| /* |
| * Copyright (c) 1999-2008 Mark D. Hill and David A. Wood |
| * All rights reserved. |
| * |
| * Redistribution and use in source and binary forms, with or without |
| * modification, are permitted provided that the following conditions are |
| * met: redistributions of source code must retain the above copyright |
| * notice, this list of conditions and the following disclaimer; |
| * redistributions in binary form must reproduce the above copyright |
| * notice, this list of conditions and the following disclaimer in the |
| * documentation and/or other materials provided with the distribution; |
| * neither the name of the copyright holders nor the names of its |
| * contributors may be used to endorse or promote products derived from |
| * this software without specific prior written permission. |
| * |
| * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS |
| * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT |
| * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR |
| * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT |
| * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, |
| * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT |
| * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
| * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
| * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
| * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE |
| * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
| */ |
| |
| #include "mem/ruby/system/Sequencer.hh" |
| |
| #include "arch/x86/ldstflags.hh" |
| #include "base/logging.hh" |
| #include "base/str.hh" |
| #include "cpu/testers/rubytest/RubyTester.hh" |
| #include "debug/MemoryAccess.hh" |
| #include "debug/ProtocolTrace.hh" |
| #include "debug/RubySequencer.hh" |
| #include "debug/RubyStats.hh" |
| #include "mem/packet.hh" |
| #include "mem/protocol/PrefetchBit.hh" |
| #include "mem/protocol/RubyAccessMode.hh" |
| #include "mem/ruby/profiler/Profiler.hh" |
| #include "mem/ruby/slicc_interface/RubyRequest.hh" |
| #include "mem/ruby/system/RubySystem.hh" |
| #include "sim/system.hh" |
| |
| using namespace std; |
| |
| Sequencer * |
| RubySequencerParams::create() |
| { |
| return new Sequencer(this); |
| } |
| |
| Sequencer::Sequencer(const Params *p) |
| : RubyPort(p), m_IncompleteTimes(MachineType_NUM), |
| deadlockCheckEvent([this]{ wakeup(); }, "Sequencer deadlock check") |
| { |
| m_outstanding_count = 0; |
| |
| m_instCache_ptr = p->icache; |
| m_dataCache_ptr = p->dcache; |
| m_max_outstanding_requests = p->max_outstanding_requests; |
| m_deadlock_threshold = p->deadlock_threshold; |
| |
| m_coreId = p->coreid; // for tracking the two CorePair sequencers |
| assert(m_max_outstanding_requests > 0); |
| assert(m_deadlock_threshold > 0); |
| assert(m_instCache_ptr != NULL); |
| assert(m_dataCache_ptr != NULL); |
| |
| m_runningGarnetStandalone = p->garnet_standalone; |
| } |
| |
| Sequencer::~Sequencer() |
| { |
| } |
| |
| void |
| Sequencer::wakeup() |
| { |
| assert(drainState() != DrainState::Draining); |
| |
| // Check for deadlock of any of the requests |
| Cycles current_time = curCycle(); |
| |
| // Check across all outstanding requests |
| int total_outstanding = 0; |
| |
| RequestTable::iterator read = m_readRequestTable.begin(); |
| RequestTable::iterator read_end = m_readRequestTable.end(); |
