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////////////////////////////////////////////////////////////////////// //// //// //// File name "tx_dequeue.v" //// //// //// //// This file is part of the "10GE MAC" project //// //// http://www.opencores.org/cores/xge_mac/ //// //// //// //// Author(s): //// //// - A. Tanguay (antanguay@opencores.org) //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2008 AUTHORS. All rights reserved. //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source 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. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// `include "defines.v" module tx_dequeue(/*AUTOARG*/ // Outputs txdfifo_ren, txhfifo_ren, txhfifo_wdata, txhfifo_wstatus, txhfifo_wen, xgmii_txd, xgmii_txc, status_txdfifo_udflow_tog, txsfifo_wen, txsfifo_wdata, // Inputs clk_xgmii_tx, reset_xgmii_tx_n, ctrl_tx_enable_ctx, status_local_fault_ctx, status_remote_fault_ctx, txdfifo_rdata, txdfifo_rstatus, txdfifo_rempty, txdfifo_ralmost_empty, txhfifo_rdata, txhfifo_rstatus, txhfifo_rempty, txhfifo_ralmost_empty, txhfifo_wfull, txhfifo_walmost_full ); `include "CRC32_D64.v" `include "CRC32_D8.v" `include "utils.v" input clk_xgmii_tx; input reset_xgmii_tx_n; input ctrl_tx_enable_ctx; input status_local_fault_ctx; input status_remote_fault_ctx; input [63:0] txdfifo_rdata; input [7:0] txdfifo_rstatus; input txdfifo_rempty; input txdfifo_ralmost_empty; input [63:0] txhfifo_rdata; input [7:0] txhfifo_rstatus; input txhfifo_rempty; input txhfifo_ralmost_empty; input txhfifo_wfull; input txhfifo_walmost_full; output txdfifo_ren; output txhfifo_ren; output [63:0] txhfifo_wdata; output [7:0] txhfifo_wstatus; output txhfifo_wen; output [63:0] xgmii_txd; output [7:0] xgmii_txc; output status_txdfifo_udflow_tog; output txsfifo_wen; output [13:0] txsfifo_wdata; /*AUTOREG*/ // Beginning of automatic regs (for this module's undeclared outputs) reg status_txdfifo_udflow_tog; reg txdfifo_ren; reg txhfifo_ren; reg [63:0] txhfifo_wdata; reg txhfifo_wen; reg [7:0] txhfifo_wstatus; reg [13:0] txsfifo_wdata; reg txsfifo_wen; reg [7:0] xgmii_txc; reg [63:0] xgmii_txd; // End of automatics /*AUTOWIRE*/ reg [63:0] xgxs_txd; reg [7:0] xgxs_txc; reg [63:0] next_xgxs_txd; reg [7:0] next_xgxs_txc; reg [2:0] curr_state_enc; reg [2:0] next_state_enc; reg [0:0] curr_state_pad; reg [0:0] next_state_pad; reg start_on_lane0; reg next_start_on_lane0; reg [2:0] ifg_deficit; reg [2:0] next_ifg_deficit; reg ifg_4b_add; reg next_ifg_4b_add; reg ifg_8b_add; reg next_ifg_8b_add; reg ifg_8b2_add; reg next_ifg_8b2_add; reg [7:0] eop; reg [7:0] next_eop; reg [63:32] xgxs_txd_barrel; reg [7:4] xgxs_txc_barrel; reg [63:0] txhfifo_rdata_d1; reg [13:0] add_cnt; reg [13:0] byte_cnt; reg [31:0] crc32_d64; reg [31:0] crc32_d8; reg [31:0] crc32_tx; reg [63:0] shift_crc_data; reg [3:0] shift_crc_eop; reg [3:0] shift_crc_cnt; reg [31:0] crc_data; reg frame_available; reg next_frame_available; reg [63:0] next_txhfifo_wdata; reg [7:0] next_txhfifo_wstatus; reg next_txhfifo_wen; reg txdfifo_ren_d1; reg