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////////////////////////////////////////////////////////////////////// //// //// //// File name: eth_phy.v //// //// //// //// This file is part of the Ethernet IP core project //// //// http://www.opencores.org/project,ethmac //// //// //// //// Author(s): //// //// - Tadej Markovic, tadej@opencores.org //// //// //// //// All additional information is available in the README.txt //// //// file. //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2002 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 1.7 2002/10/18 13:58:22 tadejm // Some code changed due to bug fixes. // // Revision 1.6 2002/10/09 13:16:51 tadejm // Just back-up; not completed testbench and some testcases are not // wotking properly yet. // // Revision 1.5 2002/09/18 17:55:08 tadej // Bug repaired in eth_phy device // // Revision 1.3 2002/09/13 14:50:15 mohor // Bug in MIIM fixed. // // Revision 1.2 2002/09/13 12:29:14 mohor // Headers changed. // // Revision 1.1 2002/09/13 11:57:20 mohor // New testbench. Thanks to Tadej M - "The Spammer". // // // `include "timescale.v" `include "eth_phy_defines.v" `include "tb_eth_defines.v" module eth_phy // This PHY model simulate simplified Intel LXT971A PHY ( // COMMON m_rst_n_i, // MAC TX mtx_clk_o, mtxd_i, mtxen_i, mtxerr_i, // MAC RX mrx_clk_o, mrxd_o, mrxdv_o, mrxerr_o, mcoll_o, mcrs_o, // MIIM mdc_i, md_io, // SYSTEM phy_log ); ////////////////////////////////////////////////////////////////////// // // Input/output signals // ////////////////////////////////////////////////////////////////////// // MAC miscellaneous signals input m_rst_n_i; // MAC TX signals output mtx_clk_o; input [3:0] mtxd_i; input mtxen_i; input mtxerr_i; // MAC RX signals output mrx_clk_o; output [3:0] mrxd_o; output mrxdv_o; output mrxerr_o; // MAC common signals output mcoll_o; output mcrs_o; // MAC management signals input mdc_i; inout md_io; // SYSTEM input [31:0] phy_log; ////////////////////////////////////////////////////////////////////// // // PHY management (MIIM) REGISTER definitions // ////////////////////////////////////////////////////////////////////// // // Supported registers: // // Addr | Register Name //-------------------------------------------------------------------- // 0 | Control reg. | // 1 | Status reg. #1 |--> normal operation // 2 | PHY ID reg. 1 | // 3 | PHY ID reg. 2 | //---------------------- // Addr | Data MEMORY |--> for testing // //-------------------------------------------------------------------- // // Control register reg control_bit15; // self clearing bit reg [14:10] control_bit14_10; reg control_bit9; // self clearing bit reg [8:0] control_bit8_0; // Status register wire [15:9] status_bit15_9 = `SUPPORTED_SPEED_AND_PORT; wire status_bit8 = `EXTENDED_STATUS; wire status_bit7 = 1'b0; // reserved reg [6:0] status_bit6_0; // PHY ID register 1 wire [15:0] phy_id1 = `PHY_ID1; // PHY ID register 2 wire [15:0] phy_id2 = {`PHY_ID2, `MAN_MODEL_NUM, `MAN_REVISION_NUM}; //-------------------------------------------------------------------- // // Data MEMORY reg [15:0] data_mem [0:31]; // 32 locations of 16-bit data width // ////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////// // // PHY clocks - RX & TX // ////////////////////////////////////////////////////////////////////// reg mtx_clk_o; reg mrx_clk_o; // random generator for a RX period when link is down real rx_link_down_halfperiod; always@(status_bit6_0[2]) begin if (!status_bit6_0[2]) // Link is down begin #1 rx_link_down_halfperiod = ({$random} % 243) + 13; `ifdef VERBOSE #1 $fdisplay(phy_log, " (%0t)(%m)MAC RX clock is %f MHz while ethernet link is down!", $time, (1000/(rx_link_down_halfperiod*2)) ); `endif end end `ifdef VERBOSE always@(status_bit6_0[2]) begin if (!status_bit6_0[2]) // Link is down #1 $fdisplay(phy_log, " (%0t)(%m)Ethernet link is down!", $time); else #1 $fdisplay(phy_log, " (%0t)(%m)Ethernet link is up!", $time); end `endif // speed selection signal eth_speed: 1'b1 - 100 Mbps, 1'b0 - 10 Mbps wire eth_speed; assign eth_speed = ( (control_bit14_10[13]) && !