem_width)-1]; // 'h10_0000 to 'h3FFF_FFFF - 1G mem `endif event mem_updated; reg check_we; reg [addr_width-1:0] check_up_add; reg [data_width-1:0] updated_data; /* preload memory from file / task automatic pre_load_mem_from_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; `ifdef XSIM_ISIM case(start_addr[31:28]) 4'd0 : $readmemh(file_name,ddr_mem0,start_addr>>shft_addr_bits); 4'd1 : $readmemh(file_name,ddr_mem1,start_addr>>shft_addr_bits); 4'd2 : $readmemh(file_name,ddr_mem2,start_addr>>shft_addr_bits); 4'd3 : $readmemh(file_name,ddr_mem3,start_addr>>shft_addr_bits); endcase `else $readmemh(file_name,ddr_mem,start_addr>>shft_addr_bits); `endif endtask /* preload memory with some random data / task automatic pre_load_mem; input [1:0] data_type; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer i; reg [addr_width-1:0] addr; begin addr = start_addr >> shft_addr_bits; for (i = 0; i < no_of_bytes; i = i + mem_width) begin case(data_type) ALL_RANDOM : set_data(addr , $random); ALL_ZEROS : set_data(addr , 32'h0000_0000); ALL_ONES : set_data(addr , 32'hFFFF_FFFF); default : set_data(addr , $random); endcase addr = addr+1; end end endtask / wait for memory update at certain location / task automatic wait_mem_update; input[addr_width-1:0] address; output[data_width-1:0] dataout; begin check_up_add = address >> shft_addr_bits; check_we = 1; @(mem_updated); dataout = updated_data; check_we = 0; end endtask / internal task to write data in memory / task automatic set_data; input [addr_width-1:0] addr; input [data_width-1:0] data; begin if(check_we && (addr === check_up_add)) begin updated_data = data; -> mem_updated; end `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : ddr_mem0[addr[25:0]] = data; 6'd1 : ddr_mem1[addr[25:0]] = data; 6'd2 : ddr_mem2[addr[25:0]] = data; 6'd3 : ddr_mem3[addr[25:0]] = data; endcase `else ddr_mem[addr] = data; `endif end endtask / internal task to read data from memory / task automatic get_data; input [addr_width-1:0] addr; output [data_width-1:0] data; begin `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : data = ddr_mem0[addr[25:0]]; 6'd1 : data = ddr_mem1[addr[25:0]]; 6'd2 : data = ddr_mem2[addr[25:0]]; 6'd3 : data = ddr_mem3[addr[25:0]]; endcase `else data = ddr_mem[addr]; `endif end endtask / Write memory / task write_mem; input [max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; reg [addr_width-1:0] addr; reg [max_burst_bits-1 :0] wr_temp_data; reg [data_width-1:0] pre_pad_data,post_pad_data,temp_data; integer bytes_left; integer pre_pad_bytes; integer post_pad_bytes; begin addr = start_addr >> shft_addr_bits; wr_temp_data = data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Writing DDR Memory starting address (0x%0h) with %0d bytes.\n Data (0x%0h)",$time, DISP_INT_INFO, start_addr, no_of_bytes, data); `endif temp_data = wr_temp_data[data_width-1:0]; bytes_left = no_of_bytes; / when the no. of bytes to be updated is less than mem_width / if(bytes_left < mem_width) begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; end bytes_left = bytes_left + pre_pad_bytes; end / This is needed for post padding the data .../ post_pad_bytes = mem_width - bytes_left; //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end else begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; bytes_left = bytes_left -1; end end else begin wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end / first data word end / //ddr_mem[addr] = temp_data; set_data(addr,temp_data); addr = addr + 1; while(bytes_left > (mem_width-1) ) begin /// for unaliged address necessary to check for mem_wd-1 , accordingly we have to pad post bytes. //ddr_mem[addr] = wr_temp_data[data_width-1:0]; set_data(addr,wr_temp_data[data_width-1:0]); addr = addr+1; wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); post_pad_bytes = mem_width - bytes_left; / This is needed for last transfer in unaliged burst / if(bytes_left > 0) begin temp_data = wr_temp_data[data_width-1:0]; repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end end `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Writing DDR Memory starting address (0x%0h)",$time, DISP_INT_INFO, start_addr ); `endif end endtask / read_memory / task read_mem; output[max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width :0] no_of_bytes; integer i; reg [addr_width-1:0] addr; reg [data_width-1:0] temp_rd_data; reg [max_burst_bits-1:0] temp_data; integer pre_bytes; integer bytes_left; begin addr = start_addr >> shft_addr_bits; pre_bytes = start_addr[shft_addr_bits-1:0]; bytes_left = no_of_bytes; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Reading DDR Memory starting address (0x%0h) -> %0d bytes",$time, DISP_INT_INFO, start_addr,no_of_bytes ); `endif / Get first data ... if unaligned address / //temp_data[(max_burst max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); if(no_of_bytes < mem_width ) begin temp_data = temp_data >> (pre_bytes * 8); repeat(max_burst_bytes - mem_width) temp_data = temp_data >> 8; end else begin bytes_left = bytes_left - (mem_width - pre_bytes); addr = addr+1; /* Got first data / while (bytes_left > (mem_width-1) ) begin temp_data = temp_data >> data_width; //temp_data[(max_burst max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); addr = addr+1; bytes_left = bytes_left - mem_width; end /* Get last valid data in the burst/ //temp_rd_data = ddr_mem[addr]; get_data(addr,temp_rd_data); while(bytes_left > 0) begin temp_data = temp_data >> 8; temp_data[max_burst_bits-1 : max_burst_bits-8] = temp_rd_data[7:0]; temp_rd_data = temp_rd_data >> 8; bytes_left = bytes_left - 1; end / align to the brst_byte length / repeat(max_burst_bytes - no_of_bytes) temp_data = temp_data >> 8; end data = temp_data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Reading DDR Memory starting address (0x%0h), Data returned(0x%0h)",$time, DISP_INT_INFO, start_addr, data ); `endif end endtask / backdoor read to memory / task peek_mem_to_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer rd_fd; integer bytes; reg [addr_width-1:0] addr; reg [data_width-1:0] rd_data; begin rd_fd = $fopen(file_name,"w"); bytes = no_of_bytes; addr = start_addr >> shft_addr_bits; while (bytes > 0) begin get_data(addr,rd_data); $fdisplayh(rd_fd,rd_data); bytes = bytes - 4; addr = addr + 1; end end endtask endmodule
module processing_system7_bfm_v2_0_5_sparse_mem(); `include "processing_system7_bfm_v2_0_5_local_params.v" parameter mem_size = 32'h4000_0000; /// 1GB mem size parameter xsim_mem_size = 32'h1000_0000; ///256 MB mem size (x4 for XSIM/ISIM) `ifdef XSIM_ISIM reg [data_width-1:0] ddr_mem0 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem1 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem2 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem3 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem `else reg /sparse/ [data_width-1:0] ddr_mem [0:(mem_size/mem_width)-1]; // 'h10_0000 to 'h3FFF_FFFF - 1G mem `endif event mem_updated; reg check_we; reg [addr_width-1:0] check_up_add; reg [data_width-1:0] updated_data; /* preload memory from file / task automatic pre_load_mem_from_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; `ifdef XSIM_ISIM case(start_addr[31:28]) 4'd0 : $readmemh(file_name,ddr_mem0,start_addr>>shft_addr_bits); 4'd1 : $readmemh(file_name,ddr_mem1,start_addr>>shft_addr_bits); 4'd2 : $readmemh(file_name,ddr_mem2,start_addr>>shft_addr_bits); 4'd3 : $readmemh(file_name,ddr_mem3,start_addr>>shft_addr_bits); endcase `else $readmemh(file_name,ddr_mem,start_addr>>shft_addr_bits); `endif endtask /* preload memory with some random data / task automatic pre_load_mem; input [1:0] data_type; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer i; reg [addr_width-1:0] addr; begin addr = start_addr >> shft_addr_bits; for (i = 0; i < no_of_bytes; i = i + mem_width) begin case(data_type) ALL_RANDOM : set_data(addr , $random); ALL_ZEROS : set_data(addr , 32'h0000_0000); ALL_ONES : set_data(addr , 32'hFFFF_FFFF); default : set_data(addr , $random); endcase addr = addr+1; end end endtask / wait for memory update at certain location / task automatic wait_mem_update; input[addr_width-1:0] address; output[data_width-1:0] dataout; begin check_up_add = address >> shft_addr_bits; check_we = 1; @(mem_updated); dataout = updated_data; check_we = 0; end endtask / internal task to write data in memory / task automatic set_data; input [addr_width-1:0] addr; input [data_width-1:0] data; begin if(check_we && (addr === check_up_add)) begin updated_data = data; -> mem_updated; end `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : ddr_mem0[addr[25:0]] = data; 6'd1 : ddr_mem1[addr[25:0]] = data; 6'd2 : ddr_mem2[addr[25:0]] = data; 6'd3 : ddr_mem3[addr[25:0]] = data; endcase `else ddr_mem[addr] = data; `endif end endtask / internal task to read data from memory / task automatic get_data; input [addr_width-1:0] addr; output [data_width-1:0] data; begin `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : data = ddr_mem0[addr[25:0]]; 6'd1 : data = ddr_mem1[addr[25:0]]; 6'd2 : data = ddr_mem2[addr[25:0]]; 6'd3 : data = ddr_mem3[addr[25:0]]; endcase `else data = ddr_mem[addr]; `endif end endtask / Write memory / task write_mem; input [max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; reg [addr_width-1:0] addr; reg [max_burst_bits-1 :0] wr_temp_data; reg [data_width-1:0] pre_pad_data,post_pad_data,temp_data; integer bytes_left; integer pre_pad_bytes; integer post_pad_bytes; begin addr = start_addr >> shft_addr_bits; wr_temp_data = data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Writing DDR Memory starting address (0x%0h) with %0d bytes.\n Data (0x%0h)",$time, DISP_INT_INFO, start_addr, no_of_bytes, data); `endif temp_data = wr_temp_data[data_width-1:0]; bytes_left = no_of_bytes; / when the no. of bytes to be updated is less than mem_width / if(bytes_left < mem_width) begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; end bytes_left = bytes_left + pre_pad_bytes; end / This is needed for post padding the data .../ post_pad_bytes = mem_width - bytes_left; //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end else begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; bytes_left = bytes_left -1; end end else begin wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end / first data word end / //ddr_mem[addr] = temp_data; set_data(addr,temp_data); addr = addr + 1; while(bytes_left > (mem_width-1) ) begin /// for unaliged address necessary to check for mem_wd-1 , accordingly we have to pad post bytes. //ddr_mem[addr] = wr_temp_data[data_width-1:0]; set_data(addr,wr_temp_data[data_width-1:0]); addr = addr+1; wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); post_pad_bytes = mem_width - bytes_left; / This is needed for last transfer in unaliged burst / if(bytes_left > 0) begin temp_data = wr_temp_data[data_width-1:0]; repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end end `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Writing DDR Memory starting address (0x%0h)",$time, DISP_INT_INFO, start_addr ); `endif end endtask / read_memory / task read_mem; output[max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width :0] no_of_bytes; integer i; reg [addr_width-1:0] addr; reg [data_width-1:0] temp_rd_data; reg [max_burst_bits-1:0] temp_data; integer pre_bytes; integer bytes_left; begin addr = start_addr >> shft_addr_bits; pre_bytes = start_addr[shft_addr_bits-1:0]; bytes_left = no_of_bytes; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Reading DDR Memory starting address (0x%0h) -> %0d bytes",$time, DISP_INT_INFO, start_addr,no_of_bytes ); `endif / Get first data ... if unaligned address / //temp_data[(max_burst max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); if(no_of_bytes < mem_width ) begin temp_data = temp_data >> (pre_bytes * 8); repeat(max_burst_bytes - mem_width) temp_data = temp_data >> 8; end else begin bytes_left = bytes_left - (mem_width - pre_bytes); addr = addr+1; /* Got first data / while (bytes_left > (mem_width-1) ) begin temp_data = temp_data >> data_width; //temp_data[(max_burst max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); addr = addr+1; bytes_left = bytes_left - mem_width; end /* Get last valid data in the burst/ //temp_rd_data = ddr_mem[addr]; get_data(addr,temp_rd_data); while(bytes_left > 0) begin temp_data = temp_data >> 8; temp_data[max_burst_bits-1 : max_burst_bits-8] = temp_rd_data[7:0]; temp_rd_data = temp_rd_data >> 8; bytes_left = bytes_left - 1; end / align to the brst_byte length / repeat(max_burst_bytes - no_of_bytes) temp_data = temp_data >> 8; end data = temp_data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Reading DDR Memory starting address (0x%0h), Data returned(0x%0h)",$time, DISP_INT_INFO, start_addr, data ); `endif end endtask / backdoor read to memory / task peek_mem_to_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer rd_fd; integer bytes; reg [addr_width-1:0] addr; reg [data_width-1:0] rd_data; begin rd_fd = $fopen(file_name,"w"); bytes = no_of_bytes; addr = start_addr >> shft_addr_bits; while (bytes > 0) begin get_data(addr,rd_data); $fdisplayh(rd_fd,rd_data); bytes = bytes - 4; addr = addr + 1; end end endtask endmodule
module processing_system7_bfm_v2_0_5_sparse_mem(); `include "processing_system7_bfm_v2_0_5_local_params.v" parameter mem_size = 32'h4000_0000; /// 1GB mem size parameter xsim_mem_size = 32'h1000_0000; ///256 MB mem size (x4 for XSIM/ISIM) `ifdef XSIM_ISIM reg [data_width-1:0] ddr_mem0 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem1 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem2 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem3 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem `else reg /sparse/ [data_width-1:0] ddr_mem [0:(mem_size/mem_width)-1]; // 'h10_0000 to 'h3FFF_FFFF - 1G mem `endif event mem_updated; reg check_we; reg [addr_width-1:0] check_up_add; reg [data_width-1:0] updated_data; /* preload memory from file / task automatic pre_load_mem_from_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; `ifdef XSIM_ISIM case(start_addr[31:28]) 4'd0 : $readmemh(file_name,ddr_mem0,start_addr>>shft_addr_bits); 4'd1 : $readmemh(file_name,ddr_mem1,start_addr>>shft_addr_bits); 4'd2 : $readmemh(file_name,ddr_mem2,start_addr>>shft_addr_bits); 4'd3 : $readmemh(file_name,ddr_mem3,start_addr>>shft_addr_bits); endcase `else $readmemh(file_name,ddr_mem,start_addr>>shft_addr_bits); `endif endtask /* preload memory with some random data / task automatic pre_load_mem; input [1:0] data_type; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer i; reg [addr_width-1:0] addr; begin addr = start_addr >> shft_addr_bits; for (i = 0; i < no_of_bytes; i = i + mem_width) begin case(data_type) ALL_RANDOM : set_data(addr , $random); ALL_ZEROS : set_data(addr , 32'h0000_0000); ALL_ONES : set_data(addr , 32'hFFFF_FFFF); default : set_data(addr , $random); endcase addr = addr+1; end end endtask / wait for memory update at certain location / task automatic wait_mem_update; input[addr_width-1:0] address; output[data_width-1:0] dataout; begin check_up_add = address >> shft_addr_bits; check_we = 1; @(mem_updated); dataout = updated_data; check_we = 0; end endtask / internal task to write data in memory / task automatic set_data; input [addr_width-1:0] addr; input [data_width-1:0] data; begin if(check_we && (addr === check_up_add)) begin updated_data = data; -> mem_updated; end `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : ddr_mem0[addr[25:0]] = data; 6'd1 : ddr_mem1[addr[25:0]] = data; 6'd2 : ddr_mem2[addr[25:0]] = data; 6'd3 : ddr_mem3[addr[25:0]] = data; endcase `else ddr_mem[addr] = data; `endif end endtask / internal task to read data from memory / task automatic get_data; input [addr_width-1:0] addr; output [data_width-1:0] data; begin `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : data = ddr_mem0[addr[25:0]]; 6'd1 : data = ddr_mem1[addr[25:0]]; 6'd2 : data = ddr_mem2[addr[25:0]]; 6'd3 : data = ddr_mem3[addr[25:0]]; endcase `else data = ddr_mem[addr]; `endif end endtask / Write memory / task write_mem; input [max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; reg [addr_width-1:0] addr; reg [max_burst_bits-1 :0] wr_temp_data; reg [data_width-1:0] pre_pad_data,post_pad_data,temp_data; integer bytes_left; integer pre_pad_bytes; integer post_pad_bytes; begin addr = start_addr >> shft_addr_bits; wr_temp_data = data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Writing DDR Memory starting address (0x%0h) with %0d bytes.\n Data (0x%0h)",$time, DISP_INT_INFO, start_addr, no_of_bytes, data); `endif temp_data = wr_temp_data[data_width-1:0]; bytes_left = no_of_bytes; / when the no. of bytes to be updated is less than mem_width / if(bytes_left < mem_width) begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; end bytes_left = bytes_left + pre_pad_bytes; end / This is needed for post padding the data .../ post_pad_bytes = mem_width - bytes_left; //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end else begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; bytes_left = bytes_left -1; end end else begin wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end / first data word end / //ddr_mem[addr] = temp_data; set_data(addr,temp_data); addr = addr + 1; while(bytes_left > (mem_width-1) ) begin /// for unaliged address necessary to check for mem_wd-1 , accordingly we have to pad post bytes. //ddr_mem[addr] = wr_temp_data[data_width-1:0]; set_data(addr,wr_temp_data[data_width-1:0]); addr = addr+1; wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); post_pad_bytes = mem_width - bytes_left; / This is needed for last transfer in unaliged burst / if(bytes_left > 0) begin temp_data = wr_temp_data[data_width-1:0]; repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end end `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Writing DDR Memory starting address (0x%0h)",$time, DISP_INT_INFO, start_addr ); `endif end endtask / read_memory / task read_mem; output[max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width :0] no_of_bytes; integer i; reg [addr_width-1:0] addr; reg [data_width-1:0] temp_rd_data; reg [max_burst_bits-1:0] temp_data; integer pre_bytes; integer bytes_left; begin addr = start_addr >> shft_addr_bits; pre_bytes = start_addr[shft_addr_bits-1:0]; bytes_left = no_of_bytes; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Reading DDR Memory starting address (0x%0h) -> %0d bytes",$time, DISP_INT_INFO, start_addr,no_of_bytes ); `endif / Get first data ... if unaligned address / //temp_data[(max_burst max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); if(no_of_bytes < mem_width ) begin temp_data = temp_data >> (pre_bytes * 8); repeat(max_burst_bytes - mem_width) temp_data = temp_data >> 8; end else begin bytes_left = bytes_left - (mem_width - pre_bytes); addr = addr+1; /* Got first data / while (bytes_left > (mem_width-1) ) begin temp_data = temp_data >> data_width; //temp_data[(max_burst max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); addr = addr+1; bytes_left = bytes_left - mem_width; end /* Get last valid data in the burst/ //temp_rd_data = ddr_mem[addr]; get_data(addr,temp_rd_data); while(bytes_left > 0) begin temp_data = temp_data >> 8; temp_data[max_burst_bits-1 : max_burst_bits-8] = temp_rd_data[7:0]; temp_rd_data = temp_rd_data >> 8; bytes_left = bytes_left - 1; end / align to the brst_byte length / repeat(max_burst_bytes - no_of_bytes) temp_data = temp_data >> 8; end data = temp_data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Reading DDR Memory starting address (0x%0h), Data returned(0x%0h)",$time, DISP_INT_INFO, start_addr, data ); `endif end endtask / backdoor read to memory / task peek_mem_to_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer rd_fd; integer bytes; reg [addr_width-1:0] addr; reg [data_width-1:0] rd_data; begin rd_fd = $fopen(file_name,"w"); bytes = no_of_bytes; addr = start_addr >> shft_addr_bits; while (bytes > 0) begin get_data(addr,rd_data); $fdisplayh(rd_fd,rd_data); bytes = bytes - 4; addr = addr + 1; end end endtask endmodule
module processing_system7_bfm_v2_0_5_sparse_mem(); `include "processing_system7_bfm_v2_0_5_local_params.v" parameter mem_size = 32'h4000_0000; /// 1GB mem size parameter xsim_mem_size = 32'h1000_0000; ///256 MB mem size (x4 for XSIM/ISIM) `ifdef XSIM_ISIM reg [data_width-1:0] ddr_mem0 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem1 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem2 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem3 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem `else reg /sparse/ [data_width-1:0] ddr_mem [0:(mem_size/mem_width)-1]; // 'h10_0000 to 'h3FFF_FFFF - 1G mem `endif event mem_updated; reg check_we; reg [addr_width-1:0] check_up_add; reg [data_width-1:0] updated_data; /* preload memory from file / task automatic pre_load_mem_from_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; `ifdef XSIM_ISIM case(start_addr[31:28]) 4'd0 : $readmemh(file_name,ddr_mem0,start_addr>>shft_addr_bits); 4'd1 : $readmemh(file_name,ddr_mem1,start_addr>>shft_addr_bits); 4'd2 : $readmemh(file_name,ddr_mem2,start_addr>>shft_addr_bits); 4'd3 : $readmemh(file_name,ddr_mem3,start_addr>>shft_addr_bits); endcase `else $readmemh(file_name,ddr_mem,start_addr>>shft_addr_bits); `endif endtask /* preload memory with some random data / task automatic pre_load_mem; input [1:0] data_type; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer i; reg [addr_width-1:0] addr; begin addr = start_addr >> shft_addr_bits; for (i = 0; i < no_of_bytes; i = i + mem_width) begin case(data_type) ALL_RANDOM : set_data(addr , $random); ALL_ZEROS : set_data(addr , 32'h0000_0000); ALL_ONES : set_data(addr , 32'hFFFF_FFFF); default : set_data(addr , $random); endcase addr = addr+1; end end endtask / wait for memory update at certain location / task automatic wait_mem_update; input[addr_width-1:0] address; output[data_width-1:0] dataout; begin check_up_add = address >> shft_addr_bits; check_we = 1; @(mem_updated); dataout = updated_data; check_we = 0; end endtask / internal task to write data in memory / task automatic set_data; input [addr_width-1:0] addr; input [data_width-1:0] data; begin if(check_we && (addr === check_up_add)) begin updated_data = data; -> mem_updated; end `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : ddr_mem0[addr[25:0]] = data; 6'd1 : ddr_mem1[addr[25:0]] = data; 6'd2 : ddr_mem2[addr[25:0]] = data; 6'd3 : ddr_mem3[addr[25:0]] = data; endcase `else ddr_mem[addr] = data; `endif end endtask / internal task to read data from memory / task automatic get_data; input [addr_width-1:0] addr; output [data_width-1:0] data; begin `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : data = ddr_mem0[addr[25:0]]; 6'd1 : data = ddr_mem1[addr[25:0]]; 6'd2 : data = ddr_mem2[addr[25:0]]; 6'd3 : data = ddr_mem3[addr[25:0]]; endcase `else data = ddr_mem[addr]; `endif end endtask / Write memory / task write_mem; input [max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; reg [addr_width-1:0] addr; reg [max_burst_bits-1 :0] wr_temp_data; reg [data_width-1:0] pre_pad_data,post_pad_data,temp_data; integer bytes_left; integer pre_pad_bytes; integer post_pad_bytes; begin addr = start_addr >> shft_addr_bits; wr_temp_data = data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Writing DDR Memory starting address (0x%0h) with %0d bytes.\n Data (0x%0h)",$time, DISP_INT_INFO, start_addr, no_of_bytes, data); `endif temp_data = wr_temp_data[data_width-1:0]; bytes_left = no_of_bytes; / when the no. of bytes to be updated is less than mem_width / if(bytes_left < mem_width) begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; end bytes_left = bytes_left + pre_pad_bytes; end / This is needed for post padding the data .../ post_pad_bytes = mem_width - bytes_left; //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end else begin / first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; bytes_left = bytes_left -1; end end else begin wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end / first data word end / //ddr_mem[addr] = temp_data; set_data(addr,temp_data); addr = addr + 1; while(bytes_left > (mem_width-1) ) begin /// for unaliged address necessary to check for mem_wd-1 , accordingly we have to pad post bytes. //ddr_mem[addr] = wr_temp_data[data_width-1:0]; set_data(addr,wr_temp_data[data_width-1:0]); addr = addr+1; wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); post_pad_bytes = mem_width - bytes_left; / This is needed for last transfer in unaliged burst / if(bytes_left > 0) begin temp_data = wr_temp_data[data_width-1:0]; repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end end `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Writing DDR Memory starting address (0x%0h)",$time, DISP_INT_INFO, start_addr ); `endif end endtask / read_memory / task read_mem; output[max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width :0] no_of_bytes; integer i; reg [addr_width-1:0] addr; reg [data_width-1:0] temp_rd_data; reg [max_burst_bits-1:0] temp_data; integer pre_bytes; integer bytes_left; begin addr = start_addr >> shft_addr_bits; pre_bytes = start_addr[shft_addr_bits-1:0]; bytes_left = no_of_bytes; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Reading DDR Memory starting address (0x%0h) -> %0d bytes",$time, DISP_INT_INFO, start_addr,no_of_bytes ); `endif / Get first data ... if unaligned address / //temp_data[(max_burst max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); if(no_of_bytes < mem_width ) begin temp_data = temp_data >> (pre_bytes * 8); repeat(max_burst_bytes - mem_width) temp_data = temp_data >> 8; end else begin bytes_left = bytes_left - (mem_width - pre_bytes); addr = addr+1; /* Got first data / while (bytes_left > (mem_width-1) ) begin temp_data = temp_data >> data_width; //temp_data[(max_burst max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); addr = addr+1; bytes_left = bytes_left - mem_width; end /* Get last valid data in the burst/ //temp_rd_data = ddr_mem[addr]; get_data(addr,temp_rd_data); while(bytes_left > 0) begin temp_data = temp_data >> 8; temp_data[max_burst_bits-1 : max_burst_bits-8] = temp_rd_data[7:0]; temp_rd_data = temp_rd_data >> 8; bytes_left = bytes_left - 1; end / align to the brst_byte length / repeat(max_burst_bytes - no_of_bytes) temp_data = temp_data >> 8; end data = temp_data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Reading DDR Memory starting address (0x%0h), Data returned(0x%0h)",$time, DISP_INT_INFO, start_addr, data ); `endif end endtask / backdoor read to memory / task peek_mem_to_file; input [(max_chars8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer rd_fd; integer bytes; reg [addr_width-1:0] addr; reg [data_width-1:0] rd_data; begin rd_fd = $fopen(file_name,"w"); bytes = no_of_bytes; addr = start_addr >> shft_addr_bits; while (bytes > 0) begin get_data(addr,rd_data); $fdisplayh(rd_fd,rd_data); bytes = bytes - 4; addr = addr + 1; end end endtask endmodule
module wishbone_mem_interconnect ( //Control Signals input clk, input rst, //Master Signals input i_m_we, input i_m_stb, input i_m_cyc, input [3:0] i_m_sel, input [31:0] i_m_adr, input [31:0] i_m_dat, output reg [31:0] o_m_dat, output reg o_m_ack, output reg o_m_int, //Slave 0 output o_s0_we, output o_s0_cyc, output o_s0_stb, output [3:0] o_s0_sel, input i_s0_ack, output [31:0] o_s0_dat, input [31:0] i_s0_dat, output [31:0] o_s0_adr, input i_s0_int ); parameter MEM_SEL_0 = 0; parameter MEM_OFFSET_0 = 0; parameter MEM_SIZE_0 = 8388607; reg [31:0] mem_select; always @(rst or i_m_adr or mem_select) begin if (rst) begin //nothing selected mem_select <= 32'hFFFFFFFF; end else begin if ((i_m_adr >= MEM_OFFSET_0) && (i_m_adr < (MEM_OFFSET_0 + MEM_SIZE_0))) begin mem_select <= MEM_SEL_0; end else begin mem_select <= 32'hFFFFFFFF; end end end //data in from slave always @ (mem_select or i_s0_dat) begin case (mem_select) MEM_SEL_0: begin o_m_dat <= i_s0_dat; end default: begin o_m_dat <= 32'h0000; end endcase end //ack in from mem slave always @ (mem_select or i_s0_ack) begin case (mem_select) MEM_SEL_0: begin o_m_ack <= i_s0_ack; end default: begin o_m_ack <= 1'h0; end endcase end //int in from slave always @ (mem_select or i_s0_int) begin case (mem_select) MEM_SEL_0: begin o_m_int <= i_s0_int; end default: begin o_m_int <= 1'h0; end endcase end assign o_s0_we = (mem_select == MEM_SEL_0) ? i_m_we: 1'b0; assign o_s0_stb = (mem_select == MEM_SEL_0) ? i_m_stb: 1'b0; assign o_s0_sel = (mem_select == MEM_SEL_0) ? i_m_sel: 4'b0; assign o_s0_cyc = (mem_select == MEM_SEL_0) ? i_m_cyc: 1'b0; assign o_s0_adr = (mem_select == MEM_SEL_0) ? i_m_adr: 32'h0; assign o_s0_dat = (mem_select == MEM_SEL_0) ? i_m_dat: 32'h0; endmodule
module wishbone_mem_interconnect ( //Control Signals input clk, input rst, //Master Signals input i_m_we, input i_m_stb, input i_m_cyc, input [3:0] i_m_sel, input [31:0] i_m_adr, input [31:0] i_m_dat, output reg [31:0] o_m_dat, output reg o_m_ack, output reg o_m_int, //Slave 0 output o_s0_we, output o_s0_cyc, output o_s0_stb, output [3:0] o_s0_sel, input i_s0_ack, output [31:0] o_s0_dat, input [31:0] i_s0_dat, output [31:0] o_s0_adr, input i_s0_int ); parameter MEM_SEL_0 = 0; parameter MEM_OFFSET_0 = 0; parameter MEM_SIZE_0 = 8388607; reg [31:0] mem_select; always @(rst or i_m_adr or mem_select) begin if (rst) begin //nothing selected mem_select <= 32'hFFFFFFFF; end else begin if ((i_m_adr >= MEM_OFFSET_0) && (i_m_adr < (MEM_OFFSET_0 + MEM_SIZE_0))) begin mem_select <= MEM_SEL_0; end else begin mem_select <= 32'hFFFFFFFF; end end end //data in from slave always @ (mem_select or i_s0_dat) begin case (mem_select) MEM_SEL_0: begin o_m_dat <= i_s0_dat; end default: begin o_m_dat <= 32'h0000; end endcase end //ack in from mem slave always @ (mem_select or i_s0_ack) begin case (mem_select) MEM_SEL_0: begin o_m_ack <= i_s0_ack; end default: begin o_m_ack <= 1'h0; end endcase end //int in from slave always @ (mem_select or i_s0_int) begin case (mem_select) MEM_SEL_0: begin o_m_int <= i_s0_int; end default: begin o_m_int <= 1'h0; end endcase end assign o_s0_we = (mem_select == MEM_SEL_0) ? i_m_we: 1'b0; assign o_s0_stb = (mem_select == MEM_SEL_0) ? i_m_stb: 1'b0; assign o_s0_sel = (mem_select == MEM_SEL_0) ? i_m_sel: 4'b0; assign o_s0_cyc = (mem_select == MEM_SEL_0) ? i_m_cyc: 1'b0; assign o_s0_adr = (mem_select == MEM_SEL_0) ? i_m_adr: 32'h0; assign o_s0_dat = (mem_select == MEM_SEL_0) ? i_m_dat: 32'h0; endmodule
module wishbone_mem_interconnect ( //Control Signals input clk, input rst, //Master Signals input i_m_we, input i_m_stb, input i_m_cyc, input [3:0] i_m_sel, input [31:0] i_m_adr, input [31:0] i_m_dat, output reg [31:0] o_m_dat, output reg o_m_ack, output reg o_m_int, //Slave 0 output o_s0_we, output o_s0_cyc, output o_s0_stb, output [3:0] o_s0_sel, input i_s0_ack, output [31:0] o_s0_dat, input [31:0] i_s0_dat, output [31:0] o_s0_adr, input i_s0_int ); parameter MEM_SEL_0 = 0; parameter MEM_OFFSET_0 = 0; parameter MEM_SIZE_0 = 8388607; reg [31:0] mem_select; always @(rst or i_m_adr or mem_select) begin if (rst) begin //nothing selected mem_select <= 32'hFFFFFFFF; end else begin if ((i_m_adr >= MEM_OFFSET_0) && (i_m_adr < (MEM_OFFSET_0 + MEM_SIZE_0))) begin mem_select <= MEM_SEL_0; end else begin mem_select <= 32'hFFFFFFFF; end end end //data in from slave always @ (mem_select or i_s0_dat) begin case (mem_select) MEM_SEL_0: begin o_m_dat <= i_s0_dat; end default: begin o_m_dat <= 32'h0000; end endcase end //ack in from mem slave always @ (mem_select or i_s0_ack) begin case (mem_select) MEM_SEL_0: begin o_m_ack <= i_s0_ack; end default: begin o_m_ack <= 1'h0; end endcase end //int in from slave always @ (mem_select or i_s0_int) begin case (mem_select) MEM_SEL_0: begin o_m_int <= i_s0_int; end default: begin o_m_int <= 1'h0; end endcase end assign o_s0_we = (mem_select == MEM_SEL_0) ? i_m_we: 1'b0; assign o_s0_stb = (mem_select == MEM_SEL_0) ? i_m_stb: 1'b0; assign o_s0_sel = (mem_select == MEM_SEL_0) ? i_m_sel: 4'b0; assign o_s0_cyc = (mem_select == MEM_SEL_0) ? i_m_cyc: 1'b0; assign o_s0_adr = (mem_select == MEM_SEL_0) ? i_m_adr: 32'h0; assign o_s0_dat = (mem_select == MEM_SEL_0) ? i_m_dat: 32'h0; endmodule
module wishbone_mem_interconnect ( //Control Signals input clk, input rst, //Master Signals input i_m_we, input i_m_stb, input i_m_cyc, input [3:0] i_m_sel, input [31:0] i_m_adr, input [31:0] i_m_dat, output reg [31:0] o_m_dat, output reg o_m_ack, output reg o_m_int, //Slave 0 output o_s0_we, output o_s0_cyc, output o_s0_stb, output [3:0] o_s0_sel, input i_s0_ack, output [31:0] o_s0_dat, input [31:0] i_s0_dat, output [31:0] o_s0_adr, input i_s0_int ); parameter MEM_SEL_0 = 0; parameter MEM_OFFSET_0 = 0; parameter MEM_SIZE_0 = 8388607; reg [31:0] mem_select; always @(rst or i_m_adr or mem_select) begin if (rst) begin //nothing selected mem_select <= 32'hFFFFFFFF; end else begin if ((i_m_adr >= MEM_OFFSET_0) && (i_m_adr < (MEM_OFFSET_0 + MEM_SIZE_0))) begin mem_select <= MEM_SEL_0; end else begin mem_select <= 32'hFFFFFFFF; end end end //data in from slave always @ (mem_select or i_s0_dat) begin case (mem_select) MEM_SEL_0: begin o_m_dat <= i_s0_dat; end default: begin o_m_dat <= 32'h0000; end endcase end //ack in from mem slave always @ (mem_select or i_s0_ack) begin case (mem_select) MEM_SEL_0: begin o_m_ack <= i_s0_ack; end default: begin o_m_ack <= 1'h0; end endcase end //int in from slave always @ (mem_select or i_s0_int) begin case (mem_select) MEM_SEL_0: begin o_m_int <= i_s0_int; end default: begin o_m_int <= 1'h0; end endcase end assign o_s0_we = (mem_select == MEM_SEL_0) ? i_m_we: 1'b0; assign o_s0_stb = (mem_select == MEM_SEL_0) ? i_m_stb: 1'b0; assign o_s0_sel = (mem_select == MEM_SEL_0) ? i_m_sel: 4'b0; assign o_s0_cyc = (mem_select == MEM_SEL_0) ? i_m_cyc: 1'b0; assign o_s0_adr = (mem_select == MEM_SEL_0) ? i_m_adr: 32'h0; assign o_s0_dat = (mem_select == MEM_SEL_0) ? i_m_dat: 32'h0; endmodule
module / / Internal counters that are used as Read/Write pointers to the fifo's that store all the transaction info on all channles. This parameter is used to define the width of these pointers --> depending on Maximum outstanding transactions supported. 1-bit extra width than the no.of.bits needed to represent the outstanding transactions Extra bit helps in generating the empty and full flags / parameter int_wr_cntr_width = clogb2(max_wr_outstanding_transactions+1); parameter int_rd_cntr_width = clogb2(max_rd_outstanding_transactions+1); / RESP data / parameter rsp_fifo_bits = axi_rsp_width+id_bus_width; parameter rsp_lsb = 0; parameter rsp_msb = axi_rsp_width-1; parameter rsp_id_lsb = rsp_msb + 1; parameter rsp_id_msb = rsp_id_lsb + id_bus_width-1; input S_RESETN; output S_ARREADY; output S_AWREADY; output S_BVALID; output S_RLAST; output S_RVALID; output S_WREADY; output [axi_rsp_width-1:0] S_BRESP; output [axi_rsp_width-1:0] S_RRESP; output [data_bus_width-1:0] S_RDATA; output [id_bus_width-1:0] S_BID; output [id_bus_width-1:0] S_RID; input S_ACLK; input S_ARVALID; input S_AWVALID; input S_BREADY; input S_RREADY; input S_WLAST; input S_WVALID; input [axi_brst_type_width-1:0] S_ARBURST; input [axi_lock_width-1:0] S_ARLOCK; input [axi_size_width-1:0] S_ARSIZE; input [axi_brst_type_width-1:0] S_AWBURST; input [axi_lock_width-1:0] S_AWLOCK; input [axi_size_width-1:0] S_AWSIZE; input [axi_prot_width-1:0] S_ARPROT; input [axi_prot_width-1:0] S_AWPROT; input [address_bus_width-1:0] S_ARADDR; input [address_bus_width-1:0] S_AWADDR; input [data_bus_width-1:0] S_WDATA; input [axi_cache_width-1:0] S_ARCACHE; input [axi_cache_width-1:0] S_ARLEN; input [axi_qos_width-1:0] S_ARQOS; input [axi_cache_width-1:0] S_AWCACHE; input [axi_len_width-1:0] S_AWLEN; input [axi_qos_width-1:0] S_AWQOS; input [(data_bus_width/8)-1:0] S_WSTRB; input [id_bus_width-1:0] S_ARID; input [id_bus_width-1:0] S_AWID; input [id_bus_width-1:0] S_WID; input SW_CLK; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output reg WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output reg [max_burst_bits-1:0] WR_DATA; output reg [addr_width-1:0] WR_ADDR; output reg [max_burst_bytes_width:0] WR_BYTES; output reg RD_REQ_OCM, RD_REQ_DDR, RD_REQ_REG; output reg [addr_width-1:0] RD_ADDR; input [max_burst_bits-1:0] RD_DATA_DDR,RD_DATA_OCM, RD_DATA_REG; output reg[max_burst_bytes_width:0] RD_BYTES; input RD_DATA_VALID_OCM,RD_DATA_VALID_DDR, RD_DATA_VALID_REG; output reg [axi_qos_width-1:0] WR_QOS, RD_QOS; wire net_ARVALID; wire net_AWVALID; wire net_WVALID; real s_aclk_period; cdn_axi3_slave_bfm #(slave_name, data_bus_width, address_bus_width, id_bus_width, slave_base_address, (slave_high_address- slave_base_address), max_outstanding_transactions, 0, ///MEMORY_MODEL_MODE, exclusive_access_supported) slave (.ACLK (S_ACLK), .ARESETn (S_RESETN), /// confirm this // Write Address Channel .AWID (S_AWID), .AWADDR (S_AWADDR), .AWLEN (S_AWLEN), .AWSIZE (S_AWSIZE), .AWBURST (S_AWBURST), .AWLOCK (S_AWLOCK), .AWCACHE (S_AWCACHE), .AWPROT (S_AWPROT), .AWVALID (net_AWVALID), .AWREADY (S_AWREADY), // Write Data Channel Signals. .WID (S_WID), .WDATA (S_WDATA), .WSTRB (S_WSTRB), .WLAST (S_WLAST), .WVALID (net_WVALID), .WREADY (S_WREADY), // Write Response Channel Signals. .BID (S_BID), .BRESP (S_BRESP), .BVALID (S_BVALID), .BREADY (S_BREADY), // Read Address Channel Signals. .ARID (S_ARID), .ARADDR (S_ARADDR), .ARLEN (S_ARLEN), .ARSIZE (S_ARSIZE), .ARBURST (S_ARBURST), .ARLOCK (S_ARLOCK), .ARCACHE (S_ARCACHE), .ARPROT (S_ARPROT), .ARVALID (net_ARVALID), .ARREADY (S_ARREADY), // Read Data Channel Signals. .RID (S_RID), .RDATA (S_RDATA), .RRESP (S_RRESP), .RLAST (S_RLAST), .RVALID (S_RVALID), .RREADY (S_RREADY)); / Latency type and Debug/Error Control / reg[1:0] latency_type = RANDOM_CASE; reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1'b1; / WR_FIFO stores 32-bit address, valid data and valid bytes for each AXI Write burst transaction / reg [wr_fifo_data_bits-1:0] wr_fifo [0:max_wr_outstanding_transactions-1]; reg [int_wr_cntr_width-1:0] wr_fifo_wr_ptr = 0, wr_fifo_rd_ptr = 0; wire wr_fifo_empty; / Store the awvalid receive time --- necessary for calculating the latency in sending the bresp/ reg [7:0] aw_time_cnt = 0, bresp_time_cnt = 0; real awvalid_receive_time[0:max_wr_outstanding_transactions]; // store the time when a new awvalid is received reg awvalid_flag[0:max_wr_outstanding_transactions]; // indicates awvalid is received / Address Write Channel handshake/ reg[int_wr_cntr_width-1:0] aw_cnt = 0;// count of awvalid / various FIFOs for storing the ADDR channel info / reg [axi_size_width-1:0] awsize [0:max_wr_outstanding_transactions-1]; reg [axi_prot_width-1:0] awprot [0:max_wr_outstanding_transactions-1]; reg [axi_lock_width-1:0] awlock [0:max_wr_outstanding_transactions-1]; reg [axi_cache_width-1:0] awcache [0:max_wr_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] awbrst [0:max_wr_outstanding_transactions-1]; reg [axi_len_width-1:0] awlen [0:max_wr_outstanding_transactions-1]; reg aw_flag [0:max_wr_outstanding_transactions-1]; reg [addr_width-1:0] awaddr [0:max_wr_outstanding_transactions-1]; reg [id_bus_width-1:0] awid [0:max_wr_outstanding_transactions-1]; reg [axi_qos_width-1:0] awqos [0:max_wr_outstanding_transactions-1]; wire aw_fifo_full; // indicates awvalid_fifo is full (max outstanding transactions reached) / internal fifos to store burst write data, ID & strobes/ reg [(data_bus_widthaxi_burst_len)-1:0] burst_data [0:max_wr_outstanding_transactions-1]; reg [max_burst_bytes_width:0] burst_valid_bytes [0:max_wr_outstanding_transactions-1]; /// total valid bytes received in a complete burst transfer reg wlast_flag [0:max_wr_outstanding_transactions-1]; // flag to indicate WLAST received wire wd_fifo_full; /* Write Data Channel and Write Response handshake signals/ reg [int_wr_cntr_width-1:0] wd_cnt = 0; reg [(data_bus_widthaxi_burst_len)-1:0] aligned_wr_data; reg [addr_width-1:0] aligned_wr_addr; reg [max_burst_bytes_width:0] valid_data_bytes; reg [int_wr_cntr_width-1:0] wr_bresp_cnt = 0; reg [axi_rsp_width-1:0] bresp; reg [rsp_fifo_bits-1:0] fifo_bresp [0:max_wr_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_bresp; reg [int_wr_cntr_width-1:0] rd_bresp_cnt = 0; integer wr_latency_count; reg wr_delayed; wire bresp_fifo_empty; /* states for managing read/write to WR_FIFO / parameter SEND_DATA = 0, WAIT_ACK = 1; reg state; / Qos/ reg [axi_qos_width-1:0] ar_qos, aw_qos; initial begin if(DEBUG_INFO) begin if(enable_this_port) $display("[%0d] : %0s : %0s : Port is ENABLED.",$time, DISP_INFO, slave_name); else $display("[%0d] : %0s : %0s : Port is DISABLED.",$time, DISP_INFO, slave_name); end end initial slave.set_disable_reset_value_checks(1); initial begin repeat(2) @(posedge S_ACLK); if(!enable_this_port) begin slave.set_channel_level_info(0); slave.set_function_level_info(0); end slave.RESPONSE_TIMEOUT = 0; end /--------------------------------------------------------------------------------/ / Set Latency type to be used / task set_latency_type; input[1:0] lat; begin if(enable_this_port) latency_type = lat; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'Latency Profile' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / Set ARQoS to be used / task set_arqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) ar_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'ARQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / Set AWQoS to be used / task set_awqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) aw_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'AWQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /--------------------------------------------------------------------------------/ / get the wr latency number / function [31:0] get_wr_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : if(slave_name == axi_acp_name) get_wr_lat_number = acp_wr_min; else get_wr_lat_number = gp_wr_min; AVG_CASE : if(slave_name == axi_acp_name) get_wr_lat_number = acp_wr_avg; else get_wr_lat_number = gp_wr_avg; WORST_CASE : if(slave_name == axi_acp_name) get_wr_lat_number = acp_wr_max; else get_wr_lat_number = gp_wr_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : if(slave_name == axi_acp_name) get_wr_lat_number = ($random()%10+ acp_wr_min); else get_wr_lat_number = ($random()%10+ gp_wr_min); 2'b01 : if(slave_name == axi_acp_name) get_wr_lat_number = ($random()%40+ acp_wr_avg); else get_wr_lat_number = ($random()%40+ gp_wr_avg); default : if(slave_name == axi_acp_name) get_wr_lat_number = ($random()%60+ acp_wr_max); else get_wr_lat_number = ($random()%60+ gp_wr_max); endcase end endcase end endfunction /--------------------------------------------------------------------------------/ / get the rd latency number / function [31:0] get_rd_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : if(slave_name == axi_acp_name) get_rd_lat_number = acp_rd_min; else get_rd_lat_number = gp_rd_min; AVG_CASE : if(slave_name == axi_acp_name) get_rd_lat_number = acp_rd_avg; else get_rd_lat_number = gp_rd_avg; WORST_CASE : if(slave_name == axi_acp_name) get_rd_lat_number = acp_rd_max; else get_rd_lat_number = gp_rd_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : if(slave_name == axi_acp_name) get_rd_lat_number = ($random()%10+ acp_rd_min); else get_rd_lat_number = ($random()%10+ gp_rd_min); 2'b01 : if(slave_name == axi_acp_name) get_rd_lat_number = ($random()%40+ acp_rd_avg); else get_rd_lat_number = ($random()%40+ gp_rd_avg); default : if(slave_name == axi_acp_name) get_rd_lat_number = ($random()%60+ acp_rd_max); else get_rd_lat_number = ($random()%60+ gp_rd_max); endcase end endcase end endfunction /--------------------------------------------------------------------------------/ / Store the Clock cycle time period / always@(S_RESETN) begin if(S_RESETN) begin @(posedge S_ACLK); s_aclk_period = $time; @(posedge S_ACLK); s_aclk_period = $time - s_aclk_period; end end /--------------------------------------------------------------------------------/ / Check for any WRITE/READs when this port is disabled / always@(S_AWVALID or S_WVALID or S_ARVALID) begin if((S_AWVALID \| S_WVALID \| S_ARVALID) && !enable_this_port) begin $display("[%0d] : %0s : %0s : Port is disabled. AXI transaction is initiated on this port ...\nSimulation will halt ..",$time, DISP_ERR, slave_name); $stop; end end /--------------------------------------------------------------------------------/ assign net_ARVALID = enable_this_port ? S_ARVALID : 1'b0; assign net_AWVALID = enable_this_port ? S_AWVALID : 1'b0; assign net_WVALID = enable_this_port ? S_WVALID : 1'b0; assign wr_fifo_empty = (wr_fifo_wr_ptr === wr_fifo_rd_ptr)?1'b1: 1'b0; assign aw_fifo_full = ((aw_cnt[int_wr_cntr_width-1] !== rd_bresp_cnt[int_wr_cntr_width-1]) && (aw_cnt[int_wr_cntr_width-2:0] === rd_bresp_cnt[int_wr_cntr_width-2:0]))?1'b1 :1'b0; /// complete this assign wd_fifo_full = ((wd_cnt[int_wr_cntr_width-1] !== rd_bresp_cnt[int_wr_cntr_width-1]) && (wd_cnt[int_wr_cntr_width-2:0] === rd_bresp_cnt[int_wr_cntr_width-2:0]))?1'b1 :1'b0; /// complete this assign bresp_fifo_empty = (wr_bresp_cnt === rd_bresp_cnt)?1'b1:1'b0; / Store the awvalid receive time --- necessary for calculating the bresp latency / always@(negedge S_RESETN or S_AWID or S_AWADDR or S_AWVALID ) begin if(!S_RESETN) aw_time_cnt = 0; else begin if(S_AWVALID) begin awvalid_receive_time[aw_time_cnt] = $time; awvalid_flag[aw_time_cnt] = 1'b1; aw_time_cnt = aw_time_cnt + 1; if(aw_time_cnt === max_wr_outstanding_transactions) aw_time_cnt = 0; end end // else end /// always /--------------------------------------------------------------------------------/ always@(posedge S_ACLK) begin if(net_AWVALID && S_AWREADY) begin if(S_AWQOS === 0) awqos[aw_cnt[int_wr_cntr_width-2:0]] = aw_qos; else awqos[aw_cnt[int_wr_cntr_width-2:0]] = S_AWQOS; end end /--------------------------------------------------------------------------------/ always@(aw_fifo_full) begin if(aw_fifo_full && DEBUG_INFO) $display("[%0d] : %0s : %0s : Reached the maximum outstanding Write transactions limit (%0d). Blocking all future Write transactions until at least 1 of the outstanding Write transaction has completed.",$time, DISP_INFO, slave_name,max_wr_outstanding_transactions); end /--------------------------------------------------------------------------------/ / Address Write Channel handshake/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin aw_cnt = 0; end else begin if(!aw_fifo_full) begin slave.RECEIVE_WRITE_ADDRESS(0, id_invalid, awaddr[aw_cnt[int_wr_cntr_width-2:0]], awlen[aw_cnt[int_wr_cntr_width-2:0]], awsize[aw_cnt[int_wr_cntr_width-2:0]], awbrst[aw_cnt[int_wr_cntr_width-2:0]], awlock[aw_cnt[int_wr_cntr_width-2:0]], awcache[aw_cnt[int_wr_cntr_width-2:0]], awprot[aw_cnt[int_wr_cntr_width-2:0]], awid[aw_cnt[int_wr_cntr_width-2:0]]); /// sampled valid ID. aw_flag[aw_cnt[int_wr_cntr_width-2:0]] = 1; aw_cnt = aw_cnt + 1; if(aw_cnt[int_wr_cntr_width-2:0] === (max_wr_outstanding_transactions-1)) begin aw_cnt[int_wr_cntr_width-1] = ~aw_cnt[int_wr_cntr_width-1]; aw_cnt[int_wr_cntr_width-2:0] = 0; end end // if (!aw_fifo_full) end /// if else end /// always /--------------------------------------------------------------------------------/ / Write Data Channel Handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wd_cnt = 0; end else begin if(!wd_fifo_full && S_WVALID) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_wr_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_wr_cntr_width-2:0]]); wlast_flag[wd_cnt[int_wr_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; if(wd_cnt[int_wr_cntr_width-2:0] === (max_wr_outstanding_transactions-1)) begin wd_cnt[int_wr_cntr_width-1] = ~wd_cnt[int_wr_cntr_width-1]; wd_cnt[int_wr_cntr_width-2:0] = 0; end end /// if end /// else end /// always /--------------------------------------------------------------------------------/ / Align the wrap data for write transaction / task automatic get_wrap_aligned_wr_data; output [(data_bus_widthaxi_burst_len)-1:0] aligned_data; output [addr_width-1:0] start_addr; /// aligned start address input [addr_width-1:0] addr; input [(data_bus_widthaxi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [(data_bus_widthaxi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; wrp_data = wrp_data << ((data_bus_widthaxi_burst_len) - (v_bytes8)); while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data << 8; temp_data[7:0] = wrp_data[(data_bus_widthaxi_burst_len)-1 : (data_bus_widthaxi_burst_len)-8]; wrp_data = wrp_data << 8; wrp_bytes = wrp_bytes - 1; end wrp_bytes = addr - start_addr; wrp_data = b_data << (wrp_bytes8); aligned_data = (temp_data \| wrp_data); end endtask /--------------------------------------------------------------------------------/ / Calculate the Response for each read/write transaction / function [axi_rsp_width-1:0] calculate_resp; input rd_wr; // indicates Read(1) or Write(0) transaction input [addr_width-1:0] awaddr; input [axi_prot_width-1:0] awprot; reg [axi_rsp_width-1:0] rsp; begin rsp = AXI_OK; / Address Decode / if(decode_address(awaddr) === INVALID_MEM_TYPE) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Invalid location(0x%0h) ",$time, DISP_ERR, slave_name, awaddr); end if(!rd_wr && decode_address(awaddr) === REG_MEM) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Write to Register Map(0x%0h) is not supported ",$time, DISP_ERR, slave_name, awaddr); end if(secure_access_enabled && awprot[1]) rsp = AXI_DEC_ERR; // decode error calculate_resp = rsp; end endfunction /--------------------------------------------------------------------------------/ / Store the Write response for each write transaction / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_bresp_cnt = 0; wr_fifo_wr_ptr = 0; end else begin enable_write_bresp = aw_flag[wr_bresp_cnt[int_wr_cntr_width-2:0]] && wlast_flag[wr_bresp_cnt[int_wr_cntr_width-2:0]]; / calculate bresp only when AWVALID && WLAST is received / if(enable_write_bresp) begin aw_flag[wr_bresp_cnt[int_wr_cntr_width-2:0]] = 0; wlast_flag[wr_bresp_cnt[int_wr_cntr_width-2:0]] = 0; bresp = calculate_resp(1'b0, awaddr[wr_bresp_cnt[int_wr_cntr_width-2:0]],awprot[wr_bresp_cnt[int_wr_cntr_width-2:0]]); fifo_bresp[wr_bresp_cnt[int_wr_cntr_width-2:0]] = {awid[wr_bresp_cnt[int_wr_cntr_width-2:0]],bresp}; / Fill WR data FIFO / if(bresp === AXI_OK) begin if(awbrst[wr_bresp_cnt[int_wr_cntr_width-2:0]] === AXI_WRAP) begin /// wrap type? then align the data get_wrap_aligned_wr_data(aligned_wr_data,aligned_wr_addr, awaddr[wr_bresp_cnt[int_wr_cntr_width-2:0]],burst_data[wr_bresp_cnt[int_wr_cntr_width-2:0]],burst_valid_bytes[wr_bresp_cnt[int_wr_cntr_width-2:0]]); /// gives wrapped start address end else begin aligned_wr_data = burst_data[wr_bresp_cnt[int_wr_cntr_width-2:0]]; aligned_wr_addr = awaddr[wr_bresp_cnt[int_wr_cntr_width-2:0]] ; end valid_data_bytes = burst_valid_bytes[wr_bresp_cnt[int_wr_cntr_width-2:0]]; end else valid_data_bytes = 0; wr_fifo[wr_fifo_wr_ptr[int_wr_cntr_width-2:0]] = {awqos[wr_bresp_cnt[int_wr_cntr_width-2:0]], aligned_wr_data, aligned_wr_addr, valid_data_bytes}; wr_fifo_wr_ptr = wr_fifo_wr_ptr + 1; wr_bresp_cnt = wr_bresp_cnt+1; if(wr_bresp_cnt[int_wr_cntr_width-2:0] === (max_wr_outstanding_transactions-1)) begin wr_bresp_cnt[int_wr_cntr_width-1] = ~ wr_bresp_cnt[int_wr_cntr_width-1]; wr_bresp_cnt[int_wr_cntr_width-2:0] = 0; end end end // else end // always /--------------------------------------------------------------------------------/ / Send Write Response Channel handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin rd_bresp_cnt = 0; wr_latency_count = get_wr_lat_number(1); wr_delayed = 0; bresp_time_cnt = 0; end else begin wr_delayed = 1'b0; if(awvalid_flag[bresp_time_cnt] && (($time - awvalid_receive_time[bresp_time_cnt])/s_aclk_period >= wr_latency_count)) wr_delayed = 1; if(!bresp_fifo_empty && wr_delayed) begin slave.SEND_WRITE_RESPONSE(fifo_bresp[rd_bresp_cnt[int_wr_cntr_width-2:0]][rsp_id_msb : rsp_id_lsb], // ID fifo_bresp[rd_bresp_cnt[int_wr_cntr_width-2:0]][rsp_msb : rsp_lsb] // Response ); wr_delayed = 0; awvalid_flag[bresp_time_cnt] = 1'b0; bresp_time_cnt = bresp_time_cnt+1; rd_bresp_cnt = rd_bresp_cnt + 1; if(rd_bresp_cnt[int_wr_cntr_width-2:0] === (max_wr_outstanding_transactions-1)) begin rd_bresp_cnt[int_wr_cntr_width-1] = ~ rd_bresp_cnt[int_wr_cntr_width-1]; rd_bresp_cnt[int_wr_cntr_width-2:0] = 0; end if(bresp_time_cnt === max_wr_outstanding_transactions) begin bresp_time_cnt = 0; end wr_latency_count = get_wr_lat_number(1); end end // else end//always /--------------------------------------------------------------------------------/ / Reading from the wr_fifo / always@(negedge S_RESETN or posedge SW_CLK) begin if(!S_RESETN) begin WR_DATA_VALID_DDR = 1'b0; WR_DATA_VALID_OCM = 1'b0; wr_fifo_rd_ptr = 0; state = SEND_DATA; WR_QOS = 0; end else begin case(state) SEND_DATA :begin state = SEND_DATA; WR_DATA_VALID_OCM = 0; WR_DATA_VALID_DDR = 0; if(!wr_fifo_empty) begin WR_DATA = wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_data_msb : wr_data_lsb]; WR_ADDR = wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_addr_msb : wr_addr_lsb]; WR_BYTES = wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_bytes_msb : wr_bytes_lsb]; WR_QOS = wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_qos_msb : wr_qos_lsb]; state = WAIT_ACK; case (decode_address(wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_addr_msb : wr_addr_lsb])) OCM_MEM : WR_DATA_VALID_OCM = 1; DDR_MEM : WR_DATA_VALID_DDR = 1; default : state = SEND_DATA; endcase wr_fifo_rd_ptr = wr_fifo_rd_ptr+1; end end WAIT_ACK :begin state = WAIT_ACK; if(WR_DATA_ACK_OCM \| WR_DATA_ACK_DDR) begin WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; state = SEND_DATA; end end endcase end end /--------------------------------------------------------------------------------/ /-------------------------------- WRITE HANDSHAKE END ----------------------------------------/ /-------------------------------- READ HANDSHAKE ---------------------------------------------/ / READ CHANNELS / / Store the arvalid receive time --- necessary for calculating latency in sending the rresp latency / reg [7:0] ar_time_cnt = 0,rresp_time_cnt = 0; real arvalid_receive_time[0:max_rd_outstanding_transactions]; // store the time when a new arvalid is received reg arvalid_flag[0:max_rd_outstanding_transactions]; // store the time when a new arvalid is received reg [int_rd_cntr_width-1:0] ar_cnt = 0; // counter for arvalid info / various FIFOs for storing the ADDR channel info / reg [axi_size_width-1:0] arsize [0:max_rd_outstanding_transactions-1]; reg [axi_prot_width-1:0] arprot [0:max_rd_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] arbrst [0:max_rd_outstanding_transactions-1]; reg [axi_len_width-1:0] arlen [0:max_rd_outstanding_transactions-1]; reg [axi_cache_width-1:0] arcache [0:max_rd_outstanding_transactions-1]; reg [axi_lock_width-1:0] arlock [0:max_rd_outstanding_transactions-1]; reg ar_flag [0:max_rd_outstanding_transactions-1]; reg [addr_width-1:0] araddr [0:max_rd_outstanding_transactions-1]; reg [id_bus_width-1:0] arid [0:max_rd_outstanding_transactions-1]; reg [axi_qos_width-1:0] arqos [0:max_rd_outstanding_transactions-1]; wire ar_fifo_full; // indicates arvalid_fifo is full (max outstanding transactions reached) reg [int_rd_cntr_width-1:0] rd_cnt = 0; reg [int_rd_cntr_width-1:0] wr_rresp_cnt = 0; reg [axi_rsp_width-1:0] rresp; reg [rsp_fifo_bits-1:0] fifo_rresp [0:max_rd_outstanding_transactions-1]; // store the ID and its corresponding response / Send Read Response & Data Channel handshake / integer rd_latency_count; reg rd_delayed; reg [max_burst_bits-1:0] read_fifo [0:max_rd_outstanding_transactions-1]; /// Store only AXI Burst Data .. reg [int_rd_cntr_width-1:0] rd_fifo_wr_ptr = 0, rd_fifo_rd_ptr = 0; wire read_fifo_full; assign read_fifo_full = (rd_fifo_wr_ptr[int_rd_cntr_width-1] !== rd_fifo_rd_ptr[int_rd_cntr_width-1] && rd_fifo_wr_ptr[int_rd_cntr_width-2:0] === rd_fifo_rd_ptr[int_rd_cntr_width-2:0])?1'b1: 1'b0; assign read_fifo_empty = (rd_fifo_wr_ptr === rd_fifo_rd_ptr)?1'b1: 1'b0; assign ar_fifo_full = ((ar_cnt[int_rd_cntr_width-1] !== rd_cnt[int_rd_cntr_width-1]) && (ar_cnt[int_rd_cntr_width-2:0] === rd_cnt[int_rd_cntr_width-2:0]))?1'b1 :1'b0; / Store the arvalid receive time --- necessary for calculating the bresp latency / always@(negedge S_RESETN or S_ARID or S_ARADDR or S_ARVALID ) begin if(!S_RESETN) ar_time_cnt = 0; else begin if(S_ARVALID) begin arvalid_receive_time[ar_time_cnt] = $time; arvalid_flag[ar_time_cnt] = 1'b1; ar_time_cnt = ar_time_cnt + 1; if(ar_time_cnt === max_rd_outstanding_transactions) ar_time_cnt = 0; end end // else end /// always /--------------------------------------------------------------------------------/ always@(posedge S_ACLK) begin if(net_ARVALID && S_ARREADY) begin if(S_ARQOS === 0) arqos[aw_cnt[int_rd_cntr_width-2:0]] = ar_qos; else arqos[aw_cnt[int_rd_cntr_width-2:0]] = S_ARQOS; end end /--------------------------------------------------------------------------------/ always@(ar_fifo_full) begin if(ar_fifo_full && DEBUG_INFO) $display("[%0d] : %0s : %0s : Reached the maximum outstanding Read transactions limit (%0d). Blocking all future Read transactions until at least 1 of the outstanding Read transaction has completed.",$time, DISP_INFO, slave_name,max_rd_outstanding_transactions); end /--------------------------------------------------------------------------------/ / Address Read Channel handshake/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin ar_cnt = 0; end else begin if(!ar_fifo_full) begin slave.RECEIVE_READ_ADDRESS(0, id_invalid, araddr[ar_cnt[int_rd_cntr_width-2:0]], arlen[ar_cnt[int_rd_cntr_width-2:0]], arsize[ar_cnt[int_rd_cntr_width-2:0]], arbrst[ar_cnt[int_rd_cntr_width-2:0]], arlock[ar_cnt[int_rd_cntr_width-2:0]], arcache[ar_cnt[int_rd_cntr_width-2:0]], arprot[ar_cnt[int_rd_cntr_width-2:0]], arid[ar_cnt[int_rd_cntr_width-2:0]]); /// sampled valid ID. ar_flag[ar_cnt[int_rd_cntr_width-2:0]] = 1'b1; ar_cnt = ar_cnt+1; if(ar_cnt[int_rd_cntr_width-2:0] === max_rd_outstanding_transactions-1) begin ar_cnt[int_rd_cntr_width-1] = ~ ar_cnt[int_rd_cntr_width-1]; ar_cnt[int_rd_cntr_width-2:0] = 0; end end /// if(!ar_fifo_full) end /// if else end /// always/ /--------------------------------------------------------------------------------/ /* Align Wrap data for read transaction/ task automatic get_wrap_aligned_rd_data; output [(data_bus_widthaxi_burst_len)-1:0] aligned_data; input [addr_width-1:0] addr; input [(data_bus_widthaxi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [addr_width-1:0] start_addr; reg [(data_bus_widthaxi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data >> 8; temp_data[(data_bus_widthaxi_burst_len)-1 : (data_bus_widthaxi_burst_len)-8] = wrp_data[7:0]; wrp_data = wrp_data >> 8; wrp_bytes = wrp_bytes - 1; end temp_data = temp_data >> ((data_bus_widthaxi_burst_len) - (v_bytes8)); wrp_bytes = addr - start_addr; wrp_data = b_data >> (wrp_bytes8); aligned_data = (temp_data \| wrp_data); end endtask /--------------------------------------------------------------------------------/ parameter RD_DATA_REQ = 1'b0, WAIT_RD_VALID = 1'b1; reg [addr_width-1:0] temp_read_address; reg [max_burst_bytes_width:0] temp_rd_valid_bytes; reg rd_fifo_state; reg invalid_rd_req; / get the data from memory && also calculate the rresp/ always@(negedge S_RESETN or posedge SW_CLK) begin if(!S_RESETN)begin rd_fifo_wr_ptr = 0; wr_rresp_cnt =0; rd_fifo_state = RD_DATA_REQ; temp_rd_valid_bytes = 0; temp_read_address = 0; RD_REQ_DDR = 0; RD_REQ_OCM = 0; RD_REQ_REG = 0; RD_QOS = 0; invalid_rd_req = 0; end else begin case(rd_fifo_state) RD_DATA_REQ : begin rd_fifo_state = RD_DATA_REQ; RD_REQ_DDR = 0; RD_REQ_OCM = 0; RD_REQ_REG = 0; RD_QOS = 0; if(ar_flag[wr_rresp_cnt[int_rd_cntr_width-2:0]] && !read_fifo_full) begin ar_flag[wr_rresp_cnt[int_rd_cntr_width-2:0]] = 0; rresp = calculate_resp(1'b1, araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]],arprot[wr_rresp_cnt[int_rd_cntr_width-2:0]]); fifo_rresp[wr_rresp_cnt[int_rd_cntr_width-2:0]] = {arid[wr_rresp_cnt[int_rd_cntr_width-2:0]],rresp}; temp_rd_valid_bytes = (arlen[wr_rresp_cnt[int_rd_cntr_width-2:0]]+1)(2*arsize[wr_rresp_cnt[int_rd_cntr_width-2:0]]);//data_bus_width/8; if(arbrst[wr_rresp_cnt[int_rd_cntr_width-2:0]] === AXI_WRAP) /// wrap begin temp_read_address = (araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]]/temp_rd_valid_bytes) temp_rd_valid_bytes; else temp_read_address = araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]]; if(rresp === AXI_OK) begin case(decode_address(temp_read_address))//decode_address(araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]]); OCM_MEM : RD_REQ_OCM = 1; DDR_MEM : RD_REQ_DDR = 1; REG_MEM : RD_REQ_REG = 1; default : invalid_rd_req = 1; endcase end else invalid_rd_req = 1; RD_QOS = arqos[wr_rresp_cnt[int_rd_cntr_width-2:0]]; RD_ADDR = temp_read_address; ///araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]]; RD_BYTES = temp_rd_valid_bytes; rd_fifo_state = WAIT_RD_VALID; wr_rresp_cnt = wr_rresp_cnt + 1; if(wr_rresp_cnt[int_rd_cntr_width-2:0] === max_rd_outstanding_transactions-1) begin wr_rresp_cnt[int_rd_cntr_width-1] = ~ wr_rresp_cnt[int_rd_cntr_width-1]; wr_rresp_cnt[int_rd_cntr_width-2:0] = 0; end end end WAIT_RD_VALID : begin rd_fifo_state = WAIT_RD_VALID; if(RD_DATA_VALID_OCM \| RD_DATA_VALID_DDR \| RD_DATA_VALID_REG \| invalid_rd_req) begin ///temp_dec == 2'b11) begin if(RD_DATA_VALID_DDR) read_fifo[rd_fifo_wr_ptr[int_rd_cntr_width-2:0]] = RD_DATA_DDR; else if(RD_DATA_VALID_OCM) read_fifo[rd_fifo_wr_ptr[int_rd_cntr_width-2:0]] = RD_DATA_OCM; else if(RD_DATA_VALID_REG) read_fifo[rd_fifo_wr_ptr[int_rd_cntr_width-2:0]] = RD_DATA_REG; else read_fifo[rd_fifo_wr_ptr[int_rd_cntr_width-2:0]] = 0; rd_fifo_wr_ptr = rd_fifo_wr_ptr + 1; RD_REQ_DDR = 0; RD_REQ_OCM = 0; RD_REQ_REG = 0; RD_QOS = 0; invalid_rd_req = 0; rd_fifo_state = RD_DATA_REQ; end end endcase end /// else end /// always /--------------------------------------------------------------------------------/ reg[max_burst_bytes_width:0] rd_v_b; reg [(data_bus_widthaxi_burst_len)-1:0] temp_read_data; reg [(data_bus_widthaxi_burst_len)-1:0] temp_wrap_data; reg[(axi_rsp_widthaxi_burst_len)-1:0] temp_read_rsp; / Read Data Channel handshake / always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_rd_ptr = 0; rd_cnt = 0; rd_latency_count = get_rd_lat_number(1); rd_delayed = 0; rresp_time_cnt = 0; rd_v_b = 0; end else begin if(arvalid_flag[rresp_time_cnt] && ((($time - arvalid_receive_time[rresp_time_cnt])/s_aclk_period) >= rd_latency_count)) rd_delayed = 1; if(!read_fifo_empty && rd_delayed)begin rd_delayed = 0; arvalid_flag[rresp_time_cnt] = 1'b0; rd_v_b = ((arlen[rd_cnt[int_rd_cntr_width-2:0]]+1)(2*arsize[rd_cnt[int_rd_cntr_width-2:0]])); temp_read_data = read_fifo[rd_fifo_rd_ptr[int_rd_cntr_width-2:0]]; rd_fifo_rd_ptr = rd_fifo_rd_ptr+1; if(arbrst[rd_cnt[int_rd_cntr_width-2:0]]=== AXI_WRAP) begin get_wrap_aligned_rd_data(temp_wrap_data, araddr[rd_cnt[int_rd_cntr_width-2:0]], temp_read_data, rd_v_b); temp_read_data = temp_wrap_data; end temp_read_rsp = 0; repeat(axi_burst_len) begin temp_read_rsp = temp_read_rsp >> axi_rsp_width; temp_read_rsp[(axi_rsp_widthaxi_burst_len)-1:(axi_rsp_width*axi_burst_len)-axi_rsp_width] = fifo_rresp[rd_cnt[int_rd_cntr_width-2:0]][rsp_msb : rsp_lsb]; end slave.SEND_READ_BURST_RESP_CTRL(arid[rd_cnt[int_rd_cntr_width-2:0]], araddr[rd_cnt[int_rd_cntr_width-2:0]], arlen[rd_cnt[int_rd_cntr_width-2:0]], arsize[rd_cnt[int_rd_cntr_width-2:0]], arbrst[rd_cnt[int_rd_cntr_width-2:0]], temp_read_data, temp_read_rsp); rd_cnt = rd_cnt + 1; rresp_time_cnt = rresp_time_cnt+1; if(rresp_time_cnt === max_rd_outstanding_transactions) rresp_time_cnt = 0; if(rd_cnt[int_rd_cntr_width-2:0] === (max_rd_outstanding_transactions-1)) begin rd_cnt[int_rd_cntr_width-1] = ~ rd_cnt[int_rd_cntr_width-1]; rd_cnt[int_rd_cntr_width-2:0] = 0; end rd_latency_count = get_rd_lat_number(1); end end /// else end /// always endmodule
module generic_baseblocks_v2_1_command_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_ENABLE_S_VALID_CARRY = 0, parameter integer C_ENABLE_REGISTERED_OUTPUT = 0, parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2C_FIFO_DEPTH_LOG // Range = [4:5]. parameter integer C_FIFO_WIDTH = 64 // Width of payload [1:512] ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Information output wire EMPTY, // FIFO empty (all stages) // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for data vector. genvar addr_cnt; genvar bit_cnt; integer index; ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIFO_DEPTH_LOG-1:0] addr; wire buffer_Full; wire buffer_Empty; wire next_Data_Exists; reg data_Exists_I; wire valid_Write; wire new_write; wire [C_FIFO_DEPTH_LOG-1:0] hsum_A; wire [C_FIFO_DEPTH_LOG-1:0] sum_A; wire [C_FIFO_DEPTH_LOG-1:0] addr_cy; wire buffer_full_early; wire [C_FIFO_WIDTH-1:0] M_MESG_I; // Payload wire M_VALID_I; // FIFO not empty wire M_READY_I; // FIFO pop ///////////////////////////////////////////////////////////////////////////// // Create Flags ///////////////////////////////////////////////////////////////////////////// assign buffer_full_early = ( (addr == {{C_FIFO_DEPTH_LOG-1{1'b1}}, 1'b0}) & valid_Write & ~M_READY_I ) \| ( buffer_Full & ~M_READY_I ); assign S_READY = ~buffer_Full; assign buffer_Empty = (addr == {C_FIFO_DEPTH_LOG{1'b0}}); assign next_Data_Exists = (data_Exists_I & ~buffer_Empty) \| (buffer_Empty & S_VALID) \| (data_Exists_I & ~(M_READY_I & data_Exists_I)); always @ (posedge ACLK) begin if (ARESET) begin data_Exists_I <= 1'b0; end else begin data_Exists_I <= next_Data_Exists; end end assign M_VALID_I = data_Exists_I; // Select RTL or FPGA optimized instatiations for critical parts. generate if ( C_FAMILY == "rtl" \|\| C_ENABLE_S_VALID_CARRY == 0 ) begin : USE_RTL_VALID_WRITE reg buffer_Full_q; assign valid_Write = S_VALID & ~buffer_Full; assign new_write = (S_VALID \| ~buffer_Empty); assign addr_cy[0] = valid_Write; always @ (posedge ACLK) begin if (ARESET) begin buffer_Full_q <= 1'b0; end else if ( data_Exists_I ) begin buffer_Full_q <= buffer_full_early; end end assign buffer_Full = buffer_Full_q; end else begin : USE_FPGA_VALID_WRITE wire s_valid_dummy1; wire s_valid_dummy2; wire sel_s_valid; wire sel_new_write; wire valid_Write_dummy1; wire valid_Write_dummy2; assign sel_s_valid = ~buffer_Full; generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst1 ( .CIN(S_VALID), .S(1'b1), .COUT(s_valid_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst2 ( .CIN(s_valid_dummy1), .S(1'b1), .COUT(s_valid_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_inst ( .CIN(s_valid_dummy2), .S(sel_s_valid), .COUT(valid_Write) ); assign sel_new_write = ~buffer_Empty; generic_baseblocks_v2_1_carry_latch_or # ( .C_FAMILY(C_FAMILY) ) new_write_inst ( .CIN(valid_Write), .I(sel_new_write), .O(new_write) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst1 ( .CIN(valid_Write), .S(1'b1), .COUT(valid_Write_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst2 ( .CIN(valid_Write_dummy1), .S(1'b1), .COUT(valid_Write_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst3 ( .CIN(valid_Write_dummy2), .S(1'b1), .COUT(addr_cy[0]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_I1 ( .Q(buffer_Full), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(buffer_full_early) // Data input ); end endgenerate ///////////////////////////////////////////////////////////////////////////// // Create address pointer ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_ADDR reg [C_FIFO_DEPTH_LOG-1:0] addr_q; always @ (posedge ACLK) begin if (ARESET) begin addr_q <= {C_FIFO_DEPTH_LOG{1'b0}}; end else if ( data_Exists_I ) begin if ( valid_Write & ~(M_READY_I & data_Exists_I) ) begin addr_q <= addr_q + 1'b1; end else if ( ~valid_Write & (M_READY_I & data_Exists_I) & ~buffer_Empty ) begin addr_q <= addr_q - 1'b1; end else begin addr_q <= addr_q; end end else begin addr_q <= addr_q; end end assign addr = addr_q; end else begin : USE_FPGA_ADDR for (addr_cnt = 0; addr_cnt < C_FIFO_DEPTH_LOG ; addr_cnt = addr_cnt + 1) begin : ADDR_GEN assign hsum_A[addr_cnt] = ((M_READY_I & data_Exists_I) ^ addr[addr_cnt]) & new_write; // Don't need the last muxcy, addr_cy(last) is not used anywhere if ( addr_cnt < C_FIFO_DEPTH_LOG - 1 ) begin : USE_MUXCY MUXCY MUXCY_inst ( .DI(addr[addr_cnt]), .CI(addr_cy[addr_cnt]), .S(hsum_A[addr_cnt]), .O(addr_cy[addr_cnt+1]) ); end else begin : NO_MUXCY end XORCY XORCY_inst ( .LI(hsum_A[addr_cnt]), .CI(addr_cy[addr_cnt]), .O(sum_A[addr_cnt]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(addr[addr_cnt]), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(sum_A[addr_cnt]) // Data input ); end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Data storage ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_FIFO reg [C_FIFO_WIDTH-1:0] data_srl[2 C_FIFO_DEPTH_LOG-1:0]; always @ (posedge ACLK) begin if ( valid_Write ) begin for (index = 0; index < 2 ** C_FIFO_DEPTH_LOG-1 ; index = index + 1) begin data_srl[index+1] <= data_srl[index]; end data_srl[0] <= S_MESG; end end assign M_MESG_I = data_srl[addr]; end else begin : USE_FPGA_FIFO for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN if ( C_FIFO_DEPTH_LOG == 5 ) begin : USE_32 SRLC32E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC32E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q31(), // SRL cascade output pin .A(addr), // 5-bit shift depth select input .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end else begin : USE_16 SRLC16E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC16E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q15(), // SRL cascade output pin .A0(addr[0]), // 4-bit shift depth select input 0 .A1(addr[1]), // 4-bit shift depth select input 1 .A2(addr[2]), // 4-bit shift depth select input 2 .A3(addr[3]), // 4-bit shift depth select input 3 .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end // C_FIFO_DEPTH_LOG end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Pipeline stage ///////////////////////////////////////////////////////////////////////////// generate if ( C_ENABLE_REGISTERED_OUTPUT != 0 ) begin : USE_FF_OUT wire [C_FIFO_WIDTH-1:0] M_MESG_FF; // Payload wire M_VALID_FF; // FIFO not empty // Select RTL or FPGA optimized instatiations for critical parts. if ( C_FAMILY == "rtl" ) begin : USE_RTL_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_Q; // Payload reg M_VALID_Q; // FIFO not empty always @ (posedge ACLK) begin if (ARESET) begin M_MESG_Q <= {C_FIFO_WIDTH{1'b0}}; M_VALID_Q <= 1'b0; end else begin if ( M_READY_I ) begin M_MESG_Q <= M_MESG_I; M_VALID_Q <= M_VALID_I; end end end assign M_MESG_FF = M_MESG_Q; assign M_VALID_FF = M_VALID_Q; end else begin : USE_FPGA_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_CMB; // Payload reg M_VALID_CMB; // FIFO not empty always @ * begin if ( M_READY_I ) begin M_MESG_CMB <= M_MESG_I; M_VALID_CMB <= M_VALID_I; end else begin M_MESG_CMB <= M_MESG_FF; M_VALID_CMB <= M_VALID_FF; end end for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_MESG_FF[bit_cnt]), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_MESG_CMB[bit_cnt]) // Data input ); end // end for bit_cnt FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_VALID_FF), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_VALID_CMB) // Data input ); end assign EMPTY = ~M_VALID_I & ~M_VALID_FF; assign M_MESG = M_MESG_FF; assign M_VALID = M_VALID_FF; assign M_READY_I = ( M_READY & M_VALID_FF ) \| ~M_VALID_FF; end else begin : NO_FF_OUT assign EMPTY = ~M_VALID_I; assign M_MESG = M_MESG_I; assign M_VALID = M_VALID_I; assign M_READY_I = M_READY; end endgenerate endmodule
module generic_baseblocks_v2_1_command_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_ENABLE_S_VALID_CARRY = 0, parameter integer C_ENABLE_REGISTERED_OUTPUT = 0, parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2C_FIFO_DEPTH_LOG // Range = [4:5]. parameter integer C_FIFO_WIDTH = 64 // Width of payload [1:512] ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Information output wire EMPTY, // FIFO empty (all stages) // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for data vector. genvar addr_cnt; genvar bit_cnt; integer index; ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIFO_DEPTH_LOG-1:0] addr; wire buffer_Full; wire buffer_Empty; wire next_Data_Exists; reg data_Exists_I; wire valid_Write; wire new_write; wire [C_FIFO_DEPTH_LOG-1:0] hsum_A; wire [C_FIFO_DEPTH_LOG-1:0] sum_A; wire [C_FIFO_DEPTH_LOG-1:0] addr_cy; wire buffer_full_early; wire [C_FIFO_WIDTH-1:0] M_MESG_I; // Payload wire M_VALID_I; // FIFO not empty wire M_READY_I; // FIFO pop ///////////////////////////////////////////////////////////////////////////// // Create Flags ///////////////////////////////////////////////////////////////////////////// assign buffer_full_early = ( (addr == {{C_FIFO_DEPTH_LOG-1{1'b1}}, 1'b0}) & valid_Write & ~M_READY_I ) \| ( buffer_Full & ~M_READY_I ); assign S_READY = ~buffer_Full; assign buffer_Empty = (addr == {C_FIFO_DEPTH_LOG{1'b0}}); assign next_Data_Exists = (data_Exists_I & ~buffer_Empty) \| (buffer_Empty & S_VALID) \| (data_Exists_I & ~(M_READY_I & data_Exists_I)); always @ (posedge ACLK) begin if (ARESET) begin data_Exists_I <= 1'b0; end else begin data_Exists_I <= next_Data_Exists; end end assign M_VALID_I = data_Exists_I; // Select RTL or FPGA optimized instatiations for critical parts. generate if ( C_FAMILY == "rtl" \|\| C_ENABLE_S_VALID_CARRY == 0 ) begin : USE_RTL_VALID_WRITE reg buffer_Full_q; assign valid_Write = S_VALID & ~buffer_Full; assign new_write = (S_VALID \| ~buffer_Empty); assign addr_cy[0] = valid_Write; always @ (posedge ACLK) begin if (ARESET) begin buffer_Full_q <= 1'b0; end else if ( data_Exists_I ) begin buffer_Full_q <= buffer_full_early; end end assign buffer_Full = buffer_Full_q; end else begin : USE_FPGA_VALID_WRITE wire s_valid_dummy1; wire s_valid_dummy2; wire sel_s_valid; wire sel_new_write; wire valid_Write_dummy1; wire valid_Write_dummy2; assign sel_s_valid = ~buffer_Full; generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst1 ( .CIN(S_VALID), .S(1'b1), .COUT(s_valid_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst2 ( .CIN(s_valid_dummy1), .S(1'b1), .COUT(s_valid_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_inst ( .CIN(s_valid_dummy2), .S(sel_s_valid), .COUT(valid_Write) ); assign sel_new_write = ~buffer_Empty; generic_baseblocks_v2_1_carry_latch_or # ( .C_FAMILY(C_FAMILY) ) new_write_inst ( .CIN(valid_Write), .I(sel_new_write), .O(new_write) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst1 ( .CIN(valid_Write), .S(1'b1), .COUT(valid_Write_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst2 ( .CIN(valid_Write_dummy1), .S(1'b1), .COUT(valid_Write_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst3 ( .CIN(valid_Write_dummy2), .S(1'b1), .COUT(addr_cy[0]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_I1 ( .Q(buffer_Full), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(buffer_full_early) // Data input ); end endgenerate ///////////////////////////////////////////////////////////////////////////// // Create address pointer ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_ADDR reg [C_FIFO_DEPTH_LOG-1:0] addr_q; always @ (posedge ACLK) begin if (ARESET) begin addr_q <= {C_FIFO_DEPTH_LOG{1'b0}}; end else if ( data_Exists_I ) begin if ( valid_Write & ~(M_READY_I & data_Exists_I) ) begin addr_q <= addr_q + 1'b1; end else if ( ~valid_Write & (M_READY_I & data_Exists_I) & ~buffer_Empty ) begin addr_q <= addr_q - 1'b1; end else begin addr_q <= addr_q; end end else begin addr_q <= addr_q; end end assign addr = addr_q; end else begin : USE_FPGA_ADDR for (addr_cnt = 0; addr_cnt < C_FIFO_DEPTH_LOG ; addr_cnt = addr_cnt + 1) begin : ADDR_GEN assign hsum_A[addr_cnt] = ((M_READY_I & data_Exists_I) ^ addr[addr_cnt]) & new_write; // Don't need the last muxcy, addr_cy(last) is not used anywhere if ( addr_cnt < C_FIFO_DEPTH_LOG - 1 ) begin : USE_MUXCY MUXCY MUXCY_inst ( .DI(addr[addr_cnt]), .CI(addr_cy[addr_cnt]), .S(hsum_A[addr_cnt]), .O(addr_cy[addr_cnt+1]) ); end else begin : NO_MUXCY end XORCY XORCY_inst ( .LI(hsum_A[addr_cnt]), .CI(addr_cy[addr_cnt]), .O(sum_A[addr_cnt]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(addr[addr_cnt]), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(sum_A[addr_cnt]) // Data input ); end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Data storage ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_FIFO reg [C_FIFO_WIDTH-1:0] data_srl[2 C_FIFO_DEPTH_LOG-1:0]; always @ (posedge ACLK) begin if ( valid_Write ) begin for (index = 0; index < 2 ** C_FIFO_DEPTH_LOG-1 ; index = index + 1) begin data_srl[index+1] <= data_srl[index]; end data_srl[0] <= S_MESG; end end assign M_MESG_I = data_srl[addr]; end else begin : USE_FPGA_FIFO for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN if ( C_FIFO_DEPTH_LOG == 5 ) begin : USE_32 SRLC32E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC32E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q31(), // SRL cascade output pin .A(addr), // 5-bit shift depth select input .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end else begin : USE_16 SRLC16E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC16E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q15(), // SRL cascade output pin .A0(addr[0]), // 4-bit shift depth select input 0 .A1(addr[1]), // 4-bit shift depth select input 1 .A2(addr[2]), // 4-bit shift depth select input 2 .A3(addr[3]), // 4-bit shift depth select input 3 .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end // C_FIFO_DEPTH_LOG end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Pipeline stage ///////////////////////////////////////////////////////////////////////////// generate if ( C_ENABLE_REGISTERED_OUTPUT != 0 ) begin : USE_FF_OUT wire [C_FIFO_WIDTH-1:0] M_MESG_FF; // Payload wire M_VALID_FF; // FIFO not empty // Select RTL or FPGA optimized instatiations for critical parts. if ( C_FAMILY == "rtl" ) begin : USE_RTL_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_Q; // Payload reg M_VALID_Q; // FIFO not empty always @ (posedge ACLK) begin if (ARESET) begin M_MESG_Q <= {C_FIFO_WIDTH{1'b0}}; M_VALID_Q <= 1'b0; end else begin if ( M_READY_I ) begin M_MESG_Q <= M_MESG_I; M_VALID_Q <= M_VALID_I; end end end assign M_MESG_FF = M_MESG_Q; assign M_VALID_FF = M_VALID_Q; end else begin : USE_FPGA_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_CMB; // Payload reg M_VALID_CMB; // FIFO not empty always @ * begin if ( M_READY_I ) begin M_MESG_CMB <= M_MESG_I; M_VALID_CMB <= M_VALID_I; end else begin M_MESG_CMB <= M_MESG_FF; M_VALID_CMB <= M_VALID_FF; end end for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_MESG_FF[bit_cnt]), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_MESG_CMB[bit_cnt]) // Data input ); end // end for bit_cnt FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_VALID_FF), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_VALID_CMB) // Data input ); end assign EMPTY = ~M_VALID_I & ~M_VALID_FF; assign M_MESG = M_MESG_FF; assign M_VALID = M_VALID_FF; assign M_READY_I = ( M_READY & M_VALID_FF ) \| ~M_VALID_FF; end else begin : NO_FF_OUT assign EMPTY = ~M_VALID_I; assign M_MESG = M_MESG_I; assign M_VALID = M_VALID_I; assign M_READY_I = M_READY; end endgenerate endmodule
module generic_baseblocks_v2_1_command_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_ENABLE_S_VALID_CARRY = 0, parameter integer C_ENABLE_REGISTERED_OUTPUT = 0, parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2C_FIFO_DEPTH_LOG // Range = [4:5]. parameter integer C_FIFO_WIDTH = 64 // Width of payload [1:512] ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Information output wire EMPTY, // FIFO empty (all stages) // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for data vector. genvar addr_cnt; genvar bit_cnt; integer index; ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIFO_DEPTH_LOG-1:0] addr; wire buffer_Full; wire buffer_Empty; wire next_Data_Exists; reg data_Exists_I; wire valid_Write; wire new_write; wire [C_FIFO_DEPTH_LOG-1:0] hsum_A; wire [C_FIFO_DEPTH_LOG-1:0] sum_A; wire [C_FIFO_DEPTH_LOG-1:0] addr_cy; wire buffer_full_early; wire [C_FIFO_WIDTH-1:0] M_MESG_I; // Payload wire M_VALID_I; // FIFO not empty wire M_READY_I; // FIFO pop ///////////////////////////////////////////////////////////////////////////// // Create Flags ///////////////////////////////////////////////////////////////////////////// assign buffer_full_early = ( (addr == {{C_FIFO_DEPTH_LOG-1{1'b1}}, 1'b0}) & valid_Write & ~M_READY_I ) \| ( buffer_Full & ~M_READY_I ); assign S_READY = ~buffer_Full; assign buffer_Empty = (addr == {C_FIFO_DEPTH_LOG{1'b0}}); assign next_Data_Exists = (data_Exists_I & ~buffer_Empty) \| (buffer_Empty & S_VALID) \| (data_Exists_I & ~(M_READY_I & data_Exists_I)); always @ (posedge ACLK) begin if (ARESET) begin data_Exists_I <= 1'b0; end else begin data_Exists_I <= next_Data_Exists; end end assign M_VALID_I = data_Exists_I; // Select RTL or FPGA optimized instatiations for critical parts. generate if ( C_FAMILY == "rtl" \|\| C_ENABLE_S_VALID_CARRY == 0 ) begin : USE_RTL_VALID_WRITE reg buffer_Full_q; assign valid_Write = S_VALID & ~buffer_Full; assign new_write = (S_VALID \| ~buffer_Empty); assign addr_cy[0] = valid_Write; always @ (posedge ACLK) begin if (ARESET) begin buffer_Full_q <= 1'b0; end else if ( data_Exists_I ) begin buffer_Full_q <= buffer_full_early; end end assign buffer_Full = buffer_Full_q; end else begin : USE_FPGA_VALID_WRITE wire s_valid_dummy1; wire s_valid_dummy2; wire sel_s_valid; wire sel_new_write; wire valid_Write_dummy1; wire valid_Write_dummy2; assign sel_s_valid = ~buffer_Full; generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst1 ( .CIN(S_VALID), .S(1'b1), .COUT(s_valid_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst2 ( .CIN(s_valid_dummy1), .S(1'b1), .COUT(s_valid_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_inst ( .CIN(s_valid_dummy2), .S(sel_s_valid), .COUT(valid_Write) ); assign sel_new_write = ~buffer_Empty; generic_baseblocks_v2_1_carry_latch_or # ( .C_FAMILY(C_FAMILY) ) new_write_inst ( .CIN(valid_Write), .I(sel_new_write), .O(new_write) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst1 ( .CIN(valid_Write), .S(1'b1), .COUT(valid_Write_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst2 ( .CIN(valid_Write_dummy1), .S(1'b1), .COUT(valid_Write_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst3 ( .CIN(valid_Write_dummy2), .S(1'b1), .COUT(addr_cy[0]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_I1 ( .Q(buffer_Full), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(buffer_full_early) // Data input ); end endgenerate ///////////////////////////////////////////////////////////////////////////// // Create address pointer ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_ADDR reg [C_FIFO_DEPTH_LOG-1:0] addr_q; always @ (posedge ACLK) begin if (ARESET) begin addr_q <= {C_FIFO_DEPTH_LOG{1'b0}}; end else if ( data_Exists_I ) begin if ( valid_Write & ~(M_READY_I & data_Exists_I) ) begin addr_q <= addr_q + 1'b1; end else if ( ~valid_Write & (M_READY_I & data_Exists_I) & ~buffer_Empty ) begin addr_q <= addr_q - 1'b1; end else begin addr_q <= addr_q; end end else begin addr_q <= addr_q; end end assign addr = addr_q; end else begin : USE_FPGA_ADDR for (addr_cnt = 0; addr_cnt < C_FIFO_DEPTH_LOG ; addr_cnt = addr_cnt + 1) begin : ADDR_GEN assign hsum_A[addr_cnt] = ((M_READY_I & data_Exists_I) ^ addr[addr_cnt]) & new_write; // Don't need the last muxcy, addr_cy(last) is not used anywhere if ( addr_cnt < C_FIFO_DEPTH_LOG - 1 ) begin : USE_MUXCY MUXCY MUXCY_inst ( .DI(addr[addr_cnt]), .CI(addr_cy[addr_cnt]), .S(hsum_A[addr_cnt]), .O(addr_cy[addr_cnt+1]) ); end else begin : NO_MUXCY end XORCY XORCY_inst ( .LI(hsum_A[addr_cnt]), .CI(addr_cy[addr_cnt]), .O(sum_A[addr_cnt]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(addr[addr_cnt]), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(sum_A[addr_cnt]) // Data input ); end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Data storage ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_FIFO reg [C_FIFO_WIDTH-1:0] data_srl[2 C_FIFO_DEPTH_LOG-1:0]; always @ (posedge ACLK) begin if ( valid_Write ) begin for (index = 0; index < 2 ** C_FIFO_DEPTH_LOG-1 ; index = index + 1) begin data_srl[index+1] <= data_srl[index]; end data_srl[0] <= S_MESG; end end assign M_MESG_I = data_srl[addr]; end else begin : USE_FPGA_FIFO for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN if ( C_FIFO_DEPTH_LOG == 5 ) begin : USE_32 SRLC32E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC32E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q31(), // SRL cascade output pin .A(addr), // 5-bit shift depth select input .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end else begin : USE_16 SRLC16E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC16E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q15(), // SRL cascade output pin .A0(addr[0]), // 4-bit shift depth select input 0 .A1(addr[1]), // 4-bit shift depth select input 1 .A2(addr[2]), // 4-bit shift depth select input 2 .A3(addr[3]), // 4-bit shift depth select input 3 .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end // C_FIFO_DEPTH_LOG end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Pipeline stage ///////////////////////////////////////////////////////////////////////////// generate if ( C_ENABLE_REGISTERED_OUTPUT != 0 ) begin : USE_FF_OUT wire [C_FIFO_WIDTH-1:0] M_MESG_FF; // Payload wire M_VALID_FF; // FIFO not empty // Select RTL or FPGA optimized instatiations for critical parts. if ( C_FAMILY == "rtl" ) begin : USE_RTL_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_Q; // Payload reg M_VALID_Q; // FIFO not empty always @ (posedge ACLK) begin if (ARESET) begin M_MESG_Q <= {C_FIFO_WIDTH{1'b0}}; M_VALID_Q <= 1'b0; end else begin if ( M_READY_I ) begin M_MESG_Q <= M_MESG_I; M_VALID_Q <= M_VALID_I; end end end assign M_MESG_FF = M_MESG_Q; assign M_VALID_FF = M_VALID_Q; end else begin : USE_FPGA_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_CMB; // Payload reg M_VALID_CMB; // FIFO not empty always @ * begin if ( M_READY_I ) begin M_MESG_CMB <= M_MESG_I; M_VALID_CMB <= M_VALID_I; end else begin M_MESG_CMB <= M_MESG_FF; M_VALID_CMB <= M_VALID_FF; end end for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_MESG_FF[bit_cnt]), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_MESG_CMB[bit_cnt]) // Data input ); end // end for bit_cnt FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_VALID_FF), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_VALID_CMB) // Data input ); end assign EMPTY = ~M_VALID_I & ~M_VALID_FF; assign M_MESG = M_MESG_FF; assign M_VALID = M_VALID_FF; assign M_READY_I = ( M_READY & M_VALID_FF ) \| ~M_VALID_FF; end else begin : NO_FF_OUT assign EMPTY = ~M_VALID_I; assign M_MESG = M_MESG_I; assign M_VALID = M_VALID_I; assign M_READY_I = M_READY; end endgenerate endmodule
module generic_baseblocks_v2_1_command_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_ENABLE_S_VALID_CARRY = 0, parameter integer C_ENABLE_REGISTERED_OUTPUT = 0, parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2C_FIFO_DEPTH_LOG // Range = [4:5]. parameter integer C_FIFO_WIDTH = 64 // Width of payload [1:512] ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Information output wire EMPTY, // FIFO empty (all stages) // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for data vector. genvar addr_cnt; genvar bit_cnt; integer index; ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIFO_DEPTH_LOG-1:0] addr; wire buffer_Full; wire buffer_Empty; wire next_Data_Exists; reg data_Exists_I; wire valid_Write; wire new_write; wire [C_FIFO_DEPTH_LOG-1:0] hsum_A; wire [C_FIFO_DEPTH_LOG-1:0] sum_A; wire [C_FIFO_DEPTH_LOG-1:0] addr_cy; wire buffer_full_early; wire [C_FIFO_WIDTH-1:0] M_MESG_I; // Payload wire M_VALID_I; // FIFO not empty wire M_READY_I; // FIFO pop ///////////////////////////////////////////////////////////////////////////// // Create Flags ///////////////////////////////////////////////////////////////////////////// assign buffer_full_early = ( (addr == {{C_FIFO_DEPTH_LOG-1{1'b1}}, 1'b0}) & valid_Write & ~M_READY_I ) \| ( buffer_Full & ~M_READY_I ); assign S_READY = ~buffer_Full; assign buffer_Empty = (addr == {C_FIFO_DEPTH_LOG{1'b0}}); assign next_Data_Exists = (data_Exists_I & ~buffer_Empty) \| (buffer_Empty & S_VALID) \| (data_Exists_I & ~(M_READY_I & data_Exists_I)); always @ (posedge ACLK) begin if (ARESET) begin data_Exists_I <= 1'b0; end else begin data_Exists_I <= next_Data_Exists; end end assign M_VALID_I = data_Exists_I; // Select RTL or FPGA optimized instatiations for critical parts. generate if ( C_FAMILY == "rtl" \|\| C_ENABLE_S_VALID_CARRY == 0 ) begin : USE_RTL_VALID_WRITE reg buffer_Full_q; assign valid_Write = S_VALID & ~buffer_Full; assign new_write = (S_VALID \| ~buffer_Empty); assign addr_cy[0] = valid_Write; always @ (posedge ACLK) begin if (ARESET) begin buffer_Full_q <= 1'b0; end else if ( data_Exists_I ) begin buffer_Full_q <= buffer_full_early; end end assign buffer_Full = buffer_Full_q; end else begin : USE_FPGA_VALID_WRITE wire s_valid_dummy1; wire s_valid_dummy2; wire sel_s_valid; wire sel_new_write; wire valid_Write_dummy1; wire valid_Write_dummy2; assign sel_s_valid = ~buffer_Full; generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst1 ( .CIN(S_VALID), .S(1'b1), .COUT(s_valid_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst2 ( .CIN(s_valid_dummy1), .S(1'b1), .COUT(s_valid_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_inst ( .CIN(s_valid_dummy2), .S(sel_s_valid), .COUT(valid_Write) ); assign sel_new_write = ~buffer_Empty; generic_baseblocks_v2_1_carry_latch_or # ( .C_FAMILY(C_FAMILY) ) new_write_inst ( .CIN(valid_Write), .I(sel_new_write), .O(new_write) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst1 ( .CIN(valid_Write), .S(1'b1), .COUT(valid_Write_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst2 ( .CIN(valid_Write_dummy1), .S(1'b1), .COUT(valid_Write_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst3 ( .CIN(valid_Write_dummy2), .S(1'b1), .COUT(addr_cy[0]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_I1 ( .Q(buffer_Full), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(buffer_full_early) // Data input ); end endgenerate ///////////////////////////////////////////////////////////////////////////// // Create address pointer ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_ADDR reg [C_FIFO_DEPTH_LOG-1:0] addr_q; always @ (posedge ACLK) begin if (ARESET) begin addr_q <= {C_FIFO_DEPTH_LOG{1'b0}}; end else if ( data_Exists_I ) begin if ( valid_Write & ~(M_READY_I & data_Exists_I) ) begin addr_q <= addr_q + 1'b1; end else if ( ~valid_Write & (M_READY_I & data_Exists_I) & ~buffer_Empty ) begin addr_q <= addr_q - 1'b1; end else begin addr_q <= addr_q; end end else begin addr_q <= addr_q; end end assign addr = addr_q; end else begin : USE_FPGA_ADDR for (addr_cnt = 0; addr_cnt < C_FIFO_DEPTH_LOG ; addr_cnt = addr_cnt + 1) begin : ADDR_GEN assign hsum_A[addr_cnt] = ((M_READY_I & data_Exists_I) ^ addr[addr_cnt]) & new_write; // Don't need the last muxcy, addr_cy(last) is not used anywhere if ( addr_cnt < C_FIFO_DEPTH_LOG - 1 ) begin : USE_MUXCY MUXCY MUXCY_inst ( .DI(addr[addr_cnt]), .CI(addr_cy[addr_cnt]), .S(hsum_A[addr_cnt]), .O(addr_cy[addr_cnt+1]) ); end else begin : NO_MUXCY end XORCY XORCY_inst ( .LI(hsum_A[addr_cnt]), .CI(addr_cy[addr_cnt]), .O(sum_A[addr_cnt]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(addr[addr_cnt]), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(sum_A[addr_cnt]) // Data input ); end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Data storage ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_FIFO reg [C_FIFO_WIDTH-1:0] data_srl[2 C_FIFO_DEPTH_LOG-1:0]; always @ (posedge ACLK) begin if ( valid_Write ) begin for (index = 0; index < 2 ** C_FIFO_DEPTH_LOG-1 ; index = index + 1) begin data_srl[index+1] <= data_srl[index]; end data_srl[0] <= S_MESG; end end assign M_MESG_I = data_srl[addr]; end else begin : USE_FPGA_FIFO for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN if ( C_FIFO_DEPTH_LOG == 5 ) begin : USE_32 SRLC32E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC32E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q31(), // SRL cascade output pin .A(addr), // 5-bit shift depth select input .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end else begin : USE_16 SRLC16E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC16E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q15(), // SRL cascade output pin .A0(addr[0]), // 4-bit shift depth select input 0 .A1(addr[1]), // 4-bit shift depth select input 1 .A2(addr[2]), // 4-bit shift depth select input 2 .A3(addr[3]), // 4-bit shift depth select input 3 .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end // C_FIFO_DEPTH_LOG end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Pipeline stage ///////////////////////////////////////////////////////////////////////////// generate if ( C_ENABLE_REGISTERED_OUTPUT != 0 ) begin : USE_FF_OUT wire [C_FIFO_WIDTH-1:0] M_MESG_FF; // Payload wire M_VALID_FF; // FIFO not empty // Select RTL or FPGA optimized instatiations for critical parts. if ( C_FAMILY == "rtl" ) begin : USE_RTL_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_Q; // Payload reg M_VALID_Q; // FIFO not empty always @ (posedge ACLK) begin if (ARESET) begin M_MESG_Q <= {C_FIFO_WIDTH{1'b0}}; M_VALID_Q <= 1'b0; end else begin if ( M_READY_I ) begin M_MESG_Q <= M_MESG_I; M_VALID_Q <= M_VALID_I; end end end assign M_MESG_FF = M_MESG_Q; assign M_VALID_FF = M_VALID_Q; end else begin : USE_FPGA_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_CMB; // Payload reg M_VALID_CMB; // FIFO not empty always @ * begin if ( M_READY_I ) begin M_MESG_CMB <= M_MESG_I; M_VALID_CMB <= M_VALID_I; end else begin M_MESG_CMB <= M_MESG_FF; M_VALID_CMB <= M_VALID_FF; end end for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_MESG_FF[bit_cnt]), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_MESG_CMB[bit_cnt]) // Data input ); end // end for bit_cnt FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_VALID_FF), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_VALID_CMB) // Data input ); end assign EMPTY = ~M_VALID_I & ~M_VALID_FF; assign M_MESG = M_MESG_FF; assign M_VALID = M_VALID_FF; assign M_READY_I = ( M_READY & M_VALID_FF ) \| ~M_VALID_FF; end else begin : NO_FF_OUT assign EMPTY = ~M_VALID_I; assign M_MESG = M_MESG_I; assign M_VALID = M_VALID_I; assign M_READY_I = M_READY; end endgenerate endmodule
module generic_baseblocks_v2_1_comparator_sel_mask_static # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter C_VALUE = 4'b0, // Static value to compare against. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {C_VALUE, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = C_VALUE; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) \| ( ( ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module generic_baseblocks_v2_1_comparator_sel_mask_static # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter C_VALUE = 4'b0, // Static value to compare against. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {C_VALUE, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = C_VALUE; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) \| ( ( ( b_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cntC_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule
module axi_data_fifo_v2_1_axic_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2**C_FIFO_DEPTH_LOG // Range = [5:9] when TYPE="lut", // Range = [5:12] when TYPE="bram", parameter integer C_FIFO_WIDTH = 64, // Width of payload [1:512] parameter C_FIFO_TYPE = "lut" // "lut" = LUT (SRL) based, // "bram" = BRAM based ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); axi_data_fifo_v2_1_fifo_gen #( .C_FAMILY(C_FAMILY), .C_COMMON_CLOCK(1), .C_FIFO_DEPTH_LOG(C_FIFO_DEPTH_LOG), .C_FIFO_WIDTH(C_FIFO_WIDTH), .C_FIFO_TYPE(C_FIFO_TYPE)) inst ( .clk(ACLK), .rst(ARESET), .wr_clk(1'b0), .wr_en(S_VALID), .wr_ready(S_READY), .wr_data(S_MESG), .rd_clk(1'b0), .rd_en(M_READY), .rd_valid(M_VALID), .rd_data(M_MESG)); endmodule
module axi_data_fifo_v2_1_axic_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2**C_FIFO_DEPTH_LOG // Range = [5:9] when TYPE="lut", // Range = [5:12] when TYPE="bram", parameter integer C_FIFO_WIDTH = 64, // Width of payload [1:512] parameter C_FIFO_TYPE = "lut" // "lut" = LUT (SRL) based, // "bram" = BRAM based ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); axi_data_fifo_v2_1_fifo_gen #( .C_FAMILY(C_FAMILY), .C_COMMON_CLOCK(1), .C_FIFO_DEPTH_LOG(C_FIFO_DEPTH_LOG), .C_FIFO_WIDTH(C_FIFO_WIDTH), .C_FIFO_TYPE(C_FIFO_TYPE)) inst ( .clk(ACLK), .rst(ARESET), .wr_clk(1'b0), .wr_en(S_VALID), .wr_ready(S_READY), .wr_data(S_MESG), .rd_clk(1'b0), .rd_en(M_READY), .rd_valid(M_VALID), .rd_data(M_MESG)); endmodule
module axi_data_fifo_v2_1_axic_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2**C_FIFO_DEPTH_LOG // Range = [5:9] when TYPE="lut", // Range = [5:12] when TYPE="bram", parameter integer C_FIFO_WIDTH = 64, // Width of payload [1:512] parameter C_FIFO_TYPE = "lut" // "lut" = LUT (SRL) based, // "bram" = BRAM based ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); axi_data_fifo_v2_1_fifo_gen #( .C_FAMILY(C_FAMILY), .C_COMMON_CLOCK(1), .C_FIFO_DEPTH_LOG(C_FIFO_DEPTH_LOG), .C_FIFO_WIDTH(C_FIFO_WIDTH), .C_FIFO_TYPE(C_FIFO_TYPE)) inst ( .clk(ACLK), .rst(ARESET), .wr_clk(1'b0), .wr_en(S_VALID), .wr_ready(S_READY), .wr_data(S_MESG), .rd_clk(1'b0), .rd_en(M_READY), .rd_valid(M_VALID), .rd_data(M_MESG)); endmodule
module axi_data_fifo_v2_1_axic_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2**C_FIFO_DEPTH_LOG // Range = [5:9] when TYPE="lut", // Range = [5:12] when TYPE="bram", parameter integer C_FIFO_WIDTH = 64, // Width of payload [1:512] parameter C_FIFO_TYPE = "lut" // "lut" = LUT (SRL) based, // "bram" = BRAM based ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); axi_data_fifo_v2_1_fifo_gen #( .C_FAMILY(C_FAMILY), .C_COMMON_CLOCK(1), .C_FIFO_DEPTH_LOG(C_FIFO_DEPTH_LOG), .C_FIFO_WIDTH(C_FIFO_WIDTH), .C_FIFO_TYPE(C_FIFO_TYPE)) inst ( .clk(ACLK), .rst(ARESET), .wr_clk(1'b0), .wr_en(S_VALID), .wr_ready(S_READY), .wr_data(S_MESG), .rd_clk(1'b0), .rd_en(M_READY), .rd_valid(M_VALID), .rd_data(M_MESG)); endmodule

