// *************************************************************************** // *************************************************************************** // Copyright 2014 - 2017 (c) Analog Devices, Inc. All rights reserved. // // In this HDL repository, there are many different and unique modules, consisting // of various HDL (Verilog or VHDL) components. The individual modules are // developed independently, and may be accompanied by separate and unique license // terms. // // The user should read each of these license terms, and understand the // freedoms and responsibilities that he or she has by using this source/core. // // This core is distributed in the hope that it will be useful, but WITHOUT ANY // WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR // A PARTICULAR PURPOSE. // // Redistribution and use of source or resulting binaries, with or without modification // of this file, are permitted under one of the following two license terms: // // 1. The GNU General Public License version 2 as published by the // Free Software Foundation, which can be found in the top level directory // of this repository (LICENSE_GPL2), and also online at: // // // OR // // 2. An ADI specific BSD license, which can be found in the top level directory // of this repository (LICENSE_ADIBSD), and also on-line at: // https://github.com/analogdevicesinc/hdl/blob/master/LICENSE_ADIBSD // This will allow to generate bit files and not release the source code, // as long as it attaches to an ADI device. // // *************************************************************************** // *************************************************************************** `timescale 1ns/100ps module axi_adcfifo_wr #( parameter AXI_DATA_WIDTH = 512, parameter AXI_SIZE = 2, parameter AXI_LENGTH = 16, parameter AXI_ADDRESS = 32'h00000000, parameter AXI_ADDRESS_LIMIT = 32'h00000000 ) ( // request and synchronization input dma_xfer_req, // read interface output reg axi_rd_req, output reg [ 31:0] axi_rd_addr, // fifo interface input adc_rst, input adc_clk, input adc_wr, input [AXI_DATA_WIDTH-1:0] adc_wdata, // axi interface input axi_clk, input axi_resetn, output reg axi_awvalid, output [ 3:0] axi_awid, output [ 1:0] axi_awburst, output axi_awlock, output [ 3:0] axi_awcache, output [ 2:0] axi_awprot, output [ 3:0] axi_awqos, output [ 3:0] axi_awuser, output [ 7:0] axi_awlen, output [ 2:0] axi_awsize, output reg [ 31:0] axi_awaddr, input axi_awready, output axi_wvalid, output [AXI_DATA_WIDTH-1:0] axi_wdata, output [AXI_BYTE_WIDTH-1:0] axi_wstrb, output axi_wlast, output [ 3:0] axi_wuser, input axi_wready, input axi_bvalid, input [ 3:0] axi_bid, input [ 1:0] axi_bresp, input [ 3:0] axi_buser, output axi_bready, // axi status output reg axi_dwovf, output reg axi_dwunf, output reg axi_werror ); localparam AXI_BYTE_WIDTH = AXI_DATA_WIDTH/8; localparam AXI_AWINCR = AXI_LENGTH * AXI_BYTE_WIDTH; localparam BUF_THRESHOLD_LO = 8'd6; localparam BUF_THRESHOLD_HI = 8'd250; // internal registers reg [ 2:0] adc_xfer_req_m = 'd0; reg adc_xfer_init = 'd0; reg adc_xfer_limit = 'd0; reg adc_xfer_enable = 'd0; reg [ 31:0] adc_xfer_addr = 'd0; reg [ 7:0] adc_waddr = 'd0; reg [ 7:0] adc_waddr_g = 'd0; reg adc_rel_enable = 'd0; reg adc_rel_toggle = 'd0; reg [ 7:0] adc_rel_waddr = 'd0; reg [ 2:0] axi_rel_toggle_m = 