cvw/testbench/testbench-xcelium.sv

///////////////////////////////////////////
// testbench.sv
//
// Written: David_Harris@hmc.edu 9 January 2021
// Modified: 
//
// Purpose: Wally Testbench and helper modules
//          Applies test programs from the riscv-arch-test and Imperas suites
// 
// A component of the Wally configurable RISC-V project.
// 
// Copyright (C) 2021 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.
////////////////////////////////////////////////////////////////////////////////////////////////

`include "config.vh"
`include "tests.vh"

import cvw::*;

module testbench;
  /* verilator lint_off WIDTHTRUNC */
  /* verilator lint_off WIDTHEXPAND */
  parameter DEBUG=0;
  parameter TEST="none";
  parameter PrintHPMCounters=1;
  parameter BPRED_LOGGER=0;
  parameter I_CACHE_ADDR_LOGGER=0;
  parameter D_CACHE_ADDR_LOGGER=0;
 
`include "parameter-defs.vh"

  logic        clk;
  logic        reset_ext, reset;
  logic        ResetMem;

  // DUT signals
  logic [P.AHBW-1:0]    HRDATAEXT;
  logic                 HREADYEXT, HRESPEXT;
  logic [P.PA_BITS-1:0] HADDR;
  logic [P.AHBW-1:0]    HWDATA;
  logic [P.XLEN/8-1:0]  HWSTRB;
  logic                 HWRITE;
  logic [2:0]           HSIZE;
  logic [2:0]           HBURST;
  logic [3:0]           HPROT;
  logic [1:0]           HTRANS;
  logic                 HMASTLOCK;
  logic                 HCLK, HRESETn;

  logic [31:0] GPIOIN, GPIOOUT, GPIOEN;
  logic        UARTSin, UARTSout;

  logic        SDCCLK;
  logic        SDCCmdIn;
  logic        SDCCmdOut;
  logic        SDCCmdOE;
  logic [3:0]  SDCDatIn;
  tri1  [3:0]  SDCDat;
  tri1         SDCCmd;

  logic        HREADY;
  logic        HSELEXT;

  
  string  ProgramAddrMapFile, ProgramLabelMapFile;
  integer ProgramAddrLabelArray [string];

  int test, i, errors, totalerrors;

  string outputfile;
  integer outputFilePointer;

  string tests[];
  logic DCacheFlushDone, DCacheFlushStart;
  logic riscofTest; 
  logic Validate;
  logic SelectTest;

  

