/* Copyright (c) 2015-2017 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-Stream XGMII frame transmitter (AXI in, XGMII out) */ module axis_xgmii_tx_64 # ( parameter ENABLE_PADDING = 1, parameter ENABLE_DIC = 1, parameter MIN_FRAME_LENGTH = 64 ) ( input wire clk, input wire rst, /* * AXI input */ input wire [63:0] input_axis_tdata, input wire [7:0] input_axis_tkeep, input wire input_axis_tvalid, output wire input_axis_tready, input wire input_axis_tlast, input wire input_axis_tuser, /* * XGMII output */ output wire [63:0] xgmii_txd, output wire [7:0] xgmii_txc, /* * Configuration */ input wire [7:0] ifg_delay ); localparam MIN_FL_NOCRC = MIN_FRAME_LENGTH-4; localparam MIN_FL_NOCRC_MS = MIN_FL_NOCRC & 16'hfff8; localparam MIN_FL_NOCRC_LS = MIN_FL_NOCRC & 16'h0007; localparam [2:0] STATE_IDLE = 3'd0, STATE_PAYLOAD = 3'd1, STATE_PAD = 3'd2, STATE_FCS_1 = 3'd3, STATE_FCS_2 = 3'd4, STATE_IFG = 3'd5, STATE_WAIT_END = 3'd6; reg [2:0] state_reg = STATE_IDLE, state_next; // datapath control signals reg reset_crc; reg update_crc; reg swap_lanes; reg unswap_lanes; reg lanes_swapped = 1'b0; reg [31:0] swap_txd = 32'd0; reg [3:0] swap_txc = 4'd0; reg [63:0] input_axis_tdata_masked; reg [63:0] input_tdata_reg = 64'd0, input_tdata_next; reg [7:0] input_tkeep_reg = 8'd0, input_tkeep_next; reg [63:0] fcs_output_txd_0; reg [63:0] fcs_output_txd_1; reg [7:0] fcs_output_txc_0; reg [7:0] fcs_output_txc_1; reg [7:0] ifg_offset; reg extra_cycle; reg [15:0] frame_ptr_reg = 16'd0, frame_ptr_next; reg [7:0] ifg_count_reg = 8'd0, ifg_count_next; reg [1:0] deficit_idle_count_reg = 2'd0, deficit_idle_count_next; reg input_axis_tready_reg = 1'b0, input_axis_tready_next; reg [31:0] crc_state = 32'hFFFFFFFF; wire [31:0] crc_next0; wire [31:0] crc_next1; wire [31:0] crc_next2; wire [31:0] crc_next3; wire [31:0] crc_next4; wire [31:0] crc_next5; wire [31:0] crc_next6; wire [31:0] crc_next7; reg [63:0] xgmii_txd_reg = 64'h0707070707070707, xgmii_txd_next; reg [7:0] xgmii_txc_reg = 8'b11111111, xgmii_txc_next; assign input_axis_tready = input_axis_tready_reg; assign xgmii_txd = xgmii_txd_reg; assign xgmii_txc = xgmii_txc_reg; lfsr #( .LFSR_WIDTH(32), .LFSR_POLY(32'h4c11db7), .LFSR_CONFIG("GALOIS"), .LFSR_FEED_FORWARD(0), .REVERSE(1), .DATA_WIDTH(8), .STYLE("AUTO") ) eth_crc_8 ( .data_in(input_tdata_reg[7:0]), .state_in(crc_state), .data_out(), .state_out(crc_next0) ); lfsr #( .LFSR_WIDTH(32), .LFSR_POLY(32'h4c11db7), .LFSR_CONFIG("GALOIS"), .LFSR_FEED_FORWARD(0), .REVERSE(1), .DATA_WIDTH(16), .STYLE("AUTO") ) eth_crc_16 ( .data_in(input_tdata_reg[15:0]), .state_in(crc_state), .data_out(), .state_out(crc_next1) ); lfsr #( .LFSR_WIDTH(32), .LFSR_POLY(32'h4c11db7), .LFSR_CONFIG("GALOIS"), .LFSR_FEED_FORWARD(0), .REVERSE(1), .DATA_WIDTH(24), .STYLE("AUTO") ) eth_crc_24 ( .data_in(input_tdata_reg[23:0]), .state_in(crc_state), .data_out(), .state_out(crc_next2) ); lfsr #( .LFSR_WIDTH(32), .LFSR_POLY(32'h4c11db7), .LFSR_CONFIG("GALOIS"), .LFSR_FEED_FORWARD(0), .REVERSE(1), .DATA_WIDTH(32), .STYLE("AUTO") ) eth_crc_32 ( .data_in(input_tdata_reg[31:0]), .state_in(crc_state), .data_out(), .state_out(crc_next3) ); lfsr #( .LFSR_WIDTH(32), .LFSR_POLY(32'h4c11db7), .LFSR_CONFIG("GALOIS"), .LFSR_FEED_FORWARD(0), .REVERSE(1), .DATA_WIDTH(40), .STYLE("AUTO") ) eth_crc_40 ( .data_in(input_tdata_reg[39:0]), .state_in(crc_state), .data_out(), .state_out(crc_next4) ); lfsr #( .LFSR_WIDTH(32), .LFSR_POLY(32'h4c11db7), .LFSR_CONFIG("GALOIS"), .LFSR_FEED_FORWARD(0), .REVERSE(1), .DATA_WIDTH(48), .STYLE("AUTO") ) eth_crc_48 ( .data_in(input_tdata_reg[47:0]), .state_in(crc_state), .data_out(), .state_out(crc_next5) ); lfsr #( .LFSR_WIDTH(32), .LFSR_POLY(32'h4c11db7), .LFSR_CONFIG("GALOIS"), .LFSR_FEED_FORWARD(0), .REVERSE(1), .DATA_WIDTH(56), .STYLE("AUTO") ) eth_crc_56 ( .data_in(input_tdata_reg[55:0]), .state_in(crc_state), .data_out(), .state_out(crc_next6) ); lfsr #( .LFSR_WIDTH(32), .LFSR_POLY(32'h4c11db7), .LFSR_CONFIG("GALOIS"), .LFSR_FEED_FORWARD(0), .REVERSE(1), .DATA_WIDTH(64), .STYLE("AUTO") ) eth_crc_64 ( .data_in(input_tdata_reg[63:0]), .state_in(crc_state), .data_out(), .state_out(crc_next7) ); function [3:0] keep2count; input [7:0] k; casez (k) 8'bzzzzzzz0: keep2count = 4'd0; 8'bzzzzzz01: keep2count = 4'd1; 8'bzzzzz011: keep2count = 4'd2; 8'bzzzz0111: keep2count = 4'd3; 8'bzzz01111: keep2count = 4'd4; 8'bzz011111: keep2count = 4'd5; 8'bz0111111: keep2count = 4'd6; 8'b01111111: keep2count = 4'd7; 8'b11111111: keep2count = 4'd8; endcase endfunction function [7:0] count2keep; input [3:0] k; case (k) 4'd0: count2keep = 8'b00000000; 4'd1: count2keep = 8'b00000001; 4'd2: count2keep = 8'b00000011; 4'd3: count2keep = 8'b00000111; 4'd4: count2keep = 8'b00001111; 4'd5: count2keep = 8'b00011111; 4'd6: count2keep = 8'b00111111; 4'd7: count2keep = 8'b01111111; 4'd8: count2keep = 8'b11111111; endcase endfunction // Mask input data integer j; always @* begin for (j = 0; j < 8; j = j + 1) begin input_axis_tdata_masked[j*8 +: 8] = input_axis_tkeep[j] ? input_axis_tdata[j*8 +: 8] : 8'd0; end end // FCS cycle calculation always @* begin casez (input_tkeep_reg) 8'bzzzzzz01: begin fcs_output_txd_0 = {24'h0707fd, ~crc_next0[31:0], input_tdata_reg[7:0]}; fcs_output_txd_1 = {63'h0707070707070707}; fcs_output_txc_0 = 8'b11100000; fcs_output_txc_1 = 8'b11111111; ifg_offset = 8'd3; extra_cycle = 1'b0; end 8'bzzzzz011: begin fcs_output_txd_0 = {16'h07fd, ~crc_next1[31:0], input_tdata_reg[15:0]}; fcs_output_txd_1 = {63'h0707070707070707}; fcs_output_txc_0 = 8'b11000000; fcs_output_txc_1 = 8'b11111111; ifg_offset = 8'd2; extra_cycle = 1'b0; end 8'bzzzz0111: begin fcs_output_txd_0 = {8'hfd, ~crc_next2[31:0], input_tdata_reg[23:0]}; fcs_output_txd_1 = {63'h0707070707070707}; fcs_output_txc_0 = 8'b10000000; fcs_output_txc_1 = 8'b11111111; ifg_offset = 8'd1; extra_cycle = 1'b0; end 8'bzzz01111: begin fcs_output_txd_0 = {~crc_next3[31:0], input_tdata_reg[31:0]}; fcs_output_txd_1 = {63'h07070707070707fd}; fcs_output_txc_0 = 8'b00000000; fcs_output_txc_1 = 8'b11111111; ifg_offset = 8'd8; extra_cycle = 1'b1; end 8'bzz011111: begin fcs_output_txd_0 = {~crc_next4[23:0], input_tdata_reg[39:0]}; fcs_output_txd_1 = {56'h070707070707fd, ~crc_next4[31:24]}; fcs_output_txc_0 = 8'b00000000; fcs_output_txc_1 = 8'b11111110; ifg_offset = 8'd7; extra_cycle = 1'b1; end 8'bz0111111: begin fcs_output_txd_0 = {~crc_next5[15:0], input_tdata_reg[47:0]}; fcs_output_txd_1 = {48'h0707070707fd, ~crc_next5[31:16]}; fcs_output_txc_0 = 8'b00000000; fcs_output_txc_1 = 8'b11111100; ifg_offset = 8'd6; extra_cycle = 1'b1; end 8'b01111111: begin fcs_output_txd_0 = {~crc_next6[7:0], input_tdata_reg[55:0]}; fcs_output_txd_1 = {40'h07070707fd, ~crc_next6[31:8]}; fcs_output_txc_0 = 8'b00000000; fcs_output_txc_1 = 8'b11111000; ifg_offset = 8'd5; extra_cycle = 1'b1; end 8'b11111111: begin fcs_output_txd_0 = input_tdata_reg; fcs_output_txd_1 = {32'h070707fd, ~crc_next7[31:0]}; fcs_output_txc_0 = 8'b00000000; fcs_output_txc_1 = 8'b11110000; ifg_offset = 8'd4; extra_cycle = 1'b1; end default: begin fcs_output_txd_0 = 64'd0; fcs_output_txd_1 = 64'd0; fcs_output_txc_0 = 8'd0; fcs_output_txc_1 = 8'd0; ifg_offset = 8'd0; extra_cycle = 1'b1; end endcase end always @* begin state_next = STATE_IDLE; reset_crc = 1'b0; update_crc = 1'b0; swap_lanes = 1'b0; unswap_lanes = 1'b0; frame_ptr_next = frame_ptr_reg; ifg_count_next = ifg_count_reg; deficit_idle_count_next = deficit_idle_count_reg; input_axis_tready_next = 1'b0; input_tdata_next = input_tdata_reg; input_tkeep_next = input_tkeep_reg; // XGMII idle xgmii_txd_next = 64'h0707070707070707; xgmii_txc_next = 8'b11111111; case (state_reg) STATE_IDLE: begin // idle state - wait for data frame_ptr_next = 16'd8; reset_crc = 1'b1; input_axis_tready_next = 1'b1; // XGMII idle xgmii_txd_next = 64'h0707070707070707; xgmii_txc_next = 8'b11111111; input_tdata_next = input_axis_tdata_masked; input_tkeep_next = input_axis_tkeep; if (input_axis_tvalid) begin // XGMII start and preamble if (ifg_count_reg > 8'd0) begin // need to send more idles - swap lanes swap_lanes = 1'b1; end else begin // no more idles - unswap unswap_lanes = 1'b1; end xgmii_txd_next = 64'hd5555555555555fb; xgmii_txc_next = 8'b00000001; input_axis_tready_next = 1'b1; state_next = STATE_PAYLOAD; end else begin ifg_count_next = 8'd0; deficit_idle_count_next = 2'd0; unswap_lanes = 1'b1; state_next = STATE_IDLE; end end STATE_PAYLOAD: begin // transfer payload update_crc = 1'b1; input_axis_tready_next = 1'b1; frame_ptr_next = frame_ptr_reg + 16'd8; xgmii_txd_next = input_tdata_reg; xgmii_txc_next = 8'b00000000; input_tdata_next = input_axis_tdata_masked; input_tkeep_next = input_axis_tkeep; if (input_axis_tvalid) begin if (input_axis_tlast) begin frame_ptr_next = frame_ptr_reg + keep2count(input_axis_tkeep); input_axis_tready_next = 1'b0; if (input_axis_tuser) begin xgmii_txd_next = 64'h070707fdfefefefe; xgmii_txc_next = 8'b11111111; frame_ptr_next = 16'd0; ifg_count_next = 8'd8; state_next = STATE_IFG; end else begin input_axis_tready_next = 1'b0; if (ENABLE_PADDING && (frame_ptr_reg < MIN_FL_NOCRC_MS || (frame_ptr_reg == MIN_FL_NOCRC_MS && keep2count(input_axis_tkeep) < MIN_FL_NOCRC_LS))) begin input_tkeep_next = 8'hff; frame_ptr_next = frame_ptr_reg + 16'd8; if (frame_ptr_reg < (MIN_FL_NOCRC_LS > 0 ? MIN_FL_NOCRC_MS : MIN_FL_NOCRC_MS-8)) begin state_next = STATE_PAD; end else begin input_tkeep_next = 8'hff >> ((8-MIN_FL_NOCRC_LS) % 8); state_next = STATE_FCS_1; end end else begin state_next = STATE_FCS_1; end end end else begin state_next = STATE_PAYLOAD; end end else begin // tvalid deassert, fail frame xgmii_txd_next = 64'h070707fdfefefefe; xgmii_txc_next = 8'b11111111; frame_ptr_next = 16'd0; ifg_count_next = 8'd8; state_next = STATE_WAIT_END; end end STATE_PAD: begin // pad frame to MIN_FRAME_LENGTH input_axis_tready_next = 1'b0; xgmii_txd_next = input_tdata_reg; xgmii_txc_next = 8'b00000000; input_tdata_next = 64'd0; input_tkeep_next = 8'hff; update_crc = 1'b1; frame_ptr_next = frame_ptr_reg + 16'd8; if (frame_ptr_reg < (MIN_FL_NOCRC_LS > 0 ? MIN_FL_NOCRC_MS : MIN_FL_NOCRC_MS-8)) begin state_next = STATE_PAD; end else begin input_tkeep_next = 8'hff >> ((8-MIN_FL_NOCRC_LS) % 8); state_next = STATE_FCS_1; end end STATE_FCS_1: begin // last cycle input_axis_tready_next = 1'b0; xgmii_txd_next = fcs_output_txd_0; xgmii_txc_next = fcs_output_txc_0; frame_ptr_next = 16'd0; ifg_count_next = (ifg_delay > 8'd12 ? ifg_delay : 8'd12) - ifg_offset + (lanes_swapped ? 8'd4 : 8'd0) + deficit_idle_count_reg; if (extra_cycle) begin state_next = STATE_FCS_2; end else begin state_next = STATE_IFG; end end STATE_FCS_2: begin // last cycle input_axis_tready_next = 1'b0; xgmii_txd_next = fcs_output_txd_1; xgmii_txc_next = fcs_output_txc_1; reset_crc = 1'b1; frame_ptr_next = 16'd0; if (ENABLE_DIC) begin if (ifg_count_next > 8'd7) begin state_next = STATE_IFG; end else begin if (ifg_count_next >= 8'd4) begin deficit_idle_count_next = ifg_count_next - 8'd4; end else begin deficit_idle_count_next = ifg_count_next; ifg_count_next = 8'd0; end input_axis_tready_next = 1'b1; state_next = STATE_IDLE; end end else begin if (ifg_count_next > 8'd4) begin state_next = STATE_IFG; end else begin input_axis_tready_next = 1'b1; state_next = STATE_IDLE; end end end STATE_IFG: begin // send IFG if (ifg_count_reg > 8'd8) begin ifg_count_next = ifg_count_reg - 8'd8; end else begin ifg_count_next = 8'd0; end reset_crc = 1'b1; if (ENABLE_DIC) begin if (ifg_count_next > 8'd7) begin state_next = STATE_IFG; end else begin if (ifg_count_next >= 8'd4) begin deficit_idle_count_next = ifg_count_next - 8'd4; end else begin deficit_idle_count_next = ifg_count_next; ifg_count_next = 8'd0; end input_axis_tready_next = 1'b1; state_next = STATE_IDLE; end end else begin if (ifg_count_next > 8'd4) begin state_next = STATE_IFG; end else begin input_axis_tready_next = 1'b1; state_next = STATE_IDLE; end end end STATE_WAIT_END: begin // wait for end of frame if (ifg_count_reg > 8'd8) begin ifg_count_next = ifg_count_reg - 8'd8; end else begin ifg_count_next = 8'd0; end reset_crc = 1'b1; if (input_axis_tvalid) begin if (input_axis_tlast) begin if (ENABLE_DIC) begin if (ifg_count_next > 8'd7) begin state_next = STATE_IFG; end else begin if (ifg_count_next >= 8'd4) begin deficit_idle_count_next = ifg_count_next - 8'd4; end else begin deficit_idle_count_next = ifg_count_next; ifg_count_next = 8'd0; end input_axis_tready_next = 1'b1; state_next = STATE_IDLE; end end else begin if (ifg_count_next > 8'd4) begin state_next = STATE_IFG; end else begin input_axis_tready_next = 1'b1; state_next = STATE_IDLE; end end end else begin state_next = STATE_WAIT_END; end end else begin state_next = STATE_WAIT_END; end end endcase end always @(posedge clk) begin if (rst) begin state_reg <= STATE_IDLE; frame_ptr_reg <= 16'd0; ifg_count_reg <= 8'd0; deficit_idle_count_reg <= 2'd0; input_axis_tready_reg <= 1'b0; xgmii_txd_reg <= 64'h0707070707070707; xgmii_txc_reg <= 8'b11111111; crc_state <= 32'hFFFFFFFF; lanes_swapped <= 1'b0; end else begin state_reg <= state_next; frame_ptr_reg <= frame_ptr_next; ifg_count_reg <= ifg_count_next; deficit_idle_count_reg <= deficit_idle_count_next; input_axis_tready_reg <= input_axis_tready_next; if (lanes_swapped) begin if (unswap_lanes) begin lanes_swapped <= 1'b0; xgmii_txd_reg <= xgmii_txd_next; xgmii_txc_reg <= xgmii_txc_next; end else begin xgmii_txd_reg <= {xgmii_txd_next[31:0], swap_txd}; xgmii_txc_reg <= {xgmii_txc_next[3:0], swap_txc}; end end else begin if (swap_lanes) begin lanes_swapped <= 1'b1; xgmii_txd_reg <= {xgmii_txd_next[31:0], swap_txd}; xgmii_txc_reg <= {xgmii_txc_next[3:0], swap_txc}; end else begin xgmii_txd_reg <= xgmii_txd_next; xgmii_txc_reg <= xgmii_txc_next; end end // datapath if (reset_crc) begin crc_state <= 32'hFFFFFFFF; end else if (update_crc) begin crc_state <= crc_next7; end end input_tdata_reg <= input_tdata_next; input_tkeep_reg <= input_tkeep_next; swap_txd <= xgmii_txd_next[63:32]; swap_txc <= xgmii_txc_next[7:4]; end endmodule