module mig_7series_v2_3_ddr_phy_wrlvl # ( parameter TCQ = 100, parameter DQS_CNT_WIDTH = 3, parameter DQ_WIDTH = 64, parameter DQS_WIDTH = 2, parameter DRAM_WIDTH = 8, parameter RANKS = 1, parameter nCK_PER_CLK = 4, parameter CLK_PERIOD = 4, parameter SIM_CAL_OPTION = "NONE" ) ( input clk, input rst, input phy_ctl_ready, input wr_level_start, input wl_sm_start, input wrlvl_final, input wrlvl_byte_redo, input [DQS_CNT_WIDTH:0] wrcal_cnt, input early1_data, input early2_data, input [DQS_CNT_WIDTH:0] oclkdelay_calib_cnt, input oclkdelay_calib_done, input [(DQ_WIDTH)-1:0] rd_data_rise0, output reg wrlvl_byte_done, output reg dqs_po_dec_done /* synthesis syn_maxfan = 2 */, output phy_ctl_rdy_dly, output reg wr_level_done /* synthesis syn_maxfan = 2 */, // to phy_init for cs logic output wrlvl_rank_done, output done_dqs_tap_inc, output [DQS_CNT_WIDTH:0] po_stg2_wl_cnt, // Fine delay line used only during write leveling // Inc/dec Phaser_Out fine delay line output reg dqs_po_stg2_f_incdec, // Enable Phaser_Out fine delay inc/dec output reg dqs_po_en_stg2_f, // Coarse delay line used during write leveling // only if 64 taps of fine delay line were not // sufficient to detect a 0->1 transition // Inc Phaser_Out coarse delay line output reg dqs_wl_po_stg2_c_incdec, // Enable Phaser_Out coarse delay inc/dec output reg dqs_wl_po_en_stg2_c, // Read Phaser_Out delay value input [8:0] po_counter_read_val, // output reg dqs_wl_po_stg2_load, // output reg [8:0] dqs_wl_po_stg2_reg_l, // CK edge undetected output reg wrlvl_err, output reg [3*DQS_WIDTH-1:0] wl_po_coarse_cnt, output reg [6*DQS_WIDTH-1:0] wl_po_fine_cnt, // Debug ports output [5:0] dbg_wl_tap_cnt, output dbg_wl_edge_detect_valid, output [(DQS_WIDTH)-1:0] dbg_rd_data_edge_detect, output [DQS_CNT_WIDTH:0] dbg_dqs_count, output [4:0] dbg_wl_state, output [6*DQS_WIDTH-1:0] dbg_wrlvl_fine_tap_cnt, output [3*DQS_WIDTH-1:0] dbg_wrlvl_coarse_tap_cnt, output [255:0] dbg_phy_wrlvl ); localparam WL_IDLE = 5'h0; localparam WL_INIT = 5'h1; localparam WL_INIT_FINE_INC = 5'h2; localparam WL_INIT_FINE_INC_WAIT1= 5'h3; localparam WL_INIT_FINE_INC_WAIT = 5'h4; localparam WL_INIT_FINE_DEC = 5'h5; localparam WL_INIT_FINE_DEC_WAIT = 5'h6; localparam WL_FINE_INC = 5'h7; localparam WL_WAIT = 5'h8; localparam WL_EDGE_CHECK = 5'h9; localparam WL_DQS_CHECK = 5'hA; localparam WL_DQS_CNT = 5'hB; localparam WL_2RANK_TAP_DEC = 5'hC; localparam WL_2RANK_DQS_CNT = 5'hD; localparam WL_FINE_DEC = 5'hE; localparam WL_FINE_DEC_WAIT = 5'hF; localparam WL_CORSE_INC = 5'h10; localparam WL_CORSE_INC_WAIT = 5'h11; localparam WL_CORSE_INC_WAIT1 = 5'h12; localparam WL_CORSE_INC_WAIT2 = 5'h13; localparam WL_CORSE_DEC = 5'h14; localparam WL_CORSE_DEC_WAIT = 5'h15; localparam WL_CORSE_DEC_WAIT1 = 5'h16; localparam WL_FINE_INC_WAIT = 5'h17; localparam WL_2RANK_FINAL_TAP = 5'h18; localparam WL_INIT_FINE_DEC_WAIT1= 5'h19; localparam WL_FINE_DEC_WAIT1 = 5'h1A; localparam WL_CORSE_INC_WAIT_TMP = 5'h1B; localparam COARSE_TAPS = 7; localparam FAST_CAL_FINE = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 45 : 48; localparam FAST_CAL_COARSE = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 1 : 2; localparam REDO_COARSE = (CLK_PERIOD/nCK_PER_CLK <= 2500) ? 2 : 5; integer i, j, k, l, p, q, r, s, t, m, n, u, v, w, x,y; reg phy_ctl_ready_r1; reg phy_ctl_ready_r2; reg phy_ctl_ready_r3; reg phy_ctl_ready_r4; reg phy_ctl_ready_r5; reg phy_ctl_ready_r6; (* max_fanout = 50 *) reg [DQS_CNT_WIDTH:0] dqs_count_r; reg [1:0] rank_cnt_r; reg [DQS_WIDTH-1:0] rd_data_rise_wl_r; reg [DQS_WIDTH-1:0] rd_data_previous_r; reg [DQS_WIDTH-1:0] rd_data_edge_detect_r; reg wr_level_done_r; reg wrlvl_rank_done_r; reg wr_level_start_r; reg [4:0] wl_state_r, wl_state_r1; reg inhibit_edge_detect_r; reg wl_edge_detect_valid_r; reg [5:0] wl_tap_count_r; reg [5:0] fine_dec_cnt; reg [5:0] fine_inc[0:DQS_WIDTH-1]; // DQS_WIDTH number of counters 6-bit each reg [2:0] corse_dec[0:DQS_WIDTH-1]; reg [2:0] corse_inc[0:DQS_WIDTH-1]; reg dq_cnt_inc; reg [3:0] stable_cnt; reg flag_ck_negedge; //reg past_negedge; reg flag_init; reg [2:0] corse_cnt[0:DQS_WIDTH-1]; reg [3*DQS_WIDTH-1:0] corse_cnt_dbg; reg [2:0] wl_corse_cnt[0:RANKS-1][0:DQS_WIDTH-1]; //reg [3*DQS_WIDTH-1:0] coarse_tap_inc; reg [2:0] final_coarse_tap[0:DQS_WIDTH-1]; reg [5:0] add_smallest[0:DQS_WIDTH-1]; reg [5:0] add_largest[0:DQS_WIDTH-1]; //reg [6*DQS_WIDTH-1:0] fine_tap_inc; //reg [6*DQS_WIDTH-1:0] fine_tap_dec; reg wr_level_done_r1; reg wr_level_done_r2; reg wr_level_done_r3; reg wr_level_done_r4; reg wr_level_done_r5; reg [5:0] wl_dqs_tap_count_r[0:RANKS-1][0:DQS_WIDTH-1]; reg [5:0] smallest[0:DQS_WIDTH-1]; reg [5:0] largest[0:DQS_WIDTH-1]; reg [5:0] final_val[0:DQS_WIDTH-1]; reg [5:0] po_dec_cnt[0:DQS_WIDTH-1]; reg done_dqs_dec; reg [8:0] po_rdval_cnt; reg po_cnt_dec; reg po_dec_done; reg dual_rnk_dec; wire [DQS_CNT_WIDTH+2:0] dqs_count_w; reg [5:0] fast_cal_fine_cnt; reg [2:0] fast_cal_coarse_cnt; reg wrlvl_byte_redo_r; reg [2:0] wrlvl_redo_corse_inc; reg wrlvl_final_r; reg final_corse_dec; wire [DQS_CNT_WIDTH+2:0] oclk_count_w; reg wrlvl_tap_done_r ; reg [3:0] wait_cnt; reg [3:0] incdec_wait_cnt; // Debug ports assign dbg_wl_edge_detect_valid = wl_edge_detect_valid_r; assign dbg_rd_data_edge_detect = rd_data_edge_detect_r; assign dbg_wl_tap_cnt = wl_tap_count_r; assign dbg_dqs_count = dqs_count_r; assign dbg_wl_state = wl_state_r; assign dbg_wrlvl_fine_tap_cnt = wl_po_fine_cnt; assign dbg_wrlvl_coarse_tap_cnt = wl_po_coarse_cnt; always @(*) begin for (v = 0; v < DQS_WIDTH; v = v + 1) corse_cnt_dbg[3*v+:3] = corse_cnt[v]; end assign dbg_phy_wrlvl[0+:27] = corse_cnt_dbg; assign dbg_phy_wrlvl[27+:5] = wl_state_r; assign dbg_phy_wrlvl[32+:4] = dqs_count_r; assign dbg_phy_wrlvl[36+:9] = rd_data_rise_wl_r; assign dbg_phy_wrlvl[45+:9] = rd_data_previous_r; assign dbg_phy_wrlvl[54+:4] = stable_cnt; assign dbg_phy_wrlvl[58] = 'd0; assign dbg_phy_wrlvl[59] = flag_ck_negedge; assign dbg_phy_wrlvl [60] = wl_edge_detect_valid_r; assign dbg_phy_wrlvl [61+:6] = wl_tap_count_r; assign dbg_phy_wrlvl [67+:9] = rd_data_edge_detect_r; assign dbg_phy_wrlvl [76+:54] = wl_po_fine_cnt; assign dbg_phy_wrlvl [130+:27] = wl_po_coarse_cnt; //************************************************************************** // DQS count to hard PHY during write leveling using Phaser_OUT Stage2 delay //************************************************************************** assign po_stg2_wl_cnt = dqs_count_r; assign wrlvl_rank_done = wrlvl_rank_done_r; assign done_dqs_tap_inc = done_dqs_dec; assign phy_ctl_rdy_dly = phy_ctl_ready_r6; always @(posedge clk) begin phy_ctl_ready_r1 <= #TCQ phy_ctl_ready; phy_ctl_ready_r2 <= #TCQ phy_ctl_ready_r1; phy_ctl_ready_r3 <= #TCQ phy_ctl_ready_r2; phy_ctl_ready_r4 <= #TCQ phy_ctl_ready_r3; phy_ctl_ready_r5 <= #TCQ phy_ctl_ready_r4; phy_ctl_ready_r6 <= #TCQ phy_ctl_ready_r5; wrlvl_byte_redo_r <= #TCQ wrlvl_byte_redo; wrlvl_final_r <= #TCQ wrlvl_final; if ((wrlvl_byte_redo && ~wrlvl_byte_redo_r) || (wrlvl_final && ~wrlvl_final_r)) wr_level_done <= #TCQ 1'b0; else wr_level_done <= #TCQ done_dqs_dec; end // Status signal that will be asserted once the first // pass of write leveling is done. always @(posedge clk) begin if(rst) begin wrlvl_tap_done_r <= #TCQ 1'b0 ; end else begin if(wrlvl_tap_done_r == 1'b0) begin if(oclkdelay_calib_done) begin wrlvl_tap_done_r <= #TCQ 1'b1 ; end end end end always @(posedge clk) begin if (rst || po_cnt_dec) wait_cnt <= #TCQ 'd8; else if (phy_ctl_ready_r6 && (wait_cnt > 'd0)) wait_cnt <= #TCQ wait_cnt - 1; end always @(posedge clk) begin if (rst) begin po_rdval_cnt <= #TCQ 'd0; end else if (phy_ctl_ready_r5 && ~phy_ctl_ready_r6) begin po_rdval_cnt <= #TCQ po_counter_read_val; end else if (po_rdval_cnt > 'd0) begin if (po_cnt_dec) po_rdval_cnt <= #TCQ po_rdval_cnt - 1; else po_rdval_cnt <= #TCQ po_rdval_cnt; end else if (po_rdval_cnt == 'd0) begin po_rdval_cnt <= #TCQ po_rdval_cnt; end end always @(posedge clk) begin if (rst || (po_rdval_cnt == 'd0)) po_cnt_dec <= #TCQ 1'b0; else if (phy_ctl_ready_r6 && (po_rdval_cnt > 'd0) && (wait_cnt == 'd1)) po_cnt_dec <= #TCQ 1'b1; else po_cnt_dec <= #TCQ 1'b0; end always @(posedge clk) begin if (rst) po_dec_done <= #TCQ 1'b0; else if (((po_cnt_dec == 'd1) && (po_rdval_cnt == 'd1)) || (phy_ctl_ready_r6 && (po_rdval_cnt == 'd0))) begin po_dec_done <= #TCQ 1'b1; end end always @(posedge clk) begin dqs_po_dec_done <= #TCQ po_dec_done; wr_level_done_r1 <= #TCQ wr_level_done_r; wr_level_done_r2 <= #TCQ wr_level_done_r1; wr_level_done_r3 <= #TCQ wr_level_done_r2; wr_level_done_r4 <= #TCQ wr_level_done_r3; wr_level_done_r5 <= #TCQ wr_level_done_r4; for (l = 0; l < DQS_WIDTH; l = l + 1) begin wl_po_coarse_cnt[3*l+:3] <= #TCQ final_coarse_tap[l]; if ((RANKS == 1) || ~oclkdelay_calib_done) wl_po_fine_cnt[6*l+:6] <= #TCQ smallest[l]; else wl_po_fine_cnt[6*l+:6] <= #TCQ final_val[l]; end end generate if (RANKS == 2) begin: dual_rank always @(posedge clk) begin if (rst || (wrlvl_byte_redo && ~wrlvl_byte_redo_r) || (wrlvl_final && ~wrlvl_final_r)) done_dqs_dec <= #TCQ 1'b0; else if ((SIM_CAL_OPTION == "FAST_CAL") || ~oclkdelay_calib_done) done_dqs_dec <= #TCQ wr_level_done_r; else if (wr_level_done_r5 && (wl_state_r == WL_IDLE)) done_dqs_dec <= #TCQ 1'b1; end end else begin: single_rank always @(posedge clk) begin if (rst || (wrlvl_byte_redo && ~wrlvl_byte_redo_r) || (wrlvl_final && ~wrlvl_final_r)) done_dqs_dec <= #TCQ 1'b0; else if (~oclkdelay_calib_done) done_dqs_dec <= #TCQ wr_level_done_r; else if (wr_level_done_r3 && ~wr_level_done_r4) done_dqs_dec <= #TCQ 1'b1; end end endgenerate always @(posedge clk) if (rst || (wrlvl_byte_redo && ~wrlvl_byte_redo_r)) wrlvl_byte_done <= #TCQ 1'b0; else if (wrlvl_byte_redo && wr_level_done_r3 && ~wr_level_done_r4) wrlvl_byte_done <= #TCQ 1'b1; // Storing DQS tap values at the end of each DQS write leveling always @(posedge clk) begin if (rst) begin for (k = 0; k < RANKS; k = k + 1) begin: rst_wl_dqs_tap_count_loop for (n = 0; n < DQS_WIDTH; n = n + 1) begin wl_corse_cnt[k][n] <= #TCQ 'b0; wl_dqs_tap_count_r[k][n] <= #TCQ 'b0; end end end else if ((wl_state_r == WL_DQS_CNT) | (wl_state_r == WL_WAIT) | (wl_state_r == WL_FINE_DEC_WAIT1) | (wl_state_r == WL_2RANK_TAP_DEC)) begin wl_dqs_tap_count_r[rank_cnt_r][dqs_count_r] <= #TCQ wl_tap_count_r; wl_corse_cnt[rank_cnt_r][dqs_count_r] <= #TCQ corse_cnt[dqs_count_r]; end else if ((SIM_CAL_OPTION == "FAST_CAL") & (wl_state_r == WL_DQS_CHECK)) begin for (p = 0; p < RANKS; p = p +1) begin: dqs_tap_rank_cnt for(q = 0; q < DQS_WIDTH; q = q +1) begin: dqs_tap_dqs_cnt wl_dqs_tap_count_r[p][q] <= #TCQ wl_tap_count_r; wl_corse_cnt[p][q] <= #TCQ corse_cnt[0]; end end end end // Convert coarse delay to fine taps in case of unequal number of coarse // taps between ranks. Assuming a difference of 1 coarse tap counts // between ranks. A common fine and coarse tap value must be used for both ranks // because Phaser_Out has only one rank register. // Coarse tap1 = period(ps)*93/360 = 34 fine taps // Other coarse taps = period(ps)*103/360 = 38 fine taps generate genvar cnt; if (RANKS == 2) begin // Dual rank for(cnt = 0; cnt < DQS_WIDTH; cnt = cnt +1) begin: coarse_dqs_cnt always @(posedge clk) begin if (rst) begin //coarse_tap_inc[3*cnt+:3] <= #TCQ 'b0; add_smallest[cnt] <= #TCQ 'd0; add_largest[cnt] <= #TCQ 'd0; final_coarse_tap[cnt] <= #TCQ 'd0; end else if (wr_level_done_r1 & ~wr_level_done_r2) begin if (~oclkdelay_calib_done) begin for(y = 0 ; y < DQS_WIDTH; y = y+1) begin final_coarse_tap[y] <= #TCQ wl_corse_cnt[0][y]; add_smallest[y] <= #TCQ 'd0; add_largest[y] <= #TCQ 'd0; end end else if (wl_corse_cnt[0][cnt] == wl_corse_cnt[1][cnt]) begin // Both ranks have use the same number of coarse delay taps. // No conversion of coarse tap to fine taps required. //coarse_tap_inc[3*cnt+:3] <= #TCQ wl_corse_cnt[1][3*cnt+:3]; final_coarse_tap[cnt] <= #TCQ wl_corse_cnt[1][cnt]; add_smallest[cnt] <= #TCQ 'd0; add_largest[cnt] <= #TCQ 'd0; end else if (wl_corse_cnt[0][cnt] < wl_corse_cnt[1][cnt]) begin // Rank 0 uses fewer coarse delay taps than rank1. // conversion of coarse tap to fine taps required for rank1. // The final coarse count will the smaller value. //coarse_tap_inc[3*cnt+:3] <= #TCQ wl_corse_cnt[1][3*cnt+:3] - 1; final_coarse_tap[cnt] <= #TCQ wl_corse_cnt[1][cnt] - 1; if (|wl_corse_cnt[0][cnt]) // Coarse tap 2 or higher being converted to fine taps // This will be added to 'largest' value in final_val // computation add_largest[cnt] <= #TCQ 'd38; else // Coarse tap 1 being converted to fine taps // This will be added to 'largest' value in final_val // computation add_largest[cnt] <= #TCQ 'd34; end else if (wl_corse_cnt[0][cnt] > wl_corse_cnt[1][cnt]) begin // This may be an unlikely scenario in a real system. // Rank 0 uses more coarse delay taps than rank1. // conversion of coarse tap to fine taps required. //coarse_tap_inc[3*cnt+:3] <= #TCQ 'd0; final_coarse_tap[cnt] <= #TCQ wl_corse_cnt[1][cnt]; if (|wl_corse_cnt[1][cnt]) // Coarse tap 2 or higher being converted to fine taps // This will be added to 'smallest' value in final_val // computation add_smallest[cnt] <= #TCQ 'd38; else // Coarse tap 1 being converted to fine taps // This will be added to 'smallest' value in // final_val computation add_smallest[cnt] <= #TCQ 'd34; end end end end end else begin // Single rank always @(posedge clk) begin //coarse_tap_inc <= #TCQ 'd0; for(w = 0; w < DQS_WIDTH; w = w + 1) begin final_coarse_tap[w] <= #TCQ wl_corse_cnt[0][w]; add_smallest[w] <= #TCQ 'd0; add_largest[w] <= #TCQ 'd0; end end end endgenerate // Determine delay value for DQS in multirank system // Assuming delay value is the smallest for rank 0 DQS // and largest delay value for rank 4 DQS // Set to smallest + ((largest-smallest)/2) always @(posedge clk) begin if (rst) begin for(x = 0; x < DQS_WIDTH; x = x +1) begin smallest[x] <= #TCQ 'b0; largest[x] <= #TCQ 'b0; end end else if ((wl_state_r == WL_DQS_CNT) & wrlvl_byte_redo) begin smallest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[0][dqs_count_r]; largest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[0][dqs_count_r]; end else if ((wl_state_r == WL_DQS_CNT) | (wl_state_r == WL_2RANK_TAP_DEC)) begin smallest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[0][dqs_count_r]; largest[dqs_count_r] <= #TCQ wl_dqs_tap_count_r[RANKS-1][dqs_count_r]; end else if (((SIM_CAL_OPTION == "FAST_CAL") | (~oclkdelay_calib_done & ~wrlvl_byte_redo)) & wr_level_done_r1 & ~wr_level_done_r2) begin for(i = 0; i < DQS_WIDTH; i = i +1) begin: smallest_dqs smallest[i] <= #TCQ wl_dqs_tap_count_r[0][i]; largest[i] <= #TCQ wl_dqs_tap_count_r[0][i]; end end end // final_val to be used for all DQSs in all ranks genvar wr_i; generate for (wr_i = 0; wr_i < DQS_WIDTH; wr_i = wr_i +1) begin: gen_final_tap always @(posedge clk) begin if (rst) final_val[wr_i] <= #TCQ 'b0; else if (wr_level_done_r2 && ~wr_level_done_r3) begin if (~oclkdelay_calib_done) final_val[wr_i] <= #TCQ (smallest[wr_i] + add_smallest[wr_i]); else if ((smallest[wr_i] + add_smallest[wr_i]) < (largest[wr_i] + add_largest[wr_i])) final_val[wr_i] <= #TCQ ((smallest[wr_i] + add_smallest[wr_i]) + (((largest[wr_i] + add_largest[wr_i]) - (smallest[wr_i] + add_smallest[wr_i]))/2)); else if ((smallest[wr_i] + add_smallest[wr_i]) > (largest[wr_i] + add_largest[wr_i])) final_val[wr_i] <= #TCQ ((largest[wr_i] + add_largest[wr_i]) + (((smallest[wr_i] + add_smallest[wr_i]) - (largest[wr_i] + add_largest[wr_i]))/2)); else if ((smallest[wr_i] + add_smallest[wr_i]) == (largest[wr_i] + add_largest[wr_i])) final_val[wr_i] <= #TCQ (largest[wr_i] + add_largest[wr_i]); end end end endgenerate // // fine tap inc/dec value for all DQSs in all ranks // genvar dqs_i; // generate // for (dqs_i = 0; dqs_i < DQS_WIDTH; dqs_i = dqs_i +1) begin: gen_fine_tap // always @(posedge clk) begin // if (rst) // fine_tap_inc[6*dqs_i+:6] <= #TCQ 'd0; // //fine_tap_dec[6*dqs_i+:6] <= #TCQ 'd0; // else if (wr_level_done_r3 && ~wr_level_done_r4) begin // fine_tap_inc[6*dqs_i+:6] <= #TCQ final_val[6*dqs_i+:6]; // //fine_tap_dec[6*dqs_i+:6] <= #TCQ 'd0; // end // end // endgenerate // Inc/Dec Phaser_Out stage 2 fine delay line always @(posedge clk) begin if (rst) begin // Fine delay line used only during write leveling dqs_po_stg2_f_incdec <= #TCQ 1'b0; dqs_po_en_stg2_f <= #TCQ 1'b0; // Dec Phaser_Out fine delay (1)before write leveling, // (2)if no 0 to 1 transition detected with 63 fine delay taps, or // (3)dual rank case where fine taps for the first rank need to be 0 end else if (po_cnt_dec || (wl_state_r == WL_INIT_FINE_DEC) || (wl_state_r == WL_FINE_DEC)) begin dqs_po_stg2_f_incdec <= #TCQ 1'b0; dqs_po_en_stg2_f <= #TCQ 1'b1; // Inc Phaser_Out fine delay during write leveling end else if ((wl_state_r == WL_INIT_FINE_INC) || (wl_state_r == WL_FINE_INC)) begin dqs_po_stg2_f_incdec <= #TCQ 1'b1; dqs_po_en_stg2_f <= #TCQ 1'b1; end else begin dqs_po_stg2_f_incdec <= #TCQ 1'b0; dqs_po_en_stg2_f <= #TCQ 1'b0; end end // Inc Phaser_Out stage 2 Coarse delay line always @(posedge clk) begin if (rst) begin // Coarse delay line used during write leveling // only if no 0->1 transition undetected with 64 // fine delay line taps dqs_wl_po_stg2_c_incdec <= #TCQ 1'b0; dqs_wl_po_en_stg2_c <= #TCQ 1'b0; end else if (wl_state_r == WL_CORSE_INC) begin // Inc Phaser_Out coarse delay during write leveling dqs_wl_po_stg2_c_incdec <= #TCQ 1'b1; dqs_wl_po_en_stg2_c <= #TCQ 1'b1; end else begin dqs_wl_po_stg2_c_incdec <= #TCQ 1'b0; dqs_wl_po_en_stg2_c <= #TCQ 1'b0; end end // only storing the rise data for checking. The data comming back during // write leveling will be a static value. Just checking for rise data is // enough. genvar rd_i; generate for(rd_i = 0; rd_i < DQS_WIDTH; rd_i = rd_i +1)begin: gen_rd always @(posedge clk) rd_data_rise_wl_r[rd_i] <= #TCQ |rd_data_rise0[(rd_i*DRAM_WIDTH)+DRAM_WIDTH-1:rd_i*DRAM_WIDTH]; end endgenerate // storing the previous data for checking later. always @(posedge clk)begin if ((wl_state_r == WL_INIT) || //(wl_state_r == WL_INIT_FINE_INC_WAIT) || //(wl_state_r == WL_INIT_FINE_INC_WAIT1) || ((wl_state_r1 == WL_INIT_FINE_INC_WAIT) & (wl_state_r == WL_INIT_FINE_INC)) || (wl_state_r == WL_FINE_DEC) || (wl_state_r == WL_FINE_DEC_WAIT1) || (wl_state_r == WL_FINE_DEC_WAIT) || (wl_state_r == WL_CORSE_INC) || (wl_state_r == WL_CORSE_INC_WAIT) || (wl_state_r == WL_CORSE_INC_WAIT_TMP) || (wl_state_r == WL_CORSE_INC_WAIT1) || (wl_state_r == WL_CORSE_INC_WAIT2) || ((wl_state_r == WL_EDGE_CHECK) & (wl_edge_detect_valid_r))) rd_data_previous_r <= #TCQ rd_data_rise_wl_r; end // changed stable count from 3 to 7 because of fine tap resolution always @(posedge clk)begin if (rst | (wl_state_r == WL_DQS_CNT) | (wl_state_r == WL_2RANK_TAP_DEC) | (wl_state_r == WL_FINE_DEC) | (rd_data_previous_r[dqs_count_r] != rd_data_rise_wl_r[dqs_count_r]) | (wl_state_r1 == WL_INIT_FINE_DEC)) stable_cnt <= #TCQ 'd0; else if ((wl_tap_count_r > 6'd0) & (((wl_state_r == WL_EDGE_CHECK) & (wl_edge_detect_valid_r)) | ((wl_state_r1 == WL_INIT_FINE_INC_WAIT) & (wl_state_r == WL_INIT_FINE_INC)))) begin if ((rd_data_previous_r[dqs_count_r] == rd_data_rise_wl_r[dqs_count_r]) & (stable_cnt < 'd14)) stable_cnt <= #TCQ stable_cnt + 1; end end // Signal to ensure that flag_ck_negedge does not incorrectly assert // when DQS is very close to CK rising edge //always @(posedge clk) begin // if (rst | (wl_state_r == WL_DQS_CNT) | // (wl_state_r == WL_DQS_CHECK) | wr_level_done_r) // past_negedge <= #TCQ 1'b0; // else if (~flag_ck_negedge && ~rd_data_previous_r[dqs_count_r] && // (stable_cnt == 'd0) && ((wl_state_r == WL_CORSE_INC_WAIT1) | // (wl_state_r == WL_CORSE_INC_WAIT2))) // past_negedge <= #TCQ 1'b1; //end // Flag to indicate negedge of CK detected and ignore 0->1 transitions // in this region always @(posedge clk)begin if (rst | (wl_state_r == WL_DQS_CNT) | (wl_state_r == WL_DQS_CHECK) | wr_level_done_r | (wl_state_r1 == WL_INIT_FINE_DEC)) flag_ck_negedge <= #TCQ 1'd0; else if ((rd_data_previous_r[dqs_count_r] && ((stable_cnt > 'd0) | (wl_state_r == WL_FINE_DEC) | (wl_state_r == WL_FINE_DEC_WAIT) | (wl_state_r == WL_FINE_DEC_WAIT1))) | (wl_state_r == WL_CORSE_INC)) flag_ck_negedge <= #TCQ 1'd1; else if (~rd_data_previous_r[dqs_count_r] && (stable_cnt == 'd14)) //&& flag_ck_negedge) flag_ck_negedge <= #TCQ 1'd0; end // Flag to inhibit rd_data_edge_detect_r before stable DQ always @(posedge clk) begin if (rst) flag_init <= #TCQ 1'b1; else if ((wl_state_r == WL_WAIT) && ((wl_state_r1 == WL_INIT_FINE_INC_WAIT) || (wl_state_r1 == WL_INIT_FINE_DEC_WAIT))) flag_init <= #TCQ 1'b0; end //checking for transition from 0 to 1 always @(posedge clk)begin if (rst | flag_ck_negedge | flag_init | (wl_tap_count_r < 'd1) | inhibit_edge_detect_r) rd_data_edge_detect_r <= #TCQ {DQS_WIDTH{1'b0}}; else if (rd_data_edge_detect_r[dqs_count_r] == 1'b1) begin if ((wl_state_r == WL_FINE_DEC) || (wl_state_r == WL_FINE_DEC_WAIT) || (wl_state_r == WL_FINE_DEC_WAIT1) || (wl_state_r == WL_CORSE_INC) || (wl_state_r == WL_CORSE_INC_WAIT) || (wl_state_r == WL_CORSE_INC_WAIT_TMP) || (wl_state_r == WL_CORSE_INC_WAIT1) || (wl_state_r == WL_CORSE_INC_WAIT2)) rd_data_edge_detect_r <= #TCQ {DQS_WIDTH{1'b0}}; else rd_data_edge_detect_r <= #TCQ rd_data_edge_detect_r; end else if (rd_data_previous_r[dqs_count_r] && (stable_cnt < 'd14)) rd_data_edge_detect_r <= #TCQ {DQS_WIDTH{1'b0}}; else rd_data_edge_detect_r <= #TCQ (~rd_data_previous_r & rd_data_rise_wl_r); end // registring the write level start signal always@(posedge clk) begin wr_level_start_r <= #TCQ wr_level_start; end // Assign dqs_count_r to dqs_count_w to perform the shift operation // instead of multiply operation assign dqs_count_w = {2'b00, dqs_count_r}; assign oclk_count_w = {2'b00, oclkdelay_calib_cnt}; always @(posedge clk) begin if (rst) incdec_wait_cnt <= #TCQ 'd0; else if ((wl_state_r == WL_FINE_DEC_WAIT1) || (wl_state_r == WL_INIT_FINE_DEC_WAIT1) || (wl_state_r == WL_CORSE_INC_WAIT_TMP)) incdec_wait_cnt <= #TCQ incdec_wait_cnt + 1; else incdec_wait_cnt <= #TCQ 'd0; end // state machine to initiate the write leveling sequence // The state machine operates on one byte at a time. // It will increment the delays to the DQS OSERDES // and sample the DQ from the memory. When it detects // a transition from 1 to 0 then the write leveling is considered // done. always @(posedge clk) begin if(rst)begin wrlvl_err <= #TCQ 1'b0; wr_level_done_r <= #TCQ 1'b0; wrlvl_rank_done_r <= #TCQ 1'b0; dqs_count_r <= #TCQ {DQS_CNT_WIDTH+1{1'b0}}; dq_cnt_inc <= #TCQ 1'b1; rank_cnt_r <= #TCQ 2'b00; wl_state_r <= #TCQ WL_IDLE; wl_state_r1 <= #TCQ WL_IDLE; inhibit_edge_detect_r <= #TCQ 1'b1; wl_edge_detect_valid_r <= #TCQ 1'b0; wl_tap_count_r <= #TCQ 6'd0; fine_dec_cnt <= #TCQ 6'd0; for (r = 0; r < DQS_WIDTH; r = r + 1) begin fine_inc[r] <= #TCQ 6'b0; corse_dec[r] <= #TCQ 3'b0; corse_inc[r] <= #TCQ 3'b0; corse_cnt[r] <= #TCQ 3'b0; end dual_rnk_dec <= #TCQ 1'b0; fast_cal_fine_cnt <= #TCQ FAST_CAL_FINE; fast_cal_coarse_cnt <= #TCQ FAST_CAL_COARSE; final_corse_dec <= #TCQ 1'b0; //zero_tran_r <= #TCQ 1'b0; wrlvl_redo_corse_inc <= #TCQ 'd0; end else begin wl_state_r1 <= #TCQ wl_state_r; case (wl_state_r) WL_IDLE: begin wrlvl_rank_done_r <= #TCQ 1'd0; inhibit_edge_detect_r <= #TCQ 1'b1; if (wrlvl_byte_redo && ~wrlvl_byte_redo_r) begin wr_level_done_r <= #TCQ 1'b0; dqs_count_r <= #TCQ wrcal_cnt; corse_cnt[wrcal_cnt] <= #TCQ final_coarse_tap[wrcal_cnt]; wl_tap_count_r <= #TCQ smallest[wrcal_cnt]; if (early1_data && (((final_coarse_tap[wrcal_cnt] < 'd6) && (CLK_PERIOD/nCK_PER_CLK <= 2500)) || ((final_coarse_tap[wrcal_cnt] < 'd3) && (CLK_PERIOD/nCK_PER_CLK > 2500)))) wrlvl_redo_corse_inc <= #TCQ REDO_COARSE; else if (early2_data && (final_coarse_tap[wrcal_cnt] < 'd2)) wrlvl_redo_corse_inc <= #TCQ 3'd6; else begin wl_state_r <= #TCQ WL_IDLE; wrlvl_err <= #TCQ 1'b1; end end else if (wrlvl_final && ~wrlvl_final_r) begin wr_level_done_r <= #TCQ 1'b0; dqs_count_r <= #TCQ 'd0; end // verilint STARC-2.2.3.3 off if(!wr_level_done_r & wr_level_start_r & wl_sm_start) begin if (SIM_CAL_OPTION == "FAST_CAL") wl_state_r <= #TCQ WL_FINE_INC; else wl_state_r <= #TCQ WL_INIT; end end // verilint STARC-2.2.3.3 on WL_INIT: begin wl_edge_detect_valid_r <= #TCQ 1'b0; inhibit_edge_detect_r <= #TCQ 1'b1; wrlvl_rank_done_r <= #TCQ 1'd0; //zero_tran_r <= #TCQ 1'b0; if (wrlvl_final) corse_cnt[dqs_count_w ] <= #TCQ final_coarse_tap[dqs_count_w ]; if (wrlvl_byte_redo) begin if (|wl_tap_count_r) begin wl_state_r <= #TCQ WL_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; end else if ((corse_cnt[dqs_count_w] + wrlvl_redo_corse_inc) <= 'd7) wl_state_r <= #TCQ WL_CORSE_INC; else begin wl_state_r <= #TCQ WL_IDLE; wrlvl_err <= #TCQ 1'b1; end end else if(wl_sm_start) wl_state_r <= #TCQ WL_INIT_FINE_INC; end // Initially Phaser_Out fine delay taps incremented // until stable_cnt=14. A stable_cnt of 14 indicates // that rd_data_rise_wl_r=rd_data_previous_r for 14 fine // tap increments. This is done to inhibit false 0->1 // edge detection when DQS is initially aligned to the // negedge of CK WL_INIT_FINE_INC: begin wl_state_r <= #TCQ WL_INIT_FINE_INC_WAIT1; wl_tap_count_r <= #TCQ wl_tap_count_r + 1'b1; final_corse_dec <= #TCQ 1'b0; end WL_INIT_FINE_INC_WAIT1: begin if (wl_sm_start) wl_state_r <= #TCQ WL_INIT_FINE_INC_WAIT; end // Case1: stable value of rd_data_previous_r=0 then // proceed to 0->1 edge detection. // Case2: stable value of rd_data_previous_r=1 then // decrement fine taps to '0' and proceed to 0->1 // edge detection. Need to decrement in this case to // make sure a valid 0->1 transition was not left // undetected. WL_INIT_FINE_INC_WAIT: begin if (wl_sm_start) begin if (stable_cnt < 'd14) wl_state_r <= #TCQ WL_INIT_FINE_INC; else if (~rd_data_previous_r[dqs_count_r]) begin wl_state_r <= #TCQ WL_WAIT; inhibit_edge_detect_r <= #TCQ 1'b0; end else begin wl_state_r <= #TCQ WL_INIT_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; end end end // Case2: stable value of rd_data_previous_r=1 then // decrement fine taps to '0' and proceed to 0->1 // edge detection. Need to decrement in this case to // make sure a valid 0->1 transition was not left // undetected. WL_INIT_FINE_DEC: begin wl_tap_count_r <= #TCQ 'd0; wl_state_r <= #TCQ WL_INIT_FINE_DEC_WAIT1; if (fine_dec_cnt > 6'd0) fine_dec_cnt <= #TCQ fine_dec_cnt - 1; else fine_dec_cnt <= #TCQ fine_dec_cnt; end WL_INIT_FINE_DEC_WAIT1: begin if (incdec_wait_cnt == 'd8) wl_state_r <= #TCQ WL_INIT_FINE_DEC_WAIT; end WL_INIT_FINE_DEC_WAIT: begin if (fine_dec_cnt > 6'd0) begin wl_state_r <= #TCQ WL_INIT_FINE_DEC; inhibit_edge_detect_r <= #TCQ 1'b1; end else begin wl_state_r <= #TCQ WL_WAIT; inhibit_edge_detect_r <= #TCQ 1'b0; end end // Inc DQS Phaser_Out Stage2 Fine Delay line WL_FINE_INC: begin wl_edge_detect_valid_r <= #TCQ 1'b0; if (SIM_CAL_OPTION == "FAST_CAL") begin wl_state_r <= #TCQ WL_FINE_INC_WAIT; if (fast_cal_fine_cnt > 'd0) fast_cal_fine_cnt <= #TCQ fast_cal_fine_cnt - 1; else fast_cal_fine_cnt <= #TCQ fast_cal_fine_cnt; end else if (wr_level_done_r5) begin wl_tap_count_r <= #TCQ 'd0; wl_state_r <= #TCQ WL_FINE_INC_WAIT; if (|fine_inc[dqs_count_w]) fine_inc[dqs_count_w] <= #TCQ fine_inc[dqs_count_w] - 1; end else begin wl_state_r <= #TCQ WL_WAIT; wl_tap_count_r <= #TCQ wl_tap_count_r + 1'b1; end end WL_FINE_INC_WAIT: begin if (SIM_CAL_OPTION == "FAST_CAL") begin if (fast_cal_fine_cnt > 'd0) wl_state_r <= #TCQ WL_FINE_INC; else if (fast_cal_coarse_cnt > 'd0) wl_state_r <= #TCQ WL_CORSE_INC; else wl_state_r <= #TCQ WL_DQS_CNT; end else if (|fine_inc[dqs_count_w]) wl_state_r <= #TCQ WL_FINE_INC; else if (dqs_count_r == (DQS_WIDTH-1)) wl_state_r <= #TCQ WL_IDLE; else begin wl_state_r <= #TCQ WL_2RANK_FINAL_TAP; dqs_count_r <= #TCQ dqs_count_r + 1; end end WL_FINE_DEC: begin wl_edge_detect_valid_r <= #TCQ 1'b0; wl_tap_count_r <= #TCQ 'd0; wl_state_r <= #TCQ WL_FINE_DEC_WAIT1; if (fine_dec_cnt > 6'd0) fine_dec_cnt <= #TCQ fine_dec_cnt - 1; else fine_dec_cnt <= #TCQ fine_dec_cnt; end WL_FINE_DEC_WAIT1: begin if (incdec_wait_cnt == 'd8) wl_state_r <= #TCQ WL_FINE_DEC_WAIT; end WL_FINE_DEC_WAIT: begin if (fine_dec_cnt > 6'd0) wl_state_r <= #TCQ WL_FINE_DEC; //else if (zero_tran_r) // wl_state_r <= #TCQ WL_DQS_CNT; else if (dual_rnk_dec) begin if (|corse_dec[dqs_count_r]) wl_state_r <= #TCQ WL_CORSE_DEC; else wl_state_r <= #TCQ WL_2RANK_DQS_CNT; end else if (wrlvl_byte_redo) begin if ((corse_cnt[dqs_count_w] + wrlvl_redo_corse_inc) <= 'd7) wl_state_r <= #TCQ WL_CORSE_INC; else begin wl_state_r <= #TCQ WL_IDLE; wrlvl_err <= #TCQ 1'b1; end end else wl_state_r <= #TCQ WL_CORSE_INC; end WL_CORSE_DEC: begin wl_state_r <= #TCQ WL_CORSE_DEC_WAIT; dual_rnk_dec <= #TCQ 1'b0; if (|corse_dec[dqs_count_r]) corse_dec[dqs_count_r] <= #TCQ corse_dec[dqs_count_r] - 1; else corse_dec[dqs_count_r] <= #TCQ corse_dec[dqs_count_r]; end WL_CORSE_DEC_WAIT: begin if (wl_sm_start) begin //if (|corse_dec[dqs_count_r]) // wl_state_r <= #TCQ WL_CORSE_DEC; if (|corse_dec[dqs_count_r]) wl_state_r <= #TCQ WL_CORSE_DEC_WAIT1; else wl_state_r <= #TCQ WL_2RANK_DQS_CNT; end end WL_CORSE_DEC_WAIT1: begin if (wl_sm_start) wl_state_r <= #TCQ WL_CORSE_DEC; end WL_CORSE_INC: begin wl_state_r <= #TCQ WL_CORSE_INC_WAIT_TMP; if (SIM_CAL_OPTION == "FAST_CAL") begin if (fast_cal_coarse_cnt > 'd0) fast_cal_coarse_cnt <= #TCQ fast_cal_coarse_cnt - 1; else fast_cal_coarse_cnt <= #TCQ fast_cal_coarse_cnt; end else if (wrlvl_byte_redo) begin corse_cnt[dqs_count_w] <= #TCQ corse_cnt[dqs_count_w] + 1; if (|wrlvl_redo_corse_inc) wrlvl_redo_corse_inc <= #TCQ wrlvl_redo_corse_inc - 1; end else if (~wr_level_done_r5) corse_cnt[dqs_count_r] <= #TCQ corse_cnt[dqs_count_r] + 1; else if (|corse_inc[dqs_count_w]) corse_inc[dqs_count_w] <= #TCQ corse_inc[dqs_count_w] - 1; end WL_CORSE_INC_WAIT_TMP: begin if (incdec_wait_cnt == 'd8) wl_state_r <= #TCQ WL_CORSE_INC_WAIT; end WL_CORSE_INC_WAIT: begin if (SIM_CAL_OPTION == "FAST_CAL") begin if (fast_cal_coarse_cnt > 'd0) wl_state_r <= #TCQ WL_CORSE_INC; else wl_state_r <= #TCQ WL_DQS_CNT; end else if (wrlvl_byte_redo) begin if (|wrlvl_redo_corse_inc) wl_state_r <= #TCQ WL_CORSE_INC; else begin wl_state_r <= #TCQ WL_INIT_FINE_INC; inhibit_edge_detect_r <= #TCQ 1'b1; end end else if (~wr_level_done_r5 && wl_sm_start) wl_state_r <= #TCQ WL_CORSE_INC_WAIT1; else if (wr_level_done_r5) begin if (|corse_inc[dqs_count_r]) wl_state_r <= #TCQ WL_CORSE_INC; else if (|fine_inc[dqs_count_w]) wl_state_r <= #TCQ WL_FINE_INC; else if (dqs_count_r == (DQS_WIDTH-1)) wl_state_r <= #TCQ WL_IDLE; else begin wl_state_r <= #TCQ WL_2RANK_FINAL_TAP; dqs_count_r <= #TCQ dqs_count_r + 1; end end end WL_CORSE_INC_WAIT1: begin if (wl_sm_start) wl_state_r <= #TCQ WL_CORSE_INC_WAIT2; end WL_CORSE_INC_WAIT2: begin if (wl_sm_start) wl_state_r <= #TCQ WL_WAIT; end WL_WAIT: begin if (wl_sm_start) wl_state_r <= #TCQ WL_EDGE_CHECK; end WL_EDGE_CHECK: begin // Look for the edge if (wl_edge_detect_valid_r == 1'b0) begin wl_state_r <= #TCQ WL_WAIT; wl_edge_detect_valid_r <= #TCQ 1'b1; end // 0->1 transition detected with DQS else if(rd_data_edge_detect_r[dqs_count_r] && wl_edge_detect_valid_r) begin wl_tap_count_r <= #TCQ wl_tap_count_r; if ((SIM_CAL_OPTION == "FAST_CAL") || (RANKS < 2) || ~oclkdelay_calib_done) wl_state_r <= #TCQ WL_DQS_CNT; else wl_state_r <= #TCQ WL_2RANK_TAP_DEC; end // For initial writes check only upto 56 taps. Reserving the // remaining taps for OCLK calibration. else if((~wrlvl_tap_done_r) && (wl_tap_count_r > 6'd55)) begin if (corse_cnt[dqs_count_r] < COARSE_TAPS) begin wl_state_r <= #TCQ WL_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; end else begin wrlvl_err <= #TCQ 1'b1; wl_state_r <= #TCQ WL_IDLE; end end else begin if (wl_tap_count_r < 6'd56) //for reuse wrlvl for complex ocal wl_state_r <= #TCQ WL_FINE_INC; else if (corse_cnt[dqs_count_r] < COARSE_TAPS) begin wl_state_r <= #TCQ WL_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; end else begin wrlvl_err <= #TCQ 1'b1; wl_state_r <= #TCQ WL_IDLE; end end end WL_2RANK_TAP_DEC: begin wl_state_r <= #TCQ WL_FINE_DEC; fine_dec_cnt <= #TCQ wl_tap_count_r; for (m = 0; m < DQS_WIDTH; m = m + 1) corse_dec[m] <= #TCQ corse_cnt[m]; wl_edge_detect_valid_r <= #TCQ 1'b0; dual_rnk_dec <= #TCQ 1'b1; end WL_DQS_CNT: begin if ((SIM_CAL_OPTION == "FAST_CAL") || (dqs_count_r == (DQS_WIDTH-1)) || wrlvl_byte_redo) begin dqs_count_r <= #TCQ dqs_count_r; dq_cnt_inc <= #TCQ 1'b0; end else begin dqs_count_r <= #TCQ dqs_count_r + 1'b1; dq_cnt_inc <= #TCQ 1'b1; end wl_state_r <= #TCQ WL_DQS_CHECK; wl_edge_detect_valid_r <= #TCQ 1'b0; end WL_2RANK_DQS_CNT: begin if ((SIM_CAL_OPTION == "FAST_CAL") || (dqs_count_r == (DQS_WIDTH-1))) begin dqs_count_r <= #TCQ dqs_count_r; dq_cnt_inc <= #TCQ 1'b0; end else begin dqs_count_r <= #TCQ dqs_count_r + 1'b1; dq_cnt_inc <= #TCQ 1'b1; end wl_state_r <= #TCQ WL_DQS_CHECK; wl_edge_detect_valid_r <= #TCQ 1'b0; dual_rnk_dec <= #TCQ 1'b0; end WL_DQS_CHECK: begin // check if all DQS have been calibrated wl_tap_count_r <= #TCQ 'd0; if (dq_cnt_inc == 1'b0)begin wrlvl_rank_done_r <= #TCQ 1'd1; for (t = 0; t < DQS_WIDTH; t = t + 1) corse_cnt[t] <= #TCQ 3'b0; if ((SIM_CAL_OPTION == "FAST_CAL") || (RANKS < 2) || ~oclkdelay_calib_done) begin wl_state_r <= #TCQ WL_IDLE; if (wrlvl_byte_redo) dqs_count_r <= #TCQ dqs_count_r; else dqs_count_r <= #TCQ 'd0; end else if (rank_cnt_r == RANKS-1) begin dqs_count_r <= #TCQ dqs_count_r; if (RANKS > 1) wl_state_r <= #TCQ WL_2RANK_FINAL_TAP; else wl_state_r <= #TCQ WL_IDLE; end else begin wl_state_r <= #TCQ WL_INIT; dqs_count_r <= #TCQ 'd0; end if ((SIM_CAL_OPTION == "FAST_CAL") || (rank_cnt_r == RANKS-1)) begin wr_level_done_r <= #TCQ 1'd1; rank_cnt_r <= #TCQ 2'b00; end else begin wr_level_done_r <= #TCQ 1'd0; rank_cnt_r <= #TCQ rank_cnt_r + 1'b1; end end else wl_state_r <= #TCQ WL_INIT; end WL_2RANK_FINAL_TAP: begin if (wr_level_done_r4 && ~wr_level_done_r5) begin for(u = 0; u < DQS_WIDTH; u = u + 1) begin corse_inc[u] <= #TCQ final_coarse_tap[u]; fine_inc[u] <= #TCQ final_val[u]; end dqs_count_r <= #TCQ 'd0; end else if (wr_level_done_r5) begin if (|corse_inc[dqs_count_r]) wl_state_r <= #TCQ WL_CORSE_INC; else if (|fine_inc[dqs_count_w]) wl_state_r <= #TCQ WL_FINE_INC; end end endcase end end // always @ (posedge clk) endmodule

