blob: 82f0d44416f96ca4d11dddb8039a7f7c9dddc14f [file] [log] [blame]
////////////////////////////////////////////////////////////////////////////
// SPDX-FileCopyrightText: 2021 , Dinesh Annayya
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// 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.
// SPDX-License-Identifier: Apache-2.0
// SPDX-FileContributor: Modified by Dinesh Annayya <dinesha@opencores.org>
//////////////////////////////////////////////////////////////////////
//// ////
//// Standalone User validation Test bench ////
//// ////
//// This file is part of the YIFive cores project ////
//// https://github.com/dineshannayya/yifive_r0.git ////
//// http://www.opencores.org/cores/yifive/ ////
//// ////
//// Description ////
//// This is a standalone test bench to validate the ////
//// Digital core. ////
//// 1. User Risc core is booted using compiled code of ////
//// user_risc_boot.c ////
//// 2. User Risc core uses Serial Flash and SDRAM to boot ////
//// 3. After successful boot, Risc core will write signature ////
//// in to user register from 0x3000_0018 to 0x3000_002C ////
//// 4. Through the External Wishbone Interface we read back ////
//// and validate the user register to declared pass fail ////
//// ////
//// To Do: ////
//// nothing ////
//// ////
//// Author(s): ////
//// - Dinesh Annayya, dinesha@opencores.org ////
//// ////
//// Revision : ////
//// 0.1 - 16th Feb 2021, Dinesh A ////
//// ////
//////////////////////////////////////////////////////////////////////
//// ////
//// Copyright (C) 2000 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 ////
//// ////
//////////////////////////////////////////////////////////////////////
`default_nettype wire
`timescale 1 ns / 1 ns
`include "s25fl256s.sv"
`include "uprj_netlists.v"
`include "mt48lc8m8a2.v"
module user_risc_boot_tb;
reg clock;
reg wb_rst_i;
reg power1, power2;
reg power3, power4;
reg wbd_ext_cyc_i; // strobe/request
reg wbd_ext_stb_i; // strobe/request
reg [31:0] wbd_ext_adr_i; // address
reg wbd_ext_we_i; // write
reg [31:0] wbd_ext_dat_i; // data output
reg [3:0] wbd_ext_sel_i; // byte enable
wire [31:0] wbd_ext_dat_o; // data input
wire wbd_ext_ack_o; // acknowlegement
wire wbd_ext_err_o; // error
// User I/O
wire [37:0] io_oeb;
wire [37:0] io_out;
wire [37:0] io_in;
wire gpio;
wire [37:0] mprj_io;
wire [7:0] mprj_io_0;
reg test_fail;
reg [31:0] read_data;
// External clock is used by default. Make this artificially fast for the
// simulation. Normally this would be a slow clock and the digital PLL
// would be the fast clock.
always #12.5 clock <= (clock === 1'b0);
initial begin
clock = 0;
wbd_ext_cyc_i ='h0; // strobe/request
wbd_ext_stb_i ='h0; // strobe/request
wbd_ext_adr_i ='h0; // address
wbd_ext_we_i ='h0; // write
wbd_ext_dat_i ='h0; // data output
wbd_ext_sel_i ='h0; // byte enable
end
`ifdef WFDUMP
initial begin
$dumpfile("risc_boot.vcd");
$dumpvars(2, user_risc_boot_tb);
end
`endif
initial begin
#200; // Wait for reset removal
repeat (10) @(posedge clock);
$display("Monitor: Standalone User Risc Boot Test Started");
// Remove Wb Reset
wb_user_core_write('h3080_0000,'h1);
#1;
//------------ SDRAM Config - 2
wb_user_core_write('h3000_0014,'h100_019E);
repeat (2) @(posedge clock);
#1;
//------------ SDRAM Config - 1
wb_user_core_write('h3000_0010,'h2F17_2242);
repeat (2) @(posedge clock);
#1;
// Remove all the reset
wb_user_core_write('h3080_0000,'hF);
