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[/] [xge_mac/] [trunk/] [rtl/] [verilog/] [rx_enqueue.v] - Rev 12
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////////////////////////////////////////////////////////////////////// //// //// //// File name "rx_enqueue.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 rx_enqueue(/*AUTOARG*/ // Outputs rxdfifo_wdata, rxdfifo_wstatus, rxdfifo_wen, rxhfifo_ren, rxhfifo_wdata, rxhfifo_wstatus, rxhfifo_wen, local_fault_msg_det, remote_fault_msg_det, status_crc_error_tog, status_fragment_error_tog, status_rxdfifo_ovflow_tog, status_pause_frame_rx_tog, // Inputs clk_xgmii_rx, reset_xgmii_rx_n, xgmii_rxd, xgmii_rxc, rxdfifo_wfull, rxhfifo_rdata, rxhfifo_rstatus, rxhfifo_rempty, rxhfifo_ralmost_empty ); `include "CRC32_D64.v" `include "CRC32_D8.v" `include "utils.v" input clk_xgmii_rx; input reset_xgmii_rx_n; input [63:0] xgmii_rxd; input [7:0] xgmii_rxc; input rxdfifo_wfull; input [63:0] rxhfifo_rdata; input [7:0] rxhfifo_rstatus; input rxhfifo_rempty; input rxhfifo_ralmost_empty; output [63:0] rxdfifo_wdata; output [7:0] rxdfifo_wstatus; output rxdfifo_wen; output rxhfifo_ren; output [63:0] rxhfifo_wdata; output [7:0] rxhfifo_wstatus; output rxhfifo_wen; output [1:0] local_fault_msg_det; output [1:0] remote_fault_msg_det; output status_crc_error_tog; output status_fragment_error_tog; output status_rxdfifo_ovflow_tog; output status_pause_frame_rx_tog; /*AUTOREG*/ // Beginning of automatic regs (for this module's undeclared outputs) reg [1:0] local_fault_msg_det; reg [1:0] remote_fault_msg_det; reg [63:0] rxdfifo_wdata; reg rxdfifo_wen; reg [7:0] rxdfifo_wstatus; reg rxhfifo_ren; reg [63:0] rxhfifo_wdata; reg rxhfifo_wen; reg [7:0] rxhfifo_wstatus; reg status_crc_error_tog; reg status_fragment_error_tog; reg status_pause_frame_rx_tog; reg status_rxdfifo_ovflow_tog; // End of automatics /*AUTOWIRE*/ reg [63:32] xgmii_rxd_d1; reg [7:4] xgmii_rxc_d1; reg [63:0] xgxs_rxd_barrel; reg [7:0] xgxs_rxc_barrel; reg [63:0] xgxs_rxd_barrel_d1; reg [7:0] xgxs_rxc_barrel_d1; reg barrel_shift; reg [31:0] crc32_d64; reg [31:0] crc32_d8; reg [3:0] crc_bytes; reg [3:0] next_crc_bytes; reg [63:0] crc_shift_data; reg crc_start_8b; reg crc_done; reg crc_good; reg crc_clear; reg [31:0] crc_rx; reg [31:0] next_crc_rx; reg [2:0] curr_state; reg [2:0] next_state; reg [13:0] curr_byte_cnt; reg [13:0] next_byte_cnt; reg fragment_error; reg rxd_ovflow_error; reg coding_error; reg next_coding_error; reg [7:0] addmask; reg [7:0] datamask; reg pause_frame; reg next_pause_frame; reg pause_frame_hold; reg good_pause_frame; reg drop_data; reg next_drop_data; reg pkt_pending; reg rxhfifo_ren_d1; reg rxhfifo_ralmost_empty_d1; parameter [2:0] SM_IDLE = 3'd0, SM_RX = 3'd1; always @(posedge clk_xgmii_rx or negedge reset_xgmii_rx_n) begin if (reset_xgmii_rx_n == 1'b0) begin xgmii_rxd_d1 <= 32'b0; xgmii_rxc_d1 <= 4'b0; xgxs_rxd_barrel <= 64'b0; xgxs_rxc_barrel <= 8'b0; xgxs_rxd_barrel_d1 <= 64'b0; xgxs_rxc_barrel_d1 <= 8'b0; barrel_shift <= 1'b0; local_fault_msg_det <= 2'b0; remote_fault_msg_det <= 2'b0; crc32_d64 <= 32'b0; crc32_d8 <= 32'b0; crc_bytes <= 4'b0; crc_shift_data <= 64'b0; crc_done <= 1'b0; crc_rx <= 32'b0; pause_frame_hold <= 1'b0; status_crc_error_tog <= 1'b0; status_fragment_error_tog <= 1'b0; status_rxdfifo_ovflow_tog <= 1'b0; status_pause_frame_rx_tog <= 1'b0; end else begin //--- // Link status RC layer // Look for local/remote messages on lower 4 lanes and upper // 4 lanes. This is a 64-bit interface but look at each 32-bit // independantly. local_fault_msg_det[1] <= (xgmii_rxd[63:32] == {`LOCAL_FAULT, 8'h0, 8'h0, `SEQUENCE} && xgmii_rxc[7:4] == 4'b0001); local_fault_msg_det[0] <= (xgmii_rxd[31:0] == {`LOCAL_FAULT, 8'h0, 8'h0, `SEQUENCE} && xgmii_rxc[3:0] == 4'b0001); remote_fault_msg_det[1] <= (xgmii_rxd[63:32] == {`REMOTE_FAULT, 8'h0, 8'h0, `SEQUENCE} && xgmii_rxc[7:4] == 4'b0001); remote_fault_msg_det[0] <= (xgmii_rxd[31:0] == {`REMOTE_FAULT, 8'h0, 8'h0, `SEQUENCE} && xgmii_rxc[3:0] == 4'b0001); //--- // Rotating barrel. This function allow us to always align the start of // a frame with LANE0. If frame starts in LANE4, it will be shifted 4 bytes // to LANE0, thus reducing the amount of logic needed at the next stage. xgmii_rxd_d1[63:32] <= xgmii_rxd[63:32]; xgmii_rxc_d1[7:4] <= xgmii_rxc[7:4]; if (xgmii_rxd[`LANE0] == `START && xgmii_rxc[0]) begin xgxs_rxd_barrel <= xgmii_rxd; xgxs_rxc_barrel <= xgmii_rxc; barrel_shift <= 1'b0; end else if (xgmii_rxd[`LANE4] == `START && xgmii_rxc[4]) begin xgxs_rxd_barrel <= {xgmii_rxd[31:0], xgmii_rxd_d1[63:32]}; xgxs_rxc_barrel <= {xgmii_rxc[3:0], xgmii_rxc_d1[7:4]}; barrel_shift <= 1'b1; end else if (barrel_shift) begin xgxs_rxd_barrel <= {xgmii_rxd[31:0], xgmii_rxd_d1[63:32]}; xgxs_rxc_barrel <= {xgmii_rxc[3:0], xgmii_rxc_d1[7:4]}; end else begin xgxs_rxd_barrel <= xgmii_rxd; xgxs_rxc_barrel <= xgmii_rxc; end xgxs_rxd_barrel_d1 <= xgxs_rxd_barrel; xgxs_rxc_barrel_d1 <= xgxs_rxc_barrel; //--- // When final CRC calculation begins we capture info relevant to // current frame CRC claculation continues while next frame is // being received. if (crc_start_8b) begin pause_frame_hold <= pause_frame; end //--- // CRC Checking crc_rx <= next_crc_rx; if (crc_clear) begin // CRC is cleared at the beginning of the frame, calculate // 64-bit at a time otherwise crc32_d64 <= 32'hffffffff; end else begin crc32_d64 <= nextCRC32_D64(reverse_64b(xgxs_rxd_barrel_d1), crc32_d64); end if (crc_bytes != 4'b0) begin // When reaching the end of the frame we switch from 64-bit mode // to 8-bit mode to accomodate odd number of bytes in the frame. // crc_bytes indicated the number of remaining payload byte to // compute CRC on. Calculate and decrement until it reaches 0. if (crc_bytes == 4'b1) begin crc_done <= 1'b1; end crc32_d8 <= nextCRC32_D8(reverse_8b(crc_shift_data[7:0]), crc32_d8); crc_shift_data <= {8'h00, crc_shift_data[63:8]}; crc_bytes <= crc_bytes - 4'b1; end else if (crc_bytes == 4'b0) begin // Per Clause 46. Control code during data must be reported // as a CRC error. Indicated here by