/* Copyright (c) 2018 Alex Forencich Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ // Language: Verilog 2001 `timescale 1ns / 1ps /* * AXI4 crossbar (write) */ module axi_crossbar_wr # ( parameter S_COUNT = 4, parameter M_COUNT = 4, parameter DATA_WIDTH = 32, parameter ADDR_WIDTH = 32, parameter STRB_WIDTH = (DATA_WIDTH/8), parameter S_ID_WIDTH = 8, parameter M_ID_WIDTH = S_ID_WIDTH+$clog2(S_COUNT), parameter AWUSER_ENABLE = 0, parameter AWUSER_WIDTH = 1, parameter WUSER_ENABLE = 0, parameter WUSER_WIDTH = 1, parameter BUSER_ENABLE = 0, parameter BUSER_WIDTH = 1, parameter S_THREADS = {S_COUNT{32'd2}}, parameter S_ACCEPT = {S_COUNT{32'd16}}, parameter M_REGIONS = 1, parameter M_BASE_ADDR = {32'h03000000, 32'h02000000, 32'h01000000, 32'h00000000}, parameter M_ADDR_WIDTH = {M_COUNT{{M_REGIONS{32'd24}}}}, parameter M_CONNECT = {M_COUNT{{S_COUNT{1'b1}}}}, parameter M_ISSUE = {M_COUNT{32'd4}}, parameter M_SECURE = {M_COUNT{1'b0}}, parameter S_AW_REG_TYPE = {S_COUNT{2'd0}}, parameter S_W_REG_TYPE = {S_COUNT{2'd0}}, parameter S_B_REG_TYPE = {S_COUNT{2'd1}}, parameter M_AW_REG_TYPE = {M_COUNT{2'd1}}, parameter M_W_REG_TYPE = {M_COUNT{2'd2}}, parameter M_B_REG_TYPE = {M_COUNT{2'd0}} ) ( input wire clk, input wire rst, /* * AXI slave interfaces */ input wire [S_COUNT*S_ID_WIDTH-1:0] s_axi_awid, input wire [S_COUNT*ADDR_WIDTH-1:0] s_axi_awaddr, input wire [S_COUNT*8-1:0] s_axi_awlen, input wire [S_COUNT*3-1:0] s_axi_awsize, input wire [S_COUNT*2-1:0] s_axi_awburst, input wire [S_COUNT-1:0] s_axi_awlock, input wire [S_COUNT*4-1:0] s_axi_awcache, input wire [S_COUNT*3-1:0] s_axi_awprot, input wire [S_COUNT*4-1:0] s_axi_awqos, input wire [S_COUNT*AWUSER_WIDTH-1:0] s_axi_awuser, input wire [S_COUNT-1:0] s_axi_awvalid, output wire [S_COUNT-1:0] s_axi_awready, input wire [S_COUNT*DATA_WIDTH-1:0] s_axi_wdata, input wire [S_COUNT*STRB_WIDTH-1:0] s_axi_wstrb, input wire [S_COUNT-1:0] s_axi_wlast, input wire [S_COUNT*WUSER_WIDTH-1:0] s_axi_wuser, input wire [S_COUNT-1:0] s_axi_wvalid, output wire [S_COUNT-1:0] s_axi_wready, output wire [S_COUNT*S_ID_WIDTH-1:0] s_axi_bid, output wire [S_COUNT*2-1:0] s_axi_bresp, output wire [S_COUNT*BUSER_WIDTH-1:0] s_axi_buser, output wire [S_COUNT-1:0] s_axi_bvalid, input wire [S_COUNT-1:0] s_axi_bready, /* * AXI master interfaces */ output wire [M_COUNT*M_ID_WIDTH-1:0] m_axi_awid, output wire [M_COUNT*ADDR_WIDTH-1:0] m_axi_awaddr, output