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[/] [ethmac/] [trunk/] [bench/] [verilog/] [tb_eth_top.v] - Blame information for rev 365

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Please use tb_ethernet.v for testbench. Testbench will soon be
updated.
 
 
 
 
 
 
 
 
 
 
 
 
 
//////////////////////////////////////////////////////////////////////
////                                                              ////
////  tb_eth_top.v                                                ////
////                                                              ////
////  This file is part of the Ethernet IP core project           ////
////  http://www.opencores.org/project,ethmac                     ////
////                                                              ////
////  Author(s):                                                  ////
////      - Igor Mohor (igorM@opencores.org)                      ////
////                                                              ////
////  All additional information is avaliable in the Readme.txt   ////
////  file.                                                       ////
////                                                              ////
//////////////////////////////////////////////////////////////////////
////                                                              ////
//// Copyright (C) 2001 Authors                                   ////
////                                                              ////
//// 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                     ////
////                                                              ////
//////////////////////////////////////////////////////////////////////
//
// CVS Revision History
//
// $Log: not supported by cvs2svn $
// Revision 1.13  2002/05/03 10:25:01  mohor
// Testbench supports unaligned accesses.
//
// Revision 1.12  2002/02/26 17:01:09  mohor
// Small fixes for external/internal DMA missmatches.
//
// Revision 1.11  2002/02/16 13:06:59  mohor
// EXTERNAL_DMA used instead of WISHBONE_DMA.
//
// Revision 1.10  2002/02/16 07:22:15  mohor
// Testbench fixed, code simplified, unused signals removed.
//
// Revision 1.9  2002/02/14 20:14:38  billditt
// Added separate tests for Multicast, Unicast, Broadcast
//
// Revision 1.8  2002/02/12 20:24:00  mohor
// HASH0 and HASH1 register read/write added.
//
// Revision 1.7  2002/02/06 14:11:35  mohor
// non-DMA host interface added. Select the right configutation in eth_defines.
//
// Revision 1.6  2001/12/08 12:36:00  mohor
// TX_BD_NUM register added instead of the RB_BD_ADDR.
//
// Revision 1.5  2001/10/19 11:24:04  mohor
// Number of addresses (wb_adr_i) minimized.
//
// Revision 1.4  2001/10/19 08:46:53  mohor
// eth_timescale.v changed to timescale.v This is done because of the
// simulation of the few cores in a one joined project.
//
// Revision 1.3  2001/09/24 14:55:49  mohor
// Defines changed (All precede with ETH_). Small changes because some
// tools generate warnings when two operands are together. Synchronization
// between two clocks domains in eth_wishbonedma.v is changed (due to ASIC
// demands).
//
// Revision 1.2  2001/08/15 14:04:30  mohor
// Signal names changed on the top level for easier pad insertion (ASIC).
//
// Revision 1.1  2001/08/06 14:41:09  mohor
// A define FPGA added to select between Artisan RAM (for ASIC) and Block Ram (For Virtex).
// Include files fixed to contain no path.
// File names and module names changed ta have a eth_ prologue in the name.
// File eth_timescale.v is used to define timescale
// All pin names on the top module are changed to contain _I, _O or _OE at the end.
// Bidirectional signal MDIO is changed to three signals (Mdc_O, Mdi_I, Mdo_O
// and Mdo_OE. The bidirectional signal must be created on the top level. This
// is done due to the ASIC tools.
//
// Revision 1.1  2001/07/30 21:46:09  mohor
// Directory structure changed. Files checked and joind together.
//
//
//
//
//
 
 
 
`include "tb_eth_defines.v"
`include "ethmac_defines.v"
`include "timescale.v"
 
module tb_eth_top();
 
 
parameter Tp = 1;
 
 
reg           WB_CLK_I;
reg           WB_RST_I;
reg   [31:0]  WB_DAT_I;
 
reg   [31:0]  WB_ADR_I;
reg    [3:0]  WB_SEL_I;
reg           WB_WE_I;
reg           WB_CYC_I;
reg           WB_STB_I;
 
wire  [31:0]  WB_DAT_O;
wire          WB_ACK_O;
wire          WB_ERR_O;
reg    [1:0]  WB_ACK_I;
 
// WISHBONE master
wire    [31:0]    m_wb_adr_o;
wire     [3:0]    m_wb_sel_o;
wire              m_wb_we_o;
reg     [31:0]    m_wb_dat_i;
wire    [31:0]    m_wb_dat_o;
wire              m_wb_cyc_o;
wire              m_wb_stb_o;
reg               m_wb_ack_i;
reg               m_wb_err_i;
 
reg           MTxClk;
wire   [3:0]  MTxD;
wire          MTxEn;
wire          MTxErr;
 
reg           MRxClk;
reg    [3:0]  MRxD;
reg           MRxDV;
reg           MRxErr;
reg           MColl;
reg           MCrs;
 
reg           Mdi_I;
wire          Mdo_O;
wire          Mdo_OE;
wire          Mdc_O;
 
 
reg [7:0] memory0 [0:65535];
reg [7:0] memory1 [0:65535];
reg [7:0] memory2 [0:65535];
reg [7:0] memory3 [0:65535];
 
reg WishboneBusy;
reg StartTB;
reg [9:0] TxBDIndex;
reg [9:0] RxBDIndex;
 
reg LogEnable;
 
  integer mcd1;
  integer mcd2;
 
reg [5:0] g_last_txbd;
 
// Connecting Ethernet top module
 
ethmac ethtop
(
  // WISHBONE common
  .wb_clk_i(WB_CLK_I), .wb_rst_i(WB_RST_I), .wb_dat_i(WB_DAT_I), .wb_dat_o(WB_DAT_O),
 
  // WISHBONE slave
        .wb_adr_i(WB_ADR_I[11:2]), .wb_sel_i(WB_SEL_I), .wb_we_i(WB_WE_I),   .wb_cyc_i(WB_CYC_I),
        .wb_stb_i(WB_STB_I),       .wb_ack_o(WB_ACK_O), .wb_err_o(WB_ERR_O),
 
// WISHBONE master
  .m_wb_adr_o(m_wb_adr_o), .m_wb_sel_o(m_wb_sel_o), .m_wb_we_o(m_wb_we_o), .m_wb_dat_i(m_wb_dat_i),
  .m_wb_dat_o(m_wb_dat_o), .m_wb_cyc_o(m_wb_cyc_o), .m_wb_stb_o(m_wb_stb_o), .m_wb_ack_i(m_wb_ack_i),
  .m_wb_err_i(m_wb_err_i),
 
  //TX
  .mtx_clk_pad_i(MTxClk), .mtxd_pad_o(MTxD), .mtxen_pad_o(MTxEn), .mtxerr_pad_o(MTxErr),
 
  //RX
  .mrx_clk_pad_i(MRxClk), .mrxd_pad_i(MRxD), .mrxdv_pad_i(MRxDV), .mrxerr_pad_i(MRxErr),
  .mcoll_pad_i(MColl),    .mcrs_pad_i(MCrs),
 
  // MIIM
  .mdc_pad_o(Mdc_O), .md_pad_i(Mdi_I), .md_pad_o(Mdo_O), .md_padoe_o(Mdo_OE),
 
  .int_o()
);
 
 
bench_cop i_bench_cop
(
  // WISHBONE common
  .wb_clk_i(WB_CLK_I), .wb_rst_i(WB_RST_I), .wb_dat_i(WB_DAT_I), .wb_dat_o(WB_DAT_O),
 
  // WISHBONE slave
        .wb_adr_i(WB_ADR_I[11:2]), .wb_sel_i(WB_SEL_I), .wb_we_i(WB_WE_I),   .wb_cyc_i(WB_CYC_I),
        .wb_stb_i(WB_STB_I),       .wb_ack_o(WB_ACK_O), .wb_err_o(WB_ERR_O),
 
// WISHBONE master
  .m_wb_adr_o(m_wb_adr_o), .m_wb_sel_o(m_wb_sel_o), .m_wb_we_o(m_wb_we_o), .m_wb_dat_i(m_wb_dat_i),
  .m_wb_dat_o(m_wb_dat_o), .m_wb_cyc_o(m_wb_cyc_o), .m_wb_stb_o(m_wb_stb_o), .m_wb_ack_i(m_wb_ack_i),
  .m_wb_err_i(m_wb_err_i),
 
  //TX
  .mtx_clk_pad_i(MTxClk), .mtxd_pad_o(MTxD), .mtxen_pad_o(MTxEn), .mtxerr_pad_o(MTxErr),
 
  //RX
  .mrx_clk_pad_i(MRxClk), .mrxd_pad_i(MRxD), .mrxdv_pad_i(MRxDV), .mrxerr_pad_i(MRxErr),
  .mcoll_pad_i(MColl),    .mcrs_pad_i(MCrs),
 
  // MIIM
  .mdc_pad_o(Mdc_O), .md_pad_i(Mdi_I), .md_pad_o(Mdo_O), .md_padoe_o(Mdo_OE),
 
  .int_o()
);
 
 
 
 
 
 
 
initial
begin
  WB_CLK_I  =  1'b0;
  WB_DAT_I  = 32'h0;
  WB_ADR_I  = 32'h0;
  WB_SEL_I  =  4'h0;
  WB_WE_I   =  1'b0;
  WB_CYC_I  =  1'b0;
  WB_STB_I  =  1'b0;
 
  m_wb_ack_i = 0;
  m_wb_err_i = 0;
  MTxClk    =  1'b0;
  MRxClk    =  1'b0;
  MRxD      =  4'h0;
  MRxDV     =  1'b0;
  MRxErr    =  1'b0;
  MColl     =  1'b0;
  MCrs      =  1'b0;
  Mdi_I     =  1'b0;
 
  WishboneBusy = 1'b0;
  TxBDIndex = 10'h0;
  RxBDIndex = 10'h0;
  LogEnable = 1'b1;
  g_last_txbd = 6'h0;
end
 
 
// Reset pulse
initial
begin
  mcd1 = $fopen("ethernet_tx.log");
  mcd2 = $fopen("ethernet_rx.log");
  WB_RST_I =  1'b1;
  #100 WB_RST_I =  1'b0;
  #100 StartTB  =  1'b1;
end
 
 
 
