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/*
* Copyright (c) 2011-2012, 2016-2018 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) 2001-2006 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.
*
* Authors: Steve Reinhardt
* Nathan Binkert
*/
#ifndef __CPU_SIMPLE_THREAD_HH__
#define __CPU_SIMPLE_THREAD_HH__
#include "arch/decoder.hh"
#include "arch/generic/tlb.hh"
#include "arch/isa.hh"
#include "arch/isa_traits.hh"
#include "arch/registers.hh"
#include "arch/types.hh"
#include "base/types.hh"
#include "config/the_isa.hh"
#include "cpu/thread_context.hh"
#include "cpu/thread_state.hh"
#include "debug/CCRegs.hh"
#include "debug/FloatRegs.hh"
#include "debug/IntRegs.hh"
#include "debug/VecPredRegs.hh"
#include "debug/VecRegs.hh"
#include "mem/page_table.hh"
#include "mem/request.hh"
#include "sim/byteswap.hh"
#include "sim/eventq.hh"
#include "sim/process.hh"
#include "sim/serialize.hh"
#include "sim/system.hh"
class BaseCPU;
class CheckerCPU;
class FunctionProfile;
class ProfileNode;
namespace TheISA {
namespace Kernel {
class Statistics;
}
}
/**
* The SimpleThread object provides a combination of the ThreadState
* object and the ThreadContext interface. It implements the
* ThreadContext interface and adds to the ThreadState object by adding all
* the objects needed for simple functional execution, including a
* simple architectural register file, and pointers to the ITB and DTB
* in full system mode. For CPU models that do not need more advanced
* ways to hold state (i.e. a separate physical register file, or
* separate fetch and commit PC's), this SimpleThread class provides
* all the necessary state for full architecture-level functional
* simulation. See the AtomicSimpleCPU or TimingSimpleCPU for
* examples.
*/
class SimpleThread : public ThreadState, public ThreadContext
{
protected:
typedef TheISA::MachInst MachInst;
using VecRegContainer = TheISA::VecRegContainer;
using VecElem = TheISA::VecElem;
using VecPredRegContainer = TheISA::VecPredRegContainer;
public:
typedef ThreadContext::Status Status;
protected:
RegVal floatRegs[TheISA::NumFloatRegs];
RegVal intRegs[TheISA::NumIntRegs];
VecRegContainer vecRegs[TheISA::NumVecRegs];
VecPredRegContainer vecPredRegs[TheISA::NumVecPredRegs];
#ifdef ISA_HAS_CC_REGS
RegVal ccRegs[TheISA::NumCCRegs];
#endif
TheISA::ISA *const isa; // one "instance" of the current ISA.
TheISA::PCState _pcState;
/** Did this instruction execute or is it predicated false */
bool predicate;
public:
std::string name() const
{
return csprintf("%s.[tid:%i]", baseCpu->name(), threadId());
}
System *system;
BaseTLB *itb;
BaseTLB *dtb;
TheISA::Decoder decoder;
// constructor: initialize SimpleThread from given process structure
// FS
SimpleThread(BaseCPU *_cpu, int _thread_num, System *_system,
BaseTLB *_itb, BaseTLB *_dtb, TheISA::ISA *_isa,
bool use_kernel_stats = true);
// SE
SimpleThread(BaseCPU *_cpu, int _thread_num, System *_system,
Process *_process, BaseTLB *_itb, BaseTLB *_dtb,
TheISA::ISA *_isa);
virtual ~SimpleThread() {}
void takeOverFrom(ThreadContext *oldContext) override;
void regStats(const std::string &name) override;
void copyState(ThreadContext *oldContext);
void serialize(CheckpointOut &cp) const override;
void unserialize(CheckpointIn &cp) override;
void startup();
/***************************************************************
* SimpleThread functions to provide CPU with access to various
* state.
**************************************************************/
/** Returns the pointer to this SimpleThread's ThreadContext. Used
* when a ThreadContext must be passed to objects outside of the
* CPU.