| for (; read != read_end; ++read) { |
| SequencerRequest* request = read->second; |
| if (current_time - request->issue_time < m_deadlock_threshold) |
| continue; |
| |
| panic("Possible Deadlock detected. Aborting!\n" |
| "version: %d request.paddr: 0x%x m_readRequestTable: %d " |
| "current time: %u issue_time: %d difference: %d\n", m_version, |
| request->pkt->getAddr(), m_readRequestTable.size(), |
| current_time * clockPeriod(), request->issue_time * clockPeriod(), |
| (current_time * clockPeriod()) - (request->issue_time * clockPeriod())); |
| } |
| |
| RequestTable::iterator write = m_writeRequestTable.begin(); |
| RequestTable::iterator write_end = m_writeRequestTable.end(); |
| for (; write != write_end; ++write) { |
| SequencerRequest* request = write->second; |
| if (current_time - request->issue_time < m_deadlock_threshold) |
| continue; |
| |
| panic("Possible Deadlock detected. Aborting!\n" |
| "version: %d request.paddr: 0x%x m_writeRequestTable: %d " |
| "current time: %u issue_time: %d difference: %d\n", m_version, |
| request->pkt->getAddr(), m_writeRequestTable.size(), |
| current_time * clockPeriod(), request->issue_time * clockPeriod(), |
| (current_time * clockPeriod()) - (request->issue_time * clockPeriod())); |
| } |
| |
| total_outstanding += m_writeRequestTable.size(); |
| total_outstanding += m_readRequestTable.size(); |
| |
| assert(m_outstanding_count == total_outstanding); |
| |
| if (m_outstanding_count > 0) { |
| // If there are still outstanding requests, keep checking |
| schedule(deadlockCheckEvent, clockEdge(m_deadlock_threshold)); |
| } |
| } |
| |
| void Sequencer::resetStats() |
| { |
| m_latencyHist.reset(); |
| m_hitLatencyHist.reset(); |
| m_missLatencyHist.reset(); |
| for (int i = 0; i < RubyRequestType_NUM; i++) { |
| m_typeLatencyHist[i]->reset(); |
| m_hitTypeLatencyHist[i]->reset(); |
| m_missTypeLatencyHist[i]->reset(); |
| for (int j = 0; j < MachineType_NUM; j++) { |
| m_hitTypeMachLatencyHist[i][j]->reset(); |
| m_missTypeMachLatencyHist[i][j]->reset(); |
| } |
| } |
| |
| for (int i = 0; i < MachineType_NUM; i++) { |
| m_missMachLatencyHist[i]->reset(); |
| m_hitMachLatencyHist[i]->reset(); |
| |
| m_IssueToInitialDelayHist[i]->reset(); |
| m_InitialToForwardDelayHist[i]->reset(); |
| m_ForwardToFirstResponseDelayHist[i]->reset(); |
| m_FirstResponseToCompletionDelayHist[i]->reset(); |
| |
| m_IncompleteTimes[i] = 0; |
| } |
| } |
| |
| // Insert the request on the correct request table. Return true if |
| // the entry was already present. |
| RequestStatus |
| Sequencer::insertRequest(PacketPtr pkt, RubyRequestType request_type) |
| { |
| assert(m_outstanding_count == |
| (m_writeRequestTable.size() + m_readRequestTable.size())); |
| |
| // See if we should schedule a deadlock check |
| if (!deadlockCheckEvent.scheduled() && |
| drainState() != DrainState::Draining) { |
| schedule(deadlockCheckEvent, clockEdge(m_deadlock_threshold)); |
| } |
| |
| Addr line_addr = makeLineAddress(pkt->getAddr()); |
| |
| // Check if the line is blocked for a Locked_RMW |
| if (m_controller->isBlocked(line_addr) && |
| (request_type != RubyRequestType_Locked_RMW_Write)) { |
| // Return that this request's cache line address aliases with |
| // a prior request that locked the cache line. The request cannot |
| // proceed until the cache line is unlocked by a Locked_RMW_Write |