  // pick tests based on modes supported
  initial begin
    $display("TEST is %s", TEST);
    //tests = '{};
    if (P.XLEN == 64) begin // RV64
      case (TEST)
        "arch64i":                               tests = arch64i;
        "arch64priv":                            tests = arch64priv;
        "arch64c":      if (P.C_SUPPORTED) 
                          if (P.ZICSR_SUPPORTED)  tests = {arch64c, arch64cpriv};
                          else                   tests = {arch64c};
        "arch64m":      if (P.M_SUPPORTED)        tests = arch64m;
        "arch64f":      if (P.F_SUPPORTED)        tests = arch64f;
        "arch64d":      if (P.D_SUPPORTED)        tests = arch64d;  
        "arch64f_fma":      if (P.F_SUPPORTED)        tests = arch64f_fma;
        "arch64d_fma":      if (P.D_SUPPORTED)        tests = arch64d_fma;  
        "arch64zi":     if (P.ZIFENCEI_SUPPORTED) tests = arch64zi;
        "imperas64i":                            tests = imperas64i;
        "imperas64f":   if (P.F_SUPPORTED)        tests = imperas64f;
        "imperas64d":   if (P.D_SUPPORTED)        tests = imperas64d;
        "imperas64m":   if (P.M_SUPPORTED)        tests = imperas64m;
        "wally64a":     if (P.A_SUPPORTED)        tests = wally64a;
        "imperas64c":   if (P.C_SUPPORTED)        tests = imperas64c;
                        else                     tests = imperas64iNOc;
        "custom":                                tests = custom;
        "wally64i":                              tests = wally64i; 
        "wally64priv":                           tests = wally64priv;
        "wally64periph":                         tests = wally64periph;
        "coremark":                              tests = coremark;
        "fpga":                                  tests = fpga;
        "ahb" :                                  tests = ahb;
        "coverage64gc" :                         tests = coverage64gc;
        "arch64zba":     if (P.ZBA_SUPPORTED)     tests = arch64zba;
        "arch64zbb":     if (P.ZBB_SUPPORTED)     tests = arch64zbb;
        "arch64zbc":     if (P.ZBC_SUPPORTED)     tests = arch64zbc;
        "arch64zbs":     if (P.ZBS_SUPPORTED)     tests = arch64zbs;
      endcase 
    end else begin // RV32
      case (TEST)
        "arch32i":                               tests = arch32i;
        "arch32priv":                            tests = arch32priv;
        "arch32c":      if (P.C_SUPPORTED) 
                          if (P.ZICSR_SUPPORTED)  tests = {arch32c, arch32cpriv};
                          else                   tests = {arch32c};
        "arch32m":      if (P.M_SUPPORTED)        tests = arch32m;
        "arch32f":      if (P.F_SUPPORTED)        tests = arch32f;
        "arch32d":      if (P.D_SUPPORTED)        tests = arch32d;
        "arch32f_fma":      if (P.F_SUPPORTED)        tests = arch32f_fma;
        "arch32d_fma":      if (P.D_SUPPORTED)        tests = arch32d_fma;
        "arch32zi":     if (P.ZIFENCEI_SUPPORTED) tests = arch32zi;
        "imperas32i":                            tests = imperas32i;
        "imperas32f":   if (P.F_SUPPORTED)        tests = imperas32f;
        "imperas32m":   if (P.M_SUPPORTED)        tests = imperas32m;
        "wally32a":     if (P.A_SUPPORTED)        tests = wally32a;
        "imperas32c":   if (P.C_SUPPORTED)        tests = imperas32c;
                        else                     tests = imperas32iNOc;
        "wally32i":                              tests = wally32i; 
        "wally32e":                              tests = wally32e; 
        "wally32priv":                           tests = wally32priv;
        "wally32periph":                         tests = wally32periph;
        "embench":                               tests = embench;
        "coremark":                              tests = coremark;
        "arch32zba":     if (P.ZBA_SUPPORTED)     tests = arch32zba;
        "arch32zbb":     if (P.ZBB_SUPPORTED)     tests = arch32zbb;
        "arch32zbc":     if (P.ZBC_SUPPORTED)     tests = arch32zbc;
        "arch32zbs":     if (P.ZBS_SUPPORTED)     tests = arch32zbs;
      endcase
    end
    if (tests.size() == 0) begin
      $display("TEST %s not supported in this configuration", TEST);
      $stop;
    end
  end // initial begin

  // Model the testbench as an fsm.
  // Do this in parts so it easier to verify
  // part 1: build a version which echos the same behavior as the below code, but does not drive anything
  // part 2: drive some of the controls
  // part 3: drive all logic and remove old inital and always @ negedge clk block

  typedef enum logic [3:0]{STATE_TESTBENCH_RESET,
                           STATE_INIT_TEST,
                           STATE_RESET_MEMORIES,
                           STATE_RESET_MEMORIES2,
                           STATE_LOAD_MEMORIES,
                           STATE_RESET_TEST,
                           STATE_RUN_TEST,
                           STATE_CHECK_TEST,
                           STATE_CHECK_TEST_WAIT,
                           STATE_VALIDATE,
                           STATE_INCR_TEST} statetype;
  statetype CurrState, NextState;
  logic        TestBenchReset;
  logic [2:0]  ResetCount, ResetThreshold;
  logic        LoadMem;
  logic        ResetCntEn;
  logic        ResetCntRst;
  

  string  signame, memfilename, pathname;
  integer begin_signature_addr;

  assign ResetThreshold = 3'd5;

  initial begin
    TestBenchReset = 1;
    # 100;
    TestBenchReset = 0;
  end

  always_ff @(posedge clk)
    if (TestBenchReset) CurrState <= #1 STATE_TESTBENCH_RESET;
    else CurrState <= #1 NextState;  

