ethernet/rtl/pmd.v

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// SPDX-License-Identifier: AGPL-3.0-Only
/*
* Copyright (C) 2022 Sean Anderson <seanga2@gmail.com>
*
* This roughly follows the design of XAPP225. However, we use a 2x rate DDR
* clock instead of two clocks 90 degrees out of phase. Yosys/nextpnr cannot
* guarantee the phase relationship of any clocks, even those from the same
* PLL. Because of this, we assume that rx_clk_250 and rx_clk_125 are unrelated.
*/
`include "common.vh"
`include "io.vh"
`timescale 1ns/1ps
module pmd (
input tx_clk,
input rx_clk_250,
input rx_clk_125,
input signal_detect,
output reg tx_p, tx_n,
input rx,
/* PMD */
output signal_status,
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input pmd_data_tx,
output reg [1:0] pmd_data_rx,
output reg [1:0] pmd_data_rx_valid
);
reg [1:0] rx_p, rx_n;
reg [3:0] sd_delay;
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`ifdef SYNTHESIS
SB_IO #(
.PIN_TYPE(`PIN_OUTPUT_NEVER | `PIN_INPUT_REGISTERED),
.IO_STANDARD("SB_LVDS_INPUT")
) signal_detect_pin (
.PACKAGE_PIN(signal_detect),
.INPUT_CLK(rx_clk_125),
.D_IN_0(sd_delay[0])
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);
SB_IO #(
.PIN_TYPE(`PIN_OUTPUT_NEVER | `PIN_INPUT_DDR),
.IO_STANDARD("SB_LVDS_INPUT")
) data_rx_pin (
.PACKAGE_PIN(rx),
.INPUT_CLK(rx_clk_250),
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.D_IN_0(rx_p[0]),
.D_IN_1(rx_n[0])
);
`else
always @(posedge rx_clk_125)
sd_delay[0] <= signal_detect;
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always @(posedge rx_clk_250)
rx_p[0] <= rx;
always @(negedge rx_clk_250)
rx_n[0] <= rx;
`endif
/*
* Delay signal status until the known good data has had a chance to
* make it through the pipeline. This isn't necessary for real hardware
* (since signal status is asserted long after we have good data), but
* it helps out during simulation. It also helps avoid metastability.
*/
always @(posedge rx_clk_125)
sd_delay[3:1] <= sd_delay[2:0];
assign signal_status = sd_delay[3];
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/*
* Get things into the rx_clk_250 domain so that we sample posedge before
* negedge. Without this we can have a negedge which happens before the
* posedge.
*/
always @(posedge rx_clk_250) begin
rx_p[1] <= rx_p[0];
rx_n[1] <= rx_n[0];
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end
reg [2:0] rx_a, rx_b, rx_c, rx_d;
/* Get everything in the rx_clk_125 domain */
always @(posedge rx_clk_125) begin
rx_a[0] <= rx_p[1];
rx_b[0] <= rx_n[1];
end
always @(negedge rx_clk_125) begin
rx_c[0] <= rx_p[1];
rx_d[0] <= rx_n[1];
end
/*
* Buffer things a bit. We wait a cycle to avoid metastability. After
* that, we need two cycles of history to detect edges.
*/
always @(posedge rx_clk_125) begin
rx_a[2:1] = rx_a[1:0];
rx_b[2:1] = rx_b[1:0];
rx_c[2:1] = rx_c[1:0];
rx_d[2:1] = rx_d[1:0];
end
localparam A = 0;
localparam B = 1;
localparam C = 2;
localparam D = 3;
reg [1:0] state, state_next;
initial state = A;
reg valid, valid_next;
initial valid = 0;
reg [1:0] pmd_data_rx_next, pmd_data_rx_valid_next;
reg [3:0] rx_r, rx_f;
always @(*) begin
rx_r = {
rx_a[1] & ~rx_a[2],
rx_b[1] & ~rx_b[2],
rx_c[1] & ~rx_c[2],
rx_d[1] & ~rx_d[2]
};
rx_f = {
~rx_a[1] & rx_a[2],
~rx_b[1] & rx_b[2],
~rx_c[1] & rx_c[2],
~rx_d[1] & rx_d[2]
};
state_next = state;
valid_next = 1;
if (rx_r == 4'b1111 || rx_f == 4'b1111)
state_next = C;
else if (rx_r == 4'b1000 || rx_f == 4'b1000)
state_next = D;
else if (rx_r == 4'b1100 || rx_f == 4'b1100)
state_next = A;
else if (rx_r == 4'b1110 || rx_f == 4'b1110)
state_next = B;
else
valid_next = valid;
if (!signal_status) begin
state_next = A;
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valid_next = 0;
end
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pmd_data_rx_next[0] = rx_d[2];
pmd_data_rx_valid_next = 1;
case (state_next)
A: begin
pmd_data_rx_next[1] = rx_a[2];
if (state == D)
pmd_data_rx_valid_next = 0;
end
B: begin
pmd_data_rx_next[1] = rx_b[2];
end
C: begin
pmd_data_rx_next[1] = rx_c[2];
end
D: begin
pmd_data_rx_next[1] = rx_d[2];
if (state == A) begin
pmd_data_rx_next[1] = rx_a[2];
pmd_data_rx_valid_next = 2;
end
end
endcase
if (!valid_next)
pmd_data_rx_valid_next = 0;
end
always @(posedge rx_clk_125) begin
state <= state_next;
valid <= valid_next;
pmd_data_rx <= pmd_data_rx_next;
pmd_data_rx_valid <= pmd_data_rx_valid_next;
end
`ifdef SYNTHESIS
SB_IO #(
.PIN_TYPE(`PIN_OUTPUT_ALWAYS | `PIN_OUTPUT_REGISTERED),
.IO_STANDARD("SB_LVDS_INPUT")
) data_txp_pin (
.PACKAGE_PIN(tx_p),
.OUTPUT_CLK(rx_clk_125),
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.D_OUT_0(pmd_data_tx)
);
SB_IO #(
.PIN_TYPE(`PIN_OUTPUT_ALWAYS | `PIN_OUTPUT_REGISTERED_INVERTED),
.IO_STANDARD("SB_LVDS_INPUT")
) data_txn_pin (
.PACKAGE_PIN(tx_n),
.OUTPUT_CLK(rx_clk_125),
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.D_OUT_0(pmd_data_tx)
);
`else
always @(posedge tx_clk) begin
tx_p <= pmd_data_tx;
tx_n <= ~pmd_data_tx;
end
`endif
`ifndef SYNTHESIS
reg [255:0] state_text;
input [13:0] delay;
always @(*) begin
case (state)
A: state_text = "A";
B: state_text = "B";
C: state_text = "C";
D: state_text = "D";
endcase
end
`endif
`DUMP(0)
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endmodule