coding_error. Corrupt CRC // if coding error is detected. if (coding_error || next_coding_error) begin crc32_d8 <= ~crc32_d64; end else begin crc32_d8 <= crc32_d64; end crc_done <= 1'b0; crc_shift_data <= xgxs_rxd_barrel_d1; crc_bytes <= next_crc_bytes; end //--- // Error detection if (crc_done && !crc_good) begin status_crc_error_tog <= ~status_crc_error_tog; end if (fragment_error) begin status_fragment_error_tog <= ~status_fragment_error_tog; end if (rxd_ovflow_error) begin status_rxdfifo_ovflow_tog <= ~status_rxdfifo_ovflow_tog; end //--- // Frame receive indication if (good_pause_frame) begin status_pause_frame_rx_tog <= ~status_pause_frame_rx_tog; end end end always @(/*AS*/crc32_d8 or crc_done or crc_rx or pause_frame_hold) begin crc_good = 1'b0; good_pause_frame = 1'b0; if (crc_done) begin // Check CRC. If this is a pause frame, report it to cpu. if (crc_rx == ~reverse_32b(crc32_d8)) begin crc_good = 1'b1; good_pause_frame = pause_frame_hold; end end end always @(posedge clk_xgmii_rx or negedge reset_xgmii_rx_n) begin if (reset_xgmii_rx_n == 1'b0) begin curr_state <= SM_IDLE; curr_byte_cnt <= 14'b0; coding_error <= 1'b0; pause_frame <= 1'b0; end else begin curr_state <= next_state; curr_byte_cnt <= next_byte_cnt; coding_error <= next_coding_error; pause_frame <= next_pause_frame; end end always @(/*AS*/coding_error or crc_rx or curr_byte_cnt or curr_state or pause_frame or xgxs_rxc_barrel or xgxs_rxc_barrel_d1 or xgxs_rxd_barrel or xgxs_rxd_barrel_d1) begin next_state = curr_state; rxhfifo_wdata = xgxs_rxd_barrel_d1; rxhfifo_wstatus = `RXSTATUS_NONE; rxhfifo_wen = 1'b0; addmask[0] = !(xgxs_rxd_barrel_d1[`LANE0] == `TERMINATE && xgxs_rxc_barrel_d1[0]); addmask[1] = !(xgxs_rxd_barrel_d1[`LANE1] == `TERMINATE && xgxs_rxc_barrel_d1[1]); addmask[2] = !(xgxs_rxd_barrel_d1[`LANE2] == `TERMINATE && xgxs_rxc_barrel_d1[2]); addmask[3] = !(xgxs_rxd_barrel_d1[`LANE3] == `TERMINATE && xgxs_rxc_barrel_d1[3]); addmask[4] = !(xgxs_rxd_barrel_d1[`LANE4] == `TERMINATE && xgxs_rxc_barrel_d1[4]); addmask[5] = !(xgxs_rxd_barrel_d1[`LANE5] == `TERMINATE && xgxs_rxc_barrel_d1[5]); addmask[6] = !(xgxs_rxd_barrel_d1[`LANE6] == `TERMINATE && xgxs_rxc_barrel_d1[6]); addmask[7] = !(xgxs_rxd_barrel_d1[`LANE7] == `TERMINATE && xgxs_rxc_barrel_d1[7]); datamask[0] = addmask[0]; datamask[1] = &addmask[1:0]; datamask[2] = &addmask[2:0]; datamask[3] = &addmask[3:0]; datamask[4] = &addmask[4:0]; datamask[5] = &addmask[5:0]; datamask[6] = &addmask[6:0]; datamask[7] = &addmask[7:0]; next_crc_bytes = 4'b0; next_crc_rx = crc_rx; crc_start_8b = 1'b0; crc_clear = 1'b0; next_byte_cnt = curr_byte_cnt; fragment_error = 1'b0; next_coding_error = coding_error; next_pause_frame = pause_frame; case (curr_state) SM_IDLE: begin next_byte_cnt = 14'b0; crc_clear = 1'b1; next_coding_error = 1'b0; next_pause_frame = 1'b0; // Detect the start of a frame if (xgxs_rxd_barrel_d1[`LANE0] == `START && xgxs_rxc_barrel_d1[0] && xgxs_rxd_barrel_d1[`LANE1] == `PREAMBLE && !xgxs_rxc_barrel_d1[1] && xgxs_rxd_barrel_d1[`LANE2] == `PREAMBLE && !xgxs_rxc_barrel_d1[2] && xgxs_rxd_barrel_d1[`LANE3] == `PREAMBLE && !xgxs_rxc_barrel_d1[3] && xgxs_rxd_barrel_d1[`LANE4] == `PREAMBLE && !xgxs_rxc_barrel_d1[4] && xgxs_rxd_barrel_d1[`LANE5] == `PREAMBLE && !xgxs_rxc_barrel_d1[5] && xgxs_rxd_barrel_d1[`LANE6] == `PREAMBLE && !xgxs_rxc_barrel_d1[6] && xgxs_rxd_barrel_d1[`LANE7] == `SFD && !xgxs_rxc_barrel_d1[7]) begin next_state = SM_RX; end end SM_RX: begin // Pause frames are filtered rxhfifo_wen = !pause_frame; if (xgxs_rxd_barrel_d1[`LANE0] == `START && xgxs_rxc_barrel_d1[0] && xgxs_rxd_barrel_d1[`LANE7] == `SFD && !xgxs_rxc_barrel_d1[7]) begin // Fragment received, if we are still at SOP stage don't store // the frame. If not, write a fake EOP and flag frame as bad. next_byte_cnt = 14'b0; crc_clear = 1'b1; next_coding_error = 1'b0; fragment_error = 1'b1; rxhfifo_wstatus[`RXSTATUS_ERR] = 1'b1; if (curr_byte_cnt == 14'b0) begin rxhfifo_wen = 1'b0; end else begin rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; end end else if (curr_byte_cnt > 14'd9900) begin // Frame too long, TERMMINATE must have been corrupted. // Abort transfer, write a fake EOP, report as fragment. fragment_error = 1'b1; rxhfifo_wstatus[`RXSTATUS_ERR] = 1'b1; rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; next_state = SM_IDLE; end else begin // Pause frame receive, these frame will be filtered if (curr_byte_cnt == 14'd0 && xgxs_rxd_barrel_d1[47:0] == `PAUSE_FRAME) begin rxhfifo_wen = 1'b0; next_pause_frame = 1'b1; end // Control character during data phase, force CRC error if (|(xgxs_rxc_barrel_d1 & datamask)) begin next_coding_error = 1'b1; end // Write SOP to status bits during first byte if (curr_byte_cnt == 14'b0) begin rxhfifo_wstatus[`RXSTATUS_SOP] = 1'b1; end /* verilator lint_off WIDTH */ next_byte_cnt = curr_byte_cnt + addmask[0] + addmask[1] + addmask[2] + addmask[3] + addmask[4] + addmask[5] + addmask[6] + addmask[7]; /* verilator lint_on WIDTH */ // We will not write to the fifo if all is left // are four or less bytes of crc. We also strip off the // crc, which requires looking one cycle ahead // wstatus: // [2:0] modulus of packet length // Look one cycle ahead for TERMINATE in lanes 0 to 4 if (xgxs_rxd_barrel[`LANE4] == `TERMINATE && xgxs_rxc_barrel[4]) begin rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; rxhfifo_wstatus[2:0] = 3'd0; crc_start_8b = 1'b1; next_crc_bytes = 4'd8; next_crc_rx = xgxs_rxd_barrel[31:0]; next_state = SM_IDLE; end if (xgxs_rxd_barrel[`LANE3] == `TERMINATE && xgxs_rxc_barrel[3]) begin rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; rxhfifo_wstatus[2:0] = 3'd7; crc_start_8b = 1'b1; next_crc_bytes = 4'd7; next_crc_rx = {xgxs_rxd_barrel[23:0], xgxs_rxd_barrel_d1[63:56]}; next_state = SM_IDLE; end if (xgxs_rxd_barrel[`LANE2] == `TERMINATE && xgxs_rxc_barrel[2]) begin rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; rxhfifo_wstatus[2:0] = 3'd6; crc_start_8b = 1'b1; next_crc_bytes = 4'd6; next_crc_rx = {xgxs_rxd_barrel[15:0], xgxs_rxd_barrel_d1[63:48]}; next_state = SM_IDLE; end