/* * Copyright (c) 2010-2014 ARM Limited * Copyright (c) 2012-2013 AMD * 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) 2004-2006 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: Kevin Lim * Korey Sewell */ #ifndef __CPU_O3_FETCH_IMPL_HH__ #define __CPU_O3_FETCH_IMPL_HH__ #include #include #include #include #include #include "arch/generic/tlb.hh" #include "arch/isa_traits.hh" #include "arch/utility.hh" #include "arch/vtophys.hh" #include "base/random.hh" #include "base/types.hh" #include "config/the_isa.hh" #include "cpu/base.hh" //#include "cpu/checker/cpu.hh" #include "cpu/o3/fetch.hh" #include "cpu/exetrace.hh" #include "debug/Activity.hh" #include "debug/Drain.hh" #include "debug/Fetch.hh" #include "debug/O3PipeView.hh" #include "mem/packet.hh" #include "params/DerivO3CPU.hh" #include "sim/byteswap.hh" #include "sim/core.hh" #include "sim/eventq.hh" #include "sim/full_system.hh" #include "sim/system.hh" #include "cpu/o3/isa_specific.hh" using namespace std; template DefaultFetch::DefaultFetch(O3CPU *_cpu, DerivO3CPUParams *params) : cpu(_cpu), branchPred(nullptr), decodeToFetchDelay(params->decodeToFetchDelay), renameToFetchDelay(params->renameToFetchDelay), iewToFetchDelay(params->iewToFetchDelay), commitToFetchDelay(params->commitToFetchDelay), fetchWidth(params->fetchWidth), decodeWidth(params->decodeWidth), retryPkt(NULL), retryTid(InvalidThreadID), cacheBlkSize(cpu->cacheLineSize()), fetchBufferSize(params->fetchBufferSize), fetchBufferMask(fetchBufferSize - 1), fetchQueueSize(params->fetchQueueSize), numThreads(params->numThreads), numFetchingThreads(params->smtNumFetchingThreads), finishTranslationEvent(this) { if (numThreads > Impl::MaxThreads) fatal("numThreads (%d) is larger than compiled limit (%d),\n" "\tincrease MaxThreads in src/cpu/o3/impl.hh\n", numThreads, static_cast(Impl::MaxThreads)); if (fetchWidth > Impl::MaxWidth) fatal("fetchWidth (%d) is larger than compiled limit (%d),\n" "\tincrease MaxWidth in src/cpu/o3/impl.hh\n", fetchWidth, static_cast(Impl::MaxWidth)); if (fetchBufferSize > cacheBlkSize) fatal("fetch buffer size (%u bytes) is greater than the cache " "block size (%u bytes)\n", fetchBufferSize, cacheBlkSize); if (cacheBlkSize % fetchBufferSize) fatal("cache block (%u bytes) is not a multiple of the " "fetch buffer (%u bytes)\n", cacheBlkSize, fetchBufferSize); std::string policy = params->smtFetchPolicy; // Convert string to lowercase std::transform(policy.begin(), policy.end(), policy.begin(), (int(*)(int)) tolower); // Figure out fetch policy if (policy == "singlethread") { fetchPolicy = SingleThread; if (numThreads > 1) panic("Invalid Fetch Policy for a SMT workload."); } else if (policy == "roundrobin") { fetchPolicy = RoundRobin; DPRINTF(Fetch, "Fetch policy set to Round Robin\n"); } else if (policy == "branch") { fetchPolicy = Branch; DPRINTF(Fetch, "Fetch policy set to Branch Count\n"); } else if (policy == "iqcount") { fetchPolicy = IQ; DPRINTF(Fetch, "Fetch policy set to IQ count\n"); } else if (policy == "lsqcount") { fetchPolicy = LSQ; DPRINTF(Fetch, "Fetch policy set to LSQ count\n"); } else { fatal("Invalid Fetch Policy. Options Are: {SingleThread," " RoundRobin,LSQcount,IQcount}\n"); } // Get the size of an instruction. instSize = sizeof(TheISA::MachInst); for (int i = 0; i < Impl::MaxThreads; i++) { fetchStatus[i] = Idle; decoder[i] = nullptr; pc[i] = 0; fetchOffset[i] = 0; macroop[i] = nullptr; delayedCommit[i] = false; memReq[i] = nullptr; stalls[i] = {false, false}; fetchBuffer[i] = NULL; fetchBufferPC[i] = 0; fetchBufferValid[i] = false; lastIcacheStall[i] = 0; issuePipelinedIfetch[i] = false; } branchPred = params->branchPred; for (ThreadID tid = 0; tid < numThreads; tid++) { decoder[tid] = new TheISA::Decoder(params->isa[tid]); // Create space to buffer the cache line data, // which may not hold the entire cache line. fetchBuffer[tid] = new uint8_t[fetchBufferSize]; } } template std::string DefaultFetch::name() const { return cpu->name() + ".fetch"; } template void DefaultFetch::regProbePoints() { ppFetch = new ProbePointArg(cpu->getProbeManager(), "Fetch"); ppFetchRequestSent = new ProbePointArg(cpu->getProbeManager(), "FetchRequest"); } template void DefaultFetch::regStats() { icacheStallCycles .name(name() + ".icacheStallCycles") .desc("Number of cycles fetch is stalled on an Icache miss") .prereq(icacheStallCycles); fetchedInsts .name(name() + ".Insts") .desc("Number of instructions fetch has processed") .prereq(fetchedInsts); fetchedBranches .name(name() + ".Branches") .desc("Number of branches that fetch encountered") .prereq(fetchedBranches); predictedBranches .name(name() + ".predictedBranches") .desc("Number of branches that fetch has predicted taken") .prereq(predictedBranches); fetchCycles .name(name() + ".Cycles") .desc("Number of cycles fetch has run and was not squashing or" " blocked") .prereq(fetchCycles); fetchSquashCycles .name(name() + ".SquashCycles") .desc("Number of cycles fetch has spent squashing") .prereq(fetchSquashCycles); fetchTlbCycles .name(name() + ".TlbCycles") .desc("Number of cycles fetch has spent waiting for tlb") .prereq(fetchTlbCycles); fetchIdleCycles .name(name() + ".IdleCycles") .desc("Number of cycles fetch was idle") .prereq(fetchIdleCycles); fetchBlockedCycles .name(name() + ".BlockedCycles") .desc("Number of cycles fetch has spent blocked") .prereq(fetchBlockedCycles); fetchedCacheLines .name(name() + ".CacheLines") .desc("Number of cache lines fetched") .prereq(fetchedCacheLines); fetchMiscStallCycles .name(name() + ".MiscStallCycles") .desc("Number of cycles fetch has spent waiting on interrupts, or " "bad addresses, or out of MSHRs") .prereq(fetchMiscStallCycles); fetchPendingDrainCycles .name(name() + ".PendingDrainCycles") .desc("Number of cycles fetch has spent waiting on pipes to drain") .prereq(fetchPendingDrainCycles); fetchNoActiveThreadStallCycles .name(name() + ".NoActiveThreadStallCycles") .desc("Number of stall cycles due to no active thread to fetch from") .prereq(fetchNoActiveThreadStallCycles); fetchPendingTrapStallCycles .name(name() + ".PendingTrapStallCycles") .desc("Number of stall cycles due to pending traps") .prereq(fetchPendingTrapStallCycles); fetchPendingQuiesceStallCycles .name(name() + ".PendingQuiesceStallCycles") .desc("Number of stall cycles due to pending quiesce instructions") .prereq(fetchPendingQuiesceStallCycles); fetchIcacheWaitRetryStallCycles .name(name() + ".IcacheWaitRetryStallCycles") .desc("Number of stall cycles due to full MSHR") .prereq(fetchIcacheWaitRetryStallCycles); fetchIcacheSquashes .name(name() + ".IcacheSquashes") .desc("Number of outstanding Icache misses that were squashed") .prereq(fetchIcacheSquashes); fetchTlbSquashes .name(name() + ".ItlbSquashes") .desc("Number of outstanding ITLB misses that were squashed") .prereq(fetchTlbSquashes); fetchNisnDist .init(/* base value */ 0, /* last value */ fetchWidth, /* bucket size */ 1) .name(name() + ".rateDist") .desc("Number of instructions fetched each cycle (Total)") .flags(Stats::pdf); idleRate .name(name() + ".idleRate") .desc("Percent of cycles fetch was idle") .prereq(idleRate); idleRate = fetchIdleCycles * 100 / cpu->numCycles; branchRate .name(name() + ".branchRate") .desc("Number of branch fetches per cycle") .flags(Stats::total); branchRate = fetchedBranches / cpu->numCycles; fetchRate .name(name() + ".rate") .desc("Number of inst fetches per cycle") .flags(Stats::total); fetchRate = fetchedInsts / cpu->numCycles; } template void DefaultFetch::setTimeBuffer(TimeBuffer *time_buffer) { timeBuffer = time_buffer; // Create wires to get information from proper places in time buffer. fromDecode = timeBuffer->getWire(-decodeToFetchDelay); fromRename = timeBuffer->getWire(-renameToFetchDelay); fromIEW = timeBuffer->getWire(-iewToFetchDelay); fromCommit = timeBuffer->getWire(-commitToFetchDelay); } template void DefaultFetch::setActiveThreads(std::list *at_ptr) { activeThreads = at_ptr; } template void DefaultFetch::setFetchQueue(TimeBuffer *ftb_ptr) { // Create wire to write information to proper place in fetch time buf. toDecode = ftb_ptr->getWire(0); } template void DefaultFetch::startupStage() { assert(priorityList.empty()); resetStage(); // Fetch needs to start fetching instructions at the very beginning, // so it must start up in active state. switchToActive(); } template void DefaultFetch::resetStage() { numInst = 0; interruptPending = false; cacheBlocked = false; priorityList.clear(); // Setup PC and nextPC with initial state. for (ThreadID tid = 0; tid < numThreads; ++tid) { fetchStatus[tid] = Running; pc[tid] = cpu->pcState(tid); fetchOffset[tid] = 0; macroop[tid] = NULL; delayedCommit[tid] = false; memReq[tid] = NULL; stalls[tid].decode = false; stalls[tid].drain = false; fetchBufferPC[tid] = 0; fetchBufferValid[tid] = false; fetchQueue[tid].clear(); priorityList.push_back(tid); } wroteToTimeBuffer = false; _status = Inactive; } template void DefaultFetch::processCacheCompletion(PacketPtr pkt) { ThreadID tid = cpu->contextToThread(pkt->req->contextId()); DPRINTF(Fetch, "[tid:%u] Waking up from cache miss.\n", tid); assert(!cpu->switchedOut()); // Only change the status if it's still waiting on the icache access // to return. if (fetchStatus[tid] != IcacheWaitResponse || pkt->req != memReq[tid]) { ++fetchIcacheSquashes; delete pkt; return; } memcpy(fetchBuffer[tid], pkt->getConstPtr(), fetchBufferSize); fetchBufferValid[tid] = true; // Wake up the CPU (if it went to sleep and was waiting on // this completion event). cpu->wakeCPU(); DPRINTF(Activity, "[tid:%u] Activating fetch due to cache completion\n", tid); switchToActive(); // Only switch to IcacheAccessComplete if we're not stalled as well. if (checkStall(tid)) { fetchStatus[tid] = Blocked; } else { fetchStatus[tid] = IcacheAccessComplete; } pkt->req->setAccessLatency(); cpu->ppInstAccessComplete->notify(pkt); // Reset the mem req to NULL. delete pkt; memReq[tid] = NULL; } template void DefaultFetch::drainResume() { for (ThreadID i = 0; i < numThreads; ++i) { stalls[i].decode = false; stalls[i].drain = false; } } template void DefaultFetch::drainSanityCheck() const { assert(isDrained()); assert(retryPkt == NULL); assert(retryTid == InvalidThreadID); assert(!cacheBlocked); assert(!interruptPending); for (ThreadID i = 0; i < numThreads; ++i) { assert(!memReq[i]); assert(fetchStatus[i] == Idle || stalls[i].drain); } branchPred->drainSanityCheck(); } template bool DefaultFetch::isDrained() const { /* Make sure that threads are either idle of that the commit stage * has signaled that draining has completed by setting the drain * stall flag. This effectively forces the pipeline to be disabled * until the whole system is drained (simulation may continue to * drain other components). */ for (ThreadID i = 0; i < numThreads; ++i) { // Verify fetch queues are drained if (!fetchQueue[i].empty()) return false; // Return false if not idle or drain stalled if (fetchStatus[i] != Idle) { if (fetchStatus[i] == Blocked && stalls[i].drain) continue; else return false; } } /* The pipeline might start up again in the middle of the drain * cycle if the finish translation event is scheduled, so make * sure that's not the case. */ return !finishTranslationEvent.scheduled(); } template void DefaultFetch::takeOverFrom() { assert(cpu->getInstPort().isConnected()); resetStage(); } template void DefaultFetch::drainStall(ThreadID tid) { assert(cpu->isDraining()); assert(!stalls[tid].drain); DPRINTF(Drain, "%i: Thread drained.\n", tid); stalls[tid].drain = true; } template void DefaultFetch::wakeFromQuiesce() { DPRINTF(Fetch, "Waking up from quiesce\n"); // Hopefully this is safe // @todo: Allow other threads to wake from quiesce. fetchStatus[0] = Running; } template inline void DefaultFetch::switchToActive() { if (_status == Inactive) { DPRINTF(Activity, "Activating stage.\n"); cpu->activateStage(O3CPU::FetchIdx); _status = Active; } } template inline void DefaultFetch::switchToInactive() { if (_status == Active) { DPRINTF(Activity, "Deactivating stage.\n"); cpu->deactivateStage(O3CPU::FetchIdx); _status = Inactive; } } template void DefaultFetch::deactivateThread(ThreadID tid) { // Update priority list auto thread_it = std::find(priorityList.begin(), priorityList.end(), tid); if (thread_it != priorityList.end()) { priorityList.erase(thread_it); } } template bool DefaultFetch::lookupAndUpdateNextPC( const DynInstPtr &inst, TheISA::PCState &nextPC) { // Do branch prediction check here. // A bit of a misnomer...next_PC is actually the current PC until // this function updates it. bool predict_taken; if (!inst->isControl()) { TheISA::advancePC(nextPC, inst->staticInst); inst->setPredTarg(nextPC); inst->setPredTaken(false); return false; } ThreadID tid = inst->threadNumber; predict_taken = branchPred->predict(inst->staticInst, inst->seqNum, nextPC, tid); if (predict_taken) { DPRINTF(Fetch, "[tid:%i]: [sn:%i]: Branch predicted to be taken to %s.\n", tid, inst->seqNum, nextPC); } else { DPRINTF(Fetch, "[tid:%i]: [sn:%i]:Branch predicted to be not taken.\n", tid, inst->seqNum); } DPRINTF(Fetch, "[tid:%i]: [sn:%i] Branch predicted to go to %s.\n", tid, inst->seqNum, nextPC); inst->setPredTarg(nextPC); inst->setPredTaken(predict_taken); ++fetchedBranches; if (predict_taken) { ++predictedBranches; } return predict_taken; } template bool DefaultFetch::fetchCacheLine(Addr vaddr, ThreadID tid, Addr pc) { Fault fault = NoFault; assert(!cpu->switchedOut()); // @todo: not sure if these should block translation. //AlphaDep if (cacheBlocked) { DPRINTF(Fetch, "[tid:%i] Can't fetch cache line, cache blocked\n", tid); return false; } else if (checkInterrupt(pc) && !delayedCommit[tid]) { // Hold off fetch from getting new instructions when: // Cache is blocked, or // while an interrupt is pending and we're not in PAL mode, or // fetch is switched out. DPRINTF(Fetch, "[tid:%i] Can't fetch cache line, interrupt pending\n", tid); return false; } // Align the fetch address to the start of a fetch buffer segment. Addr fetchBufferBlockPC = fetchBufferAlignPC(vaddr); DPRINTF(Fetch, "[tid:%i] Fetching cache line %#x for addr %#x\n", tid, fetchBufferBlockPC, vaddr); // Setup the memReq to do a read of the first instruction's address. // Set the appropriate read size and flags as well. // Build request here. RequestPtr mem_req = std::make_shared( tid, fetchBufferBlockPC, fetchBufferSize, Request::INST_FETCH, cpu->instMasterId(), pc, cpu->thread[tid]->contextId()); mem_req->taskId(cpu->taskId()); memReq[tid] = mem_req; // Initiate translation of the icache block fetchStatus[tid] = ItlbWait; FetchTranslation *trans = new FetchTranslation(this); cpu->itb->translateTiming(mem_req, cpu->thread[tid]->getTC(), trans, BaseTLB::Execute); return true; } template void DefaultFetch::finishTranslation(const Fault &fault, const RequestPtr &mem_req) { ThreadID tid = cpu->contextToThread(mem_req->contextId()); Addr fetchBufferBlockPC = mem_req->getVaddr(); assert(!cpu->switchedOut()); // Wake up CPU if it was idle cpu->wakeCPU(); if (fetchStatus[tid] != ItlbWait || mem_req != memReq[tid] || mem_req->getVaddr() != memReq[tid]->getVaddr()) { DPRINTF(Fetch, "[tid:%i] Ignoring itlb completed after squash\n", tid); ++fetchTlbSquashes; return; } // If translation was successful, attempt to read the icache block. if (fault == NoFault) { // Check that we're not going off into random memory // If we have, just wait around for commit to squash something and put // us on the right track if (!cpu->system->isMemAddr(mem_req->getPaddr())) { warn("Address %#x is outside of physical memory, stopping fetch\n", mem_req->getPaddr()); fetchStatus[tid] = NoGoodAddr; memReq[tid] = NULL; return; } // Build packet here. PacketPtr data_pkt = new Packet(mem_req, MemCmd::ReadReq); data_pkt->dataDynamic(new uint8_t[fetchBufferSize]); fetchBufferPC[tid] = fetchBufferBlockPC; fetchBufferValid[tid] = false; DPRINTF(Fetch, "Fetch: Doing instruction read.