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//////////////////////////////////////////////////////////////////////
//// ////
//// Copyright (C) 2016 Authors and OPENCORES.ORG ////
//// ////
//// 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 ////
//// ////
//////////////////////////////////////////////////////////////////////
// --------------------------------------------------------------------
//
module
cummings_sync_r2w
#(
parameter ADDRSIZE = 4
)
(
output reg [ADDRSIZE:0] wq2_rptr,
input [ADDRSIZE:0] rptr,
input wclk,
input wrst_n
);
reg [ADDRSIZE:0] wq1_rptr;
always @(posedge wclk or negedge wrst_n)
if (!wrst_n)
{wq2_rptr,wq1_rptr} <= 0;
else
{wq2_rptr,wq1_rptr} <= {wq1_rptr,rptr};
endmodule
// --------------------------------------------------------------------
//
module
cummings_sync_w2r
#(
parameter ADDRSIZE = 4
)
(
output reg [ADDRSIZE:0] rq2_wptr,
input [ADDRSIZE:0] wptr,
input rclk,
input rrst_n
);
reg [ADDRSIZE:0] rq1_wptr;
always @(posedge rclk or negedge rrst_n)
if(!rrst_n)
{rq2_wptr,rq1_wptr} <= 0;
else
{rq2_wptr,rq1_wptr} <= {rq1_wptr,wptr};
endmodule
// --------------------------------------------------------------------
//
module
cummings_fifomem
#(
parameter DATASIZE = 8, // Memory data word width
parameter ADDRSIZE = 4 // Number of mem address bits
)
(
output [DATASIZE-1:0] rdata,
input [DATASIZE-1:0] wdata,
input [ADDRSIZE-1:0] waddr,
input [ADDRSIZE-1:0] raddr,
input wclken,
input wfull,
input wclk
);
// RTL Verilog memory model
localparam DEPTH = 1<<ADDRSIZE;
reg [DATASIZE-1:0] mem [0:DEPTH-1];
assign rdata = mem[raddr];
always @(posedge wclk)
if(wclken && !wfull)
mem[waddr] <= wdata;
endmodule
// --------------------------------------------------------------------
//
module
cummings_rptr_empty
#(
parameter ADDRSIZE = 4
)
(
output reg rempty,
output [ADDRSIZE-1:0] raddr,
output reg [ADDRSIZE :0] rptr,
input [ADDRSIZE :0] rq2_wptr,
input rinc,
input rclk,
input rrst_n
);
reg [ADDRSIZE:0] rbin;
wire [ADDRSIZE:0] rgraynext, rbinnext;
//-------------------
// GRAYSTYLE2 pointer
//-------------------
always @(posedge rclk or negedge rrst_n)
if(!rrst_n)
{rbin, rptr} <= 0;
else
{rbin, rptr} <= {rbinnext, rgraynext};
// Memory read-address pointer (okay to use binary to address memory)
assign raddr = rbin[ADDRSIZE-1:0];
assign rbinnext = rbin + (rinc & ~rempty);
assign rgraynext = (rbinnext>>1) ^ rbinnext;
//---------------------------------------------------------------
// FIFO empty when the next rptr == synchronized wptr or on reset
//---------------------------------------------------------------
assign rempty_val = (rgraynext == rq2_wptr);
always @(posedge rclk or negedge rrst_n)
if(!rrst_n)
rempty <= 1'b1;
else
rempty <= rempty_val;
endmodule
// --------------------------------------------------------------------
//
module
cummings_wptr_full
#(
parameter ADDRSIZE = 4
)
(
output reg wfull,
output [ADDRSIZE-1:0] waddr,
output reg [ADDRSIZE :0] wptr,
input [ADDRSIZE :0] wq2_rptr,
input winc,
input wclk,
input wrst_n
);
reg [ADDRSIZE:0] wbin;
wire [ADDRSIZE:0] wgraynext, wbinnext;
