//===- AttributorAttributes.cpp - Attributes for Attributor deduction -----===// // // 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 // //===----------------------------------------------------------------------===// // // See the Attributor.h file comment and the class descriptions in that file for // more information. // //===----------------------------------------------------------------------===// #include "llvm/Transforms/IPO/Attributor.h" #include "llvm/ADT/APInt.h" #include "llvm/ADT/DenseMapInfo.h" #include "llvm/ADT/MapVector.h" #include "llvm/ADT/SCCIterator.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SetOperations.h" #include "llvm/ADT/SetVector.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/Statistic.h" #include "llvm/Analysis/AliasAnalysis.h" #include "llvm/Analysis/AssumeBundleQueries.h" #include "llvm/Analysis/AssumptionCache.h" #include "llvm/Analysis/CaptureTracking.h" #include "llvm/Analysis/InstructionSimplify.h" #include "llvm/Analysis/LazyValueInfo.h" #include "llvm/Analysis/MemoryBuiltins.h" #include "llvm/Analysis/OptimizationRemarkEmitter.h" #include "llvm/Analysis/ScalarEvolution.h" #include "llvm/Analysis/TargetTransformInfo.h" #include "llvm/Analysis/ValueTracking.h" #include "llvm/IR/Argument.h" #include "llvm/IR/Assumptions.h" #include "llvm/IR/BasicBlock.h" #include "llvm/IR/Constant.h" #include "llvm/IR/Constants.h" #include "llvm/IR/DataLayout.h" #include "llvm/IR/DerivedTypes.h" #include "llvm/IR/GlobalValue.h" #include "llvm/IR/IRBuilder.h" #include "llvm/IR/InstrTypes.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/Instructions.h" #include "llvm/IR/IntrinsicInst.h" #include "llvm/IR/NoFolder.h" #include "llvm/IR/Value.h" #include "llvm/IR/ValueHandle.h" #include "llvm/Support/Alignment.h" #include "llvm/Support/Casting.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/GraphWriter.h" #include "llvm/Support/MathExtras.h" #include "llvm/Support/raw_ostream.h" #include "llvm/Transforms/Utils/Local.h" #include "llvm/Transforms/Utils/ValueMapper.h" #include using namespace llvm; #define DEBUG_TYPE "attributor" static cl::opt ManifestInternal( "attributor-manifest-internal", cl::Hidden, cl::desc("Manifest Attributor internal string attributes."), cl::init(false)); static cl::opt MaxHeapToStackSize("max-heap-to-stack-size", cl::init(128), cl::Hidden); template <> unsigned llvm::PotentialConstantIntValuesState::MaxPotentialValues = 0; template <> unsigned llvm::PotentialLLVMValuesState::MaxPotentialValues = -1; static cl::opt MaxPotentialValues( "attributor-max-potential-values", cl::Hidden, cl::desc("Maximum number of potential values to be " "tracked for each position."), cl::location(llvm::PotentialConstantIntValuesState::MaxPotentialValues), cl::init(7)); static cl::opt MaxPotentialValuesIterations( "attributor-max-potential-values-iterations", cl::Hidden, cl::desc( "Maximum number of iterations we keep dismantling potential values."), cl::init(64)); static cl::opt MaxInterferingAccesses( "attributor-max-interfering-accesses", cl::Hidden, cl::desc("Maximum number of interfering accesses to " "check before assuming all might interfere."), cl::init(6)); STATISTIC(NumAAs, "Number of abstract attributes created"); // Some helper macros to deal with statistics tracking. // // Usage: // For simple IR attribute tracking overload trackStatistics in the abstract // attribute and choose the right STATS_DECLTRACK_********* macro, // e.g.,: // void trackStatistics() const override { // STATS_DECLTRACK_ARG_ATTR(returned) // } // If there is a single "increment" side one can use the macro // STATS_DECLTRACK with a custom message. If there are multiple increment // sides, STATS_DECL and STATS_TRACK can also be used separately. // #define BUILD_STAT_MSG_IR_ATTR(TYPE, NAME) \ ("Number of " #TYPE " marked '" #NAME "'") #define BUILD_STAT_NAME(NAME, TYPE) NumIR##TYPE##_##NAME #define STATS_DECL_(NAME, MSG) STATISTIC(NAME, MSG); #define STATS_DECL(NAME, TYPE, MSG) \ STATS_DECL_(BUILD_STAT_NAME(NAME, TYPE), MSG); #define STATS_TRACK(NAME, TYPE) ++(BUILD_STAT_NAME(NAME, TYPE)); #define STATS_DECLTRACK(NAME, TYPE, MSG) \ { \ STATS_DECL(NAME, TYPE, MSG) \ STATS_TRACK(NAME, TYPE) \ } #define STATS_DECLTRACK_ARG_ATTR(NAME) \ STATS_DECLTRACK(NAME, Arguments, BUILD_STAT_MSG_IR_ATTR(arguments, NAME)) #define STATS_DECLTRACK_CSARG_ATTR(NAME) \ STATS_DECLTRACK(NAME, CSArguments, \ BUILD_STAT_MSG_IR_ATTR(call site arguments, NAME)) #define STATS_DECLTRACK_FN_ATTR(NAME) \ STATS_DECLTRACK(NAME, Function, BUILD_STAT_MSG_IR_ATTR(functions, NAME)) #define STATS_DECLTRACK_CS_ATTR(NAME) \ STATS_DECLTRACK(NAME, CS, BUILD_STAT_MSG_IR_ATTR(call site, NAME)) #define STATS_DECLTRACK_FNRET_ATTR(NAME) \ STATS_DECLTRACK(NAME, FunctionReturn, \ BUILD_STAT_MSG_IR_ATTR(function returns, NAME)) #define STATS_DECLTRACK_CSRET_ATTR(NAME) \ STATS_DECLTRACK(NAME, CSReturn, \ BUILD_STAT_MSG_IR_ATTR(call site returns, NAME)) #define STATS_DECLTRACK_FLOATING_ATTR(NAME) \ STATS_DECLTRACK(NAME, Floating, \ ("Number of floating values known to be '" #NAME "'")) // Specialization of the operator<< for abstract attributes subclasses. This // disambiguates situations where multiple operators are applicable. namespace llvm { #define PIPE_OPERATOR(CLASS) \ raw_ostream &operator<<(raw_ostream &OS, const CLASS &AA) { \ return OS << static_cast(AA); \ } PIPE_OPERATOR(AAIsDead) PIPE_OPERATOR(AANoUnwind) PIPE_OPERATOR(AANoSync) PIPE_OPERATOR(AANoRecurse) PIPE_OPERATOR(AAWillReturn) PIPE_OPERATOR(AANoReturn) PIPE_OPERATOR(AAReturnedValues) PIPE_OPERATOR(AANonNull) PIPE_OPERATOR(AANoAlias) PIPE_OPERATOR(AADereferenceable) PIPE_OPERATOR(AAAlign) PIPE_OPERATOR(AAInstanceInfo) PIPE_OPERATOR(AANoCapture) PIPE_OPERATOR(AAValueSimplify) PIPE_OPERATOR(AANoFree) PIPE_OPERATOR(AAHeapToStack) PIPE_OPERATOR(AAReachability) PIPE_OPERATOR(AAMemoryBehavior) PIPE_OPERATOR(AAMemoryLocation) PIPE_OPERATOR(AAValueConstantRange) PIPE_OPERATOR(AAPrivatizablePtr) PIPE_OPERATOR(AAUndefinedBehavior) PIPE_OPERATOR(AAPotentialConstantValues) PIPE_OPERATOR(AAPotentialValues) PIPE_OPERATOR(AANoUndef) PIPE_OPERATOR(AACallEdges) PIPE_OPERATOR(AAFunctionReachability) PIPE_OPERATOR(AAPointerInfo) PIPE_OPERATOR(AAAssumptionInfo) #undef PIPE_OPERATOR template <> ChangeStatus clampStateAndIndicateChange(DerefState &S, const DerefState &R) { ChangeStatus CS0 = clampStateAndIndicateChange(S.DerefBytesState, R.DerefBytesState); ChangeStatus CS1 = clampStateAndIndicateChange(S.GlobalState, R.GlobalState); return CS0 | CS1; } } // namespace llvm /// Checks if a type could have padding bytes. static bool isDenselyPacked(Type *Ty, const DataLayout &DL) { // There is no size information, so be conservative. if (!Ty->isSized()) return false; // If the alloc size is not equal to the storage size, then there are padding // bytes. For x86_fp80 on x86-64, size: 80 alloc size: 128. if (DL.getTypeSizeInBits(Ty) != DL.getTypeAllocSizeInBits(Ty)) return false; // FIXME: This isn't the right way to check for padding in vectors with // non-byte-size elements. if (VectorType *SeqTy = dyn_cast(Ty)) return isDenselyPacked(SeqTy->getElementType(), DL); // For array types, check for padding within members. if (ArrayType *SeqTy = dyn_cast(Ty)) return isDenselyPacked(SeqTy->getElementType(), DL); if (!isa(Ty)) return true; // Check for padding within and between elements of a struct. StructType *StructTy = cast(Ty); const StructLayout *Layout = DL.getStructLayout(StructTy); uint64_t StartPos = 0; for (unsigned I = 0, E = StructTy->getNumElements(); I < E; ++I) { Type *ElTy = StructTy->getElementType(I); if (!isDenselyPacked(ElTy, DL)) return false; if (StartPos != Layout->getElementOffsetInBits(I)) return false; StartPos += DL.getTypeAllocSizeInBits(ElTy); } return true; } /// Get pointer operand of memory accessing instruction. If \p I is /// not a memory accessing instruction, return nullptr. If \p AllowVolatile, /// is set to false and the instruction is volatile, return nullptr. static const Value *getPointerOperand(const Instruction *I, bool AllowVolatile) { if (!AllowVolatile && I->isVolatile()) return nullptr; if (auto *LI = dyn_cast(I)) { return LI->getPointerOperand(); } if (auto *SI = dyn_cast(I)) { return SI->getPointerOperand(); } if (auto *CXI = dyn_cast(I)) { return CXI->getPointerOperand(); } if (auto *RMWI = dyn_cast(I)) { return RMWI->getPointerOperand(); } return nullptr; } /// Helper function to create a pointer of type \p ResTy, based on \p Ptr, and /// advanced by \p Offset bytes. To aid later analysis the method tries to build /// getelement pointer instructions that traverse the natural type of \p Ptr if /// possible. If that fails, the remaining offset is adjusted byte-wise, hence /// through a cast to i8*. /// /// TODO: This could probably live somewhere more prominantly if it doesn't /// already exist. static Value *constructPointer(Type *ResTy, Type *PtrElemTy, Value *Ptr, int64_t Offset, IRBuilder &IRB, const DataLayout &DL) { assert(Offset >= 0 && "Negative offset not supported yet!"); LLVM_DEBUG(dbgs() << "Construct pointer: " << *Ptr << " + " << Offset << "-bytes as " << *ResTy << "\n"); if (Offset) { Type *Ty = PtrElemTy; APInt IntOffset(DL.getIndexTypeSizeInBits(Ptr->getType()), Offset); SmallVector IntIndices = DL.getGEPIndicesForOffset(Ty, IntOffset); SmallVector ValIndices; std::string GEPName = Ptr->getName().str(); for (const APInt &Index : IntIndices) { ValIndices.push_back(IRB.getInt(Index)); GEPName += "." + std::to_string(Index.getZExtValue()); } // Create a GEP for the indices collected above. Ptr = IRB.CreateGEP(PtrElemTy, Ptr, ValIndices, GEPName); // If an offset is left we use byte-wise adjustment. if (IntOffset != 0) { Ptr = IRB.CreateBitCast(Ptr, IRB.getInt8PtrTy()); Ptr = IRB.CreateGEP(IRB.getInt8Ty(), Ptr, IRB.getInt(IntOffset), GEPName + ".b" + Twine(IntOffset.getZExtValue())); } } // Ensure the result has the requested type. Ptr = IRB.CreatePointerBitCastOrAddrSpaceCast(Ptr, ResTy, Ptr->getName() + ".cast"); LLVM_DEBUG(dbgs() << "Constructed pointer: " << *Ptr << "\n"); return Ptr; } bool AA::getAssumedUnderlyingObjects(Attributor &A, const Value &Ptr, SmallSetVector &Objects, const AbstractAttribute &QueryingAA, const Instruction *CtxI, bool &UsedAssumedInformation, AA::ValueScope S, SmallPtrSetImpl *SeenObjects) { SmallPtrSet LocalSeenObjects; if (!SeenObjects) SeenObjects = &LocalSeenObjects; SmallVector Values; if (!A.getAssumedSimplifiedValues(IRPosition::value(Ptr), &QueryingAA, Values, S, UsedAssumedInformation)) { Objects.insert(const_cast(&Ptr)); return true; } for (auto &VAC : Values) { Value *UO = getUnderlyingObject(VAC.getValue()); if (UO && UO != VAC.getValue() && SeenObjects->insert(UO).second) { if (!getAssumedUnderlyingObjects(A, *UO, Objects, QueryingAA, VAC.getCtxI(), UsedAssumedInformation, S, SeenObjects)) return false; continue; } Objects.insert(VAC.getValue()); } return true; } static const Value * stripAndAccumulateOffsets(Attributor &A, const AbstractAttribute &QueryingAA, const Value *Val, const DataLayout &DL, APInt &Offset, bool GetMinOffset, bool AllowNonInbounds, bool UseAssumed = false) { auto AttributorAnalysis = [&](Value &V, APInt &ROffset) -> bool { const IRPosition &Pos = IRPosition::value(V); // Only track dependence if we are going to use the assumed info. const AAValueConstantRange &ValueConstantRangeAA = A.getAAFor(QueryingAA, Pos, UseAssumed ? DepClassTy::OPTIONAL : DepClassTy::NONE); ConstantRange Range = UseAssumed ? ValueConstantRangeAA.getAssumed() : ValueConstantRangeAA.getKnown(); if (Range.isFullSet()) return false; // We can only use the lower part of the range because the upper part can // be higher than what the value can really be. if (GetMinOffset) ROffset = Range.getSignedMin(); else ROffset = Range.getSignedMax(); return true; }; return Val->stripAndAccumulateConstantOffsets(DL, Offset, AllowNonInbounds, /* AllowInvariant */ true, AttributorAnalysis); } static const Value * getMinimalBaseOfPointer(Attributor &A, const AbstractAttribute &QueryingAA, const Value *Ptr, int64_t &BytesOffset, const DataLayout &DL, bool AllowNonInbounds = false) { APInt OffsetAPInt(DL.getIndexTypeSizeInBits(Ptr->getType()), 0); const Value *Base = stripAndAccumulateOffsets(A, QueryingAA, Ptr, DL, OffsetAPInt, /* GetMinOffset */ true, AllowNonInbounds); BytesOffset = OffsetAPInt.getSExtValue(); return Base; } /// Clamp the information known for all returned values of a function /// (identified by \p QueryingAA) into \p S. template static void clampReturnedValueStates( Attributor &A, const AAType &QueryingAA, StateType &S, const IRPosition::CallBaseContext *CBContext = nullptr) { LLVM_DEBUG(dbgs() << "[Attributor] Clamp return value states for " << QueryingAA << " into " << S << "\n"); assert((QueryingAA.getIRPosition().getPositionKind() == IRPosition::IRP_RETURNED || QueryingAA.getIRPosition().getPositionKind() == IRPosition::IRP_CALL_SITE_RETURNED) && "Can only clamp returned value states for a function returned or call " "site returned position!"); // Use an optional state as there might not be any return values and we want // to join (IntegerState::operator&) the state of all there are. Optional T; // Callback for each possibly returned value. auto CheckReturnValue = [&](Value &RV) -> bool { const IRPosition &RVPos = IRPosition::value(RV, CBContext); const AAType &AA = A.getAAFor(QueryingAA, RVPos, DepClassTy::REQUIRED); LLVM_DEBUG(dbgs() << "[Attributor] RV: " << RV << " AA: " << AA.getAsStr() << " @ " << RVPos << "\n"); const StateType &AAS = AA.getState(); if (!T) T = StateType::getBestState(AAS); *T &= AAS; LLVM_DEBUG(dbgs() << "[Attributor] AA State: " << AAS << " RV State: " << T << "\n"); return T->isValidState(); }; if (!A.checkForAllReturnedValues(CheckReturnValue, QueryingAA)) S.indicatePessimisticFixpoint(); else if (T) S ^= *T; } namespace { /// Helper class for generic deduction: return value -> returned position. template struct AAReturnedFromReturnedValues : public BaseType { AAReturnedFromReturnedValues(const IRPosition &IRP, Attributor &A) : BaseType(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { StateType S(StateType::getBestState(this->getState())); clampReturnedValueStates( A, *this, S, PropagateCallBaseContext ? this->getCallBaseContext() : nullptr); // TODO: If we know we visited all returned values, thus no are assumed // dead, we can take the known information from the state T. return clampStateAndIndicateChange(this->getState(), S); } }; /// Clamp the information known at all call sites for a given argument /// (identified by \p QueryingAA) into \p S. template static void clampCallSiteArgumentStates(Attributor &A, const AAType &QueryingAA, StateType &S) { LLVM_DEBUG(dbgs() << "[Attributor] Clamp call site argument states for " << QueryingAA << " into " << S << "\n"); assert(QueryingAA.getIRPosition().getPositionKind() == IRPosition::IRP_ARGUMENT && "Can only clamp call site argument states for an argument position!"); // Use an optional state as there might not be any return values and we want // to join (IntegerState::operator&) the state of all there are. Optional T; // The argument number which is also the call site argument number. unsigned ArgNo = QueryingAA.getIRPosition().getCallSiteArgNo(); auto CallSiteCheck = [&](AbstractCallSite ACS) { const IRPosition &ACSArgPos = IRPosition::callsite_argument(ACS, ArgNo); // Check if a coresponding argument was found or if it is on not associated // (which can happen for callback calls). if (ACSArgPos.getPositionKind() == IRPosition::IRP_INVALID) return false; const AAType &AA = A.getAAFor(QueryingAA, ACSArgPos, DepClassTy::REQUIRED); LLVM_DEBUG(dbgs() << "[Attributor] ACS: " << *ACS.getInstruction() << " AA: " << AA.getAsStr() << " @" << ACSArgPos << "\n"); const StateType &AAS = AA.getState(); if (!T) T = StateType::getBestState(AAS); *T &= AAS; LLVM_DEBUG(dbgs() << "[Attributor] AA State: " << AAS << " CSA State: " << T << "\n"); return T->isValidState(); }; bool UsedAssumedInformation = false; if (!A.checkForAllCallSites(CallSiteCheck, QueryingAA, true, UsedAssumedInformation)) S.indicatePessimisticFixpoint(); else if (T) S ^= *T; } /// This function is the bridge between argument position and the call base /// context. template bool getArgumentStateFromCallBaseContext(Attributor &A, BaseType &QueryingAttribute, IRPosition &Pos, StateType &State) { assert((Pos.getPositionKind() == IRPosition::IRP_ARGUMENT) && "Expected an 'argument' position !"); const CallBase *CBContext = Pos.getCallBaseContext(); if (!CBContext) return false; int ArgNo = Pos.getCallSiteArgNo(); assert(ArgNo >= 0 && "Invalid Arg No!"); const auto &AA = A.getAAFor( QueryingAttribute, IRPosition::callsite_argument(*CBContext, ArgNo), DepClassTy::REQUIRED); const StateType &CBArgumentState = static_cast(AA.getState()); LLVM_DEBUG(dbgs() << "[Attributor] Briding Call site context to argument" << "Position:" << Pos << "CB Arg state:" << CBArgumentState << "\n"); // NOTE: If we want to do call site grouping it should happen here. State ^= CBArgumentState; return true; } /// Helper class for generic deduction: call site argument -> argument position. template struct AAArgumentFromCallSiteArguments : public BaseType { AAArgumentFromCallSiteArguments(const IRPosition &IRP, Attributor &A) : BaseType(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { StateType S = StateType::getBestState(this->getState()); if (BridgeCallBaseContext) { bool Success = getArgumentStateFromCallBaseContext( A, *this, this->getIRPosition(), S); if (Success) return clampStateAndIndicateChange(this->getState(), S); } clampCallSiteArgumentStates(A, *this, S); // TODO: If we know we visited all incoming values, thus no are assumed // dead, we can take the known information from the state T. return clampStateAndIndicateChange(this->getState(), S); } }; /// Helper class for generic replication: function returned -> cs returned. template struct AACallSiteReturnedFromReturned : public BaseType { AACallSiteReturnedFromReturned(const IRPosition &IRP, Attributor &A) : BaseType(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { assert(this->getIRPosition().getPositionKind() == IRPosition::IRP_CALL_SITE_RETURNED && "Can only wrap function returned positions for call site returned " "positions!"); auto &S = this->getState(); const Function *AssociatedFunction = this->getIRPosition().getAssociatedFunction(); if (!AssociatedFunction) return S.indicatePessimisticFixpoint(); CallBase &CBContext = cast(this->getAnchorValue()); if (IntroduceCallBaseContext) LLVM_DEBUG(dbgs() << "[Attributor] Introducing call base context:" << CBContext << "\n"); IRPosition FnPos = IRPosition::returned( *AssociatedFunction, IntroduceCallBaseContext ? &CBContext : nullptr); const AAType &AA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(S, AA.getState()); } }; /// Helper function to accumulate uses. template static void followUsesInContext(AAType &AA, Attributor &A, MustBeExecutedContextExplorer &Explorer, const Instruction *CtxI, SetVector &Uses, StateType &State) { auto EIt = Explorer.begin(CtxI), EEnd = Explorer.end(CtxI); for (unsigned u = 0; u < Uses.size(); ++u) { const Use *U = Uses[u]; if (const Instruction *UserI = dyn_cast(U->getUser())) { bool Found = Explorer.findInContextOf(UserI, EIt, EEnd); if (Found && AA.followUseInMBEC(A, U, UserI, State)) for (const Use &Us : UserI->uses()) Uses.insert(&Us); } } } /// Use the must-be-executed-context around \p I to add information into \p S. /// The AAType class is required to have `followUseInMBEC` method with the /// following signature and behaviour: /// /// bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I) /// U - Underlying use. /// I - The user of the \p U. /// Returns true if the value should be tracked transitively. /// template static void followUsesInMBEC(AAType &AA, Attributor &A, StateType &S, Instruction &CtxI) { // Container for (transitive) uses of the associated value. SetVector Uses; for (const Use &U : AA.getIRPosition().getAssociatedValue().uses()) Uses.insert(&U); MustBeExecutedContextExplorer &Explorer = A.getInfoCache().getMustBeExecutedContextExplorer(); followUsesInContext(AA, A, Explorer, &CtxI, Uses, S); if (S.isAtFixpoint()) return; SmallVector BrInsts; auto Pred = [&](const Instruction *I) { if (const BranchInst *Br = dyn_cast(I)) if (Br->isConditional()) BrInsts.push_back(Br); return true; }; // Here, accumulate conditional branch instructions in the context. We // explore the child paths and collect the known states. The disjunction of // those states can be merged to its own state. Let ParentState_i be a state // to indicate the known information for an i-th branch instruction in the // context. ChildStates are created for its successors respectively. // // ParentS_1 = ChildS_{1, 1} /\ ChildS_{1, 2} /\ ... /\ ChildS_{1, n_1} // ParentS_2 = ChildS_{2, 1} /\ ChildS_{2, 2} /\ ... /\ ChildS_{2, n_2} // ... // ParentS_m = ChildS_{m, 1} /\ ChildS_{m, 2} /\ ... /\ ChildS_{m, n_m} // // Known State |= ParentS_1 \/ ParentS_2 \/... \/ ParentS_m // // FIXME: Currently, recursive branches are not handled. For example, we // can't deduce that ptr must be dereferenced in below function. // // void f(int a, int c, int *ptr) { // if(a) // if (b) { // *ptr = 0; // } else { // *ptr = 1; // } // else { // if (b) { // *ptr = 0; // } else { // *ptr = 1; // } // } // } Explorer.checkForAllContext(&CtxI, Pred); for (const BranchInst *Br : BrInsts) { StateType ParentState; // The known state of the parent state is a conjunction of children's // known states so it is initialized with a best state. ParentState.indicateOptimisticFixpoint(); for (const BasicBlock *BB : Br->successors()) { StateType ChildState; size_t BeforeSize = Uses.size(); followUsesInContext(AA, A, Explorer, &BB->front(), Uses, ChildState); // Erase uses which only appear in the child. for (auto It = Uses.begin() + BeforeSize; It != Uses.end();) It = Uses.erase(It); ParentState &= ChildState; } // Use only known state. S += ParentState; } } } // namespace /// ------------------------ PointerInfo --------------------------------------- namespace llvm { namespace AA { namespace PointerInfo { struct State; } // namespace PointerInfo } // namespace AA /// Helper for AA::PointerInfo::Acccess DenseMap/Set usage. template <> struct DenseMapInfo : DenseMapInfo { using Access = AAPointerInfo::Access; static inline Access getEmptyKey(); static inline Access getTombstoneKey(); static unsigned getHashValue(const Access &A); static bool isEqual(const Access &LHS, const Access &RHS); }; /// Helper that allows OffsetAndSize as a key in a DenseMap. template <> struct DenseMapInfo : DenseMapInfo> {}; /// Helper for AA::PointerInfo::Acccess DenseMap/Set usage ignoring everythign /// but the instruction struct AccessAsInstructionInfo : DenseMapInfo { using Base = DenseMapInfo; using Access = AAPointerInfo::Access; static inline Access getEmptyKey(); static inline Access getTombstoneKey(); static unsigned getHashValue(const Access &A); static bool isEqual(const Access &LHS, const Access &RHS); }; } // namespace llvm /// A type to track pointer/struct usage and accesses for AAPointerInfo. struct AA::PointerInfo::State : public AbstractState { ~State() { // We do not delete the Accesses objects but need to destroy them still. for (auto &It : AccessBins) It.second->~Accesses(); } /// Return the best possible representable state. static State getBestState(const State &SIS) { return State(); } /// Return the worst possible representable state. static State getWorstState(const State &SIS) { State R; R.indicatePessimisticFixpoint(); return R; } State() = default; State(State &&SIS) : AccessBins(std::move(SIS.AccessBins)) { SIS.AccessBins.clear(); } const State &getAssumed() const { return *this; } /// See AbstractState::isValidState(). bool isValidState() const override { return BS.isValidState(); } /// See AbstractState::isAtFixpoint(). bool isAtFixpoint() const override { return BS.isAtFixpoint(); } /// See AbstractState::indicateOptimisticFixpoint(). ChangeStatus indicateOptimisticFixpoint() override { BS.indicateOptimisticFixpoint(); return ChangeStatus::UNCHANGED; } /// See AbstractState::indicatePessimisticFixpoint(). ChangeStatus indicatePessimisticFixpoint() override { BS.indicatePessimisticFixpoint(); return ChangeStatus::CHANGED; } State &operator=(const State &R) { if (this == &R) return *this; BS = R.BS; AccessBins = R.AccessBins; return *this; } State &operator=(State &&R) { if (this == &R) return *this; std::swap(BS, R.BS); std::swap(AccessBins, R.AccessBins); return *this; } bool operator==(const State &R) const { if (BS != R.BS) return false; if (AccessBins.size() != R.AccessBins.size()) return false; auto It = begin(), RIt = R.begin(), E = end(); while (It != E) { if (It->getFirst() != RIt->getFirst()) return false; auto &Accs = It->getSecond(); auto &RAccs = RIt->getSecond(); if (Accs->size() != RAccs->size()) return false; for (const auto &ZipIt : llvm::zip(*Accs, *RAccs)) if (std::get<0>(ZipIt) != std::get<1>(ZipIt)) return false; ++It; ++RIt; } return true; } bool operator!=(const State &R) const { return !(*this == R); } /// We store accesses in a set with the instruction as key. struct Accesses { SmallVector Accesses; DenseMap Map; unsigned size() const { return Accesses.size(); } using vec_iterator = decltype(Accesses)::iterator; vec_iterator begin() { return Accesses.begin(); } vec_iterator end() { return Accesses.end(); } using iterator = decltype(Map)::const_iterator; iterator find(AAPointerInfo::Access &Acc) { return Map.find(Acc.getRemoteInst()); } iterator find_end() { return Map.end(); } AAPointerInfo::Access &get(iterator &It) { return Accesses[It->getSecond()]; } void insert(AAPointerInfo::Access &Acc) { Map[Acc.getRemoteInst()] = Accesses.size(); Accesses.push_back(Acc); } }; /// We store all accesses in bins denoted by their offset and size. using AccessBinsTy = DenseMap; AccessBinsTy::const_iterator begin() const { return AccessBins.begin(); } AccessBinsTy::const_iterator end() const { return AccessBins.end(); } protected: /// The bins with all the accesses for the associated pointer. AccessBinsTy AccessBins; /// Add a new access to the state at offset \p Offset and with size \p Size. /// The access is associated with \p I, writes \p Content (if anything), and /// is of kind \p Kind. /// \Returns CHANGED, if the state changed, UNCHANGED otherwise. ChangeStatus addAccess(Attributor &A, int64_t Offset, int64_t Size, Instruction &I, Optional Content, AAPointerInfo::AccessKind Kind, Type *Ty, Instruction *RemoteI = nullptr, Accesses *BinPtr = nullptr) { AAPointerInfo::OffsetAndSize Key{Offset, Size}; Accesses *&Bin = BinPtr ? BinPtr : AccessBins[Key]; if (!Bin) Bin = new (A.Allocator) Accesses; AAPointerInfo::Access Acc(&I, RemoteI ? RemoteI : &I, Content, Kind, Ty); // Check if we have an access for this instruction in this bin, if not, // simply add it. auto It = Bin->find(Acc); if (It == Bin->find_end()) { Bin->insert(Acc); return ChangeStatus::CHANGED; } // If the existing access is the same as then new one, nothing changed. AAPointerInfo::Access &Current = Bin->get(It); AAPointerInfo::Access Before = Current; // The new one will be combined with the existing one. Current &= Acc; return Current == Before ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } /// See AAPointerInfo::forallInterferingAccesses. bool forallInterferingAccesses( AAPointerInfo::OffsetAndSize OAS, function_ref CB) const { if (!isValidState()) return false; for (auto &It : AccessBins) { AAPointerInfo::OffsetAndSize ItOAS = It.getFirst(); if (!OAS.mayOverlap(ItOAS)) continue; bool IsExact = OAS == ItOAS && !OAS.offsetOrSizeAreUnknown(); for (auto &Access : *It.getSecond()) if (!CB(Access, IsExact)) return false; } return true; } /// See AAPointerInfo::forallInterferingAccesses. bool forallInterferingAccesses( Instruction &I, function_ref CB) const { if (!isValidState()) return false; // First find the offset and size of I. AAPointerInfo::OffsetAndSize OAS(-1, -1); for (auto &It : AccessBins) { for (auto &Access : *It.getSecond()) { if (Access.getRemoteInst() == &I) { OAS = It.getFirst(); break; } } if (OAS.getSize() != -1) break; } // No access for I was found, we are done. if (OAS.getSize() == -1) return true; // Now that we have an offset and size, find all overlapping ones and use // the callback on the accesses. return forallInterferingAccesses(OAS, CB); } private: /// State to track fixpoint and validity. BooleanState BS; }; namespace { struct AAPointerInfoImpl : public StateWrapper { using BaseTy = StateWrapper; AAPointerInfoImpl(const IRPosition &IRP, Attributor &A) : BaseTy(IRP) {} /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return std::string("PointerInfo ") + (isValidState() ? (std::string("#") + std::to_string(AccessBins.size()) + " bins") : ""); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { return AAPointerInfo::manifest(A); } bool forallInterferingAccesses( OffsetAndSize OAS, function_ref CB) const override { return State::forallInterferingAccesses(OAS, CB); } bool forallInterferingAccesses(Attributor &A, const AbstractAttribute &QueryingAA, Instruction &I, function_ref UserCB, bool &HasBeenWrittenTo) const override { HasBeenWrittenTo = false; SmallPtrSet DominatingWrites; SmallVector, 8> InterferingAccesses; Function &Scope = *I.getFunction(); const auto &NoSyncAA = A.getAAFor( QueryingAA, IRPosition::function(Scope), DepClassTy::OPTIONAL); const auto *ExecDomainAA = A.lookupAAFor( IRPosition::function(Scope), &QueryingAA, DepClassTy::OPTIONAL); const bool NoSync = NoSyncAA.isAssumedNoSync(); // Helper to determine if we need to consider threading, which we cannot // right now. However, if the function is (assumed) nosync or the thread // executing all instructions is the main thread only we can ignore // threading. auto CanIgnoreThreading = [&](const Instruction &I) -> bool { if (NoSync) return true; if (ExecDomainAA && ExecDomainAA->isExecutedByInitialThreadOnly(I)) return true; return false; }; // Helper to determine if the access is executed by the same thread as the // load, for now it is sufficient to avoid any potential threading effects // as we cannot deal with them anyway. auto IsSameThreadAsLoad = [&](const Access &Acc) -> bool { return CanIgnoreThreading(*Acc.getLocalInst()); }; // TODO: Use inter-procedural reachability and dominance. const auto &NoRecurseAA = A.getAAFor( QueryingAA, IRPosition::function(Scope), DepClassTy::OPTIONAL); const bool FindInterferingWrites = I.mayReadFromMemory(); const bool FindInterferingReads = I.mayWriteToMemory(); const bool UseDominanceReasoning = FindInterferingWrites && NoRecurseAA.isKnownNoRecurse(); const bool CanUseCFGResoning = CanIgnoreThreading(I); InformationCache &InfoCache = A.getInfoCache(); const DominatorTree *DT = InfoCache.getAnalysisResultForFunction(Scope); enum GPUAddressSpace : unsigned { Generic = 0, Global = 1, Shared = 3, Constant = 4, Local = 5, }; // Helper to check if a value has "kernel lifetime", that is it will not // outlive a GPU kernel. This is true for shared, constant, and local // globals on AMD and NVIDIA GPUs. auto HasKernelLifetime = [&](Value *V, Module &M) { Triple T(M.getTargetTriple()); if (!(T.isAMDGPU() || T.isNVPTX())) return false; switch (V->getType()->getPointerAddressSpace()) { case GPUAddressSpace::Shared: case GPUAddressSpace::Constant: case GPUAddressSpace::Local: return true; default: return false; }; }; // The IsLiveInCalleeCB will be used by the AA::isPotentiallyReachable query // to determine if we should look at reachability from the callee. For // certain pointers we know the lifetime and we do not have to step into the // callee to determine reachability as the pointer would be dead in the // callee. See the conditional initialization below. std::function IsLiveInCalleeCB; if (auto *AI = dyn_cast(&getAssociatedValue())) { // If the alloca containing function is not recursive the alloca // must be dead in the callee. const Function *AIFn = AI->getFunction(); const auto &NoRecurseAA = A.getAAFor( *this, IRPosition::function(*AIFn), DepClassTy::OPTIONAL); if (NoRecurseAA.isAssumedNoRecurse()) { IsLiveInCalleeCB = [AIFn](const Function &Fn) { return AIFn != &Fn; }; } } else if (auto *GV = dyn_cast(&getAssociatedValue())) { // If the global has kernel lifetime we can stop if we reach a kernel // as it is "dead" in the (unknown) callees. if (HasKernelLifetime(GV, *GV->getParent())) IsLiveInCalleeCB = [](const Function &Fn) { return !Fn.hasFnAttribute("kernel"); }; } auto AccessCB = [&](const Access &Acc, bool Exact) { if ((!FindInterferingWrites || !Acc.isWrite()) && (!FindInterferingReads || !Acc.isRead())) return true; bool Dominates = DT && Exact && Acc.isMustAccess() && (Acc.getLocalInst()->getFunction() == &Scope) && DT->dominates(Acc.getRemoteInst(), &I); if (FindInterferingWrites && Dominates) HasBeenWrittenTo = true; // For now we only filter accesses based on CFG reasoning which does not // work yet if we have threading effects, or the access is complicated. if (CanUseCFGResoning && Dominates && UseDominanceReasoning && IsSameThreadAsLoad(Acc)) DominatingWrites.insert(&Acc); InterferingAccesses.push_back({&Acc, Exact}); return true; }; if (!State::forallInterferingAccesses(I, AccessCB)) return false; if (HasBeenWrittenTo) { const Function *ScopePtr = &Scope; IsLiveInCalleeCB = [ScopePtr](const Function &Fn) { return ScopePtr != &Fn; }; } // Helper to determine if we can skip a specific write access. This is in // the worst case quadratic as we are looking for another write that will // hide the effect of this one. auto CanSkipAccess = [&](const Access &Acc, bool Exact) { if ((!Acc.isWrite() || !AA::isPotentiallyReachable(A, *Acc.getLocalInst(), I, QueryingAA, IsLiveInCalleeCB)) && (!Acc.isRead() || !AA::isPotentiallyReachable(A, I, *Acc.getLocalInst(), QueryingAA, IsLiveInCalleeCB))) return true; if (!DT || !UseDominanceReasoning) return false; if (!IsSameThreadAsLoad(Acc)) return false; if (!DominatingWrites.count(&Acc)) return false; for (const Access *DomAcc : DominatingWrites) { assert(Acc.getLocalInst()->getFunction() == DomAcc->getLocalInst()->getFunction() && "Expected dominating writes to be in the same function!"); if (DomAcc != &Acc && DT->dominates(Acc.getLocalInst(), DomAcc->getLocalInst())) { return true; } } return false; }; // Run the user callback on all accesses we cannot skip and return if that // succeeded for all or not. unsigned NumInterferingAccesses = InterferingAccesses.size(); for (auto &It : InterferingAccesses) { if (NumInterferingAccesses > MaxInterferingAccesses || !CanSkipAccess(*It.first, It.second)) { if (!UserCB(*It.first, It.second)) return false; } } return true; } ChangeStatus translateAndAddState(Attributor &A, const AAPointerInfo &OtherAA, int64_t Offset, CallBase &CB, bool FromCallee = false) { using namespace AA::PointerInfo; if (!OtherAA.getState().isValidState() || !isValidState()) return indicatePessimisticFixpoint(); const auto &OtherAAImpl = static_cast(OtherAA); bool IsByval = FromCallee && OtherAAImpl.getAssociatedArgument()->hasByValAttr(); // Combine the accesses bin by bin. ChangeStatus Changed = ChangeStatus::UNCHANGED; for (auto &It : OtherAAImpl.getState()) { OffsetAndSize OAS = OffsetAndSize::getUnknown(); if (Offset != OffsetAndSize::Unknown) OAS = OffsetAndSize(It.first.getOffset() + Offset, It.first.getSize()); Accesses *Bin = AccessBins.lookup(OAS); for (const AAPointerInfo::Access &RAcc : *It.second) { if (IsByval && !RAcc.isRead()) continue; bool UsedAssumedInformation = false; AccessKind AK = RAcc.getKind(); Optional Content = RAcc.getContent(); if (FromCallee) { Content = A.translateArgumentToCallSiteContent( RAcc.getContent(), CB, *this, UsedAssumedInformation); AK = AccessKind(AK & (IsByval ? AccessKind::AK_R : AccessKind::AK_RW)); AK = AccessKind(AK | (RAcc.isMayAccess() ? AK_MAY : AK_MUST)); } Changed = Changed | addAccess(A, OAS.getOffset(), OAS.getSize(), CB, Content, AK, RAcc.getType(), RAcc.getRemoteInst(), Bin); } } return Changed; } /// Statistic tracking for all AAPointerInfo implementations. /// See AbstractAttribute::trackStatistics(). void trackPointerInfoStatistics(const IRPosition &IRP) const {} /// Dump the state into \p O. void dumpState(raw_ostream &O) { for (auto &It : AccessBins) { O << "[" << It.first.getOffset() << "-" << It.first.getOffset() + It.first.getSize() << "] : " << It.getSecond()->size() << "\n"; for (auto &Acc : *It.getSecond()) { O << " - " << Acc.getKind() << " - " << *Acc.getLocalInst() << "\n"; if (Acc.getLocalInst() != Acc.getRemoteInst()) O << " --> " << *Acc.getRemoteInst() << "\n"; if (!Acc.isWrittenValueYetUndetermined()) { if (Acc.getWrittenValue()) O << " - c: " << *Acc.getWrittenValue() << "\n"; else O << " - c: \n"; } } } } }; struct AAPointerInfoFloating : public AAPointerInfoImpl { using AccessKind = AAPointerInfo::AccessKind; AAPointerInfoFloating(const IRPosition &IRP, Attributor &A) : AAPointerInfoImpl(IRP, A) {} /// Deal with an access and signal if it was handled successfully. bool handleAccess(Attributor &A, Instruction &I, Value &Ptr, Optional Content, AccessKind Kind, int64_t Offset, ChangeStatus &Changed, Type *Ty, int64_t Size = OffsetAndSize::Unknown) { using namespace AA::PointerInfo; // No need to find a size if one is given or the offset is unknown. if (Offset != OffsetAndSize::Unknown && Size == OffsetAndSize::Unknown && Ty) { const DataLayout &DL = A.getDataLayout(); TypeSize AccessSize = DL.getTypeStoreSize(Ty); if (!AccessSize.isScalable()) Size = AccessSize.getFixedSize(); } Changed = Changed | addAccess(A, Offset, Size, I, Content, Kind, Ty); return true; }; /// Helper struct, will support ranges eventually. struct OffsetInfo { int64_t Offset = OffsetAndSize::Unknown; bool operator==(const OffsetInfo &OI) const { return Offset == OI.Offset; } }; /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { using namespace AA::PointerInfo; ChangeStatus Changed = ChangeStatus::UNCHANGED; Value &AssociatedValue = getAssociatedValue(); const DataLayout &DL = A.getDataLayout(); DenseMap OffsetInfoMap; OffsetInfoMap[&AssociatedValue] = OffsetInfo{0}; auto HandlePassthroughUser = [&](Value *Usr, OffsetInfo PtrOI, bool &Follow) { OffsetInfo &UsrOI = OffsetInfoMap[Usr]; UsrOI = PtrOI; Follow = true; return true; }; const auto *TLI = getAnchorScope() ? A.getInfoCache().getTargetLibraryInfoForFunction( *getAnchorScope()) : nullptr; auto UsePred = [&](const Use &U, bool &Follow) -> bool { Value *CurPtr = U.get(); User *Usr = U.getUser(); LLVM_DEBUG(dbgs() << "[AAPointerInfo] Analyze " << *CurPtr << " in " << *Usr << "\n"); assert(OffsetInfoMap.count(CurPtr) && "The current pointer offset should have been seeded!"); if (ConstantExpr *CE = dyn_cast(Usr)) { if (CE->isCast()) return HandlePassthroughUser(Usr, OffsetInfoMap[CurPtr], Follow); if (CE->isCompare()) return true; if (!isa(CE)) { LLVM_DEBUG(dbgs() << "[AAPointerInfo] Unhandled constant user " << *CE << "\n"); return false; } } if (auto *GEP = dyn_cast(Usr)) { // Note the order here, the Usr access might change the map, CurPtr is // already in it though. OffsetInfo &UsrOI = OffsetInfoMap[Usr]; OffsetInfo &PtrOI = OffsetInfoMap[CurPtr]; UsrOI = PtrOI; // TODO: Use range information. if (PtrOI.Offset == OffsetAndSize::Unknown || !GEP->hasAllConstantIndices()) { UsrOI.Offset = OffsetAndSize::Unknown; Follow = true; return true; } SmallVector Indices; for (Use &Idx : GEP->indices()) { if (auto *CIdx = dyn_cast(Idx)) { Indices.push_back(CIdx); continue; } LLVM_DEBUG(dbgs() << "[AAPointerInfo] Non constant GEP index " << *GEP << " : " << *Idx << "\n"); return false; } UsrOI.Offset = PtrOI.Offset + DL.getIndexedOffsetInType( GEP->getSourceElementType(), Indices); Follow = true; return true; } if (isa(Usr) || isa(Usr) || isa(Usr)) return HandlePassthroughUser(Usr, OffsetInfoMap[CurPtr], Follow); // For PHIs we need to take care of the recurrence explicitly as the value // might change while we iterate through a loop. For now, we give up if // the PHI is not invariant. if (isa(Usr)) { // Note the order here, the Usr access might change the map, CurPtr is // already in it though. bool IsFirstPHIUser = !OffsetInfoMap.count(Usr); OffsetInfo &UsrOI = OffsetInfoMap[Usr]; OffsetInfo &PtrOI = OffsetInfoMap[CurPtr]; // Check if the PHI is invariant (so far). if (UsrOI == PtrOI) return true; // Check if the PHI operand has already an unknown offset as we can't // improve on that anymore. if (PtrOI.Offset == OffsetAndSize::Unknown) { UsrOI = PtrOI; Follow = true; return true; } // Check if the PHI operand is not dependent on the PHI itself. APInt Offset( DL.getIndexSizeInBits(CurPtr->getType()->getPointerAddressSpace()), 0); Value *CurPtrBase = CurPtr->stripAndAccumulateConstantOffsets( DL, Offset, /* AllowNonInbounds */ true); auto It = OffsetInfoMap.find(CurPtrBase); if (It != OffsetInfoMap.end()) { Offset += It->getSecond().Offset; if (IsFirstPHIUser || Offset == UsrOI.Offset) return HandlePassthroughUser(Usr, PtrOI, Follow); LLVM_DEBUG(dbgs() << "[AAPointerInfo] PHI operand pointer offset mismatch " << *CurPtr << " in " << *Usr << "\n"); } else { LLVM_DEBUG(dbgs() << "[AAPointerInfo] PHI operand is too complex " << *CurPtr << " in " << *Usr << "\n"); } // TODO: Approximate in case we know the direction of the recurrence. UsrOI = PtrOI; UsrOI.Offset = OffsetAndSize::Unknown; Follow = true; return true; } if (auto *LoadI = dyn_cast(Usr)) { // If the access is to a pointer that may or may not be the associated // value, e.g. due to a PHI, we cannot assume it will be read. AccessKind AK = AccessKind::AK_R; if (getUnderlyingObject(CurPtr) == &AssociatedValue) AK = AccessKind(AK | AccessKind::AK_MUST); else AK = AccessKind(AK | AccessKind::AK_MAY); return handleAccess(A, *LoadI, *CurPtr, /* Content */ nullptr, AK, OffsetInfoMap[CurPtr].Offset, Changed, LoadI->getType()); } if (auto *StoreI = dyn_cast(Usr)) { if (StoreI->getValueOperand() == CurPtr) { LLVM_DEBUG(dbgs() << "[AAPointerInfo] Escaping use in store " << *StoreI << "\n"); return false; } // If the access is to a pointer that may or may not be the associated // value, e.g. due to a PHI, we cannot assume it will be written. AccessKind AK = AccessKind::AK_W; if (getUnderlyingObject(CurPtr) == &AssociatedValue) AK = AccessKind(AK | AccessKind::AK_MUST); else AK = AccessKind(AK | AccessKind::AK_MAY); bool UsedAssumedInformation = false; Optional Content = A.getAssumedSimplified(*StoreI->getValueOperand(), *this, UsedAssumedInformation, AA::Interprocedural); return handleAccess(A, *StoreI, *CurPtr, Content, AK, OffsetInfoMap[CurPtr].Offset, Changed, StoreI->getValueOperand()->getType()); } if (auto *CB = dyn_cast(Usr)) { if (CB->isLifetimeStartOrEnd()) return true; if (getFreedOperand(CB, TLI) == U) return true; if (CB->isArgOperand(&U)) { unsigned ArgNo = CB->getArgOperandNo(&U); const auto &CSArgPI = A.getAAFor( *this, IRPosition::callsite_argument(*CB, ArgNo), DepClassTy::REQUIRED); Changed = translateAndAddState(A, CSArgPI, OffsetInfoMap[CurPtr].Offset, *CB) | Changed; return isValidState(); } LLVM_DEBUG(dbgs() << "[AAPointerInfo] Call user not handled " << *CB << "\n"); // TODO: Allow some call uses return false; } LLVM_DEBUG(dbgs() << "[AAPointerInfo] User not handled " << *Usr << "\n"); return false; }; auto EquivalentUseCB = [&](const Use &OldU, const Use &NewU) { if (OffsetInfoMap.count(NewU)) { LLVM_DEBUG({ if (!