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gem5/cpu/checker/cpu.cc
Kevin Lim c23b23f4e7 Add in checker. Supports dynamically verifying the execution of instructions, as well as limited amount of control path verification. It will verify anything within the program, but anything external (traps, interrupts, XC) it assumes is redirected properly by the CPU. Similarly it assumes the results of store conditionals, uncached loads, and instructions marked as "unverifiable" are correct from the CPU. 
base/traceflags.py:
build/SConstruct:
cpu/SConscript:
cpu/cpu_models.py:
    Add in Checker.
cpu/base.cc:
    Add in checker support.  Also XC status starts off as suspended.
cpu/base.hh:
    Add in checker.

--HG--
extra : convert_revision : 091b5cc83e837858adb681ef0137a0beb30bd1b2
2006-05-16 13:59:29 -04:00

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/*
* Copyright (c) 2002-2005 The Regents of The University of Michigan
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
//#include <cmath>
#include <cstdio>
//#include <cstdlib>
#include <iostream>
#include <iomanip>
#include <list>
//#include <sstream>
#include <string>
//#include "base/cprintf.hh"
//#include "base/inifile.hh"
//#include "base/loader/symtab.hh"
#include "base/misc.hh"
//#include "base/pollevent.hh"
//#include "base/range.hh"
#include "base/refcnt.hh"
//#include "base/stats/events.hh"
#include "cpu/base.hh"
#include "cpu/base_dyn_inst.hh"
#include "cpu/checker/cpu.hh"
#include "cpu/cpu_exec_context.hh"
#include "cpu/exec_context.hh"
//#include "cpu/exetrace.hh"
//#include "cpu/profile.hh"
#include "cpu/sampler/sampler.hh"
//#include "cpu/smt.hh"
#include "cpu/static_inst.hh"
//#include "kern/kernel_stats.hh"
#include "mem/base_mem.hh"
#include "mem/mem_interface.hh"
#include "sim/byteswap.hh"
#include "sim/builder.hh"
//#include "sim/debug.hh"
//#include "sim/host.hh"
//#include "sim/sim_events.hh"
#include "sim/sim_object.hh"
#include "sim/stats.hh"
#include "cpu/o3/alpha_dyn_inst.hh"
#include "cpu/o3/alpha_impl.hh"
#include "cpu/ozone/dyn_inst.hh"
#include "cpu/ozone/ozone_impl.hh"
#include "cpu/ozone/simple_impl.hh"
#if FULL_SYSTEM
#include "base/remote_gdb.hh"
#include "mem/functional/memory_control.hh"
#include "mem/functional/physical.hh"
#include "sim/system.hh"
#include "arch/tlb.hh"
#include "arch/stacktrace.hh"
#include "arch/vtophys.hh"
#else // !FULL_SYSTEM
#include "mem/functional/functional.hh"
#endif // FULL_SYSTEM
using namespace std;
//The CheckerCPU does alpha only
using namespace AlphaISA;
void
CheckerCPU::init()
{
/*
BaseCPU::init();
#if FULL_SYSTEM
for (int i = 0; i < execContexts.size(); ++i) {
ExecContext *xc = execContexts[i];
// initialize CPU, including PC
TheISA::initCPU(xc, xc->readCpuId());
}
#endif
*/
}
CheckerCPU::CheckerCPU(Params *p)
: BaseCPU(p), cpuXC(NULL), xcProxy(NULL)
{
memReq = new MemReq();
memReq->xc = xcProxy;
memReq->asid = 0;
memReq->data = new uint8_t[64];
numInst = 0;
startNumInst = 0;
numLoad = 0;
startNumLoad = 0;
youngestSN = 0;
changedPC = willChangePC = changedNextPC = false;
exitOnError = p->exitOnError;
#if FULL_SYSTEM
itb = p->itb;
dtb = p->dtb;
systemPtr = NULL;
memPtr = NULL;
#endif
}
CheckerCPU::~CheckerCPU()
{
}
void
CheckerCPU::setMemory(FunctionalMemory *mem)
{