// GRAYSTYLE2 pointer
always @(posedge wclk or negedge wrst_n)
if(!wrst_n)
{wbin, wptr} <= 0;
else
{wbin, wptr} <= {wbinnext, wgraynext};
// Memory write-address pointer (okay to use binary to address memory)
assign waddr = wbin[ADDRSIZE-1:0];
assign wbinnext = wbin + (winc & ~wfull);
assign wgraynext = (wbinnext>>1) ^ wbinnext;
//------------------------------------------------------------------
// Simplified version of the three necessary full-tests:
// assign wfull_val=((wgnext[ADDRSIZE] !=wq2_rptr[ADDRSIZE] ) &&
// (wgnext[ADDRSIZE-1] !=wq2_rptr[ADDRSIZE-1]) &&
// (wgnext[ADDRSIZE-2:0]==wq2_rptr[ADDRSIZE-2:0]));
//------------------------------------------------------------------
assign wfull_val = (wgraynext == {~wq2_rptr[ADDRSIZE:ADDRSIZE-1], wq2_rptr[ADDRSIZE-2:0]});
always @(posedge wclk or negedge wrst_n)
if(!wrst_n)
wfull <= 1'b0;
else
wfull <= wfull_val;
endmodule
// --------------------------------------------------------------------
//
module
cummings_fifo1
#(
parameter DSIZE = 8,
parameter ASIZE = 4
)
(
output [DSIZE-1:0] rdata,
output wfull,
output rempty,
input [DSIZE-1:0] wdata,
input winc,
input wclk,
input wrst_n,
input rinc,
input rclk,
input rrst_n
);
wire [ASIZE-1:0] waddr, raddr;
wire [ASIZE:0] wptr, rptr, wq2_rptr, rq2_wptr;
cummings_sync_r2w sync_r2w (.wq2_rptr(wq2_rptr), .rptr(rptr),
.wclk(wclk), .wrst_n(wrst_n));
cummings_sync_w2r sync_w2r (.rq2_wptr(rq2_wptr), .wptr(wptr),
.rclk(rclk), .rrst_n(rrst_n));
cummings_fifomem #(DSIZE, ASIZE) fifomem
(.rdata(rdata), .wdata(wdata),
.waddr(waddr), .raddr(raddr),
.wclken(winc), .wfull(wfull),
.wclk(wclk));
cummings_rptr_empty #(ASIZE) rptr_empty
(.rempty(rempty),
.raddr(raddr),
.rptr(rptr), .rq2_wptr(rq2_wptr),
.rinc(rinc), .rclk(rclk),
.rrst_n(rrst_n));
cummings_wptr_full #(ASIZE) wptr_full
(.wfull(wfull), .waddr(waddr),
.wptr(wptr), .wq2_rptr(wq2_rptr),
.winc(winc), .wclk(wclk),
.wrst_n(wrst_n));
endmodule
// --------------------------------------------------------------------
//
// --------------------------------------------------------------------
//
// --------------------------------------------------------------------
module
async_fifo
#(
W,
D
)
(
output wr_full,
input [W-1:0] wr_data,
input wr_en,
input wr_clk,
input wr_reset,
output rd_empty,
output [W-1:0] rd_data,
input rd_en,
input rd_clk,
input rd_reset
);
// --------------------------------------------------------------------
//
cummings_fifo1 #(.DSIZE(W), .ASIZE($clog2(D)))
cummings_fifo1_i
(
.rdata(rd_data),
.wfull(wr_full),
.rempty(rd_empty),
.wdata(wr_data),
.winc(wr_en),
.wclk(wr_clk),
.wrst_n(~wr_reset),
.rinc(rd_en),
.rclk(rd_clk),
.rrst_n(~rd_reset)
);
// --------------------------------------------------------------------
// synthesis translate_off
always_ff @(posedge wr_clk)
if(wr_en & wr_full)
$stop;
always_ff @(posedge rd_clk)
if(rd_en & rd_empty)
$stop;
// synthesis translate_on
// --------------------------------------------------------------------
// --------------------------------------------------------------------
//
endmodule