(OffsetInfoMap[NewU] == OffsetInfoMap[OldU])) { dbgs() << "[AAPointerInfo] Equivalent use callback failed: " << OffsetInfoMap[NewU].Offset << " vs " << OffsetInfoMap[OldU].Offset << "\n"; } }); return OffsetInfoMap[NewU] == OffsetInfoMap[OldU]; } OffsetInfoMap[NewU] = OffsetInfoMap[OldU]; return true; }; if (!A.checkForAllUses(UsePred, *this, AssociatedValue, /* CheckBBLivenessOnly */ true, DepClassTy::OPTIONAL, /* IgnoreDroppableUses */ true, EquivalentUseCB)) { LLVM_DEBUG( dbgs() << "[AAPointerInfo] Check for all uses failed, abort!\n"); return indicatePessimisticFixpoint(); } LLVM_DEBUG({ dbgs() << "Accesses by bin after update:\n"; dumpState(dbgs()); }); return Changed; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition()); } }; struct AAPointerInfoReturned final : AAPointerInfoImpl { AAPointerInfoReturned(const IRPosition &IRP, Attributor &A) : AAPointerInfoImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { return indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition()); } }; struct AAPointerInfoArgument final : AAPointerInfoFloating { AAPointerInfoArgument(const IRPosition &IRP, Attributor &A) : AAPointerInfoFloating(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAPointerInfoFloating::initialize(A); if (getAnchorScope()->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition()); } }; struct AAPointerInfoCallSiteArgument final : AAPointerInfoFloating { AAPointerInfoCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAPointerInfoFloating(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { using namespace AA::PointerInfo; // We handle memory intrinsics explicitly, at least the first (= // destination) and second (=source) arguments as we know how they are // accessed. if (auto *MI = dyn_cast_or_null(getCtxI())) { ConstantInt *Length = dyn_cast(MI->getLength()); int64_t LengthVal = OffsetAndSize::Unknown; if (Length) LengthVal = Length->getSExtValue(); Value &Ptr = getAssociatedValue(); unsigned ArgNo = getIRPosition().getCallSiteArgNo(); ChangeStatus Changed = ChangeStatus::UNCHANGED; if (ArgNo == 0) { handleAccess(A, *MI, Ptr, nullptr, AccessKind::AK_MUST_WRITE, 0, Changed, nullptr, LengthVal); } else if (ArgNo == 1) { handleAccess(A, *MI, Ptr, nullptr, AccessKind::AK_MUST_READ, 0, Changed, nullptr, LengthVal); } else { LLVM_DEBUG(dbgs() << "[AAPointerInfo] Unhandled memory intrinsic " << *MI << "\n"); return indicatePessimisticFixpoint(); } LLVM_DEBUG({ dbgs() << "Accesses by bin after update:\n"; dumpState(dbgs()); }); return Changed; } // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Argument *Arg = getAssociatedArgument(); if (!Arg) return indicatePessimisticFixpoint(); const IRPosition &ArgPos = IRPosition::argument(*Arg); auto &ArgAA = A.getAAFor(*this, ArgPos, DepClassTy::REQUIRED); return translateAndAddState(A, ArgAA, 0, *cast(getCtxI()), /* FromCallee */ true); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition()); } }; struct AAPointerInfoCallSiteReturned final : AAPointerInfoFloating { AAPointerInfoCallSiteReturned(const IRPosition &IRP, Attributor &A) : AAPointerInfoFloating(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition()); } }; } // namespace /// -----------------------NoUnwind Function Attribute-------------------------- namespace { struct AANoUnwindImpl : AANoUnwind { AANoUnwindImpl(const IRPosition &IRP, Attributor &A) : AANoUnwind(IRP, A) {} const std::string getAsStr() const override { return getAssumed() ? "nounwind" : "may-unwind"; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { auto Opcodes = { (unsigned)Instruction::Invoke, (unsigned)Instruction::CallBr, (unsigned)Instruction::Call, (unsigned)Instruction::CleanupRet, (unsigned)Instruction::CatchSwitch, (unsigned)Instruction::Resume}; auto CheckForNoUnwind = [&](Instruction &I) { if (!I.mayThrow()) return true; if (const auto *CB = dyn_cast(&I)) { const auto &NoUnwindAA = A.getAAFor( *this, IRPosition::callsite_function(*CB), DepClassTy::REQUIRED); return NoUnwindAA.isAssumedNoUnwind(); } return false; }; bool UsedAssumedInformation = false; if (!A.checkForAllInstructions(CheckForNoUnwind, *this, Opcodes, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } }; struct AANoUnwindFunction final : public AANoUnwindImpl { AANoUnwindFunction(const IRPosition &IRP, Attributor &A) : AANoUnwindImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(nounwind) } }; /// NoUnwind attribute deduction for a call sites. struct AANoUnwindCallSite final : AANoUnwindImpl { AANoUnwindCallSite(const IRPosition &IRP, Attributor &A) : AANoUnwindImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoUnwindImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Function *F = getAssociatedFunction(); const IRPosition &FnPos = IRPosition::function(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), FnAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(nounwind); } }; } // namespace /// --------------------- Function Return Values ------------------------------- namespace { /// "Attribute" that collects all potential returned values and the return /// instructions that they arise from. /// /// If there is a unique returned value R, the manifest method will: /// - mark R with the "returned" attribute, if R is an argument. class AAReturnedValuesImpl : public AAReturnedValues, public AbstractState { /// Mapping of values potentially returned by the associated function to the /// return instructions that might return them. MapVector> ReturnedValues; /// State flags /// ///{ bool IsFixed = false; bool IsValidState = true; ///} public: AAReturnedValuesImpl(const IRPosition &IRP, Attributor &A) : AAReturnedValues(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { // Reset the state. IsFixed = false; IsValidState = true; ReturnedValues.clear(); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) { indicatePessimisticFixpoint(); return; } assert(!F->getReturnType()->isVoidTy() && "Did not expect a void return type!"); // The map from instruction opcodes to those instructions in the function. auto &OpcodeInstMap = A.getInfoCache().getOpcodeInstMapForFunction(*F); // Look through all arguments, if one is marked as returned we are done. for (Argument &Arg : F->args()) { if (Arg.hasReturnedAttr()) { auto &ReturnInstSet = ReturnedValues[&Arg]; if (auto *Insts = OpcodeInstMap.lookup(Instruction::Ret)) for (Instruction *RI : *Insts) ReturnInstSet.insert(cast(RI)); indicateOptimisticFixpoint(); return; } } if (!A.isFunctionIPOAmendable(*F)) indicatePessimisticFixpoint(); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override; /// See AbstractAttribute::getState(...). AbstractState &getState() override { return *this; } /// See AbstractAttribute::getState(...). const AbstractState &getState() const override { return *this; } /// See AbstractAttribute::updateImpl(Attributor &A). ChangeStatus updateImpl(Attributor &A) override; llvm::iterator_range returned_values() override { return llvm::make_range(ReturnedValues.begin(), ReturnedValues.end()); } llvm::iterator_range returned_values() const override { return llvm::make_range(ReturnedValues.begin(), ReturnedValues.end()); } /// Return the number of potential return values, -1 if unknown. size_t getNumReturnValues() const override { return isValidState() ? ReturnedValues.size() : -1; } /// Return an assumed unique return value if a single candidate is found. If /// there cannot be one, return a nullptr. If it is not clear yet, return the /// Optional::NoneType. Optional getAssumedUniqueReturnValue(Attributor &A) const; /// See AbstractState::checkForAllReturnedValues(...). bool checkForAllReturnedValuesAndReturnInsts( function_ref &)> Pred) const override; /// Pretty print the attribute similar to the IR representation. const std::string getAsStr() const override; /// See AbstractState::isAtFixpoint(). bool isAtFixpoint() const override { return IsFixed; } /// See AbstractState::isValidState(). bool isValidState() const override { return IsValidState; } /// See AbstractState::indicateOptimisticFixpoint(...). ChangeStatus indicateOptimisticFixpoint() override { IsFixed = true; return ChangeStatus::UNCHANGED; } ChangeStatus indicatePessimisticFixpoint() override { IsFixed = true; IsValidState = false; return ChangeStatus::CHANGED; } }; ChangeStatus AAReturnedValuesImpl::manifest(Attributor &A) { ChangeStatus Changed = ChangeStatus::UNCHANGED; // Bookkeeping. assert(isValidState()); STATS_DECLTRACK(KnownReturnValues, FunctionReturn, "Number of function with known return values"); // Check if we have an assumed unique return value that we could manifest. Optional UniqueRV = getAssumedUniqueReturnValue(A); if (!UniqueRV || !UniqueRV.value()) return Changed; // Bookkeeping. STATS_DECLTRACK(UniqueReturnValue, FunctionReturn, "Number of function with unique return"); // If the assumed unique return value is an argument, annotate it. if (auto *UniqueRVArg = dyn_cast(UniqueRV.value())) { if (UniqueRVArg->getType()->canLosslesslyBitCastTo( getAssociatedFunction()->getReturnType())) { getIRPosition() = IRPosition::argument(*UniqueRVArg); Changed = IRAttribute::manifest(A); } } return Changed; } const std::string AAReturnedValuesImpl::getAsStr() const { return (isAtFixpoint() ? "returns(#" : "may-return(#") + (isValidState() ? std::to_string(getNumReturnValues()) : "?") + ")"; } Optional AAReturnedValuesImpl::getAssumedUniqueReturnValue(Attributor &A) const { // If checkForAllReturnedValues provides a unique value, ignoring potential // undef values that can also be present, it is assumed to be the actual // return value and forwarded to the caller of this method. If there are // multiple, a nullptr is returned indicating there cannot be a unique // returned value. Optional UniqueRV; Type *Ty = getAssociatedFunction()->getReturnType(); auto Pred = [&](Value &RV) -> bool { UniqueRV = AA::combineOptionalValuesInAAValueLatice(UniqueRV, &RV, Ty); return UniqueRV != Optional(nullptr); }; if (!A.checkForAllReturnedValues(Pred, *this)) UniqueRV = nullptr; return UniqueRV; } bool AAReturnedValuesImpl::checkForAllReturnedValuesAndReturnInsts( function_ref &)> Pred) const { if (!isValidState()) return false; // Check all returned values but ignore call sites as long as we have not // encountered an overdefined one during an update. for (auto &It : ReturnedValues) { Value *RV = It.first; if (!Pred(*RV, It.second)) return false; } return true; } ChangeStatus AAReturnedValuesImpl::updateImpl(Attributor &A) { ChangeStatus Changed = ChangeStatus::UNCHANGED; SmallVector Values; bool UsedAssumedInformation = false; auto ReturnInstCB = [&](Instruction &I) { ReturnInst &Ret = cast(I); Values.clear(); if (!A.getAssumedSimplifiedValues(IRPosition::value(*Ret.getReturnValue()), *this, Values, AA::Intraprocedural, UsedAssumedInformation)) Values.push_back({*Ret.getReturnValue(), Ret}); for (auto &VAC : Values) { assert(AA::isValidInScope(*VAC.getValue(), Ret.getFunction()) && "Assumed returned value should be valid in function scope!"); if (ReturnedValues[VAC.getValue()].insert(&Ret)) Changed = ChangeStatus::CHANGED; } return true; }; // Discover returned values from all live returned instructions in the // associated function. if (!A.checkForAllInstructions(ReturnInstCB, *this, {Instruction::Ret}, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return Changed; } struct AAReturnedValuesFunction final : public AAReturnedValuesImpl { AAReturnedValuesFunction(const IRPosition &IRP, Attributor &A) : AAReturnedValuesImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(returned) } }; /// Returned values information for a call sites. struct AAReturnedValuesCallSite final : AAReturnedValuesImpl { AAReturnedValuesCallSite(const IRPosition &IRP, Attributor &A) : AAReturnedValuesImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites instead of // redirecting requests to the callee. llvm_unreachable("Abstract attributes for returned values are not " "supported for call sites yet!"); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { return indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override {} }; } // namespace /// ------------------------ NoSync Function Attribute ------------------------- bool AANoSync::isNonRelaxedAtomic(const Instruction *I) { if (!I->isAtomic()) return false; if (auto *FI = dyn_cast(I)) // All legal orderings for fence are stronger than monotonic. return FI->getSyncScopeID() != SyncScope::SingleThread; if (auto *AI = dyn_cast(I)) { // Unordered is not a legal ordering for cmpxchg. return (AI->getSuccessOrdering() != AtomicOrdering::Monotonic || AI->getFailureOrdering() != AtomicOrdering::Monotonic); } AtomicOrdering Ordering; switch (I->getOpcode()) { case Instruction::AtomicRMW: Ordering = cast(I)->getOrdering(); break; case Instruction::Store: Ordering = cast(I)->getOrdering(); break; case Instruction::Load: Ordering = cast(I)->getOrdering(); break; default: llvm_unreachable( "New atomic operations need to be known in the attributor."); } return (Ordering != AtomicOrdering::Unordered && Ordering != AtomicOrdering::Monotonic); } /// Return true if this intrinsic is nosync. This is only used for intrinsics /// which would be nosync except that they have a volatile flag. All other /// intrinsics are simply annotated with the nosync attribute in Intrinsics.td. bool AANoSync::isNoSyncIntrinsic(const Instruction *I) { if (auto *MI = dyn_cast(I)) return !MI->isVolatile(); return false; } namespace { struct AANoSyncImpl : AANoSync { AANoSyncImpl(const IRPosition &IRP, Attributor &A) : AANoSync(IRP, A) {} const std::string getAsStr() const override { return getAssumed() ? "nosync" : "may-sync"; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override; }; ChangeStatus AANoSyncImpl::updateImpl(Attributor &A) { auto CheckRWInstForNoSync = [&](Instruction &I) { return AA::isNoSyncInst(A, I, *this); }; auto CheckForNoSync = [&](Instruction &I) { // At this point we handled all read/write effects and they are all // nosync, so they can be skipped. if (I.mayReadOrWriteMemory()) return true; // non-convergent and readnone imply nosync. return !cast(I).isConvergent(); }; bool UsedAssumedInformation = false; if (!A.checkForAllReadWriteInstructions(CheckRWInstForNoSync, *this, UsedAssumedInformation) || !A.checkForAllCallLikeInstructions(CheckForNoSync, *this, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } struct AANoSyncFunction final : public AANoSyncImpl { AANoSyncFunction(const IRPosition &IRP, Attributor &A) : AANoSyncImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(nosync) } }; /// NoSync attribute deduction for a call sites. struct AANoSyncCallSite final : AANoSyncImpl { AANoSyncCallSite(const IRPosition &IRP, Attributor &A) : AANoSyncImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoSyncImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Function *F = getAssociatedFunction(); const IRPosition &FnPos = IRPosition::function(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), FnAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(nosync); } }; } // namespace /// ------------------------ No-Free Attributes ---------------------------- namespace { struct AANoFreeImpl : public AANoFree { AANoFreeImpl(const IRPosition &IRP, Attributor &A) : AANoFree(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { auto CheckForNoFree = [&](Instruction &I) { const auto &CB = cast(I); if (CB.hasFnAttr(Attribute::NoFree)) return true; const auto &NoFreeAA = A.getAAFor( *this, IRPosition::callsite_function(CB), DepClassTy::REQUIRED); return NoFreeAA.isAssumedNoFree(); }; bool UsedAssumedInformation = false; if (!A.checkForAllCallLikeInstructions(CheckForNoFree, *this, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return getAssumed() ? "nofree" : "may-free"; } }; struct AANoFreeFunction final : public AANoFreeImpl { AANoFreeFunction(const IRPosition &IRP, Attributor &A) : AANoFreeImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(nofree) } }; /// NoFree attribute deduction for a call sites. struct AANoFreeCallSite final : AANoFreeImpl { AANoFreeCallSite(const IRPosition &IRP, Attributor &A) : AANoFreeImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoFreeImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Function *F = getAssociatedFunction(); const IRPosition &FnPos = IRPosition::function(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), FnAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(nofree); } }; /// NoFree attribute for floating values. struct AANoFreeFloating : AANoFreeImpl { AANoFreeFloating(const IRPosition &IRP, Attributor &A) : AANoFreeImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override{STATS_DECLTRACK_FLOATING_ATTR(nofree)} /// See Abstract Attribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { const IRPosition &IRP = getIRPosition(); const auto &NoFreeAA = A.getAAFor( *this, IRPosition::function_scope(IRP), DepClassTy::OPTIONAL); if (NoFreeAA.isAssumedNoFree()) return ChangeStatus::UNCHANGED; Value &AssociatedValue = getIRPosition().getAssociatedValue(); auto Pred = [&](const Use &U, bool &Follow) -> bool { Instruction *UserI = cast(U.getUser()); if (auto *CB = dyn_cast(UserI)) { if (CB->isBundleOperand(&U)) return false; if (!CB->isArgOperand(&U)) return true; unsigned ArgNo = CB->getArgOperandNo(&U); const auto &NoFreeArg = A.getAAFor( *this, IRPosition::callsite_argument(*CB, ArgNo), DepClassTy::REQUIRED); return NoFreeArg.isAssumedNoFree(); } if (isa(UserI) || isa(UserI) || isa(UserI) || isa(UserI)) { Follow = true; return true; } if (isa(UserI) || isa(UserI) || isa(UserI)) return true; // Unknown user. return false; }; if (!A.checkForAllUses(Pred, *this, AssociatedValue)) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } }; /// NoFree attribute for a call site argument. struct AANoFreeArgument final : AANoFreeFloating { AANoFreeArgument(const IRPosition &IRP, Attributor &A) : AANoFreeFloating(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(nofree) } }; /// NoFree attribute for call site arguments. struct AANoFreeCallSiteArgument final : AANoFreeFloating { AANoFreeCallSiteArgument(const IRPosition &IRP, Attributor &A) : AANoFreeFloating(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Argument *Arg = getAssociatedArgument(); if (!Arg) return indicatePessimisticFixpoint(); const IRPosition &ArgPos = IRPosition::argument(*Arg); auto &ArgAA = A.getAAFor(*this, ArgPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), ArgAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override{STATS_DECLTRACK_CSARG_ATTR(nofree)}; }; /// NoFree attribute for function return value. struct AANoFreeReturned final : AANoFreeFloating { AANoFreeReturned(const IRPosition &IRP, Attributor &A) : AANoFreeFloating(IRP, A) { llvm_unreachable("NoFree is not applicable to function returns!"); } /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { llvm_unreachable("NoFree is not applicable to function returns!"); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { llvm_unreachable("NoFree is not applicable to function returns!"); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override {} }; /// NoFree attribute deduction for a call site return value. struct AANoFreeCallSiteReturned final : AANoFreeFloating { AANoFreeCallSiteReturned(const IRPosition &IRP, Attributor &A) : AANoFreeFloating(IRP, A) {} ChangeStatus manifest(Attributor &A) override { return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(nofree) } }; } // namespace /// ------------------------ NonNull Argument Attribute ------------------------ namespace { static int64_t getKnownNonNullAndDerefBytesForUse( Attributor &A, const AbstractAttribute &QueryingAA, Value &AssociatedValue, const Use *U, const Instruction *I, bool &IsNonNull, bool &TrackUse) { TrackUse = false; const Value *UseV = U->get(); if (!UseV->getType()->isPointerTy()) return 0; // We need to follow common pointer manipulation uses to the accesses they // feed into. We can try to be smart to avoid looking through things we do not // like for now, e.g., non-inbounds GEPs. if (isa(I)) { TrackUse = true; return 0; } if (isa(I)) { TrackUse = true; return 0; } Type *PtrTy = UseV->getType(); const Function *F = I->getFunction(); bool NullPointerIsDefined = F ? llvm::NullPointerIsDefined(F, PtrTy->getPointerAddressSpace()) : true; const DataLayout &DL = A.getInfoCache().getDL(); if (const auto *CB = dyn_cast(I)) { if (CB->isBundleOperand(U)) { if (RetainedKnowledge RK = getKnowledgeFromUse( U, {Attribute::NonNull, Attribute::Dereferenceable})) { IsNonNull |= (RK.AttrKind == Attribute::NonNull || !NullPointerIsDefined); return RK.ArgValue; } return 0; } if (CB->isCallee(U)) { IsNonNull |= !NullPointerIsDefined; return 0; } unsigned ArgNo = CB->getArgOperandNo(U); IRPosition IRP = IRPosition::callsite_argument(*CB, ArgNo); // As long as we only use known information there is no need to track // dependences here. auto &DerefAA = A.getAAFor(QueryingAA, IRP, DepClassTy::NONE); IsNonNull |= DerefAA.isKnownNonNull(); return DerefAA.getKnownDereferenceableBytes(); } Optional Loc = MemoryLocation::getOrNone(I); if (!Loc || Loc->Ptr != UseV || !Loc->Size.isPrecise() || I->isVolatile()) return 0; int64_t Offset; const Value *Base = getMinimalBaseOfPointer(A, QueryingAA, Loc->Ptr, Offset, DL); if (Base && Base == &AssociatedValue) { int64_t DerefBytes = Loc->Size.getValue() + Offset; IsNonNull |= !NullPointerIsDefined; return std::max(int64_t(0), DerefBytes); } /// Corner case when an offset is 0. Base = GetPointerBaseWithConstantOffset(Loc->Ptr, Offset, DL, /*AllowNonInbounds*/ true); if (Base && Base == &AssociatedValue && Offset == 0) { int64_t DerefBytes = Loc->Size.getValue(); IsNonNull |= !NullPointerIsDefined; return std::max(int64_t(0), DerefBytes); } return 0; } struct AANonNullImpl : AANonNull { AANonNullImpl(const IRPosition &IRP, Attributor &A) : AANonNull(IRP, A), NullIsDefined(NullPointerIsDefined( getAnchorScope(), getAssociatedValue().getType()->getPointerAddressSpace())) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { Value &V = *getAssociatedValue().stripPointerCasts(); if (!NullIsDefined && hasAttr({Attribute::NonNull, Attribute::Dereferenceable}, /* IgnoreSubsumingPositions */ false, &A)) { indicateOptimisticFixpoint(); return; } if (isa(V)) { indicatePessimisticFixpoint(); return; } AANonNull::initialize(A); bool CanBeNull, CanBeFreed; if (V.getPointerDereferenceableBytes(A.getDataLayout(), CanBeNull, CanBeFreed)) { if (!CanBeNull) { indicateOptimisticFixpoint(); return; } } if (isa(V)) { indicatePessimisticFixpoint(); return; } if (Instruction *CtxI = getCtxI()) followUsesInMBEC(*this, A, getState(), *CtxI); } /// See followUsesInMBEC bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I, AANonNull::StateType &State) { bool IsNonNull = false; bool TrackUse = false; getKnownNonNullAndDerefBytesForUse(A, *this, getAssociatedValue(), U, I, IsNonNull, TrackUse); State.setKnown(IsNonNull); return TrackUse; } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return getAssumed() ? "nonnull" : "may-null"; } /// Flag to determine if the underlying value can be null and still allow /// valid accesses. const bool NullIsDefined; }; /// NonNull attribute for a floating value. struct AANonNullFloating : public AANonNullImpl { AANonNullFloating(const IRPosition &IRP, Attributor &A) : AANonNullImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { const DataLayout &DL = A.getDataLayout(); bool Stripped; bool UsedAssumedInformation = false; SmallVector Values; if (!A.getAssumedSimplifiedValues(getIRPosition(), *this, Values, AA::AnyScope, UsedAssumedInformation)) { Values.push_back({getAssociatedValue(), getCtxI()}); Stripped = false; } else { Stripped = Values.size() != 1 || Values.front().getValue() != &getAssociatedValue(); } DominatorTree *DT = nullptr; AssumptionCache *AC = nullptr; InformationCache &InfoCache = A.getInfoCache(); if (const Function *Fn = getAnchorScope()) { DT = InfoCache.getAnalysisResultForFunction(*Fn); AC = InfoCache.getAnalysisResultForFunction(*Fn); } AANonNull::StateType T; auto VisitValueCB = [&](Value &V, const Instruction *CtxI) -> bool { const auto &AA = A.getAAFor(*this, IRPosition::value(V), DepClassTy::REQUIRED); if (!Stripped && this == &AA) { if (!isKnownNonZero(&V, DL, 0, AC, CtxI, DT)) T.indicatePessimisticFixpoint(); } else { // Use abstract attribute information. const AANonNull::StateType &NS = AA.getState(); T ^= NS; } return T.isValidState(); }; for (const auto &VAC : Values) if (!VisitValueCB(*VAC.getValue(), VAC.getCtxI())) return indicatePessimisticFixpoint(); return clampStateAndIndicateChange(getState(), T); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(nonnull) } }; /// NonNull attribute for function return value. struct AANonNullReturned final : AAReturnedFromReturnedValues { AANonNullReturned(const IRPosition &IRP, Attributor &A) : AAReturnedFromReturnedValues(IRP, A) {} /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return getAssumed() ? "nonnull" : "may-null"; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(nonnull) } }; /// NonNull attribute for function argument. struct AANonNullArgument final : AAArgumentFromCallSiteArguments { AANonNullArgument(const IRPosition &IRP, Attributor &A) : AAArgumentFromCallSiteArguments(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(nonnull) } }; struct AANonNullCallSiteArgument final : AANonNullFloating { AANonNullCallSiteArgument(const IRPosition &IRP, Attributor &A) : AANonNullFloating(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(nonnull) } }; /// NonNull attribute for a call site return position. struct AANonNullCallSiteReturned final : AACallSiteReturnedFromReturned { AANonNullCallSiteReturned(const IRPosition &IRP, Attributor &A) : AACallSiteReturnedFromReturned(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(nonnull) } }; } // namespace /// ------------------------ No-Recurse Attributes ---------------------------- namespace { struct AANoRecurseImpl : public AANoRecurse { AANoRecurseImpl(const IRPosition &IRP, Attributor &A) : AANoRecurse(IRP, A) {} /// See AbstractAttribute::getAsStr() const std::string getAsStr() const override { return getAssumed() ? "norecurse" : "may-recurse"; } }; struct AANoRecurseFunction final : AANoRecurseImpl { AANoRecurseFunction(const IRPosition &IRP, Attributor &A) : AANoRecurseImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // If all live call sites are known to be no-recurse, we are as well. auto CallSitePred = [&](AbstractCallSite ACS) { const auto &NoRecurseAA = A.getAAFor( *this, IRPosition::function(*ACS.getInstruction()->getFunction()), DepClassTy::NONE); return NoRecurseAA.isKnownNoRecurse(); }; bool UsedAssumedInformation = false; if (A.checkForAllCallSites(CallSitePred, *this, true, UsedAssumedInformation)) { // If we know all call sites and all are known no-recurse, we are done. // If all known call sites, which might not be all that exist, are known // to be no-recurse, we are not done but we can continue to assume // no-recurse. If one of the call sites we have not visited will become // live, another update is triggered. if (!UsedAssumedInformation) indicateOptimisticFixpoint(); return ChangeStatus::UNCHANGED; } const AAFunctionReachability &EdgeReachability = A.getAAFor(*this, getIRPosition(), DepClassTy::REQUIRED); if (EdgeReachability.canReach(A, *getAnchorScope())) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(norecurse) } }; /// NoRecurse attribute deduction for a call sites. struct AANoRecurseCallSite final : AANoRecurseImpl { AANoRecurseCallSite(const IRPosition &IRP, Attributor &A) : AANoRecurseImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoRecurseImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Function *F = getAssociatedFunction(); const IRPosition &FnPos = IRPosition::function(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), FnAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(norecurse); } }; } // namespace /// -------------------- Undefined-Behavior Attributes ------------------------ namespace { struct AAUndefinedBehaviorImpl : public AAUndefinedBehavior { AAUndefinedBehaviorImpl(const IRPosition &IRP, Attributor &A) : AAUndefinedBehavior(IRP, A) {} /// See AbstractAttribute::updateImpl(...). // through a pointer (i.e. also branches etc.) ChangeStatus updateImpl(Attributor &A) override { const size_t UBPrevSize = KnownUBInsts.size(); const size_t NoUBPrevSize = AssumedNoUBInsts.size(); auto InspectMemAccessInstForUB = [&](Instruction &I) { // Lang ref now states volatile store is not UB, let's skip them. if (I.isVolatile() && I.mayWriteToMemory()) return true; // Skip instructions that are already saved. if (AssumedNoUBInsts.count(&I) || KnownUBInsts.count(&I)) return true; // If we reach here, we know we have an instruction // that accesses memory through a pointer operand, // for which getPointerOperand() should give it to us. Value *PtrOp = const_cast(getPointerOperand(&I, /* AllowVolatile */ true)); assert(PtrOp && "Expected pointer operand of memory accessing instruction"); // Either we stopped and the appropriate action was taken, // or we got back a simplified value to continue. Optional SimplifiedPtrOp = stopOnUndefOrAssumed(A, PtrOp, &I); if (!SimplifiedPtrOp || !SimplifiedPtrOp.value()) return true; const Value *PtrOpVal = SimplifiedPtrOp.value(); // A memory access through a pointer is considered UB // only if the pointer has constant null value. // TODO: Expand it to not only check constant values. if (!isa(PtrOpVal)) { AssumedNoUBInsts.insert(&I); return true; } const Type *PtrTy = PtrOpVal->getType(); // Because we only consider instructions inside functions, // assume that a parent function exists. const Function *F = I.getFunction(); // A memory access using constant null pointer is only considered UB // if null pointer is _not_ defined for the target platform. if (llvm::NullPointerIsDefined(F, PtrTy->getPointerAddressSpace())) AssumedNoUBInsts.insert(&I); else KnownUBInsts.insert(&I); return true; }; auto InspectBrInstForUB = [&](Instruction &I) { // A conditional branch instruction is considered UB if it has `undef` // condition. // Skip instructions that are already saved. if (AssumedNoUBInsts.count(&I) || KnownUBInsts.count(&I)) return true; // We know we have a branch instruction. auto *BrInst = cast(&I); // Unconditional branches are never considered UB. if (BrInst->isUnconditional()) return true; // Either we stopped and the appropriate action was taken, // or we got back a simplified value to continue. Optional SimplifiedCond = stopOnUndefOrAssumed(A, BrInst->getCondition(), BrInst); if (!SimplifiedCond || !*SimplifiedCond) return true; AssumedNoUBInsts.insert(&I); return true; }; auto InspectCallSiteForUB = [&](Instruction &I) { // Check whether a callsite always cause UB or not // Skip instructions that are already saved. if (AssumedNoUBInsts.count(&I) || KnownUBInsts.count(&I)) return true; // Check nonnull and noundef argument attribute violation for each // callsite. CallBase &CB = cast(I); Function *Callee = CB.getCalledFunction(); if (!Callee) return true; for (unsigned idx = 0; idx < CB.arg_size(); idx++) { // If current argument is known to be simplified to null pointer and the // corresponding argument position is known to have nonnull attribute, // the argument is poison. Furthermore, if the argument is poison and // the position is known to have noundef attriubte, this callsite is // considered UB. if (idx >= Callee->arg_size()) break; Value *ArgVal = CB.getArgOperand(idx); if (!ArgVal) continue; // Here, we handle three cases. // (1) Not having a value means it is dead. (we can replace the value // with undef) // (2) Simplified to undef. The argument violate noundef attriubte. // (3) Simplified to null pointer where known to be nonnull. // The argument is a poison value and violate noundef attribute. IRPosition CalleeArgumentIRP = IRPosition::callsite_argument(CB, idx); auto &NoUndefAA = A.getAAFor(*this, CalleeArgumentIRP, DepClassTy::NONE); if (!NoUndefAA.isKnownNoUndef()) continue; bool UsedAssumedInformation = false; Optional SimplifiedVal = A.getAssumedSimplified(IRPosition::value(*ArgVal), *this, UsedAssumedInformation, AA::Interprocedural); if (UsedAssumedInformation) continue; if (SimplifiedVal && !SimplifiedVal.value()) return true; if (!SimplifiedVal || isa(*SimplifiedVal.value())) { KnownUBInsts.insert(&I); continue; } if (!ArgVal->getType()->isPointerTy() || !isa(*SimplifiedVal.value())) continue; auto &NonNullAA = A.getAAFor(*this, CalleeArgumentIRP, DepClassTy::NONE); if (NonNullAA.isKnownNonNull()) KnownUBInsts.insert(&I); } return true; }; auto InspectReturnInstForUB = [&](Instruction &I) { auto &RI = cast(I); // Either we stopped and the appropriate action was taken, // or we got back a simplified return value to continue. Optional SimplifiedRetValue = stopOnUndefOrAssumed(A, RI.getReturnValue(), &I); if (!SimplifiedRetValue || !