memPtr = mem;
#if !FULL_SYSTEM
cpuXC = new CPUExecContext(this, /* thread_num */ 0, mem,
/* asid */ 0);
cpuXC->setStatus(ExecContext::Suspended);
xcProxy = cpuXC->getProxy();
execContexts.push_back(xcProxy);
#else
if (systemPtr) {
cpuXC = new CPUExecContext(this, 0, systemPtr, itb, dtb, memPtr);
cpuXC->setStatus(ExecContext::Suspended);
xcProxy = cpuXC->getProxy();
execContexts.push_back(xcProxy);
memReq->xc = xcProxy;
}
#endif
}
#if FULL_SYSTEM
void
CheckerCPU::setSystem(System *system)
{
systemPtr = system;
if (memPtr) {
cpuXC = new CPUExecContext(this, 0, systemPtr, itb, dtb, memPtr);
cpuXC->setStatus(ExecContext::Suspended);
xcProxy = cpuXC->getProxy();
execContexts.push_back(xcProxy);
memReq->xc = xcProxy;
}
}
#endif
void
CheckerCPU::serialize(ostream &os)
{
/*
BaseCPU::serialize(os);
SERIALIZE_SCALAR(inst);
nameOut(os, csprintf("%s.xc", name()));
cpuXC->serialize(os);
cacheCompletionEvent.serialize(os);
*/
}
void
CheckerCPU::unserialize(Checkpoint *cp, const string &section)
{
/*
BaseCPU::unserialize(cp, section);
UNSERIALIZE_SCALAR(inst);
cpuXC->unserialize(cp, csprintf("%s.xc", section));
*/
}
Fault
CheckerCPU::copySrcTranslate(Addr src)
{
static bool no_warn = true;
int blk_size = 64;
// Only support block sizes of 64 atm.
assert(blk_size == 64);
int offset = src & (blk_size - 1);
// Make sure block doesn't span page
if (no_warn &&
(src & PageMask) != ((src + blk_size) & PageMask) &&
(src >> 40) != 0xfffffc) {
warn("Copied block source spans pages %x.", src);
no_warn = false;
}
memReq->reset(src & ~(blk_size - 1), blk_size);
// translate to physical address
Fault fault = cpuXC->translateDataReadReq(memReq);
if (fault == NoFault) {
cpuXC->copySrcAddr = src;
cpuXC->copySrcPhysAddr = memReq->paddr + offset;
} else {
assert(!fault->isAlignmentFault());
cpuXC->copySrcAddr = 0;
cpuXC->copySrcPhysAddr = 0;
}
return fault;
}
Fault
CheckerCPU::copy(Addr dest)
{
static bool no_warn = true;
int blk_size = 64;
// Only support block sizes of 64 atm.
assert(blk_size == 64);
uint8_t data[blk_size];
//assert(cpuXC->copySrcAddr);
int offset = dest & (blk_size - 1);
// Make sure block doesn't span page
if (no_warn &&
(dest & PageMask) != ((dest + blk_size) & PageMask) &&
(dest >> 40) != 0xfffffc) {
no_warn = false;
warn("Copied block destination spans pages %x. ", dest);
}
memReq->reset(dest & ~(blk_size -1), blk_size);
// translate to physical address
Fault fault = cpuXC->translateDataWriteReq(memReq);
if (fault == NoFault) {
Addr dest_addr = memReq->paddr + offset;
// Need to read straight from memory since we have more than 8 bytes.
memReq->paddr = cpuXC->copySrcPhysAddr;
cpuXC->mem->read(memReq, data);
memReq->paddr = dest_addr;
cpuXC->mem->write(memReq, data);
memReq->cmd = Copy;
memReq->completionEvent = NULL;
memReq->paddr = cpuXC->copySrcPhysAddr;
memReq->dest = dest_addr;
memReq->size = 64;
memReq->time = curTick;
memReq->flags &= ~INST_READ;
}
else
assert(!fault->isAlignmentFault());
return fault;
}
// precise architected memory state accessor macros
template <class T>
Fault
CheckerCPU::read(Addr addr, T &data, unsigned flags)
{
memReq->reset(addr, sizeof(T), flags);
// translate to physical address
// Should I probe the DTB? Or should I just take the physical address
// and assume correct translation?
