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/*
* Copyright (c) 2011, 2016-2018, 2020 ARM Limited
* Copyright (c) 2013 Advanced Micro Devices, Inc.
* All rights reserved
*
* The license below extends only to copyright in the software and shall
* not be construed as granting a license to any other intellectual
* property including but not limited to intellectual property relating
* to a hardware implementation of the functionality of the software
* licensed hereunder. You may use the software subject to the license
* terms below provided that you ensure that this notice is replicated
* unmodified and in its entirety in all distributions of the software,
* modified or unmodified, in source code or in binary form.
*
* Copyright (c) 2006 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.
*/
#ifndef __CPU_CHECKER_CPU_HH__
#define __CPU_CHECKER_CPU_HH__
#include <list>
#include <map>
#include <queue>
#include "arch/types.hh"
#include "base/statistics.hh"
#include "cpu/base.hh"
#include "cpu/base_dyn_inst.hh"
#include "cpu/exec_context.hh"
#include "cpu/inst_res.hh"
#include "cpu/pc_event.hh"
#include "cpu/simple_thread.hh"
#include "cpu/static_inst.hh"
#include "debug/Checker.hh"
#include "mem/request.hh"
#include "params/CheckerCPU.hh"
#include "sim/eventq.hh"
class BaseTLB;
template <class>
class BaseDynInst;
class ThreadContext;
class Request;
/**
* CheckerCPU class. Dynamically verifies instructions as they are
* completed by making sure that the instruction and its results match
* the independent execution of the benchmark inside the checker. The
* checker verifies instructions in order, regardless of the order in
* which instructions complete. There are certain results that can
* not be verified, specifically the result of a store conditional or
* the values of uncached accesses. In these cases, and with
* instructions marked as "IsUnverifiable", the checker assumes that
* the value from the main CPU's execution is correct and simply
* copies that value. It provides a CheckerThreadContext (see
* checker/thread_context.hh) that provides hooks for updating the
* Checker's state through any ThreadContext accesses. This allows the
* checker to be able to correctly verify instructions, even with
* external accesses to the ThreadContext that change state.
*/
class CheckerCPU : public BaseCPU, public ExecContext
{
protected:
typedef TheISA::MachInst MachInst;
using VecRegContainer = TheISA::VecRegContainer;
/** id attached to all issued requests */
RequestorID requestorId;
public:
void init() override;
typedef CheckerCPUParams Params;
CheckerCPU(Params *p);
virtual ~CheckerCPU();
void setSystem(System *system);
void setIcachePort(RequestPort *icache_port);
void setDcachePort(RequestPort *dcache_port);
Port &
getDataPort() override
{
// the checker does not have ports on its own so return the
// data port of the actual CPU core
assert(dcachePort);
return *dcachePort;
}
Port &
getInstPort() override
{
// the checker does not have ports on its own so return the
// data port of the actual CPU core
assert(icachePort);
return *icachePort;
}
protected:
std::vector<Process*> workload;
System *systemPtr;
RequestPort *icachePort;
RequestPort *dcachePort;
ThreadContext *tc;
BaseTLB *itb;
BaseTLB *dtb;
// ISAs like ARM can have multiple destination registers to check,
// keep them all in a std::queue
std::queue<InstResult> result;
StaticInstPtr curStaticInst;
StaticInstPtr curMacroStaticInst;
// number of simulated instructions
Counter numInst;
Counter startNumInst;
std::queue<int> miscRegIdxs;
public:
// Primary thread being run.
SimpleThread *thread;
BaseTLB* getITBPtr() { return itb; }
BaseTLB* getDTBPtr() { return dtb; }
virtual Counter totalInsts() const override
{
return 0;
}
virtual Counter totalOps() const override
{
return 0;
}
// number of simulated loads
Counter numLoad;
Counter startNumLoad;
void serialize(CheckpointOut &cp) const override;
void unserialize(CheckpointIn &cp) override;
// The register accessor methods provide the index of the
// instruction's operand (e.g., 0 or 1), not the architectural
// register index, to simplify the implementation of register
// renaming. We find the architectural register index by indexing
// into the instruction's own operand index table. Note that a
// raw pointer to the StaticInst is provided instead of a
// ref-counted StaticInstPtr to redice overhead. This is fine as
// long as these methods don't copy the pointer into any long-term
// storage (which is pretty hard to imagine they would have reason
// to do).