// Generating WB_CLK_I clock
always
begin
//  forever #2.5 WB_CLK_I = ~WB_CLK_I;  // 2*2.5 ns -> 200.0 MHz    
//  forever #5 WB_CLK_I = ~WB_CLK_I;  // 2*5 ns -> 100.0 MHz    
//  forever #10 WB_CLK_I = ~WB_CLK_I;  // 2*10 ns -> 50.0 MHz    
  forever #12.5 WB_CLK_I = ~WB_CLK_I;  // 2*12.5 ns -> 40 MHz    
//  forever #15 WB_CLK_I = ~WB_CLK_I;  // 2*10 ns -> 33.3 MHz    
//  forever #20 WB_CLK_I = ~WB_CLK_I;  // 2*20 ns -> 25 MHz    
//  forever #25 WB_CLK_I = ~WB_CLK_I;  // 2*25 ns -> 20.0 MHz
//  forever #31.25 WB_CLK_I = ~WB_CLK_I;  // 2*31.25 ns -> 16.0 MHz    
//  forever #50 WB_CLK_I = ~WB_CLK_I;  // 2*50 ns -> 10.0 MHz
//  forever #55 WB_CLK_I = ~WB_CLK_I;  // 2*55 ns ->  9.1 MHz    
end
 
// Generating MTxClk clock
always
begin
//  #3 forever #20 MTxClk = ~MTxClk;   // 2*20 ns -> 25 MHz
  #3 forever #200 MTxClk = ~MTxClk;   // 2*200 ns -> 2.5 MHz
end
 
// Generating MRxClk clock
always
begin
//  #16 forever #20 MRxClk = ~MRxClk;   // 2*20 ns -> 25 MHz
  #16 forever #200 MRxClk = ~MRxClk;   // 2*200 ns -> 2.5 MHz
//  #16 forever #62.5 MRxClk = ~MRxClk;   // 2*62.5 ns -> 8 MHz       // just for testing purposes
end
 
 
initial
begin
  wait(StartTB);  // Start of testbench
 
  // Reset eth MAC core
  WishboneWrite(32'h00000800, {26'h0, `ETH_MODER_ADR<<2});     // r_Rst = 1
  WishboneWrite(32'h00000000, {26'h0, `ETH_MODER_ADR<<2});     // r_Rst = 0
 
  InitializeMemory;
 
// Select which test you want to run:
  //  TestTxAndRx;
    TestFullDuplex;
  //  TestUnicast;
  //  TestBroadcast;
  //  TestMulticast;
end
 
task TestTxAndRx;
 
 integer ii, jj;
 integer data_in, bd, pointer;
 
 begin
  WishboneWrite(32'h00000800, {26'h0, `ETH_MODER_ADR<<2});     // r_Rst = 1
  WishboneWrite(32'h00000000, {26'h0, `ETH_MODER_ADR<<2});     // r_Rst = 0
  WishboneWrite(32'h00000080, {26'h0, `ETH_TX_BD_NUM_ADR<<2}); // r_RxBDAddress = 0x80
 
//  WishboneWrite(32'h0000a06b, {26'h0, `ETH_MODER_ADR<<2});     // RxEn, Txen, CrcEn, Pad en, half duplex, 
  WishboneWrite(32'h0000a46b, {26'h0, `ETH_MODER_ADR<<2});     // RxEn, Txen, CrcEn, Pad en, full duplex, 
//  WishboneWrite(32'h0001a06b, {26'h0, `ETH_MODER_ADR<<2});     // r_RecSmall, RxEn, Txen, CrcEn, Pad en, half duplex, 
                                                               // r_IPG, promisc On, reject broadcast 
 
  WishboneWrite(32'h00000004, {26'h0, `ETH_CTRLMODER_ADR<<2}); //r_TxFlow = 1
 
  WishboneWrite(32'h00000002, {26'h0, `ETH_MAC_ADDR1_ADR<<2}); // MAC = 000203040506
  WishboneWrite(32'h03040506, {26'h0, `ETH_MAC_ADDR0_ADR<<2});
 
/*
// Just few reads
  WishboneRead({26'h0, `ETH_MODER_ADR<<2}, data_in);       // Read from ETH_MODER register
  WishboneRead({26'h0, `ETH_TX_BD_NUM_ADR<<2}, data_in);       // Read from ETH_TX_BD_NUM_ADR register
  WishboneRead({26'h0, `ETH_MAC_ADDR1_ADR<<2}, data_in);       // Read from ETH_MAC_ADDR1_ADR register
  WishboneRead({26'h0, `ETH_MAC_ADDR0_ADR<<2}, data_in);       // Read from ETH_MAC_ADDR0_ADR register
*/
 
 
 
 
    for(jj=0; jj<8; jj=jj+4)
    begin
      WishboneWriteData(`TX_BUF_BASE + jj, 32'h11111111, 4'hf); // Initializing data to ff
    end
 
    for(jj=0; jj<8; jj=jj+4)
    begin
      WishboneWriteData(`RX_BUF_BASE + jj, 32'h11111111, 4'hf); // Initializing data to ff
    end
 
//  SendPacketX(16'h0064, 1'b0, 2'h3);
//  SendPacketX(16'h0064, 1'b0, 2'h2);
//  SendPacketX(16'h0064, 1'b0, 2'h1);
//  SendPacketX(16'h0064, 1'b0, 2'h0);
//  SendPacket(16'h0064, 1'b0);
//  SendPacket(16'h0011, 1'b0);
//  SendPacket(16'h0012, 1'b0);
 
fork
  begin
/*
  SendPacketX(16'h0064, 1'b0, 2'h1);
  SendPacketX(16'h0064, 1'b0, 2'h2);
  SendPacketX(16'h0064, 1'b0, 2'h3);
  SendPacketX(16'h0064, 1'b0, 2'h0);
*/
//    SendPacketX(16'h264, 1'b0, 2'h3);
//    SendPacketX(16'h64, 1'b0, 2'h3);
//    SendPacketX(16'h104, 1'b0, 2'h3);
  end
 
  begin
    ReceivePacketX(16'h0040, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
    ReceivePacketX(16'h0041, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
    ReceivePacketX(16'h0042, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
    ReceivePacketX(16'h0043, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
    ReceivePacketX(16'h0044, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  end
 
//  begin
//    for(ii=0; ii<10000; ii=ii+1)
//      begin
//        WishboneRead({22'h01, 10'b0}, data_in);  // read back
//        #100;
//      end
//  end
//join
 
//fork
/*
  begin
    repeat(4)
      begin
        wait(tb_eth_top.ethtop.wishbone.TxStatusWrite);   // wait until tx status is written
        @ (posedge WB_CLK_I)
        #1;
      end
  end
*/
  begin
    wait(tb_eth_top.ethtop.wishbone.RxStatusWrite);   // wait until rx status is written
  end
 
join
 
 
/*
  SendPacket(16'h0013, 1'b0);
  SendPacket(16'h0014, 1'b0);
 
  SendPacket(16'h0030, 1'b0);
  SendPacket(16'h0031, 1'b0);
  SendPacket(16'h0032, 1'b0);
  SendPacket(16'h0033, 1'b0);
  SendPacket(16'h0025, 1'b0);
  SendPacket(16'h0045, 1'b0);
  SendPacket(16'h0025, 1'b0);
  SendPacket(16'h0017, 1'b0);
*/
 
//  ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h3);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h2);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h1);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
 
//  ReceivePacket(16'h0050, 1'b0, `MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0051, 1'b0, `UNICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0052, 1'b0, `MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0053, 1'b0, `BROADCAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0054, 1'b0, `UNICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0055, 1'b0, `MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0056, 1'b0, `UNICAST_WRONG_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
 
 
  repeat(1000) @ (posedge MRxClk);        // Waiting some time for all accesses to finish before reading out the statuses.
 
//  WishboneRead({24'h04, (8'h0<<2)}, RxBD);       // Read from TxBD register
//  WishboneRead({24'h04, (8'h1<<2)}, RxBD);       // Read from TxBD register
//  WishboneRead({24'h04, (8'h2<<2)}, RxBD);       // Read from TxBD register
//  WishboneRead({24'h04, (8'h3<<2)}, RxBD);       // Read from TxBD register
//  WishboneRead({24'h04, (8'h4<<2)}, RxBD);       // Read from TxBD register
 
  for(jj=0; jj<3; jj=jj+1)    // How many TxBD do we want to read?
  begin
 
      WishboneRead({22'h01, ((10'h0+jj[4:0]*2'h2)<<2)}, bd);       // Read from TxBD
      $display("\n(%0t)\t\tRead TxBD %0x = 0x%x", $time, jj, bd);
      if(~bd[15]) // Ready = 0?
        begin
          WishboneRead({22'h01, ((10'h0+jj[4:0]*2'h2+1'h1)<<2)}, pointer);  // Read TxBD pointer
          $display("\t\t\tRead TxBDPointer 0x=%x", pointer);
          $write("\t\t\tData:");
          for(ii=0; ii<bd[31:16]; ii=ii+4)
            begin
              WishboneReadData({pointer[31:2], 2'h0}+ii, data_in);        // Read data from Tx Pointer
              $write("\t0x%x", data_in);
            end
        end
  end
 
 
  for(jj=0; jj<3; jj=jj+1)    // How many RxBD do we want to read?
  begin
 
      WishboneRead({22'h01, ((10'h80+jj[4:0]*2'h2)<<2)}, bd);       // Read from RxBD
      $display("\n(%0t)\t\tRead RxBD %0x = 0x%x", $time, jj, bd);
      if(~bd[15]) // Empty = 0?
        begin
          WishboneRead({22'h01, ((10'h80+jj[4:0]*2'h2+1'h1)<<2)}, pointer);  // Read RxBD pointer
          $display("\t\t\tRead RxBDPointer 0x=%x", pointer);
          $write("\t\t\tData:");
          for(ii=0; ii<bd[31:16]+4; ii=ii+4)
            begin
              WishboneReadData({pointer[31:2], 2'h0} + ii, data_in);        // Read data from Rx Pointer
              $write("\t0x%x", data_in);
            end
        end
  end
 
  WishboneRead({22'h01, (10'h81<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h82<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h83<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h84<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h85<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h86<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h87<<2)}, data_in);       // Read from RxBD register
 
 
 
  #100000 $stop;
 end
endtask //TestTxAndRx
 
 
 
 
 
task TestFullDuplex;
 
 integer ii, jj;
 integer data_in, bd, pointer;
 integer addr;
 
 begin
  WishboneWrite(32'h00000800, {26'h0, `ETH_MODER_ADR<<2});     // r_Rst = 1
  WishboneWrite(32'h00000000, {26'h0, `ETH_MODER_ADR<<2});     // r_Rst = 0
  WishboneWrite(32'h00000080, {26'h0, `ETH_TX_BD_NUM_ADR<<2}); // r_RxBDAddress = 0x80
 
  WishboneWrite(32'h0000a40b, {26'h0, `ETH_MODER_ADR<<2});     // CrcEn, Pad en, full duplex, reject broadcast, RxEn, TxEn
 
