/* * Copyright (c) 2014-2018, 2020 ARM Limited * 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) 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. */ #ifndef __CPU_SIMPLE_EXEC_CONTEXT_HH__ #define __CPU_SIMPLE_EXEC_CONTEXT_HH__ #include "arch/vecregs.hh" #include "base/types.hh" #include "config/the_isa.hh" #include "cpu/base.hh" #include "cpu/exec_context.hh" #include "cpu/reg_class.hh" #include "cpu/simple/base.hh" #include "cpu/static_inst_fwd.hh" #include "cpu/translation.hh" #include "mem/request.hh" class BaseSimpleCPU; class SimpleExecContext : public ExecContext { public: BaseSimpleCPU *cpu; SimpleThread* thread; // This is the offset from the current pc that fetch should be performed Addr fetchOffset; // This flag says to stay at the current pc. This is useful for // instructions which go beyond MachInst boundaries. bool stayAtPC; // Branch prediction TheISA::PCState predPC; /** PER-THREAD STATS */ Counter numInst; Counter numOp; // Number of simulated loads Counter numLoad; // Number of cycles stalled for I-cache responses Counter lastIcacheStall; // Number of cycles stalled for D-cache responses Counter lastDcacheStall; struct ExecContextStats : public Stats::Group { ExecContextStats(BaseSimpleCPU *cpu, SimpleThread *thread) : Stats::Group(cpu, csprintf("exec_context.thread_%i", thread->threadId()).c_str()), ADD_STAT(numInsts, Stats::units::Count::get(), "Number of instructions committed"), ADD_STAT(numOps, Stats::units::Count::get(), "Number of ops (including micro ops) committed"), ADD_STAT(numIntAluAccesses, Stats::units::Count::get(), "Number of integer alu accesses"), ADD_STAT(numFpAluAccesses, Stats::units::Count::get(), "Number of float alu accesses"), ADD_STAT(numVecAluAccesses, Stats::units::Count::get(), "Number of vector alu accesses"), ADD_STAT(numCallsReturns, Stats::units::Count::get(), "Number of times a function call or return occured"), ADD_STAT(numCondCtrlInsts, Stats::units::Count::get(), "Number of instructions that are conditional controls"), ADD_STAT(numIntInsts, Stats::units::Count::get(), "Number of integer instructions"), ADD_STAT(numFpInsts, Stats::units::Count::get(), "Number of float instructions"), ADD_STAT(numVecInsts, Stats::units::Count::get(), "Number of vector instructions"), ADD_STAT(numIntRegReads, Stats::units::Count::get(), "Number of times the integer registers were read"), ADD_STAT(numIntRegWrites, Stats::units::Count::get(), "Number of times the integer registers were written"), ADD_STAT(numFpRegReads, Stats::units::Count::get(), "Number of times the floating registers were read"), ADD_STAT(numFpRegWrites, Stats::units::Count::get(), "Number of times the floating registers were written"), ADD_STAT(numVecRegReads, Stats::units::Count::get(), "Number of times the vector registers were read"), ADD_STAT(numVecRegWrites, Stats::units::Count::get(), "Number of times the vector registers were written"), ADD_STAT(numVecPredRegReads, Stats::units::Count::get(), "Number of times the predicate registers were read"), ADD_STAT(numVecPredRegWrites, Stats::units::Count::get(), "Number of times the predicate registers were written"), ADD_STAT(numCCRegReads, Stats::units::Count::get(), "Number of times the CC registers were read"), ADD_STAT(numCCRegWrites, Stats::units::Count::get(), "Number of times the CC registers were written"), ADD_STAT(numMemRefs, Stats::units::Count::get(), "Number of memory refs"), ADD_STAT(numLoadInsts, Stats::units::Count::get(), "Number of load instructions"), ADD_STAT(numStoreInsts, Stats::units::Count::get(), "Number of store instructions"), ADD_STAT(numIdleCycles, Stats::units::Cycle::get(), "Number of idle cycles"), ADD_STAT(numBusyCycles, Stats::units::Cycle::get(), "Number of busy cycles"), ADD_STAT(notIdleFraction, Stats::units::Ratio::get(), "Percentage