module mig_7series_v2_3_ecc_dec_fix #( parameter TCQ = 100, parameter PAYLOAD_WIDTH = 64, parameter CODE_WIDTH = 72, parameter DATA_WIDTH = 64, parameter DQ_WIDTH = 72, parameter ECC_WIDTH = 8, parameter nCK_PER_CLK = 4 ) ( /*AUTOARG*/ // Outputs rd_data, ecc_single, ecc_multiple, // Inputs clk, rst, h_rows, phy_rddata, correct_en, ecc_status_valid ); input clk; input rst; // Compute syndromes. input [CODE_WIDTH*ECC_WIDTH-1:0] h_rows; input [2*nCK_PER_CLK*DQ_WIDTH-1:0] phy_rddata; wire [2*nCK_PER_CLK*ECC_WIDTH-1:0] syndrome_ns; genvar k; genvar m; generate for (k=0; k<2*nCK_PER_CLK; k=k+1) begin : ecc_word for (m=0; m<ECC_WIDTH; m=m+1) begin : ecc_bit assign syndrome_ns[k*ECC_WIDTH+m] = ^(phy_rddata[k*DQ_WIDTH+:CODE_WIDTH] & h_rows[m*CODE_WIDTH+:CODE_WIDTH]); end end endgenerate reg [2*nCK_PER_CLK*ECC_WIDTH-1:0] syndrome_r; always @(posedge clk) syndrome_r <= #TCQ syndrome_ns; // Extract payload bits from raw DRAM bits and register. wire [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] ecc_rddata_ns; genvar i; generate for (i=0; i<2*nCK_PER_CLK; i=i+1) begin : extract_payload assign ecc_rddata_ns[i*PAYLOAD_WIDTH+:PAYLOAD_WIDTH] = phy_rddata[i*DQ_WIDTH+:PAYLOAD_WIDTH]; end endgenerate reg [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] ecc_rddata_r; always @(posedge clk) ecc_rddata_r <= #TCQ ecc_rddata_ns; // Regenerate h_matrix from h_rows leaving out the identity part // since we're not going to correct the ECC bits themselves. genvar n; genvar p; wire [ECC_WIDTH-1:0] h_matrix [DATA_WIDTH-1:0]; generate for (n=0; n<DATA_WIDTH; n=n+1) begin : h_col for (p=0; p<ECC_WIDTH; p=p+1) begin : h_bit assign h_matrix [n][p] = h_rows [p*CODE_WIDTH+n]; end end endgenerate // Compute flip bits. wire [2*nCK_PER_CLK*DATA_WIDTH-1:0] flip_bits; genvar q; genvar r; generate for (q=0; q<2*nCK_PER_CLK; q=q+1) begin : flip_word for (r=0; r<DATA_WIDTH; r=r+1) begin : flip_bit assign flip_bits[q*DATA_WIDTH+r] = h_matrix[r] == syndrome_r[q*ECC_WIDTH+:ECC_WIDTH]; end end endgenerate // Correct data. output reg [2*nCK_PER_CLK*PAYLOAD_WIDTH-1:0] rd_data; input correct_en; integer s; always @(/*AS*/correct_en or ecc_rddata_r or flip_bits) for (s=0; s<2*nCK_PER_CLK; s=s+1) if (correct_en) rd_data[s*PAYLOAD_WIDTH+:DATA_WIDTH] = ecc_rddata_r[s*PAYLOAD_WIDTH+:DATA_WIDTH] ^ flip_bits[s*DATA_WIDTH+:DATA_WIDTH]; else rd_data[s*PAYLOAD_WIDTH+:DATA_WIDTH] = ecc_rddata_r[s*PAYLOAD_WIDTH+:DATA_WIDTH]; // Copy raw payload bits if ECC_TEST is ON. localparam RAW_BIT_WIDTH = PAYLOAD_WIDTH - DATA_WIDTH; genvar t; generate if (RAW_BIT_WIDTH > 0) for (t=0; t<2*nCK_PER_CLK; t=t+1) begin : copy_raw_bits always @(/*AS*/ecc_rddata_r) rd_data[(t+1)*PAYLOAD_WIDTH-1-:RAW_BIT_WIDTH] = ecc_rddata_r[(t+1)*PAYLOAD_WIDTH-1-:RAW_BIT_WIDTH]; end endgenerate // Generate status information. input ecc_status_valid; output wire [2*nCK_PER_CLK-1:0] ecc_single; output wire [2*nCK_PER_CLK-1:0] ecc_multiple; genvar v; generate for (v=0; v<2*nCK_PER_CLK; v=v+1) begin : compute_status wire zero = ~|syndrome_r[v*ECC_WIDTH+:ECC_WIDTH]; wire odd = ^syndrome_r[v*ECC_WIDTH+:ECC_WIDTH]; assign ecc_single[v] = ecc_status_valid && ~zero && odd; assign ecc_multiple[v] = ecc_status_valid && ~zero && ~odd; end endgenerate endmodule

module mig_7series_v2_3_ddr_phy_ocd_po_cntlr # (parameter DQS_CNT_WIDTH = 3, parameter DQS_WIDTH = 8, parameter nCK_PER_CLK = 4, parameter TCQ = 100) (/*AUTOARG*/ // Outputs scan_done, ocal_num_samples_done_r, oclkdelay_center_calib_start, oclkdelay_center_calib_done, oclk_center_write_resume, ocd2stg2_inc, ocd2stg2_dec, ocd2stg3_inc, ocd2stg3_dec, stg3, simp_stg3_final, cmplx_stg3_final, simp_stg3_final_sel, ninety_offsets, scanning_right, ocd_ktap_left, ocd_ktap_right, ocd_edge_detect_rdy, taps_set, use_noise_window, ocal_scan_win_not_found, // Inputs clk, rst, reset_scan, oclkdelay_init_val, lim2ocal_stg3_right_lim, lim2ocal_stg3_left_lim, complex_oclkdelay_calib_start, po_counter_read_val, oclkdelay_calib_cnt, mmcm_edge_detect_done, mmcm_lbclk_edge_aligned, poc_backup, phy_rddata_en_3, zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty, z2f, f2z, o2f, f2o, scan_right, samp_done, wl_po_fine_cnt_sel, po_rdy ); input clk; input rst; input reset_scan; reg scan_done_r; output scan_done; assign scan_done = scan_done_r; output [5:0] simp_stg3_final_sel; reg cmplx_samples_done_ns, cmplx_samples_done_r; always @(posedge clk) cmplx_samples_done_r <= #TCQ cmplx_samples_done_ns; output ocal_num_samples_done_r; assign ocal_num_samples_done_r = cmplx_samples_done_r; // Write Level signals during OCLKDELAY calibration input [5:0] oclkdelay_init_val; input [5:0] lim2ocal_stg3_right_lim; input [5:0] lim2ocal_stg3_left_lim; input complex_oclkdelay_calib_start; reg oclkdelay_center_calib_start_ns, oclkdelay_center_calib_start_r; always @(posedge clk) oclkdelay_center_calib_start_r <= #TCQ oclkdelay_center_calib_start_ns; output oclkdelay_center_calib_start; assign oclkdelay_center_calib_start = oclkdelay_center_calib_start_r; reg oclkdelay_center_calib_done_ns, oclkdelay_center_calib_done_r; always @(posedge clk) oclkdelay_center_calib_done_r <= #TCQ oclkdelay_center_calib_done_ns; output oclkdelay_center_calib_done; assign oclkdelay_center_calib_done = oclkdelay_center_calib_done_r; reg oclk_center_write_resume_ns, oclk_center_write_resume_r; always @(posedge clk) oclk_center_write_resume_r <= #TCQ oclk_center_write_resume_ns; output oclk_center_write_resume; assign oclk_center_write_resume = oclk_center_write_resume_r; reg ocd2stg2_inc_r, ocd2stg2_dec_r, ocd2stg3_inc_r, ocd2stg3_dec_r; output ocd2stg2_inc, ocd2stg2_dec, ocd2stg3_inc, ocd2stg3_dec; assign ocd2stg2_inc = ocd2stg2_inc_r; assign ocd2stg2_dec = ocd2stg2_dec_r; assign ocd2stg3_inc = ocd2stg3_inc_r; assign ocd2stg3_dec = ocd2stg3_dec_r; // Remember, two stage 2 steps for every stg 3 step. And we need a sign bit. reg [8:0] stg2_ns, stg2_r; always @(posedge clk) stg2_r <= #TCQ stg2_ns; reg [5:0] stg3_ns, stg3_r; always @(posedge clk) stg3_r <= #TCQ stg3_ns; output [5:0] stg3; assign stg3 = stg3_r; input [5:0] wl_po_fine_cnt_sel; input [8:0] po_counter_read_val; reg [5:0] po_counter_read_val_r; always @(posedge clk) po_counter_read_val_r <= #TCQ po_counter_read_val[5:0]; reg [DQS_WIDTH*6-1:0] simp_stg3_final_ns, simp_stg3_final_r, cmplx_stg3_final_ns, cmplx_stg3_final_r; always @(posedge clk) simp_stg3_final_r <= #TCQ simp_stg3_final_ns; always @(posedge clk) cmplx_stg3_final_r <= #TCQ cmplx_stg3_final_ns; output [DQS_WIDTH*6-1:0] simp_stg3_final, cmplx_stg3_final; assign simp_stg3_final = simp_stg3_final_r; assign cmplx_stg3_final = cmplx_stg3_final_r; input [DQS_CNT_WIDTH:0] oclkdelay_calib_cnt; wire [DQS_WIDTH*6-1:0] simp_stg3_final_shft = simp_stg3_final_r >> oclkdelay_calib_cnt * 6; assign simp_stg3_final_sel = simp_stg3_final_shft[5:0]; wire [5:0] stg3_init = complex_oclkdelay_calib_start ? simp_stg3_final_sel : oclkdelay_init_val; wire signed [8:0] stg2_steps = stg3_r > stg3_init ? -9'sd2 * $signed({3'b0, (stg3_r - stg3_init)}) : 9'sd2 * $signed({3'b0, (stg3_init - stg3_r)}); wire signed [8:0] stg2_target_ns = $signed({3'b0, wl_po_fine_cnt_sel}) + stg2_steps; reg signed [8:0] stg2_target_r; always @ (posedge clk) stg2_target_r <= #TCQ stg2_target_ns; reg [5:0] stg2_final_ns, stg2_final_r; always @(posedge clk) stg2_final_r <= #TCQ stg2_final_ns; always @(*) stg2_final_ns = stg2_target_r[8] == 1'b1 ? 6'd0 : stg2_target_r > 9'd63 ? 6'd63 : stg2_target_r[5:0]; wire final_stg2_inc = stg2_final_r > po_counter_read_val_r; wire final_stg2_dec = stg2_final_r < po_counter_read_val_r; wire left_lim = stg3_r == lim2ocal_stg3_left_lim; wire right_lim = stg3_r == lim2ocal_stg3_right_lim; reg [1:0] ninety_offsets_ns, ninety_offsets_r; always @(posedge clk) ninety_offsets_r <= #TCQ ninety_offsets_ns; output [1:0] ninety_offsets; assign ninety_offsets = ninety_offsets_r; reg scanning_right_ns, scanning_right_r; always @(posedge clk) scanning_right_r <= #TCQ scanning_right_ns; output scanning_right; assign scanning_right = scanning_right_r; reg ocd_ktap_left_ns, ocd_ktap_left_r, ocd_ktap_right_ns, ocd_ktap_right_r; always @(posedge clk) ocd_ktap_left_r <= #TCQ ocd_ktap_left_ns; always @(posedge clk) ocd_ktap_right_r <= #TCQ ocd_ktap_right_ns; output ocd_ktap_left, ocd_ktap_right; assign ocd_ktap_left = ocd_ktap_left_r; assign ocd_ktap_right = ocd_ktap_right_r; reg ocd_edge_detect_rdy_ns, ocd_edge_detect_rdy_r; always @(posedge clk) ocd_edge_detect_rdy_r <= #TCQ ocd_edge_detect_rdy_ns; output ocd_edge_detect_rdy; assign ocd_edge_detect_rdy = ocd_edge_detect_rdy_r; input mmcm_edge_detect_done; input mmcm_lbclk_edge_aligned; input poc_backup; reg poc_backup_ns, poc_backup_r; always @(posedge clk) poc_backup_r <= #TCQ poc_backup_ns; reg taps_set_r; output taps_set; assign taps_set = taps_set_r; input phy_rddata_en_3; input [5:0] zero2fuzz, fuzz2zero, oneeighty2fuzz, fuzz2oneeighty; input z2f, f2z, o2f, f2o; wire zero = f2z && z2f; wire noise = z2f && f2o; wire oneeighty = f2o && o2f; reg win_not_found; reg [1:0] ninety_offsets_final; reg [5:0] left, right, current_edge; always @(*) begin left = lim2ocal_stg3_left_lim; right = lim2ocal_stg3_right_lim; ninety_offsets_final = 2'd0; win_not_found = 1'b0; if (zero) begin left = fuzz2zero; right = zero2fuzz; end else if (noise) begin left = zero2fuzz; right = fuzz2oneeighty; ninety_offsets_final = 2'd1; end else if (oneeighty) begin left = fuzz2oneeighty; right = oneeighty2fuzz; ninety_offsets_final = 2'd2; end else if (z2f) begin right = zero2fuzz; end else if (f2o) begin left = fuzz2oneeighty; ninety_offsets_final = 2'd2; end else if (f2z) begin left = fuzz2zero; end else win_not_found = 1'b1; current_edge = ocd_ktap_left_r ? left : right; end // always @ begin output use_noise_window; assign use_noise_window = ninety_offsets == 2'd1; reg ocal_scan_win_not_found_ns, ocal_scan_win_not_found_r; always @(posedge clk) ocal_scan_win_not_found_r <= #TCQ ocal_scan_win_not_found_ns; output ocal_scan_win_not_found; assign ocal_scan_win_not_found = ocal_scan_win_not_found_r; wire inc_po_ns = current_edge > stg3_r; wire dec_po_ns = current_edge < stg3_r; reg inc_po_r, dec_po_r; always @(posedge clk) inc_po_r <= #TCQ inc_po_ns; always @(posedge clk) dec_po_r <= #TCQ dec_po_ns; input scan_right; wire left_stop = left_lim || scan_right; wire right_stop = right_lim || o2f; reg [4:0] resume_wait_ns, resume_wait_r; always @(posedge clk) resume_wait_r <= #TCQ resume_wait_ns; wire resume_wait = |resume_wait_r; reg po_done_ns, po_done_r; always @(posedge clk) po_done_r <= #TCQ po_done_ns; input samp_done; input po_rdy; reg up_ns, up_r; always @(posedge clk) up_r <= #TCQ up_ns; reg [1:0] two_ns, two_r; always @(posedge clk) two_r <= #TCQ two_ns; /* wire stg2_zero = ~|stg2_r; wire [8:0] stg2_2_zero = stg2_r[8] ? 9'd0 : stg2_r > 9'd63 ? 9'd63 : stg2_r; */ reg [3:0] sm_ns, sm_r; always @(posedge clk) sm_r <= #TCQ sm_ns; (* dont_touch = "true" *) reg phy_rddata_en_3_second_ns, phy_rddata_en_3_second_r; always @(posedge clk) phy_rddata_en_3_second_r <= #TCQ phy_rddata_en_3_second_ns; always @(*) phy_rddata_en_3_second_ns = ~reset_scan && (phy_rddata_en_3 ? ~phy_rddata_en_3_second_r : phy_rddata_en_3_second_r); (* dont_touch = "true" *) wire use_samp_done = nCK_PER_CLK == 2 ? phy_rddata_en_3 && phy_rddata_en_3_second_r : phy_rddata_en_3; reg po_center_wait; reg po_slew; reg po_finish_scan; always @(*) begin // Default next state assignments. cmplx_samples_done_ns = cmplx_samples_done_r; cmplx_stg3_final_ns = cmplx_stg3_final_r; scanning_right_ns = scanning_right_r; ninety_offsets_ns = ninety_offsets_r; ocal_scan_win_not_found_ns = ocal_scan_win_not_found_r; ocd_edge_detect_rdy_ns = ocd_edge_detect_rdy_r; ocd_ktap_left_ns = ocd_ktap_left_r; ocd_ktap_right_ns = ocd_ktap_right_r; ocd2stg2_inc_r = 1'b0; ocd2stg2_dec_r = 1'b0; ocd2stg3_inc_r = 1'b0; ocd2stg3_dec_r = 1'b0; oclkdelay_center_calib_start_ns = oclkdelay_center_calib_start_r; oclkdelay_center_calib_done_ns = 1'b0; oclk_center_write_resume_ns = oclk_center_write_resume_r; po_center_wait = 1'b0; po_done_ns = po_done_r; po_finish_scan = 1'b0; po_slew = 1'b0; poc_backup_ns = poc_backup_r; scan_done_r = 1'b0; simp_stg3_final_ns = simp_stg3_final_r; sm_ns = sm_r; taps_set_r = 1'b0; up_ns = up_r; stg2_ns = stg2_r; stg3_ns = stg3_r; two_ns = two_r; resume_wait_ns = resume_wait_r; if (rst == 1'b1) begin // RESET next states cmplx_samples_done_ns = 1'b0; ocal_scan_win_not_found_ns = 1'b0; ocd_ktap_left_ns = 1'b0; ocd_ktap_right_ns = 1'b0; ocd_edge_detect_rdy_ns = 1'b0; oclk_center_write_resume_ns = 1'b0; oclkdelay_center_calib_start_ns = 1'b0; po_done_ns = 1'b1; resume_wait_ns = 5'd0; sm_ns = /*AK("READY")*/4'd0; end else // State based actions and next states. case (sm_r) /*AL("READY")*/4'd0:begin poc_backup_ns = 1'b0; stg2_ns = {3'b0, wl_po_fine_cnt_sel}; stg3_ns = stg3_init; scanning_right_ns = 1'b0; if (complex_oclkdelay_calib_start) cmplx_samples_done_ns = 1'b1; if (!reset_scan && ~resume_wait) begin cmplx_samples_done_ns = 1'b0; ocal_scan_win_not_found_ns = 1'b0; taps_set_r = 1'b1; sm_ns = /*AK("SAMPLING")*/4'd1; end end /*AL("SAMPLING")*/4'd1:begin if (samp_done && use_samp_done) begin if (complex_oclkdelay_calib_start) cmplx_samples_done_ns = 1'b1; scanning_right_ns = scanning_right_r || left_stop; if (right_stop && scanning_right_r) begin oclkdelay_center_calib_start_ns = 1'b1; ocd_ktap_left_ns = 1'b1; ocal_scan_win_not_found_ns = win_not_found; sm_ns = /*AK("SLEW_PO")*/4'd3; end else begin if (scanning_right_ns) ocd2stg3_inc_r = 1'b1; else ocd2stg3_dec_r = 1'b1; sm_ns = /*AK("PO_WAIT")*/4'd2; end end end /*AL("PO_WAIT")*/4'd2:begin if (po_done_r && ~resume_wait) begin taps_set_r = 1'b1; sm_ns = /*AK("SAMPLING")*/4'd1; cmplx_samples_done_ns = 1'b0; end end /*AL("SLEW_PO")*/4'd3:begin po_slew = 1'b1; ninety_offsets_ns = |ninety_offsets_final ? 2'b01 : 2'b00; if (~resume_wait) begin if (po_done_r) begin if (inc_po_r) ocd2stg3_inc_r = 1'b1; else if (dec_po_r) ocd2stg3_dec_r = 1'b1; else if (~resume_wait) begin cmplx_samples_done_ns = 1'b0; sm_ns = /*AK("ALIGN_EDGES")*/4'd4; oclk_center_write_resume_ns = 1'b1; end end // if (po_done) end end // case: 3'd3 /*AL("ALIGN_EDGES")*/4'd4: if (~resume_wait) begin if (mmcm_edge_detect_done) begin ocd_edge_detect_rdy_ns = 1'b0; if (ocd_ktap_left_r) begin ocd_ktap_left_ns = 1'b0; ocd_ktap_right_ns = 1'b1; oclk_center_write_resume_ns = 1'b0; sm_ns = /*AK("SLEW_PO")*/4'd3; end else if (ocd_ktap_right_r) begin ocd_ktap_right_ns = 1'b0; sm_ns = /*AK("WAIT_ONE")*/4'd5; end else if (~mmcm_lbclk_edge_aligned) begin sm_ns = /*AK("DQS_STOP_WAIT")*/4'd6; oclk_center_write_resume_ns = 1'b0; end else begin if (ninety_offsets_r != ninety_offsets_final && ocd_edge_detect_rdy_r) begin ninety_offsets_ns = ninety_offsets_r + 2'b01; sm_ns = /*AK("WAIT_ONE")*/4'd5; end else begin oclk_center_write_resume_ns = 1'b0; poc_backup_ns = poc_backup; // stg2_ns = stg2_2_zero; sm_ns = /*AK("FINISH_SCAN")*/4'd8; end end // else: !if(~mmcm_lbclk_edge_aligned) end else ocd_edge_detect_rdy_ns = 1'b1; end // if (~resume_wait) /*AL("WAIT_ONE")*/4'd5: sm_ns = /*AK("ALIGN_EDGES")*/4'd4; /*AL("DQS_STOP_WAIT")*/4'd6: if (~resume_wait) begin ocd2stg3_dec_r = 1'b1; sm_ns = /*AK("CENTER_PO_WAIT")*/4'd7; end /*AL("CENTER_PO_WAIT")*/4'd7: begin po_center_wait = 1'b1; // Kludge to get around limitation of the AUTOs symbols. if (po_done_r) begin sm_ns = /*AK("ALIGN_EDGES")*/4'd4; oclk_center_write_resume_ns = 1'b1; end end /*AL("FINISH_SCAN")*/4'd8: begin po_finish_scan = 1'b1; if (resume_wait_r == 5'd1) begin if (~poc_backup_r) begin oclkdelay_center_calib_done_ns = 1'b1; oclkdelay_center_calib_start_ns = 1'b0; end end if (~resume_wait) begin if (po_rdy) if (poc_backup_r) begin ocd2stg3_inc_r = 1'b1; poc_backup_ns = 1'b0; end else if (~final_stg2_inc && ~final_stg2_dec) begin if (complex_oclkdelay_calib_start) cmplx_stg3_final_ns[oclkdelay_calib_cnt*6+:6] = stg3_r; else simp_stg3_final_ns[oclkdelay_calib_cnt*6+:6] = stg3_r; sm_ns = /*AK("READY")*/4'd0; scan_done_r = 1'b1; end else begin ocd2stg2_inc_r = final_stg2_inc; ocd2stg2_dec_r = final_stg2_dec; end end // if (~resume_wait) end // case: 4'd8 endcase // case (sm_r) if (ocd2stg3_inc_r) begin stg3_ns = stg3_r + 6'h1; up_ns = 1'b0; end if (ocd2stg3_dec_r) begin stg3_ns = stg3_r - 6'h1; up_ns = 1'b1; end if (ocd2stg3_inc_r || ocd2stg3_dec_r) begin po_done_ns = 1'b0; two_ns = 2'b00; end if (~po_done_r) if (po_rdy) if (two_r == 2'b10 || po_center_wait || po_slew || po_finish_scan) po_done_ns = 1'b1; else begin two_ns = two_r + 2'b1; if (up_r) begin stg2_ns = stg2_r + 9'b1; if (stg2_r >= 9'd0 && stg2_r < 9'd63) ocd2stg2_inc_r = 1'b1; end else begin stg2_ns = stg2_r - 9'b1; if (stg2_r > 9'd0 && stg2_r <= 9'd63) ocd2stg2_dec_r = 1'b1; end end // else: !if(two_r == 2'b10) if (ocd_ktap_left_ns && ~ocd_ktap_left_r) resume_wait_ns = 5'b1; else if (oclk_center_write_resume_ns ^ oclk_center_write_resume_r) resume_wait_ns = 5'd15; else if (cmplx_samples_done_ns & ~cmplx_samples_done_r || complex_oclkdelay_calib_start & reset_scan || poc_backup_r & ocd2stg3_inc_r) resume_wait_ns = 5'd31; else if (|resume_wait_r) resume_wait_ns = resume_wait_r - 5'd1; end // always @ begin endmodule

module axi_crossbar_v2_1_crossbar # ( parameter C_FAMILY = "none", parameter integer C_NUM_SLAVE_SLOTS = 1, parameter integer C_NUM_MASTER_SLOTS = 1, parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_PROTOCOL = 0, parameter [C_NUM_MASTER_SLOTS*C_NUM_ADDR_RANGES*64-1:0] C_M_AXI_BASE_ADDR = {C_NUM_MASTER_SLOTS*C_NUM_ADDR_RANGES*64{1'b1}}, parameter [C_NUM_MASTER_SLOTS*C_NUM_ADDR_RANGES*64-1:0] C_M_AXI_HIGH_ADDR = {C_NUM_MASTER_SLOTS*C_NUM_ADDR_RANGES*64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS*64-1:0] C_S_AXI_BASE_ID = {C_NUM_SLAVE_SLOTS*64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS*64-1:0] C_S_AXI_HIGH_ID = {C_NUM_SLAVE_SLOTS*64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_THREAD_ID_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_AWUSER_WIDTH = 1, parameter integer C_AXI_ARUSER_WIDTH = 1, parameter integer C_AXI_WUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_BUSER_WIDTH = 1, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_WRITE = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_READ = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_WRITE = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_READ = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_WRITE_CONNECTIVITY = {C_NUM_MASTER_SLOTS*32{1'b1}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_READ_CONNECTIVITY = {C_NUM_MASTER_SLOTS*32{1'b1}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_SINGLE_THREAD = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_WRITE_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_READ_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_WRITE_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_READ_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_ARB_PRIORITY = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_SECURE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_ERR_MODE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE = 0, parameter [(C_NUM_MASTER_SLOTS+1)*32-1:0] C_W_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [(C_NUM_MASTER_SLOTS+1)*32-1:0] C_R_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_W_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_R_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESETN, // Slave Interface Write Address Ports input wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_AWID, input wire [C_NUM_SLAVE_SLOTS*C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR, input wire [C_NUM_SLAVE_SLOTS*8-1:0] S_AXI_AWLEN, input wire [C_NUM_SLAVE_SLOTS*3-1:0] S_AXI_AWSIZE, input wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_AWBURST, input wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_AWLOCK, input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_AWCACHE, input wire [C_NUM_SLAVE_SLOTS*3-1:0] S_AXI_AWPROT, // input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_AWREGION, input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_AWQOS, input wire [C_NUM_SLAVE_SLOTS*C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWREADY, // Slave Interface Write Data Ports input wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_WID, input wire [C_NUM_SLAVE_SLOTS*C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA, input wire [C_NUM_SLAVE_SLOTS*C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WLAST, input wire [C_NUM_SLAVE_SLOTS*C_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WREADY, // Slave Interface Write Response Ports output wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_BID, output wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_BRESP, output wire [C_NUM_SLAVE_SLOTS*C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BREADY, // Slave Interface Read Address Ports input wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_ARID, input wire [C_NUM_SLAVE_SLOTS*C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR, input wire [C_NUM_SLAVE_SLOTS*8-1:0] S_AXI_ARLEN, input wire [C_NUM_SLAVE_SLOTS*3-1:0] S_AXI_ARSIZE, input wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_ARBURST, input wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_ARLOCK, input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_ARCACHE, input wire [C_NUM_SLAVE_SLOTS*3-1:0] S_AXI_ARPROT, // input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_ARREGION, input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_ARQOS, input wire [C_NUM_SLAVE_SLOTS*C_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARREADY, // Slave Interface Read Data Ports output wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_RID, output wire [C_NUM_SLAVE_SLOTS*C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA, output wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_RRESP, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RLAST, output wire [C_NUM_SLAVE_SLOTS*C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RREADY, // Master Interface Write Address Port output wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_AWID, output wire [C_NUM_MASTER_SLOTS*C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR, output wire [C_NUM_MASTER_SLOTS*8-1:0] M_AXI_AWLEN, output wire [C_NUM_MASTER_SLOTS*3-1:0] M_AXI_AWSIZE, output wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_AWBURST, output wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_AWLOCK, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_AWCACHE, output wire [C_NUM_MASTER_SLOTS*3-1:0] M_AXI_AWPROT, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_AWREGION, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_AWQOS, output wire [C_NUM_MASTER_SLOTS*C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWREADY, // Master Interface Write Data Ports output wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_WID, output wire [C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA, output wire [C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WLAST, output wire [C_NUM_MASTER_SLOTS*C_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WREADY, // Master Interface Write Response Ports input wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_BID, input wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_BRESP, input wire [C_NUM_MASTER_SLOTS*C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BREADY, // Master Interface Read Address Port output wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_ARID, output wire [C_NUM_MASTER_SLOTS*C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR, output wire [C_NUM_MASTER_SLOTS*8-1:0] M_AXI_ARLEN, output wire [C_NUM_MASTER_SLOTS*3-1:0] M_AXI_ARSIZE, output wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_ARBURST, output wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_ARLOCK, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_ARCACHE, output wire [C_NUM_MASTER_SLOTS*3-1:0] M_AXI_ARPROT, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_ARREGION, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_ARQOS, output wire [C_NUM_MASTER_SLOTS*C_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARREADY, // Master Interface Read Data Ports input wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_RID, input wire [C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA, input wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_RRESP, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RLAST, input wire [C_NUM_MASTER_SLOTS*C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RREADY ); localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_NUM_MASTER_SLOTS_LOG = f_ceil_log2(C_NUM_MASTER_SLOTS); localparam integer P_NUM_SLAVE_SLOTS_LOG = f_ceil_log2((C_NUM_SLAVE_SLOTS>1) ? C_NUM_SLAVE_SLOTS : 2); localparam integer P_AXI_WID_WIDTH = (C_AXI_PROTOCOL == P_AXI3) ? C_AXI_ID_WIDTH : 1; localparam integer P_ST_AWMESG_WIDTH = 2+4+4 + C_AXI_AWUSER_WIDTH; localparam integer P_AA_AWMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_AWMESG_WIDTH; localparam integer P_ST_ARMESG_WIDTH = 2+4+4 + C_AXI_ARUSER_WIDTH; localparam integer P_AA_ARMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_ARMESG_WIDTH; localparam integer P_ST_BMESG_WIDTH = 2 + C_AXI_BUSER_WIDTH; localparam integer P_ST_RMESG_WIDTH = 2 + C_AXI_RUSER_WIDTH + C_AXI_DATA_WIDTH; localparam integer P_WR_WMESG_WIDTH = C_AXI_DATA_WIDTH + C_AXI_DATA_WIDTH/8 + C_AXI_WUSER_WIDTH + P_AXI_WID_WIDTH; localparam [31:0] P_BYPASS = 32'h00000000; localparam [31:0] P_FWD_REV = 32'h00000001; localparam [31:0] P_SIMPLE = 32'h00000007; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_READ = {1'b1, C_M_AXI_SUPPORTS_READ[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_WRITE = {1'b1, C_M_AXI_SUPPORTS_WRITE[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)*32-1:0] P_M_AXI_WRITE_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_WRITE_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS*32]}; localparam [(C_NUM_MASTER_SLOTS+1)*32-1:0] P_M_AXI_READ_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_READ_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS*32]}; localparam [C_NUM_SLAVE_SLOTS*32-1:0] P_S_AXI_WRITE_CONNECTIVITY = f_si_write_connectivity(0); localparam [C_NUM_SLAVE_SLOTS*32-1:0] P_S_AXI_READ_CONNECTIVITY = f_si_read_connectivity(0); localparam [(C_NUM_MASTER_SLOTS+1)*32-1:0] P_M_AXI_READ_ISSUING = {32'h00000001, C_M_AXI_READ_ISSUING[0+:C_NUM_MASTER_SLOTS*32]}; localparam [(C_NUM_MASTER_SLOTS+1)*32-1:0] P_M_AXI_WRITE_ISSUING = {32'h00000001, C_M_AXI_WRITE_ISSUING[0+:C_NUM_MASTER_SLOTS*32]}; localparam P_DECERR = 2'b11; //--------------------------------------------------------------------------- // Functions //--------------------------------------------------------------------------- // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2**acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // Isolate thread bits of input S_ID and add to BASE_ID (RNG00) to form MI-side ID value // only for end-point SI-slots function [C_AXI_ID_WIDTH-1:0] f_extend_ID ( input [C_AXI_ID_WIDTH-1:0] s_id, input integer slot ); begin f_extend_ID = C_S_AXI_BASE_ID[slot*64+:C_AXI_ID_WIDTH] | (s_id & (C_S_AXI_BASE_ID[slot*64+:C_AXI_ID_WIDTH] ^ C_S_AXI_HIGH_ID[slot*64+:C_AXI_ID_WIDTH])); end endfunction // Write connectivity array transposed function [C_NUM_SLAVE_SLOTS*32-1:0] f_si_write_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS*32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS*32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot*32+mi_slot] = C_M_AXI_WRITE_CONNECTIVITY[mi_slot*32+si_slot]; end end f_si_write_connectivity = result; end endfunction // Read connectivity array transposed function [C_NUM_SLAVE_SLOTS*32-1:0] f_si_read_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS*32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS*32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot*32+mi_slot] = C_M_AXI_READ_CONNECTIVITY[mi_slot*32+si_slot]; end end f_si_read_connectivity = result; end endfunction genvar gen_si_slot; genvar gen_mi_slot; wire [C_NUM_SLAVE_SLOTS*P_ST_AWMESG_WIDTH-1:0] si_st_awmesg ; wire [C_NUM_SLAVE_SLOTS*P_ST_AWMESG_WIDTH-1:0] st_tmp_awmesg ; wire [C_NUM_SLAVE_SLOTS*P_AA_AWMESG_WIDTH-1:0] tmp_aa_awmesg ; wire [P_AA_AWMESG_WIDTH-1:0] aa_mi_awmesg ; wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] st_aa_awid ; wire [C_NUM_SLAVE_SLOTS*C_AXI_ADDR_WIDTH-1:0] st_aa_awaddr ; wire [C_NUM_SLAVE_SLOTS*8-1:0] st_aa_awlen ; wire [C_NUM_SLAVE_SLOTS*3-1:0] st_aa_awsize ; wire [C_NUM_SLAVE_SLOTS*2-1:0] st_aa_awlock ; wire [C_NUM_SLAVE_SLOTS*3-1:0] st_aa_awprot ; wire [C_NUM_SLAVE_SLOTS*4-1:0] st_aa_awregion ; wire [C_NUM_SLAVE_SLOTS*8-1:0] st_aa_awerror ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS*(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_awtarget_enc ; wire [P_NUM_SLAVE_SLOTS_LOG*1-1:0] aa_wm_awgrant_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_aa_awvalid_qual ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_ss_awvalid ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_ss_awready ; wire [C_NUM_SLAVE_SLOTS*1-1:0] ss_wr_awvalid ; wire [C_NUM_SLAVE_SLOTS*1-1:0] ss_wr_awready ; wire [C_NUM_SLAVE_SLOTS*1-1:0] ss_aa_awvalid ; wire [C_NUM_SLAVE_SLOTS*1-1:0] ss_aa_awready ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] sa_wm_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] sa_wm_awready ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_awready ; wire aa_sa_awvalid ; wire aa_sa_awready ; wire aa_mi_arready ; wire mi_awvalid_en ; wire sa_wm_awvalid_en ; wire sa_wm_awready_mux ; wire [C_NUM_SLAVE_SLOTS*P_ST_ARMESG_WIDTH-1:0] si_st_armesg ; wire [C_NUM_SLAVE_SLOTS*P_ST_ARMESG_WIDTH-1:0] st_tmp_armesg ; wire [C_NUM_SLAVE_SLOTS*P_AA_ARMESG_WIDTH-1:0] tmp_aa_armesg ; wire [P_AA_ARMESG_WIDTH-1:0] aa_mi_armesg ; wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] st_aa_arid ; wire [C_NUM_SLAVE_SLOTS*C_AXI_ADDR_WIDTH-1:0] st_aa_araddr ; wire [C_NUM_SLAVE_SLOTS*8-1:0] st_aa_arlen ; wire [C_NUM_SLAVE_SLOTS*3-1:0] st_aa_arsize ; wire [C_NUM_SLAVE_SLOTS*2-1:0] st_aa_arlock ; wire [C_NUM_SLAVE_SLOTS*3-1:0] st_aa_arprot ; wire [C_NUM_SLAVE_SLOTS*4-1:0] st_aa_arregion ; wire [C_NUM_SLAVE_SLOTS*8-1:0] st_aa_arerror ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_artarget_hot ; wire [C_NUM_SLAVE_SLOTS*(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_artarget_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_artarget_hot ; wire [P_NUM_SLAVE_SLOTS_LOG*1-1:0] aa_mi_argrant_enc ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_aa_arvalid_qual ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_aa_arvalid ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_aa_arready ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_arvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_arready ; wire aa_mi_arvalid ; wire mi_awready_mux ; wire [C_NUM_SLAVE_SLOTS*P_ST_BMESG_WIDTH-1:0] st_si_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)*P_ST_BMESG_WIDTH-1:0] st_mr_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] st_mr_bid ; wire [(C_NUM_MASTER_SLOTS+1)*2-1:0] st_mr_bresp ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_BUSER_WIDTH-1:0] st_mr_buser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_bready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)*C_NUM_SLAVE_SLOTS-1:0] tmp_mr_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)*P_NUM_SLAVE_SLOTS_LOG-1:0] debug_bid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] bid_match ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] mi_bid ; wire [(C_NUM_MASTER_SLOTS+1)*2-1:0] mi_bresp ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_BUSER_WIDTH-1:0] mi_buser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_bready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] bready_carry ; wire [C_NUM_SLAVE_SLOTS*P_ST_RMESG_WIDTH-1:0] st_si_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)*P_ST_RMESG_WIDTH-1:0] st_mr_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] st_mr_rid ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH-1:0] st_mr_rdata ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_RUSER_WIDTH-1:0] st_mr_ruser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_rlast ; wire [(C_NUM_MASTER_SLOTS+1)*2-1:0] st_mr_rresp ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_rready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)*C_NUM_SLAVE_SLOTS-1:0] tmp_mr_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)*P_NUM_SLAVE_SLOTS_LOG-1:0] debug_rid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] rid_match ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] mi_rid ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH-1:0] mi_rdata ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_RUSER_WIDTH-1:0] mi_ruser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_rlast ; wire [(C_NUM_MASTER_SLOTS+1)*2-1:0] mi_rresp ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_rready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] rready_carry ; wire [C_NUM_SLAVE_SLOTS*P_WR_WMESG_WIDTH-1:0] si_wr_wmesg ; wire [C_NUM_SLAVE_SLOTS*P_WR_WMESG_WIDTH-1:0] wr_wm_wmesg ; wire [C_NUM_SLAVE_SLOTS*1-1:0] wr_wm_wlast ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wvalid ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wready ; wire [(C_NUM_MASTER_SLOTS+1)*C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)*C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wready ; wire [(C_NUM_MASTER_SLOTS+1)*P_WR_WMESG_WIDTH-1:0] wm_mr_wmesg ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH-1:0] wm_mr_wdata ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH/8-1:0] wm_mr_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] wm_mr_wid ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_WUSER_WIDTH-1:0] wm_mr_wuser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] wm_mr_wlast ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] wm_mr_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] wm_mr_wready ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH-1:0] mi_wdata ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH/8-1:0] mi_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_WUSER_WIDTH-1:0] mi_wuser ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] mi_wid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_wlast ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_wready ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] w_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] w_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] r_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] r_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_awmaxissuing ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_armaxissuing ; reg [(C_NUM_MASTER_SLOTS+1)*8-1:0] w_issuing_cnt ; reg [(C_NUM_MASTER_SLOTS+1)*8-1:0] r_issuing_cnt ; reg [8-1:0] debug_aw_trans_seq_i ; reg [8-1:0] debug_ar_trans_seq_i ; wire [(C_NUM_MASTER_SLOTS+1)*8-1:0] debug_w_trans_seq_i ; reg [(C_NUM_MASTER_SLOTS+1)*8-1:0] debug_w_beat_cnt_i ; reg aresetn_d = 1'b0; // Reset delay register always @(posedge ACLK) begin if (~ARESETN) begin aresetn_d <= 1'b0; end else begin aresetn_d <= ARESETN; end end wire reset; assign reset = ~aresetn_d; generate for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_slave_slots if (C_S_AXI_SUPPORTS_READ[gen_si_slot]) begin : gen_si_read axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (read channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_READ), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_READ_ACCEPTANCE[gen_si_slot*32+:32]), .C_ACCEPTANCE_LOG (C_R_ACCEPT_WIDTH[gen_si_slot*32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot*32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_ARMESG_WIDTH), .C_RMESG_WIDTH (P_ST_RMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot*64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot*64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot*32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_READ_CONNECTIVITY[gen_si_slot*32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_ar ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_ARID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_ARADDR[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_ARLEN[gen_si_slot*8+:8]), .S_ASIZE (S_AXI_ARSIZE[gen_si_slot*3+:3]), .S_ABURST (S_AXI_ARBURST[gen_si_slot*2+:2]), .S_ALOCK (S_AXI_ARLOCK[gen_si_slot*2+:2]), .S_APROT (S_AXI_ARPROT[gen_si_slot*3+:3]), // .S_AREGION (S_AXI_ARREGION[gen_si_slot*4+:4]), .S_AMESG (si_st_armesg[gen_si_slot*P_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .S_AVALID (S_AXI_ARVALID[gen_si_slot]), .S_AREADY (S_AXI_ARREADY[gen_si_slot]), .M_AID (st_aa_arid[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_araddr[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_arlen[gen_si_slot*8+:8]), .M_ASIZE (st_aa_arsize[gen_si_slot*3+:3]), .M_ALOCK (st_aa_arlock[gen_si_slot*2+:2]), .M_APROT (st_aa_arprot[gen_si_slot*3+:3]), .M_AREGION (st_aa_arregion[gen_si_slot*4+:4]), .M_AMESG (st_tmp_armesg[gen_si_slot*P_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .M_ATARGET_HOT (st_aa_artarget_hot[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_artarget_enc[gen_si_slot*(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_arerror[gen_si_slot*8+:8]), .M_AVALID_QUAL (st_aa_arvalid_qual[gen_si_slot]), .M_AVALID (st_aa_arvalid[gen_si_slot]), .M_AREADY (st_aa_arready[gen_si_slot]), .S_RID (S_AXI_RID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_rmesg[gen_si_slot*P_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH]), .S_RLAST (S_AXI_RLAST[gen_si_slot]), .S_RVALID (S_AXI_RVALID[gen_si_slot]), .S_RREADY (S_AXI_RREADY[gen_si_slot]), .M_RID (st_mr_rid), .M_RLAST (st_mr_rlast), .M_RMESG (st_mr_rmesg), .M_RVALID (st_mr_rvalid), .M_RREADY (st_tmp_rready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_rid_target[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_ar_trans_seq_i : 8'h0) ); assign si_st_armesg[gen_si_slot*P_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH] = { S_AXI_ARUSER[gen_si_slot*C_AXI_ARUSER_WIDTH+:C_AXI_ARUSER_WIDTH], S_AXI_ARQOS[gen_si_slot*4+:4], S_AXI_ARCACHE[gen_si_slot*4+:4], S_AXI_ARBURST[gen_si_slot*2+:2] }; assign tmp_aa_armesg[gen_si_slot*P_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = { st_tmp_armesg[gen_si_slot*P_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH], st_aa_arregion[gen_si_slot*4+:4], st_aa_arprot[gen_si_slot*3+:3], st_aa_arlock[gen_si_slot*2+:2], st_aa_arsize[gen_si_slot*3+:3], st_aa_arlen[gen_si_slot*8+:8], st_aa_araddr[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_arid[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_RRESP[gen_si_slot*2+:2] = st_si_rmesg[gen_si_slot*P_ST_RMESG_WIDTH+:2]; assign S_AXI_RUSER[gen_si_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = st_si_rmesg[gen_si_slot*P_ST_RMESG_WIDTH+2 +: C_AXI_RUSER_WIDTH]; assign S_AXI_RDATA[gen_si_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = st_si_rmesg[gen_si_slot*P_ST_RMESG_WIDTH+2+C_AXI_RUSER_WIDTH +: C_AXI_DATA_WIDTH]; end else begin : gen_no_si_read assign S_AXI_ARREADY[gen_si_slot] = 1'b0; assign st_aa_arvalid[gen_si_slot] = 1'b0; assign st_aa_arvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_armesg[gen_si_slot*P_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = 0; assign S_AXI_RID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_RRESP[gen_si_slot*2+:2] = 0; assign S_AXI_RUSER[gen_si_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign S_AXI_RDATA[gen_si_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign S_AXI_RVALID[gen_si_slot] = 1'b0; assign S_AXI_RLAST[gen_si_slot] = 1'b0; assign st_tmp_rready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_artarget_hot[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_read if (C_S_AXI_SUPPORTS_WRITE[gen_si_slot]) begin : gen_si_write axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (write channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_WRITE), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_WRITE_ACCEPTANCE[gen_si_slot*32+:32]), .C_ACCEPTANCE_LOG (C_W_ACCEPT_WIDTH[gen_si_slot*32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot*32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_AWMESG_WIDTH), .C_RMESG_WIDTH (P_ST_BMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot*64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot*64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot*32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_WRITE_CONNECTIVITY[gen_si_slot*32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_aw ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_AWID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_AWADDR[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_AWLEN[gen_si_slot*8+:8]), .S_ASIZE (S_AXI_AWSIZE[gen_si_slot*3+:3]), .S_ABURST (S_AXI_AWBURST[gen_si_slot*2+:2]), .S_ALOCK (S_AXI_AWLOCK[gen_si_slot*2+:2]), .S_APROT (S_AXI_AWPROT[gen_si_slot*3+:3]), // .S_AREGION (S_AXI_AWREGION[gen_si_slot*4+:4]), .S_AMESG (si_st_awmesg[gen_si_slot*P_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .S_AVALID (S_AXI_AWVALID[gen_si_slot]), .S_AREADY (S_AXI_AWREADY[gen_si_slot]), .M_AID (st_aa_awid[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_awaddr[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_awlen[gen_si_slot*8+:8]), .M_ASIZE (st_aa_awsize[gen_si_slot*3+:3]), .M_ALOCK (st_aa_awlock[gen_si_slot*2+:2]), .M_APROT (st_aa_awprot[gen_si_slot*3+:3]), .M_AREGION (st_aa_awregion[gen_si_slot*4+:4]), .M_AMESG (st_tmp_awmesg[gen_si_slot*P_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .M_ATARGET_HOT (st_aa_awtarget_hot[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_awtarget_enc[gen_si_slot*(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_awerror[gen_si_slot*8+:8]), .M_AVALID_QUAL (st_aa_awvalid_qual[gen_si_slot]), .M_AVALID (st_ss_awvalid[gen_si_slot]), .M_AREADY (st_ss_awready[gen_si_slot]), .S_RID (S_AXI_BID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_bmesg[gen_si_slot*P_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH]), .S_RLAST (), .S_RVALID (S_AXI_BVALID[gen_si_slot]), .S_RREADY (S_AXI_BREADY[gen_si_slot]), .M_RID (st_mr_bid), .M_RLAST ({(C_NUM_MASTER_SLOTS+1){1'b1}}), .M_RMESG (st_mr_bmesg), .M_RVALID (st_mr_bvalid), .M_RREADY (st_tmp_bready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_bid_target[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_aw_trans_seq_i : 8'h0) ); // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign si_st_awmesg[gen_si_slot*P_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH] = { S_AXI_AWUSER[gen_si_slot*C_AXI_AWUSER_WIDTH+:C_AXI_AWUSER_WIDTH], S_AXI_AWQOS[gen_si_slot*4+:4], S_AXI_AWCACHE[gen_si_slot*4+:4], S_AXI_AWBURST[gen_si_slot*2+:2] }; assign tmp_aa_awmesg[gen_si_slot*P_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = { st_tmp_awmesg[gen_si_slot*P_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH], st_aa_awregion[gen_si_slot*4+:4], st_aa_awprot[gen_si_slot*3+:3], st_aa_awlock[gen_si_slot*2+:2], st_aa_awsize[gen_si_slot*3+:3], st_aa_awlen[gen_si_slot*8+:8], st_aa_awaddr[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_awid[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_BRESP[gen_si_slot*2+:2] = st_si_bmesg[gen_si_slot*P_ST_BMESG_WIDTH+:2]; assign S_AXI_BUSER[gen_si_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = st_si_bmesg[gen_si_slot*P_ST_BMESG_WIDTH+2 +: C_AXI_BUSER_WIDTH]; // AW SI-transactor transfer completes upon completion of both W-router address acceptance (command push) and AW arbitration axi_crossbar_v2_1_splitter # // "SS": Splitter from SI-Transactor (write channel) ( .C_NUM_M (2) ) splitter_aw_si ( .ACLK (ACLK), .ARESET (reset), .S_VALID (st_ss_awvalid[gen_si_slot]), .S_READY (st_ss_awready[gen_si_slot]), .M_VALID ({ss_wr_awvalid[gen_si_slot], ss_aa_awvalid[gen_si_slot]}), .M_READY ({ss_wr_awready[gen_si_slot], ss_aa_awready[gen_si_slot]}) ); axi_crossbar_v2_1_wdata_router # // "WR": Write data Router ( .C_FAMILY (C_FAMILY), .C_NUM_MASTER_SLOTS (C_NUM_MASTER_SLOTS+1), .C_SELECT_WIDTH (P_NUM_MASTER_SLOTS_LOG+1), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ACCEPT_WIDTH[gen_si_slot*32+:6]) ) wdata_router_w ( .ACLK (ACLK), .ARESET (reset), // Write transfer input from the current SI-slot .S_WMESG (si_wr_wmesg[gen_si_slot*P_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .S_WLAST (S_AXI_WLAST[gen_si_slot]), .S_WVALID (S_AXI_WVALID[gen_si_slot]), .S_WREADY (S_AXI_WREADY[gen_si_slot]), // Vector of write transfer outputs to each MI-slot's W-mux .M_WMESG (wr_wm_wmesg[gen_si_slot*(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH]), .M_WLAST (wr_wm_wlast[gen_si_slot]), .M_WVALID (wr_tmp_wvalid[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_WREADY (wr_tmp_wready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), // AW command push from local SI-slot .S_ASELECT (st_aa_awtarget_enc[gen_si_slot*(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), // Target MI-slot .S_AVALID (ss_wr_awvalid[gen_si_slot]), .S_AREADY (ss_wr_awready[gen_si_slot]) ); assign si_wr_wmesg[gen_si_slot*P_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH] = { ((C_AXI_PROTOCOL == P_AXI3) ? f_extend_ID(S_AXI_WID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot) : 1'b0), S_AXI_WUSER[gen_si_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH], S_AXI_WSTRB[gen_si_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8], S_AXI_WDATA[gen_si_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] }; end else begin : gen_no_si_write assign S_AXI_AWREADY[gen_si_slot] = 1'b0; assign ss_aa_awvalid[gen_si_slot] = 1'b0; assign st_aa_awvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_awmesg[gen_si_slot*P_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = 0; assign S_AXI_BID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_BRESP[gen_si_slot*2+:2] = 0; assign S_AXI_BUSER[gen_si_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign S_AXI_BVALID[gen_si_slot] = 1'b0; assign st_tmp_bready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign S_AXI_WREADY[gen_si_slot] = 1'b0; assign wr_wm_wmesg[gen_si_slot*(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH] = 0; assign wr_wm_wlast[gen_si_slot] = 1'b0; assign wr_tmp_wvalid[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_awtarget_hot[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_write end // gen_slave_slots for (gen_mi_slot=0; gen_mi_slot<C_NUM_MASTER_SLOTS+1; gen_mi_slot=gen_mi_slot+1) begin : gen_master_slots if (P_M_AXI_SUPPORTS_READ[gen_mi_slot]) begin : gen_mi_read if (C_NUM_SLAVE_SLOTS>1) begin : gen_rid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_READ_CONNECTIVITY[gen_mi_slot*32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) rid_decoder_inst ( .ADDR (st_mr_rid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_rid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_rid_target_i[gen_mi_slot*P_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (rid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_rid_decoder assign tmp_mr_rid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign rid_match[gen_mi_slot] = 1'b1; end assign st_mr_rmesg[gen_mi_slot*P_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = { st_mr_rdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH], st_mr_ruser[gen_mi_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH], st_mr_rresp[gen_mi_slot*2+:2] }; end else begin : gen_no_mi_read assign tmp_mr_rid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign rid_match[gen_mi_slot] = 1'b0; assign st_mr_rmesg[gen_mi_slot*P_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = 0; end // gen_mi_read if (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]) begin : gen_mi_write if (C_NUM_SLAVE_SLOTS>1) begin : gen_bid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_WRITE_CONNECTIVITY[gen_mi_slot*32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) bid_decoder_inst ( .ADDR (st_mr_bid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_bid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_bid_target_i[gen_mi_slot*P_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (bid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_bid_decoder assign tmp_mr_bid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign bid_match[gen_mi_slot] = 1'b1; end axi_crossbar_v2_1_wdata_mux # // "WM": Write data Mux, per MI-slot (incl error-handler) ( .C_FAMILY (C_FAMILY), .C_NUM_SLAVE_SLOTS (C_NUM_SLAVE_SLOTS), .C_SELECT_WIDTH (P_NUM_SLAVE_SLOTS_LOG), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]) ) wdata_mux_w ( .ACLK (ACLK), .ARESET (reset), // Vector of write transfer inputs from each SI-slot's W-router .S_WMESG (wr_wm_wmesg), .S_WLAST (wr_wm_wlast), .S_WVALID (tmp_wm_wvalid[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .S_WREADY (tmp_wm_wready[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), // Write transfer output to the current MI-slot .M_WMESG (wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .M_WLAST (wm_mr_wlast[gen_mi_slot]), .M_WVALID (wm_mr_wvalid[gen_mi_slot]), .M_WREADY (wm_mr_wready[gen_mi_slot]), // AW command push from AW arbiter output .S_ASELECT (aa_wm_awgrant_enc), // SI-slot selected by arbiter .S_AVALID (sa_wm_awvalid[gen_mi_slot]), .S_AREADY (sa_wm_awready[gen_mi_slot]) ); if (C_DEBUG) begin : gen_debug_w // DEBUG WRITE BEAT COUNTER always @(posedge ACLK) begin if (reset) begin debug_w_beat_cnt_i[gen_mi_slot*8+:8] <= 0; end else begin if (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot]) begin if (mi_wlast[gen_mi_slot]) begin debug_w_beat_cnt_i[gen_mi_slot*8+:8] <= 0; end else begin debug_w_beat_cnt_i[gen_mi_slot*8+:8] <= debug_w_beat_cnt_i[gen_mi_slot*8+:8] + 1; end end end end // clocked process // DEBUG W-CHANNEL TRANSACTION SEQUENCE QUEUE axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]), .C_USE_FULL (0) ) debug_w_seq_fifo ( .ACLK (ACLK), .ARESET (reset), .S_MESG (debug_aw_trans_seq_i), .S_VALID (sa_wm_awvalid[gen_mi_slot]), .S_READY (), .M_MESG (debug_w_trans_seq_i[gen_mi_slot*8+:8]), .M_VALID (), .M_READY (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot] & mi_wlast[gen_mi_slot]) ); end // gen_debug_w assign wm_mr_wdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH +: C_AXI_DATA_WIDTH]; assign wm_mr_wstrb[gen_mi_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH +: C_AXI_DATA_WIDTH/8]; assign wm_mr_wuser[gen_mi_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+C_AXI_DATA_WIDTH/8 +: C_AXI_WUSER_WIDTH]; assign wm_mr_wid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+(C_AXI_DATA_WIDTH/8)+C_AXI_WUSER_WIDTH +: P_AXI_WID_WIDTH]; assign st_mr_bmesg[gen_mi_slot*P_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = { st_mr_buser[gen_mi_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH], st_mr_bresp[gen_mi_slot*2+:2] }; end else begin : gen_no_mi_write assign tmp_mr_bid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign bid_match[gen_mi_slot] = 1'b0; assign wm_mr_wvalid[gen_mi_slot] = 0; assign wm_mr_wlast[gen_mi_slot] = 0; assign wm_mr_wdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign wm_mr_wstrb[gen_mi_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = 0; assign wm_mr_wuser[gen_mi_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = 0; assign wm_mr_wid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign st_mr_bmesg[gen_mi_slot*P_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = 0; assign tmp_wm_wready[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign sa_wm_awready[gen_mi_slot] = 0; end // gen_mi_write for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_trans_si // Transpose handshakes from W-router (SxM) to W-mux (MxS). assign tmp_wm_wvalid[gen_mi_slot*C_NUM_SLAVE_SLOTS+gen_si_slot] = wr_tmp_wvalid[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; assign wr_tmp_wready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_wm_wready[gen_mi_slot*C_NUM_SLAVE_SLOTS+gen_si_slot]; // Transpose response enables from ID decoders (MxS) to si_transactors (SxM). assign st_tmp_bid_target[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_bid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+gen_si_slot]; assign st_tmp_rid_target[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_rid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+gen_si_slot]; end // gen_trans_si assign bready_carry[gen_mi_slot] = st_tmp_bready[gen_mi_slot]; assign rready_carry[gen_mi_slot] = st_tmp_rready[gen_mi_slot]; for (gen_si_slot=1; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_resp_carry_si assign bready_carry[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_BREADY if ... bready_carry[(gen_si_slot-1)*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] | // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_bready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates BREADY for that MI-slot. assign rready_carry[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_RREADY if ... rready_carry[(gen_si_slot-1)*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] | // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_rready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates RREADY for that MI-slot. end // gen_resp_carry_si assign w_cmd_push[gen_mi_slot] = mi_awvalid[gen_mi_slot] && mi_awready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_push[gen_mi_slot] = mi_arvalid[gen_mi_slot] && mi_arready[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; assign w_cmd_pop[gen_mi_slot] = st_mr_bvalid[gen_mi_slot] && st_mr_bready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_pop[gen_mi_slot] = st_mr_rvalid[gen_mi_slot] && st_mr_rready[gen_mi_slot] && st_mr_rlast[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; // Disqualify arbitration of SI-slot if targeted MI-slot has reached its issuing limit. assign mi_awmaxissuing[gen_mi_slot] = (w_issuing_cnt[gen_mi_slot*8 +: (C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] == P_M_AXI_WRITE_ISSUING[gen_mi_slot*32 +: (C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)]) & ~w_cmd_pop[gen_mi_slot]; assign mi_armaxissuing[gen_mi_slot] = (r_issuing_cnt[gen_mi_slot*8 +: (C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] == P_M_AXI_READ_ISSUING[gen_mi_slot*32 +: (C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)]) & ~r_cmd_pop[gen_mi_slot]; always @(posedge ACLK) begin if (reset) begin w_issuing_cnt[gen_mi_slot*8+:8] <= 0; // Some high-order bits remain constant 0 r_issuing_cnt[gen_mi_slot*8+:8] <= 0; // Some high-order bits remain constant 0 end else begin if (w_cmd_push[gen_mi_slot] && ~w_cmd_pop[gen_mi_slot]) begin w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] <= w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] + 1; end else if (w_cmd_pop[gen_mi_slot] && ~w_cmd_push[gen_mi_slot] && (|w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)])) begin w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] <= w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] - 1; end if (r_cmd_push[gen_mi_slot] && ~r_cmd_pop[gen_mi_slot]) begin r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] <= r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] + 1; end else if (r_cmd_pop[gen_mi_slot] && ~r_cmd_push[gen_mi_slot] && (|r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)])) begin r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] <= r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] - 1; end end end // Clocked process // Reg-slice must break combinatorial path from M_BID and M_RID inputs to M_BREADY and M_RREADY outputs. // (See m_rready_i and m_resp_en combinatorial assignments in si_transactor.) // Reg-slice incurs +1 latency, but no bubble-cycles. axi_register_slice_v2_1_axi_register_slice # // "MR": MI-side R/B-channel Reg-slice, per MI-slot (pass-through if only 1 SI-slot configured) ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL ((C_AXI_PROTOCOL == P_AXI3) ? P_AXI3 : P_AXI4), .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (1), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (C_AXI_SUPPORTS_USER_SIGNALS), .C_AXI_AWUSER_WIDTH (1), .C_AXI_ARUSER_WIDTH (1), .C_AXI_WUSER_WIDTH (C_AXI_WUSER_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_REG_CONFIG_AW (P_BYPASS), .C_REG_CONFIG_AR (P_BYPASS), .C_REG_CONFIG_W (P_BYPASS), .C_REG_CONFIG_R (P_M_AXI_SUPPORTS_READ[gen_mi_slot] ? P_FWD_REV : P_BYPASS), .C_REG_CONFIG_B (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot] ? P_SIMPLE : P_BYPASS) ) reg_slice_mi ( .aresetn (ARESETN), .aclk (ACLK), .s_axi_awid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_awaddr ({1{1'b0}}), .s_axi_awlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_awsize ({3{1'b0}}), .s_axi_awburst ({2{1'b0}}), .s_axi_awlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_awcache ({4{1'b0}}), .s_axi_awprot ({3{1'b0}}), .s_axi_awregion ({4{1'b0}}), .s_axi_awqos ({4{1'b0}}), .s_axi_awuser ({1{1'b0}}), .s_axi_awvalid ({1{1'b0}}), .s_axi_awready (), .s_axi_wid (wm_mr_wid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .s_axi_wdata (wm_mr_wdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .s_axi_wstrb (wm_mr_wstrb[gen_mi_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .s_axi_wlast (wm_mr_wlast[gen_mi_slot]), .s_axi_wuser (wm_mr_wuser[gen_mi_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .s_axi_wvalid (wm_mr_wvalid[gen_mi_slot]), .s_axi_wready (wm_mr_wready[gen_mi_slot]), .s_axi_bid (st_mr_bid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_bresp (st_mr_bresp[gen_mi_slot*2+:2] ), .s_axi_buser (st_mr_buser[gen_mi_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .s_axi_bvalid (st_mr_bvalid[gen_mi_slot*1+:1] ), .s_axi_bready (st_mr_bready[gen_mi_slot*1+:1] ), .s_axi_arid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_araddr ({1{1'b0}}), .s_axi_arlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_arsize ({3{1'b0}}), .s_axi_arburst ({2{1'b0}}), .s_axi_arlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_arcache ({4{1'b0}}), .s_axi_arprot ({3{1'b0}}), .s_axi_arregion ({4{1'b0}}), .s_axi_arqos ({4{1'b0}}), .s_axi_aruser ({1{1'b0}}), .s_axi_arvalid ({1{1'b0}}), .s_axi_arready (), .s_axi_rid (st_mr_rid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_rdata (st_mr_rdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .s_axi_rresp (st_mr_rresp[gen_mi_slot*2+:2] ), .s_axi_rlast (st_mr_rlast[gen_mi_slot*1+:1] ), .s_axi_ruser (st_mr_ruser[gen_mi_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .s_axi_rvalid (st_mr_rvalid[gen_mi_slot*1+:1] ), .s_axi_rready (st_mr_rready[gen_mi_slot*1+:1] ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready ({1{1'b0}}), .m_axi_wid (mi_wid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .m_axi_wdata (mi_wdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .m_axi_wstrb (mi_wstrb[gen_mi_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .m_axi_wlast (mi_wlast[gen_mi_slot]), .m_axi_wuser (mi_wuser[gen_mi_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .m_axi_wvalid (mi_wvalid[gen_mi_slot]), .m_axi_wready (mi_wready[gen_mi_slot]), .m_axi_bid (mi_bid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_bresp (mi_bresp[gen_mi_slot*2+:2] ), .m_axi_buser (mi_buser[gen_mi_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .m_axi_bvalid (mi_bvalid[gen_mi_slot*1+:1] ), .m_axi_bready (mi_bready[gen_mi_slot*1+:1] ), .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready ({1{1'b0}}), .m_axi_rid (mi_rid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_rdata (mi_rdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .m_axi_rresp (mi_rresp[gen_mi_slot*2+:2] ), .m_axi_rlast (mi_rlast[gen_mi_slot*1+:1] ), .m_axi_ruser (mi_ruser[gen_mi_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .m_axi_rvalid (mi_rvalid[gen_mi_slot*1+:1] ), .m_axi_rready (mi_rready[gen_mi_slot*1+:1] ) ); end // gen_master_slots (Next gen_mi_slot) // Highest row of *ready_carry contains accumulated OR across all SI-slots, for each MI-slot. assign st_mr_bready = bready_carry[(C_NUM_SLAVE_SLOTS-1)*(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; assign st_mr_rready = rready_carry[(C_NUM_SLAVE_SLOTS-1)*(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; // Assign MI-side B, R and W channel ports (exclude error handler signals). assign mi_bid[0+:C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH] = M_AXI_BID; assign mi_bvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_BVALID; assign mi_bresp[0+:C_NUM_MASTER_SLOTS*2] = M_AXI_BRESP; assign mi_buser[0+:C_NUM_MASTER_SLOTS*C_AXI_BUSER_WIDTH] = M_AXI_BUSER; assign M_AXI_BREADY = mi_bready[0+:C_NUM_MASTER_SLOTS]; assign mi_rid[0+:C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH] = M_AXI_RID; assign mi_rlast[0+:C_NUM_MASTER_SLOTS] = M_AXI_RLAST; assign mi_rvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_RVALID; assign mi_rresp[0+:C_NUM_MASTER_SLOTS*2] = M_AXI_RRESP; assign mi_ruser[0+:C_NUM_MASTER_SLOTS*C_AXI_RUSER_WIDTH] = M_AXI_RUSER; assign mi_rdata[0+:C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH] = M_AXI_RDATA; assign M_AXI_RREADY = mi_rready[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WLAST = mi_wlast[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WVALID = mi_wvalid[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WUSER = mi_wuser[0+:C_NUM_MASTER_SLOTS*C_AXI_WUSER_WIDTH]; assign M_AXI_WID = (C_AXI_PROTOCOL == P_AXI3) ? mi_wid[0+:C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH] : 0; assign M_AXI_WDATA = mi_wdata[0+:C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH]; assign M_AXI_WSTRB = mi_wstrb[0+:C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH/8]; assign mi_wready[0+:C_NUM_MASTER_SLOTS] = M_AXI_WREADY; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AW channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_AWMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_aw ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AW command request inputs .S_MESG (tmp_aa_awmesg), .S_TARGET_HOT (st_aa_awtarget_hot), .S_VALID (ss_aa_awvalid), .S_VALID_QUAL (st_aa_awvalid_qual), .S_READY (ss_aa_awready), // Granted AW command output .M_MESG (aa_mi_awmesg), .M_TARGET_HOT (aa_mi_awtarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_wm_awgrant_enc), // SI-slot index of granted command .M_VALID (aa_sa_awvalid), .M_READY (aa_sa_awready), .ISSUING_LIMIT (mi_awmaxissuing) ); // Broadcast AW transfer payload to all MI-slots assign M_AXI_AWID = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_AWADDR = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_AWLEN = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_AWSIZE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_AWLOCK = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_AWPROT = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_AWREGION = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_AWBURST = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_AWCACHE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_AWQOS = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_AWUSER = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_AWUSER_WIDTH]}}; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AR channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_ARMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_ar ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AR command request inputs .S_MESG (tmp_aa_armesg), .S_TARGET_HOT (st_aa_artarget_hot), .S_VALID_QUAL (st_aa_arvalid_qual), .S_VALID (st_aa_arvalid), .S_READY (st_aa_arready), // Granted AR command output .M_MESG (aa_mi_armesg), .M_TARGET_HOT (aa_mi_artarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_mi_argrant_enc), .M_VALID (aa_mi_arvalid), // SI-slot index of granted command .M_READY (aa_mi_arready), .ISSUING_LIMIT (mi_armaxissuing) ); if (C_DEBUG) begin : gen_debug_trans_seq // DEBUG WRITE TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_aw_trans_seq_i <= 1; end else begin if (aa_sa_awvalid && aa_sa_awready) begin debug_aw_trans_seq_i <= debug_aw_trans_seq_i + 1; end end end // DEBUG READ TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_ar_trans_seq_i <= 1; end else begin if (aa_mi_arvalid && aa_mi_arready) begin debug_ar_trans_seq_i <= debug_ar_trans_seq_i + 1; end end end end // gen_debug_trans_seq // Broadcast AR transfer payload to all MI-slots assign M_AXI_ARID = {C_NUM_MASTER_SLOTS{aa_mi_armesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_ARADDR = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_ARLEN = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_ARSIZE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_ARLOCK = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_ARPROT = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_ARREGION = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_ARBURST = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_ARCACHE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_ARQOS = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_ARUSER = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_ARUSER_WIDTH]}}; // AW arbiter command transfer completes upon completion of both M-side AW-channel transfer and W-mux address acceptance (command push). axi_crossbar_v2_1_splitter # // "SA": Splitter for Write Addr Arbiter ( .C_NUM_M (2) ) splitter_aw_mi ( .ACLK (ACLK), .ARESET (reset), .S_VALID (aa_sa_awvalid), .S_READY (aa_sa_awready), .M_VALID ({mi_awvalid_en, sa_wm_awvalid_en}), .M_READY ({mi_awready_mux, sa_wm_awready_mux}) ); assign mi_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{mi_awvalid_en}}; assign mi_awready_mux = |(aa_mi_awtarget_hot & mi_awready); assign M_AXI_AWVALID = mi_awvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_awready[0+:C_NUM_MASTER_SLOTS] = M_AXI_AWREADY; assign sa_wm_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{sa_wm_awvalid_en}}; assign sa_wm_awready_mux = |(aa_mi_awtarget_hot & sa_wm_awready); assign mi_arvalid = aa_mi_artarget_hot & {C_NUM_MASTER_SLOTS+1{aa_mi_arvalid}}; assign aa_mi_arready = |(aa_mi_artarget_hot & mi_arready); assign M_AXI_ARVALID = mi_arvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_arready[0+:C_NUM_MASTER_SLOTS] = M_AXI_ARREADY; // MI-slot # C_NUM_MASTER_SLOTS is the error handler if (C_RANGE_CHECK) begin : gen_decerr_slave axi_crossbar_v2_1_decerr_slave # ( .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_RESP (P_DECERR) ) decerr_slave_inst ( .S_AXI_ACLK (ACLK), .S_AXI_ARESET (reset), .S_AXI_AWID (aa_mi_awmesg[0+:C_AXI_ID_WIDTH]), .S_AXI_AWVALID (mi_awvalid[C_NUM_MASTER_SLOTS]), .S_AXI_AWREADY (mi_awready[C_NUM_MASTER_SLOTS]), .S_AXI_WLAST (mi_wlast[C_NUM_MASTER_SLOTS]), .S_AXI_WVALID (mi_wvalid[C_NUM_MASTER_SLOTS]), .S_AXI_WREADY (mi_wready[C_NUM_MASTER_SLOTS]), .S_AXI_BID (mi_bid[C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_BRESP (mi_bresp[C_NUM_MASTER_SLOTS*2+:2]), .S_AXI_BUSER (mi_buser[C_NUM_MASTER_SLOTS*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH]), .S_AXI_BVALID (mi_bvalid[C_NUM_MASTER_SLOTS]), .S_AXI_BREADY (mi_bready[C_NUM_MASTER_SLOTS]), .S_AXI_ARID (aa_mi_armesg[0+:C_AXI_ID_WIDTH]), .S_AXI_ARLEN (aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]), .S_AXI_ARVALID (mi_arvalid[C_NUM_MASTER_SLOTS]), .S_AXI_ARREADY (mi_arready[C_NUM_MASTER_SLOTS]), .S_AXI_RID (mi_rid[C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_RDATA (mi_rdata[C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .S_AXI_RRESP (mi_rresp[C_NUM_MASTER_SLOTS*2+:2]), .S_AXI_RUSER (mi_ruser[C_NUM_MASTER_SLOTS*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH]), .S_AXI_RLAST (mi_rlast[C_NUM_MASTER_SLOTS]), .S_AXI_RVALID (mi_rvalid[C_NUM_MASTER_SLOTS]), .S_AXI_RREADY (mi_rready[C_NUM_MASTER_SLOTS]) ); end else begin : gen_no_decerr_slave assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_wready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_arready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_bid[C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_bresp[C_NUM_MASTER_SLOTS*2+:2] = 0; assign mi_buser[C_NUM_MASTER_SLOTS*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign mi_bvalid[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rid[C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_rdata[C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign mi_rresp[C_NUM_MASTER_SLOTS*2+:2] = 0; assign mi_ruser[C_NUM_MASTER_SLOTS*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign mi_rlast[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rvalid[C_NUM_MASTER_SLOTS] = 1'b0; end // gen_decerr_slave endgenerate endmodule