// Repeat cycles of 1000 clock edges as needed to complete testbench
repeat (30) begin
repeat (1000) @(posedge clock);
// $display("+1000 cycles");
end
$display("Monitor: Reading Back the expected value");
// User RISC core expect to write these value in global
// register, read back and decide on pass fail
// 0x30000018 = 0x11223344;
// 0x3000001C = 0x22334455;
// 0x30000020 = 0x33445566;
// 0x30000024 = 0x44556677;
// 0x30000028 = 0x55667788;
// 0x3000002C = 0x66778899;
test_fail = 0;
wb_user_core_read(32'h30000018,read_data);
if(read_data != 32'h11223344) test_fail = 1;
wb_user_core_read(32'h3000001C,read_data);
if(read_data != 32'h22334455) test_fail = 1;
wb_user_core_read(32'h30000020,read_data);
if(read_data != 32'h33445566) test_fail = 1;
wb_user_core_read(32'h30000024,read_data);
if(read_data!= 32'h44556677) test_fail = 1;
wb_user_core_read(32'h30000028,read_data);
if(read_data!= 32'h55667788) test_fail = 1;
wb_user_core_read(32'h3000002C,read_data) ;
if(read_data != 32'h66778899) test_fail = 1;
$display("###################################################");
if(test_fail == 0) begin
`ifdef GL
$display("Monitor: Standalone User Risc Boot (GL) Passed");
`else
$display("Monitor: Standalone User Risc Boot (RTL) Passed");
`endif
end else begin
`ifdef GL
$display("Monitor: Standalone User Risc Boot (GL) Failed");
`else
$display("Monitor: Standalone User Risc Boot (RTL) Failed");
`endif
end
$display("###################################################");
$finish;
end
initial begin
wb_rst_i <= 1'b1;
#100;
wb_rst_i <= 1'b0; // Release reset
end
wire USER_VDD1V8 = 1'b1;
wire VSS = 1'b0;
user_project_wrapper u_top(
`ifdef USE_POWER_PINS
.vccd1(USER_VDD1V8), // User area 1 1.8V supply
.vssd1(VSS), // User area 1 digital ground
`endif
.wb_clk_i (clock), // System clock
.user_clock2 (1'b1), // Real-time clock
.wb_rst_i (wb_rst_i), // Regular Reset signal
.wbs_cyc_i (wbd_ext_cyc_i), // strobe/request
.wbs_stb_i (wbd_ext_stb_i), // strobe/request
.wbs_adr_i (wbd_ext_adr_i), // address
.wbs_we_i (wbd_ext_we_i), // write
.wbs_dat_i (wbd_ext_dat_i), // data output
.wbs_sel_i (wbd_ext_sel_i), // byte enable
.wbs_dat_o (wbd_ext_dat_o), // data input
.wbs_ack_o (wbd_ext_ack_o), // acknowlegement
// Logic Analyzer Signals
.la_data_in ('0) ,
.la_data_out (),
.la_oenb ('0),
// IOs
.io_in (io_in) ,
.io_out (io_out) ,
.io_oeb (io_oeb) ,
.user_irq ()
);
`ifndef GL // Drive Power for Hold Fix Buf
// All standard cell need power hook-up for functionality work
initial begin
force u_top.u_spi_master.u_delay1_sdio0.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_delay1_sdio0.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_delay1_sdio0.VGND =VSS;
force u_top.u_spi_master.u_delay1_sdio0.VNB = VSS;
force u_top.u_spi_master.u_delay2_sdio0.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_delay2_sdio0.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_delay2_sdio0.VGND =VSS;
force u_top.u_spi_master.u_delay2_sdio0.VNB = VSS;
force u_top.u_spi_master.u_buf_sdio0.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_buf_sdio0.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_buf_sdio0.VGND =VSS;
force u_top.u_spi_master.u_buf_sdio0.VNB =VSS;
force u_top.u_spi_master.u_delay1_sdio1.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_delay1_sdio1.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_delay1_sdio1.VGND =VSS;
force u_top.u_spi_master.u_delay1_sdio1.VNB = VSS;