frame_end; parameter [2:0] SM_IDLE = 3'd0, SM_PREAMBLE = 3'd1, SM_TX = 3'd2, SM_EOP = 3'd3, SM_TERM = 3'd4, SM_TERM_FAIL = 3'd5, SM_IFG = 3'd6; parameter [0:0] SM_PAD_EQ = 1'd0, SM_PAD_PAD = 1'd1; //--- // RC layer always @(posedge clk_xgmii_tx or negedge reset_xgmii_tx_n) begin if (reset_xgmii_tx_n == 1'b0) begin xgmii_txd <= {8{`IDLE}}; xgmii_txc <= 8'hff; end else begin //--- // RC Layer, insert local or remote fault messages based on status // of fault state-machine if (status_local_fault_ctx) begin // If local fault detected, send remote fault message to // link partner xgmii_txd <= {`REMOTE_FAULT, 8'h0, 8'h0, `SEQUENCE, `REMOTE_FAULT, 8'h0, 8'h0, `SEQUENCE}; xgmii_txc <= {4'b0001, 4'b0001}; end else if (status_remote_fault_ctx) begin // If remote fault detected, inhibit transmission and send // idle codes xgmii_txd <= {8{`IDLE}}; xgmii_txc <= 8'hff; end else begin xgmii_txd <= xgxs_txd; xgmii_txc <= xgxs_txc; end end end always @(posedge clk_xgmii_tx or negedge reset_xgmii_tx_n) begin if (reset_xgmii_tx_n == 1'b0) begin curr_state_enc <= SM_IDLE; start_on_lane0 <= 1'b1; ifg_deficit <= 3'b0; ifg_4b_add <= 1'b0; ifg_8b_add <= 1'b0; ifg_8b2_add <= 1'b0; eop <= 8'b0; txhfifo_rdata_d1 <= 64'b0; xgxs_txd_barrel <= {4{`IDLE}}; xgxs_txc_barrel <= 4'hf; frame_available <= 1'b0; xgxs_txd <= {8{`IDLE}}; xgxs_txc <= 8'hff; status_txdfifo_udflow_tog <= 1'b0; txsfifo_wen <= 1'b0; txsfifo_wdata <= 14'b0; end else begin curr_state_enc <= next_state_enc; start_on_lane0 <= next_start_on_lane0; ifg_deficit <= next_ifg_deficit; ifg_4b_add <= next_ifg_4b_add; ifg_8b_add <= next_ifg_8b_add; ifg_8b2_add <= next_ifg_8b2_add; eop <= next_eop; txhfifo_rdata_d1 <= txhfifo_rdata; xgxs_txd_barrel <= next_xgxs_txd[63:32]; xgxs_txc_barrel <= next_xgxs_txc[7:4]; frame_available <= next_frame_available; txsfifo_wen <= 1'b0; txsfifo_wdata <= byte_cnt; //--- // Barrel shifter. Previous stage always align packet with LANE0. // This stage allow us to shift packet to align with LANE4 if needed // for correct inter frame gap (IFG). if (next_start_on_lane0) begin xgxs_txd <= next_xgxs_txd; xgxs_txc <= next_xgxs_txc; end else begin xgxs_txd <= {next_xgxs_txd[31:0], xgxs_txd_barrel}; xgxs_txc <= {next_xgxs_txc[3:0], xgxs_txc_barrel}; end //--- // FIFO errors, used to generate interrupts. if (txdfifo_ren && txdfifo_rempty) begin status_txdfifo_udflow_tog <= ~status_txdfifo_udflow_tog; end //--- // Frame count and size if (frame_end) begin txsfifo_wen <= 1'b1; end end end always @(/*AS*/crc32_tx or ctrl_tx_enable_ctx or curr_state_enc or eop or frame_available or ifg_4b_add or ifg_8b2_add or ifg_8b_add or ifg_deficit or start_on_lane0 or status_local_fault_ctx or status_remote_fault_ctx or txhfifo_ralmost_empty or txhfifo_rdata_d1 or txhfifo_rempty or txhfifo_rstatus) begin next_state_enc = curr_state_enc; next_start_on_lane0 = start_on_lane0; next_ifg_deficit = ifg_deficit; next_ifg_4b_add = ifg_4b_add; next_ifg_8b_add = ifg_8b_add; next_ifg_8b2_add = ifg_8b2_add; next_eop = eop; next_xgxs_txd = {8{`IDLE}}; next_xgxs_txc = 