module Mux_Array #(parameter SWR=26, parameter EWR=5) ( input wire clk, input wire rst, input wire load_i, input wire [SWR-1:0] Data_i, input wire FSM_left_right_i, input wire [EWR-1:0] Shift_Value_i, input wire bit_shift_i, output wire [SWR-1:0] Data_o ); //// wire [SWR-1:0] Data_array[EWR+1:0]; //////////////////7 genvar k;//Level ///////////////////77777 Rotate_Mux_Array #(.SWR(SWR)) first_rotate( .Data_i(Data_i), .select_i(FSM_left_right_i), .Data_o(Data_array [0][SWR-1:0]) ); generate for (k=0; k < 3; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+1]) ); end endgenerate RegisterAdd #(.W(SWR)) Mid_Reg( .clk(clk), .rst(rst), .load(1'b1), .D(Data_array[3]), .Q(Data_array[4]) ); generate for (k=3; k < EWR; k=k+1) begin shift_mux_array #(.SWR(SWR), .LEVEL(k)) shift_mux_array( .Data_i(Data_array[k+1]), .select_i(Shift_Value_i[k]), .bit_shift_i(bit_shift_i), .Data_o(Data_array[k+2]) ); end endgenerate Rotate_Mux_Array #(.SWR(SWR)) last_rotate( .Data_i(Data_array[EWR+1]), .select_i(FSM_left_right_i), .Data_o(Data_o) ); endmodule

module processing_system7_bfm_v2_0_5_intr_wr_mem( sw_clk, rstn, full, WR_DATA_ACK_OCM, WR_DATA_ACK_DDR, WR_ADDR, WR_DATA, WR_BYTES, WR_QOS, WR_DATA_VALID_OCM, WR_DATA_VALID_DDR ); `include "processing_system7_bfm_v2_0_5_local_params.v" /* local parameters for interconnect wr fifo model */ input sw_clk, rstn; output full; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output reg WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output reg [max_burst_bits-1:0] WR_DATA; output reg [addr_width-1:0] WR_ADDR; output reg [max_burst_bytes_width:0] WR_BYTES; output reg [axi_qos_width-1:0] WR_QOS; reg [intr_cnt_width-1:0] wr_ptr = 0, rd_ptr = 0; reg [wr_fifo_data_bits-1:0] wr_fifo [0:intr_max_outstanding-1]; wire empty; assign empty = (wr_ptr === rd_ptr)?1'b1: 1'b0; assign full = ((wr_ptr[intr_cnt_width-1]!== rd_ptr[intr_cnt_width-1]) && (wr_ptr[intr_cnt_width-2:0] === rd_ptr[intr_cnt_width-2:0]))?1'b1 :1'b0; parameter SEND_DATA = 0, WAIT_ACK = 1; reg state; task automatic write_mem; input [wr_fifo_data_bits-1:0] data; begin wr_fifo[wr_ptr[intr_cnt_width-2:0]] = data; if(wr_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) wr_ptr[intr_cnt_width-2:0] = 0; else wr_ptr = wr_ptr + 1; end endtask always@(negedge rstn or posedge sw_clk) begin if(!rstn) begin wr_ptr = 0; rd_ptr = 0; WR_DATA_VALID_DDR = 1'b0; WR_DATA_VALID_OCM = 1'b0; WR_QOS = 0; state = SEND_DATA; end else begin case(state) SEND_DATA :begin state = SEND_DATA; WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; if(!empty) begin WR_DATA = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_data_msb : wr_data_lsb]; WR_ADDR = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb]; WR_BYTES = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_bytes_msb : wr_bytes_lsb]; WR_QOS = wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_qos_msb : wr_qos_lsb]; state = WAIT_ACK; case(decode_address(wr_fifo[rd_ptr[intr_cnt_width-2:0]][wr_addr_msb : wr_addr_lsb])) OCM_MEM : WR_DATA_VALID_OCM = 1; DDR_MEM : WR_DATA_VALID_DDR = 1; default : state = SEND_DATA; endcase if(rd_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) begin rd_ptr[intr_cnt_width-2:0] = 0; end else begin rd_ptr = rd_ptr+1; end end end WAIT_ACK :begin state = WAIT_ACK; if(WR_DATA_ACK_OCM | WR_DATA_ACK_DDR) begin WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; state = SEND_DATA; end end endcase end end endmodule

module axi_crossbar_v2_1_addr_arbiter # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 1, parameter integer C_NUM_S_LOG = 1, parameter integer C_NUM_M = 1, parameter integer C_MESG_WIDTH = 1, parameter [C_NUM_S*32-1:0] C_ARB_PRIORITY = {C_NUM_S{32'h00000000}} // Arbitration priority among each SI slot. // Higher values indicate higher priority. // Format: C_NUM_SLAVE_SLOTS{Bit32}; // Range: 'h0-'hF. ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_S*C_MESG_WIDTH-1:0] S_MESG, input wire [C_NUM_S*C_NUM_M-1:0] S_TARGET_HOT, input wire [C_NUM_S-1:0] S_VALID, input wire [C_NUM_S-1:0] S_VALID_QUAL, output wire [C_NUM_S-1:0] S_READY, // Master Ports output wire [C_MESG_WIDTH-1:0] M_MESG, output wire [C_NUM_M-1:0] M_TARGET_HOT, output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, output wire M_VALID, input wire M_READY, // Sideband input input wire [C_NUM_M-1:0] ISSUING_LIMIT ); // Generates a mask for all input slots that are priority based function [C_NUM_S-1:0] f_prio_mask ( input integer null_arg ); reg [C_NUM_S-1:0] mask; integer i; begin mask = 0; for (i=0; i < C_NUM_S; i=i+1) begin mask[i] = (C_ARB_PRIORITY[i*32+:32] != 0); end f_prio_mask = mask; end endfunction // Convert 16-bit one-hot to 4-bit binary function [3:0] f_hot2enc ( input [15:0] one_hot ); begin f_hot2enc[0] = |(one_hot & 16'b1010101010101010); f_hot2enc[1] = |(one_hot & 16'b1100110011001100); f_hot2enc[2] = |(one_hot & 16'b1111000011110000); f_hot2enc[3] = |(one_hot & 16'b1111111100000000); end endfunction localparam [C_NUM_S-1:0] P_PRIO_MASK = f_prio_mask(0); reg m_valid_i; reg [C_NUM_S-1:0] s_ready_i; reg [C_NUM_S-1:0] qual_reg; reg [C_NUM_S-1:0] grant_hot; reg [C_NUM_S-1:0] last_rr_hot; reg any_grant; reg any_prio; reg found_prio; reg [C_NUM_S-1:0] which_prio_hot; reg [C_NUM_S-1:0] next_prio_hot; reg [C_NUM_S_LOG-1:0] which_prio_enc; reg [C_NUM_S_LOG-1:0] next_prio_enc; reg [4:0] current_highest; wire [C_NUM_S-1:0] valid_rr; reg [15:0] next_rr_hot; reg [C_NUM_S_LOG-1:0] next_rr_enc; reg [C_NUM_S*C_NUM_S-1:0] carry_rr; reg [C_NUM_S*C_NUM_S-1:0] mask_rr; reg found_rr; wire [C_NUM_S-1:0] next_hot; wire [C_NUM_S_LOG-1:0] next_enc; reg prio_stall; integer i; wire [C_NUM_S-1:0] valid_qual_i; reg [C_NUM_S_LOG-1:0] m_grant_enc_i; reg [C_NUM_M-1:0] m_target_hot_i; wire [C_NUM_M-1:0] m_target_hot_mux; reg [C_MESG_WIDTH-1:0] m_mesg_i; wire [C_MESG_WIDTH-1:0] m_mesg_mux; genvar gen_si; assign M_VALID = m_valid_i; assign S_READY = s_ready_i; assign M_GRANT_ENC = m_grant_enc_i; assign M_MESG = m_mesg_i; assign M_TARGET_HOT = m_target_hot_i; generate if (C_NUM_S>1) begin : gen_arbiter always @(posedge ACLK) begin if (ARESET) begin qual_reg <= 0; end else begin qual_reg <= valid_qual_i | ~S_VALID; // Don't disqualify when bus not VALID (valid_qual_i would be garbage) end end for (gen_si=0; gen_si<C_NUM_S; gen_si=gen_si+1) begin : gen_req_qual assign valid_qual_i[gen_si] = S_VALID_QUAL[gen_si] & (|(S_TARGET_HOT[gen_si*C_NUM_M+:C_NUM_M] & ~ISSUING_LIMIT)); end ///////////////////////////////////////////////////////////////////////////// // Grant a new request when there is none still pending. // If no qualified requests found, de-assert M_VALID. ///////////////////////////////////////////////////////////////////////////// assign next_hot = found_prio ? next_prio_hot : next_rr_hot; assign next_enc = found_prio ? next_prio_enc : next_rr_enc; always @(posedge ACLK) begin if (ARESET) begin m_valid_i <= 0; s_ready_i <= 0; grant_hot <= 0; any_grant <= 1'b0; m_grant_enc_i <= 0; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; m_target_hot_i <= 0; end else begin s_ready_i <= 0; if (m_valid_i) begin // Stall 1 cycle after each master-side completion. if (M_READY) begin // Master-side completion m_valid_i <= 1'b0; grant_hot <= 0; any_grant <= 1'b0; end end else if (any_grant) begin m_valid_i <= 1'b1; s_ready_i <= grant_hot; // Assert S_AW/READY for 1 cycle to complete SI address transfer (regardless of M_AREADY) end else begin if ((found_prio | found_rr) & ~prio_stall) begin // Waste 1 cycle and re-arbitrate if target of highest prio hit issuing limit in previous cycle (valid_qual_i). if (|(next_hot & valid_qual_i)) begin grant_hot <= next_hot; m_grant_enc_i <= next_enc; any_grant <= 1'b1; if (~found_prio) begin last_rr_hot <= next_rr_hot; end m_target_hot_i <= m_target_hot_mux; end end end end end ///////////////////////////////////////////////////////////////////////////// // Fixed Priority arbiter // Selects next request to grant from among inputs with PRIO > 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ * begin : ALG_PRIO integer ip; any_prio = 1'b0; prio_stall = 1'b0; which_prio_hot = 0; which_prio_enc = 0; current_highest = 0; for (ip=0; ip < C_NUM_S; ip=ip+1) begin // Disqualify slot if target hit issuing limit (pass to lower prio slot). if (P_PRIO_MASK[ip] & S_VALID[ip] & qual_reg[ip]) begin if ({1'b0, C_ARB_PRIORITY[ip*32+:4]} > current_highest) begin current_highest[0+:4] = C_ARB_PRIORITY[ip*32+:4]; // Stall 1 cycle when highest prio is recovering from SI-side handshake. // (Do not allow lower-prio slot to win arbitration.) if (s_ready_i[ip]) begin any_prio = 1'b0; prio_stall = 1'b1; which_prio_hot = 0; which_prio_enc = 0; end else begin any_prio = 1'b1; which_prio_hot = 1'b1 << ip; which_prio_enc = ip; end end end end found_prio = any_prio; next_prio_hot = which_prio_hot; next_prio_enc = which_prio_enc; end ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// // Disqualify slot if target hit issuing limit 2 or more cycles earlier (pass to next RR slot). // Disqualify for 1 cycle a slot that is recovering from SI-side handshake (s_ready_i), // and allow arbitration to pass to any other RR requester. assign valid_rr = ~P_PRIO_MASK & S_VALID & ~s_ready_i & qual_reg; always @ * begin : ALG_RR integer ir, jr, nr; next_rr_hot = 0; for (ir=0;ir<C_NUM_S;ir=ir+1) begin nr = (ir>0) ? (ir-1) : (C_NUM_S-1); carry_rr[ir*C_NUM_S] = last_rr_hot[nr]; mask_rr[ir*C_NUM_S] = ~valid_rr[nr]; for (jr=1;jr<C_NUM_S;jr=jr+1) begin nr = (ir-jr > 0) ? (ir-jr-1) : (C_NUM_S+ir-jr-1); carry_rr[ir*C_NUM_S+jr] = carry_rr[ir*C_NUM_S+jr-1] | (last_rr_hot[nr] & mask_rr[ir*C_NUM_S+jr-1]); if (jr < C_NUM_S-1) begin mask_rr[ir*C_NUM_S+jr] = mask_rr[ir*C_NUM_S+jr-1] & ~valid_rr[nr]; end end next_rr_hot[ir] = valid_rr[ir] & carry_rr[(ir+1)*C_NUM_S-1]; end next_rr_enc = f_hot2enc(next_rr_hot); found_rr = |(next_rr_hot); end generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY ("rtl"), .C_RATIO (C_NUM_S), .C_SEL_WIDTH (C_NUM_S_LOG), .C_DATA_WIDTH (C_MESG_WIDTH) ) mux_mesg ( .S (m_grant_enc_i), .A (S_MESG), .O (m_mesg_mux), .OE (1'b1) ); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY ("rtl"), .C_RATIO (C_NUM_S), .C_SEL_WIDTH (C_NUM_S_LOG), .C_DATA_WIDTH (C_NUM_M) ) si_amesg_mux_inst ( .S (next_enc), .A (S_TARGET_HOT), .O (m_target_hot_mux), .OE (1'b1) ); always @(posedge ACLK) begin if (ARESET) begin m_mesg_i <= 0; end else if (~m_valid_i) begin m_mesg_i <= m_mesg_mux; end end end else begin : gen_no_arbiter assign valid_qual_i = S_VALID_QUAL & |(S_TARGET_HOT & ~ISSUING_LIMIT); always @ (posedge ACLK) begin if (ARESET) begin m_valid_i <= 1'b0; s_ready_i <= 1'b0; m_grant_enc_i <= 0; end else begin s_ready_i <= 1'b0; if (m_valid_i) begin if (M_READY) begin m_valid_i <= 1'b0; end end else if (S_VALID[0] & valid_qual_i[0] & ~s_ready_i) begin m_valid_i <= 1'b1; s_ready_i <= 1'b1; m_target_hot_i <= S_TARGET_HOT; end end end always @(posedge ACLK) begin if (ARESET) begin m_mesg_i <= 0; end else if (~m_valid_i) begin m_mesg_i <= S_MESG; end end end // gen_arbiter endgenerate endmodule

module processing_system7_bfm_v2_0_5_intr_rd_mem( sw_clk, rstn, full, empty, req, invalid_rd_req, rd_info, RD_DATA_OCM, RD_DATA_DDR, RD_DATA_VALID_OCM, RD_DATA_VALID_DDR ); `include "processing_system7_bfm_v2_0_5_local_params.v" input sw_clk, rstn; output full, empty; input RD_DATA_VALID_DDR, RD_DATA_VALID_OCM; input [max_burst_bits-1:0] RD_DATA_DDR, RD_DATA_OCM; input req, invalid_rd_req; input [rd_info_bits-1:0] rd_info; reg [intr_cnt_width-1:0] wr_ptr = 0, rd_ptr = 0; reg [rd_afi_fifo_bits-1:0] rd_fifo [0:intr_max_outstanding-1]; // Data, addr, size, burst, len, RID, RRESP, valid bytes wire full, empty; assign empty = (wr_ptr === rd_ptr)?1'b1: 1'b0; assign full = ((wr_ptr[intr_cnt_width-1]!== rd_ptr[intr_cnt_width-1]) && (wr_ptr[intr_cnt_width-2:0] === rd_ptr[intr_cnt_width-2:0]))?1'b1 :1'b0; /* read from the fifo */ task read_mem; output [rd_afi_fifo_bits-1:0] data; begin data = rd_fifo[rd_ptr[intr_cnt_width-1:0]]; if(rd_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) rd_ptr[intr_cnt_width-2:0] = 0; else rd_ptr = rd_ptr + 1; end endtask reg state; reg invalid_rd; /* write in the fifo */ always@(negedge rstn or posedge sw_clk) begin if(!rstn) begin wr_ptr = 0; rd_ptr = 0; state = 0; invalid_rd = 0; end else begin case (state) 0 : begin state = 0; invalid_rd = 0; if(req)begin state = 1; invalid_rd = invalid_rd_req; end end 1 : begin state = 1; if(RD_DATA_VALID_OCM | RD_DATA_VALID_DDR | invalid_rd) begin if(RD_DATA_VALID_DDR) rd_fifo[wr_ptr[intr_cnt_width-2:0]] = {RD_DATA_DDR,rd_info}; else if(RD_DATA_VALID_OCM) rd_fifo[wr_ptr[intr_cnt_width-2:0]] = {RD_DATA_OCM,rd_info}; else rd_fifo[wr_ptr[intr_cnt_width-2:0]] = rd_info; if(wr_ptr[intr_cnt_width-2:0] === intr_max_outstanding-1) wr_ptr[intr_cnt_width-2:0] = 0; else wr_ptr = wr_ptr + 1; state = 0; invalid_rd = 0; end end endcase end end endmodule

module axi_crossbar_v2_1_splitter # ( parameter integer C_NUM_M = 2 // Number of master ports = [2:16] ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Port input wire S_VALID, output wire S_READY, // Master Ports output wire [C_NUM_M-1:0] M_VALID, input wire [C_NUM_M-1:0] M_READY ); reg [C_NUM_M-1:0] m_ready_d; wire s_ready_i; wire [C_NUM_M-1:0] m_valid_i; always @(posedge ACLK) begin if (ARESET | s_ready_i) m_ready_d <= {C_NUM_M{1'b0}}; else m_ready_d <= m_ready_d | (m_valid_i & M_READY); end assign s_ready_i = &(m_ready_d | M_READY); assign m_valid_i = {C_NUM_M{S_VALID}} & ~m_ready_d; assign M_VALID = m_valid_i; assign S_READY = s_ready_i; endmodule

module debounce_switch #( parameter WIDTH=1, // width of the input and output signals parameter N=3, // length of shift register parameter RATE=125000 // clock division factor )( input wire clk, input wire rst, input wire [WIDTH-1:0] in, output wire [WIDTH-1:0] out ); reg [23:0] cnt_reg = 24'd0; reg [N-1:0] debounce_reg[WIDTH-1:0]; reg [WIDTH-1:0] state; /* * The synchronized output is the state register */ assign out = state; integer k; always @(posedge clk or posedge rst) begin if (rst) begin cnt_reg <= 0; state <= 0; for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= 0; end end else begin if (cnt_reg < RATE) begin cnt_reg <= cnt_reg + 24'd1; end else begin cnt_reg <= 24'd0; end if (cnt_reg == 24'd0) begin for (k = 0; k < WIDTH; k = k + 1) begin debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]}; end end for (k = 0; k < WIDTH; k = k + 1) begin if (|debounce_reg[k] == 0) begin state[k] <= 0; end else if (&debounce_reg[k] == 1) begin state[k] <= 1; end else begin state[k] <= state[k]; end end end end endmodule

module processing_system7_bfm_v2_0_5_gen_clock( ps_clk, sw_clk, fclk_clk3, fclk_clk2, fclk_clk1, fclk_clk0 ); input ps_clk; output sw_clk; output fclk_clk3; output fclk_clk2; output fclk_clk1; output fclk_clk0; parameter freq_clk3 = 50; parameter freq_clk2 = 50; parameter freq_clk1 = 50; parameter freq_clk0 = 50; reg clk0 = 1'b0; reg clk1 = 1'b0; reg clk2 = 1'b0; reg clk3 = 1'b0; reg sw_clk = 1'b0; assign fclk_clk0 = clk0; assign fclk_clk1 = clk1; assign fclk_clk2 = clk2; assign fclk_clk3 = clk3; real clk3_p = (1000.00/freq_clk3)/2; real clk2_p = (1000.00/freq_clk2)/2; real clk1_p = (1000.00/freq_clk1)/2; real clk0_p = (1000.00/freq_clk0)/2; always #(clk3_p) clk3 = !clk3; always #(clk2_p) clk2 = !clk2; always #(clk1_p) clk1 = !clk1; always #(clk0_p) clk0 = !clk0; always #(0.5) sw_clk = !sw_clk; endmodule

module processing_system7_bfm_v2_0_5_ocmc( rstn, sw_clk, /* Goes to port 0 of OCM */ ocm_wr_ack_port0, ocm_wr_dv_port0, ocm_rd_req_port0, ocm_rd_dv_port0, ocm_wr_addr_port0, ocm_wr_data_port0, ocm_wr_bytes_port0, ocm_rd_addr_port0, ocm_rd_data_port0, ocm_rd_bytes_port0, ocm_wr_qos_port0, ocm_rd_qos_port0, /* Goes to port 1 of OCM */ ocm_wr_ack_port1, ocm_wr_dv_port1, ocm_rd_req_port1, ocm_rd_dv_port1, ocm_wr_addr_port1, ocm_wr_data_port1, ocm_wr_bytes_port1, ocm_rd_addr_port1, ocm_rd_data_port1, ocm_rd_bytes_port1, ocm_wr_qos_port1, ocm_rd_qos_port1 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; output ocm_wr_ack_port0; input ocm_wr_dv_port0; input ocm_rd_req_port0; output ocm_rd_dv_port0; input[addr_width-1:0] ocm_wr_addr_port0; input[max_burst_bits-1:0] ocm_wr_data_port0; input[max_burst_bytes_width:0] ocm_wr_bytes_port0; input[addr_width-1:0] ocm_rd_addr_port0; output[max_burst_bits-1:0] ocm_rd_data_port0; input[max_burst_bytes_width:0] ocm_rd_bytes_port0; input [axi_qos_width-1:0] ocm_wr_qos_port0; input [axi_qos_width-1:0] ocm_rd_qos_port0; output ocm_wr_ack_port1; input ocm_wr_dv_port1; input ocm_rd_req_port1; output ocm_rd_dv_port1; input[addr_width-1:0] ocm_wr_addr_port1; input[max_burst_bits-1:0] ocm_wr_data_port1; input[max_burst_bytes_width:0] ocm_wr_bytes_port1; input[addr_width-1:0] ocm_rd_addr_port1; output[max_burst_bits-1:0] ocm_rd_data_port1; input[max_burst_bytes_width:0] ocm_rd_bytes_port1; input[axi_qos_width-1:0] ocm_wr_qos_port1; input[axi_qos_width-1:0] ocm_rd_qos_port1; wire [axi_qos_width-1:0] wr_qos; wire wr_req; wire [max_burst_bits-1:0] wr_data; wire [addr_width-1:0] wr_addr; wire [max_burst_bytes_width:0] wr_bytes; reg wr_ack; wire [axi_qos_width-1:0] rd_qos; reg [max_burst_bits-1:0] rd_data; wire [addr_width-1:0] rd_addr; wire [max_burst_bytes_width:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_wr ocm_write_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_wr_qos_port0), .qos2(ocm_wr_qos_port1), .prt_dv1(ocm_wr_dv_port0), .prt_dv2(ocm_wr_dv_port1), .prt_data1(ocm_wr_data_port0), .prt_data2(ocm_wr_data_port1), .prt_addr1(ocm_wr_addr_port0), .prt_addr2(ocm_wr_addr_port1), .prt_bytes1(ocm_wr_bytes_port0), .prt_bytes2(ocm_wr_bytes_port1), .prt_ack1(ocm_wr_ack_port0), .prt_ack2(ocm_wr_ack_port1), .prt_qos(wr_qos), .prt_req(wr_req), .prt_data(wr_data), .prt_addr(wr_addr), .prt_bytes(wr_bytes), .prt_ack(wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ocm_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_rd_qos_port0), .qos2(ocm_rd_qos_port1), .prt_req1(ocm_rd_req_port0), .prt_req2(ocm_rd_req_port1), .prt_data1(ocm_rd_data_port0), .prt_data2(ocm_rd_data_port1), .prt_addr1(ocm_rd_addr_port0), .prt_addr2(ocm_rd_addr_port1), .prt_bytes1(ocm_rd_bytes_port0), .prt_bytes2(ocm_rd_bytes_port1), .prt_dv1(ocm_rd_dv_port0), .prt_dv2(ocm_rd_dv_port1), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_ocm_mem ocm(); reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin wr_ack <= 0; rd_dv <= 0; state <= 2'd0; end else begin case(state) 0:begin state <= 0; wr_ack <= 0; rd_dv <= 0; if(wr_req) begin ocm.write_mem(wr_data , wr_addr, wr_bytes); wr_ack <= 1; state <= 1; end if(rd_req) begin ocm.read_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin wr_ack <= 0; rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule

module processing_system7_bfm_v2_0_5_fmsw_gp( sw_clk, rstn, w_qos_gp0, r_qos_gp0, wr_ack_ocm_gp0, wr_ack_ddr_gp0, wr_data_gp0, wr_addr_gp0, wr_bytes_gp0, wr_dv_ocm_gp0, wr_dv_ddr_gp0, rd_req_ocm_gp0, rd_req_ddr_gp0, rd_req_reg_gp0, rd_addr_gp0, rd_bytes_gp0, rd_data_ocm_gp0, rd_data_ddr_gp0, rd_data_reg_gp0, rd_dv_ocm_gp0, rd_dv_ddr_gp0, rd_dv_reg_gp0, w_qos_gp1, r_qos_gp1, wr_ack_ocm_gp1, wr_ack_ddr_gp1, wr_data_gp1, wr_addr_gp1, wr_bytes_gp1, wr_dv_ocm_gp1, wr_dv_ddr_gp1, rd_req_ocm_gp1, rd_req_ddr_gp1, rd_req_reg_gp1, rd_addr_gp1, rd_bytes_gp1, rd_data_ocm_gp1, rd_data_ddr_gp1, rd_data_reg_gp1, rd_dv_ocm_gp1, rd_dv_ddr_gp1, rd_dv_reg_gp1, ocm_wr_ack, ocm_wr_dv, ocm_rd_req, ocm_rd_dv, ddr_wr_ack, ddr_wr_dv, ddr_rd_req, ddr_rd_dv, reg_rd_req, reg_rd_dv, ocm_wr_qos, ddr_wr_qos, ocm_rd_qos, ddr_rd_qos, reg_rd_qos, ocm_wr_addr, ocm_wr_data, ocm_wr_bytes, ocm_rd_addr, ocm_rd_data, ocm_rd_bytes, ddr_wr_addr, ddr_wr_data, ddr_wr_bytes, ddr_rd_addr, ddr_rd_data, ddr_rd_bytes, reg_rd_addr, reg_rd_data, reg_rd_bytes ); `include "processing_system7_bfm_v2_0_5_local_params.v" input sw_clk; input rstn; input [axi_qos_width-1:0]w_qos_gp0; input [axi_qos_width-1:0]r_qos_gp0; input [axi_qos_width-1:0]w_qos_gp1; input [axi_qos_width-1:0]r_qos_gp1; output [axi_qos_width-1:0]ocm_wr_qos; output [axi_qos_width-1:0]ocm_rd_qos; output [axi_qos_width-1:0]ddr_wr_qos; output [axi_qos_width-1:0]ddr_rd_qos; output [axi_qos_width-1:0]reg_rd_qos; output wr_ack_ocm_gp0; output wr_ack_ddr_gp0; input [max_burst_bits-1:0] wr_data_gp0; input [addr_width-1:0] wr_addr_gp0; input [max_burst_bytes_width:0] wr_bytes_gp0; output wr_dv_ocm_gp0; output wr_dv_ddr_gp0; input rd_req_ocm_gp0; input rd_req_ddr_gp0; input rd_req_reg_gp0; input [addr_width-1:0] rd_addr_gp0; input [max_burst_bytes_width:0] rd_bytes_gp0; output [max_burst_bits-1:0] rd_data_ocm_gp0; output [max_burst_bits-1:0] rd_data_ddr_gp0; output [max_burst_bits-1:0] rd_data_reg_gp0; output rd_dv_ocm_gp0; output rd_dv_ddr_gp0; output rd_dv_reg_gp0; output wr_ack_ocm_gp1; output wr_ack_ddr_gp1; input [max_burst_bits-1:0] wr_data_gp1; input [addr_width-1:0] wr_addr_gp1; input [max_burst_bytes_width:0] wr_bytes_gp1; output wr_dv_ocm_gp1; output wr_dv_ddr_gp1; input rd_req_ocm_gp1; input rd_req_ddr_gp1; input rd_req_reg_gp1; input [addr_width-1:0] rd_addr_gp1; input [max_burst_bytes_width:0] rd_bytes_gp1; output [max_burst_bits-1:0] rd_data_ocm_gp1; output [max_burst_bits-1:0] rd_data_ddr_gp1; output [max_burst_bits-1:0] rd_data_reg_gp1; output rd_dv_ocm_gp1; output rd_dv_ddr_gp1; output rd_dv_reg_gp1; input ocm_wr_ack; output ocm_wr_dv; output [addr_width-1:0]ocm_wr_addr; output [max_burst_bits-1:0]ocm_wr_data; output [max_burst_bytes_width:0]ocm_wr_bytes; input ocm_rd_dv; input [max_burst_bits-1:0] ocm_rd_data; output ocm_rd_req; output [addr_width-1:0] ocm_rd_addr; output [max_burst_bytes_width:0] ocm_rd_bytes; input ddr_wr_ack; output ddr_wr_dv; output [addr_width-1:0]ddr_wr_addr; output [max_burst_bits-1:0]ddr_wr_data; output [max_burst_bytes_width:0]ddr_wr_bytes; input ddr_rd_dv; input [max_burst_bits-1:0] ddr_rd_data; output ddr_rd_req; output [addr_width-1:0] ddr_rd_addr; output [max_burst_bytes_width:0] ddr_rd_bytes; input reg_rd_dv; input [max_burst_bits-1:0] reg_rd_data; output reg_rd_req; output [addr_width-1:0] reg_rd_addr; output [max_burst_bytes_width:0] reg_rd_bytes; processing_system7_bfm_v2_0_5_arb_wr ocm_gp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_gp0), .qos2(w_qos_gp1), .prt_dv1(wr_dv_ocm_gp0), .prt_dv2(wr_dv_ocm_gp1), .prt_data1(wr_data_gp0), .prt_data2(wr_data_gp1), .prt_addr1(wr_addr_gp0), .prt_addr2(wr_addr_gp1), .prt_bytes1(wr_bytes_gp0), .prt_bytes2(wr_bytes_gp1), .prt_ack1(wr_ack_ocm_gp0), .prt_ack2(wr_ack_ocm_gp1), .prt_req(ocm_wr_dv), .prt_qos(ocm_wr_qos), .prt_data(ocm_wr_data), .prt_addr(ocm_wr_addr), .prt_bytes(ocm_wr_bytes), .prt_ack(ocm_wr_ack) ); processing_system7_bfm_v2_0_5_arb_wr ddr_gp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_gp0), .qos2(w_qos_gp1), .prt_dv1(wr_dv_ddr_gp0), .prt_dv2(wr_dv_ddr_gp1), .prt_data1(wr_data_gp0), .prt_data2(wr_data_gp1), .prt_addr1(wr_addr_gp0), .prt_addr2(wr_addr_gp1), .prt_bytes1(wr_bytes_gp0), .prt_bytes2(wr_bytes_gp1), .prt_ack1(wr_ack_ddr_gp0), .prt_ack2(wr_ack_ddr_gp1), .prt_req(ddr_wr_dv), .prt_qos(ddr_wr_qos), .prt_data(ddr_wr_data), .prt_addr(ddr_wr_addr), .prt_bytes(ddr_wr_bytes), .prt_ack(ddr_wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ocm_gp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_gp0), .qos2(r_qos_gp1), .prt_req1(rd_req_ocm_gp0), .prt_req2(rd_req_ocm_gp1), .prt_data1(rd_data_ocm_gp0), .prt_data2(rd_data_ocm_gp1), .prt_addr1(rd_addr_gp0), .prt_addr2(rd_addr_gp1), .prt_bytes1(rd_bytes_gp0), .prt_bytes2(rd_bytes_gp1), .prt_dv1(rd_dv_ocm_gp0), .prt_dv2(rd_dv_ocm_gp1), .prt_req(ocm_rd_req), .prt_qos(ocm_rd_qos), .prt_data(ocm_rd_data), .prt_addr(ocm_rd_addr), .prt_bytes(ocm_rd_bytes), .prt_dv(ocm_rd_dv) ); processing_system7_bfm_v2_0_5_arb_rd ddr_gp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_gp0), .qos2(r_qos_gp1), .prt_req1(rd_req_ddr_gp0), .prt_req2(rd_req_ddr_gp1), .prt_data1(rd_data_ddr_gp0), .prt_data2(rd_data_ddr_gp1), .prt_addr1(rd_addr_gp0), .prt_addr2(rd_addr_gp1), .prt_bytes1(rd_bytes_gp0), .prt_bytes2(rd_bytes_gp1), .prt_dv1(rd_dv_ddr_gp0), .prt_dv2(rd_dv_ddr_gp1), .prt_req(ddr_rd_req), .prt_qos(ddr_rd_qos), .prt_data(ddr_rd_data), .prt_addr(ddr_rd_addr), .prt_bytes(ddr_rd_bytes), .prt_dv(ddr_rd_dv) ); processing_system7_bfm_v2_0_5_arb_rd reg_gp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_gp0), .qos2(r_qos_gp1), .prt_req1(rd_req_reg_gp0), .prt_req2(rd_req_reg_gp1), .prt_data1(rd_data_reg_gp0), .prt_data2(rd_data_reg_gp1), .prt_addr1(rd_addr_gp0), .prt_addr2(rd_addr_gp1), .prt_bytes1(rd_bytes_gp0), .prt_bytes2(rd_bytes_gp1), .prt_dv1(rd_dv_reg_gp0), .prt_dv2(rd_dv_reg_gp1), .prt_req(reg_rd_req), .prt_qos(reg_rd_qos), .prt_data(reg_rd_data), .prt_addr(reg_rd_addr), .prt_bytes(reg_rd_bytes), .prt_dv(reg_rd_dv) ); endmodule

module processing_system7_bfm_v2_0_5_arb_hp0_1( sw_clk, rstn, w_qos_hp0, r_qos_hp0, w_qos_hp1, r_qos_hp1, wr_ack_ddr_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, rd_req_ddr_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_dv_ddr_hp0, wr_ack_ddr_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, rd_req_ddr_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_dv_ddr_hp1, ddr_wr_ack, ddr_wr_dv, ddr_rd_req, ddr_rd_dv, ddr_rd_qos, ddr_wr_qos, ddr_wr_addr, ddr_wr_data, ddr_wr_bytes, ddr_rd_addr, ddr_rd_data, ddr_rd_bytes ); `include "processing_system7_bfm_v2_0_5_local_params.v" input sw_clk; input rstn; input [axi_qos_width-1:0] w_qos_hp0; input [axi_qos_width-1:0] r_qos_hp0; input [axi_qos_width-1:0] w_qos_hp1; input [axi_qos_width-1:0] r_qos_hp1; input [axi_qos_width-1:0] ddr_rd_qos; input [axi_qos_width-1:0] ddr_wr_qos; output wr_ack_ddr_hp0; input [max_burst_bits-1:0] wr_data_hp0; input [addr_width-1:0] wr_addr_hp0; input [max_burst_bytes_width:0] wr_bytes_hp0; output wr_dv_ddr_hp0; input rd_req_ddr_hp0; input [addr_width-1:0] rd_addr_hp0; input [max_burst_bytes_width:0] rd_bytes_hp0; output [max_burst_bits-1:0] rd_data_ddr_hp0; output rd_dv_ddr_hp0; output wr_ack_ddr_hp1; input [max_burst_bits-1:0] wr_data_hp1; input [addr_width-1:0] wr_addr_hp1; input [max_burst_bytes_width:0] wr_bytes_hp1; output wr_dv_ddr_hp1; input rd_req_ddr_hp1; input [addr_width-1:0] rd_addr_hp1; input [max_burst_bytes_width:0] rd_bytes_hp1; output [max_burst_bits-1:0] rd_data_ddr_hp1; output rd_dv_ddr_hp1; input ddr_wr_ack; output ddr_wr_dv; output [addr_width-1:0]ddr_wr_addr; output [max_burst_bits-1:0]ddr_wr_data; output [max_burst_bytes_width:0]ddr_wr_bytes; input ddr_rd_dv; input [max_burst_bits-1:0] ddr_rd_data; output ddr_rd_req; output [addr_width-1:0] ddr_rd_addr; output [max_burst_bytes_width:0] ddr_rd_bytes; processing_system7_bfm_v2_0_5_arb_wr ddr_hp_wr( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_hp0), .qos2(w_qos_hp1), .prt_dv1(wr_dv_ddr_hp0), .prt_dv2(wr_dv_ddr_hp1), .prt_data1(wr_data_hp0), .prt_data2(wr_data_hp1), .prt_addr1(wr_addr_hp0), .prt_addr2(wr_addr_hp1), .prt_bytes1(wr_bytes_hp0), .prt_bytes2(wr_bytes_hp1), .prt_ack1(wr_ack_ddr_hp0), .prt_ack2(wr_ack_ddr_hp1), .prt_req(ddr_wr_dv), .prt_qos(ddr_wr_qos), .prt_data(ddr_wr_data), .prt_addr(ddr_wr_addr), .prt_bytes(ddr_wr_bytes), .prt_ack(ddr_wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd ddr_hp_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_hp0), .qos2(r_qos_hp1), .prt_req1(rd_req_ddr_hp0), .prt_req2(rd_req_ddr_hp1), .prt_data1(rd_data_ddr_hp0), .prt_data2(rd_data_ddr_hp1), .prt_addr1(rd_addr_hp0), .prt_addr2(rd_addr_hp1), .prt_bytes1(rd_bytes_hp0), .prt_bytes2(rd_bytes_hp1), .prt_dv1(rd_dv_ddr_hp0), .prt_dv2(rd_dv_ddr_hp1), .prt_qos(ddr_rd_qos), .prt_req(ddr_rd_req), .prt_data(ddr_rd_data), .prt_addr(ddr_rd_addr), .prt_bytes(ddr_rd_bytes), .prt_dv(ddr_rd_dv) ); endmodule

module axi_crossbar_v2_1_decerr_slave # ( parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_BUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_PROTOCOL = 0, parameter integer C_RESP = 2'b11 ) ( input wire S_AXI_ACLK, input wire S_AXI_ARESET, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_AWID, input wire S_AXI_AWVALID, output wire S_AXI_AWREADY, input wire S_AXI_WLAST, input wire S_AXI_WVALID, output wire S_AXI_WREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_BID, output wire [1:0] S_AXI_BRESP, output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire S_AXI_BVALID, input wire S_AXI_BREADY, input wire [(C_AXI_ID_WIDTH-1):0] S_AXI_ARID, input wire [7:0] S_AXI_ARLEN, input wire S_AXI_ARVALID, output wire S_AXI_ARREADY, output wire [(C_AXI_ID_WIDTH-1):0] S_AXI_RID, output wire [(C_AXI_DATA_WIDTH-1):0] S_AXI_RDATA, output wire [1:0] S_AXI_RRESP, output wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire S_AXI_RLAST, output wire S_AXI_RVALID, input wire S_AXI_RREADY ); reg s_axi_awready_i; reg s_axi_wready_i; reg s_axi_bvalid_i; reg s_axi_arready_i; reg s_axi_rvalid_i; localparam P_WRITE_IDLE = 2'b00; localparam P_WRITE_DATA = 2'b01; localparam P_WRITE_RESP = 2'b10; localparam P_READ_IDLE = 1'b0; localparam P_READ_DATA = 1'b1; localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; assign S_AXI_BRESP = C_RESP; assign S_AXI_RRESP = C_RESP; assign S_AXI_RDATA = {C_AXI_DATA_WIDTH{1'b0}}; assign S_AXI_BUSER = {C_AXI_BUSER_WIDTH{1'b0}}; assign S_AXI_RUSER = {C_AXI_RUSER_WIDTH{1'b0}}; assign S_AXI_AWREADY = s_axi_awready_i; assign S_AXI_WREADY = s_axi_wready_i; assign S_AXI_BVALID = s_axi_bvalid_i; assign S_AXI_ARREADY = s_axi_arready_i; assign S_AXI_RVALID = s_axi_rvalid_i; generate if (C_AXI_PROTOCOL == P_AXILITE) begin : gen_axilite assign S_AXI_RLAST = 1'b1; assign S_AXI_BID = 0; assign S_AXI_RID = 0; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; end else begin if (s_axi_bvalid_i) begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; end end else if (S_AXI_AWVALID & S_AXI_WVALID) begin if (s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; end else begin s_axi_awready_i <= 1'b1; s_axi_wready_i <= 1'b1; end end end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; end else begin if (s_axi_rvalid_i) begin if (S_AXI_RREADY) begin s_axi_rvalid_i <= 1'b0; end end else if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b1; end else begin s_axi_arready_i <= 1'b1; end end end end else begin : gen_axi reg s_axi_rlast_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_bid_i; reg [(C_AXI_ID_WIDTH-1):0] s_axi_rid_i; reg [7:0] read_cnt; reg [1:0] write_cs; reg [0:0] read_cs; assign S_AXI_RLAST = s_axi_rlast_i; assign S_AXI_BID = s_axi_bid_i; assign S_AXI_RID = s_axi_rid_i; always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin write_cs <= P_WRITE_IDLE; s_axi_awready_i <= 1'b0; s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b0; s_axi_bid_i <= 0; end else begin case (write_cs) P_WRITE_IDLE: begin if (S_AXI_AWVALID & s_axi_awready_i) begin s_axi_awready_i <= 1'b0; s_axi_bid_i <= S_AXI_AWID; s_axi_wready_i <= 1'b1; write_cs <= P_WRITE_DATA; end else begin s_axi_awready_i <= 1'b1; end end P_WRITE_DATA: begin if (S_AXI_WVALID & S_AXI_WLAST) begin s_axi_wready_i <= 1'b0; s_axi_bvalid_i <= 1'b1; write_cs <= P_WRITE_RESP; end end P_WRITE_RESP: begin if (S_AXI_BREADY) begin s_axi_bvalid_i <= 1'b0; s_axi_awready_i <= 1'b1; write_cs <= P_WRITE_IDLE; end end endcase end end always @(posedge S_AXI_ACLK) begin if (S_AXI_ARESET) begin read_cs <= P_READ_IDLE; s_axi_arready_i <= 1'b0; s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_rid_i <= 0; read_cnt <= 0; end else begin case (read_cs) P_READ_IDLE: begin if (S_AXI_ARVALID & s_axi_arready_i) begin s_axi_arready_i <= 1'b0; s_axi_rid_i <= S_AXI_ARID; read_cnt <= S_AXI_ARLEN; s_axi_rvalid_i <= 1'b1; if (S_AXI_ARLEN == 0) begin s_axi_rlast_i <= 1'b1; end else begin s_axi_rlast_i <= 1'b0; end read_cs <= P_READ_DATA; end else begin s_axi_arready_i <= 1'b1; end end P_READ_DATA: begin if (S_AXI_RREADY) begin if (read_cnt == 0) begin s_axi_rvalid_i <= 1'b0; s_axi_rlast_i <= 1'b0; s_axi_arready_i <= 1'b1; read_cs <= P_READ_IDLE; end else begin if (read_cnt == 1) begin s_axi_rlast_i <= 1'b1; end read_cnt <= read_cnt - 1; end end end endcase end end end endgenerate endmodule