'd0; reg [ 7:0] axi_rel_waddr = 'd0; reg [ 7:0] axi_waddr_m1 = 'd0; reg [ 7:0] axi_waddr_m2 = 'd0; reg [ 7:0] axi_waddr = 'd0; reg [ 7:0] axi_addr_diff = 'd0; reg axi_almost_full = 'd0; reg axi_almost_empty = 'd0; reg [ 2:0] axi_xfer_req_m = 'd0; reg axi_xfer_init = 'd0; reg [ 7:0] axi_raddr = 'd0; reg axi_rd = 'd0; reg axi_rlast = 'd0; reg axi_rd_d = 'd0; reg axi_rlast_d = 'd0; reg [AXI_DATA_WIDTH-1:0] axi_rdata_d = 'd0; reg axi_reset = 'd0; // internal signals wire axi_rel_toggle_s; wire [ 8:0] axi_addr_diff_s; wire axi_wready_s; wire axi_rd_s; wire axi_req_s; wire axi_rlast_s; wire [AXI_DATA_WIDTH-1:0] axi_rdata_s; // binary to grey conversion function [7:0] b2g; input [7:0] b; reg [7:0] g; begin g[7] = b[7]; g[6] = b[7] ^ b[6]; g[5] = b[6] ^ b[5]; g[4] = b[5] ^ b[4]; g[3] = b[4] ^ b[3]; g[2] = b[3] ^ b[2]; g[1] = b[2] ^ b[1]; g[0] = b[1] ^ b[0]; b2g = g; end endfunction // grey to binary conversion function [7:0] g2b; input [7:0] g; reg [7:0] b; begin b[7] = g[7]; b[6] = b[7] ^ g[6]; b[5] = b[6] ^ g[5]; b[4] = b[5] ^ g[4]; b[3] = b[4] ^ g[3]; b[2] = b[3] ^ g[2]; b[1] = b[2] ^ g[1]; b[0] = b[1] ^ g[0]; g2b = b; end endfunction // fifo interface always @(posedge adc_clk) begin if (adc_rst == 1'b1) begin adc_waddr <= 'd0; adc_waddr_g <= 'd0; adc_xfer_req_m <= 'd0; adc_xfer_init <= 'd0; adc_xfer_limit <= 'd0; adc_xfer_enable <= 'd0; adc_xfer_addr <= 'd0; adc_rel_enable <= 'd0; adc_rel_toggle <= 'd0; adc_rel_waddr <= 'd0; end else begin if ((adc_wr == 1'b1) && (adc_xfer_enable == 1'b1)) begin adc_waddr <= adc_waddr + 1'b1; end adc_waddr_g <= b2g(adc_waddr); adc_xfer_req_m <= {adc_xfer_req_m[1:0], dma_xfer_req}; adc_xfer_init <= adc_xfer_req_m[1] & ~adc_xfer_req_m[2]; if (adc_xfer_init == 1'b1) begin adc_xfer_limit <= 1'd1; end else if ((adc_xfer_addr >= AXI_ADDRESS_LIMIT) || (adc_xfer_enable == 1'b0)) begin adc_xfer_limit <= 1'd0; end if (adc_xfer_init == 1'b1) begin adc_xfer_enable <= 1'b1; adc_xfer_addr <= AXI_ADDRESS; end else if ((adc_waddr[1:0] == 2'h3) && (adc_wr == 1'b1)) begin adc_xfer_enable <= adc_xfer_req_m[2] & adc_xfer_limit; adc_xfer_addr <= adc_xfer_addr + AXI_AWINCR; end if (adc_waddr[1:0] == 2'h3) begin adc_rel_enable <= adc_wr; end else begin adc_rel_enable <= 1'd0; end if (adc_rel_enable == 1'b1) begin adc_rel_toggle <= ~adc_rel_toggle; adc_rel_waddr <= adc_waddr; end end end // fifo signals on axi side assign axi_rel_toggle_s = axi_rel_toggle_m[2] ^ axi_rel_toggle_m[1]; always @(posedge axi_clk or negedge axi_resetn) begin if (axi_resetn == 1'b0) begin axi_rel_toggle_m <= 'd0; axi_rel_waddr <= 'd0; axi_waddr_m1 <= 'd0; axi_waddr_m2 <= 'd0; axi_waddr <= 'd0; end else begin axi_rel_toggle_m <= {axi_rel_toggle_m[1:0], adc_rel_toggle}; if (axi_rel_toggle_s == 1'b1) begin axi_rel_waddr <= adc_rel_waddr; end axi_waddr_m1 <= adc_waddr_g; axi_waddr_m2 <= axi_waddr_m1; axi_waddr <= g2b(axi_waddr_m2); end end // overflow (no underflow possible) assign axi_addr_diff_s = {1'b1, axi_waddr} - axi_raddr; always @(posedge axi_clk or negedge axi_resetn) begin if (axi_resetn == 1'b0) begin axi_addr_diff <= 'd0; axi_almost_full <= 'd0; axi_dwunf <= 'd0; axi_almost_empty <= 'd0; axi_dwovf <= 'd0; end else begin axi_addr_diff <= axi_addr_diff_s[7:0]; if (axi_addr_diff > BUF_THRESHOLD_HI) begin axi_almost_full <= 1'b1; axi_dwunf <= axi_almost_empty; end else begin axi_almost_full <= 1'b0; axi_dwunf <= 1'b0; end if (axi_addr_diff < BUF_THRESHOLD_LO) begin axi_almost_empty <= 1'b1; axi_dwovf <= axi_almost_full; end else begin axi_almost_empty <= 1'b0; axi_dwovf <= 1'b0; end end end // transfer request is required to keep things in sync always @(posedge axi_clk or negedge axi_resetn) begin if (axi_resetn == 1'b0) begin axi_xfer_req_m <= 'd0; axi_xfer_init <= 'd0; end else begin axi_xfer_req_m <= {axi_xfer_req_m[1:0], dma_xfer_req}; axi_xfer_init <= axi_xfer_req_m[1] & ~axi_xfer_req_m[2]; end end // read is initiated if xfer enabled assign axi_wready_s = ~axi_wvalid | axi_wready; assign axi_rd_s = (axi_rel_waddr == axi_raddr) ? 1'b0 : axi_wready_s; assign axi_req_s = (axi_raddr[1:0] == 2'h0) ? axi_rd_s : 1'b0; assign axi_rlast_s = (axi_raddr[1:0] == 2'h3) ? axi_rd_s : 1'b0; always @(posedge axi_clk or negedge axi_resetn) begin if (axi_resetn == 1'b0) begin axi_raddr <= 'd0; axi_rd <= 'd0; axi_rlast <= 'd0; axi_rd_d <= 'd0; axi_rlast_d <= 'd0; axi_rdata_d <= 'd0; end else begin if (axi_rd_s == 1'b1) begin axi_raddr <= axi_raddr + 1'b1; end axi_rd <= axi_rd_s; axi_rlast <= axi_rlast_s; axi_rd_d <= axi_rd; axi_rlast_d <= axi_rlast; axi_rdata_d <= axi_rdata_s; end end // send read request for every burst about to be completed always @(posedge axi_clk or negedge axi_resetn) begin if (axi_resetn == 1'b0) begin axi_rd_req <= 'd0; axi_rd_addr <= 'd0; end else begin axi_rd_req <= axi_rlast_s; if (axi_xfer_init == 1'b1) begin axi_rd_addr <= AXI_ADDRESS; end else if (axi_rd_req == 1'b1) begin axi_rd_addr <= axi_rd_addr + AXI_AWINCR; end end end // address channel assign axi_awid = 4'b0000; assign axi_awburst = 2'b01; assign axi_awlock = 1'b0; assign axi_awcache = 4'b0010; assign axi_awprot = 3'b000; assign axi_awqos = 4'b0000; assign axi_awuser = 4'b0001; assign axi_awlen = AXI_LENGTH - 1; assign axi_awsize = AXI_SIZE; always @(posedge axi_clk or negedge axi_resetn) begin if (axi_resetn == 1'b0) begin axi_awvalid <= 'd0; axi_awaddr <= 'd0; end else begin if (axi_awvalid == 1'b1) begin if (axi_awready == 1'b1) begin axi_awvalid <= 1'b0; end end else begin if (axi_req_s == 1'b1) begin axi_awvalid <= 1'b1; end end if (axi_xfer_init == 1'b1) begin axi_awaddr <= AXI_ADDRESS; end else if ((axi_awvalid == 1'b1) && (axi_awready == 1'b1)) begin axi_awaddr <= axi_awaddr + AXI_AWINCR; end end end // write channel assign axi_wstrb = {AXI_BYTE_WIDTH{1'b1}}; assign axi_wuser = 4'b0000; // response channel assign axi_bready = 1'b1; always @(posedge axi_clk or negedge axi_resetn) begin if (axi_resetn == 1'b0) begin axi_werror <= 'd0; end else begin axi_werror <= axi_bvalid & axi_bready & axi_bresp[1]; end end // fifo needs a reset always @(posedge axi_clk or negedge axi_resetn) begin if (axi_resetn == 1'b0) begin axi_reset <= 1'b1; end else begin axi_reset <= 1'b0; end end // interface handler ad_axis_inf_rx #( .DATA_WIDTH(AXI_DATA_WIDTH) ) i_axis_inf ( .clk (axi_clk), .rst (axi_reset), .valid (axi_rd_d), .last (axi_rlast_d), .data (axi_rdata_d), .inf_valid (axi_wvalid), .inf_last (axi_wlast), .inf_data (axi_wdata), .inf_ready (axi_wready)); // buffer ad_mem #( .DATA_WIDTH(AXI_DATA_WIDTH), .ADDRESS_WIDTH(8) ) i_mem ( .clka (adc_clk), .wea (adc_wr), .addra (adc_waddr), .dina (adc_wdata), .clkb (axi_clk), .reb (1'b1), .addrb (axi_raddr), .doutb (axi_rdata_s)); endmodule