  WishboneWrite(32'h00000002, {26'h0, `ETH_MAC_ADDR1_ADR<<2}); // MAC = 000203040506
  WishboneWrite(32'h03040506, {26'h0, `ETH_MAC_ADDR0_ADR<<2});
 
  initialize_txbd(5);
  initialize_rxbd(6);
 
  send_packet(48'h000123456789, 16'h0064);
 
 
  /*
  for(ii=0; ii<12; ii=ii+1) begin
    addr = 32'h400 + ii*4;
    WishboneRead(addr, data_in);
    $display("\n(%0t)\t\tRead TxBD %0x = 0x%x", $time, ii, data_in);
  end
 
  for(ii=0; ii<14; ii=ii+1) begin
    addr = 32'h600 + ii*4;
    WishboneRead(addr, data_in);
    $display("\n(%0t)\t\tRead RxBD %0x = 0x%x", $time, ii, data_in);
  end
  */
 
//  WishboneRead({22'h01, 10'b0}, data_in);  // read back
//  WishboneRead({22'h01, ((10'h0+jj[4:0]*2'h2)<<2)}, bd);       // Read from TxBD
 
/*
  for(jj=0; jj<8; jj=jj+4)
    WishboneWriteData(`TX_BUF_BASE + jj, 32'h11111111, 4'hf); // Initializing data to ff
 
  for(jj=0; jj<8; jj=jj+4)
    WishboneWriteData(`RX_BUF_BASE + jj, 32'h11111111, 4'hf); // Initializing data to ff
 
 
fork
  begin
  SendPacketX(16'h0064, 1'b0, 2'h1);
  SendPacketX(16'h0065, 1'b0, 2'h2);
  SendPacketX(16'h0066, 1'b0, 2'h3);
  SendPacketX(16'h0067, 1'b0, 2'h0);
  end
 
  begin
    ReceivePacketX(16'h0040, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
    ReceivePacketX(16'h0041, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
    ReceivePacketX(16'h0042, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
    ReceivePacketX(16'h0043, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
    ReceivePacketX(16'h0044, 1'b0, `UNICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  end
*/
 
//fork
/*
  begin
    repeat(4)
      begin
        wait(tb_eth_top.ethtop.wishbone.TxStatusWrite);   // wait until tx status is written
        @ (posedge WB_CLK_I)
        #1;
      end
  end
*/
 
/*
  begin
    wait(tb_eth_top.ethtop.wishbone.RxStatusWrite);   // wait until rx status is written
  end
 
join
*/
 
/*
  SendPacket(16'h0013, 1'b0);
  SendPacket(16'h0014, 1'b0);
 
  SendPacket(16'h0030, 1'b0);
  SendPacket(16'h0031, 1'b0);
  SendPacket(16'h0032, 1'b0);
  SendPacket(16'h0033, 1'b0);
  SendPacket(16'h0025, 1'b0);
  SendPacket(16'h0045, 1'b0);
  SendPacket(16'h0025, 1'b0);
  SendPacket(16'h0017, 1'b0);
*/
 
//  ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h3);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h2);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h1);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h0);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
 
//  ReceivePacket(16'h0050, 1'b0, `MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0051, 1'b0, `UNICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0052, 1'b0, `MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0053, 1'b0, `BROADCAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0054, 1'b0, `UNICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0055, 1'b0, `MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
//  ReceivePacket(16'h0056, 1'b0, `UNICAST_WRONG_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
 
 
  repeat(1000) @ (posedge MRxClk);        // Waiting some time for all accesses to finish before reading out the statuses.
 
//  WishboneRead({24'h04, (8'h0<<2)}, RxBD);       // Read from TxBD register
//  WishboneRead({24'h04, (8'h1<<2)}, RxBD);       // Read from TxBD register
//  WishboneRead({24'h04, (8'h2<<2)}, RxBD);       // Read from TxBD register
//  WishboneRead({24'h04, (8'h3<<2)}, RxBD);       // Read from TxBD register
//  WishboneRead({24'h04, (8'h4<<2)}, RxBD);       // Read from TxBD register
 
/*
  for(jj=0; jj<3; jj=jj+1)    // How many TxBD do we want to read?
  begin
 
      WishboneRead({22'h01, ((10'h0+jj[4:0]*2'h2)<<2)}, bd);       // Read from TxBD
      $display("\n(%0t)\t\tRead TxBD %0x = 0x%x", $time, jj, bd);
      if(~bd[15]) // Ready = 0?
        begin
          WishboneRead({22'h01, ((10'h0+jj[4:0]*2'h2+1'h1)<<2)}, pointer);  // Read TxBD pointer
          $display("\t\t\tRead TxBDPointer 0x=%x", pointer);
          $write("\t\t\tData:");
          for(ii=0; ii<bd[31:16]; ii=ii+4)
            begin
              WishboneReadData({pointer[31:2], 2'h0}+ii, data_in);        // Read data from Tx Pointer
              $write("\t0x%x", data_in);
            end
        end
  end
 
 
  for(jj=0; jj<3; jj=jj+1)    // How many RxBD do we want to read?
  begin
 
      WishboneRead({22'h01, ((10'h80+jj[4:0]*2'h2)<<2)}, bd);       // Read from RxBD
      $display("\n(%0t)\t\tRead RxBD %0x = 0x%x", $time, jj, bd);
      if(~bd[15]) // Empty = 0?
        begin
          WishboneRead({22'h01, ((10'h80+jj[4:0]*2'h2+1'h1)<<2)}, pointer);  // Read RxBD pointer
          $display("\t\t\tRead RxBDPointer 0x=%x", pointer);
          $write("\t\t\tData:");
          for(ii=0; ii<bd[31:16]+4; ii=ii+4)
            begin
              WishboneReadData({pointer[31:2], 2'h0} + ii, data_in);        // Read data from Rx Pointer
              $write("\t0x%x", data_in);
            end
        end
  end
 
  WishboneRead({22'h01, (10'h81<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h82<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h83<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h84<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h85<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h86<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h87<<2)}, data_in);       // Read from RxBD register
*/
 
 
  #100000 $stop;
 end
endtask //TestFullDuplex
 
 
 
task initialize_txbd;
  input [6:0] txbd_num;
 
  integer i, j;
  integer bd_status_addr, buf_addr, bd_ptr_addr;
 
  for(i=0; i<txbd_num; i=i+1) begin
    buf_addr = `TX_BUF_BASE + i * 32'h600;
    bd_status_addr = `TX_BD_BASE + i * 8;
    bd_ptr_addr = bd_status_addr + 4;
 
    // Initializing BD - status
    if(i==txbd_num-1)
      WishboneWrite(32'h00007800, bd_status_addr);  // last BD: + WRAP
    else
      WishboneWrite(32'h00005800, bd_status_addr);  // IRQ + PAD + CRC
 
    WishboneWrite(buf_addr, bd_ptr_addr);   // Initializing BD - pointer
  end
endtask // initialize_txbd
 
 
task initialize_rxbd;
  input [6:0] rxbd_num;
 
  integer i, j;
  integer bd_status_addr, buf_addr, bd_ptr_addr;
 
  for(i=0; i<rxbd_num; i=i+1) begin
    buf_addr = `RX_BUF_BASE + i * 32'h600;
    bd_status_addr = `RX_BD_BASE + i * 8;
    bd_ptr_addr = bd_status_addr + 4;
 
    // Initializing BD - status
    if(i==rxbd_num-1)
      WishboneWrite(32'h0000e000, bd_status_addr);  // last BD: + WRAP
    else
      WishboneWrite(32'h0000c000, bd_status_addr);  // IRQ + PAD + CRC
 
    WishboneWrite(buf_addr, bd_ptr_addr);   // Initializing BD - pointer
  end
endtask // initialize_rxbd
 
 
 
 
 
 
reg [7:0] LateCollisionCounter;
reg EnableCollisionCounter;
// Making a late collision
 
initial
EnableCollisionCounter =0;  // Collision = OFF
 
always @ (posedge MTxClk)
begin
  if(tb_eth_top.ethtop.wishbone.TxStartFrm)
    begin
      LateCollisionCounter = 0;
    end
  else
  if(EnableCollisionCounter)
    LateCollisionCounter = LateCollisionCounter + 1;
end
 
// Making a late collision
always @ (posedge MTxClk)
begin
  if(LateCollisionCounter==0)
    MColl = 0;
  else
  if(LateCollisionCounter==150)
    MColl = 1;
  else
  if(LateCollisionCounter==155)
    begin
      MColl = 0;
      MCrs = 0;
      EnableCollisionCounter=0;
      LateCollisionCounter=1;
    end
end
 
 
// Switching Carrier Sense ON and OFF
always @ (posedge MTxClk)
begin
  wait(tb_eth_top.ethtop.wishbone.TxStartFrm);
  MCrs=1;
  wait(tb_eth_top.ethtop.wishbone.TxEndFrm || !MCrs);
  MCrs=0;
end
 
 
task TestUnicast;
 
 integer ii, jj;
 integer data_in, bd, pointer;
 
 begin
  $display("\nBegin TestUnicast \n");
  WishboneWrite(32'h00000800, {26'h0, `ETH_MODER_ADR, 2'h0});     // r_Rst = 1
  WishboneWrite(32'h00000000, {26'h0, `ETH_MODER_ADR, 2'h0});     // r_Rst = 0
  WishboneWrite(32'h00000080, {26'h0, `ETH_TX_BD_NUM_ADR, 2'h0}); // r_RxBDAddress = 0x80
  WishboneWrite(32'h0000204b, {26'h0, `ETH_MODER_ADR, 2'h0});     // RxEn, Txen, CrcEn, no Pad, r_IFG, promisc off, broadcast off
  WishboneWrite(32'h00000004, {26'h0, `ETH_CTRLMODER_ADR, 2'h0}); // r_TxFlow = 1
 
  $display("\n This Uniicast packet will be rejected, wrong address in MAC Address Regs\n");
 
  ReceivePacket(16'h0014, 1'b0,`UNICAST_XFR);
 
  WishboneWrite(32'h03040506, {26'h0,`ETH_MAC_ADDR0_ADR ,2'h0}); // Mac Address 
  WishboneWrite(32'h00000002, {26'h0,`ETH_MAC_ADDR1_ADR ,2'h0}); // Mac Address
 
  $display("\n Set Proper Unicast Address in MAC_ADDRESS regs, resend packet\n");
 
  ReceivePacket(16'h0015, 1'b0,`UNICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  ReceivePacket(16'h0016, 1'b0,`MULTICAST_XFR);  // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  ReceivePacket(16'h0017, 1'b0,`UNICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  ReceivePacket(16'h0018, 1'b0,`BROADCAST_XFR);  // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  ReceivePacket(16'h0019, 1'b0,`UNICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
 
  repeat(5000) @ (posedge MRxClk);        // Waiting some time for all accesses to finish before reading out the statuses.
 