if (xgxs_rxd_barrel[`LANE1] == `TERMINATE && xgxs_rxc_barrel[1]) begin rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; rxhfifo_wstatus[2:0] = 3'd5; crc_start_8b = 1'b1; next_crc_bytes = 4'd5; next_crc_rx = {xgxs_rxd_barrel[7:0], xgxs_rxd_barrel_d1[63:40]}; next_state = SM_IDLE; end if (xgxs_rxd_barrel[`LANE0] == `TERMINATE && xgxs_rxc_barrel[0]) begin rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; rxhfifo_wstatus[2:0] = 3'd4; crc_start_8b = 1'b1; next_crc_bytes = 4'd4; next_crc_rx = xgxs_rxd_barrel_d1[63:32]; next_state = SM_IDLE; end // Look at current cycle for TERMINATE in lanes 5 to 7 if (xgxs_rxd_barrel_d1[`LANE7] == `TERMINATE && xgxs_rxc_barrel_d1[7]) begin rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; rxhfifo_wstatus[2:0] = 3'd3; crc_start_8b = 1'b1; next_crc_bytes = 4'd3; next_crc_rx = xgxs_rxd_barrel_d1[55:24]; next_state = SM_IDLE; end if (xgxs_rxd_barrel_d1[`LANE6] == `TERMINATE && xgxs_rxc_barrel_d1[6]) begin rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; rxhfifo_wstatus[2:0] = 3'd2; crc_start_8b = 1'b1; next_crc_bytes = 4'd2; next_crc_rx = xgxs_rxd_barrel_d1[47:16]; next_state = SM_IDLE; end if (xgxs_rxd_barrel_d1[`LANE5] == `TERMINATE && xgxs_rxc_barrel_d1[5]) begin rxhfifo_wstatus[`RXSTATUS_EOP] = 1'b1; rxhfifo_wstatus[2:0] = 3'd1; crc_start_8b = 1'b1; next_crc_bytes = 4'd1; next_crc_rx = xgxs_rxd_barrel_d1[39:8]; next_state = SM_IDLE; end end end default: begin next_state = SM_IDLE; end endcase end always @(posedge clk_xgmii_rx or negedge reset_xgmii_rx_n) begin if (reset_xgmii_rx_n == 1'b0) begin rxhfifo_ralmost_empty_d1 <= 1'b1; drop_data <= 1'b0; pkt_pending <= 1'b0; rxhfifo_ren_d1 <= 1'b0; end else begin rxhfifo_ralmost_empty_d1 <= rxhfifo_ralmost_empty; drop_data <= next_drop_data; pkt_pending <= rxhfifo_ren; rxhfifo_ren_d1 <= rxhfifo_ren; end end always @(/*AS*/crc_done or crc_good or drop_data or pkt_pending or rxdfifo_wfull or rxhfifo_ralmost_empty_d1 or rxhfifo_rdata or rxhfifo_ren_d1 or rxhfifo_rstatus) begin rxd_ovflow_error = 1'b0; rxdfifo_wdata = rxhfifo_rdata; rxdfifo_wstatus = rxhfifo_rstatus; next_drop_data = drop_data; // There must be at least 8 words in holding FIFO before we start reading. // This provides enough time for CRC calculation. rxhfifo_ren = !rxhfifo_ralmost_empty_d1 || (pkt_pending && !rxhfifo_rstatus[`RXSTATUS_EOP]); if (rxhfifo_ren_d1 && rxhfifo_rstatus[`RXSTATUS_SOP]) begin // Reset drop flag on SOP next_drop_data = 1'b0; end if (rxhfifo_ren_d1 && rxdfifo_wfull && !next_drop_data) begin // FIFO overflow, abort transfer. The rest of the frame // will be dropped. Since we can't put an EOP indication // in a fifo already full, there will be no EOP and receive // side will need to sync on next SOP. rxd_ovflow_error = 1'b1; next_drop_data = 1'b1; end rxdfifo_wen = rxhfifo_ren_d1 && !next_drop_data; if (crc_done && !crc_good) begin // Flag packet with error when CRC error is detected rxdfifo_wstatus[`RXSTATUS_ERR] = 1'b1; end end endmodule
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