//===- NewGVN.cpp - Global Value Numbering Pass ---------------------------===// // // 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 new LLVM's Global Value Numbering pass. /// GVN partitions values computed by a function into congruence classes. /// Values ending up in the same congruence class are guaranteed to be the same /// for every execution of the program. In that respect, congruency is a /// compile-time approximation of equivalence of values at runtime. /// The algorithm implemented here uses a sparse formulation and it's based /// on the ideas described in the paper: /// "A Sparse Algorithm for Predicated Global Value Numbering" from /// Karthik Gargi. /// /// A brief overview of the algorithm: The algorithm is essentially the same as /// the standard RPO value numbering algorithm (a good reference is the paper /// "SCC based value numbering" by L. Taylor Simpson) with one major difference: /// The RPO algorithm proceeds, on every iteration, to process every reachable /// block and every instruction in that block. This is because the standard RPO /// algorithm does not track what things have the same value number, it only /// tracks what the value number of a given operation is (the mapping is /// operation -> value number). Thus, when a value number of an operation /// changes, it must reprocess everything to ensure all uses of a value number /// get updated properly. In constrast, the sparse algorithm we use *also* /// tracks what operations have a given value number (IE it also tracks the /// reverse mapping from value number -> operations with that value number), so /// that it only needs to reprocess the instructions that are affected when /// something's value number changes. The vast majority of complexity and code /// in this file is devoted to tracking what value numbers could change for what /// instructions when various things happen. The rest of the algorithm is /// devoted to performing symbolic evaluation, forward propagation, and /// simplification of operations based on the value numbers deduced so far /// /// In order to make the GVN mostly-complete, we use a technique derived from /// "Detection of Redundant Expressions: A Complete and Polynomial-time /// Algorithm in SSA" by R.R. Pai. The source of incompleteness in most SSA /// based GVN algorithms is related to their inability to detect equivalence /// between phi of ops (IE phi(a+b, c+d)) and op of phis (phi(a,c) + phi(b, d)). /// We resolve this issue by generating the equivalent "phi of ops" form for /// each op of phis we see, in a way that only takes polynomial time to resolve. /// /// We also do not perform elimination by using any published algorithm. All /// published algorithms are O(Instructions). Instead, we use a technique that /// is O(number of operations with the same value number), enabling us to skip /// trying to eliminate things that have unique value numbers. // //===----------------------------------------------------------------------===// #include "llvm/Transforms/Scalar/NewGVN.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/BitVector.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/DenseMapInfo.h" #include "llvm/ADT/DenseSet.h" #include "llvm/ADT/DepthFirstIterator.h" #include "llvm/ADT/GraphTraits.h" #include "llvm/ADT/Hashing.h" #include "llvm/ADT/PointerIntPair.h" #include "llvm/ADT/PostOrderIterator.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/SparseBitVector.h" #include "llvm/ADT/Statistic.h" #include "llvm/ADT/iterator_range.h" #include "llvm/Analysis/AliasAnalysis.h" #include "llvm/Analysis/AssumptionCache.h" #include "llvm/Analysis/CFGPrinter.h" #include "llvm/Analysis/ConstantFolding.h" #include "llvm/Analysis/GlobalsModRef.h" #include "llvm/Analysis/InstructionSimplify.h" #include "llvm/Analysis/MemoryBuiltins.h" #include "llvm/Analysis/MemorySSA.h" #include "llvm/Analysis/TargetLibraryInfo.h" #include "llvm/IR/Argument.h" #include "llvm/IR/BasicBlock.h" #include "llvm/IR/Constant.h" #include "llvm/IR/Constants.h" #include "llvm/IR/Dominators.h" #include "llvm/IR/Function.h" #include "llvm/IR/InstrTypes.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/Instructions.h" #include "llvm/IR/IntrinsicInst.h" #include "llvm/IR/Intrinsics.h" #include "llvm/IR/LLVMContext.h" #include "llvm/IR/PatternMatch.h" #include "llvm/IR/Type.h" #include "llvm/IR/Use.h" #include "llvm/IR/User.h" #include "llvm/IR/Value.h" #include "llvm/InitializePasses.h" #include "llvm/Pass.h" #include "llvm/Support/Allocator.h" #include "llvm/Support/ArrayRecycler.h" #include "llvm/Support/Casting.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Support/DebugCounter.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/PointerLikeTypeTraits.h" #include "llvm/Support/raw_ostream.h" #include "llvm/Transforms/Scalar.h" #include "llvm/Transforms/Scalar/GVNExpression.h" #include "llvm/Transforms/Utils/AssumeBundleBuilder.h" #include "llvm/Transforms/Utils/Local.h" #include "llvm/Transforms/Utils/PredicateInfo.h" #include "llvm/Transforms/Utils/VNCoercion.h" #include #include #include #include #include #include #include #include #include #include #include using namespace llvm; using namespace llvm::GVNExpression; using namespace llvm::VNCoercion; using namespace llvm::PatternMatch; #define DEBUG_TYPE "newgvn" STATISTIC(NumGVNInstrDeleted, "Number of instructions deleted"); STATISTIC(NumGVNBlocksDeleted, "Number of blocks deleted"); STATISTIC(NumGVNOpsSimplified, "Number of Expressions simplified"); STATISTIC(NumGVNPhisAllSame, "Number of PHIs whos arguments are all the same"); STATISTIC(NumGVNMaxIterations, "Maximum Number of iterations it took to converge GVN"); STATISTIC(NumGVNLeaderChanges, "Number of leader changes"); STATISTIC(NumGVNSortedLeaderChanges, "Number of sorted leader changes"); STATISTIC(NumGVNAvoidedSortedLeaderChanges, "Number of avoided sorted leader changes"); STATISTIC(NumGVNDeadStores, "Number of redundant/dead stores eliminated"); STATISTIC(NumGVNPHIOfOpsCreated, "Number of PHI of ops created"); STATISTIC(NumGVNPHIOfOpsEliminations, "Number of things eliminated using PHI of ops"); DEBUG_COUNTER(VNCounter, "newgvn-vn", "Controls which instructions are value numbered"); DEBUG_COUNTER(PHIOfOpsCounter, "newgvn-phi", "Controls which instructions we create phi of ops for"); // Currently store defining access refinement is too slow due to basicaa being // egregiously slow. This flag lets us keep it working while we work on this // issue. static cl::opt EnableStoreRefinement("enable-store-refinement", cl::init(false), cl::Hidden); /// Currently, the generation "phi of ops" can result in correctness issues. static cl::opt EnablePhiOfOps("enable-phi-of-ops", cl::init(true), cl::Hidden); //===----------------------------------------------------------------------===// // GVN Pass //===----------------------------------------------------------------------===// // Anchor methods. namespace llvm { namespace GVNExpression { Expression::~Expression() = default; BasicExpression::~BasicExpression() = default; CallExpression::~CallExpression() = default; LoadExpression::~LoadExpression() = default; StoreExpression::~StoreExpression() = default; AggregateValueExpression::~AggregateValueExpression() = default; PHIExpression::~PHIExpression() = default; } // end namespace GVNExpression } // end namespace llvm namespace { // Tarjan's SCC finding algorithm with Nuutila's improvements // SCCIterator is actually fairly complex for the simple thing we want. // It also wants to hand us SCC's that are unrelated to the phi node we ask // about, and have us process them there or risk redoing work. // Graph traits over a filter iterator also doesn't work that well here. // This SCC finder is specialized to walk use-def chains, and only follows // instructions, // not generic values (arguments, etc). struct TarjanSCC { TarjanSCC() : Components(1) {} void Start(const Instruction *Start) { if (Root.lookup(Start) == 0) FindSCC(Start); } const SmallPtrSetImpl &getComponentFor(const Value *V) const { unsigned ComponentID = ValueToComponent.lookup(V); assert(ComponentID > 0 && "Asking for a component for a value we never processed"); return Components[ComponentID]; } private: void FindSCC(const Instruction *I) { Root[I] = ++DFSNum; // Store the DFS Number we had before it possibly gets incremented. unsigned int OurDFS = DFSNum; for (auto &Op : I->operands()) { if (auto *InstOp = dyn_cast(Op)) { if (Root.lookup(Op) == 0) FindSCC(InstOp); if (!InComponent.count(Op)) Root[I] = std::min(Root.lookup(I), Root.lookup(Op)); } } // See if we really were the root of a component, by seeing if we still have // our DFSNumber. If we do, we are the root of the component, and we have // completed a component. If we do not, we are not the root of a component, // and belong on the component stack. if (Root.lookup(I) == OurDFS) { unsigned ComponentID = Components.size(); Components.resize(Components.size() + 1); auto &Component = Components.back(); Component.insert(I); LLVM_DEBUG(dbgs() << "Component root is " << *I << "\n"); InComponent.insert(I); ValueToComponent[I] = ComponentID; // Pop a component off the stack and label it. while (!Stack.empty() && Root.lookup(Stack.back()) >= OurDFS) { auto *Member = Stack.back(); LLVM_DEBUG(dbgs() << "Component member is " << *Member << "\n"); Component.insert(Member); InComponent.insert(Member); ValueToComponent[Member] = ComponentID; Stack.pop_back(); } } else { // Part of a component, push to stack Stack.push_back(I); } } unsigned int DFSNum = 1; SmallPtrSet InComponent; DenseMap Root; SmallVector Stack; // Store the components as vector of ptr sets, because we need the topo order // of SCC's, but not individual member order SmallVector, 8> Components; DenseMap ValueToComponent; }; // Congruence classes represent the set of expressions/instructions // that are all the same *during some scope in the function*. // That is, because of the way we perform equality propagation, and // because of memory value numbering, it is not correct to assume // you can willy-nilly replace any member with any other at any // point in the function. // // For any Value in the Member set, it is valid to replace any dominated member // with that Value. // // Every congruence class has a leader, and the leader is used to symbolize // instructions in a canonical way (IE every operand of an instruction that is a // member of the same congruence class will always be replaced with leader // during symbolization). To simplify symbolization, we keep the leader as a // constant if class can be proved to be a constant value. Otherwise, the // leader is the member of the value set with the smallest DFS number. Each // congruence class also has a defining expression, though the expression may be // null. If it exists, it can be used for forward propagation and reassociation // of values. // For memory, we also track a representative MemoryAccess, and a set of memory // members for MemoryPhis (which have no real instructions). Note that for // memory, it seems tempting to try to split the memory members into a // MemoryCongruenceClass or something. Unfortunately, this does not work // easily. The value numbering of a given memory expression depends on the // leader of the memory congruence class, and the leader of memory congruence // class depends on the value numbering of a given memory expression. This // leads to wasted propagation, and in some cases, missed optimization. For // example: If we had value numbered two stores together before, but now do not, // we move them to a new value congruence class. This in turn will move at one // of the memorydefs to a new memory congruence class. Which in turn, affects // the value numbering of the stores we just value numbered (because the memory // congruence class is part of the value number). So while theoretically // possible to split them up, it turns out to be *incredibly* complicated to get // it to work right, because of the interdependency. While structurally // slightly messier, it is algorithmically much simpler and faster to do what we // do here, and track them both at once in the same class. // Note: The default iterators for this class iterate over values class CongruenceClass { public: using MemberType = Value; using MemberSet = SmallPtrSet; using MemoryMemberType = MemoryPhi; using MemoryMemberSet = SmallPtrSet; explicit CongruenceClass(unsigned ID) : ID(ID) {} CongruenceClass(unsigned ID, Value *Leader, const Expression *E) : ID(ID), RepLeader(Leader), DefiningExpr(E) {} unsigned getID() const { return ID; } // True if this class has no members left. This is mainly used for assertion // purposes, and for skipping empty classes. bool isDead() const { // If it's both dead from a value perspective, and dead from a memory // perspective, it's really dead. return empty() && memory_empty(); } // Leader functions Value *getLeader() const { return RepLeader; } void setLeader(Value *Leader) { RepLeader = Leader; } const std::pair &getNextLeader() const { return NextLeader; } void resetNextLeader() { NextLeader = {nullptr, ~0}; } void addPossibleNextLeader(std::pair LeaderPair) { if (LeaderPair.second < NextLeader.second) NextLeader = LeaderPair; } Value *getStoredValue() const { return RepStoredValue; } void setStoredValue(Value *Leader) { RepStoredValue = Leader; } const MemoryAccess *getMemoryLeader() const { return RepMemoryAccess; } void setMemoryLeader(const MemoryAccess *Leader) { RepMemoryAccess = Leader; } // Forward propagation info const Expression *getDefiningExpr() const { return DefiningExpr; } // Value member set bool empty() const { return Members.empty(); } unsigned size() const { return Members.size(); } MemberSet::const_iterator begin() const { return Members.begin(); } MemberSet::const_iterator end() const { return Members.end(); } void insert(MemberType *M) { Members.insert(M); } void erase(MemberType *M) { Members.erase(M); } void swap(MemberSet &Other) { Members.swap(Other); } // Memory member set bool memory_empty() const { return MemoryMembers.empty(); } unsigned memory_size() const { return MemoryMembers.size(); } MemoryMemberSet::const_iterator memory_begin() const { return MemoryMembers.begin(); } MemoryMemberSet::const_iterator memory_end() const { return MemoryMembers.end(); } iterator_range memory() const { return make_range(memory_begin(), memory_end()); } void memory_insert(const MemoryMemberType *M) { MemoryMembers.insert(M); } void memory_erase(const MemoryMemberType *M) { MemoryMembers.erase(M); } // Store count unsigned getStoreCount() const { return StoreCount; } void incStoreCount() { ++StoreCount; } void decStoreCount() { assert(StoreCount != 0 && "Store count went negative"); --StoreCount; } // True if this class has no memory members. bool definesNoMemory() const { return StoreCount == 0 && memory_empty(); } // Return true if two congruence classes are equivalent to each other. This // means that every field but the ID number and the dead field are equivalent. bool isEquivalentTo(const CongruenceClass *Other) const { if (!Other) return false; if (this == Other) return true; if (std::tie(StoreCount, RepLeader, RepStoredValue, RepMemoryAccess) != std::tie(Other->StoreCount, Other->RepLeader, Other->RepStoredValue, Other->RepMemoryAccess)) return false; if (DefiningExpr != Other->DefiningExpr) if (!DefiningExpr || !Other->DefiningExpr || *DefiningExpr != *Other->DefiningExpr) return false; if (Members.size() != Other->Members.size()) return false; return all_of(Members, [&](const Value *V) { return Other->Members.count(V); }); } private: unsigned ID; // Representative leader. Value *RepLeader = nullptr; // The most dominating leader after our current leader, because the member set // is not sorted and is expensive to keep sorted all the time. std::pair NextLeader = {nullptr, ~0U}; // If this is represented by a store, the value of the store. Value *RepStoredValue = nullptr; // If this class contains MemoryDefs or MemoryPhis, this is the leading memory // access. const MemoryAccess *RepMemoryAccess = nullptr; // Defining Expression. const Expression *DefiningExpr = nullptr; // Actual members of this class. MemberSet Members; // This is the set of MemoryPhis that exist in the class. MemoryDefs and // MemoryUses have real instructions representing them, so we only need to // track MemoryPhis here. MemoryMemberSet MemoryMembers; // Number of stores in this congruence class. // This is used so we can detect store equivalence changes properly. int StoreCount = 0; }; } // end anonymous namespace namespace llvm { struct ExactEqualsExpression { const Expression &E; explicit ExactEqualsExpression(const Expression &E) : E(E) {} hash_code getComputedHash() const { return E.getComputedHash(); } bool operator==(const Expression &Other) const { return E.exactlyEquals(Other); } }; template <> struct DenseMapInfo { static const Expression *getEmptyKey() { auto Val = static_cast(-1); Val <<= PointerLikeTypeTraits::NumLowBitsAvailable; return reinterpret_cast(Val); } static const Expression *getTombstoneKey() { auto Val = static_cast(~1U); Val <<= PointerLikeTypeTraits::NumLowBitsAvailable; return reinterpret_cast(Val); } static unsigned getHashValue(const Expression *E) { return E->getComputedHash(); } static unsigned getHashValue(const ExactEqualsExpression &E) { return E.getComputedHash(); } static bool isEqual(const ExactEqualsExpression &LHS, const Expression *RHS) { if (RHS == getTombstoneKey() || RHS == getEmptyKey()) return false; return LHS == *RHS; } static bool isEqual(const Expression *LHS, const Expression *RHS) { if (LHS == RHS) return true; if (LHS == getTombstoneKey() || RHS == getTombstoneKey() || LHS == getEmptyKey() || RHS == getEmptyKey()) return false; // Compare hashes before equality. This is *not* what the hashtable does, // since it is computing it modulo the number of buckets, whereas we are // using the full hash keyspace. Since the hashes are precomputed, this // check is *much* faster than equality. if (LHS->getComputedHash() != RHS->getComputedHash()) return false; return *LHS == *RHS; } }; } // end namespace llvm namespace { class NewGVN { Function &F; DominatorTree *DT = nullptr; const TargetLibraryInfo *TLI = nullptr; AliasAnalysis *AA = nullptr; MemorySSA *MSSA = nullptr; MemorySSAWalker *MSSAWalker = nullptr; AssumptionCache *AC = nullptr; const DataLayout &DL; std::unique_ptr PredInfo; // These are the only two things the create* functions should have // side-effects on due to allocating memory. mutable BumpPtrAllocator ExpressionAllocator; mutable ArrayRecycler ArgRecycler; mutable TarjanSCC SCCFinder; const SimplifyQuery SQ; // Number of function arguments, used by ranking unsigned int NumFuncArgs = 0; // RPOOrdering of basic blocks DenseMap RPOOrdering; // Congruence class info. // This class is called INITIAL in the paper. It is the class everything // startsout in, and represents any value. Being an optimistic analysis, // anything in the TOP class has the value TOP, which is indeterminate and // equivalent to everything. CongruenceClass *TOPClass = nullptr; std::vector CongruenceClasses; unsigned NextCongruenceNum = 0; // Value Mappings. DenseMap ValueToClass; DenseMap ValueToExpression; // Value PHI handling, used to make equivalence between phi(op, op) and // op(phi, phi). // These mappings just store various data that would normally be part of the // IR. SmallPtrSet PHINodeUses; DenseMap OpSafeForPHIOfOps; // Map a temporary instruction we created to a parent block. DenseMap TempToBlock; // Map between the already in-program instructions and the temporary phis we // created that they are known equivalent to. DenseMap RealToTemp; // In order to know when we should re-process instructions that have // phi-of-ops, we track the set of expressions that they needed as // leaders. When we discover new leaders for those expressions, we process the // associated phi-of-op instructions again in case they have changed. The // other way they may change is if they had leaders, and those leaders // disappear. However, at the point they have leaders, there are uses of the // relevant operands in the created phi node, and so they will get reprocessed // through the normal user marking we perform. mutable DenseMap> AdditionalUsers; DenseMap> ExpressionToPhiOfOps; // Map from temporary operation to MemoryAccess. DenseMap TempToMemory; // Set of all temporary instructions we created. // Note: This will include instructions that were just created during value // numbering. The way to test if something is using them is to check // RealToTemp. DenseSet AllTempInstructions; // This is the set of instructions to revisit on a reachability change. At // the end of the main iteration loop it will contain at least all the phi of // ops instructions that will be changed to phis, as well as regular phis. // During the iteration loop, it may contain other things, such as phi of ops // instructions that used edge reachability to reach a result, and so need to // be revisited when the edge changes, independent of whether the phi they // depended on changes. DenseMap> RevisitOnReachabilityChange; // Mapping from predicate info we used to the instructions we used it with. // In order to correctly ensure propagation, we must keep track of what // comparisons we used, so that when the values of the comparisons change, we // propagate the information to the places we used the comparison. mutable DenseMap> PredicateToUsers; // the same reasoning as PredicateToUsers. When we skip MemoryAccesses for // stores, we no longer can rely solely on the def-use chains of MemorySSA. mutable DenseMap> MemoryToUsers; // A table storing which memorydefs/phis represent a memory state provably // equivalent to another memory state. // We could use the congruence class machinery, but the MemoryAccess's are // abstract memory states, so they can only ever be equivalent to each other, // and not to constants, etc. DenseMap MemoryAccessToClass; // We could, if we wanted, build MemoryPhiExpressions and // MemoryVariableExpressions, etc, and value number them the same way we value // number phi expressions. For the moment, this seems like overkill. They // can only exist in one of three states: they can be TOP (equal to // everything), Equivalent to something else, or unique. Because we do not // create expressions for them, we need to simulate leader change not just // when they change class, but when they change state. Note: We can do the // same thing for phis, and avoid having phi expressions if we wanted, We // should eventually unify in one direction or the other, so this is a little // bit of an experiment in which turns out easier to maintain. enum MemoryPhiState { MPS_Invalid, MPS_TOP, MPS_Equivalent, MPS_Unique }; DenseMap MemoryPhiState; enum InstCycleState { ICS_Unknown, ICS_CycleFree, ICS_Cycle }; mutable DenseMap InstCycleState; // Expression to class mapping. using ExpressionClassMap = DenseMap; ExpressionClassMap ExpressionToClass; // We have a single expression that represents currently DeadExpressions. // For dead expressions we can prove will stay dead, we mark them with // DFS number zero. However, it's possible in the case of phi nodes // for us to assume/prove all arguments are dead during fixpointing. // We use DeadExpression for that case. DeadExpression *SingletonDeadExpression = nullptr; // Which values have changed as a result of leader changes. SmallPtrSet LeaderChanges; // Reachability info. using BlockEdge = BasicBlockEdge; DenseSet ReachableEdges; SmallPtrSet ReachableBlocks; // This is a bitvector because, on larger functions, we may have // thousands of touched instructions at once (entire blocks, // instructions with hundreds of uses, etc). Even with optimization // for when we mark whole blocks as touched, when this was a // SmallPtrSet or DenseSet, for some functions, we spent >20% of all // the time in GVN just managing this list. The bitvector, on the // other hand, efficiently supports test/set/clear of both // individual and ranges, as well as "find next element" This // enables us to use it as a worklist with essentially 0 cost. BitVector TouchedInstructions; DenseMap> BlockInstRange; #ifndef NDEBUG // Debugging for how many times each block and instruction got processed. DenseMap ProcessedCount; #endif // DFS info. // This contains a mapping from Instructions to DFS numbers. // The numbering starts at 1. An instruction with DFS number zero // means that the instruction is dead. DenseMap InstrDFS; // This contains the mapping DFS numbers to instructions. SmallVector DFSToInstr; // Deletion info. SmallPtrSet InstructionsToErase; public: NewGVN(Function &F, DominatorTree *DT, AssumptionCache *AC, TargetLibraryInfo *TLI, AliasAnalysis *AA, MemorySSA *MSSA, const DataLayout &DL) : F(F), DT(DT), TLI(TLI), AA(AA), MSSA(MSSA), AC(AC), DL(DL), PredInfo(std::make_unique(F, *DT, *AC)), SQ(DL, TLI, DT, AC, /*CtxI=*/nullptr, /*UseInstrInfo=*/false, /*CanUseUndef=*/false) {} bool runGVN(); private: // Expression handling. const Expression *createExpression(Instruction *) const; const Expression *createBinaryExpression(unsigned, Type *, Value *, Value *, Instruction *) const; // Our canonical form for phi arguments is a pair of incoming value, incoming // basic block. using ValPair = std::pair; PHIExpression *createPHIExpression(ArrayRef, const Instruction *, BasicBlock *, bool &HasBackEdge, bool &OriginalOpsConstant) const; const DeadExpression *createDeadExpression() const; const VariableExpression *createVariableExpression(Value *) const; const ConstantExpression *createConstantExpression(Constant *) const; const Expression *createVariableOrConstant(Value *V) const; const UnknownExpression *createUnknownExpression(Instruction *) const; const StoreExpression *createStoreExpression(StoreInst *, const MemoryAccess *) const; LoadExpression *createLoadExpression(Type *, Value *, LoadInst *, const MemoryAccess *) const; const CallExpression *createCallExpression(CallInst *, const MemoryAccess *) const; const AggregateValueExpression * createAggregateValueExpression(Instruction *) const; bool setBasicExpressionInfo(Instruction *, BasicExpression *) const; // Congruence class handling. CongruenceClass *createCongruenceClass(Value *Leader, const Expression *E) { auto *result = new CongruenceClass(NextCongruenceNum++, Leader, E); CongruenceClasses.emplace_back(result); return result; } CongruenceClass *createMemoryClass(MemoryAccess *MA) { auto *CC = createCongruenceClass(nullptr, nullptr); CC->setMemoryLeader(MA); return CC; } CongruenceClass *ensureLeaderOfMemoryClass(MemoryAccess *MA) { auto *CC = getMemoryClass(MA); if (CC->getMemoryLeader() != MA) CC = createMemoryClass(MA); return CC; } CongruenceClass *createSingletonCongruenceClass(Value *Member) { CongruenceClass *CClass = createCongruenceClass(Member, nullptr); CClass->insert(Member); ValueToClass[Member] = CClass; return CClass; } void initializeCongruenceClasses(Function &F); const Expression *makePossiblePHIOfOps(Instruction *, SmallPtrSetImpl &); Value *findLeaderForInst(Instruction *ValueOp, SmallPtrSetImpl &Visited, MemoryAccess *MemAccess, Instruction *OrigInst, BasicBlock *PredBB); bool OpIsSafeForPHIOfOpsHelper(Value *V, const BasicBlock *PHIBlock, SmallPtrSetImpl &Visited, SmallVectorImpl &Worklist); bool OpIsSafeForPHIOfOps(Value *Op, const BasicBlock *PHIBlock, SmallPtrSetImpl &); void addPhiOfOps(PHINode *Op, BasicBlock *BB, Instruction *ExistingValue); void removePhiOfOps(Instruction *I, PHINode *PHITemp); // Value number an Instruction or MemoryPhi. void valueNumberMemoryPhi(MemoryPhi *); void valueNumberInstruction(Instruction *); // Symbolic evaluation. const Expression *checkSimplificationResults(Expression *, Instruction *, Value *) const; const Expression *performSymbolicEvaluation(Value *, SmallPtrSetImpl &) const; const Expression *performSymbolicLoadCoercion(Type *, Value *, LoadInst *, Instruction *, MemoryAccess *) const; const Expression *performSymbolicLoadEvaluation(Instruction *) const; const Expression *performSymbolicStoreEvaluation(Instruction *) const; const Expression *performSymbolicCallEvaluation(Instruction *) const; void sortPHIOps(MutableArrayRef Ops) const; const Expression *performSymbolicPHIEvaluation(ArrayRef, Instruction *I, BasicBlock *PHIBlock) const; const Expression *performSymbolicAggrValueEvaluation(Instruction *) const; const Expression *performSymbolicCmpEvaluation(Instruction *) const; const Expression *performSymbolicPredicateInfoEvaluation(Instruction *) const; // Congruence finding. bool someEquivalentDominates(const Instruction *, const Instruction *) const; Value *lookupOperandLeader(Value *) const; CongruenceClass *getClassForExpression(const Expression *E) const; void performCongruenceFinding(Instruction *, const Expression *); void moveValueToNewCongruenceClass(Instruction *, const Expression *, CongruenceClass *, CongruenceClass *); void moveMemoryToNewCongruenceClass(Instruction *, MemoryAccess *, CongruenceClass *, CongruenceClass *); Value *getNextValueLeader(CongruenceClass *) const; const MemoryAccess *getNextMemoryLeader(CongruenceClass *) const; bool setMemoryClass(const MemoryAccess *From, CongruenceClass *To); CongruenceClass *getMemoryClass(const MemoryAccess *MA) const; const MemoryAccess *lookupMemoryLeader(const MemoryAccess *) const; bool isMemoryAccessTOP(const MemoryAccess *) const; // Ranking unsigned int getRank(const Value *) const; bool shouldSwapOperands(const Value *, const Value *) const; // Reachability handling. void updateReachableEdge(BasicBlock *, BasicBlock *); void processOutgoingEdges(Instruction *, BasicBlock *); Value *findConditionEquivalence(Value *) const; // Elimination. struct ValueDFS; void convertClassToDFSOrdered(const CongruenceClass &, SmallVectorImpl &, DenseMap &, SmallPtrSetImpl &) const; void convertClassToLoadsAndStores(const CongruenceClass &, SmallVectorImpl &) const; bool eliminateInstructions(Function &); void replaceInstruction(Instruction *, Value *); void markInstructionForDeletion(Instruction *); void deleteInstructionsInBlock(BasicBlock *); Value *findPHIOfOpsLeader(const Expression *, const Instruction *, const BasicBlock *) const; // Various instruction touch utilities template void touchAndErase(Map &, const KeyType &); void markUsersTouched(Value *); void markMemoryUsersTouched(const MemoryAccess *); void markMemoryDefTouched(const MemoryAccess *); void markPredicateUsersTouched(Instruction *); void markValueLeaderChangeTouched(CongruenceClass *CC); void markMemoryLeaderChangeTouched(CongruenceClass *CC); void markPhiOfOpsChanged(const Expression *E); void addPredicateUsers(const PredicateBase *, Instruction *) const; void addMemoryUsers(const MemoryAccess *To, MemoryAccess *U) const; void addAdditionalUsers(Value *To, Value *User) const; // Main loop of value numbering void iterateTouchedInstructions(); // Utilities. void cleanupTables(); std::pair assignDFSNumbers(BasicBlock *, unsigned); void updateProcessedCount(const Value *V); void verifyMemoryCongruency() const; void verifyIterationSettled(Function &F); void verifyStoreExpressions() const; bool singleReachablePHIPath(SmallPtrSet &, const MemoryAccess *, const MemoryAccess *) const; BasicBlock *getBlockForValue(Value *V) const; void deleteExpression(const Expression *E) const; MemoryUseOrDef *getMemoryAccess(const Instruction *) const; MemoryPhi *getMemoryAccess(const BasicBlock *) const; template T *getMinDFSOfRange(const Range &) const; unsigned InstrToDFSNum(const Value *V) const { assert(isa(V) && "This should not be used for MemoryAccesses"); return InstrDFS.lookup(V); } unsigned InstrToDFSNum(const MemoryAccess *MA) const { return MemoryToDFSNum(MA); } Value *InstrFromDFSNum(unsigned DFSNum) { return DFSToInstr[DFSNum]; } // Given a MemoryAccess, return the relevant instruction DFS number. Note: // This deliberately takes a value so it can be used with Use's, which will // auto-convert to Value's but not to MemoryAccess's. unsigned MemoryToDFSNum(const Value *MA) const { assert(isa(MA) && "This should not be used with instructions"); return isa(MA) ? InstrToDFSNum(cast(MA)->getMemoryInst()) : InstrDFS.lookup(MA); } bool isCycleFree(const Instruction *) const; bool isBackedge(BasicBlock *From, BasicBlock *To) const; // Debug counter info. When verifying, we have to reset the value numbering // debug counter to the same state it started in to get the same results. int64_t StartingVNCounter = 0; }; } // end anonymous namespace template static bool equalsLoadStoreHelper(const T &LHS, const Expression &RHS) { if (!isa(RHS) && !isa(RHS)) return false; return LHS.MemoryExpression::equals(RHS); } bool LoadExpression::equals(const Expression &Other) const { return equalsLoadStoreHelper(*this, Other); } bool StoreExpression::equals(const Expression &Other) const { if (!equalsLoadStoreHelper(*this, Other)) return false; // Make sure that store vs store includes the value operand. if (const auto *S = dyn_cast(&Other)) if (getStoredValue() != S->getStoredValue()) return false; return true; } // Determine if the edge From->To is a backedge bool NewGVN::isBackedge(BasicBlock *From, BasicBlock *To) const { return From == To || RPOOrdering.lookup(DT->getNode(From)) >= RPOOrdering.lookup(DT->getNode(To)); } #ifndef NDEBUG static std::string getBlockName(const BasicBlock *B) { return DOTGraphTraits::getSimpleNodeLabel(B, nullptr); } #endif // Get a MemoryAccess for an instruction, fake or real. MemoryUseOrDef *NewGVN::getMemoryAccess(const Instruction *I) const { auto *Result = MSSA->getMemoryAccess(I); return Result ? Result : TempToMemory.lookup(I); } // Get a MemoryPhi for a basic block. These are all real. MemoryPhi *NewGVN::getMemoryAccess(const BasicBlock *BB) const { return MSSA->getMemoryAccess(BB); } // Get the basic block from an instruction/memory value. BasicBlock *NewGVN::getBlockForValue(Value *V) const { if (auto *I = dyn_cast(V)) { auto *Parent = I->getParent(); if (Parent) return Parent; Parent = TempToBlock.lookup(V); assert(Parent && "Every fake instruction should have a block"); return Parent; } auto *MP = dyn_cast(V); assert(MP && "Should have been an instruction or a MemoryPhi"); return MP->getBlock(); } // Delete a definitely dead expression, so it can be reused by the expression // allocator. Some of these are not in creation functions, so we have to accept // const versions. void NewGVN::deleteExpression(const Expression *E) const { assert(isa(E)); auto *BE = cast(E); const_cast(BE)->deallocateOperands(ArgRecycler); ExpressionAllocator.Deallocate(E); } // If V is a predicateinfo copy, get the thing it is a copy of. static Value *getCopyOf(const Value *V) { if (auto *II = dyn_cast(V)) if (II->getIntrinsicID() == Intrinsic::ssa_copy) return II->getOperand(0); return nullptr; } // Return true if V is really PN, even accounting for predicateinfo copies. static bool isCopyOfPHI(const Value *V, const PHINode *PN) { return V == PN || getCopyOf(V) == PN; } static bool isCopyOfAPHI(const Value *V) { auto *CO = getCopyOf(V); return CO && isa(CO); } // Sort PHI Operands into a canonical order. What we use here is an RPO // order. The BlockInstRange numbers are generated in an RPO walk of the basic // blocks. void NewGVN::sortPHIOps(MutableArrayRef Ops) const { llvm::sort(Ops, [&](const ValPair &P1, const ValPair &P2) { return BlockInstRange.lookup(P1.second).first < BlockInstRange.lookup(P2.second).first; }); } // Return true if V is a value that will always be available (IE can // be placed anywhere) in the function. We don't do globals here // because they are often worse to put in place. static bool alwaysAvailable(Value *V) { return isa(V) || isa(V); } // Create a PHIExpression from an array of {incoming edge, value} pairs. I is // the original instruction we are creating a PHIExpression for (but may not be // a phi node). We require, as an invariant, that all the PHIOperands in the // same block are sorted the same way. sortPHIOps will sort them into a // canonical order. PHIExpression *NewGVN::createPHIExpression(ArrayRef PHIOperands, const Instruction *I, BasicBlock *PHIBlock, bool &HasBackedge, bool &OriginalOpsConstant) const { unsigned NumOps = PHIOperands.size(); auto *E = new (ExpressionAllocator) PHIExpression(NumOps, PHIBlock); E->allocateOperands(ArgRecycler, ExpressionAllocator); E->setType(PHIOperands.begin()->first->getType()); E->setOpcode(Instruction::PHI); // Filter out unreachable phi operands. auto Filtered = make_filter_range(PHIOperands, [&](const ValPair &P) { auto *BB = P.second; if (auto *PHIOp = dyn_cast(I)) if (isCopyOfPHI(P.first, PHIOp)) return false; if (!ReachableEdges.count({BB, PHIBlock})) return