*/
ThreadContext *getTC() { return this; }
void demapPage(Addr vaddr, uint64_t asn)
{
itb->demapPage(vaddr, asn);
dtb->demapPage(vaddr, asn);
}
void demapInstPage(Addr vaddr, uint64_t asn)
{
itb->demapPage(vaddr, asn);
}
void demapDataPage(Addr vaddr, uint64_t asn)
{
dtb->demapPage(vaddr, asn);
}
void dumpFuncProfile() override;
Fault hwrei();
bool simPalCheck(int palFunc);
/*******************************************
* ThreadContext interface functions.
******************************************/
BaseCPU *getCpuPtr() override { return baseCpu; }
int cpuId() const override { return ThreadState::cpuId(); }
uint32_t socketId() const override { return ThreadState::socketId(); }
int threadId() const override { return ThreadState::threadId(); }
void setThreadId(int id) override { ThreadState::setThreadId(id); }
ContextID contextId() const override { return ThreadState::contextId(); }
void setContextId(ContextID id) override { ThreadState::setContextId(id); }
BaseTLB *getITBPtr() override { return itb; }
BaseTLB *getDTBPtr() override { return dtb; }
CheckerCPU *getCheckerCpuPtr() override { return NULL; }
TheISA::ISA *getIsaPtr() override { return isa; }
TheISA::Decoder *getDecoderPtr() override { return &decoder; }
System *getSystemPtr() override { return system; }
TheISA::Kernel::Statistics *
getKernelStats() override
{
return ThreadState::getKernelStats();
}
PortProxy &getPhysProxy() override { return ThreadState::getPhysProxy(); }
FSTranslatingPortProxy &
getVirtProxy() override
{
return ThreadState::getVirtProxy();
}
void initMemProxies(ThreadContext *tc) override
{
ThreadState::initMemProxies(tc);
}
SETranslatingPortProxy &
getMemProxy() override
{
return ThreadState::getMemProxy();
}
Process *getProcessPtr() override { return ThreadState::getProcessPtr(); }
void setProcessPtr(Process *p) override { ThreadState::setProcessPtr(p); }
Status status() const override { return _status; }
void setStatus(Status newStatus) override { _status = newStatus; }
/// Set the status to Active.
void activate() override;
/// Set the status to Suspended.
void suspend() override;
/// Set the status to Halted.
void halt() override;
EndQuiesceEvent *
getQuiesceEvent() override
{
return ThreadState::getQuiesceEvent();
}
Tick
readLastActivate() override
{
return ThreadState::readLastActivate();
}
Tick
readLastSuspend() override
{
return ThreadState::readLastSuspend();
}
void profileClear() override { ThreadState::profileClear(); }
void profileSample() override { ThreadState::profileSample(); }
void copyArchRegs(ThreadContext *tc) override;
void clearArchRegs() override
{
_pcState = 0;
memset(intRegs, 0, sizeof(intRegs));
memset(floatRegs, 0, sizeof(floatRegs));
for (int i = 0; i < TheISA::NumVecRegs; i++) {
vecRegs[i].zero();
}
for (int i = 0; i < TheISA::NumVecPredRegs; i++) {
vecPredRegs[i].reset();
}
#ifdef ISA_HAS_CC_REGS
memset(ccRegs, 0, sizeof(ccRegs));
#endif
isa->clear();
}
//
// New accessors for new decoder.