\n"); fetchedCacheLines++; // Access the cache. if (!cpu->getInstPort().sendTimingReq(data_pkt)) { assert(retryPkt == NULL); assert(retryTid == InvalidThreadID); DPRINTF(Fetch, "[tid:%i] Out of MSHRs!\n", tid); fetchStatus[tid] = IcacheWaitRetry; retryPkt = data_pkt; retryTid = tid; cacheBlocked = true; } else { DPRINTF(Fetch, "[tid:%i]: Doing Icache access.\n", tid); DPRINTF(Activity, "[tid:%i]: Activity: Waiting on I-cache " "response.\n", tid); lastIcacheStall[tid] = curTick(); fetchStatus[tid] = IcacheWaitResponse; // Notify Fetch Request probe when a packet containing a fetch // request is successfully sent ppFetchRequestSent->notify(mem_req); } } else { // Don't send an instruction to decode if we can't handle it. if (!(numInst < fetchWidth) || !(fetchQueue[tid].size() < fetchQueueSize)) { assert(!finishTranslationEvent.scheduled()); finishTranslationEvent.setFault(fault); finishTranslationEvent.setReq(mem_req); cpu->schedule(finishTranslationEvent, cpu->clockEdge(Cycles(1))); return; } DPRINTF(Fetch, "[tid:%i] Got back req with addr %#x but expected %#x\n", tid, mem_req->getVaddr(), memReq[tid]->getVaddr()); // Translation faulted, icache request won't be sent. memReq[tid] = NULL; // Send the fault to commit. This thread will not do anything // until commit handles the fault. The only other way it can // wake up is if a squash comes along and changes the PC. TheISA::PCState fetchPC = pc[tid]; DPRINTF(Fetch, "[tid:%i]: Translation faulted, building noop.\n", tid); // We will use a nop in ordier to carry the fault. DynInstPtr instruction = buildInst(tid, StaticInst::nopStaticInstPtr, NULL, fetchPC, fetchPC, false); instruction->setNotAnInst(); instruction->setPredTarg(fetchPC); instruction->fault = fault; wroteToTimeBuffer = true; DPRINTF(Activity, "Activity this cycle.\n"); cpu->activityThisCycle(); fetchStatus[tid] = TrapPending; DPRINTF(Fetch, "[tid:%i]: Blocked, need to handle the trap.\n", tid); DPRINTF(Fetch, "[tid:%i]: fault (%s) detected @ PC %s.\n", tid, fault->name(), pc[tid]); } _status = updateFetchStatus(); } template inline void DefaultFetch::doSquash(const TheISA::PCState &newPC, const DynInstPtr squashInst, ThreadID tid) { DPRINTF(Fetch, "[tid:%i]: Squashing, setting PC to: %s.\n", tid, newPC); pc[tid] = newPC; fetchOffset[tid] = 0; if (squashInst && squashInst->pcState().instAddr() == newPC.instAddr()) macroop[tid] = squashInst->macroop; else macroop[tid] = NULL; decoder[tid]->reset(); // Clear the icache miss if it's outstanding. if (fetchStatus[tid] == IcacheWaitResponse) { DPRINTF(Fetch, "[tid:%i]: Squashing outstanding Icache miss.\n", tid); memReq[tid] = NULL; } else if (fetchStatus[tid] == ItlbWait) { DPRINTF(Fetch, "[tid:%i]: Squashing outstanding ITLB miss.\n", tid); memReq[tid] = NULL; } // Get rid of the retrying packet if it was from this thread. if (retryTid == tid) { assert(cacheBlocked); if (retryPkt) { delete retryPkt; } retryPkt = NULL; retryTid = InvalidThreadID; } fetchStatus[tid] = Squashing; // Empty fetch queue fetchQueue[tid].clear(); // microops are being squashed, it is not known wheather the // youngest non-squashed microop was marked delayed commit // or not. Setting the flag to true ensures that the // interrupts are not handled when they cannot be, though // some opportunities to handle interrupts may be missed. delayedCommit[tid] = true; ++fetchSquashCycles; } template void DefaultFetch::squashFromDecode(const TheISA::PCState &newPC, const DynInstPtr squashInst, const InstSeqNum seq_num, ThreadID tid) { DPRINTF(Fetch, "[tid:%i]: Squashing from decode.\n", tid); doSquash(newPC, squashInst, tid); // Tell the CPU to remove any instructions that are in flight between // fetch and decode. cpu->removeInstsUntil(seq_num, tid); } template bool DefaultFetch::checkStall(ThreadID tid) const { bool ret_val = false; if (stalls[tid].drain) { assert(cpu->isDraining()); DPRINTF(Fetch,"[tid:%i]: Drain stall detected.\n",tid); ret_val = true; } return ret_val; } template typename DefaultFetch::FetchStatus DefaultFetch::updateFetchStatus() { //Check Running list::iterator threads = activeThreads->begin(); list::iterator end = activeThreads->end(); while (threads != end) { ThreadID tid = *threads++; if (fetchStatus[tid] == Running || fetchStatus[tid] == Squashing || fetchStatus[tid] == IcacheAccessComplete) { if (_status == Inactive) { DPRINTF(Activity, "[tid:%i]: Activating stage.\n",tid); if (fetchStatus[tid] == IcacheAccessComplete) { DPRINTF(Activity, "[tid:%i]: Activating fetch due to cache" "completion\n",tid); } cpu->activateStage(O3CPU::FetchIdx); } return Active; } } // Stage is switching from active to inactive, notify CPU of it. if (_status == Active) { DPRINTF(Activity, "Deactivating stage.