| //////////////////////////////////////////////////////////////////////////// |
| // 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 0x1003_0058 to 0x1003_006C //// |
| //// 4. Through the External Wishbone Interface we read back //// |
| //// from 0x3003_0058 to 0x3003_006C //// |
| //// 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 "uprj_netlists.v" |
| |
| `define ADDR_SPACE_UART 32'h1001_0000 |
| `define ADDR_SPACE_I2C 32'h1001_0000 |
| `define ADDR_SPACE_GLBL 32'h1002_0000 |
| |
| module user_risc_soft_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; |
| logic [7:0] tem_mem[0:4095]; |
| logic [31:0] tem_mem_32b[0:511]; |
| |
| `ifdef VERILATOR |
| logic [255:0] test_ram_file; |
| `else // VERILATOR |
| |
| string test_ram_file; |
| |
| `endif // VERILATOR |
| |
| integer i; |
| |
| |
| // 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("simx.vcd"); |
| $dumpvars(4, user_risc_soft_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); |
| |
| $readmemh("user_risc_boot.hex",tem_mem); |
| // convert 8 bit 32 mem format |
| for(i =0; i < 511; i = i+1) |
| tem_mem_32b[i] = {tem_mem[(i*4)+3],tem_mem[(i*4)+2],tem_mem[(i*4)+1],tem_mem[(i*4)]}; |
| |
| $writememh("sram_bank0.hex",tem_mem_32b,0,511); |
| $readmemh("sram_bank0.hex",u_top.u_sram0_2kb.mem,0,511); |
| |
| for(i =512; i < 1023; i = i+1) |
| tem_mem_32b[i-512] = {tem_mem[(i*4)+3],tem_mem[(i*4)+2],tem_mem[(i*4)+1],tem_mem[(i*4)]}; |
| |
| $writememh("sram_bank1.hex",tem_mem_32b,0,511); |
| $readmemh("sram_bank1.hex",u_top.u_sram1_2kb.mem,0,511); |
| |
| // Enable the SRAM Remap to boot region and keep bank sel=0x10 |
| wb_user_core_write('h3080_0004,{20'h0,4'b1111,8'h10}); |
| repeat (2) @(posedge clock); |
| #1; |
| // Remove the reset, mbist, wishbone, riscv |
| wb_user_core_write('h3080_0000,'h4F); |
| |
| |
| // Repeat cycles of 1000 clock edges as needed to complete testbench |
| repeat (10) begin |
| repeat (400) @(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_check(`ADDR_SPACE_GLBL+8'h18,read_data,32'h11223344); |
| wb_user_core_read_check(`ADDR_SPACE_GLBL+8'h1C,read_data,32'h22334455); |
| wb_user_core_read_check(`ADDR_SPACE_GLBL+8'h20,read_data,32'h33445566); |
| wb_user_core_read_check(`ADDR_SPACE_GLBL+8'h24,read_data,32'h44556677); |
| wb_user_core_read_check(`ADDR_SPACE_GLBL+8'h28,read_data,32'h55667788); |
| wb_user_core_read_check(`ADDR_SPACE_GLBL+8'h2C,read_data,32'h66778899); |
| |
| |
| $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 |
| |
| end |
| `endif |
| |
| |
| |
| 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 |
| |
| task wb_user_core_read_check; |
| input [31:0] address; |
| output [31:0] data; |
| input [31:0] cmp_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 |
| if(data !== cmp_data) begin |
| $display("ERROR : WB USER ACCESS READ Address : 0x%x, Exd: 0x%x Rxd: 0x%x ",address,cmp_data,data); |
| test_fail = 1; |
| end else begin |
| $display("STATUS: WB USER ACCESS READ Address : 0x%x, Data : 0x%x",address,data); |
| end |
| 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 |