//===- GCNIterativeScheduler.cpp ------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// /// /// \file /// This file implements the class GCNIterativeScheduler. /// //===----------------------------------------------------------------------===// #include "GCNIterativeScheduler.h" #include "GCNSchedStrategy.h" #include "SIMachineFunctionInfo.h" using namespace llvm; #define DEBUG_TYPE "machine-scheduler" namespace llvm { std::vector makeMinRegSchedule(ArrayRef TopRoots, const ScheduleDAG &DAG); std::vector makeGCNILPScheduler(ArrayRef BotRoots, const ScheduleDAG &DAG); } // shim accessors for different order containers static inline MachineInstr *getMachineInstr(MachineInstr *MI) { return MI; } static inline MachineInstr *getMachineInstr(const SUnit *SU) { return SU->getInstr(); } static inline MachineInstr *getMachineInstr(const SUnit &SU) { return SU.getInstr(); } #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) LLVM_DUMP_METHOD static void printRegion(raw_ostream &OS, MachineBasicBlock::iterator Begin, MachineBasicBlock::iterator End, const LiveIntervals *LIS, unsigned MaxInstNum = std::numeric_limits::max()) { auto BB = Begin->getParent(); OS << BB->getParent()->getName() << ":" << printMBBReference(*BB) << ' ' << BB->getName() << ":\n"; auto I = Begin; MaxInstNum = std::max(MaxInstNum, 1u); for (; I != End && MaxInstNum; ++I, --MaxInstNum) { if (!I->isDebugInstr() && LIS) OS << LIS->getInstructionIndex(*I); OS << '\t' << *I; } if (I != End) { OS << "\t...\n"; I = std::prev(End); if (!I->isDebugInstr() && LIS) OS << LIS->getInstructionIndex(*I); OS << '\t' << *I; } if (End != BB->end()) { // print boundary inst if present OS << "----\n"; if (LIS) OS << LIS->getInstructionIndex(*End) << '\t'; OS << *End; } } LLVM_DUMP_METHOD static void printLivenessInfo(raw_ostream &OS, MachineBasicBlock::iterator Begin, MachineBasicBlock::iterator End, const LiveIntervals *LIS) { const auto BB = Begin->getParent(); const auto &MRI = BB->getParent()->getRegInfo(); const auto LiveIns = getLiveRegsBefore(*Begin, *LIS); OS << "LIn RP: "; getRegPressure(MRI, LiveIns).print(OS); const auto BottomMI = End == BB->end() ? std::prev(End) : End; const auto LiveOuts = getLiveRegsAfter(*BottomMI, *LIS); OS << "LOt RP: "; getRegPressure(MRI, LiveOuts).print(OS); } LLVM_DUMP_METHOD void GCNIterativeScheduler::printRegions(raw_ostream &OS) const { const auto &ST = MF.getSubtarget(); for (const auto R : Regions) { OS << "Region to schedule "; printRegion(OS, R->Begin, R->End, LIS, 1); printLivenessInfo(OS, R->Begin, R->End, LIS); OS << "Max RP: "; R->MaxPressure.print(OS, &ST); } } LLVM_DUMP_METHOD void GCNIterativeScheduler::printSchedResult(raw_ostream &OS, const Region *R, const GCNRegPressure &RP) const { OS << "\nAfter scheduling "; printRegion(OS, R->Begin, R->End, LIS); printSchedRP(OS, R->MaxPressure, RP); OS << '\n'; } LLVM_DUMP_METHOD void GCNIterativeScheduler::printSchedRP(raw_ostream &OS, const GCNRegPressure &Before, const GCNRegPressure &After) const { const auto &ST = MF.getSubtarget(); OS << "RP before: "; Before.print(OS, &ST); OS << "RP after: "; After.print(OS, &ST); } #endif // DAG builder helper class GCNIterativeScheduler::BuildDAG { GCNIterativeScheduler &Sch; SmallVector TopRoots; SmallVector BotRoots; public: BuildDAG(const Region &R, GCNIterativeScheduler &_Sch) : Sch(_Sch) { auto BB = R.Begin->getParent(); Sch.BaseClass::startBlock(BB); Sch.BaseClass::enterRegion(BB, R.Begin, R.End, R.NumRegionInstrs); Sch.buildSchedGraph(Sch.AA, nullptr, nullptr, nullptr, /*TrackLaneMask*/true); Sch.Topo.InitDAGTopologicalSorting(); Sch.findRootsAndBiasEdges(TopRoots, BotRoots); } ~BuildDAG() { Sch.BaseClass::exitRegion(); Sch.BaseClass::finishBlock(); } ArrayRef getTopRoots() const { return TopRoots; } ArrayRef getBottomRoots() const { return BotRoots; } }; class GCNIterativeScheduler::OverrideLegacyStrategy { GCNIterativeScheduler &Sch; Region &Rgn; std::unique_ptr SaveSchedImpl; GCNRegPressure SaveMaxRP; public: OverrideLegacyStrategy(Region &R, MachineSchedStrategy &OverrideStrategy, GCNIterativeScheduler &_Sch) : Sch(_Sch) , Rgn(R) , SaveSchedImpl(std::move(_Sch.SchedImpl)) , SaveMaxRP(R.MaxPressure) { Sch.SchedImpl.reset(&OverrideStrategy); auto BB = R.Begin->getParent(); Sch.BaseClass::startBlock(BB); Sch.BaseClass::enterRegion(BB, R.Begin, R.End, R.NumRegionInstrs); } ~OverrideLegacyStrategy() { Sch.BaseClass::exitRegion(); Sch.BaseClass::finishBlock(); Sch.SchedImpl.release(); Sch.SchedImpl = std::move(SaveSchedImpl); } void schedule() { assert(Sch.RegionBegin == Rgn.Begin && Sch.RegionEnd == Rgn.End); LLVM_DEBUG(dbgs() << "\nScheduling "; printRegion(dbgs(), Rgn.Begin, Rgn.End, Sch.LIS, 2)); Sch.BaseClass::schedule(); // Unfortunatelly placeDebugValues incorrectly modifies RegionEnd, restore Sch.RegionEnd = Rgn.End; //assert(Rgn.End == Sch.RegionEnd); Rgn.Begin = Sch.RegionBegin; Rgn.MaxPressure.clear(); } void restoreOrder() { assert(Sch.RegionBegin == Rgn.Begin && Sch.RegionEnd == Rgn.End); // DAG SUnits are stored using original region's order // so just use SUnits as the restoring schedule Sch.scheduleRegion(Rgn, Sch.SUnits, SaveMaxRP); } }; namespace { // just a stub to make base class happy class SchedStrategyStub : public MachineSchedStrategy { public: bool shouldTrackPressure() const override { return false; } bool shouldTrackLaneMasks() const override { return false; } void initialize(ScheduleDAGMI *DAG) override {} SUnit *pickNode(bool &IsTopNode) override { return nullptr; } void schedNode(SUnit *SU, bool IsTopNode) override {} void releaseTopNode(SUnit *SU) override {} void releaseBottomNode(SUnit *SU) override {} }; } // end anonymous namespace GCNIterativeScheduler::GCNIterativeScheduler(MachineSchedContext *C, StrategyKind S) : BaseClass(C, std::make_unique()) , Context(C) , Strategy(S) , UPTracker(*LIS) { } // returns max pressure for a region GCNRegPressure GCNIterativeScheduler::getRegionPressure(MachineBasicBlock::iterator Begin, MachineBasicBlock::iterator End) const { // For the purpose of pressure tracking bottom inst of the region should // be also processed. End is either BB end, BB terminator inst or sched // boundary inst. auto const BBEnd = Begin->getParent()->end(); auto const BottomMI = End == BBEnd ? std::prev(End) : End; // scheduleRegions walks bottom to top, so its likely we just get next // instruction to track auto AfterBottomMI = std::next(BottomMI); if (AfterBottomMI == BBEnd || &*AfterBottomMI != UPTracker.getLastTrackedMI()) { UPTracker.reset(*BottomMI); } else { assert(UPTracker.isValid()); } for (auto I = BottomMI; I != Begin; --I) UPTracker.recede(*I); UPTracker.recede(*Begin); assert(UPTracker.isValid() || (dbgs() << "Tracked region ", printRegion(dbgs(), Begin, End, LIS), false)); return UPTracker.moveMaxPressure(); } // returns max pressure for a tentative schedule template GCNRegPressure