of non-idle cycles"), ADD_STAT(idleFraction, Stats::units::Ratio::get(), "Percentage of idle cycles"), ADD_STAT(icacheStallCycles, Stats::units::Cycle::get(), "ICache total stall cycles"), ADD_STAT(dcacheStallCycles, Stats::units::Cycle::get(), "DCache total stall cycles"), ADD_STAT(numBranches, Stats::units::Count::get(), "Number of branches fetched"), ADD_STAT(numPredictedBranches, Stats::units::Count::get(), "Number of branches predicted as taken"), ADD_STAT(numBranchMispred, Stats::units::Count::get(), "Number of branch mispredictions"), ADD_STAT(statExecutedInstType, Stats::units::Count::get(), "Class of executed instruction.") { numCCRegReads .flags(Stats::nozero); numCCRegWrites .flags(Stats::nozero); icacheStallCycles .prereq(icacheStallCycles); dcacheStallCycles .prereq(dcacheStallCycles); statExecutedInstType .init(Enums::Num_OpClass) .flags(Stats::total | Stats::pdf | Stats::dist); for (unsigned i = 0; i < Num_OpClasses; ++i) { statExecutedInstType.subname(i, Enums::OpClassStrings[i]); } idleFraction = Stats::constant(1.0) - notIdleFraction; numIdleCycles = idleFraction * cpu->baseStats.numCycles; numBusyCycles = notIdleFraction * cpu->baseStats.numCycles; numBranches .prereq(numBranches); numPredictedBranches .prereq(numPredictedBranches); numBranchMispred .prereq(numBranchMispred); } // Number of simulated instructions Stats::Scalar numInsts; Stats::Scalar numOps; // Number of integer alu accesses Stats::Scalar numIntAluAccesses; // Number of float alu accesses Stats::Scalar numFpAluAccesses; // Number of vector alu accesses Stats::Scalar numVecAluAccesses; // Number of function calls/returns Stats::Scalar numCallsReturns; // Conditional control instructions; Stats::Scalar numCondCtrlInsts; // Number of int instructions Stats::Scalar numIntInsts; // Number of float instructions Stats::Scalar numFpInsts; // Number of vector instructions Stats::Scalar numVecInsts; // Number of integer register file accesses Stats::Scalar numIntRegReads; Stats::Scalar numIntRegWrites; // Number of float register file accesses Stats::Scalar numFpRegReads; Stats::Scalar numFpRegWrites; // Number of vector register file accesses mutable Stats::Scalar numVecRegReads; Stats::Scalar numVecRegWrites; // Number of predicate register file accesses mutable Stats::Scalar numVecPredRegReads; Stats::Scalar numVecPredRegWrites; // Number of condition code register file accesses Stats::Scalar numCCRegReads; Stats::Scalar numCCRegWrites; // Number of simulated memory references Stats::Scalar numMemRefs; Stats::Scalar numLoadInsts; Stats::Scalar numStoreInsts; // Number of idle cycles Stats::Formula numIdleCycles; // Number of busy cycles Stats::Formula numBusyCycles; // Number of idle cycles Stats::Average notIdleFraction; Stats::Formula idleFraction; // Number of cycles stalled for I-cache responses Stats::Scalar icacheStallCycles; // Number of cycles stalled for D-cache responses Stats::Scalar dcacheStallCycles; /// @{ /// Total number of branches fetched Stats::Scalar numBranches; /// Number of branches predicted as taken Stats::Scalar numPredictedBranches; /// Number of misprediced branches Stats::Scalar numBranchMispred; /// @} // Instruction mix histogram by OpClass Stats::Vector statExecutedInstType; } execContextStats; public: /** Constructor */ SimpleExecContext(BaseSimpleCPU* _cpu, SimpleThread* _thread) : cpu(_cpu), thread(_thread), fetchOffset(0), stayAtPC(false), numInst(0), numOp(0), numLoad(0), lastIcacheStall(0), lastDcacheStall(0), execContextStats(cpu, thread) { } /** Reads an integer register. */ RegVal readIntRegOperand(const StaticInst *si, int idx) override { execContextStats.numIntRegReads++; const RegId& reg = si->srcRegIdx(idx); assert(reg.is(IntRegClass)); return