| return RequestStatus_Aliased; |
| } |
| |
| // Create a default entry, mapping the address to NULL, the cast is |
| // there to make gcc 4.4 happy |
| RequestTable::value_type default_entry(line_addr, |
| (SequencerRequest*) NULL); |
| |
| if ((request_type == RubyRequestType_ST) || |
| (request_type == RubyRequestType_RMW_Read) || |
| (request_type == RubyRequestType_RMW_Write) || |
| (request_type == RubyRequestType_Load_Linked) || |
| (request_type == RubyRequestType_Store_Conditional) || |
| (request_type == RubyRequestType_Locked_RMW_Read) || |
| (request_type == RubyRequestType_Locked_RMW_Write) || |
| (request_type == RubyRequestType_FLUSH)) { |
| |
| // Check if there is any outstanding read request for the same |
| // cache line. |
| if (m_readRequestTable.count(line_addr) > 0) { |
| m_store_waiting_on_load++; |
| return RequestStatus_Aliased; |
| } |
| |
| pair<RequestTable::iterator, bool> r = |
| m_writeRequestTable.insert(default_entry); |
| if (r.second) { |
| RequestTable::iterator i = r.first; |
| i->second = new SequencerRequest(pkt, request_type, curCycle()); |
| m_outstanding_count++; |
| } else { |
| // There is an outstanding write request for the cache line |
| m_store_waiting_on_store++; |
| return RequestStatus_Aliased; |
| } |
| } else { |
| // Check if there is any outstanding write request for the same |
| // cache line. |
| if (m_writeRequestTable.count(line_addr) > 0) { |
| m_load_waiting_on_store++; |
| return RequestStatus_Aliased; |
| } |
| |
| pair<RequestTable::iterator, bool> r = |
| m_readRequestTable.insert(default_entry); |
| |
| if (r.second) { |
| RequestTable::iterator i = r.first; |
| i->second = new SequencerRequest(pkt, request_type, curCycle()); |
| m_outstanding_count++; |
| } else { |
| // There is an outstanding read request for the cache line |
| m_load_waiting_on_load++; |
| return RequestStatus_Aliased; |
| } |
| } |
| |
| m_outstandReqHist.sample(m_outstanding_count); |
| assert(m_outstanding_count == |
| (m_writeRequestTable.size() + m_readRequestTable.size())); |
| |
| return RequestStatus_Ready; |
| } |
| |
| void |
| Sequencer::markRemoved() |
| { |
| m_outstanding_count--; |
| assert(m_outstanding_count == |
| m_writeRequestTable.size() + m_readRequestTable.size()); |
| } |
| |
| void |
| Sequencer::invalidateSC(Addr address) |
| { |
| AbstractCacheEntry *e = m_dataCache_ptr->lookup(address); |
| // The controller has lost the coherence permissions, hence the lock |
| // on the cache line maintained by the cache should be cleared. |
| if (e && e->isLocked(m_version)) { |
| e->clearLocked(); |
| } |
| } |
| |
| bool |
| Sequencer::handleLlsc(Addr address, SequencerRequest* request) |
| { |
| AbstractCacheEntry *e = m_dataCache_ptr->lookup(address); |
| if (!e) |
| return true; |
| |
| // The success flag indicates whether the LLSC operation was successful. |
| // LL ops will always succeed, but SC may fail if the cache line is no |
| // longer locked. |
| bool success = true; |
| if (request->m_type == RubyRequestType_Store_Conditional) { |
| if (!e->isLocked(m_version)) { |
| // |
| // For failed SC requests, indicate the failure to the cpu by |
| // setting the extra data to zero. |
| // |
| request->pkt->req->setExtraData(0); |
| success = false; |
| } else { |
| // |
| // For successful SC requests, indicate the success to the cpu by |