module axi_crossbar_v2_1_si_transactor # ( parameter C_FAMILY = "none", parameter integer C_SI = 0, // SI-slot number of current instance. parameter integer C_DIR = 0, // Direction: 0 = Write; 1 = Read. parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_NUM_M = 2, parameter integer C_NUM_M_LOG = 1, parameter integer C_ACCEPTANCE = 1, // Acceptance limit of this SI-slot. parameter integer C_ACCEPTANCE_LOG = 0, // Width of acceptance counter for this SI-slot. parameter integer C_ID_WIDTH = 1, parameter integer C_THREAD_ID_WIDTH = 0, parameter integer C_ADDR_WIDTH = 32, parameter integer C_AMESG_WIDTH = 1, // Used for AW or AR channel payload, depending on instantiation. parameter integer C_RMESG_WIDTH = 1, // Used for B or R channel payload, depending on instantiation. parameter [C_ID_WIDTH-1:0] C_BASE_ID = {C_ID_WIDTH{1'b0}}, parameter [C_ID_WIDTH-1:0] C_HIGH_ID = {C_ID_WIDTH{1'b0}}, parameter [C_NUM_M*C_NUM_ADDR_RANGES*64-1:0] C_BASE_ADDR = {C_NUM_M*C_NUM_ADDR_RANGES*64{1'b1}}, parameter [C_NUM_M*C_NUM_ADDR_RANGES*64-1:0] C_HIGH_ADDR = {C_NUM_M*C_NUM_ADDR_RANGES*64{1'b0}}, parameter integer C_SINGLE_THREAD = 0, parameter [C_NUM_M-1:0] C_TARGET_QUAL = {C_NUM_M{1'b1}}, parameter [C_NUM_M*32-1:0] C_M_AXI_SECURE = {C_NUM_M{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE =0, parameter [C_NUM_M*32-1:0] C_ERR_MODE = {C_NUM_M{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Address Channel Interface Ports input wire [C_ID_WIDTH-1:0] S_AID, input wire [C_ADDR_WIDTH-1:0] S_AADDR, input wire [8-1:0] S_ALEN, input wire [3-1:0] S_ASIZE, input wire [2-1:0] S_ABURST, input wire [2-1:0] S_ALOCK, input wire [3-1:0] S_APROT, // input wire [4-1:0] S_AREGION, input wire [C_AMESG_WIDTH-1:0] S_AMESG, input wire S_AVALID, output wire S_AREADY, // Master Address Channel Interface Ports output wire [C_ID_WIDTH-1:0] M_AID, output wire [C_ADDR_WIDTH-1:0] M_AADDR, output wire [8-1:0] M_ALEN, output wire [3-1:0] M_ASIZE, output wire [2-1:0] M_ALOCK, output wire [3-1:0] M_APROT, output wire [4-1:0] M_AREGION, output wire [C_AMESG_WIDTH-1:0] M_AMESG, output wire [(C_NUM_M+1)-1:0] M_ATARGET_HOT, output wire [(C_NUM_M_LOG+1)-1:0] M_ATARGET_ENC, output wire [7:0] M_AERROR, output wire M_AVALID_QUAL, output wire M_AVALID, input wire M_AREADY, // Slave Response Channel Interface Ports output wire [C_ID_WIDTH-1:0] S_RID, output wire [C_RMESG_WIDTH-1:0] S_RMESG, output wire S_RLAST, output wire S_RVALID, input wire S_RREADY, // Master Response Channel Interface Ports input wire [(C_NUM_M+1)*C_ID_WIDTH-1:0] M_RID, input wire [(C_NUM_M+1)*C_RMESG_WIDTH-1:0] M_RMESG, input wire [(C_NUM_M+1)-1:0] M_RLAST, input wire [(C_NUM_M+1)-1:0] M_RVALID, output wire [(C_NUM_M+1)-1:0] M_RREADY, input wire [(C_NUM_M+1)-1:0] M_RTARGET, // Does response ID from each MI-slot target this SI slot? input wire [8-1:0] DEBUG_A_TRANS_SEQ ); localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_RMUX_MESG_WIDTH = C_ID_WIDTH + C_RMESG_WIDTH + 1; localparam [31:0] P_AXILITE_ERRMODE = 32'h00000001; localparam integer P_NONSECURE_BIT = 1; localparam integer P_NUM_M_LOG_M1 = C_NUM_M_LOG ? C_NUM_M_LOG : 1; localparam [C_NUM_M-1:0] P_M_AXILITE = f_m_axilite(0); // Mask of AxiLite MI-slots localparam [1:0] P_FIXED = 2'b00; localparam integer P_NUM_M_DE_LOG = f_ceil_log2(C_NUM_M+1); localparam integer P_THREAD_ID_WIDTH_M1 = (C_THREAD_ID_WIDTH > 0) ? C_THREAD_ID_WIDTH : 1; localparam integer P_NUM_ID_VAL = 2**C_THREAD_ID_WIDTH; localparam integer P_NUM_THREADS = (P_NUM_ID_VAL < C_ACCEPTANCE) ? P_NUM_ID_VAL : C_ACCEPTANCE; localparam [C_NUM_M-1:0] P_M_SECURE_MASK = f_bit32to1_mi(C_M_AXI_SECURE); // Mask of secure MI-slots // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2**acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // AxiLite protocol flag vector function [C_NUM_M-1:0] f_m_axilite ( input integer null_arg ); integer mi; begin for (mi=0; mi<C_NUM_M; mi=mi+1) begin f_m_axilite[mi] = (C_ERR_MODE[mi*32+:32] == P_AXILITE_ERRMODE); end end endfunction // Convert Bit32 vector of range [0,1] to Bit1 vector on MI function [C_NUM_M-1:0] f_bit32to1_mi (input [C_NUM_M*32-1:0] vec32); integer mi; begin for (mi=0; mi<C_NUM_M; mi=mi+1) begin f_bit32to1_mi[mi] = vec32[mi*32]; end end endfunction wire [C_NUM_M-1:0] target_mi_hot; wire [P_NUM_M_LOG_M1-1:0] target_mi_enc; wire [(C_NUM_M+1)-1:0] m_atarget_hot_i; wire [(P_NUM_M_DE_LOG)-1:0] m_atarget_enc_i; wire match; wire [3:0] target_region; wire [3:0] m_aregion_i; wire m_avalid_i; wire s_aready_i; wire any_error; wire s_rvalid_i; wire [C_ID_WIDTH-1:0] s_rid_i; wire s_rlast_i; wire [P_RMUX_MESG_WIDTH-1:0] si_rmux_mesg; wire [(C_NUM_M+1)*P_RMUX_MESG_WIDTH-1:0] mi_rmux_mesg; wire [(C_NUM_M+1)-1:0] m_rvalid_qual; wire [(C_NUM_M+1)-1:0] m_rready_arb; wire [(C_NUM_M+1)-1:0] m_rready_i; wire target_secure; wire target_axilite; wire m_avalid_qual_i; wire [7:0] m_aerror_i; genvar gen_mi; genvar gen_thread; generate if (C_ADDR_DECODE) begin : gen_addr_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_M), .C_NUM_TARGETS_LOG (P_NUM_M_LOG_M1), .C_NUM_RANGES (C_NUM_ADDR_RANGES), .C_ADDR_WIDTH (C_ADDR_WIDTH), .C_TARGET_ENC (1), .C_TARGET_HOT (1), .C_REGION_ENC (1), .C_BASE_ADDR (C_BASE_ADDR), .C_HIGH_ADDR (C_HIGH_ADDR), .C_TARGET_QUAL (C_TARGET_QUAL), .C_RESOLUTION (2) ) addr_decoder_inst ( .ADDR (S_AADDR), .TARGET_HOT (target_mi_hot), .TARGET_ENC (target_mi_enc), .MATCH (match), .REGION (target_region) ); end else begin : gen_no_addr_decoder assign target_mi_hot = 1; assign target_mi_enc = 0; assign match = 1'b1; assign target_region = 4'b0000; end endgenerate assign target_secure = |(target_mi_hot & P_M_SECURE_MASK); assign target_axilite = |(target_mi_hot & P_M_AXILITE); assign any_error = C_RANGE_CHECK && (m_aerror_i != 0); // DECERR if error-detection enabled and any error condition. assign m_aerror_i[0] = ~match; // Invalid target address assign m_aerror_i[1] = target_secure && S_APROT[P_NONSECURE_BIT]; // TrustZone violation assign m_aerror_i[2] = target_axilite && ((S_ALEN != 0) || (S_ASIZE[1:0] == 2'b11) || (S_ASIZE[2] == 1'b1)); // AxiLite access violation assign m_aerror_i[7:3] = 5'b00000; // Reserved assign M_ATARGET_HOT = m_atarget_hot_i; assign m_atarget_hot_i = (any_error ? {1'b1, {C_NUM_M{1'b0}}} : {1'b0, target_mi_hot}); assign m_atarget_enc_i = (any_error ? C_NUM_M : target_mi_enc); assign M_AVALID = m_avalid_i; assign m_avalid_i = S_AVALID; assign M_AVALID_QUAL = m_avalid_qual_i; assign S_AREADY = s_aready_i; assign s_aready_i = M_AREADY; assign M_AERROR = m_aerror_i; assign M_ATARGET_ENC = m_atarget_enc_i; assign m_aregion_i = any_error ? 4'b0000 : (C_ADDR_DECODE != 0) ? target_region : 4'b0000; // assign m_aregion_i = any_error ? 4'b0000 : (C_ADDR_DECODE != 0) ? target_region : S_AREGION; assign M_AREGION = m_aregion_i; assign M_AID = S_AID; assign M_AADDR = S_AADDR; assign M_ALEN = S_ALEN; assign M_ASIZE = S_ASIZE; assign M_ALOCK = S_ALOCK; assign M_APROT = S_APROT; assign M_AMESG = S_AMESG; assign S_RVALID = s_rvalid_i; assign M_RREADY = m_rready_i; assign s_rid_i = si_rmux_mesg[0+:C_ID_WIDTH]; assign S_RMESG = si_rmux_mesg[C_ID_WIDTH+:C_RMESG_WIDTH]; assign s_rlast_i = si_rmux_mesg[C_ID_WIDTH+C_RMESG_WIDTH+:1]; assign S_RID = s_rid_i; assign S_RLAST = s_rlast_i; assign m_rvalid_qual = M_RVALID & M_RTARGET; assign m_rready_i = m_rready_arb & M_RTARGET; generate for (gen_mi=0; gen_mi<(C_NUM_M+1); gen_mi=gen_mi+1) begin : gen_rmesg_mi // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign mi_rmux_mesg[gen_mi*P_RMUX_MESG_WIDTH+:P_RMUX_MESG_WIDTH] = { M_RLAST[gen_mi], M_RMESG[gen_mi*C_RMESG_WIDTH+:C_RMESG_WIDTH], M_RID[gen_mi*C_ID_WIDTH+:C_ID_WIDTH] }; end // gen_rmesg_mi if (C_ACCEPTANCE == 1) begin : gen_single_issue wire cmd_push; wire cmd_pop; reg [(C_NUM_M+1)-1:0] active_target_hot; reg [P_NUM_M_DE_LOG-1:0] active_target_enc; reg accept_cnt; reg [8-1:0] debug_r_beat_cnt_i; wire [8-1:0] debug_r_trans_seq_i; assign cmd_push = M_AREADY; assign cmd_pop = s_rvalid_i && S_RREADY && s_rlast_i; // Pop command queue if end of read burst assign m_avalid_qual_i = ~accept_cnt | cmd_pop; // Ready for arbitration if no outstanding transaction or transaction being completed always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 1'b0; active_target_enc <= 0; active_target_hot <= 0; end else begin if (cmd_push) begin active_target_enc <= m_atarget_enc_i; active_target_hot <= m_atarget_hot_i; accept_cnt <= 1'b1; end else if (cmd_pop) begin accept_cnt <= 1'b0; end end end // Clocked process assign m_rready_arb = active_target_hot & {(C_NUM_M+1){S_RREADY}}; assign s_rvalid_i = |(active_target_hot & m_rvalid_qual); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_single_issue ( .S (active_target_enc), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); if (C_DEBUG) begin : gen_debug_r_single_issue // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i && S_RREADY) begin if (s_rlast_i) begin debug_r_beat_cnt_i <= 0; end else begin debug_r_beat_cnt_i <= debug_r_beat_cnt_i + 1; end end end else begin debug_r_beat_cnt_i <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_single_issue ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push), .S_READY (), .M_MESG (debug_r_trans_seq_i), .M_VALID (), .M_READY (cmd_pop) ); end // gen_debug_r end else if (C_SINGLE_THREAD || (P_NUM_ID_VAL==1)) begin : gen_single_thread wire s_avalid_en; wire cmd_push; wire cmd_pop; reg [C_ID_WIDTH-1:0] active_id; reg [(C_NUM_M+1)-1:0] active_target_hot; reg [P_NUM_M_DE_LOG-1:0] active_target_enc; reg [4-1:0] active_region; reg [(C_ACCEPTANCE_LOG+1)-1:0] accept_cnt; reg [8-1:0] debug_r_beat_cnt_i; wire [8-1:0] debug_r_trans_seq_i; wire accept_limit ; // Implement single-region-per-ID cyclic dependency avoidance method. assign s_avalid_en = // This transaction is qualified to request arbitration if ... (accept_cnt == 0) || // Either there are no outstanding transactions, or ... (((P_NUM_ID_VAL==1) || (S_AID[P_THREAD_ID_WIDTH_M1-1:0] == active_id[P_THREAD_ID_WIDTH_M1-1:0])) && // the current transaction ID matches the previous, and ... (active_target_enc == m_atarget_enc_i) && // all outstanding transactions are to the same target MI ... (active_region == m_aregion_i)); // and to the same REGION. assign cmd_push = M_AREADY; assign cmd_pop = s_rvalid_i && S_RREADY && s_rlast_i; // Pop command queue if end of read burst assign accept_limit = (accept_cnt == C_ACCEPTANCE) & ~cmd_pop; // Allow next push if a transaction is currently being completed assign m_avalid_qual_i = s_avalid_en & ~accept_limit; always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 0; active_id <= 0; active_target_enc <= 0; active_target_hot <= 0; active_region <= 0; end else begin if (cmd_push) begin active_id <= S_AID[P_THREAD_ID_WIDTH_M1-1:0]; active_target_enc <= m_atarget_enc_i; active_target_hot <= m_atarget_hot_i; active_region <= m_aregion_i; if (~cmd_pop) begin accept_cnt <= accept_cnt + 1; end end else begin if (cmd_pop & (accept_cnt != 0)) begin accept_cnt <= accept_cnt - 1; end end end end // Clocked process assign m_rready_arb = active_target_hot & {(C_NUM_M+1){S_RREADY}}; assign s_rvalid_i = |(active_target_hot & m_rvalid_qual); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_single_thread ( .S (active_target_enc), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); if (C_DEBUG) begin : gen_debug_r_single_thread // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i && S_RREADY) begin if (s_rlast_i) begin debug_r_beat_cnt_i <= 0; end else begin debug_r_beat_cnt_i <= debug_r_beat_cnt_i + 1; end end end else begin debug_r_beat_cnt_i <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_single_thread ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push), .S_READY (), .M_MESG (debug_r_trans_seq_i), .M_VALID (), .M_READY (cmd_pop) ); end // gen_debug_r end else begin : gen_multi_thread wire [(P_NUM_M_DE_LOG)-1:0] resp_select; reg [(C_ACCEPTANCE_LOG+1)-1:0] accept_cnt; wire [P_NUM_THREADS-1:0] s_avalid_en; wire [P_NUM_THREADS-1:0] thread_valid; wire [P_NUM_THREADS-1:0] aid_match; wire [P_NUM_THREADS-1:0] rid_match; wire [P_NUM_THREADS-1:0] cmd_push; wire [P_NUM_THREADS-1:0] cmd_pop; wire [P_NUM_THREADS:0] accum_push; reg [P_NUM_THREADS*C_ID_WIDTH-1:0] active_id; reg [P_NUM_THREADS*8-1:0] active_target; reg [P_NUM_THREADS*8-1:0] active_region; reg [P_NUM_THREADS*8-1:0] active_cnt; reg [P_NUM_THREADS*8-1:0] debug_r_beat_cnt_i; wire [P_NUM_THREADS*8-1:0] debug_r_trans_seq_i; wire any_aid_match; wire any_rid_match; wire accept_limit; wire any_push; wire any_pop; axi_crossbar_v2_1_arbiter_resp # // Multi-thread response arbiter ( .C_FAMILY (C_FAMILY), .C_NUM_S (C_NUM_M+1), .C_NUM_S_LOG (P_NUM_M_DE_LOG), .C_GRANT_ENC (1), .C_GRANT_HOT (0) ) arbiter_resp_inst ( .ACLK (ACLK), .ARESET (ARESET), .S_VALID (m_rvalid_qual), .S_READY (m_rready_arb), .M_GRANT_HOT (), .M_GRANT_ENC (resp_select), .M_VALID (s_rvalid_i), .M_READY (S_RREADY) ); generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY (C_FAMILY), .C_RATIO (C_NUM_M+1), .C_SEL_WIDTH (P_NUM_M_DE_LOG), .C_DATA_WIDTH (P_RMUX_MESG_WIDTH) ) mux_resp_multi_thread ( .S (resp_select), .A (mi_rmux_mesg), .O (si_rmux_mesg), .OE (1'b1) ); assign any_push = M_AREADY; assign any_pop = s_rvalid_i & S_RREADY & s_rlast_i; assign accept_limit = (accept_cnt == C_ACCEPTANCE) & ~any_pop; // Allow next push if a transaction is currently being completed assign m_avalid_qual_i = (&s_avalid_en) & ~accept_limit; // The current request is qualified for arbitration when it is qualified against all outstanding transaction threads. assign any_aid_match = |aid_match; assign any_rid_match = |rid_match; assign accum_push[0] = 1'b0; always @(posedge ACLK) begin if (ARESET) begin accept_cnt <= 0; end else begin if (any_push & ~any_pop) begin accept_cnt <= accept_cnt + 1; end else if (any_pop & ~any_push & (accept_cnt != 0)) begin accept_cnt <= accept_cnt - 1; end end end // Clocked process for (gen_thread=0; gen_thread<P_NUM_THREADS; gen_thread=gen_thread+1) begin : gen_thread_loop assign thread_valid[gen_thread] = (active_cnt[gen_thread*8 +: C_ACCEPTANCE_LOG+1] != 0); assign aid_match[gen_thread] = // The currect thread is active for the requested transaction if thread_valid[gen_thread] && // this thread slot is not vacant, and ((S_AID[P_THREAD_ID_WIDTH_M1-1:0]) == active_id[gen_thread*C_ID_WIDTH+:P_THREAD_ID_WIDTH_M1]); // the requested ID matches the active ID for this thread. assign s_avalid_en[gen_thread] = // The current request is qualified against this thread slot if (~aid_match[gen_thread]) || // This thread slot is not active for the requested ID, or ((m_atarget_enc_i == active_target[gen_thread*8+:P_NUM_M_DE_LOG]) && // this outstanding transaction was to the same target and (m_aregion_i == active_region[gen_thread*8+:4])); // to the same region. // cmd_push points to the position of either the active thread for the requested ID or the lowest vacant thread slot. assign accum_push[gen_thread+1] = accum_push[gen_thread] | ~thread_valid[gen_thread]; assign cmd_push[gen_thread] = any_push & (aid_match[gen_thread] | ((~any_aid_match) & ~thread_valid[gen_thread] & ~accum_push[gen_thread])); // cmd_pop points to the position of the active thread that matches the current RID. assign rid_match[gen_thread] = thread_valid[gen_thread] & ((s_rid_i[P_THREAD_ID_WIDTH_M1-1:0]) == active_id[gen_thread*C_ID_WIDTH+:P_THREAD_ID_WIDTH_M1]); assign cmd_pop[gen_thread] = any_pop & rid_match[gen_thread]; always @(posedge ACLK) begin if (ARESET) begin active_id[gen_thread*C_ID_WIDTH+:C_ID_WIDTH] <= 0; active_target[gen_thread*8+:8] <= 0; active_region[gen_thread*8+:8] <= 0; active_cnt[gen_thread*8+:8] <= 0; end else begin if (cmd_push[gen_thread]) begin active_id[gen_thread*C_ID_WIDTH+:P_THREAD_ID_WIDTH_M1] <= S_AID[P_THREAD_ID_WIDTH_M1-1:0]; active_target[gen_thread*8+:P_NUM_M_DE_LOG] <= m_atarget_enc_i; active_region[gen_thread*8+:4] <= m_aregion_i; if (~cmd_pop[gen_thread]) begin active_cnt[gen_thread*8+:C_ACCEPTANCE_LOG+1] <= active_cnt[gen_thread*8+:C_ACCEPTANCE_LOG+1] + 1; end end else if (cmd_pop[gen_thread]) begin active_cnt[gen_thread*8+:C_ACCEPTANCE_LOG+1] <= active_cnt[gen_thread*8+:C_ACCEPTANCE_LOG+1] - 1; end end end // Clocked process if (C_DEBUG) begin : gen_debug_r_multi_thread // DEBUG READ BEAT COUNTER (only meaningful for R-channel) always @(posedge ACLK) begin if (ARESET) begin debug_r_beat_cnt_i[gen_thread*8+:8] <= 0; end else if (C_DIR == P_READ) begin if (s_rvalid_i & S_RREADY & rid_match[gen_thread]) begin if (s_rlast_i) begin debug_r_beat_cnt_i[gen_thread*8+:8] <= 0; end else begin debug_r_beat_cnt_i[gen_thread*8+:8] <= debug_r_beat_cnt_i[gen_thread*8+:8] + 1; end end end else begin debug_r_beat_cnt_i[gen_thread*8+:8] <= 0; end end // Clocked process // DEBUG R-CHANNEL TRANSACTION SEQUENCE FIFO axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_ACCEPTANCE_LOG+1), .C_USE_FULL (0) ) debug_r_seq_fifo_multi_thread ( .ACLK (ACLK), .ARESET (ARESET), .S_MESG (DEBUG_A_TRANS_SEQ), .S_VALID (cmd_push[gen_thread]), .S_READY (), .M_MESG (debug_r_trans_seq_i[gen_thread*8+:8]), .M_VALID (), .M_READY (cmd_pop[gen_thread]) ); end // gen_debug_r_multi_thread end // Next gen_thread_loop end // thread control endgenerate endmodule

module processing_system7_bfm_v2_0_5_interconnect_model ( rstn, sw_clk, w_qos_gp0, w_qos_gp1, w_qos_hp0, w_qos_hp1, w_qos_hp2, w_qos_hp3, r_qos_gp0, r_qos_gp1, r_qos_hp0, r_qos_hp1, r_qos_hp2, r_qos_hp3, wr_ack_ddr_gp0, wr_ack_ocm_gp0, wr_data_gp0, wr_addr_gp0, wr_bytes_gp0, wr_dv_ddr_gp0, wr_dv_ocm_gp0, rd_req_ddr_gp0, rd_req_ocm_gp0, rd_req_reg_gp0, rd_addr_gp0, rd_bytes_gp0, rd_data_ddr_gp0, rd_data_ocm_gp0, rd_data_reg_gp0, rd_dv_ddr_gp0, rd_dv_ocm_gp0, rd_dv_reg_gp0, wr_ack_ddr_gp1, wr_ack_ocm_gp1, wr_data_gp1, wr_addr_gp1, wr_bytes_gp1, wr_dv_ddr_gp1, wr_dv_ocm_gp1, rd_req_ddr_gp1, rd_req_ocm_gp1, rd_req_reg_gp1, rd_addr_gp1, rd_bytes_gp1, rd_data_ddr_gp1, rd_data_ocm_gp1, rd_data_reg_gp1, rd_dv_ddr_gp1, rd_dv_ocm_gp1, rd_dv_reg_gp1, wr_ack_ddr_hp0, wr_ack_ocm_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, wr_dv_ocm_hp0, rd_req_ddr_hp0, rd_req_ocm_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_data_ocm_hp0, rd_dv_ddr_hp0, rd_dv_ocm_hp0, wr_ack_ddr_hp1, wr_ack_ocm_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, wr_dv_ocm_hp1, rd_req_ddr_hp1, rd_req_ocm_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_data_ocm_hp1, rd_dv_ddr_hp1, rd_dv_ocm_hp1, wr_ack_ddr_hp2, wr_ack_ocm_hp2, wr_data_hp2, wr_addr_hp2, wr_bytes_hp2, wr_dv_ddr_hp2, wr_dv_ocm_hp2, rd_req_ddr_hp2, rd_req_ocm_hp2, rd_addr_hp2, rd_bytes_hp2, rd_data_ddr_hp2, rd_data_ocm_hp2, rd_dv_ddr_hp2, rd_dv_ocm_hp2, wr_ack_ddr_hp3, wr_ack_ocm_hp3, wr_data_hp3, wr_addr_hp3, wr_bytes_hp3, wr_dv_ddr_hp3, wr_dv_ocm_hp3, rd_req_ddr_hp3, rd_req_ocm_hp3, rd_addr_hp3, rd_bytes_hp3, rd_data_ddr_hp3, rd_data_ocm_hp3, rd_dv_ddr_hp3, rd_dv_ocm_hp3, /* Goes to port 1 of DDR */ ddr_wr_ack_port1, ddr_wr_dv_port1, ddr_rd_req_port1, ddr_rd_dv_port1, ddr_wr_addr_port1, ddr_wr_data_port1, ddr_wr_bytes_port1, ddr_rd_addr_port1, ddr_rd_data_port1, ddr_rd_bytes_port1, ddr_wr_qos_port1, ddr_rd_qos_port1, /* Goes to port2 of DDR */ ddr_wr_ack_port2, ddr_wr_dv_port2, ddr_rd_req_port2, ddr_rd_dv_port2, ddr_wr_addr_port2, ddr_wr_data_port2, ddr_wr_bytes_port2, ddr_rd_addr_port2, ddr_rd_data_port2, ddr_rd_bytes_port2, ddr_wr_qos_port2, ddr_rd_qos_port2, /* Goes to port3 of DDR */ ddr_wr_ack_port3, ddr_wr_dv_port3, ddr_rd_req_port3, ddr_rd_dv_port3, ddr_wr_addr_port3, ddr_wr_data_port3, ddr_wr_bytes_port3, ddr_rd_addr_port3, ddr_rd_data_port3, ddr_rd_bytes_port3, ddr_wr_qos_port3, ddr_rd_qos_port3, /* Goes to port1 of OCM */ ocm_wr_qos_port1, ocm_rd_qos_port1, ocm_wr_dv_port1, ocm_wr_data_port1, ocm_wr_addr_port1, ocm_wr_bytes_port1, ocm_wr_ack_port1, ocm_rd_req_port1, ocm_rd_data_port1, ocm_rd_addr_port1, ocm_rd_bytes_port1, ocm_rd_dv_port1, /* Goes to port1 for RegMap */ reg_rd_qos_port1, reg_rd_req_port1, reg_rd_data_port1, reg_rd_addr_port1, reg_rd_bytes_port1, reg_rd_dv_port1 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; input [axi_qos_width-1:0] w_qos_gp0; input [axi_qos_width-1:0] w_qos_gp1; input [axi_qos_width-1:0] w_qos_hp0; input [axi_qos_width-1:0] w_qos_hp1; input [axi_qos_width-1:0] w_qos_hp2; input [axi_qos_width-1:0] w_qos_hp3; input [axi_qos_width-1:0] r_qos_gp0; input [axi_qos_width-1:0] r_qos_gp1; input [axi_qos_width-1:0] r_qos_hp0; input [axi_qos_width-1:0] r_qos_hp1; input [axi_qos_width-1:0] r_qos_hp2; input [axi_qos_width-1:0] r_qos_hp3; output [axi_qos_width-1:0] ocm_wr_qos_port1; output [axi_qos_width-1:0] ocm_rd_qos_port1; output wr_ack_ddr_gp0; output wr_ack_ocm_gp0; input[max_burst_bits-1:0] wr_data_gp0; input[addr_width-1:0] wr_addr_gp0; input[max_burst_bytes_width:0] wr_bytes_gp0; input wr_dv_ddr_gp0; input wr_dv_ocm_gp0; input rd_req_ddr_gp0; input rd_req_ocm_gp0; input rd_req_reg_gp0; input[addr_width-1:0] rd_addr_gp0; input[max_burst_bytes_width:0] rd_bytes_gp0; output[max_burst_bits-1:0] rd_data_ddr_gp0; output[max_burst_bits-1:0] rd_data_ocm_gp0; output[max_burst_bits-1:0] rd_data_reg_gp0; output rd_dv_ddr_gp0; output rd_dv_ocm_gp0; output rd_dv_reg_gp0; output wr_ack_ddr_gp1; output wr_ack_ocm_gp1; input[max_burst_bits-1:0] wr_data_gp1; input[addr_width-1:0] wr_addr_gp1; input[max_burst_bytes_width:0] wr_bytes_gp1; input wr_dv_ddr_gp1; input wr_dv_ocm_gp1; input rd_req_ddr_gp1; input rd_req_ocm_gp1; input rd_req_reg_gp1; input[addr_width-1:0] rd_addr_gp1; input[max_burst_bytes_width:0] rd_bytes_gp1; output[max_burst_bits-1:0] rd_data_ddr_gp1; output[max_burst_bits-1:0] rd_data_ocm_gp1; output[max_burst_bits-1:0] rd_data_reg_gp1; output rd_dv_ddr_gp1; output rd_dv_ocm_gp1; output rd_dv_reg_gp1; output wr_ack_ddr_hp0; output wr_ack_ocm_hp0; input[max_burst_bits-1:0] wr_data_hp0; input[addr_width-1:0] wr_addr_hp0; input[max_burst_bytes_width:0] wr_bytes_hp0; input wr_dv_ddr_hp0; input wr_dv_ocm_hp0; input rd_req_ddr_hp0; input rd_req_ocm_hp0; input[addr_width-1:0] rd_addr_hp0; input[max_burst_bytes_width:0] rd_bytes_hp0; output[max_burst_bits-1:0] rd_data_ddr_hp0; output[max_burst_bits-1:0] rd_data_ocm_hp0; output rd_dv_ddr_hp0; output rd_dv_ocm_hp0; output wr_ack_ddr_hp1; output wr_ack_ocm_hp1; input[max_burst_bits-1:0] wr_data_hp1; input[addr_width-1:0] wr_addr_hp1; input[max_burst_bytes_width:0] wr_bytes_hp1; input wr_dv_ddr_hp1; input wr_dv_ocm_hp1; input rd_req_ddr_hp1; input rd_req_ocm_hp1; input[addr_width-1:0] rd_addr_hp1; input[max_burst_bytes_width:0] rd_bytes_hp1; output[max_burst_bits-1:0] rd_data_ddr_hp1; output[max_burst_bits-1:0] rd_data_ocm_hp1; output rd_dv_ddr_hp1; output rd_dv_ocm_hp1; output wr_ack_ddr_hp2; output wr_ack_ocm_hp2; input[max_burst_bits-1:0] wr_data_hp2; input[addr_width-1:0] wr_addr_hp2; input[max_burst_bytes_width:0] wr_bytes_hp2; input wr_dv_ddr_hp2; input wr_dv_ocm_hp2; input rd_req_ddr_hp2; input rd_req_ocm_hp2; input[addr_width-1:0] rd_addr_hp2; input[max_burst_bytes_width:0] rd_bytes_hp2; output[max_burst_bits-1:0] rd_data_ddr_hp2; output[max_burst_bits-1:0] rd_data_ocm_hp2; output rd_dv_ddr_hp2; output rd_dv_ocm_hp2; output wr_ack_ddr_hp3; output wr_ack_ocm_hp3; input[max_burst_bits-1:0] wr_data_hp3; input[addr_width-1:0] wr_addr_hp3; input[max_burst_bytes_width:0] wr_bytes_hp3; input wr_dv_ddr_hp3; input wr_dv_ocm_hp3; input rd_req_ddr_hp3; input rd_req_ocm_hp3; input[addr_width-1:0] rd_addr_hp3; input[max_burst_bytes_width:0] rd_bytes_hp3; output[max_burst_bits-1:0] rd_data_ddr_hp3; output[max_burst_bits-1:0] rd_data_ocm_hp3; output rd_dv_ddr_hp3; output rd_dv_ocm_hp3; /* Goes to port 1 of DDR */ input ddr_wr_ack_port1; output ddr_wr_dv_port1; output ddr_rd_req_port1; input ddr_rd_dv_port1; output[addr_width-1:0] ddr_wr_addr_port1; output[max_burst_bits-1:0] ddr_wr_data_port1; output[max_burst_bytes_width:0] ddr_wr_bytes_port1; output[addr_width-1:0] ddr_rd_addr_port1; input[max_burst_bits-1:0] ddr_rd_data_port1; output[max_burst_bytes_width:0] ddr_rd_bytes_port1; output [axi_qos_width-1:0] ddr_wr_qos_port1; output [axi_qos_width-1:0] ddr_rd_qos_port1; /* Goes to port2 of DDR */ input ddr_wr_ack_port2; output ddr_wr_dv_port2; output ddr_rd_req_port2; input ddr_rd_dv_port2; output[addr_width-1:0] ddr_wr_addr_port2; output[max_burst_bits-1:0] ddr_wr_data_port2; output[max_burst_bytes_width:0] ddr_wr_bytes_port2; output[addr_width-1:0] ddr_rd_addr_port2; input[max_burst_bits-1:0] ddr_rd_data_port2; output[max_burst_bytes_width:0] ddr_rd_bytes_port2; output [axi_qos_width-1:0] ddr_wr_qos_port2; output [axi_qos_width-1:0] ddr_rd_qos_port2; /* Goes to port3 of DDR */ input ddr_wr_ack_port3; output ddr_wr_dv_port3; output ddr_rd_req_port3; input ddr_rd_dv_port3; output[addr_width-1:0] ddr_wr_addr_port3; output[max_burst_bits-1:0] ddr_wr_data_port3; output[max_burst_bytes_width:0] ddr_wr_bytes_port3; output[addr_width-1:0] ddr_rd_addr_port3; input[max_burst_bits-1:0] ddr_rd_data_port3; output[max_burst_bytes_width:0] ddr_rd_bytes_port3; output [axi_qos_width-1:0] ddr_wr_qos_port3; output [axi_qos_width-1:0] ddr_rd_qos_port3; /* Goes to port1 of OCM */ input ocm_wr_ack_port1; output ocm_wr_dv_port1; output ocm_rd_req_port1; input ocm_rd_dv_port1; output[max_burst_bits-1:0] ocm_wr_data_port1; output[addr_width-1:0] ocm_wr_addr_port1; output[max_burst_bytes_width:0] ocm_wr_bytes_port1; input[max_burst_bits-1:0] ocm_rd_data_port1; output[addr_width-1:0] ocm_rd_addr_port1; output[max_burst_bytes_width:0] ocm_rd_bytes_port1; /* Goes to port1 of REG */ output [axi_qos_width-1:0] reg_rd_qos_port1; output reg_rd_req_port1; input reg_rd_dv_port1; input[max_burst_bits-1:0] reg_rd_data_port1; output[addr_width-1:0] reg_rd_addr_port1; output[max_burst_bytes_width:0] reg_rd_bytes_port1; wire ocm_wr_dv_osw0; wire ocm_wr_dv_osw1; wire[max_burst_bits-1:0] ocm_wr_data_osw0; wire[max_burst_bits-1:0] ocm_wr_data_osw1; wire[addr_width-1:0] ocm_wr_addr_osw0; wire[addr_width-1:0] ocm_wr_addr_osw1; wire[max_burst_bytes_width:0] ocm_wr_bytes_osw0; wire[max_burst_bytes_width:0] ocm_wr_bytes_osw1; wire ocm_wr_ack_osw0; wire ocm_wr_ack_osw1; wire ocm_rd_req_osw0; wire ocm_rd_req_osw1; wire[max_burst_bits-1:0] ocm_rd_data_osw0; wire[max_burst_bits-1:0] ocm_rd_data_osw1; wire[addr_width-1:0] ocm_rd_addr_osw0; wire[addr_width-1:0] ocm_rd_addr_osw1; wire[max_burst_bytes_width:0] ocm_rd_bytes_osw0; wire[max_burst_bytes_width:0] ocm_rd_bytes_osw1; wire ocm_rd_dv_osw0; wire ocm_rd_dv_osw1; wire [axi_qos_width-1:0] ocm_wr_qos_osw0; wire [axi_qos_width-1:0] ocm_wr_qos_osw1; wire [axi_qos_width-1:0] ocm_rd_qos_osw0; wire [axi_qos_width-1:0] ocm_rd_qos_osw1; processing_system7_bfm_v2_0_5_fmsw_gp fmsw ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_gp0(w_qos_gp0), .r_qos_gp0(r_qos_gp0), .wr_ack_ocm_gp0(wr_ack_ocm_gp0), .wr_ack_ddr_gp0(wr_ack_ddr_gp0), .wr_data_gp0(wr_data_gp0), .wr_addr_gp0(wr_addr_gp0), .wr_bytes_gp0(wr_bytes_gp0), .wr_dv_ocm_gp0(wr_dv_ocm_gp0), .wr_dv_ddr_gp0(wr_dv_ddr_gp0), .rd_req_ocm_gp0(rd_req_ocm_gp0), .rd_req_ddr_gp0(rd_req_ddr_gp0), .rd_req_reg_gp0(rd_req_reg_gp0), .rd_addr_gp0(rd_addr_gp0), .rd_bytes_gp0(rd_bytes_gp0), .rd_data_ddr_gp0(rd_data_ddr_gp0), .rd_data_ocm_gp0(rd_data_ocm_gp0), .rd_data_reg_gp0(rd_data_reg_gp0), .rd_dv_ocm_gp0(rd_dv_ocm_gp0), .rd_dv_ddr_gp0(rd_dv_ddr_gp0), .rd_dv_reg_gp0(rd_dv_reg_gp0), .w_qos_gp1(w_qos_gp1), .r_qos_gp1(r_qos_gp1), .wr_ack_ocm_gp1(wr_ack_ocm_gp1), .wr_ack_ddr_gp1(wr_ack_ddr_gp1), .wr_data_gp1(wr_data_gp1), .wr_addr_gp1(wr_addr_gp1), .wr_bytes_gp1(wr_bytes_gp1), .wr_dv_ocm_gp1(wr_dv_ocm_gp1), .wr_dv_ddr_gp1(wr_dv_ddr_gp1), .rd_req_ocm_gp1(rd_req_ocm_gp1), .rd_req_ddr_gp1(rd_req_ddr_gp1), .rd_req_reg_gp1(rd_req_reg_gp1), .rd_addr_gp1(rd_addr_gp1), .rd_bytes_gp1(rd_bytes_gp1), .rd_data_ddr_gp1(rd_data_ddr_gp1), .rd_data_ocm_gp1(rd_data_ocm_gp1), .rd_data_reg_gp1(rd_data_reg_gp1), .rd_dv_ocm_gp1(rd_dv_ocm_gp1), .rd_dv_ddr_gp1(rd_dv_ddr_gp1), .rd_dv_reg_gp1(rd_dv_reg_gp1), .ocm_wr_ack (ocm_wr_ack_osw0), .ocm_wr_dv (ocm_wr_dv_osw0), .ocm_rd_req (ocm_rd_req_osw0), .ocm_rd_dv (ocm_rd_dv_osw0), .ocm_wr_addr(ocm_wr_addr_osw0), .ocm_wr_data(ocm_wr_data_osw0), .ocm_wr_bytes(ocm_wr_bytes_osw0), .ocm_rd_addr(ocm_rd_addr_osw0), .ocm_rd_data(ocm_rd_data_osw0), .ocm_rd_bytes(ocm_rd_bytes_osw0), .ocm_wr_qos(ocm_wr_qos_osw0), .ocm_rd_qos(ocm_rd_qos_osw0), .ddr_wr_qos(ddr_wr_qos_port1), .ddr_rd_qos(ddr_rd_qos_port1), .reg_rd_qos(reg_rd_qos_port1), .ddr_wr_ack(ddr_wr_ack_port1), .ddr_wr_dv(ddr_wr_dv_port1), .ddr_rd_req(ddr_rd_req_port1), .ddr_rd_dv(ddr_rd_dv_port1), .ddr_wr_addr(ddr_wr_addr_port1), .ddr_wr_data(ddr_wr_data_port1), .ddr_wr_bytes(ddr_wr_bytes_port1), .ddr_rd_addr(ddr_rd_addr_port1), .ddr_rd_data(ddr_rd_data_port1), .ddr_rd_bytes(ddr_rd_bytes_port1), .reg_rd_req(reg_rd_req_port1), .reg_rd_dv(reg_rd_dv_port1), .reg_rd_addr(reg_rd_addr_port1), .reg_rd_data(reg_rd_data_port1), .reg_rd_bytes(reg_rd_bytes_port1) ); processing_system7_bfm_v2_0_5_ssw_hp ssw( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp0(w_qos_hp0), .r_qos_hp0(r_qos_hp0), .w_qos_hp1(w_qos_hp1), .r_qos_hp1(r_qos_hp1), .w_qos_hp2(w_qos_hp2), .r_qos_hp2(r_qos_hp2), .w_qos_hp3(w_qos_hp3), .r_qos_hp3(r_qos_hp3), .wr_ack_ddr_hp0(wr_ack_ddr_hp0), .wr_data_hp0(wr_data_hp0), .wr_addr_hp0(wr_addr_hp0), .wr_bytes_hp0(wr_bytes_hp0), .wr_dv_ddr_hp0(wr_dv_ddr_hp0), .rd_req_ddr_hp0(rd_req_ddr_hp0), .rd_addr_hp0(rd_addr_hp0), .rd_bytes_hp0(rd_bytes_hp0), .rd_data_ddr_hp0(rd_data_ddr_hp0), .rd_data_ocm_hp0(rd_data_ocm_hp0), .rd_dv_ddr_hp0(rd_dv_ddr_hp0), .wr_ack_ocm_hp0(wr_ack_ocm_hp0), .wr_dv_ocm_hp0(wr_dv_ocm_hp0), .rd_req_ocm_hp0(rd_req_ocm_hp0), .rd_dv_ocm_hp0(rd_dv_ocm_hp0), .wr_ack_ddr_hp1(wr_ack_ddr_hp1), .wr_data_hp1(wr_data_hp1), .wr_addr_hp1(wr_addr_hp1), .wr_bytes_hp1(wr_bytes_hp1), .wr_dv_ddr_hp1(wr_dv_ddr_hp1), .rd_req_ddr_hp1(rd_req_ddr_hp1), .rd_addr_hp1(rd_addr_hp1), .rd_bytes_hp1(rd_bytes_hp1), .rd_data_ddr_hp1(rd_data_ddr_hp1), .rd_data_ocm_hp1(rd_data_ocm_hp1), .rd_dv_ddr_hp1(rd_dv_ddr_hp1), .wr_ack_ocm_hp1(wr_ack_ocm_hp1), .wr_dv_ocm_hp1(wr_dv_ocm_hp1), .rd_req_ocm_hp1(rd_req_ocm_hp1), .rd_dv_ocm_hp1(rd_dv_ocm_hp1), .wr_ack_ddr_hp2(wr_ack_ddr_hp2), .wr_data_hp2(wr_data_hp2), .wr_addr_hp2(wr_addr_hp2), .wr_bytes_hp2(wr_bytes_hp2), .wr_dv_ddr_hp2(wr_dv_ddr_hp2), .rd_req_ddr_hp2(rd_req_ddr_hp2), .rd_addr_hp2(rd_addr_hp2), .rd_bytes_hp2(rd_bytes_hp2), .rd_data_ddr_hp2(rd_data_ddr_hp2), .rd_data_ocm_hp2(rd_data_ocm_hp2), .rd_dv_ddr_hp2(rd_dv_ddr_hp2), .wr_ack_ocm_hp2(wr_ack_ocm_hp2), .wr_dv_ocm_hp2(wr_dv_ocm_hp2), .rd_req_ocm_hp2(rd_req_ocm_hp2), .rd_dv_ocm_hp2(rd_dv_ocm_hp2), .wr_ack_ddr_hp3(wr_ack_ddr_hp3), .wr_data_hp3(wr_data_hp3), .wr_addr_hp3(wr_addr_hp3), .wr_bytes_hp3(wr_bytes_hp3), .wr_dv_ddr_hp3(wr_dv_ddr_hp3), .rd_req_ddr_hp3(rd_req_ddr_hp3), .rd_addr_hp3(rd_addr_hp3), .rd_bytes_hp3(rd_bytes_hp3), .rd_data_ddr_hp3(rd_data_ddr_hp3), .rd_data_ocm_hp3(rd_data_ocm_hp3), .rd_dv_ddr_hp3(rd_dv_ddr_hp3), .wr_ack_ocm_hp3(wr_ack_ocm_hp3), .wr_dv_ocm_hp3(wr_dv_ocm_hp3), .rd_req_ocm_hp3(rd_req_ocm_hp3), .rd_dv_ocm_hp3(rd_dv_ocm_hp3), .ddr_wr_ack0(ddr_wr_ack_port2), .ddr_wr_dv0(ddr_wr_dv_port2), .ddr_rd_req0(ddr_rd_req_port2), .ddr_rd_dv0(ddr_rd_dv_port2), .ddr_wr_addr0(ddr_wr_addr_port2), .ddr_wr_data0(ddr_wr_data_port2), .ddr_wr_bytes0(ddr_wr_bytes_port2), .ddr_rd_addr0(ddr_rd_addr_port2), .ddr_rd_data0(ddr_rd_data_port2), .ddr_rd_bytes0(ddr_rd_bytes_port2), .ddr_wr_qos0(ddr_wr_qos_port2), .ddr_rd_qos0(ddr_rd_qos_port2), .ddr_wr_ack1(ddr_wr_ack_port3), .ddr_wr_dv1(ddr_wr_dv_port3), .ddr_rd_req1(ddr_rd_req_port3), .ddr_rd_dv1(ddr_rd_dv_port3), .ddr_wr_addr1(ddr_wr_addr_port3), .ddr_wr_data1(ddr_wr_data_port3), .ddr_wr_bytes1(ddr_wr_bytes_port3), .ddr_rd_addr1(ddr_rd_addr_port3), .ddr_rd_data1(ddr_rd_data_port3), .ddr_rd_bytes1(ddr_rd_bytes_port3), .ddr_wr_qos1(ddr_wr_qos_port3), .ddr_rd_qos1(ddr_rd_qos_port3), .ocm_wr_qos(ocm_wr_qos_osw1), .ocm_rd_qos(ocm_rd_qos_osw1), .ocm_wr_ack (ocm_wr_ack_osw1), .ocm_wr_dv (ocm_wr_dv_osw1), .ocm_rd_req (ocm_rd_req_osw1), .ocm_rd_dv (ocm_rd_dv_osw1), .ocm_wr_addr(ocm_wr_addr_osw1), .ocm_wr_data(ocm_wr_data_osw1), .ocm_wr_bytes(ocm_wr_bytes_osw1), .ocm_rd_addr(ocm_rd_addr_osw1), .ocm_rd_data(ocm_rd_data_osw1), .ocm_rd_bytes(ocm_rd_bytes_osw1) ); processing_system7_bfm_v2_0_5_arb_wr osw_wr ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_wr_qos_osw0), /// chk .qos2(ocm_wr_qos_osw1), /// chk .prt_dv1(ocm_wr_dv_osw0), .prt_dv2(ocm_wr_dv_osw1), .prt_data1(ocm_wr_data_osw0), .prt_data2(ocm_wr_data_osw1), .prt_addr1(ocm_wr_addr_osw0), .prt_addr2(ocm_wr_addr_osw1), .prt_bytes1(ocm_wr_bytes_osw0), .prt_bytes2(ocm_wr_bytes_osw1), .prt_ack1(ocm_wr_ack_osw0), .prt_ack2(ocm_wr_ack_osw1), .prt_req(ocm_wr_dv_port1), .prt_qos(ocm_wr_qos_port1), .prt_data(ocm_wr_data_port1), .prt_addr(ocm_wr_addr_port1), .prt_bytes(ocm_wr_bytes_port1), .prt_ack(ocm_wr_ack_port1) ); processing_system7_bfm_v2_0_5_arb_rd osw_rd( .rstn(rstn), .sw_clk(sw_clk), .qos1(ocm_rd_qos_osw0), // chk .qos2(ocm_rd_qos_osw1), // chk .prt_req1(ocm_rd_req_osw0), .prt_req2(ocm_rd_req_osw1), .prt_data1(ocm_rd_data_osw0), .prt_data2(ocm_rd_data_osw1), .prt_addr1(ocm_rd_addr_osw0), .prt_addr2(ocm_rd_addr_osw1), .prt_bytes1(ocm_rd_bytes_osw0), .prt_bytes2(ocm_rd_bytes_osw1), .prt_dv1(ocm_rd_dv_osw0), .prt_dv2(ocm_rd_dv_osw1), .prt_req(ocm_rd_req_port1), .prt_qos(ocm_rd_qos_port1), .prt_data(ocm_rd_data_port1), .prt_addr(ocm_rd_addr_port1), .prt_bytes(ocm_rd_bytes_port1), .prt_dv(ocm_rd_dv_port1) ); endmodule

module processing_system7_bfm_v2_0_5_arb_wr_4( rstn, sw_clk, qos1, qos2, qos3, qos4, prt_dv1, prt_dv2, prt_dv3, prt_dv4, prt_data1, prt_data2, prt_data3, prt_data4, prt_addr1, prt_addr2, prt_addr3, prt_addr4, prt_bytes1, prt_bytes2, prt_bytes3, prt_bytes4, prt_ack1, prt_ack2, prt_ack3, prt_ack4, prt_qos, prt_req, prt_data, prt_addr, prt_bytes, prt_ack ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2,qos3,qos4; input [max_burst_bits-1:0] prt_data1,prt_data2,prt_data3,prt_data4; input [addr_width-1:0] prt_addr1,prt_addr2,prt_addr3,prt_addr4; input [max_burst_bytes_width:0] prt_bytes1,prt_bytes2,prt_bytes3,prt_bytes4; input prt_dv1, prt_dv2,prt_dv3, prt_dv4, prt_ack; output reg prt_ack1,prt_ack2,prt_ack3,prt_ack4,prt_req; output reg [max_burst_bits-1:0] prt_data; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; output reg [axi_qos_width-1:0] prt_qos; parameter wait_req = 3'b000, serv_req1 = 3'b001, serv_req2 = 3'b010, serv_req3 = 3'b011, serv_req4 = 4'b100,wait_ack_low = 3'b101; reg [2:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; prt_req = 0; if(prt_dv1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_dv2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_dv4) begin prt_req = 1; prt_qos = qos4; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; state = serv_req4; end end serv_req1:begin state = serv_req1; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; if(prt_ack)begin prt_ack1 = 1'b1; //state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv2) begin state = serv_req2; prt_qos = qos2; prt_req = 1; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_dv4) begin prt_req = 1; prt_qos = qos4; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; state = serv_req4; end end end serv_req2:begin state = serv_req2; prt_ack1 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; if(prt_ack)begin prt_ack2 = 1'b1; //state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv3) begin state = serv_req3; prt_qos = qos3; prt_req = 1; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_dv4) begin state = serv_req4; prt_req = 1; prt_qos = qos4; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_dv1) begin prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req3:begin state = serv_req3; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack4 = 1'b0; if(prt_ack)begin prt_ack3 = 1'b1; // state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv4) begin state = serv_req4; prt_qos = qos4; prt_req = 1; prt_data = prt_data4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_dv1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_dv2) begin prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end end end serv_req4:begin state = serv_req4; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; if(prt_ack)begin prt_ack4 = 1'b1; //state = wait_req; state = wait_ack_low; prt_req = 0; if(prt_dv1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_dv2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv3) begin prt_req = 1; prt_qos = qos3; prt_data = prt_data3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; state = serv_req3; end end end wait_ack_low:begin state = wait_ack_low; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_ack3 = 1'b0; prt_ack4 = 1'b0; if(!prt_ack) state = wait_req; end endcase end /// if else end /// always endmodule

module processing_system7_bfm_v2_0_5_gen_reset( por_rst_n, sys_rst_n, rst_out_n, m_axi_gp0_clk, m_axi_gp1_clk, s_axi_gp0_clk, s_axi_gp1_clk, s_axi_hp0_clk, s_axi_hp1_clk, s_axi_hp2_clk, s_axi_hp3_clk, s_axi_acp_clk, m_axi_gp0_rstn, m_axi_gp1_rstn, s_axi_gp0_rstn, s_axi_gp1_rstn, s_axi_hp0_rstn, s_axi_hp1_rstn, s_axi_hp2_rstn, s_axi_hp3_rstn, s_axi_acp_rstn, fclk_reset3_n, fclk_reset2_n, fclk_reset1_n, fclk_reset0_n, fpga_acp_reset_n, fpga_gp_m0_reset_n, fpga_gp_m1_reset_n, fpga_gp_s0_reset_n, fpga_gp_s1_reset_n, fpga_hp_s0_reset_n, fpga_hp_s1_reset_n, fpga_hp_s2_reset_n, fpga_hp_s3_reset_n ); input por_rst_n; input sys_rst_n; input m_axi_gp0_clk; input m_axi_gp1_clk; input s_axi_gp0_clk; input s_axi_gp1_clk; input s_axi_hp0_clk; input s_axi_hp1_clk; input s_axi_hp2_clk; input s_axi_hp3_clk; input s_axi_acp_clk; output reg m_axi_gp0_rstn; output reg m_axi_gp1_rstn; output reg s_axi_gp0_rstn; output reg s_axi_gp1_rstn; output reg s_axi_hp0_rstn; output reg s_axi_hp1_rstn; output reg s_axi_hp2_rstn; output reg s_axi_hp3_rstn; output reg s_axi_acp_rstn; output rst_out_n; output fclk_reset3_n; output fclk_reset2_n; output fclk_reset1_n; output fclk_reset0_n; output fpga_acp_reset_n; output fpga_gp_m0_reset_n; output fpga_gp_m1_reset_n; output fpga_gp_s0_reset_n; output fpga_gp_s1_reset_n; output fpga_hp_s0_reset_n; output fpga_hp_s1_reset_n; output fpga_hp_s2_reset_n; output fpga_hp_s3_reset_n; reg [31:0] fabric_rst_n; reg r_m_axi_gp0_rstn; reg r_m_axi_gp1_rstn; reg r_s_axi_gp0_rstn; reg r_s_axi_gp1_rstn; reg r_s_axi_hp0_rstn; reg r_s_axi_hp1_rstn; reg r_s_axi_hp2_rstn; reg r_s_axi_hp3_rstn; reg r_s_axi_acp_rstn; assign rst_out_n = por_rst_n & sys_rst_n; assign fclk_reset0_n = !fabric_rst_n[0]; assign fclk_reset1_n = !fabric_rst_n[1]; assign fclk_reset2_n = !fabric_rst_n[2]; assign fclk_reset3_n = !fabric_rst_n[3]; assign fpga_acp_reset_n = !fabric_rst_n[24]; assign fpga_hp_s3_reset_n = !fabric_rst_n[23]; assign fpga_hp_s2_reset_n = !fabric_rst_n[22]; assign fpga_hp_s1_reset_n = !fabric_rst_n[21]; assign fpga_hp_s0_reset_n = !fabric_rst_n[20]; assign fpga_gp_s1_reset_n = !fabric_rst_n[17]; assign fpga_gp_s0_reset_n = !fabric_rst_n[16]; assign fpga_gp_m1_reset_n = !fabric_rst_n[13]; assign fpga_gp_m0_reset_n = !fabric_rst_n[12]; task fpga_soft_reset; input[31:0] reset_ctrl; begin fabric_rst_n[0] = reset_ctrl[0]; fabric_rst_n[1] = reset_ctrl[1]; fabric_rst_n[2] = reset_ctrl[2]; fabric_rst_n[3] = reset_ctrl[3]; fabric_rst_n[12] = reset_ctrl[12]; fabric_rst_n[13] = reset_ctrl[13]; fabric_rst_n[16] = reset_ctrl[16]; fabric_rst_n[17] = reset_ctrl[17]; fabric_rst_n[20] = reset_ctrl[20]; fabric_rst_n[21] = reset_ctrl[21]; fabric_rst_n[22] = reset_ctrl[22]; fabric_rst_n[23] = reset_ctrl[23]; fabric_rst_n[24] = reset_ctrl[24]; end endtask always@(negedge por_rst_n or negedge sys_rst_n) fabric_rst_n = 32'h01f3_300f; always@(posedge m_axi_gp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) m_axi_gp0_rstn = 1'b0; else m_axi_gp0_rstn = 1'b1; end always@(posedge m_axi_gp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) m_axi_gp1_rstn = 1'b0; else m_axi_gp1_rstn = 1'b1; end always@(posedge s_axi_gp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_gp0_rstn = 1'b0; else s_axi_gp0_rstn = 1'b1; end always@(posedge s_axi_gp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_gp1_rstn = 1'b0; else s_axi_gp1_rstn = 1'b1; end always@(posedge s_axi_hp0_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp0_rstn = 1'b0; else s_axi_hp0_rstn = 1'b1; end always@(posedge s_axi_hp1_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp1_rstn = 1'b0; else s_axi_hp1_rstn = 1'b1; end always@(posedge s_axi_hp2_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp2_rstn = 1'b0; else s_axi_hp2_rstn = 1'b1; end always@(posedge s_axi_hp3_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_hp3_rstn = 1'b0; else s_axi_hp3_rstn = 1'b1; end always@(posedge s_axi_acp_clk or negedge (por_rst_n & sys_rst_n)) begin if (!(por_rst_n & sys_rst_n)) s_axi_acp_rstn = 1'b0; else s_axi_acp_rstn = 1'b1; end always@(*) begin if ((por_rst_n!= 1'b0) && (por_rst_n!= 1'b1) && (sys_rst_n != 1'b0) && (sys_rst_n != 1'b1)) begin $display(" Error:processing_system7_bfm_v2_0_5_gen_reset. PS_PORB and PS_SRSTB must be driven to known state"); $finish(); end end endmodule

module axi_crossbar_v2_1_addr_arbiter_sasd # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 1, parameter integer C_NUM_S_LOG = 1, parameter integer C_AMESG_WIDTH = 1, parameter C_GRANT_ENC = 0, parameter [C_NUM_S*32-1:0] C_ARB_PRIORITY = {C_NUM_S{32'h00000000}} // Arbitration priority among each SI slot. // Higher values indicate higher priority. // Format: C_NUM_SLAVE_SLOTS{Bit32}; // Range: 'h0-'hF. ) ( // Global Signals input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_S*C_AMESG_WIDTH-1:0] S_AWMESG, input wire [C_NUM_S*C_AMESG_WIDTH-1:0] S_ARMESG, input wire [C_NUM_S-1:0] S_AWVALID, output wire [C_NUM_S-1:0] S_AWREADY, input wire [C_NUM_S-1:0] S_ARVALID, output wire [C_NUM_S-1:0] S_ARREADY, // Master Ports output wire [C_AMESG_WIDTH-1:0] M_AMESG, output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, output wire [C_NUM_S-1:0] M_GRANT_HOT, output wire M_GRANT_RNW, output wire M_GRANT_ANY, output wire M_AWVALID, input wire M_AWREADY, output wire M_ARVALID, input wire M_ARREADY ); // Generates a mask for all input slots that are priority based function [C_NUM_S-1:0] f_prio_mask ( input integer null_arg ); reg [C_NUM_S-1:0] mask; integer i; begin mask = 0; for (i=0; i < C_NUM_S; i=i+1) begin mask[i] = (C_ARB_PRIORITY[i*32+:32] != 0); end f_prio_mask = mask; end endfunction // Convert 16-bit one-hot to 4-bit binary function [3:0] f_hot2enc ( input [15:0] one_hot ); begin f_hot2enc[0] = |(one_hot & 16'b1010101010101010); f_hot2enc[1] = |(one_hot & 16'b1100110011001100); f_hot2enc[2] = |(one_hot & 16'b1111000011110000); f_hot2enc[3] = |(one_hot & 16'b1111111100000000); end endfunction localparam [C_NUM_S-1:0] P_PRIO_MASK = f_prio_mask(0); reg m_valid_i; reg [C_NUM_S-1:0] s_ready_i; reg [C_NUM_S-1:0] s_awvalid_reg; reg [C_NUM_S-1:0] s_arvalid_reg; wire [15:0] s_avalid; wire m_aready; wire [C_NUM_S-1:0] rnw; reg grant_rnw; reg [C_NUM_S_LOG-1:0] m_grant_enc_i; reg [C_NUM_S-1:0] m_grant_hot_i; reg [C_NUM_S-1:0] last_rr_hot; reg any_grant; reg any_prio; reg [C_NUM_S-1:0] which_prio_hot; reg [C_NUM_S_LOG-1:0] which_prio_enc; reg [4:0] current_highest; reg [15:0] next_prio_hot; reg [C_NUM_S_LOG-1:0] next_prio_enc; reg found_prio; wire [C_NUM_S-1:0] valid_rr; reg [15:0] next_rr_hot; reg [C_NUM_S_LOG-1:0] next_rr_enc; reg [C_NUM_S*C_NUM_S-1:0] carry_rr; reg [C_NUM_S*C_NUM_S-1:0] mask_rr; reg found_rr; wire [C_NUM_S-1:0] next_hot; wire [C_NUM_S_LOG-1:0] next_enc; integer i; wire [C_AMESG_WIDTH-1:0] amesg_mux; reg [C_AMESG_WIDTH-1:0] m_amesg_i; wire [C_NUM_S*C_AMESG_WIDTH-1:0] s_amesg; genvar gen_si; always @(posedge ACLK) begin if (ARESET) begin s_awvalid_reg <= 0; s_arvalid_reg <= 0; end else if (|s_ready_i) begin s_awvalid_reg <= 0; s_arvalid_reg <= 0; end else begin s_arvalid_reg <= S_ARVALID & ~s_awvalid_reg; s_awvalid_reg <= S_AWVALID & ~s_arvalid_reg & (~S_ARVALID | s_awvalid_reg); end end assign s_avalid = S_AWVALID | S_ARVALID; assign M_AWVALID = m_valid_i & ~grant_rnw; assign M_ARVALID = m_valid_i & grant_rnw; assign S_AWREADY = s_ready_i & {C_NUM_S{~grant_rnw}}; assign S_ARREADY = s_ready_i & {C_NUM_S{grant_rnw}}; assign M_GRANT_ENC = C_GRANT_ENC ? m_grant_enc_i : 0; assign M_GRANT_HOT = m_grant_hot_i; assign M_GRANT_RNW = grant_rnw; assign rnw = S_ARVALID & ~s_awvalid_reg; assign M_AMESG = m_amesg_i; assign m_aready = grant_rnw ? M_ARREADY : M_AWREADY; generate for (gen_si=0; gen_si<C_NUM_S; gen_si=gen_si+1) begin : gen_mesg_mux assign s_amesg[C_AMESG_WIDTH*gen_si +: C_AMESG_WIDTH] = rnw[gen_si] ? S_ARMESG[C_AMESG_WIDTH*gen_si +: C_AMESG_WIDTH] : S_AWMESG[C_AMESG_WIDTH*gen_si +: C_AMESG_WIDTH]; end // gen_mesg_mux if (C_NUM_S>1) begin : gen_arbiter ///////////////////////////////////////////////////////////////////////////// // Grant a new request when there is none still pending. // If no qualified requests found, de-assert M_VALID. ///////////////////////////////////////////////////////////////////////////// assign M_GRANT_ANY = any_grant; assign next_hot = found_prio ? next_prio_hot : next_rr_hot; assign next_enc = found_prio ? next_prio_enc : next_rr_enc; always @(posedge ACLK) begin if (ARESET) begin m_valid_i <= 0; s_ready_i <= 0; m_grant_hot_i <= 0; m_grant_enc_i <= 0; any_grant <= 1'b0; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; grant_rnw <= 1'b0; end else begin s_ready_i <= 0; if (m_valid_i) begin // Stall 1 cycle after each master-side completion. if (m_aready) begin // Master-side completion m_valid_i <= 1'b0; m_grant_hot_i <= 0; any_grant <= 1'b0; end end else if (any_grant) begin m_valid_i <= 1'b1; s_ready_i <= m_grant_hot_i; // Assert S_AW/READY for 1 cycle to complete SI address transfer end else begin if (found_prio | found_rr) begin m_grant_hot_i <= next_hot; m_grant_enc_i <= next_enc; any_grant <= 1'b1; grant_rnw <= |(rnw & next_hot); if (~found_prio) begin last_rr_hot <= next_rr_hot; end end end end end ///////////////////////////////////////////////////////////////////////////// // Fixed Priority arbiter // Selects next request to grant from among inputs with PRIO > 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ * begin : ALG_PRIO integer ip; any_prio = 1'b0; which_prio_hot = 0; which_prio_enc = 0; current_highest = 0; for (ip=0; ip < C_NUM_S; ip=ip+1) begin if (P_PRIO_MASK[ip] & ({1'b0, C_ARB_PRIORITY[ip*32+:4]} > current_highest)) begin if (s_avalid[ip]) begin current_highest[0+:4] = C_ARB_PRIORITY[ip*32+:4]; any_prio = 1'b1; which_prio_hot = 1'b1 << ip; which_prio_enc = ip; end end end found_prio = any_prio; next_prio_hot = which_prio_hot; next_prio_enc = which_prio_enc; end ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// assign valid_rr = ~P_PRIO_MASK & s_avalid; always @ * begin : ALG_RR integer ir, jr, nr; next_rr_hot = 0; for (ir=0;ir<C_NUM_S;ir=ir+1) begin nr = (ir>0) ? (ir-1) : (C_NUM_S-1); carry_rr[ir*C_NUM_S] = last_rr_hot[nr]; mask_rr[ir*C_NUM_S] = ~valid_rr[nr]; for (jr=1;jr<C_NUM_S;jr=jr+1) begin nr = (ir-jr > 0) ? (ir-jr-1) : (C_NUM_S+ir-jr-1); carry_rr[ir*C_NUM_S+jr] = carry_rr[ir*C_NUM_S+jr-1] | (last_rr_hot[nr] & mask_rr[ir*C_NUM_S+jr-1]); if (jr < C_NUM_S-1) begin mask_rr[ir*C_NUM_S+jr] = mask_rr[ir*C_NUM_S+jr-1] & ~valid_rr[nr]; end end next_rr_hot[ir] = valid_rr[ir] & carry_rr[(ir+1)*C_NUM_S-1]; end next_rr_enc = f_hot2enc(next_rr_hot); found_rr = |(next_rr_hot); end generic_baseblocks_v2_1_mux_enc # ( .C_FAMILY ("rtl"), .C_RATIO (C_NUM_S), .C_SEL_WIDTH (C_NUM_S_LOG), .C_DATA_WIDTH (C_AMESG_WIDTH) ) si_amesg_mux_inst ( .S (next_enc), .A (s_amesg), .O (amesg_mux), .OE (1'b1) ); always @(posedge ACLK) begin if (ARESET) begin m_amesg_i <= 0; end else if (~any_grant) begin m_amesg_i <= amesg_mux; end end end else begin : gen_no_arbiter assign M_GRANT_ANY = m_grant_hot_i; always @ (posedge ACLK) begin if (ARESET) begin m_valid_i <= 1'b0; s_ready_i <= 1'b0; m_grant_enc_i <= 0; m_grant_hot_i <= 1'b0; grant_rnw <= 1'b0; end else begin s_ready_i <= 1'b0; if (m_valid_i) begin if (m_aready) begin m_valid_i <= 1'b0; m_grant_hot_i <= 1'b0; end end else if (m_grant_hot_i) begin m_valid_i <= 1'b1; s_ready_i[0] <= 1'b1; // Assert S_AW/READY for 1 cycle to complete SI address transfer end else if (s_avalid[0]) begin m_grant_hot_i <= 1'b1; grant_rnw <= rnw[0]; end end end always @ (posedge ACLK) begin if (ARESET) begin m_amesg_i <= 0; end else if (~m_grant_hot_i) begin m_amesg_i <= s_amesg; end end end // gen_arbiter endgenerate endmodule

module processing_system7_bfm_v2_0_5_arb_wr( rstn, sw_clk, qos1, qos2, prt_dv1, prt_dv2, prt_data1, prt_data2, prt_addr1, prt_addr2, prt_bytes1, prt_bytes2, prt_ack1, prt_ack2, prt_qos, prt_req, prt_data, prt_addr, prt_bytes, prt_ack ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2; input [max_burst_bits-1:0] prt_data1,prt_data2; input [addr_width-1:0] prt_addr1,prt_addr2; input [max_burst_bytes_width:0] prt_bytes1,prt_bytes2; input prt_dv1, prt_dv2, prt_ack; output reg prt_ack1,prt_ack2,prt_req; output reg [max_burst_bits-1:0] prt_data; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; output reg [axi_qos_width-1:0] prt_qos; parameter wait_req = 2'b00, serv_req1 = 2'b01, serv_req2 = 2'b10,wait_ack_low = 2'b11; reg [1:0] state,temp_state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_ack1 = 1'b0; prt_ack2 = 1'b0; prt_req = 1'b0; if(prt_dv1 && !prt_dv2) begin state = serv_req1; prt_req = 1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; prt_qos = qos1; end else if(!prt_dv1 && prt_dv2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_dv1 && prt_dv2) begin if(qos1 > qos2) begin prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else if(qos1 < qos2) begin prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end else begin prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req1:begin state = serv_req1; prt_ack2 = 1'b0; if(prt_ack) begin prt_ack1 = 1'b1; prt_req = 0; if(prt_dv2) begin prt_req = 1; prt_qos = qos2; prt_data = prt_data2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end else begin // state = wait_req; state = wait_ack_low; end end end serv_req2:begin state = serv_req2; prt_ack1 = 1'b0; if(prt_ack) begin prt_ack2 = 1'b1; prt_req = 0; if(prt_dv1) begin prt_req = 1; prt_qos = qos1; prt_data = prt_data1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else begin state = wait_ack_low; // state = wait_req; end end end wait_ack_low:begin prt_ack1 = 1'b0; prt_ack2 = 1'b0; state = wait_ack_low; if(!prt_ack) state = wait_req; end endcase end /// if else end /// always endmodule

