//===- DFAJumpThreading.cpp - Threads a switch statement inside a loop ----===// // // 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 // //===----------------------------------------------------------------------===// // // Transform each threading path to effectively jump thread the DFA. For // example, the CFG below could be transformed as follows, where the cloned // blocks unconditionally branch to the next correct case based on what is // identified in the analysis. // // sw.bb sw.bb // / | \ / | \ // case1 case2 case3 case1 case2 case3 // \ | / | | | // determinator det.2 det.3 det.1 // br sw.bb / | \ // sw.bb.2 sw.bb.3 sw.bb.1 // br case2 br case3 br case1ยง // // Definitions and Terminology: // // * Threading path: // a list of basic blocks, the exit state, and the block that determines // the next state, for which the following notation will be used: // < path of BBs that form a cycle > [ state, determinator ] // // * Predictable switch: // The switch variable is always a known constant so that all conditional // jumps based on switch variable can be converted to unconditional jump. // // * Determinator: // The basic block that determines the next state of the DFA. // // Representing the optimization in C-like pseudocode: the code pattern on the // left could functionally be transformed to the right pattern if the switch // condition is predictable. // // X = A goto A // for (...) A: // switch (X) ... // case A goto B // X = B B: // case B ... // X = C goto C // // The pass first checks that switch variable X is decided by the control flow // path taken in the loop; for example, in case B, the next value of X is // decided to be C. It then enumerates through all paths in the loop and labels // the basic blocks where the next state is decided. // // Using this information it creates new paths that unconditionally branch to // the next case. This involves cloning code, so it only gets triggered if the // amount of code duplicated is below a threshold. // //===----------------------------------------------------------------------===// #include "llvm/Transforms/Scalar/DFAJumpThreading.h" #include "llvm/ADT/APInt.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/DepthFirstIterator.h" #include "llvm/ADT/SmallSet.h" #include "llvm/ADT/Statistic.h" #include "llvm/Analysis/AssumptionCache.h" #include "llvm/Analysis/CodeMetrics.h" #include "llvm/Analysis/LoopIterator.h" #include "llvm/Analysis/OptimizationRemarkEmitter.h" #include "llvm/Analysis/TargetTransformInfo.h" #include "llvm/IR/CFG.h" #include "llvm/IR/Constants.h" #include "llvm/IR/IntrinsicInst.h" #include "llvm/IR/Verifier.h" #include "llvm/InitializePasses.h" #include "llvm/Pass.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Transforms/Scalar.h" #include "llvm/Transforms/Utils/BasicBlockUtils.h" #include "llvm/Transforms/Utils/Cloning.h" #include "llvm/Transforms/Utils/SSAUpdaterBulk.h" #include "llvm/Transforms/Utils/ValueMapper.h" #include #include using namespace llvm; #define DEBUG_TYPE "dfa-jump-threading" STATISTIC(NumTransforms, "Number of transformations done"); STATISTIC(NumCloned, "Number of blocks cloned"); STATISTIC(NumPaths, "Number of individual paths threaded"); static cl::opt ClViewCfgBefore("dfa-jump-view-cfg-before", cl::desc("View the CFG before DFA Jump Threading"), cl::Hidden, cl::init(false)); static cl::opt MaxPathLength( "dfa-max-path-length", cl::desc("Max number of blocks searched to find a threading path"), cl::Hidden, cl::init(20)); static cl::opt CostThreshold("dfa-cost-threshold", cl::desc("Maximum cost accepted for the transformation"), cl::Hidden, cl::init(50)); namespace { class SelectInstToUnfold { SelectInst *SI; PHINode *SIUse; public: SelectInstToUnfold(SelectInst *SI, PHINode *SIUse) : SI(SI), SIUse(SIUse) {} SelectInst *getInst() { return SI; } PHINode *getUse() { return SIUse; } explicit operator bool() const { return SI && SIUse; } }; void unfold(DomTreeUpdater *DTU, SelectInstToUnfold SIToUnfold, std::vector *NewSIsToUnfold, std::vector *NewBBs); class DFAJumpThreading { public: DFAJumpThreading(AssumptionCache *AC, DominatorTree *DT, TargetTransformInfo *TTI, OptimizationRemarkEmitter *ORE) : AC(AC), DT(DT), TTI(TTI), ORE(ORE) {} bool run(Function &F); private: void unfoldSelectInstrs(DominatorTree *DT, const SmallVector &SelectInsts) { DomTreeUpdater DTU(DT, DomTreeUpdater::UpdateStrategy::Eager); SmallVector Stack; for (SelectInstToUnfold SIToUnfold : SelectInsts) Stack.push_back(SIToUnfold); while (!Stack.empty()) { SelectInstToUnfold SIToUnfold = Stack.pop_back_val(); std::vector NewSIsToUnfold; std::vector NewBBs; unfold(&DTU, SIToUnfold, &NewSIsToUnfold, &NewBBs); // Put newly discovered select instructions into the work list. for (const SelectInstToUnfold &NewSIToUnfold : NewSIsToUnfold) Stack.push_back(NewSIToUnfold); } } AssumptionCache *AC; DominatorTree *DT; TargetTransformInfo *TTI; OptimizationRemarkEmitter *ORE; }; class DFAJumpThreadingLegacyPass : public FunctionPass { public: static char ID; // Pass identification