8'hff; txhfifo_ren = 1'b0; next_frame_available = frame_available; case (curr_state_enc) SM_IDLE: begin // Wait for frame to be available. There should be a least N bytes in the // data fifo or a crc in the control fifo. The N bytes in the data fifo // give time to the enqueue engine to calculate crc and write it to the // control fifo. If crc is already in control fifo we can start transmitting // with no concern. Transmission is inhibited if local or remote faults // are detected. if (ctrl_tx_enable_ctx && frame_available && !status_local_fault_ctx && !status_remote_fault_ctx) begin txhfifo_ren = 1'b1; next_state_enc = SM_PREAMBLE; end else begin next_frame_available = !txhfifo_ralmost_empty; next_ifg_4b_add = 1'b0; end end SM_PREAMBLE: begin // On reading SOP from fifo, send SFD and preamble characters if (txhfifo_rstatus[`TXSTATUS_SOP]) begin next_xgxs_txd = {`SFD, {6{`PREAMBLE}}, `START}; next_xgxs_txc = 8'h01; txhfifo_ren = 1'b1; next_state_enc = SM_TX; end else begin next_frame_available = 1'b0; next_state_enc = SM_IDLE; end // Depending on deficit idle count calculations, add 4 bytes // or IFG or not. This will determine on which lane start the // next frame. if (ifg_4b_add) begin next_start_on_lane0 = 1'b0; end else begin next_start_on_lane0 = 1'b1; end end SM_TX: begin next_xgxs_txd = txhfifo_rdata_d1; next_xgxs_txc = 8'h00; txhfifo_ren = 1'b1; // Wait for EOP indication to be read from the fifo, then // transition to next state. if (txhfifo_rstatus[`TXSTATUS_EOP]) begin txhfifo_ren = 1'b0; next_frame_available = !txhfifo_ralmost_empty; next_state_enc = SM_EOP; end else if (txhfifo_rempty || txhfifo_rstatus[`TXSTATUS_SOP]) begin // Failure condition, we did not see EOP and there // is no more data in fifo or SOP, force end of packet transmit. next_state_enc = SM_TERM_FAIL; end next_eop[0] = txhfifo_rstatus[2:0] == 3'd1; next_eop[1] = txhfifo_rstatus[2:0] == 3'd2; next_eop[2] = txhfifo_rstatus[2:0] == 3'd3; next_eop[3] = txhfifo_rstatus[2:0] == 3'd4; next_eop[4] = txhfifo_rstatus[2:0] == 3'd5; next_eop[5] = txhfifo_rstatus[2:0] == 3'd6; next_eop[6] = txhfifo_rstatus[2:0] == 3'd7; next_eop[7] = txhfifo_rstatus[2:0] == 3'd0; end SM_EOP: begin // Insert TERMINATE character in correct lane depending on position // of EOP read from fifo. Also insert CRC read from control fifo. if (eop[0]) begin next_xgxs_txd = {{2{`IDLE}}, `TERMINATE, crc32_tx[31:0], txhfifo_rdata_d1[7:0]}; next_xgxs_txc = 8'b11100000; end if (eop[1]) begin next_xgxs_txd = {`IDLE, `TERMINATE, crc32_tx[31:0], txhfifo_rdata_d1[15:0]}; next_xgxs_txc = 8'b11000000; end if (eop[2]) begin next_xgxs_txd = {`TERMINATE, crc32_tx[31:0], txhfifo_rdata_d1[23:0]}; next_xgxs_txc = 8'b10000000; end if (eop[3]) begin next_xgxs_txd = {crc32_tx[31:0], txhfifo_rdata_d1[31:0]}; next_xgxs_txc = 8'b00000000; end if (eop[4]) begin next_xgxs_txd = {crc32_tx[23:0], txhfifo_rdata_d1[39:0]}; next_xgxs_txc = 8'b00000000; end if (eop[5]) begin next_xgxs_txd = {crc32_tx[15:0], txhfifo_rdata_d1[47:0]}; next_xgxs_txc = 8'b00000000; end if (eop[6]) begin