\n"); cpu->deactivateStage(O3CPU::FetchIdx); } return Inactive; } template void DefaultFetch::squash(const TheISA::PCState &newPC, const InstSeqNum seq_num, DynInstPtr squashInst, ThreadID tid) { DPRINTF(Fetch, "[tid:%u]: Squash from commit.\n", tid); doSquash(newPC, squashInst, tid); // Tell the CPU to remove any instructions that are not in the ROB. cpu->removeInstsNotInROB(tid); } template void DefaultFetch::tick() { list::iterator threads = activeThreads->begin(); list::iterator end = activeThreads->end(); bool status_change = false; wroteToTimeBuffer = false; for (ThreadID i = 0; i < numThreads; ++i) { issuePipelinedIfetch[i] = false; } while (threads != end) { ThreadID tid = *threads++; // Check the signals for each thread to determine the proper status // for each thread. bool updated_status = checkSignalsAndUpdate(tid); status_change = status_change || updated_status; } DPRINTF(Fetch, "Running stage.\n"); if (FullSystem) { if (fromCommit->commitInfo[0].interruptPending) { interruptPending = true; } if (fromCommit->commitInfo[0].clearInterrupt) { interruptPending = false; } } for (threadFetched = 0; threadFetched < numFetchingThreads; threadFetched++) { // Fetch each of the actively fetching threads. fetch(status_change); } // Record number of instructions fetched this cycle for distribution. fetchNisnDist.sample(numInst); if (status_change) { // Change the fetch stage status if there was a status change. _status = updateFetchStatus(); } // Issue the next I-cache request if possible. for (ThreadID i = 0; i < numThreads; ++i) { if (issuePipelinedIfetch[i]) { pipelineIcacheAccesses(i); } } // Send instructions enqueued into the fetch queue to decode. // Limit rate by fetchWidth. Stall if decode is stalled. unsigned insts_to_decode = 0; unsigned available_insts = 0; for (auto tid : *activeThreads) { if (!stalls[tid].decode) { available_insts += fetchQueue[tid].size(); } } // Pick a random thread to start trying to grab instructions from auto tid_itr = activeThreads->begin(); std::advance(tid_itr, random_mt.random(0, activeThreads->size() - 1)); while (available_insts != 0 && insts_to_decode < decodeWidth) { ThreadID tid = *tid_itr; if (!stalls[tid].decode && !fetchQueue[tid].empty()) { const auto& inst = fetchQueue[tid].front(); toDecode->insts[toDecode->size++] = inst; DPRINTF(Fetch, "[tid:%i][sn:%i]: Sending instruction to decode from " "fetch queue. Fetch queue size: %i.\n", tid, inst->seqNum, fetchQueue[tid].size()); wroteToTimeBuffer = true; fetchQueue[tid].pop_front(); insts_to_decode++; available_insts--; } tid_itr++; // Wrap around if at end of active threads list if (tid_itr == activeThreads->end()) tid_itr = activeThreads->begin(); } // If there was activity this cycle, inform the CPU of it. if (wroteToTimeBuffer) { DPRINTF(Activity, "Activity this cycle.\n"); cpu->activityThisCycle(); } // Reset the number of the instruction we've fetched. numInst = 0; } template bool DefaultFetch::checkSignalsAndUpdate(ThreadID tid) { // Update the per thread stall statuses. if (fromDecode->decodeBlock[tid]) { stalls[tid].decode = true; } if (fromDecode->decodeUnblock[tid]) { assert(stalls[tid].decode); assert(!fromDecode->decodeBlock[tid]); stalls[tid].decode = false; } // Check squash signals from commit. if (fromCommit->commitInfo[tid].squash) { DPRINTF(Fetch, "[tid:%u]: Squashing instructions due to squash " "from commit.\n",tid); // In any case, squash. squash(fromCommit->commitInfo[tid].pc, fromCommit->commitInfo[tid].doneSeqNum, fromCommit->commitInfo[tid].squashInst, tid); // If it was a branch mispredict on a control instruction, update the // branch predictor with that instruction, otherwise just kill the // invalid state we generated in after sequence number if (fromCommit->commitInfo[tid].mispredictInst && fromCommit->commitInfo[tid].mispredictInst->isControl()) { branchPred->squash(fromCommit->commitInfo[tid].doneSeqNum, fromCommit->commitInfo[tid].pc, fromCommit->commitInfo[tid].branchTaken, tid); } else { branchPred->squash(fromCommit->commitInfo[tid].doneSeqNum, tid); } return true; } else if (fromCommit->commitInfo[tid].doneSeqNum) { // Update the branch predictor if it wasn't a squashed instruction // that was broadcasted. branchPred->update(fromCommit->commitInfo[tid].doneSeqNum, tid); } // Check squash signals from decode. if (fromDecode->decodeInfo[tid].squash) { DPRINTF(Fetch, "[tid:%u]: Squashing instructions due to squash " "from decode.\n",tid); // Update the branch predictor. if (fromDecode->decodeInfo[tid].branchMispredict) { branchPred->squash(fromDecode->decodeInfo[tid].doneSeqNum, fromDecode->decodeInfo[tid].nextPC, fromDecode->decodeInfo[tid].branchTaken, tid); } else { branchPred->squash(fromDecode->decodeInfo[tid].doneSeqNum, tid); } if (fetchStatus[tid] != Squashing) { DPRINTF(Fetch, "Squashing from decode with PC = %s\n", fromDecode->decodeInfo[tid].nextPC); // Squash unless we're already squashing squashFromDecode(fromDecode->decodeInfo[tid].nextPC, fromDecode->decodeInfo[tid].squashInst, fromDecode->decodeInfo[tid].doneSeqNum, tid); return true; } } if (checkStall(tid) && fetchStatus[tid] != IcacheWaitResponse && fetchStatus[tid] != IcacheWaitRetry && fetchStatus[tid] != ItlbWait && fetchStatus[tid] != QuiescePending) { DPRINTF(Fetch, "[tid:%i]: Setting to blocked\n",tid); fetchStatus[tid] = Blocked; return true; } if (fetchStatus[tid] == Blocked || fetchStatus[tid] == Squashing) { // Switch status to running if fetch isn't being told to block or // squash this cycle. DPRINTF(Fetch, "[tid:%i]: Done squashing, switching to running.