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//
// Copyright 2011 Ettus Research LLC
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program 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 General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
//
// FIXME need to add flow control
module serdes_tb();
reg clk, rst;
wire ser_rx_clk, ser_tx_clk;
wire ser_rklsb, ser_rkmsb, ser_tklsb, ser_tkmsb;
wire [15:0] ser_r, ser_t;
initial clk = 0;
initial rst = 1;
initial #1000 rst = 0;
always #100 clk = ~clk;
// Wishbone
reg [31:0] wb_dat_i;
wire [31:0] wb_dat_o_rx, wb_dat_o_tx;
reg wb_we, wb_en_rx, wb_en_tx;
reg [8:0] wb_adr;
// Buffer Control
reg go, clear, read, write;
reg [3:0] buf_num;
wire [31:0] ctrl_word = {buf_num,3'b0,clear,write,read,step,lastline,firstline};
reg [8:0] firstline = 0, lastline = 0;
reg [3:0] step = 1;
reg first_tx = 1, first_rx = 1; // for verif
// TX Side
reg wb_we_tx;
wire en_tx, we_tx;
wire [8:0] addr_tx;
wire [31:0] f2r_tx, r2f_tx;
wire [31:0] data_tx;
wire read_tx, done_tx, error_tx, sop_tx, eop_tx;
wire fdone_tx, ferror_tx;
reg even;
reg channel_error = 0;
serdes_tx serdes_tx
(.clk(clk),.rst(rst),
.ser_tx_clk(ser_tx_clk),.ser_t(ser_t),.ser_tklsb(ser_tklsb),.ser_tkmsb(ser_tkmsb),
.rd_dat_i(data_tx),.rd_read_o(read_tx),.rd_done_o(done_tx),
.rd_error_o(error_tx),.rd_sop_i(sop_tx),.rd_eop_i(eop_tx) );
ram_2port #(.DWIDTH(32),.AWIDTH(9))
ram_tx(.clka(clk),.ena(wb_en_tx),.wea(wb_we_tx),.addra(wb_adr),.dia(wb_dat_i),.doa(wb_dat_o_tx),
.clkb(clk),.enb(en_tx),.web(we_tx),.addrb(addr_tx),.dib(f2r_tx),.dob(r2f_tx));
buffer_int #(.BUFF_NUM(1)) buffer_int_tx
(.clk(clk),.rst(rst),
.ctrl_word(ctrl_word),.go(go),
.done(fdone_tx),.error(ferror_tx),
.en_o(en_tx),.we_o(we_tx),.addr_o(addr_tx),.dat_to_buf(f2r_tx),.dat_from_buf(r2f_tx),
.wr_dat_i(0),.wr_write_i(0),.wr_done_i(0),
.wr_error_i(0),.wr_ready_o(),.wr_full_o(),
.rd_dat_o(data_tx),.rd_read_i(read_tx),.rd_done_i(done_tx),
.rd_error_i(error_tx),.rd_sop_o(sop_tx),.rd_eop_o(eop_tx) );
// RX Side
reg wb_we_rx;
wire en_rx, we_rx;
wire [8:0] addr_rx;
wire [31:0] f2r_rx, r2f_rx;
wire [31:0] data_rx;
wire write_rx, done_rx, error_rx, ready_rx, empty_rx;
wire fdone_rx, ferror_rx;
serdes_rx serdes_rx
(.clk(clk),.rst(rst),
.ser_rx_clk(ser_rx_clk),.ser_r(ser_r),.ser_rklsb(ser_rklsb),.ser_rkmsb(ser_rkmsb),
.wr_dat_o(data_rx),.wr_write_o(write_rx),.wr_done_o(done_rx),
.wr_error_o(error_rx),.wr_ready_i(ready_rx),.wr_full_i(full_rx) );
ram_2port #(.DWIDTH(32),.AWIDTH(9))
ram_rx(.clka(clk),.ena(wb_en_rx),.wea(wb_we_rx),.addra(wb_adr),.dia(wb_dat_i),.doa(wb_dat_o_rx),
.clkb(clk),.enb(en_rx),.web(we_rx),.addrb(addr_rx),.dib(f2r_rx),.dob(r2f_rx) );
buffer_int #(.BUFF_NUM(0)) buffer_int_rx
(.clk(clk),.rst(rst),
.ctrl_word(ctrl_word),.go(go),
.done(fdone_rx),.error(ferror_rx),
.en_o(en_rx),.we_o(we_rx),.addr_o(addr_rx),.dat_to_buf(f2r_rx),.dat_from_buf(r2f_rx),
.wr_dat_i(data_rx),.wr_write_i(write_rx),.wr_done_i(done_rx),
.wr_error_i(error_rx),.wr_ready_o(ready_rx),.wr_full_o(full_rx),
.rd_dat_o(),.rd_read_i(0),.rd_done_i(0),
.rd_error_i(0),.rd_sop_o(),.rd_eop_o() );
// Simulate the connection
serdes_model serdes_model
(.ser_tx_clk(ser_tx_clk), .ser_tkmsb(ser_tkmsb), .ser_tklsb(ser_tklsb), .ser_t(ser_t),
.ser_rx_clk(ser_rx_clk), .ser_rkmsb(ser_rkmsb), .ser_rklsb(ser_rklsb), .ser_r(ser_r),
.even(even), .error(channel_error) );
initial begin
wb_en_rx <= 0;
wb_en_tx <=0;
wb_we_tx <= 0;
wb_we_rx <= 0;
wb_adr <= 0;
wb_dat_i <= 0;
go <= 0;
even <= 0;
@(negedge rst);
@(posedge clk);
FillTXRAM;
ClearRXRAM;
ResetBuffer(0);
ResetBuffer(1);
// receive a full buffer