false; // Things in TOPClass are equivalent to everything. if (ValueToClass.lookup(P.first) == TOPClass) return false; OriginalOpsConstant = OriginalOpsConstant && isa(P.first); HasBackedge = HasBackedge || isBackedge(BB, PHIBlock); return lookupOperandLeader(P.first) != I; }); std::transform(Filtered.begin(), Filtered.end(), op_inserter(E), [&](const ValPair &P) -> Value * { return lookupOperandLeader(P.first); }); return E; } // Set basic expression info (Arguments, type, opcode) for Expression // E from Instruction I in block B. bool NewGVN::setBasicExpressionInfo(Instruction *I, BasicExpression *E) const { bool AllConstant = true; if (auto *GEP = dyn_cast(I)) E->setType(GEP->getSourceElementType()); else E->setType(I->getType()); E->setOpcode(I->getOpcode()); E->allocateOperands(ArgRecycler, ExpressionAllocator); // Transform the operand array into an operand leader array, and keep track of // whether all members are constant. std::transform(I->op_begin(), I->op_end(), op_inserter(E), [&](Value *O) { auto Operand = lookupOperandLeader(O); AllConstant = AllConstant && isa(Operand); return Operand; }); return AllConstant; } const Expression *NewGVN::createBinaryExpression(unsigned Opcode, Type *T, Value *Arg1, Value *Arg2, Instruction *I) const { auto *E = new (ExpressionAllocator) BasicExpression(2); E->setType(T); E->setOpcode(Opcode); E->allocateOperands(ArgRecycler, ExpressionAllocator); if (Instruction::isCommutative(Opcode)) { // Ensure that commutative instructions that only differ by a permutation // of their operands get the same value number by sorting the operand value // numbers. Since all commutative instructions have two operands it is more // efficient to sort by hand rather than using, say, std::sort. if (shouldSwapOperands(Arg1, Arg2)) std::swap(Arg1, Arg2); } E->op_push_back(lookupOperandLeader(Arg1)); E->op_push_back(lookupOperandLeader(Arg2)); Value *V = SimplifyBinOp(Opcode, E->getOperand(0), E->getOperand(1), SQ); if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V)) return SimplifiedE; return E; } // Take a Value returned by simplification of Expression E/Instruction // I, and see if it resulted in a simpler expression. If so, return // that expression. const Expression *NewGVN::checkSimplificationResults(Expression *E, Instruction *I, Value *V) const { if (!V) return nullptr; if (auto *C = dyn_cast(V)) { if (I) LLVM_DEBUG(dbgs() << "Simplified " << *I << " to " << " constant " << *C << "\n"); NumGVNOpsSimplified++; assert(isa(E) && "We should always have had a basic expression here"); deleteExpression(E); return createConstantExpression(C); } else if (isa(V) || isa(V)) { if (I) LLVM_DEBUG(dbgs() << "Simplified " << *I << " to " << " variable " << *V << "\n"); deleteExpression(E); return createVariableExpression(V); } CongruenceClass *CC = ValueToClass.lookup(V); if (CC) { if (CC->getLeader() && CC->getLeader() != I) { // If we simplified to something else, we need to communicate // that we're users of the value we simplified to. if (I != V) { // Don't add temporary instructions to the user lists. if (!AllTempInstructions.count(I)) addAdditionalUsers(V, I); } return createVariableOrConstant(CC->getLeader()); } if (CC->getDefiningExpr()) { // If we simplified to something else, we need to communicate // that we're users of the value we simplified to. if (I != V) { // Don't add temporary instructions to the user lists. if (!AllTempInstructions.count(I)) addAdditionalUsers(V, I); } if (I) LLVM_DEBUG(dbgs() << "Simplified " << *I << " to " << " expression " << *CC->getDefiningExpr() << "\n"); NumGVNOpsSimplified++; deleteExpression(E); return CC->getDefiningExpr(); } } return nullptr; } // Create a value expression from the instruction I, replacing operands with // their leaders. const Expression *NewGVN::createExpression(Instruction *I) const { auto *E = new (ExpressionAllocator) BasicExpression(I->getNumOperands()); bool AllConstant = setBasicExpressionInfo(I, E); if (I->isCommutative()) { // Ensure that commutative instructions that only differ by a permutation // of their operands get the same value number by sorting the operand value // numbers. Since all commutative instructions have two operands it is more // efficient to sort by hand rather than using, say, std::sort. assert(I->getNumOperands() == 2 && "Unsupported commutative instruction!"); if (shouldSwapOperands(E->getOperand(0), E->getOperand(1))) E->swapOperands(0, 1); } // Perform simplification. if (auto *CI = dyn_cast(I)) { // Sort the operand value numbers so xx get the same value // number. CmpInst::Predicate Predicate = CI->getPredicate(); if (shouldSwapOperands(E->getOperand(0), E->getOperand(1))) { E->swapOperands(0, 1); Predicate = CmpInst::getSwappedPredicate(Predicate); } E->setOpcode((CI->getOpcode() << 8) | Predicate); // TODO: 25% of our time is spent in SimplifyCmpInst with pointer operands assert(I->getOperand(0)->getType() == I->getOperand(1)->getType() && "Wrong types on cmp instruction"); assert((E->getOperand(0)->getType() == I->getOperand(0)->getType() && E->getOperand(1)->getType() == I->getOperand(1)->getType())); Value *V = SimplifyCmpInst(Predicate, E->getOperand(0), E->getOperand(1), SQ); if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V)) return SimplifiedE; } else if (isa(I)) { if (isa(E->getOperand(0)) || E->getOperand(1) == E->getOperand(2)) { assert(E->getOperand(1)->getType() == I->getOperand(1)->getType() && E->getOperand(2)->getType() == I->getOperand(2)->getType()); Value *V = SimplifySelectInst(E->getOperand(0), E->getOperand(1), E->getOperand(2), SQ); if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V)) return SimplifiedE; } } else if (I->isBinaryOp()) { Value *V = SimplifyBinOp(E->getOpcode(), E->getOperand(0), E->getOperand(1), SQ); if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V)) return SimplifiedE; } else if (auto *CI = dyn_cast(I)) { Value *V = SimplifyCastInst(CI->getOpcode(), E->getOperand(0), CI->getType(), SQ); if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V)) return SimplifiedE; } else if (isa(I)) { Value *V = SimplifyGEPInst( E->getType(), ArrayRef(E->op_begin(), E->op_end()), SQ); if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V)) return SimplifiedE; } else if (AllConstant) { // We don't bother trying to simplify unless all of the operands // were constant. // TODO: There are a lot of Simplify*'s we could call here, if we // wanted to. The original motivating case for this code was a // zext i1 false to i8, which we don't have an interface to // simplify (IE there is no SimplifyZExt). SmallVector C; for (Value *Arg : E->operands()) C.emplace_back(cast(Arg)); if (Value *V = ConstantFoldInstOperands(I, C, DL, TLI)) if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V)) return SimplifiedE; } return E; } const AggregateValueExpression * NewGVN::createAggregateValueExpression(Instruction *I) const { if (auto *II = dyn_cast(I)) { auto *E = new (ExpressionAllocator) AggregateValueExpression(I->getNumOperands(), II->getNumIndices()); setBasicExpressionInfo(I, E); E->allocateIntOperands(ExpressionAllocator); std::copy(II->idx_begin(), II->idx_end(), int_op_inserter(E)); return E; } else if (auto *EI = dyn_cast(I)) { auto *E = new (ExpressionAllocator) AggregateValueExpression(I->getNumOperands(), EI->getNumIndices()); setBasicExpressionInfo(EI, E); E->allocateIntOperands(ExpressionAllocator); std::copy(EI->idx_begin(), EI->idx_end(), int_op_inserter(E)); return E; } llvm_unreachable("Unhandled type of aggregate value operation"); } const DeadExpression *NewGVN::createDeadExpression() const { // DeadExpression has no arguments and all DeadExpression's are the same, // so we only need one of them. return SingletonDeadExpression; } const VariableExpression *NewGVN::createVariableExpression(Value *V) const { auto *E = new (ExpressionAllocator) VariableExpression(V); E->setOpcode(V->getValueID()); return E; } const Expression *NewGVN::createVariableOrConstant(Value *V) const { if (auto *C = dyn_cast(V)) return createConstantExpression(C); return createVariableExpression(V); } const ConstantExpression *NewGVN::createConstantExpression(Constant *C) const { auto *E = new (ExpressionAllocator) ConstantExpression(C); E->setOpcode(C->getValueID()); return E; } const UnknownExpression *NewGVN::createUnknownExpression(Instruction *I) const { auto *E = new (ExpressionAllocator) UnknownExpression(I); E->setOpcode(I->getOpcode()); return E; } const CallExpression * NewGVN::createCallExpression(CallInst *CI, const MemoryAccess *MA) const { // FIXME: Add operand bundles for calls. // FIXME: Allow commutative matching for intrinsics. auto *E = new (ExpressionAllocator) CallExpression(CI->getNumOperands(), CI, MA); setBasicExpressionInfo(CI, E); return E; } // Return true if some equivalent of instruction Inst dominates instruction U. bool NewGVN::someEquivalentDominates(const Instruction *Inst, const Instruction *U) const { auto *CC = ValueToClass.lookup(Inst); // This must be an instruction because we are only called from phi nodes // in the case that the value it needs to check against is an instruction. // The most likely candidates for dominance are the leader and the next leader. // The leader or nextleader will dominate in all cases where there is an // equivalent that is higher up in the dom tree. // We can't *only* check them, however, because the // dominator tree could have an infinite number of non-dominating siblings // with instructions that are in the right congruence class. // A // B C D E F G // | // H // Instruction U could be in H, with equivalents in every other sibling. // Depending on the rpo order picked, the leader could be the equivalent in // any of these siblings. if (!CC) return false; if (alwaysAvailable(CC->getLeader())) return true; if (DT->dominates(cast(CC->getLeader()), U)) return true; if (CC->getNextLeader().first && DT->dominates(cast(CC->getNextLeader().first), U)) return true; return llvm::any_of(*CC, [&](const Value *Member) { return Member != CC->getLeader() && DT->dominates(cast(Member), U); }); } // See if we have a congruence class and leader for this operand, and if so, // return it. Otherwise, return the operand itself. Value *NewGVN::lookupOperandLeader(Value *V) const { CongruenceClass *CC = ValueToClass.lookup(V); if (CC) { // Everything in TOP is represented by undef, as it can be any value. // We do have to make sure we get the type right though, so we can't set the // RepLeader to undef. if (CC == TOPClass) return UndefValue::get(V->getType()); return CC->getStoredValue() ? CC->getStoredValue() : CC->getLeader(); } return V; } const MemoryAccess *NewGVN::lookupMemoryLeader(const MemoryAccess *MA) const { auto *CC = getMemoryClass(MA); assert(CC->getMemoryLeader() && "Every MemoryAccess should be mapped to a congruence class with a " "representative memory access"); return CC->getMemoryLeader(); } // Return true if the MemoryAccess is really equivalent to everything. This is // equivalent to the lattice value "TOP" in most lattices. This is the initial // state of all MemoryAccesses. bool NewGVN::isMemoryAccessTOP(const MemoryAccess *MA) const { return getMemoryClass(MA) == TOPClass; } LoadExpression *NewGVN::createLoadExpression(Type *LoadType, Value *PointerOp, LoadInst *LI, const MemoryAccess *MA) const { auto *E = new (ExpressionAllocator) LoadExpression(1, LI, lookupMemoryLeader(MA)); E->allocateOperands(ArgRecycler, ExpressionAllocator); E->setType(LoadType); // Give store and loads same opcode so they value number together. E->setOpcode(0); E->op_push_back(PointerOp); // TODO: Value number heap versions. We may be able to discover // things alias analysis can't on it's own (IE that a store and a // load have the same value, and thus, it isn't clobbering the load). return E; } const StoreExpression * NewGVN::createStoreExpression(StoreInst *SI, const MemoryAccess *MA) const { auto *StoredValueLeader = lookupOperandLeader(SI->getValueOperand()); auto *E = new (ExpressionAllocator) StoreExpression(SI->getNumOperands(), SI, StoredValueLeader, MA); E->allocateOperands(ArgRecycler, ExpressionAllocator); E->setType(SI->getValueOperand()->getType()); // Give store and loads same opcode so they value number together. E->setOpcode(0); E->op_push_back(lookupOperandLeader(SI->getPointerOperand())); // TODO: Value number heap versions. We may be able to discover // things alias analysis can't on it's own (IE that a store and a // load have the same value, and thus, it isn't clobbering the load). return E; } const Expression *NewGVN::performSymbolicStoreEvaluation(Instruction *I) const { // Unlike loads, we never try to eliminate stores, so we do not check if they // are simple and avoid value numbering them. auto *SI = cast(I); auto *StoreAccess = getMemoryAccess(SI); // Get the expression, if any, for the RHS of the MemoryDef. const MemoryAccess *StoreRHS = StoreAccess->getDefiningAccess(); if (EnableStoreRefinement) StoreRHS = MSSAWalker->getClobberingMemoryAccess(StoreAccess); // If we bypassed the use-def chains, make sure we add a use. StoreRHS = lookupMemoryLeader(StoreRHS); if (StoreRHS != StoreAccess->getDefiningAccess()) addMemoryUsers(StoreRHS, StoreAccess); // If we are defined by ourselves, use the live on entry def. if (StoreRHS == StoreAccess) StoreRHS = MSSA->getLiveOnEntryDef(); if (SI->isSimple()) { // See if we are defined by a previous store expression, it already has a // value, and it's the same value as our current store. FIXME: Right now, we // only do this for simple stores, we should expand to cover memcpys, etc. const auto *LastStore = createStoreExpression(SI, StoreRHS); const auto *LastCC = ExpressionToClass.lookup(LastStore); // We really want to check whether the expression we matched was a store. No // easy way to do that. However, we can check that the class we found has a // store, which, assuming the value numbering state is not corrupt, is // sufficient, because we must also be equivalent to that store's expression // for it to be in the same class as the load. if (LastCC && LastCC->getStoredValue() == LastStore->getStoredValue()) return LastStore; // Also check if our value operand is defined by a load of the same memory // location, and the memory state is the same as it was then (otherwise, it // could have been overwritten later. See test32 in // transforms/DeadStoreElimination/simple.ll). if (auto *LI = dyn_cast(LastStore->getStoredValue())) if ((lookupOperandLeader(LI->getPointerOperand()) == LastStore->getOperand(0)) && (lookupMemoryLeader(getMemoryAccess(LI)->getDefiningAccess()) == StoreRHS)) return LastStore; deleteExpression(LastStore); } // If the store is not equivalent to anything, value number it as a store that // produces a unique memory state (instead of using it's MemoryUse, we use // it's MemoryDef). return createStoreExpression(SI, StoreAccess); } // See if we can extract the value of a loaded pointer from a load, a store, or // a memory instruction. const Expression * NewGVN::performSymbolicLoadCoercion(Type *LoadType, Value *LoadPtr, LoadInst *LI, Instruction *DepInst, MemoryAccess *DefiningAccess) const { assert((!LI || LI->isSimple()) && "Not a simple load"); if (auto *DepSI = dyn_cast(DepInst)) { // Can't forward from non-atomic to atomic without violating memory model. // Also don't need to coerce if they are the same type, we will just // propagate. if (LI->isAtomic() > DepSI->isAtomic() || LoadType == DepSI->getValueOperand()->getType()) return nullptr; int Offset = analyzeLoadFromClobberingStore(LoadType, LoadPtr, DepSI, DL); if (Offset >= 0) { if (auto *C = dyn_cast( lookupOperandLeader(DepSI->getValueOperand()))) { LLVM_DEBUG(dbgs() << "Coercing load from store " << *DepSI << " to constant " << *C << "\n"); return createConstantExpression( getConstantStoreValueForLoad(C, Offset, LoadType, DL)); } } } else if (auto *DepLI = dyn_cast(DepInst)) { // Can't forward from non-atomic to atomic without violating memory model. if (LI->isAtomic() > DepLI->isAtomic()) return nullptr; int Offset = analyzeLoadFromClobberingLoad(LoadType, LoadPtr, DepLI, DL); if (Offset >= 0) { // We can coerce a constant load into a load. if (auto *C = dyn_cast(lookupOperandLeader(DepLI))) if (auto *PossibleConstant = getConstantLoadValueForLoad(C, Offset, LoadType, DL)) { LLVM_DEBUG(dbgs() << "Coercing load from load " << *LI << " to constant " << *PossibleConstant << "\n"); return createConstantExpression(PossibleConstant); } } } else if (auto *DepMI = dyn_cast(DepInst)) { int Offset = analyzeLoadFromClobberingMemInst(LoadType, LoadPtr, DepMI, DL); if (Offset >= 0) { if (auto *PossibleConstant = getConstantMemInstValueForLoad(DepMI, Offset, LoadType, DL)) { LLVM_DEBUG(dbgs() << "Coercing load from meminst " << *DepMI << " to constant " << *PossibleConstant << "\n"); return createConstantExpression(PossibleConstant); } } } // All of the below are only true if the loaded pointer is produced // by the dependent instruction. if (LoadPtr != lookupOperandLeader(DepInst) && !AA->isMustAlias(LoadPtr, DepInst)) return nullptr; // If this load really doesn't depend on anything, then we must be loading an // undef value. This can happen when loading for a fresh allocation with no // intervening stores, for example. Note that this is only true in the case // that the result of the allocation is pointer equal to the load ptr. if (isa(DepInst) || isMallocLikeFn(DepInst, TLI) || isAlignedAllocLikeFn(DepInst, TLI)) { return createConstantExpression(UndefValue::get(LoadType)); } // If this load occurs either right after a lifetime begin, // then the loaded value is undefined. else if (auto *II = dyn_cast(DepInst)) { if (II->getIntrinsicID() == Intrinsic::lifetime_start) return createConstantExpression(UndefValue::get(LoadType)); } // If this load follows a calloc (which zero initializes memory), // then the loaded value is zero else if (isCallocLikeFn(DepInst, TLI)) { return createConstantExpression(Constant::getNullValue(LoadType)); } return nullptr; } const Expression *NewGVN::performSymbolicLoadEvaluation(Instruction *I) const { auto *LI = cast(I); // We can eliminate in favor of non-simple loads, but we won't be able to // eliminate the loads themselves. if (!LI->isSimple()) return nullptr; Value *LoadAddressLeader = lookupOperandLeader(LI->getPointerOperand()); // Load of undef is undef. if (isa(LoadAddressLeader)) return createConstantExpression(UndefValue::get(LI->getType())); MemoryAccess *OriginalAccess = getMemoryAccess(I); MemoryAccess *DefiningAccess = MSSAWalker->getClobberingMemoryAccess(OriginalAccess); if (!MSSA->isLiveOnEntryDef(DefiningAccess)) { if (auto *MD = dyn_cast(DefiningAccess)) { Instruction *DefiningInst = MD->getMemoryInst(); // If the defining instruction is not reachable, replace with undef. if (!ReachableBlocks.count(DefiningInst->getParent())) return createConstantExpression(UndefValue::get(LI->getType())); // This will handle stores and memory insts. We only do if it the // defining access has a different type, or it is a pointer produced by // certain memory operations that cause the memory to have a fixed value // (IE things like calloc). if (const auto *CoercionResult = performSymbolicLoadCoercion(LI->getType(), LoadAddressLeader, LI, DefiningInst, DefiningAccess)) return CoercionResult; } } const auto *LE = createLoadExpression(LI->getType(), LoadAddressLeader, LI, DefiningAccess); // If our MemoryLeader is not our defining access, add a use to the // MemoryLeader, so that we get reprocessed when it changes. if (LE->getMemoryLeader() != DefiningAccess) addMemoryUsers(LE->getMemoryLeader(), OriginalAccess); return LE; } const Expression * NewGVN::performSymbolicPredicateInfoEvaluation(Instruction *I) const { auto *PI = PredInfo->getPredicateInfoFor(I); if (!PI) return nullptr; LLVM_DEBUG(dbgs() << "Found predicate info from instruction !