//
RegVal
readIntReg(RegIndex reg_idx) const override
{
int flatIndex = isa->flattenIntIndex(reg_idx);
assert(flatIndex < TheISA::NumIntRegs);
uint64_t regVal(readIntRegFlat(flatIndex));
DPRINTF(IntRegs, "Reading int reg %d (%d) as %#x.\n",
reg_idx, flatIndex, regVal);
return regVal;
}
RegVal
readFloatReg(RegIndex reg_idx) const override
{
int flatIndex = isa->flattenFloatIndex(reg_idx);
assert(flatIndex < TheISA::NumFloatRegs);
RegVal regVal(readFloatRegFlat(flatIndex));
DPRINTF(FloatRegs, "Reading float reg %d (%d) bits as %#x.\n",
reg_idx, flatIndex, regVal);
return regVal;
}
const VecRegContainer&
readVecReg(const RegId& reg) const override
{
int flatIndex = isa->flattenVecIndex(reg.index());
assert(flatIndex < TheISA::NumVecRegs);
const VecRegContainer& regVal = readVecRegFlat(flatIndex);
DPRINTF(VecRegs, "Reading vector reg %d (%d) as %s.\n",
reg.index(), flatIndex, regVal.print());
return regVal;
}
VecRegContainer&
getWritableVecReg(const RegId& reg) override
{
int flatIndex = isa->flattenVecIndex(reg.index());
assert(flatIndex < TheISA::NumVecRegs);
VecRegContainer& regVal = getWritableVecRegFlat(flatIndex);
DPRINTF(VecRegs, "Reading vector reg %d (%d) as %s for modify.\n",
reg.index(), flatIndex, regVal.print());
return regVal;
}
/** Vector Register Lane Interfaces. */
/** @{ */
/** Reads source vector <T> operand. */
template <typename T>
VecLaneT<T, true>
readVecLane(const RegId& reg) const
{
int flatIndex = isa->flattenVecIndex(reg.index());
assert(flatIndex < TheISA::NumVecRegs);
auto regVal = readVecLaneFlat<T>(flatIndex, reg.elemIndex());
DPRINTF(VecRegs, "Reading vector lane %d (%d)[%d] as %lx.\n",
reg.index(), flatIndex, reg.elemIndex(), regVal);
return regVal;
}
/** Reads source vector 8bit operand. */
virtual ConstVecLane8
readVec8BitLaneReg(const RegId ®) const override
{
return readVecLane<uint8_t>(reg);
}
/** Reads source vector 16bit operand. */
virtual ConstVecLane16
readVec16BitLaneReg(const RegId ®) const override
{
return readVecLane<uint16_t>(reg);
}
/** Reads source vector 32bit operand. */
virtual ConstVecLane32
readVec32BitLaneReg(const RegId ®) const override
{
return readVecLane<uint32_t>(reg);
}
/** Reads source vector 64bit operand. */
virtual ConstVecLane64
readVec64BitLaneReg(const RegId ®) const override
{
return readVecLane<uint64_t>(reg);
}
/** Write a lane of the destination vector register. */
template <typename LD>
void
setVecLaneT(const RegId ®, const LD &val)
{
int flatIndex = isa->flattenVecIndex(reg.index());
assert(flatIndex < TheISA::NumVecRegs);
setVecLaneFlat(flatIndex, reg.elemIndex(), val);
DPRINTF(VecRegs, "Reading vector lane %d (%d)[%d] to %lx.\n",
reg.index(), flatIndex, reg.elemIndex(), val);
}
virtual void
setVecLane(const RegId ®, const LaneData<LaneSize::Byte> &val) override
{
return setVecLaneT(reg, val);
}
virtual void
setVecLane(const RegId ®,
const LaneData<LaneSize::TwoByte> &val) override
{
return setVecLaneT(reg, val);
}
virtual void
setVecLane(const RegId ®,
const LaneData<LaneSize::FourByte> &val) override
{
return setVecLaneT(reg, val);
}
virtual void
setVecLane(const RegId ®,
const LaneData<LaneSize::EightByte> &val) override
{
return setVecLaneT(reg, val);
}
/** @} */
const VecElem &
readVecElem(const RegId ®) const override
{
int flatIndex = isa->flattenVecElemIndex(reg.index());