*SimplifiedRetValue) return true; // Check if a return instruction always cause UB or not // Note: It is guaranteed that the returned position of the anchor // scope has noundef attribute when this is called. // We also ensure the return position is not "assumed dead" // because the returned value was then potentially simplified to // `undef` in AAReturnedValues without removing the `noundef` // attribute yet. // When the returned position has noundef attriubte, UB occurs in the // following cases. // (1) Returned value is known to be undef. // (2) The value is known to be a null pointer and the returned // position has nonnull attribute (because the returned value is // poison). if (isa(*SimplifiedRetValue)) { auto &NonNullAA = A.getAAFor( *this, IRPosition::returned(*getAnchorScope()), DepClassTy::NONE); if (NonNullAA.isKnownNonNull()) KnownUBInsts.insert(&I); } return true; }; bool UsedAssumedInformation = false; A.checkForAllInstructions(InspectMemAccessInstForUB, *this, {Instruction::Load, Instruction::Store, Instruction::AtomicCmpXchg, Instruction::AtomicRMW}, UsedAssumedInformation, /* CheckBBLivenessOnly */ true); A.checkForAllInstructions(InspectBrInstForUB, *this, {Instruction::Br}, UsedAssumedInformation, /* CheckBBLivenessOnly */ true); A.checkForAllCallLikeInstructions(InspectCallSiteForUB, *this, UsedAssumedInformation); // If the returned position of the anchor scope has noundef attriubte, check // all returned instructions. if (!getAnchorScope()->getReturnType()->isVoidTy()) { const IRPosition &ReturnIRP = IRPosition::returned(*getAnchorScope()); if (!A.isAssumedDead(ReturnIRP, this, nullptr, UsedAssumedInformation)) { auto &RetPosNoUndefAA = A.getAAFor(*this, ReturnIRP, DepClassTy::NONE); if (RetPosNoUndefAA.isKnownNoUndef()) A.checkForAllInstructions(InspectReturnInstForUB, *this, {Instruction::Ret}, UsedAssumedInformation, /* CheckBBLivenessOnly */ true); } } if (NoUBPrevSize != AssumedNoUBInsts.size() || UBPrevSize != KnownUBInsts.size()) return ChangeStatus::CHANGED; return ChangeStatus::UNCHANGED; } bool isKnownToCauseUB(Instruction *I) const override { return KnownUBInsts.count(I); } bool isAssumedToCauseUB(Instruction *I) const override { // In simple words, if an instruction is not in the assumed to _not_ // cause UB, then it is assumed UB (that includes those // in the KnownUBInsts set). The rest is boilerplate // is to ensure that it is one of the instructions we test // for UB. switch (I->getOpcode()) { case Instruction::Load: case Instruction::Store: case Instruction::AtomicCmpXchg: case Instruction::AtomicRMW: return !AssumedNoUBInsts.count(I); case Instruction::Br: { auto *BrInst = cast(I); if (BrInst->isUnconditional()) return false; return !AssumedNoUBInsts.count(I); } break; default: return false; } return false; } ChangeStatus manifest(Attributor &A) override { if (KnownUBInsts.empty()) return ChangeStatus::UNCHANGED; for (Instruction *I : KnownUBInsts) A.changeToUnreachableAfterManifest(I); return ChangeStatus::CHANGED; } /// See AbstractAttribute::getAsStr() const std::string getAsStr() const override { return getAssumed() ? "undefined-behavior" : "no-ub"; } /// Note: The correctness of this analysis depends on the fact that the /// following 2 sets will stop changing after some point. /// "Change" here means that their size changes. /// The size of each set is monotonically increasing /// (we only add items to them) and it is upper bounded by the number of /// instructions in the processed function (we can never save more /// elements in either set than this number). Hence, at some point, /// they will stop increasing. /// Consequently, at some point, both sets will have stopped /// changing, effectively making the analysis reach a fixpoint. /// Note: These 2 sets are disjoint and an instruction can be considered /// one of 3 things: /// 1) Known to cause UB (AAUndefinedBehavior could prove it) and put it in /// the KnownUBInsts set. /// 2) Assumed to cause UB (in every updateImpl, AAUndefinedBehavior /// has a reason to assume it). /// 3) Assumed to not cause UB. very other instruction - AAUndefinedBehavior /// could not find a reason to assume or prove that it can cause UB, /// hence it assumes it doesn't. We have a set for these instructions /// so that we don't reprocess them in every update. /// Note however that instructions in this set may cause UB. protected: /// A set of all live instructions _known_ to cause UB. SmallPtrSet KnownUBInsts; private: /// A set of all the (live) instructions that are assumed to _not_ cause UB. SmallPtrSet AssumedNoUBInsts; // Should be called on updates in which if we're processing an instruction // \p I that depends on a value \p V, one of the following has to happen: // - If the value is assumed, then stop. // - If the value is known but undef, then consider it UB. // - Otherwise, do specific processing with the simplified value. // We return None in the first 2 cases to signify that an appropriate // action was taken and the caller should stop. // Otherwise, we return the simplified value that the caller should // use for specific processing. Optional stopOnUndefOrAssumed(Attributor &A, Value *V, Instruction *I) { bool UsedAssumedInformation = false; Optional SimplifiedV = A.getAssumedSimplified(IRPosition::value(*V), *this, UsedAssumedInformation, AA::Interprocedural); if (!UsedAssumedInformation) { // Don't depend on assumed values. if (!SimplifiedV) { // If it is known (which we tested above) but it doesn't have a value, // then we can assume `undef` and hence the instruction is UB. KnownUBInsts.insert(I); return llvm::None; } if (!*SimplifiedV) return nullptr; V = *SimplifiedV; } if (isa(V)) { KnownUBInsts.insert(I); return llvm::None; } return V; } }; struct AAUndefinedBehaviorFunction final : AAUndefinedBehaviorImpl { AAUndefinedBehaviorFunction(const IRPosition &IRP, Attributor &A) : AAUndefinedBehaviorImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECL(UndefinedBehaviorInstruction, Instruction, "Number of instructions known to have UB"); BUILD_STAT_NAME(UndefinedBehaviorInstruction, Instruction) += KnownUBInsts.size(); } }; } // namespace /// ------------------------ Will-Return Attributes ---------------------------- namespace { // Helper function that checks whether a function has any cycle which we don't // know if it is bounded or not. // Loops with maximum trip count are considered bounded, any other cycle not. static bool mayContainUnboundedCycle(Function &F, Attributor &A) { ScalarEvolution *SE = A.getInfoCache().getAnalysisResultForFunction(F); LoopInfo *LI = A.getInfoCache().getAnalysisResultForFunction(F); // If either SCEV or LoopInfo is not available for the function then we assume // any cycle to be unbounded cycle. // We use scc_iterator which uses Tarjan algorithm to find all the maximal // SCCs.To detect if there's a cycle, we only need to find the maximal ones. if (!SE || !LI) { for (scc_iterator SCCI = scc_begin(&F); !SCCI.isAtEnd(); ++SCCI) if (SCCI.hasCycle()) return true; return false; } // If there's irreducible control, the function may contain non-loop cycles. if (mayContainIrreducibleControl(F, LI)) return true; // Any loop that does not have a max trip count is considered unbounded cycle. for (auto *L : LI->getLoopsInPreorder()) { if (!SE->getSmallConstantMaxTripCount(L)) return true; } return false; } struct AAWillReturnImpl : public AAWillReturn { AAWillReturnImpl(const IRPosition &IRP, Attributor &A) : AAWillReturn(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAWillReturn::initialize(A); if (isImpliedByMustprogressAndReadonly(A, /* KnownOnly */ true)) { indicateOptimisticFixpoint(); return; } } /// Check for `mustprogress` and `readonly` as they imply `willreturn`. bool isImpliedByMustprogressAndReadonly(Attributor &A, bool KnownOnly) { // Check for `mustprogress` in the scope and the associated function which // might be different if this is a call site. if ((!getAnchorScope() || !getAnchorScope()->mustProgress()) && (!getAssociatedFunction() || !getAssociatedFunction()->mustProgress())) return false; bool IsKnown; if (AA::isAssumedReadOnly(A, getIRPosition(), *this, IsKnown)) return IsKnown || !KnownOnly; return false; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { if (isImpliedByMustprogressAndReadonly(A, /* KnownOnly */ false)) return ChangeStatus::UNCHANGED; auto CheckForWillReturn = [&](Instruction &I) { IRPosition IPos = IRPosition::callsite_function(cast(I)); const auto &WillReturnAA = A.getAAFor(*this, IPos, DepClassTy::REQUIRED); if (WillReturnAA.isKnownWillReturn()) return true; if (!WillReturnAA.isAssumedWillReturn()) return false; const auto &NoRecurseAA = A.getAAFor(*this, IPos, DepClassTy::REQUIRED); return NoRecurseAA.isAssumedNoRecurse(); }; bool UsedAssumedInformation = false; if (!A.checkForAllCallLikeInstructions(CheckForWillReturn, *this, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::getAsStr() const std::string getAsStr() const override { return getAssumed() ? "willreturn" : "may-noreturn"; } }; struct AAWillReturnFunction final : AAWillReturnImpl { AAWillReturnFunction(const IRPosition &IRP, Attributor &A) : AAWillReturnImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAWillReturnImpl::initialize(A); Function *F = getAnchorScope(); if (!F || F->isDeclaration() || mayContainUnboundedCycle(*F, A)) indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(willreturn) } }; /// WillReturn attribute deduction for a call sites. struct AAWillReturnCallSite final : AAWillReturnImpl { AAWillReturnCallSite(const IRPosition &IRP, Attributor &A) : AAWillReturnImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAWillReturnImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || !A.isFunctionIPOAmendable(*F)) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { if (isImpliedByMustprogressAndReadonly(A, /* KnownOnly */ false)) return ChangeStatus::UNCHANGED; // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Function *F = getAssociatedFunction(); const IRPosition &FnPos = IRPosition::function(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), FnAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(willreturn); } }; } // namespace /// -------------------AAReachability Attribute-------------------------- namespace { struct AAReachabilityImpl : AAReachability { AAReachabilityImpl(const IRPosition &IRP, Attributor &A) : AAReachability(IRP, A) {} const std::string getAsStr() const override { // TODO: Return the number of reachable queries. return "reachable"; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { return ChangeStatus::UNCHANGED; } }; struct AAReachabilityFunction final : public AAReachabilityImpl { AAReachabilityFunction(const IRPosition &IRP, Attributor &A) : AAReachabilityImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(reachable); } }; } // namespace /// ------------------------ NoAlias Argument Attribute ------------------------ namespace { struct AANoAliasImpl : AANoAlias { AANoAliasImpl(const IRPosition &IRP, Attributor &A) : AANoAlias(IRP, A) { assert(getAssociatedType()->isPointerTy() && "Noalias is a pointer attribute"); } const std::string getAsStr() const override { return getAssumed() ? "noalias" : "may-alias"; } }; /// NoAlias attribute for a floating value. struct AANoAliasFloating final : AANoAliasImpl { AANoAliasFloating(const IRPosition &IRP, Attributor &A) : AANoAliasImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoAliasImpl::initialize(A); Value *Val = &getAssociatedValue(); do { CastInst *CI = dyn_cast(Val); if (!CI) break; Value *Base = CI->getOperand(0); if (!Base->hasOneUse()) break; Val = Base; } while (true); if (!Val->getType()->isPointerTy()) { indicatePessimisticFixpoint(); return; } if (isa(Val)) indicateOptimisticFixpoint(); else if (isa(Val) && !NullPointerIsDefined(getAnchorScope(), Val->getType()->getPointerAddressSpace())) indicateOptimisticFixpoint(); else if (Val != &getAssociatedValue()) { const auto &ValNoAliasAA = A.getAAFor( *this, IRPosition::value(*Val), DepClassTy::OPTIONAL); if (ValNoAliasAA.isKnownNoAlias()) indicateOptimisticFixpoint(); } } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Implement this. return indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(noalias) } }; /// NoAlias attribute for an argument. struct AANoAliasArgument final : AAArgumentFromCallSiteArguments { using Base = AAArgumentFromCallSiteArguments; AANoAliasArgument(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { Base::initialize(A); // See callsite argument attribute and callee argument attribute. if (hasAttr({Attribute::ByVal})) indicateOptimisticFixpoint(); } /// See AbstractAttribute::update(...). ChangeStatus updateImpl(Attributor &A) override { // We have to make sure no-alias on the argument does not break // synchronization when this is a callback argument, see also [1] below. // If synchronization cannot be affected, we delegate to the base updateImpl // function, otherwise we give up for now. // If the function is no-sync, no-alias cannot break synchronization. const auto &NoSyncAA = A.getAAFor(*this, IRPosition::function_scope(getIRPosition()), DepClassTy::OPTIONAL); if (NoSyncAA.isAssumedNoSync()) return Base::updateImpl(A); // If the argument is read-only, no-alias cannot break synchronization. bool IsKnown; if (AA::isAssumedReadOnly(A, getIRPosition(), *this, IsKnown)) return Base::updateImpl(A); // If the argument is never passed through callbacks, no-alias cannot break // synchronization. bool UsedAssumedInformation = false; if (A.checkForAllCallSites( [](AbstractCallSite ACS) { return !ACS.isCallbackCall(); }, *this, true, UsedAssumedInformation)) return Base::updateImpl(A); // TODO: add no-alias but make sure it doesn't break synchronization by // introducing fake uses. See: // [1] Compiler Optimizations for OpenMP, J. Doerfert and H. Finkel, // International Workshop on OpenMP 2018, // http://compilers.cs.uni-saarland.de/people/doerfert/par_opt18.pdf return indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(noalias) } }; struct AANoAliasCallSiteArgument final : AANoAliasImpl { AANoAliasCallSiteArgument(const IRPosition &IRP, Attributor &A) : AANoAliasImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { // See callsite argument attribute and callee argument attribute. const auto &CB = cast(getAnchorValue()); if (CB.paramHasAttr(getCallSiteArgNo(), Attribute::NoAlias)) indicateOptimisticFixpoint(); Value &Val = getAssociatedValue(); if (isa(Val) && !NullPointerIsDefined(getAnchorScope(), Val.getType()->getPointerAddressSpace())) indicateOptimisticFixpoint(); } /// Determine if the underlying value may alias with the call site argument /// \p OtherArgNo of \p ICS (= the underlying call site). bool mayAliasWithArgument(Attributor &A, AAResults *&AAR, const AAMemoryBehavior &MemBehaviorAA, const CallBase &CB, unsigned OtherArgNo) { // We do not need to worry about aliasing with the underlying IRP. if (this->getCalleeArgNo() == (int)OtherArgNo) return false; // If it is not a pointer or pointer vector we do not alias. const Value *ArgOp = CB.getArgOperand(OtherArgNo); if (!ArgOp->getType()->isPtrOrPtrVectorTy()) return false; auto &CBArgMemBehaviorAA = A.getAAFor( *this, IRPosition::callsite_argument(CB, OtherArgNo), DepClassTy::NONE); // If the argument is readnone, there is no read-write aliasing. if (CBArgMemBehaviorAA.isAssumedReadNone()) { A.recordDependence(CBArgMemBehaviorAA, *this, DepClassTy::OPTIONAL); return false; } // If the argument is readonly and the underlying value is readonly, there // is no read-write aliasing. bool IsReadOnly = MemBehaviorAA.isAssumedReadOnly(); if (CBArgMemBehaviorAA.isAssumedReadOnly() && IsReadOnly) { A.recordDependence(MemBehaviorAA, *this, DepClassTy::OPTIONAL); A.recordDependence(CBArgMemBehaviorAA, *this, DepClassTy::OPTIONAL); return false; } // We have to utilize actual alias analysis queries so we need the object. if (!AAR) AAR = A.getInfoCache().getAAResultsForFunction(*getAnchorScope()); // Try to rule it out at the call site. bool IsAliasing = !AAR || !AAR->isNoAlias(&getAssociatedValue(), ArgOp); LLVM_DEBUG(dbgs() << "[NoAliasCSArg] Check alias between " "callsite arguments: " << getAssociatedValue() << " " << *ArgOp << " => " << (IsAliasing ? "" : "no-") << "alias \n"); return IsAliasing; } bool isKnownNoAliasDueToNoAliasPreservation(Attributor &A, AAResults *&AAR, const AAMemoryBehavior &MemBehaviorAA, const AANoAlias &NoAliasAA) { // We can deduce "noalias" if the following conditions hold. // (i) Associated value is assumed to be noalias in the definition. // (ii) Associated value is assumed to be no-capture in all the uses // possibly executed before this callsite. // (iii) There is no other pointer argument which could alias with the // value. bool AssociatedValueIsNoAliasAtDef = NoAliasAA.isAssumedNoAlias(); if (!AssociatedValueIsNoAliasAtDef) { LLVM_DEBUG(dbgs() << "[AANoAlias] " << getAssociatedValue() << " is not no-alias at the definition\n"); return false; } auto IsDereferenceableOrNull = [&](Value *O, const DataLayout &DL) { const auto &DerefAA = A.getAAFor( *this, IRPosition::value(*O), DepClassTy::OPTIONAL); return DerefAA.getAssumedDereferenceableBytes(); }; A.recordDependence(NoAliasAA, *this, DepClassTy::OPTIONAL); const IRPosition &VIRP = IRPosition::value(getAssociatedValue()); const Function *ScopeFn = VIRP.getAnchorScope(); auto &NoCaptureAA = A.getAAFor(*this, VIRP, DepClassTy::NONE); // Check whether the value is captured in the scope using AANoCapture. // Look at CFG and check only uses possibly executed before this // callsite. auto UsePred = [&](const Use &U, bool &Follow) -> bool { Instruction *UserI = cast(U.getUser()); // If UserI is the curr instruction and there is a single potential use of // the value in UserI we allow the use. // TODO: We should inspect the operands and allow those that cannot alias // with the value. if (UserI == getCtxI() && UserI->getNumOperands() == 1) return true; if (ScopeFn) { if (auto *CB = dyn_cast(UserI)) { if (CB->isArgOperand(&U)) { unsigned ArgNo = CB->getArgOperandNo(&U); const auto &NoCaptureAA = A.getAAFor( *this, IRPosition::callsite_argument(*CB, ArgNo), DepClassTy::OPTIONAL); if (NoCaptureAA.isAssumedNoCapture()) return true; } } if (!AA::isPotentiallyReachable( A, *UserI, *getCtxI(), *this, [ScopeFn](const Function &Fn) { return &Fn != ScopeFn; })) return true; } // TODO: We should track the capturing uses in AANoCapture but the problem // is CGSCC runs. For those we would need to "allow" AANoCapture for // a value in the module slice. switch (DetermineUseCaptureKind(U, IsDereferenceableOrNull)) { case UseCaptureKind::NO_CAPTURE: return true; case UseCaptureKind::MAY_CAPTURE: LLVM_DEBUG(dbgs() << "[AANoAliasCSArg] Unknown user: " << *UserI << "\n"); return false; case UseCaptureKind::PASSTHROUGH: Follow = true; return true; } llvm_unreachable("unknown UseCaptureKind"); }; if (!NoCaptureAA.isAssumedNoCaptureMaybeReturned()) { if (!A.checkForAllUses(UsePred, *this, getAssociatedValue())) { LLVM_DEBUG( dbgs() << "[AANoAliasCSArg] " << getAssociatedValue() << " cannot be noalias as it is potentially captured\n"); return false; } } A.recordDependence(NoCaptureAA, *this, DepClassTy::OPTIONAL); // Check there is no other pointer argument which could alias with the // value passed at this call site. // TODO: AbstractCallSite const auto &CB = cast(getAnchorValue()); for (unsigned OtherArgNo = 0; OtherArgNo < CB.arg_size(); OtherArgNo++) if (mayAliasWithArgument(A, AAR, MemBehaviorAA, CB, OtherArgNo)) return false; return true; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // If the argument is readnone we are done as there are no accesses via the // argument. auto &MemBehaviorAA = A.getAAFor(*this, getIRPosition(), DepClassTy::NONE); if (MemBehaviorAA.isAssumedReadNone()) { A.recordDependence(MemBehaviorAA, *this, DepClassTy::OPTIONAL); return ChangeStatus::UNCHANGED; } const IRPosition &VIRP = IRPosition::value(getAssociatedValue()); const auto &NoAliasAA = A.getAAFor(*this, VIRP, DepClassTy::NONE); AAResults *AAR = nullptr; if (isKnownNoAliasDueToNoAliasPreservation(A, AAR, MemBehaviorAA, NoAliasAA)) { LLVM_DEBUG( dbgs() << "[AANoAlias] No-Alias deduced via no-alias preservation\n"); return ChangeStatus::UNCHANGED; } return indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(noalias) } }; /// NoAlias attribute for function return value. struct AANoAliasReturned final : AANoAliasImpl { AANoAliasReturned(const IRPosition &IRP, Attributor &A) : AANoAliasImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoAliasImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { auto CheckReturnValue = [&](Value &RV) -> bool { if (Constant *C = dyn_cast(&RV)) if (C->isNullValue() || isa(C)) return true; /// For now, we can only deduce noalias if we have call sites. /// FIXME: add more support. if (!isa(&RV)) return false; const IRPosition &RVPos = IRPosition::value(RV); const auto &NoAliasAA = A.getAAFor(*this, RVPos, DepClassTy::REQUIRED); if (!NoAliasAA.isAssumedNoAlias()) return false; const auto &NoCaptureAA = A.getAAFor(*this, RVPos, DepClassTy::REQUIRED); return NoCaptureAA.isAssumedNoCaptureMaybeReturned(); }; if (!A.checkForAllReturnedValues(CheckReturnValue, *this)) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(noalias) } }; /// NoAlias attribute deduction for a call site return value. struct AANoAliasCallSiteReturned final : AANoAliasImpl { AANoAliasCallSiteReturned(const IRPosition &IRP, Attributor &A) : AANoAliasImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoAliasImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Function *F = getAssociatedFunction(); const IRPosition &FnPos = IRPosition::returned(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), FnAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(noalias); } }; } // namespace /// -------------------AAIsDead Function Attribute----------------------- namespace { struct AAIsDeadValueImpl : public AAIsDead { AAIsDeadValueImpl(const IRPosition &IRP, Attributor &A) : AAIsDead(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { if (auto *Scope = getAnchorScope()) if (!A.isRunOn(*Scope)) indicatePessimisticFixpoint(); } /// See AAIsDead::isAssumedDead(). bool isAssumedDead() const override { return isAssumed(IS_DEAD); } /// See AAIsDead::isKnownDead(). bool isKnownDead() const override { return isKnown(IS_DEAD); } /// See AAIsDead::isAssumedDead(BasicBlock *). bool isAssumedDead(const BasicBlock *BB) const override { return false; } /// See AAIsDead::isKnownDead(BasicBlock *). bool isKnownDead(const BasicBlock *BB) const override { return false; } /// See AAIsDead::isAssumedDead(Instruction *I). bool isAssumedDead(const Instruction *I) const override { return I == getCtxI() && isAssumedDead(); } /// See AAIsDead::isKnownDead(Instruction *I). bool isKnownDead(const Instruction *I) const override { return isAssumedDead(I) && isKnownDead(); } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return isAssumedDead() ? "assumed-dead" : "assumed-live"; } /// Check if all uses are assumed dead. bool areAllUsesAssumedDead(Attributor &A, Value &V) { // Callers might not check the type, void has no uses. if (V.getType()->isVoidTy() || V.use_empty()) return true; // If we replace a value with a constant there are no uses left afterwards. if (!isa(V)) { if (auto *I = dyn_cast(&V)) if (!A.isRunOn(*I->getFunction())) return false; bool UsedAssumedInformation = false; Optional C = A.getAssumedConstant(V, *this, UsedAssumedInformation); if (!C || *C) return true; } auto UsePred = [&](const Use &U, bool &Follow) { return false; }; // Explicitly set the dependence class to required because we want a long // chain of N dependent instructions to be considered live as soon as one is // without going through N update cycles. This is not required for // correctness. return A.checkForAllUses(UsePred, *this, V, /* CheckBBLivenessOnly */ false, DepClassTy::REQUIRED, /* IgnoreDroppableUses */ false); } /// Determine if \p I is assumed to be side-effect free. bool isAssumedSideEffectFree(Attributor &A, Instruction *I) { if (!I || wouldInstructionBeTriviallyDead(I)) return true; auto *CB = dyn_cast(I); if (!CB || isa(CB)) return false; const IRPosition &CallIRP = IRPosition::callsite_function(*CB); const auto &NoUnwindAA = A.getAndUpdateAAFor(*this, CallIRP, DepClassTy::NONE); if (!NoUnwindAA.isAssumedNoUnwind()) return false; if (!NoUnwindAA.isKnownNoUnwind()) A.recordDependence(NoUnwindAA, *this, DepClassTy::OPTIONAL); bool IsKnown; return AA::isAssumedReadOnly(A, CallIRP, *this, IsKnown); } }; struct AAIsDeadFloating : public AAIsDeadValueImpl { AAIsDeadFloating(const IRPosition &IRP, Attributor &A) : AAIsDeadValueImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAIsDeadValueImpl::initialize(A); if (isa(getAssociatedValue())) { indicatePessimisticFixpoint(); return; } Instruction *I = dyn_cast(&getAssociatedValue()); if (!isAssumedSideEffectFree(A, I)) { if (!isa_and_nonnull(I)) indicatePessimisticFixpoint(); else removeAssumedBits(HAS_NO_EFFECT); } } bool isDeadStore(Attributor &A, StoreInst &SI) { // Lang ref now states volatile store is not UB/dead, let's skip them. if (SI.isVolatile()) return false; bool UsedAssumedInformation = false; SmallSetVector PotentialCopies; if (!AA::getPotentialCopiesOfStoredValue(A, SI, PotentialCopies, *this, UsedAssumedInformation)) return false; return llvm::all_of(PotentialCopies, [&](Value *V) { return A.isAssumedDead(IRPosition::value(*V), this, nullptr, UsedAssumedInformation); }); } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { Instruction *I = dyn_cast(&getAssociatedValue()); if (isa_and_nonnull(I)) if (isValidState()) return "assumed-dead-store"; return AAIsDeadValueImpl::getAsStr(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { Instruction *I = dyn_cast(&getAssociatedValue()); if (auto *SI = dyn_cast_or_null(I)) { if (!isDeadStore(A, *SI)) return indicatePessimisticFixpoint(); } else { if (!isAssumedSideEffectFree(A, I)) return indicatePessimisticFixpoint(); if (!areAllUsesAssumedDead(A, getAssociatedValue())) return indicatePessimisticFixpoint(); } return ChangeStatus::UNCHANGED; } bool isRemovableStore() const override { return isAssumed(IS_REMOVABLE) && isa(&getAssociatedValue()); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { Value &V = getAssociatedValue(); if (auto *I = dyn_cast(&V)) { // If we get here we basically know the users are all dead. We check if // isAssumedSideEffectFree returns true here again because it might not be // the case and only the users are dead but the instruction (=call) is // still needed. if (isa(I) || (isAssumedSideEffectFree(A, I) && !isa(I))) { A.deleteAfterManifest(*I); return ChangeStatus::CHANGED; } } return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(IsDead) } }; struct AAIsDeadArgument : public AAIsDeadFloating { AAIsDeadArgument(const IRPosition &IRP, Attributor &A) : AAIsDeadFloating(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAIsDeadFloating::initialize(A); if (!A.isFunctionIPOAmendable(*getAnchorScope())) indicatePessimisticFixpoint(); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { Argument &Arg = *getAssociatedArgument(); if (A.isValidFunctionSignatureRewrite(Arg, /* ReplacementTypes */ {})) if (A.registerFunctionSignatureRewrite( Arg, /* ReplacementTypes */ {}, Attributor::ArgumentReplacementInfo::CalleeRepairCBTy{}, Attributor::ArgumentReplacementInfo::ACSRepairCBTy{})) { return ChangeStatus::CHANGED; } return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(IsDead) } }; struct AAIsDeadCallSiteArgument : public AAIsDeadValueImpl { AAIsDeadCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAIsDeadValueImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAIsDeadValueImpl::initialize(A); if (isa(getAssociatedValue())) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Argument *Arg = getAssociatedArgument(); if (!Arg) return indicatePessimisticFixpoint(); const IRPosition &ArgPos = IRPosition::argument(*Arg); auto &ArgAA = A.getAAFor(*this, ArgPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), ArgAA.getState()); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { CallBase &CB = cast(getAnchorValue()); Use &U = CB.getArgOperandUse(getCallSiteArgNo()); assert(!isa(U.get()) && "Expected undef values to be filtered out!"); UndefValue &UV = *UndefValue::get(U->getType()); if (A.changeUseAfterManifest(U, UV)) return ChangeStatus::CHANGED; return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(IsDead) } }; struct AAIsDeadCallSiteReturned : public AAIsDeadFloating { AAIsDeadCallSiteReturned(const IRPosition &IRP, Attributor &A) : AAIsDeadFloating(IRP, A) {} /// See AAIsDead::isAssumedDead(). bool isAssumedDead() const override { return AAIsDeadFloating::isAssumedDead() && IsAssumedSideEffectFree; } /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAIsDeadFloating::initialize(A); if (isa(getAssociatedValue())) { indicatePessimisticFixpoint(); return; } // We track this separately as a secondary state. IsAssumedSideEffectFree = isAssumedSideEffectFree(A, getCtxI()); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { ChangeStatus Changed = ChangeStatus::UNCHANGED; if (IsAssumedSideEffectFree && !isAssumedSideEffectFree(A, getCtxI())) { IsAssumedSideEffectFree = false; Changed = ChangeStatus::CHANGED; } if (!areAllUsesAssumedDead(A, getAssociatedValue())) return indicatePessimisticFixpoint(); return Changed; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { if (IsAssumedSideEffectFree) STATS_DECLTRACK_CSRET_ATTR(IsDead) else STATS_DECLTRACK_CSRET_ATTR(UnusedResult) } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return isAssumedDead() ? "assumed-dead" : (getAssumed() ? "assumed-dead-users" : "assumed-live"); } private: bool IsAssumedSideEffectFree = true; }; struct AAIsDeadReturned : public AAIsDeadValueImpl { AAIsDeadReturned(const IRPosition &IRP, Attributor &A) : AAIsDeadValueImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { bool UsedAssumedInformation = false; A.checkForAllInstructions([](Instruction &) { return true; }, *this, {Instruction::Ret}, UsedAssumedInformation); auto PredForCallSite = [&](AbstractCallSite ACS) { if (ACS.isCallbackCall() || !ACS.getInstruction()) return false; return areAllUsesAssumedDead(A, *ACS.getInstruction()); }; if (!A.checkForAllCallSites(PredForCallSite, *this, true, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { // TODO: Rewrite the signature to return void? bool AnyChange = false; UndefValue &UV = *UndefValue::get(getAssociatedFunction()->getReturnType()); auto RetInstPred = [&](Instruction &I) { ReturnInst &RI = cast(I); if (!isa(RI.getReturnValue())) AnyChange |= A.changeUseAfterManifest(RI.getOperandUse(0), UV); return true; }; bool UsedAssumedInformation = false; A.checkForAllInstructions(RetInstPred, *this, {Instruction::Ret}, UsedAssumedInformation); return AnyChange ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(IsDead) } }; struct AAIsDeadFunction : public AAIsDead { AAIsDeadFunction(const IRPosition &IRP, Attributor &A) : AAIsDead(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { Function *F = getAnchorScope(); if (!F || F->isDeclaration() || !A.isRunOn(*F)) { indicatePessimisticFixpoint(); return; } ToBeExploredFrom.insert(&F->getEntryBlock().front()); assumeLive(A, F->getEntryBlock()); } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return "Live[#BB " + std::to_string(AssumedLiveBlocks.size()) + "/" + std::to_string(getAnchorScope()->size()) + "][#TBEP " + std::to_string(ToBeExploredFrom.size()) + "][#KDE " + std::to_string(KnownDeadEnds.size()) + "]"; } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { assert(getState().isValidState() && "Attempted to manifest an invalid state!"); ChangeStatus HasChanged = ChangeStatus::UNCHANGED; Function &F = *getAnchorScope(); if (AssumedLiveBlocks.empty()) { A.deleteAfterManifest(F); return ChangeStatus::CHANGED; } // Flag to determine if we can change an invoke to a call assuming the // callee is nounwind. This is not possible if the personality of the // function allows to catch asynchronous exceptions. bool Invoke2CallAllowed = !mayCatchAsynchronousExceptions(F); KnownDeadEnds.set_union(ToBeExploredFrom); for (const Instruction *DeadEndI : KnownDeadEnds) { auto *CB = dyn_cast(DeadEndI); if (!CB) continue; const auto &NoReturnAA = A.getAndUpdateAAFor( *this, IRPosition::callsite_function(*CB), DepClassTy::OPTIONAL); bool MayReturn = !NoReturnAA.isAssumedNoReturn(); if (MayReturn && (!Invoke2CallAllowed || !isa(CB))) continue; if (auto *II = dyn_cast(DeadEndI)) A.registerInvokeWithDeadSuccessor(const_cast(*II)); else A.changeToUnreachableAfterManifest( const_cast(DeadEndI->getNextNode())); HasChanged = ChangeStatus::CHANGED; } STATS_DECL(AAIsDead, BasicBlock, "Number of dead basic blocks deleted."); for (BasicBlock &BB : F) if (!AssumedLiveBlocks.count(&BB)) { A.deleteAfterManifest(BB); ++BUILD_STAT_NAME(AAIsDead, BasicBlock); HasChanged = ChangeStatus::CHANGED; } return HasChanged; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override; bool isEdgeDead(const BasicBlock *From, const BasicBlock *To) const override { assert(From->getParent() == getAnchorScope() && To->getParent() == getAnchorScope() && "Used AAIsDead of the wrong function"); return isValidState() && !AssumedLiveEdges.count(std::make_pair(From, To)); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override {} /// Returns true if the function is assumed dead. bool isAssumedDead() const override { return false; } /// See AAIsDead::isKnownDead(). bool isKnownDead() const override { return false; } /// See AAIsDead::isAssumedDead(BasicBlock *). bool isAssumedDead(const BasicBlock *BB) const override { assert(BB->getParent() == getAnchorScope() && "BB must be in the same anchor scope function."); if (!getAssumed()) return false; return !AssumedLiveBlocks.count(BB); } /// See AAIsDead::isKnownDead(BasicBlock *). bool isKnownDead(const BasicBlock *BB) const override { return getKnown() && isAssumedDead(BB); } /// See AAIsDead::isAssumed(Instruction *I). bool isAssumedDead(const Instruction *I) const override { assert(I->getParent()->getParent() == getAnchorScope() && "Instruction must be in the same anchor scope function."); if (!getAssumed()) return false; // If it is not in AssumedLiveBlocks then it for sure dead. // Otherwise, it can still be after noreturn call in a live block. if (!AssumedLiveBlocks.count(I->getParent())) return true; // If it is not after a liveness barrier it is live. const Instruction *PrevI = I->getPrevNode(); while (PrevI) { if (KnownDeadEnds.count(PrevI) || ToBeExploredFrom.count(PrevI)) return true; PrevI = PrevI->getPrevNode(); } return false; } /// See AAIsDead::isKnownDead(Instruction *I). bool isKnownDead(const Instruction *I) const override { return getKnown() && isAssumedDead(I); } /// Assume \p BB is (partially) live now and indicate to the Attributor \p A /// that internal function called from \p BB should now be looked at. bool assumeLive(Attributor &A, const BasicBlock &BB) { if (!AssumedLiveBlocks.insert(&BB).second) return false; // We assume that all of BB is (probably) live now and if there are calls to // internal functions we will assume that those are now live as well. This // is a performance optimization for blocks with calls to a lot of internal // functions. It can however cause dead functions to be treated as live. for (const Instruction &I : BB) if (const auto *CB = dyn_cast(&I)) if (const Function *F = CB->getCalledFunction()) if (F->hasLocalLinkage()) A.markLiveInternalFunction(*F); return true; } /// Collection of instructions that need to be explored again, e.g., we /// did assume they do not transfer control to (one of their) successors. SmallSetVector ToBeExploredFrom; /// Collection of instructions that are known to not transfer control. SmallSetVector KnownDeadEnds; /// Collection of all assumed live edges DenseSet> AssumedLiveEdges; /// Collection of all assumed live BasicBlocks. DenseSet AssumedLiveBlocks; }; static bool identifyAliveSuccessors(Attributor &A, const CallBase &CB, AbstractAttribute &AA, SmallVectorImpl &AliveSuccessors) { const IRPosition &IPos = IRPosition::callsite_function(CB); const auto &NoReturnAA = A.getAndUpdateAAFor(AA, IPos, DepClassTy::OPTIONAL); if (NoReturnAA.isAssumedNoReturn()) return !NoReturnAA.isKnownNoReturn(); if (CB.isTerminator()) AliveSuccessors.push_back(&CB.getSuccessor(0)->front()); else AliveSuccessors.push_back(CB.getNextNode()); return false; } static bool identifyAliveSuccessors(Attributor &A, const InvokeInst &II, AbstractAttribute &AA, SmallVectorImpl &AliveSuccessors) { bool UsedAssumedInformation = identifyAliveSuccessors(A, cast(II), AA, AliveSuccessors); // First, determine if we can change an invoke to a call assuming the // callee is nounwind. This is not possible if the personality of the // function allows to catch asynchronous exceptions. if (AAIsDeadFunction::mayCatchAsynchronousExceptions(*II.getFunction())) { AliveSuccessors.push_back(&II.getUnwindDest()->front()); } else { const IRPosition &IPos = IRPosition::callsite_function(II); const auto &AANoUnw = A.getAndUpdateAAFor(AA, IPos, DepClassTy::OPTIONAL); if (AANoUnw.isAssumedNoUnwind()) { UsedAssumedInformation |= !AANoUnw.isKnownNoUnwind(); } else { AliveSuccessors.push_back(&II.getUnwindDest()->front()); } } return UsedAssumedInformation; } static bool identifyAliveSuccessors(Attributor &A, const BranchInst &BI, AbstractAttribute &AA, SmallVectorImpl &AliveSuccessors) { bool UsedAssumedInformation = false; if (BI.getNumSuccessors() == 1) { AliveSuccessors.push_back(&BI.getSuccessor(0)->front()); } else { Optional C = A.getAssumedConstant(*BI.getCondition(), AA, UsedAssumedInformation); if (!C || isa_and_nonnull(*C)) { // No value yet, assume both edges are dead. } else if (isa_and_nonnull(*C)) { const BasicBlock *SuccBB = BI.getSuccessor(1 - cast(*C)->getValue().getZExtValue()); AliveSuccessors.push_back(&SuccBB->front()); } else { AliveSuccessors.push_back(&BI.getSuccessor(0)->front()); AliveSuccessors.push_back(&BI.getSuccessor(1)->front()); UsedAssumedInformation = false; } } return UsedAssumedInformation; } static bool identifyAliveSuccessors(Attributor &A, const SwitchInst &SI, AbstractAttribute &AA, SmallVectorImpl &AliveSuccessors) { bool UsedAssumedInformation = false; Optional C = A.getAssumedConstant(*SI.getCondition(), AA, UsedAssumedInformation); if (!C || isa_and_nonnull(C.value())) { // No value yet, assume all edges are dead. } else if (isa_and_nonnull(C.value())) { for (auto &CaseIt : SI.cases()) { if (CaseIt.getCaseValue() == C.value()) { AliveSuccessors.push_back(&CaseIt.getCaseSuccessor()->front()); return UsedAssumedInformation; } } AliveSuccessors.push_back(&SI.getDefaultDest()->front()); return UsedAssumedInformation; } else { for (const BasicBlock *SuccBB : successors(SI.getParent())) AliveSuccessors.push_back(&SuccBB->front()); } return UsedAssumedInformation; } ChangeStatus AAIsDeadFunction::updateImpl(Attributor &A) { ChangeStatus Change = ChangeStatus::UNCHANGED; LLVM_DEBUG(dbgs() << "[AAIsDead] Live [" << AssumedLiveBlocks.size() << "/" << getAnchorScope()->size() << "] BBs and " << ToBeExploredFrom.size() << " exploration points and " << KnownDeadEnds.size() << " known dead ends\n"); // Copy and clear the list of instructions we need to explore from. It is // refilled with instructions the next update has to look at. SmallVector Worklist(ToBeExploredFrom.begin(), ToBeExploredFrom.end()); decltype(ToBeExploredFrom) NewToBeExploredFrom; SmallVector AliveSuccessors; while (!Worklist.empty()) { const Instruction *I = Worklist.pop_back_val(); LLVM_DEBUG(dbgs() << "[AAIsDead] Exploration inst: " << *I << "\n"); // Fast forward for uninteresting instructions. We could look for UB here // though. while (!I->isTerminator() && !isa(I)) I = I->getNextNode(); AliveSuccessors.clear(); bool UsedAssumedInformation = false; switch (I->getOpcode()) { // TODO: look for (assumed) UB to backwards propagate "deadness". default: assert(I->isTerminator() && "Expected non-terminators to be handled already!"); for (const BasicBlock *SuccBB : successors(I->getParent())) AliveSuccessors.push_back(&SuccBB->front()); break; case Instruction::Call: UsedAssumedInformation = identifyAliveSuccessors(A, cast(*I), *this, AliveSuccessors); break; case Instruction::Invoke: UsedAssumedInformation = identifyAliveSuccessors(A, cast(*I), *this, AliveSuccessors); break; case Instruction::Br: UsedAssumedInformation = identifyAliveSuccessors(A, cast(*I), *this, AliveSuccessors); break; case Instruction::Switch: UsedAssumedInformation = identifyAliveSuccessors(A, cast(*I), *this, AliveSuccessors); break; } if (UsedAssumedInformation) { NewToBeExploredFrom.insert(I); } else if (AliveSuccessors.empty() || (I->isTerminator() && AliveSuccessors.size() < I->getNumSuccessors())) { if (KnownDeadEnds.insert(I)) Change = ChangeStatus::CHANGED; } LLVM_DEBUG(dbgs() << "[AAIsDead] #AliveSuccessors: " << AliveSuccessors.size() << " UsedAssumedInformation: " << UsedAssumedInformation << "\n"); for (const Instruction *AliveSuccessor : AliveSuccessors) { if (!I->isTerminator()) { assert(AliveSuccessors.size() == 1 && "Non-terminator expected to have a single successor!"); Worklist.push_back(AliveSuccessor); } else { // record the assumed live edge auto Edge = std::make_pair(I->getParent(), AliveSuccessor->getParent()); if (AssumedLiveEdges.insert(Edge).second) Change = ChangeStatus::CHANGED; if (assumeLive(A, *AliveSuccessor->getParent())) Worklist.push_back(AliveSuccessor); } } } // Check if the content of ToBeExploredFrom changed, ignore the order. if (NewToBeExploredFrom.size() != ToBeExploredFrom.size() || llvm::any_of(NewToBeExploredFrom, [&](const Instruction *I) { return !ToBeExploredFrom.count(I); })) { Change = ChangeStatus::CHANGED; ToBeExploredFrom = std::move(NewToBeExploredFrom); } // If