| // setting the extra data to one. |
| // |
| request->pkt->req->setExtraData(1); |
| } |
| // |
| // Independent of success, all SC operations must clear the lock |
| // |
| e->clearLocked(); |
| } else if (request->m_type == RubyRequestType_Load_Linked) { |
| // |
| // Note: To fully follow Alpha LLSC semantics, should the LL clear any |
| // previously locked cache lines? |
| // |
| e->setLocked(m_version); |
| } else if (e->isLocked(m_version)) { |
| // |
| // Normal writes should clear the locked address |
| // |
| e->clearLocked(); |
| } |
| return success; |
| } |
| |
| void |
| Sequencer::recordMissLatency(const Cycles cycles, const RubyRequestType type, |
| const MachineType respondingMach, |
| bool isExternalHit, Cycles issuedTime, |
| Cycles initialRequestTime, |
| Cycles forwardRequestTime, |
| Cycles firstResponseTime, Cycles completionTime) |
| { |
| m_latencyHist.sample(cycles); |
| m_typeLatencyHist[type]->sample(cycles); |
| |
| if (isExternalHit) { |
| m_missLatencyHist.sample(cycles); |
| m_missTypeLatencyHist[type]->sample(cycles); |
| |
| if (respondingMach != MachineType_NUM) { |
| m_missMachLatencyHist[respondingMach]->sample(cycles); |
| m_missTypeMachLatencyHist[type][respondingMach]->sample(cycles); |
| |
| if ((issuedTime <= initialRequestTime) && |
| (initialRequestTime <= forwardRequestTime) && |
| (forwardRequestTime <= firstResponseTime) && |
| (firstResponseTime <= completionTime)) { |
| |
| m_IssueToInitialDelayHist[respondingMach]->sample( |
| initialRequestTime - issuedTime); |
| m_InitialToForwardDelayHist[respondingMach]->sample( |
| forwardRequestTime - initialRequestTime); |
| m_ForwardToFirstResponseDelayHist[respondingMach]->sample( |
| firstResponseTime - forwardRequestTime); |
| m_FirstResponseToCompletionDelayHist[respondingMach]->sample( |
| completionTime - firstResponseTime); |
| } else { |
| m_IncompleteTimes[respondingMach]++; |
| } |
| } |
| } else { |
| m_hitLatencyHist.sample(cycles); |
| m_hitTypeLatencyHist[type]->sample(cycles); |
| |
| if (respondingMach != MachineType_NUM) { |
| m_hitMachLatencyHist[respondingMach]->sample(cycles); |
| m_hitTypeMachLatencyHist[type][respondingMach]->sample(cycles); |
| } |
| } |
| } |
| |
| void |
| Sequencer::writeCallback(Addr address, DataBlock& data, |
| const bool externalHit, const MachineType mach, |
| const Cycles initialRequestTime, |
| const Cycles forwardRequestTime, |
| const Cycles firstResponseTime) |
| { |
| assert(address == makeLineAddress(address)); |
| assert(m_writeRequestTable.count(makeLineAddress(address))); |
| |
| RequestTable::iterator i = m_writeRequestTable.find(address); |
| assert(i != m_writeRequestTable.end()); |
| SequencerRequest* request = i->second; |
| |
| m_writeRequestTable.erase(i); |
| markRemoved(); |
| |
| assert((request->m_type == RubyRequestType_ST) || |
| (request->m_type == RubyRequestType_ATOMIC) || |
| (request->m_type == RubyRequestType_RMW_Read) || |
| (request->m_type == RubyRequestType_RMW_Write) || |
| (request->m_type == RubyRequestType_Load_Linked) || |
| (request->m_type == RubyRequestType_Store_Conditional) || |
| (request->m_type == RubyRequestType_Locked_RMW_Read) || |
| (request->m_type == RubyRequestType_Locked_RMW_Write) || |
| (request->m_type == RubyRequestType_FLUSH)); |
| |
| // |