ReceiveSERDES(0,10);
SendSERDES(0,10);
// Receive a partial buffer
SendSERDES(11,20);
ReceiveSERDES(11,50);
// Receive too many for buffer
SendSERDES(21,100);
ReceiveSERDES(21,30);
// Send 3 packets, then wait to receive them, so they stack up in the rx fifo
SendSERDES(31,40);
SendSERDES(41,50);
SendSERDES(51,60);
repeat (10)
@(posedge clk);
ReceiveSERDES(31,40);
ReceiveSERDES(41,50);
repeat (1000)
@(posedge clk);
ReceiveSERDES(51,60);
// Overfill the FIFO, should get an error on 3rd packet
SendSERDES(1,400);
SendSERDES(1,400);
WaitForTX;
//WaitForRX;
repeat(1000)
@(posedge clk);
ReceiveSERDES(101,500);
ReceiveSERDES(101,500);
ReadRAM(80);
$finish;
end // initial begin
always @(posedge clk)
if(write_rx)
$display("SERDES RX, FIFO WRITE %x, FIFO RDY %d, FIFO FULL %d",data_rx, ready_rx, full_rx);
always @(posedge clk)
if(read_tx)
$display("SERDES TX, FIFO READ %x, SOP %d, EOP %d",data_tx, sop_tx, eop_tx);
initial begin
$dumpfile("serdes_tb.vcd");
$dumpvars(0,serdes_tb);
end
initial #10000000 $finish;
initial #259300 channel_error <= 1;
initial #259500 channel_error <= 0;
task FillTXRAM;
begin
wb_adr <= 0;
wb_dat_i <= 32'h10802000;
wb_we_tx <= 1;
wb_en_tx <= 1;
@(posedge clk);
repeat(511) begin
wb_dat_i <= wb_dat_i + 32'h00010001;
wb_adr <= wb_adr + 1;
@(posedge clk);
end // repeat (511)
wb_we_tx <= 0;
wb_en_tx <= 0;
@(posedge clk);
$display("Done entering Data into TX RAM\n");
end
endtask // FillTXRAM
task ClearRXRAM;
begin
wb_adr <= 0;
wb_dat_i <= 0;
wb_we_rx <= 1;
wb_en_rx <= 1;
wb_dat_i <= 0;
@(posedge clk);
repeat(511) begin
wb_adr <= wb_adr + 1;
@(posedge clk);
end // repeat (511)
wb_we_rx <= 0;
wb_en_rx <= 0;
@(posedge clk);
$display("Done clearing RX RAM\n");
end
endtask // FillRAM
task ReadRAM;
input [8:0] lastline;
begin
wb_en_rx <= 1;
wb_adr <= 0;
@(posedge clk);
@(posedge clk);
repeat(lastline) begin
$display("ADDR: %h DATA %h", wb_adr, wb_dat_o_rx);
wb_adr <= wb_adr + 1;
@(posedge clk);
@(posedge clk);
end // repeat (511)
$display("ADDR: %h DATA %h", wb_adr, wb_dat_o_rx);
wb_en_rx <= 0;
@(posedge clk);
$display("Done reading out RX RAM\n");
end
endtask // FillRAM
task ResetBuffer;
input [3:0] buffer_num;
begin
buf_num <= buffer_num;
clear <= 1; read <= 0; write <= 0;
go <= 1;
@(posedge clk);
go <= 0;
@(posedge clk);
$display("Buffer Reset");
end
endtask // ClearBuffer
task SetBufferWrite;
input [3:0] buffer_num;
input [8:0] start;
input [8:0] stop;
begin
buf_num <= buffer_num;
clear <= 0; read <= 0; write <= 1;
firstline <= start;
lastline <= stop;
go <= 1;
@(posedge clk);
go <= 0;
@(posedge clk);
$display("Buffer Set for Write");
end
endtask // SetBufferWrite
task SetBufferRead;
input [3:0] buffer_num;
input [8:0] start;
input [8:0] stop;
begin
buf_num <= buffer_num;
clear <= 0; read <= 1; write <= 0;
firstline <= start;
lastline <= stop;
go <= 1;
@(posedge clk);
go <= 0;
@(posedge clk);
$display("Buffer Set for Read");
end
endtask // SetBufferRead
task WaitForTX;
begin
while (!(fdone_tx | ferror_tx))
@(posedge clk);
end
endtask // WaitForTX
task WaitForRX;
begin
while (!(fdone_rx | ferror_rx))
@(posedge clk);
end
endtask // WaitForRX
task SendSERDES;
input [8:0] start;
input [8:0] stop;
begin
if(~first_tx)
WaitForTX;
else
first_tx <= 0;
ResetBuffer(1);
SetBufferRead(1,start,stop);
$display("Here");
end
endtask // SendSERDES
task ReceiveSERDES;
input [8:0] start;
input [8:0] stop;
begin
if(~first_rx)
WaitForRX;
else
first_rx <= 0;
ResetBuffer(0);
SetBufferWrite(0,start,stop);
$display("Here2");
end
endtask // ReceiveSERDES
endmodule // serdes_tb
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