we know everything is live there is no need to query for liveness. // Instead, indicating a pessimistic fixpoint will cause the state to be // "invalid" and all queries to be answered conservatively without lookups. // To be in this state we have to (1) finished the exploration and (3) not // discovered any non-trivial dead end and (2) not ruled unreachable code // dead. if (ToBeExploredFrom.empty() && getAnchorScope()->size() == AssumedLiveBlocks.size() && llvm::all_of(KnownDeadEnds, [](const Instruction *DeadEndI) { return DeadEndI->isTerminator() && DeadEndI->getNumSuccessors() == 0; })) return indicatePessimisticFixpoint(); return Change; } /// Liveness information for a call sites. struct AAIsDeadCallSite final : AAIsDeadFunction { AAIsDeadCallSite(const IRPosition &IRP, Attributor &A) : AAIsDeadFunction(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites instead of // redirecting requests to the callee. llvm_unreachable("Abstract attributes for liveness are not " "supported for call sites yet!"); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { return indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override {} }; } // namespace /// -------------------- Dereferenceable Argument Attribute -------------------- namespace { struct AADereferenceableImpl : AADereferenceable { AADereferenceableImpl(const IRPosition &IRP, Attributor &A) : AADereferenceable(IRP, A) {} using StateType = DerefState; /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { Value &V = *getAssociatedValue().stripPointerCasts(); SmallVector Attrs; getAttrs({Attribute::Dereferenceable, Attribute::DereferenceableOrNull}, Attrs, /* IgnoreSubsumingPositions */ false, &A); for (const Attribute &Attr : Attrs) takeKnownDerefBytesMaximum(Attr.getValueAsInt()); const IRPosition &IRP = this->getIRPosition(); NonNullAA = &A.getAAFor(*this, IRP, DepClassTy::NONE); bool CanBeNull, CanBeFreed; takeKnownDerefBytesMaximum(V.getPointerDereferenceableBytes( A.getDataLayout(), CanBeNull, CanBeFreed)); bool IsFnInterface = IRP.isFnInterfaceKind(); Function *FnScope = IRP.getAnchorScope(); if (IsFnInterface && (!FnScope || !A.isFunctionIPOAmendable(*FnScope))) { indicatePessimisticFixpoint(); return; } if (Instruction *CtxI = getCtxI()) followUsesInMBEC(*this, A, getState(), *CtxI); } /// See AbstractAttribute::getState() /// { StateType &getState() override { return *this; } const StateType &getState() const override { return *this; } /// } /// Helper function for collecting accessed bytes in must-be-executed-context void addAccessedBytesForUse(Attributor &A, const Use *U, const Instruction *I, DerefState &State) { const Value *UseV = U->get(); if (!UseV->getType()->isPointerTy()) return; Optional Loc = MemoryLocation::getOrNone(I); if (!Loc || Loc->Ptr != UseV || !Loc->Size.isPrecise() || I->isVolatile()) return; int64_t Offset; const Value *Base = GetPointerBaseWithConstantOffset( Loc->Ptr, Offset, A.getDataLayout(), /*AllowNonInbounds*/ true); if (Base && Base == &getAssociatedValue()) State.addAccessedBytes(Offset, Loc->Size.getValue()); } /// See followUsesInMBEC bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I, AADereferenceable::StateType &State) { bool IsNonNull = false; bool TrackUse = false; int64_t DerefBytes = getKnownNonNullAndDerefBytesForUse( A, *this, getAssociatedValue(), U, I, IsNonNull, TrackUse); LLVM_DEBUG(dbgs() << "[AADereferenceable] Deref bytes: " << DerefBytes << " for instruction " << *I << "\n"); addAccessedBytesForUse(A, U, I, State); State.takeKnownDerefBytesMaximum(DerefBytes); return TrackUse; } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { ChangeStatus Change = AADereferenceable::manifest(A); if (isAssumedNonNull() && hasAttr(Attribute::DereferenceableOrNull)) { removeAttrs({Attribute::DereferenceableOrNull}); return ChangeStatus::CHANGED; } return Change; } void getDeducedAttributes(LLVMContext &Ctx, SmallVectorImpl &Attrs) const override { // TODO: Add *_globally support if (isAssumedNonNull()) Attrs.emplace_back(Attribute::getWithDereferenceableBytes( Ctx, getAssumedDereferenceableBytes())); else Attrs.emplace_back(Attribute::getWithDereferenceableOrNullBytes( Ctx, getAssumedDereferenceableBytes())); } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { if (!getAssumedDereferenceableBytes()) return "unknown-dereferenceable"; return std::string("dereferenceable") + (isAssumedNonNull() ? "" : "_or_null") + (isAssumedGlobal() ? "_globally" : "") + "<" + std::to_string(getKnownDereferenceableBytes()) + "-" + std::to_string(getAssumedDereferenceableBytes()) + ">"; } }; /// Dereferenceable attribute for a floating value. struct AADereferenceableFloating : AADereferenceableImpl { AADereferenceableFloating(const IRPosition &IRP, Attributor &A) : AADereferenceableImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { bool Stripped; bool UsedAssumedInformation = false; SmallVector Values; if (!A.getAssumedSimplifiedValues(getIRPosition(), *this, Values, AA::AnyScope, UsedAssumedInformation)) { Values.push_back({getAssociatedValue(), getCtxI()}); Stripped = false; } else { Stripped = Values.size() != 1 || Values.front().getValue() != &getAssociatedValue(); } const DataLayout &DL = A.getDataLayout(); DerefState T; auto VisitValueCB = [&](const Value &V) -> bool { unsigned IdxWidth = DL.getIndexSizeInBits(V.getType()->getPointerAddressSpace()); APInt Offset(IdxWidth, 0); const Value *Base = stripAndAccumulateOffsets( A, *this, &V, DL, Offset, /* GetMinOffset */ false, /* AllowNonInbounds */ true); const auto &AA = A.getAAFor( *this, IRPosition::value(*Base), DepClassTy::REQUIRED); int64_t DerefBytes = 0; if (!Stripped && this == &AA) { // Use IR information if we did not strip anything. // TODO: track globally. bool CanBeNull, CanBeFreed; DerefBytes = Base->getPointerDereferenceableBytes(DL, CanBeNull, CanBeFreed); T.GlobalState.indicatePessimisticFixpoint(); } else { const DerefState &DS = AA.getState(); DerefBytes = DS.DerefBytesState.getAssumed(); T.GlobalState &= DS.GlobalState; } // For now we do not try to "increase" dereferenceability due to negative // indices as we first have to come up with code to deal with loops and // for overflows of the dereferenceable bytes. int64_t OffsetSExt = Offset.getSExtValue(); if (OffsetSExt < 0) OffsetSExt = 0; T.takeAssumedDerefBytesMinimum( std::max(int64_t(0), DerefBytes - OffsetSExt)); if (this == &AA) { if (!Stripped) { // If nothing was stripped IR information is all we got. T.takeKnownDerefBytesMaximum( std::max(int64_t(0), DerefBytes - OffsetSExt)); T.indicatePessimisticFixpoint(); } else if (OffsetSExt > 0) { // If something was stripped but there is circular reasoning we look // for the offset. If it is positive we basically decrease the // dereferenceable bytes in a circluar loop now, which will simply // drive them down to the known value in a very slow way which we // can accelerate. T.indicatePessimisticFixpoint(); } } return T.isValidState(); }; for (const auto &VAC : Values) if (!VisitValueCB(*VAC.getValue())) return indicatePessimisticFixpoint(); return clampStateAndIndicateChange(getState(), T); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(dereferenceable) } }; /// Dereferenceable attribute for a return value. struct AADereferenceableReturned final : AAReturnedFromReturnedValues { AADereferenceableReturned(const IRPosition &IRP, Attributor &A) : AAReturnedFromReturnedValues( IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(dereferenceable) } }; /// Dereferenceable attribute for an argument struct AADereferenceableArgument final : AAArgumentFromCallSiteArguments { using Base = AAArgumentFromCallSiteArguments; AADereferenceableArgument(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(dereferenceable) } }; /// Dereferenceable attribute for a call site argument. struct AADereferenceableCallSiteArgument final : AADereferenceableFloating { AADereferenceableCallSiteArgument(const IRPosition &IRP, Attributor &A) : AADereferenceableFloating(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(dereferenceable) } }; /// Dereferenceable attribute deduction for a call site return value. struct AADereferenceableCallSiteReturned final : AACallSiteReturnedFromReturned { using Base = AACallSiteReturnedFromReturned; AADereferenceableCallSiteReturned(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(dereferenceable); } }; } // namespace // ------------------------ Align Argument Attribute ------------------------ namespace { static unsigned getKnownAlignForUse(Attributor &A, AAAlign &QueryingAA, Value &AssociatedValue, const Use *U, const Instruction *I, bool &TrackUse) { // We need to follow common pointer manipulation uses to the accesses they // feed into. if (isa(I)) { // Follow all but ptr2int casts. TrackUse = !isa(I); return 0; } if (auto *GEP = dyn_cast(I)) { if (GEP->hasAllConstantIndices()) TrackUse = true; return 0; } MaybeAlign MA; if (const auto *CB = dyn_cast(I)) { if (CB->isBundleOperand(U) || CB->isCallee(U)) return 0; unsigned ArgNo = CB->getArgOperandNo(U); IRPosition IRP = IRPosition::callsite_argument(*CB, ArgNo); // As long as we only use known information there is no need to track // dependences here. auto &AlignAA = A.getAAFor(QueryingAA, IRP, DepClassTy::NONE); MA = MaybeAlign(AlignAA.getKnownAlign()); } const DataLayout &DL = A.getDataLayout(); const Value *UseV = U->get(); if (auto *SI = dyn_cast(I)) { if (SI->getPointerOperand() == UseV) MA = SI->getAlign(); } else if (auto *LI = dyn_cast(I)) { if (LI->getPointerOperand() == UseV) MA = LI->getAlign(); } if (!MA || *MA <= QueryingAA.getKnownAlign()) return 0; unsigned Alignment = MA->value(); int64_t Offset; if (const Value *Base = GetPointerBaseWithConstantOffset(UseV, Offset, DL)) { if (Base == &AssociatedValue) { // BasePointerAddr + Offset = Alignment * Q for some integer Q. // So we can say that the maximum power of two which is a divisor of // gcd(Offset, Alignment) is an alignment. uint32_t gcd = greatestCommonDivisor(uint32_t(abs((int32_t)Offset)), Alignment); Alignment = llvm::PowerOf2Floor(gcd); } } return Alignment; } struct AAAlignImpl : AAAlign { AAAlignImpl(const IRPosition &IRP, Attributor &A) : AAAlign(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { SmallVector Attrs; getAttrs({Attribute::Alignment}, Attrs); for (const Attribute &Attr : Attrs) takeKnownMaximum(Attr.getValueAsInt()); Value &V = *getAssociatedValue().stripPointerCasts(); takeKnownMaximum(V.getPointerAlignment(A.getDataLayout()).value()); if (getIRPosition().isFnInterfaceKind() && (!getAnchorScope() || !A.isFunctionIPOAmendable(*getAssociatedFunction()))) { indicatePessimisticFixpoint(); return; } if (Instruction *CtxI = getCtxI()) followUsesInMBEC(*this, A, getState(), *CtxI); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { ChangeStatus LoadStoreChanged = ChangeStatus::UNCHANGED; // Check for users that allow alignment annotations. Value &AssociatedValue = getAssociatedValue(); for (const Use &U : AssociatedValue.uses()) { if (auto *SI = dyn_cast(U.getUser())) { if (SI->getPointerOperand() == &AssociatedValue) if (SI->getAlign() < getAssumedAlign()) { STATS_DECLTRACK(AAAlign, Store, "Number of times alignment added to a store"); SI->setAlignment(getAssumedAlign()); LoadStoreChanged = ChangeStatus::CHANGED; } } else if (auto *LI = dyn_cast(U.getUser())) { if (LI->getPointerOperand() == &AssociatedValue) if (LI->getAlign() < getAssumedAlign()) { LI->setAlignment(getAssumedAlign()); STATS_DECLTRACK(AAAlign, Load, "Number of times alignment added to a load"); LoadStoreChanged = ChangeStatus::CHANGED; } } } ChangeStatus Changed = AAAlign::manifest(A); Align InheritAlign = getAssociatedValue().getPointerAlignment(A.getDataLayout()); if (InheritAlign >= getAssumedAlign()) return LoadStoreChanged; return Changed | LoadStoreChanged; } // TODO: Provide a helper to determine the implied ABI alignment and check in // the existing manifest method and a new one for AAAlignImpl that value // to avoid making the alignment explicit if it did not improve. /// See AbstractAttribute::getDeducedAttributes void getDeducedAttributes(LLVMContext &Ctx, SmallVectorImpl &Attrs) const override { if (getAssumedAlign() > 1) Attrs.emplace_back( Attribute::getWithAlignment(Ctx, Align(getAssumedAlign()))); } /// See followUsesInMBEC bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I, AAAlign::StateType &State) { bool TrackUse = false; unsigned int KnownAlign = getKnownAlignForUse(A, *this, getAssociatedValue(), U, I, TrackUse); State.takeKnownMaximum(KnownAlign); return TrackUse; } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return "align<" + std::to_string(getKnownAlign().value()) + "-" + std::to_string(getAssumedAlign().value()) + ">"; } }; /// Align attribute for a floating value. struct AAAlignFloating : AAAlignImpl { AAAlignFloating(const IRPosition &IRP, Attributor &A) : AAAlignImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { const DataLayout &DL = A.getDataLayout(); bool Stripped; bool UsedAssumedInformation = false; SmallVector Values; if (!A.getAssumedSimplifiedValues(getIRPosition(), *this, Values, AA::AnyScope, UsedAssumedInformation)) { Values.push_back({getAssociatedValue(), getCtxI()}); Stripped = false; } else { Stripped = Values.size() != 1 || Values.front().getValue() != &getAssociatedValue(); } StateType T; auto VisitValueCB = [&](Value &V) -> bool { if (isa(V) || isa(V)) return true; const auto &AA = A.getAAFor(*this, IRPosition::value(V), DepClassTy::REQUIRED); if (!Stripped && this == &AA) { int64_t Offset; unsigned Alignment = 1; if (const Value *Base = GetPointerBaseWithConstantOffset(&V, Offset, DL)) { // TODO: Use AAAlign for the base too. Align PA = Base->getPointerAlignment(DL); // BasePointerAddr + Offset = Alignment * Q for some integer Q. // So we can say that the maximum power of two which is a divisor of // gcd(Offset, Alignment) is an alignment. uint32_t gcd = greatestCommonDivisor(uint32_t(abs((int32_t)Offset)), uint32_t(PA.value())); Alignment = llvm::PowerOf2Floor(gcd); } else { Alignment = V.getPointerAlignment(DL).value(); } // Use only IR information if we did not strip anything. T.takeKnownMaximum(Alignment); T.indicatePessimisticFixpoint(); } else { // Use abstract attribute information. const AAAlign::StateType &DS = AA.getState(); T ^= DS; } return T.isValidState(); }; for (const auto &VAC : Values) { if (!VisitValueCB(*VAC.getValue())) return indicatePessimisticFixpoint(); } // TODO: If we know we visited all incoming values, thus no are assumed // dead, we can take the known information from the state T. return clampStateAndIndicateChange(getState(), T); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(align) } }; /// Align attribute for function return value. struct AAAlignReturned final : AAReturnedFromReturnedValues { using Base = AAReturnedFromReturnedValues; AAAlignReturned(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { Base::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(aligned) } }; /// Align attribute for function argument. struct AAAlignArgument final : AAArgumentFromCallSiteArguments { using Base = AAArgumentFromCallSiteArguments; AAAlignArgument(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { // If the associated argument is involved in a must-tail call we give up // because we would need to keep the argument alignments of caller and // callee in-sync. Just does not seem worth the trouble right now. if (A.getInfoCache().isInvolvedInMustTailCall(*getAssociatedArgument())) return ChangeStatus::UNCHANGED; return Base::manifest(A); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(aligned) } }; struct AAAlignCallSiteArgument final : AAAlignFloating { AAAlignCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAAlignFloating(IRP, A) {} /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { // If the associated argument is involved in a must-tail call we give up // because we would need to keep the argument alignments of caller and // callee in-sync. Just does not seem worth the trouble right now. if (Argument *Arg = getAssociatedArgument()) if (A.getInfoCache().isInvolvedInMustTailCall(*Arg)) return ChangeStatus::UNCHANGED; ChangeStatus Changed = AAAlignImpl::manifest(A); Align InheritAlign = getAssociatedValue().getPointerAlignment(A.getDataLayout()); if (InheritAlign >= getAssumedAlign()) Changed = ChangeStatus::UNCHANGED; return Changed; } /// See AbstractAttribute::updateImpl(Attributor &A). ChangeStatus updateImpl(Attributor &A) override { ChangeStatus Changed = AAAlignFloating::updateImpl(A); if (Argument *Arg = getAssociatedArgument()) { // We only take known information from the argument // so we do not need to track a dependence. const auto &ArgAlignAA = A.getAAFor( *this, IRPosition::argument(*Arg), DepClassTy::NONE); takeKnownMaximum(ArgAlignAA.getKnownAlign().value()); } return Changed; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(aligned) } }; /// Align attribute deduction for a call site return value. struct AAAlignCallSiteReturned final : AACallSiteReturnedFromReturned { using Base = AACallSiteReturnedFromReturned; AAAlignCallSiteReturned(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { Base::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(align); } }; } // namespace /// ------------------ Function No-Return Attribute ---------------------------- namespace { struct AANoReturnImpl : public AANoReturn { AANoReturnImpl(const IRPosition &IRP, Attributor &A) : AANoReturn(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoReturn::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return getAssumed() ? "noreturn" : "may-return"; } /// See AbstractAttribute::updateImpl(Attributor &A). ChangeStatus updateImpl(Attributor &A) override { auto CheckForNoReturn = [](Instruction &) { return false; }; bool UsedAssumedInformation = false; if (!A.checkForAllInstructions(CheckForNoReturn, *this, {(unsigned)Instruction::Ret}, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } }; struct AANoReturnFunction final : AANoReturnImpl { AANoReturnFunction(const IRPosition &IRP, Attributor &A) : AANoReturnImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(noreturn) } }; /// NoReturn attribute deduction for a call sites. struct AANoReturnCallSite final : AANoReturnImpl { AANoReturnCallSite(const IRPosition &IRP, Attributor &A) : AANoReturnImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoReturnImpl::initialize(A); if (Function *F = getAssociatedFunction()) { const IRPosition &FnPos = IRPosition::function(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); if (!FnAA.isAssumedNoReturn()) indicatePessimisticFixpoint(); } } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Function *F = getAssociatedFunction(); const IRPosition &FnPos = IRPosition::function(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), FnAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(noreturn); } }; } // namespace /// ----------------------- Instance Info --------------------------------- namespace { /// A class to hold the state of for no-capture attributes. struct AAInstanceInfoImpl : public AAInstanceInfo { AAInstanceInfoImpl(const IRPosition &IRP, Attributor &A) : AAInstanceInfo(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { Value &V = getAssociatedValue(); if (auto *C = dyn_cast(&V)) { if (C->isThreadDependent()) indicatePessimisticFixpoint(); else indicateOptimisticFixpoint(); return; } if (auto *CB = dyn_cast(&V)) if (CB->arg_size() == 0 && !CB->mayHaveSideEffects() && !CB->mayReadFromMemory()) { indicateOptimisticFixpoint(); return; } } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { ChangeStatus Changed = ChangeStatus::UNCHANGED; Value &V = getAssociatedValue(); const Function *Scope = nullptr; if (auto *I = dyn_cast(&V)) Scope = I->getFunction(); if (auto *A = dyn_cast(&V)) { Scope = A->getParent(); if (!Scope->hasLocalLinkage()) return Changed; } if (!Scope) return indicateOptimisticFixpoint(); auto &NoRecurseAA = A.getAAFor( *this, IRPosition::function(*Scope), DepClassTy::OPTIONAL); if (NoRecurseAA.isAssumedNoRecurse()) return Changed; auto UsePred = [&](const Use &U, bool &Follow) { const Instruction *UserI = dyn_cast(U.getUser()); if (!UserI || isa(UserI) || isa(UserI) || isa(UserI) || isa(UserI)) { Follow = true; return true; } if (isa(UserI) || isa(UserI) || (isa(UserI) && cast(UserI)->getValueOperand() != U.get())) return true; if (auto *CB = dyn_cast(UserI)) { // This check is not guaranteeing uniqueness but for now that we cannot // end up with two versions of \p U thinking it was one. if (!CB->getCalledFunction() || !CB->getCalledFunction()->hasLocalLinkage()) return true; if (!CB->isArgOperand(&U)) return false; const auto &ArgInstanceInfoAA = A.getAAFor( *this, IRPosition::callsite_argument(*CB, CB->getArgOperandNo(&U)), DepClassTy::OPTIONAL); if (!ArgInstanceInfoAA.isAssumedUniqueForAnalysis()) return false; // If this call base might reach the scope again we might forward the // argument back here. This is very conservative. if (AA::isPotentiallyReachable( A, *CB, *Scope, *this, [Scope](const Function &Fn) { return &Fn != Scope; })) return false; return true; } return false; }; auto EquivalentUseCB = [&](const Use &OldU, const Use &NewU) { if (auto *SI = dyn_cast(OldU.getUser())) { auto *Ptr = SI->getPointerOperand()->stripPointerCasts(); if (isa(Ptr) && AA::isDynamicallyUnique(A, *this, *Ptr)) return true; auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction( *SI->getFunction()); if (isAllocationFn(Ptr, TLI) && AA::isDynamicallyUnique(A, *this, *Ptr)) return true; } return false; }; if (!A.checkForAllUses(UsePred, *this, V, /* CheckBBLivenessOnly */ true, DepClassTy::OPTIONAL, /* IgnoreDroppableUses */ true, EquivalentUseCB)) return indicatePessimisticFixpoint(); return Changed; } /// See AbstractState::getAsStr(). const std::string getAsStr() const override { return isAssumedUniqueForAnalysis() ? "" : ""; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override {} }; /// InstanceInfo attribute for floating values. struct AAInstanceInfoFloating : AAInstanceInfoImpl { AAInstanceInfoFloating(const IRPosition &IRP, Attributor &A) : AAInstanceInfoImpl(IRP, A) {} }; /// NoCapture attribute for function arguments. struct AAInstanceInfoArgument final : AAInstanceInfoFloating { AAInstanceInfoArgument(const IRPosition &IRP, Attributor &A) : AAInstanceInfoFloating(IRP, A) {} }; /// InstanceInfo attribute for call site arguments. struct AAInstanceInfoCallSiteArgument final : AAInstanceInfoImpl { AAInstanceInfoCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAInstanceInfoImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Argument *Arg = getAssociatedArgument(); if (!Arg) return indicatePessimisticFixpoint(); const IRPosition &ArgPos = IRPosition::argument(*Arg); auto &ArgAA = A.getAAFor(*this, ArgPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), ArgAA.getState()); } }; /// InstanceInfo attribute for function return value. struct AAInstanceInfoReturned final : AAInstanceInfoImpl { AAInstanceInfoReturned(const IRPosition &IRP, Attributor &A) : AAInstanceInfoImpl(IRP, A) { llvm_unreachable("InstanceInfo is not applicable to function returns!"); } /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { llvm_unreachable("InstanceInfo is not applicable to function returns!"); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { llvm_unreachable("InstanceInfo is not applicable to function returns!"); } }; /// InstanceInfo attribute deduction for a call site return value. struct AAInstanceInfoCallSiteReturned final : AAInstanceInfoFloating { AAInstanceInfoCallSiteReturned(const IRPosition &IRP, Attributor &A) : AAInstanceInfoFloating(IRP, A) {} }; } // namespace /// ----------------------- Variable Capturing --------------------------------- namespace { /// A class to hold the state of for no-capture attributes. struct AANoCaptureImpl : public AANoCapture { AANoCaptureImpl(const IRPosition &IRP, Attributor &A) : AANoCapture(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { if (hasAttr(getAttrKind(), /* IgnoreSubsumingPositions */ true)) { indicateOptimisticFixpoint(); return; } Function *AnchorScope = getAnchorScope(); if (isFnInterfaceKind() && (!AnchorScope || !A.isFunctionIPOAmendable(*AnchorScope))) { indicatePessimisticFixpoint(); return; } // You cannot "capture" null in the default address space. if (isa(getAssociatedValue()) && getAssociatedValue().getType()->getPointerAddressSpace() == 0) { indicateOptimisticFixpoint(); return; } const Function *F = isArgumentPosition() ? getAssociatedFunction() : AnchorScope; // Check what state the associated function can actually capture. if (F) determineFunctionCaptureCapabilities(getIRPosition(), *F, *this); else indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override; /// see AbstractAttribute::isAssumedNoCaptureMaybeReturned(...). void getDeducedAttributes(LLVMContext &Ctx, SmallVectorImpl &Attrs) const override { if (!isAssumedNoCaptureMaybeReturned()) return; if (isArgumentPosition()) { if (isAssumedNoCapture()) Attrs.emplace_back(Attribute::get(Ctx, Attribute::NoCapture)); else if (ManifestInternal) Attrs.emplace_back(Attribute::get(Ctx, "no-capture-maybe-returned")); } } /// Set the NOT_CAPTURED_IN_MEM and NOT_CAPTURED_IN_RET bits in \p Known /// depending on the ability of the function associated with \p IRP to capture /// state in memory and through "returning/throwing", respectively. static void determineFunctionCaptureCapabilities(const IRPosition &IRP, const Function &F, BitIntegerState &State) { // TODO: Once we have memory behavior attributes we should use them here. // If we know we cannot communicate or write to memory, we do not care about // ptr2int anymore. if (F.onlyReadsMemory() && F.doesNotThrow() && F.getReturnType()->isVoidTy()) { State.addKnownBits(NO_CAPTURE); return; } // A function cannot capture state in memory if it only reads memory, it can // however return/throw state and the state might be influenced by the // pointer value, e.g., loading from a returned pointer might reveal a bit. if (F.onlyReadsMemory()) State.addKnownBits(NOT_CAPTURED_IN_MEM); // A function cannot communicate state back if it does not through // exceptions and doesn not return values. if (F.doesNotThrow() && F.getReturnType()->isVoidTy()) State.addKnownBits(NOT_CAPTURED_IN_RET); // Check existing "returned" attributes. int ArgNo = IRP.getCalleeArgNo(); if (F.doesNotThrow() && ArgNo >= 0) { for (unsigned u = 0, e = F.arg_size(); u < e; ++u) if (F.hasParamAttribute(u, Attribute::Returned)) { if (u == unsigned(ArgNo)) State.removeAssumedBits(NOT_CAPTURED_IN_RET); else if (F.onlyReadsMemory()) State.addKnownBits(NO_CAPTURE); else State.addKnownBits(NOT_CAPTURED_IN_RET); break; } } } /// See AbstractState::getAsStr(). const std::string getAsStr() const override { if (isKnownNoCapture()) return "known not-captured"; if (isAssumedNoCapture()) return "assumed not-captured"; if (isKnownNoCaptureMaybeReturned()) return "known not-captured-maybe-returned"; if (isAssumedNoCaptureMaybeReturned()) return "assumed not-captured-maybe-returned"; return "assumed-captured"; } /// Check the use \p U and update \p State accordingly. Return true if we /// should continue to update the state. bool checkUse(Attributor &A, AANoCapture::StateType &State, const Use &U, bool &Follow) { Instruction *UInst = cast(U.getUser()); LLVM_DEBUG(dbgs() << "[AANoCapture] Check use: " << *U.get() << " in " << *UInst << "\n"); // Deal with ptr2int by following uses. if (isa(UInst)) { LLVM_DEBUG(dbgs() << " - ptr2int assume the worst!\n"); return isCapturedIn(State, /* Memory */ true, /* Integer */ true, /* Return */ true); } // For stores we already checked if we can follow them, if they make it // here we give up. if (isa(UInst)) return isCapturedIn(State, /* Memory */ true, /* Integer */ false, /* Return */ false); // Explicitly catch return instructions. if (isa(UInst)) { if (UInst->getFunction() == getAnchorScope()) return isCapturedIn(State, /* Memory */ false, /* Integer */ false, /* Return */ true); return isCapturedIn(State, /* Memory */ true, /* Integer */ true, /* Return */ true); } // For now we only use special logic for call sites. However, the tracker // itself knows about a lot of other non-capturing cases already. auto *CB = dyn_cast(UInst); if (!CB || !CB->isArgOperand(&U)) return isCapturedIn(State, /* Memory */ true, /* Integer */ true, /* Return */ true); unsigned ArgNo = CB->getArgOperandNo(&U); const IRPosition &CSArgPos = IRPosition::callsite_argument(*CB, ArgNo); // If we have a abstract no-capture attribute for the argument we can use // it to justify a non-capture attribute here. This allows recursion! auto &ArgNoCaptureAA = A.getAAFor(*this, CSArgPos, DepClassTy::REQUIRED); if (ArgNoCaptureAA.isAssumedNoCapture()) return isCapturedIn(State, /* Memory */ false, /* Integer */ false, /* Return */ false); if (ArgNoCaptureAA.isAssumedNoCaptureMaybeReturned()) { Follow = true; return isCapturedIn(State, /* Memory */ false, /* Integer */ false, /* Return */ false); } // Lastly, we could not find a reason no-capture can be assumed so we don't. return isCapturedIn(State, /* Memory */ true, /* Integer */ true, /* Return */ true); } /// Update \p State according to \p CapturedInMem, \p CapturedInInt, and /// \p CapturedInRet, then return true if we should continue updating the /// state. static bool isCapturedIn(AANoCapture::StateType &State, bool CapturedInMem, bool CapturedInInt, bool CapturedInRet) { LLVM_DEBUG(dbgs() << " - captures [Mem " << CapturedInMem << "|Int " << CapturedInInt << "|Ret " << CapturedInRet << "]\n"); if (CapturedInMem) State.removeAssumedBits(AANoCapture::NOT_CAPTURED_IN_MEM); if (CapturedInInt) State.removeAssumedBits(AANoCapture::NOT_CAPTURED_IN_INT); if (CapturedInRet) State.removeAssumedBits(AANoCapture::NOT_CAPTURED_IN_RET); return State.isAssumed(AANoCapture::NO_CAPTURE_MAYBE_RETURNED); } }; ChangeStatus AANoCaptureImpl::updateImpl(Attributor &A) { const IRPosition &IRP = getIRPosition(); Value *V = isArgumentPosition() ? IRP.getAssociatedArgument() : &IRP.getAssociatedValue(); if (!V) return indicatePessimisticFixpoint(); const Function *F = isArgumentPosition() ? IRP.getAssociatedFunction() : IRP.getAnchorScope(); assert(F && "Expected a function!"); const IRPosition &FnPos = IRPosition::function(*F); AANoCapture::StateType T; // Readonly means we cannot capture through memory. bool IsKnown; if (AA::isAssumedReadOnly(A, FnPos, *this, IsKnown)) { T.addKnownBits(NOT_CAPTURED_IN_MEM); if (IsKnown) addKnownBits(NOT_CAPTURED_IN_MEM); } // Make sure all returned values are different than the underlying value. // TODO: we could do this in a more sophisticated way inside // AAReturnedValues, e.g., track all values that escape through returns // directly somehow. auto CheckReturnedArgs = [&](const AAReturnedValues &RVAA) { if (!RVAA.getState().isValidState()) return false; bool SeenConstant = false; for (auto &It : RVAA.returned_values()) { if (isa(It.first)) { if (SeenConstant) return false; SeenConstant = true; } else if (!isa(It.first) || It.first == getAssociatedArgument()) return false; } return true; }; const auto &NoUnwindAA = A.getAAFor(*this, FnPos, DepClassTy::OPTIONAL); if (NoUnwindAA.isAssumedNoUnwind()) { bool IsVoidTy = F->getReturnType()->isVoidTy(); const AAReturnedValues *RVAA = IsVoidTy ? nullptr : &A.getAAFor(*this, FnPos, DepClassTy::OPTIONAL); if (IsVoidTy || CheckReturnedArgs(*RVAA)) { T.addKnownBits(NOT_CAPTURED_IN_RET); if (T.isKnown(NOT_CAPTURED_IN_MEM)) return ChangeStatus::UNCHANGED; if (NoUnwindAA.isKnownNoUnwind() && (IsVoidTy || RVAA->getState().isAtFixpoint())) { addKnownBits(NOT_CAPTURED_IN_RET); if (isKnown(NOT_CAPTURED_IN_MEM)) return indicateOptimisticFixpoint(); } } } auto IsDereferenceableOrNull = [&](Value *O, const DataLayout &DL) { const auto &DerefAA = A.getAAFor( *this, IRPosition::value(*O), DepClassTy::OPTIONAL); return DerefAA.getAssumedDereferenceableBytes(); }; auto UseCheck = [&](const Use &U, bool &Follow) -> bool { switch (DetermineUseCaptureKind(U, IsDereferenceableOrNull)) { case UseCaptureKind::NO_CAPTURE: return true; case UseCaptureKind::MAY_CAPTURE: return checkUse(A, T, U, Follow); case UseCaptureKind::PASSTHROUGH: Follow = true; return true; } llvm_unreachable("Unexpected use capture kind!"); }; if (!A.checkForAllUses(UseCheck, *this, *V)) return indicatePessimisticFixpoint(); AANoCapture::StateType &S = getState(); auto Assumed = S.getAssumed(); S.intersectAssumedBits(T.getAssumed()); if (!isAssumedNoCaptureMaybeReturned()) return indicatePessimisticFixpoint(); return Assumed == S.getAssumed() ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } /// NoCapture attribute for function arguments. struct AANoCaptureArgument final : AANoCaptureImpl { AANoCaptureArgument(const IRPosition &IRP, Attributor &A) : AANoCaptureImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(nocapture) } }; /// NoCapture attribute for call site arguments. struct AANoCaptureCallSiteArgument final : AANoCaptureImpl { AANoCaptureCallSiteArgument(const IRPosition &IRP, Attributor &A) : AANoCaptureImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { if (Argument *Arg = getAssociatedArgument()) if (Arg->hasByValAttr()) indicateOptimisticFixpoint(); AANoCaptureImpl::initialize(A); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Argument *Arg = getAssociatedArgument(); if (!Arg) return indicatePessimisticFixpoint(); const IRPosition &ArgPos = IRPosition::argument(*Arg); auto &ArgAA = A.getAAFor(*this, ArgPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), ArgAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override{STATS_DECLTRACK_CSARG_ATTR(nocapture)}; }; /// NoCapture attribute for floating values. struct AANoCaptureFloating final : AANoCaptureImpl { AANoCaptureFloating(const IRPosition &IRP, Attributor &A) : AANoCaptureImpl(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(nocapture) } }; /// NoCapture attribute for function return value. struct AANoCaptureReturned final : AANoCaptureImpl { AANoCaptureReturned(const IRPosition &IRP, Attributor &A) : AANoCaptureImpl(IRP, A) { llvm_unreachable("NoCapture is not applicable to function returns!"); } /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { llvm_unreachable("NoCapture is not applicable to function returns!"); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { llvm_unreachable("NoCapture is not applicable to function returns!"); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override {} }; /// NoCapture attribute deduction for a call site return value. struct AANoCaptureCallSiteReturned final : AANoCaptureImpl { AANoCaptureCallSiteReturned(const IRPosition &IRP, Attributor &A) : AANoCaptureImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { const Function *F = getAnchorScope(); // Check what state the associated function can actually capture. determineFunctionCaptureCapabilities(getIRPosition(), *F, *this); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(nocapture) } }; } // namespace /// ------------------ Value Simplify Attribute ---------------------------- bool ValueSimplifyStateType::unionAssumed(Optional Other) { // FIXME: Add a typecast support. SimplifiedAssociatedValue = AA::combineOptionalValuesInAAValueLatice( SimplifiedAssociatedValue, Other, Ty); if (SimplifiedAssociatedValue == Optional(nullptr)) return false; LLVM_DEBUG({ if (SimplifiedAssociatedValue) dbgs() << "[ValueSimplify] is assumed to be " << **SimplifiedAssociatedValue << "\n"; else dbgs() << "[ValueSimplify] is assumed to be \n"; }); return true; } namespace { struct AAValueSimplifyImpl : AAValueSimplify { AAValueSimplifyImpl(const IRPosition &IRP, Attributor &A) : AAValueSimplify(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { if (getAssociatedValue().getType()->isVoidTy()) indicatePessimisticFixpoint(); if (A.hasSimplificationCallback(getIRPosition())) indicatePessimisticFixpoint(); } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { LLVM_DEBUG({ dbgs() << "SAV: " << (bool)SimplifiedAssociatedValue << " "; if (SimplifiedAssociatedValue && *SimplifiedAssociatedValue) dbgs() << "SAV: " << **SimplifiedAssociatedValue << " "; }); return isValidState() ? (isAtFixpoint() ? "simplified" : "maybe-simple") : "not-simple"; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override {} /// See AAValueSimplify::getAssumedSimplifiedValue() Optional getAssumedSimplifiedValue(Attributor &A) const override { return SimplifiedAssociatedValue; } /// Ensure the return value is \p V with type \p Ty, if not possible return /// nullptr. If \p Check is true we will only verify such an operation would /// suceed and return a non-nullptr value if that is the case. No IR is /// generated or modified. static Value *ensureType(Attributor &A, Value &V, Type &Ty, Instruction *CtxI, bool Check) { if (auto *TypedV = AA::getWithType(V, Ty)) return TypedV; if (CtxI && V.getType()->canLosslesslyBitCastTo(&Ty)) return Check ? &V : BitCastInst::CreatePointerBitCastOrAddrSpaceCast(&V, &Ty, "", CtxI); return nullptr; } /// Reproduce \p I with type \p Ty or return nullptr if that is not posisble. /// If \p Check is true we will only verify such an operation would suceed and /// return a non-nullptr value if that is the case. No IR is generated or /// modified. static Value *reproduceInst(Attributor &A, const AbstractAttribute &QueryingAA, Instruction &I, Type &Ty, Instruction *CtxI, bool Check, ValueToValueMapTy &VMap) { assert(CtxI && "Cannot reproduce an instruction without context!"); if (Check && (I.mayReadFromMemory() || !isSafeToSpeculativelyExecute(&I, CtxI, /* DT */ nullptr, /* TLI */ nullptr))) return nullptr; for (Value *Op : I.operands()) { Value *NewOp = reproduceValue(A, QueryingAA, *Op, Ty, CtxI, Check, VMap); if (!NewOp) { assert(Check && "Manifest of new value unexpectedly failed!"); return nullptr; } if (!Check) VMap[Op] = NewOp; } if (Check) return &I; Instruction *CloneI = I.clone(); // TODO: Try to salvage debug information here. CloneI->setDebugLoc(DebugLoc()); VMap[&I] = CloneI; CloneI->insertBefore(CtxI); RemapInstruction(CloneI, VMap); return CloneI; } /// Reproduce \p V with type \p Ty or return nullptr if that is not posisble. /// If \p Check is true we will only verify such an operation would suceed and /// return a non-nullptr value if that is the case. No IR is generated or /// modified. static Value *reproduceValue(Attributor &A, const AbstractAttribute &QueryingAA, Value &V, Type &Ty, Instruction *CtxI, bool Check, ValueToValueMapTy &VMap) { if (const auto &NewV = VMap.lookup(&V)) return NewV; bool UsedAssumedInformation = false; Optional SimpleV = A.getAssumedSimplified( V, QueryingAA, UsedAssumedInformation, AA::Interprocedural); if (!SimpleV.has_value()) return PoisonValue::get(&Ty); Value *EffectiveV = &V; if (SimpleV.value()) EffectiveV = SimpleV.value(); if (auto *C = dyn_cast(EffectiveV)) return C; if (CtxI && AA::isValidAtPosition(AA::ValueAndContext(*EffectiveV, *CtxI), A.getInfoCache())) return ensureType(A, *EffectiveV, Ty, CtxI, Check); if (auto *I = dyn_cast(EffectiveV)) if (Value *NewV = reproduceInst(A, QueryingAA, *I, Ty, CtxI, Check, VMap)) return ensureType(A, *NewV, Ty, CtxI, Check); return nullptr; } /// Return a value we can use as replacement for the associated one, or /// nullptr if we don't have one that makes sense. Value *manifestReplacementValue(Attributor &A, Instruction *CtxI) const { Value *NewV = SimplifiedAssociatedValue ? SimplifiedAssociatedValue.value() : UndefValue::get(getAssociatedType()); if (NewV && NewV != &getAssociatedValue()) { ValueToValueMapTy VMap; // First verify we can reprduce the value with the required type at the // context location before we actually start modifying the IR. if (reproduceValue(A, *this, *NewV, *getAssociatedType(), CtxI, /* CheckOnly */ true, VMap)) return reproduceValue(A, *this, *NewV, *getAssociatedType(), CtxI, /* CheckOnly */ false, VMap); } return nullptr; } /// Helper function for querying AAValueSimplify and updating candicate. /// \param IRP The value position we are trying to unify with SimplifiedValue bool checkAndUpdate(Attributor &A, const AbstractAttribute &QueryingAA, const IRPosition &IRP, bool Simplify = true) { bool UsedAssumedInformation = false; Optional QueryingValueSimplified = &IRP.getAssociatedValue(); if (Simplify) QueryingValueSimplified = A.getAssumedSimplified( IRP, QueryingAA, UsedAssumedInformation, AA::Interprocedural); return unionAssumed(QueryingValueSimplified); } /// Returns a candidate is found or not template bool askSimplifiedValueFor(Attributor &A) { if (!getAssociatedValue().getType()->isIntegerTy()) return false; // This will also pass the call base context. const auto &AA = A.getAAFor(*this, getIRPosition(), DepClassTy::NONE); Optional COpt = AA.getAssumedConstant(A); if (!COpt) { SimplifiedAssociatedValue = llvm::None; A.recordDependence(AA, *this, DepClassTy::OPTIONAL); return true; } if (auto *C = *COpt) { SimplifiedAssociatedValue = C; A.recordDependence(AA, *this, DepClassTy::OPTIONAL); return true; } return false; } bool askSimplifiedValueForOtherAAs(Attributor &A) { if (askSimplifiedValueFor(A)) return true; if (askSimplifiedValueFor(A)) return true; return false; } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { ChangeStatus Changed = ChangeStatus::UNCHANGED; for (auto &U : getAssociatedValue().uses()) { // Check if we need to adjust the insertion point to make sure the IR is // valid. Instruction *IP = dyn_cast(U.getUser()); if (auto *PHI = dyn_cast_or_null(IP)) IP = PHI->getIncomingBlock(U)->getTerminator(); if (auto *NewV = manifestReplacementValue(A, IP)) { LLVM_DEBUG(dbgs() << "[ValueSimplify] " << getAssociatedValue() << " -> " << *NewV << " :: " << *this << "\n"); if (A.changeUseAfterManifest(U, *NewV)) Changed = ChangeStatus::CHANGED; } } return Changed | AAValueSimplify::manifest(A); } /// See AbstractState::indicatePessimisticFixpoint(...). ChangeStatus indicatePessimisticFixpoint() override { SimplifiedAssociatedValue = &getAssociatedValue(); return AAValueSimplify::indicatePessimisticFixpoint(); } }; struct AAValueSimplifyArgument final : AAValueSimplifyImpl { AAValueSimplifyArgument(const IRPosition &IRP, Attributor &A) : AAValueSimplifyImpl(IRP, A) {} void initialize(Attributor &A) override { AAValueSimplifyImpl::initialize(A); if (!getAnchorScope() || getAnchorScope()->isDeclaration()) indicatePessimisticFixpoint(); if (hasAttr({Attribute::InAlloca, Attribute::Preallocated, Attribute::StructRet, Attribute::Nest, Attribute::ByVal}, /* IgnoreSubsumingPositions */ true)) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // Byval is only replacable if it is readonly otherwise we would write into // the replaced value and not the copy that byval creates implicitly. Argument *Arg = getAssociatedArgument(); if (Arg->hasByValAttr()) { // TODO: We probably need to verify synchronization is not an issue, e.g., // there is no race by not copying a constant byval. bool IsKnown; if (!AA::isAssumedReadOnly(A, getIRPosition(), *this, IsKnown)) return indicatePessimisticFixpoint(); } auto Before = SimplifiedAssociatedValue; auto PredForCallSite = [&](AbstractCallSite ACS) { const IRPosition &ACSArgPos = IRPosition::callsite_argument(ACS, getCallSiteArgNo()); // Check if a coresponding argument was found or if it is on not // associated (which can happen for callback calls). if (ACSArgPos.getPositionKind() == IRPosition::IRP_INVALID) return false; // Simplify the argument operand explicitly and check if the result is // valid in the current scope. This avoids refering to simplified values // in other functions, e.g., we don't want to say a an argument in a // static function is actually an argument in a different function. bool UsedAssumedInformation = false; Optional SimpleArgOp = A.getAssumedConstant(ACSArgPos, *this, UsedAssumedInformation); if (!SimpleArgOp) return true; if (!SimpleArgOp.value()) return false; if (!AA::isDynamicallyUnique(A, *this, **SimpleArgOp)) return false; return unionAssumed(*SimpleArgOp); }; // Generate a answer specific to a call site context. bool Success; bool UsedAssumedInformation = false; if (hasCallBaseContext() && getCallBaseContext()->getCalledFunction() == Arg->getParent()) Success = PredForCallSite( AbstractCallSite(&getCallBaseContext()->getCalledOperandUse())); else Success = A.checkForAllCallSites(PredForCallSite, *this, true, UsedAssumedInformation); if (!Success) if (!askSimplifiedValueForOtherAAs(A)) return indicatePessimisticFixpoint(); // If a candicate was found in this update, return CHANGED. return Before == SimplifiedAssociatedValue ? ChangeStatus::UNCHANGED : ChangeStatus ::CHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(value_simplify) } }; struct AAValueSimplifyReturned : AAValueSimplifyImpl { AAValueSimplifyReturned(const IRPosition &IRP, Attributor &A) : AAValueSimplifyImpl(IRP, A) {} /// See AAValueSimplify::getAssumedSimplifiedValue() Optional getAssumedSimplifiedValue(Attributor &A) const override { if (!isValidState()) return nullptr; return SimplifiedAssociatedValue; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { auto Before = SimplifiedAssociatedValue; auto ReturnInstCB = [&](Instruction &I) { auto &RI = cast(I); return checkAndUpdate( A, *this, IRPosition::value(*RI.getReturnValue(), getCallBaseContext())); }; bool UsedAssumedInformation = false; if (!A.checkForAllInstructions(ReturnInstCB, *this, {Instruction::Ret}, UsedAssumedInformation)) if (!askSimplifiedValueForOtherAAs(A)) return indicatePessimisticFixpoint(); // If a candicate was found in this update, return CHANGED. return Before == SimplifiedAssociatedValue ? ChangeStatus::UNCHANGED : ChangeStatus ::CHANGED; } ChangeStatus manifest(Attributor &A) override { // We queried AAValueSimplify for the returned values so they will be // replaced if a simplified form was found. Nothing to do here. return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(value_simplify) } }; struct AAValueSimplifyFloating : AAValueSimplifyImpl { AAValueSimplifyFloating(const IRPosition &IRP, Attributor &A) : AAValueSimplifyImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAValueSimplifyImpl::initialize(A); Value &V = getAnchorValue(); // TODO: add other stuffs if (isa(V)) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { auto Before = SimplifiedAssociatedValue; if (!askSimplifiedValueForOtherAAs(A)) return indicatePessimisticFixpoint(); // If a candicate was found in this update, return CHANGED. return Before == SimplifiedAssociatedValue ? ChangeStatus::UNCHANGED : ChangeStatus ::CHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(value_simplify) } }; struct AAValueSimplifyFunction : AAValueSimplifyImpl { AAValueSimplifyFunction(const IRPosition &IRP, Attributor &A) : AAValueSimplifyImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { SimplifiedAssociatedValue = nullptr; indicateOptimisticFixpoint(); } /// See AbstractAttribute::initialize(...). ChangeStatus updateImpl(Attributor &A) override { llvm_unreachable( "AAValueSimplify(Function|CallSite)::updateImpl will not be called"); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(value_simplify) } }; struct AAValueSimplifyCallSite : AAValueSimplifyFunction { AAValueSimplifyCallSite(const IRPosition &IRP, Attributor &A) : AAValueSimplifyFunction(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(value_simplify) } }; struct AAValueSimplifyCallSiteReturned : AAValueSimplifyImpl { AAValueSimplifyCallSiteReturned(const IRPosition &IRP, Attributor &A) : AAValueSimplifyImpl(IRP, A) {} void initialize(Attributor &A) override { AAValueSimplifyImpl::initialize(A); Function *Fn = getAssociatedFunction(); if (!Fn) { indicatePessimisticFixpoint(); return; } for (Argument &Arg : Fn->args()) { if (Arg.hasReturnedAttr()) { auto IRP = IRPosition::callsite_argument(*cast(getCtxI()), Arg.getArgNo()); if (IRP.getPositionKind() == IRPosition::IRP_CALL_SITE_ARGUMENT && checkAndUpdate(A, *this, IRP)) indicateOptimisticFixpoint(); else indicatePessimisticFixpoint(); return; } } } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { auto Before = SimplifiedAssociatedValue; auto &RetAA = A.getAAFor( *this, IRPosition::function(*getAssociatedFunction()), DepClassTy::REQUIRED); auto PredForReturned = [&](Value &RetVal, const SmallSetVector &RetInsts) { bool UsedAssumedInformation = false; Optional CSRetVal = A.translateArgumentToCallSiteContent( &RetVal, *cast(getCtxI()), *this, UsedAssumedInformation); SimplifiedAssociatedValue = AA::combineOptionalValuesInAAValueLatice( SimplifiedAssociatedValue, CSRetVal, getAssociatedType()); return SimplifiedAssociatedValue != Optional(nullptr); }; if (!RetAA.checkForAllReturnedValuesAndReturnInsts(PredForReturned)) if (!askSimplifiedValueForOtherAAs(A)) return indicatePessimisticFixpoint(); return Before == SimplifiedAssociatedValue ? ChangeStatus::UNCHANGED : ChangeStatus ::CHANGED; } void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(value_simplify) } }; struct AAValueSimplifyCallSiteArgument : AAValueSimplifyFloating { AAValueSimplifyCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAValueSimplifyFloating(IRP, A) {} /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { ChangeStatus Changed = ChangeStatus::UNCHANGED; // TODO: We should avoid simplification duplication to begin with. auto *FloatAA = A.lookupAAFor( IRPosition::value(getAssociatedValue()), this, DepClassTy::NONE); if (FloatAA && FloatAA->getState().isValidState()) return Changed; if (auto *NewV = manifestReplacementValue(A, getCtxI())) { Use &U = cast(&getAnchorValue()) ->getArgOperandUse(getCallSiteArgNo()); if (A.changeUseAfterManifest(U, *NewV)) Changed = ChangeStatus::CHANGED; } return Changed | AAValueSimplify::manifest(A); } void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(value_simplify) } }; } // namespace /// ----------------------- Heap-To-Stack Conversion --------------------------- namespace { struct AAHeapToStackFunction final : public AAHeapToStack { struct AllocationInfo { /// The call that allocates the memory. CallBase *const CB; /// The library function id for the allocation. LibFunc LibraryFunctionId = NotLibFunc; /// The status wrt. a rewrite. enum { STACK_DUE_TO_USE, STACK_DUE_TO_FREE, INVALID, } Status = STACK_DUE_TO_USE; /// Flag to indicate if we encountered a use that might free this allocation /// but which is not in the deallocation infos. bool HasPotentiallyFreeingUnknownUses = false; /// Flag to indicate that we should place the new alloca in the function /// entry block rather than where the call site (CB) is. bool MoveAllocaIntoEntry = true; /// The set of free calls that use this allocation. SmallSetVector PotentialFreeCalls{}; }; struct DeallocationInfo { /// The call that deallocates the memory. CallBase *const CB; /// The value freed by the call. Value *FreedOp; /// Flag to indicate if we don't know all objects this deallocation might /// free. bool MightFreeUnknownObjects = false; /// The set of allocation calls that are potentially freed. SmallSetVector PotentialAllocationCalls{}; }; AAHeapToStackFunction(const IRPosition &IRP, Attributor &A) : AAHeapToStack(IRP, A) {} ~AAHeapToStackFunction() { // Ensure we call the destructor so we release any memory allocated in the // sets. for (auto &It : AllocationInfos) It.second->~AllocationInfo(); for (auto &It : DeallocationInfos) It.second->~DeallocationInfo(); } void initialize(Attributor &A) override { AAHeapToStack::initialize(A); const Function *F = getAnchorScope(); const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F); auto AllocationIdentifierCB = [&](Instruction &I) { CallBase *CB = dyn_cast(&I); if (!CB) return true; if (Value *FreedOp = getFreedOperand(CB, TLI)) { DeallocationInfos[CB] = new (A.Allocator) DeallocationInfo{CB, FreedOp}; return true; } // To do heap to stack, we need to know that the allocation itself is // removable once uses are rewritten, and that we can initialize the // alloca to the same pattern as the original allocation result. if (isRemovableAlloc(CB, TLI)) { auto *I8Ty = Type::getInt8Ty(CB->getParent()->getContext()); if (nullptr != getInitialValueOfAllocation(CB, TLI, I8Ty)) { AllocationInfo *AI = new (A.Allocator) AllocationInfo{CB}; AllocationInfos[CB] = AI; if (TLI) TLI->getLibFunc(*CB, AI->LibraryFunctionId); } } return true; }; bool UsedAssumedInformation = false; bool Success = A.checkForAllCallLikeInstructions( AllocationIdentifierCB, *this, UsedAssumedInformation, /* CheckBBLivenessOnly */ false, /* CheckPotentiallyDead */ true); (void)Success; assert(Success && "Did not expect the call base visit callback to fail!"); Attributor::SimplifictionCallbackTy SCB = [](const IRPosition &, const AbstractAttribute *, bool &) -> Optional { return nullptr; }; for (const auto &It : AllocationInfos) A.registerSimplificationCallback(IRPosition::callsite_returned(*It.first), SCB); for (const auto &It : DeallocationInfos) A.registerSimplificationCallback(IRPosition::callsite_returned(*It.first), SCB); } const std::string getAsStr() const override { unsigned NumH2SMallocs = 0, NumInvalidMallocs = 0; for (const auto &It : AllocationInfos) { if (It.second->Status == AllocationInfo::INVALID) ++NumInvalidMallocs; else ++NumH2SMallocs; } return "[H2S] Mallocs Good/Bad: " + std::to_string(NumH2SMallocs) + "/" + std::to_string(NumInvalidMallocs); } /// See AbstractAttribute::trackStatistics(). void trackStatistics() const override { STATS_DECL( MallocCalls, Function, "Number of malloc/calloc/aligned_alloc calls converted to allocas"); for (auto &It : AllocationInfos) if (It.second->Status != AllocationInfo::INVALID) ++BUILD_STAT_NAME(MallocCalls, Function); } bool isAssumedHeapToStack(const CallBase &CB) const override { if (isValidState()) if (AllocationInfo *AI = AllocationInfos.lookup(const_cast(&CB))) return AI->Status != AllocationInfo::INVALID; return false; } bool isAssumedHeapToStackRemovedFree(CallBase &CB) const override { if (!isValidState()) return false; for (auto &It : AllocationInfos) { AllocationInfo &AI = *It.second; if (AI.Status == AllocationInfo::INVALID) continue; if (AI.PotentialFreeCalls.count(&CB)) return true; } return false; } ChangeStatus manifest(Attributor &A) override { assert(getState().isValidState() && "Attempted to manifest an invalid state!"); ChangeStatus HasChanged = ChangeStatus::UNCHANGED; Function *F = getAnchorScope(); const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F); for (auto &It : AllocationInfos) { AllocationInfo &AI = *It.second; if (AI.Status == AllocationInfo::INVALID) continue; for (CallBase *FreeCall : AI.PotentialFreeCalls) { LLVM_DEBUG(dbgs() << "H2S: Removing free call: " << *FreeCall << "\n"); A.deleteAfterManifest(*FreeCall); HasChanged = ChangeStatus::CHANGED; } LLVM_DEBUG(dbgs() << "H2S: Removing malloc-like call: " << *AI.CB << "\n"); auto Remark = [&](OptimizationRemark OR) { LibFunc IsAllocShared; if (TLI->getLibFunc(*AI.CB, IsAllocShared)) if (IsAllocShared == LibFunc___kmpc_alloc_shared) return OR << "Moving globalized variable to the stack."; return OR << "Moving memory allocation from the heap to the stack."; }; if (AI.LibraryFunctionId == LibFunc___kmpc_alloc_shared) A.emitRemark(AI.CB, "OMP110", Remark); else A.emitRemark(AI.CB, "HeapToStack", Remark); const DataLayout &DL = A.getInfoCache().getDL(); Value *Size; Optional SizeAPI = getSize(A, *this, AI); if (SizeAPI) { Size = ConstantInt::get(AI.CB->getContext(), *SizeAPI); } else { LLVMContext &Ctx = AI.CB->getContext(); ObjectSizeOpts Opts; ObjectSizeOffsetEvaluator Eval(DL, TLI, Ctx, Opts); SizeOffsetEvalType SizeOffsetPair = Eval.compute(AI.CB); assert(SizeOffsetPair != ObjectSizeOffsetEvaluator::unknown() && cast(SizeOffsetPair.second)->isZero()); Size = SizeOffsetPair.first; } Instruction *IP = AI.MoveAllocaIntoEntry ? &F->getEntryBlock().front() : AI.CB; Align Alignment(1); if (MaybeAlign RetAlign = AI.CB->getRetAlign()) Alignment = std::max(Alignment, *RetAlign); if (Value *Align = getAllocAlignment(AI.CB, TLI)) { Optional AlignmentAPI = getAPInt(A, *this, *Align); assert(AlignmentAPI && AlignmentAPI.value().getZExtValue() > 0 && "Expected an alignment during manifest!"); Alignment = std::max( Alignment, assumeAligned(AlignmentAPI.value().getZExtValue())); } // TODO: Hoist the alloca towards the function entry. unsigned AS = DL.getAllocaAddrSpace(); Instruction *Alloca = new AllocaInst(Type::getInt8Ty(F->getContext()), AS, Size, Alignment, AI.CB->getName() + ".h2s", IP); if (Alloca->getType() != AI.CB->getType()) Alloca = BitCastInst::CreatePointerBitCastOrAddrSpaceCast( Alloca, AI.CB->getType(), "malloc_cast", AI.CB); auto *I8Ty = Type::getInt8Ty(F->getContext()); auto *InitVal = getInitialValueOfAllocation(AI.CB, TLI, I8Ty); assert(InitVal && "Must be able to materialize initial memory state of allocation"); A.changeAfterManifest(IRPosition::inst(*AI.CB), *Alloca); if (auto *II = dyn_cast(AI.CB)) { auto *NBB = II->getNormalDest(); BranchInst::Create(NBB, AI.CB->getParent()); A.deleteAfterManifest(*AI.CB); } else { A.deleteAfterManifest(*AI.CB); } // Initialize the alloca with the same value as used by the allocation // function. We can skip undef as the initial value of an alloc is // undef, and the memset would simply end up being DSEd. if (!isa(InitVal)) { IRBuilder<> Builder(Alloca->getNextNode()); // TODO: Use alignment above if align!=1 Builder.CreateMemSet(Alloca, InitVal, Size, None); } HasChanged = ChangeStatus::CHANGED; } return HasChanged; } Optional getAPInt(Attributor &A, const AbstractAttribute &AA, Value &V) { bool UsedAssumedInformation = false; Optional SimpleV = A.getAssumedConstant(V, AA, UsedAssumedInformation); if (!SimpleV) return APInt(64, 0); if (auto *CI = dyn_cast_or_null(SimpleV.value())) return CI->getValue(); return llvm::None; } Optional getSize(Attributor &A, const AbstractAttribute &AA, AllocationInfo &AI) { auto Mapper = [&](const Value *V) -> const Value * { bool UsedAssumedInformation = false; if (Optional SimpleV = A.getAssumedConstant(*V, AA, UsedAssumedInformation)) if (*SimpleV) return *SimpleV; return V; }; const Function *F = getAnchorScope(); const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F); return getAllocSize(AI.CB, TLI, Mapper); } /// Collection of all malloc-like calls in a function with associated /// information. MapVector AllocationInfos; /// Collection of all free-like calls in a function with associated /// information. MapVector DeallocationInfos; ChangeStatus updateImpl(Attributor &A) override; }; ChangeStatus AAHeapToStackFunction::updateImpl(Attributor &A) { ChangeStatus Changed = ChangeStatus::UNCHANGED; const Function *F = getAnchorScope(); const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F); const auto &LivenessAA = A.getAAFor(*this, IRPosition::function(*F), DepClassTy::NONE); MustBeExecutedContextExplorer &Explorer = A.getInfoCache().getMustBeExecutedContextExplorer(); bool StackIsAccessibleByOtherThreads = A.getInfoCache().stackIsAccessibleByOtherThreads(); LoopInfo *LI = A.getInfoCache().getAnalysisResultForFunction(*F); Optional MayContainIrreducibleControl; auto IsInLoop = [&](BasicBlock &BB) { if (&F->getEntryBlock() == &BB) return false; if (!MayContainIrreducibleControl.has_value()) MayContainIrreducibleControl = mayContainIrreducibleControl(*F, LI); if (MayContainIrreducibleControl.value()) return true; if (!LI) return true; return LI->getLoopFor(&BB) != nullptr; }; // Flag to ensure we update our deallocation information at most once per // updateImpl call and only if we use the free check reasoning. bool HasUpdatedFrees = false; auto UpdateFrees = [&]() { HasUpdatedFrees = true; for (auto &It : DeallocationInfos) { DeallocationInfo &DI = *It.second; // For now we cannot use deallocations that have unknown inputs, skip // them. if (DI.MightFreeUnknownObjects) continue; // No need to analyze dead calls, ignore them instead. bool UsedAssumedInformation = false; if (A.isAssumedDead(*DI.CB, this, &LivenessAA, UsedAssumedInformation, /* CheckBBLivenessOnly */ true)) continue; // Use the non-optimistic version to get the freed object. Value *Obj = getUnderlyingObject(DI.FreedOp); if (!Obj) { LLVM_DEBUG(dbgs() << "[H2S] Unknown underlying object for free!\n"); DI.MightFreeUnknownObjects = true; continue; } // Free of null and undef can be ignored as no-ops (or UB in the latter // case). if (isa(Obj) || isa(Obj)) continue; CallBase *ObjCB = dyn_cast(Obj); if (!ObjCB) { LLVM_DEBUG(dbgs() << "[H2S] Free of a non-call object: " << *Obj << "\n"); DI.MightFreeUnknownObjects = true; continue; } AllocationInfo *AI = AllocationInfos.lookup(ObjCB); if (!AI) { LLVM_DEBUG(dbgs() << "[H2S] Free of a non-allocation object: " << *Obj << "\n"); DI.MightFreeUnknownObjects = true; continue; } DI.PotentialAllocationCalls.insert(ObjCB); } }; auto FreeCheck = [&](AllocationInfo &AI) { // If the stack is not accessible by other threads, the "must-free" logic // doesn't apply as the pointer could be shared and needs to be places in // "shareable" memory. if (!StackIsAccessibleByOtherThreads) { auto &NoSyncAA = A.getAAFor(*this, getIRPosition(), DepClassTy::OPTIONAL); if (!NoSyncAA.isAssumedNoSync()) { LLVM_DEBUG( dbgs() << "[H2S] found an escaping use, stack is not accessible by " "other threads and function is not nosync:\n"); return false; } } if (!HasUpdatedFrees) UpdateFrees(); // TODO: Allow multi exit functions that have different free calls. if (AI.PotentialFreeCalls.size() != 1) { LLVM_DEBUG(dbgs() << "[H2S] did not find one free call but " << AI.PotentialFreeCalls.size() << "\n"); return false; } CallBase *UniqueFree = *AI.PotentialFreeCalls.begin(); DeallocationInfo *DI = DeallocationInfos.lookup(UniqueFree); if (!DI) { LLVM_DEBUG( dbgs() << "[H2S] unique free call was not known as deallocation call " << *UniqueFree << "\n"); return false; } if (DI->MightFreeUnknownObjects) { LLVM_DEBUG( dbgs() << "[H2S] unique free call might free unknown allocations\n"); return false; } if (DI->PotentialAllocationCalls.empty()) return true; if (DI->PotentialAllocationCalls.size() > 1) { LLVM_DEBUG(dbgs() << "[H2S] unique free call might free " << DI->PotentialAllocationCalls.size() << " different allocations\n"); return false; } if (*DI->PotentialAllocationCalls.begin() != AI.CB) { LLVM_DEBUG( dbgs() << "[H2S] unique free call not known to free this allocation but " << **DI->PotentialAllocationCalls.begin() << "\n"); return false; } Instruction *CtxI = isa(AI.CB) ? AI.CB : AI.CB->getNextNode(); if (!Explorer.findInContextOf(UniqueFree, CtxI)) { LLVM_DEBUG( dbgs() << "[H2S] unique free call might not be executed with the allocation " << *UniqueFree << "\n"); return false; } return true; }; auto UsesCheck = [&](AllocationInfo &AI) { bool ValidUsesOnly = true; auto Pred = [&](const Use &U, bool &Follow) -> bool { Instruction *UserI = cast(U.getUser()); if (isa(UserI)) return true; if (auto *SI = dyn_cast(UserI)) { if (SI->getValueOperand() == U.get()) { LLVM_DEBUG(dbgs() << "[H2S] escaping store to memory: " << *UserI << "\n"); ValidUsesOnly = false; } else { // A store into the malloc'ed memory is fine. } return true; } if (auto *CB = dyn_cast(UserI)) { if (!CB->isArgOperand(&U) || CB->isLifetimeStartOrEnd()) return true; if (DeallocationInfos.count(CB)) { AI.PotentialFreeCalls.insert(CB); return true; } unsigned ArgNo = CB->getArgOperandNo(&U); const auto &NoCaptureAA = A.getAAFor( *this, IRPosition::callsite_argument(*CB, ArgNo), DepClassTy::OPTIONAL); // If a call site argument use is nofree, we are fine. const auto &ArgNoFreeAA = A.getAAFor( *this, IRPosition::callsite_argument(*CB, ArgNo), DepClassTy::OPTIONAL); bool MaybeCaptured = !NoCaptureAA.isAssumedNoCapture(); bool MaybeFreed = !ArgNoFreeAA.isAssumedNoFree(); if (MaybeCaptured || (AI.LibraryFunctionId != LibFunc___kmpc_alloc_shared && MaybeFreed)) { AI.HasPotentiallyFreeingUnknownUses |= MaybeFreed; // Emit a missed remark if this is missed OpenMP globalization. auto Remark = [&](OptimizationRemarkMissed ORM) { return ORM << "Could not move globalized variable to the stack. " "Variable is potentially captured in call. Mark " "parameter as `__attribute__((noescape))` to override."; }; if (ValidUsesOnly && AI.LibraryFunctionId == LibFunc___kmpc_alloc_shared) A.emitRemark(CB, "OMP113", Remark); LLVM_DEBUG(dbgs() << "[H2S] Bad user: " << *UserI << "\n"); ValidUsesOnly = false; } return true; } if (isa(UserI) || isa(UserI) || isa(UserI) || isa(UserI)) { Follow = true; return true; } // Unknown user for which we can not track uses further (in a way that // makes sense). LLVM_DEBUG(dbgs() << "[H2S] Unknown user: " << *UserI << "\n"); ValidUsesOnly = false; return true; }; if (!A.checkForAllUses(Pred, *this, *AI.CB)) return false; return ValidUsesOnly; }; // The actual update starts here. We look at all allocations and depending on // their status perform the appropriate check(s). for (auto &It : AllocationInfos) { AllocationInfo &AI = *It.second; if (AI.Status == AllocationInfo::INVALID) continue; if (Value *Align = getAllocAlignment(AI.CB, TLI)) { Optional APAlign = getAPInt(A, *this, *Align); if (!APAlign) { // Can't generate an alloca which respects the required alignment // on the allocation. LLVM_DEBUG(dbgs() << "[H2S] Unknown allocation alignment: " << *AI.CB << "\n"); AI.Status = AllocationInfo::INVALID; Changed = ChangeStatus::CHANGED; continue; } if (APAlign->ugt(llvm::Value::MaximumAlignment) || !APAlign->isPowerOf2()) { LLVM_DEBUG(dbgs() << "[H2S] Invalid allocation alignment: " << APAlign << "\n"); AI.Status = AllocationInfo::INVALID; Changed = ChangeStatus::CHANGED; continue; } } Optional Size = getSize(A, *this, AI); if (MaxHeapToStackSize != -1) { if (!Size || Size.value().ugt(MaxHeapToStackSize)) { LLVM_DEBUG({ if (!Size) dbgs() << "[H2S] Unknown allocation size: " << *AI.CB << "\n"; else dbgs() << "[H2S] Allocation size too large: " << *AI.CB << " vs. " << MaxHeapToStackSize << "\n"; }); AI.Status = AllocationInfo::INVALID; Changed = ChangeStatus::CHANGED; continue; } } switch (AI.Status) { case AllocationInfo::STACK_DUE_TO_USE: if (UsesCheck(AI)) break; AI.Status = AllocationInfo::STACK_DUE_TO_FREE; LLVM_FALLTHROUGH; case AllocationInfo::STACK_DUE_TO_FREE: if (FreeCheck(AI)) break; AI.Status = AllocationInfo::INVALID; Changed = ChangeStatus::CHANGED; break; case AllocationInfo::INVALID: llvm_unreachable("Invalid allocations should never reach this point!"); }; // Check if we still think we can move it into the entry block. if (AI.MoveAllocaIntoEntry && (!Size.has_value() || IsInLoop(*AI.CB->getParent()))) AI.MoveAllocaIntoEntry = false; } return Changed; } } // namespace /// ----------------------- Privatizable Pointers ------------------------------ namespace { struct AAPrivatizablePtrImpl : public AAPrivatizablePtr { AAPrivatizablePtrImpl(const IRPosition &IRP, Attributor &A) : AAPrivatizablePtr(IRP, A), PrivatizableType(llvm::None) {} ChangeStatus indicatePessimisticFixpoint() override { AAPrivatizablePtr::indicatePessimisticFixpoint(); PrivatizableType = nullptr; return ChangeStatus::CHANGED; } /// Identify the type we can chose for a private copy of the underlying /// argument. None means it is not clear yet, nullptr means there is none. virtual Optional identifyPrivatizableType(Attributor &A) = 0; /// Return a privatizable type that encloses both T0 and T1. /// TODO: This is merely a stub for now as we should manage a mapping as well. Optional combineTypes(Optional T0, Optional T1) { if (!T0) return T1; if (!T1) return T0; if (T0 == T1) return T0; return nullptr; } Optional getPrivatizableType() const override { return PrivatizableType; } const std::string getAsStr() const override { return isAssumedPrivatizablePtr() ? "[priv]" : "[no-priv]"; } protected: Optional PrivatizableType; }; // TODO: Do this for call site arguments (probably also other values) as well. struct AAPrivatizablePtrArgument final : public AAPrivatizablePtrImpl { AAPrivatizablePtrArgument(const IRPosition &IRP, Attributor &A) : AAPrivatizablePtrImpl(IRP, A) {} /// See AAPrivatizablePtrImpl::identifyPrivatizableType(...) Optional identifyPrivatizableType(Attributor &A) override { // If this is a byval argument and we know all the call sites (so we can // rewrite them), there is no need to check them explicitly. bool UsedAssumedInformation = false; SmallVector Attrs; getAttrs({Attribute::ByVal}, Attrs, /* IgnoreSubsumingPositions */ true); if (!Attrs.empty() && A.checkForAllCallSites([](AbstractCallSite ACS) { return true; }, *this, true, UsedAssumedInformation)) return Attrs[0].getValueAsType(); Optional Ty; unsigned ArgNo = getIRPosition().getCallSiteArgNo(); // Make sure the associated call site argument has the same type at all call // sites and it is an allocation we know is safe to privatize, for now that // means we only allow alloca instructions. // TODO: We can additionally analyze the accesses in the callee to create // the type from that information instead. That is a little more // involved and will be done in a follow up patch. auto CallSiteCheck = [&](AbstractCallSite ACS) { IRPosition ACSArgPos = IRPosition::callsite_argument(ACS, ArgNo); // Check if a coresponding argument was found or if it is one not // associated (which can happen for callback calls). if (ACSArgPos.getPositionKind() == IRPosition::IRP_INVALID) return false; // Check that all call sites agree on a type. auto &PrivCSArgAA = A.getAAFor(*this, ACSArgPos, DepClassTy::REQUIRED); Optional CSTy = PrivCSArgAA.getPrivatizableType(); LLVM_DEBUG({ dbgs() << "[AAPrivatizablePtr] ACSPos: " << ACSArgPos << ", CSTy: "; if (CSTy && CSTy.value()) CSTy.value()->print(dbgs()); else if (CSTy) dbgs() << ""; else dbgs() << ""; }); Ty = combineTypes(Ty, CSTy); LLVM_DEBUG({ dbgs() << " : New Type: "; if (Ty && Ty.value()) Ty.value()->print(dbgs()); else if (Ty) dbgs() << ""; else dbgs() << ""; dbgs() << "\n"; }); return !Ty || Ty.value(); }; if (!A.checkForAllCallSites(CallSiteCheck, *this, true, UsedAssumedInformation)) return nullptr; return Ty; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { PrivatizableType = identifyPrivatizableType(A); if (!PrivatizableType) return ChangeStatus::UNCHANGED; if (!PrivatizableType.value()) return indicatePessimisticFixpoint(); // The dependence is optional so we don't give up once we give up on the // alignment. A.getAAFor(*this, IRPosition::value(getAssociatedValue()), DepClassTy::OPTIONAL); // Avoid arguments with padding for now. if (!getIRPosition().hasAttr(Attribute::ByVal) && !isDenselyPacked(*PrivatizableType, A.getInfoCache().getDL())) { LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] Padding detected\n"); return indicatePessimisticFixpoint(); } // Collect the types that will replace the privatizable type in the function // signature. SmallVector ReplacementTypes; identifyReplacementTypes(*PrivatizableType, ReplacementTypes); // Verify callee and caller agree on how the promoted argument would be // passed. Function &Fn = *getIRPosition().getAnchorScope(); const auto *TTI = A.getInfoCache().getAnalysisResultForFunction(Fn); if (!TTI) { LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] Missing TTI for function " << Fn.getName() << "\n"); return indicatePessimisticFixpoint(); } auto CallSiteCheck = [&](AbstractCallSite ACS) { CallBase *CB = ACS.getInstruction(); return TTI->areTypesABICompatible( CB->getCaller(), CB->getCalledFunction(), ReplacementTypes); }; bool UsedAssumedInformation = false; if (!A.checkForAllCallSites(CallSiteCheck, *this, true, UsedAssumedInformation)) { LLVM_DEBUG( dbgs() << "[AAPrivatizablePtr] ABI incompatibility detected for " << Fn.getName() << "\n"); return indicatePessimisticFixpoint(); } // Register a rewrite of the argument. Argument *Arg = getAssociatedArgument(); if (!A.isValidFunctionSignatureRewrite(*Arg, ReplacementTypes)) { LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] Rewrite not valid\n"); return indicatePessimisticFixpoint(); } unsigned ArgNo = Arg->getArgNo(); // Helper to check if for the given call site the associated argument is // passed to a callback where the privatization would be different. auto IsCompatiblePrivArgOfCallback = [&](CallBase &CB) { SmallVector CallbackUses; AbstractCallSite::getCallbackUses(CB, CallbackUses); for (const Use *U : CallbackUses) { AbstractCallSite CBACS(U); assert(CBACS && CBACS.isCallbackCall()); for (Argument &CBArg : CBACS.getCalledFunction()->args()) { int CBArgNo = CBACS.getCallArgOperandNo(CBArg); LLVM_DEBUG({ dbgs() << "[AAPrivatizablePtr] Argument " << *Arg << "check if can be privatized in the context of its parent (" << Arg->getParent()->getName() << ")\n[AAPrivatizablePtr] because it is an argument in a " "callback (" << CBArgNo << "@" << CBACS.getCalledFunction()->getName() << ")\n[AAPrivatizablePtr] " << CBArg << " : " << CBACS.getCallArgOperand(CBArg) << " vs " << CB.getArgOperand(ArgNo) << "\n" << "[AAPrivatizablePtr] " << CBArg << " : " << CBACS.getCallArgOperandNo(CBArg) << " vs " << ArgNo << "\n"; }); if (CBArgNo != int(ArgNo)) continue; const auto &CBArgPrivAA = A.getAAFor( *this, IRPosition::argument(CBArg), DepClassTy::REQUIRED); if (CBArgPrivAA.isValidState()) { auto CBArgPrivTy = CBArgPrivAA.getPrivatizableType(); if (!CBArgPrivTy) continue; if (CBArgPrivTy.value() == PrivatizableType) continue; } LLVM_DEBUG({ dbgs() << "[AAPrivatizablePtr] Argument " << *Arg << " cannot be privatized in the context of its parent (" << Arg->getParent()->getName() << ")\n[AAPrivatizablePtr] because it is an argument in a " "callback (" << CBArgNo << "@" << CBACS.getCalledFunction()->getName() << ").\n[AAPrivatizablePtr] for which the argument " "privatization is not compatible.\n"; }); return false; } } return true; }; // Helper to check if for the given call site the associated argument is // passed to a direct call where the privatization would be different. auto IsCompatiblePrivArgOfDirectCS = [&](AbstractCallSite ACS) { CallBase *DC = cast(ACS.getInstruction()); int DCArgNo = ACS.getCallArgOperandNo(ArgNo); assert(DCArgNo >= 0 && unsigned(DCArgNo) < DC->arg_size() && "Expected a direct call operand for callback call operand"); LLVM_DEBUG({ dbgs() << "[AAPrivatizablePtr] Argument " << *Arg << " check if be privatized in the context of its parent (" << Arg->getParent()->getName() << ")\n[AAPrivatizablePtr] because it is an argument in a " "direct call of (" << DCArgNo << "@" << DC->getCalledFunction()->getName() << ").\n"; }); Function *DCCallee = DC->getCalledFunction(); if (unsigned(DCArgNo) < DCCallee->arg_size()) { const auto &DCArgPrivAA = A.getAAFor( *this, IRPosition::argument(*DCCallee->getArg(DCArgNo)), DepClassTy::REQUIRED); if (DCArgPrivAA.isValidState()) { auto DCArgPrivTy = DCArgPrivAA.getPrivatizableType(); if (!DCArgPrivTy) return true; if (DCArgPrivTy.value() == PrivatizableType) return true; } } LLVM_DEBUG({ dbgs() << "[AAPrivatizablePtr] Argument " << *Arg << " cannot be privatized in the context of its parent (" << Arg->getParent()->getName() << ")\n[AAPrivatizablePtr] because it is an argument in a " "direct call of (" << ACS.getInstruction()->getCalledFunction()->getName() << ").\n[AAPrivatizablePtr] for which the argument " "privatization is not compatible.