thread->readIntReg(reg.index()); } /** Sets an integer register to a value. */ void setIntRegOperand(const StaticInst *si, int idx, RegVal val) override { execContextStats.numIntRegWrites++; const RegId& reg = si->destRegIdx(idx); assert(reg.is(IntRegClass)); thread->setIntReg(reg.index(), val); } /** Reads a floating point register in its binary format, instead * of by value. */ RegVal readFloatRegOperandBits(const StaticInst *si, int idx) override { execContextStats.numFpRegReads++; const RegId& reg = si->srcRegIdx(idx); assert(reg.is(FloatRegClass)); return thread->readFloatReg(reg.index()); } /** Sets the bits of a floating point register of single width * to a binary value. */ void setFloatRegOperandBits(const StaticInst *si, int idx, RegVal val) override { execContextStats.numFpRegWrites++; const RegId& reg = si->destRegIdx(idx); assert(reg.is(FloatRegClass)); thread->setFloatReg(reg.index(), val); } /** Reads a vector register. */ const TheISA::VecRegContainer & readVecRegOperand(const StaticInst *si, int idx) const override { execContextStats.numVecRegReads++; const RegId& reg = si->srcRegIdx(idx); assert(reg.is(VecRegClass)); return thread->readVecReg(reg); } /** Reads a vector register for modification. */ TheISA::VecRegContainer & getWritableVecRegOperand(const StaticInst *si, int idx) override { execContextStats.numVecRegWrites++; const RegId& reg = si->destRegIdx(idx); assert(reg.is(VecRegClass)); return thread->getWritableVecReg(reg); } /** Sets a vector register to a value. */ void setVecRegOperand(const StaticInst *si, int idx, const TheISA::VecRegContainer& val) override { execContextStats.numVecRegWrites++; const RegId& reg = si->destRegIdx(idx); assert(reg.is(VecRegClass)); thread->setVecReg(reg, val); } /** Reads an element of a vector register. */ TheISA::VecElem readVecElemOperand(const StaticInst *si, int idx) const override { execContextStats.numVecRegReads++; const RegId& reg = si->srcRegIdx(idx); assert(reg.is(VecElemClass)); return thread->readVecElem(reg); } /** Sets an element of a vector register to a value. */ void setVecElemOperand(const StaticInst *si, int idx, const TheISA::VecElem val) override { execContextStats.numVecRegWrites++; const RegId& reg = si->destRegIdx(idx); assert(reg.is(VecElemClass)); thread->setVecElem(reg, val); } const TheISA::VecPredRegContainer& readVecPredRegOperand(const StaticInst *si, int idx) const override { execContextStats.numVecPredRegReads++; const RegId& reg = si->srcRegIdx(idx); assert(reg.is(VecPredRegClass)); return thread->readVecPredReg(reg); } TheISA::VecPredRegContainer& getWritableVecPredRegOperand(const StaticInst *si, int idx) override { execContextStats.numVecPredRegWrites++; const RegId& reg = si->destRegIdx(idx); assert(reg.is(VecPredRegClass)); return thread->getWritableVecPredReg(reg); } void setVecPredRegOperand(const StaticInst *si, int idx, const TheISA::VecPredRegContainer& val) override { execContextStats.numVecPredRegWrites++; const RegId& reg = si->destRegIdx(idx); assert(reg.is(VecPredRegClass)); thread->setVecPredReg(reg, val); } RegVal readCCRegOperand(const StaticInst *si, int idx) override { execContextStats.numCCRegReads++; const RegId& reg = si->srcRegIdx(idx); assert(reg.is(CCRegClass)); return thread->readCCReg(reg.index()); } void setCCRegOperand(const StaticInst *si, int idx, RegVal val) override { execContextStats.numCCRegWrites++; const RegId& reg = si->destRegIdx(idx); assert(reg.is(CCRegClass)); thread->setCCReg(reg.index(), val); } RegVal readMiscRegOperand(const StaticInst *si, int idx) override { execContextStats.numIntRegReads++; const RegId& reg = si->srcRegIdx(idx); assert(reg.is(MiscRegClass)); return thread->readMiscReg(reg.index()); } void setMiscRegOperand(const StaticInst *si, int