| // For Alpha, properly handle LL, SC, and write requests with respect to |
| // locked cache blocks. |
| // |
| // Not valid for Garnet_standalone protocl |
| // |
| bool success = true; |
| if (!m_runningGarnetStandalone) |
| success = handleLlsc(address, request); |
| |
| // Handle SLICC block_on behavior for Locked_RMW accesses. NOTE: the |
| // address variable here is assumed to be a line address, so when |
| // blocking buffers, must check line addresses. |
| if (request->m_type == RubyRequestType_Locked_RMW_Read) { |
| // blockOnQueue blocks all first-level cache controller queues |
| // waiting on memory accesses for the specified address that go to |
| // the specified queue. In this case, a Locked_RMW_Write must go to |
| // the mandatory_q before unblocking the first-level controller. |
| // This will block standard loads, stores, ifetches, etc. |
| m_controller->blockOnQueue(address, m_mandatory_q_ptr); |
| } else if (request->m_type == RubyRequestType_Locked_RMW_Write) { |
| m_controller->unblock(address); |
| } |
| |
| hitCallback(request, data, success, mach, externalHit, |
| initialRequestTime, forwardRequestTime, firstResponseTime); |
| } |
| |
| void |
| Sequencer::readCallback(Addr address, DataBlock& data, |
| bool externalHit, const MachineType mach, |
| Cycles initialRequestTime, |
| Cycles forwardRequestTime, |
| Cycles firstResponseTime) |
| { |
| assert(address == makeLineAddress(address)); |
| assert(m_readRequestTable.count(makeLineAddress(address))); |
| |
| RequestTable::iterator i = m_readRequestTable.find(address); |
| assert(i != m_readRequestTable.end()); |
| SequencerRequest* request = i->second; |
| |
| m_readRequestTable.erase(i); |
| markRemoved(); |
| |
| assert((request->m_type == RubyRequestType_LD) || |
| (request->m_type == RubyRequestType_IFETCH)); |
| |
| hitCallback(request, data, true, mach, externalHit, |
| initialRequestTime, forwardRequestTime, firstResponseTime); |
| } |
| |
| void |
| Sequencer::hitCallback(SequencerRequest* srequest, DataBlock& data, |
| bool llscSuccess, |
| const MachineType mach, const bool externalHit, |
| const Cycles initialRequestTime, |
| const Cycles forwardRequestTime, |
| const Cycles firstResponseTime) |
| { |
| warn_once("Replacement policy updates recently became the responsibility " |
| "of SLICC state machines. Make sure to setMRU() near callbacks " |
| "in .sm files!"); |
| |
| PacketPtr pkt = srequest->pkt; |
| Addr request_address(pkt->getAddr()); |
| RubyRequestType type = srequest->m_type; |
| Cycles issued_time = srequest->issue_time; |
| |
| assert(curCycle() >= issued_time); |
| Cycles total_latency = curCycle() - issued_time; |
| |
| // Profile the latency for all demand accesses. |
| recordMissLatency(total_latency, type, mach, externalHit, issued_time, |
| initialRequestTime, forwardRequestTime, |
| firstResponseTime, curCycle()); |
| |
| DPRINTFR(ProtocolTrace, "%15s %3s %10s%20s %6s>%-6s %#x %d cycles\n", |
| curTick(), m_version, "Seq", |
| llscSuccess ? "Done" : "SC_Failed", "", "", |
| printAddress(request_address), total_latency); |
| |
| // update the data unless it is a non-data-carrying flush |
| if (RubySystem::getWarmupEnabled()) { |
| data.setData(pkt->getConstPtr<uint8_t>(), |
| getOffset(request_address), pkt->getSize()); |
| } else if (!pkt->isFlush()) { |
| if ((type == RubyRequestType_LD) || |