RegVal
readIntRegOperand(const StaticInst *si, int idx) override
{
const RegId& reg = si->srcRegIdx(idx);
assert(reg.isIntReg());
return thread->readIntReg(reg.index());
}
RegVal
readFloatRegOperandBits(const StaticInst *si, int idx) override
{
const RegId& reg = si->srcRegIdx(idx);
assert(reg.isFloatReg());
return thread->readFloatReg(reg.index());
}
/**
* Read source vector register operand.
*/
const VecRegContainer &
readVecRegOperand(const StaticInst *si, int idx) const override
{
const RegId& reg = si->srcRegIdx(idx);
assert(reg.isVecReg());
return thread->readVecReg(reg);
}
/**
* Read destination vector register operand for modification.
*/
VecRegContainer &
getWritableVecRegOperand(const StaticInst *si, int idx) override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecReg());
return thread->getWritableVecReg(reg);
}
/** Vector Register Lane Interfaces. */
/** @{ */
/** Reads source vector 8bit operand. */
virtual ConstVecLane8
readVec8BitLaneOperand(const StaticInst *si, int idx) const override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecReg());
return thread->readVec8BitLaneReg(reg);
}
/** Reads source vector 16bit operand. */
virtual ConstVecLane16
readVec16BitLaneOperand(const StaticInst *si, int idx) const override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecReg());
return thread->readVec16BitLaneReg(reg);
}
/** Reads source vector 32bit operand. */
virtual ConstVecLane32
readVec32BitLaneOperand(const StaticInst *si, int idx) const override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecReg());
return thread->readVec32BitLaneReg(reg);
}
/** Reads source vector 64bit operand. */
virtual ConstVecLane64
readVec64BitLaneOperand(const StaticInst *si, int idx) const override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecReg());
return thread->readVec64BitLaneReg(reg);
}
/** Write a lane of the destination vector operand. */
template <typename LD>
void
setVecLaneOperandT(const StaticInst *si, int idx, const LD& val)
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecReg());
return thread->setVecLane(reg, val);
}
virtual void
setVecLaneOperand(const StaticInst *si, int idx,
const LaneData<LaneSize::Byte>& val) override
{
setVecLaneOperandT(si, idx, val);
}
virtual void
setVecLaneOperand(const StaticInst *si, int idx,
const LaneData<LaneSize::TwoByte>& val) override
{
setVecLaneOperandT(si, idx, val);
}
virtual void
setVecLaneOperand(const StaticInst *si, int idx,
const LaneData<LaneSize::FourByte>& val) override
{
setVecLaneOperandT(si, idx, val);
}
virtual void
setVecLaneOperand(const StaticInst *si, int idx,
const LaneData<LaneSize::EightByte>& val) override
{
setVecLaneOperandT(si, idx, val);
}
/** @} */
VecElem
readVecElemOperand(const StaticInst *si, int idx) const override
{
const RegId& reg = si->srcRegIdx(idx);
return thread->readVecElem(reg);
}
const VecPredRegContainer&
readVecPredRegOperand(const StaticInst *si, int idx) const override
{
const RegId& reg = si->srcRegIdx(idx);
assert(reg.isVecPredReg());
return thread->readVecPredReg(reg);
}
VecPredRegContainer&
getWritableVecPredRegOperand(const StaticInst *si, int idx) override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecPredReg());
return thread->getWritableVecPredReg(reg);
}
RegVal
readCCRegOperand(const StaticInst *si, int idx) override
{
const RegId& reg = si->srcRegIdx(idx);
assert(reg.isCCReg());
return thread->readCCReg(reg.index());
}
template<typename T>
void
setScalarResult(T&& t)
{
result.push(InstResult(std::forward<T>(t),
InstResult::ResultType::Scalar));
}
template<typename T>
void
setVecResult(T&& t)
{
result.push(InstResult(std::forward<T>(t),
InstResult::ResultType::VecReg));
}
template<typename T>
void
setVecElemResult(T&& t)
{
result.push(InstResult(std::forward<T>(t),
InstResult::ResultType::VecElem));
}
template<typename T>
void
setVecPredResult(T&& t)
{
result.push(InstResult(std::forward<T>(t),
InstResult::ResultType::VecPredReg));
}
void
setIntRegOperand(const StaticInst *si, int idx, RegVal val) override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isIntReg());
thread->setIntReg(reg.index(), val);