\n"); const Optional &Constraint = PI->getConstraint(); if (!Constraint) return nullptr; CmpInst::Predicate Predicate = Constraint->Predicate; Value *CmpOp0 = I->getOperand(0); Value *CmpOp1 = Constraint->OtherOp; Value *FirstOp = lookupOperandLeader(CmpOp0); Value *SecondOp = lookupOperandLeader(CmpOp1); Value *AdditionallyUsedValue = CmpOp0; // Sort the ops. if (shouldSwapOperands(FirstOp, SecondOp)) { std::swap(FirstOp, SecondOp); Predicate = CmpInst::getSwappedPredicate(Predicate); AdditionallyUsedValue = CmpOp1; } if (Predicate == CmpInst::ICMP_EQ) { addPredicateUsers(PI, I); addAdditionalUsers(AdditionallyUsedValue, I); return createVariableOrConstant(FirstOp); } // Handle the special case of floating point. if (Predicate == CmpInst::FCMP_OEQ && isa(FirstOp) && !cast(FirstOp)->isZero()) { addPredicateUsers(PI, I); addAdditionalUsers(AdditionallyUsedValue, I); return createConstantExpression(cast(FirstOp)); } return nullptr; } // Evaluate read only and pure calls, and create an expression result. const Expression *NewGVN::performSymbolicCallEvaluation(Instruction *I) const { auto *CI = cast(I); if (auto *II = dyn_cast(I)) { // Intrinsics with the returned attribute are copies of arguments. if (auto *ReturnedValue = II->getReturnedArgOperand()) { if (II->getIntrinsicID() == Intrinsic::ssa_copy) if (const auto *Result = performSymbolicPredicateInfoEvaluation(I)) return Result; return createVariableOrConstant(ReturnedValue); } } if (AA->doesNotAccessMemory(CI)) { return createCallExpression(CI, TOPClass->getMemoryLeader()); } else if (AA->onlyReadsMemory(CI)) { if (auto *MA = MSSA->getMemoryAccess(CI)) { auto *DefiningAccess = MSSAWalker->getClobberingMemoryAccess(MA); return createCallExpression(CI, DefiningAccess); } else // MSSA determined that CI does not access memory. return createCallExpression(CI, TOPClass->getMemoryLeader()); } return nullptr; } // Retrieve the memory class for a given MemoryAccess. CongruenceClass *NewGVN::getMemoryClass(const MemoryAccess *MA) const { auto *Result = MemoryAccessToClass.lookup(MA); assert(Result && "Should have found memory class"); return Result; } // Update the MemoryAccess equivalence table to say that From is equal to To, // and return true if this is different from what already existed in the table. bool NewGVN::setMemoryClass(const MemoryAccess *From, CongruenceClass *NewClass) { assert(NewClass && "Every MemoryAccess should be getting mapped to a non-null class"); LLVM_DEBUG(dbgs() << "Setting " << *From); LLVM_DEBUG(dbgs() << " equivalent to congruence class "); LLVM_DEBUG(dbgs() << NewClass->getID() << " with current MemoryAccess leader "); LLVM_DEBUG(dbgs() << *NewClass->getMemoryLeader() << "\n"); auto LookupResult = MemoryAccessToClass.find(From); bool Changed = false; // If it's already in the table, see if the value changed. if (LookupResult != MemoryAccessToClass.end()) { auto *OldClass = LookupResult->second; if (OldClass != NewClass) { // If this is a phi, we have to handle memory member updates. if (auto *MP = dyn_cast(From)) { OldClass->memory_erase(MP); NewClass->memory_insert(MP); // This may have killed the class if it had no non-memory members if (OldClass->getMemoryLeader() == From) { if (OldClass->definesNoMemory()) { OldClass->setMemoryLeader(nullptr); } else { OldClass->setMemoryLeader(getNextMemoryLeader(OldClass)); LLVM_DEBUG(dbgs() << "Memory class leader change for class " << OldClass->getID() << " to " << *OldClass->getMemoryLeader() << " due to removal of a memory member " << *From << "\n"); markMemoryLeaderChangeTouched(OldClass); } } } // It wasn't equivalent before, and now it is. LookupResult->second = NewClass; Changed = true; } } return Changed; } // Determine if a instruction is cycle-free. That means the values in the // instruction don't depend on any expressions that can change value as a result // of the instruction. For example, a non-cycle free instruction would be v = // phi(0, v+1). bool NewGVN::isCycleFree(const Instruction *I) const { // In order to compute cycle-freeness, we do SCC finding on the instruction, // and see what kind of SCC it ends up in. If it is a singleton, it is // cycle-free. If it is not in a singleton, it is only cycle free if the // other members are all phi nodes (as they do not compute anything, they are // copies). auto ICS = InstCycleState.lookup(I); if (ICS == ICS_Unknown) { SCCFinder.Start(I); auto &SCC = SCCFinder.getComponentFor(I); // It's cycle free if it's size 1 or the SCC is *only* phi nodes. if (SCC.size() == 1) InstCycleState.insert({I, ICS_CycleFree}); else { bool AllPhis = llvm::all_of(SCC, [](const Value *V) { return isa(V) || isCopyOfAPHI(V); }); ICS = AllPhis ? ICS_CycleFree : ICS_Cycle; for (auto *Member : SCC) if (auto *MemberPhi = dyn_cast(Member)) InstCycleState.insert({MemberPhi, ICS}); } } if (ICS == ICS_Cycle) return false; return true; } // Evaluate PHI nodes symbolically and create an expression result. const Expression * NewGVN::performSymbolicPHIEvaluation(ArrayRef PHIOps, Instruction *I, BasicBlock *PHIBlock) const { // True if one of the incoming phi edges is a backedge. bool HasBackedge = false; // All constant tracks the state of whether all the *original* phi operands // This is really shorthand for "this phi cannot cycle due to forward // change in value of the phi is guaranteed not to later change the value of // the phi. IE it can't be v = phi(undef, v+1) bool OriginalOpsConstant = true; auto *E = cast(createPHIExpression( PHIOps, I, PHIBlock, HasBackedge, OriginalOpsConstant)); // We match the semantics of SimplifyPhiNode from InstructionSimplify here. // See if all arguments are the same. // We track if any were undef because they need special handling. bool HasUndef = false; auto Filtered = make_filter_range(E->operands(), [&](Value *Arg) { if (isa(Arg)) { HasUndef = true; return false; } return true; }); // If we are left with no operands, it's dead. if (Filtered.empty()) { // If it has undef at this point, it means there are no-non-undef arguments, // and thus, the value of the phi node must be undef. if (HasUndef) { LLVM_DEBUG( dbgs() << "PHI Node " << *I << " has no non-undef arguments, valuing it as undef\n"); return createConstantExpression(UndefValue::get(I->getType())); } LLVM_DEBUG(dbgs() << "No arguments of PHI node " << *I << " are live\n"); deleteExpression(E); return createDeadExpression(); } Value *AllSameValue = *(Filtered.begin()); ++Filtered.begin(); // Can't use std::equal here, sadly, because filter.begin moves. if (llvm::all_of(Filtered, [&](Value *Arg) { return Arg == AllSameValue; })) { // In LLVM's non-standard representation of phi nodes, it's possible to have // phi nodes with cycles (IE dependent on other phis that are .... dependent // on the original phi node), especially in weird CFG's where some arguments // are unreachable, or uninitialized along certain paths. This can cause // infinite loops during evaluation. We work around this by not trying to // really evaluate them independently, but instead using a variable // expression to say if one is equivalent to the other. // We also special case undef, so that if we have an undef, we can't use the // common value unless it dominates the phi block. if (HasUndef) { // If we have undef and at least one other value, this is really a // multivalued phi, and we need to know if it's cycle free in order to // evaluate whether we can ignore the undef. The other parts of this are // just shortcuts. If there is no backedge, or all operands are // constants, it also must be cycle free. if (HasBackedge && !OriginalOpsConstant && !isa(AllSameValue) && !isCycleFree(I)) return E; // Only have to check for instructions if (auto *AllSameInst = dyn_cast(AllSameValue)) if (!someEquivalentDominates(AllSameInst, I)) return E; } // Can't simplify to something that comes later in the iteration. // Otherwise, when and if it changes congruence class, we will never catch // up. We will always be a class behind it. if (isa(AllSameValue) && InstrToDFSNum(AllSameValue) > InstrToDFSNum(I)) return E; NumGVNPhisAllSame++; LLVM_DEBUG(dbgs() << "Simplified PHI node " << *I << " to " << *AllSameValue << "\n"); deleteExpression(E); return createVariableOrConstant(AllSameValue); } return E; } const Expression * NewGVN::performSymbolicAggrValueEvaluation(Instruction *I) const { if (auto *EI = dyn_cast(I)) { auto *WO = dyn_cast(EI->getAggregateOperand()); if (WO && EI->getNumIndices() == 1 && *EI->idx_begin() == 0) // EI is an extract from one of our with.overflow intrinsics. Synthesize // a semantically equivalent expression instead of an extract value // expression. return createBinaryExpression(WO->getBinaryOp(), EI->getType(), WO->getLHS(), WO->getRHS(), I); } return createAggregateValueExpression(I); } const Expression *NewGVN::performSymbolicCmpEvaluation(Instruction *I) const { assert(isa(I) && "Expected a cmp instruction."); auto *CI = cast(I); // See if our operands are equal to those of a previous predicate, and if so, // if it implies true or false. auto Op0 = lookupOperandLeader(CI->getOperand(0)); auto Op1 = lookupOperandLeader(CI->getOperand(1)); auto OurPredicate = CI->getPredicate(); if (shouldSwapOperands(Op0, Op1)) { std::swap(Op0, Op1); OurPredicate = CI->getSwappedPredicate(); } // Avoid processing the same info twice. const PredicateBase *LastPredInfo = nullptr; // See if we know something about the comparison itself, like it is the target // of an assume. auto *CmpPI = PredInfo->getPredicateInfoFor(I); if (dyn_cast_or_null(CmpPI)) return createConstantExpression(ConstantInt::getTrue(CI->getType())); if (Op0 == Op1) { // This condition does not depend on predicates, no need to add users if (CI->isTrueWhenEqual()) return createConstantExpression(ConstantInt::getTrue(CI->getType())); else if (CI->isFalseWhenEqual()) return createConstantExpression(ConstantInt::getFalse(CI->getType())); } // NOTE: Because we are comparing both operands here and below, and using // previous comparisons, we rely on fact that predicateinfo knows to mark // comparisons that use renamed operands as users of the earlier comparisons. // It is *not* enough to just mark predicateinfo renamed operands as users of // the earlier comparisons, because the *other* operand may have changed in a // previous iteration. // Example: // icmp slt %a, %b // %b.0 = ssa.copy(%b) // false branch: // icmp slt %c, %b.0 // %c and %a may start out equal, and thus, the code below will say the second // %icmp is false. c may become equal to something else, and in that case the // %second icmp *must* be reexamined, but would not if only the renamed // %operands are considered users of the icmp. // *Currently* we only check one level of comparisons back, and only mark one // level back as touched when changes happen. If you modify this code to look // back farther through comparisons, you *must* mark the appropriate // comparisons as users in PredicateInfo.cpp, or you will cause bugs. See if // we know something just from the operands themselves // See if our operands have predicate info, so that we may be able to derive // something from a previous comparison. for (const auto &Op : CI->operands()) { auto *PI = PredInfo->getPredicateInfoFor(Op); if (const auto *PBranch = dyn_cast_or_null(PI)) { if (PI == LastPredInfo) continue; LastPredInfo = PI; // In phi of ops cases, we may have predicate info that we are evaluating // in a different context. if (!DT->dominates(PBranch->To, getBlockForValue(I))) continue; // TODO: Along the false edge, we may know more things too, like // icmp of // same operands is false. // TODO: We only handle actual comparison conditions below, not // and/or. auto *BranchCond = dyn_cast(PBranch->Condition); if (!BranchCond) continue; auto *BranchOp0 = lookupOperandLeader(BranchCond->getOperand(0)); auto *BranchOp1 = lookupOperandLeader(BranchCond->getOperand(1)); auto BranchPredicate = BranchCond->getPredicate(); if (shouldSwapOperands(BranchOp0, BranchOp1)) { std::swap(BranchOp0, BranchOp1); BranchPredicate = BranchCond->getSwappedPredicate(); } if (BranchOp0 == Op0 && BranchOp1 == Op1) { if (PBranch->TrueEdge) { // If we know the previous predicate is true and we are in the true // edge then we may be implied true or false. if (CmpInst::isImpliedTrueByMatchingCmp(BranchPredicate, OurPredicate)) { addPredicateUsers(PI, I); return createConstantExpression( ConstantInt::getTrue(CI->getType())); } if (CmpInst::isImpliedFalseByMatchingCmp(BranchPredicate, OurPredicate)) { addPredicateUsers(PI, I); return createConstantExpression( ConstantInt::getFalse(CI->getType())); } } else { // Just handle the ne and eq cases, where if we have the same // operands, we may know something. if (BranchPredicate == OurPredicate) { addPredicateUsers(PI, I); // Same predicate, same ops,we know it was false, so this is false. return createConstantExpression( ConstantInt::getFalse(CI->getType())); } else if (BranchPredicate == CmpInst::getInversePredicate(OurPredicate)) { addPredicateUsers(PI, I); // Inverse predicate, we know the other was false, so this is true. return createConstantExpression( ConstantInt::getTrue(CI->getType())); } } } } } // Create expression will take care of simplifyCmpInst return createExpression(I); } // Substitute and symbolize the value before value numbering. const Expression * NewGVN::performSymbolicEvaluation(Value *V, SmallPtrSetImpl &Visited) const { const Expression *E = nullptr; if (auto *C = dyn_cast(V)) E = createConstantExpression(C); else if (isa(V) || isa(V)) { E = createVariableExpression(V); } else { // TODO: memory intrinsics. // TODO: Some day, we should do the forward propagation and reassociation // parts of the algorithm. auto *I = cast(V); switch (I->getOpcode()) { case Instruction::ExtractValue: case Instruction::InsertValue: E = performSymbolicAggrValueEvaluation(I); break; case Instruction::PHI: { SmallVector Ops; auto *PN = cast(I); for (unsigned i = 0; i < PN->getNumOperands(); ++i) Ops.push_back({PN->getIncomingValue(i), PN->getIncomingBlock(i)}); // Sort to ensure the invariant createPHIExpression requires is met. sortPHIOps(Ops); E = performSymbolicPHIEvaluation(Ops, I, getBlockForValue(I)); } break; case Instruction::Call: E = performSymbolicCallEvaluation(I); break; case Instruction::Store: E = performSymbolicStoreEvaluation(I); break; case Instruction::Load: E = performSymbolicLoadEvaluation(I); break; case Instruction::BitCast: case Instruction::AddrSpaceCast: E = createExpression(I); break; case Instruction::ICmp: case Instruction::FCmp: E = performSymbolicCmpEvaluation(I); break; case Instruction::FNeg: case Instruction::Add: case Instruction::FAdd: case Instruction::Sub: case Instruction::FSub: case Instruction::Mul: case Instruction::FMul: case Instruction::UDiv: case Instruction::SDiv: case Instruction::FDiv: case Instruction::URem: case Instruction::SRem: case Instruction::FRem: case Instruction::Shl: case Instruction::LShr: case Instruction::AShr: case Instruction::And: case Instruction::Or: case Instruction::Xor: case Instruction::Trunc: case Instruction::ZExt: case Instruction::SExt: case Instruction::FPToUI: case Instruction::FPToSI: case Instruction::UIToFP: case Instruction::SIToFP: case Instruction::FPTrunc: case Instruction::FPExt: case Instruction::PtrToInt: case Instruction::IntToPtr: case Instruction::Select: case Instruction::ExtractElement: case Instruction::InsertElement: case Instruction::GetElementPtr: E = createExpression(I); break; case Instruction::ShuffleVector: // FIXME: Add support for shufflevector to createExpression. return nullptr; default: return nullptr; } } return E; } // Look up a container of values/instructions in a map, and touch all the // instructions in the container. Then erase value from the map. template void NewGVN::touchAndErase(Map &M, const KeyType &Key) { const auto Result = M.find_as(Key); if (Result != M.end()) { for (const typename Map::mapped_type::value_type Mapped : Result->second) TouchedInstructions.set(InstrToDFSNum(Mapped)); M.erase(Result); } } void NewGVN::addAdditionalUsers(Value *To, Value *User) const { assert(User && To != User); if (isa(To)) AdditionalUsers[To].insert(User); } void NewGVN::markUsersTouched(Value *V) { // Now mark the users as touched. for (auto *User : V->users()) { assert(isa(User) && "Use of value not within an instruction?"); TouchedInstructions.set(InstrToDFSNum(User)); } touchAndErase(AdditionalUsers, V); } void NewGVN::addMemoryUsers(const MemoryAccess *To, MemoryAccess *U) const { LLVM_DEBUG(dbgs() << "Adding memory user " << *U << " to " << *To << "\n"); MemoryToUsers[To].insert(U); } void NewGVN::markMemoryDefTouched(const MemoryAccess *MA) { TouchedInstructions.set(MemoryToDFSNum(MA)); } void NewGVN::markMemoryUsersTouched(const MemoryAccess *MA) { if (isa(MA)) return; for (auto U : MA->users()) TouchedInstructions.set(MemoryToDFSNum(U)); touchAndErase(MemoryToUsers, MA); } // Add I to the set of users of a given predicate. void NewGVN::addPredicateUsers(const PredicateBase *PB, Instruction *I) const { // Don't add temporary instructions to the user lists. if (AllTempInstructions.count(I)) return; if (auto *PBranch = dyn_cast(PB)) PredicateToUsers[PBranch->Condition].insert(I); else if (auto *PAssume = dyn_cast(PB)) PredicateToUsers[PAssume->Condition].insert(I); } // Touch all the predicates that depend on this instruction. void NewGVN::markPredicateUsersTouched(Instruction *I) { touchAndErase(PredicateToUsers, I); } // Mark users affected by a memory leader change. void NewGVN::markMemoryLeaderChangeTouched(CongruenceClass *CC) { for (auto M : CC->memory()) markMemoryDefTouched(M); } // Touch the instructions that need to be updated after a congruence class has a // leader change, and mark changed values. void NewGVN::markValueLeaderChangeTouched(CongruenceClass *CC) { for (auto M : *CC) { if (auto *I = dyn_cast(M)) TouchedInstructions.set(InstrToDFSNum(I)); LeaderChanges.insert(M); } } // Give a range of things that have instruction DFS numbers, this will return // the member of the range with the smallest dfs number. template T *NewGVN::getMinDFSOfRange(const Range &R) const { std::pair MinDFS = {nullptr, ~0U}; for (const auto X : R) { auto DFSNum = InstrToDFSNum(X); if (DFSNum < MinDFS.second) MinDFS = {X, DFSNum}; } return MinDFS.first; } // This function returns the MemoryAccess that should be the next leader of // congruence class CC, under the assumption that the current leader is going to // disappear. const MemoryAccess *NewGVN::getNextMemoryLeader(CongruenceClass *CC) const { // TODO: If this ends up to slow, we can maintain a next memory leader like we // do for regular leaders. // Make sure there will be a leader to find. assert(!CC->definesNoMemory() && "Can't get next leader if there is none"); if (CC->getStoreCount() > 0) { if (auto *NL = dyn_cast_or_null(CC->getNextLeader().first)) return getMemoryAccess(NL); // Find the store with the minimum DFS number. auto *V = getMinDFSOfRange(make_filter_range( *CC, [&](const Value *V) { return isa(V); })); return getMemoryAccess(cast(V)); } assert(CC->getStoreCount() == 0); // Given our assertion, hitting this part must mean // !OldClass->memory_empty() if (CC->memory_size() == 1) return *CC->memory_begin(); return getMinDFSOfRange(CC->memory()); } // This function returns the next value leader of a congruence class, under the // assumption that the current leader is going away. This should end up being // the next most dominating member. Value *NewGVN::getNextValueLeader(CongruenceClass *CC) const { // We don't need to sort members if there is only 1, and we don't care about // sorting the TOP class because everything either gets out of it or is // unreachable. if (CC->size() == 1 || CC == TOPClass) { return *(CC->begin()); } else if (CC->getNextLeader().first) { ++NumGVNAvoidedSortedLeaderChanges; return CC->getNextLeader().first; } else { ++NumGVNSortedLeaderChanges; // NOTE: If this ends up to slow, we can maintain a dual structure for // member testing/insertion, or keep things mostly sorted, and sort only // here, or use SparseBitVector or .... return getMinDFSOfRange(*CC); } } // Move a MemoryAccess, currently in OldClass, to NewClass, including updates to // the memory members, etc for the move. // // The invariants of this function are: // // - I must be moving to NewClass from OldClass // - The StoreCount of OldClass and NewClass is expected to have been updated // for I already if it is a store. // - The OldClass memory leader has not been updated yet if I was the leader. void NewGVN::moveMemoryToNewCongruenceClass(Instruction *I, MemoryAccess *InstMA, CongruenceClass *OldClass, CongruenceClass *NewClass) { // If the leader is I, and we had a representative MemoryAccess, it should // be the MemoryAccess of OldClass. assert((!InstMA || !OldClass->getMemoryLeader() || OldClass->getLeader() != I || MemoryAccessToClass.lookup(OldClass->getMemoryLeader()) == MemoryAccessToClass.lookup(InstMA)) && "Representative MemoryAccess mismatch"); // First, see what happens to the new class if (!NewClass->getMemoryLeader()) { // Should be a new class, or a store becoming a leader of a new class. assert(NewClass->size() == 1 || (isa(I) && NewClass->getStoreCount() == 1)); NewClass->setMemoryLeader(InstMA); // Mark it touched if we didn't just create a singleton LLVM_DEBUG(dbgs() << "Memory class leader change for class " << NewClass->getID() << " due to new memory instruction becoming leader\n"); markMemoryLeaderChangeTouched(NewClass); } setMemoryClass(InstMA, NewClass); // Now, fixup the old class if necessary if (OldClass->getMemoryLeader() == InstMA) { if (!OldClass->definesNoMemory()) { OldClass->setMemoryLeader(getNextMemoryLeader(OldClass)); LLVM_DEBUG(dbgs() << "Memory class leader change for class " << OldClass->getID() << " to " << *OldClass->getMemoryLeader() << " due to removal of old leader " << *InstMA << "\n"); markMemoryLeaderChangeTouched(OldClass); } else OldClass->setMemoryLeader(nullptr); } } // Move a value, currently in OldClass, to be part of NewClass // Update OldClass and NewClass for the move (including changing leaders, etc). void NewGVN::moveValueToNewCongruenceClass(Instruction *I, const Expression *E, CongruenceClass *OldClass, CongruenceClass *NewClass) { if (I == OldClass->getNextLeader().first) OldClass->resetNextLeader(); OldClass->erase(I); NewClass->insert(I); if (NewClass->getLeader() != I) NewClass->addPossibleNextLeader({I, InstrToDFSNum(I)}); // Handle our special casing of stores. if (auto *SI = dyn_cast(I)) { OldClass->decStoreCount(); // Okay, so when do we want to make a store a leader of a class? // If we have a store defined by an earlier load, we want the earlier load // to lead the class. // If we have a store defined by something else, we want the store to lead // the class so everything else gets the "something else" as a value. // If we have a store as the single member of the class, we want the store // as the leader if (NewClass->getStoreCount() == 0 && !NewClass->getStoredValue()) { // If it's a store expression we are using, it means we are not equivalent // to something earlier. if (auto *SE = dyn_cast(E)) { NewClass->setStoredValue(SE->getStoredValue()); markValueLeaderChangeTouched(NewClass); // Shift the new class leader to be the store LLVM_DEBUG(dbgs() << "Changing leader of congruence class " << NewClass->getID() << " from " << *NewClass->getLeader() << " to " << *SI << " because store joined class\n"); // If we changed the leader, we have to mark it changed because we don't // know what it will do to symbolic evaluation. NewClass->setLeader(SI); } // We rely on the code below handling the MemoryAccess change. } NewClass->incStoreCount(); } // True if there is no memory instructions left in a class that had memory // instructions before. // If it's not a memory use, set the MemoryAccess equivalence auto *InstMA = dyn_cast_or_null(getMemoryAccess(I)); if (InstMA) moveMemoryToNewCongruenceClass(I, InstMA, OldClass, NewClass); ValueToClass[I] = NewClass; // See if we destroyed the class or need to swap leaders. if (OldClass->empty() && OldClass != TOPClass) { if (OldClass->getDefiningExpr()) { LLVM_DEBUG(dbgs() << "Erasing expression " << *OldClass->getDefiningExpr() << " from table\n"); // We erase it as an exact expression to make sure we don't just erase an // equivalent one. auto Iter = ExpressionToClass.find_as( ExactEqualsExpression(*OldClass->getDefiningExpr())); if (Iter != ExpressionToClass.end()) ExpressionToClass.erase(Iter); #ifdef EXPENSIVE_CHECKS assert( (*OldClass->getDefiningExpr() != *E || ExpressionToClass.lookup(E)) && "We erased the expression we just inserted, which should not happen"); #endif } } else if (OldClass->getLeader() == I) { // When the leader changes, the value numbering of // everything may change due to symbolization changes, so we need to // reprocess. LLVM_DEBUG(dbgs() << "Value class leader change for class " << OldClass->getID() << "\n"); ++NumGVNLeaderChanges; // Destroy the stored value if there are no more stores to represent it. // Note that this is basically clean up for the expression removal that // happens below. If we remove stores from a class, we may leave it as a // class of equivalent memory phis. if (OldClass->getStoreCount() == 0) { if (OldClass->getStoredValue()) OldClass->setStoredValue(nullptr); } OldClass->setLeader(getNextValueLeader(OldClass)); OldClass->resetNextLeader(); markValueLeaderChangeTouched(OldClass); } } // For a given expression, mark the phi of ops instructions that could have // changed as a result. void NewGVN::markPhiOfOpsChanged(const Expression *E) { touchAndErase(ExpressionToPhiOfOps, E); } // Perform congruence finding on a given value numbering expression. void NewGVN::performCongruenceFinding(Instruction *I, const Expression *E) { // This is guaranteed to return something, since it will at least find // TOP. CongruenceClass *IClass = ValueToClass.lookup(I); assert(IClass && "Should have found a IClass"); // Dead classes should have been eliminated from the mapping. assert(!IClass->isDead() && "Found a dead class"); CongruenceClass *EClass = nullptr; if (const auto *VE = dyn_cast(E)) { EClass = ValueToClass.lookup(VE->getVariableValue()); } else if (isa(E)) { EClass = TOPClass; } if (!EClass) { auto lookupResult = ExpressionToClass.insert({E, nullptr}); // If it's not in the value table, create a new congruence class. if (lookupResult.second) { CongruenceClass *NewClass = createCongruenceClass(nullptr, E); auto place = lookupResult.first; place->second = NewClass; // Constants and variables should always be made the leader. if (const auto *CE = dyn_cast(E)) { NewClass->setLeader(CE->getConstantValue()); } else if (const auto *SE = dyn_cast(E)) { StoreInst *SI = SE->getStoreInst(); NewClass->setLeader(SI); NewClass->setStoredValue(SE->getStoredValue()); // The RepMemoryAccess field will be filled in properly by the // moveValueToNewCongruenceClass call. } else { NewClass->setLeader(I); } assert(!isa(E) && "VariableExpression should have been handled already"); EClass = NewClass; LLVM_DEBUG(dbgs() << "Created new congruence class for " << *I << " using expression " << *E << " at " << NewClass->getID() << " and leader " << *(NewClass->getLeader())); if (NewClass->getStoredValue()) LLVM_DEBUG(dbgs() << " and stored value " << *(NewClass->getStoredValue())); LLVM_DEBUG(dbgs() << "\n"); } else { EClass = lookupResult.first->second; if (isa(E)) assert((isa(EClass->getLeader()) || (EClass->getStoredValue() && isa(EClass->getStoredValue()))) && "Any class with a constant expression should have a " "constant leader"); assert(EClass && "Somehow don't have an eclass"); assert(!EClass->isDead() && "We accidentally looked up a dead class"); } } bool ClassChanged = IClass != EClass; bool LeaderChanged = LeaderChanges.erase(I); if (ClassChanged || LeaderChanged) { LLVM_DEBUG(dbgs() << "New class " << EClass->getID() << " for expression " << *E << "\n"); if (ClassChanged) { moveValueToNewCongruenceClass(I, E, IClass, EClass); markPhiOfOpsChanged(E); } markUsersTouched(I); if (MemoryAccess *MA = getMemoryAccess(I)) markMemoryUsersTouched(MA); if (auto *CI = dyn_cast(I)) markPredicateUsersTouched(CI); } // If we changed the class of the store, we want to ensure nothing finds the // old store expression. In particular, loads do not compare against stored // value, so they will find old store expressions (and associated class // mappings) if we leave them in the table. if (ClassChanged && isa(I)) { auto *OldE = ValueToExpression.lookup(I); // It could just be that the old class died. We don't want to erase it if we // just moved classes. if (OldE && isa(OldE) && *E != *OldE) { // Erase this as an exact expression to ensure we don't erase expressions // equivalent to it. auto Iter = ExpressionToClass.find_as(ExactEqualsExpression(*OldE)); if (Iter != ExpressionToClass.end()) ExpressionToClass.erase(Iter); } } ValueToExpression[I] = E; } // Process the fact that Edge (from, to) is reachable, including marking // any newly reachable blocks and instructions for processing. void NewGVN::updateReachableEdge(BasicBlock *From, BasicBlock *To) { // Check if the Edge was reachable before. if (ReachableEdges.insert({From, To}).second) { // If this block wasn't reachable before, all instructions are touched. if (ReachableBlocks.insert(To).second) { LLVM_DEBUG(dbgs() << "Block " << getBlockName(To) << " marked reachable\n"); const auto &InstRange = BlockInstRange.lookup(To); TouchedInstructions.set(InstRange.first, InstRange.second); } else { LLVM_DEBUG(dbgs() << "Block " << getBlockName(To) << " was reachable, but new edge {" << getBlockName(From) << "," << getBlockName(To) << "} to it found\n"); // We've made an edge reachable to an existing block, which may // impact predicates. Otherwise, only mark the phi nodes as touched, as // they are the only thing that depend on new edges. Anything using their // values will get propagated to if necessary. if (MemoryAccess *MemPhi = getMemoryAccess(To)) TouchedInstructions.set(InstrToDFSNum(MemPhi)); // FIXME: We should just add a union op on a Bitvector and // SparseBitVector. We can do it word by word faster than we are doing it // here. for (auto InstNum : RevisitOnReachabilityChange[To]) TouchedInstructions.set(InstNum); } } } // Given a predicate condition (from a switch, cmp, or whatever) and a block, // see if we know some constant value for it already. Value *NewGVN::findConditionEquivalence(Value *Cond) const { auto Result = lookupOperandLeader(Cond); return isa(Result) ? Result : nullptr; } // Process the outgoing edges of a block for reachability. void NewGVN::processOutgoingEdges(Instruction *TI, BasicBlock *B) { // Evaluate reachability of terminator instruction. Value *Cond; BasicBlock *TrueSucc, *FalseSucc; if (match(TI, m_Br(m_Value(Cond), TrueSucc, FalseSucc))) { Value *CondEvaluated = findConditionEquivalence(Cond); if (!CondEvaluated) { if (auto *I = dyn_cast(Cond)) { const Expression *E = createExpression(I); if (const auto *CE = dyn_cast(E)) { CondEvaluated = CE->getConstantValue(); } } else if (isa(Cond)) { CondEvaluated = Cond; } } ConstantInt *CI; if (CondEvaluated && (CI = dyn_cast(CondEvaluated))) { if (CI->isOne()) { LLVM_DEBUG(dbgs() << "Condition for Terminator " << *TI << " evaluated to true\n"); updateReachableEdge(B, TrueSucc); } else if (CI->isZero()) { LLVM_DEBUG(dbgs() << "Condition for Terminator " << *TI << " evaluated to false\n"); updateReachableEdge(B, FalseSucc); } } else { updateReachableEdge(B, TrueSucc); updateReachableEdge(B, FalseSucc); } } else if (auto *SI = dyn_cast(TI)) { // For switches, propagate the case values into the case // destinations. Value *SwitchCond = SI->getCondition(); Value *CondEvaluated = findConditionEquivalence(SwitchCond); // See if we were able to turn this switch statement into a constant. if (CondEvaluated && isa(CondEvaluated)) { auto *CondVal = cast(CondEvaluated); // We should be able to get case value for this. auto Case = *SI->findCaseValue(CondVal); if (Case.getCaseSuccessor() == SI->getDefaultDest()) { // We proved the value is outside of the range of the case. // We can't do anything other than mark the default dest as reachable, // and go home. updateReachableEdge(B, SI->getDefaultDest()); return; } // Now get where it goes and mark it reachable. BasicBlock *TargetBlock = Case.getCaseSuccessor(); updateReachableEdge(B, TargetBlock); } else { for (unsigned i = 0, e = SI->getNumSuccessors(); i != e; ++i) { BasicBlock *TargetBlock = SI->getSuccessor(i); updateReachableEdge(B, TargetBlock); } } } else { // Otherwise this is either unconditional, or a type we have no // idea about. Just mark successors as reachable. for (unsigned i = 0, e = TI->getNumSuccessors(); i != e; ++i) { BasicBlock *TargetBlock = TI->getSuccessor(i); updateReachableEdge(B, TargetBlock); } // This also may be a memory defining terminator, in which case, set it // equivalent only to itself. // auto *MA = getMemoryAccess(TI); if (MA && !isa(MA)) { auto *CC = ensureLeaderOfMemoryClass(MA); if (setMemoryClass(MA, CC)) markMemoryUsersTouched(MA); } } } // Remove the PHI of Ops PHI for I void NewGVN::removePhiOfOps(Instruction *I, PHINode *PHITemp) { InstrDFS.erase(PHITemp); // It's still a temp instruction. We keep it in the array so it gets erased. // However, it's no longer used by I, or in the block TempToBlock.erase(PHITemp); RealToTemp.erase(I); // We don't remove the users from the phi node uses. This wastes a little // time, but such is life. We could use two sets to track which were there // are the start of NewGVN, and which were added, but right nowt he cost of // tracking is more than the cost of checking for more phi of ops. } // Add PHI Op in BB as a PHI of operations version of ExistingValue. void NewGVN::addPhiOfOps(PHINode *Op, BasicBlock *BB, Instruction *ExistingValue) { InstrDFS[Op] = InstrToDFSNum(ExistingValue); AllTempInstructions.insert(Op); TempToBlock[Op] = BB; RealToTemp[ExistingValue] = Op; // Add all users to phi node use, as they are now uses of the phi of ops phis // and may themselves be phi of ops. for (auto *U : ExistingValue->users()) if (auto *UI = dyn_cast(U)) PHINodeUses.insert(UI); } static bool okayForPHIOfOps(const Instruction *I) { if (!EnablePhiOfOps) return false; return isa(I) || isa(I) || isa(I) || isa(I); } bool NewGVN::OpIsSafeForPHIOfOpsHelper( Value *V, const BasicBlock *PHIBlock, SmallPtrSetImpl &Visited, SmallVectorImpl &Worklist) { if (!isa(V)) return true; auto OISIt = OpSafeForPHIOfOps.find(V); if (OISIt != OpSafeForPHIOfOps.end()) return OISIt->second; // Keep walking until we either dominate the phi block, or hit a phi, or run // out of things to check. if (DT->properlyDominates(getBlockForValue(V), PHIBlock)) { OpSafeForPHIOfOps.insert({V, true}); return true; } // PHI in the same block. if (isa(V) && getBlockForValue(V) == PHIBlock) { OpSafeForPHIOfOps.insert({V, false}); return false; } auto *OrigI = cast(V); for (auto *Op : OrigI->operand_values()) { if (!isa(Op)) continue; // Stop now if we find an unsafe operand. auto OISIt = OpSafeForPHIOfOps.find(OrigI); if (OISIt != OpSafeForPHIOfOps.end()) { if (!OISIt->second) { OpSafeForPHIOfOps.insert({V, false}); return