force u_top.u_spi_master.u_delay2_sdio1.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_delay2_sdio1.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_delay2_sdio1.VGND =VSS;
force u_top.u_spi_master.u_delay2_sdio1.VNB = VSS;
force u_top.u_spi_master.u_buf_sdio1.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_buf_sdio1.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_buf_sdio1.VGND =VSS;
force u_top.u_spi_master.u_buf_sdio1.VNB =VSS;
force u_top.u_spi_master.u_delay1_sdio2.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_delay1_sdio2.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_delay1_sdio2.VGND =VSS;
force u_top.u_spi_master.u_delay1_sdio2.VNB = VSS;
force u_top.u_spi_master.u_delay2_sdio2.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_delay2_sdio2.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_delay2_sdio2.VGND =VSS;
force u_top.u_spi_master.u_delay2_sdio2.VNB = VSS;
force u_top.u_spi_master.u_buf_sdio2.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_buf_sdio2.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_buf_sdio2.VGND =VSS;
force u_top.u_spi_master.u_buf_sdio2.VNB =VSS;
force u_top.u_spi_master.u_delay1_sdio3.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_delay1_sdio3.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_delay1_sdio3.VGND =VSS;
force u_top.u_spi_master.u_delay1_sdio3.VNB = VSS;
force u_top.u_spi_master.u_delay2_sdio3.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_delay2_sdio3.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_delay2_sdio3.VGND =VSS;
force u_top.u_spi_master.u_delay2_sdio3.VNB = VSS;
force u_top.u_spi_master.u_buf_sdio3.VPWR =USER_VDD1V8;
force u_top.u_spi_master.u_buf_sdio3.VPB =USER_VDD1V8;
force u_top.u_spi_master.u_buf_sdio3.VGND =VSS;
force u_top.u_spi_master.u_buf_sdio3.VNB =VSS;
force u_top.u_uart_i2c_usb.u_uart_core.u_lineclk_buf.VPWR =USER_VDD1V8;
force u_top.u_uart_i2c_usb.u_uart_core.u_lineclk_buf.VPB =USER_VDD1V8;
force u_top.u_uart_i2c_usb.u_uart_core.u_lineclk_buf.VGND =VSS;
force u_top.u_uart_i2c_usb.u_uart_core.u_lineclk_buf.VNB = VSS;
force u_top.u_wb_host.u_buf_wb_rst.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_buf_wb_rst.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_buf_wb_rst.VGND =VSS;
force u_top.u_wb_host.u_buf_wb_rst.VNB = VSS;
force u_top.u_wb_host.u_buf_cpu_rst.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_buf_cpu_rst.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_buf_cpu_rst.VGND =VSS;
force u_top.u_wb_host.u_buf_cpu_rst.VNB = VSS;
force u_top.u_wb_host.u_buf_spi_rst.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_buf_spi_rst.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_buf_spi_rst.VGND =VSS;
force u_top.u_wb_host.u_buf_spi_rst.VNB = VSS;
force u_top.u_wb_host.u_buf_sdram_rst.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_buf_sdram_rst.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_buf_sdram_rst.VGND =VSS;
force u_top.u_wb_host.u_buf_sdram_rst.VNB = VSS;
force u_top.u_wb_host.u_buf_uart_rst.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_buf_uart_rst.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_buf_uart_rst.VGND =VSS;
force u_top.u_wb_host.u_buf_uart_rst.VNB = VSS;
force u_top.u_wb_host.u_buf_i2cm_rst.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_buf_i2cm_rst.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_buf_i2cm_rst.VGND =VSS;
force u_top.u_wb_host.u_buf_i2cm_rst.VNB = VSS;
