pluto_hdl_adi/library/util_wfifo/util_wfifo.v

318 lines
11 KiB
Verilog

// ***************************************************************************
// ***************************************************************************
// Copyright 2014 - 2017 (c) Analog Devices, Inc. All rights reserved.
//
// This core 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.
//
// Redistribution and use of source or resulting binaries, with or without modification
// of this file, are permitted under one of the following two license terms:
//
// 1. The GNU General Public License version 2 as published by the
// Free Software Foundation, which can be found in the top level directory of
// the repository (LICENSE_GPL2), and at: <https://www.gnu.org/licenses/old-licenses/gpl-2.0.html>
//
// OR
//
// 2. An ADI specific BSD license as noted in the top level directory, or on-line at:
// https://github.com/analogdevicesinc/hdl/blob/master/LICENSE_ADIBSD
// This will allow to generate bit files and not release the source code,
// as long as it attaches to an ADI device.
//
// ***************************************************************************
// ***************************************************************************
`timescale 1ns/100ps
module util_wfifo #(
parameter NUM_OF_CHANNELS = 4,
parameter DIN_DATA_WIDTH = 32,
parameter DOUT_DATA_WIDTH = 64,
parameter DIN_ADDRESS_WIDTH = 8) (
// d-in interface
input din_rst,
input din_clk,
input din_enable_0,
input din_valid_0,
input [DIN_DATA_WIDTH-1:0] din_data_0,
input din_enable_1,
input din_valid_1,
input [DIN_DATA_WIDTH-1:0] din_data_1,
input din_enable_2,
input din_valid_2,
input [DIN_DATA_WIDTH-1:0] din_data_2,
input din_enable_3,
input din_valid_3,
input [DIN_DATA_WIDTH-1:0] din_data_3,
input din_enable_4,
input din_valid_4,
input [DIN_DATA_WIDTH-1:0] din_data_4,
input din_enable_5,
input din_valid_5,
input [DIN_DATA_WIDTH-1:0] din_data_5,
input din_enable_6,
input din_valid_6,
input [DIN_DATA_WIDTH-1:0] din_data_6,
input din_enable_7,
input din_valid_7,
input [DIN_DATA_WIDTH-1:0] din_data_7,
output reg din_ovf,
// d-out interface
input dout_rstn,
input dout_clk,
output dout_enable_0,
output dout_valid_0,
output [DOUT_DATA_WIDTH-1:0] dout_data_0,
output dout_enable_1,
output dout_valid_1,
output [DOUT_DATA_WIDTH-1:0] dout_data_1,
output dout_enable_2,
output dout_valid_2,
output [DOUT_DATA_WIDTH-1:0] dout_data_2,
output dout_enable_3,
output dout_valid_3,
output [DOUT_DATA_WIDTH-1:0] dout_data_3,
output dout_enable_4,
output dout_valid_4,
output [DOUT_DATA_WIDTH-1:0] dout_data_4,
output dout_enable_5,
output dout_valid_5,
output [DOUT_DATA_WIDTH-1:0] dout_data_5,
output dout_enable_6,
output dout_valid_6,
output [DOUT_DATA_WIDTH-1:0] dout_data_6,
output dout_enable_7,
output dout_valid_7,
output [DOUT_DATA_WIDTH-1:0] dout_data_7,
input dout_ovf);
localparam M_MEM_RATIO = DOUT_DATA_WIDTH/DIN_DATA_WIDTH;
localparam ADDRESS_WIDTH = (DIN_ADDRESS_WIDTH > 4) ? DIN_ADDRESS_WIDTH : 4;
localparam DATA_WIDTH = DOUT_DATA_WIDTH * NUM_OF_CHANNELS;