  // fsm next state logic
  always_comb begin
    // riscof tests have a different signature, tests[0] == "1" refers to RiscvArchTests 
    // and tests[0] == "2" refers to WallyRiscvArchTests 
    riscofTest = tests[0] == "1" | tests[0] == "2"; 
    pathname = tvpaths[tests[0].atoi()];

    case(CurrState)
      STATE_TESTBENCH_RESET:                      NextState = STATE_INIT_TEST;
      STATE_INIT_TEST:                            NextState = STATE_RESET_MEMORIES;
      STATE_RESET_MEMORIES:                       NextState = STATE_RESET_MEMORIES2;
      STATE_RESET_MEMORIES2:                      NextState = STATE_LOAD_MEMORIES;  // Give the reset enough time to ensure the bus is reset before loading the memories.
      STATE_LOAD_MEMORIES:                        NextState = STATE_RESET_TEST;
      STATE_RESET_TEST:      if(ResetCount < ResetThreshold) NextState = STATE_RESET_TEST;
                             else                 NextState = STATE_RUN_TEST;
      STATE_RUN_TEST:        if(DCacheFlushStart) NextState = STATE_CHECK_TEST;
                             else                 NextState = STATE_RUN_TEST;
      STATE_CHECK_TEST:      if (DCacheFlushDone) NextState = STATE_VALIDATE;
                             else                 NextState = STATE_CHECK_TEST_WAIT;
      STATE_CHECK_TEST_WAIT: if(DCacheFlushDone)  NextState = STATE_VALIDATE;
                             else                 NextState = STATE_CHECK_TEST_WAIT;
      STATE_VALIDATE:                             NextState = STATE_INIT_TEST;
      STATE_INCR_TEST:                            NextState = STATE_INIT_TEST;
      default:                                    NextState = STATE_TESTBENCH_RESET;
    endcase
  end // always_comb
  // fsm output control logic 
  assign reset_ext = CurrState == STATE_TESTBENCH_RESET | CurrState == STATE_INIT_TEST | 
                     CurrState == STATE_RESET_MEMORIES | CurrState == STATE_RESET_MEMORIES2 | 
                     CurrState == STATE_LOAD_MEMORIES | CurrState ==STATE_RESET_TEST;
  // this initialization is very expensive, only do it for coremark.  
  assign ResetMem = (CurrState == STATE_RESET_MEMORIES | CurrState == STATE_RESET_MEMORIES2) & TEST == "coremark";
  assign LoadMem = CurrState == STATE_LOAD_MEMORIES;
  assign ResetCntRst = CurrState == STATE_INIT_TEST;
  assign ResetCntEn = CurrState == STATE_RESET_TEST;
  assign Validate = CurrState == STATE_VALIDATE;
  assign SelectTest = CurrState == STATE_INIT_TEST;

  // fsm reset counter
  counter #(3) RstCounter(clk, ResetCntRst, ResetCntEn, ResetCount);

  ////////////////////////////////////////////////////////////////////////////////
  // Find the test vector files and populate the PC to function label converter
  ////////////////////////////////////////////////////////////////////////////////
  logic [P.XLEN-1:0] testadr;
  assign begin_signature_addr = ProgramAddrLabelArray["begin_signature"];
  always @(posedge clk) begin
    if(SelectTest) begin
      if (riscofTest) memfilename = {pathname, tests[test], "/ref/ref.elf.memfile"};
      else            memfilename = {pathname, tests[test], ".elf.memfile"};
      if (riscofTest) begin
        ProgramAddrMapFile = {pathname, tests[test], "/ref/ref.elf.objdump.addr"};
        ProgramLabelMapFile = {pathname, tests[test], "/ref/ref.elf.objdump.lab"};
      end else begin
        ProgramAddrMapFile = {pathname, tests[test], ".elf.objdump.addr"};
        ProgramLabelMapFile = {pathname, tests[test], ".elf.objdump.lab"};
      end
      // declare memory labels that interest us, the updateProgramAddrLabelArray task will find 
      // the addr of each label and fill the array. To expand, add more elements to this array 
      // and initialize them to zero (also initilaize them to zero at the start of the next test)
      if(!P.FPGA) begin
        updateProgramAddrLabelArray(ProgramAddrMapFile, ProgramLabelMapFile, ProgramAddrLabelArray);
      end
    end
    