module */ /* Internal counters that are used as Read/Write pointers to the fifo's that store all the transaction info on all channles. This parameter is used to define the width of these pointers --> depending on Maximum outstanding transactions supported. 1-bit extra width than the no.of.bits needed to represent the outstanding transactions Extra bit helps in generating the empty and full flags */ parameter int_cntr_width = clogb2(max_outstanding_transactions)+1; /* RESP data */ parameter rsp_fifo_bits = axi_rsp_width+id_bus_width; parameter rsp_lsb = 0; parameter rsp_msb = axi_rsp_width-1; parameter rsp_id_lsb = rsp_msb + 1; parameter rsp_id_msb = rsp_id_lsb + id_bus_width-1; input S_RESETN; output S_ARREADY; output S_AWREADY; output S_BVALID; output S_RLAST; output S_RVALID; output S_WREADY; output [axi_rsp_width-1:0] S_BRESP; output [axi_rsp_width-1:0] S_RRESP; output [data_bus_width-1:0] S_RDATA; output [id_bus_width-1:0] S_BID; output [id_bus_width-1:0] S_RID; input S_ACLK; input S_ARVALID; input S_AWVALID; input S_BREADY; input S_RREADY; input S_WLAST; input S_WVALID; input [axi_brst_type_width-1:0] S_ARBURST; input [axi_lock_width-1:0] S_ARLOCK; input [axi_size_width-1:0] S_ARSIZE; input [axi_brst_type_width-1:0] S_AWBURST; input [axi_lock_width-1:0] S_AWLOCK; input [axi_size_width-1:0] S_AWSIZE; input [axi_prot_width-1:0] S_ARPROT; input [axi_prot_width-1:0] S_AWPROT; input [address_bus_width-1:0] S_ARADDR; input [address_bus_width-1:0] S_AWADDR; input [data_bus_width-1:0] S_WDATA; input [axi_cache_width-1:0] S_ARCACHE; input [axi_cache_width-1:0] S_ARLEN; input [axi_qos_width-1:0] S_ARQOS; input [axi_cache_width-1:0] S_AWCACHE; input [axi_len_width-1:0] S_AWLEN; input [axi_qos_width-1:0] S_AWQOS; input [(data_bus_width/8)-1:0] S_WSTRB; input [id_bus_width-1:0] S_ARID; input [id_bus_width-1:0] S_AWID; input [id_bus_width-1:0] S_WID; input SW_CLK; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output [max_burst_bits-1:0] WR_DATA; output [addr_width-1:0] WR_ADDR; output [max_transfer_bytes_width:0] WR_BYTES; output reg RD_REQ_OCM, RD_REQ_DDR; output reg [addr_width-1:0] RD_ADDR; input [max_burst_bits-1:0] RD_DATA_DDR,RD_DATA_OCM; output reg[max_transfer_bytes_width:0] RD_BYTES; input RD_DATA_VALID_OCM,RD_DATA_VALID_DDR; output [axi_qos_width-1:0] WR_QOS; output reg [axi_qos_width-1:0] RD_QOS; input S_RDISSUECAP1_EN; input S_WRISSUECAP1_EN; output [7:0] S_RCOUNT; output [7:0] S_WCOUNT; output [2:0] S_RACOUNT; output [5:0] S_WACOUNT; wire net_ARVALID; wire net_AWVALID; wire net_WVALID; real s_aclk_period; cdn_axi3_slave_bfm #(slave_name, data_bus_width, address_bus_width, id_bus_width, slave_base_address, (slave_high_address- slave_base_address), max_outstanding_transactions, 0, ///MEMORY_MODEL_MODE, exclusive_access_supported) slave (.ACLK (S_ACLK), .ARESETn (S_RESETN), /// confirm this // Write Address Channel .AWID (S_AWID), .AWADDR (S_AWADDR), .AWLEN (S_AWLEN), .AWSIZE (S_AWSIZE), .AWBURST (S_AWBURST), .AWLOCK (S_AWLOCK), .AWCACHE (S_AWCACHE), .AWPROT (S_AWPROT), .AWVALID (net_AWVALID), .AWREADY (S_AWREADY), // Write Data Channel Signals. .WID (S_WID), .WDATA (S_WDATA), .WSTRB (S_WSTRB), .WLAST (S_WLAST), .WVALID (net_WVALID), .WREADY (S_WREADY), // Write Response Channel Signals. .BID (S_BID), .BRESP (S_BRESP), .BVALID (S_BVALID), .BREADY (S_BREADY), // Read Address Channel Signals. .ARID (S_ARID), .ARADDR (S_ARADDR), .ARLEN (S_ARLEN), .ARSIZE (S_ARSIZE), .ARBURST (S_ARBURST), .ARLOCK (S_ARLOCK), .ARCACHE (S_ARCACHE), .ARPROT (S_ARPROT), .ARVALID (net_ARVALID), .ARREADY (S_ARREADY), // Read Data Channel Signals. .RID (S_RID), .RDATA (S_RDATA), .RRESP (S_RRESP), .RLAST (S_RLAST), .RVALID (S_RVALID), .RREADY (S_RREADY)); wire wr_intr_fifo_full; reg temp_wr_intr_fifo_full; /* Interconnect WR_FIFO model instance */ processing_system7_bfm_v2_0_5_intr_wr_mem wr_intr_fifo(SW_CLK, S_RESETN, wr_intr_fifo_full, WR_DATA_ACK_OCM, WR_DATA_ACK_DDR, WR_ADDR, WR_DATA, WR_BYTES, WR_QOS, WR_DATA_VALID_OCM, WR_DATA_VALID_DDR); /* Register the async 'full' signal to S_ACLK clock */ always@(posedge S_ACLK) temp_wr_intr_fifo_full = wr_intr_fifo_full; /* Latency type and Debug/Error Control */ reg[1:0] latency_type = RANDOM_CASE; reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1'b1; /* Internal nets/regs for calling slave BFM API's*/ reg [wr_afi_fifo_data_bits-1:0] wr_fifo [0:max_outstanding_transactions-1]; reg [int_cntr_width-1:0] wr_fifo_wr_ptr = 0, wr_fifo_rd_ptr = 0; wire wr_fifo_empty; /* Store the awvalid receive time --- necessary for calculating the bresp latency */ reg [7:0] aw_time_cnt = 0,bresp_time_cnt = 0; real awvalid_receive_time[0:max_outstanding_transactions]; // store the time when a new awvalid is received reg awvalid_flag[0:max_outstanding_transactions]; // store the time when a new awvalid is received /* Address Write Channel handshake*/ reg[int_cntr_width-1:0] aw_cnt = 0;// /* various FIFOs for storing the ADDR channel info */ reg [axi_size_width-1:0] awsize [0:max_outstanding_transactions-1]; reg [axi_prot_width-1:0] awprot [0:max_outstanding_transactions-1]; reg [axi_lock_width-1:0] awlock [0:max_outstanding_transactions-1]; reg [axi_cache_width-1:0] awcache [0:max_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] awbrst [0:max_outstanding_transactions-1]; reg [axi_len_width-1:0] awlen [0:max_outstanding_transactions-1]; reg aw_flag [0:max_outstanding_transactions-1]; reg [addr_width-1:0] awaddr [0:max_outstanding_transactions-1]; reg [id_bus_width-1:0] awid [0:max_outstanding_transactions-1]; reg [axi_qos_width-1:0] awqos [0:max_outstanding_transactions-1]; wire aw_fifo_full; // indicates awvalid_fifo is full (max outstanding transactions reached) /* internal fifos to store burst write data, ID & strobes*/ reg [(data_bus_width*axi_burst_len)-1:0] burst_data [0:max_outstanding_transactions-1]; reg [max_burst_bytes_width:0] burst_valid_bytes [0:max_outstanding_transactions-1]; /// total valid bytes received in a complete burst transfer reg wlast_flag [0:max_outstanding_transactions-1]; // flag to indicate WLAST received wire wd_fifo_full; /* Write Data Channel and Write Response handshake signals*/ reg [int_cntr_width-1:0] wd_cnt = 0; reg [(data_bus_width*axi_burst_len)-1:0] aligned_wr_data; reg [addr_width-1:0] aligned_wr_addr; reg [max_burst_bytes_width:0] valid_data_bytes; reg [int_cntr_width-1:0] wr_bresp_cnt = 0; reg [axi_rsp_width-1:0] bresp; reg [rsp_fifo_bits-1:0] fifo_bresp [0:max_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_bresp; reg [int_cntr_width-1:0] rd_bresp_cnt = 0; integer wr_latency_count; reg wr_delayed; wire bresp_fifo_empty; /* keep track of count values */ reg[7:0] wcount; reg[5:0] wacount; /* Qos*/ reg [axi_qos_width-1:0] ar_qos, aw_qos; initial begin if(DEBUG_INFO) begin if(enable_this_port) $display("[%0d] : %0s : %0s : Port is ENABLED.",$time, DISP_INFO, slave_name); else $display("[%0d] : %0s : %0s : Port is DISABLED.",$time, DISP_INFO, slave_name); end end /*--------------------------------------------------------------------------------*/ /* Store the Clock cycle time period */ always@(S_RESETN) begin if(S_RESETN) begin @(posedge S_ACLK); s_aclk_period = $time; @(posedge S_ACLK); s_aclk_period = $time - s_aclk_period; end end /*--------------------------------------------------------------------------------*/ initial slave.set_disable_reset_value_checks(1); initial begin repeat(2) @(posedge S_ACLK); if(!enable_this_port) begin slave.set_channel_level_info(0); slave.set_function_level_info(0); end slave.RESPONSE_TIMEOUT = 0; end /*--------------------------------------------------------------------------------*/ /* Set Latency type to be used */ task set_latency_type; input[1:0] lat; begin if(enable_this_port) latency_type = lat; else begin //if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'Latency Profile' will not be set...",$time, DISP_WARN, slave_name); end end endtask /*--------------------------------------------------------------------------------*/ /* Set ARQoS to be used */ task set_arqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) ar_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'ARQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /*--------------------------------------------------------------------------------*/ /* Set AWQoS to be used */ task set_awqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) aw_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'AWQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /*--------------------------------------------------------------------------------*/ /* get the wr latency number */ function [31:0] get_wr_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : get_wr_lat_number = afi_wr_min; AVG_CASE : get_wr_lat_number = afi_wr_avg; WORST_CASE : get_wr_lat_number = afi_wr_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : get_wr_lat_number = ($random()%10+ afi_wr_min); 2'b01 : get_wr_lat_number = ($random()%40+ afi_wr_avg); default : get_wr_lat_number = ($random()%60+ afi_wr_max); endcase end endcase end endfunction /*--------------------------------------------------------------------------------*/ /* get the rd latency number */ function [31:0] get_rd_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : get_rd_lat_number = afi_rd_min; AVG_CASE : get_rd_lat_number = afi_rd_avg; WORST_CASE : get_rd_lat_number = afi_rd_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : get_rd_lat_number = ($random()%10+ afi_rd_min); 2'b01 : get_rd_lat_number = ($random()%40+ afi_rd_avg); default : get_rd_lat_number = ($random()%60+ afi_rd_max); endcase end endcase end endfunction /*--------------------------------------------------------------------------------*/ /* Check for any WRITE/READs when this port is disabled */ always@(S_AWVALID or S_WVALID or S_ARVALID) begin if((S_AWVALID | S_WVALID | S_ARVALID) && !enable_this_port) begin $display("[%0d] : %0s : %0s : Port is disabled. AXI transaction is initiated on this port ...\nSimulation will halt ..",$time, DISP_ERR, slave_name); $stop; end end /*--------------------------------------------------------------------------------*/ assign net_ARVALID = enable_this_port ? S_ARVALID : 1'b0; assign net_AWVALID = enable_this_port ? S_AWVALID : 1'b0; assign net_WVALID = enable_this_port ? S_WVALID : 1'b0; assign wr_fifo_empty = (wr_fifo_wr_ptr === wr_fifo_rd_ptr)?1'b1: 1'b0; assign bresp_fifo_empty = (wr_bresp_cnt === rd_bresp_cnt)?1'b1:1'b0; assign bresp_fifo_full = ((wr_bresp_cnt[int_cntr_width-1] !== rd_bresp_cnt[int_cntr_width-1]) && (wr_bresp_cnt[int_cntr_width-2:0] === rd_bresp_cnt[int_cntr_width-2:0]))?1'b1:1'b0; assign S_WCOUNT = wcount; assign S_WACOUNT = wacount; // FIFO_STATUS (only if AFI port) 1- full function automatic wrfifo_full ; input [axi_len_width:0] fifo_space_exp; integer fifo_space_left; begin fifo_space_left = afi_fifo_locations - wcount; if(fifo_space_left < fifo_space_exp) wrfifo_full = 1; else wrfifo_full = 0; end endfunction /*--------------------------------------------------------------------------------*/ /* Store the awvalid receive time --- necessary for calculating the bresp latency */ always@(negedge S_RESETN or S_AWID or S_AWADDR or S_AWVALID ) begin if(!S_RESETN) aw_time_cnt = 0; else begin if(S_AWVALID) begin awvalid_receive_time[aw_time_cnt] = $time; awvalid_flag[aw_time_cnt] = 1'b1; aw_time_cnt = aw_time_cnt + 1; end end // else end /// always /*--------------------------------------------------------------------------------*/ always@(posedge S_ACLK) begin if(net_AWVALID && S_AWREADY) begin if(S_AWQOS === 0) awqos[aw_cnt[int_cntr_width-2:0]] = aw_qos; else awqos[aw_cnt[int_cntr_width-2:0]] = S_AWQOS; end end /* Address Write Channel handshake*/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin aw_cnt = 0; wacount = 0; end else begin if(S_AWVALID && !wrfifo_full(S_AWLEN+1)) begin slave.RECEIVE_WRITE_ADDRESS(0, id_invalid, awaddr[aw_cnt[int_cntr_width-2:0]], awlen[aw_cnt[int_cntr_width-2:0]], awsize[aw_cnt[int_cntr_width-2:0]], awbrst[aw_cnt[int_cntr_width-2:0]], awlock[aw_cnt[int_cntr_width-2:0]], awcache[aw_cnt[int_cntr_width-2:0]], awprot[aw_cnt[int_cntr_width-2:0]], awid[aw_cnt[int_cntr_width-2:0]]); /// sampled valid ID. aw_flag[aw_cnt[int_cntr_width-2:0]] = 1'b1; aw_cnt = aw_cnt + 1; wacount = wacount + 1; end // if (!aw_fifo_full) end /// if else end /// always /*--------------------------------------------------------------------------------*/ /* Write Data Channel Handshake */ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wd_cnt = 0; end else begin if(aw_flag[wd_cnt[int_cntr_width-2:0]]) begin if(S_WVALID && !wrfifo_full(awlen[wd_cnt[int_cntr_width-2:0]] + 1)) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_cntr_width-2:0]]); wlast_flag[wd_cnt[int_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; end end else begin if(!wrfifo_full(axi_burst_len+1) && S_WVALID) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_cntr_width-2:0]]); wlast_flag[wd_cnt[int_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; end end /// if end /// else end /// always /*--------------------------------------------------------------------------------*/ /* Align the wrap data for write transaction */ task automatic get_wrap_aligned_wr_data; output [(data_bus_width*axi_burst_len)-1:0] aligned_data; output [addr_width-1:0] start_addr; /// aligned start address input [addr_width-1:0] addr; input [(data_bus_width*axi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [(data_bus_width*axi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; wrp_data = wrp_data << ((data_bus_width*axi_burst_len) - (v_bytes*8)); while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data << 8; temp_data[7:0] = wrp_data[(data_bus_width*axi_burst_len)-1 : (data_bus_width*axi_burst_len)-8]; wrp_data = wrp_data << 8; wrp_bytes = wrp_bytes - 1; end wrp_bytes = addr - start_addr; wrp_data = b_data << (wrp_bytes*8); aligned_data = (temp_data | wrp_data); end endtask /*--------------------------------------------------------------------------------*/ /* Calculate the Response for each read/write transaction */ function [axi_rsp_width-1:0] calculate_resp; input [addr_width-1:0] awaddr; input [axi_prot_width-1:0] awprot; reg [axi_rsp_width-1:0] rsp; begin rsp = AXI_OK; /* Address Decode */ if(decode_address(awaddr) === INVALID_MEM_TYPE) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Invalid location(0x%0h) ",$time, DISP_ERR, slave_name, awaddr); end else if(decode_address(awaddr) === REG_MEM) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Register Map(0x%0h) is not allowed through this port.",$time, DISP_ERR, slave_name, awaddr); end if(secure_access_enabled && awprot[1]) rsp = AXI_DEC_ERR; // decode error calculate_resp = rsp; end endfunction /*--------------------------------------------------------------------------------*/ reg[max_burst_bits-1:0] temp_wr_data; /* Store the Write response for each write transaction */ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_fifo_wr_ptr = 0; wcount = 0; end else begin enable_write_bresp = aw_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] && wlast_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]]; /* calculate bresp only when AWVALID && WLAST is received */ if(enable_write_bresp) begin aw_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] = 0; wlast_flag[wr_fifo_wr_ptr[int_cntr_width-2:0]] = 0; bresp = calculate_resp(awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]], awprot[wr_fifo_wr_ptr[int_cntr_width-2:0]]); /* Fill AFI_WR_data FIFO */ if(bresp === AXI_OK ) begin if(awbrst[wr_fifo_wr_ptr[int_cntr_width-2:0]]=== AXI_WRAP) begin /// wrap type? then align the data get_wrap_aligned_wr_data(aligned_wr_data, aligned_wr_addr, awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]], burst_data[wr_fifo_wr_ptr[int_cntr_width-2:0]],burst_valid_bytes[wr_fifo_wr_ptr[int_cntr_width-2:0]]); /// gives wrapped start address end else begin aligned_wr_data = burst_data[wr_fifo_wr_ptr[int_cntr_width-2:0]]; aligned_wr_addr = awaddr[wr_fifo_wr_ptr[int_cntr_width-2:0]] ; end valid_data_bytes = burst_valid_bytes[wr_fifo_wr_ptr[int_cntr_width-2:0]]; end else valid_data_bytes = 0; temp_wr_data = aligned_wr_data; wr_fifo[wr_fifo_wr_ptr[int_cntr_width-2:0]] = {awqos[wr_fifo_wr_ptr[int_cntr_width-2:0]], awlen[wr_fifo_wr_ptr[int_cntr_width-2:0]], awid[wr_fifo_wr_ptr[int_cntr_width-2:0]], bresp, temp_wr_data, aligned_wr_addr, valid_data_bytes}; wcount = wcount + awlen[wr_fifo_wr_ptr[int_cntr_width-2:0]]+1; wr_fifo_wr_ptr = wr_fifo_wr_ptr + 1; end end // else end // always /*--------------------------------------------------------------------------------*/ /* Send Write Response Channel handshake */ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin rd_bresp_cnt = 0; wr_latency_count = get_wr_lat_number(1); wr_delayed = 0; bresp_time_cnt = 0; end else begin wr_delayed = 1'b0; if(awvalid_flag[bresp_time_cnt] && (($time - awvalid_receive_time[bresp_time_cnt])/s_aclk_period >= wr_latency_count)) wr_delayed = 1; if(!bresp_fifo_empty && wr_delayed) begin slave.SEND_WRITE_RESPONSE(fifo_bresp[rd_bresp_cnt[int_cntr_width-2:0]][rsp_id_msb : rsp_id_lsb], // ID fifo_bresp[rd_bresp_cnt[int_cntr_width-2:0]][rsp_msb : rsp_lsb] // Response ); wr_delayed = 0; awvalid_flag[bresp_time_cnt] = 1'b0; bresp_time_cnt = bresp_time_cnt+1; rd_bresp_cnt = rd_bresp_cnt + 1; wr_latency_count = get_wr_lat_number(1); end end // else end//always /*--------------------------------------------------------------------------------*/ /* Write Response Channel handshake */ reg wr_int_state; /* Reading from the wr_fifo and sending to Interconnect fifo*/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_int_state = 1'b0; wr_bresp_cnt = 0; wr_fifo_rd_ptr = 0; end else begin case(wr_int_state) 1'b0 : begin wr_int_state = 1'b0; if(!temp_wr_intr_fifo_full && !bresp_fifo_full && !wr_fifo_empty) begin wr_intr_fifo.write_mem({wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_qos_msb:wr_afi_qos_lsb], wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_data_msb:wr_afi_bytes_lsb]}); /// qos, data, address and valid_bytes wr_int_state = 1'b1; /* start filling the write response fifo at the same time */ fifo_bresp[wr_bresp_cnt[int_cntr_width-2:0]] = wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_id_msb:wr_afi_rsp_lsb]; // ID and Resp wcount = wcount - (wr_fifo[wr_fifo_rd_ptr[int_cntr_width-2:0]][wr_afi_ln_msb:wr_afi_ln_lsb] + 1); /// burst length wacount = wacount - 1; wr_fifo_rd_ptr = wr_fifo_rd_ptr + 1; wr_bresp_cnt = wr_bresp_cnt+1; end end 1'b1 : begin wr_int_state = 0; end endcase end end /*--------------------------------------------------------------------------------*/ /*-------------------------------- WRITE HANDSHAKE END ----------------------------------------*/ /*-------------------------------- READ HANDSHAKE ---------------------------------------------*/ /* READ CHANNELS */ /* Store the arvalid receive time --- necessary for calculating latency in sending the rresp latency */ reg [7:0] ar_time_cnt = 0,rresp_time_cnt = 0; real arvalid_receive_time[0:max_outstanding_transactions]; // store the time when a new arvalid is received reg arvalid_flag[0:max_outstanding_transactions]; // store the time when a new arvalid is received reg [int_cntr_width-1:0] ar_cnt = 0;// counter for arvalid info /* various FIFOs for storing the ADDR channel info */ reg [axi_size_width-1:0] arsize [0:max_outstanding_transactions-1]; reg [axi_prot_width-1:0] arprot [0:max_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] arbrst [0:max_outstanding_transactions-1]; reg [axi_len_width-1:0] arlen [0:max_outstanding_transactions-1]; reg [axi_cache_width-1:0] arcache [0:max_outstanding_transactions-1]; reg [axi_lock_width-1:0] arlock [0:max_outstanding_transactions-1]; reg ar_flag [0:max_outstanding_transactions-1]; reg [addr_width-1:0] araddr [0:max_outstanding_transactions-1]; reg [id_bus_width-1:0] arid [0:max_outstanding_transactions-1]; reg [axi_qos_width-1:0] arqos [0:max_outstanding_transactions-1]; wire ar_fifo_full; // indicates arvalid_fifo is full (max outstanding transactions reached) reg [int_cntr_width-1:0] wr_rresp_cnt = 0; reg [axi_rsp_width-1:0] rresp; reg [rsp_fifo_bits-1:0] fifo_rresp [0:max_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_rresp; /* Send Read Response & Data Channel handshake */ integer rd_latency_count; reg rd_delayed; reg [rd_afi_fifo_bits-1:0] read_fifo[0:max_outstanding_transactions-1]; /// Read Burst Data, addr, size, burst, len, RID, RRESP, valid_bytes reg [int_cntr_width-1:0] rd_fifo_wr_ptr = 0, rd_fifo_rd_ptr = 0; wire read_fifo_full; reg [7:0] rcount; reg [2:0] racount; wire rd_intr_fifo_full, rd_intr_fifo_empty; wire read_fifo_empty; /* signals to communicate with interconnect RD_FIFO model */ reg rd_req, invalid_rd_req; /* REad control Info 56:25 : Address (32) 24:22 : Size (3) 21:20 : BRST (2) 19:16 : LEN (4) 15:10 : RID (6) 9:8 : RRSP (2) 7:0 : byte cnt (8) */ reg [rd_info_bits-1:0] read_control_info; reg [(data_bus_width*axi_burst_len)-1:0] aligned_rd_data; reg temp_rd_intr_fifo_empty; processing_system7_bfm_v2_0_5_intr_rd_mem rd_intr_fifo(SW_CLK, S_RESETN, rd_intr_fifo_full, rd_intr_fifo_empty, rd_req, invalid_rd_req, read_control_info , RD_DATA_OCM, RD_DATA_DDR, RD_DATA_VALID_OCM, RD_DATA_VALID_DDR); assign read_fifo_empty = (rd_fifo_wr_ptr === rd_fifo_rd_ptr)?1'b1: 1'b0; assign S_RCOUNT = rcount; assign S_RACOUNT = racount; /* Register the asynch signal empty coming from Interconnect READ FIFO */ always@(posedge S_ACLK) temp_rd_intr_fifo_empty = rd_intr_fifo_empty; // FIFO_STATUS (only if AFI port) 1- full function automatic rdfifo_full ; input [axi_len_width:0] fifo_space_exp; integer fifo_space_left; begin fifo_space_left = afi_fifo_locations - rcount; if(fifo_space_left < fifo_space_exp) rdfifo_full = 1; else rdfifo_full = 0; end endfunction /* Store the arvalid receive time --- necessary for calculating the bresp latency */ always@(negedge S_RESETN or S_ARID or S_ARADDR or S_ARVALID ) begin if(!S_RESETN) ar_time_cnt = 0; else begin if(S_ARVALID) begin arvalid_receive_time[ar_time_cnt] = $time; arvalid_flag[ar_time_cnt] = 1'b1; ar_time_cnt = ar_time_cnt + 1; end end // else end /// always /*--------------------------------------------------------------------------------*/ always@(posedge S_ACLK) begin if(net_ARVALID && S_ARREADY) begin if(S_ARQOS === 0) arqos[aw_cnt[int_cntr_width-2:0]] = ar_qos; else arqos[aw_cnt[int_cntr_width-2:0]] = S_ARQOS; end end /* Address Read Channel handshake*/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin ar_cnt = 0; racount = 0; end else begin if(S_ARVALID && !rdfifo_full(S_ARLEN+1)) begin /// if AFI read fifo is not full slave.RECEIVE_READ_ADDRESS(0, id_invalid, araddr[ar_cnt[int_cntr_width-2:0]], arlen[ar_cnt[int_cntr_width-2:0]], arsize[ar_cnt[int_cntr_width-2:0]], arbrst[ar_cnt[int_cntr_width-2:0]], arlock[ar_cnt[int_cntr_width-2:0]], arcache[ar_cnt[int_cntr_width-2:0]], arprot[ar_cnt[int_cntr_width-2:0]], arid[ar_cnt[int_cntr_width-2:0]]); /// sampled valid ID. ar_flag[ar_cnt[int_cntr_width-2:0]] = 1'b1; ar_cnt = ar_cnt+1; racount = racount + 1; end /// if(!ar_fifo_full) end /// if else end /// always*/ /*--------------------------------------------------------------------------------*/ /* Align Wrap data for read transaction*/ task automatic get_wrap_aligned_rd_data; output [(data_bus_width*axi_burst_len)-1:0] aligned_data; input [addr_width-1:0] addr; input [(data_bus_width*axi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [addr_width-1:0] start_addr; reg [(data_bus_width*axi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data >> 8; temp_data[(data_bus_width*axi_burst_len)-1 : (data_bus_width*axi_burst_len)-8] = wrp_data[7:0]; wrp_data = wrp_data >> 8; wrp_bytes = wrp_bytes - 1; end temp_data = temp_data >> ((data_bus_width*axi_burst_len) - (v_bytes*8)); wrp_bytes = addr - start_addr; wrp_data = b_data >> (wrp_bytes*8); aligned_data = (temp_data | wrp_data); end endtask /*--------------------------------------------------------------------------------*/ parameter RD_DATA_REQ = 1'b0, WAIT_RD_VALID = 1'b1; reg rd_fifo_state; reg [addr_width-1:0] temp_read_address; reg [max_burst_bytes_width:0] temp_rd_valid_bytes; /* get the data from memory && also calculate the rresp*/ always@(negedge S_RESETN or posedge SW_CLK) begin if(!S_RESETN)begin wr_rresp_cnt =0; rd_fifo_state = RD_DATA_REQ; temp_rd_valid_bytes = 0; temp_read_address = 0; RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; rd_req = 0; invalid_rd_req= 0; RD_QOS = 0; end else begin case(rd_fifo_state) RD_DATA_REQ : begin rd_fifo_state = RD_DATA_REQ; RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; invalid_rd_req = 0; if(ar_flag[wr_rresp_cnt[int_cntr_width-2:0]] && !rd_intr_fifo_full) begin /// check the rd_fifo_bytes, interconnect fifo full condition ar_flag[wr_rresp_cnt[int_cntr_width-2:0]] = 0; rresp = calculate_resp(araddr[wr_rresp_cnt[int_cntr_width-2:0]],arprot[wr_rresp_cnt[int_cntr_width-2:0]]); temp_rd_valid_bytes = (arlen[wr_rresp_cnt[int_cntr_width-2:0]]+1)*(2**arsize[wr_rresp_cnt[int_cntr_width-2:0]]);//data_bus_width/8; if(arbrst[wr_rresp_cnt[int_cntr_width-2:0]] === AXI_WRAP) /// wrap begin temp_read_address = (araddr[wr_rresp_cnt[int_cntr_width-2:0]]/temp_rd_valid_bytes) * temp_rd_valid_bytes; else temp_read_address = araddr[wr_rresp_cnt[int_cntr_width-2:0]]; if(rresp === AXI_OK) begin case(decode_address(temp_read_address))//decode_address(araddr[wr_rresp_cnt[int_cntr_width-2:0]]); OCM_MEM : RD_REQ_OCM = 1; DDR_MEM : RD_REQ_DDR = 1; default : invalid_rd_req = 1; endcase end else invalid_rd_req = 1; RD_ADDR = temp_read_address; ///araddr[wr_rresp_cnt[int_cntr_width-2:0]]; RD_BYTES = temp_rd_valid_bytes; RD_QOS = arqos[wr_rresp_cnt[int_cntr_width-2:0]]; rd_fifo_state = WAIT_RD_VALID; rd_req = 1; racount = racount - 1; read_control_info = {araddr[wr_rresp_cnt[int_cntr_width-2:0]], arsize[wr_rresp_cnt[int_cntr_width-2:0]], arbrst[wr_rresp_cnt[int_cntr_width-2:0]], arlen[wr_rresp_cnt[int_cntr_width-2:0]], arid[wr_rresp_cnt[int_cntr_width-2:0]], rresp, temp_rd_valid_bytes }; wr_rresp_cnt = wr_rresp_cnt + 1; end end WAIT_RD_VALID : begin rd_fifo_state = WAIT_RD_VALID; rd_req = 0; if(RD_DATA_VALID_OCM | RD_DATA_VALID_DDR | invalid_rd_req) begin ///temp_dec == 2'b11) begin RD_REQ_DDR = 1'b0; RD_REQ_OCM = 1'b0; invalid_rd_req = 0; rd_fifo_state = RD_DATA_REQ; end end endcase end /// else end /// always /*--------------------------------------------------------------------------------*/ /* thread to fill in the AFI RD_FIFO */ reg[rd_afi_fifo_bits-1:0] temp_rd_data;//Read Burst Data, addr, size, burst, len, RID, RRESP, valid bytes reg tmp_state; always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_wr_ptr = 0; rcount = 0; tmp_state = 0; end else begin case(tmp_state) 0 : begin tmp_state = 0; if(!temp_rd_intr_fifo_empty) begin rd_intr_fifo.read_mem(temp_rd_data); tmp_state = 1; end end 1 : begin tmp_state = 1; if(!rdfifo_full(temp_rd_data[rd_afi_ln_msb:rd_afi_ln_lsb]+1)) begin read_fifo[rd_fifo_wr_ptr[int_cntr_width-2:0]] = temp_rd_data; rd_fifo_wr_ptr = rd_fifo_wr_ptr + 1; rcount = rcount + temp_rd_data[rd_afi_ln_msb:rd_afi_ln_lsb]+1; /// Burst length tmp_state = 0; end end endcase end end /*--------------------------------------------------------------------------------*/ reg[max_burst_bytes_width:0] rd_v_b; reg[rd_afi_fifo_bits-1:0] tmp_fifo_rd; /// Data, addr, size, burst, len, RID, RRESP,valid_bytes reg[(data_bus_width*axi_burst_len)-1:0] temp_read_data; reg[(axi_rsp_width*axi_burst_len)-1:0] temp_read_rsp; /* Read Data Channel handshake */ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_rd_ptr = 0; rd_latency_count = get_rd_lat_number(1); rd_delayed = 0; rresp_time_cnt = 0; rd_v_b = 0; end else begin if(arvalid_flag[rresp_time_cnt] && ((($time - arvalid_receive_time[rresp_time_cnt])/s_aclk_period) >= rd_latency_count)) begin rd_delayed = 1; end if(!read_fifo_empty && rd_delayed)begin rd_delayed = 0; arvalid_flag[rresp_time_cnt] = 1'b0; tmp_fifo_rd = read_fifo[rd_fifo_rd_ptr[int_cntr_width-2:0]]; rd_v_b = (tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb]+1)*(2**tmp_fifo_rd[rd_afi_siz_msb : rd_afi_siz_lsb]); temp_read_data = tmp_fifo_rd[rd_afi_data_msb : rd_afi_data_lsb]; if(tmp_fifo_rd[rd_afi_brst_msb : rd_afi_brst_lsb] === AXI_WRAP) begin get_wrap_aligned_rd_data(aligned_rd_data, tmp_fifo_rd[rd_afi_addr_msb : rd_afi_addr_lsb], tmp_fifo_rd[rd_afi_data_msb : rd_afi_data_lsb], rd_v_b); temp_read_data = aligned_rd_data; end temp_read_rsp = 0; repeat(axi_burst_len) begin temp_read_rsp = temp_read_rsp >> axi_rsp_width; temp_read_rsp[(axi_rsp_width*axi_burst_len)-1:(axi_rsp_width*axi_burst_len)-axi_rsp_width] = tmp_fifo_rd[rd_afi_rsp_msb : rd_afi_rsp_lsb]; end slave.SEND_READ_BURST_RESP_CTRL(tmp_fifo_rd[rd_afi_id_msb : rd_afi_id_lsb], tmp_fifo_rd[rd_afi_addr_msb : rd_afi_addr_lsb], tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb], tmp_fifo_rd[rd_afi_siz_msb : rd_afi_siz_lsb], tmp_fifo_rd[rd_afi_brst_msb : rd_afi_brst_lsb], temp_read_data, temp_read_rsp); rcount = rcount - (tmp_fifo_rd[rd_afi_ln_msb : rd_afi_ln_lsb]+ 1) ; rresp_time_cnt = rresp_time_cnt+1; rd_latency_count = get_rd_lat_number(1); rd_fifo_rd_ptr = rd_fifo_rd_ptr+1; end end /// else end /// always endmodule

module processing_system7_bfm_v2_0_5_regc( rstn, sw_clk, /* Goes to port 0 of REG */ reg_rd_req_port0, reg_rd_dv_port0, reg_rd_addr_port0, reg_rd_data_port0, reg_rd_bytes_port0, reg_rd_qos_port0, /* Goes to port 1 of REG */ reg_rd_req_port1, reg_rd_dv_port1, reg_rd_addr_port1, reg_rd_data_port1, reg_rd_bytes_port1, reg_rd_qos_port1 ); input rstn; input sw_clk; input reg_rd_req_port0; output reg_rd_dv_port0; input[31:0] reg_rd_addr_port0; output[1023:0] reg_rd_data_port0; input[7:0] reg_rd_bytes_port0; input [3:0] reg_rd_qos_port0; input reg_rd_req_port1; output reg_rd_dv_port1; input[31:0] reg_rd_addr_port1; output[1023:0] reg_rd_data_port1; input[7:0] reg_rd_bytes_port1; input[3:0] reg_rd_qos_port1; wire [3:0] rd_qos; reg [1023:0] rd_data; wire [31:0] rd_addr; wire [7:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_rd reg_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(reg_rd_qos_port0), .qos2(reg_rd_qos_port1), .prt_req1(reg_rd_req_port0), .prt_req2(reg_rd_req_port1), .prt_data1(reg_rd_data_port0), .prt_data2(reg_rd_data_port1), .prt_addr1(reg_rd_addr_port0), .prt_addr2(reg_rd_addr_port1), .prt_bytes1(reg_rd_bytes_port0), .prt_bytes2(reg_rd_bytes_port1), .prt_dv1(reg_rd_dv_port0), .prt_dv2(reg_rd_dv_port1), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_reg_map regm(); reg state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin rd_dv <= 0; state <= 0; end else begin case(state) 0:begin state <= 0; rd_dv <= 0; if(rd_req) begin regm.read_reg_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule

module processing_system7_bfm_v2_0_5_arb_rd_4( rstn, sw_clk, qos1, qos2, qos3, qos4, prt_req1, prt_req2, prt_req3, prt_req4, prt_data1, prt_data2, prt_data3, prt_data4, prt_addr1, prt_addr2, prt_addr3, prt_addr4, prt_bytes1, prt_bytes2, prt_bytes3, prt_bytes4, prt_dv1, prt_dv2, prt_dv3, prt_dv4, prt_qos, prt_req, prt_data, prt_addr, prt_bytes, prt_dv ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2,qos3,qos4; input prt_req1, prt_req2,prt_req3, prt_req4, prt_dv; output reg [max_burst_bits-1:0] prt_data1,prt_data2,prt_data3,prt_data4; input [addr_width-1:0] prt_addr1,prt_addr2,prt_addr3,prt_addr4; input [max_burst_bytes_width:0] prt_bytes1,prt_bytes2,prt_bytes3,prt_bytes4; output reg prt_dv1,prt_dv2,prt_dv3,prt_dv4,prt_req; input [max_burst_bits-1:0] prt_data; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; output reg [axi_qos_width-1:0] prt_qos; parameter wait_req = 3'b000, serv_req1 = 3'b001, serv_req2 = 3'b010, serv_req3 = 3'b011, serv_req4 = 3'b100, wait_dv_low=3'b101; reg [2:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; prt_req = 1'b0; if(prt_req1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_req4) begin prt_req = 1; prt_addr = prt_addr4; prt_qos = qos4; prt_bytes = prt_bytes4; state = serv_req4; end end serv_req1:begin state = serv_req1; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; if(prt_dv)begin prt_dv1 = 1'b1; prt_data1 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req2) begin state = serv_req2; prt_qos = qos2; prt_req = 1; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req3) begin state = serv_req3; prt_qos = qos3; prt_req = 1; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_req4) begin prt_req = 1; prt_qos = qos4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; state = serv_req4; end end end serv_req2:begin state = serv_req2; prt_dv1 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; if(prt_dv)begin prt_dv2 = 1'b1; prt_data2 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req3) begin state = serv_req3; prt_req = 1; prt_qos = qos3; prt_addr = prt_addr3; prt_bytes = prt_bytes3; end else if(prt_req4) begin state = serv_req4; prt_req = 1; prt_qos = qos4; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_req1) begin prt_req = 1; prt_addr = prt_addr1; prt_qos = qos1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req3:begin state = serv_req3; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv4 = 1'b0; if(prt_dv)begin prt_dv3 = 1'b1; prt_data3 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req4) begin state = serv_req4; prt_qos = qos4; prt_req = 1; prt_addr = prt_addr4; prt_bytes = prt_bytes4; end else if(prt_req1) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_req2) begin prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end end end serv_req4:begin state = serv_req4; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; if(prt_dv)begin prt_dv4 = 1'b1; prt_data4 = prt_data; //state = wait_req; state = wait_dv_low; prt_req = 1'b0; if(prt_req1) begin state = serv_req1; prt_qos = qos1; prt_req = 1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req3) begin prt_req = 1; prt_addr = prt_addr3; prt_qos = qos3; prt_bytes = prt_bytes3; state = serv_req3; end end end wait_dv_low:begin state = wait_dv_low; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_dv3 = 1'b0; prt_dv4 = 1'b0; if(!prt_dv) state = wait_req; end endcase end /// if else end /// always endmodule

module processing_system7_bfm_v2_0_5_ssw_hp( sw_clk, rstn, w_qos_hp0, r_qos_hp0, w_qos_hp1, r_qos_hp1, w_qos_hp2, r_qos_hp2, w_qos_hp3, r_qos_hp3, wr_ack_ddr_hp0, wr_data_hp0, wr_addr_hp0, wr_bytes_hp0, wr_dv_ddr_hp0, rd_req_ddr_hp0, rd_addr_hp0, rd_bytes_hp0, rd_data_ddr_hp0, rd_dv_ddr_hp0, rd_data_ocm_hp0, wr_ack_ocm_hp0, wr_dv_ocm_hp0, rd_req_ocm_hp0, rd_dv_ocm_hp0, wr_ack_ddr_hp1, wr_data_hp1, wr_addr_hp1, wr_bytes_hp1, wr_dv_ddr_hp1, rd_req_ddr_hp1, rd_addr_hp1, rd_bytes_hp1, rd_data_ddr_hp1, rd_data_ocm_hp1, rd_dv_ddr_hp1, wr_ack_ocm_hp1, wr_dv_ocm_hp1, rd_req_ocm_hp1, rd_dv_ocm_hp1, wr_ack_ddr_hp2, wr_data_hp2, wr_addr_hp2, wr_bytes_hp2, wr_dv_ddr_hp2, rd_req_ddr_hp2, rd_addr_hp2, rd_bytes_hp2, rd_data_ddr_hp2, rd_data_ocm_hp2, rd_dv_ddr_hp2, wr_ack_ocm_hp2, wr_dv_ocm_hp2, rd_req_ocm_hp2, rd_dv_ocm_hp2, wr_ack_ddr_hp3, wr_data_hp3, wr_addr_hp3, wr_bytes_hp3, wr_dv_ddr_hp3, rd_req_ddr_hp3, rd_addr_hp3, rd_bytes_hp3, rd_data_ocm_hp3, rd_data_ddr_hp3, rd_dv_ddr_hp3, wr_ack_ocm_hp3, wr_dv_ocm_hp3, rd_req_ocm_hp3, rd_dv_ocm_hp3, ddr_wr_ack0, ddr_wr_dv0, ddr_rd_req0, ddr_rd_dv0, ddr_rd_qos0, ddr_wr_qos0, ddr_wr_addr0, ddr_wr_data0, ddr_wr_bytes0, ddr_rd_addr0, ddr_rd_data0, ddr_rd_bytes0, ddr_wr_ack1, ddr_wr_dv1, ddr_rd_req1, ddr_rd_dv1, ddr_rd_qos1, ddr_wr_qos1, ddr_wr_addr1, ddr_wr_data1, ddr_wr_bytes1, ddr_rd_addr1, ddr_rd_data1, ddr_rd_bytes1, ocm_wr_ack, ocm_wr_dv, ocm_rd_req, ocm_rd_dv, ocm_wr_qos, ocm_rd_qos, ocm_wr_addr, ocm_wr_data, ocm_wr_bytes, ocm_rd_addr, ocm_rd_data, ocm_rd_bytes ); input sw_clk; input rstn; input [3:0] w_qos_hp0; input [3:0] r_qos_hp0; input [3:0] w_qos_hp1; input [3:0] r_qos_hp1; input [3:0] w_qos_hp2; input [3:0] r_qos_hp2; input [3:0] w_qos_hp3; input [3:0] r_qos_hp3; output [3:0] ddr_rd_qos0; output [3:0] ddr_wr_qos0; output [3:0] ddr_rd_qos1; output [3:0] ddr_wr_qos1; output [3:0] ocm_wr_qos; output [3:0] ocm_rd_qos; output wr_ack_ddr_hp0; input [1023:0] wr_data_hp0; input [31:0] wr_addr_hp0; input [7:0] wr_bytes_hp0; output wr_dv_ddr_hp0; input rd_req_ddr_hp0; input [31:0] rd_addr_hp0; input [7:0] rd_bytes_hp0; output [1023:0] rd_data_ddr_hp0; output rd_dv_ddr_hp0; output wr_ack_ddr_hp1; input [1023:0] wr_data_hp1; input [31:0] wr_addr_hp1; input [7:0] wr_bytes_hp1; output wr_dv_ddr_hp1; input rd_req_ddr_hp1; input [31:0] rd_addr_hp1; input [7:0] rd_bytes_hp1; output [1023:0] rd_data_ddr_hp1; output rd_dv_ddr_hp1; output wr_ack_ddr_hp2; input [1023:0] wr_data_hp2; input [31:0] wr_addr_hp2; input [7:0] wr_bytes_hp2; output wr_dv_ddr_hp2; input rd_req_ddr_hp2; input [31:0] rd_addr_hp2; input [7:0] rd_bytes_hp2; output [1023:0] rd_data_ddr_hp2; output rd_dv_ddr_hp2; output wr_ack_ddr_hp3; input [1023:0] wr_data_hp3; input [31:0] wr_addr_hp3; input [7:0] wr_bytes_hp3; output wr_dv_ddr_hp3; input rd_req_ddr_hp3; input [31:0] rd_addr_hp3; input [7:0] rd_bytes_hp3; output [1023:0] rd_data_ddr_hp3; output rd_dv_ddr_hp3; input ddr_wr_ack0; output ddr_wr_dv0; output [31:0]ddr_wr_addr0; output [1023:0]ddr_wr_data0; output [7:0]ddr_wr_bytes0; input ddr_rd_dv0; input [1023:0] ddr_rd_data0; output ddr_rd_req0; output [31:0] ddr_rd_addr0; output [7:0] ddr_rd_bytes0; input ddr_wr_ack1; output ddr_wr_dv1; output [31:0]ddr_wr_addr1; output [1023:0]ddr_wr_data1; output [7:0]ddr_wr_bytes1; input ddr_rd_dv1; input [1023:0] ddr_rd_data1; output ddr_rd_req1; output [31:0] ddr_rd_addr1; output [7:0] ddr_rd_bytes1; output wr_ack_ocm_hp0; input wr_dv_ocm_hp0; input rd_req_ocm_hp0; output rd_dv_ocm_hp0; output [1023:0] rd_data_ocm_hp0; output wr_ack_ocm_hp1; input wr_dv_ocm_hp1; input rd_req_ocm_hp1; output rd_dv_ocm_hp1; output [1023:0] rd_data_ocm_hp1; output wr_ack_ocm_hp2; input wr_dv_ocm_hp2; input rd_req_ocm_hp2; output rd_dv_ocm_hp2; output [1023:0] rd_data_ocm_hp2; output wr_ack_ocm_hp3; input wr_dv_ocm_hp3; input rd_req_ocm_hp3; output rd_dv_ocm_hp3; output [1023:0] rd_data_ocm_hp3; input ocm_wr_ack; output ocm_wr_dv; output [31:0]ocm_wr_addr; output [1023:0]ocm_wr_data; output [7:0]ocm_wr_bytes; input ocm_rd_dv; input [1023:0] ocm_rd_data; output ocm_rd_req; output [31:0] ocm_rd_addr; output [7:0] ocm_rd_bytes; /* FOR DDR */ processing_system7_bfm_v2_0_5_arb_hp0_1 ddr_hp01 ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp0(w_qos_hp0), .r_qos_hp0(r_qos_hp0), .w_qos_hp1(w_qos_hp1), .r_qos_hp1(r_qos_hp1), .wr_ack_ddr_hp0(wr_ack_ddr_hp0), .wr_data_hp0(wr_data_hp0), .wr_addr_hp0(wr_addr_hp0), .wr_bytes_hp0(wr_bytes_hp0), .wr_dv_ddr_hp0(wr_dv_ddr_hp0), .rd_req_ddr_hp0(rd_req_ddr_hp0), .rd_addr_hp0(rd_addr_hp0), .rd_bytes_hp0(rd_bytes_hp0), .rd_data_ddr_hp0(rd_data_ddr_hp0), .rd_dv_ddr_hp0(rd_dv_ddr_hp0), .wr_ack_ddr_hp1(wr_ack_ddr_hp1), .wr_data_hp1(wr_data_hp1), .wr_addr_hp1(wr_addr_hp1), .wr_bytes_hp1(wr_bytes_hp1), .wr_dv_ddr_hp1(wr_dv_ddr_hp1), .rd_req_ddr_hp1(rd_req_ddr_hp1), .rd_addr_hp1(rd_addr_hp1), .rd_bytes_hp1(rd_bytes_hp1), .rd_data_ddr_hp1(rd_data_ddr_hp1), .rd_dv_ddr_hp1(rd_dv_ddr_hp1), .ddr_wr_ack(ddr_wr_ack0), .ddr_wr_dv(ddr_wr_dv0), .ddr_rd_req(ddr_rd_req0), .ddr_rd_dv(ddr_rd_dv0), .ddr_rd_qos(ddr_rd_qos0), .ddr_wr_qos(ddr_wr_qos0), .ddr_wr_addr(ddr_wr_addr0), .ddr_wr_data(ddr_wr_data0), .ddr_wr_bytes(ddr_wr_bytes0), .ddr_rd_addr(ddr_rd_addr0), .ddr_rd_data(ddr_rd_data0), .ddr_rd_bytes(ddr_rd_bytes0) ); /* FOR DDR */ processing_system7_bfm_v2_0_5_arb_hp2_3 ddr_hp23 ( .sw_clk(sw_clk), .rstn(rstn), .w_qos_hp2(w_qos_hp2), .r_qos_hp2(r_qos_hp2), .w_qos_hp3(w_qos_hp3), .r_qos_hp3(r_qos_hp3), .wr_ack_ddr_hp2(wr_ack_ddr_hp2), .wr_data_hp2(wr_data_hp2), .wr_addr_hp2(wr_addr_hp2), .wr_bytes_hp2(wr_bytes_hp2), .wr_dv_ddr_hp2(wr_dv_ddr_hp2), .rd_req_ddr_hp2(rd_req_ddr_hp2), .rd_addr_hp2(rd_addr_hp2), .rd_bytes_hp2(rd_bytes_hp2), .rd_data_ddr_hp2(rd_data_ddr_hp2), .rd_dv_ddr_hp2(rd_dv_ddr_hp2), .wr_ack_ddr_hp3(wr_ack_ddr_hp3), .wr_data_hp3(wr_data_hp3), .wr_addr_hp3(wr_addr_hp3), .wr_bytes_hp3(wr_bytes_hp3), .wr_dv_ddr_hp3(wr_dv_ddr_hp3), .rd_req_ddr_hp3(rd_req_ddr_hp3), .rd_addr_hp3(rd_addr_hp3), .rd_bytes_hp3(rd_bytes_hp3), .rd_data_ddr_hp3(rd_data_ddr_hp3), .rd_dv_ddr_hp3(rd_dv_ddr_hp3), .ddr_wr_ack(ddr_wr_ack1), .ddr_wr_dv(ddr_wr_dv1), .ddr_rd_req(ddr_rd_req1), .ddr_rd_dv(ddr_rd_dv1), .ddr_rd_qos(ddr_rd_qos1), .ddr_wr_qos(ddr_wr_qos1), .ddr_wr_addr(ddr_wr_addr1), .ddr_wr_data(ddr_wr_data1), .ddr_wr_bytes(ddr_wr_bytes1), .ddr_rd_addr(ddr_rd_addr1), .ddr_rd_data(ddr_rd_data1), .ddr_rd_bytes(ddr_rd_bytes1) ); /* FOR OCM_WR */ processing_system7_bfm_v2_0_5_arb_wr_4 ocm_wr_hp( .rstn(rstn), .sw_clk(sw_clk), .qos1(w_qos_hp0), .qos2(w_qos_hp1), .qos3(w_qos_hp2), .qos4(w_qos_hp3), .prt_dv1(wr_dv_ocm_hp0), .prt_dv2(wr_dv_ocm_hp1), .prt_dv3(wr_dv_ocm_hp2), .prt_dv4(wr_dv_ocm_hp3), .prt_data1(wr_data_hp0), .prt_data2(wr_data_hp1), .prt_data3(wr_data_hp2), .prt_data4(wr_data_hp3), .prt_addr1(wr_addr_hp0), .prt_addr2(wr_addr_hp1), .prt_addr3(wr_addr_hp2), .prt_addr4(wr_addr_hp3), .prt_bytes1(wr_bytes_hp0), .prt_bytes2(wr_bytes_hp1), .prt_bytes3(wr_bytes_hp2), .prt_bytes4(wr_bytes_hp3), .prt_ack1(wr_ack_ocm_hp0), .prt_ack2(wr_ack_ocm_hp1), .prt_ack3(wr_ack_ocm_hp2), .prt_ack4(wr_ack_ocm_hp3), .prt_qos(ocm_wr_qos), .prt_req(ocm_wr_dv), .prt_data(ocm_wr_data), .prt_addr(ocm_wr_addr), .prt_bytes(ocm_wr_bytes), .prt_ack(ocm_wr_ack) ); /* FOR OCM_RD */ processing_system7_bfm_v2_0_5_arb_rd_4 ocm_rd_hp( .rstn(rstn), .sw_clk(sw_clk), .qos1(r_qos_hp0), .qos2(r_qos_hp1), .qos3(r_qos_hp2), .qos4(r_qos_hp3), .prt_req1(rd_req_ocm_hp0), .prt_req2(rd_req_ocm_hp1), .prt_req3(rd_req_ocm_hp2), .prt_req4(rd_req_ocm_hp3), .prt_data1(rd_data_ocm_hp0), .prt_data2(rd_data_ocm_hp1), .prt_data3(rd_data_ocm_hp2), .prt_data4(rd_data_ocm_hp3), .prt_addr1(rd_addr_hp0), .prt_addr2(rd_addr_hp1), .prt_addr3(rd_addr_hp2), .prt_addr4(rd_addr_hp3), .prt_bytes1(rd_bytes_hp0), .prt_bytes2(rd_bytes_hp1), .prt_bytes3(rd_bytes_hp2), .prt_bytes4(rd_bytes_hp3), .prt_dv1(rd_dv_ocm_hp0), .prt_dv2(rd_dv_ocm_hp1), .prt_dv3(rd_dv_ocm_hp2), .prt_dv4(rd_dv_ocm_hp3), .prt_qos(ocm_rd_qos), .prt_req(ocm_rd_req), .prt_data(ocm_rd_data), .prt_addr(ocm_rd_addr), .prt_bytes(ocm_rd_bytes), .prt_dv(ocm_rd_dv) ); endmodule

module processing_system7_bfm_v2_0_5_reg_map(); `include "processing_system7_bfm_v2_0_5_local_params.v" /* Register definitions */ `include "processing_system7_bfm_v2_0_5_reg_params.v" parameter mem_size = 32'h2000_0000; ///as the memory is implemented 4 byte wide parameter xsim_mem_size = 32'h1000_0000; ///as the memory is implemented 4 byte wide 256 MB `ifdef XSIM_ISIM reg [data_width-1:0] reg_mem0 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] reg_mem1 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem parameter addr_offset_bits = 26; `else reg /*sparse*/ [data_width-1:0] reg_mem [0:(mem_size/mem_width)-1]; // 512 MB needed for reg space parameter addr_offset_bits = 27; `endif /* preload reset_values from file */ task automatic pre_load_rst_values; input dummy; begin `include "processing_system7_bfm_v2_0_5_reg_init.v" /* This file has list of set_reset_data() calls to set the reset value for each register*/ end endtask /* writes the reset data into the reg memory */ task automatic set_reset_data; input [addr_width-1:0] address; input [data_width-1:0] data; reg [addr_width-1:0] addr; begin addr = address >> 2; `ifdef XSIM_ISIM case(addr[addr_width-1:addr_offset_bits]) 14 : reg_mem0[addr[addr_offset_bits-1:0]] = data; 15 : reg_mem1[addr[addr_offset_bits-1:0]] = data; endcase `else reg_mem[addr[addr_offset_bits-1:0]] = data; `endif end endtask /* writes the data into the reg memory */ task automatic set_data; input [addr_width-1:0] addr; input [data_width-1:0] data; begin `ifdef XSIM_ISIM case(addr[addr_width-1:addr_offset_bits]) 6'h0E : reg_mem0[addr[addr_offset_bits-1:0]] = data; 6'h0F : reg_mem1[addr[addr_offset_bits-1:0]] = data; endcase `else reg_mem[addr[addr_offset_bits-1:0]] = data; `endif end endtask /* get the read data from reg mem */ task automatic get_data; input [addr_width-1:0] addr; output [data_width-1:0] data; begin `ifdef XSIM_ISIM case(addr[addr_width-1:addr_offset_bits]) 6'h0E : data = reg_mem0[addr[addr_offset_bits-1:0]]; 6'h0F : data = reg_mem1[addr[addr_offset_bits-1:0]]; endcase `else data = reg_mem[addr[addr_offset_bits-1:0]]; `endif end endtask /* read chunk of registers */ task read_reg_mem; output[max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; integer i; reg [addr_width-1:0] addr; reg [data_width-1:0] temp_rd_data; reg [max_burst_bits-1:0] temp_data; integer bytes_left; begin addr = start_addr >> shft_addr_bits; bytes_left = no_of_bytes; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Reading Register Map starting address (0x%0h) -> %0d bytes",$time, DISP_INT_INFO, start_addr,no_of_bytes ); `endif /* Get first data ... if unaligned address */ get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits- data_width]); if(no_of_bytes < mem_width ) begin repeat(max_burst_bytes - mem_width) temp_data = temp_data >> 8; end else begin bytes_left = bytes_left - mem_width; addr = addr+1; /* Got first data */ while (bytes_left > (mem_width-1) ) begin temp_data = temp_data >> data_width; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); addr = addr+1; bytes_left = bytes_left - mem_width; end /* Get last valid data in the burst*/ get_data(addr,temp_rd_data); while(bytes_left > 0) begin temp_data = temp_data >> 8; temp_data[max_burst_bits-1 : max_burst_bits-8] = temp_rd_data[7:0]; temp_rd_data = temp_rd_data >> 8; bytes_left = bytes_left - 1; end /* align to the brst_byte length */ repeat(max_burst_bytes - no_of_bytes) temp_data = temp_data >> 8; end data = temp_data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Reading Register Map starting address (0x%0h), Data returned(0x%0h)",$time, DISP_INT_INFO, start_addr, data ); `endif end endtask initial begin pre_load_rst_values(1); end endmodule