DFAJumpThreadingLegacyPass() : FunctionPass(ID) {} void getAnalysisUsage(AnalysisUsage &AU) const override { AU.addRequired(); AU.addRequired(); AU.addPreserved(); AU.addRequired(); AU.addRequired(); } bool runOnFunction(Function &F) override { if (skipFunction(F)) return false; AssumptionCache *AC = &getAnalysis().getAssumptionCache(F); DominatorTree *DT = &getAnalysis().getDomTree(); TargetTransformInfo *TTI = &getAnalysis().getTTI(F); OptimizationRemarkEmitter *ORE = &getAnalysis().getORE(); return DFAJumpThreading(AC, DT, TTI, ORE).run(F); } }; } // end anonymous namespace char DFAJumpThreadingLegacyPass::ID = 0; INITIALIZE_PASS_BEGIN(DFAJumpThreadingLegacyPass, "dfa-jump-threading", "DFA Jump Threading", false, false) INITIALIZE_PASS_DEPENDENCY(AssumptionCacheTracker) INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass) INITIALIZE_PASS_DEPENDENCY(TargetTransformInfoWrapperPass) INITIALIZE_PASS_DEPENDENCY(OptimizationRemarkEmitterWrapperPass) INITIALIZE_PASS_END(DFAJumpThreadingLegacyPass, "dfa-jump-threading", "DFA Jump Threading", false, false) // Public interface to the DFA Jump Threading pass FunctionPass *llvm::createDFAJumpThreadingPass() { return new DFAJumpThreadingLegacyPass(); } namespace { /// Create a new basic block and sink \p SIToSink into it. void createBasicBlockAndSinkSelectInst( DomTreeUpdater *DTU, SelectInst *SI, PHINode *SIUse, SelectInst *SIToSink, BasicBlock *EndBlock, StringRef NewBBName, BasicBlock **NewBlock, BranchInst **NewBranch, std::vector *NewSIsToUnfold, std::vector *NewBBs) { assert(SIToSink->hasOneUse()); assert(NewBlock); assert(NewBranch); *NewBlock = BasicBlock::Create(SI->getContext(), NewBBName, EndBlock->getParent(), EndBlock); NewBBs->push_back(*NewBlock); *NewBranch = BranchInst::Create(EndBlock, *NewBlock); SIToSink->moveBefore(*NewBranch); NewSIsToUnfold->push_back(SelectInstToUnfold(SIToSink, SIUse)); DTU->applyUpdates({{DominatorTree::Insert, *NewBlock, EndBlock}}); } /// Unfold the select instruction held in \p SIToUnfold by replacing it with /// control flow. /// /// Put newly discovered select instructions into \p NewSIsToUnfold. Put newly /// created basic blocks into \p NewBBs. /// /// TODO: merge it with CodeGenPrepare::optimizeSelectInst() if possible. void unfold(DomTreeUpdater *DTU, SelectInstToUnfold SIToUnfold, std::vector *NewSIsToUnfold, std::vector *NewBBs) { SelectInst *SI = SIToUnfold.getInst(); PHINode *SIUse = SIToUnfold.getUse(); BasicBlock *StartBlock = SI->getParent(); BasicBlock *EndBlock = SIUse->getParent(); BranchInst *StartBlockTerm = dyn_cast(StartBlock->getTerminator()); assert(StartBlockTerm && StartBlockTerm->isUnconditional()); assert(SI->hasOneUse()); // These are the new basic blocks for the conditional branch. // At least one will become an actual new basic block. BasicBlock *TrueBlock = nullptr; BasicBlock *FalseBlock = nullptr; BranchInst *TrueBranch = nullptr; BranchInst *FalseBranch = nullptr; // Sink select instructions to be able to unfold them later. if (SelectInst *SIOp = dyn_cast(SI->getTrueValue())) { createBasicBlockAndSinkSelectInst(DTU, SI, SIUse, SIOp, EndBlock, "si.unfold.true", &TrueBlock, &TrueBranch, NewSIsToUnfold, NewBBs); } if (SelectInst *SIOp = dyn_cast(SI->getFalseValue())) { createBasicBlockAndSinkSelectInst(DTU, SI, SIUse, SIOp, EndBlock, "si.unfold.false", &FalseBlock, &FalseBranch, NewSIsToUnfold, NewBBs); } // If there was nothing to sink, then arbitrarily choose the 'false' side // for a new input value to the PHI. if (!TrueBlock && !FalseBlock) { FalseBlock = BasicBlock::Create(SI->getContext(), "si.unfold.false", EndBlock->getParent(), EndBlock); NewBBs->push_back(FalseBlock); BranchInst::Create(EndBlock, FalseBlock); DTU->applyUpdates({{DominatorTree::Insert, FalseBlock, EndBlock}}); } // Insert the real conditional branch based on the original condition. // If we did not create a new block for one of the 'true' or 'false' paths // of the condition, it means that side of the branch goes to the end block // directly and the path originates from the start block from the point of // view of the new PHI. BasicBlock *TT = EndBlock; BasicBlock *FT = EndBlock; if (TrueBlock && FalseBlock) { // A diamond. TT = TrueBlock; FT = FalseBlock; // Update the phi node of SI. SIUse->removeIncomingValue(StartBlock, /* DeletePHIIfEmpty = */ false); SIUse->addIncoming(SI->getTrueValue(), TrueBlock); SIUse->addIncoming(SI->getFalseValue(), FalseBlock); // Update any other PHI nodes in EndBlock. for (PHINode &Phi : EndBlock->phis()) { if (&Phi != SIUse) { Phi.addIncoming(Phi.getIncomingValueForBlock(StartBlock), TrueBlock); Phi.addIncoming(Phi.getIncomingValueForBlock(StartBlock), FalseBlock); } } } else { BasicBlock *NewBlock = nullptr; Value *SIOp1 = SI->getTrueValue(); Value *SIOp2 = SI->getFalseValue(); // A triangle pointing right. if (!TrueBlock) { NewBlock = FalseBlock; FT = FalseBlock; } // A triangle pointing left. else { NewBlock = TrueBlock; TT = TrueBlock; std::swap(SIOp1, SIOp2); } // Update the phi node of SI. for (unsigned Idx = 0; Idx < SIUse->getNumIncomingValues(); ++Idx) { if (SIUse->getIncomingBlock(Idx) == StartBlock) SIUse->setIncomingValue(Idx, SIOp1); } SIUse->addIncoming(SIOp2, NewBlock); // Update any other PHI nodes in EndBlock. for (auto II = EndBlock->begin(); PHINode *Phi = dyn_cast(II); ++II) { if (Phi != SIUse) Phi->addIncoming(Phi->getIncomingValueForBlock(StartBlock), NewBlock); } } StartBlockTerm->eraseFromParent(); BranchInst::Create(TT, FT, SI->getCondition(), StartBlock); DTU->applyUpdates({{DominatorTree::Insert, StartBlock, TT}, {DominatorTree::Insert, StartBlock, FT}}); // The select is now dead. SI->eraseFromParent(); } struct ClonedBlock { BasicBlock *BB; uint64_t State; ///< \p State corresponds to the next value of a switch stmnt. }; typedef std::deque PathType; typedef std::vector PathsType; typedef SmallPtrSet VisitedBlocks; typedef std::vector CloneList; // This data structure keeps track of all blocks that have been cloned. If two // different ThreadingPaths clone the same block for a certain state it should // be reused, and it can be looked up in this map. typedef DenseMap DuplicateBlockMap; // This map keeps track of all the new definitions for an instruction. This // information is needed when restoring SSA form after cloning blocks. typedef MapVector> DefMap; inline raw_ostream &operator<<(raw_ostream &OS, const PathType &Path) { OS << "< "; for (const BasicBlock *BB : Path) { std::string BBName; if (BB->hasName()) raw_string_ostream(BBName) << BB->getName(); else raw_string_ostream(BBName) << BB; OS << BBName << " "; } OS << ">"; return OS; } /// ThreadingPath is a path in the control flow of a loop that can be threaded /// by cloning necessary basic blocks and replacing conditional branches with /// unconditional ones. A threading path includes a list of basic blocks, the /// exit state, and the block that determines the next state. struct ThreadingPath { /// Exit value is DFA's exit state for the given path. uint64_t getExitValue() const { return ExitVal; } void setExitValue(const ConstantInt *V) { ExitVal = V->getZExtValue(); IsExitValSet = true; } bool isExitValueSet() const { return IsExitValSet; } /// Determinator is the basic block that determines the next state of the DFA. const BasicBlock *getDeterminatorBB() const { return DBB; } void setDeterminator(const BasicBlock *BB) { DBB = BB; } /// Path is a list of basic blocks. const PathType &getPath() const { return Path; } void setPath(const PathType &NewPath) { Path = NewPath; } void print(raw_ostream &OS) const { OS << Path << " [ " << ExitVal << ", " << DBB->getName() << " ]"; } private: PathType Path; uint64_t ExitVal; const BasicBlock *DBB = nullptr; bool IsExitValSet = false; }; #ifndef NDEBUG inline raw_ostream &operator<<(raw_ostream &OS, const ThreadingPath &TPath) { TPath.print(OS); return OS; } #endif struct MainSwitch { MainSwitch(SwitchInst *SI, OptimizationRemarkEmitter *ORE) { if (isPredictable(SI)) { Instr = SI; } else { ORE->emit([&]() { return OptimizationRemarkMissed(DEBUG_TYPE, "SwitchNotPredictable", SI) << "Switch instruction is not predictable."; }); } } virtual ~MainSwitch() = default; SwitchInst *getInstr() const { return Instr; } const SmallVector getSelectInsts() { return SelectInsts; } private: /// Do a use-def chain traversal. Make sure the value of the switch variable /// is always a known constant. This means that all conditional jumps based on /// switch variable can be converted to unconditional jumps. bool isPredictable(const SwitchInst *SI) { std::deque Q; SmallSet SeenValues; SelectInsts.clear(); Value *FirstDef = SI->getOperand(0); auto *Inst = dyn_cast(FirstDef); // If this is a function argument or another non-instruction, then give up. // We are interested in loop local variables. if (!Inst) return false; // Require the first definition to be a PHINode if (!isa(Inst)) return false; LLVM_DEBUG(dbgs() << "\tisPredictable() FirstDef: " << *Inst << "\n"); Q.push_back(Inst); SeenValues.insert(FirstDef); while (!Q.empty()) { Instruction *Current = Q.front(); Q.pop_front(); if (auto *Phi = dyn_cast(Current)) { for (Value *Incoming : Phi->incoming_values()) { if (!isPredictableValue(Incoming, SeenValues)) return false; addInstToQueue(Incoming, Q, SeenValues); } LLVM_DEBUG(dbgs() << "\tisPredictable() phi: " << *Phi << "\n"); } else if (SelectInst *SelI = dyn_cast(Current)) { if (!isValidSelectInst(SelI)) return false; if (!isPredictableValue(SelI->getTrueValue(), SeenValues) || !isPredictableValue(SelI->getFalseValue(), SeenValues)) { return false; } addInstToQueue(SelI->getTrueValue(), Q, SeenValues); addInstToQueue(SelI->getFalseValue(), Q, SeenValues); LLVM_DEBUG(dbgs() << "\tisPredictable() select: " << *SelI << "\n"); if (auto *SelIUse = dyn_cast(SelI->user_back())) SelectInsts.push_back(SelectInstToUnfold(SelI, SelIUse)); } else { // If it is neither a phi nor a select, then we give up. return false; } } return true; } bool isPredictableValue(Value *InpVal, SmallSet &SeenValues) { if (SeenValues.contains(InpVal)) return true; if (isa(InpVal)) return true; // If this is a function argument or another non-instruction, then give up. if (!isa(InpVal)) return false; return true; } void addInstToQueue(Value *Val, std::deque &Q, SmallSet &SeenValues) { if (SeenValues.contains(Val)) return; if (Instruction *I = dyn_cast(Val)) Q.push_back(I); SeenValues.insert(Val); } bool isValidSelectInst(SelectInst *SI) { if (!SI->hasOneUse()) return false; Instruction *SIUse = dyn_cast(SI->user_back()); // The use of the select inst should be either a phi or another select. if (!SIUse && !