\n", tid); fetchStatus[tid] = Running; return true; } // If we've reached this point, we have not gotten any signals that // cause fetch to change its status. Fetch remains the same as before. return false; } template typename Impl::DynInstPtr DefaultFetch::buildInst(ThreadID tid, StaticInstPtr staticInst, StaticInstPtr curMacroop, TheISA::PCState thisPC, TheISA::PCState nextPC, bool trace) { // Get a sequence number. InstSeqNum seq = cpu->getAndIncrementInstSeq(); // Create a new DynInst from the instruction fetched. DynInstPtr instruction = new DynInst(staticInst, curMacroop, thisPC, nextPC, seq, cpu); instruction->setTid(tid); instruction->setASID(tid); instruction->setThreadState(cpu->thread[tid]); DPRINTF(Fetch, "[tid:%i]: Instruction PC %#x (%d) created " "[sn:%lli].\n", tid, thisPC.instAddr(), thisPC.microPC(), seq); DPRINTF(Fetch, "[tid:%i]: Instruction is: %s\n", tid, instruction->staticInst-> disassemble(thisPC.instAddr())); #if TRACING_ON if (trace) { instruction->traceData = cpu->getTracer()->getInstRecord(curTick(), cpu->tcBase(tid), instruction->staticInst, thisPC, curMacroop); } #else instruction->traceData = NULL; #endif // Add instruction to the CPU's list of instructions. instruction->setInstListIt(cpu->addInst(instruction)); // Write the instruction to the first slot in the queue // that heads to decode. assert(numInst < fetchWidth); fetchQueue[tid].push_back(instruction); assert(fetchQueue[tid].size() <= fetchQueueSize); DPRINTF(Fetch, "[tid:%i]: Fetch queue entry created (%i/%i).\n", tid, fetchQueue[tid].size(), fetchQueueSize); //toDecode->insts[toDecode->size++] = instruction; // Keep track of if we can take an interrupt at this boundary delayedCommit[tid] = instruction->isDelayedCommit(); return instruction; } template void DefaultFetch::fetch(bool &status_change) { ////////////////////////////////////////// // Start actual fetch ////////////////////////////////////////// ThreadID tid = getFetchingThread(fetchPolicy); assert(!cpu->switchedOut()); if (tid == InvalidThreadID) { // Breaks looping condition in tick() threadFetched = numFetchingThreads; if (numThreads == 1) { // @todo Per-thread stats profileStall(0); } return; } DPRINTF(Fetch, "Attempting to fetch from [tid:%i]\n", tid); // The current PC. TheISA::PCState thisPC = pc[tid]; Addr pcOffset = fetchOffset[tid]; Addr fetchAddr = (thisPC.instAddr() + pcOffset) & BaseCPU::PCMask; bool inRom = isRomMicroPC(thisPC.microPC()); // If returning from the delay of a cache miss, then update the status // to running, otherwise do the cache access. Possibly move this up // to tick() function. if (fetchStatus[tid] == IcacheAccessComplete) { DPRINTF(Fetch, "[tid:%i]: Icache miss is complete.\n", tid); fetchStatus[tid] = Running; status_change = true; } else if (fetchStatus[tid] == Running) { // Align the fetch PC so its at the start of a fetch buffer segment. Addr fetchBufferBlockPC = fetchBufferAlignPC(fetchAddr); // If buffer is no longer valid or fetchAddr has moved to point // to the next cache block, AND we have no remaining ucode // from a macro-op, then start fetch from icache. if (!(fetchBufferValid[tid] && fetchBufferBlockPC == fetchBufferPC[tid]) && !inRom && !macroop[tid]) { DPRINTF(Fetch, "[tid:%i]: Attempting to translate and read " "instruction, starting at PC %s.\n", tid, thisPC); fetchCacheLine(fetchAddr, tid, thisPC.instAddr()); if (fetchStatus[tid] == IcacheWaitResponse) ++icacheStallCycles; else if (fetchStatus[tid] == ItlbWait) ++fetchTlbCycles; else ++fetchMiscStallCycles; return; } else if ((checkInterrupt(thisPC.instAddr()) && !delayedCommit[tid])) { // Stall CPU if an interrupt is posted and we're not issuing // an delayed commit micro-op currently (delayed commit instructions // are not interruptable by interrupts, only faults) ++fetchMiscStallCycles; DPRINTF(Fetch, "[tid:%i]: Fetch is stalled!\n", tid); return; } } else { if (fetchStatus[tid] == Idle) { ++fetchIdleCycles; DPRINTF(Fetch, "[tid:%i]: Fetch is idle!\n", tid); } // Status is Idle, so fetch should do nothing. return; } ++fetchCycles; TheISA::PCState nextPC = thisPC; StaticInstPtr staticInst = NULL; StaticInstPtr curMacroop = macroop[tid]; // If the read of the first instruction was successful, then grab the // instructions from the rest of the cache line and put them into the // queue heading to decode. DPRINTF(Fetch, "[tid:%i]: Adding instructions to queue to " "decode.