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cvw/pipelined/src/uncore/ram.sv
David Harris 120fb7863f Reformatted MIT license to 95 characters
2022-01-07 12:58:40 +00:00

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///////////////////////////////////////////
// ram.sv
//
// Written: David_Harris@hmc.edu 9 January 2021
// Modified:
//
// Purpose: On-chip RAM, external to hart
//
// A component of the Wally configurable RISC-V project.
//
// Copyright (C) 2021 Harvey Mudd College & Oklahoma State University
//
// MIT LICENSE
// Permission is hereby granted, free of charge, to any person obtaining a copy of this
// software and associated documentation files (the "Software"), to deal in the Software
// without restriction, including without limitation the rights to use, copy, modify, merge,
// publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons
// to whom the Software is furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all copies or
// substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED,
// INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR
// PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
// BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
// TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE
// OR OTHER DEALINGS IN THE SOFTWARE.
////////////////////////////////////////////////////////////////////////////////////////////////
`include "wally-config.vh"
module ram #(parameter BASE=0, RANGE = 65535) (
input logic HCLK, HRESETn,
input logic HSELRam,
input logic [31:0] HADDR,
input logic HWRITE,
input logic HREADY,
input logic [1:0] HTRANS,
input logic [`XLEN-1:0] HWDATA,
output logic [`XLEN-1:0] HREADRam,
output logic HRESPRam, HREADYRam
);
localparam MemStartAddr = BASE>>(1+`XLEN/32);
localparam MemEndAddr = (RANGE+BASE)>>1+(`XLEN/32);
logic [`XLEN-1:0] RAM[BASE>>(1+`XLEN/32):(RANGE+BASE)>>1+(`XLEN/32)];
logic [31:0] HWADDR, A;
logic [`XLEN-1:0] HREADRam0;
logic prevHREADYRam, risingHREADYRam;
logic initTrans;
logic memwrite;
logic [3:0] busycount;
if(`FPGA) begin:ram
initial begin
//$readmemh(PRELOAD, RAM);
RAM[0] = 64'h94e1819300002197;
RAM[1] = 64'h4281420141014081;
RAM[2] = 64'h4481440143814301;
RAM[3] = 64'h4681460145814501;
RAM[4] = 64'h4881480147814701;
RAM[5] = 64'h4a814a0149814901;
RAM[6] = 64'h4c814c014b814b01;
RAM[7] = 64'h4e814e014d814d01;
RAM[8] = 64'h0110011b4f814f01;
RAM[9] = 64'h059b45011161016e;
RAM[10] = 64'h0004063705fe0010;
RAM[11] = 64'h05a000ef8006061b;
RAM[12] = 64'h0ff003930000100f;
RAM[13] = 64'h4e952e3110012e37;
RAM[14] = 64'hc602829b0053f2b7;
RAM[15] = 64'h2023fe02dfe312fd;
RAM[16] = 64'h829b0053f2b7007e;
RAM[17] = 64'hfe02dfe312fdc602;
RAM[18] = 64'h4de31efd000e2023;
RAM[19] = 64'h059bf1402573fdd0;
RAM[20] = 64'h0000061705e20870;
RAM[21] = 64'h0010029b01260613;
RAM[22] = 64'h11010002806702fe;
RAM[23] = 64'h84b2842ae426e822;
RAM[24] = 64'h892ee04aec064505;
RAM[25] = 64'h06e000ef07e000ef;
RAM[26] = 64'h979334fd02905563;
RAM[27] = 64'h07930177d4930204;
RAM[28] = 64'h4089093394be2004;
RAM[29] = 64'h04138522008905b3;
RAM[30] = 64'h19e3014000ef2004;
RAM[31] = 64'h64a2644260e2fe94;
RAM[32] = 64'h6749808261056902;
RAM[33] = 64'hdfed8b8510472783;
RAM[34] = 64'h2423479110a73823;
RAM[35] = 64'h10472783674910f7;
RAM[36] = 64'h20058693ffed8b89;
RAM[37] = 64'h05a1118737836749;
RAM[38] = 64'hfed59be3fef5bc23;
RAM[39] = 64'h1047278367498082;
RAM[40] = 64'h67c98082dfed8b85;
RAM[41] = 64'h0000808210a7a023;
end // initial begin
end // if (FPGA)
assign initTrans = HREADY & HSELRam & (HTRANS != 2'b00);
// *** this seems like a weird way to use reset
flopenr #(1) memwritereg(HCLK, 1'b0, initTrans | ~HRESETn, HSELRam & HWRITE, memwrite);
flopenr #(32) haddrreg(HCLK, 1'b0, initTrans | ~HRESETn, HADDR, A);
// busy FSM to extend READY signal
always_ff @(posedge HCLK, negedge HRESETn)
if (~HRESETn) begin
busycount <= 0;
HREADYRam <= #1 0;
end else begin
if (initTrans) begin
busycount <= 0;
HREADYRam <= #1 0;
end else if (~HREADYRam) begin
if (busycount == 0) begin // Ram latency, for testing purposes. *** test with different values such as 2
HREADYRam <= #1 1;
end else begin
busycount <= busycount + 1;
end
end
end
assign HRESPRam = 0; // OK
// Rising HREADY edge detector
// Indicates when ram is finishing up
// Needed because HREADY may go high for other reasons,
// and we only want to write data when finishing up.
flopr #(1) prevhreadyRamreg(HCLK,~HRESETn,HREADYRam,prevHREADYRam);
assign risingHREADYRam = HREADYRam & ~prevHREADYRam;
// Model memory read and write
/* -----\/----- EXCLUDED -----\/-----
integer index;
initial begin
for(index = MemStartAddr; index < MemEndAddr; index = index + 1) begin
RAM[index] <= {`XLEN{1'b0}};
end
end
-----/\----- EXCLUDED -----/\----- */
/* verilator lint_off WIDTH */
if (`XLEN == 64) begin:ramrw
always_ff @(posedge HCLK) begin
HWADDR <= #1 A;
HREADRam0 <= #1 RAM[A[31:3]];
if (memwrite & risingHREADYRam) RAM[HWADDR[31:3]] <= #1 HWDATA;
end
end else begin
always_ff @(posedge HCLK) begin:ramrw
HWADDR <= #1 A;
HREADRam0 <= #1 RAM[A[31:2]];
if (memwrite & risingHREADYRam) RAM[HWADDR[31:2]] <= #1 HWDATA;
end
end
/* verilator lint_on WIDTH */
//assign HREADRam = HREADYRam ? HREADRam0 : `XLEN'bz;
// *** Ross Thompson: removed tristate as fpga synthesis removes.
assign HREADRam = HREADRam0;
endmodule
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