false; } continue; } if (!Visited.insert(Op).second) continue; Worklist.push_back(cast(Op)); } return true; } // Return true if this operand will be safe to use for phi of ops. // // The reason some operands are unsafe is that we are not trying to recursively // translate everything back through phi nodes. We actually expect some lookups // of expressions to fail. In particular, a lookup where the expression cannot // exist in the predecessor. This is true even if the expression, as shown, can // be determined to be constant. bool NewGVN::OpIsSafeForPHIOfOps(Value *V, const BasicBlock *PHIBlock, SmallPtrSetImpl &Visited) { SmallVector Worklist; if (!OpIsSafeForPHIOfOpsHelper(V, PHIBlock, Visited, Worklist)) return false; while (!Worklist.empty()) { auto *I = Worklist.pop_back_val(); if (!OpIsSafeForPHIOfOpsHelper(I, PHIBlock, Visited, Worklist)) return false; } OpSafeForPHIOfOps.insert({V, true}); return true; } // Try to find a leader for instruction TransInst, which is a phi translated // version of something in our original program. Visited is used to ensure we // don't infinite loop during translations of cycles. OrigInst is the // instruction in the original program, and PredBB is the predecessor we // translated it through. Value *NewGVN::findLeaderForInst(Instruction *TransInst, SmallPtrSetImpl &Visited, MemoryAccess *MemAccess, Instruction *OrigInst, BasicBlock *PredBB) { unsigned IDFSNum = InstrToDFSNum(OrigInst); // Make sure it's marked as a temporary instruction. AllTempInstructions.insert(TransInst); // and make sure anything that tries to add it's DFS number is // redirected to the instruction we are making a phi of ops // for. TempToBlock.insert({TransInst, PredBB}); InstrDFS.insert({TransInst, IDFSNum}); const Expression *E = performSymbolicEvaluation(TransInst, Visited); InstrDFS.erase(TransInst); AllTempInstructions.erase(TransInst); TempToBlock.erase(TransInst); if (MemAccess) TempToMemory.erase(TransInst); if (!E) return nullptr; auto *FoundVal = findPHIOfOpsLeader(E, OrigInst, PredBB); if (!FoundVal) { ExpressionToPhiOfOps[E].insert(OrigInst); LLVM_DEBUG(dbgs() << "Cannot find phi of ops operand for " << *TransInst << " in block " << getBlockName(PredBB) << "\n"); return nullptr; } if (auto *SI = dyn_cast(FoundVal)) FoundVal = SI->getValueOperand(); return FoundVal; } // When we see an instruction that is an op of phis, generate the equivalent phi // of ops form. const Expression * NewGVN::makePossiblePHIOfOps(Instruction *I, SmallPtrSetImpl &Visited) { if (!okayForPHIOfOps(I)) return nullptr; if (!Visited.insert(I).second) return nullptr; // For now, we require the instruction be cycle free because we don't // *always* create a phi of ops for instructions that could be done as phi // of ops, we only do it if we think it is useful. If we did do it all the // time, we could remove the cycle free check. if (!isCycleFree(I)) return nullptr; SmallPtrSet ProcessedPHIs; // TODO: We don't do phi translation on memory accesses because it's // complicated. For a load, we'd need to be able to simulate a new memoryuse, // which we don't have a good way of doing ATM. auto *MemAccess = getMemoryAccess(I); // If the memory operation is defined by a memory operation this block that // isn't a MemoryPhi, transforming the pointer backwards through a scalar phi // can't help, as it would still be killed by that memory operation. if (MemAccess && !isa(MemAccess->getDefiningAccess()) && MemAccess->getDefiningAccess()->getBlock() == I->getParent()) return nullptr; // Convert op of phis to phi of ops SmallPtrSet VisitedOps; SmallVector Ops(I->operand_values()); BasicBlock *SamePHIBlock = nullptr; PHINode *OpPHI = nullptr; if (!DebugCounter::shouldExecute(PHIOfOpsCounter)) return nullptr; for (auto *Op : Ops) { if (!isa(Op)) { auto *ValuePHI = RealToTemp.lookup(Op); if (!ValuePHI) continue; LLVM_DEBUG(dbgs() << "Found possible dependent phi of ops\n"); Op = ValuePHI; } OpPHI = cast(Op); if (!SamePHIBlock) { SamePHIBlock = getBlockForValue(OpPHI); } else if (SamePHIBlock != getBlockForValue(OpPHI)) { LLVM_DEBUG( dbgs() << "PHIs for operands are not all in the same block, aborting\n"); return nullptr; } // No point in doing this for one-operand phis. if (OpPHI->getNumOperands() == 1) { OpPHI = nullptr; continue; } } if (!OpPHI) return nullptr; SmallVector PHIOps; SmallPtrSet Deps; auto *PHIBlock = getBlockForValue(OpPHI); RevisitOnReachabilityChange[PHIBlock].reset(InstrToDFSNum(I)); for (unsigned PredNum = 0; PredNum < OpPHI->getNumOperands(); ++PredNum) { auto *PredBB = OpPHI->getIncomingBlock(PredNum); Value *FoundVal = nullptr; SmallPtrSet CurrentDeps; // We could just skip unreachable edges entirely but it's tricky to do // with rewriting existing phi nodes. if (ReachableEdges.count({PredBB, PHIBlock})) { // Clone the instruction, create an expression from it that is // translated back into the predecessor, and see if we have a leader. Instruction *ValueOp = I->clone(); if (MemAccess) TempToMemory.insert({ValueOp, MemAccess}); bool SafeForPHIOfOps = true; VisitedOps.clear(); for (auto &Op : ValueOp->operands()) { auto *OrigOp = &*Op; // When these operand changes, it could change whether there is a // leader for us or not, so we have to add additional users. if (isa(Op)) { Op = Op->DoPHITranslation(PHIBlock, PredBB); if (Op != OrigOp && Op != I) CurrentDeps.insert(Op); } else if (auto *ValuePHI = RealToTemp.lookup(Op)) { if (getBlockForValue(ValuePHI) == PHIBlock) Op = ValuePHI->getIncomingValueForBlock(PredBB); } // If we phi-translated the op, it must be safe. SafeForPHIOfOps = SafeForPHIOfOps && (Op != OrigOp || OpIsSafeForPHIOfOps(Op, PHIBlock, VisitedOps)); } // FIXME: For those things that are not safe we could generate // expressions all the way down, and see if this comes out to a // constant. For anything where that is true, and unsafe, we should // have made a phi-of-ops (or value numbered it equivalent to something) // for the pieces already. FoundVal = !SafeForPHIOfOps ? nullptr : findLeaderForInst(ValueOp, Visited, MemAccess, I, PredBB); ValueOp->deleteValue(); if (!FoundVal) { // We failed to find a leader for the current ValueOp, but this might // change in case of the translated operands change. if (SafeForPHIOfOps) for (auto Dep : CurrentDeps) addAdditionalUsers(Dep, I); return nullptr; } Deps.insert(CurrentDeps.begin(), CurrentDeps.end()); } else { LLVM_DEBUG(dbgs() << "Skipping phi of ops operand for incoming block " << getBlockName(PredBB) << " because the block is unreachable\n"); FoundVal = UndefValue::get(I->getType()); RevisitOnReachabilityChange[PHIBlock].set(InstrToDFSNum(I)); } PHIOps.push_back({FoundVal, PredBB}); LLVM_DEBUG(dbgs() << "Found phi of ops operand " << *FoundVal << " in " << getBlockName(PredBB) << "\n"); } for (auto Dep : Deps) addAdditionalUsers(Dep, I); sortPHIOps(PHIOps); auto *E = performSymbolicPHIEvaluation(PHIOps, I, PHIBlock); if (isa(E) || isa(E)) { LLVM_DEBUG( dbgs() << "Not creating real PHI of ops because it simplified to existing " "value or constant\n"); return E; } auto *ValuePHI = RealToTemp.lookup(I); bool NewPHI = false; if (!ValuePHI) { ValuePHI = PHINode::Create(I->getType(), OpPHI->getNumOperands(), "phiofops"); addPhiOfOps(ValuePHI, PHIBlock, I); NewPHI = true; NumGVNPHIOfOpsCreated++; } if (NewPHI) { for (auto PHIOp : PHIOps) ValuePHI->addIncoming(PHIOp.first, PHIOp.second); } else { TempToBlock[ValuePHI] = PHIBlock; unsigned int i = 0; for (auto PHIOp : PHIOps) { ValuePHI->setIncomingValue(i, PHIOp.first); ValuePHI->setIncomingBlock(i, PHIOp.second); ++i; } } RevisitOnReachabilityChange[PHIBlock].set(InstrToDFSNum(I)); LLVM_DEBUG(dbgs() << "Created phi of ops " << *ValuePHI << " for " << *I << "\n"); return E; } // The algorithm initially places the values of the routine in the TOP // congruence class. The leader of TOP is the undetermined value `undef`. // When the algorithm has finished, values still in TOP are unreachable. void NewGVN::initializeCongruenceClasses(Function &F) { NextCongruenceNum = 0; // Note that even though we use the live on entry def as a representative // MemoryAccess, it is *not* the same as the actual live on entry def. We // have no real equivalemnt to undef for MemoryAccesses, and so we really // should be checking whether the MemoryAccess is top if we want to know if it // is equivalent to everything. Otherwise, what this really signifies is that // the access "it reaches all the way back to the beginning of the function" // Initialize all other instructions to be in TOP class. TOPClass = createCongruenceClass(nullptr, nullptr); TOPClass->setMemoryLeader(MSSA->getLiveOnEntryDef()); // The live on entry def gets put into it's own class MemoryAccessToClass[MSSA->getLiveOnEntryDef()] = createMemoryClass(MSSA->getLiveOnEntryDef()); for (auto DTN : nodes(DT)) { BasicBlock *BB = DTN->getBlock(); // All MemoryAccesses are equivalent to live on entry to start. They must // be initialized to something so that initial changes are noticed. For // the maximal answer, we initialize them all to be the same as // liveOnEntry. auto *MemoryBlockDefs = MSSA->getBlockDefs(BB); if (MemoryBlockDefs) for (const auto &Def : *MemoryBlockDefs) { MemoryAccessToClass[&Def] = TOPClass; auto *MD = dyn_cast(&Def); // Insert the memory phis into the member list. if (!MD) { const MemoryPhi *MP = cast(&Def); TOPClass->memory_insert(MP); MemoryPhiState.insert({MP, MPS_TOP}); } if (MD && isa(MD->getMemoryInst())) TOPClass->incStoreCount(); } // FIXME: This is trying to discover which instructions are uses of phi // nodes. We should move this into one of the myriad of places that walk // all the operands already. for (auto &I : *BB) { if (isa(&I)) for (auto *U : I.users()) if (auto *UInst = dyn_cast(U)) if (InstrToDFSNum(UInst) != 0 && okayForPHIOfOps(UInst)) PHINodeUses.insert(UInst); // Don't insert void terminators into the class. We don't value number // them, and they just end up sitting in TOP. if (I.isTerminator() && I.getType()->isVoidTy()) continue; TOPClass->insert(&I); ValueToClass[&I] = TOPClass; } } // Initialize arguments to be in their own unique congruence classes for (auto &FA : F.args()) createSingletonCongruenceClass(&FA); } void NewGVN::cleanupTables() { for (unsigned i = 0, e = CongruenceClasses.size(); i != e; ++i) { LLVM_DEBUG(dbgs() << "Congruence class " << CongruenceClasses[i]->getID() << " has " << CongruenceClasses[i]->size() << " members\n"); // Make sure we delete the congruence class (probably worth switching to // a unique_ptr at some point. delete CongruenceClasses[i]; CongruenceClasses[i] = nullptr; } // Destroy the value expressions SmallVector TempInst(AllTempInstructions.begin(), AllTempInstructions.end()); AllTempInstructions.clear(); // We have to drop all references for everything first, so there are no uses // left as we delete them. for (auto *I : TempInst) { I->dropAllReferences(); } while (!TempInst.empty()) { auto *I = TempInst.pop_back_val(); I->deleteValue(); } ValueToClass.clear(); ArgRecycler.clear(ExpressionAllocator); ExpressionAllocator.Reset(); CongruenceClasses.clear(); ExpressionToClass.clear(); ValueToExpression.clear(); RealToTemp.clear(); AdditionalUsers.clear(); ExpressionToPhiOfOps.clear(); TempToBlock.clear(); TempToMemory.clear(); PHINodeUses.clear(); OpSafeForPHIOfOps.clear(); ReachableBlocks.clear(); ReachableEdges.clear(); #ifndef NDEBUG ProcessedCount.clear(); #endif InstrDFS.clear(); InstructionsToErase.clear(); DFSToInstr.clear(); BlockInstRange.clear(); TouchedInstructions.clear(); MemoryAccessToClass.clear(); PredicateToUsers.clear(); MemoryToUsers.clear(); RevisitOnReachabilityChange.clear(); } // Assign local DFS number mapping to instructions, and leave space for Value // PHI's. std::pair NewGVN::assignDFSNumbers(BasicBlock *B, unsigned Start) { unsigned End = Start; if (MemoryAccess *MemPhi = getMemoryAccess(B)) { InstrDFS[MemPhi] = End++; DFSToInstr.emplace_back(MemPhi); } // Then the real block goes next. for (auto &I : *B) { // There's no need to call isInstructionTriviallyDead more than once on // an instruction. Therefore, once we know that an instruction is dead // we change its DFS number so that it doesn't get value numbered. if (isInstructionTriviallyDead(&I, TLI)) { InstrDFS[&I] = 0; LLVM_DEBUG(dbgs() << "Skipping trivially dead instruction " << I << "\n"); markInstructionForDeletion(&I); continue; } if (isa(&I)) RevisitOnReachabilityChange[B].set(End); InstrDFS[&I] = End++; DFSToInstr.emplace_back(&I); } // All of the range functions taken half-open ranges (open on the end side). // So we do not subtract one from count, because at this point it is one // greater than the last instruction. return std::make_pair(Start, End); } void NewGVN::updateProcessedCount(const Value *V) { #ifndef NDEBUG if (ProcessedCount.count(V) == 0) { ProcessedCount.insert({V, 1}); } else { ++ProcessedCount[V]; assert(ProcessedCount[V] < 100 && "Seem to have processed the same Value a lot"); } #endif } // Evaluate MemoryPhi nodes symbolically, just like PHI nodes void NewGVN::valueNumberMemoryPhi(MemoryPhi *MP) { // If all the arguments are the same, the MemoryPhi has the same value as the // argument. Filter out unreachable blocks and self phis from our operands. // TODO: We could do cycle-checking on the memory phis to allow valueizing for // self-phi checking. const BasicBlock *PHIBlock = MP->getBlock(); auto Filtered = make_filter_range(MP->operands(), [&](const Use &U) { return cast(U) != MP && !isMemoryAccessTOP(cast(U)) && ReachableEdges.count({MP->getIncomingBlock(U), PHIBlock}); }); // If all that is left is nothing, our memoryphi is undef. We keep it as // InitialClass. Note: The only case this should happen is if we have at // least one self-argument. if (Filtered.begin() == Filtered.end()) { if (setMemoryClass(MP, TOPClass)) markMemoryUsersTouched(MP); return; } // Transform the remaining operands into operand leaders. // FIXME: mapped_iterator should have a range version. auto LookupFunc = [&](const Use &U) { return lookupMemoryLeader(cast(U)); }; auto MappedBegin = map_iterator(Filtered.begin(), LookupFunc); auto MappedEnd = map_iterator(Filtered.end(), LookupFunc); // and now check if all the elements are equal. // Sadly, we can't use std::equals since these are random access iterators. const auto *AllSameValue = *MappedBegin; ++MappedBegin; bool AllEqual = std::all_of( MappedBegin, MappedEnd, [&AllSameValue](const MemoryAccess *V) { return V == AllSameValue; }); if (AllEqual) LLVM_DEBUG(dbgs() << "Memory Phi value numbered to " << *AllSameValue << "\n"); else LLVM_DEBUG(dbgs() << "Memory Phi value numbered to itself\n"); // If it's equal to something, it's in that class. Otherwise, it has to be in // a class where it is the leader (other things may be equivalent to it, but // it needs to start off in its own class, which means it must have been the // leader, and it can't have stopped being the leader because it was never // removed). CongruenceClass *CC = AllEqual ? getMemoryClass(AllSameValue) : ensureLeaderOfMemoryClass(MP); auto OldState = MemoryPhiState.lookup(MP); assert(OldState != MPS_Invalid && "Invalid memory phi state"); auto NewState = AllEqual ? MPS_Equivalent : MPS_Unique; MemoryPhiState[MP] = NewState; if (setMemoryClass(MP, CC) || OldState != NewState) markMemoryUsersTouched(MP); } // Value number a single instruction, symbolically evaluating, performing // congruence finding, and updating mappings. void NewGVN::valueNumberInstruction(Instruction *I) { LLVM_DEBUG(dbgs() << "Processing instruction " << *I << "\n"); if (!I->isTerminator()) { const Expression *Symbolized = nullptr; SmallPtrSet Visited; if (DebugCounter::shouldExecute(VNCounter)) { Symbolized = performSymbolicEvaluation(I, Visited); // Make a phi of ops if necessary if (Symbolized && !isa(Symbolized) && !isa(Symbolized) && PHINodeUses.count(I)) { auto *PHIE = makePossiblePHIOfOps(I, Visited); // If we created a phi of ops, use it. // If we couldn't create one, make sure we don't leave one lying around if (PHIE) { Symbolized = PHIE; } else if (auto *Op = RealToTemp.lookup(I)) { removePhiOfOps(I, Op); } } } else { // Mark the instruction as unused so we don't value number it again. InstrDFS[I] = 0; } // If we couldn't come up with a symbolic expression, use the unknown // expression if (Symbolized == nullptr) Symbolized = createUnknownExpression(I); performCongruenceFinding(I, Symbolized); } else { // Handle terminators that return values. All of them produce values we // don't currently understand. We don't place non-value producing // terminators in a class. if (!I->getType()->isVoidTy()) { auto *Symbolized = createUnknownExpression(I); performCongruenceFinding(I, Symbolized); } processOutgoingEdges(I, I->getParent()); } } // Check if there is a path, using single or equal argument phi nodes, from // First to Second. bool NewGVN::singleReachablePHIPath( SmallPtrSet &Visited, const MemoryAccess *First, const MemoryAccess *Second) const { if (First == Second) return true; if (MSSA->isLiveOnEntryDef(First)) return false; // This is not perfect, but as we're just verifying here, we can live with // the loss of precision. The real solution would be that of doing strongly // connected component finding in this routine, and it's probably not worth // the complexity for the time being. So, we just keep a set of visited // MemoryAccess and return true when we hit a cycle. if (Visited.count(First)) return true; Visited.insert(First); const auto *EndDef = First; for (auto *ChainDef : optimized_def_chain(First)) { if (ChainDef == Second) return true; if (MSSA->isLiveOnEntryDef(ChainDef)) return false; EndDef = ChainDef; } auto *MP = cast(EndDef); auto ReachableOperandPred = [&](const Use &U) { return ReachableEdges.count({MP->getIncomingBlock(U), MP->getBlock()}); }; auto FilteredPhiArgs = make_filter_range(MP->operands(), ReachableOperandPred); SmallVector OperandList; llvm::copy(FilteredPhiArgs, std::back_inserter(OperandList)); bool Okay = is_splat(OperandList); if (Okay) return singleReachablePHIPath(Visited, cast(OperandList[0]), Second); return false; } // Verify the that the memory equivalence table makes sense relative to the // congruence classes. Note that this checking is not perfect, and is currently // subject to very rare false negatives. It is only useful for // testing/debugging. void