((`LED_CFG1) && (`LED_CFG2)) ); `ifdef VERBOSE always@(eth_speed) begin if (eth_speed) #1 $fdisplay(phy_log, " (%0t)(%m)PHY configured to 100 Mbps!", $time); else #1 $fdisplay(phy_log, " (%0t)(%m)PHY configured tp 10 Mbps!", $time); end `endif // different clock calculation between RX and TX, so that there is alsways a litle difference /*initial begin set_mrx_equal_mtx = 1; // default end*/ always begin mtx_clk_o = 0; #7; forever begin if (eth_speed) // 100 Mbps - 25 MHz, 40 ns begin #20 mtx_clk_o = ~mtx_clk_o; end else // 10 Mbps - 2.5 MHz, 400 ns begin #200 mtx_clk_o = ~mtx_clk_o; end end end always begin // EQUAL mrx_clk to mtx_clk mrx_clk_o = 0; #7; forever begin if (eth_speed) // 100 Mbps - 25 MHz, 40 ns begin #20 mrx_clk_o = ~mrx_clk_o; end else // 10 Mbps - 2.5 MHz, 400 ns begin #200 mrx_clk_o = ~mrx_clk_o; end end // DIFFERENT mrx_clk than mtx_clk /* mrx_clk_diff_than_mtx = 1; #3; forever begin if (status_bit6_0[2]) // Link is UP begin if (eth_speed) // 100 Mbps - 25 MHz, 40 ns begin //#(((1/0.025001)/2)) #19.99 mrx_clk_diff_than_mtx = ~mrx_clk_diff_than_mtx; // period is calculated from frequency in GHz end else // 10 Mbps - 2.5 MHz, 400 ns begin //#(((1/0.0024999)/2)) #200.01 mrx_clk_diff_than_mtx = ~mrx_clk_diff_than_mtx; // period is calculated from frequency in GHz end end else // Link is down begin #(rx_link_down_halfperiod) mrx_clk_diff_than_mtx = ~mrx_clk_diff_than_mtx; // random frequency between 2 MHz and 40 MHz end end*/ // // set output mrx_clk // if (set_mrx_equal_mtx) // mrx_clk_o = mrx_clk_equal_to_mtx; // else // mrx_clk_o = mrx_clk_diff_than_mtx; end // set output mrx_clk //assign mrx_clk_o = set_mrx_equal_mtx ? mrx_clk_equal_to_mtx : mrx_clk_diff_than_mtx ; ////////////////////////////////////////////////////////////////////// // // PHY management (MIIM) interface // ////////////////////////////////////////////////////////////////////// reg respond_to_all_phy_addr; // PHY will respond to all phy addresses reg no_preamble; // PHY responds to frames without preamble integer md_transfer_cnt; // counter countes the value of whole data transfer reg md_transfer_cnt_reset; // for reseting the counter reg md_io_reg; // registered input reg md_io_output; // registered output reg md_io_rd_wr; // op-code latched (read or write) reg md_io_enable; // output enable reg [4:0] phy_address; // address of PHY device reg [4:0] reg_address; // address of a register reg md_get_phy_address; // for shifting PHY address in reg md_get_reg_address; // for shifting register address in reg [15:0] reg_data_in; // data to be written in a register reg md_get_reg_data_in; // for shifting data in reg md_put_reg_data_in; // for storing data into a selected register reg [15:0] reg_data_out; // data to be read from a register reg md_put_reg_data_out; // for registering data from a selected register wire [15:0] register_bus_in; // data bus to a selected register reg [15:0] register_bus_out; // data bus from a selected register initial begin md_io_enable = 1'b0; respond_to_all_phy_addr = 1'b0; no_preamble = 1'b0; end // tristate output assign #1 md_io = (m_rst_n_i && md_io_enable) ? md_io_output : 1'bz ; // registering input always@(posedge mdc_i or negedge m_rst_n_i) begin if (!m_rst_n_i) md_io_reg <= #1 0; else md_io_reg <= #1 md_io; end // getting (shifting) PHY address, Register address and Data in // putting Data out and shifting always@(posedge mdc_i or negedge m_rst_n_i) begin if (!m_rst_n_i) begin phy_address <= 0; reg_address <= 0; reg_data_in <= 0; reg_data_out <= 0; md_io_output <= 0; end else begin if (md_get_phy_address) begin phy_address[4:1] <= phy_address[3:0]; // correct address is `ETH_PHY_ADDR phy_address[0] <= md_io; end if (md_get_reg_address) begin reg_address[4:1] <= reg_address[3:0]; reg_address[0] <= md_io; end if (md_get_reg_data_in) begin reg_data_in[15:1] <= reg_data_in[14:0]; reg_data_in[0] <= md_io; end if (md_put_reg_data_out) begin reg_data_out <= register_bus_out; end if (md_io_enable) begin md_io_output <= reg_data_out[15]; reg_data_out[15:1] <= reg_data_out[14:0]; reg_data_out[0] <= 1'b0; end end end assign #1 register_bus_in = reg_data_in; // md_put_reg_data_in - allows writing to a selected register // counter for transfer to and from MIIM always@(posedge mdc_i or negedge m_rst_n_i) begin if (!m_rst_n_i) begin if (no_preamble) md_transfer_cnt <= 33; else md_transfer_cnt <= 1; end else begin if (md_transfer_cnt_reset) begin if (no_preamble) md_transfer_cnt <= 33; else md_transfer_cnt <= 1; end else if (md_transfer_cnt < 64) begin md_transfer_cnt <= md_transfer_cnt + 1'b1; end else begin if (no_preamble) md_transfer_cnt <= 33; else md_transfer_cnt <= 1; end end end // MIIM transfer control always@(m_rst_n_i or md_transfer_cnt or md_io_reg or md_io_rd_wr or phy_address or respond_to_all_phy_addr or no_preamble) begin #1; while ((m_rst_n_i) && (md_transfer_cnt <= 64)) begin // reset the signal - put registered data in the register (when write) // check preamble if (md_transfer_cnt < 33) begin #4 md_put_reg_data_in = 1'b0; if (md_io_reg !== 1'b1) begin #1 md_transfer_cnt_reset = 1'b1; end else begin #1 md_transfer_cnt_reset = 1'b0; end end // check start bits else if (md_transfer_cnt == 33) begin if (no_preamble) begin #4 md_put_reg_data_in = 1'b0; if (md_io_reg === 1'b0) begin #1 md_transfer_cnt_reset = 1'b0; end else begin #1 md_transfer_cnt_reset = 1'b1; //if ((md_io_reg !== 1'bz) && (md_io_reg !== 1'b1)) if (md_io_reg !== 1'bz) begin // ERROR - start ! `ifdef VERBOSE $fdisplay(phy_log, "*E (%0t)(%m)MIIM - wrong first start bit (without preamble)", $time); `endif #10 $stop; end end end else // with preamble begin #4 ; `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m)MIIM - 32-bit preamble received", $time); `endif // check start bit only if md_transfer_cnt_reset is inactive, because if // preamble suppression was changed start bit should not be checked if ((md_io_reg !== 1'b0) && (md_transfer_cnt_reset == 1'b0)) begin // ERROR - start ! `ifdef VERBOSE $fdisplay(phy_log, "*E (%0t)(%m)MIIM - wrong first start bit", $time); `endif #10 $stop; end end end else if (md_transfer_cnt == 34) begin #4; if (md_io_reg !== 1'b1) begin // ERROR - start ! #1; `ifdef VERBOSE if (no_preamble) $fdisplay(phy_log, "*E (%0t)(%m)MIIM - wrong second start bit (without preamble)", $time); else $fdisplay(phy_log, "*E (%0t)(%m)MIIM - wrong second start bit", $time); `endif #10 $stop; end else begin `ifdef VERBOSE if (no_preamble) #1 $fdisplay(phy_log, " (%0t)(%m)MIIM - 2 start bits received (without preamble)", $time); else #1 $fdisplay(phy_log, " (%0t)(%m)MIIM - 2 start bits received", $time); `endif end end // register the op-code (rd / wr) else if (md_transfer_cnt == 35) begin #4; if (md_io_reg === 1'b1) begin #1 md_io_rd_wr = 1'b1; end else begin #1 md_io_rd_wr = 1'b0; end end else if (md_transfer_cnt == 36) begin #4; if ((md_io_reg === 1'b0) && (md_io_rd_wr == 1'b1)) begin #1 md_io_rd_wr = 1'b1; // reading from PHY registers `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m)MIIM - op-code for READING from registers", $time); `endif end else if ((md_io_reg === 1'b1) && (md_io_rd_wr == 1'b0)) begin #1 md_io_rd_wr = 1'b0; // writing to PHY registers `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m)MIIM - op-code for WRITING to registers", $time); `endif end else begin // ERROR - wrong opcode ! `ifdef VERBOSE #1 $fdisplay(phy_log, "*E (%0t)(%m)MIIM - wrong OP-CODE", $time); `endif #10 $stop; end // set the signal - get PHY address begin #1 md_get_phy_address = 1'b1; end end // reset the signal - get PHY address else if (md_transfer_cnt == 41) begin #4 md_get_phy_address = 1'b0; // set the signal - get register address #1 md_get_reg_address = 1'b1; end // reset the signal - get register address // set the signal - put register data to output register else if (md_transfer_cnt == 46) begin #4 md_get_reg_address = 1'b0; #1 md_put_reg_data_out = 1'b1; end // reset the signal - put register data to output register // set the signal - enable md_io as output when read else if (md_transfer_cnt == 47) begin #4 md_put_reg_data_out = 1'b0; if (md_io_rd_wr) //read begin if (md_io_reg !