GCNIterativeScheduler::getSchedulePressure(const Region &R, Range &&Schedule) const { auto const BBEnd = R.Begin->getParent()->end(); GCNUpwardRPTracker RPTracker(*LIS); if (R.End != BBEnd) { // R.End points to the boundary instruction but the // schedule doesn't include it RPTracker.reset(*R.End); RPTracker.recede(*R.End); } else { // R.End doesn't point to the boundary instruction RPTracker.reset(*std::prev(BBEnd)); } for (auto I = Schedule.end(), B = Schedule.begin(); I != B;) { RPTracker.recede(*getMachineInstr(*--I)); } return RPTracker.moveMaxPressure(); } void GCNIterativeScheduler::enterRegion(MachineBasicBlock *BB, // overriden MachineBasicBlock::iterator Begin, MachineBasicBlock::iterator End, unsigned NumRegionInstrs) { BaseClass::enterRegion(BB, Begin, End, NumRegionInstrs); if (NumRegionInstrs > 2) { Regions.push_back( new (Alloc.Allocate()) Region { Begin, End, NumRegionInstrs, getRegionPressure(Begin, End), nullptr }); } } void GCNIterativeScheduler::schedule() { // overriden // do nothing LLVM_DEBUG(printLivenessInfo(dbgs(), RegionBegin, RegionEnd, LIS); if (!Regions.empty() && Regions.back()->Begin == RegionBegin) { dbgs() << "Max RP: "; Regions.back()->MaxPressure.print( dbgs(), &MF.getSubtarget()); } dbgs() << '\n';); } void GCNIterativeScheduler::finalizeSchedule() { // overriden if (Regions.empty()) return; switch (Strategy) { case SCHEDULE_MINREGONLY: scheduleMinReg(); break; case SCHEDULE_MINREGFORCED: scheduleMinReg(true); break; case SCHEDULE_LEGACYMAXOCCUPANCY: scheduleLegacyMaxOccupancy(); break; case SCHEDULE_ILP: scheduleILP(false); break; } } // Detach schedule from SUnits and interleave it with debug values. // Returned schedule becomes independent of DAG state. std::vector GCNIterativeScheduler::detachSchedule(ScheduleRef Schedule) const { std::vector Res; Res.reserve(Schedule.size() * 2); if (FirstDbgValue) Res.push_back(FirstDbgValue); const auto DbgB = DbgValues.begin(), DbgE = DbgValues.end(); for (auto SU : Schedule) { Res.push_back(SU->getInstr()); const auto &D = std::find_if(DbgB, DbgE, [SU](decltype(*DbgB) &P) { return P.second == SU->getInstr(); }); if (D != DbgE) Res.push_back(D->first); } return Res; } void GCNIterativeScheduler::setBestSchedule(Region &R, ScheduleRef Schedule, const GCNRegPressure &MaxRP) { R.BestSchedule.reset( new TentativeSchedule{ detachSchedule(Schedule), MaxRP }); } void GCNIterativeScheduler::scheduleBest(Region &R) { assert(R.BestSchedule.get() && "No schedule specified"); scheduleRegion(R, R.BestSchedule->Schedule, R.BestSchedule->MaxPressure); R.BestSchedule.reset(); } // minimal required region scheduler, works for ranges of SUnits*, // SUnits or MachineIntrs* template void GCNIterativeScheduler::scheduleRegion(Region &R, Range &&Schedule, const GCNRegPressure &MaxRP) { assert(RegionBegin == R.Begin && RegionEnd == R.End); assert(LIS != nullptr); #ifndef NDEBUG const auto SchedMaxRP = getSchedulePressure(R, Schedule); #endif auto BB = R.Begin->getParent(); auto Top = R.Begin; for (const auto &I : Schedule) { auto MI = getMachineInstr(I); if (MI != &*Top) { BB->remove(MI); BB->insert(Top, MI); if (!MI->isDebugInstr()) LIS->handleMove(*MI, true); } if (!MI->isDebugInstr()) { // Reset read - undef flags and update them later. for (auto &Op : MI->operands()) if (Op.isReg() && Op.isDef()) Op.setIsUndef(false); RegisterOperands RegOpers; RegOpers.collect(*MI, *TRI, MRI, /*ShouldTrackLaneMasks*/true, /*IgnoreDead*/false); // Adjust