\n"; }); return false; }; // Helper to check if the associated argument is used at the given abstract // call site in a way that is incompatible with the privatization assumed // here. auto IsCompatiblePrivArgOfOtherCallSite = [&](AbstractCallSite ACS) { if (ACS.isDirectCall()) return IsCompatiblePrivArgOfCallback(*ACS.getInstruction()); if (ACS.isCallbackCall()) return IsCompatiblePrivArgOfDirectCS(ACS); return false; }; if (!A.checkForAllCallSites(IsCompatiblePrivArgOfOtherCallSite, *this, true, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return ChangeStatus::UNCHANGED; } /// Given a type to private \p PrivType, collect the constituates (which are /// used) in \p ReplacementTypes. static void identifyReplacementTypes(Type *PrivType, SmallVectorImpl &ReplacementTypes) { // TODO: For now we expand the privatization type to the fullest which can // lead to dead arguments that need to be removed later. assert(PrivType && "Expected privatizable type!"); // Traverse the type, extract constituate types on the outermost level. if (auto *PrivStructType = dyn_cast(PrivType)) { for (unsigned u = 0, e = PrivStructType->getNumElements(); u < e; u++) ReplacementTypes.push_back(PrivStructType->getElementType(u)); } else if (auto *PrivArrayType = dyn_cast(PrivType)) { ReplacementTypes.append(PrivArrayType->getNumElements(), PrivArrayType->getElementType()); } else { ReplacementTypes.push_back(PrivType); } } /// Initialize \p Base according to the type \p PrivType at position \p IP. /// The values needed are taken from the arguments of \p F starting at /// position \p ArgNo. static void createInitialization(Type *PrivType, Value &Base, Function &F, unsigned ArgNo, Instruction &IP) { assert(PrivType && "Expected privatizable type!"); IRBuilder IRB(&IP); const DataLayout &DL = F.getParent()->getDataLayout(); // Traverse the type, build GEPs and stores. if (auto *PrivStructType = dyn_cast(PrivType)) { const StructLayout *PrivStructLayout = DL.getStructLayout(PrivStructType); for (unsigned u = 0, e = PrivStructType->getNumElements(); u < e; u++) { Type *PointeeTy = PrivStructType->getElementType(u)->getPointerTo(); Value *Ptr = constructPointer(PointeeTy, PrivType, &Base, PrivStructLayout->getElementOffset(u), IRB, DL); new StoreInst(F.getArg(ArgNo + u), Ptr, &IP); } } else if (auto *PrivArrayType = dyn_cast(PrivType)) { Type *PointeeTy = PrivArrayType->getElementType(); Type *PointeePtrTy = PointeeTy->getPointerTo(); uint64_t PointeeTySize = DL.getTypeStoreSize(PointeeTy); for (unsigned u = 0, e = PrivArrayType->getNumElements(); u < e; u++) { Value *Ptr = constructPointer(PointeePtrTy, PrivType, &Base, u * PointeeTySize, IRB, DL); new StoreInst(F.getArg(ArgNo + u), Ptr, &IP); } } else { new StoreInst(F.getArg(ArgNo), &Base, &IP); } } /// Extract values from \p Base according to the type \p PrivType at the /// call position \p ACS. The values are appended to \p ReplacementValues. void createReplacementValues(Align Alignment, Type *PrivType, AbstractCallSite ACS, Value *Base, SmallVectorImpl &ReplacementValues) { assert(Base && "Expected base value!"); assert(PrivType && "Expected privatizable type!"); Instruction *IP = ACS.getInstruction(); IRBuilder IRB(IP); const DataLayout &DL = IP->getModule()->getDataLayout(); Type *PrivPtrType = PrivType->getPointerTo(); if (Base->getType() != PrivPtrType) Base = BitCastInst::CreatePointerBitCastOrAddrSpaceCast( Base, PrivPtrType, "", ACS.getInstruction()); // Traverse the type, build GEPs and loads. if (auto *PrivStructType = dyn_cast(PrivType)) { const StructLayout *PrivStructLayout = DL.getStructLayout(PrivStructType); for (unsigned u = 0, e = PrivStructType->getNumElements(); u < e; u++) { Type *PointeeTy = PrivStructType->getElementType(u); Value *Ptr = constructPointer(PointeeTy->getPointerTo(), PrivType, Base, PrivStructLayout->getElementOffset(u), IRB, DL); LoadInst *L = new LoadInst(PointeeTy, Ptr, "", IP); L->setAlignment(Alignment); ReplacementValues.push_back(L); } } else if (auto *PrivArrayType = dyn_cast(PrivType)) { Type *PointeeTy = PrivArrayType->getElementType(); uint64_t PointeeTySize = DL.getTypeStoreSize(PointeeTy); Type *PointeePtrTy = PointeeTy->getPointerTo(); for (unsigned u = 0, e = PrivArrayType->getNumElements(); u < e; u++) { Value *Ptr = constructPointer(PointeePtrTy, PrivType, Base, u * PointeeTySize, IRB, DL); LoadInst *L = new LoadInst(PointeeTy, Ptr, "", IP); L->setAlignment(Alignment); ReplacementValues.push_back(L); } } else { LoadInst *L = new LoadInst(PrivType, Base, "", IP); L->setAlignment(Alignment); ReplacementValues.push_back(L); } } /// See AbstractAttribute::manifest(...) ChangeStatus manifest(Attributor &A) override { if (!PrivatizableType) return ChangeStatus::UNCHANGED; assert(PrivatizableType.value() && "Expected privatizable type!"); // Collect all tail calls in the function as we cannot allow new allocas to // escape into tail recursion. // TODO: Be smarter about new allocas escaping into tail calls. SmallVector TailCalls; bool UsedAssumedInformation = false; if (!A.checkForAllInstructions( [&](Instruction &I) { CallInst &CI = cast(I); if (CI.isTailCall()) TailCalls.push_back(&CI); return true; }, *this, {Instruction::Call}, UsedAssumedInformation)) return ChangeStatus::UNCHANGED; Argument *Arg = getAssociatedArgument(); // Query AAAlign attribute for alignment of associated argument to // determine the best alignment of loads. const auto &AlignAA = A.getAAFor(*this, IRPosition::value(*Arg), DepClassTy::NONE); // Callback to repair the associated function. A new alloca is placed at the // beginning and initialized with the values passed through arguments. The // new alloca replaces the use of the old pointer argument. Attributor::ArgumentReplacementInfo::CalleeRepairCBTy FnRepairCB = [=](const Attributor::ArgumentReplacementInfo &ARI, Function &ReplacementFn, Function::arg_iterator ArgIt) { BasicBlock &EntryBB = ReplacementFn.getEntryBlock(); Instruction *IP = &*EntryBB.getFirstInsertionPt(); const DataLayout &DL = IP->getModule()->getDataLayout(); unsigned AS = DL.getAllocaAddrSpace(); Instruction *AI = new AllocaInst(PrivatizableType.value(), AS, Arg->getName() + ".priv", IP); createInitialization(PrivatizableType.value(), *AI, ReplacementFn, ArgIt->getArgNo(), *IP); if (AI->getType() != Arg->getType()) AI = BitCastInst::CreatePointerBitCastOrAddrSpaceCast( AI, Arg->getType(), "", IP); Arg->replaceAllUsesWith(AI); for (CallInst *CI : TailCalls) CI->setTailCall(false); }; // Callback to repair a call site of the associated function. The elements // of the privatizable type are loaded prior to the call and passed to the // new function version. Attributor::ArgumentReplacementInfo::ACSRepairCBTy ACSRepairCB = [=, &AlignAA](const Attributor::ArgumentReplacementInfo &ARI, AbstractCallSite ACS, SmallVectorImpl &NewArgOperands) { // When no alignment is specified for the load instruction, // natural alignment is assumed. createReplacementValues( AlignAA.getAssumedAlign(), *PrivatizableType, ACS, ACS.getCallArgOperand(ARI.getReplacedArg().getArgNo()), NewArgOperands); }; // Collect the types that will replace the privatizable type in the function // signature. SmallVector ReplacementTypes; identifyReplacementTypes(*PrivatizableType, ReplacementTypes); // Register a rewrite of the argument. if (A.registerFunctionSignatureRewrite(*Arg, ReplacementTypes, std::move(FnRepairCB), std::move(ACSRepairCB))) return ChangeStatus::CHANGED; return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(privatizable_ptr); } }; struct AAPrivatizablePtrFloating : public AAPrivatizablePtrImpl { AAPrivatizablePtrFloating(const IRPosition &IRP, Attributor &A) : AAPrivatizablePtrImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { // TODO: We can privatize more than arguments. indicatePessimisticFixpoint(); } ChangeStatus updateImpl(Attributor &A) override { llvm_unreachable("AAPrivatizablePtr(Floating|Returned|CallSiteReturned)::" "updateImpl will not be called"); } /// See AAPrivatizablePtrImpl::identifyPrivatizableType(...) Optional identifyPrivatizableType(Attributor &A) override { Value *Obj = getUnderlyingObject(&getAssociatedValue()); if (!Obj) { LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] No underlying object found!\n"); return nullptr; } if (auto *AI = dyn_cast(Obj)) if (auto *CI = dyn_cast(AI->getArraySize())) if (CI->isOne()) return AI->getAllocatedType(); if (auto *Arg = dyn_cast(Obj)) { auto &PrivArgAA = A.getAAFor( *this, IRPosition::argument(*Arg), DepClassTy::REQUIRED); if (PrivArgAA.isAssumedPrivatizablePtr()) return PrivArgAA.getPrivatizableType(); } LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] Underlying object neither valid " "alloca nor privatizable argument: " << *Obj << "!\n"); return nullptr; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(privatizable_ptr); } }; struct AAPrivatizablePtrCallSiteArgument final : public AAPrivatizablePtrFloating { AAPrivatizablePtrCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAPrivatizablePtrFloating(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { if (getIRPosition().hasAttr(Attribute::ByVal)) indicateOptimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { PrivatizableType = identifyPrivatizableType(A); if (!PrivatizableType) return ChangeStatus::UNCHANGED; if (!PrivatizableType.value()) return indicatePessimisticFixpoint(); const IRPosition &IRP = getIRPosition(); auto &NoCaptureAA = A.getAAFor(*this, IRP, DepClassTy::REQUIRED); if (!NoCaptureAA.isAssumedNoCapture()) { LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] pointer might be captured!\n"); return indicatePessimisticFixpoint(); } auto &NoAliasAA = A.getAAFor(*this, IRP, DepClassTy::REQUIRED); if (!NoAliasAA.isAssumedNoAlias()) { LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] pointer might alias!\n"); return indicatePessimisticFixpoint(); } bool IsKnown; if (!AA::isAssumedReadOnly(A, IRP, *this, IsKnown)) { LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] pointer is written!\n"); return indicatePessimisticFixpoint(); } return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(privatizable_ptr); } }; struct AAPrivatizablePtrCallSiteReturned final : public AAPrivatizablePtrFloating { AAPrivatizablePtrCallSiteReturned(const IRPosition &IRP, Attributor &A) : AAPrivatizablePtrFloating(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { // TODO: We can privatize more than arguments. indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(privatizable_ptr); } }; struct AAPrivatizablePtrReturned final : public AAPrivatizablePtrFloating { AAPrivatizablePtrReturned(const IRPosition &IRP, Attributor &A) : AAPrivatizablePtrFloating(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { // TODO: We can privatize more than arguments. indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(privatizable_ptr); } }; } // namespace /// -------------------- Memory Behavior Attributes ---------------------------- /// Includes read-none, read-only, and write-only. /// ---------------------------------------------------------------------------- namespace { struct AAMemoryBehaviorImpl : public AAMemoryBehavior { AAMemoryBehaviorImpl(const IRPosition &IRP, Attributor &A) : AAMemoryBehavior(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { intersectAssumedBits(BEST_STATE); getKnownStateFromValue(getIRPosition(), getState()); AAMemoryBehavior::initialize(A); } /// Return the memory behavior information encoded in the IR for \p IRP. static void getKnownStateFromValue(const IRPosition &IRP, BitIntegerState &State, bool IgnoreSubsumingPositions = false) { SmallVector Attrs; IRP.getAttrs(AttrKinds, Attrs, IgnoreSubsumingPositions); for (const Attribute &Attr : Attrs) { switch (Attr.getKindAsEnum()) { case Attribute::ReadNone: State.addKnownBits(NO_ACCESSES); break; case Attribute::ReadOnly: State.addKnownBits(NO_WRITES); break; case Attribute::WriteOnly: State.addKnownBits(NO_READS); break; default: llvm_unreachable("Unexpected attribute!"); } } if (auto *I = dyn_cast(&IRP.getAnchorValue())) { if (!I->mayReadFromMemory()) State.addKnownBits(NO_READS); if (!I->mayWriteToMemory()) State.addKnownBits(NO_WRITES); } } /// See AbstractAttribute::getDeducedAttributes(...). void getDeducedAttributes(LLVMContext &Ctx, SmallVectorImpl &Attrs) const override { assert(Attrs.size() == 0); if (isAssumedReadNone()) Attrs.push_back(Attribute::get(Ctx, Attribute::ReadNone)); else if (isAssumedReadOnly()) Attrs.push_back(Attribute::get(Ctx, Attribute::ReadOnly)); else if (isAssumedWriteOnly()) Attrs.push_back(Attribute::get(Ctx, Attribute::WriteOnly)); assert(Attrs.size() <= 1); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { if (hasAttr(Attribute::ReadNone, /* IgnoreSubsumingPositions */ true)) return ChangeStatus::UNCHANGED; const IRPosition &IRP = getIRPosition(); // Check if we would improve the existing attributes first. SmallVector DeducedAttrs; getDeducedAttributes(IRP.getAnchorValue().getContext(), DeducedAttrs); if (llvm::all_of(DeducedAttrs, [&](const Attribute &Attr) { return IRP.hasAttr(Attr.getKindAsEnum(), /* IgnoreSubsumingPositions */ true); })) return ChangeStatus::UNCHANGED; // Clear existing attributes. IRP.removeAttrs(AttrKinds); // Use the generic manifest method. return IRAttribute::manifest(A); } /// See AbstractState::getAsStr(). const std::string getAsStr() const override { if (isAssumedReadNone()) return "readnone"; if (isAssumedReadOnly()) return "readonly"; if (isAssumedWriteOnly()) return "writeonly"; return "may-read/write"; } /// The set of IR attributes AAMemoryBehavior deals with. static const Attribute::AttrKind AttrKinds[3]; }; const Attribute::AttrKind AAMemoryBehaviorImpl::AttrKinds[] = { Attribute::ReadNone, Attribute::ReadOnly, Attribute::WriteOnly}; /// Memory behavior attribute for a floating value. struct AAMemoryBehaviorFloating : AAMemoryBehaviorImpl { AAMemoryBehaviorFloating(const IRPosition &IRP, Attributor &A) : AAMemoryBehaviorImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override; /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { if (isAssumedReadNone()) STATS_DECLTRACK_FLOATING_ATTR(readnone) else if (isAssumedReadOnly()) STATS_DECLTRACK_FLOATING_ATTR(readonly) else if (isAssumedWriteOnly()) STATS_DECLTRACK_FLOATING_ATTR(writeonly) } private: /// Return true if users of \p UserI might access the underlying /// variable/location described by \p U and should therefore be analyzed. bool followUsersOfUseIn(Attributor &A, const Use &U, const Instruction *UserI); /// Update the state according to the effect of use \p U in \p UserI. void analyzeUseIn(Attributor &A, const Use &U, const Instruction *UserI); }; /// Memory behavior attribute for function argument. struct AAMemoryBehaviorArgument : AAMemoryBehaviorFloating { AAMemoryBehaviorArgument(const IRPosition &IRP, Attributor &A) : AAMemoryBehaviorFloating(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { intersectAssumedBits(BEST_STATE); const IRPosition &IRP = getIRPosition(); // TODO: Make IgnoreSubsumingPositions a property of an IRAttribute so we // can query it when we use has/getAttr. That would allow us to reuse the // initialize of the base class here. bool HasByVal = IRP.hasAttr({Attribute::ByVal}, /* IgnoreSubsumingPositions */ true); getKnownStateFromValue(IRP, getState(), /* IgnoreSubsumingPositions */ HasByVal); // Initialize the use vector with all direct uses of the associated value. Argument *Arg = getAssociatedArgument(); if (!Arg || !A.isFunctionIPOAmendable(*(Arg->getParent()))) indicatePessimisticFixpoint(); } ChangeStatus manifest(Attributor &A) override { // TODO: Pointer arguments are not supported on vectors of pointers yet. if (!getAssociatedValue().getType()->isPointerTy()) return ChangeStatus::UNCHANGED; // TODO: From readattrs.ll: "inalloca parameters are always // considered written" if (hasAttr({Attribute::InAlloca, Attribute::Preallocated})) { removeKnownBits(NO_WRITES); removeAssumedBits(NO_WRITES); } return AAMemoryBehaviorFloating::manifest(A); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { if (isAssumedReadNone()) STATS_DECLTRACK_ARG_ATTR(readnone) else if (isAssumedReadOnly()) STATS_DECLTRACK_ARG_ATTR(readonly) else if (isAssumedWriteOnly()) STATS_DECLTRACK_ARG_ATTR(writeonly) } }; struct AAMemoryBehaviorCallSiteArgument final : AAMemoryBehaviorArgument { AAMemoryBehaviorCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAMemoryBehaviorArgument(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { // If we don't have an associated attribute this is either a variadic call // or an indirect call, either way, nothing to do here. Argument *Arg = getAssociatedArgument(); if (!Arg) { indicatePessimisticFixpoint(); return; } if (Arg->hasByValAttr()) { addKnownBits(NO_WRITES); removeKnownBits(NO_READS); removeAssumedBits(NO_READS); } AAMemoryBehaviorArgument::initialize(A); if (getAssociatedFunction()->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Argument *Arg = getAssociatedArgument(); const IRPosition &ArgPos = IRPosition::argument(*Arg); auto &ArgAA = A.getAAFor(*this, ArgPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), ArgAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { if (isAssumedReadNone()) STATS_DECLTRACK_CSARG_ATTR(readnone) else if (isAssumedReadOnly()) STATS_DECLTRACK_CSARG_ATTR(readonly) else if (isAssumedWriteOnly()) STATS_DECLTRACK_CSARG_ATTR(writeonly) } }; /// Memory behavior attribute for a call site return position. struct AAMemoryBehaviorCallSiteReturned final : AAMemoryBehaviorFloating { AAMemoryBehaviorCallSiteReturned(const IRPosition &IRP, Attributor &A) : AAMemoryBehaviorFloating(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAMemoryBehaviorImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { // We do not annotate returned values. return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override {} }; /// An AA to represent the memory behavior function attributes. struct AAMemoryBehaviorFunction final : public AAMemoryBehaviorImpl { AAMemoryBehaviorFunction(const IRPosition &IRP, Attributor &A) : AAMemoryBehaviorImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(Attributor &A). ChangeStatus updateImpl(Attributor &A) override; /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { Function &F = cast(getAnchorValue()); if (isAssumedReadNone()) { F.removeFnAttr(Attribute::ArgMemOnly); F.removeFnAttr(Attribute::InaccessibleMemOnly); F.removeFnAttr(Attribute::InaccessibleMemOrArgMemOnly); } return AAMemoryBehaviorImpl::manifest(A); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { if (isAssumedReadNone()) STATS_DECLTRACK_FN_ATTR(readnone) else if (isAssumedReadOnly()) STATS_DECLTRACK_FN_ATTR(readonly) else if (isAssumedWriteOnly()) STATS_DECLTRACK_FN_ATTR(writeonly) } }; /// AAMemoryBehavior attribute for call sites. struct AAMemoryBehaviorCallSite final : AAMemoryBehaviorImpl { AAMemoryBehaviorCallSite(const IRPosition &IRP, Attributor &A) : AAMemoryBehaviorImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAMemoryBehaviorImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Function *F = getAssociatedFunction(); const IRPosition &FnPos = IRPosition::function(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); return clampStateAndIndicateChange(getState(), FnAA.getState()); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { if (isAssumedReadNone()) STATS_DECLTRACK_CS_ATTR(readnone) else if (isAssumedReadOnly()) STATS_DECLTRACK_CS_ATTR(readonly) else if (isAssumedWriteOnly()) STATS_DECLTRACK_CS_ATTR(writeonly) } }; ChangeStatus AAMemoryBehaviorFunction::updateImpl(Attributor &A) { // The current assumed state used to determine a change. auto AssumedState = getAssumed(); auto CheckRWInst = [&](Instruction &I) { // If the instruction has an own memory behavior state, use it to restrict // the local state. No further analysis is required as the other memory // state is as optimistic as it gets. if (const auto *CB = dyn_cast(&I)) { const auto &MemBehaviorAA = A.getAAFor( *this, IRPosition::callsite_function(*CB), DepClassTy::REQUIRED); intersectAssumedBits(MemBehaviorAA.getAssumed()); return !isAtFixpoint(); } // Remove access kind modifiers if necessary. if (I.mayReadFromMemory()) removeAssumedBits(NO_READS); if (I.mayWriteToMemory()) removeAssumedBits(NO_WRITES); return !isAtFixpoint(); }; bool UsedAssumedInformation = false; if (!A.checkForAllReadWriteInstructions(CheckRWInst, *this, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return (AssumedState != getAssumed()) ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } ChangeStatus AAMemoryBehaviorFloating::updateImpl(Attributor &A) { const IRPosition &IRP = getIRPosition(); const IRPosition &FnPos = IRPosition::function_scope(IRP); AAMemoryBehavior::StateType &S = getState(); // First, check the function scope. We take the known information and we avoid // work if the assumed information implies the current assumed information for // this attribute. This is a valid for all but byval arguments. Argument *Arg = IRP.getAssociatedArgument(); AAMemoryBehavior::base_t FnMemAssumedState = AAMemoryBehavior::StateType::getWorstState(); if (!Arg || !Arg->hasByValAttr()) { const auto &FnMemAA = A.getAAFor(*this, FnPos, DepClassTy::OPTIONAL); FnMemAssumedState = FnMemAA.getAssumed(); S.addKnownBits(FnMemAA.getKnown()); if ((S.getAssumed() & FnMemAA.getAssumed()) == S.getAssumed()) return ChangeStatus::UNCHANGED; } // The current assumed state used to determine a change. auto AssumedState = S.getAssumed(); // Make sure the value is not captured (except through "return"), if // it is, any information derived would be irrelevant anyway as we cannot // check the potential aliases introduced by the capture. However, no need // to fall back to anythign less optimistic than the function state. const auto &ArgNoCaptureAA = A.getAAFor(*this, IRP, DepClassTy::OPTIONAL); if (!ArgNoCaptureAA.isAssumedNoCaptureMaybeReturned()) { S.intersectAssumedBits(FnMemAssumedState); return (AssumedState != getAssumed()) ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } // Visit and expand uses until all are analyzed or a fixpoint is reached. auto UsePred = [&](const Use &U, bool &Follow) -> bool { Instruction *UserI = cast(U.getUser()); LLVM_DEBUG(dbgs() << "[AAMemoryBehavior] Use: " << *U << " in " << *UserI << " \n"); // Droppable users, e.g., llvm::assume does not actually perform any action. if (UserI->isDroppable()) return true; // Check if the users of UserI should also be visited. Follow = followUsersOfUseIn(A, U, UserI); // If UserI might touch memory we analyze the use in detail. if (UserI->mayReadOrWriteMemory()) analyzeUseIn(A, U, UserI); return !isAtFixpoint(); }; if (!A.checkForAllUses(UsePred, *this, getAssociatedValue())) return indicatePessimisticFixpoint(); return (AssumedState != getAssumed()) ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } bool AAMemoryBehaviorFloating::followUsersOfUseIn(Attributor &A, const Use &U, const Instruction *UserI) { // The loaded value is unrelated to the pointer argument, no need to // follow the users of the load. if (isa(UserI) || isa(UserI)) return false; // By default we follow all uses assuming UserI might leak information on U, // we have special handling for call sites operands though. const auto *CB = dyn_cast(UserI); if (!CB || !CB->isArgOperand(&U)) return true; // If the use is a call argument known not to be captured, the users of // the call do not need to be visited because they have to be unrelated to // the input. Note that this check is not trivial even though we disallow // general capturing of the underlying argument. The reason is that the // call might the argument "through return", which we allow and for which we // need to check call users. if (U.get()->getType()->isPointerTy()) { unsigned ArgNo = CB->getArgOperandNo(&U); const auto &ArgNoCaptureAA = A.getAAFor( *this, IRPosition::callsite_argument(*CB, ArgNo), DepClassTy::OPTIONAL); return !ArgNoCaptureAA.isAssumedNoCapture(); } return true; } void AAMemoryBehaviorFloating::analyzeUseIn(Attributor &A, const Use &U, const Instruction *UserI) { assert(UserI->mayReadOrWriteMemory()); switch (UserI->getOpcode()) { default: // TODO: Handle all atomics and other side-effect operations we know of. break; case Instruction::Load: // Loads cause the NO_READS property to disappear. removeAssumedBits(NO_READS); return; case Instruction::Store: // Stores cause the NO_WRITES property to disappear if the use is the // pointer operand. Note that while capturing was taken care of somewhere // else we need to deal with stores of the value that is not looked through. if (cast(UserI)->getPointerOperand() == U.get()) removeAssumedBits(NO_WRITES); else indicatePessimisticFixpoint(); return; case Instruction::Call: case Instruction::CallBr: case Instruction::Invoke: { // For call sites we look at the argument memory behavior attribute (this // could be recursive!) in order to restrict our own state. const auto *CB = cast(UserI); // Give up on operand bundles. if (CB->isBundleOperand(&U)) { indicatePessimisticFixpoint(); return; } // Calling a function does read the function pointer, maybe write it if the // function is self-modifying. if (CB->isCallee(&U)) { removeAssumedBits(NO_READS); break; } // Adjust the possible access behavior based on the information on the // argument. IRPosition Pos; if (U.get()->getType()->isPointerTy()) Pos = IRPosition::callsite_argument(*CB, CB->getArgOperandNo(&U)); else Pos = IRPosition::callsite_function(*CB); const auto &MemBehaviorAA = A.getAAFor(*this, Pos, DepClassTy::OPTIONAL); // "assumed" has at most the same bits as the MemBehaviorAA assumed // and at least "known". intersectAssumedBits(MemBehaviorAA.getAssumed()); return; } }; // Generally, look at the "may-properties" and adjust the assumed state if we // did not trigger special handling before. if (UserI->mayReadFromMemory()) removeAssumedBits(NO_READS); if (UserI->mayWriteToMemory()) removeAssumedBits(NO_WRITES); } } // namespace /// -------------------- Memory Locations Attributes --------------------------- /// Includes read-none, argmemonly, inaccessiblememonly, /// inaccessiblememorargmemonly /// ---------------------------------------------------------------------------- std::string AAMemoryLocation::getMemoryLocationsAsStr( AAMemoryLocation::MemoryLocationsKind MLK) { if (0 == (MLK & AAMemoryLocation::NO_LOCATIONS)) return "all memory"; if (MLK == AAMemoryLocation::NO_LOCATIONS) return "no memory"; std::string S = "memory:"; if (0 == (MLK & AAMemoryLocation::NO_LOCAL_MEM)) S += "stack,"; if (0 == (MLK & AAMemoryLocation::NO_CONST_MEM)) S += "constant,"; if (0 == (MLK & AAMemoryLocation::NO_GLOBAL_INTERNAL_MEM)) S += "internal global,"; if (0 == (MLK & AAMemoryLocation::NO_GLOBAL_EXTERNAL_MEM)) S += "external global,"; if (0 == (MLK & AAMemoryLocation::NO_ARGUMENT_MEM)) S += "argument,"; if (0 == (MLK & AAMemoryLocation::NO_INACCESSIBLE_MEM)) S += "inaccessible,"; if (0 == (MLK & AAMemoryLocation::NO_MALLOCED_MEM)) S += "malloced,"; if (0 == (MLK & AAMemoryLocation::NO_UNKOWN_MEM)) S += "unknown,"; S.pop_back(); return S; } namespace { struct AAMemoryLocationImpl : public AAMemoryLocation { AAMemoryLocationImpl(const IRPosition &IRP, Attributor &A) : AAMemoryLocation(IRP, A), Allocator(A.Allocator) { AccessKind2Accesses.fill(nullptr); } ~AAMemoryLocationImpl() { // The AccessSets are allocated via a BumpPtrAllocator, we call // the destructor manually. for (AccessSet *AS : AccessKind2Accesses) if (AS) AS->~AccessSet(); } /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { intersectAssumedBits(BEST_STATE); getKnownStateFromValue(A, getIRPosition(), getState()); AAMemoryLocation::initialize(A); } /// Return the memory behavior information encoded in the IR for \p IRP. static void getKnownStateFromValue(Attributor &A, const IRPosition &IRP, BitIntegerState &State, bool IgnoreSubsumingPositions = false) { // For internal functions we ignore `argmemonly` and // `inaccessiblememorargmemonly` as we might break it via interprocedural // constant propagation. It is unclear if this is the best way but it is // unlikely this will cause real performance problems. If we are deriving // attributes for the anchor function we even remove the attribute in // addition to ignoring it. bool UseArgMemOnly = true; Function *AnchorFn = IRP.getAnchorScope(); if (AnchorFn && A.isRunOn(*AnchorFn)) UseArgMemOnly = !AnchorFn->hasLocalLinkage(); SmallVector Attrs; IRP.getAttrs(AttrKinds, Attrs, IgnoreSubsumingPositions); for (const Attribute &Attr : Attrs) { switch (Attr.getKindAsEnum()) { case Attribute::ReadNone: State.addKnownBits(NO_LOCAL_MEM | NO_CONST_MEM); break; case Attribute::InaccessibleMemOnly: State.addKnownBits(inverseLocation(NO_INACCESSIBLE_MEM, true, true)); break; case Attribute::ArgMemOnly: if (UseArgMemOnly) State.addKnownBits(inverseLocation(NO_ARGUMENT_MEM, true, true)); else IRP.removeAttrs({Attribute::ArgMemOnly}); break; case Attribute::InaccessibleMemOrArgMemOnly: if (UseArgMemOnly) State.addKnownBits(inverseLocation( NO_INACCESSIBLE_MEM | NO_ARGUMENT_MEM, true, true)); else IRP.removeAttrs({Attribute::InaccessibleMemOrArgMemOnly}); break; default: llvm_unreachable("Unexpected attribute!"); } } } /// See AbstractAttribute::getDeducedAttributes(...). void getDeducedAttributes(LLVMContext &Ctx, SmallVectorImpl &Attrs) const override { assert(Attrs.size() == 0); if (isAssumedReadNone()) { Attrs.push_back(Attribute::get(Ctx, Attribute::ReadNone)); } else if (getIRPosition().getPositionKind() == IRPosition::IRP_FUNCTION) { if (isAssumedInaccessibleMemOnly()) Attrs.push_back(Attribute::get(Ctx, Attribute::InaccessibleMemOnly)); else if (isAssumedArgMemOnly()) Attrs.push_back(Attribute::get(Ctx, Attribute::ArgMemOnly)); else if (isAssumedInaccessibleOrArgMemOnly()) Attrs.push_back( Attribute::get(Ctx, Attribute::InaccessibleMemOrArgMemOnly)); } assert(Attrs.size() <= 1); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { const IRPosition &IRP = getIRPosition(); // Check if we would improve the existing attributes first. SmallVector DeducedAttrs; getDeducedAttributes(IRP.getAnchorValue().getContext(), DeducedAttrs); if (llvm::all_of(DeducedAttrs, [&](const Attribute &Attr) { return IRP.hasAttr(Attr.getKindAsEnum(), /* IgnoreSubsumingPositions */ true); })) return ChangeStatus::UNCHANGED; // Clear existing attributes. IRP.removeAttrs(AttrKinds); if (isAssumedReadNone()) IRP.removeAttrs(AAMemoryBehaviorImpl::AttrKinds); // Use the generic manifest method. return IRAttribute::manifest(A); } /// See AAMemoryLocation::checkForAllAccessesToMemoryKind(...). bool checkForAllAccessesToMemoryKind( function_ref Pred, MemoryLocationsKind RequestedMLK) const override { if (!isValidState()) return false; MemoryLocationsKind AssumedMLK = getAssumedNotAccessedLocation(); if (AssumedMLK == NO_LOCATIONS) return true; unsigned Idx = 0; for (MemoryLocationsKind CurMLK = 1; CurMLK < NO_LOCATIONS; CurMLK *= 2, ++Idx) { if (CurMLK & RequestedMLK) continue; if (const AccessSet *Accesses = AccessKind2Accesses[Idx]) for (const AccessInfo &AI : *Accesses) if (!Pred(AI.I, AI.Ptr, AI.Kind, CurMLK)) return false; } return true; } ChangeStatus indicatePessimisticFixpoint() override { // If we give up and indicate a pessimistic fixpoint this instruction will // become an access for all potential access kinds: // TODO: Add pointers for argmemonly and globals to improve the results of // checkForAllAccessesToMemoryKind. bool Changed = false; MemoryLocationsKind KnownMLK = getKnown(); Instruction *I = dyn_cast(&getAssociatedValue()); for (MemoryLocationsKind CurMLK = 1; CurMLK < NO_LOCATIONS; CurMLK *= 2) if (!(CurMLK & KnownMLK)) updateStateAndAccessesMap(getState(), CurMLK, I, nullptr, Changed, getAccessKindFromInst(I)); return AAMemoryLocation::indicatePessimisticFixpoint(); } protected: /// Helper struct to tie together an instruction that has a read or write /// effect with the pointer it accesses (if any). struct AccessInfo { /// The instruction that caused the access. const Instruction *I; /// The base pointer that is accessed, or null if unknown. const Value *Ptr; /// The kind of access (read/write/read+write). AccessKind Kind; bool operator==(const AccessInfo &RHS) const { return I == RHS.I && Ptr == RHS.Ptr && Kind == RHS.Kind; } bool operator()(const AccessInfo &LHS, const AccessInfo &RHS) const { if (LHS.I != RHS.I) return LHS.I < RHS.I; if (LHS.Ptr != RHS.Ptr) return LHS.Ptr < RHS.Ptr; if (LHS.Kind != RHS.Kind) return LHS.Kind < RHS.Kind; return false; } }; /// Mapping from *single* memory location kinds, e.g., LOCAL_MEM with the /// value of NO_LOCAL_MEM, to the accesses encountered for this memory kind. using AccessSet = SmallSet; std::array()> AccessKind2Accesses; /// Categorize the pointer arguments of CB that might access memory in /// AccessedLoc and update the state and access map accordingly. void categorizeArgumentPointerLocations(Attributor &A, CallBase &CB, AAMemoryLocation::StateType &AccessedLocs, bool &Changed); /// Return the kind(s) of location that may be accessed by \p V. AAMemoryLocation::MemoryLocationsKind categorizeAccessedLocations(Attributor &A, Instruction &I, bool &Changed); /// Return the access kind as determined by \p I. AccessKind getAccessKindFromInst(const Instruction *I) { AccessKind AK = READ_WRITE; if (I) { AK = I->mayReadFromMemory() ? READ : NONE; AK = AccessKind(AK | (I->mayWriteToMemory() ? WRITE : NONE)); } return AK; } /// Update the state \p State and the AccessKind2Accesses given that \p I is /// an access of kind \p AK to a \p MLK memory location with the access /// pointer \p Ptr. void updateStateAndAccessesMap(AAMemoryLocation::StateType &State, MemoryLocationsKind MLK, const Instruction *I, const Value *Ptr, bool &Changed, AccessKind AK = READ_WRITE) { assert(isPowerOf2_32(MLK) && "Expected a single location set!"); auto *&Accesses = AccessKind2Accesses[llvm::Log2_32(MLK)]; if (!Accesses) Accesses = new (Allocator) AccessSet(); Changed |= Accesses->insert(AccessInfo{I, Ptr, AK}).second; State.removeAssumedBits(MLK); } /// Determine the underlying locations kinds for \p Ptr, e.g., globals or /// arguments, and update the state and access map accordingly. void categorizePtrValue(Attributor &A, const Instruction &I, const Value &Ptr, AAMemoryLocation::StateType &State, bool &Changed); /// Used to allocate access sets. BumpPtrAllocator &Allocator; /// The set of IR attributes AAMemoryLocation deals with. static const Attribute::AttrKind AttrKinds[4]; }; const Attribute::AttrKind AAMemoryLocationImpl::AttrKinds[] = { Attribute::ReadNone, Attribute::InaccessibleMemOnly, Attribute::ArgMemOnly, Attribute::InaccessibleMemOrArgMemOnly}; void AAMemoryLocationImpl::categorizePtrValue( Attributor &A, const Instruction &I, const Value &Ptr, AAMemoryLocation::StateType &State, bool &Changed) { LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Categorize pointer locations for " << Ptr << " [" << getMemoryLocationsAsStr(State.getAssumed()) << "]\n"); SmallSetVector Objects; bool UsedAssumedInformation = false; if (!AA::getAssumedUnderlyingObjects(A, Ptr, Objects, *this, &I, UsedAssumedInformation, AA::Intraprocedural)) { LLVM_DEBUG( dbgs() << "[AAMemoryLocation] Pointer locations not categorized\n"); updateStateAndAccessesMap(State, NO_UNKOWN_MEM, &I, nullptr, Changed, getAccessKindFromInst(&I)); return; } for (Value *Obj : Objects) { // TODO: recognize the TBAA used for constant accesses. MemoryLocationsKind MLK = NO_LOCATIONS; if (isa(Obj)) continue; if (isa(Obj)) { // TODO: For now we do not treat byval arguments as local copies performed // on the call edge, though, we should. To make that happen we need to // teach various passes, e.g., DSE, about the copy effect of a byval. That // would also allow us to mark functions only accessing byval arguments as // readnone again, atguably their acceses have no effect outside of the // function, like accesses to allocas. MLK = NO_ARGUMENT_MEM; } else if (auto *GV = dyn_cast(Obj)) { // Reading constant memory is not treated as a read "effect" by the // function attr pass so we won't neither. Constants defined by TBAA are // similar. (We know we do not write it because it is constant.) if (auto *GVar = dyn_cast(GV)) if (GVar->isConstant()) continue; if (GV->hasLocalLinkage()) MLK = NO_GLOBAL_INTERNAL_MEM; else MLK = NO_GLOBAL_EXTERNAL_MEM; } else if (isa(Obj) && !NullPointerIsDefined(getAssociatedFunction(), Ptr.getType()->getPointerAddressSpace())) { continue; } else if (isa(Obj)) { MLK = NO_LOCAL_MEM; } else if (const auto *CB = dyn_cast(Obj)) { const auto &NoAliasAA = A.getAAFor( *this, IRPosition::callsite_returned(*CB), DepClassTy::OPTIONAL); if (NoAliasAA.isAssumedNoAlias()) MLK = NO_MALLOCED_MEM; else MLK = NO_UNKOWN_MEM; } else { MLK = NO_UNKOWN_MEM; } assert(MLK != NO_LOCATIONS && "No location specified!"); LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Ptr value can be categorized: " << *Obj << " -> " << getMemoryLocationsAsStr(MLK) << "\n"); updateStateAndAccessesMap(getState(), MLK, &I, Obj, Changed, getAccessKindFromInst(&I)); } LLVM_DEBUG( dbgs() << "[AAMemoryLocation] Accessed locations with pointer locations: " << getMemoryLocationsAsStr(State.getAssumed()) << "\n"); } void AAMemoryLocationImpl::categorizeArgumentPointerLocations( Attributor &A, CallBase &CB, AAMemoryLocation::StateType &AccessedLocs, bool &Changed) { for (unsigned ArgNo = 0, E = CB.arg_size(); ArgNo < E; ++ArgNo) { // Skip non-pointer arguments. const Value *ArgOp = CB.getArgOperand(ArgNo); if (!ArgOp->getType()->isPtrOrPtrVectorTy()) continue; // Skip readnone arguments. const IRPosition &ArgOpIRP = IRPosition::callsite_argument(CB, ArgNo); const auto &ArgOpMemLocationAA = A.getAAFor(*this, ArgOpIRP, DepClassTy::OPTIONAL); if (ArgOpMemLocationAA.isAssumedReadNone()) continue; // Categorize potentially accessed pointer arguments as if there was an // access instruction with them as pointer. categorizePtrValue(A, CB, *ArgOp, AccessedLocs, Changed); } } AAMemoryLocation::MemoryLocationsKind AAMemoryLocationImpl::categorizeAccessedLocations(Attributor &A, Instruction &I, bool &Changed) { LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Categorize accessed locations for " << I << "\n"); AAMemoryLocation::StateType AccessedLocs; AccessedLocs.intersectAssumedBits(NO_LOCATIONS); if (auto *CB = dyn_cast(&I)) { // First check if we assume any memory is access is visible. const auto &CBMemLocationAA = A.getAAFor( *this, IRPosition::callsite_function(*CB), DepClassTy::OPTIONAL); LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Categorize call site: " << I << " [" << CBMemLocationAA << "]\n"); if (CBMemLocationAA.isAssumedReadNone()) return NO_LOCATIONS; if (CBMemLocationAA.isAssumedInaccessibleMemOnly()) { updateStateAndAccessesMap(AccessedLocs, NO_INACCESSIBLE_MEM, &I, nullptr, Changed, getAccessKindFromInst(&I)); return AccessedLocs.getAssumed(); } uint32_t CBAssumedNotAccessedLocs = CBMemLocationAA.getAssumedNotAccessedLocation(); // Set the argmemonly and global bit as we handle them separately below. uint32_t CBAssumedNotAccessedLocsNoArgMem = CBAssumedNotAccessedLocs | NO_ARGUMENT_MEM | NO_GLOBAL_MEM; for (MemoryLocationsKind CurMLK = 1; CurMLK < NO_LOCATIONS; CurMLK *= 2) { if (CBAssumedNotAccessedLocsNoArgMem & CurMLK) continue; updateStateAndAccessesMap(AccessedLocs, CurMLK, &I, nullptr, Changed, getAccessKindFromInst(&I)); } // Now handle global memory if it might be accessed. This is slightly tricky // as NO_GLOBAL_MEM has multiple bits set. bool HasGlobalAccesses = ((~CBAssumedNotAccessedLocs) & NO_GLOBAL_MEM); if (HasGlobalAccesses) { auto AccessPred = [&](const Instruction *, const Value *Ptr, AccessKind Kind, MemoryLocationsKind MLK) { updateStateAndAccessesMap(AccessedLocs, MLK, &I, Ptr, Changed, getAccessKindFromInst(&I)); return true; }; if (!CBMemLocationAA.checkForAllAccessesToMemoryKind( AccessPred, inverseLocation(NO_GLOBAL_MEM, false, false))) return AccessedLocs.getWorstState(); } LLVM_DEBUG( dbgs() << "[AAMemoryLocation] Accessed state before argument handling: " << getMemoryLocationsAsStr(AccessedLocs.getAssumed()) << "\n"); // Now handle argument memory if it might be accessed. bool HasArgAccesses = ((~CBAssumedNotAccessedLocs) & NO_ARGUMENT_MEM); if (HasArgAccesses) categorizeArgumentPointerLocations(A, *CB, AccessedLocs, Changed); LLVM_DEBUG( dbgs() << "[AAMemoryLocation] Accessed state after argument handling: " << getMemoryLocationsAsStr(AccessedLocs.getAssumed()) << "\n"); return AccessedLocs.getAssumed(); } if (const Value *Ptr = getPointerOperand(&I, /* AllowVolatile */ true)) { LLVM_DEBUG( dbgs() << "[AAMemoryLocation] Categorize memory access with pointer: " << I << " [" << *Ptr << "]\n"); categorizePtrValue(A, I, *Ptr, AccessedLocs, Changed); return AccessedLocs.getAssumed(); } LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Failed to categorize instruction: " << I << "\n"); updateStateAndAccessesMap(AccessedLocs, NO_UNKOWN_MEM, &I, nullptr, Changed, getAccessKindFromInst(&I)); return AccessedLocs.getAssumed(); } /// An AA to represent the memory behavior function attributes. struct AAMemoryLocationFunction final : public AAMemoryLocationImpl { AAMemoryLocationFunction(const IRPosition &IRP, Attributor &A) : AAMemoryLocationImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(Attributor &A). ChangeStatus updateImpl(Attributor &A) override { const auto &MemBehaviorAA = A.getAAFor(*this, getIRPosition(), DepClassTy::NONE); if (MemBehaviorAA.isAssumedReadNone()) { if (MemBehaviorAA.isKnownReadNone()) return indicateOptimisticFixpoint(); assert(isAssumedReadNone() && "AAMemoryLocation was not read-none but AAMemoryBehavior was!"); A.recordDependence(MemBehaviorAA, *this, DepClassTy::OPTIONAL); return ChangeStatus::UNCHANGED; } // The current assumed state used to determine a change. auto AssumedState = getAssumed(); bool Changed = false; auto CheckRWInst = [&](Instruction &I) { MemoryLocationsKind MLK = categorizeAccessedLocations(A, I, Changed); LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Accessed locations for " << I << ": " << getMemoryLocationsAsStr(MLK) << "\n"); removeAssumedBits(inverseLocation(MLK, false, false)); // Stop once only the valid bit set in the *not assumed location*, thus // once we don't actually exclude any memory locations in the state. return getAssumedNotAccessedLocation() != VALID_STATE; }; bool UsedAssumedInformation = false; if (!A.checkForAllReadWriteInstructions(CheckRWInst, *this, UsedAssumedInformation)) return indicatePessimisticFixpoint(); Changed |= AssumedState != getAssumed(); return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { if (isAssumedReadNone()) STATS_DECLTRACK_FN_ATTR(readnone) else if (isAssumedArgMemOnly()) STATS_DECLTRACK_FN_ATTR(argmemonly) else if (isAssumedInaccessibleMemOnly()) STATS_DECLTRACK_FN_ATTR(inaccessiblememonly) else if (isAssumedInaccessibleOrArgMemOnly()) STATS_DECLTRACK_FN_ATTR(inaccessiblememorargmemonly) } }; /// AAMemoryLocation attribute for call sites. struct AAMemoryLocationCallSite final : AAMemoryLocationImpl { AAMemoryLocationCallSite(const