next_xgxs_txd = {crc32_tx[7:0], txhfifo_rdata_d1[55:0]}; next_xgxs_txc = 8'b00000000; end if (eop[7]) begin next_xgxs_txd = {txhfifo_rdata_d1[63:0]}; next_xgxs_txc = 8'b00000000; end if (!frame_available) begin // If there is not another frame ready to be transmitted, interface // will go idle and idle deficit idle count calculation is irrelevant. // Set deficit to 0. next_ifg_deficit = 3'b0; end else begin // Idle deficit count calculated based on number of "wasted" bytes // between TERMINATE and alignment of next frame in LANE0. next_ifg_deficit = ifg_deficit + {2'b0, eop[0] | eop[4]} + {1'b0, eop[1] | eop[5], 1'b0} + {1'b0, eop[2] | eop[6], eop[2] | eop[6]}; end // IFG corrections based on deficit count and previous starting lane // Calculated based on following table: // // DIC=0 DIC=1 DIC=2 DIC=3 // ------------- ------------- ------------- ------------- // PktLen IFG Next IFG Next IFG Next IFG Next // Modulus Length DIC Length DIC Length DIC Length DIC // ----------------------------------------------------------------------- // 0 12 0 12 1 12 2 12 3 // 1 11 1 11 2 11 3 15 0 // 2 10 2 10 3 14 0 14 1 // 3 9 3 13 0 13 1 13 2 // // // In logic it translates into adding 4, 8, or 12 bytes of IFG relative // to LANE0. // IFG and Add columns assume no deficit applied // IFG+DIC and Add+DIC assume deficit must be applied // // Start lane 0 Start lane 4 // EOP Pads IFG IFG+DIC Add Add+DIC Add Add IFG // 0 3 11 15 8 12 12 16 // 1 2 10 14 8 12 12 16 // 2 1 9 13 8 12 12 16 // 3 8 12 12 4 4 8 8 // 4 7 11 15 4 8 8 12 // 5 6 10 14 4 8 8 12 // 6 5 9 13 4 8 8 12 // 7 4 12 12 8 8 12 12 if (!frame_available) begin // If there is not another frame ready to be transmitted, interface // will go idle and idle deficit idle count calculation is irrelevant. next_ifg_4b_add = 1'b0; next_ifg_8b_add = 1'b0; next_ifg_8b2_add = 1'b0; end else if (next_ifg_deficit[2] == ifg_deficit[2]) begin // Add 4 bytes IFG next_ifg_4b_add = (eop[0] & !start_on_lane0) | (eop[1] & !start_on_lane0) | (eop[2] & !start_on_lane0) | (eop[3] & start_on_lane0) | (eop[4] & start_on_lane0) | (eop[5] & start_on_lane0) | (eop[6] & start_on_lane0) | (eop[7] & !start_on_lane0); // Add 8 bytes IFG next_ifg_8b_add = (eop[0]) | (eop[1]) | (eop[2]) | (eop[3] & !start_on_lane0) | (eop[4] & !start_on_lane0) | (eop[5] & !start_on_lane0) | (eop[6] & !start_on_lane0) | (eop[7]); // Add another 8 bytes IFG next_ifg_8b2_add = 1'b0; end else begin // Add 4 bytes IFG next_ifg_4b_add = (eop[0] & start_on_lane0) | (eop[1] & start_on_lane0) | (eop[2] & start_on_lane0) | (eop[3] & start_on_lane0) | (eop[4] & !start_on_lane0) | (eop[5] & !start_on_lane0) | (eop[6] & !start_on_lane0) | (eop[7] & !start_on_lane0); // Add 8 bytes IFG next_ifg_8b_add = (eop[0]) | (eop[1]) | (eop[2]) | (eop[3] & !start_on_lane0) | (eop[4]) | (eop[5]) | (eop[6]) | (eop[7]); // Add another 8 bytes IFG next_ifg_8b2_add = (eop[0] & !start_on_lane0) | (eop[1] & !start_on_lane0) | (eop[2] & !start_on_lane0); end if (|eop[2:0]) begin if (frame_available) begin // Next state depends on number of