liveness and add missing dead+read-undef flags. auto SlotIdx = LIS->getInstructionIndex(*MI).getRegSlot(); RegOpers.adjustLaneLiveness(*LIS, MRI, SlotIdx, MI); } Top = std::next(MI->getIterator()); } RegionBegin = getMachineInstr(Schedule.front()); // Schedule consisting of MachineInstr* is considered 'detached' // and already interleaved with debug values if (!std::is_same::value) { placeDebugValues(); // Unfortunatelly placeDebugValues incorrectly modifies RegionEnd, restore //assert(R.End == RegionEnd); RegionEnd = R.End; } R.Begin = RegionBegin; R.MaxPressure = MaxRP; #ifndef NDEBUG const auto RegionMaxRP = getRegionPressure(R); const auto &ST = MF.getSubtarget(); #endif assert((SchedMaxRP == RegionMaxRP && (MaxRP.empty() || SchedMaxRP == MaxRP)) || (dbgs() << "Max RP mismatch!!!\n" "RP for schedule (calculated): ", SchedMaxRP.print(dbgs(), &ST), dbgs() << "RP for schedule (reported): ", MaxRP.print(dbgs(), &ST), dbgs() << "RP after scheduling: ", RegionMaxRP.print(dbgs(), &ST), false)); } // Sort recorded regions by pressure - highest at the front void GCNIterativeScheduler::sortRegionsByPressure(unsigned TargetOcc) { const auto &ST = MF.getSubtarget(); llvm::sort(Regions, [&ST, TargetOcc](const Region *R1, const Region *R2) { return R2->MaxPressure.less(ST, R1->MaxPressure, TargetOcc); }); } /////////////////////////////////////////////////////////////////////////////// // Legacy MaxOccupancy Strategy // Tries to increase occupancy applying minreg scheduler for a sequence of // most demanding regions. Obtained schedules are saved as BestSchedule for a // region. // TargetOcc is the best achievable occupancy for a kernel. // Returns better occupancy on success or current occupancy on fail. // BestSchedules aren't deleted on fail. unsigned GCNIterativeScheduler::tryMaximizeOccupancy(unsigned TargetOcc) { // TODO: assert Regions are sorted descending by pressure const auto &ST = MF.getSubtarget(); const auto Occ = Regions.front()->MaxPressure.getOccupancy(ST); LLVM_DEBUG(dbgs() << "Trying to improve occupancy, target = " << TargetOcc << ", current = " << Occ << '\n'); auto NewOcc = TargetOcc; for (auto R : Regions) { if (R->MaxPressure.getOccupancy(ST) >= NewOcc) break; LLVM_DEBUG(printRegion(dbgs(), R->Begin, R->End, LIS, 3); printLivenessInfo(dbgs(), R->Begin, R->End, LIS)); BuildDAG DAG(*R, *this); const auto MinSchedule = makeMinRegSchedule(DAG.getTopRoots(), *this); const auto MaxRP = getSchedulePressure(*R, MinSchedule); LLVM_DEBUG(dbgs() << "Occupancy improvement attempt:\n"; printSchedRP(dbgs(), R->MaxPressure, MaxRP)); NewOcc = std::min(NewOcc, MaxRP.getOccupancy(ST)); if (NewOcc <= Occ) break; setBestSchedule(*R, MinSchedule, MaxRP); } LLVM_DEBUG(dbgs() << "New occupancy = " << NewOcc << ", prev occupancy = " << Occ << '\n'); if (NewOcc > Occ) { SIMachineFunctionInfo *MFI = MF.getInfo(); MFI->increaseOccupancy(MF, NewOcc); } return std::max(NewOcc, Occ); } void GCNIterativeScheduler::scheduleLegacyMaxOccupancy( bool TryMaximizeOccupancy) { const auto &ST = MF.getSubtarget(); SIMachineFunctionInfo *MFI = MF.getInfo(); auto TgtOcc = MFI->getMinAllowedOccupancy(); sortRegionsByPressure(TgtOcc); auto Occ = Regions.front()->MaxPressure.getOccupancy(ST); if (TryMaximizeOccupancy && Occ < TgtOcc) Occ = tryMaximizeOccupancy(TgtOcc); // This is really weird but for some magic scheduling regions twice // gives performance improvement const int NumPasses = Occ < TgtOcc ? 