/* Copyright (c) 2015-2018 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 /* * RGMII PHY interface */ module rgmii_phy_if # ( // target ("SIM", "GENERIC", "XILINX", "ALTERA") parameter TARGET = "GENERIC", // IODDR style ("IODDR", "IODDR2") // Use IODDR for Virtex-4, Virtex-5, Virtex-6, 7 Series, Ultrascale // Use IODDR2 for Spartan-6 parameter IODDR_STYLE = "IODDR2", // Clock input style ("BUFG", "BUFR", "BUFIO", "BUFIO2") // Use BUFR for Virtex-6, 7-series // Use BUFG for Virtex-5, Spartan-6, Ultrascale parameter CLOCK_INPUT_STYLE = "BUFG", // Use 90 degree clock for RGMII transmit ("TRUE", "FALSE") parameter USE_CLK90 = "TRUE" ) ( input wire clk, input wire clk90, input wire rst, /* * GMII interface to MAC */ output wire mac_gmii_rx_clk, output wire mac_gmii_rx_rst, output wire [7:0] mac_gmii_rxd, output wire mac_gmii_rx_dv, output wire mac_gmii_rx_er, output wire mac_gmii_tx_clk, output wire mac_gmii_tx_rst, output wire mac_gmii_tx_clk_en, input wire [7:0] mac_gmii_txd, input wire mac_gmii_tx_en, input wire mac_gmii_tx_er, /* * RGMII interface to PHY */ input wire phy_rgmii_rx_clk, input wire [3:0] phy_rgmii_rxd, input wire phy_rgmii_rx_ctl, output wire phy_rgmii_tx_clk, output wire [3:0] phy_rgmii_txd, output wire phy_rgmii_tx_ctl, /* * Control */ input wire [1:0] speed ); // receive wire rgmii_rx_ctl_1; wire rgmii_rx_ctl_2; ssio_ddr_in # ( .TARGET(TARGET), .CLOCK_INPUT_STYLE(CLOCK_INPUT_STYLE), .IODDR_STYLE(IODDR_STYLE), .WIDTH(5) ) rx_ssio_ddr_inst ( .input_clk(phy_rgmii_rx_clk), .input_d({phy_rgmii_rxd, phy_rgmii_rx_ctl}), .output_clk(mac_gmii_rx_clk), .output_q1({mac_gmii_rxd[3:0], rgmii_rx_ctl_1}), .output_q2({mac_gmii_rxd[7:4], rgmii_rx_ctl_2}) ); assign mac_gmii_rx_dv = rgmii_rx_ctl_1; assign mac_gmii_rx_er = rgmii_rx_ctl_1 ^ rgmii_rx_ctl_2; // transmit reg rgmii_tx_clk_1 = 1'b1; reg rgmii_tx_clk_2 = 1'b0; reg rgmii_tx_clk_rise = 1'b1; reg rgmii_tx_clk_fall = 1'b1; reg [5:0] count_reg = 6'd0, count_next; always @(posedge clk) begin if (rst) begin rgmii_tx_clk_1 <= 1'b1; rgmii_tx_clk_2 <= 1'b0; rgmii_tx_clk_rise <= 1'b1; rgmii_tx_clk_fall <= 1'b1; count_reg <= 0; end else begin rgmii_tx_clk_1 <= rgmii_tx_clk_2; if (speed == 2'b00) begin // 10M count_reg <= count_reg + 1; rgmii_tx_clk_rise <= 1'b0; rgmii_tx_clk_fall <= 1'b0; if (count_reg == 24) begin rgmii_tx_clk_1 <= 1'b1; rgmii_tx_clk_2 <= 1'b1; rgmii_tx_clk_rise <= 1'b1; end else if (count_reg >= 49) begin rgmii_tx_clk_1 <= 1'b0; rgmii_tx_clk_2 <= 1'b0; rgmii_tx_clk_fall <= 1'b1; count_reg <= 0; end end