module processing_system7_bfm_v2_0_5_processing_system7_bfm ( CAN0_PHY_TX, CAN0_PHY_RX, CAN1_PHY_TX, CAN1_PHY_RX, ENET0_GMII_TX_EN, ENET0_GMII_TX_ER, ENET0_MDIO_MDC, ENET0_MDIO_O, ENET0_MDIO_T, ENET0_PTP_DELAY_REQ_RX, ENET0_PTP_DELAY_REQ_TX, ENET0_PTP_PDELAY_REQ_RX, ENET0_PTP_PDELAY_REQ_TX, ENET0_PTP_PDELAY_RESP_RX, ENET0_PTP_PDELAY_RESP_TX, ENET0_PTP_SYNC_FRAME_RX, ENET0_PTP_SYNC_FRAME_TX, ENET0_SOF_RX, ENET0_SOF_TX, ENET0_GMII_TXD, ENET0_GMII_COL, ENET0_GMII_CRS, ENET0_EXT_INTIN, ENET0_GMII_RX_CLK, ENET0_GMII_RX_DV, ENET0_GMII_RX_ER, ENET0_GMII_TX_CLK, ENET0_MDIO_I, ENET0_GMII_RXD, ENET1_GMII_TX_EN, ENET1_GMII_TX_ER, ENET1_MDIO_MDC, ENET1_MDIO_O, ENET1_MDIO_T, ENET1_PTP_DELAY_REQ_RX, ENET1_PTP_DELAY_REQ_TX, ENET1_PTP_PDELAY_REQ_RX, ENET1_PTP_PDELAY_REQ_TX, ENET1_PTP_PDELAY_RESP_RX, ENET1_PTP_PDELAY_RESP_TX, ENET1_PTP_SYNC_FRAME_RX, ENET1_PTP_SYNC_FRAME_TX, ENET1_SOF_RX, ENET1_SOF_TX, ENET1_GMII_TXD, ENET1_GMII_COL, ENET1_GMII_CRS, ENET1_EXT_INTIN, ENET1_GMII_RX_CLK, ENET1_GMII_RX_DV, ENET1_GMII_RX_ER, ENET1_GMII_TX_CLK, ENET1_MDIO_I, ENET1_GMII_RXD, GPIO_I, GPIO_O, GPIO_T, I2C0_SDA_I, I2C0_SDA_O, I2C0_SDA_T, I2C0_SCL_I, I2C0_SCL_O, I2C0_SCL_T, I2C1_SDA_I, I2C1_SDA_O, I2C1_SDA_T, I2C1_SCL_I, I2C1_SCL_O, I2C1_SCL_T, PJTAG_TCK, PJTAG_TMS, PJTAG_TD_I, PJTAG_TD_T, PJTAG_TD_O, SDIO0_CLK, SDIO0_CLK_FB, SDIO0_CMD_O, SDIO0_CMD_I, SDIO0_CMD_T, SDIO0_DATA_I, SDIO0_DATA_O, SDIO0_DATA_T, SDIO0_LED, SDIO0_CDN, SDIO0_WP, SDIO0_BUSPOW, SDIO0_BUSVOLT, SDIO1_CLK, SDIO1_CLK_FB, SDIO1_CMD_O, SDIO1_CMD_I, SDIO1_CMD_T, SDIO1_DATA_I, SDIO1_DATA_O, SDIO1_DATA_T, SDIO1_LED, SDIO1_CDN, SDIO1_WP, SDIO1_BUSPOW, SDIO1_BUSVOLT, SPI0_SCLK_I, SPI0_SCLK_O, SPI0_SCLK_T, SPI0_MOSI_I, SPI0_MOSI_O, SPI0_MOSI_T, SPI0_MISO_I, SPI0_MISO_O, SPI0_MISO_T, SPI0_SS_I, SPI0_SS_O, SPI0_SS1_O, SPI0_SS2_O, SPI0_SS_T, SPI1_SCLK_I, SPI1_SCLK_O, SPI1_SCLK_T, SPI1_MOSI_I, SPI1_MOSI_O, SPI1_MOSI_T, SPI1_MISO_I, SPI1_MISO_O, SPI1_MISO_T, SPI1_SS_I, SPI1_SS_O, SPI1_SS1_O, SPI1_SS2_O, SPI1_SS_T, UART0_DTRN, UART0_RTSN, UART0_TX, UART0_CTSN, UART0_DCDN, UART0_DSRN, UART0_RIN, UART0_RX, UART1_DTRN, UART1_RTSN, UART1_TX, UART1_CTSN, UART1_DCDN, UART1_DSRN, UART1_RIN, UART1_RX, TTC0_WAVE0_OUT, TTC0_WAVE1_OUT, TTC0_WAVE2_OUT, TTC0_CLK0_IN, TTC0_CLK1_IN, TTC0_CLK2_IN, TTC1_WAVE0_OUT, TTC1_WAVE1_OUT, TTC1_WAVE2_OUT, TTC1_CLK0_IN, TTC1_CLK1_IN, TTC1_CLK2_IN, WDT_CLK_IN, WDT_RST_OUT, TRACE_CLK, TRACE_CTL, TRACE_DATA, USB0_PORT_INDCTL, USB1_PORT_INDCTL, USB0_VBUS_PWRSELECT, USB1_VBUS_PWRSELECT, USB0_VBUS_PWRFAULT, USB1_VBUS_PWRFAULT, SRAM_INTIN, M_AXI_GP0_ARVALID, M_AXI_GP0_AWVALID, M_AXI_GP0_BREADY, M_AXI_GP0_RREADY, M_AXI_GP0_WLAST, M_AXI_GP0_WVALID, M_AXI_GP0_ARID, M_AXI_GP0_AWID, M_AXI_GP0_WID, M_AXI_GP0_ARBURST, M_AXI_GP0_ARLOCK, M_AXI_GP0_ARSIZE, M_AXI_GP0_AWBURST, M_AXI_GP0_AWLOCK, M_AXI_GP0_AWSIZE, M_AXI_GP0_ARPROT, M_AXI_GP0_AWPROT, M_AXI_GP0_ARADDR, M_AXI_GP0_AWADDR, M_AXI_GP0_WDATA, M_AXI_GP0_ARCACHE, M_AXI_GP0_ARLEN, M_AXI_GP0_ARQOS, M_AXI_GP0_AWCACHE, M_AXI_GP0_AWLEN, M_AXI_GP0_AWQOS, M_AXI_GP0_WSTRB, M_AXI_GP0_ACLK, M_AXI_GP0_ARREADY, M_AXI_GP0_AWREADY, M_AXI_GP0_BVALID, M_AXI_GP0_RLAST, M_AXI_GP0_RVALID, M_AXI_GP0_WREADY, M_AXI_GP0_BID, M_AXI_GP0_RID, M_AXI_GP0_BRESP, M_AXI_GP0_RRESP, M_AXI_GP0_RDATA, M_AXI_GP1_ARVALID, M_AXI_GP1_AWVALID, M_AXI_GP1_BREADY, M_AXI_GP1_RREADY, M_AXI_GP1_WLAST, M_AXI_GP1_WVALID, M_AXI_GP1_ARID, M_AXI_GP1_AWID, M_AXI_GP1_WID, M_AXI_GP1_ARBURST, M_AXI_GP1_ARLOCK, M_AXI_GP1_ARSIZE, M_AXI_GP1_AWBURST, M_AXI_GP1_AWLOCK, M_AXI_GP1_AWSIZE, M_AXI_GP1_ARPROT, M_AXI_GP1_AWPROT, M_AXI_GP1_ARADDR, M_AXI_GP1_AWADDR, M_AXI_GP1_WDATA, M_AXI_GP1_ARCACHE, M_AXI_GP1_ARLEN, M_AXI_GP1_ARQOS, M_AXI_GP1_AWCACHE, M_AXI_GP1_AWLEN, M_AXI_GP1_AWQOS, M_AXI_GP1_WSTRB, M_AXI_GP1_ACLK, M_AXI_GP1_ARREADY, M_AXI_GP1_AWREADY, M_AXI_GP1_BVALID, M_AXI_GP1_RLAST, M_AXI_GP1_RVALID, M_AXI_GP1_WREADY, M_AXI_GP1_BID, M_AXI_GP1_RID, M_AXI_GP1_BRESP, M_AXI_GP1_RRESP, M_AXI_GP1_RDATA, S_AXI_GP0_ARREADY, S_AXI_GP0_AWREADY, S_AXI_GP0_BVALID, S_AXI_GP0_RLAST, S_AXI_GP0_RVALID, S_AXI_GP0_WREADY, S_AXI_GP0_BRESP, S_AXI_GP0_RRESP, S_AXI_GP0_RDATA, S_AXI_GP0_BID, S_AXI_GP0_RID, S_AXI_GP0_ACLK, S_AXI_GP0_ARVALID, S_AXI_GP0_AWVALID, S_AXI_GP0_BREADY, S_AXI_GP0_RREADY, S_AXI_GP0_WLAST, S_AXI_GP0_WVALID, S_AXI_GP0_ARBURST, S_AXI_GP0_ARLOCK, S_AXI_GP0_ARSIZE, S_AXI_GP0_AWBURST, S_AXI_GP0_AWLOCK, S_AXI_GP0_AWSIZE, S_AXI_GP0_ARPROT, S_AXI_GP0_AWPROT, S_AXI_GP0_ARADDR, S_AXI_GP0_AWADDR, S_AXI_GP0_WDATA, S_AXI_GP0_ARCACHE, S_AXI_GP0_ARLEN, S_AXI_GP0_ARQOS, S_AXI_GP0_AWCACHE, S_AXI_GP0_AWLEN, S_AXI_GP0_AWQOS, S_AXI_GP0_WSTRB, S_AXI_GP0_ARID, S_AXI_GP0_AWID, S_AXI_GP0_WID, S_AXI_GP1_ARREADY, S_AXI_GP1_AWREADY, S_AXI_GP1_BVALID, S_AXI_GP1_RLAST, S_AXI_GP1_RVALID, S_AXI_GP1_WREADY, S_AXI_GP1_BRESP, S_AXI_GP1_RRESP, S_AXI_GP1_RDATA, S_AXI_GP1_BID, S_AXI_GP1_RID, S_AXI_GP1_ACLK, S_AXI_GP1_ARVALID, S_AXI_GP1_AWVALID, S_AXI_GP1_BREADY, S_AXI_GP1_RREADY, S_AXI_GP1_WLAST, S_AXI_GP1_WVALID, S_AXI_GP1_ARBURST, S_AXI_GP1_ARLOCK, S_AXI_GP1_ARSIZE, S_AXI_GP1_AWBURST, S_AXI_GP1_AWLOCK, S_AXI_GP1_AWSIZE, S_AXI_GP1_ARPROT, S_AXI_GP1_AWPROT, S_AXI_GP1_ARADDR, S_AXI_GP1_AWADDR, S_AXI_GP1_WDATA, S_AXI_GP1_ARCACHE, S_AXI_GP1_ARLEN, S_AXI_GP1_ARQOS, S_AXI_GP1_AWCACHE, S_AXI_GP1_AWLEN, S_AXI_GP1_AWQOS, S_AXI_GP1_WSTRB, S_AXI_GP1_ARID, S_AXI_GP1_AWID, S_AXI_GP1_WID, S_AXI_ACP_AWREADY, S_AXI_ACP_ARREADY, S_AXI_ACP_BVALID, S_AXI_ACP_RLAST, S_AXI_ACP_RVALID, S_AXI_ACP_WREADY, S_AXI_ACP_BRESP, S_AXI_ACP_RRESP, S_AXI_ACP_BID, S_AXI_ACP_RID, S_AXI_ACP_RDATA, S_AXI_ACP_ACLK, S_AXI_ACP_ARVALID, S_AXI_ACP_AWVALID, S_AXI_ACP_BREADY, S_AXI_ACP_RREADY, S_AXI_ACP_WLAST, S_AXI_ACP_WVALID, S_AXI_ACP_ARID, S_AXI_ACP_ARPROT, S_AXI_ACP_AWID, S_AXI_ACP_AWPROT, S_AXI_ACP_WID, S_AXI_ACP_ARADDR, S_AXI_ACP_AWADDR, S_AXI_ACP_ARCACHE, S_AXI_ACP_ARLEN, S_AXI_ACP_ARQOS, S_AXI_ACP_AWCACHE, S_AXI_ACP_AWLEN, S_AXI_ACP_AWQOS, S_AXI_ACP_ARBURST, S_AXI_ACP_ARLOCK, S_AXI_ACP_ARSIZE, S_AXI_ACP_AWBURST, S_AXI_ACP_AWLOCK, S_AXI_ACP_AWSIZE, S_AXI_ACP_ARUSER, S_AXI_ACP_AWUSER, S_AXI_ACP_WDATA, S_AXI_ACP_WSTRB, S_AXI_HP0_ARREADY, S_AXI_HP0_AWREADY, S_AXI_HP0_BVALID, S_AXI_HP0_RLAST, S_AXI_HP0_RVALID, S_AXI_HP0_WREADY, S_AXI_HP0_BRESP, S_AXI_HP0_RRESP, S_AXI_HP0_BID, S_AXI_HP0_RID, S_AXI_HP0_RDATA, S_AXI_HP0_RCOUNT, S_AXI_HP0_WCOUNT, S_AXI_HP0_RACOUNT, S_AXI_HP0_WACOUNT, S_AXI_HP0_ACLK, S_AXI_HP0_ARVALID, S_AXI_HP0_AWVALID, S_AXI_HP0_BREADY, S_AXI_HP0_RDISSUECAP1_EN, S_AXI_HP0_RREADY, S_AXI_HP0_WLAST, S_AXI_HP0_WRISSUECAP1_EN, S_AXI_HP0_WVALID, S_AXI_HP0_ARBURST, S_AXI_HP0_ARLOCK, S_AXI_HP0_ARSIZE, S_AXI_HP0_AWBURST, S_AXI_HP0_AWLOCK, S_AXI_HP0_AWSIZE, S_AXI_HP0_ARPROT, S_AXI_HP0_AWPROT, S_AXI_HP0_ARADDR, S_AXI_HP0_AWADDR, S_AXI_HP0_ARCACHE, S_AXI_HP0_ARLEN, S_AXI_HP0_ARQOS, S_AXI_HP0_AWCACHE, S_AXI_HP0_AWLEN, S_AXI_HP0_AWQOS, S_AXI_HP0_ARID, S_AXI_HP0_AWID, S_AXI_HP0_WID, S_AXI_HP0_WDATA, S_AXI_HP0_WSTRB, S_AXI_HP1_ARREADY, S_AXI_HP1_AWREADY, S_AXI_HP1_BVALID, S_AXI_HP1_RLAST, S_AXI_HP1_RVALID, S_AXI_HP1_WREADY, S_AXI_HP1_BRESP, S_AXI_HP1_RRESP, S_AXI_HP1_BID, S_AXI_HP1_RID, S_AXI_HP1_RDATA, S_AXI_HP1_RCOUNT, S_AXI_HP1_WCOUNT, S_AXI_HP1_RACOUNT, S_AXI_HP1_WACOUNT, S_AXI_HP1_ACLK, S_AXI_HP1_ARVALID, S_AXI_HP1_AWVALID, S_AXI_HP1_BREADY, S_AXI_HP1_RDISSUECAP1_EN, S_AXI_HP1_RREADY, S_AXI_HP1_WLAST, S_AXI_HP1_WRISSUECAP1_EN, S_AXI_HP1_WVALID, S_AXI_HP1_ARBURST, S_AXI_HP1_ARLOCK, S_AXI_HP1_ARSIZE, S_AXI_HP1_AWBURST, S_AXI_HP1_AWLOCK, S_AXI_HP1_AWSIZE, S_AXI_HP1_ARPROT, S_AXI_HP1_AWPROT, S_AXI_HP1_ARADDR, S_AXI_HP1_AWADDR, S_AXI_HP1_ARCACHE, S_AXI_HP1_ARLEN, S_AXI_HP1_ARQOS, S_AXI_HP1_AWCACHE, S_AXI_HP1_AWLEN, S_AXI_HP1_AWQOS, S_AXI_HP1_ARID, S_AXI_HP1_AWID, S_AXI_HP1_WID, S_AXI_HP1_WDATA, S_AXI_HP1_WSTRB, S_AXI_HP2_ARREADY, S_AXI_HP2_AWREADY, S_AXI_HP2_BVALID, S_AXI_HP2_RLAST, S_AXI_HP2_RVALID, S_AXI_HP2_WREADY, S_AXI_HP2_BRESP, S_AXI_HP2_RRESP, S_AXI_HP2_BID, S_AXI_HP2_RID, S_AXI_HP2_RDATA, S_AXI_HP2_RCOUNT, S_AXI_HP2_WCOUNT, S_AXI_HP2_RACOUNT, S_AXI_HP2_WACOUNT, S_AXI_HP2_ACLK, S_AXI_HP2_ARVALID, S_AXI_HP2_AWVALID, S_AXI_HP2_BREADY, S_AXI_HP2_RDISSUECAP1_EN, S_AXI_HP2_RREADY, S_AXI_HP2_WLAST, S_AXI_HP2_WRISSUECAP1_EN, S_AXI_HP2_WVALID, S_AXI_HP2_ARBURST, S_AXI_HP2_ARLOCK, S_AXI_HP2_ARSIZE, S_AXI_HP2_AWBURST, S_AXI_HP2_AWLOCK, S_AXI_HP2_AWSIZE, S_AXI_HP2_ARPROT, S_AXI_HP2_AWPROT, S_AXI_HP2_ARADDR, S_AXI_HP2_AWADDR, S_AXI_HP2_ARCACHE, S_AXI_HP2_ARLEN, S_AXI_HP2_ARQOS, S_AXI_HP2_AWCACHE, S_AXI_HP2_AWLEN, S_AXI_HP2_AWQOS, S_AXI_HP2_ARID, S_AXI_HP2_AWID, S_AXI_HP2_WID, S_AXI_HP2_WDATA, S_AXI_HP2_WSTRB, S_AXI_HP3_ARREADY, S_AXI_HP3_AWREADY, S_AXI_HP3_BVALID, S_AXI_HP3_RLAST, S_AXI_HP3_RVALID, S_AXI_HP3_WREADY, S_AXI_HP3_BRESP, S_AXI_HP3_RRESP, S_AXI_HP3_BID, S_AXI_HP3_RID, S_AXI_HP3_RDATA, S_AXI_HP3_RCOUNT, S_AXI_HP3_WCOUNT, S_AXI_HP3_RACOUNT, S_AXI_HP3_WACOUNT, S_AXI_HP3_ACLK, S_AXI_HP3_ARVALID, S_AXI_HP3_AWVALID, S_AXI_HP3_BREADY, S_AXI_HP3_RDISSUECAP1_EN, S_AXI_HP3_RREADY, S_AXI_HP3_WLAST, S_AXI_HP3_WRISSUECAP1_EN, S_AXI_HP3_WVALID, S_AXI_HP3_ARBURST, S_AXI_HP3_ARLOCK, S_AXI_HP3_ARSIZE, S_AXI_HP3_AWBURST, S_AXI_HP3_AWLOCK, S_AXI_HP3_AWSIZE, S_AXI_HP3_ARPROT, S_AXI_HP3_AWPROT, S_AXI_HP3_ARADDR, S_AXI_HP3_AWADDR, S_AXI_HP3_ARCACHE, S_AXI_HP3_ARLEN, S_AXI_HP3_ARQOS, S_AXI_HP3_AWCACHE, S_AXI_HP3_AWLEN, S_AXI_HP3_AWQOS, S_AXI_HP3_ARID, S_AXI_HP3_AWID, S_AXI_HP3_WID, S_AXI_HP3_WDATA, S_AXI_HP3_WSTRB, DMA0_DATYPE, DMA0_DAVALID, DMA0_DRREADY, DMA0_ACLK, DMA0_DAREADY, DMA0_DRLAST, DMA0_DRVALID, DMA0_DRTYPE, DMA1_DATYPE, DMA1_DAVALID, DMA1_DRREADY, DMA1_ACLK, DMA1_DAREADY, DMA1_DRLAST, DMA1_DRVALID, DMA1_DRTYPE, DMA2_DATYPE, DMA2_DAVALID, DMA2_DRREADY, DMA2_ACLK, DMA2_DAREADY, DMA2_DRLAST, DMA2_DRVALID, DMA3_DRVALID, DMA3_DATYPE, DMA3_DAVALID, DMA3_DRREADY, DMA3_ACLK, DMA3_DAREADY, DMA3_DRLAST, DMA2_DRTYPE, DMA3_DRTYPE, FTMD_TRACEIN_DATA, FTMD_TRACEIN_VALID, FTMD_TRACEIN_CLK, FTMD_TRACEIN_ATID, FTMT_F2P_TRIG, FTMT_F2P_TRIGACK, FTMT_F2P_DEBUG, FTMT_P2F_TRIGACK, FTMT_P2F_TRIG, FTMT_P2F_DEBUG, FCLK_CLK3, FCLK_CLK2, FCLK_CLK1, FCLK_CLK0, FCLK_CLKTRIG3_N, FCLK_CLKTRIG2_N, FCLK_CLKTRIG1_N, FCLK_CLKTRIG0_N, FCLK_RESET3_N, FCLK_RESET2_N, FCLK_RESET1_N, FCLK_RESET0_N, FPGA_IDLE_N, DDR_ARB, IRQ_F2P, Core0_nFIQ, Core0_nIRQ, Core1_nFIQ, Core1_nIRQ, EVENT_EVENTO, EVENT_STANDBYWFE, EVENT_STANDBYWFI, EVENT_EVENTI, MIO, DDR_Clk, DDR_Clk_n, DDR_CKE, DDR_CS_n, DDR_RAS_n, DDR_CAS_n, DDR_WEB, DDR_BankAddr, DDR_Addr, DDR_ODT, DDR_DRSTB, DDR_DQ, DDR_DM, DDR_DQS, DDR_DQS_n, DDR_VRN, DDR_VRP, PS_SRSTB, PS_CLK, PS_PORB, IRQ_P2F_DMAC_ABORT, IRQ_P2F_DMAC0, IRQ_P2F_DMAC1, IRQ_P2F_DMAC2, IRQ_P2F_DMAC3, IRQ_P2F_DMAC4, IRQ_P2F_DMAC5, IRQ_P2F_DMAC6, IRQ_P2F_DMAC7, IRQ_P2F_SMC, IRQ_P2F_QSPI, IRQ_P2F_CTI, IRQ_P2F_GPIO, IRQ_P2F_USB0, IRQ_P2F_ENET0, IRQ_P2F_ENET_WAKE0, IRQ_P2F_SDIO0, IRQ_P2F_I2C0, IRQ_P2F_SPI0, IRQ_P2F_UART0, IRQ_P2F_CAN0, IRQ_P2F_USB1, IRQ_P2F_ENET1, IRQ_P2F_ENET_WAKE1, IRQ_P2F_SDIO1, IRQ_P2F_I2C1, IRQ_P2F_SPI1, IRQ_P2F_UART1, IRQ_P2F_CAN1 ); /* parameters for gen_clk */ parameter C_FCLK_CLK0_FREQ = 50; parameter C_FCLK_CLK1_FREQ = 50; parameter C_FCLK_CLK3_FREQ = 50; parameter C_FCLK_CLK2_FREQ = 50; parameter C_HIGH_OCM_EN = 0; /* parameters for HP ports */ parameter C_USE_S_AXI_HP0 = 0; parameter C_USE_S_AXI_HP1 = 0; parameter C_USE_S_AXI_HP2 = 0; parameter C_USE_S_AXI_HP3 = 0; parameter C_S_AXI_HP0_DATA_WIDTH = 32; parameter C_S_AXI_HP1_DATA_WIDTH = 32; parameter C_S_AXI_HP2_DATA_WIDTH = 32; parameter C_S_AXI_HP3_DATA_WIDTH = 32; parameter C_M_AXI_GP0_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP1_THREAD_ID_WIDTH = 12; parameter C_M_AXI_GP0_ENABLE_STATIC_REMAP = 0; parameter C_M_AXI_GP1_ENABLE_STATIC_REMAP = 0; /* Do we need these parameter C_S_AXI_HP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP2_ENABLE_HIGHOCM = 0; parameter C_S_AXI_HP3_ENABLE_HIGHOCM = 0; */ parameter C_S_AXI_HP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP2_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP3_BASEADDR = 32'h0000_0000; parameter C_S_AXI_HP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP2_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_HP3_HIGHADDR = 32'hFFFF_FFFF; /* parameters for GP and ACP ports */ parameter C_USE_M_AXI_GP0 = 0; parameter C_USE_M_AXI_GP1 = 0; parameter C_USE_S_AXI_GP0 = 1; parameter C_USE_S_AXI_GP1 = 1; /* Do we need this? parameter C_M_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_M_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP0_ENABLE_HIGHOCM = 0; parameter C_S_AXI_GP1_ENABLE_HIGHOCM = 0; parameter C_S_AXI_ACP_ENABLE_HIGHOCM = 0;*/ parameter C_S_AXI_GP0_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP1_BASEADDR = 32'h0000_0000; parameter C_S_AXI_GP0_HIGHADDR = 32'hFFFF_FFFF; parameter C_S_AXI_GP1_HIGHADDR = 32'hFFFF_FFFF; parameter C_USE_S_AXI_ACP = 1; parameter C_S_AXI_ACP_BASEADDR = 32'h0000_0000; parameter C_S_AXI_ACP_HIGHADDR = 32'hFFFF_FFFF; `include "processing_system7_bfm_v2_0_5_local_params.v" output CAN0_PHY_TX; input CAN0_PHY_RX; output CAN1_PHY_TX; input CAN1_PHY_RX; output ENET0_GMII_TX_EN; output ENET0_GMII_TX_ER; output ENET0_MDIO_MDC; output ENET0_MDIO_O; output ENET0_MDIO_T; output ENET0_PTP_DELAY_REQ_RX; output ENET0_PTP_DELAY_REQ_TX; output ENET0_PTP_PDELAY_REQ_RX; output ENET0_PTP_PDELAY_REQ_TX; output ENET0_PTP_PDELAY_RESP_RX; output ENET0_PTP_PDELAY_RESP_TX; output ENET0_PTP_SYNC_FRAME_RX; output ENET0_PTP_SYNC_FRAME_TX; output ENET0_SOF_RX; output ENET0_SOF_TX; output [7:0] ENET0_GMII_TXD; input ENET0_GMII_COL; input ENET0_GMII_CRS; input ENET0_EXT_INTIN; input ENET0_GMII_RX_CLK; input ENET0_GMII_RX_DV; input ENET0_GMII_RX_ER; input ENET0_GMII_TX_CLK; input ENET0_MDIO_I; input [7:0] ENET0_GMII_RXD; output ENET1_GMII_TX_EN; output ENET1_GMII_TX_ER; output ENET1_MDIO_MDC; output ENET1_MDIO_O; output ENET1_MDIO_T; output ENET1_PTP_DELAY_REQ_RX; output ENET1_PTP_DELAY_REQ_TX; output ENET1_PTP_PDELAY_REQ_RX; output ENET1_PTP_PDELAY_REQ_TX; output ENET1_PTP_PDELAY_RESP_RX; output ENET1_PTP_PDELAY_RESP_TX; output ENET1_PTP_SYNC_FRAME_RX; output ENET1_PTP_SYNC_FRAME_TX; output ENET1_SOF_RX; output ENET1_SOF_TX; output [7:0] ENET1_GMII_TXD; input ENET1_GMII_COL; input ENET1_GMII_CRS; input ENET1_EXT_INTIN; input ENET1_GMII_RX_CLK; input ENET1_GMII_RX_DV; input ENET1_GMII_RX_ER; input ENET1_GMII_TX_CLK; input ENET1_MDIO_I; input [7:0] ENET1_GMII_RXD; input [63:0] GPIO_I; output [63:0] GPIO_O; output [63:0] GPIO_T; input I2C0_SDA_I; output I2C0_SDA_O; output I2C0_SDA_T; input I2C0_SCL_I; output I2C0_SCL_O; output I2C0_SCL_T; input I2C1_SDA_I; output I2C1_SDA_O; output I2C1_SDA_T; input I2C1_SCL_I; output I2C1_SCL_O; output I2C1_SCL_T; input PJTAG_TCK; input PJTAG_TMS; input PJTAG_TD_I; output PJTAG_TD_T; output PJTAG_TD_O; output SDIO0_CLK; input SDIO0_CLK_FB; output SDIO0_CMD_O; input SDIO0_CMD_I; output SDIO0_CMD_T; input [3:0] SDIO0_DATA_I; output [3:0] SDIO0_DATA_O; output [3:0] SDIO0_DATA_T; output SDIO0_LED; input SDIO0_CDN; input SDIO0_WP; output SDIO0_BUSPOW; output [2:0] SDIO0_BUSVOLT; output SDIO1_CLK; input SDIO1_CLK_FB; output SDIO1_CMD_O; input SDIO1_CMD_I; output SDIO1_CMD_T; input [3:0] SDIO1_DATA_I; output [3:0] SDIO1_DATA_O; output [3:0] SDIO1_DATA_T; output SDIO1_LED; input SDIO1_CDN; input SDIO1_WP; output SDIO1_BUSPOW; output [2:0] SDIO1_BUSVOLT; input SPI0_SCLK_I; output SPI0_SCLK_O; output SPI0_SCLK_T; input SPI0_MOSI_I; output SPI0_MOSI_O; output SPI0_MOSI_T; input SPI0_MISO_I; output SPI0_MISO_O; output SPI0_MISO_T; input SPI0_SS_I; output SPI0_SS_O; output SPI0_SS1_O; output SPI0_SS2_O; output SPI0_SS_T; input SPI1_SCLK_I; output SPI1_SCLK_O; output SPI1_SCLK_T; input SPI1_MOSI_I; output SPI1_MOSI_O; output SPI1_MOSI_T; input SPI1_MISO_I; output SPI1_MISO_O; output SPI1_MISO_T; input SPI1_SS_I; output SPI1_SS_O; output SPI1_SS1_O; output SPI1_SS2_O; output SPI1_SS_T; output UART0_DTRN; output UART0_RTSN; output UART0_TX; input UART0_CTSN; input UART0_DCDN; input UART0_DSRN; input UART0_RIN; input UART0_RX; output UART1_DTRN; output UART1_RTSN; output UART1_TX; input UART1_CTSN; input UART1_DCDN; input UART1_DSRN; input UART1_RIN; input UART1_RX; output TTC0_WAVE0_OUT; output TTC0_WAVE1_OUT; output TTC0_WAVE2_OUT; input TTC0_CLK0_IN; input TTC0_CLK1_IN; input TTC0_CLK2_IN; output TTC1_WAVE0_OUT; output TTC1_WAVE1_OUT; output TTC1_WAVE2_OUT; input TTC1_CLK0_IN; input TTC1_CLK1_IN; input TTC1_CLK2_IN; input WDT_CLK_IN; output WDT_RST_OUT; input TRACE_CLK; output TRACE_CTL; output [31:0] TRACE_DATA; output [1:0] USB0_PORT_INDCTL; output [1:0] USB1_PORT_INDCTL; output USB0_VBUS_PWRSELECT; output USB1_VBUS_PWRSELECT; input USB0_VBUS_PWRFAULT; input USB1_VBUS_PWRFAULT; input SRAM_INTIN; output M_AXI_GP0_ARVALID; output M_AXI_GP0_AWVALID; output M_AXI_GP0_BREADY; output M_AXI_GP0_RREADY; output M_AXI_GP0_WLAST; output M_AXI_GP0_WVALID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_ARID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_AWID; output [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_WID; output [1:0] M_AXI_GP0_ARBURST; output [1:0] M_AXI_GP0_ARLOCK; output [2:0] M_AXI_GP0_ARSIZE; output [1:0] M_AXI_GP0_AWBURST; output [1:0] M_AXI_GP0_AWLOCK; output [2:0] M_AXI_GP0_AWSIZE; output [2:0] M_AXI_GP0_ARPROT; output [2:0] M_AXI_GP0_AWPROT; output [31:0] M_AXI_GP0_ARADDR; output [31:0] M_AXI_GP0_AWADDR; output [31:0] M_AXI_GP0_WDATA; output [3:0] M_AXI_GP0_ARCACHE; output [3:0] M_AXI_GP0_ARLEN; output [3:0] M_AXI_GP0_ARQOS; output [3:0] M_AXI_GP0_AWCACHE; output [3:0] M_AXI_GP0_AWLEN; output [3:0] M_AXI_GP0_AWQOS; output [3:0] M_AXI_GP0_WSTRB; input M_AXI_GP0_ACLK; input M_AXI_GP0_ARREADY; input M_AXI_GP0_AWREADY; input M_AXI_GP0_BVALID; input M_AXI_GP0_RLAST; input M_AXI_GP0_RVALID; input M_AXI_GP0_WREADY; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_BID; input [C_M_AXI_GP0_THREAD_ID_WIDTH-1:0] M_AXI_GP0_RID; input [1:0] M_AXI_GP0_BRESP; input [1:0] M_AXI_GP0_RRESP; input [31:0] M_AXI_GP0_RDATA; output M_AXI_GP1_ARVALID; output M_AXI_GP1_AWVALID; output M_AXI_GP1_BREADY; output M_AXI_GP1_RREADY; output M_AXI_GP1_WLAST; output M_AXI_GP1_WVALID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_ARID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_AWID; output [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_WID; output [1:0] M_AXI_GP1_ARBURST; output [1:0] M_AXI_GP1_ARLOCK; output [2:0] M_AXI_GP1_ARSIZE; output [1:0] M_AXI_GP1_AWBURST; output [1:0] M_AXI_GP1_AWLOCK; output [2:0] M_AXI_GP1_AWSIZE; output [2:0] M_AXI_GP1_ARPROT; output [2:0] M_AXI_GP1_AWPROT; output [31:0] M_AXI_GP1_ARADDR; output [31:0] M_AXI_GP1_AWADDR; output [31:0] M_AXI_GP1_WDATA; output [3:0] M_AXI_GP1_ARCACHE; output [3:0] M_AXI_GP1_ARLEN; output [3:0] M_AXI_GP1_ARQOS; output [3:0] M_AXI_GP1_AWCACHE; output [3:0] M_AXI_GP1_AWLEN; output [3:0] M_AXI_GP1_AWQOS; output [3:0] M_AXI_GP1_WSTRB; input M_AXI_GP1_ACLK; input M_AXI_GP1_ARREADY; input M_AXI_GP1_AWREADY; input M_AXI_GP1_BVALID; input M_AXI_GP1_RLAST; input M_AXI_GP1_RVALID; input M_AXI_GP1_WREADY; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_BID; input [C_M_AXI_GP1_THREAD_ID_WIDTH-1:0] M_AXI_GP1_RID; input [1:0] M_AXI_GP1_BRESP; input [1:0] M_AXI_GP1_RRESP; input [31:0] M_AXI_GP1_RDATA; output S_AXI_GP0_ARREADY; output S_AXI_GP0_AWREADY; output S_AXI_GP0_BVALID; output S_AXI_GP0_RLAST; output S_AXI_GP0_RVALID; output S_AXI_GP0_WREADY; output [1:0] S_AXI_GP0_BRESP; output [1:0] S_AXI_GP0_RRESP; output [31:0] S_AXI_GP0_RDATA; output [5:0] S_AXI_GP0_BID; output [5:0] S_AXI_GP0_RID; input S_AXI_GP0_ACLK; input S_AXI_GP0_ARVALID; input S_AXI_GP0_AWVALID; input S_AXI_GP0_BREADY; input S_AXI_GP0_RREADY; input S_AXI_GP0_WLAST; input S_AXI_GP0_WVALID; input [1:0] S_AXI_GP0_ARBURST; input [1:0] S_AXI_GP0_ARLOCK; input [2:0] S_AXI_GP0_ARSIZE; input [1:0] S_AXI_GP0_AWBURST; input [1:0] S_AXI_GP0_AWLOCK; input [2:0] S_AXI_GP0_AWSIZE; input [2:0] S_AXI_GP0_ARPROT; input [2:0] S_AXI_GP0_AWPROT; input [31:0] S_AXI_GP0_ARADDR; input [31:0] S_AXI_GP0_AWADDR; input [31:0] S_AXI_GP0_WDATA; input [3:0] S_AXI_GP0_ARCACHE; input [3:0] S_AXI_GP0_ARLEN; input [3:0] S_AXI_GP0_ARQOS; input [3:0] S_AXI_GP0_AWCACHE; input [3:0] S_AXI_GP0_AWLEN; input [3:0] S_AXI_GP0_AWQOS; input [3:0] S_AXI_GP0_WSTRB; input [5:0] S_AXI_GP0_ARID; input [5:0] S_AXI_GP0_AWID; input [5:0] S_AXI_GP0_WID; output S_AXI_GP1_ARREADY; output S_AXI_GP1_AWREADY; output S_AXI_GP1_BVALID; output S_AXI_GP1_RLAST; output S_AXI_GP1_RVALID; output S_AXI_GP1_WREADY; output [1:0] S_AXI_GP1_BRESP; output [1:0] S_AXI_GP1_RRESP; output [31:0] S_AXI_GP1_RDATA; output [5:0] S_AXI_GP1_BID; output [5:0] S_AXI_GP1_RID; input S_AXI_GP1_ACLK; input S_AXI_GP1_ARVALID; input S_AXI_GP1_AWVALID; input S_AXI_GP1_BREADY; input S_AXI_GP1_RREADY; input S_AXI_GP1_WLAST; input S_AXI_GP1_WVALID; input [1:0] S_AXI_GP1_ARBURST; input [1:0] S_AXI_GP1_ARLOCK; input [2:0] S_AXI_GP1_ARSIZE; input [1:0] S_AXI_GP1_AWBURST; input [1:0] S_AXI_GP1_AWLOCK; input [2:0] S_AXI_GP1_AWSIZE; input [2:0] S_AXI_GP1_ARPROT; input [2:0] S_AXI_GP1_AWPROT; input [31:0] S_AXI_GP1_ARADDR; input [31:0] S_AXI_GP1_AWADDR; input [31:0] S_AXI_GP1_WDATA; input [3:0] S_AXI_GP1_ARCACHE; input [3:0] S_AXI_GP1_ARLEN; input [3:0] S_AXI_GP1_ARQOS; input [3:0] S_AXI_GP1_AWCACHE; input [3:0] S_AXI_GP1_AWLEN; input [3:0] S_AXI_GP1_AWQOS; input [3:0] S_AXI_GP1_WSTRB; input [5:0] S_AXI_GP1_ARID; input [5:0] S_AXI_GP1_AWID; input [5:0] S_AXI_GP1_WID; output S_AXI_ACP_AWREADY; output S_AXI_ACP_ARREADY; output S_AXI_ACP_BVALID; output S_AXI_ACP_RLAST; output S_AXI_ACP_RVALID; output S_AXI_ACP_WREADY; output [1:0] S_AXI_ACP_BRESP; output [1:0] S_AXI_ACP_RRESP; output [2:0] S_AXI_ACP_BID; output [2:0] S_AXI_ACP_RID; output [63:0] S_AXI_ACP_RDATA; input S_AXI_ACP_ACLK; input S_AXI_ACP_ARVALID; input S_AXI_ACP_AWVALID; input S_AXI_ACP_BREADY; input S_AXI_ACP_RREADY; input S_AXI_ACP_WLAST; input S_AXI_ACP_WVALID; input [2:0] S_AXI_ACP_ARID; input [2:0] S_AXI_ACP_ARPROT; input [2:0] S_AXI_ACP_AWID; input [2:0] S_AXI_ACP_AWPROT; input [2:0] S_AXI_ACP_WID; input [31:0] S_AXI_ACP_ARADDR; input [31:0] S_AXI_ACP_AWADDR; input [3:0] S_AXI_ACP_ARCACHE; input [3:0] S_AXI_ACP_ARLEN; input [3:0] S_AXI_ACP_ARQOS; input [3:0] S_AXI_ACP_AWCACHE; input [3:0] S_AXI_ACP_AWLEN; input [3:0] S_AXI_ACP_AWQOS; input [1:0] S_AXI_ACP_ARBURST; input [1:0] S_AXI_ACP_ARLOCK; input [2:0] S_AXI_ACP_ARSIZE; input [1:0] S_AXI_ACP_AWBURST; input [1:0] S_AXI_ACP_AWLOCK; input [2:0] S_AXI_ACP_AWSIZE; input [4:0] S_AXI_ACP_ARUSER; input [4:0] S_AXI_ACP_AWUSER; input [63:0] S_AXI_ACP_WDATA; input [7:0] S_AXI_ACP_WSTRB; output S_AXI_HP0_ARREADY; output S_AXI_HP0_AWREADY; output S_AXI_HP0_BVALID; output S_AXI_HP0_RLAST; output S_AXI_HP0_RVALID; output S_AXI_HP0_WREADY; output [1:0] S_AXI_HP0_BRESP; output [1:0] S_AXI_HP0_RRESP; output [5:0] S_AXI_HP0_BID; output [5:0] S_AXI_HP0_RID; output [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_RDATA; output [7:0] S_AXI_HP0_RCOUNT; output [7:0] S_AXI_HP0_WCOUNT; output [2:0] S_AXI_HP0_RACOUNT; output [5:0] S_AXI_HP0_WACOUNT; input S_AXI_HP0_ACLK; input S_AXI_HP0_ARVALID; input S_AXI_HP0_AWVALID; input S_AXI_HP0_BREADY; input S_AXI_HP0_RDISSUECAP1_EN; input S_AXI_HP0_RREADY; input S_AXI_HP0_WLAST; input S_AXI_HP0_WRISSUECAP1_EN; input S_AXI_HP0_WVALID; input [1:0] S_AXI_HP0_ARBURST; input [1:0] S_AXI_HP0_ARLOCK; input [2:0] S_AXI_HP0_ARSIZE; input [1:0] S_AXI_HP0_AWBURST; input [1:0] S_AXI_HP0_AWLOCK; input [2:0] S_AXI_HP0_AWSIZE; input [2:0] S_AXI_HP0_ARPROT; input [2:0] S_AXI_HP0_AWPROT; input [31:0] S_AXI_HP0_ARADDR; input [31:0] S_AXI_HP0_AWADDR; input [3:0] S_AXI_HP0_ARCACHE; input [3:0] S_AXI_HP0_ARLEN; input [3:0] S_AXI_HP0_ARQOS; input [3:0] S_AXI_HP0_AWCACHE; input [3:0] S_AXI_HP0_AWLEN; input [3:0] S_AXI_HP0_AWQOS; input [5:0] S_AXI_HP0_ARID; input [5:0] S_AXI_HP0_AWID; input [5:0] S_AXI_HP0_WID; input [C_S_AXI_HP0_DATA_WIDTH-1:0] S_AXI_HP0_WDATA; input [C_S_AXI_HP0_DATA_WIDTH/8-1:0] S_AXI_HP0_WSTRB; output S_AXI_HP1_ARREADY; output S_AXI_HP1_AWREADY; output S_AXI_HP1_BVALID; output S_AXI_HP1_RLAST; output S_AXI_HP1_RVALID; output S_AXI_HP1_WREADY; output [1:0] S_AXI_HP1_BRESP; output [1:0] S_AXI_HP1_RRESP; output [5:0] S_AXI_HP1_BID; output [5:0] S_AXI_HP1_RID; output [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_RDATA; output [7:0] S_AXI_HP1_RCOUNT; output [7:0] S_AXI_HP1_WCOUNT; output [2:0] S_AXI_HP1_RACOUNT; output [5:0] S_AXI_HP1_WACOUNT; input S_AXI_HP1_ACLK; input S_AXI_HP1_ARVALID; input S_AXI_HP1_AWVALID; input S_AXI_HP1_BREADY; input S_AXI_HP1_RDISSUECAP1_EN; input S_AXI_HP1_RREADY; input S_AXI_HP1_WLAST; input S_AXI_HP1_WRISSUECAP1_EN; input S_AXI_HP1_WVALID; input [1:0] S_AXI_HP1_ARBURST; input [1:0] S_AXI_HP1_ARLOCK; input [2:0] S_AXI_HP1_ARSIZE; input [1:0] S_AXI_HP1_AWBURST; input [1:0] S_AXI_HP1_AWLOCK; input [2:0] S_AXI_HP1_AWSIZE; input [2:0] S_AXI_HP1_ARPROT; input [2:0] S_AXI_HP1_AWPROT; input [31:0] S_AXI_HP1_ARADDR; input [31:0] S_AXI_HP1_AWADDR; input [3:0] S_AXI_HP1_ARCACHE; input [3:0] S_AXI_HP1_ARLEN; input [3:0] S_AXI_HP1_ARQOS; input [3:0] S_AXI_HP1_AWCACHE; input [3:0] S_AXI_HP1_AWLEN; input [3:0] S_AXI_HP1_AWQOS; input [5:0] S_AXI_HP1_ARID; input [5:0] S_AXI_HP1_AWID; input [5:0] S_AXI_HP1_WID; input [C_S_AXI_HP1_DATA_WIDTH-1:0] S_AXI_HP1_WDATA; input [C_S_AXI_HP1_DATA_WIDTH/8-1:0] S_AXI_HP1_WSTRB; output S_AXI_HP2_ARREADY; output S_AXI_HP2_AWREADY; output S_AXI_HP2_BVALID; output S_AXI_HP2_RLAST; output S_AXI_HP2_RVALID; output S_AXI_HP2_WREADY; output [1:0] S_AXI_HP2_BRESP; output [1:0] S_AXI_HP2_RRESP; output [5:0] S_AXI_HP2_BID; output [5:0] S_AXI_HP2_RID; output [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_RDATA; output [7:0] S_AXI_HP2_RCOUNT; output [7:0] S_AXI_HP2_WCOUNT; output [2:0] S_AXI_HP2_RACOUNT; output [5:0] S_AXI_HP2_WACOUNT; input S_AXI_HP2_ACLK; input S_AXI_HP2_ARVALID; input S_AXI_HP2_AWVALID; input S_AXI_HP2_BREADY; input S_AXI_HP2_RDISSUECAP1_EN; input S_AXI_HP2_RREADY; input S_AXI_HP2_WLAST; input S_AXI_HP2_WRISSUECAP1_EN; input S_AXI_HP2_WVALID; input [1:0] S_AXI_HP2_ARBURST; input [1:0] S_AXI_HP2_ARLOCK; input [2:0] S_AXI_HP2_ARSIZE; input [1:0] S_AXI_HP2_AWBURST; input [1:0] S_AXI_HP2_AWLOCK; input [2:0] S_AXI_HP2_AWSIZE; input [2:0] S_AXI_HP2_ARPROT; input [2:0] S_AXI_HP2_AWPROT; input [31:0] S_AXI_HP2_ARADDR; input [31:0] S_AXI_HP2_AWADDR; input [3:0] S_AXI_HP2_ARCACHE; input [3:0] S_AXI_HP2_ARLEN; input [3:0] S_AXI_HP2_ARQOS; input [3:0] S_AXI_HP2_AWCACHE; input [3:0] S_AXI_HP2_AWLEN; input [3:0] S_AXI_HP2_AWQOS; input [5:0] S_AXI_HP2_ARID; input [5:0] S_AXI_HP2_AWID; input [5:0] S_AXI_HP2_WID; input [C_S_AXI_HP2_DATA_WIDTH-1:0] S_AXI_HP2_WDATA; input [C_S_AXI_HP2_DATA_WIDTH/8-1:0] S_AXI_HP2_WSTRB; output S_AXI_HP3_ARREADY; output S_AXI_HP3_AWREADY; output S_AXI_HP3_BVALID; output S_AXI_HP3_RLAST; output S_AXI_HP3_RVALID; output S_AXI_HP3_WREADY; output [1:0] S_AXI_HP3_BRESP; output [1:0] S_AXI_HP3_RRESP; output [5:0] S_AXI_HP3_BID; output [5:0] S_AXI_HP3_RID; output [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_RDATA; output [7:0] S_AXI_HP3_RCOUNT; output [7:0] S_AXI_HP3_WCOUNT; output [2:0] S_AXI_HP3_RACOUNT; output [5:0] S_AXI_HP3_WACOUNT; input S_AXI_HP3_ACLK; input S_AXI_HP3_ARVALID; input S_AXI_HP3_AWVALID; input S_AXI_HP3_BREADY; input S_AXI_HP3_RDISSUECAP1_EN; input S_AXI_HP3_RREADY; input S_AXI_HP3_WLAST; input S_AXI_HP3_WRISSUECAP1_EN; input S_AXI_HP3_WVALID; input [1:0] S_AXI_HP3_ARBURST; input [1:0] S_AXI_HP3_ARLOCK; input [2:0] S_AXI_HP3_ARSIZE; input [1:0] S_AXI_HP3_AWBURST; input [1:0] S_AXI_HP3_AWLOCK; input [2:0] S_AXI_HP3_AWSIZE; input [2:0] S_AXI_HP3_ARPROT; input [2:0] S_AXI_HP3_AWPROT; input [31:0] S_AXI_HP3_ARADDR; input [31:0] S_AXI_HP3_AWADDR; input [3:0] S_AXI_HP3_ARCACHE; input [3:0] S_AXI_HP3_ARLEN; input [3:0] S_AXI_HP3_ARQOS; input [3:0] S_AXI_HP3_AWCACHE; input [3:0] S_AXI_HP3_AWLEN; input [3:0] S_AXI_HP3_AWQOS; input [5:0] S_AXI_HP3_ARID; input [5:0] S_AXI_HP3_AWID; input [5:0] S_AXI_HP3_WID; input [C_S_AXI_HP3_DATA_WIDTH-1:0] S_AXI_HP3_WDATA; input [C_S_AXI_HP3_DATA_WIDTH/8-1:0] S_AXI_HP3_WSTRB; output [1:0] DMA0_DATYPE; output DMA0_DAVALID; output DMA0_DRREADY; input DMA0_ACLK; input DMA0_DAREADY; input DMA0_DRLAST; input DMA0_DRVALID; input [1:0] DMA0_DRTYPE; output [1:0] DMA1_DATYPE; output DMA1_DAVALID; output DMA1_DRREADY; input DMA1_ACLK; input DMA1_DAREADY; input DMA1_DRLAST; input DMA1_DRVALID; input [1:0] DMA1_DRTYPE; output [1:0] DMA2_DATYPE; output DMA2_DAVALID; output DMA2_DRREADY; input DMA2_ACLK; input DMA2_DAREADY; input DMA2_DRLAST; input DMA2_DRVALID; input DMA3_DRVALID; output [1:0] DMA3_DATYPE; output DMA3_DAVALID; output DMA3_DRREADY; input DMA3_ACLK; input DMA3_DAREADY; input DMA3_DRLAST; input [1:0] DMA2_DRTYPE; input [1:0] DMA3_DRTYPE; input [31:0] FTMD_TRACEIN_DATA; input FTMD_TRACEIN_VALID; input FTMD_TRACEIN_CLK; input [3:0] FTMD_TRACEIN_ATID; input [3:0] FTMT_F2P_TRIG; output [3:0] FTMT_F2P_TRIGACK; input [31:0] FTMT_F2P_DEBUG; input [3:0] FTMT_P2F_TRIGACK; output [3:0] FTMT_P2F_TRIG; output [31:0] FTMT_P2F_DEBUG; output FCLK_CLK3; output FCLK_CLK2; output FCLK_CLK1; output FCLK_CLK0; input FCLK_CLKTRIG3_N; input FCLK_CLKTRIG2_N; input FCLK_CLKTRIG1_N; input FCLK_CLKTRIG0_N; output FCLK_RESET3_N; output FCLK_RESET2_N; output FCLK_RESET1_N; output FCLK_RESET0_N; input FPGA_IDLE_N; input [3:0] DDR_ARB; input [irq_width-1:0] IRQ_F2P; input Core0_nFIQ; input Core0_nIRQ; input Core1_nFIQ; input Core1_nIRQ; output EVENT_EVENTO; output [1:0] EVENT_STANDBYWFE; output [1:0] EVENT_STANDBYWFI; input EVENT_EVENTI; inout [53:0] MIO; inout DDR_Clk; inout DDR_Clk_n; inout DDR_CKE; inout DDR_CS_n; inout DDR_RAS_n; inout DDR_CAS_n; output DDR_WEB; inout [2:0] DDR_BankAddr; inout [14:0] DDR_Addr; inout DDR_ODT; inout DDR_DRSTB; inout [31:0] DDR_DQ; inout [3:0] DDR_DM; inout [3:0] DDR_DQS; inout [3:0] DDR_DQS_n; inout DDR_VRN; inout DDR_VRP; /* Reset Input & Clock Input */ input PS_SRSTB; input PS_CLK; input PS_PORB; output IRQ_P2F_DMAC_ABORT; output IRQ_P2F_DMAC0; output IRQ_P2F_DMAC1; output IRQ_P2F_DMAC2; output IRQ_P2F_DMAC3; output IRQ_P2F_DMAC4; output IRQ_P2F_DMAC5; output IRQ_P2F_DMAC6; output IRQ_P2F_DMAC7; output IRQ_P2F_SMC; output IRQ_P2F_QSPI; output IRQ_P2F_CTI; output IRQ_P2F_GPIO; output IRQ_P2F_USB0; output IRQ_P2F_ENET0; output IRQ_P2F_ENET_WAKE0; output IRQ_P2F_SDIO0; output IRQ_P2F_I2C0; output IRQ_P2F_SPI0; output IRQ_P2F_UART0; output IRQ_P2F_CAN0; output IRQ_P2F_USB1; output IRQ_P2F_ENET1; output IRQ_P2F_ENET_WAKE1; output IRQ_P2F_SDIO1; output IRQ_P2F_I2C1; output IRQ_P2F_SPI1; output IRQ_P2F_UART1; output IRQ_P2F_CAN1; /* Internal wires/nets used for connectivity */ wire net_rstn; wire net_sw_clk; wire net_ocm_clk; wire net_arbiter_clk; wire net_axi_mgp0_rstn; wire net_axi_mgp1_rstn; wire net_axi_gp0_rstn; wire net_axi_gp1_rstn; wire net_axi_hp0_rstn; wire net_axi_hp1_rstn; wire net_axi_hp2_rstn; wire net_axi_hp3_rstn; wire net_axi_acp_rstn; wire [4:0] net_axi_acp_awuser; wire [4:0] net_axi_acp_aruser; /* Dummy */ assign net_axi_acp_awuser = S_AXI_ACP_AWUSER; assign net_axi_acp_aruser = S_AXI_ACP_ARUSER; /* Global variables */ reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1; /* local variable acting as semaphore for wait_mem_update and wait_reg_update task */ reg mem_update_key = 1; reg reg_update_key_0 = 1; reg reg_update_key_1 = 1; /* assignments and semantic checks for unused ports */ `include "processing_system7_bfm_v2_0_5_unused_ports.v" /* include api definition */ `include "processing_system7_bfm_v2_0_5_apis.v" /* Reset Generator */ processing_system7_bfm_v2_0_5_gen_reset gen_rst(.por_rst_n(PS_PORB), .sys_rst_n(PS_SRSTB), .rst_out_n(net_rstn), .m_axi_gp0_clk(M_AXI_GP0_ACLK), .m_axi_gp1_clk(M_AXI_GP1_ACLK), .s_axi_gp0_clk(S_AXI_GP0_ACLK), .s_axi_gp1_clk(S_AXI_GP1_ACLK), .s_axi_hp0_clk(S_AXI_HP0_ACLK), .s_axi_hp1_clk(S_AXI_HP1_ACLK), .s_axi_hp2_clk(S_AXI_HP2_ACLK), .s_axi_hp3_clk(S_AXI_HP3_ACLK), .s_axi_acp_clk(S_AXI_ACP_ACLK), .m_axi_gp0_rstn(net_axi_mgp0_rstn), .m_axi_gp1_rstn(net_axi_mgp1_rstn), .s_axi_gp0_rstn(net_axi_gp0_rstn), .s_axi_gp1_rstn(net_axi_gp1_rstn), .s_axi_hp0_rstn(net_axi_hp0_rstn), .s_axi_hp1_rstn(net_axi_hp1_rstn), .s_axi_hp2_rstn(net_axi_hp2_rstn), .s_axi_hp3_rstn(net_axi_hp3_rstn), .s_axi_acp_rstn(net_axi_acp_rstn), .fclk_reset3_n(FCLK_RESET3_N), .fclk_reset2_n(FCLK_RESET2_N), .fclk_reset1_n(FCLK_RESET1_N), .fclk_reset0_n(FCLK_RESET0_N), .fpga_acp_reset_n(), ////S_AXI_ACP_ARESETN), (These are removed from Zynq IP) .fpga_gp_m0_reset_n(), ////M_AXI_GP0_ARESETN), .fpga_gp_m1_reset_n(), ////M_AXI_GP1_ARESETN), .fpga_gp_s0_reset_n(), ////S_AXI_GP0_ARESETN), .fpga_gp_s1_reset_n(), ////S_AXI_GP1_ARESETN), .fpga_hp_s0_reset_n(), ////S_AXI_HP0_ARESETN), .fpga_hp_s1_reset_n(), ////S_AXI_HP1_ARESETN), .fpga_hp_s2_reset_n(), ////S_AXI_HP2_ARESETN), .fpga_hp_s3_reset_n() ////S_AXI_HP3_ARESETN) ); /* Clock Generator */ processing_system7_bfm_v2_0_5_gen_clock #(C_FCLK_CLK3_FREQ, C_FCLK_CLK2_FREQ, C_FCLK_CLK1_FREQ, C_FCLK_CLK0_FREQ) gen_clk(.ps_clk(PS_CLK), .sw_clk(net_sw_clk), .fclk_clk3(FCLK_CLK3), .fclk_clk2(FCLK_CLK2), .fclk_clk1(FCLK_CLK1), .fclk_clk0(FCLK_CLK0) ); wire net_wr_ack_ocm_gp0, net_wr_ack_ddr_gp0, net_wr_ack_ocm_gp1, net_wr_ack_ddr_gp1; wire net_wr_dv_ocm_gp0, net_wr_dv_ddr_gp0, net_wr_dv_ocm_gp1, net_wr_dv_ddr_gp1; wire [max_burst_bits-1:0] net_wr_data_gp0, net_wr_data_gp1; wire [addr_width-1:0] net_wr_addr_gp0, net_wr_addr_gp1; wire [max_burst_bytes_width:0] net_wr_bytes_gp0, net_wr_bytes_gp1; wire [axi_qos_width-1:0] net_wr_qos_gp0, net_wr_qos_gp1; wire net_rd_req_ddr_gp0, net_rd_req_ddr_gp1; wire net_rd_req_ocm_gp0, net_rd_req_ocm_gp1; wire net_rd_req_reg_gp0, net_rd_req_reg_gp1; wire [addr_width-1:0] net_rd_addr_gp0, net_rd_addr_gp1; wire [max_burst_bytes_width:0] net_rd_bytes_gp0, net_rd_bytes_gp1; wire [max_burst_bits-1:0] net_rd_data_ddr_gp0, net_rd_data_ddr_gp1; wire [max_burst_bits-1:0] net_rd_data_ocm_gp0, net_rd_data_ocm_gp1; wire [max_burst_bits-1:0] net_rd_data_reg_gp0, net_rd_data_reg_gp1; wire net_rd_dv_ddr_gp0, net_rd_dv_ddr_gp1; wire net_rd_dv_ocm_gp0, net_rd_dv_ocm_gp1; wire net_rd_dv_reg_gp0, net_rd_dv_reg_gp1; wire [axi_qos_width-1:0] net_rd_qos_gp0, net_rd_qos_gp1; wire net_wr_ack_ddr_hp0, net_wr_ack_ddr_hp1, net_wr_ack_ddr_hp2, net_wr_ack_ddr_hp3; wire net_wr_ack_ocm_hp0, net_wr_ack_ocm_hp1, net_wr_ack_ocm_hp2, net_wr_ack_ocm_hp3; wire net_wr_dv_ddr_hp0, net_wr_dv_ddr_hp1, net_wr_dv_ddr_hp2, net_wr_dv_ddr_hp3; wire net_wr_dv_ocm_hp0, net_wr_dv_ocm_hp1, net_wr_dv_ocm_hp2, net_wr_dv_ocm_hp3; wire [max_burst_bits-1:0] net_wr_data_hp0, net_wr_data_hp1, net_wr_data_hp2, net_wr_data_hp3; wire [addr_width-1:0] net_wr_addr_hp0, net_wr_addr_hp1, net_wr_addr_hp2, net_wr_addr_hp3; wire [max_burst_bytes_width:0] net_wr_bytes_hp0, net_wr_bytes_hp1, net_wr_bytes_hp2, net_wr_bytes_hp3; wire [axi_qos_width-1:0] net_wr_qos_hp0, net_wr_qos_hp1, net_wr_qos_hp2, net_wr_qos_hp3; wire net_rd_req_ddr_hp0, net_rd_req_ddr_hp1, net_rd_req_ddr_hp2, net_rd_req_ddr_hp3; wire net_rd_req_ocm_hp0, net_rd_req_ocm_hp1, net_rd_req_ocm_hp2, net_rd_req_ocm_hp3; wire [addr_width-1:0] net_rd_addr_hp0, net_rd_addr_hp1, net_rd_addr_hp2, net_rd_addr_hp3; wire [max_burst_bytes_width:0] net_rd_bytes_hp0, net_rd_bytes_hp1, net_rd_bytes_hp2, net_rd_bytes_hp3; wire [max_burst_bits-1:0] net_rd_data_ddr_hp0, net_rd_data_ddr_hp1, net_rd_data_ddr_hp2, net_rd_data_ddr_hp3; wire [max_burst_bits-1:0] net_rd_data_ocm_hp0, net_rd_data_ocm_hp1, net_rd_data_ocm_hp2, net_rd_data_ocm_hp3; wire net_rd_dv_ddr_hp0, net_rd_dv_ddr_hp1, net_rd_dv_ddr_hp2, net_rd_dv_ddr_hp3; wire net_rd_dv_ocm_hp0, net_rd_dv_ocm_hp1, net_rd_dv_ocm_hp2, net_rd_dv_ocm_hp3; wire [axi_qos_width-1:0] net_rd_qos_hp0, net_rd_qos_hp1, net_rd_qos_hp2, net_rd_qos_hp3; wire net_wr_ack_ddr_acp,net_wr_ack_ocm_acp; wire net_wr_dv_ddr_acp,net_wr_dv_ocm_acp; wire [max_burst_bits-1:0] net_wr_data_acp; wire [addr_width-1:0] net_wr_addr_acp; wire [max_burst_bytes_width:0] net_wr_bytes_acp; wire [axi_qos_width-1:0] net_wr_qos_acp; wire net_rd_req_ddr_acp, net_rd_req_ocm_acp; wire [addr_width-1:0] net_rd_addr_acp; wire [max_burst_bytes_width:0] net_rd_bytes_acp; wire [max_burst_bits-1:0] net_rd_data_ddr_acp; wire [max_burst_bits-1:0] net_rd_data_ocm_acp; wire net_rd_dv_ddr_acp,net_rd_dv_ocm_acp; wire [axi_qos_width-1:0] net_rd_qos_acp; wire ocm_wr_ack_port0; wire ocm_wr_dv_port0; wire ocm_rd_req_port0; wire ocm_rd_dv_port0; wire [addr_width-1:0] ocm_wr_addr_port0; wire [max_burst_bits-1:0] ocm_wr_data_port0; wire [max_burst_bytes_width:0] ocm_wr_bytes_port0; wire [addr_width-1:0] ocm_rd_addr_port0; wire [max_burst_bits-1:0] ocm_rd_data_port0; wire [max_burst_bytes_width:0] ocm_rd_bytes_port0; wire [axi_qos_width-1:0] ocm_wr_qos_port0; wire [axi_qos_width-1:0] ocm_rd_qos_port0; wire ocm_wr_ack_port1; wire ocm_wr_dv_port1; wire ocm_rd_req_port1; wire ocm_rd_dv_port1; wire [addr_width-1:0] ocm_wr_addr_port1; wire [max_burst_bits-1:0] ocm_wr_data_port1; wire [max_burst_bytes_width:0] ocm_wr_bytes_port1; wire [addr_width-1:0] ocm_rd_addr_port1; wire [max_burst_bits-1:0] ocm_rd_data_port1; wire [max_burst_bytes_width:0] ocm_rd_bytes_port1; wire [axi_qos_width-1:0] ocm_wr_qos_port1; wire [axi_qos_width-1:0] ocm_rd_qos_port1; wire ddr_wr_ack_port0; wire ddr_wr_dv_port0; wire ddr_rd_req_port0; wire ddr_rd_dv_port0; wire[addr_width-1:0] ddr_wr_addr_port0; wire[max_burst_bits-1:0] ddr_wr_data_port0; wire[max_burst_bytes_width:0] ddr_wr_bytes_port0; wire[addr_width-1:0] ddr_rd_addr_port0; wire[max_burst_bits-1:0] ddr_rd_data_port0; wire[max_burst_bytes_width:0] ddr_rd_bytes_port0; wire [axi_qos_width-1:0] ddr_wr_qos_port0; wire [axi_qos_width-1:0] ddr_rd_qos_port0; wire ddr_wr_ack_port1; wire ddr_wr_dv_port1; wire ddr_rd_req_port1; wire ddr_rd_dv_port1; wire[addr_width-1:0] ddr_wr_addr_port1; wire[max_burst_bits-1:0] ddr_wr_data_port1; wire[max_burst_bytes_width:0] ddr_wr_bytes_port1; wire[addr_width-1:0] ddr_rd_addr_port1; wire[max_burst_bits-1:0] ddr_rd_data_port1; wire[max_burst_bytes_width:0] ddr_rd_bytes_port1; wire[axi_qos_width-1:0] ddr_wr_qos_port1; wire[axi_qos_width-1:0] ddr_rd_qos_port1; wire ddr_wr_ack_port2; wire ddr_wr_dv_port2; wire ddr_rd_req_port2; wire ddr_rd_dv_port2; wire[addr_width-1:0] ddr_wr_addr_port2; wire[max_burst_bits-1:0] ddr_wr_data_port2; wire[max_burst_bytes_width:0] ddr_wr_bytes_port2; wire[addr_width-1:0] ddr_rd_addr_port2; wire[max_burst_bits-1:0] ddr_rd_data_port2; wire[max_burst_bytes_width:0] ddr_rd_bytes_port2; wire[axi_qos_width-1:0] ddr_wr_qos_port2; wire[axi_qos_width-1:0] ddr_rd_qos_port2; wire ddr_wr_ack_port3; wire ddr_wr_dv_port3; wire ddr_rd_req_port3; wire ddr_rd_dv_port3; wire[addr_width-1:0] ddr_wr_addr_port3; wire[max_burst_bits-1:0] ddr_wr_data_port3; wire[max_burst_bytes_width:0] ddr_wr_bytes_port3; wire[addr_width-1:0] ddr_rd_addr_port3; wire[max_burst_bits-1:0] ddr_rd_data_port3; wire[max_burst_bytes_width:0] ddr_rd_bytes_port3; wire[axi_qos_width-1:0] ddr_wr_qos_port3; wire[axi_qos_width-1:0] ddr_rd_qos_port3; wire reg_rd_req_port0; wire reg_rd_dv_port0; wire[addr_width-1:0] reg_rd_addr_port0; wire[max_burst_bits-1:0] reg_rd_data_port0; wire[max_burst_bytes_width:0] reg_rd_bytes_port0; wire [axi_qos_width-1:0] reg_rd_qos_port0; wire reg_rd_req_port1; wire reg_rd_dv_port1; wire[addr_width-1:0] reg_rd_addr_port1; wire[max_burst_bits-1:0] reg_rd_data_port1; wire[max_burst_bytes_width:0] reg_rd_bytes_port1; wire [axi_qos_width-1:0] reg_rd_qos_port1; wire [11:0] M_AXI_GP0_AWID_FULL; wire [11:0] M_AXI_GP0_WID_FULL; wire [11:0] M_AXI_GP0_ARID_FULL; wire [11:0] M_AXI_GP0_BID_FULL; wire [11:0] M_AXI_GP0_RID_FULL; wire [11:0] M_AXI_GP1_AWID_FULL; wire [11:0] M_AXI_GP1_WID_FULL; wire [11:0] M_AXI_GP1_ARID_FULL; wire [11:0] M_AXI_GP1_BID_FULL; wire [11:0] M_AXI_GP1_RID_FULL; function [5:0] compress_id; input [11:0] id; begin compress_id = id[5:0]; end endfunction function [11:0] uncompress_id; input [5:0] id; begin uncompress_id = {6'b110000, id[5:0]}; end endfunction assign M_AXI_GP0_AWID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_AWID_FULL) : M_AXI_GP0_AWID_FULL; assign M_AXI_GP0_WID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_WID_FULL) : M_AXI_GP0_WID_FULL; assign M_AXI_GP0_ARID = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP0_ARID_FULL) : M_AXI_GP0_ARID_FULL; assign M_AXI_GP0_BID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_BID) : M_AXI_GP0_BID; assign M_AXI_GP0_RID_FULL = (C_M_AXI_GP0_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP0_RID) : M_AXI_GP0_RID; assign M_AXI_GP1_AWID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_AWID_FULL) : M_AXI_GP1_AWID_FULL; assign M_AXI_GP1_WID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_WID_FULL) : M_AXI_GP1_WID_FULL; assign M_AXI_GP1_ARID = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? compress_id(M_AXI_GP1_ARID_FULL) : M_AXI_GP1_ARID_FULL; assign M_AXI_GP1_BID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_BID) : M_AXI_GP1_BID; assign M_AXI_GP1_RID_FULL = (C_M_AXI_GP1_ENABLE_STATIC_REMAP == 1) ? uncompress_id(M_AXI_GP1_RID) : M_AXI_GP1_RID; processing_system7_bfm_v2_0_5_interconnect_model icm ( .rstn(net_rstn), .sw_clk(net_sw_clk), .w_qos_gp0(net_wr_qos_gp0), .w_qos_gp1(net_wr_qos_gp1), .w_qos_hp0(net_wr_qos_hp0), .w_qos_hp1(net_wr_qos_hp1), .w_qos_hp2(net_wr_qos_hp2), .w_qos_hp3(net_wr_qos_hp3), .r_qos_gp0(net_rd_qos_gp0), .r_qos_gp1(net_rd_qos_gp1), .r_qos_hp0(net_rd_qos_hp0), .r_qos_hp1(net_rd_qos_hp1), .r_qos_hp2(net_rd_qos_hp2), .r_qos_hp3(net_rd_qos_hp3), /* GP Slave ports access */ .wr_ack_ddr_gp0(net_wr_ack_ddr_gp0), .wr_ack_ocm_gp0(net_wr_ack_ocm_gp0), .wr_data_gp0(net_wr_data_gp0), .wr_addr_gp0(net_wr_addr_gp0), .wr_bytes_gp0(net_wr_bytes_gp0), .wr_dv_ddr_gp0(net_wr_dv_ddr_gp0), .wr_dv_ocm_gp0(net_wr_dv_ocm_gp0), .rd_req_ddr_gp0(net_rd_req_ddr_gp0), .rd_req_ocm_gp0(net_rd_req_ocm_gp0), .rd_req_reg_gp0(net_rd_req_reg_gp0), .rd_addr_gp0(net_rd_addr_gp0), .rd_bytes_gp0(net_rd_bytes_gp0), .rd_data_ddr_gp0(net_rd_data_ddr_gp0), .rd_data_ocm_gp0(net_rd_data_ocm_gp0), .rd_data_reg_gp0(net_rd_data_reg_gp0), .rd_dv_ddr_gp0(net_rd_dv_ddr_gp0), .rd_dv_ocm_gp0(net_rd_dv_ocm_gp0), .rd_dv_reg_gp0(net_rd_dv_reg_gp0), .wr_ack_ddr_gp1(net_wr_ack_ddr_gp1), .wr_ack_ocm_gp1(net_wr_ack_ocm_gp1), .wr_data_gp1(net_wr_data_gp1), .wr_addr_gp1(net_wr_addr_gp1), .wr_bytes_gp1(net_wr_bytes_gp1), .wr_dv_ddr_gp1(net_wr_dv_ddr_gp1), .wr_dv_ocm_gp1(net_wr_dv_ocm_gp1), .rd_req_ddr_gp1(net_rd_req_ddr_gp1), .rd_req_ocm_gp1(net_rd_req_ocm_gp1), .rd_req_reg_gp1(net_rd_req_reg_gp1), .rd_addr_gp1(net_rd_addr_gp1), .rd_bytes_gp1(net_rd_bytes_gp1), .rd_data_ddr_gp1(net_rd_data_ddr_gp1), .rd_data_ocm_gp1(net_rd_data_ocm_gp1), .rd_data_reg_gp1(net_rd_data_reg_gp1), .rd_dv_ddr_gp1(net_rd_dv_ddr_gp1), .rd_dv_ocm_gp1(net_rd_dv_ocm_gp1), .rd_dv_reg_gp1(net_rd_dv_reg_gp1), /* HP Slave ports access */ .wr_ack_ddr_hp0(net_wr_ack_ddr_hp0), .wr_ack_ocm_hp0(net_wr_ack_ocm_hp0), .wr_data_hp0(net_wr_data_hp0), .wr_addr_hp0(net_wr_addr_hp0), .wr_bytes_hp0(net_wr_bytes_hp0), .wr_dv_ddr_hp0(net_wr_dv_ddr_hp0), .wr_dv_ocm_hp0(net_wr_dv_ocm_hp0), .rd_req_ddr_hp0(net_rd_req_ddr_hp0), .rd_req_ocm_hp0(net_rd_req_ocm_hp0), .rd_addr_hp0(net_rd_addr_hp0), .rd_bytes_hp0(net_rd_bytes_hp0), .rd_data_ddr_hp0(net_rd_data_ddr_hp0), .rd_data_ocm_hp0(net_rd_data_ocm_hp0), .rd_dv_ddr_hp0(net_rd_dv_ddr_hp0), .rd_dv_ocm_hp0(net_rd_dv_ocm_hp0), .wr_ack_ddr_hp1(net_wr_ack_ddr_hp1), .wr_ack_ocm_hp1(net_wr_ack_ocm_hp1), .wr_data_hp1(net_wr_data_hp1), .wr_addr_hp1(net_wr_addr_hp1), .wr_bytes_hp1(net_wr_bytes_hp1), .wr_dv_ddr_hp1(net_wr_dv_ddr_hp1), .wr_dv_ocm_hp1(net_wr_dv_ocm_hp1), .rd_req_ddr_hp1(net_rd_req_ddr_hp1), .rd_req_ocm_hp1(net_rd_req_ocm_hp1), .rd_addr_hp1(net_rd_addr_hp1), .rd_bytes_hp1(net_rd_bytes_hp1), .rd_data_ddr_hp1(net_rd_data_ddr_hp1), .rd_data_ocm_hp1(net_rd_data_ocm_hp1), .rd_dv_ocm_hp1(net_rd_dv_ocm_hp1), .rd_dv_ddr_hp1(net_rd_dv_ddr_hp1), .wr_ack_ddr_hp2(net_wr_ack_ddr_hp2), .wr_ack_ocm_hp2(net_wr_ack_ocm_hp2), .wr_data_hp2(net_wr_data_hp2), .wr_addr_hp2(net_wr_addr_hp2), .wr_bytes_hp2(net_wr_bytes_hp2), .wr_dv_ocm_hp2(net_wr_dv_ocm_hp2), .wr_dv_ddr_hp2(net_wr_dv_ddr_hp2), .rd_req_ddr_hp2(net_rd_req_ddr_hp2), .rd_req_ocm_hp2(net_rd_req_ocm_hp2), .rd_addr_hp2(net_rd_addr_hp2), .rd_bytes_hp2(net_rd_bytes_hp2), .rd_data_ddr_hp2(net_rd_data_ddr_hp2), .rd_data_ocm_hp2(net_rd_data_ocm_hp2), .rd_dv_ddr_hp2(net_rd_dv_ddr_hp2), .rd_dv_ocm_hp2(net_rd_dv_ocm_hp2), .wr_ack_ocm_hp3(net_wr_ack_ocm_hp3), .wr_ack_ddr_hp3(net_wr_ack_ddr_hp3), .wr_data_hp3(net_wr_data_hp3), .wr_addr_hp3(net_wr_addr_hp3), .wr_bytes_hp3(net_wr_bytes_hp3), .wr_dv_ddr_hp3(net_wr_dv_ddr_hp3), .wr_dv_ocm_hp3(net_wr_dv_ocm_hp3), .rd_req_ddr_hp3(net_rd_req_ddr_hp3), .rd_req_ocm_hp3(net_rd_req_ocm_hp3), .rd_addr_hp3(net_rd_addr_hp3), .rd_bytes_hp3(net_rd_bytes_hp3), .rd_data_ddr_hp3(net_rd_data_ddr_hp3), .rd_data_ocm_hp3(net_rd_data_ocm_hp3), .rd_dv_ddr_hp3(net_rd_dv_ddr_hp3), .rd_dv_ocm_hp3(net_rd_dv_ocm_hp3), /* Goes to port 1 of DDR */ .ddr_wr_ack_port1(ddr_wr_ack_port1), .ddr_wr_dv_port1(ddr_wr_dv_port1), .ddr_rd_req_port1(ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1(ddr_wr_qos_port1), .ddr_rd_qos_port1(ddr_rd_qos_port1), /* Goes to port2 of DDR */ .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), /* Goes to port3 of DDR */ .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3), /* Goes to port 0 of OCM */ .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1), /* Goes to port 0 of REG */ .reg_rd_qos_port1 (reg_rd_qos_port1) , .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1) ); processing_system7_bfm_v2_0_5_ddrc ddrc ( .rstn(net_rstn), .sw_clk(net_sw_clk), /* Goes to port 0 of DDR */ .ddr_wr_ack_port0 (ddr_wr_ack_port0), .ddr_wr_dv_port0 (ddr_wr_dv_port0), .ddr_rd_req_port0 (ddr_rd_req_port0), .ddr_rd_dv_port0 (ddr_rd_dv_port0), .ddr_wr_addr_port0(net_wr_addr_acp), .ddr_wr_data_port0(net_wr_data_acp), .ddr_wr_bytes_port0(net_wr_bytes_acp), .ddr_rd_addr_port0(net_rd_addr_acp), .ddr_rd_bytes_port0(net_rd_bytes_acp), .ddr_rd_data_port0(ddr_rd_data_port0), .ddr_wr_qos_port0 (net_wr_qos_acp), .ddr_rd_qos_port0 (net_rd_qos_acp), /* Goes to port 1 of DDR */ .ddr_wr_ack_port1 (ddr_wr_ack_port1), .ddr_wr_dv_port1 (ddr_wr_dv_port1), .ddr_rd_req_port1 (ddr_rd_req_port1), .ddr_rd_dv_port1 (ddr_rd_dv_port1), .ddr_wr_addr_port1(ddr_wr_addr_port1), .ddr_wr_data_port1(ddr_wr_data_port1), .ddr_wr_bytes_port1(ddr_wr_bytes_port1), .ddr_rd_addr_port1(ddr_rd_addr_port1), .ddr_rd_data_port1(ddr_rd_data_port1), .ddr_rd_bytes_port1(ddr_rd_bytes_port1), .ddr_wr_qos_port1 (ddr_wr_qos_port1), .ddr_rd_qos_port1 (ddr_rd_qos_port1), /* Goes to port2 of DDR */ .ddr_wr_ack_port2 (ddr_wr_ack_port2), .ddr_wr_dv_port2 (ddr_wr_dv_port2), .ddr_rd_req_port2 (ddr_rd_req_port2), .ddr_rd_dv_port2 (ddr_rd_dv_port2), .ddr_wr_addr_port2(ddr_wr_addr_port2), .ddr_wr_data_port2(ddr_wr_data_port2), .ddr_wr_bytes_port2(ddr_wr_bytes_port2), .ddr_rd_addr_port2(ddr_rd_addr_port2), .ddr_rd_data_port2(ddr_rd_data_port2), .ddr_rd_bytes_port2(ddr_rd_bytes_port2), .ddr_wr_qos_port2 (ddr_wr_qos_port2), .ddr_rd_qos_port2 (ddr_rd_qos_port2), /* Goes to port3 of DDR */ .ddr_wr_ack_port3 (ddr_wr_ack_port3), .ddr_wr_dv_port3 (ddr_wr_dv_port3), .ddr_rd_req_port3 (ddr_rd_req_port3), .ddr_rd_dv_port3 (ddr_rd_dv_port3), .ddr_wr_addr_port3(ddr_wr_addr_port3), .ddr_wr_data_port3(ddr_wr_data_port3), .ddr_wr_bytes_port3(ddr_wr_bytes_port3), .ddr_rd_addr_port3(ddr_rd_addr_port3), .ddr_rd_data_port3(ddr_rd_data_port3), .ddr_rd_bytes_port3(ddr_rd_bytes_port3), .ddr_wr_qos_port3 (ddr_wr_qos_port3), .ddr_rd_qos_port3 (ddr_rd_qos_port3) ); processing_system7_bfm_v2_0_5_ocmc ocmc ( .rstn(net_rstn), .sw_clk(net_sw_clk), /* Goes to port 0 of OCM */ .ocm_wr_ack_port0 (ocm_wr_ack_port0), .ocm_wr_dv_port0 (ocm_wr_dv_port0), .ocm_rd_req_port0 (ocm_rd_req_port0), .ocm_rd_dv_port0 (ocm_rd_dv_port0), .ocm_wr_addr_port0(net_wr_addr_acp), .ocm_wr_data_port0(net_wr_data_acp), .ocm_wr_bytes_port0(net_wr_bytes_acp), .ocm_rd_addr_port0(net_rd_addr_acp), .ocm_rd_bytes_port0(net_rd_bytes_acp), .ocm_rd_data_port0(ocm_rd_data_port0), .ocm_wr_qos_port0 (net_wr_qos_acp), .ocm_rd_qos_port0 (net_rd_qos_acp), /* Goes to port 1 of OCM */ .ocm_wr_ack_port1 (ocm_wr_ack_port1), .ocm_wr_dv_port1 (ocm_wr_dv_port1), .ocm_rd_req_port1 (ocm_rd_req_port1), .ocm_rd_dv_port1 (ocm_rd_dv_port1), .ocm_wr_addr_port1(ocm_wr_addr_port1), .ocm_wr_data_port1(ocm_wr_data_port1), .ocm_wr_bytes_port1(ocm_wr_bytes_port1), .ocm_rd_addr_port1(ocm_rd_addr_port1), .ocm_rd_data_port1(ocm_rd_data_port1), .ocm_rd_bytes_port1(ocm_rd_bytes_port1), .ocm_wr_qos_port1(ocm_wr_qos_port1), .ocm_rd_qos_port1(ocm_rd_qos_port1) ); processing_system7_bfm_v2_0_5_regc regc ( .rstn(net_rstn), .sw_clk(net_sw_clk), /* Goes to port 0 of REG */ .reg_rd_req_port0 (reg_rd_req_port0), .reg_rd_dv_port0 (reg_rd_dv_port0), .reg_rd_addr_port0(net_rd_addr_acp), .reg_rd_bytes_port0(net_rd_bytes_acp), .reg_rd_data_port0(reg_rd_data_port0), .reg_rd_qos_port0 (net_rd_qos_acp), /* Goes to port 1 of REG */ .reg_rd_req_port1 (reg_rd_req_port1), .reg_rd_dv_port1 (reg_rd_dv_port1), .reg_rd_addr_port1(reg_rd_addr_port1), .reg_rd_data_port1(reg_rd_data_port1), .reg_rd_bytes_port1(reg_rd_bytes_port1), .reg_rd_qos_port1(reg_rd_qos_port1) ); /* include axi_gp port instantiations */ `include "processing_system7_bfm_v2_0_5_axi_gp.v" /* include axi_hp port instantiations */ `include "processing_system7_bfm_v2_0_5_axi_hp.v" /* include axi_acp port instantiations */ `include "processing_system7_bfm_v2_0_5_axi_acp.v" endmodule

module processing_system7_bfm_v2_0_5_ddrc( rstn, sw_clk, /* Goes to port 0 of DDR */ ddr_wr_ack_port0, ddr_wr_dv_port0, ddr_rd_req_port0, ddr_rd_dv_port0, ddr_wr_addr_port0, ddr_wr_data_port0, ddr_wr_bytes_port0, ddr_rd_addr_port0, ddr_rd_data_port0, ddr_rd_bytes_port0, ddr_wr_qos_port0, ddr_rd_qos_port0, /* Goes to port 1 of DDR */ ddr_wr_ack_port1, ddr_wr_dv_port1, ddr_rd_req_port1, ddr_rd_dv_port1, ddr_wr_addr_port1, ddr_wr_data_port1, ddr_wr_bytes_port1, ddr_rd_addr_port1, ddr_rd_data_port1, ddr_rd_bytes_port1, ddr_wr_qos_port1, ddr_rd_qos_port1, /* Goes to port2 of DDR */ ddr_wr_ack_port2, ddr_wr_dv_port2, ddr_rd_req_port2, ddr_rd_dv_port2, ddr_wr_addr_port2, ddr_wr_data_port2, ddr_wr_bytes_port2, ddr_rd_addr_port2, ddr_rd_data_port2, ddr_rd_bytes_port2, ddr_wr_qos_port2, ddr_rd_qos_port2, /* Goes to port3 of DDR */ ddr_wr_ack_port3, ddr_wr_dv_port3, ddr_rd_req_port3, ddr_rd_dv_port3, ddr_wr_addr_port3, ddr_wr_data_port3, ddr_wr_bytes_port3, ddr_rd_addr_port3, ddr_rd_data_port3, ddr_rd_bytes_port3, ddr_wr_qos_port3, ddr_rd_qos_port3 ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn; input sw_clk; output ddr_wr_ack_port0; input ddr_wr_dv_port0; input ddr_rd_req_port0; output ddr_rd_dv_port0; input[addr_width-1:0] ddr_wr_addr_port0; input[max_burst_bits-1:0] ddr_wr_data_port0; input[max_burst_bytes_width:0] ddr_wr_bytes_port0; input[addr_width-1:0] ddr_rd_addr_port0; output[max_burst_bits-1:0] ddr_rd_data_port0; input[max_burst_bytes_width:0] ddr_rd_bytes_port0; input [axi_qos_width-1:0] ddr_wr_qos_port0; input [axi_qos_width-1:0] ddr_rd_qos_port0; output ddr_wr_ack_port1; input ddr_wr_dv_port1; input ddr_rd_req_port1; output ddr_rd_dv_port1; input[addr_width-1:0] ddr_wr_addr_port1; input[max_burst_bits-1:0] ddr_wr_data_port1; input[max_burst_bytes_width:0] ddr_wr_bytes_port1; input[addr_width-1:0] ddr_rd_addr_port1; output[max_burst_bits-1:0] ddr_rd_data_port1; input[max_burst_bytes_width:0] ddr_rd_bytes_port1; input[axi_qos_width-1:0] ddr_wr_qos_port1; input[axi_qos_width-1:0] ddr_rd_qos_port1; output ddr_wr_ack_port2; input ddr_wr_dv_port2; input ddr_rd_req_port2; output ddr_rd_dv_port2; input[addr_width-1:0] ddr_wr_addr_port2; input[max_burst_bits-1:0] ddr_wr_data_port2; input[max_burst_bytes_width:0] ddr_wr_bytes_port2; input[addr_width-1:0] ddr_rd_addr_port2; output[max_burst_bits-1:0] ddr_rd_data_port2; input[max_burst_bytes_width:0] ddr_rd_bytes_port2; input[axi_qos_width-1:0] ddr_wr_qos_port2; input[axi_qos_width-1:0] ddr_rd_qos_port2; output ddr_wr_ack_port3; input ddr_wr_dv_port3; input ddr_rd_req_port3; output ddr_rd_dv_port3; input[addr_width-1:0] ddr_wr_addr_port3; input[max_burst_bits-1:0] ddr_wr_data_port3; input[max_burst_bytes_width:0] ddr_wr_bytes_port3; input[addr_width-1:0] ddr_rd_addr_port3; output[max_burst_bits-1:0] ddr_rd_data_port3; input[max_burst_bytes_width:0] ddr_rd_bytes_port3; input[axi_qos_width-1:0] ddr_wr_qos_port3; input[axi_qos_width-1:0] ddr_rd_qos_port3; wire [axi_qos_width-1:0] wr_qos; wire wr_req; wire [max_burst_bits-1:0] wr_data; wire [addr_width-1:0] wr_addr; wire [max_burst_bytes_width:0] wr_bytes; reg wr_ack; wire [axi_qos_width-1:0] rd_qos; reg [max_burst_bits-1:0] rd_data; wire [addr_width-1:0] rd_addr; wire [max_burst_bytes_width:0] rd_bytes; reg rd_dv; wire rd_req; processing_system7_bfm_v2_0_5_arb_wr_4 ddr_write_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_wr_qos_port0), .qos2(ddr_wr_qos_port1), .qos3(ddr_wr_qos_port2), .qos4(ddr_wr_qos_port3), .prt_dv1(ddr_wr_dv_port0), .prt_dv2(ddr_wr_dv_port1), .prt_dv3(ddr_wr_dv_port2), .prt_dv4(ddr_wr_dv_port3), .prt_data1(ddr_wr_data_port0), .prt_data2(ddr_wr_data_port1), .prt_data3(ddr_wr_data_port2), .prt_data4(ddr_wr_data_port3), .prt_addr1(ddr_wr_addr_port0), .prt_addr2(ddr_wr_addr_port1), .prt_addr3(ddr_wr_addr_port2), .prt_addr4(ddr_wr_addr_port3), .prt_bytes1(ddr_wr_bytes_port0), .prt_bytes2(ddr_wr_bytes_port1), .prt_bytes3(ddr_wr_bytes_port2), .prt_bytes4(ddr_wr_bytes_port3), .prt_ack1(ddr_wr_ack_port0), .prt_ack2(ddr_wr_ack_port1), .prt_ack3(ddr_wr_ack_port2), .prt_ack4(ddr_wr_ack_port3), .prt_qos(wr_qos), .prt_req(wr_req), .prt_data(wr_data), .prt_addr(wr_addr), .prt_bytes(wr_bytes), .prt_ack(wr_ack) ); processing_system7_bfm_v2_0_5_arb_rd_4 ddr_read_ports ( .rstn(rstn), .sw_clk(sw_clk), .qos1(ddr_rd_qos_port0), .qos2(ddr_rd_qos_port1), .qos3(ddr_rd_qos_port2), .qos4(ddr_rd_qos_port3), .prt_req1(ddr_rd_req_port0), .prt_req2(ddr_rd_req_port1), .prt_req3(ddr_rd_req_port2), .prt_req4(ddr_rd_req_port3), .prt_data1(ddr_rd_data_port0), .prt_data2(ddr_rd_data_port1), .prt_data3(ddr_rd_data_port2), .prt_data4(ddr_rd_data_port3), .prt_addr1(ddr_rd_addr_port0), .prt_addr2(ddr_rd_addr_port1), .prt_addr3(ddr_rd_addr_port2), .prt_addr4(ddr_rd_addr_port3), .prt_bytes1(ddr_rd_bytes_port0), .prt_bytes2(ddr_rd_bytes_port1), .prt_bytes3(ddr_rd_bytes_port2), .prt_bytes4(ddr_rd_bytes_port3), .prt_dv1(ddr_rd_dv_port0), .prt_dv2(ddr_rd_dv_port1), .prt_dv3(ddr_rd_dv_port2), .prt_dv4(ddr_rd_dv_port3), .prt_qos(rd_qos), .prt_req(rd_req), .prt_data(rd_data), .prt_addr(rd_addr), .prt_bytes(rd_bytes), .prt_dv(rd_dv) ); processing_system7_bfm_v2_0_5_sparse_mem ddr(); reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin wr_ack <= 0; rd_dv <= 0; state <= 2'd0; end else begin case(state) 0:begin state <= 0; wr_ack <= 0; rd_dv <= 0; if(wr_req) begin ddr.write_mem(wr_data , wr_addr, wr_bytes); wr_ack <= 1; state <= 1; end if(rd_req) begin ddr.read_mem(rd_data,rd_addr, rd_bytes); rd_dv <= 1; state <= 1; end end 1:begin wr_ack <= 0; rd_dv <= 0; state <= 0; end endcase end /// if end// always endmodule

module processing_system7_bfm_v2_0_5_arb_rd( rstn, sw_clk, qos1, qos2, prt_req1, prt_req2, prt_bytes1, prt_bytes2, prt_addr1, prt_addr2, prt_data1, prt_data2, prt_dv1, prt_dv2, prt_req, prt_qos, prt_addr, prt_bytes, prt_data, prt_dv ); `include "processing_system7_bfm_v2_0_5_local_params.v" input rstn, sw_clk; input [axi_qos_width-1:0] qos1,qos2; input prt_req1, prt_req2; input [addr_width-1:0] prt_addr1, prt_addr2; input [max_burst_bytes_width:0] prt_bytes1, prt_bytes2; output reg prt_dv1, prt_dv2; output reg [max_burst_bits-1:0] prt_data1,prt_data2; output reg prt_req; output reg [axi_qos_width-1:0] prt_qos; output reg [addr_width-1:0] prt_addr; output reg [max_burst_bytes_width:0] prt_bytes; input [max_burst_bits-1:0] prt_data; input prt_dv; parameter wait_req = 2'b00, serv_req1 = 2'b01, serv_req2 = 2'b10,wait_dv_low = 2'b11; reg [1:0] state; always@(posedge sw_clk or negedge rstn) begin if(!rstn) begin state = wait_req; prt_req = 1'b0; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_qos = 0; end else begin case(state) wait_req:begin state = wait_req; prt_dv1 = 1'b0; prt_dv2 = 1'b0; prt_req = 0; if(prt_req1 && !prt_req2) begin state = serv_req1; prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; end else if(!prt_req1 && prt_req2) begin state = serv_req2; prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; end else if(prt_req1 && prt_req2) begin if(qos1 > qos2) begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else if(qos1 < qos2) begin prt_req = 1; prt_addr = prt_addr2; prt_qos = qos2; prt_bytes = prt_bytes2; state = serv_req2; end else begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end end end serv_req1:begin state = serv_req1; prt_dv2 = 1'b0; if(prt_dv) begin prt_dv1 = 1'b1; prt_data1 = prt_data; prt_req = 0; if(prt_req2) begin prt_req = 1; prt_qos = qos2; prt_addr = prt_addr2; prt_bytes = prt_bytes2; state = serv_req2; end else begin state = wait_dv_low; //state = wait_req; end end end serv_req2:begin state = serv_req2; prt_dv1 = 1'b0; if(prt_dv) begin prt_dv2 = 1'b1; prt_data2 = prt_data; prt_req = 0; if(prt_req1) begin prt_req = 1; prt_qos = qos1; prt_addr = prt_addr1; prt_bytes = prt_bytes1; state = serv_req1; end else begin state = wait_dv_low; //state = wait_req; end end end wait_dv_low:begin prt_dv1 = 1'b0; prt_dv2 = 1'b0; state = wait_dv_low; if(!prt_dv) state = wait_req; end endcase end /// if else end /// always endmodule