  WishboneRead({26'h0, `ETH_MODER_ADR}, data_in);   // Read from MODER register
 
  WishboneRead({22'h01, (10'h80<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h81<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h82<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h83<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h84<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h85<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h86<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h87<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h88<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h89<<2)}, data_in);       // Read from RxBD register
 
 
  for(jj=0; jj<5; jj=jj+1)    // How many RxBD do we want to read?
  begin
 
      WishboneRead({22'h01, ((10'h80+jj[4:0]*2'h2)<<2)}, bd);       // Read from RxBD
      $display("\n(%0t)\t\tRead RxBD %0x = 0x%x", $time, jj, bd);
      if(~bd[15]) // Empty = 0?
        begin
          WishboneRead({22'h01, ((10'h80+jj[4:0]*2'h2+1'h1)<<2)}, pointer);  // Read RxBD pointer
          $display("\t\t\tRead RxBDPointer 0x=%x", pointer);
          $write("\t\t\tData:");
          for(ii=0; ii<bd[31:16]+4; ii=ii+4)
            begin
              WishboneReadData({pointer[31:2], 2'h0} + ii, data_in);        // Read data from Rx Pointer
              $write("\t0x%x", data_in);
            end
        end
  end
 
 
 
  #100000 $stop;
  $display("\nEnd TestUnicast \n");
end
endtask //TestUnicast
 
task TestMulticast;
 
  integer data_in;
 
 begin
  $display("\nBegin TestMulticast \n");
  WishboneWrite(32'h00000800, {26'h0, `ETH_MODER_ADR, 2'h0});     // r_Rst = 1
  WishboneWrite(32'h00000000, {26'h0, `ETH_MODER_ADR, 2'h0});     // r_Rst = 0
  WishboneWrite(32'h00000080, {26'h0, `ETH_TX_BD_NUM_ADR, 2'h0}); // r_RxBDAddress = 0x80
  WishboneWrite(32'h00002043, {26'h0, `ETH_MODER_ADR, 2'h0});     // RxEn, Txen, CrcEn, No Pad, r_IFG, promiscuos off, broadcast enable
  WishboneWrite(32'h00000004, {26'h0, `ETH_CTRLMODER_ADR, 2'h0}); // r_TxFlow = 1
 
  $display("\n This Multicast packet will be rejected by Hash Filter\n");
 
  ReceivePacket(16'h0014, 1'b0,`MULTICAST_XFR);
 
  WishboneWrite(32'h00400000, {26'h0, `ETH_HASH1_ADR,2'h0}); // set bit 16, multicast hash 36
  WishboneRead({26'h0, `ETH_HASH1_ADR, 2'h0}, data_in);  // read back
 
  $display("\n Set Hash Filter to accept this Multicast packet, resend packet\n");
 
  ReceivePacket(16'h0015, 1'b0,`MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  ReceivePacket(16'h0016, 1'b0,`MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  ReceivePacket(16'h0017, 1'b0,`MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  ReceivePacket(16'h0018, 1'b0,`MULTICAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
 
  repeat(5000) @ (posedge MRxClk);        // Waiting some time for all accesses to finish before reading out the statuses.
 
  WishboneRead({26'h0, `ETH_MODER_ADR}, data_in);   // Read from MODER register
 
  WishboneRead({22'h01, (10'h80<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h81<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h82<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h83<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h84<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h85<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h86<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h87<<2)}, data_in);       // Read from RxBD register
 
  $display("\nEnd TestMulticast \n");
  #100000 $stop;
end
endtask //TestMulticast
 
 
task TestBroadcast;
 
  integer data_in;
 
 begin
  $display("\n\n\nBegin TestBroadcast");
  WishboneWrite(32'h00000800, {26'h0, `ETH_MODER_ADR, 2'h0});     // r_Rst = 1
  WishboneWrite(32'h00000000, {26'h0, `ETH_MODER_ADR, 2'h0});     // r_Rst = 0
  WishboneWrite(32'h00000080, {26'h0, `ETH_TX_BD_NUM_ADR, 2'h0}); // r_RxBDAddress = 0x80
 
  WishboneWrite(32'h0000A04b, {26'h0, `ETH_MODER_ADR, 2'h0});     // PadEn, CrcEn, IFG=accept, Reject Broadcast, TxEn, RxEn
  WishboneWrite(32'h00000004, {26'h0, `ETH_CTRLMODER_ADR, 2'h0}); // r_TxFlow = 1
 
  $display("\nThis Broadcast packet will be rejected, r_BRO = 1");
  ReceivePacket(16'h0014, 1'b0,`BROADCAST_XFR);
 
  $display("\nSet r_Bro = 0, resend packet");
  WishboneWrite(32'h0000A043, {26'h0, `ETH_MODER_ADR, 2'h0});  // PadEn, CrcEn, IFG=accept, Accept Broadcast, TxEn, RxEn
  ReceivePacket(16'h0015, 1'b0,`BROADCAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
 
  $display("\n This Broadcast packet will be rejected, r_BRO = 1");
  WishboneWrite(32'h0000A04b, {26'h0, `ETH_MODER_ADR, 2'h0});     // PadEn, CrcEn, IFG=accept, Reject Broadcast, TxEn, RxEn
  ReceivePacket(16'h0016, 1'b0,`BROADCAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  ReceivePacket(16'h0017, 1'b0,`BROADCAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
 
  $display("\n Set r_Bro = 0, resend packet");
  WishboneWrite(32'h0000A043, {26'h0, `ETH_MODER_ADR, 2'h0});  // PadEn, CrcEn, IFG=accept, Accept Broadcast, TxEn, RxEn
  ReceivePacket(16'h0018, 1'b0,`BROADCAST_XFR);    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
 
  repeat(5000) @ (posedge MRxClk);        // Waiting some time for all accesses to finish before reading out the statuses.
 
  WishboneRead({26'h0, `ETH_MODER_ADR}, data_in);   // Read from MODER register
 
  WishboneRead({22'h01, (10'h80<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h81<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h82<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h83<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h84<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h85<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h86<<2)}, data_in);       // Read from RxBD register
  WishboneRead({22'h01, (10'h87<<2)}, data_in);       // Read from RxBD register
 
  #100000 $stop;
  $display("\nEnd TestBroadcast \n");
end
endtask //TestBroadcast
 
 
always @ (posedge WB_CLK_I)
begin
  if(m_wb_cyc_o & m_wb_stb_o) // Add valid address range
    begin
      repeat(2) @ (posedge WB_CLK_I);
        begin
          m_wb_ack_i <=#Tp 1'b1;
          if(~m_wb_we_o)
            begin
              #Tp;
              if(m_wb_adr_o[1:0] == 2'b00)       // word access
                begin
                  m_wb_dat_i[31:24] = memory3[{m_wb_adr_o[31:2], 2'h0}];
                  m_wb_dat_i[23:16] = memory2[{m_wb_adr_o[31:2], 2'h0}];
                  m_wb_dat_i[15:08] = memory1[{m_wb_adr_o[31:2], 2'h0}];
                  m_wb_dat_i[07:00] = memory0[{m_wb_adr_o[31:2], 2'h0}];
                end
              else if(m_wb_adr_o[1:0] == 2'b10)       // half access
                begin
                  m_wb_dat_i[31:24] = 0;
                  m_wb_dat_i[23:16] = 0;
                  m_wb_dat_i[15:08] = memory1[{m_wb_adr_o[31:2], 2'h0}];
                  m_wb_dat_i[07:00] = memory0[{m_wb_adr_o[31:2], 2'h0}];
                end
              else if(m_wb_adr_o[1:0] == 2'b01)       // byte access
                begin
                  m_wb_dat_i[31:24] = 0;
                  m_wb_dat_i[23:16] = memory2[{m_wb_adr_o[31:2], 2'h0}];
                  m_wb_dat_i[15:08] = 0;
                  m_wb_dat_i[07:00] = 0;
                end
              else if(m_wb_adr_o[1:0] == 2'b11)       // byte access
                begin
                  m_wb_dat_i[31:24] = 0;
                  m_wb_dat_i[23:16] = 0;
                  m_wb_dat_i[15:08] = 0;
                  m_wb_dat_i[07:00] = memory0[{m_wb_adr_o[31:2], 2'h0}];
                end
 
              $fdisplay(mcd1, "(%0t) master read (0x%0x) = 0x%0x", $time, m_wb_adr_o, m_wb_dat_i);
            end
          else
            begin
              $fdisplay(mcd2, "(%0t) master write (0x%0x) = 0x%0x", $time, m_wb_adr_o, m_wb_dat_o);
              if(m_wb_sel_o[0])
                memory0[m_wb_adr_o] = m_wb_dat_o[7:0];
              if(m_wb_sel_o[1])
                memory1[m_wb_adr_o] = m_wb_dat_o[15:8];
              if(m_wb_sel_o[2])
                memory2[m_wb_adr_o] = m_wb_dat_o[23:16];
              if(m_wb_sel_o[3])
                memory3[m_wb_adr_o] = m_wb_dat_o[31:24];
            end
        end
      @ (posedge WB_CLK_I);
      m_wb_ack_i <=#Tp 1'b0;
    end
end
 
 
 
// Detecting ram_oe and ram_we being active at the same time
always @ (posedge WB_CLK_I)
begin
  if(tb_eth_top.ethtop.wishbone.ram_we & tb_eth_top.ethtop.wishbone.ram_oe)
    begin
      $display("\n\n(%0t)ERROR: ram_we and ram_oe both activated at the same time", $time);
      #1000;
      $stop;
    end
end
 
 
 
 
always @ (posedge WB_CLK_I)
  if(tb_eth_top.ethtop.wishbone.RxStatusWrite)
    $fdisplay(mcd2, "");  // newline added
 
task WishboneWrite;
  input [31:0] Data;
  input [31:0] Address;
  integer ii;
 
  begin
    wait (~WishboneBusy);
    WishboneBusy = 1;
    @ (posedge WB_CLK_I);
    #1;
    WB_ADR_I = Address;
    WB_DAT_I = Data;
    WB_WE_I  = 1'b1;
    WB_CYC_I = 1'b1;
    WB_STB_I = 1'b1;
    WB_SEL_I = 4'hf;
 
 
    wait(WB_ACK_O);   // waiting for acknowledge response
 
    // Writing information about the access to the screen
    @ (posedge WB_CLK_I);
    if(LogEnable)
    begin
      if(~Address[11] & ~Address[10])
        $write("\n(%0t) Write to register (Data: 0x%x, Reg. Addr: 0x%0x)", $time, Data, Address);
      else
      if(~Address[11] & Address[10])
        if(Address[9:2] < tb_eth_top.ethtop.r_TxBDNum)
          begin
            $write("\n(%0t) Write to TxBD (Data: 0x%x, TxBD Addr: 0x%0x)", $time, Data, Address);
            if(Address[9:2] == tb_eth_top.ethtop.r_TxBDNum-2'h2)
              $write("(%0t) Send Control packet\n", $time);
          end
        else
          $write("\n(%0t) Write to RxBD (Data: 0x%x, RxBD Addr: 0x%0x)", $time, Data, Address);
      else
        $write("\n(%0t) WB write ??????????????     Data: 0x%x      Addr: 0x%0x", $time, Data, Address);
    end
 