translateDataReadReq(memReq);
// if we have a cache, do cache access too
memReq->cmd = Read;
memReq->completionEvent = NULL;
memReq->time = curTick;
memReq->flags &= ~INST_READ;
if (!(memReq->flags & UNCACHEABLE)) {
cpuXC->read(memReq, data);
} else {
// Assume the data is correct if it's an uncached access
memcpy(&data, &unverifiedResult.integer, sizeof(T));
}
return NoFault;
}
#ifndef DOXYGEN_SHOULD_SKIP_THIS
template
Fault
CheckerCPU::read(Addr addr, uint64_t &data, unsigned flags);
template
Fault
CheckerCPU::read(Addr addr, uint32_t &data, unsigned flags);
template
Fault
CheckerCPU::read(Addr addr, uint16_t &data, unsigned flags);
template
Fault
CheckerCPU::read(Addr addr, uint8_t &data, unsigned flags);
#endif //DOXYGEN_SHOULD_SKIP_THIS
template<>
Fault
CheckerCPU::read(Addr addr, double &data, unsigned flags)
{
return read(addr, *(uint64_t*)&data, flags);
}
template<>
Fault
CheckerCPU::read(Addr addr, float &data, unsigned flags)
{
return read(addr, *(uint32_t*)&data, flags);
}
template<>
Fault
CheckerCPU::read(Addr addr, int32_t &data, unsigned flags)
{
return read(addr, (uint32_t&)data, flags);
}
template <class T>
Fault
CheckerCPU::write(T data, Addr addr, unsigned flags, uint64_t *res)
{
memReq->reset(addr, sizeof(T), flags);
// translate to physical address
cpuXC->translateDataWriteReq(memReq);
if ((!(unverifiedReq->flags & LOCKED) ||
((unverifiedReq->flags & LOCKED) &&
unverifiedReq->result == 1)) &&
!(unverifiedReq->flags & UNCACHEABLE)) {
// do functional access
// cpuXC->read(memReq, data);
memReq->cmd = Write;
// memcpy(memReq->data,(uint8_t *)&data,memReq->size);
T inst_data;
memcpy(&inst_data, unverifiedReq->data, sizeof(T));
memReq->completionEvent = NULL;
memReq->time = curTick;
memReq->flags &= ~INST_READ;
// Hard to verify this as the data writes back after the
// instruction commits. May only be able to check that the
// value produced from execute() matches the value produced
// from the instruction's first execution.
if (data != inst_data) {
warn("Store value does not match value in memory! "
"Instruction: %#x, memory: %#x",
inst_data, data);
handleError();
}
}
// Assume the result was the same as the one passed in. This checker
// doesn't check if the SC should succeed or fail, it just checks the
// value.