setScalarResult(val);
}
void
setFloatRegOperandBits(const StaticInst *si, int idx, RegVal val) override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isFloatReg());
thread->setFloatReg(reg.index(), val);
setScalarResult(val);
}
void
setCCRegOperand(const StaticInst *si, int idx, RegVal val) override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isCCReg());
thread->setCCReg(reg.index(), val);
setScalarResult((uint64_t)val);
}
void
setVecRegOperand(const StaticInst *si, int idx,
const VecRegContainer& val) override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecReg());
thread->setVecReg(reg, val);
setVecResult(val);
}
void
setVecElemOperand(const StaticInst *si, int idx,
const VecElem val) override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecElem());
thread->setVecElem(reg, val);
setVecElemResult(val);
}
void setVecPredRegOperand(const StaticInst *si, int idx,
const VecPredRegContainer& val) override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isVecPredReg());
thread->setVecPredReg(reg, val);
setVecPredResult(val);
}
bool readPredicate() const override { return thread->readPredicate(); }
void
setPredicate(bool val) override
{
thread->setPredicate(val);
}
bool
readMemAccPredicate() const override
{
return thread->readMemAccPredicate();
}
void
setMemAccPredicate(bool val) override
{
thread->setMemAccPredicate(val);
}
uint64_t
getHtmTransactionUid() const override
{
panic("not yet supported!");
return 0;
};
uint64_t
newHtmTransactionUid() const override
{
panic("not yet supported!");
return 0;
};
Fault
initiateHtmCmd(Request::Flags flags) override
{
panic("not yet supported!");
return NoFault;
}
bool
inHtmTransactionalState() const override
{
panic("not yet supported!");
return false;
}
uint64_t
getHtmTransactionalDepth() const override
{
panic("not yet supported!");
return 0;
}
TheISA::PCState pcState() const override { return thread->pcState(); }
void
pcState(const TheISA::PCState &val) override
{
DPRINTF(Checker, "Changing PC to %s, old PC %s.\n",
val, thread->pcState());
thread->pcState(val);
}
Addr instAddr() { return thread->instAddr(); }
Addr nextInstAddr() { return thread->nextInstAddr(); }
MicroPC microPC() { return thread->microPC(); }
//////////////////////////////////////////
RegVal
readMiscRegNoEffect(int misc_reg) const
{
return thread->readMiscRegNoEffect(misc_reg);
}
RegVal
readMiscReg(int misc_reg) override
{
return thread->readMiscReg(misc_reg);
}
void
setMiscRegNoEffect(int misc_reg, RegVal val)
{
DPRINTF(Checker, "Setting misc reg %d with no effect to check later\n",
misc_reg);
miscRegIdxs.push(misc_reg);
return thread->setMiscRegNoEffect(misc_reg, val);
}
void
setMiscReg(int misc_reg, RegVal val) override
{
DPRINTF(Checker, "Setting misc reg %d with effect to check later\n",
misc_reg);
miscRegIdxs.push(misc_reg);
return thread->setMiscReg(misc_reg, val);
}
RegVal
readMiscRegOperand(const StaticInst *si, int idx) override
{
const RegId& reg = si->srcRegIdx(idx);
assert(reg.isMiscReg());
return thread->readMiscReg(reg.index());
}
void
setMiscRegOperand(const StaticInst *si, int idx, RegVal val) override
{
const RegId& reg = si->destRegIdx(idx);
assert(reg.isMiscReg());
return this->setMiscReg(reg.index(), val);
}
/////////////////////////////////////////
void
recordPCChange(const TheISA::PCState &val)
{
changedPC = true;
newPCState = val;
}
void
demapPage(Addr vaddr, uint64_t asn) override
{
this->itb->demapPage(vaddr, asn);
this->dtb->demapPage(vaddr, asn);
}
// monitor/mwait funtions
void armMonitor(Addr address) override { BaseCPU::armMonitor(0, address); }
bool mwait(PacketPtr pkt) override { return BaseCPU::mwait(0, pkt); }
void mwaitAtomic(ThreadContext *tc) override
{ return BaseCPU::mwaitAtomic(0, tc, thread->dtb); }
AddressMonitor *getAddrMonitor() override
{ return BaseCPU::getCpuAddrMonitor(0); }
void
demapInstPage(Addr vaddr, uint64_t asn)
{
this->itb->demapPage(vaddr, asn);
}
void
demapDataPage(Addr vaddr, uint64_t asn)
{
this->dtb->demapPage(vaddr, asn);
}
/**
* Helper function used to generate the request for a single fragment of a
* memory access.