    #1;
    WB_ADR_I = 32'hx;
    WB_DAT_I = 32'hx;
    WB_WE_I  = 1'bx;
    WB_CYC_I = 1'b0;
    WB_STB_I = 1'b0;
    WB_SEL_I = 4'hx;
    #5 WishboneBusy = 0;
  end
endtask
 
 
task WishboneRead;
  input [31:0] Address;
  output[31:0] data;
 
  begin
    wait (~WishboneBusy);
    WishboneBusy = 1;
    @ (posedge WB_CLK_I);
    #1;
    WB_ADR_I = Address;
    WB_WE_I  = 1'b0;
    WB_CYC_I = 1'b1;
    WB_STB_I = 1'b1;
    WB_SEL_I = 4'hf;
    #3;
    wait(WB_ACK_O);   // waiting for acknowledge response
    @ (posedge WB_CLK_I);
      data = WB_DAT_O;
      if(~Address[11] & ~Address[10])
//        $write("\n(%0t) Read from register (Data: 0x%x, Reg. Addr: 0x%0x)", $time, WB_DAT_O, Address);
        $write("\n(%0t) Read from register (Data: 0x%x, Reg. Addr: 0x%0x)", $time, data, Address);
      else
      if(~Address[11] & Address[10])
        if(Address[9:2] < tb_eth_top.ethtop.r_TxBDNum)
//          ; //$write("\n(%0t) Read from TxBD (Data: 0x%x, TxBD Addr: 0x%0x)", $time, WB_DAT_O, Address);
          ; //$write("\n(%0t) Read from TxBD (Data: 0x%x, TxBD Addr: 0x%0x)", $time, data, Address);
        else
//          ;//$write("\n(%0t) Read from RxBD (Data: 0x%x, RxBD Addr: 0x%0x)", $time, WB_DAT_O, Address);
          ;//$write("\n(%0t) Read from RxBD (Data: 0x%x, RxBD Addr: 0x%0x)", $time, data, Address);
      else
//        $write("\n(%0t) WB read  ?????????    Data: 0x%x      Addr: 0x%0x", $time, WB_DAT_O, Address);
        $write("\n(%0t) WB read  ?????????    Data: 0x%x      Addr: 0x%0x", $time, data, Address);
    #1;
    WB_ADR_I = 32'hx;
    WB_WE_I  = 1'bx;
    WB_CYC_I = 1'b0;
    WB_STB_I = 1'b0;
    WB_SEL_I = 4'hx;
    #5 WishboneBusy = 0;
  end
endtask
 
 
 
task WishboneReadData;
  input [31:0] Address;
  output[31:0] data;
 
  begin
    @ (posedge WB_CLK_I);
    data = {memory3[Address], memory2[Address], memory1[Address], memory0[Address]};
    #5;
  end
endtask
 
 
task WishboneWriteData;
  input [31:0] Address;
  input [31:0] data;
  input [3:0]  Select;
 
  begin
    @ (posedge WB_CLK_I);
    if(Select[0])
      memory0[Address] = data[7:0];
    if(Select[1])
      memory1[Address] = data[15:8];
    if(Select[2])
      memory2[Address] = data[23:16];
    if(Select[3])
      memory3[Address] = data[31:24];
//    $display("\n(%0t) Write data to memory (Data: 0x%x, Addr: 0x%0x)", $time, data, Address);
    #5;
  end
endtask
 
 
 
 
task SendPacket;
  input [15:0]  Length;
  input         ControlFrame;
  reg           Wrap;
  reg [31:0]    TempAddr;
  reg [31:0]    TempData;
  reg [31:0]    kk;
 
  begin
//    if(TxBDIndex == 6)    // Only 3 buffer descriptors are used 
//      Wrap = 1'b1;
//    else
      Wrap = 1'b0;    // At the moment no wrap bit is set
 
 
    // Writing data to buffer
    for(kk=0; kk<Length; kk=kk+4)
    begin
      TempAddr = `TX_BUF_BASE + TxBDIndex * 32'h600 + kk;
      TempData = {kk[7:0], kk[7:0]+2'h1, kk[7:0]+2'h2, kk[7:0]+2'h3};
      WishboneWriteData(TempAddr, TempData, 4'hf); // Writing Data to buffer that is pointed by the BD
    end
 
 
    // Writing buffer pointer
    TempAddr = {22'h01, ((TxBDIndex*2'h2 + 1'b1)<<2)};
    TempData = `TX_BUF_BASE + TxBDIndex * 32'h600; // 1536 bytes is reserved for one frame
    WishboneWrite(TempData, TempAddr); // Writing Tx pointer
 
    TempAddr = {22'h01, ((TxBDIndex*2'h2)<<2)};
    TempData = {Length[15:0], 1'b1, 1'b0, Wrap, 3'h0, ControlFrame, 1'b0, TxBDIndex[7:0]};  // Ready and Wrap = 1
 
    #1;
//    if(TxBDIndex == 6)    // Only 4 buffer descriptors are used
//      TxBDIndex = 0;
//    else
      TxBDIndex = TxBDIndex + 1;
 
    WishboneWrite(TempData, TempAddr); // Writing status to TxBD
  end
endtask
 
 
 
task SendPacketX;
  input [15:0]  Length;
  input         ControlFrame;
  input  [1:0]  AddrOffset;
  reg           Wrap;
  reg [31:0]    TempAddr;
  reg [31:0]    TempData;
  reg [31:0]    kk;
  reg  [3:0]    Select;
 
  begin
    Wrap = 1'b0;
 
    case(AddrOffset)
      2'h0 : Select = 4'hf;
      2'h1 : Select = 4'h7;
      2'h2 : Select = 4'h3;
      2'h3 : Select = 4'h1;
    endcase
 
    // Writing data to buffer
    for(kk=0; kk<Length+4; kk=kk+4)   // Length+4 is because we might start up to 3 bytes later
    begin
      if(kk>0)
        Select = 4'hf;
      TempAddr = `TX_BUF_BASE + TxBDIndex * 32'h600 + kk;
      TempData = {kk[7:0]+3'h1, kk[7:0]+3'h2, kk[7:0]+3'h3, kk[7:0]+3'h4};
      WishboneWriteData(TempAddr, TempData, Select); // Writing Data to buffer that is pointed by the BD
    end
 
 
    // Writing buffer pointer
    TempAddr = {22'h01, ((TxBDIndex*2'h2 + 1'b1)<<2)};
    TempData = `TX_BUF_BASE + TxBDIndex * 32'h600 + AddrOffset; // 1536 bytes is reserved for one frame
    WishboneWrite(TempData, TempAddr); // Writing Tx pointer
 
    TempAddr = {22'h01, ((TxBDIndex*2'h2)<<2)};
    TempData = {Length[15:0], 1'b1, 1'b1, Wrap, 3'h0, ControlFrame, 1'b0, TxBDIndex[7:0]};  // Ready, interrupt and Wrap = 1
 
    #1;
    if(Wrap)
      TxBDIndex = 0;
    else
      TxBDIndex = TxBDIndex + 1;
 
    WishboneWrite(TempData, TempAddr); // Writing status to TxBD
  end
endtask
 
 
task send_packet;
  input [47:0] dest_addr;
  input [15:0] length;
 
  reg [31:0] BD, ptr;
  reg [31:0] i;
  reg [2:0]  increment;
 
  reg [31:0]    TempAddr;
  reg [31:0]    TempData;
  reg [15:0]    kk;
  reg  [3:0]    Select;
 
  begin
    bd_status_addr = `TX_BD_BASE + g_last_txbd * 8;
 
    mama
    WishboneRead(bd_status_addr, BD);           // Read BD
    WishboneRead(bd_status_addr+4, ptr);        // Read buffer pointer
 
    case(ptr[1:0])
      2'h0 : begin Select = 4'hf; increment = 3'h4 end
      2'h1 : begin Select = 4'h7; increment = 3'h3 end
      2'h2 : begin Select = 4'h3; increment = 3'h2 end
      2'h3 : begin Select = 4'h1; increment = 3'h1 end
    endcase
 
    // Writing data to buffer
    for(i=ptr; i<(length+ptr); i=i+increment)   // (i=0; i<length; i=i+increment)
    begin
      if(i>ptr)   // After first write all accesses are word accesses
        begin Select = 4'hf; increment=3'h4; end
 
      TempAddr = `TX_BUF_BASE + TxBDIndex * 32'h600 + kk;
      TempData = {i[7:0]+3'h1, i[7:0]+3'h2, i[7:0]+3'h3, i[7:0]+3'h4};
mama
      WishboneWriteData(TempAddr, TempData, Select); // Writing Data to buffer that is pointed by the BD
    end
 
 
    // Writing buffer pointer
    TempAddr = {22'h01, ((TxBDIndex*2'h2 + 1'b1)<<2)};
    TempData = `TX_BUF_BASE + TxBDIndex * 32'h600 + AddrOffset; // 1536 bytes is reserved for one frame
    WishboneWrite(TempData, TempAddr); // Writing Tx pointer
 
    TempAddr = {22'h01, ((TxBDIndex*2'h2)<<2)};
    TempData = {length[15:0], 1'b1, 1'b1, Wrap, 3'h0, ControlFrame, 1'b0, TxBDIndex[7:0]};  // Ready, interrupt and Wrap = 1
 
    #1;
    if(Wrap)
      TxBDIndex = 0;
    else
      TxBDIndex = TxBDIndex + 1;
 
    WishboneWrite(TempData, TempAddr); // Writing status to TxBD
 
    if(BD & 32'h2000)     // Wrap bit set ?
      g_last_txbd = 0;
    else
      g_last_txbd = g_last_txbd+1;
 
  end
endtask // send_packet
 
 
task ReceivePacket;    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  input [15:0] LengthRx;
  input        RxControlFrame;
  input [31:0] TransferType;  //Broadcast,Unicast,Multicast
  reg        WrapRx;
  reg [31:0] TempRxAddr;
//  reg [31:0] TempRxData;
  integer TempRxData;
  reg abc;
  begin
//    if(RxBDIndex == 6)    // Only 3 buffer descriptors are used
//      WrapRx = 1'b1;
//    else
      WrapRx = 1'b0;
 