(isa(SIUse) || isa(SIUse))) return false; BasicBlock *SIBB = SI->getParent(); // Currently, we can only expand select instructions in basic blocks with // one successor. BranchInst *SITerm = dyn_cast(SIBB->getTerminator()); if (!SITerm || !SITerm->isUnconditional()) return false; if (isa(SIUse) && SIBB->getSingleSuccessor() != cast(SIUse)->getParent()) return false; // If select will not be sunk during unfolding, and it is in the same basic // block as another state defining select, then cannot unfold both. for (SelectInstToUnfold SIToUnfold : SelectInsts) { SelectInst *PrevSI = SIToUnfold.getInst(); if (PrevSI->getTrueValue() != SI && PrevSI->getFalseValue() != SI && PrevSI->getParent() == SI->getParent()) return false; } return true; } SwitchInst *Instr = nullptr; SmallVector SelectInsts; }; struct AllSwitchPaths { AllSwitchPaths(const MainSwitch *MSwitch, OptimizationRemarkEmitter *ORE) : Switch(MSwitch->getInstr()), SwitchBlock(Switch->getParent()), ORE(ORE) {} std::vector &getThreadingPaths() { return TPaths; } unsigned getNumThreadingPaths() { return TPaths.size(); } SwitchInst *getSwitchInst() { return Switch; } BasicBlock *getSwitchBlock() { return SwitchBlock; } void run() { VisitedBlocks Visited; PathsType LoopPaths = paths(SwitchBlock, Visited, /* PathDepth = */ 1); StateDefMap StateDef = getStateDefMap(); for (PathType Path : LoopPaths) { ThreadingPath TPath; const BasicBlock *PrevBB = Path.back(); for (const BasicBlock *BB : Path) { if (StateDef.count(BB) != 0) { const PHINode *Phi = dyn_cast(StateDef[BB]); assert(Phi && "Expected a state-defining instr to be a phi node."); const Value *V = Phi->getIncomingValueForBlock(PrevBB); if (const ConstantInt *C = dyn_cast(V)) { TPath.setExitValue(C); TPath.setDeterminator(BB); TPath.setPath(Path); } } // Switch block is the determinator, this is the final exit value. if (TPath.isExitValueSet() && BB == Path.front()) break; PrevBB = BB; } if (TPath.isExitValueSet() && isSupported(TPath)) TPaths.push_back(TPath); } } private: // Value: an instruction that defines a switch state; // Key: the parent basic block of that instruction. typedef DenseMap StateDefMap; PathsType paths(BasicBlock *BB, VisitedBlocks &Visited, unsigned PathDepth) const { PathsType Res; // Stop exploring paths after visiting MaxPathLength blocks if (PathDepth > MaxPathLength) { ORE->emit([&]() { return OptimizationRemarkAnalysis(DEBUG_TYPE, "MaxPathLengthReached", Switch) << "Exploration stopped after visiting MaxPathLength=" << ore::NV("MaxPathLength", MaxPathLength) << " blocks."; }); return Res; } Visited.insert(BB); // Some blocks have multiple edges to the same successor, and this set // is used to prevent a duplicate path from being generated SmallSet Successors; for (BasicBlock *Succ : successors(BB)) { if (!Successors.insert(Succ).second) continue; // Found a cycle through the SwitchBlock if (Succ == SwitchBlock) { Res.push_back({BB}); continue; } // We have encountered a cycle, do not get caught in it if (Visited.contains(Succ)) continue; PathsType SuccPaths = paths(Succ, Visited, PathDepth + 1); for (PathType Path : SuccPaths) { PathType NewPath(Path); NewPath.push_front(BB); Res.push_back(NewPath); } } // This block could now be visited again from a different predecessor. Note // that this will result in exponential runtime. Subpaths could possibly be // cached but it takes a lot of memory to store them. Visited.erase(BB); return Res; } /// Walk the use-def chain and collect all the state-defining instructions. StateDefMap getStateDefMap() const { StateDefMap Res; Value *FirstDef = Switch->getOperand(0); assert(isa(FirstDef) && "After select unfolding, all state " "definitions are expected to be phi " "nodes."); SmallVector Stack; Stack.push_back(dyn_cast(FirstDef)); SmallSet SeenValues; while (!Stack.empty()) { PHINode *CurPhi = Stack.pop_back_val(); Res[CurPhi->getParent()] = CurPhi; SeenValues.insert(CurPhi); for (Value *Incoming : CurPhi->incoming_values()) { if (Incoming == FirstDef || isa(Incoming) || SeenValues.contains(Incoming)) { continue; } assert(isa(Incoming) && "After select unfolding, all state " "definitions are expected to be phi " "nodes."); Stack.push_back(cast(Incoming)); } } return Res; } /// The determinator BB should precede the switch-defining BB. /// /// Otherwise, it is possible that the state defined in the determinator block /// defines the state for the next iteration of the loop, rather than for the /// current one. /// /// Currently supported paths: /// \code /// < switch bb1 determ def > [ 42, determ ] /// < switch_and_def bb1 determ > [ 