else if (speed == 2'b01) begin // 100M count_reg <= count_reg + 1; rgmii_tx_clk_rise <= 1'b0; rgmii_tx_clk_fall <= 1'b0; if (count_reg == 2) begin rgmii_tx_clk_1 <= 1'b1; rgmii_tx_clk_2 <= 1'b1; rgmii_tx_clk_rise <= 1'b1; end else if (count_reg >= 4) begin rgmii_tx_clk_2 <= 1'b0; rgmii_tx_clk_fall <= 1'b1; count_reg <= 0; end end else begin // 1000M rgmii_tx_clk_1 <= 1'b1; rgmii_tx_clk_2 <= 1'b0; rgmii_tx_clk_rise <= 1'b1; rgmii_tx_clk_fall <= 1'b1; end end end reg [3:0] rgmii_txd_1 = 0; reg [3:0] rgmii_txd_2 = 0; reg rgmii_tx_ctl_1 = 1'b0; reg rgmii_tx_ctl_2 = 1'b0; reg gmii_clk_en = 1'b1; always @* begin if (speed == 2'b00) begin // 10M rgmii_txd_1 = mac_gmii_txd[3:0]; rgmii_txd_2 = mac_gmii_txd[3:0]; if (rgmii_tx_clk_2) begin rgmii_tx_ctl_1 = mac_gmii_tx_en; rgmii_tx_ctl_2 = mac_gmii_tx_en; end else begin rgmii_tx_ctl_1 = mac_gmii_tx_en ^ mac_gmii_tx_er; rgmii_tx_ctl_2 = mac_gmii_tx_en ^ mac_gmii_tx_er; end gmii_clk_en = rgmii_tx_clk_fall; end else if (speed == 2'b01) begin // 100M rgmii_txd_1 = mac_gmii_txd[3:0]; rgmii_txd_2 = mac_gmii_txd[3:0]; if (rgmii_tx_clk_2) begin rgmii_tx_ctl_1 = mac_gmii_tx_en; rgmii_tx_ctl_2 = mac_gmii_tx_en; end else begin rgmii_tx_ctl_1 = mac_gmii_tx_en ^ mac_gmii_tx_er; rgmii_tx_ctl_2 = mac_gmii_tx_en ^ mac_gmii_tx_er; end gmii_clk_en = rgmii_tx_clk_fall; end else begin // 1000M rgmii_txd_1 = mac_gmii_txd[3:0]; rgmii_txd_2 = mac_gmii_txd[7:4]; rgmii_tx_ctl_1 = mac_gmii_tx_en; rgmii_tx_ctl_2 = mac_gmii_tx_en ^ mac_gmii_tx_er; gmii_clk_en = 1; end end wire phy_rgmii_tx_clk_new; wire [3:0] phy_rgmii_txd_new; wire phy_rgmii_tx_ctl_new; oddr #( .TARGET(TARGET), .IODDR_STYLE(IODDR_STYLE), .WIDTH(1) ) clk_oddr_inst ( .clk(USE_CLK90 == "TRUE" ? clk90 : clk), .d1(rgmii_tx_clk_1), .d2(rgmii_tx_clk_2), .q(phy_rgmii_tx_clk) ); oddr #( .TARGET(TARGET), .IODDR_STYLE(IODDR_STYLE), .WIDTH(5) ) data_oddr_inst ( .clk(clk), .d1({rgmii_txd_1, rgmii_tx_ctl_1}), .d2({rgmii_txd_2, rgmii_tx_ctl_2}), .q({phy_rgmii_txd, phy_rgmii_tx_ctl}) ); assign mac_gmii_tx_clk = clk; assign mac_gmii_tx_clk_en = gmii_clk_en; // reset sync reg [3:0] tx_rst_reg = 4'hf; assign mac_gmii_tx_rst = tx_rst_reg[0]; always @(posedge mac_gmii_tx_clk or posedge rst) begin if (rst) begin tx_rst_reg <= 4'hf; end else begin tx_rst_reg <= {1'b0, tx_rst_reg[3:1]}; end end reg [3:0] rx_rst_reg = 4'hf; assign mac_gmii_rx_rst = rx_rst_reg[0]; always @(posedge mac_gmii_rx_clk or posedge rst) begin if (rst) begin rx_rst_reg <= 4'hf; end else begin rx_rst_reg <= {1'b0, rx_rst_reg[3:1]}; end end endmodule