    TempRxAddr = {22'h01, ((tb_eth_top.ethtop.r_TxBDNum + RxBDIndex*2'h2 + 1'b1)<<2)};
    TempRxData = `RX_BUF_BASE + RxBDIndex * 32'h600; // 1536 bytes is reserved for one frame
    WishboneWrite(TempRxData, TempRxAddr); // Writing Rx pointer
 
    TempRxAddr = {22'h01, ((tb_eth_top.ethtop.r_TxBDNum + RxBDIndex*2'h2)<<2)};
    TempRxData = {16'h0, 1'b1, 1'b0, WrapRx, 5'h0, RxBDIndex[7:0]};  // Ready and WrapRx = 1 or 0
 
    #1;
//    if(RxBDIndex == 6)    // Only 4 buffer descriptors are used
//      RxBDIndex = 0;
//    else
      RxBDIndex = RxBDIndex + 1;
 
    abc=1;
    WishboneWrite(TempRxData, TempRxAddr); // Writing status to RxBD
    abc=0;
 
      begin
        #200;
        if(RxControlFrame)
          GetControlDataOnMRxD(LengthRx); // LengthRx = PAUSE timer value.
        else
          GetDataOnMRxD(LengthRx, TransferType); // LengthRx bytes is comming on MRxD[3:0] signals
      end
 
  end
endtask
 
 
task ReceivePacketX;    // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
  input [15:0] LengthRx;
  input        RxControlFrame;
  input [31:0] TransferType;  //Broadcast,Unicast,Multicast
  input  [1:0]  AddrOffset;
  reg        WrapRx;
  reg [31:0] TempRxAddr;
  integer TempRxData;
  reg abc;
  begin
    WrapRx = 1'b0;
 
    TempRxAddr = {22'h01, ((tb_eth_top.ethtop.r_TxBDNum + RxBDIndex*2'h2 + 1'b1)<<2)};
    TempRxData = `RX_BUF_BASE + RxBDIndex * 32'h600 + AddrOffset; // 1536 bytes is reserved for one frame
    WishboneWrite(TempRxData, TempRxAddr); // Writing Rx pointer
 
    TempRxAddr = {22'h01, ((tb_eth_top.ethtop.r_TxBDNum + RxBDIndex*2'h2)<<2)};
    TempRxData = {16'h0, 1'b1, 1'b1, WrapRx, 5'h0, RxBDIndex[7:0]};  // Ready, interrupt and WrapRx = 1 or 0
 
    #1;
      RxBDIndex = RxBDIndex + 1;
 
    abc=1;
    WishboneWrite(TempRxData, TempRxAddr); // Writing status to RxBD
    abc=0;
 
      begin
        #200;
        if(RxControlFrame)
          GetControlDataOnMRxD(LengthRx); // LengthRx = PAUSE timer value.
        else
          GetDataOnMRxD(LengthRx, TransferType); // LengthRx bytes is comming on MRxD[3:0] signals
      end
 
  end
endtask
 
 
task GetDataOnMRxD;
  input [15:0] Len;
  input [31:0] TransferType;
  integer tt;
 
  begin
    @ (posedge MRxClk);
    MRxDV=1'b1;
 
    for(tt=0; tt<15; tt=tt+1)
    begin
      MRxD=4'h5;              // preamble
      @ (posedge MRxClk);
    end
    MRxD=4'hd;                // SFD
 
  for(tt=1; tt<(Len+1); tt=tt+1)
 
    begin
 
      @ (posedge MRxClk);
          if(TransferType == `UNICAST_XFR && tt == 1)
           MRxD= 4'h0;   // Unicast transfer
          else if(TransferType == `BROADCAST_XFR && tt < 7)
           MRxD = 4'hf;
          else
       MRxD=tt[3:0]; // Multicast transfer
 
    @ (posedge MRxClk);
 
           if(TransferType == `BROADCAST_XFR && tt < 7)
            MRxD = 4'hf;
          else
        MRxD=tt[7:4];
    end
 
    @ (posedge MRxClk);
    MRxDV=1'b0;
  end
endtask
 
 
task GetControlDataOnMRxD;
  input [15:0] Timer;
  reg [127:0] Packet;
  reg [127:0] Data;
  reg [31:0] Crc;
  integer tt;
 
  begin
  Packet = 128'h10082C000010_deadbeef0013_8880_0010; // 0180c2000001 + 8808 + 0001
  Crc = 32'h6014fe08; // not a correct value
 
    @ (posedge MRxClk);
    MRxDV=1'b1;
 
    for(tt=0; tt<15; tt=tt+1)
    begin
      MRxD=4'h5;              // preamble
      @ (posedge MRxClk);
    end
    MRxD=4'hd;                // SFD
 
    for(tt=0; tt<32; tt=tt+1)
    begin
      Data = Packet << (tt*4);
      @ (posedge MRxClk);
      MRxD=Data[127:124];
    end
 
    for(tt=0; tt<2; tt=tt+1)    // timer
    begin
      Data[15:0] = Timer << (tt*8);
      @ (posedge MRxClk);
      MRxD=Data[11:8];
      @ (posedge MRxClk);
      MRxD=Data[15:12];
    end
 
    for(tt=0; tt<42; tt=tt+1)   // padding
    begin
      Data[7:0] = 8'h0;
      @ (posedge MRxClk);
      MRxD=Data[3:0];
      @ (posedge MRxClk);
      MRxD=Data[3:0];
    end
 
    for(tt=0; tt<4; tt=tt+1)    // crc
    begin
      Data[31:0] = Crc << (tt*8);
      @ (posedge MRxClk);
      MRxD=Data[27:24];
      @ (posedge MRxClk);
      MRxD=Data[31:28];
    end
 
 
 
    @ (posedge MRxClk);
    MRxDV=1'b0;
  end
endtask
 
task InitializeMemory;
  reg [9:0] mem_addr;
 
  begin
    LogEnable = 1'b0;
    $display("\n\n(%0t) Initializing Memory...", $time);
    for(mem_addr=0; mem_addr<=10'h0ff; mem_addr=mem_addr+1'b1)
      WishboneWrite(32'h0, {22'h01, mem_addr<<2}); // Writing status to RxBD
    LogEnable = 1'b1;
  end
endtask
 
 
 