force u_top.u_wb_host.u_buf_usb_rst.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_buf_usb_rst.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_buf_usb_rst.VGND =VSS;
force u_top.u_wb_host.u_buf_usb_rst.VNB = VSS;
force u_top.u_wb_host.u_clkbuf_sdram.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_clkbuf_sdram.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_clkbuf_sdram.VGND =VSS;
force u_top.u_wb_host.u_clkbuf_sdram.VNB = VSS;
force u_top.u_wb_host.u_clkbuf_cpu.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_clkbuf_cpu.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_clkbuf_cpu.VGND =VSS;
force u_top.u_wb_host.u_clkbuf_cpu.VNB = VSS;
force u_top.u_wb_host.u_clkbuf_rtc.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_clkbuf_rtc.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_clkbuf_rtc.VGND =VSS;
force u_top.u_wb_host.u_clkbuf_rtc.VNB = VSS;
force u_top.u_wb_host.u_clkbuf_usb.VPWR =USER_VDD1V8;
force u_top.u_wb_host.u_clkbuf_usb.VPB =USER_VDD1V8;
force u_top.u_wb_host.u_clkbuf_usb.VGND =VSS;
force u_top.u_wb_host.u_clkbuf_usb.VNB = VSS;
end
`endif
//------------------------------------------------------
// Integrate the Serial flash with qurd support to
// user core using the gpio pads
// ----------------------------------------------------
wire flash_clk = io_out[30];
wire flash_csb = io_out[31];
// Creating Pad Delay
wire #1 io_oeb_32 = io_oeb[32];
wire #1 io_oeb_33 = io_oeb[33];
wire #1 io_oeb_34 = io_oeb[34];
wire #1 io_oeb_35 = io_oeb[35];
tri flash_io0 = (io_oeb_32== 1'b0) ? io_out[32] : 1'bz;
tri flash_io1 = (io_oeb_33== 1'b0) ? io_out[33] : 1'bz;
tri flash_io2 = (io_oeb_34== 1'b0) ? io_out[34] : 1'bz;
tri flash_io3 = (io_oeb_35== 1'b0) ? io_out[35] : 1'bz;
assign io_in[32] = flash_io0;
assign io_in[33] = flash_io1;
assign io_in[34] = flash_io2;
assign io_in[35] = flash_io3;
// Quard flash
s25fl256s #(.mem_file_name("user_risc_boot.hex"),
.otp_file_name("none"),
.TimingModel("S25FL512SAGMFI010_F_30pF"))
u_spi_flash_256mb (
// Data Inputs/Outputs
.SI (flash_io0),
.SO (flash_io1),
// Controls
.SCK (flash_clk),
.CSNeg (flash_csb),
.WPNeg (flash_io2),
.HOLDNeg (flash_io3),
.RSTNeg (!wb_rst_i)
);
//------------------------------------------------
// Integrate the SDRAM 8 BIT Memory
// -----------------------------------------------
wire [7:0] Dq ; // SDRAM Read/Write Data Bus
wire [0:0] sdr_dqm ; // SDRAM DATA Mask
wire [1:0] sdr_ba ; // SDRAM Bank Select
wire [12:0] sdr_addr ; // SDRAM ADRESS
wire sdr_cs_n ; // chip select
wire sdr_cke ; // clock gate
wire sdr_ras_n ; // ras
wire sdr_cas_n ; // cas
wire sdr_we_n ; // write enable
wire sdram_clk ;
assign Dq[7:0] = (io_oeb[7:0] == 8'h0) ? io_out [7:0] : 8'hZZ;
assign sdr_addr[12:0] = io_out [20:8] ;
assign sdr_ba[1:0] = io_out [22:21] ;
assign sdr_dqm[0] = io_out [23] ;
assign sdr_we_n = io_out [24] ;
assign sdr_cas_n = io_out [25] ;
assign sdr_ras_n = io_out [26] ;
assign sdr_cs_n = io_out [27] ;
assign sdr_cke = io_out [28] ;
assign sdram_clk = io_out [29] ;
assign io_in[29] = sdram_clk;
assign #(1) io_in[7:0] = Dq;
// to fix the sdram interface timing issue
wire #(1) sdram_clk_d = sdram_clk;
// SDRAM 8bit
mt48lc8m8a2 #(.data_bits(8)) u_sdram8 (
.Dq (Dq ) ,
.Addr (sdr_addr[11:0] ),
.Ba (sdr_ba ),
.Clk (sdram_clk_d ),
.Cke (sdr_cke ),
.Cs_n (sdr_cs_n ),
.Ras_n (sdr_ras_n ),
.Cas_n (sdr_cas_n ),
.We_n (sdr_we_n ),
.Dqm (sdr_dqm )
);
task wb_user_core_write;
