/* 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 interconnect */ module axi_interconnect # ( parameter DATA_WIDTH = 32, parameter ADDR_WIDTH = 32, parameter STRB_WIDTH = (DATA_WIDTH/8), parameter ID_WIDTH = 8, 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 ARUSER_ENABLE = 0, parameter ARUSER_WIDTH = 1, parameter RUSER_ENABLE = 0, parameter RUSER_WIDTH = 1, parameter FORWARD_ID = 0, parameter S_COUNT = 4, parameter M_COUNT = 4, parameter M_BASE_ADDR = {32'h03000000, 32'h02000000, 32'h01000000, 32'h00000000}, parameter M_ADDR_WIDTH = {M_COUNT{32'd24}}, parameter M_CONNECT_READ = {M_COUNT{{S_COUNT{1'b1}}}}, parameter M_CONNECT_WRITE = {M_COUNT{{S_COUNT{1'b1}}}} ) ( input wire clk, input wire rst, /* * AXI slave interfaces */ input wire [S_COUNT*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*4-1:0] s_axi_awregion, 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*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, input wire [S_COUNT*ID_WIDTH-1:0] s_axi_arid, input wire [S_COUNT*ADDR_WIDTH-1:0] s_axi_araddr, input wire [S_COUNT*8-1:0] s_axi_arlen, input wire [S_COUNT*3-1:0] s_axi_arsize, input wire [S_COUNT*2-1:0] s_axi_arburst, input wire [S_COUNT-1:0] s_axi_arlock, input wire [S_COUNT*4-1:0] s_axi_arcache, input wire [S_COUNT*3-1:0] s_axi_arprot, input wire [S_COUNT*4-1:0] s_axi_arqos, input wire [S_COUNT*4-1:0] s_axi_arregion, input wire [S_COUNT*ARUSER_WIDTH-1:0] s_axi_aruser, input wire [S_COUNT-1:0] s_axi_arvalid, output wire [S_COUNT-1:0] s_axi_arready, output wire [S_COUNT*ID_WIDTH-1:0] s_axi_rid, output wire [S_COUNT*DATA_WIDTH-1:0] s_axi_rdata, output wire [S_COUNT*2-1:0] s_axi_rresp, output wire [S_COUNT-1:0] s_axi_rlast, output wire [S_COUNT*RUSER_WIDTH-1:0] s_axi_ruser, output wire [S_COUNT-1:0] s_axi_rvalid, input wire [S_COUNT-1:0] s_axi_rready, /* * AXI master interfaces */ output wire [M_COUNT*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*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, output wire [M_COUNT*ID_WIDTH-1:0] m_axi_arid, output wire [M_COUNT*ADDR_WIDTH-1:0] m_axi_araddr, output wire [M_COUNT*8-1:0] m_axi_arlen, output wire [M_COUNT*3-1:0] m_axi_arsize, output wire [M_COUNT*2-1:0] m_axi_arburst, output wire [M_COUNT-1:0] m_axi_arlock, output wire [M_COUNT*4-1:0] m_axi_arcache, output wire [M_COUNT*3-1:0] m_axi_arprot, output wire [M_COUNT*4-1:0] m_axi_arqos, output wire [M_COUNT*4-1:0] m_axi_arregion, output wire [M_COUNT*ARUSER_WIDTH-1:0] m_axi_aruser, output wire [M_COUNT-1:0] m_axi_arvalid, input wire [M_COUNT-1:0] m_axi_arready, input wire [M_COUNT*ID_WIDTH-1:0] m_axi_rid, input wire [M_COUNT*DATA_WIDTH-1:0] m_axi_rdata, input wire [M_COUNT*2-1:0] m_axi_rresp, input wire [M_COUNT-1:0] m_axi_rlast, input wire [M_COUNT*RUSER_WIDTH-1:0] m_axi_ruser, input wire [M_COUNT-1:0] m_axi_rvalid, output wire [M_COUNT-1:0] m_axi_rready ); parameter CL_S_COUNT = $clog2(S_COUNT); parameter CL_M_COUNT = $clog2(M_COUNT); parameter AUSER_WIDTH = AWUSER_WIDTH > ARUSER_WIDTH ? AWUSER_WIDTH : ARUSER_WIDTH; integer i, j; // check configuration initial begin for (i = 0; i < M_COUNT; i = i + 1) begin if (M_ADDR_WIDTH[i*32 +: 32] && (M_ADDR_WIDTH[i*32 +: 32] < 0 || M_ADDR_WIDTH[i*32 +: 32] > ADDR_WIDTH)) begin $error("Error: value out of range"); $finish; end end end localparam [2:0] STATE_IDLE = 3'd0, STATE_DECODE = 3'd1, STATE_WRITE = 3'd2, STATE_WRITE_RESP = 3'd3, STATE_WRITE_DROP = 3'd4, STATE_READ = 3'd5, STATE_READ_DROP = 3'd6, STATE_WAIT_IDLE = 3'd7; reg [2:0] state_reg = STATE_IDLE, state_next; reg match; reg [CL_M_COUNT-1:0] m_select_reg = 2'd0, m_select_next; reg [ID_WIDTH-1:0] axi_id_reg = {ID_WIDTH{1'b0}}, axi_id_next; reg [ADDR_WIDTH-1:0] axi_addr_reg = {ADDR_WIDTH{1'b0}}, axi_addr_next; reg axi_addr_valid_reg = 1'b0, axi_addr_valid_next; reg [7:0] axi_len_reg = 8'd0, axi_len_next; reg [2:0] axi_size_reg = 3'd0, axi_size_next; reg [1:0] axi_burst_reg = 2'd0, axi_burst_next; reg axi_lock_reg = 1'b0, axi_lock_next; reg [3:0] axi_cache_reg = 4'd0, axi_cache_next; reg [2:0] axi_prot_reg = 3'b000, axi_prot_next; reg [3:0] axi_qos_reg = 4'd0, axi_qos_next; reg [3:0] axi_region_reg = 4'd0, axi_region_next; reg [AUSER_WIDTH-1:0] axi_auser_reg = {AUSER_WIDTH{1'b0}}, axi_auser_next; reg [1:0] axi_bresp_reg = 2'b00, axi_bresp_next; reg [BUSER_WIDTH-1:0] axi_buser_reg = {BUSER_WIDTH{1'b0}}, axi_buser_next; reg [S_COUNT-1:0] s_axi_awready_reg = 0, s_axi_awready_next; reg [S_COUNT-1:0] s_axi_wready_reg = 0, s_axi_wready_next; reg [S_COUNT-1:0] s_axi_bvalid_reg = 0, s_axi_bvalid_next; reg [S_COUNT-1:0] s_axi_arready_reg = 0, s_axi_arready_next; reg [M_COUNT-1:0] m_axi_awvalid_reg = 0, m_axi_awvalid_next; reg [M_COUNT-1:0] m_axi_bready_reg = 0, m_axi_bready_next; reg [M_COUNT-1:0] m_axi_arvalid_reg = 0, m_axi_arvalid_next; reg [M_COUNT-1:0] m_axi_rready_reg = 0, m_axi_rready_next; // internal datapath reg [ID_WIDTH-1:0] s_axi_rid_int; reg [DATA_WIDTH-1:0] s_axi_rdata_int; reg [1:0] s_axi_rresp_int; reg s_axi_rlast_int; reg [RUSER_WIDTH-1:0] s_axi_ruser_int; reg s_axi_rvalid_int; reg s_axi_rready_int_reg = 1'b0; wire s_axi_rready_int_early; reg [DATA_WIDTH-1:0] m_axi_wdata_int; reg [STRB_WIDTH-1:0] m_axi_wstrb_int; reg m_axi_wlast_int; reg [WUSER_WIDTH-1:0] m_axi_wuser_int; reg m_axi_wvalid_int; reg m_axi_wready_int_reg = 1'b0; wire m_axi_wready_int_early; assign s_axi_awready = s_axi_awready_reg; assign s_axi_wready = s_axi_wready_reg; assign s_axi_bid = {S_COUNT{axi_id_reg}}; assign s_axi_bresp = {S_COUNT{axi_bresp_reg}}; assign s_axi_buser = {S_COUNT{BUSER_ENABLE ? axi_buser_reg : {BUSER_WIDTH{1'b0}}}}; assign s_axi_bvalid = s_axi_bvalid_reg; assign s_axi_arready = s_axi_arready_reg; assign m_axi_awid = {M_COUNT{FORWARD_ID ? axi_id_reg : {ID_WIDTH{1'b0}}}}; assign m_axi_awaddr = {M_COUNT{axi_addr_reg}}; assign m_axi_awlen = {M_COUNT{axi_len_reg}}; assign m_axi_awsize = {M_COUNT{axi_size_reg}}; assign m_axi_awburst = {M_COUNT{axi_burst_reg}}; assign m_axi_awlock = {M_COUNT{axi_lock_reg}}; assign m_axi_awcache = {M_COUNT{axi_cache_reg}}; assign m_axi_awprot = {M_COUNT{axi_prot_reg}}; assign m_axi_awqos = {M_COUNT{axi_qos_reg}}; assign m_axi_awregion = {M_COUNT{axi_region_reg}}; assign m_axi_awuser = {M_COUNT{AWUSER_ENABLE ? axi_auser_reg[AWUSER_WIDTH-1:0] : {AWUSER_WIDTH{1'b0}}}}; assign m_axi_awvalid = m_axi_awvalid_reg; assign m_axi_bready = m_axi_bready_reg; assign m_axi_arid = {M_COUNT{FORWARD_ID ? axi_id_reg : {ID_WIDTH{1'b0}}}}; assign m_axi_araddr = {M_COUNT{axi_addr_reg}}; assign m_axi_arlen = {M_COUNT{axi_len_reg}}; assign m_axi_arsize = {M_COUNT{axi_size_reg}}; assign m_axi_arburst = {M_COUNT{axi_burst_reg}}; assign m_axi_arlock = {M_COUNT{axi_lock_reg}}; assign m_axi_arcache = {M_COUNT{axi_cache_reg}}; assign m_axi_arprot = {M_COUNT{axi_prot_reg}}; assign m_axi_arqos = {M_COUNT{axi_qos_reg}}; assign m_axi_arregion = {M_COUNT{axi_region_reg}}; assign m_axi_aruser = {M_COUNT{ARUSER_ENABLE ? axi_auser_reg[ARUSER_WIDTH-1:0] : {ARUSER_WIDTH{1'b0}}}}; assign m_axi_arvalid = m_axi_arvalid_reg; assign m_axi_rready = m_axi_rready_reg; // slave side mux wire [ID_WIDTH-1:0] current_s_axi_awid = s_axi_awid[s_select*ID_WIDTH +: ID_WIDTH]; wire [ADDR_WIDTH-1:0] current_s_axi_awaddr = s_axi_awaddr[s_select*ADDR_WIDTH +: ADDR_WIDTH]; wire [7:0] current_s_axi_awlen = s_axi_awlen[s_select*8 +: 8]; wire [2:0] current_s_axi_awsize = s_axi_awsize[s_select*3 +: 3]; wire [1:0] current_s_axi_awburst = s_axi_awburst[s_select*2 +: 2]; wire current_s_axi_awlock = s_axi_awlock[s_select]; wire [3:0] current_s_axi_awcache = s_axi_awcache[s_select*4 +: 4]; wire [2:0] current_s_axi_awprot = s_axi_awprot[s_select*3 +: 3]; wire [3:0] current_s_axi_awqos = s_axi_awqos[s_select*4 +: 4]; wire [3:0] current_s_axi_awregion = s_axi_awregion[s_select*4 +: 4]; wire [AWUSER_WIDTH-1:0] current_s_axi_awuser = s_axi_awuser[s_select*AWUSER_WIDTH +: AWUSER_WIDTH]; wire current_s_axi_awvalid = s_axi_awvalid[s_select]; wire current_s_axi_awready = s_axi_awready[s_select]; wire [DATA_WIDTH-1:0] current_s_axi_wdata = s_axi_wdata[s_select*DATA_WIDTH +: DATA_WIDTH]; wire [STRB_WIDTH-1:0] current_s_axi_wstrb = s_axi_wstrb[s_select*STRB_WIDTH +: STRB_WIDTH]; wire current_s_axi_wlast = s_axi_wlast[s_select]; wire [WUSER_WIDTH-1:0] current_s_axi_wuser = s_axi_wuser[s_select*WUSER_WIDTH +: WUSER_WIDTH]; wire current_s_axi_wvalid = s_axi_wvalid[s_select]; wire current_s_axi_wready = s_axi_wready[s_select]; wire [ID_WIDTH-1:0] current_s_axi_bid = s_axi_bid[s_select*ID_WIDTH +: ID_WIDTH]; wire [1:0] current_s_axi_bresp = s_axi_bresp[s_select*2 +: 2]; wire [BUSER_WIDTH-1:0] current_s_axi_buser = s_axi_buser[s_select*BUSER_WIDTH +: BUSER_WIDTH]; wire current_s_axi_bvalid = s_axi_bvalid[s_select]; wire current_s_axi_bready = s_axi_bready[s_select]; wire [ID_WIDTH-1:0] current_s_axi_arid = s_axi_arid[s_select*ID_WIDTH +: ID_WIDTH]; wire [ADDR_WIDTH-1:0] current_s_axi_araddr = s_axi_araddr[s_select*ADDR_WIDTH +: ADDR_WIDTH]; wire [7:0] current_s_axi_arlen = s_axi_arlen[s_select*8 +: 8]; wire [2:0] current_s_axi_arsize = s_axi_arsize[s_select*3 +: 3]; wire [1:0] current_s_axi_arburst = s_axi_arburst[s_select*2 +: 2]; wire current_s_axi_arlock = s_axi_arlock[s_select]; wire [3:0] current_s_axi_arcache = s_axi_arcache[s_select*4 +: 4]; wire [2:0] current_s_axi_arprot = s_axi_arprot[s_select*3 +: 3]; wire [3:0] current_s_axi_arqos = s_axi_arqos[s_select*4 +: 4]; wire [3:0] current_s_axi_arregion = s_axi_arregion[s_select*4 +: 4]; wire [ARUSER_WIDTH-1:0] current_s_axi_aruser = s_axi_aruser[s_select*ARUSER_WIDTH +: ARUSER_WIDTH]; wire current_s_axi_arvalid = s_axi_arvalid[s_select]; wire current_s_axi_arready = s_axi_arready[s_select]; wire [ID_WIDTH-1:0] current_s_axi_rid = s_axi_rid[s_select*ID_WIDTH +: ID_WIDTH]; wire [DATA_WIDTH-1:0] current_s_axi_rdata = s_axi_rdata[s_select*DATA_WIDTH +: DATA_WIDTH]; wire [1:0] current_s_axi_rresp = s_axi_rresp[s_select*2 +: 2]; wire current_s_axi_rlast = s_axi_rlast[s_select]; wire [RUSER_WIDTH-1:0] current_s_axi_ruser = s_axi_ruser[s_select*RUSER_WIDTH +: RUSER_WIDTH]; wire current_s_axi_rvalid = s_axi_rvalid[s_select]; wire current_s_axi_rready = s_axi_rready[s_select]; // master side mux wire [ID_WIDTH-1:0] current_m_axi_awid = m_axi_awid[m_select_reg*ID_WIDTH +: ID_WIDTH]; wire [ADDR_WIDTH-1:0] current_m_axi_awaddr = m_axi_awaddr[m_select_reg*ADDR_WIDTH +: ADDR_WIDTH]; wire [7:0] current_m_axi_awlen = m_axi_awlen[m_select_reg*8 +: 8]; wire [2:0] current_m_axi_awsize = m_axi_awsize[m_select_reg*3 +: 3]; wire [1:0] current_m_axi_awburst = m_axi_awburst[m_select_reg*2 +: 2]; wire current_m_axi_awlock = m_axi_awlock[m_select_reg]; wire [3:0] current_m_axi_awcache = m_axi_awcache[m_select_reg*4 +: 4]; wire [2:0] current_m_axi_awprot = m_axi_awprot[m_select_reg*3 +: 3]; wire [3:0] current_m_axi_awqos = m_axi_awqos[m_select_reg*4 +: 4]; wire [3:0] current_m_axi_awregion = m_axi_awregion[m_select_reg*4 +: 4]; wire [AWUSER_WIDTH-1:0] current_m_axi_awuser = m_axi_awuser[m_select_reg*AWUSER_WIDTH +: AWUSER_WIDTH]; wire current_m_axi_awvalid = m_axi_awvalid[m_select_reg]; wire current_m_axi_awready = m_axi_awready[m_select_reg]; wire [DATA_WIDTH-1:0] current_m_axi_wdata = m_axi_wdata[m_select_reg*DATA_WIDTH +: DATA_WIDTH]; wire [STRB_WIDTH-1:0] current_m_axi_wstrb = m_axi_wstrb[m_select_reg*STRB_WIDTH +: STRB_WIDTH]; wire current_m_axi_wlast = m_axi_wlast[m_select_reg]; wire [WUSER_WIDTH-1:0] current_m_axi_wuser = m_axi_wuser[m_select_reg*WUSER_WIDTH +: WUSER_WIDTH]; wire current_m_axi_wvalid = m_axi_wvalid[m_select_reg]; wire current_m_axi_wready = m_axi_wready[m_select_reg]; wire [ID_WIDTH-1:0] current_m_axi_bid = m_axi_bid[m_select_reg*ID_WIDTH +: ID_WIDTH]; wire [1:0] current_m_axi_bresp = m_axi_bresp[m_select_reg*2 +: 2]; wire [BUSER_WIDTH-1:0] current_m_axi_buser = m_axi_buser[m_select_reg*BUSER_WIDTH +: BUSER_WIDTH]; wire current_m_axi_bvalid = m_axi_bvalid[m_select_reg]; wire current_m_axi_bready = m_axi_bready[m_select_reg]; wire [ID_WIDTH-1:0] current_m_axi_arid = m_axi_arid[m_select_reg*ID_WIDTH +: ID_WIDTH]; wire [ADDR_WIDTH-1:0] current_m_axi_araddr = m_axi_araddr[m_select_reg*ADDR_WIDTH +: ADDR_WIDTH]; wire [7:0] current_m_axi_arlen = m_axi_arlen[m_select_reg*8 +: 8]; wire [2:0] current_m_axi_arsize = m_axi_arsize[m_select_reg*3 +: 3]; wire [1:0] current_m_axi_arburst = m_axi_arburst[m_select_reg*2 +: 2]; wire current_m_axi_arlock = m_axi_arlock[m_select_reg]; wire [3:0] current_m_axi_arcache = m_axi_arcache[m_select_reg*4 +: 4]; wire [2:0] current_m_axi_arprot = m_axi_arprot[m_select_reg*3 +: 3]; wire [3:0] current_m_axi_arqos = m_axi_arqos[m_select_reg*4 +: 4]; wire [3:0] current_m_axi_arregion = m_axi_arregion[m_select_reg*4 +: 4]; wire [ARUSER_WIDTH-1:0] current_m_axi_aruser = m_axi_aruser[m_select_reg*ARUSER_WIDTH +: ARUSER_WIDTH]; wire current_m_axi_arvalid = m_axi_arvalid[m_select_reg]; wire current_m_axi_arready = m_axi_arready[m_select_reg]; wire [ID_WIDTH-1:0] current_m_axi_rid = m_axi_rid[m_select_reg*ID_WIDTH +: ID_WIDTH]; wire [DATA_WIDTH-1:0] current_m_axi_rdata = m_axi_rdata[m_select_reg*DATA_WIDTH +: DATA_WIDTH]; wire [1:0] current_m_axi_rresp = m_axi_rresp[m_select_reg*2 +: 2]; wire current_m_axi_rlast = m_axi_rlast[m_select_reg]; wire [RUSER_WIDTH-1:0] current_m_axi_ruser = m_axi_ruser[m_select_reg*RUSER_WIDTH +: RUSER_WIDTH]; wire current_m_axi_rvalid = m_axi_rvalid[m_select_reg]; wire current_m_axi_rready = m_axi_rready[m_select_reg]; // arbiter instance wire [S_COUNT*2-1:0] request; wire [S_COUNT*2-1:0] acknowledge; wire [S_COUNT*2-1:0] grant; wire grant_valid; wire [CL_S_COUNT:0] grant_encoded; wire read = grant_encoded[0]; wire [(CL_S_COUNT > 0 ? CL_S_COUNT-1 : 0):0] s_select = grant_encoded >> 1; arbiter #( .PORTS(S_COUNT*2), .TYPE("ROUND_ROBIN"), .BLOCK("ACKNOWLEDGE"), .LSB_PRIORITY("HIGH") ) arb_inst ( .clk(clk), .rst(rst), .request(request), .acknowledge(acknowledge), .grant(grant), .grant_valid(grant_valid), .grant_encoded(grant_encoded) ); genvar n; // request generation generate for (n = 0; n < S_COUNT; n = n + 1) begin assign request[2*n] = s_axi_awvalid[n]; assign request[2*n+1] = s_axi_arvalid[n]; end endgenerate // acknowledge generation generate for (n = 0; n < S_COUNT; n = n + 1) begin assign acknowledge[2*n] = grant[2*n] && s_axi_bvalid[n] && s_axi_bready[n]; assign acknowledge[2*n+1] = grant[2*n+1] && s_axi_rvalid[n] && s_axi_rready[n] && s_axi_rlast[n]; end endgenerate always @* begin state_next = STATE_IDLE; match = 1'b0; m_select_next = m_select_reg; axi_id_next = axi_id_reg; axi_addr_next = axi_addr_reg; axi_addr_valid_next = axi_addr_valid_reg; axi_len_next = axi_len_reg; axi_size_next = axi_size_reg; axi_burst_next = axi_burst_reg; axi_lock_next = axi_lock_reg; axi_cache_next = axi_cache_reg; axi_prot_next = axi_prot_reg; axi_qos_next = axi_qos_reg; axi_region_next = axi_region_reg; axi_auser_next = axi_auser_reg; axi_bresp_next = axi_bresp_reg; axi_buser_next = axi_buser_reg; s_axi_awready_next = 0; s_axi_wready_next = 0; s_axi_bvalid_next = s_axi_bvalid_reg & ~s_axi_bready; s_axi_arready_next = 0; m_axi_awvalid_next = m_axi_awvalid_reg & ~m_axi_awready; m_axi_bready_next = 0; m_axi_arvalid_next = m_axi_arvalid_reg & ~m_axi_arready; m_axi_rready_next = 0; s_axi_rid_int = axi_id_reg; s_axi_rdata_int = current_m_axi_rdata; s_axi_rresp_int = current_m_axi_rresp; s_axi_rlast_int = current_m_axi_rlast; s_axi_ruser_int = current_m_axi_ruser; s_axi_rvalid_int = 1'b0; m_axi_wdata_int = current_s_axi_wdata; m_axi_wstrb_int = current_s_axi_wstrb; m_axi_wlast_int = current_s_axi_wlast; m_axi_wuser_int = current_s_axi_wuser; m_axi_wvalid_int = 1'b0; case (state_reg) STATE_IDLE: begin // idle state; wait for arbitration if (grant_valid) begin axi_addr_valid_next = 1'b1; if (read) begin // reading axi_addr_next = current_s_axi_araddr; axi_prot_next = current_s_axi_arprot; axi_id_next = current_s_axi_arid; axi_addr_next = current_s_axi_araddr; axi_len_next = current_s_axi_arlen; axi_size_next = current_s_axi_arsize; axi_burst_next = current_s_axi_arburst; axi_lock_next = current_s_axi_arlock; axi_cache_next = current_s_axi_arcache; axi_prot_next = current_s_axi_arprot; axi_qos_next = current_s_axi_arqos; axi_region_next = current_s_axi_arregion; axi_auser_next = current_s_axi_aruser; s_axi_arready_next[s_select] = 1'b1; end else begin // writing axi_addr_next = current_s_axi_awaddr; axi_prot_next = current_s_axi_awprot; axi_id_next = current_s_axi_awid; axi_addr_next = current_s_axi_awaddr; axi_len_next = current_s_axi_awlen; axi_size_next = current_s_axi_awsize; axi_burst_next = current_s_axi_awburst; axi_lock_next = current_s_axi_awlock; axi_cache_next = current_s_axi_awcache; axi_prot_next = current_s_axi_awprot; axi_qos_next = current_s_axi_awqos; axi_region_next = current_s_axi_awregion; axi_auser_next = current_s_axi_awuser; s_axi_awready_next[s_select] = 1'b1; end state_next = STATE_DECODE; end else begin state_next = STATE_IDLE; end end STATE_DECODE: begin // decode state; determine master interface match = 1'b0; for (i = 0; i < M_COUNT; i = i + 1) begin if (M_ADDR_WIDTH[i*32 +: 32] && ((read ? M_CONNECT_READ : M_CONNECT_WRITE) & (1 << (s_select+i*S_COUNT))) && (axi_addr_reg >> M_ADDR_WIDTH[i*32 +: 32]) == (M_BASE_ADDR[i*ADDR_WIDTH +: ADDR_WIDTH] >> M_ADDR_WIDTH[i*32 +: 32])) begin m_select_next = i; match = 1'b1; end end if (match) begin if (read) begin // reading m_axi_rready_next[m_select_reg] = s_axi_rready_int_early; state_next = STATE_READ; end else begin // writing s_axi_wready_next[s_select] = m_axi_wready_int_early; state_next = STATE_WRITE; end end else begin // no match; return decode error if (read) begin // reading state_next = STATE_READ_DROP; end else begin // writing axi_bresp_next = 2'b11; s_axi_wready_next[s_select] = 1'b1; state_next = STATE_WRITE_DROP; end end end STATE_WRITE: begin // write state; store and forward write data s_axi_wready_next[s_select] = m_axi_wready_int_early; if (axi_addr_valid_reg) begin m_axi_awvalid_next[m_select_reg] = 1'b1; end axi_addr_valid_next = 1'b0; if (current_s_axi_wready && current_s_axi_wvalid) begin m_axi_wdata_int = current_s_axi_wdata; m_axi_wstrb_int = current_s_axi_wstrb; m_axi_wlast_int = current_s_axi_wlast; m_axi_wuser_int = current_s_axi_wuser; m_axi_wvalid_int = 1'b1; if (current_s_axi_wlast) begin s_axi_wready_next[s_select] = 1'b0; m_axi_bready_next[m_select_reg] = 1'b1; state_next = STATE_WRITE_RESP; end else begin state_next = STATE_WRITE; end end else begin state_next = STATE_WRITE; end end STATE_WRITE_RESP: begin // write response state; store and forward write response m_axi_bready_next[m_select_reg] = 1'b1; if (current_m_axi_bready && current_m_axi_bvalid) begin m_axi_bready_next[m_select_reg] = 1'b0; axi_bresp_next = current_m_axi_bresp; s_axi_bvalid_next[s_select] = 1'b1; state_next = STATE_WAIT_IDLE; end else begin state_next = STATE_WRITE_RESP; end end STATE_WRITE_DROP: begin // write drop state; drop write data s_axi_wready_next[s_select] = 1'b1; axi_addr_valid_next = 1'b0; if (current_s_axi_wready && current_s_axi_wvalid) begin s_axi_wready_next[s_select] = 1'b0; s_axi_bvalid_next[s_select] = 1'b1; state_next = STATE_WAIT_IDLE; end else begin state_next = STATE_WRITE_DROP; end end STATE_READ: begin // read state; store and forward read response m_axi_rready_next[m_select_reg] = s_axi_rready_int_early; if (axi_addr_valid_reg) begin m_axi_arvalid_next[m_select_reg] = 1'b1; end axi_addr_valid_next = 1'b0; if (current_m_axi_rready && current_m_axi_rvalid) begin s_axi_rid_int = axi_id_reg; s_axi_rdata_int = current_m_axi_rdata; s_axi_rresp_int = current_m_axi_rresp; s_axi_rlast_int = current_m_axi_rlast; s_axi_ruser_int = current_m_axi_ruser; s_axi_rvalid_int = 1'b1; if (current_m_axi_rlast) begin m_axi_rready_next[m_select_reg] = 1'b0; state_next = STATE_WAIT_IDLE; end else begin state_next = STATE_READ; end end else begin state_next = STATE_READ; end end STATE_READ_DROP: begin // read drop state; generate decode error read response s_axi_rid_int = axi_id_reg; s_axi_rdata_int = {DATA_WIDTH{1'b0}}; s_axi_rresp_int = 2'b11; s_axi_rlast_int = axi_len_reg == 0; s_axi_ruser_int = {RUSER_WIDTH{1'b0}}; s_axi_rvalid_int = 1'b1; if (s_axi_rready_int_reg) begin axi_len_next = axi_len_reg - 1; if (axi_len_reg == 0) begin state_next = STATE_WAIT_IDLE; end else begin state_next = STATE_READ_DROP; end end else begin state_next = STATE_READ_DROP; end end STATE_WAIT_IDLE: begin // wait for idle state; wait untl grant valid is deasserted if (!grant_valid || acknowledge) begin state_next = STATE_IDLE; end else begin state_next = STATE_WAIT_IDLE; end end endcase end always @(posedge clk) begin if (rst) begin state_reg <= STATE_IDLE; s_axi_awready_reg <= 0; s_axi_wready_reg <= 0; s_axi_bvalid_reg <= 0; s_axi_arready_reg <= 0; s_axi_rvalid_reg <= 0; m_axi_awvalid_reg <= 0; m_axi_wvalid_reg <= 0; m_axi_bready_reg <= 0; m_axi_arvalid_reg <= 0; m_axi_rready_reg <= 0; end else begin state_reg <= state_next; s_axi_awready_reg <= s_axi_awready_next; s_axi_wready_reg <= s_axi_wready_next; s_axi_bvalid_reg <= s_axi_bvalid_next; s_axi_arready_reg <= s_axi_arready_next; s_axi_rvalid_reg <= s_axi_rvalid_next; m_axi_awvalid_reg <= m_axi_awvalid_next; m_axi_wvalid_reg <= m_axi_wvalid_next; m_axi_bready_reg <= m_axi_bready_next; m_axi_arvalid_reg <= m_axi_arvalid_next; m_axi_rready_reg <= m_axi_rready_next; end m_select_reg <= m_select_next; axi_id_reg <= axi_id_next; axi_addr_reg <= axi_addr_next; axi_addr_valid_reg <= axi_addr_valid_next; axi_len_reg <= axi_len_next; axi_size_reg <= axi_size_next; axi_burst_reg <= axi_burst_next; axi_lock_reg <= axi_lock_next; axi_cache_reg <= axi_cache_next; axi_prot_reg <= axi_prot_next; axi_qos_reg <= axi_qos_next; axi_region_reg <= axi_region_next; axi_auser_reg <= axi_auser_next; axi_bresp_reg <= axi_bresp_next; axi_buser_reg <= axi_buser_next; end // output datapath logic (R channel) reg [ID_WIDTH-1:0] s_axi_rid_reg = {ID_WIDTH{1'b0}}; reg [DATA_WIDTH-1:0] s_axi_rdata_reg = {DATA_WIDTH{1'b0}}; reg [1:0] s_axi_rresp_reg = 2'd0; reg s_axi_rlast_reg = 1'b0; reg [RUSER_WIDTH-1:0] s_axi_ruser_reg = 1'b0; reg [S_COUNT-1:0] s_axi_rvalid_reg = 1'b0, s_axi_rvalid_next; reg [ID_WIDTH-1:0] temp_s_axi_rid_reg = {ID_WIDTH{1'b0}}; reg [DATA_WIDTH-1:0] temp_s_axi_rdata_reg = {DATA_WIDTH{1'b0}}; reg [1:0] temp_s_axi_rresp_reg = 2'd0; reg temp_s_axi_rlast_reg = 1'b0; reg [RUSER_WIDTH-1:0] temp_s_axi_ruser_reg = 1'b0; reg temp_s_axi_rvalid_reg = 1'b0, temp_s_axi_rvalid_next; // datapath control reg store_axi_r_int_to_output; reg store_axi_r_int_to_temp; reg store_axi_r_temp_to_output; assign s_axi_rid = {S_COUNT{s_axi_rid_reg}}; assign s_axi_rdata = {S_COUNT{s_axi_rdata_reg}}; assign s_axi_rresp = {S_COUNT{s_axi_rresp_reg}}; assign s_axi_rlast = {S_COUNT{s_axi_rlast_reg}}; assign s_axi_ruser = {S_COUNT{RUSER_ENABLE ? s_axi_ruser_reg : {RUSER_WIDTH{1'b0}}}}; assign s_axi_rvalid = s_axi_rvalid_reg; // enable ready input next cycle if output is ready or the temp reg will not be filled on the next cycle (output reg empty or no input) assign s_axi_rready_int_early = current_s_axi_rready | (~temp_s_axi_rvalid_reg & (~current_s_axi_rvalid | ~s_axi_rvalid_int)); always @* begin // transfer sink ready state to source s_axi_rvalid_next = s_axi_rvalid_reg; temp_s_axi_rvalid_next = temp_s_axi_rvalid_reg; store_axi_r_int_to_output = 1'b0; store_axi_r_int_to_temp = 1'b0; store_axi_r_temp_to_output = 1'b0; if (s_axi_rready_int_reg) begin // input is ready if (current_s_axi_rready | ~current_s_axi_rvalid) begin // output is ready or currently not valid, transfer data to output s_axi_rvalid_next[s_select] = s_axi_rvalid_int; store_axi_r_int_to_output = 1'b1; end else begin // output is not ready, store input in temp temp_s_axi_rvalid_next = s_axi_rvalid_int; store_axi_r_int_to_temp = 1'b1; end end else if (current_s_axi_rready) begin // input is not ready, but output is ready s_axi_rvalid_next[s_select] = temp_s_axi_rvalid_reg; temp_s_axi_rvalid_next = 1'b0; store_axi_r_temp_to_output = 1'b1; end end always @(posedge clk) begin if (rst) begin s_axi_rvalid_reg <= 1'b0; s_axi_rready_int_reg <= 1'b0; temp_s_axi_rvalid_reg <= 1'b0; end else begin s_axi_rvalid_reg <= s_axi_rvalid_next; s_axi_rready_int_reg <= s_axi_rready_int_early; temp_s_axi_rvalid_reg <= temp_s_axi_rvalid_next; end // datapath if (store_axi_r_int_to_output) begin s_axi_rid_reg <= s_axi_rid_int; s_axi_rdata_reg <= s_axi_rdata_int; s_axi_rresp_reg <= s_axi_rresp_int; s_axi_rlast_reg <= s_axi_rlast_int; s_axi_ruser_reg <= s_axi_ruser_int; end else if (store_axi_r_temp_to_output) begin s_axi_rid_reg <= temp_s_axi_rid_reg; s_axi_rdata_reg <= temp_s_axi_rdata_reg; s_axi_rresp_reg <= temp_s_axi_rresp_reg; s_axi_rlast_reg <= temp_s_axi_rlast_reg; s_axi_ruser_reg <= temp_s_axi_ruser_reg; end if (store_axi_r_int_to_temp) begin temp_s_axi_rid_reg <= s_axi_rid_int; temp_s_axi_rdata_reg <= s_axi_rdata_int; temp_s_axi_rresp_reg <= s_axi_rresp_int; temp_s_axi_rlast_reg <= s_axi_rlast_int; temp_s_axi_ruser_reg <= s_axi_ruser_int; end end // output datapath logic (W channel) reg [DATA_WIDTH-1:0] m_axi_wdata_reg = {DATA_WIDTH{1'b0}}; reg [STRB_WIDTH-1:0] m_axi_wstrb_reg = {STRB_WIDTH{1'b0}}; reg m_axi_wlast_reg = 1'b0; reg [WUSER_WIDTH-1:0] m_axi_wuser_reg = 1'b0; reg [M_COUNT-1:0] m_axi_wvalid_reg = 1'b0, m_axi_wvalid_next; reg [DATA_WIDTH-1:0] temp_m_axi_wdata_reg = {DATA_WIDTH{1'b0}}; reg [STRB_WIDTH-1:0] temp_m_axi_wstrb_reg = {STRB_WIDTH{1'b0}}; reg temp_m_axi_wlast_reg = 1'b0; reg [WUSER_WIDTH-1:0] temp_m_axi_wuser_reg = 1'b0; reg temp_m_axi_wvalid_reg = 1'b0, temp_m_axi_wvalid_next; // datapath control reg store_axi_w_int_to_output; reg store_axi_w_int_to_temp; reg store_axi_w_temp_to_output; assign m_axi_wdata = {M_COUNT{m_axi_wdata_reg}}; assign m_axi_wstrb = {M_COUNT{m_axi_wstrb_reg}}; assign m_axi_wlast = {M_COUNT{m_axi_wlast_reg}}; assign m_axi_wuser = {M_COUNT{WUSER_ENABLE ? m_axi_wuser_reg : {WUSER_WIDTH{1'b0}}}}; assign m_axi_wvalid = m_axi_wvalid_reg; // enable ready input next cycle if output is ready or the temp reg will not be filled on the next cycle (output reg empty or no input) assign m_axi_wready_int_early = current_m_axi_wready | (~temp_m_axi_wvalid_reg & (~current_m_axi_wvalid | ~m_axi_wvalid_int)); always @* begin // transfer sink ready state to source m_axi_wvalid_next = m_axi_wvalid_reg; temp_m_axi_wvalid_next = temp_m_axi_wvalid_reg; store_axi_w_int_to_output = 1'b0; store_axi_w_int_to_temp = 1'b0; store_axi_w_temp_to_output = 1'b0; if (m_axi_wready_int_reg) begin // input is ready if (current_m_axi_wready | ~current_m_axi_wvalid) begin // output is ready or currently not valid, transfer data to output m_axi_wvalid_next[m_select_reg] = m_axi_wvalid_int; store_axi_w_int_to_output = 1'b1; end else begin // output is not ready, store input in temp temp_m_axi_wvalid_next = m_axi_wvalid_int; store_axi_w_int_to_temp = 1'b1; end end else if (current_m_axi_wready) begin // input is not ready, but output is ready m_axi_wvalid_next[m_select_reg] = temp_m_axi_wvalid_reg; temp_m_axi_wvalid_next = 1'b0; store_axi_w_temp_to_output = 1'b1; end end always @(posedge clk) begin if (rst) begin m_axi_wvalid_reg <= 1'b0; m_axi_wready_int_reg <= 1'b0; temp_m_axi_wvalid_reg <= 1'b0; end else begin m_axi_wvalid_reg <= m_axi_wvalid_next; m_axi_wready_int_reg <= m_axi_wready_int_early; temp_m_axi_wvalid_reg <= temp_m_axi_wvalid_next; end // datapath if (store_axi_w_int_to_output) begin m_axi_wdata_reg <= m_axi_wdata_int; m_axi_wstrb_reg <= m_axi_wstrb_int; m_axi_wlast_reg <= m_axi_wlast_int; m_axi_wuser_reg <= m_axi_wuser_int; end else if (store_axi_w_temp_to_output) begin m_axi_wdata_reg <= temp_m_axi_wdata_reg; m_axi_wstrb_reg <= temp_m_axi_wstrb_reg; m_axi_wlast_reg <= temp_m_axi_wlast_reg; m_axi_wuser_reg <= temp_m_axi_wuser_reg; end if (store_axi_w_int_to_temp) begin temp_m_axi_wdata_reg <= m_axi_wdata_int; temp_m_axi_wstrb_reg <= m_axi_wstrb_int; temp_m_axi_wlast_reg <= m_axi_wlast_int; temp_m_axi_wuser_reg <= m_axi_wuser_int; end end endmodule