 
endmodule

Line No.	Rev	Author	Line
1	157	mohor
2
3
4
5
6
7
8
9			`Please use tb_ethernet.v for testbench. Testbench will soon be`
10			`updated.`
11
12
13
14
15
16
17
18
19
20
21
22
23
24	66	mohor	`//////////////////////////////////////////////////////////////////////`
25	15	mohor	`//// ////`
26			`//// tb_eth_top.v ////`
27			`//// ////`
28			`//// This file is part of the Ethernet IP core project ////`
29	346	olof	`//// http://www.opencores.org/project,ethmac ////`
30	15	mohor	`//// ////`
31			`//// Author(s): ////`
32			`//// - Igor Mohor (igorM@opencores.org) ////`
33			`//// ////`
34			`//// All additional information is avaliable in the Readme.txt ////`
35			`//// file. ////`
36			`//// ////`
37			`//////////////////////////////////////////////////////////////////////`
38			`//// ////`
39			`//// Copyright (C) 2001 Authors ////`
40			`//// ////`
41			`//// This source file may be used and distributed without ////`
42			`//// restriction provided that this copyright statement is not ////`
43			`//// removed from the file and that any derivative work contains ////`
44			`//// the original copyright notice and the associated disclaimer. ////`
45			`//// ////`
46			`//// This source file is free software; you can redistribute it ////`
47			`//// and/or modify it under the terms of the GNU Lesser General ////`
48			`//// Public License as published by the Free Software Foundation; ////`
49			`//// either version 2.1 of the License, or (at your option) any ////`
50			`//// later version. ////`
51			`//// ////`
52			`//// This source is distributed in the hope that it will be ////`
53			`//// useful, but WITHOUT ANY WARRANTY; without even the implied ////`
54			`//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////`
55			`//// PURPOSE. See the GNU Lesser General Public License for more ////`
56			`//// details. ////`
57			`//// ////`
58			`//// You should have received a copy of the GNU Lesser General ////`
59			`//// Public License along with this source; if not, download it ////`
60			`//// from http://www.opencores.org/lgpl.shtml ////`
61			`//// ////`
62			`//////////////////////////////////////////////////////////////////////`
63			`//`
64			`// CVS Revision History`
65			`//`
66			`// $Log: not supported by cvs2svn $`
67	157	mohor	`// Revision 1.13 2002/05/03 10:25:01 mohor`
68			`// Testbench supports unaligned accesses.`
69			`//`
70	108	mohor	`// Revision 1.12 2002/02/26 17:01:09 mohor`
71			`// Small fixes for external/internal DMA missmatches.`
72			`//`
73	80	mohor	`// Revision 1.11 2002/02/16 13:06:59 mohor`
74			`// EXTERNAL_DMA used instead of WISHBONE_DMA.`
75			`//`
76	67	mohor	`// Revision 1.10 2002/02/16 07:22:15 mohor`
77			`// Testbench fixed, code simplified, unused signals removed.`
78			`//`
79	66	mohor	`// Revision 1.9 2002/02/14 20:14:38 billditt`
80			`// Added separate tests for Multicast, Unicast, Broadcast`
81			`//`
82			`// Revision 1.8 2002/02/12 20:24:00 mohor`
83			`// HASH0 and HASH1 register read/write added.`
84			`//`
85	49	mohor	`// Revision 1.7 2002/02/06 14:11:35 mohor`
86			`// non-DMA host interface added. Select the right configutation in eth_defines.`
87			`//`
88	41	mohor	`// Revision 1.6 2001/12/08 12:36:00 mohor`
89			`// TX_BD_NUM register added instead of the RB_BD_ADDR.`
90			`//`
91	36	mohor	`// Revision 1.5 2001/10/19 11:24:04 mohor`
92			`// Number of addresses (wb_adr_i) minimized.`
93			`//`
94	23	mohor	`// Revision 1.4 2001/10/19 08:46:53 mohor`
95			`// eth_timescale.v changed to timescale.v This is done because of the`
96			`// simulation of the few cores in a one joined project.`
97			`//`
98	22	mohor	`// Revision 1.3 2001/09/24 14:55:49 mohor`
99			`// Defines changed (All precede with ETH_). Small changes because some`
100			`// tools generate warnings when two operands are together. Synchronization`
101			`// between two clocks domains in eth_wishbonedma.v is changed (due to ASIC`
102			`// demands).`
103			`//`
104	19	mohor	`// Revision 1.2 2001/08/15 14:04:30 mohor`
105			`// Signal names changed on the top level for easier pad insertion (ASIC).`
106			`//`
107	17	mohor	`// Revision 1.1 2001/08/06 14:41:09 mohor`
108			`// A define FPGA added to select between Artisan RAM (for ASIC) and Block Ram (For Virtex).`
109			`// Include files fixed to contain no path.`
110			`// File names and module names changed ta have a eth_ prologue in the name.`
111			`// File eth_timescale.v is used to define timescale`
112			`// All pin names on the top module are changed to contain _I, _O or _OE at the end.`
113			`// Bidirectional signal MDIO is changed to three signals (Mdc_O, Mdi_I, Mdo_O`
114			`// and Mdo_OE. The bidirectional signal must be created on the top level. This`
115			`// is done due to the ASIC tools.`
116			`//`
117	15	mohor	`// Revision 1.1 2001/07/30 21:46:09 mohor`
118			`// Directory structure changed. Files checked and joind together.`
119			`//`
120			`//`
121			`//`
122			`//`
123			`//`
124
125
126
127	108	mohor	`include "tb_eth_defines.v"
128	356	olof	`include "ethmac_defines.v"
129	22	mohor	`include "timescale.v"
130	15	mohor
131			`module tb_eth_top();`
132
133
134			`parameter Tp = 1;`
135
136
137			`reg WB_CLK_I;`
138			`reg WB_RST_I;`
139			`reg [31:0] WB_DAT_I;`
140
141			`reg [31:0] WB_ADR_I;`
142			`reg [3:0] WB_SEL_I;`
143			`reg WB_WE_I;`
144			`reg WB_CYC_I;`
145			`reg WB_STB_I;`
146
147			`wire [31:0] WB_DAT_O;`
148			`wire WB_ACK_O;`
149			`wire WB_ERR_O;`
150	41	mohor	`reg [1:0] WB_ACK_I;`
151
152			`// WISHBONE master`
153			`wire [31:0] m_wb_adr_o;`
154			`wire [3:0] m_wb_sel_o;`
155			`wire m_wb_we_o;`
156			`reg [31:0] m_wb_dat_i;`
157			`wire [31:0] m_wb_dat_o;`
158			`wire m_wb_cyc_o;`
159			`wire m_wb_stb_o;`
160			`reg m_wb_ack_i;`
161			`reg m_wb_err_i;`
162	15	mohor
163			`reg MTxClk;`
164			`wire [3:0] MTxD;`
165			`wire MTxEn;`
166			`wire MTxErr;`
167
168			`reg MRxClk;`
169			`reg [3:0] MRxD;`
170			`reg MRxDV;`
171			`reg MRxErr;`
172			`reg MColl;`
173			`reg MCrs;`
174
175			`reg Mdi_I;`
176			`wire Mdo_O;`
177			`wire Mdo_OE;`
178			`wire Mdc_O;`
179
180
181	108	mohor	`reg [7:0] memory0 [0:65535];`
182			`reg [7:0] memory1 [0:65535];`
183			`reg [7:0] memory2 [0:65535];`
184			`reg [7:0] memory3 [0:65535];`
185	15	mohor
186			`reg WishboneBusy;`
187			`reg StartTB;`
188			`reg [9:0] TxBDIndex;`
189			`reg [9:0] RxBDIndex;`
190
191	108	mohor	`reg LogEnable;`
192
193	41	mohor	`integer mcd1;`
194			`integer mcd2;`
195	15	mohor
196	157	mohor	`reg [5:0] g_last_txbd;`
197
198	15	mohor	`// Connecting Ethernet top module`
199
200	364	olof	`ethmac ethtop`
201	15	mohor	`(`
202			`// WISHBONE common`
203	17	mohor	`.wb_clk_i(WB_CLK_I), .wb_rst_i(WB_RST_I), .wb_dat_i(WB_DAT_I), .wb_dat_o(WB_DAT_O),`
204	15	mohor
205			`// WISHBONE slave`
206	23	mohor	`.wb_adr_i(WB_ADR_I[11:2]), .wb_sel_i(WB_SEL_I), .wb_we_i(WB_WE_I), .wb_cyc_i(WB_CYC_I),`
207	80	mohor	`.wb_stb_i(WB_STB_I), .wb_ack_o(WB_ACK_O), .wb_err_o(WB_ERR_O),`
208	41	mohor
209			`// WISHBONE master`
210			`.m_wb_adr_o(m_wb_adr_o), .m_wb_sel_o(m_wb_sel_o), .m_wb_we_o(m_wb_we_o), .m_wb_dat_i(m_wb_dat_i),`
211			`.m_wb_dat_o(m_wb_dat_o), .m_wb_cyc_o(m_wb_cyc_o), .m_wb_stb_o(m_wb_stb_o), .m_wb_ack_i(m_wb_ack_i),`
212			`.m_wb_err_i(m_wb_err_i),`
213	15	mohor
214			`//TX`
215	19	mohor	`.mtx_clk_pad_i(MTxClk), .mtxd_pad_o(MTxD), .mtxen_pad_o(MTxEn), .mtxerr_pad_o(MTxErr),`
216	15	mohor
217			`//RX`
218	19	mohor	`.mrx_clk_pad_i(MRxClk), .mrxd_pad_i(MRxD), .mrxdv_pad_i(MRxDV), .mrxerr_pad_i(MRxErr),`
219	157	mohor	`.mcoll_pad_i(MColl), .mcrs_pad_i(MCrs),`
220	15	mohor
221			`// MIIM`
222	108	mohor	`.mdc_pad_o(Mdc_O), .md_pad_i(Mdi_I), .md_pad_o(Mdo_O), .md_padoe_o(Mdo_OE),`
223	22	mohor
224			`.int_o()`
225	15	mohor	`);`
226
227
228	157	mohor	`bench_cop i_bench_cop`
229			`(`
230			`// WISHBONE common`
231			`.wb_clk_i(WB_CLK_I), .wb_rst_i(WB_RST_I), .wb_dat_i(WB_DAT_I), .wb_dat_o(WB_DAT_O),`
232	15	mohor
233	157	mohor	`// WISHBONE slave`
234			`.wb_adr_i(WB_ADR_I[11:2]), .wb_sel_i(WB_SEL_I), .wb_we_i(WB_WE_I), .wb_cyc_i(WB_CYC_I),`
235			`.wb_stb_i(WB_STB_I), .wb_ack_o(WB_ACK_O), .wb_err_o(WB_ERR_O),`
236
237			`// WISHBONE master`
238			`.m_wb_adr_o(m_wb_adr_o), .m_wb_sel_o(m_wb_sel_o), .m_wb_we_o(m_wb_we_o), .m_wb_dat_i(m_wb_dat_i),`
239			`.m_wb_dat_o(m_wb_dat_o), .m_wb_cyc_o(m_wb_cyc_o), .m_wb_stb_o(m_wb_stb_o), .m_wb_ack_i(m_wb_ack_i),`
240			`.m_wb_err_i(m_wb_err_i),`
241	15	mohor
242	157	mohor	`//TX`
243			`.mtx_clk_pad_i(MTxClk), .mtxd_pad_o(MTxD), .mtxen_pad_o(MTxEn), .mtxerr_pad_o(MTxErr),`
244	15	mohor
245	157	mohor	`//RX`
246			`.mrx_clk_pad_i(MRxClk), .mrxd_pad_i(MRxD), .mrxdv_pad_i(MRxDV), .mrxerr_pad_i(MRxErr),`
247			`.mcoll_pad_i(MColl), .mcrs_pad_i(MCrs),`
248
249			`// MIIM`
250			`.mdc_pad_o(Mdc_O), .md_pad_i(Mdi_I), .md_pad_o(Mdo_O), .md_padoe_o(Mdo_OE),`
251
252			`.int_o()`
253			`);`
254	15	mohor
255
256	157	mohor
257
258
259
260
261	15	mohor	`initial`
262			`begin`
263			`WB_CLK_I = 1'b0;`
264	19	mohor	`WB_DAT_I = 32'h0;`
265			`WB_ADR_I = 32'h0;`
266			`WB_SEL_I = 4'h0;`
267			`WB_WE_I = 1'b0;`
268	15	mohor	`WB_CYC_I = 1'b0;`
269			`WB_STB_I = 1'b0;`
270	41	mohor
271			`m_wb_ack_i = 0;`
272			`m_wb_err_i = 0;`
273	15	mohor	`MTxClk = 1'b0;`
274			`MRxClk = 1'b0;`
275			`MRxD = 4'h0;`
276			`MRxDV = 1'b0;`
277			`MRxErr = 1'b0;`
278			`MColl = 1'b0;`
279			`MCrs = 1'b0;`
280			`Mdi_I = 1'b0;`
281