\n", tid); // Need to keep track of whether or not a predicted branch // ended this fetch block. bool predictedBranch = false; // Need to halt fetch if quiesce instruction detected bool quiesce = false; TheISA::MachInst *cacheInsts = reinterpret_cast(fetchBuffer[tid]); const unsigned numInsts = fetchBufferSize / instSize; unsigned blkOffset = (fetchAddr - fetchBufferPC[tid]) / instSize; // Loop through instruction memory from the cache. // Keep issuing while fetchWidth is available and branch is not // predicted taken while (numInst < fetchWidth && fetchQueue[tid].size() < fetchQueueSize && !predictedBranch && !quiesce) { // We need to process more memory if we aren't going to get a // StaticInst from the rom, the current macroop, or what's already // in the decoder. bool needMem = !inRom && !curMacroop && !decoder[tid]->instReady(); fetchAddr = (thisPC.instAddr() + pcOffset) & BaseCPU::PCMask; Addr fetchBufferBlockPC = fetchBufferAlignPC(fetchAddr); if (needMem) { // If buffer is no longer valid or fetchAddr has moved to point // to the next cache block then start fetch from icache. if (!fetchBufferValid[tid] || fetchBufferBlockPC != fetchBufferPC[tid]) break; if (blkOffset >= numInsts) { // We need to process more memory, but we've run out of the // current block. break; } MachInst inst = TheISA::gtoh(cacheInsts[blkOffset]); decoder[tid]->moreBytes(thisPC, fetchAddr, inst); if (decoder[tid]->needMoreBytes()) { blkOffset++; fetchAddr += instSize; pcOffset += instSize; } } // Extract as many instructions and/or microops as we can from // the memory we've processed so far. do { if (!(curMacroop || inRom)) { if (decoder[tid]->instReady()) { staticInst = decoder[tid]->decode(thisPC); // Increment stat of fetched instructions. ++fetchedInsts; if (staticInst->isMacroop()) { curMacroop = staticInst; } else { pcOffset = 0; } } else { // We need more bytes for this instruction so blkOffset and // pcOffset will be updated break; } } // Whether we're moving to a new macroop because we're at the // end of the current one, or the branch predictor incorrectly // thinks we are... bool newMacro = false; if (curMacroop || inRom) { if (inRom) { staticInst = cpu->microcodeRom.fetchMicroop( thisPC.microPC(), curMacroop); } else { staticInst = curMacroop->fetchMicroop(thisPC.microPC()); } newMacro |= staticInst->isLastMicroop(); } DynInstPtr instruction = buildInst(tid, staticInst, curMacroop, thisPC, nextPC, true); ppFetch->notify(instruction); numInst++; #if TRACING_ON if (DTRACE(O3PipeView)) { instruction->fetchTick = curTick(); } #endif nextPC = thisPC; // If we're branching after this instruction, quit fetching // from the same block. predictedBranch |= thisPC.branching(); predictedBranch |= lookupAndUpdateNextPC(instruction, nextPC); if (predictedBranch) { DPRINTF(Fetch, "Branch detected with PC = %s\n", thisPC); } newMacro |= thisPC.instAddr() != nextPC.instAddr(); // Move to the next instruction, unless we have a branch. thisPC = nextPC; inRom = isRomMicroPC(thisPC.microPC()); if (newMacro) { fetchAddr = thisPC.instAddr() & BaseCPU::PCMask; blkOffset = (fetchAddr - fetchBufferPC[tid]) / instSize; pcOffset = 0; curMacroop = NULL; } if (instruction->isQuiesce()) { DPRINTF(Fetch, "Quiesce instruction encountered, halting fetch!\n"); fetchStatus[tid] = QuiescePending; status_change = true; quiesce = true; break; } } while ((curMacroop || decoder[tid]->instReady()) && numInst < fetchWidth && fetchQueue[tid].size() < fetchQueueSize); // Re-evaluate whether the next instruction to fetch is in micro-op ROM // or not. inRom = isRomMicroPC(thisPC.microPC()); } if (predictedBranch) { DPRINTF(Fetch, "[tid:%i]: Done fetching, predicted branch " "instruction encountered.\n", tid); } else if (numInst >= fetchWidth) { DPRINTF(Fetch, "[tid:%i]: Done fetching, reached fetch bandwidth " "for this cycle.\n", tid); } else if (blkOffset >= fetchBufferSize) { DPRINTF(Fetch, "[tid:%i]: Done fetching, reached the end of the" "fetch buffer.\n", tid); } macroop[tid] = curMacroop; fetchOffset[tid] = pcOffset; if (numInst > 0) { wroteToTimeBuffer = true; } pc[tid] = thisPC; // pipeline a fetch if we're crossing a fetch buffer boundary and not in // a state that would preclude fetching fetchAddr = (thisPC.instAddr() + pcOffset) & BaseCPU::PCMask; Addr fetchBufferBlockPC = fetchBufferAlignPC(fetchAddr); issuePipelinedIfetch[tid] = fetchBufferBlockPC != fetchBufferPC[tid] && fetchStatus[tid] != IcacheWaitResponse && fetchStatus[tid] != ItlbWait && fetchStatus[tid] != IcacheWaitRetry && fetchStatus[tid] != QuiescePending && !curMacroop; } template void DefaultFetch::recvReqRetry() { if (retryPkt != NULL) { assert(cacheBlocked); assert(retryTid != InvalidThreadID); assert(fetchStatus[retryTid] == IcacheWaitRetry); if (cpu->getInstPort().sendTimingReq(retryPkt)) { fetchStatus[retryTid] = IcacheWaitResponse; // Notify Fetch Request probe when a retryPkt is successfully sent. // Note that notify must be called before retryPkt is set to NULL. ppFetchRequestSent->notify(retryPkt->req); retryPkt = NULL; retryTid = InvalidThreadID; cacheBlocked = false; } } else { assert(retryTid == InvalidThreadID); // Access has been squashed since it was sent out. Just clear // the cache being blocked. cacheBlocked = false; } } /////////////////////////////////////// // // // SMT FETCH POLICY MAINTAINED HERE // // // /////////////////////////////////////// template ThreadID DefaultFetch::getFetchingThread(FetchPriority &fetch_priority) { if (numThreads > 1) { switch (fetch_priority) { case SingleThread: return 0; case RoundRobin: return roundRobin(); case IQ: return iqCount(); case LSQ: return lsqCount(); case Branch: return branchCount(); default: return InvalidThreadID; } } else { list::iterator thread = activeThreads->begin(); if (thread == activeThreads->end()) { return InvalidThreadID; } ThreadID tid = *thread; if (fetchStatus[tid] == Running || fetchStatus[tid] == IcacheAccessComplete || fetchStatus[tid] == Idle) { return tid; } else { return InvalidThreadID; } } } template ThreadID DefaultFetch::roundRobin() { list::iterator pri_iter = priorityList.begin(); list::iterator end = priorityList.end(); ThreadID high_pri; while (pri_iter != end) { high_pri = *pri_iter; assert(high_pri <= numThreads); if (fetchStatus[high_pri] == Running || fetchStatus[high_pri] == IcacheAccessComplete || fetchStatus[high_pri] == Idle) { priorityList.erase(pri_iter); priorityList.push_back(high_pri); return high_pri; } pri_iter++; } return InvalidThreadID; } template ThreadID DefaultFetch::iqCount() { //sorted from lowest->highest std::priority_queue, std::greater > PQ; std::map threadMap; list::iterator threads = activeThreads->begin(); list::iterator end = activeThreads->end(); while (threads != end) { ThreadID tid = *threads++; unsigned iqCount = fromIEW->iewInfo[tid].iqCount; //we can potentially get tid collisions if two threads //have the same iqCount, but this should be rare. PQ.push(iqCount); threadMap[iqCount] = tid; } while (!PQ.empty()) { ThreadID high_pri = threadMap[PQ.top()]; if (fetchStatus[high_pri] == Running || fetchStatus[high_pri] == IcacheAccessComplete || fetchStatus[high_pri] == Idle) return high_pri; else PQ.pop(); } return InvalidThreadID; } template ThreadID DefaultFetch::lsqCount() { //sorted from lowest->highest std::priority_queue, std::greater > PQ; std::map threadMap; list::iterator threads = activeThreads->begin(); list::iterator end = activeThreads->end(); while (threads != end) { ThreadID tid = *threads++; unsigned ldstqCount = fromIEW->iewInfo[tid].ldstqCount; //we can potentially get tid collisions if two threads //have the same iqCount, but this should be rare. PQ.push(ldstqCount); threadMap[ldstqCount] = tid; } while (!PQ.empty()) { ThreadID high_pri = threadMap[PQ.top()]; if (fetchStatus[high_pri] == Running || fetchStatus[high_pri] == IcacheAccessComplete || fetchStatus[high_pri] == Idle) return high_pri; else PQ.pop(); } return InvalidThreadID; } template ThreadID DefaultFetch::branchCount() { #if 0 list::iterator thread = activeThreads->begin(); assert(thread != activeThreads->end()); ThreadID tid = *thread; #endif panic("Branch Count Fetch policy unimplemented\n"); return InvalidThreadID; } template void DefaultFetch::pipelineIcacheAccesses(ThreadID tid) { if (!issuePipelinedIfetch[tid]) { return; } // The next PC to access. TheISA::PCState thisPC = pc[tid]; if (isRomMicroPC(thisPC.microPC())) { return; } Addr pcOffset = fetchOffset[tid]; Addr fetchAddr = (thisPC.instAddr() + pcOffset) & BaseCPU::PCMask; // Align the fetch PC so its at the start of a fetch buffer segment. Addr fetchBufferBlockPC = fetchBufferAlignPC(fetchAddr); // Unless buffer already got the block, fetch it from icache. if (!(fetchBufferValid[tid] && fetchBufferBlockPC == fetchBufferPC[tid])) { DPRINTF(Fetch, "[tid:%i]: Issuing a pipelined I-cache access, " "starting at PC %s.\n", tid, thisPC); fetchCacheLine(fetchAddr, tid, thisPC.instAddr()); } } template void DefaultFetch::profileStall(ThreadID tid) { DPRINTF(Fetch,"There are no more threads available to fetch from.\n"); // @todo Per-thread stats if (stalls[tid].drain) { ++fetchPendingDrainCycles; DPRINTF(Fetch, "Fetch is waiting for a drain!\n"); } else if (activeThreads->empty()) { ++fetchNoActiveThreadStallCycles; DPRINTF(Fetch, "Fetch has no active thread!\n"); } else if (fetchStatus[tid] == Blocked) { ++fetchBlockedCycles; DPRINTF(Fetch, "[tid:%i]: Fetch is blocked!\n", tid); } else if (fetchStatus[tid] == Squashing) { ++fetchSquashCycles; DPRINTF(Fetch, "[tid:%i]: Fetch is squashing!\n", tid); } else if (fetchStatus[tid] == IcacheWaitResponse) { ++icacheStallCycles; DPRINTF(Fetch, "[tid:%i]: Fetch is waiting cache response!\n", tid); } else if (fetchStatus[tid] == ItlbWait) { ++fetchTlbCycles; DPRINTF(Fetch, "[tid:%i]: Fetch is waiting ITLB walk to " "finish!\n", tid); } else if (fetchStatus[tid] == TrapPending) { ++fetchPendingTrapStallCycles; DPRINTF(Fetch, "[tid:%i]: Fetch is waiting for a pending trap!\n", tid); } else if (fetchStatus[tid] == QuiescePending) { ++fetchPendingQuiesceStallCycles; DPRINTF(Fetch, "[tid:%i]: Fetch is waiting for a pending quiesce " "instruction!\n", tid); } else if (fetchStatus[tid] == IcacheWaitRetry) { ++fetchIcacheWaitRetryStallCycles; DPRINTF(Fetch, "[tid:%i]: Fetch is waiting for an I-cache retry!\n", tid); } else if (fetchStatus[tid] == NoGoodAddr) { DPRINTF(Fetch, "[tid:%i]: Fetch predicted non-executable address\n", tid); } else { DPRINTF(Fetch, "[tid:%i]: Unexpected fetch stall reason (Status: %i).\n", tid, fetchStatus[tid]); } } #endif//__CPU_O3_FETCH_IMPL_HH__