  ////////////////////////////////////////////////////////////////////////////////
  // Verify the test ran correctly by checking the memory against a known signature.
  ////////////////////////////////////////////////////////////////////////////////
    if(TestBenchReset) test = 1;
    if (TEST == "coremark")
      if (dut.core.EcallFaultM) begin
        $display("Benchmark: coremark is done.");
        $stop;
      end
    if(Validate) begin
      if (TEST == "embench") begin
        // Writes contents of begin_signature to .sim.output file
        // this contains instret and cycles for start and end of test run, used by embench 
        // python speed script to calculate embench speed score. 
        // also, begin_signature contains the results of the self checking mechanism, 
        // which will be read by the python script for error checking
        $display("Embench Benchmark: %s is done.", tests[test]);
        if (riscofTest) outputfile = {pathname, tests[test], "/ref/ref.sim.output"};
        else outputfile = {pathname, tests[test], ".sim.output"};
        outputFilePointer = $fopen(outputfile, "w");
        i = 0;
        testadr = ($unsigned(begin_signature_addr))/(P.XLEN/8);
        while ($unsigned(i) < $unsigned(5'd5)) begin
          $fdisplayh(outputFilePointer, DCacheFlushFSM.ShadowRAM[testadr+i]);
          i = i + 1;
        end
        $fclose(outputFilePointer);
        $display("Embench Benchmark: created output file: %s", outputfile);
      end else if (TEST == "coverage64gc") begin
        $display("Coverage tests don't get checked");
      end else begin 
        // for tests with no self checking mechanism, read .signature.output file and compare to check for errors
        // clear signature to prevent contamination from previous tests
      end

      if (!begin_signature_addr)
        $display("begin_signature addr not found in %s", ProgramLabelMapFile);
      else if (TEST != "embench") begin   // *** quick hack for embench.  need a better long term solution
        CheckSignature(pathname, tests[test], riscofTest, begin_signature_addr, errors);
      end
      if(errors > 0) totalerrors = totalerrors + 1;
      test = test + 1; // *** this probably needs to be moved.
      if (test == tests.size()) begin
        if (totalerrors == 0) $display("SUCCESS! All tests ran without failures.");
        else $display("FAIL: %d test programs had errors", totalerrors);
        $stop;
      end
    end
  end


  ////////////////////////////////////////////////////////////////////////////////
  // Some memories are not reset, but should be zeros or set to some initial value for simulation
  ////////////////////////////////////////////////////////////////////////////////
  integer adrindex;

  if (P.UNCORE_RAM_SUPPORTED) `define TB_UNCORE_RAM_SUPPORTED;
  if (P.BPRED_SUPPORTED) `define TB_BPRED_SUPPORTED;
  if (P.BPRED_TYPE == BP_LOCAL_AHEAD | P.BPRED_TYPE == BP_LOCAL_REPAIR) `define TB_BHT;

  always @(posedge clk) begin
    if (ResetMem)  // program memory is sometimes reset
      if (P.UNCORE_RAM_SUPPORTED) begin
      `ifdef TB_UNCORE_RAM_SUPPORTED
        for (adrindex=0; adrindex<(P.UNCORE_RAM_RANGE>>1+(P.XLEN/32)); adrindex = adrindex+1) 
          dut.uncore.uncore.ram.ram.memory.RAM[adrindex] = '0;
      `endif
      end
    if(reset) begin  // branch predictor must always be reset
      if (P.BPRED_SUPPORTED) begin
      `ifdef TB_BPRED_SUPPORTED
        // local history only
        if (P.BPRED_TYPE == BP_LOCAL_AHEAD | P.BPRED_TYPE == BP_LOCAL_REPAIR) begin
        `ifdef TB_BHT
          for(adrindex = 0; adrindex < 2**P.BPRED_NUM_LHR; adrindex++)
            dut.core.ifu.bpred.bpred.Predictor.DirPredictor.BHT.mem[adrindex] = 0;
        `endif
        end
        // these are both always included if there is a bpred
        for(adrindex = 0; adrindex < 2**P.BTB_SIZE; adrindex++)
          dut.core.ifu.bpred.bpred.TargetPredictor.memory.mem[adrindex] = 0;
        for(adrindex = 0; adrindex < 2**P.BPRED_SIZE; adrindex++)
          dut.core.ifu.bpred.bpred.Predictor.DirPredictor.PHT.mem[adrindex] = 0;
      `endif
      end
    end
  end