| (type == RubyRequestType_IFETCH) || |
| (type == RubyRequestType_RMW_Read) || |
| (type == RubyRequestType_Locked_RMW_Read) || |
| (type == RubyRequestType_Load_Linked)) { |
| pkt->setData( |
| data.getData(getOffset(request_address), pkt->getSize())); |
| DPRINTF(RubySequencer, "read data %s\n", data); |
| } else if (pkt->req->isSwap()) { |
| std::vector<uint8_t> overwrite_val(pkt->getSize()); |
| pkt->writeData(&overwrite_val[0]); |
| pkt->setData( |
| data.getData(getOffset(request_address), pkt->getSize())); |
| data.setData(&overwrite_val[0], |
| getOffset(request_address), pkt->getSize()); |
| DPRINTF(RubySequencer, "swap data %s\n", data); |
| } else if (type != RubyRequestType_Store_Conditional || llscSuccess) { |
| // Types of stores set the actual data here, apart from |
| // failed Store Conditional requests |
| data.setData(pkt->getConstPtr<uint8_t>(), |
| getOffset(request_address), pkt->getSize()); |
| DPRINTF(RubySequencer, "set data %s\n", data); |
| } |
| } |
| |
| // If using the RubyTester, update the RubyTester sender state's |
| // subBlock with the recieved data. The tester will later access |
| // this state. |
| if (m_usingRubyTester) { |
| DPRINTF(RubySequencer, "hitCallback %s 0x%x using RubyTester\n", |
| pkt->cmdString(), pkt->getAddr()); |
| RubyTester::SenderState* testerSenderState = |
| pkt->findNextSenderState<RubyTester::SenderState>(); |
| assert(testerSenderState); |
| testerSenderState->subBlock.mergeFrom(data); |
| } |
| |
| delete srequest; |
| |
| RubySystem *rs = m_ruby_system; |
| if (RubySystem::getWarmupEnabled()) { |
| assert(pkt->req); |
| delete pkt; |
| rs->m_cache_recorder->enqueueNextFetchRequest(); |
| } else if (RubySystem::getCooldownEnabled()) { |
| delete pkt; |
| rs->m_cache_recorder->enqueueNextFlushRequest(); |
| } else { |
| ruby_hit_callback(pkt); |
| testDrainComplete(); |
| } |
| } |
| |
| bool |
| Sequencer::empty() const |
| { |
| return m_writeRequestTable.empty() && m_readRequestTable.empty(); |
| } |
| |
| RequestStatus |
| Sequencer::makeRequest(PacketPtr pkt) |
| { |
| if (m_outstanding_count >= m_max_outstanding_requests) { |
| return RequestStatus_BufferFull; |
| } |
| |
| RubyRequestType primary_type = RubyRequestType_NULL; |
| RubyRequestType secondary_type = RubyRequestType_NULL; |
| |
| if (pkt->isLLSC()) { |
| // |
| // Alpha LL/SC instructions need to be handled carefully by the cache |
| // coherence protocol to ensure they follow the proper semantics. In |
| // particular, by identifying the operations as atomic, the protocol |
| // should understand that migratory sharing optimizations should not |
| // be performed (i.e. a load between the LL and SC should not steal |
| // away exclusive permission). |
| // |
| if (pkt->isWrite()) { |
| DPRINTF(RubySequencer, "Issuing SC\n"); |
| primary_type = RubyRequestType_Store_Conditional; |
| } else { |
| DPRINTF(RubySequencer, "Issuing LL\n"); |
| assert(pkt->isRead()); |
| primary_type = RubyRequestType_Load_Linked; |
| } |
| secondary_type = RubyRequestType_ATOMIC; |
| } else if (pkt->req->isLockedRMW()) { |
| // |
| // x86 locked instructions are translated to store cache coherence |
| // requests because these requests should always be treated as read |
| // exclusive operations and should leverage any migratory sharing |
| // optimization built into the protocol. |
| // |