IRPosition &IRP, Attributor &A) : AAMemoryLocationImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAMemoryLocationImpl::initialize(A); Function *F = getAssociatedFunction(); if (!F || F->isDeclaration()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { // TODO: Once we have call site specific value information we can provide // call site specific liveness liveness information and then it makes // sense to specialize attributes for call sites arguments instead of // redirecting requests to the callee argument. Function *F = getAssociatedFunction(); const IRPosition &FnPos = IRPosition::function(*F); auto &FnAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); bool Changed = false; auto AccessPred = [&](const Instruction *I, const Value *Ptr, AccessKind Kind, MemoryLocationsKind MLK) { updateStateAndAccessesMap(getState(), MLK, I, Ptr, Changed, getAccessKindFromInst(I)); return true; }; if (!FnAA.checkForAllAccessesToMemoryKind(AccessPred, ALL_LOCATIONS)) return indicatePessimisticFixpoint(); return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { if (isAssumedReadNone()) STATS_DECLTRACK_CS_ATTR(readnone) } }; } // namespace /// ------------------ Value Constant Range Attribute ------------------------- namespace { struct AAValueConstantRangeImpl : AAValueConstantRange { using StateType = IntegerRangeState; AAValueConstantRangeImpl(const IRPosition &IRP, Attributor &A) : AAValueConstantRange(IRP, A) {} /// See AbstractAttribute::initialize(..). void initialize(Attributor &A) override { if (A.hasSimplificationCallback(getIRPosition())) { indicatePessimisticFixpoint(); return; } // Intersect a range given by SCEV. intersectKnown(getConstantRangeFromSCEV(A, getCtxI())); // Intersect a range given by LVI. intersectKnown(getConstantRangeFromLVI(A, getCtxI())); } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { std::string Str; llvm::raw_string_ostream OS(Str); OS << "range(" << getBitWidth() << ")<"; getKnown().print(OS); OS << " / "; getAssumed().print(OS); OS << ">"; return OS.str(); } /// Helper function to get a SCEV expr for the associated value at program /// point \p I. const SCEV *getSCEV(Attributor &A, const Instruction *I = nullptr) const { if (!getAnchorScope()) return nullptr; ScalarEvolution *SE = A.getInfoCache().getAnalysisResultForFunction( *getAnchorScope()); LoopInfo *LI = A.getInfoCache().getAnalysisResultForFunction( *getAnchorScope()); if (!SE || !LI) return nullptr; const SCEV *S = SE->getSCEV(&getAssociatedValue()); if (!I) return S; return SE->getSCEVAtScope(S, LI->getLoopFor(I->getParent())); } /// Helper function to get a range from SCEV for the associated value at /// program point \p I. ConstantRange getConstantRangeFromSCEV(Attributor &A, const Instruction *I = nullptr) const { if (!getAnchorScope()) return getWorstState(getBitWidth()); ScalarEvolution *SE = A.getInfoCache().getAnalysisResultForFunction( *getAnchorScope()); const SCEV *S = getSCEV(A, I); if (!SE || !S) return getWorstState(getBitWidth()); return SE->getUnsignedRange(S); } /// Helper function to get a range from LVI for the associated value at /// program point \p I. ConstantRange getConstantRangeFromLVI(Attributor &A, const Instruction *CtxI = nullptr) const { if (!getAnchorScope()) return getWorstState(getBitWidth()); LazyValueInfo *LVI = A.getInfoCache().getAnalysisResultForFunction( *getAnchorScope()); if (!LVI || !CtxI) return getWorstState(getBitWidth()); return LVI->getConstantRange(&getAssociatedValue(), const_cast(CtxI)); } /// Return true if \p CtxI is valid for querying outside analyses. /// This basically makes sure we do not ask intra-procedural analysis /// about a context in the wrong function or a context that violates /// dominance assumptions they might have. The \p AllowAACtxI flag indicates /// if the original context of this AA is OK or should be considered invalid. bool isValidCtxInstructionForOutsideAnalysis(Attributor &A, const Instruction *CtxI, bool AllowAACtxI) const { if (!CtxI || (!AllowAACtxI && CtxI == getCtxI())) return false; // Our context might be in a different function, neither intra-procedural // analysis (ScalarEvolution nor LazyValueInfo) can handle that. if (!AA::isValidInScope(getAssociatedValue(), CtxI->getFunction())) return false; // If the context is not dominated by the value there are paths to the // context that do not define the value. This cannot be handled by // LazyValueInfo so we need to bail. if (auto *I = dyn_cast(&getAssociatedValue())) { InformationCache &InfoCache = A.getInfoCache(); const DominatorTree *DT = InfoCache.getAnalysisResultForFunction( *I->getFunction()); return DT && DT->dominates(I, CtxI); } return true; } /// See AAValueConstantRange::getKnownConstantRange(..). ConstantRange getKnownConstantRange(Attributor &A, const Instruction *CtxI = nullptr) const override { if (!isValidCtxInstructionForOutsideAnalysis(A, CtxI, /* AllowAACtxI */ false)) return getKnown(); ConstantRange LVIR = getConstantRangeFromLVI(A, CtxI); ConstantRange SCEVR = getConstantRangeFromSCEV(A, CtxI); return getKnown().intersectWith(SCEVR).intersectWith(LVIR); } /// See AAValueConstantRange::getAssumedConstantRange(..). ConstantRange getAssumedConstantRange(Attributor &A, const Instruction *CtxI = nullptr) const override { // TODO: Make SCEV use Attributor assumption. // We may be able to bound a variable range via assumptions in // Attributor. ex.) If x is assumed to be in [1, 3] and y is known to // evolve to x^2 + x, then we can say that y is in [2, 12]. if (!isValidCtxInstructionForOutsideAnalysis(A, CtxI, /* AllowAACtxI */ false)) return getAssumed(); ConstantRange LVIR = getConstantRangeFromLVI(A, CtxI); ConstantRange SCEVR = getConstantRangeFromSCEV(A, CtxI); return getAssumed().intersectWith(SCEVR).intersectWith(LVIR); } /// Helper function to create MDNode for range metadata. static MDNode * getMDNodeForConstantRange(Type *Ty, LLVMContext &Ctx, const ConstantRange &AssumedConstantRange) { Metadata *LowAndHigh[] = {ConstantAsMetadata::get(ConstantInt::get( Ty, AssumedConstantRange.getLower())), ConstantAsMetadata::get(ConstantInt::get( Ty, AssumedConstantRange.getUpper()))}; return MDNode::get(Ctx, LowAndHigh); } /// Return true if \p Assumed is included in \p KnownRanges. static bool isBetterRange(const ConstantRange &Assumed, MDNode *KnownRanges) { if (Assumed.isFullSet()) return false; if (!KnownRanges) return true; // If multiple ranges are annotated in IR, we give up to annotate assumed // range for now. // TODO: If there exists a known range which containts assumed range, we // can say assumed range is better. if (KnownRanges->getNumOperands() > 2) return false; ConstantInt *Lower = mdconst::extract(KnownRanges->getOperand(0)); ConstantInt *Upper = mdconst::extract(KnownRanges->getOperand(1)); ConstantRange Known(Lower->getValue(), Upper->getValue()); return Known.contains(Assumed) && Known != Assumed; } /// Helper function to set range metadata. static bool setRangeMetadataIfisBetterRange(Instruction *I, const ConstantRange &AssumedConstantRange) { auto *OldRangeMD = I->getMetadata(LLVMContext::MD_range); if (isBetterRange(AssumedConstantRange, OldRangeMD)) { if (!AssumedConstantRange.isEmptySet()) { I->setMetadata(LLVMContext::MD_range, getMDNodeForConstantRange(I->getType(), I->getContext(), AssumedConstantRange)); return true; } } return false; } /// See AbstractAttribute::manifest() ChangeStatus manifest(Attributor &A) override { ChangeStatus Changed = ChangeStatus::UNCHANGED; ConstantRange AssumedConstantRange = getAssumedConstantRange(A); assert(!AssumedConstantRange.isFullSet() && "Invalid state"); auto &V = getAssociatedValue(); if (!AssumedConstantRange.isEmptySet() && !AssumedConstantRange.isSingleElement()) { if (Instruction *I = dyn_cast(&V)) { assert(I == getCtxI() && "Should not annotate an instruction which is " "not the context instruction"); if (isa(I) || isa(I)) if (setRangeMetadataIfisBetterRange(I, AssumedConstantRange)) Changed = ChangeStatus::CHANGED; } } return Changed; } }; struct AAValueConstantRangeArgument final : AAArgumentFromCallSiteArguments< AAValueConstantRange, AAValueConstantRangeImpl, IntegerRangeState, true /* BridgeCallBaseContext */> { using Base = AAArgumentFromCallSiteArguments< AAValueConstantRange, AAValueConstantRangeImpl, IntegerRangeState, true /* BridgeCallBaseContext */>; AAValueConstantRangeArgument(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::initialize(..). void initialize(Attributor &A) override { if (!getAnchorScope() || getAnchorScope()->isDeclaration()) { indicatePessimisticFixpoint(); } else { Base::initialize(A); } } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(value_range) } }; struct AAValueConstantRangeReturned : AAReturnedFromReturnedValues { using Base = AAReturnedFromReturnedValues; AAValueConstantRangeReturned(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(value_range) } }; struct AAValueConstantRangeFloating : AAValueConstantRangeImpl { AAValueConstantRangeFloating(const IRPosition &IRP, Attributor &A) : AAValueConstantRangeImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AAValueConstantRangeImpl::initialize(A); if (isAtFixpoint()) return; Value &V = getAssociatedValue(); if (auto *C = dyn_cast(&V)) { unionAssumed(ConstantRange(C->getValue())); indicateOptimisticFixpoint(); return; } if (isa(&V)) { // Collapse the undef state to 0. unionAssumed(ConstantRange(APInt(getBitWidth(), 0))); indicateOptimisticFixpoint(); return; } if (isa(&V)) return; if (isa(&V) || isa(&V) || isa(&V)) return; // If it is a load instruction with range metadata, use it. if (LoadInst *LI = dyn_cast(&V)) if (auto *RangeMD = LI->getMetadata(LLVMContext::MD_range)) { intersectKnown(getConstantRangeFromMetadata(*RangeMD)); return; } // We can work with PHI and select instruction as we traverse their operands // during update. if (isa(V) || isa(V)) return; // Otherwise we give up. indicatePessimisticFixpoint(); LLVM_DEBUG(dbgs() << "[AAValueConstantRange] We give up: " << getAssociatedValue() << "\n"); } bool calculateBinaryOperator( Attributor &A, BinaryOperator *BinOp, IntegerRangeState &T, const Instruction *CtxI, SmallVectorImpl &QuerriedAAs) { Value *LHS = BinOp->getOperand(0); Value *RHS = BinOp->getOperand(1); // Simplify the operands first. bool UsedAssumedInformation = false; const auto &SimplifiedLHS = A.getAssumedSimplified( IRPosition::value(*LHS, getCallBaseContext()), *this, UsedAssumedInformation, AA::Interprocedural); if (!SimplifiedLHS.has_value()) return true; if (!SimplifiedLHS.value()) return false; LHS = *SimplifiedLHS; const auto &SimplifiedRHS = A.getAssumedSimplified( IRPosition::value(*RHS, getCallBaseContext()), *this, UsedAssumedInformation, AA::Interprocedural); if (!SimplifiedRHS.has_value()) return true; if (!SimplifiedRHS.value()) return false; RHS = *SimplifiedRHS; // TODO: Allow non integers as well. if (!LHS->getType()->isIntegerTy() || !RHS->getType()->isIntegerTy()) return false; auto &LHSAA = A.getAAFor( *this, IRPosition::value(*LHS, getCallBaseContext()), DepClassTy::REQUIRED); QuerriedAAs.push_back(&LHSAA); auto LHSAARange = LHSAA.getAssumedConstantRange(A, CtxI); auto &RHSAA = A.getAAFor( *this, IRPosition::value(*RHS, getCallBaseContext()), DepClassTy::REQUIRED); QuerriedAAs.push_back(&RHSAA); auto RHSAARange = RHSAA.getAssumedConstantRange(A, CtxI); auto AssumedRange = LHSAARange.binaryOp(BinOp->getOpcode(), RHSAARange); T.unionAssumed(AssumedRange); // TODO: Track a known state too. return T.isValidState(); } bool calculateCastInst( Attributor &A, CastInst *CastI, IntegerRangeState &T, const Instruction *CtxI, SmallVectorImpl &QuerriedAAs) { assert(CastI->getNumOperands() == 1 && "Expected cast to be unary!"); // TODO: Allow non integers as well. Value *OpV = CastI->getOperand(0); // Simplify the operand first. bool UsedAssumedInformation = false; const auto &SimplifiedOpV = A.getAssumedSimplified( IRPosition::value(*OpV, getCallBaseContext()), *this, UsedAssumedInformation, AA::Interprocedural); if (!SimplifiedOpV.has_value()) return true; if (!SimplifiedOpV.value()) return false; OpV = *SimplifiedOpV; if (!OpV->getType()->isIntegerTy()) return false; auto &OpAA = A.getAAFor( *this, IRPosition::value(*OpV, getCallBaseContext()), DepClassTy::REQUIRED); QuerriedAAs.push_back(&OpAA); T.unionAssumed( OpAA.getAssumed().castOp(CastI->getOpcode(), getState().getBitWidth())); return T.isValidState(); } bool calculateCmpInst(Attributor &A, CmpInst *CmpI, IntegerRangeState &T, const Instruction *CtxI, SmallVectorImpl &QuerriedAAs) { Value *LHS = CmpI->getOperand(0); Value *RHS = CmpI->getOperand(1); // Simplify the operands first. bool UsedAssumedInformation = false; const auto &SimplifiedLHS = A.getAssumedSimplified( IRPosition::value(*LHS, getCallBaseContext()), *this, UsedAssumedInformation, AA::Interprocedural); if (!SimplifiedLHS.has_value()) return true; if (!SimplifiedLHS.value()) return false; LHS = *SimplifiedLHS; const auto &SimplifiedRHS = A.getAssumedSimplified( IRPosition::value(*RHS, getCallBaseContext()), *this, UsedAssumedInformation, AA::Interprocedural); if (!SimplifiedRHS.has_value()) return true; if (!SimplifiedRHS.value()) return false; RHS = *SimplifiedRHS; // TODO: Allow non integers as well. if (!LHS->getType()->isIntegerTy() || !RHS->getType()->isIntegerTy()) return false; auto &LHSAA = A.getAAFor( *this, IRPosition::value(*LHS, getCallBaseContext()), DepClassTy::REQUIRED); QuerriedAAs.push_back(&LHSAA); auto &RHSAA = A.getAAFor( *this, IRPosition::value(*RHS, getCallBaseContext()), DepClassTy::REQUIRED); QuerriedAAs.push_back(&RHSAA); auto LHSAARange = LHSAA.getAssumedConstantRange(A, CtxI); auto RHSAARange = RHSAA.getAssumedConstantRange(A, CtxI); // If one of them is empty set, we can't decide. if (LHSAARange.isEmptySet() || RHSAARange.isEmptySet()) return true; bool MustTrue = false, MustFalse = false; auto AllowedRegion = ConstantRange::makeAllowedICmpRegion(CmpI->getPredicate(), RHSAARange); if (AllowedRegion.intersectWith(LHSAARange).isEmptySet()) MustFalse = true; if (LHSAARange.icmp(CmpI->getPredicate(), RHSAARange)) MustTrue = true; assert((!MustTrue || !MustFalse) && "Either MustTrue or MustFalse should be false!"); if (MustTrue) T.unionAssumed(ConstantRange(APInt(/* numBits */ 1, /* val */ 1))); else if (MustFalse) T.unionAssumed(ConstantRange(APInt(/* numBits */ 1, /* val */ 0))); else T.unionAssumed(ConstantRange(/* BitWidth */ 1, /* isFullSet */ true)); LLVM_DEBUG(dbgs() << "[AAValueConstantRange] " << *CmpI << " " << LHSAA << " " << RHSAA << "\n"); // TODO: Track a known state too. return T.isValidState(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { IntegerRangeState T(getBitWidth()); auto VisitValueCB = [&](Value &V, const Instruction *CtxI) -> bool { Instruction *I = dyn_cast(&V); if (!I || isa(I)) { // Simplify the operand first. bool UsedAssumedInformation = false; const auto &SimplifiedOpV = A.getAssumedSimplified( IRPosition::value(V, getCallBaseContext()), *this, UsedAssumedInformation, AA::Interprocedural); if (!SimplifiedOpV.has_value()) return true; if (!SimplifiedOpV.value()) return false; Value *VPtr = *SimplifiedOpV; // If the value is not instruction, we query AA to Attributor. const auto &AA = A.getAAFor( *this, IRPosition::value(*VPtr, getCallBaseContext()), DepClassTy::REQUIRED); // Clamp operator is not used to utilize a program point CtxI. T.unionAssumed(AA.getAssumedConstantRange(A, CtxI)); return T.isValidState(); } SmallVector QuerriedAAs; if (auto *BinOp = dyn_cast(I)) { if (!calculateBinaryOperator(A, BinOp, T, CtxI, QuerriedAAs)) return false; } else if (auto *CmpI = dyn_cast(I)) { if (!calculateCmpInst(A, CmpI, T, CtxI, QuerriedAAs)) return false; } else if (auto *CastI = dyn_cast(I)) { if (!calculateCastInst(A, CastI, T, CtxI, QuerriedAAs)) return false; } else { // Give up with other instructions. // TODO: Add other instructions T.indicatePessimisticFixpoint(); return false; } // Catch circular reasoning in a pessimistic way for now. // TODO: Check how the range evolves and if we stripped anything, see also // AADereferenceable or AAAlign for similar situations. for (const AAValueConstantRange *QueriedAA : QuerriedAAs) { if (QueriedAA != this) continue; // If we are in a stady state we do not need to worry. if (T.getAssumed() == getState().getAssumed()) continue; T.indicatePessimisticFixpoint(); } return T.isValidState(); }; if (!VisitValueCB(getAssociatedValue(), getCtxI())) return indicatePessimisticFixpoint(); // Ensure that long def-use chains can't cause circular reasoning either by // introducing a cutoff below. if (clampStateAndIndicateChange(getState(), T) == ChangeStatus::UNCHANGED) return ChangeStatus::UNCHANGED; if (++NumChanges > MaxNumChanges) { LLVM_DEBUG(dbgs() << "[AAValueConstantRange] performed " << NumChanges << " but only " << MaxNumChanges << " are allowed to avoid cyclic reasoning."); return indicatePessimisticFixpoint(); } return ChangeStatus::CHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(value_range) } /// Tracker to bail after too many widening steps of the constant range. int NumChanges = 0; /// Upper bound for the number of allowed changes (=widening steps) for the /// constant range before we give up. static constexpr int MaxNumChanges = 5; }; struct AAValueConstantRangeFunction : AAValueConstantRangeImpl { AAValueConstantRangeFunction(const IRPosition &IRP, Attributor &A) : AAValueConstantRangeImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). ChangeStatus updateImpl(Attributor &A) override { llvm_unreachable("AAValueConstantRange(Function|CallSite)::updateImpl will " "not be called"); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(value_range) } }; struct AAValueConstantRangeCallSite : AAValueConstantRangeFunction { AAValueConstantRangeCallSite(const IRPosition &IRP, Attributor &A) : AAValueConstantRangeFunction(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(value_range) } }; struct AAValueConstantRangeCallSiteReturned : AACallSiteReturnedFromReturned { AAValueConstantRangeCallSiteReturned(const IRPosition &IRP, Attributor &A) : AACallSiteReturnedFromReturned(IRP, A) { } /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { // If it is a load instruction with range metadata, use the metadata. if (CallInst *CI = dyn_cast(&getAssociatedValue())) if (auto *RangeMD = CI->getMetadata(LLVMContext::MD_range)) intersectKnown(getConstantRangeFromMetadata(*RangeMD)); AAValueConstantRangeImpl::initialize(A); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(value_range) } }; struct AAValueConstantRangeCallSiteArgument : AAValueConstantRangeFloating { AAValueConstantRangeCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAValueConstantRangeFloating(IRP, A) {} /// See AbstractAttribute::manifest() ChangeStatus manifest(Attributor &A) override { return ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(value_range) } }; } // namespace /// ------------------ Potential Values Attribute ------------------------- namespace { struct AAPotentialConstantValuesImpl : AAPotentialConstantValues { using StateType = PotentialConstantIntValuesState; AAPotentialConstantValuesImpl(const IRPosition &IRP, Attributor &A) : AAPotentialConstantValues(IRP, A) {} /// See AbstractAttribute::initialize(..). void initialize(Attributor &A) override { if (A.hasSimplificationCallback(getIRPosition())) indicatePessimisticFixpoint(); else AAPotentialConstantValues::initialize(A); } bool fillSetWithConstantValues(Attributor &A, const IRPosition &IRP, SetTy &S, bool &ContainsUndef) { SmallVector Values; bool UsedAssumedInformation = false; if (!A.getAssumedSimplifiedValues(IRP, *this, Values, AA::Interprocedural, UsedAssumedInformation)) { if (!IRP.getAssociatedType()->isIntegerTy()) return false; auto &PotentialValuesAA = A.getAAFor( *this, IRP, DepClassTy::REQUIRED); if (!PotentialValuesAA.getState().isValidState()) return false; ContainsUndef = PotentialValuesAA.getState().undefIsContained(); S = PotentialValuesAA.getState().getAssumedSet(); return true; } for (auto &It : Values) { if (isa(It.getValue())) continue; auto *CI = dyn_cast(It.getValue()); if (!CI) return false; S.insert(CI->getValue()); } ContainsUndef = S.empty(); return true; } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { std::string Str; llvm::raw_string_ostream OS(Str); OS << getState(); return OS.str(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { return indicatePessimisticFixpoint(); } }; struct AAPotentialConstantValuesArgument final : AAArgumentFromCallSiteArguments { using Base = AAArgumentFromCallSiteArguments; AAPotentialConstantValuesArgument(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::initialize(..). void initialize(Attributor &A) override { if (!getAnchorScope() || getAnchorScope()->isDeclaration()) { indicatePessimisticFixpoint(); } else { Base::initialize(A); } } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(potential_values) } }; struct AAPotentialConstantValuesReturned : AAReturnedFromReturnedValues { using Base = AAReturnedFromReturnedValues; AAPotentialConstantValuesReturned(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(potential_values) } }; struct AAPotentialConstantValuesFloating : AAPotentialConstantValuesImpl { AAPotentialConstantValuesFloating(const IRPosition &IRP, Attributor &A) : AAPotentialConstantValuesImpl(IRP, A) {} /// See AbstractAttribute::initialize(..). void initialize(Attributor &A) override { AAPotentialConstantValuesImpl::initialize(A); if (isAtFixpoint()) return; Value &V = getAssociatedValue(); if (auto *C = dyn_cast(&V)) { unionAssumed(C->getValue()); indicateOptimisticFixpoint(); return; } if (isa(&V)) { unionAssumedWithUndef(); indicateOptimisticFixpoint(); return; } if (isa(&V) || isa(&V) || isa(&V)) return; if (isa(V) || isa(V) || isa(V)) return; indicatePessimisticFixpoint(); LLVM_DEBUG(dbgs() << "[AAPotentialConstantValues] We give up: " << getAssociatedValue() << "\n"); } static bool calculateICmpInst(const ICmpInst *ICI, const APInt &LHS, const APInt &RHS) { return ICmpInst::compare(LHS, RHS, ICI->getPredicate()); } static APInt calculateCastInst(const CastInst *CI, const APInt &Src, uint32_t ResultBitWidth) { Instruction::CastOps CastOp = CI->getOpcode(); switch (CastOp) { default: llvm_unreachable("unsupported or not integer cast"); case Instruction::Trunc: return Src.trunc(ResultBitWidth); case Instruction::SExt: return Src.sext(ResultBitWidth); case Instruction::ZExt: return Src.zext(ResultBitWidth); case Instruction::BitCast: return Src; } } static APInt calculateBinaryOperator(const BinaryOperator *BinOp, const APInt &LHS, const APInt &RHS, bool &SkipOperation, bool &Unsupported) { Instruction::BinaryOps BinOpcode = BinOp->getOpcode(); // Unsupported is set to true when the binary operator is not supported. // SkipOperation is set to true when UB occur with the given operand pair // (LHS, RHS). // TODO: we should look at nsw and nuw keywords to handle operations // that create poison or undef value. switch (BinOpcode) { default: Unsupported = true; return LHS; case Instruction::Add: return LHS + RHS; case Instruction::Sub: return LHS - RHS; case Instruction::Mul: return LHS * RHS; case Instruction::UDiv: if (RHS.isZero()) { SkipOperation = true; return LHS; } return LHS.udiv(RHS); case Instruction::SDiv: if (RHS.isZero()) { SkipOperation = true; return LHS; } return LHS.sdiv(RHS); case Instruction::URem: if (RHS.isZero()) { SkipOperation = true; return LHS; } return LHS.urem(RHS); case Instruction::SRem: if (RHS.isZero()) { SkipOperation = true; return LHS; } return LHS.srem(RHS); case Instruction::Shl: return LHS.shl(RHS); case Instruction::LShr: return LHS.lshr(RHS); case Instruction::AShr: return LHS.ashr(RHS); case Instruction::And: return LHS & RHS; case Instruction::Or: return LHS | RHS; case Instruction::Xor: return LHS ^ RHS; } } bool calculateBinaryOperatorAndTakeUnion(const BinaryOperator *BinOp, const APInt &LHS, const APInt &RHS) { bool SkipOperation = false; bool Unsupported = false; APInt Result = calculateBinaryOperator(BinOp, LHS, RHS, SkipOperation, Unsupported); if (Unsupported) return false; // If SkipOperation is true, we can ignore this operand pair (L, R). if (!SkipOperation) unionAssumed(Result); return isValidState(); } ChangeStatus updateWithICmpInst(Attributor &A, ICmpInst *ICI) { auto AssumedBefore = getAssumed(); Value *LHS = ICI->getOperand(0); Value *RHS = ICI->getOperand(1); bool LHSContainsUndef = false, RHSContainsUndef = false; SetTy LHSAAPVS, RHSAAPVS; if (!fillSetWithConstantValues(A, IRPosition::value(*LHS), LHSAAPVS, LHSContainsUndef) || !fillSetWithConstantValues(A, IRPosition::value(*RHS), RHSAAPVS, RHSContainsUndef)) return indicatePessimisticFixpoint(); // TODO: make use of undef flag to limit potential values aggressively. bool MaybeTrue = false, MaybeFalse = false; const APInt Zero(RHS->getType()->getIntegerBitWidth(), 0); if (LHSContainsUndef && RHSContainsUndef) { // The result of any comparison between undefs can be soundly replaced // with undef. unionAssumedWithUndef(); } else if (LHSContainsUndef) { for (const APInt &R : RHSAAPVS) { bool CmpResult = calculateICmpInst(ICI, Zero, R); MaybeTrue |= CmpResult; MaybeFalse |= !CmpResult; if (MaybeTrue & MaybeFalse) return indicatePessimisticFixpoint(); } } else if (RHSContainsUndef) { for (const APInt &L : LHSAAPVS) { bool CmpResult = calculateICmpInst(ICI, L, Zero); MaybeTrue |= CmpResult; MaybeFalse |= !CmpResult; if (MaybeTrue & MaybeFalse) return indicatePessimisticFixpoint(); } } else { for (const APInt &L : LHSAAPVS) { for (const APInt &R : RHSAAPVS) { bool CmpResult = calculateICmpInst(ICI, L, R); MaybeTrue |= CmpResult; MaybeFalse |= !CmpResult; if (MaybeTrue & MaybeFalse) return indicatePessimisticFixpoint(); } } } if (MaybeTrue) unionAssumed(APInt(/* numBits */ 1, /* val */ 1)); if (MaybeFalse) unionAssumed(APInt(/* numBits */ 1, /* val */ 0)); return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } ChangeStatus updateWithSelectInst(Attributor &A, SelectInst *SI) { auto AssumedBefore = getAssumed(); Value *LHS = SI->getTrueValue(); Value *RHS = SI->getFalseValue(); bool UsedAssumedInformation = false; Optional C = A.getAssumedConstant(*SI->getCondition(), *this, UsedAssumedInformation); // Check if we only need one operand. bool OnlyLeft = false, OnlyRight = false; if (C && *C && (*C)->isOneValue()) OnlyLeft = true; else if (C && *C && (*C)->isZeroValue()) OnlyRight = true; bool LHSContainsUndef = false, RHSContainsUndef = false; SetTy LHSAAPVS, RHSAAPVS; if (!OnlyRight && !fillSetWithConstantValues(A, IRPosition::value(*LHS), LHSAAPVS, LHSContainsUndef)) return indicatePessimisticFixpoint(); if (!OnlyLeft && !fillSetWithConstantValues(A, IRPosition::value(*RHS), RHSAAPVS, RHSContainsUndef)) return indicatePessimisticFixpoint(); if (OnlyLeft || OnlyRight) { // select (true/false), lhs, rhs auto *OpAA = OnlyLeft ? &LHSAAPVS : &RHSAAPVS; auto Undef = OnlyLeft ? LHSContainsUndef : RHSContainsUndef; if (Undef) unionAssumedWithUndef(); else { for (auto &It : *OpAA) unionAssumed(It); } } else if (LHSContainsUndef && RHSContainsUndef) { // select i1 *, undef , undef => undef unionAssumedWithUndef(); } else { for (auto &It : LHSAAPVS) unionAssumed(It); for (auto &It : RHSAAPVS) unionAssumed(It); } return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } ChangeStatus updateWithCastInst(Attributor &A, CastInst *CI) { auto AssumedBefore = getAssumed(); if (!CI->isIntegerCast()) return indicatePessimisticFixpoint(); assert(CI->getNumOperands() == 1 && "Expected cast to be unary!"); uint32_t ResultBitWidth = CI->getDestTy()->getIntegerBitWidth(); Value *Src = CI->getOperand(0); bool SrcContainsUndef = false; SetTy SrcPVS; if (!fillSetWithConstantValues(A, IRPosition::value(*Src), SrcPVS, SrcContainsUndef)) return indicatePessimisticFixpoint(); if (SrcContainsUndef) unionAssumedWithUndef(); else { for (const APInt &S : SrcPVS) { APInt T = calculateCastInst(CI, S, ResultBitWidth); unionAssumed(T); } } return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } ChangeStatus updateWithBinaryOperator(Attributor &A, BinaryOperator *BinOp) { auto AssumedBefore = getAssumed(); Value *LHS = BinOp->getOperand(0); Value *RHS = BinOp->getOperand(1); bool LHSContainsUndef = false, RHSContainsUndef = false; SetTy LHSAAPVS, RHSAAPVS; if (!fillSetWithConstantValues(A, IRPosition::value(*LHS), LHSAAPVS, LHSContainsUndef) || !fillSetWithConstantValues(A, IRPosition::value(*RHS), RHSAAPVS, RHSContainsUndef)) return indicatePessimisticFixpoint(); const APInt Zero = APInt(LHS->getType()->getIntegerBitWidth(), 0); // TODO: make use of undef flag to limit potential values aggressively. if (LHSContainsUndef && RHSContainsUndef) { if (!calculateBinaryOperatorAndTakeUnion(BinOp, Zero, Zero)) return indicatePessimisticFixpoint(); } else if (LHSContainsUndef) { for (const APInt &R : RHSAAPVS) { if (!calculateBinaryOperatorAndTakeUnion(BinOp, Zero, R)) return indicatePessimisticFixpoint(); } } else if (RHSContainsUndef) { for (const APInt &L : LHSAAPVS) { if (!calculateBinaryOperatorAndTakeUnion(BinOp, L, Zero)) return indicatePessimisticFixpoint(); } } else { for (const APInt &L : LHSAAPVS) { for (const APInt &R : RHSAAPVS) { if (!calculateBinaryOperatorAndTakeUnion(BinOp, L, R)) return indicatePessimisticFixpoint(); } } } return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { Value &V = getAssociatedValue(); Instruction *I = dyn_cast(&V); if (auto *ICI = dyn_cast(I)) return updateWithICmpInst(A, ICI); if (auto *SI = dyn_cast(I)) return updateWithSelectInst(A, SI); if (auto *CI = dyn_cast(I)) return updateWithCastInst(A, CI); if (auto *BinOp = dyn_cast(I)) return updateWithBinaryOperator(A, BinOp); return indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(potential_values) } }; struct AAPotentialConstantValuesFunction : AAPotentialConstantValuesImpl { AAPotentialConstantValuesFunction(const IRPosition &IRP, Attributor &A) : AAPotentialConstantValuesImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). ChangeStatus updateImpl(Attributor &A) override { llvm_unreachable( "AAPotentialConstantValues(Function|CallSite)::updateImpl will " "not be called"); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(potential_values) } }; struct AAPotentialConstantValuesCallSite : AAPotentialConstantValuesFunction { AAPotentialConstantValuesCallSite(const IRPosition &IRP, Attributor &A) : AAPotentialConstantValuesFunction(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(potential_values) } }; struct AAPotentialConstantValuesCallSiteReturned : AACallSiteReturnedFromReturned { AAPotentialConstantValuesCallSiteReturned(const IRPosition &IRP, Attributor &A) : AACallSiteReturnedFromReturned(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(potential_values) } }; struct AAPotentialConstantValuesCallSiteArgument : AAPotentialConstantValuesFloating { AAPotentialConstantValuesCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAPotentialConstantValuesFloating(IRP, A) {} /// See AbstractAttribute::initialize(..). void initialize(Attributor &A) override { AAPotentialConstantValuesImpl::initialize(A); if (isAtFixpoint()) return; Value &V = getAssociatedValue(); if (auto *C = dyn_cast(&V)) { unionAssumed(C->getValue()); indicateOptimisticFixpoint(); return; } if (isa(&V)) { unionAssumedWithUndef(); indicateOptimisticFixpoint(); return; } } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { Value &V = getAssociatedValue(); auto AssumedBefore = getAssumed(); auto &AA = A.getAAFor( *this, IRPosition::value(V), DepClassTy::REQUIRED); const auto &S = AA.getAssumed(); unionAssumed(S); return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(potential_values) } }; /// ------------------------ NoUndef Attribute --------------------------------- struct AANoUndefImpl : AANoUndef { AANoUndefImpl(const IRPosition &IRP, Attributor &A) : AANoUndef(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { if (getIRPosition().hasAttr({Attribute::NoUndef})) { indicateOptimisticFixpoint(); return; } Value &V = getAssociatedValue(); if (isa(V)) indicatePessimisticFixpoint(); else if (isa(V)) indicateOptimisticFixpoint(); else if (getPositionKind() != IRPosition::IRP_RETURNED && isGuaranteedNotToBeUndefOrPoison(&V)) indicateOptimisticFixpoint(); else AANoUndef::initialize(A); } /// See followUsesInMBEC bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I, AANoUndef::StateType &State) { const Value *UseV = U->get(); const DominatorTree *DT = nullptr; AssumptionCache *AC = nullptr; InformationCache &InfoCache = A.getInfoCache(); if (Function *F = getAnchorScope()) { DT = InfoCache.getAnalysisResultForFunction(*F); AC = InfoCache.getAnalysisResultForFunction(*F); } State.setKnown(isGuaranteedNotToBeUndefOrPoison(UseV, AC, I, DT)); bool TrackUse = false; // Track use for instructions which must produce undef or poison bits when // at least one operand contains such bits. if (isa(*I) || isa(*I)) TrackUse = true; return TrackUse; } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { return getAssumed() ? "noundef" : "may-undef-or-poison"; } ChangeStatus manifest(Attributor &A) override { // We don't manifest noundef attribute for dead positions because the // associated values with dead positions would be replaced with undef // values. bool UsedAssumedInformation = false; if (A.isAssumedDead(getIRPosition(), nullptr, nullptr, UsedAssumedInformation)) return ChangeStatus::UNCHANGED; // A position whose simplified value does not have any value is // considered to be dead. We don't manifest noundef in such positions for // the same reason above. if (!A.getAssumedSimplified(getIRPosition(), *this, UsedAssumedInformation, AA::Interprocedural) .has_value()) return ChangeStatus::UNCHANGED; return AANoUndef::manifest(A); } }; struct AANoUndefFloating : public AANoUndefImpl { AANoUndefFloating(const IRPosition &IRP, Attributor &A) : AANoUndefImpl(IRP, A) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { AANoUndefImpl::initialize(A); if (!getState().isAtFixpoint()) if (Instruction *CtxI = getCtxI()) followUsesInMBEC(*this, A, getState(), *CtxI); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { SmallVector Values; bool UsedAssumedInformation = false; if (!A.getAssumedSimplifiedValues(getIRPosition(), *this, Values, AA::AnyScope, UsedAssumedInformation)) { Values.push_back({getAssociatedValue(), getCtxI()}); } StateType T; auto VisitValueCB = [&](Value &V, const Instruction *CtxI) -> bool { const auto &AA = A.getAAFor(*this, IRPosition::value(V), DepClassTy::REQUIRED); if (this == &AA) { T.indicatePessimisticFixpoint(); } else { const AANoUndef::StateType &S = static_cast(AA.getState()); T ^= S; } return T.isValidState(); }; for (const auto &VAC : Values) if (!VisitValueCB(*VAC.getValue(), VAC.getCtxI())) return indicatePessimisticFixpoint(); return clampStateAndIndicateChange(getState(), T); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(noundef) } }; struct AANoUndefReturned final : AAReturnedFromReturnedValues { AANoUndefReturned(const IRPosition &IRP, Attributor &A) : AAReturnedFromReturnedValues(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(noundef) } }; struct AANoUndefArgument final : AAArgumentFromCallSiteArguments { AANoUndefArgument(const IRPosition &IRP, Attributor &A) : AAArgumentFromCallSiteArguments(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(noundef) } }; struct AANoUndefCallSiteArgument final : AANoUndefFloating { AANoUndefCallSiteArgument(const IRPosition &IRP, Attributor &A) : AANoUndefFloating(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(noundef) } }; struct AANoUndefCallSiteReturned final : AACallSiteReturnedFromReturned { AANoUndefCallSiteReturned(const IRPosition &IRP, Attributor &A) : AACallSiteReturnedFromReturned(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(noundef) } }; struct AACallEdgesImpl : public AACallEdges { AACallEdgesImpl(const IRPosition &IRP, Attributor &A) : AACallEdges(IRP, A) {} const SetVector &getOptimisticEdges() const override { return CalledFunctions; } bool hasUnknownCallee() const override { return HasUnknownCallee; } bool hasNonAsmUnknownCallee() const override { return HasUnknownCalleeNonAsm; } const std::string getAsStr() const override { return "CallEdges[" + std::to_string(HasUnknownCallee) + "," + std::to_string(CalledFunctions.size()) + "]"; } void trackStatistics() const override {} protected: void addCalledFunction(Function *Fn, ChangeStatus &Change) { if (CalledFunctions.insert(Fn)) { Change = ChangeStatus::CHANGED; LLVM_DEBUG(dbgs() << "[AACallEdges] New call edge: " << Fn->getName() << "\n"); } } void setHasUnknownCallee(bool NonAsm, ChangeStatus &Change) { if (!HasUnknownCallee) Change = ChangeStatus::CHANGED; if (NonAsm && !HasUnknownCalleeNonAsm) Change = ChangeStatus::CHANGED; HasUnknownCalleeNonAsm |= NonAsm; HasUnknownCallee = true; } private: /// Optimistic set of functions that might be called by this position. SetVector CalledFunctions; /// Is there any call with a unknown callee. bool HasUnknownCallee = false; /// Is there any call with a unknown callee, excluding any inline asm. bool HasUnknownCalleeNonAsm = false; }; struct AACallEdgesCallSite : public AACallEdgesImpl { AACallEdgesCallSite(const IRPosition &IRP, Attributor &A) : AACallEdgesImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { ChangeStatus Change = ChangeStatus::UNCHANGED; auto VisitValue = [&](Value &V, const Instruction *CtxI) -> bool { if (Function *Fn = dyn_cast(&V)) { addCalledFunction(Fn, Change); } else { LLVM_DEBUG(dbgs() << "[AACallEdges] Unrecognized value: " << V << "\n"); setHasUnknownCallee(true, Change); } // Explore all values. return true; }; SmallVector Values; // Process any value that we might call. auto ProcessCalledOperand = [&](Value *V, Instruction *CtxI) { bool UsedAssumedInformation = false; Values.clear(); if (!A.getAssumedSimplifiedValues(IRPosition::value(*V), *this, Values, AA::AnyScope, UsedAssumedInformation)) { Values.push_back({*V, CtxI}); } for (auto &VAC : Values) VisitValue(*VAC.getValue(), VAC.getCtxI()); }; CallBase *CB = cast(getCtxI()); if (CB->isInlineAsm()) { if (!hasAssumption(*CB->getCaller(), "ompx_no_call_asm") && !hasAssumption(*CB, "ompx_no_call_asm")) setHasUnknownCallee(false, Change); return Change; } // Process callee metadata if available. if (auto *MD = getCtxI()->getMetadata(LLVMContext::MD_callees)) { for (auto &Op : MD->operands()) { Function *Callee = mdconst::dyn_extract_or_null(Op); if (Callee) addCalledFunction(Callee, Change); } return Change; } // The most simple case. ProcessCalledOperand(CB->getCalledOperand(), CB); // Process callback functions. SmallVector CallbackUses; AbstractCallSite::getCallbackUses(*CB, CallbackUses); for (const Use *U : CallbackUses) ProcessCalledOperand(U->get(), CB); return Change; } }; struct AACallEdgesFunction : public AACallEdgesImpl { AACallEdgesFunction(const IRPosition &IRP, Attributor &A) : AACallEdgesImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { ChangeStatus Change = ChangeStatus::UNCHANGED; auto ProcessCallInst = [&](Instruction &Inst) { CallBase &CB = cast(Inst); auto &CBEdges = A.getAAFor( *this, IRPosition::callsite_function(CB), DepClassTy::REQUIRED); if (CBEdges.hasNonAsmUnknownCallee()) setHasUnknownCallee(true, Change); if (CBEdges.hasUnknownCallee()) setHasUnknownCallee(false, Change); for (Function *F : CBEdges.getOptimisticEdges()) addCalledFunction(F, Change); return true; }; // Visit all callable instructions. bool UsedAssumedInformation = false; if (!A.checkForAllCallLikeInstructions(ProcessCallInst, *this, UsedAssumedInformation, /* CheckBBLivenessOnly */ true)) { // If we haven't looked at all call like instructions, assume that there // are unknown callees. setHasUnknownCallee(true, Change); } return Change; } }; struct AAFunctionReachabilityFunction : public AAFunctionReachability { private: struct QuerySet { void markReachable(const Function &Fn) { Reachable.insert(&Fn); Unreachable.erase(&Fn); } /// If there is no information about the function None is returned. Optional isCachedReachable(const Function &Fn) { // Assume that we can reach the function. // TODO: Be more specific with the unknown callee. if (CanReachUnknownCallee) return true; if (Reachable.count(&Fn)) return true; if (Unreachable.count(&Fn)) return false; return llvm::None; } /// Set of functions that we know for sure is reachable. DenseSet Reachable; /// Set of functions that are unreachable, but might become reachable. DenseSet Unreachable; /// If we can reach a function with a call to a unknown function we assume /// that we can reach any function. bool CanReachUnknownCallee = false; }; struct QueryResolver : public QuerySet { ChangeStatus update(Attributor &A, const AAFunctionReachability &AA, ArrayRef AAEdgesList) { ChangeStatus Change = ChangeStatus::UNCHANGED; for (auto *AAEdges : AAEdgesList) { if (AAEdges->hasUnknownCallee()) { if (!CanReachUnknownCallee) { LLVM_DEBUG(dbgs() << "[QueryResolver] Edges include unknown callee!