if (res)
*res = unverifiedReq->result;
return NoFault;
}
#ifndef DOXYGEN_SHOULD_SKIP_THIS
template
Fault
CheckerCPU::write(uint64_t data, Addr addr, unsigned flags, uint64_t *res);
template
Fault
CheckerCPU::write(uint32_t data, Addr addr, unsigned flags, uint64_t *res);
template
Fault
CheckerCPU::write(uint16_t data, Addr addr, unsigned flags, uint64_t *res);
template
Fault
CheckerCPU::write(uint8_t data, Addr addr, unsigned flags, uint64_t *res);
#endif //DOXYGEN_SHOULD_SKIP_THIS
template<>
Fault
CheckerCPU::write(double data, Addr addr, unsigned flags, uint64_t *res)
{
return write(*(uint64_t*)&data, addr, flags, res);
}
template<>
Fault
CheckerCPU::write(float data, Addr addr, unsigned flags, uint64_t *res)
{
return write(*(uint32_t*)&data, addr, flags, res);
}
template<>
Fault
CheckerCPU::write(int32_t data, Addr addr, unsigned flags, uint64_t *res)
{
return write((uint32_t)data, addr, flags, res);
}
#if FULL_SYSTEM
Addr
CheckerCPU::dbg_vtophys(Addr addr)
{
return vtophys(xcProxy, addr);
}
#endif // FULL_SYSTEM
#if FULL_SYSTEM
void
CheckerCPU::post_interrupt(int int_num, int index)
{
BaseCPU::post_interrupt(int_num, index);
if (cpuXC->status() == ExecContext::Suspended) {
DPRINTF(IPI,"Suspended Processor awoke\n");
cpuXC->activate();
}
}
#endif // FULL_SYSTEM
bool
CheckerCPU::translateInstReq(MemReqPtr &req)
{
#if FULL_SYSTEM
return (cpuXC->translateInstReq(req) == NoFault);
#else
cpuXC->translateInstReq(req);
return true;
#endif
}
void
CheckerCPU::translateDataReadReq(MemReqPtr &req)
{
cpuXC->translateDataReadReq(req);
if (req->vaddr != unverifiedReq->vaddr) {
warn("Request virtual addresses do not match! Inst: %#x, checker:"
" %#x",
unverifiedReq->vaddr, req->vaddr);
}
req->paddr = unverifiedReq->paddr;
if (checkFlags(req)) {
warn("Request flags do not match! Inst: %#x, checker: %#x",
unverifiedReq->flags, req->flags);
handleError();
}
}
void
CheckerCPU::translateDataWriteReq(MemReqPtr &req)
{
cpuXC->translateDataWriteReq(req);
if (req->vaddr != unverifiedReq->vaddr) {
warn("Request virtual addresses do not match! Inst: %#x, checker:"
" %#x",
unverifiedReq->vaddr, req->vaddr);
}
req->paddr = unverifiedReq->paddr;
if (checkFlags(req)) {
warn("Request flags do not match! Inst: %#x, checker: %#x",
unverifiedReq->flags, req->flags);
handleError();
}
}
bool
CheckerCPU::checkFlags(MemReqPtr &req)
{
// Remove any dynamic flags that don't have to do with the request itself.
unsigned flags = unverifiedReq->flags;
unsigned mask = LOCKED | PHYSICAL | VPTE | ALTMODE | UNCACHEABLE | NO_FAULT;
flags = flags & (mask);
if (flags == req->flags) {
return false;
} else {
return true;
}
}
/* start simulation, program loaded, processor precise state initialized */
template <class DynInstPtr>
void
Checker<DynInstPtr>::tick(DynInstPtr &completed_inst)
{
DynInstPtr inst;
if (!instList.empty()) {
if (youngestSN < completed_inst->seqNum) {
DPRINTF(Checker, "Adding instruction [sn:%lli] PC:%#x to list.\n",
completed_inst->seqNum, completed_inst->readPC());
instList.push_back(completed_inst);
youngestSN = completed_inst->seqNum;
}
if (!instList.front()->isCompleted()) {
return;
} else {
inst = instList.front();
instList.pop_front();
}
} else {
if (!completed_inst->isCompleted()) {
if (youngestSN < completed_inst->seqNum) {
DPRINTF(Checker, "Adding instruction [sn:%lli] PC:%#x to list.\n",
completed_inst->seqNum, completed_inst->readPC());
instList.push_back(completed_inst);
youngestSN = completed_inst->seqNum;
}
return;
} else {
if (youngestSN < completed_inst->seqNum) {
inst = completed_inst;
youngestSN = completed_inst->seqNum;
} else {
// panic("SN already seen yet the list is empty!");
return;
}
}
}
while (1) {
DPRINTF(Checker, "Processing instruction [sn:%lli] PC:%#x.\n",
inst->seqNum, inst->readPC());
// verifyInst = completed_inst;
unverifiedResult.integer = inst->readIntResult();