  ////////////////////////////////////////////////////////////////////////////////
  // load memories with program image
  ////////////////////////////////////////////////////////////////////////////////
  if (P.FPGA) `define TB_FPGA  // this is a gross hack for xcelium and verilator
  if (P.IROM_SUPPORTED) `define TB_IROM_SUPPORTED
  if (P.DTIM_SUPPORTED) `define TB_DTIM_SUPPORTED
  if (P.BUS_SUPPORTED) `define TB_BUS_SUPPORTED
  always @(posedge clk) begin
    if (LoadMem) begin
      if (P.FPGA) begin
      `ifdef TB_FPGA
        string romfilename, sdcfilename;
        romfilename = {"../tests/custom/fpga-test-sdc/bin/fpga-test-sdc.memfile"};
        sdcfilename = {"../testbench/sdc/ramdisk2.hex"};   
        $readmemh(romfilename, dut.uncore.uncore.bootrom.bootrom.memory.ROM);
        $readmemh(sdcfilename, sdcard.sdcard.FLASHmem);
        // shorten sdc timers for simulation
        dut.uncore.uncore.sdc.SDC.LimitTimers = 1;
      `endif
      end
      else if (P.IROM_SUPPORTED) begin
      `ifdef TB_IROM_SUPPORTED
        $readmemh(memfilename, dut.core.ifu.irom.irom.rom.ROM);
      `endif
      end
      else if (P.BUS_SUPPORTED) begin
      `ifdef TB_BUS_SUPPORTED
        $readmemh(memfilename, dut.uncore.uncore.ram.ram.memory.RAM);
      `endif
      end
      if (P.DTIM_SUPPORTED) begin
      `ifdef TB_DTIM_SUPPORTED
        $readmemh(memfilename, dut.core.lsu.dtim.dtim.ram.RAM);
      `endif
      end
      $display("Read memfile %s", memfilename);
    end
  end  

  ////////////////////////////////////////////////////////////////////////////////
  // Actual hardware
  ////////////////////////////////////////////////////////////////////////////////

  // instantiate device to be tested
  assign GPIOIN = 0;
  assign UARTSin = 1;

  if(P.EXT_MEM_SUPPORTED) begin
    ram_ahb #(.BASE(P.EXT_MEM_BASE), .RANGE(P.EXT_MEM_RANGE)) 
    ram (.HCLK, .HRESETn, .HADDR, .HWRITE, .HTRANS, .HWDATA, .HSELRam(HSELEXT), 
      .HREADRam(HRDATAEXT), .HREADYRam(HREADYEXT), .HRESPRam(HRESPEXT), .HREADY, .HWSTRB);
  end else begin 
    assign HREADYEXT = 1;
    assign {HRESPEXT, HRDATAEXT} = '0;
  end

  if(P.FPGA) begin : sdcard
    sdModel sdcard
      (.sdClk(SDCCLK),
       .cmd(SDCCmd), 
       .dat(SDCDat));

    assign SDCCmd = SDCCmdOE ? SDCCmdOut : 1'bz;
    assign SDCCmdIn = SDCCmd;
    assign SDCDatIn = SDCDat;
  end else begin
    assign SDCCmd = '0;
    assign SDCDat = '0;
  end

  wallypipelinedsoc  #(P) dut(.clk, .reset_ext, .reset, .HRDATAEXT,.HREADYEXT, .HRESPEXT,.HSELEXT,
    .HCLK, .HRESETn, .HADDR, .HWDATA, .HWSTRB, .HWRITE, .HSIZE, .HBURST, .HPROT,
    .HTRANS, .HMASTLOCK, .HREADY, .TIMECLK(1'b0), .GPIOIN, .GPIOOUT, .GPIOEN,
    .UARTSin, .UARTSout, .SDCCmdIn, .SDCCmdOut, .SDCCmdOE, .SDCDatIn, .SDCCLK); 

  // generate clock to sequence tests
  always begin
    clk = 1; # 5; clk = 0; # 5;
  end

  ////////////////////////////////////////////////////////////////////////////////
  // Support logic
  ////////////////////////////////////////////////////////////////////////////////