IFG bytes to be inserted. // Skip idle state if needed. if (next_ifg_8b2_add) begin next_state_enc = SM_IFG; end else if (next_ifg_8b_add) begin next_state_enc = SM_IDLE; end else begin txhfifo_ren = 1'b1; next_state_enc = SM_PREAMBLE; end end else begin next_state_enc = SM_IFG; end end if (|eop[7:3]) begin next_state_enc = SM_TERM; end end SM_TERM: begin // Insert TERMINATE character in correct lane depending on position // of EOP read from fifo. Also insert CRC read from control fifo. if (eop[3]) begin next_xgxs_txd = {{7{`IDLE}}, `TERMINATE}; next_xgxs_txc = 8'b11111111; end if (eop[4]) begin next_xgxs_txd = {{6{`IDLE}}, `TERMINATE, crc32_tx[31:24]}; next_xgxs_txc = 8'b11111110; end if (eop[5]) begin next_xgxs_txd = {{5{`IDLE}}, `TERMINATE, crc32_tx[31:16]}; next_xgxs_txc = 8'b11111100; end if (eop[6]) begin next_xgxs_txd = {{4{`IDLE}}, `TERMINATE, crc32_tx[31:8]}; next_xgxs_txc = 8'b11111000; end if (eop[7]) begin next_xgxs_txd = {{3{`IDLE}}, `TERMINATE, crc32_tx[31:0]}; next_xgxs_txc = 8'b11110000; end // Next state depends on number of IFG bytes to be inserted. // Skip idle state if needed. if (frame_available && !ifg_8b_add) begin txhfifo_ren = 1'b1; next_state_enc = SM_PREAMBLE; end else if (frame_available) begin next_state_enc = SM_IDLE; end else begin next_state_enc = SM_IFG; end end SM_TERM_FAIL: begin next_xgxs_txd = {{7{`IDLE}}, `TERMINATE}; next_xgxs_txc = 8'b11111111; next_state_enc = SM_IFG; end SM_IFG: begin next_state_enc = SM_IDLE; end default: begin next_state_enc = SM_IDLE; end endcase end always @(/*AS*/crc32_d64 or next_txhfifo_wstatus or txhfifo_wen or txhfifo_wstatus) begin if (txhfifo_wen && txhfifo_wstatus[`TXSTATUS_SOP]) begin crc_data = 32'hffffffff; end else begin crc_data = crc32_d64; end if (next_txhfifo_wstatus[`TXSTATUS_EOP] && next_txhfifo_wstatus[2:0] != 3'b0) begin add_cnt = {11'b0, next_txhfifo_wstatus[2:0]}; end else begin add_cnt = 14'd8; end end always @(/*AS*/byte_cnt or curr_state_pad or txdfifo_rdata or txdfifo_rempty or txdfifo_ren_d1 or txdfifo_rstatus or txhfifo_walmost_full) begin next_state_pad = curr_state_pad; next_txhfifo_wdata = txdfifo_rdata; next_txhfifo_wstatus = txdfifo_rstatus; txdfifo_ren = 1'b0; next_txhfifo_wen = 1'b0; case (curr_state_pad) SM_PAD_EQ: begin //--- // If room availabe in hoding fifo and data available in // data fifo, transfer data words. If transmit state machine // is reading from fifo we can assume room will be available. if (!txhfifo_walmost_full) begin txdfifo_ren = !txdfifo_rempty; end //--- // This logic dependent on read during previous cycle. if (txdfifo_ren_d1) begin next_txhfifo_wen = 1'b1; // On EOP, decide if padding is required for this packet. if (txdfifo_rstatus[`TXSTATUS_EOP]) begin if (byte_cnt < 14'd60) begin next_txhfifo_wstatus = `TXSTATUS_NONE; txdfifo_ren = 1'b0; next_state_pad = SM_PAD_PAD; end else if (byte_cnt == 14'd60 && (txdfifo_rstatus[2:0] == 3'd1 || txdfifo_rstatus[2:0] == 3'd2 || txdfifo_rstatus[2:0] == 3'd3)) begin // Pad up to LANE3, keep the other 4 bytes for crc that will // be