*
* Takes care of setting up the appropriate byte-enable mask for the
* fragment, given the mask for the entire memory access.
*
* @param frag_addr Start address of the fragment.
* @param size Total size of the memory access in bytes.
* @param flags Request flags.
* @param byte_enable Byte-enable mask for the entire memory access.
* @param[out] frag_size Fragment size.
* @param[in,out] size_left Size left to be processed in the memory access.
* @return Pointer to the allocated Request, nullptr if the byte-enable
* mask is all-false for the fragment.
*/
RequestPtr genMemFragmentRequest(Addr frag_addr, int size,
Request::Flags flags,
const std::vector<bool>& byte_enable,
int& frag_size, int& size_left) const;
Fault readMem(Addr addr, uint8_t *data, unsigned size,
Request::Flags flags,
const std::vector<bool>& byte_enable = std::vector<bool>())
override;
Fault writeMem(uint8_t *data, unsigned size, Addr addr,
Request::Flags flags, uint64_t *res,
const std::vector<bool>& byte_enable = std::vector<bool>())
override;
Fault amoMem(Addr addr, uint8_t* data, unsigned size,
Request::Flags flags, AtomicOpFunctorPtr amo_op) override
{
panic("AMO is not supported yet in CPU checker\n");
}
unsigned int
readStCondFailures() const override {
return thread->readStCondFailures();
}
void setStCondFailures(unsigned int sc_failures) override {}
/////////////////////////////////////////////////////
void wakeup(ThreadID tid) override { }
// Assume that the normal CPU's call to syscall was successful.
// The checker's state would have already been updated by the syscall.
void syscall() override { }
void
handleError()
{
if (exitOnError)
dumpAndExit();
}
bool checkFlags(const RequestPtr &unverified_req, Addr vAddr,
Addr pAddr, int flags);
void dumpAndExit();
ThreadContext *tcBase() const override { return tc; }
SimpleThread *threadBase() { return thread; }
InstResult unverifiedResult;
RequestPtr unverifiedReq;
uint8_t *unverifiedMemData;
bool changedPC;
bool willChangePC;
TheISA::PCState newPCState;
bool exitOnError;
bool updateOnError;
bool warnOnlyOnLoadError;
InstSeqNum youngestSN;
};
/**
* Templated Checker class. This Checker class is templated on the
* DynInstPtr of the instruction type that will be verified. Proper
* template instantiations of the Checker must be placed at the bottom
* of checker/cpu.cc.
*/
template <class Impl>
class Checker : public CheckerCPU
{
private:
typedef typename Impl::DynInstPtr DynInstPtr;
public:
Checker(Params *p)
: CheckerCPU(p), updateThisCycle(false), unverifiedInst(NULL)
{ }
void switchOut();
void takeOverFrom(BaseCPU *oldCPU);
void advancePC(const Fault &fault);
void verify(const DynInstPtr &inst);
void validateInst(const DynInstPtr &inst);
void validateExecution(const DynInstPtr &inst);
void validateState();
void copyResult(const DynInstPtr &inst, const InstResult& mismatch_val,
int start_idx);
void handlePendingInt();
private:
void handleError(const DynInstPtr &inst)
{
if (exitOnError) {
dumpAndExit(inst);
} else if (updateOnError) {
updateThisCycle = true;
}
}
void dumpAndExit(const DynInstPtr &inst);
bool updateThisCycle;
DynInstPtr unverifiedInst;
std::list<DynInstPtr> instList;
typedef typename std::list<DynInstPtr>::iterator InstListIt;
void dumpInsts();
};
#endif // __CPU_CHECKER_CPU_HH__