  // Track names of instructions
  string InstrFName, InstrDName, InstrEName, InstrMName, InstrWName;
  logic [31:0] InstrW;
  flopenr #(32)    InstrWReg(clk, reset, ~dut.core.ieu.dp.StallW,  dut.core.ifu.InstrM, InstrW);
  instrTrackerTB it(clk, reset, dut.core.ieu.dp.FlushE,
                dut.core.ifu.InstrRawF[31:0],
                dut.core.ifu.InstrD, dut.core.ifu.InstrE,
                dut.core.ifu.InstrM,  InstrW,
                InstrFName, InstrDName, InstrEName, InstrMName, InstrWName);

  // watch for problems such as lockup, reading unitialized memory, bad configs
  watchdog #(P.XLEN, 1000000) watchdog(.clk, .reset);  // check if PCW is stuck
  ramxdetector #(P.XLEN, P.LLEN) ramxdetector(clk, dut.core.lsu.MemRWM[1], dut.core.lsu.LSULoadAccessFaultM, dut.core.lsu.ReadDataM, 
                                      dut.core.ifu.PCM, dut.core.ifu.InstrM, dut.core.lsu.IEUAdrM, InstrMName);
  riscvassertions #(P) riscvassertions();  // check assertions for a legal configuration
  loggers #(P, TEST, PrintHPMCounters, I_CACHE_ADDR_LOGGER, D_CACHE_ADDR_LOGGER, BPRED_LOGGER)
  loggers (clk, reset, DCacheFlushStart, DCacheFlushDone, memfilename);

  // track the current function or global label
  if (DEBUG == 1 | (PrintHPMCounters & P.ZICNTR_SUPPORTED)) begin : FunctionName
    FunctionName #(P) FunctionName(.reset(reset_ext | TestBenchReset),
			      .clk(clk), .ProgramAddrMapFile(ProgramAddrMapFile), .ProgramLabelMapFile(ProgramLabelMapFile));
  end


  // Termination condition
  // terminate on a specific ECALL after li x3,1 for old Imperas tests,  *** remove this when old imperas tests are removed
  // or sw	gp,-56(t0) for new Imperas tests
  // or sd gp, -56(t0) 
  // or on a jump to self infinite loop (6f) for RISC-V Arch tests
  logic ecf; // remove this once we don't rely on old Imperas tests with Ecalls
  if (P.ZICSR_SUPPORTED) assign ecf = dut.core.priv.priv.EcallFaultM;
  else                  assign ecf = 0;
  assign DCacheFlushStart = ecf & 
			    (dut.core.ieu.dp.regf.rf[3] == 1 | 
			     (dut.core.ieu.dp.regf.we3 & 
			      dut.core.ieu.dp.regf.a3 == 3 & 
			      dut.core.ieu.dp.regf.wd3 == 1)) |
           ((dut.core.ifu.InstrM == 32'h6f | dut.core.ifu.InstrM == 32'hfc32a423 | dut.core.ifu.InstrM == 32'hfc32a823) & dut.core.ieu.c.InstrValidM ) |
           ((dut.core.lsu.IEUAdrM == ProgramAddrLabelArray["tohost"]) & InstrMName == "SW" ); 

  DCacheFlushFSM #(P) DCacheFlushFSM(.clk(clk), .reset(reset), .start(DCacheFlushStart), .done(DCacheFlushDone));

  task automatic CheckSignature;
    // This task must be declared inside this module as it needs access to parameter P.  There is
    // no way to pass P to the task unless we convert it to a module.
    
    input string  pathname;
    input string  TestName;
    input logic   riscofTest;
    input integer begin_signature_addr;
    output integer errors;

    localparam SIGNATURESIZE = 5000000;
    integer        i;
    logic [31:0]   sig32[0:SIGNATURESIZE];
    logic [P.XLEN-1:0] signature[0:SIGNATURESIZE];
    string            signame;
    logic [P.XLEN-1:0] testadr, testadrNoBase;