wire [M_COUNT*8-1:0] m_axi_awlen, output wire [M_COUNT*3-1:0] m_axi_awsize, output wire [M_COUNT*2-1:0] m_axi_awburst, output wire [M_COUNT-1:0] m_axi_awlock, output wire [M_COUNT*4-1:0] m_axi_awcache, output wire [M_COUNT*3-1:0] m_axi_awprot, output wire [M_COUNT*4-1:0] m_axi_awqos, output wire [M_COUNT*4-1:0] m_axi_awregion, output wire [M_COUNT*AWUSER_WIDTH-1:0] m_axi_awuser, output wire [M_COUNT-1:0] m_axi_awvalid, input wire [M_COUNT-1:0] m_axi_awready, output wire [M_COUNT*DATA_WIDTH-1:0] m_axi_wdata, output wire [M_COUNT*STRB_WIDTH-1:0] m_axi_wstrb, output wire [M_COUNT-1:0] m_axi_wlast, output wire [M_COUNT*WUSER_WIDTH-1:0] m_axi_wuser, output wire [M_COUNT-1:0] m_axi_wvalid, input wire [M_COUNT-1:0] m_axi_wready, input wire [M_COUNT*M_ID_WIDTH-1:0] m_axi_bid, input wire [M_COUNT*2-1:0] m_axi_bresp, input wire [M_COUNT*BUSER_WIDTH-1:0] m_axi_buser, input wire [M_COUNT-1:0] m_axi_bvalid, output wire [M_COUNT-1:0] m_axi_bready ); parameter CL_S_COUNT = $clog2(S_COUNT); parameter CL_M_COUNT = $clog2(M_COUNT); parameter M_COUNT_P1 = M_COUNT+1; parameter CL_M_COUNT_P1 = $clog2(M_COUNT_P1); integer i; // check configuration initial begin if (M_ID_WIDTH < S_ID_WIDTH+$clog2(S_COUNT)) begin $error("Error: M_ID_WIDTH must be at least $clog2(S_COUNT) larger than S_ID_WIDTH"); $finish; end for (i = 0; i < M_COUNT*M_REGIONS; i = i + 1) begin if (M_ADDR_WIDTH[i*32 +: 32] && (M_ADDR_WIDTH[i*32 +: 32] < 12 || M_ADDR_WIDTH[i*32 +: 32] > ADDR_WIDTH)) begin $error("Error: value out of range"); $finish; end end end wire [S_COUNT*S_ID_WIDTH-1:0] int_s_axi_awid; wire [S_COUNT*ADDR_WIDTH-1:0] int_s_axi_awaddr; wire [S_COUNT*8-1:0] int_s_axi_awlen; wire [S_COUNT*3-1:0] int_s_axi_awsize; wire [S_COUNT*2-1:0] int_s_axi_awburst; wire [S_COUNT-1:0] int_s_axi_awlock; wire [S_COUNT*4-1:0] int_s_axi_awcache; wire [S_COUNT*3-1:0] int_s_axi_awprot; wire [S_COUNT*4-1:0] int_s_axi_awqos; wire [S_COUNT*4-1:0] int_s_axi_awregion; wire [S_COUNT*AWUSER_WIDTH-1:0] int_s_axi_awuser; wire [S_COUNT-1:0] int_s_axi_awvalid; wire [S_COUNT-1:0] int_s_axi_awready; wire [S_COUNT*M_COUNT-1:0] int_axi_awvalid; wire [M_COUNT*S_COUNT-1:0] int_axi_awready; wire [S_COUNT*DATA_WIDTH-1:0] int_s_axi_wdata; wire [S_COUNT*STRB_WIDTH-1:0] int_s_axi_wstrb; wire [S_COUNT-1:0] int_s_axi_wlast; wire [S_COUNT*WUSER_WIDTH-1:0] int_s_axi_wuser; wire [S_COUNT-1:0] int_s_axi_wvalid; wire [S_COUNT-1:0] int_s_axi_wready; wire [S_COUNT*M_COUNT-1:0] int_axi_wvalid; wire [M_COUNT*S_COUNT-1:0] int_axi_wready; wire [M_COUNT*M_ID_WIDTH-1:0] int_m_axi_bid; wire [M_COUNT*2-1:0] int_m_axi_bresp; wire [M_COUNT*BUSER_WIDTH-1:0] int_m_axi_buser; wire [M_COUNT-1:0] int_m_axi_bvalid; wire [M_COUNT-1:0] int_m_axi_bready; wire [M_COUNT*S_COUNT-1:0] int_axi_bvalid; wire [S_COUNT*M_COUNT-1:0] int_axi_bready; generate genvar m, n; for (m = 0; m < S_COUNT; m = m + 1) begin : s_ifaces // address decode and admission control wire [CL_M_COUNT-1:0] a_select; wire m_axi_avalid; wire m_axi_aready; wire [CL_M_COUNT-1:0] m_wc_select; wire m_wc_decerr; wire m_wc_valid; wire m_wc_ready; wire m_rc_decerr; wire m_rc_valid; wire m_rc_ready; wire [S_ID_WIDTH-1:0] s_cpl_id; wire s_cpl_valid; axi_crossbar_addr #( .S(m), .S_COUNT(S_COUNT), .M_COUNT(M_COUNT), .ADDR_WIDTH(ADDR_WIDTH), .ID_WIDTH(S_ID_WIDTH), .S_THREADS(S_THREADS[m*32 +: 32]), .S_ACCEPT(S_ACCEPT[m*32 +: 32]), .M_REGIONS(M_REGIONS), .M_BASE_ADDR(M_BASE_ADDR), .M_ADDR_WIDTH(M_ADDR_WIDTH), .M_CONNECT(M_CONNECT), .M_SECURE(M_SECURE), .WC_OUTPUT(1) ) addr_inst ( .clk(clk), .rst(rst), /* * Address input */ .s_axi_aid(int_s_axi_awid[m*S_ID_WIDTH +: S_ID_WIDTH]), .s_axi_aaddr(int_s_axi_awaddr[m*ADDR_WIDTH +: ADDR_WIDTH]), .s_axi_aprot(int_s_axi_awprot[m*3 +: 3]), .s_axi_aqos(int_s_axi_awqos[m*4 +: 4]), .s_axi_avalid(int_s_axi_awvalid[m]), .s_axi_aready(int_s_axi_awready[m]), /* * Address output */ .m_axi_aregion(int_s_axi_awregion[m*4 +: 4]), .m_select(a_select), .m_axi_avalid(m_axi_avalid), .m_axi_aready(m_axi_aready), /* * Write command output */ .m_wc_select(m_wc_select), .m_wc_decerr(m_wc_decerr), .m_wc_valid(m_wc_valid), .m_wc_ready(m_wc_ready), /* * Response command output */ .m_rc_decerr(m_rc_decerr), .m_rc_valid(m_rc_valid), .m_rc_ready(m_rc_ready), /* * Completion input */ .s_cpl_id(s_cpl_id), .s_cpl_valid(s_cpl_valid) ); assign int_axi_awvalid[m*M_COUNT +: M_COUNT] = m_axi_avalid << a_select; assign m_axi_aready = int_axi_awready[a_select*S_COUNT+m]; // write command handling reg [CL_M_COUNT-1:0] w_select_reg = 0, w_select_next; reg w_drop_reg = 1'b0, w_drop_next; reg w_select_valid_reg = 1'b0, w_select_valid_next; assign m_wc_ready = !w_select_valid_reg; always @* begin w_select_next = w_select_reg; w_drop_next = w_drop_reg && !(int_s_axi_wvalid[m] && int_s_axi_wready[m] && int_s_axi_wlast[m]); w_select_valid_next = w_select_valid_reg && !