unverifiedReq = inst->req;
numCycles++;
Fault fault = NoFault;
// maintain $r0 semantics
cpuXC->setIntReg(ZeroReg, 0);
#ifdef TARGET_ALPHA
cpuXC->setFloatRegDouble(ZeroReg, 0.0);
#endif // TARGET_ALPHA
// Try to fetch an instruction
// set up memory request for instruction fetch
#if FULL_SYSTEM
#define IFETCH_FLAGS(pc) ((pc) & 1) ? PHYSICAL : 0
#else
#define IFETCH_FLAGS(pc) 0
#endif
if (changedPC) {
DPRINTF(Checker, "Changed PC recently to %#x\n",
cpuXC->readPC());
if (willChangePC) {
if (newPC == cpuXC->readPC()) {
DPRINTF(Checker, "Changed PC matches expected PC\n");
} else {
warn("Changed PC does not match expected PC, changed: %#x, "
"expected: %#x",
cpuXC->readPC(), newPC);
handleError();
}
willChangePC = false;
}
changedPC = false;
}
if (changedNextPC) {
DPRINTF(Checker, "Changed NextPC recently to %#x\n",
cpuXC->readNextPC());
changedNextPC = false;
}
memReq->cmd = Read;
memReq->reset(cpuXC->readPC() & ~3, sizeof(uint32_t),
IFETCH_FLAGS(cpuXC->readPC()));
bool succeeded = translateInstReq(memReq);
if (!succeeded) {
warn("Instruction PC %#x was not found in the ITB!",
cpuXC->readPC());
handleError();
// go to the next instruction
cpuXC->setPC(cpuXC->readNextPC());
cpuXC->setNextPC(cpuXC->readNextPC() + sizeof(MachInst));
return;
}
// if (fault == NoFault)
// fault = cpuXC->mem->read(memReq, machInst);
cpuXC->mem->read(memReq, machInst);
// If we've got a valid instruction (i.e., no fault on instruction
// fetch), then execute it.
// keep an instruction count
numInst++;
// numInsts++;
// decode the instruction
machInst = gtoh(machInst);
// Checks that the instruction matches what we expected it to be.
// Checks both the machine instruction and the PC.
validateInst(inst);
curStaticInst = StaticInst::decode(makeExtMI(machInst, cpuXC->readPC()));
#if FULL_SYSTEM
cpuXC->setInst(machInst);
#endif // FULL_SYSTEM
fault = inst->getFault();
// Either the instruction was a fault and we should process the fault,
// or we should just go ahead execute the instruction. This assumes
// that the instruction is properly marked as a fault.
if (fault == NoFault) {
cpuXC->func_exe_inst++;
fault = curStaticInst->execute(this, NULL);
// Checks to make sure instrution results are correct.
validateExecution(inst);
// if (curStaticInst->isMemRef()) {
// numMemRefs++;
// }
if (curStaticInst->isLoad()) {
++numLoad;
}
}
if (fault != NoFault) {
#if FULL_SYSTEM
fault->invoke(xcProxy);
willChangePC = true;
newPC = cpuXC->readPC();
DPRINTF(Checker, "Fault, PC is now %#x\n", newPC);
#else // !FULL_SYSTEM
fatal("fault (%d) detected @ PC 0x%08p", fault, cpuXC->readPC());
#endif // FULL_SYSTEM
} else {
#if THE_ISA != MIPS_ISA
// go to the next instruction
cpuXC->setPC(cpuXC->readNextPC());
cpuXC->setNextPC(cpuXC->readNextPC() + sizeof(MachInst));
#else
// go to the next instruction
cpuXC->setPC(cpuXC->readNextPC());
cpuXC->setNextPC(cpuXC->readNextNPC());
cpuXC->setNextNPC(cpuXC->readNextNPC() + sizeof(MachInst));
#endif
}
#if FULL_SYSTEM
Addr oldpc;
int count = 0;
do {
oldpc = cpuXC->readPC();
system->pcEventQueue.service(xcProxy);
count++;
} while (oldpc != cpuXC->readPC());
if (count > 1) {
willChangePC = true;
newPC = cpuXC->readPC();
DPRINTF(Checker, "PC Event, PC is now %#x\n", newPC);
}
#endif
// Checks PC, next PC. Optionally can check all registers. (Or just those
// that have been modified).
validateState();
if (instList.empty()) {
break;
} else if (instList.front()->isCompleted()) {
inst = instList.front();
instList.pop_front();
} else {
break;
}
}
}
template <class DynInstPtr>
void
Checker<DynInstPtr>::switchOut(Sampler *s)
{
sampler = s;
instList.clear();
}
template <class DynInstPtr>
void
Checker<DynInstPtr>::takeOverFrom(BaseCPU *oldCPU)
{
// BaseCPU::takeOverFrom(oldCPU);
// if any of this CPU's ExecContexts are active, mark the CPU as
// running and schedule its tick event.