42, determ ] /// < switch_and_def_and_determ bb1 > [ 42, switch_and_def_and_determ ] /// \endcode /// /// Unsupported paths: /// \code /// < switch bb1 def determ > [ 43, determ ] /// < switch_and_determ bb1 def > [ 43, switch_and_determ ] /// \endcode bool isSupported(const ThreadingPath &TPath) { Instruction *SwitchCondI = dyn_cast(Switch->getCondition()); assert(SwitchCondI); if (!SwitchCondI) return false; const BasicBlock *SwitchCondDefBB = SwitchCondI->getParent(); const BasicBlock *SwitchCondUseBB = Switch->getParent(); const BasicBlock *DeterminatorBB = TPath.getDeterminatorBB(); assert( SwitchCondUseBB == TPath.getPath().front() && "The first BB in a threading path should have the switch instruction"); if (SwitchCondUseBB != TPath.getPath().front()) return false; // Make DeterminatorBB the first element in Path. PathType Path = TPath.getPath(); auto ItDet = std::find(Path.begin(), Path.end(), DeterminatorBB); std::rotate(Path.begin(), ItDet, Path.end()); bool IsDetBBSeen = false; bool IsDefBBSeen = false; bool IsUseBBSeen = false; for (BasicBlock *BB : Path) { if (BB == DeterminatorBB) IsDetBBSeen = true; if (BB == SwitchCondDefBB) IsDefBBSeen = true; if (BB == SwitchCondUseBB) IsUseBBSeen = true; if (IsDetBBSeen && IsUseBBSeen && !IsDefBBSeen) return false; } return true; } SwitchInst *Switch; BasicBlock *SwitchBlock; OptimizationRemarkEmitter *ORE; std::vector TPaths; }; struct TransformDFA { TransformDFA(AllSwitchPaths *SwitchPaths, DominatorTree *DT, AssumptionCache *AC, TargetTransformInfo *TTI, OptimizationRemarkEmitter *ORE, SmallPtrSet EphValues) : SwitchPaths(SwitchPaths), DT(DT), AC(AC), TTI(TTI), ORE(ORE), EphValues(EphValues) {} void run() { if (isLegalAndProfitableToTransform()) { createAllExitPaths(); NumTransforms++; } } private: /// This function performs both a legality check and profitability check at /// the same time since it is convenient to do so. It iterates through all /// blocks that will be cloned, and keeps track of the duplication cost. It /// also returns false if it is illegal to clone some required block. bool isLegalAndProfitableToTransform() { CodeMetrics Metrics; SwitchInst *Switch = SwitchPaths->getSwitchInst(); // Note that DuplicateBlockMap is not being used as intended here. It is // just being used to ensure (BB, State) pairs are only counted once. DuplicateBlockMap DuplicateMap; for (ThreadingPath &TPath : SwitchPaths->getThreadingPaths()) { PathType PathBBs = TPath.getPath(); uint64_t NextState = TPath.getExitValue(); const BasicBlock *Determinator = TPath.getDeterminatorBB(); // Update Metrics for the Switch block, this is always cloned BasicBlock *BB = SwitchPaths->getSwitchBlock(); BasicBlock *VisitedBB = getClonedBB(BB, NextState, DuplicateMap); if (!VisitedBB) { Metrics.analyzeBasicBlock(BB, *TTI, EphValues); DuplicateMap[BB].push_back({BB, NextState}); } // If the Switch block is the Determinator, then we can continue since // this is the only block that is cloned and we already counted for it. if (PathBBs.front() == Determinator) continue; // Otherwise update Metrics for all blocks that will be cloned. If any // block is already cloned and would be reused, don't double count it. auto DetIt = std::find(PathBBs.begin(), PathBBs.end(), Determinator); for (auto BBIt = DetIt; BBIt != PathBBs.end(); BBIt++) { BB = *BBIt; VisitedBB = getClonedBB(BB, NextState, DuplicateMap); if (VisitedBB) continue; Metrics.analyzeBasicBlock(BB, *TTI, EphValues); DuplicateMap[BB].push_back({BB, NextState}); } if (Metrics.notDuplicatable) { LLVM_DEBUG(dbgs() << "DFA Jump Threading: Not jump threading, contains " << "non-duplicatable instructions.\n"); ORE->emit([&]() { return OptimizationRemarkMissed(DEBUG_TYPE, "NonDuplicatableInst", Switch) << "Contains non-duplicatable instructions."; }); return false; } if (Metrics.convergent) { LLVM_DEBUG(dbgs() << "DFA Jump Threading: Not jump threading, contains " << "convergent instructions.\n"); ORE->emit([&]() { return OptimizationRemarkMissed(DEBUG_TYPE, "ConvergentInst", Switch) << "Contains convergent instructions."; }); return false; } } unsigned DuplicationCost = 0; unsigned JumpTableSize = 0; TTI->getEstimatedNumberOfCaseClusters(*Switch, JumpTableSize, nullptr, nullptr); if (JumpTableSize == 0) { // Factor in the number of conditional branches reduced from jump // threading. Assume that lowering the switch block is implemented by // using binary search, hence the LogBase2(). unsigned CondBranches = APInt(32, Switch->getNumSuccessors()).ceilLogBase2(); DuplicationCost = Metrics.NumInsts / CondBranches; } else { // Compared with jump tables, the DFA optimizer removes an indirect branch // on each loop iteration, thus making branch prediction more precise. The // more branch targets there are, the more likely it is for the branch // predictor to make a mistake, and the more benefit there is in the DFA // optimizer. Thus, the more branch targets there are, the lower is the // cost of the DFA opt. DuplicationCost = Metrics.NumInsts / JumpTableSize; } LLVM_DEBUG(dbgs() << "\nDFA Jump Threading: Cost to jump thread block " << SwitchPaths->getSwitchBlock()->getName() << " is: " << DuplicationCost << "\n\n"); if (DuplicationCost > CostThreshold) { LLVM_DEBUG(dbgs() << "Not jump threading, duplication cost exceeds the " << "cost threshold.