282			`WishboneBusy = 1'b0;`
283			`TxBDIndex = 10'h0;`
284			`RxBDIndex = 10'h0;`
285	108	mohor	`LogEnable = 1'b1;`
286	157	mohor	`g_last_txbd = 6'h0;`
287	15	mohor	`end`
288
289
290			`// Reset pulse`
291			`initial`
292			`begin`
293	41	mohor	`mcd1 = $fopen("ethernet_tx.log");`
294			`mcd2 = $fopen("ethernet_rx.log");`
295			`WB_RST_I = 1'b1;`
296	15	mohor	`#100 WB_RST_I = 1'b0;`
297			`#100 StartTB = 1'b1;`
298			`end`
299
300
301
302			`// Generating WB_CLK_I clock`
303			`always`
304			`begin`
305	41	mohor	`// forever #2.5 WB_CLK_I = ~WB_CLK_I; // 2*2.5 ns -> 200.0 MHz`
306	19	mohor	`// forever #5 WB_CLK_I = ~WB_CLK_I; // 2*5 ns -> 100.0 MHz`
307	15	mohor	`// forever #10 WB_CLK_I = ~WB_CLK_I; // 2*10 ns -> 50.0 MHz`
308	157	mohor	`forever #12.5 WB_CLK_I = ~WB_CLK_I; // 2*12.5 ns -> 40 MHz`
309	108	mohor	`// forever #15 WB_CLK_I = ~WB_CLK_I; // 2*10 ns -> 33.3 MHz`
310	157	mohor	`// forever #20 WB_CLK_I = ~WB_CLK_I; // 2*20 ns -> 25 MHz`
311	41	mohor	`// forever #25 WB_CLK_I = ~WB_CLK_I; // 2*25 ns -> 20.0 MHz`
312	108	mohor	`// forever #31.25 WB_CLK_I = ~WB_CLK_I; // 2*31.25 ns -> 16.0 MHz`
313	41	mohor	`// forever #50 WB_CLK_I = ~WB_CLK_I; // 2*50 ns -> 10.0 MHz`
314			`// forever #55 WB_CLK_I = ~WB_CLK_I; // 2*55 ns -> 9.1 MHz`
315	15	mohor	`end`
316
317			`// Generating MTxClk clock`
318			`always`
319			`begin`
320	108	mohor	`// #3 forever #20 MTxClk = ~MTxClk; // 2*20 ns -> 25 MHz`
321			`#3 forever #200 MTxClk = ~MTxClk; // 2*200 ns -> 2.5 MHz`
322	15	mohor	`end`
323
324			`// Generating MRxClk clock`
325			`always`
326			`begin`
327	108	mohor	`// #16 forever #20 MRxClk = ~MRxClk; // 2*20 ns -> 25 MHz`
328	157	mohor	`#16 forever #200 MRxClk = ~MRxClk; // 2*200 ns -> 2.5 MHz`
329			`// #16 forever #62.5 MRxClk = ~MRxClk; // 2*62.5 ns -> 8 MHz // just for testing purposes`
330	15	mohor	`end`
331
332	157	mohor
333	15	mohor	`initial`
334			`begin`
335			`wait(StartTB); // Start of testbench`
336
337	157	mohor	`// Reset eth MAC core`
338	22	mohor	WishboneWrite(32'h00000800, {26'h0, `ETH_MODER_ADR<<2}); // r_Rst = 1
339			WishboneWrite(32'h00000000, {26'h0, `ETH_MODER_ADR<<2}); // r_Rst = 0
340	15	mohor
341	157	mohor	`InitializeMemory;`
342	15	mohor
343	157	mohor	`// Select which test you want to run:`
344			`// TestTxAndRx;`
345			`TestFullDuplex;`
346			`// TestUnicast;`
347			`// TestBroadcast;`
348			`// TestMulticast;`
349	15	mohor	`end`
350	157	mohor
351			`task TestTxAndRx;`
352	15	mohor
353	157	mohor	`integer ii, jj;`
354			`integer data_in, bd, pointer;`
355	15	mohor
356	157	mohor	`begin`
357			WishboneWrite(32'h00000800, {26'h0, `ETH_MODER_ADR<<2}); // r_Rst = 1
358			WishboneWrite(32'h00000000, {26'h0, `ETH_MODER_ADR<<2}); // r_Rst = 0
359			WishboneWrite(32'h00000080, {26'h0, `ETH_TX_BD_NUM_ADR<<2}); // r_RxBDAddress = 0x80
360	15	mohor
361	157	mohor	// WishboneWrite(32'h0000a06b, {26'h0, `ETH_MODER_ADR<<2}); // RxEn, Txen, CrcEn, Pad en, half duplex,
362			WishboneWrite(32'h0000a46b, {26'h0, `ETH_MODER_ADR<<2}); // RxEn, Txen, CrcEn, Pad en, full duplex,
363			// WishboneWrite(32'h0001a06b, {26'h0, `ETH_MODER_ADR<<2}); // r_RecSmall, RxEn, Txen, CrcEn, Pad en, half duplex,
364			`// r_IPG, promisc On, reject broadcast`
365	15	mohor
366	157	mohor	WishboneWrite(32'h00000004, {26'h0, `ETH_CTRLMODER_ADR<<2}); //r_TxFlow = 1
367	15	mohor
368	157	mohor	WishboneWrite(32'h00000002, {26'h0, `ETH_MAC_ADDR1_ADR<<2}); // MAC = 000203040506
369			WishboneWrite(32'h03040506, {26'h0, `ETH_MAC_ADDR0_ADR<<2});
370	15	mohor
371	157	mohor	`/*`
372			`// Just few reads`
373			WishboneRead({26'h0, `ETH_MODER_ADR<<2}, data_in); // Read from ETH_MODER register
374			WishboneRead({26'h0, `ETH_TX_BD_NUM_ADR<<2}, data_in); // Read from ETH_TX_BD_NUM_ADR register
375			WishboneRead({26'h0, `ETH_MAC_ADDR1_ADR<<2}, data_in); // Read from ETH_MAC_ADDR1_ADR register
376			WishboneRead({26'h0, `ETH_MAC_ADDR0_ADR<<2}, data_in); // Read from ETH_MAC_ADDR0_ADR register
377			`*/`
378	15	mohor
379
380
381	19	mohor
382	157	mohor	`for(jj=0; jj<8; jj=jj+4)`
383			`begin`
384			WishboneWriteData(`TX_BUF_BASE + jj, 32'h11111111, 4'hf); // Initializing data to ff
385			`end`
386	15	mohor
387	157	mohor	`for(jj=0; jj<8; jj=jj+4)`
388	15	mohor	`begin`
389	157	mohor	WishboneWriteData(`RX_BUF_BASE + jj, 32'h11111111, 4'hf); // Initializing data to ff
390	15	mohor	`end`
391
392	157	mohor	`// SendPacketX(16'h0064, 1'b0, 2'h3);`
393			`// SendPacketX(16'h0064, 1'b0, 2'h2);`
394			`// SendPacketX(16'h0064, 1'b0, 2'h1);`
395			`// SendPacketX(16'h0064, 1'b0, 2'h0);`
396			`// SendPacket(16'h0064, 1'b0);`
397			`// SendPacket(16'h0011, 1'b0);`
398			`// SendPacket(16'h0012, 1'b0);`
399	15	mohor
400	157	mohor	`fork`
401			`begin`
402			`/*`
403			`SendPacketX(16'h0064, 1'b0, 2'h1);`
404			`SendPacketX(16'h0064, 1'b0, 2'h2);`
405			`SendPacketX(16'h0064, 1'b0, 2'h3);`
406			`SendPacketX(16'h0064, 1'b0, 2'h0);`
407			`*/`
408			`// SendPacketX(16'h264, 1'b0, 2'h3);`
409			`// SendPacketX(16'h64, 1'b0, 2'h3);`
410			`// SendPacketX(16'h104, 1'b0, 2'h3);`
411	15	mohor	`end`
412
413			`begin`
414	157	mohor	ReceivePacketX(16'h0040, 1'b0, `UNICAST_XFR, 2'h0); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
415			ReceivePacketX(16'h0041, 1'b0, `UNICAST_XFR, 2'h0); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
416			ReceivePacketX(16'h0042, 1'b0, `UNICAST_XFR, 2'h0); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
417			ReceivePacketX(16'h0043, 1'b0, `UNICAST_XFR, 2'h0); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
418			ReceivePacketX(16'h0044, 1'b0, `UNICAST_XFR, 2'h0); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
419			`end`
420	15	mohor
421	157	mohor	`// begin`
422			`// for(ii=0; ii<10000; ii=ii+1)`
423			`// begin`
424			`// WishboneRead({22'h01, 10'b0}, data_in); // read back`
425			`// #100;`
426			`// end`
427			`// end`
428			`//join`
429	15	mohor
430	157	mohor	`//fork`
431			`/*`
432			`begin`
433			`repeat(4)`
434	15	mohor	`begin`
435	157	mohor	`wait(tb_eth_top.ethtop.wishbone.TxStatusWrite); // wait until tx status is written`
436			`@ (posedge WB_CLK_I)`
437			`#1;`
438	15	mohor	`end`
439			`end`
440	157	mohor	`*/`
441			`begin`
442			`wait(tb_eth_top.ethtop.wishbone.RxStatusWrite); // wait until rx status is written`
443			`end`
444	15	mohor
445	157	mohor	`join`
446	15	mohor
447
448	157	mohor	`/*`
449			`SendPacket(16'h0013, 1'b0);`
450			`SendPacket(16'h0014, 1'b0);`
451	15	mohor
452	157	mohor	`SendPacket(16'h0030, 1'b0);`
453			`SendPacket(16'h0031, 1'b0);`
454			`SendPacket(16'h0032, 1'b0);`
455			`SendPacket(16'h0033, 1'b0);`
456			`SendPacket(16'h0025, 1'b0);`
457			`SendPacket(16'h0045, 1'b0);`
458			`SendPacket(16'h0025, 1'b0);`
459			`SendPacket(16'h0017, 1'b0);`
460			`*/`
461	15	mohor
462	157	mohor	// ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h3); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
463			// ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h2); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
464			// ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h1); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
465			// ReceivePacketX(16'h0050, 1'b0, `MULTICAST_XFR, 2'h0); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
466	15	mohor
467	157	mohor	// ReceivePacket(16'h0050, 1'b0, `MULTICAST_XFR); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
468			// ReceivePacket(16'h0051, 1'b0, `UNICAST_XFR); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
469			// ReceivePacket(16'h0052, 1'b0, `MULTICAST_XFR); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
470			// ReceivePacket(16'h0053, 1'b0, `BROADCAST_XFR); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
471			// ReceivePacket(16'h0054, 1'b0, `UNICAST_XFR); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
472			// ReceivePacket(16'h0055, 1'b0, `MULTICAST_XFR); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
473			// ReceivePacket(16'h0056, 1'b0, `UNICAST_WRONG_XFR); // Initializes RxBD and then generates traffic on the MRxD[3:0] signals.
474	15	mohor
475
476	157	mohor	`repeat(1000) @ (posedge MRxClk); // Waiting some time for all accesses to finish before reading out the statuses.`
477	15	mohor
478	157	mohor	`// WishboneRead({24'h04, (8'h0<<2)}, RxBD); // Read from TxBD register`
479			`// WishboneRead({24'h04, (8'h1<<2)}, RxBD); // Read from TxBD register`
480			`// WishboneRead({24'h04, (8'h2<<2)}, RxBD); // Read from TxBD register`
481			`// WishboneRead({24'h04, (8'h3<<2)}, RxBD); // Read from TxBD register`
482			`// WishboneRead({24'h04, (8'h4<<2)}, RxBD); // Read from TxBD register`
483	15	mohor
484	157	mohor	`for(jj=0; jj<3; jj=jj+1) // How many TxBD do we want to read?`
485	15	mohor	`begin`
486	157	mohor
487			`WishboneRead({22'h01, ((10'h0+jj[4:0]*2'h2)<<2)}, bd); // Read from TxBD`
488			`$display("\n(%0t)\t\tRead TxBD %0x = 0x%x", $time, jj, bd);`
489			`if(~bd[15]) // Ready = 0?`
490			`begin`
491			`WishboneRead({22'h01, ((10'h0+jj[4:0]*2'h2+1'h1)<<2)}, pointer); // Read TxBD pointer`
492			`$display("\t\t\tRead TxBDPointer 0x=%x", pointer);`
493			`$write("\t\t\tData:");`
494			`for(ii=0; ii<bd[31:16]; ii=ii+4)`
495			`begin`
496			`WishboneReadData({pointer[31:2], 2'h0}+ii, data_in); // Read data from Tx Pointer`
497			`$write("\t0x%x", data_in);`
498			`end`
499			`end`
500	15	mohor	`end`

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