/////////////////////////////////////////// // 1 port sram. // // Written: avercruysse@hmc.edu (Modified from ram1p1rwbe, by ross1728@gmail.com) // Created: 04 April 2023 // // Purpose: ram1p1wre, but without byte-enable. Used for icache data. // Be careful using this module, since coverage is turned off for (ce & we). // In read-only caches, we never get (we=1, ce=0), so this waiver is needed. // // Documentation: // // A component of the CORE-V-WALLY configurable RISC-V project. // // Copyright (C) 2021-23 Harvey Mudd College & Oklahoma State University // // SPDX-License-Identifier: Apache-2.0 WITH SHL-2.1 // // Licensed under the Solderpad Hardware License v 2.1 (the “License”); you may not use this file // except in compliance with the License, or, at your option, the Apache License version 2.0. You // may obtain a copy of the License at // // https://solderpad.org/licenses/SHL-2.1/ // // Unless required by applicable law or agreed to in writing, any work distributed under the // License is distributed on an “AS IS” BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, // either express or implied. See the License for the specific language governing permissions // and limitations under the License. //////////////////////////////////////////////////////////////////////////////////////////////// // WIDTH is number of bits in one "word" of the memory, DEPTH is number of such words `include "wally-config.vh" module ram1p1rwe #(parameter DEPTH=64, WIDTH=44) ( input logic clk, input logic ce, input logic [$clog2(DEPTH)-1:0] addr, input logic [WIDTH-1:0] din, input logic we, output logic [WIDTH-1:0] dout ); logic [WIDTH-1:0] RAM[DEPTH-1:0]; // *************************************************************************** // TRUE SRAM macro // *************************************************************************** if ((`USE_SRAM == 1) & (WIDTH == 128) & (DEPTH == 64)) begin // Cache data subarray // 64 x 128-bit SRAM ram1p1rwbe_64x128 sram1A (.CLK(clk), .CEB(~ce), .WEB(~we), .A(addr), .D(din), .BWEB('0), .Q(dout)); end else if ((`USE_SRAM == 1) & (WIDTH == 44) & (DEPTH == 64)) begin // RV64 cache tag // 64 x 44-bit SRAM ram1p1rwbe_64x44 sram1B (.CLK(clk), .CEB(~ce), .WEB(~we), .A(addr), .D(din), .BWEB('0), .Q(dout)); end else if ((`USE_SRAM == 1) & (WIDTH == 22) & (DEPTH == 64)) begin // RV32 cache tag // 64 x 22-bit SRAM ram1p1rwbe_64x22 sram1B (.CLK(clk), .CEB(~ce), .WEB(~we), .A(addr), .D(din), .BWEB('0), .Q(dout)); // *************************************************************************** // READ first SRAM model // *************************************************************************** end else begin: ram // *** Vivado is not implementing this as block ram for some reason. // The version with byte write enables it correctly infers block ram. integer i; // Read logic [$clog2(DEPTH)-1:0] addrd; flopen #($clog2(DEPTH)) adrreg(clk, ce, addr, addrd); assign dout = RAM[addrd]; /* // Read always_ff @(posedge clk) if(ce) dout <= #1 mem[addr]; */ // Write divided into part for bytes and part for extra msbs // Questa sim version 2022.3_2 does not allow multiple drivers for RAM when using always_ff. // Therefore these always blocks use the older always @(posedge clk) always @(posedge clk) // coverage off // ce only goes low when cachefsm is in READY state and Flush is asserted. // for read-only caches, we only goes high in the STATE_WRITE_LINE cachefsm state. // so we can never get we=1, ce=0 for I$. if (ce & we) // coverage on RAM[addr] <= #1 din; end endmodule