assert(flatIndex < TheISA::NumVecRegs);
const VecElem& regVal = readVecElemFlat(flatIndex, reg.elemIndex());
DPRINTF(VecRegs, "Reading element %d of vector reg %d (%d) as"
" %#x.\n", reg.elemIndex(), reg.index(), flatIndex, regVal);
return regVal;
}
const VecPredRegContainer &
readVecPredReg(const RegId ®) const override
{
int flatIndex = isa->flattenVecPredIndex(reg.index());
assert(flatIndex < TheISA::NumVecPredRegs);
const VecPredRegContainer& regVal = readVecPredRegFlat(flatIndex);
DPRINTF(VecPredRegs, "Reading predicate reg %d (%d) as %s.\n",
reg.index(), flatIndex, regVal.print());
return regVal;
}
VecPredRegContainer &
getWritableVecPredReg(const RegId ®) override
{
int flatIndex = isa->flattenVecPredIndex(reg.index());
assert(flatIndex < TheISA::NumVecPredRegs);
VecPredRegContainer& regVal = getWritableVecPredRegFlat(flatIndex);
DPRINTF(VecPredRegs,
"Reading predicate reg %d (%d) as %s for modify.\n",
reg.index(), flatIndex, regVal.print());
return regVal;
}
RegVal
readCCReg(RegIndex reg_idx) const override
{
#ifdef ISA_HAS_CC_REGS
int flatIndex = isa->flattenCCIndex(reg_idx);
assert(0 <= flatIndex);
assert(flatIndex < TheISA::NumCCRegs);
uint64_t regVal(readCCRegFlat(flatIndex));
DPRINTF(CCRegs, "Reading CC reg %d (%d) as %#x.\n",
reg_idx, flatIndex, regVal);
return regVal;
#else
panic("Tried to read a CC register.");
return 0;
#endif
}
void
setIntReg(RegIndex reg_idx, RegVal val) override
{
int flatIndex = isa->flattenIntIndex(reg_idx);
assert(flatIndex < TheISA::NumIntRegs);
DPRINTF(IntRegs, "Setting int reg %d (%d) to %#x.\n",
reg_idx, flatIndex, val);
setIntRegFlat(flatIndex, val);
}
void
setFloatReg(RegIndex reg_idx, RegVal val) override
{
int flatIndex = isa->flattenFloatIndex(reg_idx);
assert(flatIndex < TheISA::NumFloatRegs);
// XXX: Fix array out of bounds compiler error for gem5.fast
// when checkercpu enabled
if (flatIndex < TheISA::NumFloatRegs)
setFloatRegFlat(flatIndex, val);
DPRINTF(FloatRegs, "Setting float reg %d (%d) bits to %#x.\n",
reg_idx, flatIndex, val);
}
void
setVecReg(const RegId ®, const VecRegContainer &val) override
{
int flatIndex = isa->flattenVecIndex(reg.index());
assert(flatIndex < TheISA::NumVecRegs);
setVecRegFlat(flatIndex, val);
DPRINTF(VecRegs, "Setting vector reg %d (%d) to %s.\n",
reg.index(), flatIndex, val.print());
}
void
setVecElem(const RegId ®, const VecElem &val) override
{
int flatIndex = isa->flattenVecElemIndex(reg.index());
assert(flatIndex < TheISA::NumVecRegs);
setVecElemFlat(flatIndex, reg.elemIndex(), val);
DPRINTF(VecRegs, "Setting element %d of vector reg %d (%d) to"
" %#x.\n", reg.elemIndex(), reg.index(), flatIndex, val);
}
void
setVecPredReg(const RegId ®, const VecPredRegContainer &val) override
{
int flatIndex = isa->flattenVecPredIndex(reg.index());
assert(flatIndex < TheISA::NumVecPredRegs);
setVecPredRegFlat(flatIndex, val);
DPRINTF(VecPredRegs, "Setting predicate reg %d (%d) to %s.\n",
reg.index(), flatIndex, val.print());
}
void
setCCReg(RegIndex reg_idx, RegVal val) override
{
#ifdef ISA_HAS_CC_REGS
int flatIndex = isa->flattenCCIndex(reg_idx);
assert(flatIndex < TheISA::NumCCRegs);
DPRINTF(CCRegs, "Setting CC reg %d (%d) to %#x.\n",
reg_idx, flatIndex, val);
setCCRegFlat(flatIndex, val);
#else
panic("Tried to set a CC register.");
#endif
}