module axi_crossbar_v2_1_arbiter_resp # ( parameter C_FAMILY = "none", parameter integer C_NUM_S = 4, // Number of requesting Slave ports = [2:16] parameter integer C_NUM_S_LOG = 2, // Log2(C_NUM_S) parameter integer C_GRANT_ENC = 0, // Enable encoded grant output parameter integer C_GRANT_HOT = 1 // Enable 1-hot grant output ) ( // Global Inputs input wire ACLK, input wire ARESET, // Slave Ports input wire [C_NUM_S-1:0] S_VALID, // Request from each slave output wire [C_NUM_S-1:0] S_READY, // Grant response to each slave // Master Ports output wire [C_NUM_S_LOG-1:0] M_GRANT_ENC, // Granted slave index (encoded) output wire [C_NUM_S-1:0] M_GRANT_HOT, // Granted slave index (1-hot) output wire M_VALID, // Grant event input wire M_READY ); // Generates a binary coded from onehotone encoded function [4:0] f_hot2enc ( input [16:0] one_hot ); begin f_hot2enc[0] = |(one_hot & 17'b01010101010101010); f_hot2enc[1] = |(one_hot & 17'b01100110011001100); f_hot2enc[2] = |(one_hot & 17'b01111000011110000); f_hot2enc[3] = |(one_hot & 17'b01111111100000000); f_hot2enc[4] = |(one_hot & 17'b10000000000000000); end endfunction (* use_clock_enable = "yes" *) reg [C_NUM_S-1:0] chosen; wire [C_NUM_S-1:0] grant_hot; wire master_selected; wire active_master; wire need_arbitration; wire m_valid_i; wire [C_NUM_S-1:0] s_ready_i; wire access_done; reg [C_NUM_S-1:0] last_rr_hot; wire [C_NUM_S-1:0] valid_rr; reg [C_NUM_S-1:0] next_rr_hot; reg [C_NUM_S*C_NUM_S-1:0] carry_rr; reg [C_NUM_S*C_NUM_S-1:0] mask_rr; integer i; integer j; integer n; ///////////////////////////////////////////////////////////////////////////// // // Implementation of the arbiter outputs independant of arbitration // ///////////////////////////////////////////////////////////////////////////// // Mask the current requests with the chosen master assign grant_hot = chosen & S_VALID; // See if we have a selected master assign master_selected = |grant_hot[0+:C_NUM_S]; // See if we have current requests assign active_master = |S_VALID; // Access is completed assign access_done = m_valid_i & M_READY; // Need to handle if we drive S_ready combinatorial and without an IDLE state // Drive S_READY on the master who has been chosen when we get a M_READY assign s_ready_i = {C_NUM_S{M_READY}} & grant_hot[0+:C_NUM_S]; // Drive M_VALID if we have a selected master assign m_valid_i = master_selected; // If we have request and not a selected master, we need to arbitrate a new chosen assign need_arbitration = (active_master & ~master_selected) | access_done; // need internal signals of the output signals assign M_VALID = m_valid_i; assign S_READY = s_ready_i; ///////////////////////////////////////////////////////////////////////////// // Assign conditional onehot target output signal. assign M_GRANT_HOT = (C_GRANT_HOT == 1) ? grant_hot[0+:C_NUM_S] : {C_NUM_S{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Assign conditional encoded target output signal. assign M_GRANT_ENC = (C_GRANT_ENC == 1) ? f_hot2enc(grant_hot) : {C_NUM_S_LOG{1'b0}}; ///////////////////////////////////////////////////////////////////////////// // Select a new chosen when we need to arbitrate // If we don't have a new chosen, keep the old one since it's a good chance // that it will do another request always @(posedge ACLK) begin if (ARESET) begin chosen <= {C_NUM_S{1'b0}}; last_rr_hot <= {1'b1, {C_NUM_S-1{1'b0}}}; end else if (need_arbitration) begin chosen <= next_rr_hot; if (|next_rr_hot) last_rr_hot <= next_rr_hot; end end assign valid_rr = S_VALID; ///////////////////////////////////////////////////////////////////////////// // Round-robin arbiter // Selects next request to grant from among inputs with PRIO = 0, if any. ///////////////////////////////////////////////////////////////////////////// always @ * begin next_rr_hot = 0; for (i=0;i<C_NUM_S;i=i+1) begin n = (i>0) ? (i-1) : (C_NUM_S-1); carry_rr[i*C_NUM_S] = last_rr_hot[n]; mask_rr[i*C_NUM_S] = ~valid_rr[n]; for (j=1;j<C_NUM_S;j=j+1) begin n = (i-j > 0) ? (i-j-1) : (C_NUM_S+i-j-1); carry_rr[i*C_NUM_S+j] = carry_rr[i*C_NUM_S+j-1] | (last_rr_hot[n] & mask_rr[i*C_NUM_S+j-1]); if (j < C_NUM_S-1) begin mask_rr[i*C_NUM_S+j] = mask_rr[i*C_NUM_S+j-1] & ~valid_rr[n]; end end next_rr_hot[i] = valid_rr[i] & carry_rr[(i+1)*C_NUM_S-1]; end end endmodule

module processing_system7_bfm_v2_0_5_ocm_mem(); `include "processing_system7_bfm_v2_0_5_local_params.v" parameter mem_size = 32'h4_0000; /// 256 KB parameter mem_addr_width = clogb2(mem_size/mem_width); reg [data_width-1:0] ocm_memory [0:(mem_size/mem_width)-1]; /// 256 KB memory /* preload memory from file */ task automatic pre_load_mem_from_file; input [(max_chars*8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; $readmemh(file_name,ocm_memory,start_addr>>shft_addr_bits); endtask /* preload memory with some random data */ task automatic pre_load_mem; input [1:0] data_type; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer i; reg [mem_addr_width-1:0] addr; begin addr = start_addr >> shft_addr_bits; for (i = 0; i < no_of_bytes; i = i + mem_width) begin case(data_type) ALL_RANDOM : ocm_memory[addr] = $random; ALL_ZEROS : ocm_memory[addr] = 32'h0000_0000; ALL_ONES : ocm_memory[addr] = 32'hFFFF_FFFF; default : ocm_memory[addr] = $random; endcase addr = addr+1; end end endtask /* Write memory */ task write_mem; input [max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; reg [mem_addr_width-1:0] addr; reg [max_burst_bits-1 :0] wr_temp_data; reg [data_width-1:0] pre_pad_data,post_pad_data,temp_data; integer bytes_left; integer pre_pad_bytes; integer post_pad_bytes; begin addr = start_addr >> shft_addr_bits; wr_temp_data = data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Writing OCM Memory starting address (0x%0h) with %0d bytes.\n Data (0x%0h)",$time, DISP_INT_INFO, start_addr, no_of_bytes, data); `endif temp_data = wr_temp_data[data_width-1:0]; bytes_left = no_of_bytes; /* when the no. of bytes to be updated is less than mem_width */ if(bytes_left < mem_width) begin /* first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write*/ if(start_addr[shft_addr_bits-1:0] > 0) begin temp_data = ocm_memory[addr]; pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; end bytes_left = bytes_left + pre_pad_bytes; end /* This is needed for post padding the data ...*/ post_pad_bytes = mem_width - bytes_left; post_pad_data = ocm_memory[addr]; repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end ocm_memory[addr] = temp_data; end else begin /* first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write*/ if(start_addr[shft_addr_bits-1:0] > 0) begin temp_data = ocm_memory[addr]; pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; bytes_left = bytes_left -1; end end else begin wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end /* first data word end */ ocm_memory[addr] = temp_data; addr = addr + 1; while(bytes_left > (mem_width-1) ) begin /// for unaliged address necessary to check for mem_wd-1 , accordingly we have to pad post bytes. ocm_memory[addr] = wr_temp_data[data_width-1:0]; addr = addr+1; wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end post_pad_data = ocm_memory[addr]; post_pad_bytes = mem_width - bytes_left; /* This is needed for last transfer in unaliged burst */ if(bytes_left > 0) begin temp_data = wr_temp_data[data_width-1:0]; repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end ocm_memory[addr] = temp_data; end end `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Writing OCM Memory starting address (0x%0h)",$time, DISP_INT_INFO, start_addr ); `endif end endtask /* read_memory */ task read_mem; output[max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; integer i; reg [mem_addr_width-1:0] addr; reg [data_width-1:0] temp_rd_data; reg [max_burst_bits-1:0] temp_data; integer pre_bytes; integer bytes_left; begin addr = start_addr >> shft_addr_bits; pre_bytes = start_addr[shft_addr_bits-1:0]; bytes_left = no_of_bytes; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Reading OCM Memory starting address (0x%0h) -> %0d bytes",$time, DISP_INT_INFO, start_addr,no_of_bytes ); `endif /* Get first data ... if unaligned address */ temp_data[max_burst_bits-1 : max_burst_bits-data_width] = ocm_memory[addr]; if(no_of_bytes < mem_width ) begin temp_data = temp_data >> (pre_bytes * 8); repeat(max_burst_bytes - mem_width) temp_data = temp_data >> 8; end else begin bytes_left = bytes_left - (mem_width - pre_bytes); addr = addr+1; /* Got first data */ while (bytes_left > (mem_width-1) ) begin temp_data = temp_data >> data_width; temp_data[max_burst_bits-1 : max_burst_bits-data_width] = ocm_memory[addr]; addr = addr+1; bytes_left = bytes_left - mem_width; end /* Get last valid data in the burst*/ temp_rd_data = ocm_memory[addr]; while(bytes_left > 0) begin temp_data = temp_data >> 8; temp_data[max_burst_bits-1 : max_burst_bits-8] = temp_rd_data[7:0]; temp_rd_data = temp_rd_data >> 8; bytes_left = bytes_left - 1; end /* align to the brst_byte length */ repeat(max_burst_bytes - no_of_bytes) temp_data = temp_data >> 8; end data = temp_data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Reading OCM Memory starting address (0x%0h), Data returned(0x%0h)",$time, DISP_INT_INFO, start_addr, data ); `endif end endtask /* backdoor read to memory */ task peek_mem_to_file; input [(max_chars*8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer rd_fd; integer bytes; reg [addr_width-1:0] addr; reg [data_width-1:0] rd_data; begin rd_fd = $fopen(file_name,"w"); bytes = no_of_bytes; addr = start_addr >> shft_addr_bits; while (bytes > 0) begin rd_data = ocm_memory[addr]; $fdisplayh(rd_fd,rd_data); bytes = bytes - 4; addr = addr + 1; end end endtask endmodule

module processing_system7_bfm_v2_0_5_sparse_mem(); `include "processing_system7_bfm_v2_0_5_local_params.v" parameter mem_size = 32'h4000_0000; /// 1GB mem size parameter xsim_mem_size = 32'h1000_0000; ///256 MB mem size (x4 for XSIM/ISIM) `ifdef XSIM_ISIM reg [data_width-1:0] ddr_mem0 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem1 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem2 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem reg [data_width-1:0] ddr_mem3 [0:(xsim_mem_size/mem_width)-1]; // 256MB mem `else reg /*sparse*/ [data_width-1:0] ddr_mem [0:(mem_size/mem_width)-1]; // 'h10_0000 to 'h3FFF_FFFF - 1G mem `endif event mem_updated; reg check_we; reg [addr_width-1:0] check_up_add; reg [data_width-1:0] updated_data; /* preload memory from file */ task automatic pre_load_mem_from_file; input [(max_chars*8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; `ifdef XSIM_ISIM case(start_addr[31:28]) 4'd0 : $readmemh(file_name,ddr_mem0,start_addr>>shft_addr_bits); 4'd1 : $readmemh(file_name,ddr_mem1,start_addr>>shft_addr_bits); 4'd2 : $readmemh(file_name,ddr_mem2,start_addr>>shft_addr_bits); 4'd3 : $readmemh(file_name,ddr_mem3,start_addr>>shft_addr_bits); endcase `else $readmemh(file_name,ddr_mem,start_addr>>shft_addr_bits); `endif endtask /* preload memory with some random data */ task automatic pre_load_mem; input [1:0] data_type; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer i; reg [addr_width-1:0] addr; begin addr = start_addr >> shft_addr_bits; for (i = 0; i < no_of_bytes; i = i + mem_width) begin case(data_type) ALL_RANDOM : set_data(addr , $random); ALL_ZEROS : set_data(addr , 32'h0000_0000); ALL_ONES : set_data(addr , 32'hFFFF_FFFF); default : set_data(addr , $random); endcase addr = addr+1; end end endtask /* wait for memory update at certain location */ task automatic wait_mem_update; input[addr_width-1:0] address; output[data_width-1:0] dataout; begin check_up_add = address >> shft_addr_bits; check_we = 1; @(mem_updated); dataout = updated_data; check_we = 0; end endtask /* internal task to write data in memory */ task automatic set_data; input [addr_width-1:0] addr; input [data_width-1:0] data; begin if(check_we && (addr === check_up_add)) begin updated_data = data; -> mem_updated; end `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : ddr_mem0[addr[25:0]] = data; 6'd1 : ddr_mem1[addr[25:0]] = data; 6'd2 : ddr_mem2[addr[25:0]] = data; 6'd3 : ddr_mem3[addr[25:0]] = data; endcase `else ddr_mem[addr] = data; `endif end endtask /* internal task to read data from memory */ task automatic get_data; input [addr_width-1:0] addr; output [data_width-1:0] data; begin `ifdef XSIM_ISIM case(addr[31:26]) 6'd0 : data = ddr_mem0[addr[25:0]]; 6'd1 : data = ddr_mem1[addr[25:0]]; 6'd2 : data = ddr_mem2[addr[25:0]]; 6'd3 : data = ddr_mem3[addr[25:0]]; endcase `else data = ddr_mem[addr]; `endif end endtask /* Write memory */ task write_mem; input [max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width:0] no_of_bytes; reg [addr_width-1:0] addr; reg [max_burst_bits-1 :0] wr_temp_data; reg [data_width-1:0] pre_pad_data,post_pad_data,temp_data; integer bytes_left; integer pre_pad_bytes; integer post_pad_bytes; begin addr = start_addr >> shft_addr_bits; wr_temp_data = data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Writing DDR Memory starting address (0x%0h) with %0d bytes.\n Data (0x%0h)",$time, DISP_INT_INFO, start_addr, no_of_bytes, data); `endif temp_data = wr_temp_data[data_width-1:0]; bytes_left = no_of_bytes; /* when the no. of bytes to be updated is less than mem_width */ if(bytes_left < mem_width) begin /* first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write*/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; end bytes_left = bytes_left + pre_pad_bytes; end /* This is needed for post padding the data ...*/ post_pad_bytes = mem_width - bytes_left; //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end else begin /* first data word in the burst , if unaligned address, the adjust the wr_data accordingly for first write*/ if(start_addr[shft_addr_bits-1:0] > 0) begin //temp_data = ddr_mem[addr]; get_data(addr,temp_data); pre_pad_bytes = mem_width - start_addr[shft_addr_bits-1:0]; repeat(pre_pad_bytes) temp_data = temp_data << 8; repeat(pre_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = wr_temp_data[7:0]; wr_temp_data = wr_temp_data >> 8; bytes_left = bytes_left -1; end end else begin wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end /* first data word end */ //ddr_mem[addr] = temp_data; set_data(addr,temp_data); addr = addr + 1; while(bytes_left > (mem_width-1) ) begin /// for unaliged address necessary to check for mem_wd-1 , accordingly we have to pad post bytes. //ddr_mem[addr] = wr_temp_data[data_width-1:0]; set_data(addr,wr_temp_data[data_width-1:0]); addr = addr+1; wr_temp_data = wr_temp_data >> data_width; bytes_left = bytes_left - mem_width; end //post_pad_data = ddr_mem[addr]; get_data(addr,post_pad_data); post_pad_bytes = mem_width - bytes_left; /* This is needed for last transfer in unaliged burst */ if(bytes_left > 0) begin temp_data = wr_temp_data[data_width-1:0]; repeat(post_pad_bytes) temp_data = temp_data << 8; repeat(bytes_left) post_pad_data = post_pad_data >> 8; repeat(post_pad_bytes) begin temp_data = temp_data >> 8; temp_data[data_width-1:data_width-8] = post_pad_data[7:0]; post_pad_data = post_pad_data >> 8; end //ddr_mem[addr] = temp_data; set_data(addr,temp_data); end end `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Writing DDR Memory starting address (0x%0h)",$time, DISP_INT_INFO, start_addr ); `endif end endtask /* read_memory */ task read_mem; output[max_burst_bits-1 :0] data; input [addr_width-1:0] start_addr; input [max_burst_bytes_width :0] no_of_bytes; integer i; reg [addr_width-1:0] addr; reg [data_width-1:0] temp_rd_data; reg [max_burst_bits-1:0] temp_data; integer pre_bytes; integer bytes_left; begin addr = start_addr >> shft_addr_bits; pre_bytes = start_addr[shft_addr_bits-1:0]; bytes_left = no_of_bytes; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : Reading DDR Memory starting address (0x%0h) -> %0d bytes",$time, DISP_INT_INFO, start_addr,no_of_bytes ); `endif /* Get first data ... if unaligned address */ //temp_data[(max_burst * max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); if(no_of_bytes < mem_width ) begin temp_data = temp_data >> (pre_bytes * 8); repeat(max_burst_bytes - mem_width) temp_data = temp_data >> 8; end else begin bytes_left = bytes_left - (mem_width - pre_bytes); addr = addr+1; /* Got first data */ while (bytes_left > (mem_width-1) ) begin temp_data = temp_data >> data_width; //temp_data[(max_burst * max_data_burst)-1 : (max_burst * max_data_burst)- data_width] = ddr_mem[addr]; get_data(addr,temp_data[max_burst_bits-1 : max_burst_bits-data_width]); addr = addr+1; bytes_left = bytes_left - mem_width; end /* Get last valid data in the burst*/ //temp_rd_data = ddr_mem[addr]; get_data(addr,temp_rd_data); while(bytes_left > 0) begin temp_data = temp_data >> 8; temp_data[max_burst_bits-1 : max_burst_bits-8] = temp_rd_data[7:0]; temp_rd_data = temp_rd_data >> 8; bytes_left = bytes_left - 1; end /* align to the brst_byte length */ repeat(max_burst_bytes - no_of_bytes) temp_data = temp_data >> 8; end data = temp_data; `ifdef XLNX_INT_DBG $display("[%0d] : %0s : DONE -> Reading DDR Memory starting address (0x%0h), Data returned(0x%0h)",$time, DISP_INT_INFO, start_addr, data ); `endif end endtask /* backdoor read to memory */ task peek_mem_to_file; input [(max_chars*8)-1:0] file_name; input [addr_width-1:0] start_addr; input [int_width-1:0] no_of_bytes; integer rd_fd; integer bytes; reg [addr_width-1:0] addr; reg [data_width-1:0] rd_data; begin rd_fd = $fopen(file_name,"w"); bytes = no_of_bytes; addr = start_addr >> shft_addr_bits; while (bytes > 0) begin get_data(addr,rd_data); $fdisplayh(rd_fd,rd_data); bytes = bytes - 4; addr = addr + 1; end end endtask endmodule

module wishbone_mem_interconnect ( //Control Signals input clk, input rst, //Master Signals input i_m_we, input i_m_stb, input i_m_cyc, input [3:0] i_m_sel, input [31:0] i_m_adr, input [31:0] i_m_dat, output reg [31:0] o_m_dat, output reg o_m_ack, output reg o_m_int, //Slave 0 output o_s0_we, output o_s0_cyc, output o_s0_stb, output [3:0] o_s0_sel, input i_s0_ack, output [31:0] o_s0_dat, input [31:0] i_s0_dat, output [31:0] o_s0_adr, input i_s0_int ); parameter MEM_SEL_0 = 0; parameter MEM_OFFSET_0 = 0; parameter MEM_SIZE_0 = 8388607; reg [31:0] mem_select; always @(rst or i_m_adr or mem_select) begin if (rst) begin //nothing selected mem_select <= 32'hFFFFFFFF; end else begin if ((i_m_adr >= MEM_OFFSET_0) && (i_m_adr < (MEM_OFFSET_0 + MEM_SIZE_0))) begin mem_select <= MEM_SEL_0; end else begin mem_select <= 32'hFFFFFFFF; end end end //data in from slave always @ (mem_select or i_s0_dat) begin case (mem_select) MEM_SEL_0: begin o_m_dat <= i_s0_dat; end default: begin o_m_dat <= 32'h0000; end endcase end //ack in from mem slave always @ (mem_select or i_s0_ack) begin case (mem_select) MEM_SEL_0: begin o_m_ack <= i_s0_ack; end default: begin o_m_ack <= 1'h0; end endcase end //int in from slave always @ (mem_select or i_s0_int) begin case (mem_select) MEM_SEL_0: begin o_m_int <= i_s0_int; end default: begin o_m_int <= 1'h0; end endcase end assign o_s0_we = (mem_select == MEM_SEL_0) ? i_m_we: 1'b0; assign o_s0_stb = (mem_select == MEM_SEL_0) ? i_m_stb: 1'b0; assign o_s0_sel = (mem_select == MEM_SEL_0) ? i_m_sel: 4'b0; assign o_s0_cyc = (mem_select == MEM_SEL_0) ? i_m_cyc: 1'b0; assign o_s0_adr = (mem_select == MEM_SEL_0) ? i_m_adr: 32'h0; assign o_s0_dat = (mem_select == MEM_SEL_0) ? i_m_dat: 32'h0; endmodule

module */ /* Internal counters that are used as Read/Write pointers to the fifo's that store all the transaction info on all channles. This parameter is used to define the width of these pointers --> depending on Maximum outstanding transactions supported. 1-bit extra width than the no.of.bits needed to represent the outstanding transactions Extra bit helps in generating the empty and full flags */ parameter int_wr_cntr_width = clogb2(max_wr_outstanding_transactions+1); parameter int_rd_cntr_width = clogb2(max_rd_outstanding_transactions+1); /* RESP data */ parameter rsp_fifo_bits = axi_rsp_width+id_bus_width; parameter rsp_lsb = 0; parameter rsp_msb = axi_rsp_width-1; parameter rsp_id_lsb = rsp_msb + 1; parameter rsp_id_msb = rsp_id_lsb + id_bus_width-1; input S_RESETN; output S_ARREADY; output S_AWREADY; output S_BVALID; output S_RLAST; output S_RVALID; output S_WREADY; output [axi_rsp_width-1:0] S_BRESP; output [axi_rsp_width-1:0] S_RRESP; output [data_bus_width-1:0] S_RDATA; output [id_bus_width-1:0] S_BID; output [id_bus_width-1:0] S_RID; input S_ACLK; input S_ARVALID; input S_AWVALID; input S_BREADY; input S_RREADY; input S_WLAST; input S_WVALID; input [axi_brst_type_width-1:0] S_ARBURST; input [axi_lock_width-1:0] S_ARLOCK; input [axi_size_width-1:0] S_ARSIZE; input [axi_brst_type_width-1:0] S_AWBURST; input [axi_lock_width-1:0] S_AWLOCK; input [axi_size_width-1:0] S_AWSIZE; input [axi_prot_width-1:0] S_ARPROT; input [axi_prot_width-1:0] S_AWPROT; input [address_bus_width-1:0] S_ARADDR; input [address_bus_width-1:0] S_AWADDR; input [data_bus_width-1:0] S_WDATA; input [axi_cache_width-1:0] S_ARCACHE; input [axi_cache_width-1:0] S_ARLEN; input [axi_qos_width-1:0] S_ARQOS; input [axi_cache_width-1:0] S_AWCACHE; input [axi_len_width-1:0] S_AWLEN; input [axi_qos_width-1:0] S_AWQOS; input [(data_bus_width/8)-1:0] S_WSTRB; input [id_bus_width-1:0] S_ARID; input [id_bus_width-1:0] S_AWID; input [id_bus_width-1:0] S_WID; input SW_CLK; input WR_DATA_ACK_DDR, WR_DATA_ACK_OCM; output reg WR_DATA_VALID_DDR, WR_DATA_VALID_OCM; output reg [max_burst_bits-1:0] WR_DATA; output reg [addr_width-1:0] WR_ADDR; output reg [max_burst_bytes_width:0] WR_BYTES; output reg RD_REQ_OCM, RD_REQ_DDR, RD_REQ_REG; output reg [addr_width-1:0] RD_ADDR; input [max_burst_bits-1:0] RD_DATA_DDR,RD_DATA_OCM, RD_DATA_REG; output reg[max_burst_bytes_width:0] RD_BYTES; input RD_DATA_VALID_OCM,RD_DATA_VALID_DDR, RD_DATA_VALID_REG; output reg [axi_qos_width-1:0] WR_QOS, RD_QOS; wire net_ARVALID; wire net_AWVALID; wire net_WVALID; real s_aclk_period; cdn_axi3_slave_bfm #(slave_name, data_bus_width, address_bus_width, id_bus_width, slave_base_address, (slave_high_address- slave_base_address), max_outstanding_transactions, 0, ///MEMORY_MODEL_MODE, exclusive_access_supported) slave (.ACLK (S_ACLK), .ARESETn (S_RESETN), /// confirm this // Write Address Channel .AWID (S_AWID), .AWADDR (S_AWADDR), .AWLEN (S_AWLEN), .AWSIZE (S_AWSIZE), .AWBURST (S_AWBURST), .AWLOCK (S_AWLOCK), .AWCACHE (S_AWCACHE), .AWPROT (S_AWPROT), .AWVALID (net_AWVALID), .AWREADY (S_AWREADY), // Write Data Channel Signals. .WID (S_WID), .WDATA (S_WDATA), .WSTRB (S_WSTRB), .WLAST (S_WLAST), .WVALID (net_WVALID), .WREADY (S_WREADY), // Write Response Channel Signals. .BID (S_BID), .BRESP (S_BRESP), .BVALID (S_BVALID), .BREADY (S_BREADY), // Read Address Channel Signals. .ARID (S_ARID), .ARADDR (S_ARADDR), .ARLEN (S_ARLEN), .ARSIZE (S_ARSIZE), .ARBURST (S_ARBURST), .ARLOCK (S_ARLOCK), .ARCACHE (S_ARCACHE), .ARPROT (S_ARPROT), .ARVALID (net_ARVALID), .ARREADY (S_ARREADY), // Read Data Channel Signals. .RID (S_RID), .RDATA (S_RDATA), .RRESP (S_RRESP), .RLAST (S_RLAST), .RVALID (S_RVALID), .RREADY (S_RREADY)); /* Latency type and Debug/Error Control */ reg[1:0] latency_type = RANDOM_CASE; reg DEBUG_INFO = 1; reg STOP_ON_ERROR = 1'b1; /* WR_FIFO stores 32-bit address, valid data and valid bytes for each AXI Write burst transaction */ reg [wr_fifo_data_bits-1:0] wr_fifo [0:max_wr_outstanding_transactions-1]; reg [int_wr_cntr_width-1:0] wr_fifo_wr_ptr = 0, wr_fifo_rd_ptr = 0; wire wr_fifo_empty; /* Store the awvalid receive time --- necessary for calculating the latency in sending the bresp*/ reg [7:0] aw_time_cnt = 0, bresp_time_cnt = 0; real awvalid_receive_time[0:max_wr_outstanding_transactions]; // store the time when a new awvalid is received reg awvalid_flag[0:max_wr_outstanding_transactions]; // indicates awvalid is received /* Address Write Channel handshake*/ reg[int_wr_cntr_width-1:0] aw_cnt = 0;// count of awvalid /* various FIFOs for storing the ADDR channel info */ reg [axi_size_width-1:0] awsize [0:max_wr_outstanding_transactions-1]; reg [axi_prot_width-1:0] awprot [0:max_wr_outstanding_transactions-1]; reg [axi_lock_width-1:0] awlock [0:max_wr_outstanding_transactions-1]; reg [axi_cache_width-1:0] awcache [0:max_wr_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] awbrst [0:max_wr_outstanding_transactions-1]; reg [axi_len_width-1:0] awlen [0:max_wr_outstanding_transactions-1]; reg aw_flag [0:max_wr_outstanding_transactions-1]; reg [addr_width-1:0] awaddr [0:max_wr_outstanding_transactions-1]; reg [id_bus_width-1:0] awid [0:max_wr_outstanding_transactions-1]; reg [axi_qos_width-1:0] awqos [0:max_wr_outstanding_transactions-1]; wire aw_fifo_full; // indicates awvalid_fifo is full (max outstanding transactions reached) /* internal fifos to store burst write data, ID & strobes*/ reg [(data_bus_width*axi_burst_len)-1:0] burst_data [0:max_wr_outstanding_transactions-1]; reg [max_burst_bytes_width:0] burst_valid_bytes [0:max_wr_outstanding_transactions-1]; /// total valid bytes received in a complete burst transfer reg wlast_flag [0:max_wr_outstanding_transactions-1]; // flag to indicate WLAST received wire wd_fifo_full; /* Write Data Channel and Write Response handshake signals*/ reg [int_wr_cntr_width-1:0] wd_cnt = 0; reg [(data_bus_width*axi_burst_len)-1:0] aligned_wr_data; reg [addr_width-1:0] aligned_wr_addr; reg [max_burst_bytes_width:0] valid_data_bytes; reg [int_wr_cntr_width-1:0] wr_bresp_cnt = 0; reg [axi_rsp_width-1:0] bresp; reg [rsp_fifo_bits-1:0] fifo_bresp [0:max_wr_outstanding_transactions-1]; // store the ID and its corresponding response reg enable_write_bresp; reg [int_wr_cntr_width-1:0] rd_bresp_cnt = 0; integer wr_latency_count; reg wr_delayed; wire bresp_fifo_empty; /* states for managing read/write to WR_FIFO */ parameter SEND_DATA = 0, WAIT_ACK = 1; reg state; /* Qos*/ reg [axi_qos_width-1:0] ar_qos, aw_qos; initial begin if(DEBUG_INFO) begin if(enable_this_port) $display("[%0d] : %0s : %0s : Port is ENABLED.",$time, DISP_INFO, slave_name); else $display("[%0d] : %0s : %0s : Port is DISABLED.",$time, DISP_INFO, slave_name); end end initial slave.set_disable_reset_value_checks(1); initial begin repeat(2) @(posedge S_ACLK); if(!enable_this_port) begin slave.set_channel_level_info(0); slave.set_function_level_info(0); end slave.RESPONSE_TIMEOUT = 0; end /*--------------------------------------------------------------------------------*/ /* Set Latency type to be used */ task set_latency_type; input[1:0] lat; begin if(enable_this_port) latency_type = lat; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'Latency Profile' will not be set...",$time, DISP_WARN, slave_name); end end endtask /*--------------------------------------------------------------------------------*/ /* Set ARQoS to be used */ task set_arqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) ar_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'ARQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /*--------------------------------------------------------------------------------*/ /* Set AWQoS to be used */ task set_awqos; input[axi_qos_width-1:0] qos; begin if(enable_this_port) aw_qos = qos; else begin if(DEBUG_INFO) $display("[%0d] : %0s : %0s : Port is disabled. 'AWQOS' will not be set...",$time, DISP_WARN, slave_name); end end endtask /*--------------------------------------------------------------------------------*/ /* get the wr latency number */ function [31:0] get_wr_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : if(slave_name == axi_acp_name) get_wr_lat_number = acp_wr_min; else get_wr_lat_number = gp_wr_min; AVG_CASE : if(slave_name == axi_acp_name) get_wr_lat_number = acp_wr_avg; else get_wr_lat_number = gp_wr_avg; WORST_CASE : if(slave_name == axi_acp_name) get_wr_lat_number = acp_wr_max; else get_wr_lat_number = gp_wr_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : if(slave_name == axi_acp_name) get_wr_lat_number = ($random()%10+ acp_wr_min); else get_wr_lat_number = ($random()%10+ gp_wr_min); 2'b01 : if(slave_name == axi_acp_name) get_wr_lat_number = ($random()%40+ acp_wr_avg); else get_wr_lat_number = ($random()%40+ gp_wr_avg); default : if(slave_name == axi_acp_name) get_wr_lat_number = ($random()%60+ acp_wr_max); else get_wr_lat_number = ($random()%60+ gp_wr_max); endcase end endcase end endfunction /*--------------------------------------------------------------------------------*/ /* get the rd latency number */ function [31:0] get_rd_lat_number; input dummy; reg[1:0] temp; begin case(latency_type) BEST_CASE : if(slave_name == axi_acp_name) get_rd_lat_number = acp_rd_min; else get_rd_lat_number = gp_rd_min; AVG_CASE : if(slave_name == axi_acp_name) get_rd_lat_number = acp_rd_avg; else get_rd_lat_number = gp_rd_avg; WORST_CASE : if(slave_name == axi_acp_name) get_rd_lat_number = acp_rd_max; else get_rd_lat_number = gp_rd_max; default : begin // RANDOM_CASE temp = $random; case(temp) 2'b00 : if(slave_name == axi_acp_name) get_rd_lat_number = ($random()%10+ acp_rd_min); else get_rd_lat_number = ($random()%10+ gp_rd_min); 2'b01 : if(slave_name == axi_acp_name) get_rd_lat_number = ($random()%40+ acp_rd_avg); else get_rd_lat_number = ($random()%40+ gp_rd_avg); default : if(slave_name == axi_acp_name) get_rd_lat_number = ($random()%60+ acp_rd_max); else get_rd_lat_number = ($random()%60+ gp_rd_max); endcase end endcase end endfunction /*--------------------------------------------------------------------------------*/ /* Store the Clock cycle time period */ always@(S_RESETN) begin if(S_RESETN) begin @(posedge S_ACLK); s_aclk_period = $time; @(posedge S_ACLK); s_aclk_period = $time - s_aclk_period; end end /*--------------------------------------------------------------------------------*/ /* Check for any WRITE/READs when this port is disabled */ always@(S_AWVALID or S_WVALID or S_ARVALID) begin if((S_AWVALID | S_WVALID | S_ARVALID) && !enable_this_port) begin $display("[%0d] : %0s : %0s : Port is disabled. AXI transaction is initiated on this port ...\nSimulation will halt ..",$time, DISP_ERR, slave_name); $stop; end end /*--------------------------------------------------------------------------------*/ assign net_ARVALID = enable_this_port ? S_ARVALID : 1'b0; assign net_AWVALID = enable_this_port ? S_AWVALID : 1'b0; assign net_WVALID = enable_this_port ? S_WVALID : 1'b0; assign wr_fifo_empty = (wr_fifo_wr_ptr === wr_fifo_rd_ptr)?1'b1: 1'b0; assign aw_fifo_full = ((aw_cnt[int_wr_cntr_width-1] !== rd_bresp_cnt[int_wr_cntr_width-1]) && (aw_cnt[int_wr_cntr_width-2:0] === rd_bresp_cnt[int_wr_cntr_width-2:0]))?1'b1 :1'b0; /// complete this assign wd_fifo_full = ((wd_cnt[int_wr_cntr_width-1] !== rd_bresp_cnt[int_wr_cntr_width-1]) && (wd_cnt[int_wr_cntr_width-2:0] === rd_bresp_cnt[int_wr_cntr_width-2:0]))?1'b1 :1'b0; /// complete this assign bresp_fifo_empty = (wr_bresp_cnt === rd_bresp_cnt)?1'b1:1'b0; /* Store the awvalid receive time --- necessary for calculating the bresp latency */ always@(negedge S_RESETN or S_AWID or S_AWADDR or S_AWVALID ) begin if(!S_RESETN) aw_time_cnt = 0; else begin if(S_AWVALID) begin awvalid_receive_time[aw_time_cnt] = $time; awvalid_flag[aw_time_cnt] = 1'b1; aw_time_cnt = aw_time_cnt + 1; if(aw_time_cnt === max_wr_outstanding_transactions) aw_time_cnt = 0; end end // else end /// always /*--------------------------------------------------------------------------------*/ always@(posedge S_ACLK) begin if(net_AWVALID && S_AWREADY) begin if(S_AWQOS === 0) awqos[aw_cnt[int_wr_cntr_width-2:0]] = aw_qos; else awqos[aw_cnt[int_wr_cntr_width-2:0]] = S_AWQOS; end end /*--------------------------------------------------------------------------------*/ always@(aw_fifo_full) begin if(aw_fifo_full && DEBUG_INFO) $display("[%0d] : %0s : %0s : Reached the maximum outstanding Write transactions limit (%0d). Blocking all future Write transactions until at least 1 of the outstanding Write transaction has completed.",$time, DISP_INFO, slave_name,max_wr_outstanding_transactions); end /*--------------------------------------------------------------------------------*/ /* Address Write Channel handshake*/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin aw_cnt = 0; end else begin if(!aw_fifo_full) begin slave.RECEIVE_WRITE_ADDRESS(0, id_invalid, awaddr[aw_cnt[int_wr_cntr_width-2:0]], awlen[aw_cnt[int_wr_cntr_width-2:0]], awsize[aw_cnt[int_wr_cntr_width-2:0]], awbrst[aw_cnt[int_wr_cntr_width-2:0]], awlock[aw_cnt[int_wr_cntr_width-2:0]], awcache[aw_cnt[int_wr_cntr_width-2:0]], awprot[aw_cnt[int_wr_cntr_width-2:0]], awid[aw_cnt[int_wr_cntr_width-2:0]]); /// sampled valid ID. aw_flag[aw_cnt[int_wr_cntr_width-2:0]] = 1; aw_cnt = aw_cnt + 1; if(aw_cnt[int_wr_cntr_width-2:0] === (max_wr_outstanding_transactions-1)) begin aw_cnt[int_wr_cntr_width-1] = ~aw_cnt[int_wr_cntr_width-1]; aw_cnt[int_wr_cntr_width-2:0] = 0; end end // if (!aw_fifo_full) end /// if else end /// always /*--------------------------------------------------------------------------------*/ /* Write Data Channel Handshake */ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wd_cnt = 0; end else begin if(!wd_fifo_full && S_WVALID) begin slave.RECEIVE_WRITE_BURST_NO_CHECKS(S_WID, burst_data[wd_cnt[int_wr_cntr_width-2:0]], burst_valid_bytes[wd_cnt[int_wr_cntr_width-2:0]]); wlast_flag[wd_cnt[int_wr_cntr_width-2:0]] = 1'b1; wd_cnt = wd_cnt + 1; if(wd_cnt[int_wr_cntr_width-2:0] === (max_wr_outstanding_transactions-1)) begin wd_cnt[int_wr_cntr_width-1] = ~wd_cnt[int_wr_cntr_width-1]; wd_cnt[int_wr_cntr_width-2:0] = 0; end end /// if end /// else end /// always /*--------------------------------------------------------------------------------*/ /* Align the wrap data for write transaction */ task automatic get_wrap_aligned_wr_data; output [(data_bus_width*axi_burst_len)-1:0] aligned_data; output [addr_width-1:0] start_addr; /// aligned start address input [addr_width-1:0] addr; input [(data_bus_width*axi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [(data_bus_width*axi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; wrp_data = wrp_data << ((data_bus_width*axi_burst_len) - (v_bytes*8)); while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data << 8; temp_data[7:0] = wrp_data[(data_bus_width*axi_burst_len)-1 : (data_bus_width*axi_burst_len)-8]; wrp_data = wrp_data << 8; wrp_bytes = wrp_bytes - 1; end wrp_bytes = addr - start_addr; wrp_data = b_data << (wrp_bytes*8); aligned_data = (temp_data | wrp_data); end endtask /*--------------------------------------------------------------------------------*/ /* Calculate the Response for each read/write transaction */ function [axi_rsp_width-1:0] calculate_resp; input rd_wr; // indicates Read(1) or Write(0) transaction input [addr_width-1:0] awaddr; input [axi_prot_width-1:0] awprot; reg [axi_rsp_width-1:0] rsp; begin rsp = AXI_OK; /* Address Decode */ if(decode_address(awaddr) === INVALID_MEM_TYPE) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Access to Invalid location(0x%0h) ",$time, DISP_ERR, slave_name, awaddr); end if(!rd_wr && decode_address(awaddr) === REG_MEM) begin rsp = AXI_SLV_ERR; //slave error $display("[%0d] : %0s : %0s : AXI Write to Register Map(0x%0h) is not supported ",$time, DISP_ERR, slave_name, awaddr); end if(secure_access_enabled && awprot[1]) rsp = AXI_DEC_ERR; // decode error calculate_resp = rsp; end endfunction /*--------------------------------------------------------------------------------*/ /* Store the Write response for each write transaction */ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin wr_bresp_cnt = 0; wr_fifo_wr_ptr = 0; end else begin enable_write_bresp = aw_flag[wr_bresp_cnt[int_wr_cntr_width-2:0]] && wlast_flag[wr_bresp_cnt[int_wr_cntr_width-2:0]]; /* calculate bresp only when AWVALID && WLAST is received */ if(enable_write_bresp) begin aw_flag[wr_bresp_cnt[int_wr_cntr_width-2:0]] = 0; wlast_flag[wr_bresp_cnt[int_wr_cntr_width-2:0]] = 0; bresp = calculate_resp(1'b0, awaddr[wr_bresp_cnt[int_wr_cntr_width-2:0]],awprot[wr_bresp_cnt[int_wr_cntr_width-2:0]]); fifo_bresp[wr_bresp_cnt[int_wr_cntr_width-2:0]] = {awid[wr_bresp_cnt[int_wr_cntr_width-2:0]],bresp}; /* Fill WR data FIFO */ if(bresp === AXI_OK) begin if(awbrst[wr_bresp_cnt[int_wr_cntr_width-2:0]] === AXI_WRAP) begin /// wrap type? then align the data get_wrap_aligned_wr_data(aligned_wr_data,aligned_wr_addr, awaddr[wr_bresp_cnt[int_wr_cntr_width-2:0]],burst_data[wr_bresp_cnt[int_wr_cntr_width-2:0]],burst_valid_bytes[wr_bresp_cnt[int_wr_cntr_width-2:0]]); /// gives wrapped start address end else begin aligned_wr_data = burst_data[wr_bresp_cnt[int_wr_cntr_width-2:0]]; aligned_wr_addr = awaddr[wr_bresp_cnt[int_wr_cntr_width-2:0]] ; end valid_data_bytes = burst_valid_bytes[wr_bresp_cnt[int_wr_cntr_width-2:0]]; end else valid_data_bytes = 0; wr_fifo[wr_fifo_wr_ptr[int_wr_cntr_width-2:0]] = {awqos[wr_bresp_cnt[int_wr_cntr_width-2:0]], aligned_wr_data, aligned_wr_addr, valid_data_bytes}; wr_fifo_wr_ptr = wr_fifo_wr_ptr + 1; wr_bresp_cnt = wr_bresp_cnt+1; if(wr_bresp_cnt[int_wr_cntr_width-2:0] === (max_wr_outstanding_transactions-1)) begin wr_bresp_cnt[int_wr_cntr_width-1] = ~ wr_bresp_cnt[int_wr_cntr_width-1]; wr_bresp_cnt[int_wr_cntr_width-2:0] = 0; end end end // else end // always /*--------------------------------------------------------------------------------*/ /* Send Write Response Channel handshake */ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin rd_bresp_cnt = 0; wr_latency_count = get_wr_lat_number(1); wr_delayed = 0; bresp_time_cnt = 0; end else begin wr_delayed = 1'b0; if(awvalid_flag[bresp_time_cnt] && (($time - awvalid_receive_time[bresp_time_cnt])/s_aclk_period >= wr_latency_count)) wr_delayed = 1; if(!bresp_fifo_empty && wr_delayed) begin slave.SEND_WRITE_RESPONSE(fifo_bresp[rd_bresp_cnt[int_wr_cntr_width-2:0]][rsp_id_msb : rsp_id_lsb], // ID fifo_bresp[rd_bresp_cnt[int_wr_cntr_width-2:0]][rsp_msb : rsp_lsb] // Response ); wr_delayed = 0; awvalid_flag[bresp_time_cnt] = 1'b0; bresp_time_cnt = bresp_time_cnt+1; rd_bresp_cnt = rd_bresp_cnt + 1; if(rd_bresp_cnt[int_wr_cntr_width-2:0] === (max_wr_outstanding_transactions-1)) begin rd_bresp_cnt[int_wr_cntr_width-1] = ~ rd_bresp_cnt[int_wr_cntr_width-1]; rd_bresp_cnt[int_wr_cntr_width-2:0] = 0; end if(bresp_time_cnt === max_wr_outstanding_transactions) begin bresp_time_cnt = 0; end wr_latency_count = get_wr_lat_number(1); end end // else end//always /*--------------------------------------------------------------------------------*/ /* Reading from the wr_fifo */ always@(negedge S_RESETN or posedge SW_CLK) begin if(!S_RESETN) begin WR_DATA_VALID_DDR = 1'b0; WR_DATA_VALID_OCM = 1'b0; wr_fifo_rd_ptr = 0; state = SEND_DATA; WR_QOS = 0; end else begin case(state) SEND_DATA :begin state = SEND_DATA; WR_DATA_VALID_OCM = 0; WR_DATA_VALID_DDR = 0; if(!wr_fifo_empty) begin WR_DATA = wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_data_msb : wr_data_lsb]; WR_ADDR = wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_addr_msb : wr_addr_lsb]; WR_BYTES = wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_bytes_msb : wr_bytes_lsb]; WR_QOS = wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_qos_msb : wr_qos_lsb]; state = WAIT_ACK; case (decode_address(wr_fifo[wr_fifo_rd_ptr[int_wr_cntr_width-2:0]][wr_addr_msb : wr_addr_lsb])) OCM_MEM : WR_DATA_VALID_OCM = 1; DDR_MEM : WR_DATA_VALID_DDR = 1; default : state = SEND_DATA; endcase wr_fifo_rd_ptr = wr_fifo_rd_ptr+1; end end WAIT_ACK :begin state = WAIT_ACK; if(WR_DATA_ACK_OCM | WR_DATA_ACK_DDR) begin WR_DATA_VALID_OCM = 1'b0; WR_DATA_VALID_DDR = 1'b0; state = SEND_DATA; end end endcase end end /*--------------------------------------------------------------------------------*/ /*-------------------------------- WRITE HANDSHAKE END ----------------------------------------*/ /*-------------------------------- READ HANDSHAKE ---------------------------------------------*/ /* READ CHANNELS */ /* Store the arvalid receive time --- necessary for calculating latency in sending the rresp latency */ reg [7:0] ar_time_cnt = 0,rresp_time_cnt = 0; real arvalid_receive_time[0:max_rd_outstanding_transactions]; // store the time when a new arvalid is received reg arvalid_flag[0:max_rd_outstanding_transactions]; // store the time when a new arvalid is received reg [int_rd_cntr_width-1:0] ar_cnt = 0; // counter for arvalid info /* various FIFOs for storing the ADDR channel info */ reg [axi_size_width-1:0] arsize [0:max_rd_outstanding_transactions-1]; reg [axi_prot_width-1:0] arprot [0:max_rd_outstanding_transactions-1]; reg [axi_brst_type_width-1:0] arbrst [0:max_rd_outstanding_transactions-1]; reg [axi_len_width-1:0] arlen [0:max_rd_outstanding_transactions-1]; reg [axi_cache_width-1:0] arcache [0:max_rd_outstanding_transactions-1]; reg [axi_lock_width-1:0] arlock [0:max_rd_outstanding_transactions-1]; reg ar_flag [0:max_rd_outstanding_transactions-1]; reg [addr_width-1:0] araddr [0:max_rd_outstanding_transactions-1]; reg [id_bus_width-1:0] arid [0:max_rd_outstanding_transactions-1]; reg [axi_qos_width-1:0] arqos [0:max_rd_outstanding_transactions-1]; wire ar_fifo_full; // indicates arvalid_fifo is full (max outstanding transactions reached) reg [int_rd_cntr_width-1:0] rd_cnt = 0; reg [int_rd_cntr_width-1:0] wr_rresp_cnt = 0; reg [axi_rsp_width-1:0] rresp; reg [rsp_fifo_bits-1:0] fifo_rresp [0:max_rd_outstanding_transactions-1]; // store the ID and its corresponding response /* Send Read Response & Data Channel handshake */ integer rd_latency_count; reg rd_delayed; reg [max_burst_bits-1:0] read_fifo [0:max_rd_outstanding_transactions-1]; /// Store only AXI Burst Data .. reg [int_rd_cntr_width-1:0] rd_fifo_wr_ptr = 0, rd_fifo_rd_ptr = 0; wire read_fifo_full; assign read_fifo_full = (rd_fifo_wr_ptr[int_rd_cntr_width-1] !== rd_fifo_rd_ptr[int_rd_cntr_width-1] && rd_fifo_wr_ptr[int_rd_cntr_width-2:0] === rd_fifo_rd_ptr[int_rd_cntr_width-2:0])?1'b1: 1'b0; assign read_fifo_empty = (rd_fifo_wr_ptr === rd_fifo_rd_ptr)?1'b1: 1'b0; assign ar_fifo_full = ((ar_cnt[int_rd_cntr_width-1] !== rd_cnt[int_rd_cntr_width-1]) && (ar_cnt[int_rd_cntr_width-2:0] === rd_cnt[int_rd_cntr_width-2:0]))?1'b1 :1'b0; /* Store the arvalid receive time --- necessary for calculating the bresp latency */ always@(negedge S_RESETN or S_ARID or S_ARADDR or S_ARVALID ) begin if(!S_RESETN) ar_time_cnt = 0; else begin if(S_ARVALID) begin arvalid_receive_time[ar_time_cnt] = $time; arvalid_flag[ar_time_cnt] = 1'b1; ar_time_cnt = ar_time_cnt + 1; if(ar_time_cnt === max_rd_outstanding_transactions) ar_time_cnt = 0; end end // else end /// always /*--------------------------------------------------------------------------------*/ always@(posedge S_ACLK) begin if(net_ARVALID && S_ARREADY) begin if(S_ARQOS === 0) arqos[aw_cnt[int_rd_cntr_width-2:0]] = ar_qos; else arqos[aw_cnt[int_rd_cntr_width-2:0]] = S_ARQOS; end end /*--------------------------------------------------------------------------------*/ always@(ar_fifo_full) begin if(ar_fifo_full && DEBUG_INFO) $display("[%0d] : %0s : %0s : Reached the maximum outstanding Read transactions limit (%0d). Blocking all future Read transactions until at least 1 of the outstanding Read transaction has completed.",$time, DISP_INFO, slave_name,max_rd_outstanding_transactions); end /*--------------------------------------------------------------------------------*/ /* Address Read Channel handshake*/ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN) begin ar_cnt = 0; end else begin if(!ar_fifo_full) begin slave.RECEIVE_READ_ADDRESS(0, id_invalid, araddr[ar_cnt[int_rd_cntr_width-2:0]], arlen[ar_cnt[int_rd_cntr_width-2:0]], arsize[ar_cnt[int_rd_cntr_width-2:0]], arbrst[ar_cnt[int_rd_cntr_width-2:0]], arlock[ar_cnt[int_rd_cntr_width-2:0]], arcache[ar_cnt[int_rd_cntr_width-2:0]], arprot[ar_cnt[int_rd_cntr_width-2:0]], arid[ar_cnt[int_rd_cntr_width-2:0]]); /// sampled valid ID. ar_flag[ar_cnt[int_rd_cntr_width-2:0]] = 1'b1; ar_cnt = ar_cnt+1; if(ar_cnt[int_rd_cntr_width-2:0] === max_rd_outstanding_transactions-1) begin ar_cnt[int_rd_cntr_width-1] = ~ ar_cnt[int_rd_cntr_width-1]; ar_cnt[int_rd_cntr_width-2:0] = 0; end end /// if(!ar_fifo_full) end /// if else end /// always*/ /*--------------------------------------------------------------------------------*/ /* Align Wrap data for read transaction*/ task automatic get_wrap_aligned_rd_data; output [(data_bus_width*axi_burst_len)-1:0] aligned_data; input [addr_width-1:0] addr; input [(data_bus_width*axi_burst_len)-1:0] b_data; input [max_burst_bytes_width:0] v_bytes; reg [addr_width-1:0] start_addr; reg [(data_bus_width*axi_burst_len)-1:0] temp_data, wrp_data; integer wrp_bytes; integer i; begin start_addr = (addr/v_bytes) * v_bytes; wrp_bytes = addr - start_addr; wrp_data = b_data; temp_data = 0; while(wrp_bytes > 0) begin /// get the data that is wrapped temp_data = temp_data >> 8; temp_data[(data_bus_width*axi_burst_len)-1 : (data_bus_width*axi_burst_len)-8] = wrp_data[7:0]; wrp_data = wrp_data >> 8; wrp_bytes = wrp_bytes - 1; end temp_data = temp_data >> ((data_bus_width*axi_burst_len) - (v_bytes*8)); wrp_bytes = addr - start_addr; wrp_data = b_data >> (wrp_bytes*8); aligned_data = (temp_data | wrp_data); end endtask /*--------------------------------------------------------------------------------*/ parameter RD_DATA_REQ = 1'b0, WAIT_RD_VALID = 1'b1; reg [addr_width-1:0] temp_read_address; reg [max_burst_bytes_width:0] temp_rd_valid_bytes; reg rd_fifo_state; reg invalid_rd_req; /* get the data from memory && also calculate the rresp*/ always@(negedge S_RESETN or posedge SW_CLK) begin if(!S_RESETN)begin rd_fifo_wr_ptr = 0; wr_rresp_cnt =0; rd_fifo_state = RD_DATA_REQ; temp_rd_valid_bytes = 0; temp_read_address = 0; RD_REQ_DDR = 0; RD_REQ_OCM = 0; RD_REQ_REG = 0; RD_QOS = 0; invalid_rd_req = 0; end else begin case(rd_fifo_state) RD_DATA_REQ : begin rd_fifo_state = RD_DATA_REQ; RD_REQ_DDR = 0; RD_REQ_OCM = 0; RD_REQ_REG = 0; RD_QOS = 0; if(ar_flag[wr_rresp_cnt[int_rd_cntr_width-2:0]] && !read_fifo_full) begin ar_flag[wr_rresp_cnt[int_rd_cntr_width-2:0]] = 0; rresp = calculate_resp(1'b1, araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]],arprot[wr_rresp_cnt[int_rd_cntr_width-2:0]]); fifo_rresp[wr_rresp_cnt[int_rd_cntr_width-2:0]] = {arid[wr_rresp_cnt[int_rd_cntr_width-2:0]],rresp}; temp_rd_valid_bytes = (arlen[wr_rresp_cnt[int_rd_cntr_width-2:0]]+1)*(2**arsize[wr_rresp_cnt[int_rd_cntr_width-2:0]]);//data_bus_width/8; if(arbrst[wr_rresp_cnt[int_rd_cntr_width-2:0]] === AXI_WRAP) /// wrap begin temp_read_address = (araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]]/temp_rd_valid_bytes) * temp_rd_valid_bytes; else temp_read_address = araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]]; if(rresp === AXI_OK) begin case(decode_address(temp_read_address))//decode_address(araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]]); OCM_MEM : RD_REQ_OCM = 1; DDR_MEM : RD_REQ_DDR = 1; REG_MEM : RD_REQ_REG = 1; default : invalid_rd_req = 1; endcase end else invalid_rd_req = 1; RD_QOS = arqos[wr_rresp_cnt[int_rd_cntr_width-2:0]]; RD_ADDR = temp_read_address; ///araddr[wr_rresp_cnt[int_rd_cntr_width-2:0]]; RD_BYTES = temp_rd_valid_bytes; rd_fifo_state = WAIT_RD_VALID; wr_rresp_cnt = wr_rresp_cnt + 1; if(wr_rresp_cnt[int_rd_cntr_width-2:0] === max_rd_outstanding_transactions-1) begin wr_rresp_cnt[int_rd_cntr_width-1] = ~ wr_rresp_cnt[int_rd_cntr_width-1]; wr_rresp_cnt[int_rd_cntr_width-2:0] = 0; end end end WAIT_RD_VALID : begin rd_fifo_state = WAIT_RD_VALID; if(RD_DATA_VALID_OCM | RD_DATA_VALID_DDR | RD_DATA_VALID_REG | invalid_rd_req) begin ///temp_dec == 2'b11) begin if(RD_DATA_VALID_DDR) read_fifo[rd_fifo_wr_ptr[int_rd_cntr_width-2:0]] = RD_DATA_DDR; else if(RD_DATA_VALID_OCM) read_fifo[rd_fifo_wr_ptr[int_rd_cntr_width-2:0]] = RD_DATA_OCM; else if(RD_DATA_VALID_REG) read_fifo[rd_fifo_wr_ptr[int_rd_cntr_width-2:0]] = RD_DATA_REG; else read_fifo[rd_fifo_wr_ptr[int_rd_cntr_width-2:0]] = 0; rd_fifo_wr_ptr = rd_fifo_wr_ptr + 1; RD_REQ_DDR = 0; RD_REQ_OCM = 0; RD_REQ_REG = 0; RD_QOS = 0; invalid_rd_req = 0; rd_fifo_state = RD_DATA_REQ; end end endcase end /// else end /// always /*--------------------------------------------------------------------------------*/ reg[max_burst_bytes_width:0] rd_v_b; reg [(data_bus_width*axi_burst_len)-1:0] temp_read_data; reg [(data_bus_width*axi_burst_len)-1:0] temp_wrap_data; reg[(axi_rsp_width*axi_burst_len)-1:0] temp_read_rsp; /* Read Data Channel handshake */ always@(negedge S_RESETN or posedge S_ACLK) begin if(!S_RESETN)begin rd_fifo_rd_ptr = 0; rd_cnt = 0; rd_latency_count = get_rd_lat_number(1); rd_delayed = 0; rresp_time_cnt = 0; rd_v_b = 0; end else begin if(arvalid_flag[rresp_time_cnt] && ((($time - arvalid_receive_time[rresp_time_cnt])/s_aclk_period) >= rd_latency_count)) rd_delayed = 1; if(!read_fifo_empty && rd_delayed)begin rd_delayed = 0; arvalid_flag[rresp_time_cnt] = 1'b0; rd_v_b = ((arlen[rd_cnt[int_rd_cntr_width-2:0]]+1)*(2**arsize[rd_cnt[int_rd_cntr_width-2:0]])); temp_read_data = read_fifo[rd_fifo_rd_ptr[int_rd_cntr_width-2:0]]; rd_fifo_rd_ptr = rd_fifo_rd_ptr+1; if(arbrst[rd_cnt[int_rd_cntr_width-2:0]]=== AXI_WRAP) begin get_wrap_aligned_rd_data(temp_wrap_data, araddr[rd_cnt[int_rd_cntr_width-2:0]], temp_read_data, rd_v_b); temp_read_data = temp_wrap_data; end temp_read_rsp = 0; repeat(axi_burst_len) begin temp_read_rsp = temp_read_rsp >> axi_rsp_width; temp_read_rsp[(axi_rsp_width*axi_burst_len)-1:(axi_rsp_width*axi_burst_len)-axi_rsp_width] = fifo_rresp[rd_cnt[int_rd_cntr_width-2:0]][rsp_msb : rsp_lsb]; end slave.SEND_READ_BURST_RESP_CTRL(arid[rd_cnt[int_rd_cntr_width-2:0]], araddr[rd_cnt[int_rd_cntr_width-2:0]], arlen[rd_cnt[int_rd_cntr_width-2:0]], arsize[rd_cnt[int_rd_cntr_width-2:0]], arbrst[rd_cnt[int_rd_cntr_width-2:0]], temp_read_data, temp_read_rsp); rd_cnt = rd_cnt + 1; rresp_time_cnt = rresp_time_cnt+1; if(rresp_time_cnt === max_rd_outstanding_transactions) rresp_time_cnt = 0; if(rd_cnt[int_rd_cntr_width-2:0] === (max_rd_outstanding_transactions-1)) begin rd_cnt[int_rd_cntr_width-1] = ~ rd_cnt[int_rd_cntr_width-1]; rd_cnt[int_rd_cntr_width-2:0] = 0; end rd_latency_count = get_rd_lat_number(1); end end /// else end /// always endmodule

module generic_baseblocks_v2_1_command_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_ENABLE_S_VALID_CARRY = 0, parameter integer C_ENABLE_REGISTERED_OUTPUT = 0, parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2**C_FIFO_DEPTH_LOG // Range = [4:5]. parameter integer C_FIFO_WIDTH = 64 // Width of payload [1:512] ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Information output wire EMPTY, // FIFO empty (all stages) // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for data vector. genvar addr_cnt; genvar bit_cnt; integer index; ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIFO_DEPTH_LOG-1:0] addr; wire buffer_Full; wire buffer_Empty; wire next_Data_Exists; reg data_Exists_I; wire valid_Write; wire new_write; wire [C_FIFO_DEPTH_LOG-1:0] hsum_A; wire [C_FIFO_DEPTH_LOG-1:0] sum_A; wire [C_FIFO_DEPTH_LOG-1:0] addr_cy; wire buffer_full_early; wire [C_FIFO_WIDTH-1:0] M_MESG_I; // Payload wire M_VALID_I; // FIFO not empty wire M_READY_I; // FIFO pop ///////////////////////////////////////////////////////////////////////////// // Create Flags ///////////////////////////////////////////////////////////////////////////// assign buffer_full_early = ( (addr == {{C_FIFO_DEPTH_LOG-1{1'b1}}, 1'b0}) & valid_Write & ~M_READY_I ) | ( buffer_Full & ~M_READY_I ); assign S_READY = ~buffer_Full; assign buffer_Empty = (addr == {C_FIFO_DEPTH_LOG{1'b0}}); assign next_Data_Exists = (data_Exists_I & ~buffer_Empty) | (buffer_Empty & S_VALID) | (data_Exists_I & ~(M_READY_I & data_Exists_I)); always @ (posedge ACLK) begin if (ARESET) begin data_Exists_I <= 1'b0; end else begin data_Exists_I <= next_Data_Exists; end end assign M_VALID_I = data_Exists_I; // Select RTL or FPGA optimized instatiations for critical parts. generate if ( C_FAMILY == "rtl" || C_ENABLE_S_VALID_CARRY == 0 ) begin : USE_RTL_VALID_WRITE reg buffer_Full_q; assign valid_Write = S_VALID & ~buffer_Full; assign new_write = (S_VALID | ~buffer_Empty); assign addr_cy[0] = valid_Write; always @ (posedge ACLK) begin if (ARESET) begin buffer_Full_q <= 1'b0; end else if ( data_Exists_I ) begin buffer_Full_q <= buffer_full_early; end end assign buffer_Full = buffer_Full_q; end else begin : USE_FPGA_VALID_WRITE wire s_valid_dummy1; wire s_valid_dummy2; wire sel_s_valid; wire sel_new_write; wire valid_Write_dummy1; wire valid_Write_dummy2; assign sel_s_valid = ~buffer_Full; generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst1 ( .CIN(S_VALID), .S(1'b1), .COUT(s_valid_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) s_valid_dummy_inst2 ( .CIN(s_valid_dummy1), .S(1'b1), .COUT(s_valid_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_inst ( .CIN(s_valid_dummy2), .S(sel_s_valid), .COUT(valid_Write) ); assign sel_new_write = ~buffer_Empty; generic_baseblocks_v2_1_carry_latch_or # ( .C_FAMILY(C_FAMILY) ) new_write_inst ( .CIN(valid_Write), .I(sel_new_write), .O(new_write) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst1 ( .CIN(valid_Write), .S(1'b1), .COUT(valid_Write_dummy1) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst2 ( .CIN(valid_Write_dummy1), .S(1'b1), .COUT(valid_Write_dummy2) ); generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) valid_write_dummy_inst3 ( .CIN(valid_Write_dummy2), .S(1'b1), .COUT(addr_cy[0]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_I1 ( .Q(buffer_Full), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(buffer_full_early) // Data input ); end endgenerate ///////////////////////////////////////////////////////////////////////////// // Create address pointer ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_ADDR reg [C_FIFO_DEPTH_LOG-1:0] addr_q; always @ (posedge ACLK) begin if (ARESET) begin addr_q <= {C_FIFO_DEPTH_LOG{1'b0}}; end else if ( data_Exists_I ) begin if ( valid_Write & ~(M_READY_I & data_Exists_I) ) begin addr_q <= addr_q + 1'b1; end else if ( ~valid_Write & (M_READY_I & data_Exists_I) & ~buffer_Empty ) begin addr_q <= addr_q - 1'b1; end else begin addr_q <= addr_q; end end else begin addr_q <= addr_q; end end assign addr = addr_q; end else begin : USE_FPGA_ADDR for (addr_cnt = 0; addr_cnt < C_FIFO_DEPTH_LOG ; addr_cnt = addr_cnt + 1) begin : ADDR_GEN assign hsum_A[addr_cnt] = ((M_READY_I & data_Exists_I) ^ addr[addr_cnt]) & new_write; // Don't need the last muxcy, addr_cy(last) is not used anywhere if ( addr_cnt < C_FIFO_DEPTH_LOG - 1 ) begin : USE_MUXCY MUXCY MUXCY_inst ( .DI(addr[addr_cnt]), .CI(addr_cy[addr_cnt]), .S(hsum_A[addr_cnt]), .O(addr_cy[addr_cnt+1]) ); end else begin : NO_MUXCY end XORCY XORCY_inst ( .LI(hsum_A[addr_cnt]), .CI(addr_cy[addr_cnt]), .O(sum_A[addr_cnt]) ); FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(addr[addr_cnt]), // Data output .C(ACLK), // Clock input .CE(data_Exists_I), // Clock enable input .R(ARESET), // Synchronous reset input .D(sum_A[addr_cnt]) // Data input ); end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Data storage ///////////////////////////////////////////////////////////////////////////// generate if ( C_FAMILY == "rtl" ) begin : USE_RTL_FIFO reg [C_FIFO_WIDTH-1:0] data_srl[2 ** C_FIFO_DEPTH_LOG-1:0]; always @ (posedge ACLK) begin if ( valid_Write ) begin for (index = 0; index < 2 ** C_FIFO_DEPTH_LOG-1 ; index = index + 1) begin data_srl[index+1] <= data_srl[index]; end data_srl[0] <= S_MESG; end end assign M_MESG_I = data_srl[addr]; end else begin : USE_FPGA_FIFO for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN if ( C_FIFO_DEPTH_LOG == 5 ) begin : USE_32 SRLC32E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC32E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q31(), // SRL cascade output pin .A(addr), // 5-bit shift depth select input .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end else begin : USE_16 SRLC16E # ( .INIT(32'h00000000) // Initial Value of Shift Register ) SRLC16E_inst ( .Q(M_MESG_I[bit_cnt]), // SRL data output .Q15(), // SRL cascade output pin .A0(addr[0]), // 4-bit shift depth select input 0 .A1(addr[1]), // 4-bit shift depth select input 1 .A2(addr[2]), // 4-bit shift depth select input 2 .A3(addr[3]), // 4-bit shift depth select input 3 .CE(valid_Write), // Clock enable input .CLK(ACLK), // Clock input .D(S_MESG[bit_cnt]) // SRL data input ); end // C_FIFO_DEPTH_LOG end // end for bit_cnt end // C_FAMILY endgenerate ///////////////////////////////////////////////////////////////////////////// // Pipeline stage ///////////////////////////////////////////////////////////////////////////// generate if ( C_ENABLE_REGISTERED_OUTPUT != 0 ) begin : USE_FF_OUT wire [C_FIFO_WIDTH-1:0] M_MESG_FF; // Payload wire M_VALID_FF; // FIFO not empty // Select RTL or FPGA optimized instatiations for critical parts. if ( C_FAMILY == "rtl" ) begin : USE_RTL_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_Q; // Payload reg M_VALID_Q; // FIFO not empty always @ (posedge ACLK) begin if (ARESET) begin M_MESG_Q <= {C_FIFO_WIDTH{1'b0}}; M_VALID_Q <= 1'b0; end else begin if ( M_READY_I ) begin M_MESG_Q <= M_MESG_I; M_VALID_Q <= M_VALID_I; end end end assign M_MESG_FF = M_MESG_Q; assign M_VALID_FF = M_VALID_Q; end else begin : USE_FPGA_OUTPUT_PIPELINE reg [C_FIFO_WIDTH-1:0] M_MESG_CMB; // Payload reg M_VALID_CMB; // FIFO not empty always @ * begin if ( M_READY_I ) begin M_MESG_CMB <= M_MESG_I; M_VALID_CMB <= M_VALID_I; end else begin M_MESG_CMB <= M_MESG_FF; M_VALID_CMB <= M_VALID_FF; end end for (bit_cnt = 0; bit_cnt < C_FIFO_WIDTH ; bit_cnt = bit_cnt + 1) begin : DATA_GEN FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_MESG_FF[bit_cnt]), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_MESG_CMB[bit_cnt]) // Data input ); end // end for bit_cnt FDRE #( .INIT(1'b0) // Initial value of register (1'b0 or 1'b1) ) FDRE_inst ( .Q(M_VALID_FF), // Data output .C(ACLK), // Clock input .CE(1'b1), // Clock enable input .R(ARESET), // Synchronous reset input .D(M_VALID_CMB) // Data input ); end assign EMPTY = ~M_VALID_I & ~M_VALID_FF; assign M_MESG = M_MESG_FF; assign M_VALID = M_VALID_FF; assign M_READY_I = ( M_READY & M_VALID_FF ) | ~M_VALID_FF; end else begin : NO_FF_OUT assign EMPTY = ~M_VALID_I; assign M_MESG = M_MESG_I; assign M_VALID = M_VALID_I; assign M_READY_I = M_READY; end endgenerate endmodule

module generic_baseblocks_v2_1_comparator_sel_mask_static # ( parameter C_FAMILY = "virtex6", // FPGA Family. Current version: virtex6 or spartan6. parameter C_VALUE = 4'b0, // Static value to compare against. parameter integer C_DATA_WIDTH = 4 // Data width for comparator. ) ( input wire CIN, input wire S, input wire [C_DATA_WIDTH-1:0] A, input wire [C_DATA_WIDTH-1:0] B, input wire [C_DATA_WIDTH-1:0] M, output wire COUT ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// // Generate variable for bit vector. genvar lut_cnt; ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Bits per LUT for this architecture. localparam integer C_BITS_PER_LUT = 1; // Constants for packing levels. localparam integer C_NUM_LUT = ( C_DATA_WIDTH + C_BITS_PER_LUT - 1 ) / C_BITS_PER_LUT; // localparam integer C_FIX_DATA_WIDTH = ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) ? C_NUM_LUT * C_BITS_PER_LUT : C_DATA_WIDTH; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire [C_FIX_DATA_WIDTH-1:0] a_local; wire [C_FIX_DATA_WIDTH-1:0] b_local; wire [C_FIX_DATA_WIDTH-1:0] m_local; wire [C_FIX_DATA_WIDTH-1:0] v_local; wire [C_NUM_LUT-1:0] sel; wire [C_NUM_LUT:0] carry_local; ///////////////////////////////////////////////////////////////////////////// // ///////////////////////////////////////////////////////////////////////////// generate // Assign input to local vectors. assign carry_local[0] = CIN; // Extend input data to fit. if ( C_NUM_LUT * C_BITS_PER_LUT > C_DATA_WIDTH ) begin : USE_EXTENDED_DATA assign a_local = {A, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign b_local = {B, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign m_local = {M, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; assign v_local = {C_VALUE, {C_NUM_LUT * C_BITS_PER_LUT - C_DATA_WIDTH{1'b0}}}; end else begin : NO_EXTENDED_DATA assign a_local = A; assign b_local = B; assign m_local = M; assign v_local = C_VALUE; end // Instantiate one generic_baseblocks_v2_1_carry and per level. for (lut_cnt = 0; lut_cnt < C_NUM_LUT ; lut_cnt = lut_cnt + 1) begin : LUT_LEVEL // Create the local select signal assign sel[lut_cnt] = ( ( ( a_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b0 ) ) | ( ( ( b_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) == ( v_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] & m_local[lut_cnt*C_BITS_PER_LUT +: C_BITS_PER_LUT] ) ) & ( S == 1'b1 ) ); // Instantiate each LUT level. generic_baseblocks_v2_1_carry_and # ( .C_FAMILY(C_FAMILY) ) compare_inst ( .COUT (carry_local[lut_cnt+1]), .CIN (carry_local[lut_cnt]), .S (sel[lut_cnt]) ); end // end for lut_cnt // Assign output from local vector. assign COUT = carry_local[C_NUM_LUT]; endgenerate endmodule

module axi_data_fifo_v2_1_axic_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2**C_FIFO_DEPTH_LOG // Range = [5:9] when TYPE="lut", // Range = [5:12] when TYPE="bram", parameter integer C_FIFO_WIDTH = 64, // Width of payload [1:512] parameter C_FIFO_TYPE = "lut" // "lut" = LUT (SRL) based, // "bram" = BRAM based ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); axi_data_fifo_v2_1_fifo_gen #( .C_FAMILY(C_FAMILY), .C_COMMON_CLOCK(1), .C_FIFO_DEPTH_LOG(C_FIFO_DEPTH_LOG), .C_FIFO_WIDTH(C_FIFO_WIDTH), .C_FIFO_TYPE(C_FIFO_TYPE)) inst ( .clk(ACLK), .rst(ARESET), .wr_clk(1'b0), .wr_en(S_VALID), .wr_ready(S_READY), .wr_data(S_MESG), .rd_clk(1'b0), .rd_en(M_READY), .rd_valid(M_VALID), .rd_data(M_MESG)); endmodule