localparam T_DIN_DATA_WIDTH = DIN_DATA_WIDTH * 8;
localparam T_DOUT_DATA_WIDTH = DOUT_DATA_WIDTH * 8;
// internal registers
reg [(DATA_WIDTH-1):0] din_wdata = 'd0;
reg [ 7:0] din_enable = 'd0;
reg [ 2:0] din_dcnt = 'd0;
reg din_wr = 'd0;
reg [(ADDRESS_WIDTH-1):0] din_waddr = 'd0;
reg din_req_t = 'd0;
reg [(ADDRESS_WIDTH-4):0] din_rinit = 'd0;
reg din_ovf_m1 = 'd0;
reg dout_req_t_m1 = 'd0;
reg dout_req_t_m2 = 'd0;
reg dout_req_t_m3 = 'd0;
reg dout_req_t = 'd0;
reg [(ADDRESS_WIDTH-4):0] dout_rinit = 'd0;
reg dout_ovf_d = 'd0;
reg [ 3:0] dout_req_cnt = 'd0;
reg [(ADDRESS_WIDTH-1):0] dout_raddr = 'd8;
reg dout_rd_d = 'd0;
reg dout_valid = 'd0;
reg [ 7:0] dout_enable_m1 = 'd0;
reg [ 7:0] dout_enable = 'd0;
reg [(DATA_WIDTH-1):0] dout_rdata = 'd0;
// internal signals
wire [ 7:0] din_enable_s;
wire [ 7:0] din_valid_s;
wire [(T_DIN_DATA_WIDTH-1):0] din_data_s;
wire dout_req_t_s;
wire [(DATA_WIDTH-1):0] dout_rdata_s;
wire [(T_DOUT_DATA_WIDTH+1):0] dout_data_s;
// variables
genvar n;
// concat signals, valid_0 must always be active
assign din_enable_s = { din_enable_7, din_enable_6, din_enable_5, din_enable_4,
din_enable_3, din_enable_2, din_enable_1, din_enable_0};
assign din_valid_s = { din_valid_7, din_valid_6, din_valid_5, din_valid_4,
din_valid_3, din_valid_2, din_valid_1, din_valid_0};
assign din_data_s = { din_data_7, din_data_6, din_data_5, din_data_4,
din_data_3, din_data_2, din_data_1, din_data_0};
// simple data transfer-- no ovf/unf handling- read-bw > write-bw (equal will NOT work)
// dout_width >= din_width only-
generate
for (n = 0; n < NUM_OF_CHANNELS; n = n + 1) begin: g_in
if (M_MEM_RATIO == 1) begin
always @(posedge din_clk) begin
if (din_valid_s[n] == 1'b1) begin
din_wdata[((DOUT_DATA_WIDTH*(n+1))-1):(DOUT_DATA_WIDTH*n)] <=
din_data_s[((DIN_DATA_WIDTH*(n+1))-1):(DIN_DATA_WIDTH*n)];
end
end
end else begin
always @(posedge din_clk) begin
if (din_valid_s[n] == 1'b1) begin
din_wdata[((DOUT_DATA_WIDTH*(n+1))-1):(DOUT_DATA_WIDTH*n)] <=
{din_data_s[((DIN_DATA_WIDTH*(n+1))-1):(DIN_DATA_WIDTH*n)],
din_wdata[((DOUT_DATA_WIDTH*(n+1))-1):(DIN_DATA_WIDTH+(DOUT_DATA_WIDTH*n))]};
end
end
end
end
endgenerate
always @(posedge din_clk) begin
if (din_rst == 1'b1) begin
din_enable <= 8'd0;
din_dcnt <= 3'd0;
din_wr <= 1'd0;
din_waddr <= 'd0;
din_req_t <= 1'd0;
din_rinit <= 'd0;
din_ovf_m1 <= 'd0;
din_ovf <= 'd0;
end else begin
din_enable <= din_enable_s;
if (din_valid_s[0] == 1'b1) begin
din_dcnt <= din_dcnt + 1'b1;
end
case (M_MEM_RATIO)
8: din_wr <= din_valid_s[0] & din_dcnt[0] & din_dcnt[1] & din_dcnt[2];
4: din_wr <= din_valid_s[0] & din_dcnt[0] & din_dcnt[1];
2: din_wr <= din_valid_s[0] & din_dcnt[0];
default: din_wr <= din_valid_s[0];
endcase
if (din_wr == 1'b1) begin
din_waddr <= din_waddr + 1'b1;
end
if ((din_wr == 1'b1) && (din_waddr[2:0] == 3'd7)) begin
din_req_t <= ~din_req_t;
din_rinit <= din_waddr[(ADDRESS_WIDTH-1):3];
end
din_ovf_m1 <= dout_ovf_d;
din_ovf <= din_ovf_m1;
end
end
// read interface (bus expansion and/or clock conversion)