TheISA::PCState pcState() const override { return _pcState; }
void pcState(const TheISA::PCState &val) override { _pcState = val; }
void
pcStateNoRecord(const TheISA::PCState &val) override
{
_pcState = val;
}
Addr instAddr() const override { return _pcState.instAddr(); }
Addr nextInstAddr() const override { return _pcState.nextInstAddr(); }
MicroPC microPC() const override { return _pcState.microPC(); }
bool readPredicate() const { return predicate; }
void setPredicate(bool val) { predicate = val; }
RegVal
readMiscRegNoEffect(RegIndex misc_reg) const override
{
return isa->readMiscRegNoEffect(misc_reg);
}
RegVal
readMiscReg(RegIndex misc_reg) override
{
return isa->readMiscReg(misc_reg, this);
}
void
setMiscRegNoEffect(RegIndex misc_reg, RegVal val) override
{
return isa->setMiscRegNoEffect(misc_reg, val);
}
void
setMiscReg(RegIndex misc_reg, RegVal val) override
{
return isa->setMiscReg(misc_reg, val, this);
}
RegId
flattenRegId(const RegId& regId) const override
{
return isa->flattenRegId(regId);
}
unsigned readStCondFailures() const override { return storeCondFailures; }
void
setStCondFailures(unsigned sc_failures) override
{
storeCondFailures = sc_failures;
}
Counter
readFuncExeInst() const override
{
return ThreadState::readFuncExeInst();
}
void
syscall(int64_t callnum, Fault *fault) override
{
process->syscall(callnum, this, fault);
}
RegVal readIntRegFlat(RegIndex idx) const override { return intRegs[idx]; }
void
setIntRegFlat(RegIndex idx, RegVal val) override
{
intRegs[idx] = val;
}
RegVal
readFloatRegFlat(RegIndex idx) const override
{
return floatRegs[idx];
}
void
setFloatRegFlat(RegIndex idx, RegVal val) override
{
floatRegs[idx] = val;
}
const VecRegContainer &
readVecRegFlat(RegIndex reg) const override
{
return vecRegs[reg];
}
VecRegContainer &
getWritableVecRegFlat(RegIndex reg) override
{
return vecRegs[reg];
}
void
setVecRegFlat(RegIndex reg, const VecRegContainer &val) override
{
vecRegs[reg] = val;
}
template <typename T>
VecLaneT<T, true>
readVecLaneFlat(RegIndex reg, int lId) const
{
return vecRegs[reg].laneView<T>(lId);
}
template <typename LD>
void
setVecLaneFlat(RegIndex reg, int lId, const LD &val)
{
vecRegs[reg].laneView<typename LD::UnderlyingType>(lId) = val;
}
const VecElem &
readVecElemFlat(RegIndex reg, const ElemIndex &elemIndex) const override
{
return vecRegs[reg].as<TheISA::VecElem>()[elemIndex];
}
void
setVecElemFlat(RegIndex reg, const ElemIndex &elemIndex,
const VecElem &val) override
{
vecRegs[reg].as<TheISA::VecElem>()[elemIndex] = val;
}
const VecPredRegContainer &
readVecPredRegFlat(RegIndex reg) const override
{
return vecPredRegs[reg];
}
VecPredRegContainer &
getWritableVecPredRegFlat(RegIndex reg) override
{
return vecPredRegs[reg];
}
void
setVecPredRegFlat(RegIndex reg, const VecPredRegContainer &val) override
{
vecPredRegs[reg] = val;
}
#ifdef ISA_HAS_CC_REGS
RegVal readCCRegFlat(RegIndex idx) const override { return ccRegs[idx]; }
void setCCRegFlat(RegIndex idx, RegVal val) override { ccRegs[idx] = val; }
#else
RegVal
readCCRegFlat(RegIndex idx) const override
{
panic("readCCRegFlat w/no CC regs!\n");
}
void
setCCRegFlat(RegIndex idx, RegVal val) override
{
panic("setCCRegFlat w/no CC regs!\n");
}
#endif
};
#endif // __CPU_CPU_EXEC_CONTEXT_HH__
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