\n"); ORE->emit([&]() { return OptimizationRemarkMissed(DEBUG_TYPE, "NotProfitable", Switch) << "Duplication cost exceeds the cost threshold (cost=" << ore::NV("Cost", DuplicationCost) << ", threshold=" << ore::NV("Threshold", CostThreshold) << ")."; }); return false; } ORE->emit([&]() { return OptimizationRemark(DEBUG_TYPE, "JumpThreaded", Switch) << "Switch statement jump-threaded."; }); return true; } /// Transform each threading path to effectively jump thread the DFA. void createAllExitPaths() { DomTreeUpdater DTU(*DT, DomTreeUpdater::UpdateStrategy::Eager); // Move the switch block to the end of the path, since it will be duplicated BasicBlock *SwitchBlock = SwitchPaths->getSwitchBlock(); for (ThreadingPath &TPath : SwitchPaths->getThreadingPaths()) { LLVM_DEBUG(dbgs() << TPath << "\n"); PathType NewPath(TPath.getPath()); NewPath.push_back(SwitchBlock); TPath.setPath(NewPath); } // Transform the ThreadingPaths and keep track of the cloned values DuplicateBlockMap DuplicateMap; DefMap NewDefs; SmallSet BlocksToClean; for (BasicBlock *BB : successors(SwitchBlock)) BlocksToClean.insert(BB); for (ThreadingPath &TPath : SwitchPaths->getThreadingPaths()) { createExitPath(NewDefs, TPath, DuplicateMap, BlocksToClean, &DTU); NumPaths++; } // After all paths are cloned, now update the last successor of the cloned // path so it skips over the switch statement for (ThreadingPath &TPath : SwitchPaths->getThreadingPaths()) updateLastSuccessor(TPath, DuplicateMap, &DTU); // For each instruction that was cloned and used outside, update its uses updateSSA(NewDefs); // Clean PHI Nodes for the newly created blocks for (BasicBlock *BB : BlocksToClean) cleanPhiNodes(BB); } /// For a specific ThreadingPath \p Path, create an exit path starting from /// the determinator block. /// /// To remember the correct destination, we have to duplicate blocks /// corresponding to each state. Also update the terminating instruction of /// the predecessors, and phis in the successor blocks. void createExitPath(DefMap &NewDefs, ThreadingPath &Path, DuplicateBlockMap &DuplicateMap, SmallSet &BlocksToClean, DomTreeUpdater *DTU) { uint64_t NextState = Path.getExitValue(); const BasicBlock *Determinator = Path.getDeterminatorBB(); PathType PathBBs = Path.getPath(); // Don't select the placeholder block in front if (PathBBs.front() == Determinator) PathBBs.pop_front(); auto DetIt = std::find(PathBBs.begin(), PathBBs.end(), Determinator); auto Prev = std::prev(DetIt); BasicBlock *PrevBB = *Prev; for (auto BBIt = DetIt; BBIt != PathBBs.end(); BBIt++) { BasicBlock *BB = *BBIt; BlocksToClean.insert(BB); // We already cloned BB for this NextState, now just update the branch // and continue. BasicBlock *NextBB = getClonedBB(BB, NextState, DuplicateMap); if (NextBB) { updatePredecessor(PrevBB, BB, NextBB, DTU); PrevBB = NextBB; continue; } // Clone the BB and update the successor of Prev to jump to the new block BasicBlock *NewBB = cloneBlockAndUpdatePredecessor( BB, PrevBB, NextState, DuplicateMap, NewDefs, DTU); DuplicateMap[BB].push_back({NewBB, NextState}); BlocksToClean.insert(NewBB); PrevBB = NewBB; } } /// Restore SSA form after cloning blocks. /// /// Each cloned block creates new defs for a variable, and the uses need to be /// updated to reflect this. The uses may be replaced with a cloned value, or /// some derived phi instruction. Note that all uses of a value defined in the /// same block were already remapped when cloning the block. void updateSSA(DefMap &NewDefs) { SSAUpdaterBulk SSAUpdate; SmallVector UsesToRename; for (auto KV : NewDefs) { Instruction *I = KV.first; BasicBlock *BB = I->getParent(); std::vector Cloned = KV.second; // Scan all uses of this instruction to see if it is used outside of its // block, and if so, record them in UsesToRename. for (Use &U : I->uses()) { Instruction *User = cast(U.getUser()); if (PHINode *UserPN = dyn_cast(User)) { if (UserPN->getIncomingBlock(U) == BB) continue; } else if (User->getParent() == BB) { continue; } UsesToRename.push_back(&U); } // If there are no uses outside the block, we're done with this // instruction. if (UsesToRename.empty()) continue; LLVM_DEBUG(dbgs() << "DFA-JT: Renaming non-local uses of: " << *I << "\n"); // We found a use of I outside of BB. Rename all uses of I that are // outside its block to be uses of the appropriate PHI node etc. See // ValuesInBlocks with the values we know. unsigned VarNum = SSAUpdate.AddVariable(I->getName(), I->getType()); SSAUpdate.AddAvailableValue(VarNum, BB, I); for (Instruction *New : Cloned) SSAUpdate.AddAvailableValue(VarNum, New->getParent(), New); while (!UsesToRename.empty()) SSAUpdate.AddUse(VarNum, UsesToRename.pop_back_val()); LLVM_DEBUG(dbgs() << "\n"); } // SSAUpdater handles phi placement and renaming uses with the appropriate // value. SSAUpdate.RewriteAllUses(DT); } /// Clones a basic block, and adds it to the CFG. /// /// This function also includes updating phi nodes in the successors of the /// BB, and remapping uses that were defined locally in the cloned BB. BasicBlock *cloneBlockAndUpdatePredecessor(BasicBlock *BB, BasicBlock *PrevBB, uint64_t NextState, DuplicateBlockMap &DuplicateMap, DefMap &NewDefs, DomTreeUpdater *DTU) { ValueToValueMapTy VMap; BasicBlock *NewBB = CloneBasicBlock( BB, VMap, ".jt" + std::to_string(NextState), BB->getParent()); NewBB->moveAfter(BB); NumCloned++; for (Instruction &I : *NewBB) { // Do not remap operands of PHINode in case a definition in BB is an // incoming value to a phi in the same block. This incoming value will // be renamed later while restoring SSA. if (isa(&I)) continue; RemapInstruction(&I, VMap, RF_IgnoreMissingLocals | RF_NoModuleLevelChanges); if (AssumeInst *II = dyn_cast(&I)) AC->registerAssumption(II); } updateSuccessorPhis(BB, NewBB, NextState, VMap, DuplicateMap); updatePredecessor(PrevBB, BB, NewBB, DTU); updateDefMap(NewDefs, VMap); // Add all successors to the DominatorTree SmallPtrSet SuccSet; for (auto *SuccBB : successors(NewBB)) { if (SuccSet.insert(SuccBB).second) DTU->applyUpdates({{DominatorTree::Insert, NewBB, SuccBB}}); } SuccSet.clear(); return NewBB; } /// Update the phi nodes in BB's successors. /// /// This means creating a new incoming value from NewBB with the new /// instruction wherever there is an incoming value from BB. void updateSuccessorPhis(BasicBlock *BB, BasicBlock *ClonedBB, uint64_t NextState, ValueToValueMapTy &VMap, DuplicateBlockMap &DuplicateMap) { std::vector BlocksToUpdate; // If BB is the last block in the path, we can simply update the one case // successor that will be reached. if (BB == SwitchPaths->getSwitchBlock()) { SwitchInst *Switch = SwitchPaths->getSwitchInst(); BasicBlock *NextCase = getNextCaseSuccessor(Switch, NextState); BlocksToUpdate.push_back(NextCase); BasicBlock *ClonedSucc = getClonedBB(NextCase, NextState, DuplicateMap); if (ClonedSucc) BlocksToUpdate.push_back(ClonedSucc); } // Otherwise update phis in all successors. else { for (BasicBlock *Succ : successors(BB)) { BlocksToUpdate.push_back(Succ); // Check if a successor has already been cloned for the particular exit // value. In this case if a successor was already cloned, the phi nodes // in the cloned block should be updated directly. BasicBlock *ClonedSucc = getClonedBB(Succ, NextState, DuplicateMap); if (ClonedSucc) BlocksToUpdate.push_back(ClonedSucc); } } // If there is a phi with an incoming value from BB, create a new incoming // value for the new predecessor ClonedBB. The value will either be the same // value from BB or a cloned value. for (BasicBlock *Succ : BlocksToUpdate) { for (auto II = Succ->begin(); PHINode *Phi = dyn_cast(II); ++II) { Value *Incoming = Phi->getIncomingValueForBlock(BB); if (Incoming) { if (isa(Incoming)) { Phi->addIncoming(Incoming, ClonedBB); continue; } Value *ClonedVal = VMap[Incoming]; if (ClonedVal) Phi->addIncoming(ClonedVal, ClonedBB); else Phi->addIncoming(Incoming, ClonedBB); } } } } /// Sets the successor of PrevBB to be NewBB instead of OldBB. Note that all /// other successors are kept as well. void updatePredecessor(BasicBlock *PrevBB, BasicBlock *OldBB, BasicBlock *NewBB, DomTreeUpdater *DTU) { // When a path is reused, there is a chance that predecessors were already // updated before. Check if the predecessor needs to be updated first. if (!isPredecessor(OldBB, PrevBB)) return; Instruction *PrevTerm = PrevBB->getTerminator(); for (unsigned Idx = 0; Idx < PrevTerm->getNumSuccessors(); Idx++) { if (PrevTerm->getSuccessor(Idx) == OldBB) { OldBB->removePredecessor(PrevBB, /* KeepOneInputPHIs = */ true); PrevTerm->setSuccessor(Idx, NewBB); } } DTU->applyUpdates({{DominatorTree::Delete, PrevBB, OldBB}, {DominatorTree::Insert, PrevBB, NewBB}}); } /// Add new value mappings to the DefMap to keep track of all new definitions /// for a particular instruction. These will be used while updating SSA form. void updateDefMap(DefMap &NewDefs, ValueToValueMapTy &VMap) { SmallVector> NewDefsVector; NewDefsVector.reserve(VMap.size()); for (auto Entry : VMap) { Instruction *Inst = dyn_cast(const_cast(Entry.first)); if (!Inst || !Entry.second || isa(Inst) || isa(Inst)) { continue; } Instruction *Cloned = dyn_cast(Entry.second); if (!Cloned) continue; NewDefsVector.push_back({Inst, Cloned}); } // Sort the defs to get deterministic insertion order into NewDefs. sort(NewDefsVector, [](const auto &LHS, const auto &RHS) { if (LHS.first == RHS.first) return LHS.second->comesBefore(RHS.second); return LHS.first->comesBefore(RHS.first); }); for (const auto &KV : NewDefsVector) NewDefs[KV.first].push_back(KV.second); } /// Update the last branch of a particular cloned path to point to the correct /// case successor. /// /// Note that this is an optional step and would have been done in later /// optimizations, but it makes the CFG significantly easier to work with. void updateLastSuccessor(ThreadingPath &TPath, DuplicateBlockMap &DuplicateMap, DomTreeUpdater *DTU) { uint64_t NextState = TPath.getExitValue(); BasicBlock *BB = TPath.getPath().back(); BasicBlock *LastBlock = getClonedBB(BB, NextState, DuplicateMap); // Note multiple paths can end at the same block so check that it is not // updated yet if (!isa(LastBlock->getTerminator())) return; SwitchInst *Switch = cast(LastBlock->getTerminator()); BasicBlock *NextCase = getNextCaseSuccessor(Switch, NextState); std::vector DTUpdates; SmallPtrSet SuccSet; for (BasicBlock *Succ : successors(LastBlock)) { if (Succ != NextCase && SuccSet.insert(Succ).second) DTUpdates.push_back({DominatorTree::Delete, LastBlock, Succ}); } Switch->eraseFromParent(); BranchInst::Create(NextCase, LastBlock); DTU->applyUpdates(DTUpdates); } /// After cloning blocks, some of the phi nodes have extra incoming values /// that are no longer used. This function removes them. void cleanPhiNodes(BasicBlock *BB) { // If BB is no longer reachable, remove any remaining phi nodes if (pred_empty(BB)) { std::vector PhiToRemove; for (auto II = BB->begin(); PHINode *Phi = dyn_cast(II); ++II) { PhiToRemove.push_back(Phi); } for (PHINode *PN : PhiToRemove) { PN->replaceAllUsesWith(UndefValue::get(PN->getType())); PN->eraseFromParent(); } return; } // Remove any incoming values that come from an invalid predecessor for (auto II = BB->begin(); PHINode *Phi = dyn_cast(II); ++II) { std::vector BlocksToRemove; for (BasicBlock *IncomingBB : Phi->blocks()) { if (!isPredecessor(BB, IncomingBB)) BlocksToRemove.push_back(IncomingBB); } for (BasicBlock *BB : BlocksToRemove) Phi->removeIncomingValue(BB); } } /// Checks if BB was already cloned for a particular next state value. If it /// was then it returns this cloned block, and otherwise null. BasicBlock *getClonedBB(BasicBlock *BB, uint64_t NextState, DuplicateBlockMap &DuplicateMap) { CloneList ClonedBBs = DuplicateMap[BB]; // Find an entry in the CloneList with this NextState. If it exists then // return the corresponding BB auto It = llvm::find_if(ClonedBBs, [NextState](const ClonedBlock &C) { return C.State == NextState; }); return It != ClonedBBs.end() ? (*It).BB : nullptr; } /// Helper to get the successor corresponding to a particular case value for /// a switch statement. BasicBlock *getNextCaseSuccessor(SwitchInst *Switch, uint64_t NextState) { BasicBlock *NextCase = nullptr; for (auto Case : Switch->cases()) { if (Case.getCaseValue()->getZExtValue() == NextState) { NextCase = Case.getCaseSuccessor(); break; } } if (!NextCase) NextCase = Switch->getDefaultDest(); return NextCase; } /// Returns true if IncomingBB is a predecessor of BB. bool isPredecessor(BasicBlock *BB, BasicBlock *IncomingBB) { return llvm::find(predecessors(BB), IncomingBB) != pred_end(BB); } AllSwitchPaths *SwitchPaths; DominatorTree *DT; AssumptionCache *AC; TargetTransformInfo *TTI; OptimizationRemarkEmitter *ORE; SmallPtrSet EphValues; std::vector TPaths; }; bool DFAJumpThreading::run(Function &F) { LLVM_DEBUG(dbgs() << "\nDFA Jump threading: " << F.getName() << "\n"); if (F.hasOptSize()) { LLVM_DEBUG(dbgs() << "Skipping due to the 'minsize' attribute\n"); return false; } if (ClViewCfgBefore) F.viewCFG(); SmallVector ThreadableLoops; bool MadeChanges = false; for (BasicBlock &BB : F) { auto *SI = dyn_cast(BB.getTerminator()); if (!SI) continue; LLVM_DEBUG(dbgs() << "\nCheck if SwitchInst in BB " << BB.getName() << " is predictable\n"); MainSwitch Switch(SI, ORE); if (!Switch.getInstr()) continue; LLVM_DEBUG(dbgs() << "\nSwitchInst in BB " << BB.getName() << " is a " << "candidate for jump threading\n"); LLVM_DEBUG(SI->dump()); unfoldSelectInstrs(DT, Switch.getSelectInsts()); if (!Switch.getSelectInsts().empty()) MadeChanges = true; AllSwitchPaths SwitchPaths(&Switch, ORE); SwitchPaths.run(); if (SwitchPaths.getNumThreadingPaths() > 0) { ThreadableLoops.push_back(SwitchPaths); // For the time being limit this optimization to occurring once in a // function since it can change the CFG significantly. This is not a // strict requirement but it can cause buggy behavior if there is an // overlap of blocks in different opportunities. There is a lot of room to // experiment with catching more opportunities here. break; } } SmallPtrSet EphValues; if (ThreadableLoops.size() > 0) CodeMetrics::collectEphemeralValues(&F, AC, EphValues); for (AllSwitchPaths SwitchPaths : ThreadableLoops) { TransformDFA Transform(&SwitchPaths, DT, AC, TTI, ORE, EphValues); Transform.run(); MadeChanges = true; } #ifdef EXPENSIVE_CHECKS assert(DT->verify(DominatorTree::VerificationLevel::Full)); verifyFunction(F, &dbgs()); #endif return MadeChanges; } } // end anonymous namespace /// Integrate with the new Pass Manager PreservedAnalyses DFAJumpThreadingPass::run(Function &F, FunctionAnalysisManager &AM) { AssumptionCache &AC = AM.getResult(F); DominatorTree &DT = AM.getResult(F); TargetTransformInfo &TTI = AM.getResult(F); OptimizationRemarkEmitter ORE(&F); if (!DFAJumpThreading(&AC, &DT, &TTI, &ORE).run(F)) return PreservedAnalyses::all(); PreservedAnalyses PA; PA.preserve(); return PA; }