idx, RegVal val) override { execContextStats.numIntRegWrites++; const RegId& reg = si->destRegIdx(idx); assert(reg.is(MiscRegClass)); thread->setMiscReg(reg.index(), val); } /** * Reads a miscellaneous register, handling any architectural * side effects due to reading that register. */ RegVal readMiscReg(int misc_reg) override { execContextStats.numIntRegReads++; return thread->readMiscReg(misc_reg); } /** * Sets a miscellaneous register, handling any architectural * side effects due to writing that register. */ void setMiscReg(int misc_reg, RegVal val) override { execContextStats.numIntRegWrites++; thread->setMiscReg(misc_reg, val); } TheISA::PCState pcState() const override { return thread->pcState(); } void pcState(const TheISA::PCState &val) override { thread->pcState(val); } Fault readMem(Addr addr, uint8_t *data, unsigned int size, Request::Flags flags, const std::vector& byte_enable) override { assert(byte_enable.size() == size); return cpu->readMem(addr, data, size, flags, byte_enable); } Fault initiateMemRead(Addr addr, unsigned int size, Request::Flags flags, const std::vector& byte_enable) override { assert(byte_enable.size() == size); return cpu->initiateMemRead(addr, size, flags, byte_enable); } Fault writeMem(uint8_t *data, unsigned int size, Addr addr, Request::Flags flags, uint64_t *res, const std::vector& byte_enable) override { assert(byte_enable.size() == size); return cpu->writeMem(data, size, addr, flags, res, byte_enable); } Fault amoMem(Addr addr, uint8_t *data, unsigned int size, Request::Flags flags, AtomicOpFunctorPtr amo_op) override { return cpu->amoMem(addr, data, size, flags, std::move(amo_op)); } Fault initiateMemAMO(Addr addr, unsigned int size, Request::Flags flags, AtomicOpFunctorPtr amo_op) override { return cpu->initiateMemAMO(addr, size, flags, std::move(amo_op)); } Fault initiateHtmCmd(Request::Flags flags) override { return cpu->initiateHtmCmd(flags); } /** * Sets the number of consecutive store conditional failures. */ void setStCondFailures(unsigned int sc_failures) override { thread->setStCondFailures(sc_failures); } /** * Returns the number of consecutive store conditional failures. */ unsigned int readStCondFailures() const override { return thread->readStCondFailures(); } /** Returns a pointer to the ThreadContext. */ ThreadContext *tcBase() const override { return thread->getTC(); } bool readPredicate() const override { return thread->readPredicate(); } void setPredicate(bool val) override { thread->setPredicate(val); if (cpu->traceData) { cpu->traceData->setPredicate(val); } } bool readMemAccPredicate() const override { return thread->readMemAccPredicate(); } void setMemAccPredicate(bool val) override { thread->setMemAccPredicate(val); } uint64_t getHtmTransactionUid() const override { return tcBase()->getHtmCheckpointPtr()->getHtmUid(); } uint64_t newHtmTransactionUid() const override { return tcBase()->getHtmCheckpointPtr()->newHtmUid(); } bool inHtmTransactionalState() const override { return (getHtmTransactionalDepth() > 0); } uint64_t getHtmTransactionalDepth() const override { assert(thread->htmTransactionStarts >= thread->htmTransactionStops); return (thread->htmTransactionStarts - thread->htmTransactionStops); } /** * Invalidate a page in the DTLB and ITLB. */ void demapPage(Addr vaddr, uint64_t asn) override { thread->demapPage(vaddr, asn); } void armMonitor(Addr address) override { cpu->armMonitor(thread->threadId(), address); } bool mwait(PacketPtr pkt) override { return cpu->mwait(thread->threadId(), pkt); } void mwaitAtomic(ThreadContext *tc) override { cpu->mwaitAtomic(thread->threadId(), tc, thread->mmu); } AddressMonitor * getAddrMonitor() override { return cpu->getCpuAddrMonitor(thread->threadId()); } }; #endif // __CPU_EXEC_CONTEXT_HH__