| if (pkt->isWrite()) { |
| DPRINTF(RubySequencer, "Issuing Locked RMW Write\n"); |
| primary_type = RubyRequestType_Locked_RMW_Write; |
| } else { |
| DPRINTF(RubySequencer, "Issuing Locked RMW Read\n"); |
| assert(pkt->isRead()); |
| primary_type = RubyRequestType_Locked_RMW_Read; |
| } |
| secondary_type = RubyRequestType_ST; |
| } else { |
| // |
| // To support SwapReq, we need to check isWrite() first: a SwapReq |
| // should always be treated like a write, but since a SwapReq implies |
| // both isWrite() and isRead() are true, check isWrite() first here. |
| // |
| if (pkt->isWrite()) { |
| // |
| // Note: M5 packets do not differentiate ST from RMW_Write |
| // |
| primary_type = secondary_type = RubyRequestType_ST; |
| } else if (pkt->isRead()) { |
| if (pkt->req->isInstFetch()) { |
| primary_type = secondary_type = RubyRequestType_IFETCH; |
| } else { |
| bool storeCheck = false; |
| // only X86 need the store check |
| if (system->getArch() == Arch::X86ISA) { |
| uint32_t flags = pkt->req->getFlags(); |
| storeCheck = flags & |
| (X86ISA::StoreCheck << X86ISA::FlagShift); |
| } |
| if (storeCheck) { |
| primary_type = RubyRequestType_RMW_Read; |
| secondary_type = RubyRequestType_ST; |
| } else { |
| primary_type = secondary_type = RubyRequestType_LD; |
| } |
| } |
| } else if (pkt->isFlush()) { |
| primary_type = secondary_type = RubyRequestType_FLUSH; |
| } else { |
| panic("Unsupported ruby packet type\n"); |
| } |
| } |
| |
| RequestStatus status = insertRequest(pkt, primary_type); |
| if (status != RequestStatus_Ready) |
| return status; |
| |
| issueRequest(pkt, secondary_type); |
| |
| // TODO: issue hardware prefetches here |
| return RequestStatus_Issued; |
| } |
| |
| void |
| Sequencer::issueRequest(PacketPtr pkt, RubyRequestType secondary_type) |
| { |
| assert(pkt != NULL); |
| ContextID proc_id = pkt->req->hasContextId() ? |
| pkt->req->contextId() : InvalidContextID; |
| |
| ContextID core_id = coreId(); |
| |
| // If valid, copy the pc to the ruby request |
| Addr pc = 0; |
| if (pkt->req->hasPC()) { |
| pc = pkt->req->getPC(); |
| } |
| |
| // check if the packet has data as for example prefetch and flush |
| // requests do not |
| std::shared_ptr<RubyRequest> msg = |
| std::make_shared<RubyRequest>(clockEdge(), pkt->getAddr(), |
| pkt->isFlush() ? |
| nullptr : pkt->getPtr<uint8_t>(), |
| pkt->getSize(), pc, secondary_type, |
| RubyAccessMode_Supervisor, pkt, |
| PrefetchBit_No, proc_id, core_id); |
| |
| DPRINTFR(ProtocolTrace, "%15s %3s %10s%20s %6s>%-6s %#x %s\n", |
| curTick(), m_version, "Seq", "Begin", "", "", |
| printAddress(msg->getPhysicalAddress()), |
| RubyRequestType_to_string(secondary_type)); |
| |
| Tick latency = cyclesToTicks( |
| m_controller->mandatoryQueueLatency(secondary_type)); |
| assert(latency > 0); |
| |
| assert(m_mandatory_q_ptr != NULL); |
| m_mandatory_q_ptr->enqueue(msg, clockEdge(), latency); |
| } |
| |
| template <class KEY, class VALUE> |
| std::ostream & |
| operator<<(ostream &out, const std::unordered_map<KEY, VALUE> &map) |
| { |
| auto i = map.begin(); |
| auto end = map.end(); |
| |
| out << "["; |
| for (; i != end; ++i) |
| out << " " << i->first << "=" << i->second; |
| out << " ]"; |
| |
| return out; |
| } |
| |
| void |
| Sequencer::print(ostream& out) const |
| { |
| out << "[Sequencer: " << m_version |