NewGVN::verifyMemoryCongruency() const { #ifndef NDEBUG // Verify that the memory table equivalence and memory member set match for (const auto *CC : CongruenceClasses) { if (CC == TOPClass || CC->isDead()) continue; if (CC->getStoreCount() != 0) { assert((CC->getStoredValue() || !isa(CC->getLeader())) && "Any class with a store as a leader should have a " "representative stored value"); assert(CC->getMemoryLeader() && "Any congruence class with a store should have a " "representative access"); } if (CC->getMemoryLeader()) assert(MemoryAccessToClass.lookup(CC->getMemoryLeader()) == CC && "Representative MemoryAccess does not appear to be reverse " "mapped properly"); for (auto M : CC->memory()) assert(MemoryAccessToClass.lookup(M) == CC && "Memory member does not appear to be reverse mapped properly"); } // Anything equivalent in the MemoryAccess table should be in the same // congruence class. // Filter out the unreachable and trivially dead entries, because they may // never have been updated if the instructions were not processed. auto ReachableAccessPred = [&](const std::pair Pair) { bool Result = ReachableBlocks.count(Pair.first->getBlock()); if (!Result || MSSA->isLiveOnEntryDef(Pair.first) || MemoryToDFSNum(Pair.first) == 0) return false; if (auto *MemDef = dyn_cast(Pair.first)) return !isInstructionTriviallyDead(MemDef->getMemoryInst()); // We could have phi nodes which operands are all trivially dead, // so we don't process them. if (auto *MemPHI = dyn_cast(Pair.first)) { for (auto &U : MemPHI->incoming_values()) { if (auto *I = dyn_cast(&*U)) { if (!isInstructionTriviallyDead(I)) return true; } } return false; } return true; }; auto Filtered = make_filter_range(MemoryAccessToClass, ReachableAccessPred); for (auto KV : Filtered) { if (auto *FirstMUD = dyn_cast(KV.first)) { auto *SecondMUD = dyn_cast(KV.second->getMemoryLeader()); if (FirstMUD && SecondMUD) { SmallPtrSet VisitedMAS; assert((singleReachablePHIPath(VisitedMAS, FirstMUD, SecondMUD) || ValueToClass.lookup(FirstMUD->getMemoryInst()) == ValueToClass.lookup(SecondMUD->getMemoryInst())) && "The instructions for these memory operations should have " "been in the same congruence class or reachable through" "a single argument phi"); } } else if (auto *FirstMP = dyn_cast(KV.first)) { // We can only sanely verify that MemoryDefs in the operand list all have // the same class. auto ReachableOperandPred = [&](const Use &U) { return ReachableEdges.count( {FirstMP->getIncomingBlock(U), FirstMP->getBlock()}) && isa(U); }; // All arguments should in the same class, ignoring unreachable arguments auto FilteredPhiArgs = make_filter_range(FirstMP->operands(), ReachableOperandPred); SmallVector PhiOpClasses; std::transform(FilteredPhiArgs.begin(), FilteredPhiArgs.end(), std::back_inserter(PhiOpClasses), [&](const Use &U) { const MemoryDef *MD = cast(U); return ValueToClass.lookup(MD->getMemoryInst()); }); assert(is_splat(PhiOpClasses) && "All MemoryPhi arguments should be in the same class"); } } #endif } // Verify that the sparse propagation we did actually found the maximal fixpoint // We do this by storing the value to class mapping, touching all instructions, // and redoing the iteration to see if anything changed. void NewGVN::verifyIterationSettled(Function &F) { #ifndef NDEBUG LLVM_DEBUG(dbgs() << "Beginning iteration verification\n"); if (DebugCounter::isCounterSet(VNCounter)) DebugCounter::setCounterValue(VNCounter, StartingVNCounter); // Note that we have to store the actual classes, as we may change existing // classes during iteration. This is because our memory iteration propagation // is not perfect, and so may waste a little work. But it should generate // exactly the same congruence classes we have now, with different IDs. std::map BeforeIteration; for (auto &KV : ValueToClass) { if (auto *I = dyn_cast(KV.first)) // Skip unused/dead instructions. if (InstrToDFSNum(I) == 0) continue; BeforeIteration.insert({KV.first, *KV.second}); } TouchedInstructions.set(); TouchedInstructions.reset(0); iterateTouchedInstructions(); DenseSet> EqualClasses; for (const auto &KV : ValueToClass) { if (auto *I = dyn_cast(KV.first)) // Skip unused/dead instructions. if (InstrToDFSNum(I) == 0) continue; // We could sink these uses, but i think this adds a bit of clarity here as // to what we are comparing. auto *BeforeCC = &BeforeIteration.find(KV.first)->second; auto *AfterCC = KV.second; // Note that the classes can't change at this point, so we memoize the set // that are equal. if (!EqualClasses.count({BeforeCC, AfterCC})) { assert(BeforeCC->isEquivalentTo(AfterCC) && "Value number changed after main loop completed!"); EqualClasses.insert({BeforeCC, AfterCC}); } } #endif } // Verify that for each store expression in the expression to class mapping, // only the latest appears, and multiple ones do not appear. // Because loads do not use the stored value when doing equality with stores, // if we don't erase the old store expressions from the table, a load can find // a no-longer valid StoreExpression. void NewGVN::verifyStoreExpressions() const { #ifndef NDEBUG // This is the only use of this, and it's not worth defining a complicated // densemapinfo hash/equality function for it. std::set< std::pair>> StoreExpressionSet; for (const auto &KV : ExpressionToClass) { if (auto *SE = dyn_cast(KV.first)) { // Make sure a version that will conflict with loads is not already there auto Res = StoreExpressionSet.insert( {SE->getOperand(0), std::make_tuple(SE->getMemoryLeader(), KV.second, SE->getStoredValue())}); bool Okay = Res.second; // It's okay to have the same expression already in there if it is // identical in nature. // This can happen when the leader of the stored value changes over time. if (!Okay) Okay = (std::get<1>(Res.first->second) == KV.second) && (lookupOperandLeader(std::get<2>(Res.first->second)) == lookupOperandLeader(SE->getStoredValue())); assert(Okay && "Stored expression conflict exists in expression table"); auto *ValueExpr = ValueToExpression.lookup(SE->getStoreInst()); assert(ValueExpr && ValueExpr->equals(*SE) && "StoreExpression in ExpressionToClass is not latest " "StoreExpression for value"); } } #endif } // This is the main value numbering loop, it iterates over the initial touched // instruction set, propagating value numbers, marking things touched, etc, // until the set of touched instructions is completely empty. void NewGVN::iterateTouchedInstructions() { unsigned int Iterations = 0; // Figure out where touchedinstructions starts int FirstInstr = TouchedInstructions.find_first(); // Nothing set, nothing to iterate, just return. if (FirstInstr == -1) return; const BasicBlock *LastBlock = getBlockForValue(InstrFromDFSNum(FirstInstr)); while (TouchedInstructions.any()) { ++Iterations; // Walk through all the instructions in all the blocks in RPO. // TODO: As we hit a new block, we should push and pop equalities into a // table lookupOperandLeader can use, to catch things PredicateInfo // might miss, like edge-only equivalences. for (unsigned InstrNum : TouchedInstructions.set_bits()) { // This instruction was found to be dead. We don't bother looking // at it again. if (InstrNum == 0) { TouchedInstructions.reset(InstrNum); continue; } Value *V = InstrFromDFSNum(InstrNum); const BasicBlock *CurrBlock = getBlockForValue(V); // If we hit a new block, do reachability processing. if (CurrBlock != LastBlock) { LastBlock = CurrBlock; bool BlockReachable = ReachableBlocks.count(CurrBlock); const auto &CurrInstRange = BlockInstRange.lookup(CurrBlock); // If it's not reachable, erase any touched instructions and move on. if (!BlockReachable) { TouchedInstructions.reset(CurrInstRange.first, CurrInstRange.second); LLVM_DEBUG(dbgs() << "Skipping instructions in block " << getBlockName(CurrBlock) << " because it is unreachable\n"); continue; } updateProcessedCount(CurrBlock); } // Reset after processing (because we may mark ourselves as touched when // we propagate equalities). TouchedInstructions.reset(InstrNum); if (auto *MP = dyn_cast(V)) { LLVM_DEBUG(dbgs() << "Processing MemoryPhi " << *MP << "\n"); valueNumberMemoryPhi(MP); } else if (auto *I = dyn_cast(V)) { valueNumberInstruction(I); } else { llvm_unreachable("Should have been a MemoryPhi or Instruction"); } updateProcessedCount(V); } } NumGVNMaxIterations = std::max(NumGVNMaxIterations.getValue(), Iterations); } // This is the main transformation entry point. bool NewGVN::runGVN() { if (DebugCounter::isCounterSet(VNCounter)) StartingVNCounter = DebugCounter::getCounterValue(VNCounter); bool Changed = false; NumFuncArgs = F.arg_size(); MSSAWalker = MSSA->getWalker(); SingletonDeadExpression = new (ExpressionAllocator) DeadExpression(); // Count number of instructions for sizing of hash tables, and come // up with a global dfs numbering for instructions. unsigned ICount = 1; // Add an empty instruction to account for the fact that we start at 1 DFSToInstr.emplace_back(nullptr); // Note: We want ideal RPO traversal of the blocks, which is not quite the // same as dominator tree order, particularly with regard whether backedges // get visited first or second, given a block with multiple successors. // If we visit in the wrong order, we will end up performing N times as many // iterations. // The dominator tree does guarantee that, for a given dom tree node, it's // parent must occur before it in the RPO ordering. Thus, we only need to sort // the siblings. ReversePostOrderTraversal RPOT(&F); unsigned Counter = 0; for (auto &B : RPOT) { auto *Node = DT->getNode(B); assert(Node && "RPO and Dominator tree should have same reachability"); RPOOrdering[Node] = ++Counter; } // Sort dominator tree children arrays into RPO. for (auto &B : RPOT) { auto *Node = DT->getNode(B); if (Node->getNumChildren() > 1) llvm::sort(*Node, [&](const DomTreeNode *A, const DomTreeNode *B) { return RPOOrdering[A] < RPOOrdering[B]; }); } // Now a standard depth first ordering of the domtree is equivalent to RPO. for (auto DTN : depth_first(DT->getRootNode())) { BasicBlock *B = DTN->getBlock(); const auto &BlockRange = assignDFSNumbers(B, ICount); BlockInstRange.insert({B, BlockRange}); ICount += BlockRange.second - BlockRange.first; } initializeCongruenceClasses(F); TouchedInstructions.resize(ICount); // Ensure we don't end up resizing the expressionToClass map, as // that can be quite expensive. At most, we have one expression per // instruction. ExpressionToClass.reserve(ICount); // Initialize the touched instructions to include the entry block. const auto &InstRange = BlockInstRange.lookup(&F.getEntryBlock()); TouchedInstructions.set(InstRange.first, InstRange.second); LLVM_DEBUG(dbgs() << "Block " << getBlockName(&F.getEntryBlock()) << " marked reachable\n"); ReachableBlocks.insert(&F.getEntryBlock()); iterateTouchedInstructions(); verifyMemoryCongruency(); verifyIterationSettled(F); verifyStoreExpressions(); Changed |= eliminateInstructions(F); // Delete all instructions marked for deletion. for (Instruction *ToErase : InstructionsToErase) { if (!ToErase->use_empty()) ToErase->replaceAllUsesWith(UndefValue::get(ToErase->getType())); assert(ToErase->getParent() && "BB containing ToErase deleted unexpectedly!"); ToErase->eraseFromParent(); } Changed |= !InstructionsToErase.empty(); // Delete all unreachable blocks. auto UnreachableBlockPred = [&](const BasicBlock &BB) { return !ReachableBlocks.count(&BB); }; for (auto &BB : make_filter_range(F, UnreachableBlockPred)) { LLVM_DEBUG(dbgs() << "We believe block " << getBlockName(&BB) << " is unreachable\n"); deleteInstructionsInBlock(&BB); Changed = true; } cleanupTables(); return Changed; } struct NewGVN::ValueDFS { int DFSIn = 0; int DFSOut = 0; int LocalNum = 0; // Only one of Def and U will be set. // The bool in the Def tells us whether the Def is the stored value of a // store. PointerIntPair Def; Use *U = nullptr; bool operator<(const ValueDFS &Other) const { // It's not enough that any given field be less than - we have sets // of fields that need to be evaluated together to give a proper ordering. // For example, if you have; // DFS (1, 3) // Val 0 // DFS (1, 2) // Val 50 // We want the second to be less than the first, but if we just go field // by field, we will get to Val 0 < Val 50 and say the first is less than // the second. We only want it to be less than if the DFS orders are equal. // // Each LLVM instruction only produces one value, and thus the lowest-level // differentiator that really matters for the stack (and what we use as as a // replacement) is the local dfs number. // Everything else in the structure is instruction level, and only affects // the order in which we will replace operands of a given instruction. // // For a given instruction (IE things with equal dfsin, dfsout, localnum), // the order of replacement of uses does not matter. // IE given, // a = 5 // b = a + a // When you hit b, you will have two valuedfs with the same dfsin, out, and // localnum. // The .val will be the same as well. // The .u's will be different. // You will replace both, and it does not matter what order you replace them // in (IE whether you replace operand 2, then operand 1, or operand 1, then // operand 2). // Similarly for the case of same dfsin, dfsout, localnum, but different // .val's // a = 5 // b = 6 // c = a + b // in c, we will a valuedfs for a, and one for b,with everything the same // but .val and .u. // It does not matter what order we replace these operands in. // You will always end up with the same IR, and this is guaranteed. return std::tie(DFSIn, DFSOut, LocalNum, Def, U) < std::tie(Other.DFSIn, Other.DFSOut, Other.LocalNum, Other.Def, Other.U); } }; // This function converts the set of members for a congruence class from values, // to sets of defs and uses with associated DFS info. The total number of // reachable uses for each value is stored in UseCount, and instructions that // seem // dead (have no non-dead uses) are stored in ProbablyDead. void NewGVN::convertClassToDFSOrdered( const CongruenceClass &Dense, SmallVectorImpl &DFSOrderedSet, DenseMap &UseCounts, SmallPtrSetImpl &ProbablyDead) const { for (auto D : Dense) { // First add the value. BasicBlock *BB = getBlockForValue(D); // Constants are handled prior to ever calling this function, so // we should only be left with instructions as members. assert(BB && "Should have figured out a basic block for value"); ValueDFS VDDef; DomTreeNode *DomNode = DT->getNode(BB); VDDef.DFSIn = DomNode->getDFSNumIn(); VDDef.DFSOut = DomNode->getDFSNumOut(); // If it's a store, use the leader of the value operand, if it's always // available, or the value operand. TODO: We could do dominance checks to // find a dominating leader, but not worth it ATM. if (auto *SI = dyn_cast(D)) { auto Leader = lookupOperandLeader(SI->getValueOperand()); if (alwaysAvailable(Leader)) { VDDef.Def.setPointer(Leader); } else { VDDef.Def.setPointer(SI->getValueOperand()); VDDef.Def.setInt(true); } } else { VDDef.Def.setPointer(D); } assert(isa(D) && "The dense set member should always be an instruction"); Instruction *Def = cast(D); VDDef.LocalNum = InstrToDFSNum(D); DFSOrderedSet.push_back(VDDef); // If there is a phi node equivalent, add it if (auto *PN = RealToTemp.lookup(Def)) { auto *PHIE = dyn_cast_or_null(ValueToExpression.lookup(Def)); if (PHIE) { VDDef.Def.setInt(false); VDDef.Def.setPointer(PN); VDDef.LocalNum = 0; DFSOrderedSet.push_back(VDDef); } } unsigned int UseCount = 0; // Now add the uses. for (auto &U : Def->uses()) { if (auto *I = dyn_cast(U.getUser())) { // Don't try to replace into dead uses if (InstructionsToErase.count(I)) continue; ValueDFS VDUse; // Put the phi node uses in the incoming block. BasicBlock *IBlock; if (auto *P = dyn_cast(I)) { IBlock = P->getIncomingBlock(U); // Make phi node users appear last in the incoming block // they are from. VDUse.LocalNum = InstrDFS.size() + 1; } else { IBlock = getBlockForValue(I); VDUse.LocalNum = InstrToDFSNum(I); } // Skip uses in unreachable blocks, as we're going // to delete them. if (ReachableBlocks.count(IBlock) == 0) continue; DomTreeNode *DomNode = DT->getNode(IBlock); VDUse.DFSIn = DomNode->getDFSNumIn(); VDUse.DFSOut = DomNode->getDFSNumOut(); VDUse.U = &U; ++UseCount; DFSOrderedSet.emplace_back(VDUse); } } // If there are no uses, it's probably dead (but it may have side-effects, // so not definitely dead. Otherwise, store the number of uses so we can // track if it becomes dead later). if (UseCount == 0) ProbablyDead.insert(Def); else UseCounts[Def] = UseCount; } } // This function converts the set of members for a congruence class from values, // to the set of defs for loads and stores, with associated DFS info. void NewGVN::convertClassToLoadsAndStores( const CongruenceClass &Dense, SmallVectorImpl &LoadsAndStores) const { for (auto D : Dense) { if (!isa(D) && !isa(D)) continue; BasicBlock *BB = getBlockForValue(D); ValueDFS VD; DomTreeNode *DomNode = DT->getNode(BB); VD.DFSIn = DomNode->getDFSNumIn(); VD.DFSOut = DomNode->getDFSNumOut(); VD.Def.setPointer(D); // If it's an instruction, use the real local dfs number. if (auto *I = dyn_cast(D)) VD.LocalNum = InstrToDFSNum(I); else llvm_unreachable("Should have been an instruction"); LoadsAndStores.emplace_back(VD); } } static void patchAndReplaceAllUsesWith(Instruction *I, Value *Repl) { patchReplacementInstruction(I, Repl); I->replaceAllUsesWith(Repl); } void NewGVN::deleteInstructionsInBlock(BasicBlock *BB) { LLVM_DEBUG(dbgs() << " BasicBlock Dead:" << *BB); ++NumGVNBlocksDeleted; // Delete the instructions backwards, as it has a reduced likelihood of having // to update as many def-use and use-def chains. Start after the terminator. auto StartPoint = BB->rbegin(); ++StartPoint; // Note that we explicitly recalculate BB->rend() on each iteration, // as it may change when we remove the first instruction. for (BasicBlock::reverse_iterator I(StartPoint); I != BB->rend();) { Instruction &Inst = *I++; if (!Inst.use_empty()) Inst.replaceAllUsesWith(UndefValue::get(Inst.getType())); if (isa(Inst)) continue; salvageKnowledge(&Inst, AC); Inst.eraseFromParent(); ++NumGVNInstrDeleted; } // Now insert something that simplifycfg will turn into an unreachable. Type *Int8Ty = Type::getInt8Ty(BB->getContext()); new StoreInst(UndefValue::get(Int8Ty), Constant::getNullValue(Int8Ty->getPointerTo()), BB->getTerminator()); } void NewGVN::markInstructionForDeletion(Instruction *I) { LLVM_DEBUG(dbgs() << "Marking " << *I << " for deletion\n"); InstructionsToErase.insert(I); } void NewGVN::replaceInstruction(Instruction *I, Value *V) { LLVM_DEBUG(dbgs() << "Replacing " << *I << " with " << *V << "\n"); patchAndReplaceAllUsesWith(I, V); // We save the actual erasing to avoid invalidating memory // dependencies until we are done with everything. markInstructionForDeletion(I); } namespace { // This is a stack that contains both the value and dfs info of where // that value is valid. class ValueDFSStack { public: Value *back() const { return ValueStack.back(); } std::pair dfs_back() const { return DFSStack.back(); } void push_back(Value *V, int DFSIn, int DFSOut) { ValueStack.emplace_back(V); DFSStack.emplace_back(DFSIn, DFSOut); } bool empty() const { return DFSStack.empty(); } bool isInScope(int DFSIn, int DFSOut) const { if (empty()) return false; return DFSIn >= DFSStack.back().first && DFSOut <= DFSStack.back().second; } void popUntilDFSScope(int DFSIn, int DFSOut) { // These two should always be in sync at this point. assert(ValueStack.size() == DFSStack.size() && "Mismatch between ValueStack and DFSStack"); while ( !DFSStack.empty() && !