2 : 1; TgtOcc = std::min(Occ, TgtOcc); LLVM_DEBUG(dbgs() << "Scheduling using default scheduler, " "target occupancy = " << TgtOcc << '\n'); GCNMaxOccupancySchedStrategy LStrgy(Context); unsigned FinalOccupancy = std::min(Occ, MFI->getOccupancy()); for (int I = 0; I < NumPasses; ++I) { // running first pass with TargetOccupancy = 0 mimics previous scheduling // approach and is a performance magic LStrgy.setTargetOccupancy(I == 0 ? 0 : TgtOcc); for (auto R : Regions) { OverrideLegacyStrategy Ovr(*R, LStrgy, *this); Ovr.schedule(); const auto RP = getRegionPressure(*R); LLVM_DEBUG(printSchedRP(dbgs(), R->MaxPressure, RP)); if (RP.getOccupancy(ST) < TgtOcc) { LLVM_DEBUG(dbgs() << "Didn't fit into target occupancy O" << TgtOcc); if (R->BestSchedule.get() && R->BestSchedule->MaxPressure.getOccupancy(ST) >= TgtOcc) { LLVM_DEBUG(dbgs() << ", scheduling minimal register\n"); scheduleBest(*R); } else { LLVM_DEBUG(dbgs() << ", restoring\n"); Ovr.restoreOrder(); assert(R->MaxPressure.getOccupancy(ST) >= TgtOcc); } } FinalOccupancy = std::min(FinalOccupancy, RP.getOccupancy(ST)); } } MFI->limitOccupancy(FinalOccupancy); } /////////////////////////////////////////////////////////////////////////////// // Minimal Register Strategy void GCNIterativeScheduler::scheduleMinReg(bool force) { const auto &ST = MF.getSubtarget(); const SIMachineFunctionInfo *MFI = MF.getInfo(); const auto TgtOcc = MFI->getOccupancy(); sortRegionsByPressure(TgtOcc); auto MaxPressure = Regions.front()->MaxPressure; for (auto R : Regions) { if (!force && R->MaxPressure.less(ST, MaxPressure, TgtOcc)) break; BuildDAG DAG(*R, *this); const auto MinSchedule = makeMinRegSchedule(DAG.getTopRoots(), *this); const auto RP = getSchedulePressure(*R, MinSchedule); LLVM_DEBUG(if (R->MaxPressure.less(ST, RP, TgtOcc)) { dbgs() << "\nWarning: Pressure becomes worse after minreg!"; printSchedRP(dbgs(), R->MaxPressure, RP); }); if (!force && MaxPressure.less(ST, RP, TgtOcc)) break; scheduleRegion(*R, MinSchedule, RP); LLVM_DEBUG(printSchedResult(dbgs(), R, RP)); MaxPressure = RP; } } /////////////////////////////////////////////////////////////////////////////// // ILP scheduler port void GCNIterativeScheduler::scheduleILP( bool TryMaximizeOccupancy) { const auto &ST = MF.getSubtarget(); SIMachineFunctionInfo *MFI = MF.getInfo(); auto TgtOcc = MFI->getMinAllowedOccupancy(); sortRegionsByPressure(TgtOcc); auto Occ = Regions.front()->MaxPressure.getOccupancy(ST); if (TryMaximizeOccupancy && Occ < TgtOcc) Occ = tryMaximizeOccupancy(TgtOcc); TgtOcc = std::min(Occ, TgtOcc); LLVM_DEBUG(dbgs() << "Scheduling using default scheduler, " "target occupancy = " << TgtOcc << '\n'); unsigned FinalOccupancy = std::min(Occ, MFI->getOccupancy()); for (auto R : Regions) { BuildDAG DAG(*R, *this); const auto ILPSchedule = makeGCNILPScheduler(DAG.getBottomRoots(), *this); const auto RP = getSchedulePressure(*R, ILPSchedule); LLVM_DEBUG(printSchedRP(dbgs(), R->MaxPressure, RP)); if (RP.getOccupancy(ST) < TgtOcc) { LLVM_DEBUG(dbgs() << "Didn't fit into target occupancy O" << TgtOcc); if (R->BestSchedule.get() && R->BestSchedule->MaxPressure.getOccupancy(ST) >= TgtOcc) { LLVM_DEBUG(dbgs() << ", scheduling minimal register\n"); scheduleBest(*R); } } else { scheduleRegion(*R, ILPSchedule, RP); LLVM_DEBUG(printSchedResult(dbgs(), R, RP)); FinalOccupancy = std::min(FinalOccupancy, RP.getOccupancy(ST)); } } MFI->limitOccupancy(FinalOccupancy); }