| << ", outstanding requests: " << m_outstanding_count |
| << ", read request table: " << m_readRequestTable |
| << ", write request table: " << m_writeRequestTable |
| << "]"; |
| } |
| |
| // this can be called from setState whenever coherence permissions are |
| // upgraded when invoked, coherence violations will be checked for the |
| // given block |
| void |
| Sequencer::checkCoherence(Addr addr) |
| { |
| } |
| |
| void |
| Sequencer::recordRequestType(SequencerRequestType requestType) { |
| DPRINTF(RubyStats, "Recorded statistic: %s\n", |
| SequencerRequestType_to_string(requestType)); |
| } |
| |
| |
| void |
| Sequencer::evictionCallback(Addr address) |
| { |
| ruby_eviction_callback(address); |
| } |
| |
| void |
| Sequencer::regStats() |
| { |
| RubyPort::regStats(); |
| |
| m_store_waiting_on_load |
| .name(name() + ".store_waiting_on_load") |
| .desc("Number of times a store aliased with a pending load") |
| .flags(Stats::nozero); |
| m_store_waiting_on_store |
| .name(name() + ".store_waiting_on_store") |
| .desc("Number of times a store aliased with a pending store") |
| .flags(Stats::nozero); |
| m_load_waiting_on_load |
| .name(name() + ".load_waiting_on_load") |
| .desc("Number of times a load aliased with a pending load") |
| .flags(Stats::nozero); |
| m_load_waiting_on_store |
| .name(name() + ".load_waiting_on_store") |
| .desc("Number of times a load aliased with a pending store") |
| .flags(Stats::nozero); |
| |
| // These statistical variables are not for display. |
| // The profiler will collate these across different |
| // sequencers and display those collated statistics. |
| m_outstandReqHist.init(10); |
| m_latencyHist.init(10); |
| m_hitLatencyHist.init(10); |
| m_missLatencyHist.init(10); |
| |
| for (int i = 0; i < RubyRequestType_NUM; i++) { |
| m_typeLatencyHist.push_back(new Stats::Histogram()); |
| m_typeLatencyHist[i]->init(10); |
| |
| m_hitTypeLatencyHist.push_back(new Stats::Histogram()); |
| m_hitTypeLatencyHist[i]->init(10); |
| |
| m_missTypeLatencyHist.push_back(new Stats::Histogram()); |
| m_missTypeLatencyHist[i]->init(10); |
| } |
| |
| for (int i = 0; i < MachineType_NUM; i++) { |
| m_hitMachLatencyHist.push_back(new Stats::Histogram()); |
| m_hitMachLatencyHist[i]->init(10); |
| |
| m_missMachLatencyHist.push_back(new Stats::Histogram()); |
| m_missMachLatencyHist[i]->init(10); |
| |
| m_IssueToInitialDelayHist.push_back(new Stats::Histogram()); |
| m_IssueToInitialDelayHist[i]->init(10); |
| |
| m_InitialToForwardDelayHist.push_back(new Stats::Histogram()); |
| m_InitialToForwardDelayHist[i]->init(10); |
| |
| m_ForwardToFirstResponseDelayHist.push_back(new Stats::Histogram()); |
| m_ForwardToFirstResponseDelayHist[i]->init(10); |
| |
| m_FirstResponseToCompletionDelayHist.push_back(new Stats::Histogram()); |
| m_FirstResponseToCompletionDelayHist[i]->init(10); |
| } |
| |
| for (int i = 0; i < RubyRequestType_NUM; i++) { |
| m_hitTypeMachLatencyHist.push_back(std::vector<Stats::Histogram *>()); |
| m_missTypeMachLatencyHist.push_back(std::vector<Stats::Histogram *>()); |
| |
| for (int j = 0; j < MachineType_NUM; j++) { |
| m_hitTypeMachLatencyHist[i].push_back(new Stats::Histogram()); |
| m_hitTypeMachLatencyHist[i][j]->init(10); |
| |
| m_missTypeMachLatencyHist[i].push_back(new Stats::Histogram()); |
| m_missTypeMachLatencyHist[i][j]->init(10); |
| } |
| } |
| } |