/*
for (int i = 0; i < execContexts.size(); ++i) {
ExecContext *xc = execContexts[i];
}
*/
}
template <class DynInstPtr>
void
Checker<DynInstPtr>::validateInst(DynInstPtr &inst)
{
if (inst->readPC() != cpuXC->readPC()) {
warn("PCs do not match! Inst: %#x, checker: %#x",
inst->readPC(), cpuXC->readPC());
if (changedPC) {
warn("Changed PCs recently, may not be an error");
} else {
handleError();
}
}
if (static_cast<MachInst>(inst->staticInst->machInst) !=
machInst) {
warn("Binary instructions do not match! Inst: %#x, checker: %#x",
static_cast<MachInst>(inst->staticInst->machInst),
machInst);
handleError();
}
}
template <class DynInstPtr>
void
Checker<DynInstPtr>::validateExecution(DynInstPtr &inst)
{
if (inst->numDestRegs()) {
if (inst->isUnverifiable()) {
// @todo: Support more destination registers.
// Grab the result from the instruction and write it to the
// register.
RegIndex idx = inst->destRegIdx(0);
if (idx < TheISA::FP_Base_DepTag) {
cpuXC->setIntReg(idx, inst->readIntResult());
} else if (idx < TheISA::Fpcr_DepTag) {
cpuXC->setFloatRegInt(idx, inst->readIntResult());
} else {
cpuXC->setMiscReg(idx, inst->readIntResult());
}
} else if (result.integer != inst->readIntResult()) {
warn("Instruction results do not match! (May not be integer results) "
"Inst: %#x, checker: %#x",
inst->readIntResult(), result.integer);
handleError();
}
}
if (inst->readNextPC() != cpuXC->readNextPC()) {
warn("Instruction next PCs do not match! Inst: %#x, checker: %#x",
inst->readNextPC(), cpuXC->readNextPC());
handleError();
}
// Checking side effect registers can be difficult if they are not
// checked simultaneously with the execution of the instruction.
// This is because other valid instructions may have modified
// these registers in the meantime, and their values are not
// stored within the DynInst.
while (!miscRegIdxs.empty()) {
int misc_reg_idx = miscRegIdxs.front();
miscRegIdxs.pop();
if (inst->xcBase()->readMiscReg(misc_reg_idx) !=
cpuXC->readMiscReg(misc_reg_idx)) {
warn("Misc reg idx %i (side effect) does not match! Inst: %#x, "
"checker: %#x",
misc_reg_idx, inst->xcBase()->readMiscReg(misc_reg_idx),
cpuXC->readMiscReg(misc_reg_idx));
handleError();
}
}
}
template <class DynInstPtr>
void
Checker<DynInstPtr>::validateState()
{
}
template <class DynInstPtr>
void
Checker<DynInstPtr>::dumpInsts()
{
int num = 0;
InstListIt inst_list_it = --(instList.end());
cprintf("Inst list size: %i\n", instList.size());
while (inst_list_it != instList.end())
{
cprintf("Instruction:%i\n",
num);
cprintf("PC:%#x\n[sn:%lli]\n[tid:%i]\n"
"Completed:%i\n",
(*inst_list_it)->readPC(),
(*inst_list_it)->seqNum,
(*inst_list_it)->threadNumber,
(*inst_list_it)->isCompleted());
cprintf("\n");
inst_list_it--;
++num;
}
}
template
class Checker<RefCountingPtr<OzoneDynInst<OzoneImpl> > >;
template
class Checker<RefCountingPtr<AlphaDynInst<AlphaSimpleImpl> > >;
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