== 1'bz) begin // ERROR - turn around ! `ifdef VERBOSE #1 $fdisplay(phy_log, "*E (%0t)(%m)MIIM - wrong turn-around cycle before reading data out", $time); `endif #10 $stop; end if ((phy_address === `ETH_PHY_ADDR) || respond_to_all_phy_addr) // check the PHY address begin #1 md_io_enable = 1'b1; `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m)MIIM - received correct PHY ADDRESS: %x", $time, phy_address); `endif end else begin `ifdef VERBOSE #1 $fdisplay(phy_log, "*W (%0t)(%m)MIIM - received different PHY ADDRESS: %x", $time, phy_address); `endif end end else // write begin #1 md_io_enable = 1'b0; // check turn around cycle when write on clock 47 if (md_io_reg !== 1'b1) begin // ERROR - turn around ! `ifdef VERBOSE #1 $fdisplay(phy_log, "*E (%0t)(%m)MIIM - wrong 1. turn-around cycle before writing data in", $time); `endif #10 $stop; end end end // set the signal - get register data in when write else if (md_transfer_cnt == 48) begin #4; if (!md_io_rd_wr) // write begin #1 md_get_reg_data_in = 1'b1; // check turn around cycle when write on clock 48 if (md_io_reg !== 1'b0) begin // ERROR - turn around ! `ifdef VERBOSE #1 $fdisplay(phy_log, "*E (%0t)(%m)MIIM - wrong 2. turn-around cycle before writing data in", $time); `endif #10 $stop; end end else // read begin #1 md_get_reg_data_in = 1'b0; end end // reset the signal - enable md_io as output when read // reset the signal - get register data in when write // set the signal - put registered data in the register when write else if (md_transfer_cnt == 64) begin #1 md_io_enable = 1'b0; #4 md_get_reg_data_in = 1'b0; if (!md_io_rd_wr) // write begin if ((phy_address === `ETH_PHY_ADDR) || respond_to_all_phy_addr) // check the PHY address begin #1 md_put_reg_data_in = 1'b1; `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m)MIIM - received correct PHY ADDRESS: %x", $time, phy_address); $fdisplay(phy_log, " (%0t)(%m)MIIM - WRITING to register %x COMPLETED!", $time, reg_address); `endif end else begin `ifdef VERBOSE #1 $fdisplay(phy_log, "*W (%0t)(%m)MIIM - received different PHY ADDRESS: %x", $time, phy_address); $fdisplay(phy_log, "*W (%0t)(%m)MIIM - NO WRITING to register %x !", $time, reg_address); `endif end end else // read begin `ifdef VERBOSE if ((phy_address === `ETH_PHY_ADDR) || respond_to_all_phy_addr) // check the PHY address #1 $fdisplay(phy_log, " (%0t)(%m)MIIM - READING from register %x COMPLETED!", $time, reg_address); else #1 $fdisplay(phy_log, "*W (%0t)(%m)MIIM - NO READING from register %x !", $time, reg_address); `endif end end // wait for one clock period @(posedge mdc_i) #1; end end //==================================================================== // // PHY management (MIIM) REGISTERS // //==================================================================== // // Supported registers (normal operation): // // Addr | Register Name //-------------------------------------------------------------------- // 0 | Control reg. // 1 | Status reg. #1 // 2 | PHY ID reg. 1 // 3 | PHY ID reg. 2 //---------------------- // Addr | Data MEMORY |--> for testing // //-------------------------------------------------------------------- // // Control register // reg control_bit15; // self clearing bit // reg [14:10] control_bit14_10; // reg control_bit9; // self clearing bit // reg [8:0] control_bit8_0; // Status register // wire [15:9] status_bit15_9 = `SUPPORTED_SPEED_AND_PORT; // wire status_bit8 = `EXTENDED_STATUS; // wire status_bit7 = 1'b0; // reserved // reg [6:0] status_bit6_0 = `DEFAULT_STATUS; // PHY ID register 1 // wire [15:0] phy_id1 = `PHY_ID1; // PHY ID register 2 // wire [15:0] phy_id2 = {`PHY_ID2, `MAN_MODEL_NUM, `MAN_REVISION_NUM}; //-------------------------------------------------------------------- // // Data MEMORY // reg [15:0] data_mem [0:31]; // 32 locations of 16-bit data width // //==================================================================== ////////////////////////////////////////////////////////////////////// // // PHY management (MIIM) REGISTER control // ////////////////////////////////////////////////////////////////////// // wholy writable registers for walking ONE's on data, phy and reg. addresses reg registers_addr_data_test_operation; // Non writable status registers initial // always begin #1 status_bit6_0[6] = no_preamble; status_bit6_0[5] = 1'b0; status_bit6_0[3] = 1'b1; status_bit6_0[0] = 1'b1; end always@(posedge mrx_clk_o) begin status_bit6_0[4] <= #1 1'b0; status_bit6_0[1] <= #1 1'b0; end initial begin status_bit6_0[2] = 1'b1; registers_addr_data_test_operation = 0; end // Reading from a selected registers always@(reg_address or registers_addr_data_test_operation or md_put_reg_data_out or control_bit15 or control_bit14_10 or control_bit9 or control_bit8_0 or status_bit15_9 or status_bit8 or status_bit7 or status_bit6_0 or phy_id1 or phy_id2) begin if (registers_addr_data_test_operation) // test operation begin if (md_put_reg_data_out) // read enable begin register_bus_out = #1 data_mem[reg_address]; end end else // normal operation begin if (md_put_reg_data_out) // read enable begin case (reg_address) 5'h0: register_bus_out = #1 {control_bit15, control_bit14_10, control_bit9, control_bit8_0}; 5'h1: register_bus_out = #1 {status_bit15_9, status_bit8, status_bit7, status_bit6_0}; 5'h2: register_bus_out = #1 phy_id1; 5'h3: register_bus_out = #1 phy_id2; default: register_bus_out = #1 16'hDEAD; endcase end end end // Self clear control signals reg self_clear_d0; reg self_clear_d1; reg self_clear_d2; reg self_clear_d3; // Self clearing control always@(posedge mdc_i or negedge m_rst_n_i) begin if (!m_rst_n_i) begin self_clear_d0 <= #1 0; self_clear_d1 <= #1 0; self_clear_d2 <= #1 0; self_clear_d3 <= #1 0; end else begin self_clear_d0 <= #1 md_put_reg_data_in; self_clear_d1 <= #1 self_clear_d0; self_clear_d2 <= #1 self_clear_d1; self_clear_d3 <= #1 self_clear_d2; end end // Writing to a selected register always@(posedge mdc_i or negedge m_rst_n_i) begin if ((!m_rst_n_i) || (control_bit15)) begin if (!registers_addr_data_test_operation) // normal operation begin control_bit15 <= #1 0; control_bit14_10 <= #1 {1'b0, (`LED_CFG1 || `LED_CFG2), `LED_CFG1, 2'b0}; control_bit9 <= #1 0; control_bit8_0 <= #1 {`LED_CFG3, 8'b0}; end end else begin if (registers_addr_data_test_operation) // test operation begin if (md_put_reg_data_in) begin data_mem[reg_address] <= #1 register_bus_in[15:0]; end end else // normal operation begin // bits that are normaly written if (md_put_reg_data_in) begin case (reg_address) 5'h0: begin control_bit14_10 <= #1 register_bus_in[14:10]; control_bit8_0 <= #1 register_bus_in[8:0]; end default: begin end endcase end // self cleared bits written if ((md_put_reg_data_in) && (reg_address == 5'h0)) begin control_bit15 <= #1 register_bus_in[15]; control_bit9 <= #1 register_bus_in[9]; end else if (self_clear_d3) // self cleared bits cleared begin control_bit15 <= #1 1'b0; control_bit9 <= #1 1'b0; end end end end ////////////////////////////////////////////////////////////////////// // // PHY <-> MAC control (RX and TX clocks are at the begining) // ////////////////////////////////////////////////////////////////////// // CARRIER SENSE & COLLISION // MAC common signals reg mcoll_o; reg mcrs_o; // Internal signals controling Carrier sense & Collision // MAC common signals generated when appropriate transfer reg mcrs_rx; reg mcrs_tx; // delayed mtxen_i signal for generating delayed tx carrier sense reg mtxen_d1; reg mtxen_d2; reg mtxen_d3; reg mtxen_d4; reg mtxen_d5; reg mtxen_d6; // collision signal set or rest within task for controling collision reg task_mcoll; // carrier sense signal set or rest within task for controling carrier sense reg task_mcrs; reg task_mcrs_lost; // do not generate collision in half duplex - not normal operation reg no_collision_in_half_duplex; // generate collision in full-duplex mode also - not normal operation reg collision_in_full_duplex; // do not generate carrier sense in half duplex mode - not normal operation reg no_carrier_sense_in_tx_half_duplex; reg no_carrier_sense_in_rx_half_duplex; // generate carrier sense during TX in full-duplex mode also - not normal operation reg carrier_sense_in_tx_full_duplex; // do not generate carrier sense during RX in full-duplex mode - not normal operation reg no_carrier_sense_in_rx_full_duplex; // on RX: delay after carrier sense signal; on