(int_s_axi_wvalid[m] && int_s_axi_wready[m] && int_s_axi_wlast[m]); if (m_wc_valid && !w_select_valid_reg) begin w_select_next = m_wc_select; w_drop_next = m_wc_decerr; w_select_valid_next = m_wc_valid; end end always @(posedge clk) begin if (rst) begin w_select_valid_reg <= 1'b0; end else begin w_select_valid_reg <= w_select_valid_next; end w_select_reg <= w_select_next; w_drop_reg <= w_drop_next; end // write data forwarding assign int_axi_wvalid[m*M_COUNT +: M_COUNT] = (int_s_axi_wvalid[m] && w_select_valid_reg && !w_drop_reg) << w_select_reg; assign int_s_axi_wready[m] = int_axi_wready[w_select_reg*S_COUNT+m] || w_drop_reg; // decode error handling reg [S_ID_WIDTH-1:0] decerr_m_axi_bid_reg = {S_ID_WIDTH{1'b0}}, decerr_m_axi_bid_next; reg decerr_m_axi_bvalid_reg = 1'b0, decerr_m_axi_bvalid_next; wire decerr_m_axi_bready; assign m_rc_ready = !decerr_m_axi_bvalid_reg; always @* begin decerr_m_axi_bid_next = decerr_m_axi_bid_reg; decerr_m_axi_bvalid_next = decerr_m_axi_bvalid_reg; if (decerr_m_axi_bvalid_reg) begin if (decerr_m_axi_bready) begin decerr_m_axi_bvalid_next = 1'b0; end end else if (m_rc_valid && m_rc_ready) begin decerr_m_axi_bid_next = int_s_axi_awid[m*S_ID_WIDTH +: S_ID_WIDTH]; decerr_m_axi_bvalid_next = 1'b1; end end always @(posedge clk) begin if (rst) begin decerr_m_axi_bvalid_reg <= 1'b0; end else begin decerr_m_axi_bvalid_reg <= decerr_m_axi_bvalid_next; end decerr_m_axi_bid_reg <= decerr_m_axi_bid_next; end // write response arbitration wire [M_COUNT_P1-1:0] b_request; wire [M_COUNT_P1-1:0] b_acknowledge; wire [M_COUNT_P1-1:0] b_grant; wire b_grant_valid; wire [CL_M_COUNT_P1-1:0] b_grant_encoded; arbiter #( .PORTS(M_COUNT_P1), .TYPE("ROUND_ROBIN"), .BLOCK("ACKNOWLEDGE"), .LSB_PRIORITY("HIGH") ) b_arb_inst ( .clk(clk), .rst(rst), .request(b_request), .acknowledge(b_acknowledge), .grant(b_grant), .grant_valid(b_grant_valid), .grant_encoded(b_grant_encoded) ); // write response mux wire [S_ID_WIDTH-1:0] m_axi_bid_mux = {decerr_m_axi_bid_reg, int_m_axi_bid} >> b_grant_encoded*M_ID_WIDTH; wire [1:0] m_axi_bresp_mux = {2'b11, int_m_axi_bresp} >> b_grant_encoded*2; wire [BUSER_WIDTH-1:0] m_axi_buser_mux = {{BUSER_WIDTH{1'b0}}, int_m_axi_buser} >> b_grant_encoded*BUSER_WIDTH; wire m_axi_bvalid_mux = ({decerr_m_axi_bvalid_reg, int_m_axi_bvalid} >> b_grant_encoded) & b_grant_valid; wire m_axi_bready_mux; assign int_axi_bready[m*M_COUNT +: M_COUNT] = (b_grant_valid && m_axi_bready_mux) << b_grant_encoded; assign decerr_m_axi_bready = (b_grant_valid && m_axi_bready_mux) && (b_grant_encoded == M_COUNT_P1-1); for (n = 0; n < M_COUNT; n = n + 1) begin assign b_request[n] = int_axi_bvalid[n*S_COUNT+m] && !b_grant[n]; assign b_acknowledge[n] = b_grant[n] && int_axi_bvalid[n*S_COUNT+m] && m_axi_bready_mux; end assign b_request[M_COUNT_P1-1] = decerr_m_axi_bvalid_reg && !b_grant[M_COUNT_P1-1]; assign b_acknowledge[M_COUNT_P1-1] = b_grant[M_COUNT_P1-1] && decerr_m_axi_bvalid_reg && m_axi_bready_mux; assign s_cpl_id = m_axi_bid_mux; assign s_cpl_valid = m_axi_bvalid_mux && m_axi_bready_mux; // S side register axi_register_wr #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .STRB_WIDTH(STRB_WIDTH), .ID_WIDTH(S_ID_WIDTH), .AWUSER_ENABLE(AWUSER_ENABLE), .AWUSER_WIDTH(AWUSER_WIDTH), .WUSER_ENABLE(WUSER_ENABLE), .WUSER_WIDTH(WUSER_WIDTH), .BUSER_ENABLE(BUSER_ENABLE), .BUSER_WIDTH(BUSER_WIDTH), .AW_REG_TYPE(S_AW_REG_TYPE[m*2 +: 2]), .W_REG_TYPE(S_W_REG_TYPE[m*2 +: 2]), .B_REG_TYPE(S_B_REG_TYPE[m*2 +: 2]) ) reg_inst ( .clk(clk), .rst(rst), .s_axi_awid(s_axi_awid[m*S_ID_WIDTH +: S_ID_WIDTH]), .s_axi_awaddr(s_axi_awaddr[m*ADDR_WIDTH +: ADDR_WIDTH]), .s_axi_awlen(s_axi_awlen[m*8 +: 8]), .s_axi_awsize(s_axi_awsize[m*3 +: 3]), .s_axi_awburst(s_axi_awburst[m*2 +: 2]), .s_axi_awlock(s_axi_awlock[m]), .s_axi_awcache(s_axi_awcache[m*4 +: 4]), .s_axi_awprot(s_axi_awprot[m*3 +: 3]), .s_axi_awqos(s_axi_awqos[m*4 +: 4]), .s_axi_awregion(4'd0), .s_axi_awuser(s_axi_awuser[m*AWUSER_WIDTH +: AWUSER_WIDTH]), .s_axi_awvalid(s_axi_awvalid[m]), .s_axi_awready(s_axi_awready[m]), .s_axi_wdata(s_axi_wdata[m*DATA_WIDTH +: DATA_WIDTH]), .s_axi_wstrb(s_axi_wstrb[m*STRB_WIDTH +: STRB_WIDTH]), .s_axi_wlast(s_axi_wlast[m]), .s_axi_wuser(s_axi_wuser[m*WUSER_WIDTH +: WUSER_WIDTH]), .s_axi_wvalid(s_axi_wvalid[m]), .s_axi_wready(s_axi_wready[m]), .s_axi_bid(s_axi_bid[m*S_ID_WIDTH +: S_ID_WIDTH]), .s_axi_bresp(s_axi_bresp[m*2 +: 2]), .s_axi_buser(s_axi_buser[m*BUSER_WIDTH +: BUSER_WIDTH]), .s_axi_bvalid(s_axi_bvalid[m]), .s_axi_bready(s_axi_bready[m]), .m_axi_awid(int_s_axi_awid[m*S_ID_WIDTH +: S_ID_WIDTH]), .m_axi_awaddr(int_s_axi_awaddr[m*ADDR_WIDTH +: ADDR_WIDTH]), .m_axi_awlen(int_s_axi_awlen[m*8 +: 8]), .m_axi_awsize(int_s_axi_awsize[m*3 +: 3]), .m_axi_awburst(int_s_axi_awburst[m*2 +: 2]), .m_axi_awlock(int_s_axi_awlock[m]), .m_axi_awcache(int_s_axi_awcache[m*4 +: 4]), .m_axi_awprot(int_s_axi_awprot[m*3 +: 3]), .m_axi_awqos(int_s_axi_awqos[m*4 +: 4]), .m_axi_awregion(), .m_axi_awuser(int_s_axi_awuser[m*AWUSER_WIDTH +: AWUSER_WIDTH]), .m_axi_awvalid(int_s_axi_awvalid[m]), .m_axi_awready(int_s_axi_awready[m]), .m_axi_wdata(int_s_axi_wdata[m*DATA_WIDTH +: DATA_WIDTH]), .m_axi_wstrb(int_s_axi_wstrb[m*STRB_WIDTH +: STRB_WIDTH]), .m_axi_wlast(int_s_axi_wlast[m]), .m_axi_wuser(int_s_axi_wuser[m*WUSER_WIDTH +: WUSER_WIDTH]), .m_axi_wvalid(int_s_axi_wvalid[m]), .m_axi_wready(int_s_axi_wready[m]), .m_axi_bid(m_axi_bid_mux), .m_axi_bresp(m_axi_bresp_mux), .m_axi_buser(m_axi_buser_mux), .m_axi_bvalid(m_axi_bvalid_mux), .m_axi_bready(m_axi_bready_mux) ); end // s_ifaces for (n = 0; n < M_COUNT; n = n + 1) begin : m_ifaces // in-flight transaction count wire trans_start; wire trans_complete; reg [$clog2(M_ISSUE[n*32 +: 32]+1)-1:0] trans_count_reg = 0; wire trans_limit = trans_count_reg >= M_ISSUE[n*32 +: 32] && !trans_complete; always @(posedge clk) begin if (rst) begin trans_count_reg <= 0; end else begin if (trans_start && !trans_complete) begin trans_count_reg <= trans_count_reg + 1; end else if (!trans_start && trans_complete) begin trans_count_reg <= trans_count_reg - 1; end end end // address arbitration reg [CL_S_COUNT-1:0] w_select_reg = 0, w_select_next; reg w_select_valid_reg = 1'b0, w_select_valid_next; reg w_select_new_reg = 1'b0, w_select_new_next; wire [S_COUNT-1:0] a_request; wire [S_COUNT-1:0] a_acknowledge; wire [S_COUNT-1:0] a_grant; wire a_grant_valid; wire [CL_S_COUNT-1:0] a_grant_encoded; arbiter #( .PORTS(S_COUNT), .TYPE("ROUND_ROBIN"), .BLOCK("ACKNOWLEDGE"), .LSB_PRIORITY("HIGH") ) a_arb_inst ( .clk(clk), .rst(rst), .request(a_request), .acknowledge(a_acknowledge), .grant(a_grant), .grant_valid(a_grant_valid), .grant_encoded(a_grant_encoded) ); // address mux wire [M_ID_WIDTH-1:0] s_axi_awid_mux = int_s_axi_awid[a_grant_encoded*S_ID_WIDTH +: S_ID_WIDTH] | (a_grant_encoded << S_ID_WIDTH); wire [ADDR_WIDTH-1:0] s_axi_awaddr_mux = int_s_axi_awaddr[a_grant_encoded*ADDR_WIDTH +: ADDR_WIDTH]; wire [7:0] s_axi_awlen_mux = int_s_axi_awlen[a_grant_encoded*8 +: 8]; wire [2:0] s_axi_awsize_mux = int_s_axi_awsize[a_grant_encoded*3 +: 3]; wire [1:0] s_axi_awburst_mux = int_s_axi_awburst[a_grant_encoded*2 +: 2]; wire s_axi_awlock_mux = int_s_axi_awlock[a_grant_encoded]; wire [3:0] s_axi_awcache_mux = int_s_axi_awcache[a_grant_encoded*4 +: 4]; wire [2:0] s_axi_awprot_mux = int_s_axi_awprot[a_grant_encoded*3 +: 3]; wire [3:0] s_axi_awqos_mux = int_s_axi_awqos[a_grant_encoded*4 +: 4]; wire [3:0] s_axi_awregion_mux = int_s_axi_awregion[a_grant_encoded*4 +: 4]; wire [AWUSER_WIDTH-1:0] s_axi_awuser_mux = int_s_axi_awuser[a_grant_encoded*AWUSER_WIDTH +: AWUSER_WIDTH]; wire s_axi_awvalid_mux = int_axi_awvalid[a_grant_encoded*M_COUNT+n] && a_grant_valid; wire s_axi_awready_mux; assign int_axi_awready[n*S_COUNT +: S_COUNT] = (a_grant_valid && s_axi_awready_mux) << a_grant_encoded; for (m = 0; m < S_COUNT; m = m + 1) begin assign a_request[m] = int_axi_awvalid[m*M_COUNT+n] && !a_grant[m] && !trans_limit && !w_select_valid_next; assign a_acknowledge[m] = a_grant[m] && int_axi_awvalid[m*M_COUNT+n] && s_axi_awready_mux; end assign trans_start = s_axi_awvalid_mux && s_axi_awready_mux && a_grant_valid; // write data mux wire [DATA_WIDTH-1:0] s_axi_wdata_mux = int_s_axi_wdata[w_select_reg*DATA_WIDTH +: DATA_WIDTH]; wire [STRB_WIDTH-1:0] s_axi_wstrb_mux = int_s_axi_wstrb[w_select_reg*STRB_WIDTH +: STRB_WIDTH]; wire s_axi_wlast_mux = int_s_axi_wlast[w_select_reg]; wire [WUSER_WIDTH-1:0] s_axi_wuser_mux = int_s_axi_wuser[w_select_reg*WUSER_WIDTH +: WUSER_WIDTH]; wire s_axi_wvalid_mux = int_axi_wvalid[w_select_reg*M_COUNT+n] && w_select_valid_reg; wire s_axi_wready_mux; assign int_axi_wready[n*S_COUNT +: S_COUNT] = (w_select_valid_reg && s_axi_wready_mux) << w_select_reg; // write data routing always @* begin w_select_next = w_select_reg; w_select_valid_next = w_select_valid_reg && !(s_axi_wvalid_mux && s_axi_wready_mux && s_axi_wlast_mux); w_select_new_next = w_select_new_reg || !a_grant_valid || a_acknowledge; if (a_grant_valid && !w_select_valid_reg && w_select_new_reg) begin w_select_next = a_grant_encoded; w_select_valid_next = a_grant_valid; w_select_new_next = 1'b0; end end always @(posedge clk) begin if (rst) begin w_select_valid_reg <= 1'b0; w_select_new_reg <= 1'b1; end else begin w_select_valid_reg <= w_select_valid_next; w_select_new_reg <= w_select_new_next; end w_select_reg <= w_select_next; end // write response forwarding wire [CL_S_COUNT-1:0] b_select = m_axi_bid[n*M_ID_WIDTH +: M_ID_WIDTH] >> S_ID_WIDTH; assign int_axi_bvalid[n*S_COUNT +: S_COUNT] = int_m_axi_bvalid[n] << b_select; assign int_m_axi_bready[n] = int_axi_bready[b_select*M_COUNT+n]; assign trans_complete = int_m_axi_bvalid[n] && int_m_axi_bready[n]; // M side register axi_register_wr #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .STRB_WIDTH(STRB_WIDTH), .ID_WIDTH(M_ID_WIDTH), .AWUSER_ENABLE(AWUSER_ENABLE), .AWUSER_WIDTH(AWUSER_WIDTH), .WUSER_ENABLE(WUSER_ENABLE), .WUSER_WIDTH(WUSER_WIDTH), .BUSER_ENABLE(BUSER_ENABLE), .BUSER_WIDTH(BUSER_WIDTH), .AW_REG_TYPE(M_AW_REG_TYPE[n*2 +: 2]), .W_REG_TYPE(M_W_REG_TYPE[n*2 +: 2]), .B_REG_TYPE(M_B_REG_TYPE[n*2 +: 2]) ) reg_inst ( .clk(clk), .rst(rst), .s_axi_awid(s_axi_awid_mux), .s_axi_awaddr(s_axi_awaddr_mux), .s_axi_awlen(s_axi_awlen_mux), .s_axi_awsize(s_axi_awsize_mux), .s_axi_awburst(s_axi_awburst_mux), .s_axi_awlock(s_axi_awlock_mux), .s_axi_awcache(s_axi_awcache_mux), .s_axi_awprot(s_axi_awprot_mux), .s_axi_awqos(s_axi_awqos_mux), .s_axi_awregion(s_axi_awregion_mux), .s_axi_awuser(s_axi_awuser_mux), .s_axi_awvalid(s_axi_awvalid_mux), .s_axi_awready(s_axi_awready_mux), .s_axi_wdata(s_axi_wdata_mux), .s_axi_wstrb(s_axi_wstrb_mux), .s_axi_wlast(s_axi_wlast_mux), .s_axi_wuser(s_axi_wuser_mux), .s_axi_wvalid(s_axi_wvalid_mux), .s_axi_wready(s_axi_wready_mux), .s_axi_bid(int_m_axi_bid[n*M_ID_WIDTH +: M_ID_WIDTH]), .s_axi_bresp(int_m_axi_bresp[n*2 +: 2]), .s_axi_buser(int_m_axi_buser[n*BUSER_WIDTH +: BUSER_WIDTH]), .s_axi_bvalid(int_m_axi_bvalid[n]), .s_axi_bready(int_m_axi_bready[n]), .m_axi_awid(m_axi_awid[n*M_ID_WIDTH +: M_ID_WIDTH]), .m_axi_awaddr(m_axi_awaddr[n*ADDR_WIDTH +: ADDR_WIDTH]), .m_axi_awlen(m_axi_awlen[n*8 +: 8]), .m_axi_awsize(m_axi_awsize[n*3 +: 3]), .m_axi_awburst(m_axi_awburst[n*2 +: 2]), .m_axi_awlock(m_axi_awlock[n]), .m_axi_awcache(m_axi_awcache[n*4 +: 4]), .m_axi_awprot(m_axi_awprot[n*3 +: 3]), .m_axi_awqos(m_axi_awqos[n*4 +: 4]), .m_axi_awregion(m_axi_awregion[n*4 +: 4]), .m_axi_awuser(m_axi_awuser[n*AWUSER_WIDTH +: AWUSER_WIDTH]), .m_axi_awvalid(m_axi_awvalid[n]), .m_axi_awready(m_axi_awready[n]), .m_axi_wdata(m_axi_wdata[n*DATA_WIDTH +: DATA_WIDTH]), .m_axi_wstrb(m_axi_wstrb[n*STRB_WIDTH +: STRB_WIDTH]), .m_axi_wlast(m_axi_wlast[n]), .m_axi_wuser(m_axi_wuser[n*WUSER_WIDTH +: WUSER_WIDTH]), .m_axi_wvalid(m_axi_wvalid[n]), .m_axi_wready(m_axi_wready[n]), .m_axi_bid(m_axi_bid[n*M_ID_WIDTH +: M_ID_WIDTH]), .m_axi_bresp(m_axi_bresp[n*2 +: 2]), .m_axi_buser(m_axi_buser[n*BUSER_WIDTH +: BUSER_WIDTH]), .m_axi_bvalid(m_axi_bvalid[n]), .m_axi_bready(m_axi_bready[n]) ); end // m_ifaces endgenerate endmodule