(DFSIn >= DFSStack.back().first && DFSOut <= DFSStack.back().second)) { DFSStack.pop_back(); ValueStack.pop_back(); } } private: SmallVector ValueStack; SmallVector, 8> DFSStack; }; } // end anonymous namespace // Given an expression, get the congruence class for it. CongruenceClass *NewGVN::getClassForExpression(const Expression *E) const { if (auto *VE = dyn_cast(E)) return ValueToClass.lookup(VE->getVariableValue()); else if (isa(E)) return TOPClass; return ExpressionToClass.lookup(E); } // Given a value and a basic block we are trying to see if it is available in, // see if the value has a leader available in that block. Value *NewGVN::findPHIOfOpsLeader(const Expression *E, const Instruction *OrigInst, const BasicBlock *BB) const { // It would already be constant if we could make it constant if (auto *CE = dyn_cast(E)) return CE->getConstantValue(); if (auto *VE = dyn_cast(E)) { auto *V = VE->getVariableValue(); if (alwaysAvailable(V) || DT->dominates(getBlockForValue(V), BB)) return VE->getVariableValue(); } auto *CC = getClassForExpression(E); if (!CC) return nullptr; if (alwaysAvailable(CC->getLeader())) return CC->getLeader(); for (auto Member : *CC) { auto *MemberInst = dyn_cast(Member); if (MemberInst == OrigInst) continue; // Anything that isn't an instruction is always available. if (!MemberInst) return Member; if (DT->dominates(getBlockForValue(MemberInst), BB)) return Member; } return nullptr; } bool NewGVN::eliminateInstructions(Function &F) { // This is a non-standard eliminator. The normal way to eliminate is // to walk the dominator tree in order, keeping track of available // values, and eliminating them. However, this is mildly // pointless. It requires doing lookups on every instruction, // regardless of whether we will ever eliminate it. For // instructions part of most singleton congruence classes, we know we // will never eliminate them. // Instead, this eliminator looks at the congruence classes directly, sorts // them into a DFS ordering of the dominator tree, and then we just // perform elimination straight on the sets by walking the congruence // class member uses in order, and eliminate the ones dominated by the // last member. This is worst case O(E log E) where E = number of // instructions in a single congruence class. In theory, this is all // instructions. In practice, it is much faster, as most instructions are // either in singleton congruence classes or can't possibly be eliminated // anyway (if there are no overlapping DFS ranges in class). // When we find something not dominated, it becomes the new leader // for elimination purposes. // TODO: If we wanted to be faster, We could remove any members with no // overlapping ranges while sorting, as we will never eliminate anything // with those members, as they don't dominate anything else in our set. bool AnythingReplaced = false; // Since we are going to walk the domtree anyway, and we can't guarantee the // DFS numbers are updated, we compute some ourselves. DT->updateDFSNumbers(); // Go through all of our phi nodes, and kill the arguments associated with // unreachable edges. auto ReplaceUnreachablePHIArgs = [&](PHINode *PHI, BasicBlock *BB) { for (auto &Operand : PHI->incoming_values()) if (!ReachableEdges.count({PHI->getIncomingBlock(Operand), BB})) { LLVM_DEBUG(dbgs() << "Replacing incoming value of " << PHI << " for block " << getBlockName(PHI->getIncomingBlock(Operand)) << " with undef due to it being unreachable\n"); Operand.set(UndefValue::get(PHI->getType())); } }; // Replace unreachable phi arguments. // At this point, RevisitOnReachabilityChange only contains: // // 1. PHIs // 2. Temporaries that will convert to PHIs // 3. Operations that are affected by an unreachable edge but do not fit into // 1 or 2 (rare). // So it is a slight overshoot of what we want. We could make it exact by // using two SparseBitVectors per block. DenseMap ReachablePredCount; for (auto &KV : ReachableEdges) ReachablePredCount[KV.getEnd()]++; for (auto &BBPair : RevisitOnReachabilityChange) { for (auto InstNum : BBPair.second) { auto *Inst = InstrFromDFSNum(InstNum); auto *PHI = dyn_cast(Inst); PHI = PHI ? PHI : dyn_cast_or_null(RealToTemp.lookup(Inst)); if (!PHI) continue; auto *BB = BBPair.first; if (ReachablePredCount.lookup(BB) != PHI->getNumIncomingValues()) ReplaceUnreachablePHIArgs(PHI, BB); } } // Map to store the use counts DenseMap UseCounts; for (auto *CC : reverse(CongruenceClasses)) { LLVM_DEBUG(dbgs() << "Eliminating in congruence class " << CC->getID() << "\n"); // Track the equivalent store info so we can decide whether to try // dead store elimination. SmallVector PossibleDeadStores; SmallPtrSet ProbablyDead; if (CC->isDead() || CC->empty()) continue; // Everything still in the TOP class is unreachable or dead. if (CC == TOPClass) { for (auto M : *CC) { auto *VTE = ValueToExpression.lookup(M); if (VTE && isa(VTE)) markInstructionForDeletion(cast(M)); assert((!ReachableBlocks.count(cast(M)->getParent()) || InstructionsToErase.count(cast(M))) && "Everything in TOP should be unreachable or dead at this " "point"); } continue; } assert(CC->getLeader() && "We should have had a leader"); // If this is a leader that is always available, and it's a // constant or has no equivalences, just replace everything with // it. We then update the congruence class with whatever members // are left. Value *Leader = CC->getStoredValue() ? CC->getStoredValue() : CC->getLeader(); if (alwaysAvailable(Leader)) { CongruenceClass::MemberSet MembersLeft; for (auto M : *CC) { Value *Member = M; // Void things have no uses we can replace. if (Member == Leader || !isa(Member) || Member->getType()->isVoidTy()) { MembersLeft.insert(Member); continue; } LLVM_DEBUG(dbgs() << "Found replacement " << *(Leader) << " for " << *Member << "\n"); auto *I = cast(Member); assert(Leader != I && "About to accidentally remove our leader"); replaceInstruction(I, Leader); AnythingReplaced = true; } CC->swap(MembersLeft); } else { // If this is a singleton, we can skip it. if (CC->size() != 1 || RealToTemp.count(Leader)) { // This is a stack because equality replacement/etc may place // constants in the middle of the member list, and we want to use // those constant values in preference to the current leader, over // the scope of those constants. ValueDFSStack EliminationStack; // Convert the members to DFS ordered sets and then merge them. SmallVector DFSOrderedSet; convertClassToDFSOrdered(*CC, DFSOrderedSet, UseCounts, ProbablyDead); // Sort the whole thing. llvm::sort(DFSOrderedSet); for (auto &VD : DFSOrderedSet) { int MemberDFSIn = VD.DFSIn; int MemberDFSOut = VD.DFSOut; Value *Def = VD.Def.getPointer(); bool FromStore = VD.Def.getInt(); Use *U = VD.U; // We ignore void things because we can't get a value from them. if (Def && Def->getType()->isVoidTy()) continue; auto *DefInst = dyn_cast_or_null(Def); if (DefInst && AllTempInstructions.count(DefInst)) { auto *PN = cast(DefInst); // If this is a value phi and that's the expression we used, insert // it into the program // remove from temp instruction list. AllTempInstructions.erase(PN); auto *DefBlock = getBlockForValue(Def); LLVM_DEBUG(dbgs() << "Inserting fully real phi of ops" << *Def << " into block " << getBlockName(getBlockForValue(Def)) << "\n"); PN->insertBefore(&DefBlock->front()); Def = PN; NumGVNPHIOfOpsEliminations++; } if (EliminationStack.empty()) { LLVM_DEBUG(dbgs() << "Elimination Stack is empty\n"); } else { LLVM_DEBUG(dbgs() << "Elimination Stack Top DFS numbers are (" << EliminationStack.dfs_back().first << "," << EliminationStack.dfs_back().second << ")\n"); } LLVM_DEBUG(dbgs() << "Current DFS numbers are (" << MemberDFSIn << "," << MemberDFSOut << ")\n"); // First, we see if we are out of scope or empty. If so, // and there equivalences, we try to replace the top of // stack with equivalences (if it's on the stack, it must // not have been eliminated yet). // Then we synchronize to our current scope, by // popping until we are back within a DFS scope that // dominates the current member. // Then, what happens depends on a few factors // If the stack is now empty, we need to push // If we have a constant or a local equivalence we want to // start using, we also push. // Otherwise, we walk along, processing members who are // dominated by this scope, and eliminate them. bool ShouldPush = Def && EliminationStack.empty(); bool OutOfScope = !EliminationStack.isInScope(MemberDFSIn, MemberDFSOut); if (OutOfScope || ShouldPush) { // Sync to our current scope. EliminationStack.popUntilDFSScope(MemberDFSIn, MemberDFSOut); bool ShouldPush = Def && EliminationStack.empty(); if (ShouldPush) { EliminationStack.push_back(Def, MemberDFSIn, MemberDFSOut); } } // Skip the Def's, we only want to eliminate on their uses. But mark // dominated defs as dead. if (Def) { // For anything in this case, what and how we value number // guarantees that any side-effets that would have occurred (ie // throwing, etc) can be proven to either still occur (because it's // dominated by something that has the same side-effects), or never // occur. Otherwise, we would not have been able to prove it value // equivalent to something else. For these things, we can just mark // it all dead. Note that this is different from the "ProbablyDead" // set, which may not be dominated by anything, and thus, are only // easy to prove dead if they are also side-effect free. Note that // because stores are put in terms of the stored value, we skip // stored values here. If the stored value is really dead, it will // still be marked for deletion when we process it in its own class. if (!EliminationStack.empty() && Def != EliminationStack.back() && isa(Def) && !FromStore) markInstructionForDeletion(cast(Def)); continue; } // At this point, we know it is a Use we are trying to possibly // replace. assert(isa(U->get()) && "Current def should have been an instruction"); assert(isa(U->getUser()) && "Current user should have been an instruction"); // If the thing we are replacing into is already marked to be dead, // this use is dead. Note that this is true regardless of whether // we have anything dominating the use or not. We do this here // because we are already walking all the uses anyway. Instruction *InstUse = cast(U->getUser()); if (InstructionsToErase.count(InstUse)) { auto &UseCount = UseCounts[U->get()]; if (--UseCount == 0) { ProbablyDead.insert(cast(U->get())); } } // If we get to this point, and the stack is empty we must have a use // with nothing we can use to eliminate this use, so just skip it. if (EliminationStack.empty()) continue; Value *DominatingLeader = EliminationStack.back(); auto *II = dyn_cast(DominatingLeader); bool isSSACopy = II && II->getIntrinsicID() == Intrinsic::ssa_copy; if (isSSACopy) DominatingLeader = II->getOperand(0); // Don't replace our existing users with ourselves. if (U->get() == DominatingLeader) continue; LLVM_DEBUG(dbgs() << "Found replacement " << *DominatingLeader << " for " << *U->get() << " in " << *(U->getUser()) << "\n"); // If we replaced something in an instruction, handle the patching of // metadata. Skip this if we are replacing predicateinfo with its // original operand, as we already know we can just drop it. auto *ReplacedInst = cast(U->get()); auto *PI = PredInfo->getPredicateInfoFor(ReplacedInst); if (!PI || DominatingLeader != PI->OriginalOp) patchReplacementInstruction(ReplacedInst, DominatingLeader); U->set(DominatingLeader); // This is now a use of the dominating leader, which means if the // dominating leader was dead, it's now live! auto &LeaderUseCount = UseCounts[DominatingLeader]; // It's about to be alive again. if (LeaderUseCount == 0 && isa(DominatingLeader)) ProbablyDead.erase(cast(DominatingLeader)); // For copy instructions, we use their operand as a leader, // which means we remove a user of the copy and it may become dead. if (isSSACopy) { unsigned &IIUseCount = UseCounts[II]; if (--IIUseCount == 0) ProbablyDead.insert(II); } ++LeaderUseCount; AnythingReplaced = true; } } } // At this point, anything still in the ProbablyDead set is actually dead if // would be trivially dead. for (auto *I : ProbablyDead) if (wouldInstructionBeTriviallyDead(I)) markInstructionForDeletion(I); // Cleanup the congruence class. CongruenceClass::MemberSet MembersLeft; for (auto *Member : *CC) if (!isa(Member) || !InstructionsToErase.count(cast(Member))) MembersLeft.insert(Member); CC->swap(MembersLeft); // If we have possible dead stores to look at, try to eliminate them. if (CC->getStoreCount() > 0) { convertClassToLoadsAndStores(*CC, PossibleDeadStores); llvm::sort(PossibleDeadStores); ValueDFSStack EliminationStack; for (auto &VD : PossibleDeadStores) { int MemberDFSIn = VD.DFSIn; int MemberDFSOut = VD.DFSOut; Instruction *Member = cast(VD.Def.getPointer()); if (EliminationStack.empty() || !EliminationStack.isInScope(MemberDFSIn, MemberDFSOut)) { // Sync to our current scope. EliminationStack.popUntilDFSScope(MemberDFSIn, MemberDFSOut); if (EliminationStack.empty()) { EliminationStack.push_back(Member, MemberDFSIn, MemberDFSOut); continue; } } // We already did load elimination, so nothing to do here. if (isa(Member)) continue; assert(!EliminationStack.empty()); Instruction *Leader = cast(EliminationStack.back()); (void)Leader; assert(DT->dominates(Leader->getParent(), Member->getParent())); // Member is dominater by Leader, and thus dead LLVM_DEBUG(dbgs() << "Marking dead store " << *Member << " that is dominated by " << *Leader << "\n"); markInstructionForDeletion(Member); CC->erase(Member); ++NumGVNDeadStores; } } } return AnythingReplaced; } // This function provides global ranking of operations so that we can place them // in a canonical order. Note that rank alone is not necessarily enough for a // complete ordering, as constants all have the same rank. However, generally, // we will simplify an operation with all constants so that it doesn't matter // what order they appear in. unsigned int NewGVN::getRank(const Value *V) const { // Prefer constants to undef to anything else // Undef is a constant, have to check it first. // Prefer smaller constants to constantexprs if (isa(V)) return 2; if (isa(V)) return 1; if (isa(V)) return 0; else if (auto *A = dyn_cast(V)) return 3 + A->getArgNo(); // Need to shift the instruction DFS by number of arguments + 3 to account for // the constant and argument ranking above. unsigned Result = InstrToDFSNum(V); if (Result > 0) return 4 + NumFuncArgs + Result; // Unreachable or something else, just return a really large number. return ~0; } // This is a function that says whether two commutative operations should // have their order swapped when canonicalizing. bool NewGVN::shouldSwapOperands(const Value *A, const Value *B) const { // Because we only care about a total ordering, and don't rewrite expressions // in this order, we order by rank, which will give a strict weak ordering to // everything but constants, and then we order by pointer address. return std::make_pair(getRank(A), A) > std::make_pair(getRank(B), B); } namespace { class NewGVNLegacyPass : public FunctionPass { public: // Pass identification, replacement for typeid. static char ID; NewGVNLegacyPass() : FunctionPass(ID) { initializeNewGVNLegacyPassPass(*PassRegistry::getPassRegistry()); } bool runOnFunction(Function &F) override; private: void getAnalysisUsage(AnalysisUsage &AU) const override { AU.addRequired(); AU.addRequired(); AU.addRequired(); AU.addRequired(); AU.addRequired(); AU.addPreserved(); AU.addPreserved(); } }; } // end anonymous namespace bool NewGVNLegacyPass::runOnFunction(Function &F) { if (skipFunction(F)) return false; return NewGVN(F, &getAnalysis().getDomTree(), &getAnalysis().getAssumptionCache(F), &getAnalysis().getTLI(F), &getAnalysis().getAAResults(), &getAnalysis().getMSSA(), F.getParent()->getDataLayout()) .runGVN(); } char NewGVNLegacyPass::ID = 0; INITIALIZE_PASS_BEGIN(NewGVNLegacyPass, "newgvn", "Global Value Numbering", false, false) INITIALIZE_PASS_DEPENDENCY(AssumptionCacheTracker) INITIALIZE_PASS_DEPENDENCY(MemorySSAWrapperPass) INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass) INITIALIZE_PASS_DEPENDENCY(TargetLibraryInfoWrapperPass) INITIALIZE_PASS_DEPENDENCY(AAResultsWrapperPass) INITIALIZE_PASS_DEPENDENCY(GlobalsAAWrapperPass) INITIALIZE_PASS_END(NewGVNLegacyPass, "newgvn", "Global Value Numbering", false, false) // createGVNPass - The public interface to this file. FunctionPass *llvm::createNewGVNPass() { return new NewGVNLegacyPass(); } PreservedAnalyses NewGVNPass::run(Function &F, AnalysisManager &AM) { // Apparently the order in which we get these results matter for // the old GVN (see Chandler's comment in GVN.cpp). I'll keep // the same order here, just in case. auto &AC = AM.getResult(F); auto &DT = AM.getResult(F); auto &TLI = AM.getResult(F); auto &AA = AM.getResult(F); auto &MSSA = AM.getResult(F).getMSSA(); bool Changed = NewGVN(F, &DT, &AC, &TLI, &AA, &MSSA, F.getParent()->getDataLayout()) .runGVN(); if (!Changed) return PreservedAnalyses::all(); PreservedAnalyses PA; PA.preserve(); PA.preserve(); return PA; }