TX: carrier sense delayed (delay is one clock period) reg real_carrier_sense; initial begin mcrs_rx = 0; mcrs_tx = 0; task_mcoll = 0; task_mcrs = 0; task_mcrs_lost = 0; no_collision_in_half_duplex = 0; collision_in_full_duplex = 0; no_carrier_sense_in_tx_half_duplex = 0; no_carrier_sense_in_rx_half_duplex = 0; carrier_sense_in_tx_full_duplex = 0; no_carrier_sense_in_rx_full_duplex = 0; real_carrier_sense = 0; end // Collision always@(m_rst_n_i or control_bit8_0 or collision_in_full_duplex or mcrs_rx or mcrs_tx or task_mcoll or no_collision_in_half_duplex ) begin if (!m_rst_n_i) mcoll_o = 0; else begin if (control_bit8_0[8]) // full duplex begin if (collision_in_full_duplex) // collision is usually not asserted in full duplex begin mcoll_o = ((mcrs_rx && mcrs_tx) || task_mcoll); `ifdef VERBOSE if (mcrs_rx && mcrs_tx) $fdisplay(phy_log, " (%0t)(%m) Collision set in FullDuplex!", $time); if (task_mcoll) $fdisplay(phy_log, " (%0t)(%m) Collision set in FullDuplex from TASK!", $time); `endif end else begin mcoll_o = task_mcoll; `ifdef VERBOSE if (task_mcoll) $fdisplay(phy_log, " (%0t)(%m) Collision set in FullDuplex from TASK!", $time); `endif end end else // half duplex begin mcoll_o = ((mcrs_rx && mcrs_tx && !no_collision_in_half_duplex) || task_mcoll); `ifdef VERBOSE if (mcrs_rx && mcrs_tx) $fdisplay(phy_log, " (%0t)(%m) Collision set in HalfDuplex!", $time); if (task_mcoll) $fdisplay(phy_log, " (%0t)(%m) Collision set in HalfDuplex from TASK!", $time); `endif end end end // Carrier sense always@(m_rst_n_i or control_bit8_0 or carrier_sense_in_tx_full_duplex or no_carrier_sense_in_rx_full_duplex or no_carrier_sense_in_tx_half_duplex or no_carrier_sense_in_rx_half_duplex or mcrs_rx or mcrs_tx or task_mcrs or task_mcrs_lost ) begin if (!m_rst_n_i) mcrs_o = 0; else begin if (control_bit8_0[8]) // full duplex begin if (carrier_sense_in_tx_full_duplex) // carrier sense is usually not asserted during TX in full duplex mcrs_o = ((mcrs_rx && !no_carrier_sense_in_rx_full_duplex) || mcrs_tx || task_mcrs) && !task_mcrs_lost; else mcrs_o = ((mcrs_rx && !no_carrier_sense_in_rx_full_duplex) || task_mcrs) && !task_mcrs_lost; end else // half duplex begin mcrs_o = ((mcrs_rx && !no_carrier_sense_in_rx_half_duplex) || (mcrs_tx && !no_carrier_sense_in_tx_half_duplex) || task_mcrs) && !task_mcrs_lost; end end end // MAC TX CONTROL (RECEIVING AT PHY) // storage memory for TX data received from MAC reg [7:0] tx_mem [0:4194303]; // 4194304 locations (22 address lines) of 8-bit data width reg [31:0] tx_mem_addr_in; // address for storing to TX memory reg [7:0] tx_mem_data_in; // data for storing to TX memory reg [31:0] tx_cnt; // counts nibbles // control data of a TX packet for upper layer of testbench reg tx_preamble_ok; reg tx_sfd_ok; // if there is a drible nibble, then tx packet is not byte aligned! reg tx_byte_aligned_ok; // complete length of TX packet (Bytes) received (without preamble and SFD) reg [31:0] tx_len; // complete length of TX packet (Bytes) received (without preamble and SFD) untill MTxErr signal was set first reg [31:0] tx_len_err; // TX control always@(posedge mtx_clk_o) begin // storing data and basic checking of frame if (!m_rst_n_i) begin tx_cnt <= 0; tx_preamble_ok <= 0; tx_sfd_ok <= 0; tx_len <= 0; tx_len_err <= 0; end else begin if (!mtxen_i) begin tx_cnt <= 0; end else begin // tx nibble counter tx_cnt <= tx_cnt + 1; // set initial values and check first preamble nibble if (tx_cnt == 0) begin `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m) TX frame started with tx_en set!", $time); `endif if (mtxd_i == 4'h5) tx_preamble_ok <= 1; else tx_preamble_ok <= 0; tx_sfd_ok <= 0; tx_byte_aligned_ok <= 0; tx_len <= 0; tx_len_err <= 0; // tx_mem_addr_in <= 0; end // check preamble if ((tx_cnt > 0) && (tx_cnt <= 13)) begin if ((tx_preamble_ok != 1) || (mtxd_i != 4'h5)) tx_preamble_ok <= 0; end // check SFD if (tx_cnt == 14) begin `ifdef VERBOSE if (tx_preamble_ok == 1) $fdisplay(phy_log, " (%0t)(%m) TX frame preamble OK!", $time); else $fdisplay(phy_log, "*E (%0t)(%m) TX frame preamble NOT OK!", $time); `endif if (mtxd_i == 4'h5) tx_sfd_ok <= 