input [31:0] address;
input [31:0] data;
begin
repeat (1) @(posedge clock);
#1;
wbd_ext_adr_i =address; // address
wbd_ext_we_i ='h1; // write
wbd_ext_dat_i =data; // data output
wbd_ext_sel_i ='hF; // byte enable
wbd_ext_cyc_i ='h1; // strobe/request
wbd_ext_stb_i ='h1; // strobe/request
wait(wbd_ext_ack_o == 1);
repeat (1) @(posedge clock);
#1;
wbd_ext_cyc_i ='h0; // strobe/request
wbd_ext_stb_i ='h0; // strobe/request
wbd_ext_adr_i ='h0; // address
wbd_ext_we_i ='h0; // write
wbd_ext_dat_i ='h0; // data output
wbd_ext_sel_i ='h0; // byte enable
$display("DEBUG WB USER ACCESS WRITE Address : %x, Data : %x",address,data);
repeat (2) @(posedge clock);
end
endtask
task wb_user_core_read;
input [31:0] address;
output [31:0] data;
reg [31:0] data;
begin
repeat (1) @(posedge clock);
#1;
wbd_ext_adr_i =address; // address
wbd_ext_we_i ='h0; // write
wbd_ext_dat_i ='0; // data output
wbd_ext_sel_i ='hF; // byte enable
wbd_ext_cyc_i ='h1; // strobe/request
wbd_ext_stb_i ='h1; // strobe/request
wait(wbd_ext_ack_o == 1);
data = wbd_ext_dat_o;
repeat (1) @(posedge clock);
#1;
wbd_ext_cyc_i ='h0; // strobe/request
wbd_ext_stb_i ='h0; // strobe/request
wbd_ext_adr_i ='h0; // address
wbd_ext_we_i ='h0; // write
wbd_ext_dat_i ='h0; // data output
wbd_ext_sel_i ='h0; // byte enable
$display("DEBUG WB USER ACCESS READ Address : %x, Data : %x",address,data);
repeat (2) @(posedge clock);
end
endtask
`ifdef GL
wire wbd_spi_stb_i = u_top.u_spi_master.wbd_stb_i;
wire wbd_spi_ack_o = u_top.u_spi_master.wbd_ack_o;
wire wbd_spi_we_i = u_top.u_spi_master.wbd_we_i;
wire [31:0] wbd_spi_adr_i = u_top.u_spi_master.wbd_adr_i;
wire [31:0] wbd_spi_dat_i = u_top.u_spi_master.wbd_dat_i;
wire [31:0] wbd_spi_dat_o = u_top.u_spi_master.wbd_dat_o;
wire [3:0] wbd_spi_sel_i = u_top.u_spi_master.wbd_sel_i;
wire wbd_sdram_stb_i = u_top.u_sdram_ctrl.wb_stb_i;
wire wbd_sdram_ack_o = u_top.u_sdram_ctrl.wb_ack_o;
wire wbd_sdram_we_i = u_top.u_sdram_ctrl.wb_we_i;
wire [31:0] wbd_sdram_adr_i = u_top.u_sdram_ctrl.wb_addr_i;
wire [31:0] wbd_sdram_dat_i = u_top.u_sdram_ctrl.wb_dat_i;
wire [31:0] wbd_sdram_dat_o = u_top.u_sdram_ctrl.wb_dat_o;
wire [3:0] wbd_sdram_sel_i = u_top.u_sdram_ctrl.wb_sel_i;
wire wbd_uart_stb_i = u_top.u_uart_i2c_usb.reg_cs;
wire wbd_uart_ack_o = u_top.u_uart_i2c_usb.reg_ack;
wire wbd_uart_we_i = u_top.u_uart_i2c_usb.reg_wr;
wire [7:0] wbd_uart_adr_i = u_top.u_uart_i2c_usb.reg_addr;
wire [7:0] wbd_uart_dat_i = u_top.u_uart_i2c_usb.reg_wdata;
wire [7:0] wbd_uart_dat_o = u_top.u_uart_i2c_usb.reg_rdata;
wire wbd_uart_sel_i = u_top.u_uart_i2c_usb.reg_be;
`endif
/**
`ifdef GL
//-----------------------------------------------------------------------------
// RISC IMEM amd DMEM Monitoring TASK
//-----------------------------------------------------------------------------
`define RISC_CORE user_uart_tb.u_top.u_core.u_riscv_top
always@(posedge `RISC_CORE.wb_clk) begin
if(`RISC_CORE.wbd_imem_ack_i)
$display("RISCV-DEBUG => IMEM ADDRESS: %x Read Data : %x", `RISC_CORE.wbd_imem_adr_o,`RISC_CORE.wbd_imem_dat_i);
if(`RISC_CORE.wbd_dmem_ack_i && `RISC_CORE.wbd_dmem_we_o)
$display("RISCV-DEBUG => DMEM ADDRESS: %x Write Data: %x Resonse: %x", `RISC_CORE.wbd_dmem_adr_o,`RISC_CORE.wbd_dmem_dat_o);
if(`RISC_CORE.wbd_dmem_ack_i && !`RISC_CORE.wbd_dmem_we_o)
$display("RISCV-DEBUG => DMEM ADDRESS: %x READ Data : %x Resonse: %x", `RISC_CORE.wbd_dmem_adr_o,`RISC_CORE.wbd_dmem_dat_i);
end
`endif
**/
endmodule
`default_nettype wire