inserted by dequeue engine. next_txhfifo_wstatus[2:0] = 3'd4; // Pad end bytes with zeros. if (txdfifo_rstatus[2:0] == 3'd1) next_txhfifo_wdata[31:8] = 24'b0; if (txdfifo_rstatus[2:0] == 3'd2) next_txhfifo_wdata[31:16] = 16'b0; if (txdfifo_rstatus[2:0] == 3'd3) next_txhfifo_wdata[31:24] = 8'b0; txdfifo_ren = 1'b0; end else begin txdfifo_ren = 1'b0; end end end end SM_PAD_PAD: begin //--- // Pad packet to 64 bytes by writting zeros to holding fifo. if (!txhfifo_walmost_full) begin next_txhfifo_wdata = 64'b0; next_txhfifo_wstatus = `TXSTATUS_NONE; next_txhfifo_wen = 1'b1; if (byte_cnt == 14'd60) begin // Pad up to LANE3, keep the other 4 bytes for crc that will // be inserted by dequeue engine. next_txhfifo_wstatus[`TXSTATUS_EOP] = 1'b1; next_txhfifo_wstatus[2:0] = 3'd4; next_state_pad = SM_PAD_EQ; end end end default: begin next_state_pad = SM_PAD_EQ; end endcase end always @(posedge clk_xgmii_tx or negedge reset_xgmii_tx_n) begin if (reset_xgmii_tx_n == 1'b0) begin curr_state_pad <= SM_PAD_EQ; txdfifo_ren_d1 <= 1'b0; txhfifo_wdata <= 64'b0; txhfifo_wstatus <= 8'b0; txhfifo_wen <= 1'b0; byte_cnt <= 14'b0; shift_crc_data <= 64'b0; shift_crc_eop <= 4'b0; shift_crc_cnt <= 4'b0; crc32_d64 <= 32'b0; crc32_d8 <= 32'b0; crc32_tx <= 32'b0; frame_end <= 1'b0; end else begin curr_state_pad <= next_state_pad; txdfifo_ren_d1 <= txdfifo_ren; txhfifo_wdata <= next_txhfifo_wdata; txhfifo_wstatus <= next_txhfifo_wstatus; txhfifo_wen <= next_txhfifo_wen; frame_end <= 1'b0; //--- // Reset byte count on SOP if (next_txhfifo_wen) begin if (next_txhfifo_wstatus[`TXSTATUS_SOP]) begin // Init byte count, 8-bytes + 4-bytes for CRC at the end of frame byte_cnt <= 14'd12; end else begin byte_cnt <= byte_cnt + add_cnt; end frame_end <= next_txhfifo_wstatus[`TXSTATUS_EOP]; end //--- // Calculate CRC as data is written to holding fifo. The holding fifo creates // a delay that allow the CRC calculation to complete before the end of the frame // is ready to be transmited. if (txhfifo_wen) begin crc32_d64 <= nextCRC32_D64(reverse_64b(txhfifo_wdata), crc_data); end if (txhfifo_wen && txhfifo_wstatus[`TXSTATUS_EOP]) begin // Last bytes calculated 8-bit at a time instead of 64-bit. Start // this process at the end of the frame. crc32_d8 <= crc32_d64; shift_crc_data <= txhfifo_wdata; shift_crc_cnt <= 4'd9; if (txhfifo_wstatus[2:0] == 3'b0) begin shift_crc_eop <= 4'd8; end else begin shift_crc_eop <= {1'b0, txhfifo_wstatus[2:0]}; end end else if (shift_crc_eop != 4'b0) begin // Complete crc calculation 8-bit at a time until finished. This can // be 1 to 8 bytes long. crc32_d8 <= nextCRC32_D8(reverse_8b(shift_crc_data[7:0]), crc32_d8); shift_crc_data <= {8'b0, shift_crc_data[63:8]}; shift_crc_eop <= shift_crc_eop - 4'd1; end //--- // Update CRC register at the end of calculation. Always update after 8 // cycles for deterministic results, even if a single byte was present in // last data word. if (shift_crc_cnt == 4'b1) begin crc32_tx <= ~reverse_32b(crc32_d8); end else begin shift_crc_cnt <= shift_crc_cnt - 4'd1; end end end endmodule