    if (P.DTIM_SUPPORTED) `define TB_DTIM_SUPPORTED2
    
    // for tests with no self checking mechanism, read .signature.output file and compare to check for errors
    // clear signature to prevent contamination from previous tests
    for(i=0; i<SIGNATURESIZE; i=i+1) begin
      sig32[i] = 'bx;
    end
    if (riscofTest) signame = {pathname, TestName, "/ref/Reference-sail_c_simulator.signature"};
    else signame = {pathname, TestName, ".signature.output"};
    // read signature, reformat in 64 bits if necessary
    $readmemh(signame, sig32);
    i = 0;
    while (i < SIGNATURESIZE) begin
      if (P.XLEN == 32) begin
        signature[i] = sig32[i];
        i = i+1;
      end else begin
        signature[i/2] = {sig32[i+1], sig32[i]};
        i = i + 2;
      end
      if (i >= 4 & sig32[i-4] === 'bx) begin
        if (i == 4) begin
          i = SIGNATURESIZE+1; // flag empty file
          $display("  Error: empty test file");
        end else i = SIGNATURESIZE; // skip over the rest of the x's for efficiency
      end
    end

    // Check errors
    errors = (i == SIGNATURESIZE+1); // error if file is empty
    i = 0;
    testadr = ($unsigned(begin_signature_addr))/(P.XLEN/8);
    testadrNoBase = (begin_signature_addr - P.UNCORE_RAM_BASE)/(P.XLEN/8);
    /* verilator lint_off INFINITELOOP */
    while (signature[i] !== 'bx) begin
      logic [P.XLEN-1:0] sig;
      if (P.DTIM_SUPPORTED) begin
      `ifdef TB_DTIM_SUPPORTED2
        //sig = testbench.dut.core.lsu.dtim.dtim.ram.RAM[testadrNoBase+i];
      `endif
      end
      else if (P.UNCORE_RAM_SUPPORTED) begin
      `ifdef TB_UNCORE_RAM_SUPPORTED
        sig = testbench.dut.uncore.uncore.ram.ram.memory.RAM[testadrNoBase+i];
      //$display("signature[%h] = %h sig = %h", i, signature[i], sig);
      `endif
      end
      if (signature[i] !== sig & (signature[i] !== testbench.DCacheFlushFSM.ShadowRAM[testadr+i])) begin  
        errors = errors+1;
        $display("  Error on test %s result %d: adr = %h sim (D$) %h sim (DTIM_SUPPORTED) = %h, signature = %h", 
			     TestName, i, (testadr+i)*(P.XLEN/8), testbench.DCacheFlushFSM.ShadowRAM[testadr+i], sig, signature[i]);
        $stop; //***debug
      end
      i = i + 1;
    end
    /* verilator lint_on INFINITELOOP */
    if (errors == 0) begin
      $display("%s succeeded.  Brilliant!!!", TestName);
    end else begin
      $display("%s failed with %d errors. :(", TestName, errors);
      //totalerrors = totalerrors+1;
    end

  endtask //
  
  /* verilator lint_on WIDTHTRUNC */
  /* verilator lint_on WIDTHEXPAND */

endmodule

/* verilator lint_on STMTDLY */
/* verilator lint_on WIDTH */

task automatic updateProgramAddrLabelArray;
  /* verilator lint_off WIDTHTRUNC */
  /* verilator lint_off WIDTHEXPAND */
  input string ProgramAddrMapFile, ProgramLabelMapFile;
  inout  integer ProgramAddrLabelArray [string];
  // Gets the memory location of begin_signature
  integer ProgramLabelMapFP, ProgramAddrMapFP;
  ProgramLabelMapFP = $fopen(ProgramLabelMapFile, "r");
  ProgramAddrMapFP = $fopen(ProgramAddrMapFile, "r");


  if (ProgramLabelMapFP & ProgramAddrMapFP) begin // check we found both files
    // *** RT: I'm a bit confused by the required initialization here.
    ProgramAddrLabelArray["begin_signature"] = 0;
    ProgramAddrLabelArray["tohost"] = 0;
    while (!$feof(ProgramLabelMapFP)) begin
      string label, adrstr;
      integer returncode;
      returncode = $fscanf(ProgramLabelMapFP, "%s\n", label);
      returncode = $fscanf(ProgramAddrMapFP, "%s\n", adrstr);
      if (ProgramAddrLabelArray.exists(label)) ProgramAddrLabelArray[label] = adrstr.atohex();
    end
  end
  $fclose(ProgramLabelMapFP);
  $fclose(ProgramAddrMapFP);
  /* verilator lint_on WIDTHTRUNC */
  /* verilator lint_on WIDTHEXPAND */
endtask