1; else tx_sfd_ok <= 0; end if (tx_cnt == 15) begin if ((tx_sfd_ok != 1) || (mtxd_i != 4'hD)) tx_sfd_ok <= 0; end // control for storing addresses, type/length, data and FCS to TX memory if (tx_cnt > 15) begin if (tx_cnt == 16) begin `ifdef VERBOSE if (tx_sfd_ok == 1) $fdisplay(phy_log, " (%0t)(%m) TX frame SFD OK!", $time); else $fdisplay(phy_log, "*E (%0t)(%m) TX frame SFD NOT OK!", $time); `endif end if (tx_cnt[0] == 0) begin tx_mem_data_in[3:0] <= mtxd_i; // storing LSB nibble tx_byte_aligned_ok <= 0; // if transfer will stop after this, then there was drible nibble end else begin tx_mem[tx_mem_addr_in[21:0]] <= {mtxd_i, tx_mem_data_in[3:0]}; // storing data into tx memory tx_len <= tx_len + 1; // enlarge byte length counter tx_byte_aligned_ok <= 1; // if transfer will stop after this, then transfer is byte alligned tx_mem_addr_in <= tx_mem_addr_in + 1'b1; end if (mtxerr_i) tx_len_err <= tx_len; end end end // generating CARRIER SENSE for TX with or without delay if (!m_rst_n_i) begin mcrs_tx <= 0; mtxen_d1 <= 0; mtxen_d2 <= 0; mtxen_d3 <= 0; mtxen_d4 <= 0; mtxen_d5 <= 0; mtxen_d6 <= 0; end else begin mtxen_d1 <= mtxen_i; mtxen_d2 <= mtxen_d1; mtxen_d3 <= mtxen_d2; mtxen_d4 <= mtxen_d3; mtxen_d5 <= mtxen_d4; mtxen_d6 <= mtxen_d5; if (real_carrier_sense) mcrs_tx <= mtxen_d6; else mcrs_tx <= mtxen_i; end end `ifdef VERBOSE reg frame_started; initial begin frame_started = 0; end always@(posedge mtxen_i) begin frame_started <= 1; end always@(negedge mtxen_i) begin if (frame_started) begin $fdisplay(phy_log, " (%0t)(%m) TX frame ended with tx_en reset!", $time); frame_started <= 0; end end always@(posedge mrxerr_o) begin $fdisplay(phy_log, " (%0t)(%m) RX frame ERROR signal was set!", $time); end `endif ////////////////////////////////////////////////////////////////////// // // Tasks for PHY <-> MAC transactions // ////////////////////////////////////////////////////////////////////// initial begin tx_mem_addr_in = 0; end // setting the address of tx_mem, to set the starting point of tx packet task set_tx_mem_addr; input [31:0] tx_mem_address; begin #1 tx_mem_addr_in = tx_mem_address; end endtask // set_tx_mem_addr // storage memory for RX data to be transmited to MAC reg [7:0] rx_mem [0:4194303]; // 4194304 locations (22 address lines) of 8-bit data width // MAC RX signals reg [3:0] mrxd_o; reg mrxdv_o; reg mrxerr_o; initial begin mrxd_o = 0; mrxdv_o = 0; mrxerr_o = 0; mcrs_rx = 0; end task send_rx_packet; input [(8*8)-1:0] preamble_data; // preamble data to be sent - correct is 64'h0055_5555_5555_5555 input [3:0] preamble_len; // length of preamble in bytes - max is 4'h8, correct is 4'h7 input [7:0] sfd_data; // SFD data to be sent - correct is 8'hD5 input [31:0] start_addr; // start address input [31:0] len; // length of frame in Bytes (without preamble and SFD) input plus_drible_nibble; // if length is longer for one nibble integer rx_cnt; reg [31:0] rx_mem_addr_in; // address for reading from RX memory reg [7:0] rx_mem_data_out; // data for reading from RX memory begin @(posedge mrx_clk_o); // generating CARRIER SENSE for TX with or without delay if (real_carrier_sense) #1 mcrs_rx = 1; else #1 mcrs_rx = 0; @(posedge mrx_clk_o); #1 mcrs_rx = 1; #1 mrxdv_o = 1; `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m) RX frame started with rx_dv set!", $time); `endif // set initial rx memory address rx_mem_addr_in = start_addr; // send preamble for (rx_cnt = 0; (rx_cnt < (preamble_len << 1)) && (rx_cnt < 16); rx_cnt = rx_cnt + 1) begin #1 mrxd_o = preamble_data[3:0]; #1 preamble_data = preamble_data >> 4; @(posedge mrx_clk_o); end // send SFD for (rx_cnt = 0; rx_cnt < 2; rx_cnt = rx_cnt + 1) begin #1 mrxd_o = sfd_data[3:0]; #1 sfd_data = sfd_data >> 4; @(posedge mrx_clk_o); end `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m) RX frame preamble and SFD sent!", $time); `endif // send packet's addresses, type/length, data and FCS for (rx_cnt = 0; rx_cnt < len; rx_cnt = rx_cnt + 1) begin #1; rx_mem_data_out = rx_mem[rx_mem_addr_in[21:0]]; mrxd_o = rx_mem_data_out[3:0]; @(posedge mrx_clk_o); #1; mrxd_o = rx_mem_data_out[7:4]; rx_mem_addr_in = rx_mem_addr_in + 1; @(posedge mrx_clk_o); #1; end if (plus_drible_nibble) begin rx_mem_data_out = rx_mem[rx_mem_addr_in[21:0]]; mrxd_o = rx_mem_data_out[3:0]; @(posedge mrx_clk_o); end `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m) RX frame addresses, type/length, data and FCS sent!", $time); `endif #1 mcrs_rx = 0; #1 mrxdv_o = 0; @(posedge mrx_clk_o); `ifdef VERBOSE $fdisplay(phy_log, " (%0t)(%m) RX frame ended with rx_dv reset!", $time); `endif end endtask // send_rx_packet task GetDataOnMRxD; input [15:0] Len; input [31:0] TransferType; integer tt; begin @ (posedge mrx_clk_o); #1 mrxdv_o=1'b1; for(tt=0; tt<15; tt=tt+1) begin mrxd_o=4'h5; // preamble @ (posedge mrx_clk_o); #1; end mrxd_o=4'hd; // SFD for(tt=1; tt<(Len+1); tt=tt+1) begin @ (posedge mrx_clk_o); #1; if(TransferType == `UNICAST_XFR && tt == 1) mrxd_o = 4'h0; // Unicast transfer else if(TransferType == `BROADCAST_XFR && tt < 7) mrxd_o = 4'hf; else mrxd_o = tt[3:0]; // Multicast transfer @ (posedge mrx_clk_o); #1; if(TransferType == `BROADCAST_XFR && tt == 6) mrxd_o = 4'he; else if(TransferType == `BROADCAST_XFR && tt < 7) mrxd_o = 4'hf; else mrxd_o = tt[7:4]; end @ (posedge mrx_clk_o); #1; mrxdv_o = 1'b0; end endtask // GetDataOnMRxD ////////////////////////////////////////////////////////////////////// // // Tastks for controling PHY statuses and rx error // ////////////////////////////////////////////////////////////////////// // Link control tasks task link_up_down; input test_op; begin #1 status_bit6_0[2] = test_op; // 1 - link up; 0 - link down end endtask // RX error task rx_err; input test_op; begin #1 mrxerr_o = test_op; // 1 - RX error set; 0 - RX error reset end endtask ////////////////////////////////////////////////////////////////////// // // Tastks for controling PHY carrier sense and collision // ////////////////////////////////////////////////////////////////////// // Collision task collision; input test_op; begin #1 task_mcoll = test_op; end endtask // Carrier sense task carrier_sense; input test_op; begin #1 task_mcrs = test_op; end endtask // Carrier sense lost - higher priority than Carrier sense task task carrier_sense_lost; input test_op; begin #1 task_mcrs_lost = test_op; end endtask // No collision detection in half duplex task no_collision_hd_detect; input test_op; begin #1 no_collision_in_half_duplex = test_op; end endtask // Collision detection in full duplex also task collision_fd_detect; input test_op; begin #1 collision_in_full_duplex = test_op; end endtask // No carrier sense detection at TX in half duplex task no_carrier_sense_tx_hd_detect; input test_op; begin #1 no_carrier_sense_in_tx_half_duplex = test_op; end endtask // No carrier sense detection at RX in half duplex task no_carrier_sense_rx_hd_detect; input test_op; begin #1 no_carrier_sense_in_rx_half_duplex = test_op; end endtask // Carrier sense detection at TX in full duplex also task carrier_sense_tx_fd_detect; input test_op; begin #1 carrier_sense_in_tx_full_duplex = test_op; end endtask // No carrier sense detection at RX in full duplex task no_carrier_sense_rx_fd_detect; input test_op; begin #1 no_carrier_sense_in_rx_full_duplex = test_op; end endtask // Set real delay on carrier sense signal (and therefor collision signal) task carrier_sense_real_delay; input test_op; begin #1 real_carrier_sense = test_op; end endtask ////////////////////////////////////////////////////////////////////// // // Tastks for controling PHY management test operation // ////////////////////////////////////////////////////////////////////// // Set registers to test operation and respond to all phy addresses task test_regs; input test_op; begin #1 registers_addr_data_test_operation = test_op; respond_to_all_phy_addr = test_op; end endtask // Clears data memory for testing the MII task clear_test_regs; integer i; begin for (i = 0; i < 32; i = i + 1) begin #1 data_mem[i] = 16'h0; end end endtask // Accept frames with preamble suppresed task preamble_suppresed; input test_op; begin #1 no_preamble = test_op; md_transfer_cnt_reset = 1'b1; @(posedge mdc_i); #1 md_transfer_cnt_reset = 1'b0; end endtask endmodule