assign dout_req_t_s = dout_req_t_m3 ^ dout_req_t_m2;
always @(posedge dout_clk or negedge dout_rstn) begin
if (dout_rstn == 1'b0) begin
dout_req_t_m1 <= 'd0;
dout_req_t_m2 <= 'd0;
dout_req_t_m3 <= 'd0;
dout_req_t <= 'd0;
dout_rinit <= 'd0;
dout_ovf_d <= 'd0;
end else begin
dout_req_t_m1 <= din_req_t;
dout_req_t_m2 <= dout_req_t_m1;
dout_req_t_m3 <= dout_req_t_m2;
dout_req_t <= dout_req_t_s;
if (dout_req_t_s == 1'b1) begin
dout_rinit <= din_rinit;
end
dout_ovf_d <= dout_ovf;
end
end
always @(posedge dout_clk or negedge dout_rstn) begin
if (dout_rstn == 1'b0) begin
dout_req_cnt <= 'd0;
dout_raddr <= 'd8;
dout_rd_d <= 'd0;
dout_valid <= 'd0;
end else begin
if (dout_req_t == 1'b1) begin
dout_req_cnt <= 4'h8;
dout_raddr <= {dout_rinit, 3'd0};
end else if (dout_req_cnt[3] == 1'b1) begin
dout_req_cnt <= dout_req_cnt + 1'b1;
dout_raddr <= dout_raddr + 1'b1;
end
dout_rd_d <= dout_req_cnt[3];
dout_valid <= dout_rd_d;
end
end
always @(posedge dout_clk or negedge dout_rstn) begin
if (dout_rstn == 1'b0) begin
dout_enable_m1 <= 'd0;
dout_enable <= 'd0;
end else begin
dout_enable_m1 <= din_enable;
dout_enable <= dout_enable_m1;
end
end
always @(posedge dout_clk) begin
dout_rdata <= dout_rdata_s;
end
generate
if (NUM_OF_CHANNELS >= 8) begin
assign dout_data_s = dout_rdata;
end else begin
assign dout_data_s[(T_DOUT_DATA_WIDTH+1):DATA_WIDTH] = 'd0;
assign dout_data_s[(DATA_WIDTH-1):0] = dout_rdata;
end
endgenerate
assign dout_enable_7 = dout_enable[7];
assign dout_valid_7 = dout_valid;
assign dout_data_7 = dout_data_s[((DOUT_DATA_WIDTH*8)-1):(DOUT_DATA_WIDTH*7)];
assign dout_enable_6 = dout_enable[6];
assign dout_valid_6 = dout_valid;
assign dout_data_6 = dout_data_s[((DOUT_DATA_WIDTH*7)-1):(DOUT_DATA_WIDTH*6)];
assign dout_enable_5 = dout_enable[5];
assign dout_valid_5 = dout_valid;
assign dout_data_5 = dout_data_s[((DOUT_DATA_WIDTH*6)-1):(DOUT_DATA_WIDTH*5)];
assign dout_enable_4 = dout_enable[4];
assign dout_valid_4 = dout_valid;
assign dout_data_4 = dout_data_s[((DOUT_DATA_WIDTH*5)-1):(DOUT_DATA_WIDTH*4)];
assign dout_enable_3 = dout_enable[3];
assign dout_valid_3 = dout_valid;
assign dout_data_3 = dout_data_s[((DOUT_DATA_WIDTH*4)-1):(DOUT_DATA_WIDTH*3)];
assign dout_enable_2 = dout_enable[2];
assign dout_valid_2 = dout_valid;
assign dout_data_2 = dout_data_s[((DOUT_DATA_WIDTH*3)-1):(DOUT_DATA_WIDTH*2)];
assign dout_enable_1 = dout_enable[1];
assign dout_valid_1 = dout_valid;
assign dout_data_1 = dout_data_s[((DOUT_DATA_WIDTH*2)-1):(DOUT_DATA_WIDTH*1)];
assign dout_enable_0 = dout_enable[0];
assign dout_valid_0 = dout_valid;
assign dout_data_0 = dout_data_s[((DOUT_DATA_WIDTH*1)-1):(DOUT_DATA_WIDTH*0)];
// instantiations
ad_mem #(.ADDRESS_WIDTH(ADDRESS_WIDTH), .DATA_WIDTH(DATA_WIDTH)) i_mem (
.clka (din_clk),
.wea (din_wr),
.addra (din_waddr),
.dina (din_wdata),
.clkb (dout_clk),
.addrb (dout_raddr),
.doutb (dout_rdata_s));
endmodule
// ***************************************************************************
// ***************************************************************************