\n"); Change = ChangeStatus::CHANGED; } CanReachUnknownCallee = true; return Change; } } for (const Function *Fn : make_early_inc_range(Unreachable)) { if (checkIfReachable(A, AA, AAEdgesList, *Fn)) { Change = ChangeStatus::CHANGED; markReachable(*Fn); } } return Change; } bool isReachable(Attributor &A, AAFunctionReachability &AA, ArrayRef AAEdgesList, const Function &Fn) { Optional Cached = isCachedReachable(Fn); if (Cached) return Cached.value(); // The query was not cached, thus it is new. We need to request an update // explicitly to make sure this the information is properly run to a // fixpoint. A.registerForUpdate(AA); // We need to assume that this function can't reach Fn to prevent // an infinite loop if this function is recursive. Unreachable.insert(&Fn); bool Result = checkIfReachable(A, AA, AAEdgesList, Fn); if (Result) markReachable(Fn); return Result; } bool checkIfReachable(Attributor &A, const AAFunctionReachability &AA, ArrayRef AAEdgesList, const Function &Fn) const { // Handle the most trivial case first. for (auto *AAEdges : AAEdgesList) { const SetVector &Edges = AAEdges->getOptimisticEdges(); if (Edges.count(const_cast(&Fn))) return true; } SmallVector Deps; for (auto &AAEdges : AAEdgesList) { const SetVector &Edges = AAEdges->getOptimisticEdges(); for (Function *Edge : Edges) { // Functions that do not call back into the module can be ignored. if (Edge->hasFnAttribute(Attribute::NoCallback)) continue; // We don't need a dependency if the result is reachable. const AAFunctionReachability &EdgeReachability = A.getAAFor( AA, IRPosition::function(*Edge), DepClassTy::NONE); Deps.push_back(&EdgeReachability); if (EdgeReachability.canReach(A, Fn)) return true; } } // The result is false for now, set dependencies and leave. for (auto *Dep : Deps) A.recordDependence(*Dep, AA, DepClassTy::REQUIRED); return false; } }; /// Get call edges that can be reached by this instruction. bool getReachableCallEdges(Attributor &A, const AAReachability &Reachability, const Instruction &Inst, SmallVector &Result) const { // Determine call like instructions that we can reach from the inst. auto CheckCallBase = [&](Instruction &CBInst) { if (!Reachability.isAssumedReachable(A, Inst, CBInst)) return true; auto &CB = cast(CBInst); const AACallEdges &AAEdges = A.getAAFor( *this, IRPosition::callsite_function(CB), DepClassTy::REQUIRED); Result.push_back(&AAEdges); return true; }; bool UsedAssumedInformation = false; return A.checkForAllCallLikeInstructions(CheckCallBase, *this, UsedAssumedInformation, /* CheckBBLivenessOnly */ true); } public: AAFunctionReachabilityFunction(const IRPosition &IRP, Attributor &A) : AAFunctionReachability(IRP, A) {} bool canReach(Attributor &A, const Function &Fn) const override { if (!isValidState()) return true; const AACallEdges &AAEdges = A.getAAFor(*this, getIRPosition(), DepClassTy::REQUIRED); // Attributor returns attributes as const, so this function has to be // const for users of this attribute to use it without having to do // a const_cast. // This is a hack for us to be able to cache queries. auto *NonConstThis = const_cast(this); bool Result = NonConstThis->WholeFunction.isReachable(A, *NonConstThis, {&AAEdges}, Fn); return Result; } /// Can \p CB reach \p Fn bool canReach(Attributor &A, CallBase &CB, const Function &Fn) const override { if (!isValidState()) return true; const AACallEdges &AAEdges = A.getAAFor( *this, IRPosition::callsite_function(CB), DepClassTy::REQUIRED); // Attributor returns attributes as const, so this function has to be // const for users of this attribute to use it without having to do // a const_cast. // This is a hack for us to be able to cache queries. auto *NonConstThis = const_cast(this); QueryResolver &CBQuery = NonConstThis->CBQueries[&CB]; bool Result = CBQuery.isReachable(A, *NonConstThis, {&AAEdges}, Fn); return Result; } bool instructionCanReach(Attributor &A, const Instruction &Inst, const Function &Fn) const override { if (!isValidState()) return true; const auto &Reachability = A.getAAFor( *this, IRPosition::function(*getAssociatedFunction()), DepClassTy::REQUIRED); SmallVector CallEdges; bool AllKnown = getReachableCallEdges(A, Reachability, Inst, CallEdges); // Attributor returns attributes as const, so this function has to be // const for users of this attribute to use it without having to do // a const_cast. // This is a hack for us to be able to cache queries. auto *NonConstThis = const_cast(this); QueryResolver &InstQSet = NonConstThis->InstQueries[&Inst]; if (!AllKnown) { LLVM_DEBUG(dbgs() << "[AAReachability] Not all reachable edges known, " "may reach unknown callee!\n"); InstQSet.CanReachUnknownCallee = true; } return InstQSet.isReachable(A, *NonConstThis, CallEdges, Fn); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { const AACallEdges &AAEdges = A.getAAFor(*this, getIRPosition(), DepClassTy::REQUIRED); ChangeStatus Change = ChangeStatus::UNCHANGED; Change |= WholeFunction.update(A, *this, {&AAEdges}); for (auto &CBPair : CBQueries) { const AACallEdges &AAEdges = A.getAAFor( *this, IRPosition::callsite_function(*CBPair.first), DepClassTy::REQUIRED); Change |= CBPair.second.update(A, *this, {&AAEdges}); } // Update the Instruction queries. if (!InstQueries.empty()) { const AAReachability *Reachability = &A.getAAFor( *this, IRPosition::function(*getAssociatedFunction()), DepClassTy::REQUIRED); // Check for local callbases first. for (auto &InstPair : InstQueries) { SmallVector CallEdges; bool AllKnown = getReachableCallEdges(A, *Reachability, *InstPair.first, CallEdges); // Update will return change if we this effects any queries. if (!AllKnown) { LLVM_DEBUG(dbgs() << "[AAReachability] Not all reachable edges " "known, may reach unknown callee!\n"); InstPair.second.CanReachUnknownCallee = true; } Change |= InstPair.second.update(A, *this, CallEdges); } } return Change; } const std::string getAsStr() const override { size_t QueryCount = WholeFunction.Reachable.size() + WholeFunction.Unreachable.size(); return "FunctionReachability [" + (canReachUnknownCallee() ? "unknown" : (std::to_string(WholeFunction.Reachable.size()) + "," + std::to_string(QueryCount))) + "]"; } void trackStatistics() const override {} private: bool canReachUnknownCallee() const override { return WholeFunction.CanReachUnknownCallee; } /// Used to answer if a the whole function can reacha a specific function. QueryResolver WholeFunction; /// Used to answer if a call base inside this function can reach a specific /// function. MapVector CBQueries; /// This is for instruction queries than scan "forward". MapVector InstQueries; }; } // namespace template static Optional askForAssumedConstant(Attributor &A, const AbstractAttribute &QueryingAA, const IRPosition &IRP, Type &Ty) { if (!Ty.isIntegerTy()) return nullptr; // This will also pass the call base context. const auto &AA = A.getAAFor(QueryingAA, IRP, DepClassTy::NONE); Optional COpt = AA.getAssumedConstant(A); if (!COpt.has_value()) { A.recordDependence(AA, QueryingAA, DepClassTy::OPTIONAL); return llvm::None; } if (auto *C = COpt.value()) { A.recordDependence(AA, QueryingAA, DepClassTy::OPTIONAL); return C; } return nullptr; } Value *AAPotentialValues::getSingleValue( Attributor &A, const AbstractAttribute &AA, const IRPosition &IRP, SmallVectorImpl &Values) { Type &Ty = *IRP.getAssociatedType(); Optional V; for (auto &It : Values) { V = AA::combineOptionalValuesInAAValueLatice(V, It.getValue(), &Ty); if (V.has_value() && !V.value()) break; } if (!V.has_value()) return UndefValue::get(&Ty); return V.value(); } namespace { struct AAPotentialValuesImpl : AAPotentialValues { using StateType = PotentialLLVMValuesState; AAPotentialValuesImpl(const IRPosition &IRP, Attributor &A) : AAPotentialValues(IRP, A) {} /// See AbstractAttribute::initialize(..). void initialize(Attributor &A) override { if (A.hasSimplificationCallback(getIRPosition())) { indicatePessimisticFixpoint(); return; } Value *Stripped = getAssociatedValue().stripPointerCasts(); if (isa(Stripped)) { addValue(A, getState(), *Stripped, getCtxI(), AA::AnyScope, getAnchorScope()); indicateOptimisticFixpoint(); return; } AAPotentialValues::initialize(A); } /// See AbstractAttribute::getAsStr(). const std::string getAsStr() const override { std::string Str; llvm::raw_string_ostream OS(Str); OS << getState(); return OS.str(); } template static Optional askOtherAA(Attributor &A, const AbstractAttribute &AA, const IRPosition &IRP, Type &Ty) { if (isa(IRP.getAssociatedValue())) return &IRP.getAssociatedValue(); Optional C = askForAssumedConstant(A, AA, IRP, Ty); if (!C) return llvm::None; if (C.value()) if (auto *CC = AA::getWithType(**C, Ty)) return CC; return nullptr; } void addValue(Attributor &A, StateType &State, Value &V, const Instruction *CtxI, AA::ValueScope S, Function *AnchorScope) const { IRPosition ValIRP = IRPosition::value(V); if (auto *CB = dyn_cast_or_null(CtxI)) { for (auto &U : CB->args()) { if (U.get() != &V) continue; ValIRP = IRPosition::callsite_argument(*CB, CB->getArgOperandNo(&U)); break; } } Value *VPtr = &V; if (ValIRP.getAssociatedType()->isIntegerTy()) { Type &Ty = *getAssociatedType(); Optional SimpleV = askOtherAA(A, *this, ValIRP, Ty); if (SimpleV.has_value() && !SimpleV.value()) { auto &PotentialConstantsAA = A.getAAFor( *this, ValIRP, DepClassTy::OPTIONAL); if (PotentialConstantsAA.isValidState()) { for (auto &It : PotentialConstantsAA.getAssumedSet()) { State.unionAssumed({{*ConstantInt::get(&Ty, It), nullptr}, S}); } assert(!PotentialConstantsAA.undefIsContained() && "Undef should be an explicit value!"); return; } } if (!SimpleV.has_value()) return; if (SimpleV.value()) VPtr = SimpleV.value(); } if (isa(VPtr)) CtxI = nullptr; if (!AA::isValidInScope(*VPtr, AnchorScope)) S = AA::ValueScope(S | AA::Interprocedural); State.unionAssumed({{*VPtr, CtxI}, S}); } /// Helper struct to tie a value+context pair together with the scope for /// which this is the simplified version. struct ItemInfo { AA::ValueAndContext I; AA::ValueScope S; bool operator==(const ItemInfo &II) const { return II.I == I && II.S == S; }; bool operator<(const ItemInfo &II) const { if (I == II.I) return S < II.S; return I < II.I; }; }; bool recurseForValue(Attributor &A, const IRPosition &IRP, AA::ValueScope S) { SmallMapVector ValueScopeMap; for (auto CS : {AA::Intraprocedural, AA::Interprocedural}) { if (!(CS & S)) continue; bool UsedAssumedInformation = false; SmallVector Values; if (!A.getAssumedSimplifiedValues(IRP, this, Values, CS, UsedAssumedInformation)) return false; for (auto &It : Values) ValueScopeMap[It] += CS; } for (auto &It : ValueScopeMap) addValue(A, getState(), *It.first.getValue(), It.first.getCtxI(), AA::ValueScope(It.second), getAnchorScope()); return true; } void giveUpOnIntraprocedural(Attributor &A) { auto NewS = StateType::getBestState(getState()); for (auto &It : getAssumedSet()) { if (It.second == AA::Intraprocedural) continue; addValue(A, NewS, *It.first.getValue(), It.first.getCtxI(), AA::Interprocedural, getAnchorScope()); } assert(!undefIsContained() && "Undef should be an explicit value!"); addValue(A, NewS, getAssociatedValue(), getCtxI(), AA::Intraprocedural, getAnchorScope()); getState() = NewS; } /// See AbstractState::indicatePessimisticFixpoint(...). ChangeStatus indicatePessimisticFixpoint() override { getState() = StateType::getBestState(getState()); getState().unionAssumed({{getAssociatedValue(), getCtxI()}, AA::AnyScope}); AAPotentialValues::indicateOptimisticFixpoint(); return ChangeStatus::CHANGED; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { return indicatePessimisticFixpoint(); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { SmallVector Values; for (AA::ValueScope S : {AA::Interprocedural, AA::Intraprocedural}) { Values.clear(); if (!getAssumedSimplifiedValues(A, Values, S)) continue; Value &OldV = getAssociatedValue(); if (isa(OldV)) continue; Value *NewV = getSingleValue(A, *this, getIRPosition(), Values); if (!NewV || NewV == &OldV) continue; if (getCtxI() && !AA::isValidAtPosition({*NewV, *getCtxI()}, A.getInfoCache())) continue; if (A.changeAfterManifest(getIRPosition(), *NewV)) return ChangeStatus::CHANGED; } return ChangeStatus::UNCHANGED; } bool getAssumedSimplifiedValues(Attributor &A, SmallVectorImpl &Values, AA::ValueScope S) const override { if (!isValidState()) return false; for (auto &It : getAssumedSet()) if (It.second & S) Values.push_back(It.first); assert(!undefIsContained() && "Undef should be an explicit value!"); return true; } }; struct AAPotentialValuesFloating : AAPotentialValuesImpl { AAPotentialValuesFloating(const IRPosition &IRP, Attributor &A) : AAPotentialValuesImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { auto AssumedBefore = getAssumed(); genericValueTraversal(A); return (AssumedBefore == getAssumed()) ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } /// Helper struct to remember which AAIsDead instances we actually used. struct LivenessInfo { const AAIsDead *LivenessAA = nullptr; bool AnyDead = false; }; /// Check if \p Cmp is a comparison we can simplify. /// /// We handle multiple cases, one in which at least one operand is an /// (assumed) nullptr. If so, try to simplify it using AANonNull on the other /// operand. Return true if successful, in that case Worklist will be updated. bool handleCmp(Attributor &A, CmpInst &Cmp, ItemInfo II, SmallVectorImpl &Worklist) { Value *LHS = Cmp.getOperand(0); Value *RHS = Cmp.getOperand(1); // Simplify the operands first. bool UsedAssumedInformation = false; const auto &SimplifiedLHS = A.getAssumedSimplified( IRPosition::value(*LHS, getCallBaseContext()), *this, UsedAssumedInformation, AA::Intraprocedural); if (!SimplifiedLHS.has_value()) return true; if (!SimplifiedLHS.value()) return false; LHS = *SimplifiedLHS; const auto &SimplifiedRHS = A.getAssumedSimplified( IRPosition::value(*RHS, getCallBaseContext()), *this, UsedAssumedInformation, AA::Intraprocedural); if (!SimplifiedRHS.has_value()) return true; if (!SimplifiedRHS.value()) return false; RHS = *SimplifiedRHS; LLVMContext &Ctx = Cmp.getContext(); // Handle the trivial case first in which we don't even need to think about // null or non-null. if (LHS == RHS && (Cmp.isTrueWhenEqual() || Cmp.isFalseWhenEqual())) { Constant *NewV = ConstantInt::get(Type::getInt1Ty(Ctx), Cmp.isTrueWhenEqual()); addValue(A, getState(), *NewV, /* CtxI */ nullptr, II.S, getAnchorScope()); return true; } // From now on we only handle equalities (==, !=). ICmpInst *ICmp = dyn_cast(&Cmp); if (!ICmp || !ICmp->isEquality()) return false; bool LHSIsNull = isa(LHS); bool RHSIsNull = isa(RHS); if (!LHSIsNull && !RHSIsNull) return false; // Left is the nullptr ==/!= non-nullptr case. We'll use AANonNull on the // non-nullptr operand and if we assume it's non-null we can conclude the // result of the comparison. assert((LHSIsNull || RHSIsNull) && "Expected nullptr versus non-nullptr comparison at this point"); // The index is the operand that we assume is not null. unsigned PtrIdx = LHSIsNull; auto &PtrNonNullAA = A.getAAFor( *this, IRPosition::value(*ICmp->getOperand(PtrIdx)), DepClassTy::REQUIRED); if (!PtrNonNullAA.isAssumedNonNull()) return false; // The new value depends on the predicate, true for != and false for ==. Constant *NewV = ConstantInt::get(Type::getInt1Ty(Ctx), ICmp->getPredicate() == CmpInst::ICMP_NE); addValue(A, getState(), *NewV, /* CtxI */ nullptr, II.S, getAnchorScope()); return true; } bool handleSelectInst(Attributor &A, SelectInst &SI, ItemInfo II, SmallVectorImpl &Worklist) { const Instruction *CtxI = II.I.getCtxI(); bool UsedAssumedInformation = false; Optional C = A.getAssumedConstant(*SI.getCondition(), *this, UsedAssumedInformation); bool NoValueYet = !C.has_value(); if (NoValueYet || isa_and_nonnull(*C)) return true; if (auto *CI = dyn_cast_or_null(*C)) { if (CI->isZero()) Worklist.push_back({{*SI.getFalseValue(), CtxI}, II.S}); else Worklist.push_back({{*SI.getTrueValue(), CtxI}, II.S}); } else { // We could not simplify the condition, assume both values. Worklist.push_back({{*SI.getTrueValue(), CtxI}, II.S}); Worklist.push_back({{*SI.getFalseValue(), CtxI}, II.S}); } return true; } bool handleLoadInst(Attributor &A, LoadInst &LI, ItemInfo II, SmallVectorImpl &Worklist) { SmallSetVector PotentialCopies; SmallSetVector PotentialValueOrigins; bool UsedAssumedInformation = false; if (!AA::getPotentiallyLoadedValues(A, LI, PotentialCopies, PotentialValueOrigins, *this, UsedAssumedInformation, /* OnlyExact */ true)) { LLVM_DEBUG(dbgs() << "[AAPotentialValues] Failed to get potentially " "loaded values for load instruction " << LI << "\n"); return false; } // Do not simplify loads that are only used in llvm.assume if we cannot also // remove all stores that may feed into the load. The reason is that the // assume is probably worth something as long as the stores are around. InformationCache &InfoCache = A.getInfoCache(); if (InfoCache.isOnlyUsedByAssume(LI)) { if (!llvm::all_of(PotentialValueOrigins, [&](Instruction *I) { if (!I) return true; if (auto *SI = dyn_cast(I)) return A.isAssumedDead(SI->getOperandUse(0), this, /* LivenessAA */ nullptr, UsedAssumedInformation, /* CheckBBLivenessOnly */ false); return A.isAssumedDead(*I, this, /* LivenessAA */ nullptr, UsedAssumedInformation, /* CheckBBLivenessOnly */ false); })) { LLVM_DEBUG(dbgs() << "[AAPotentialValues] Load is onl used by assumes " "and we cannot delete all the stores: " << LI << "\n"); return false; } } // Values have to be dynamically unique or we loose the fact that a // single llvm::Value might represent two runtime values (e.g., // stack locations in different recursive calls). const Instruction *CtxI = II.I.getCtxI(); bool ScopeIsLocal = (II.S & AA::Intraprocedural); bool AllLocal = ScopeIsLocal; bool DynamicallyUnique = llvm::all_of(PotentialCopies, [&](Value *PC) { AllLocal &= AA::isValidInScope(*PC, getAnchorScope()); return AA::isDynamicallyUnique(A, *this, *PC); }); if (!DynamicallyUnique) { LLVM_DEBUG(dbgs() << "[AAPotentialValues] Not all potentially loaded " "values are dynamically unique: " << LI << "\n"); return false; } for (auto *PotentialCopy : PotentialCopies) { if (AllLocal) { Worklist.push_back({{*PotentialCopy, CtxI}, II.S}); } else { Worklist.push_back({{*PotentialCopy, CtxI}, AA::Interprocedural}); } } if (!AllLocal && ScopeIsLocal) addValue(A, getState(), LI, CtxI, AA::Intraprocedural, getAnchorScope()); return true; } bool handlePHINode( Attributor &A, PHINode &PHI, ItemInfo II, SmallVectorImpl &Worklist, SmallMapVector &LivenessAAs) { auto GetLivenessInfo = [&](const Function &F) -> LivenessInfo & { LivenessInfo &LI = LivenessAAs[&F]; if (!LI.LivenessAA) LI.LivenessAA = &A.getAAFor(*this, IRPosition::function(F), DepClassTy::NONE); return LI; }; LivenessInfo &LI = GetLivenessInfo(*PHI.getFunction()); for (unsigned u = 0, e = PHI.getNumIncomingValues(); u < e; u++) { BasicBlock *IncomingBB = PHI.getIncomingBlock(u); if (LI.LivenessAA->isEdgeDead(IncomingBB, PHI.getParent())) { LI.AnyDead = true; continue; } Worklist.push_back( {{*PHI.getIncomingValue(u), IncomingBB->getTerminator()}, II.S}); } return true; } /// Use the generic, non-optimistic InstSimplfy functionality if we managed to /// simplify any operand of the instruction \p I. Return true if successful, /// in that case Worklist will be updated. bool handleGenericInst(Attributor &A, Instruction &I, ItemInfo II, SmallVectorImpl &Worklist) { bool SomeSimplified = false; bool UsedAssumedInformation = false; SmallVector NewOps(I.getNumOperands()); int Idx = 0; for (Value *Op : I.operands()) { const auto &SimplifiedOp = A.getAssumedSimplified( IRPosition::value(*Op, getCallBaseContext()), *this, UsedAssumedInformation, AA::Intraprocedural); // If we are not sure about any operand we are not sure about the entire // instruction, we'll wait. if (!SimplifiedOp.has_value()) return true; if (SimplifiedOp.value()) NewOps[Idx] = SimplifiedOp.value(); else NewOps[Idx] = Op; SomeSimplified |= (NewOps[Idx] != Op); ++Idx; } // We won't bother with the InstSimplify interface if we didn't simplify any // operand ourselves. if (!SomeSimplified) return false; InformationCache &InfoCache = A.getInfoCache(); Function *F = I.getFunction(); const auto *DT = InfoCache.getAnalysisResultForFunction(*F); const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F); auto *AC = InfoCache.getAnalysisResultForFunction(*F); OptimizationRemarkEmitter *ORE = nullptr; const DataLayout &DL = I.getModule()->getDataLayout(); SimplifyQuery Q(DL, TLI, DT, AC, &I); Value *NewV = simplifyInstructionWithOperands(&I, NewOps, Q, ORE); if (!NewV || NewV == &I) return false; LLVM_DEBUG(dbgs() << "Generic inst " << I << " assumed simplified to " << *NewV << "\n"); Worklist.push_back({{*NewV, II.I.getCtxI()}, II.S}); return true; } bool simplifyInstruction( Attributor &A, Instruction &I, ItemInfo II, SmallVectorImpl &Worklist, SmallMapVector &LivenessAAs) { if (auto *CI = dyn_cast(&I)) if (handleCmp(A, *CI, II, Worklist)) return true; switch (I.getOpcode()) { case Instruction::Select: return handleSelectInst(A, cast(I), II, Worklist); case Instruction::PHI: return handlePHINode(A, cast(I), II, Worklist, LivenessAAs); case Instruction::Load: return handleLoadInst(A, cast(I), II, Worklist); default: return handleGenericInst(A, I, II, Worklist); }; return false; } void genericValueTraversal(Attributor &A) { SmallMapVector LivenessAAs; Value *InitialV = &getAssociatedValue(); SmallSet Visited; SmallVector Worklist; Worklist.push_back({{*InitialV, getCtxI()}, AA::AnyScope}); int Iteration = 0; do { ItemInfo II = Worklist.pop_back_val(); Value *V = II.I.getValue(); assert(V); const Instruction *CtxI = II.I.getCtxI(); AA::ValueScope S = II.S; // Check if we should process the current value. To prevent endless // recursion keep a record of the values we followed! if (!Visited.insert(II).second) continue; // Make sure we limit the compile time for complex expressions. if (Iteration++ >= MaxPotentialValuesIterations) { LLVM_DEBUG(dbgs() << "Generic value traversal reached iteration limit: " << Iteration << "!\n"); addValue(A, getState(), *V, CtxI, S, getAnchorScope()); continue; } // Explicitly look through calls with a "returned" attribute if we do // not have a pointer as stripPointerCasts only works on them. Value *NewV = nullptr; if (V->getType()->isPointerTy()) { NewV = AA::getWithType(*V->stripPointerCasts(), *V->getType()); } else { auto *CB = dyn_cast(V); if (CB && CB->getCalledFunction()) { for (Argument &Arg : CB->getCalledFunction()->args()) if (Arg.hasReturnedAttr()) { NewV = CB->getArgOperand(Arg.getArgNo()); break; } } } if (NewV && NewV != V) { Worklist.push_back({{*NewV, CtxI}, S}); continue; } if (auto *I = dyn_cast(V)) { if (simplifyInstruction(A, *I, II, Worklist, LivenessAAs)) continue; } if (V != InitialV || isa(V)) if (recurseForValue(A, IRPosition::value(*V), II.S)) continue; // If we haven't stripped anything we give up. if (V == InitialV && CtxI == getCtxI()) { indicatePessimisticFixpoint(); return; } addValue(A, getState(), *V, CtxI, S, getAnchorScope()); } while (!Worklist.empty()); // If we actually used liveness information so we have to record a // dependence. for (auto &It : LivenessAAs) if (It.second.AnyDead) A.recordDependence(*It.second.LivenessAA, *this, DepClassTy::OPTIONAL); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(potential_values) } }; struct AAPotentialValuesArgument final : AAPotentialValuesImpl { using Base = AAPotentialValuesImpl; AAPotentialValuesArgument(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::initialize(..). void initialize(Attributor &A) override { auto &Arg = cast(getAssociatedValue()); if (Arg.hasPointeeInMemoryValueAttr()) indicatePessimisticFixpoint(); } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { auto AssumedBefore = getAssumed(); unsigned CSArgNo = getCallSiteArgNo(); bool UsedAssumedInformation = false; SmallVector Values; auto CallSitePred = [&](AbstractCallSite ACS) { const auto CSArgIRP = IRPosition::callsite_argument(ACS, CSArgNo); if (CSArgIRP.getPositionKind() == IRP_INVALID) return false; if (!A.getAssumedSimplifiedValues(CSArgIRP, this, Values, AA::Interprocedural, UsedAssumedInformation)) return false; return isValidState(); }; if (!A.checkForAllCallSites(CallSitePred, *this, /* RequireAllCallSites */ true, UsedAssumedInformation)) return indicatePessimisticFixpoint(); Function *Fn = getAssociatedFunction(); bool AnyNonLocal = false; for (auto &It : Values) { if (isa(It.getValue())) { addValue(A, getState(), *It.getValue(), It.getCtxI(), AA::AnyScope, getAnchorScope()); continue; } if (!AA::isDynamicallyUnique(A, *this, *It.getValue())) return indicatePessimisticFixpoint(); if (auto *Arg = dyn_cast(It.getValue())) if (Arg->getParent() == Fn) { addValue(A, getState(), *It.getValue(), It.getCtxI(), AA::AnyScope, getAnchorScope()); continue; } addValue(A, getState(), *It.getValue(), It.getCtxI(), AA::Interprocedural, getAnchorScope()); AnyNonLocal = true; } if (undefIsContained()) unionAssumedWithUndef(); if (AnyNonLocal) giveUpOnIntraprocedural(A); return (AssumedBefore == getAssumed()) ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(potential_values) } }; struct AAPotentialValuesReturned : AAReturnedFromReturnedValues { using Base = AAReturnedFromReturnedValues; AAPotentialValuesReturned(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {} /// See AbstractAttribute::initialize(..). void initialize(Attributor &A) override { if (A.hasSimplificationCallback(getIRPosition())) indicatePessimisticFixpoint(); else AAPotentialValues::initialize(A); } ChangeStatus manifest(Attributor &A) override { // We queried AAValueSimplify for the returned values so they will be // replaced if a simplified form was found. Nothing to do here. return ChangeStatus::UNCHANGED; } ChangeStatus indicatePessimisticFixpoint() override { return AAPotentialValues::indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(potential_values) } }; struct AAPotentialValuesFunction : AAPotentialValuesImpl { AAPotentialValuesFunction(const IRPosition &IRP, Attributor &A) : AAPotentialValuesImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { llvm_unreachable("AAPotentialValues(Function|CallSite)::updateImpl will " "not be called"); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(potential_values) } }; struct AAPotentialValuesCallSite : AAPotentialValuesFunction { AAPotentialValuesCallSite(const IRPosition &IRP, Attributor &A) : AAPotentialValuesFunction(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(potential_values) } }; struct AAPotentialValuesCallSiteReturned : AAPotentialValuesImpl { AAPotentialValuesCallSiteReturned(const IRPosition &IRP, Attributor &A) : AAPotentialValuesImpl(IRP, A) {} /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { auto AssumedBefore = getAssumed(); Function *Callee = getAssociatedFunction(); if (!Callee) return indicatePessimisticFixpoint(); bool UsedAssumedInformation = false; auto *CB = cast(getCtxI()); if (CB->isMustTailCall() && !A.isAssumedDead(IRPosition::inst(*CB), this, nullptr, UsedAssumedInformation)) return indicatePessimisticFixpoint(); SmallVector Values; if (!A.getAssumedSimplifiedValues(IRPosition::returned(*Callee), this, Values, AA::Intraprocedural, UsedAssumedInformation)) return indicatePessimisticFixpoint(); Function *Caller = CB->getCaller(); bool AnyNonLocal = false; for (auto &It : Values) { Value *V = It.getValue(); Optional CallerV = A.translateArgumentToCallSiteContent( V, *CB, *this, UsedAssumedInformation); if (!CallerV.has_value()) { // Nothing to do as long as no value was determined. continue; } V = CallerV.value() ? CallerV.value() : V; if (AA::isDynamicallyUnique(A, *this, *V) && AA::isValidInScope(*V, Caller)) { if (CallerV.value()) { SmallVector ArgValues; IRPosition IRP = IRPosition::value(*V); if (auto *Arg = dyn_cast(V)) if (Arg->getParent() == CB->getCalledFunction()) IRP = IRPosition::callsite_argument(*CB, Arg->getArgNo()); if (recurseForValue(A, IRP, AA::AnyScope)) continue; } addValue(A, getState(), *V, CB, AA::AnyScope, getAnchorScope()); } else { AnyNonLocal = true; break; } } if (AnyNonLocal) { Values.clear(); if (!A.getAssumedSimplifiedValues(IRPosition::returned(*Callee), this, Values, AA::Interprocedural, UsedAssumedInformation)) return indicatePessimisticFixpoint(); AnyNonLocal = false; getState() = PotentialLLVMValuesState::getBestState(); for (auto &It : Values) { Value *V = It.getValue(); if (!AA::isDynamicallyUnique(A, *this, *V)) return indicatePessimisticFixpoint(); if (AA::isValidInScope(*V, Caller)) { addValue(A, getState(), *V, CB, AA::AnyScope, getAnchorScope()); } else { AnyNonLocal = true; addValue(A, getState(), *V, CB, AA::Interprocedural, getAnchorScope()); } } if (AnyNonLocal) giveUpOnIntraprocedural(A); } return (AssumedBefore == getAssumed()) ? ChangeStatus::UNCHANGED : ChangeStatus::CHANGED; } ChangeStatus indicatePessimisticFixpoint() override { return AAPotentialValues::indicatePessimisticFixpoint(); } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(potential_values) } }; struct AAPotentialValuesCallSiteArgument : AAPotentialValuesFloating { AAPotentialValuesCallSiteArgument(const IRPosition &IRP, Attributor &A) : AAPotentialValuesFloating(IRP, A) {} /// See AbstractAttribute::trackStatistics() void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(potential_values) } }; } // namespace /// ---------------------- Assumption Propagation ------------------------------ namespace { struct AAAssumptionInfoImpl : public AAAssumptionInfo { AAAssumptionInfoImpl(const IRPosition &IRP, Attributor &A, const DenseSet &Known) : AAAssumptionInfo(IRP, A, Known) {} bool hasAssumption(const StringRef Assumption) const override { return isValidState() && setContains(Assumption); } /// See AbstractAttribute::getAsStr() const std::string getAsStr() const override { const SetContents &Known = getKnown(); const SetContents &Assumed = getAssumed(); const std::string KnownStr = llvm::join(Known.getSet().begin(), Known.getSet().end(), ","); const std::string AssumedStr = (Assumed.isUniversal()) ? "Universal" : llvm::join(Assumed.getSet().begin(), Assumed.getSet().end(), ","); return "Known [" + KnownStr + "]," + " Assumed [" + AssumedStr + "]"; } }; /// Propagates assumption information from parent functions to all of their /// successors. An assumption can be propagated if the containing function /// dominates the called function. /// /// We start with a "known" set of assumptions already valid for the associated /// function and an "assumed" set that initially contains all possible /// assumptions. The assumed set is inter-procedurally updated by narrowing its /// contents as concrete values are known. The concrete values are seeded by the /// first nodes that are either entries into the call graph, or contains no /// assumptions. Each node is updated as the intersection of the assumed state /// with all of its predecessors. struct AAAssumptionInfoFunction final : AAAssumptionInfoImpl { AAAssumptionInfoFunction(const IRPosition &IRP, Attributor &A) : AAAssumptionInfoImpl(IRP, A, getAssumptions(*IRP.getAssociatedFunction())) {} /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { const auto &Assumptions = getKnown(); // Don't manifest a universal set if it somehow made it here. if (Assumptions.isUniversal()) return ChangeStatus::UNCHANGED; Function *AssociatedFunction = getAssociatedFunction(); bool Changed = addAssumptions(*AssociatedFunction, Assumptions.getSet()); return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { bool Changed = false; auto CallSitePred = [&](AbstractCallSite ACS) { const auto &AssumptionAA = A.getAAFor( *this, IRPosition::callsite_function(*ACS.getInstruction()), DepClassTy::REQUIRED); // Get the set of assumptions shared by all of this function's callers. Changed |= getIntersection(AssumptionAA.getAssumed()); return !getAssumed().empty() || !getKnown().empty(); }; bool UsedAssumedInformation = false; // Get the intersection of all assumptions held by this node's predecessors. // If we don't know all the call sites then this is either an entry into the // call graph or an empty node. This node is known to only contain its own // assumptions and can be propagated to its successors. if (!A.checkForAllCallSites(CallSitePred, *this, true, UsedAssumedInformation)) return indicatePessimisticFixpoint(); return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } void trackStatistics() const override {} }; /// Assumption Info defined for call sites. struct AAAssumptionInfoCallSite final : AAAssumptionInfoImpl { AAAssumptionInfoCallSite(const IRPosition &IRP, Attributor &A) : AAAssumptionInfoImpl(IRP, A, getInitialAssumptions(IRP)) {} /// See AbstractAttribute::initialize(...). void initialize(Attributor &A) override { const IRPosition &FnPos = IRPosition::function(*getAnchorScope()); A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); } /// See AbstractAttribute::manifest(...). ChangeStatus manifest(Attributor &A) override { // Don't manifest a universal set if it somehow made it here. if (getKnown().isUniversal()) return ChangeStatus::UNCHANGED; CallBase &AssociatedCall = cast(getAssociatedValue()); bool Changed = addAssumptions(AssociatedCall, getAssumed().getSet()); return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } /// See AbstractAttribute::updateImpl(...). ChangeStatus updateImpl(Attributor &A) override { const IRPosition &FnPos = IRPosition::function(*getAnchorScope()); auto &AssumptionAA = A.getAAFor(*this, FnPos, DepClassTy::REQUIRED); bool Changed = getIntersection(AssumptionAA.getAssumed()); return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED; } /// See AbstractAttribute::trackStatistics() void trackStatistics() const override {} private: /// Helper to initialized the known set as all the assumptions this call and /// the callee contain. DenseSet getInitialAssumptions(const IRPosition &IRP) { const CallBase &CB = cast(IRP.getAssociatedValue()); auto Assumptions = getAssumptions(CB); if (Function *F = IRP.getAssociatedFunction()) set_union(Assumptions, getAssumptions(*F)); if (Function *F = IRP.getAssociatedFunction()) set_union(Assumptions, getAssumptions(*F)); return Assumptions; } }; } // namespace AACallGraphNode *AACallEdgeIterator::operator*() const { return static_cast(const_cast( &A.getOrCreateAAFor(IRPosition::function(**I)))); } void AttributorCallGraph::print() { llvm::WriteGraph(outs(), this); } const char AAReturnedValues::ID = 0; const char AANoUnwind::ID = 0; const char AANoSync::ID = 0; const char AANoFree::ID = 0; const char AANonNull::ID = 0; const char AANoRecurse::ID = 0; const char AAWillReturn::ID = 0; const char AAUndefinedBehavior::ID = 0; const char AANoAlias::ID = 0; const char AAReachability::ID = 0; const char AANoReturn::ID = 0; const char AAIsDead::ID = 0; const char AADereferenceable::ID = 0; const char AAAlign::ID = 0; const char AAInstanceInfo::ID = 0; const char AANoCapture::ID = 0; const char AAValueSimplify::ID = 0; const char AAHeapToStack::ID = 0; const char AAPrivatizablePtr::ID = 0; const char AAMemoryBehavior::ID = 0; const char AAMemoryLocation::ID = 0; const char AAValueConstantRange::ID = 0; const char AAPotentialConstantValues::ID = 0; const char AAPotentialValues::ID = 0; const char AANoUndef::ID = 0; const char AACallEdges::ID = 0; const char AAFunctionReachability::ID = 0; const char AAPointerInfo::ID = 0; const char AAAssumptionInfo::ID = 0; // Macro magic to create the static generator function for attributes that // follow the naming scheme. #define SWITCH_PK_INV(CLASS, PK, POS_NAME) \ case IRPosition::PK: \ llvm_unreachable("Cannot create " #CLASS " for a " POS_NAME " position!"); #define SWITCH_PK_CREATE(CLASS, IRP, PK, SUFFIX) \ case IRPosition::PK: \ AA = new (A.Allocator) CLASS##SUFFIX(IRP, A); \ ++NumAAs; \ break; #define CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS) \ CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) { \ CLASS *AA = nullptr; \ switch (IRP.getPositionKind()) { \ SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid") \ SWITCH_PK_INV(CLASS, IRP_FLOAT, "floating") \ SWITCH_PK_INV(CLASS, IRP_ARGUMENT, "argument") \ SWITCH_PK_INV(CLASS, IRP_RETURNED, "returned") \ SWITCH_PK_INV(CLASS, IRP_CALL_SITE_RETURNED, "call site returned") \ SWITCH_PK_INV(CLASS, IRP_CALL_SITE_ARGUMENT, "call site argument") \ SWITCH_PK_CREATE(CLASS, IRP, IRP_FUNCTION, Function) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE, CallSite) \ } \ return *AA; \ } #define CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS) \ CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) { \ CLASS *AA = nullptr; \ switch (IRP.getPositionKind()) { \ SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid") \ SWITCH_PK_INV(CLASS, IRP_FUNCTION, "function") \ SWITCH_PK_INV(CLASS, IRP_CALL_SITE, "call site") \ SWITCH_PK_CREATE(CLASS, IRP, IRP_FLOAT, Floating) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_ARGUMENT, Argument) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_RETURNED, Returned) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_RETURNED, CallSiteReturned) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_ARGUMENT, CallSiteArgument) \ } \ return *AA; \ } #define CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS) \ CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) { \ CLASS *AA = nullptr; \ switch (IRP.getPositionKind()) { \ SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid") \ SWITCH_PK_CREATE(CLASS, IRP, IRP_FUNCTION, Function) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE, CallSite) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_FLOAT, Floating) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_ARGUMENT, Argument) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_RETURNED, Returned) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_RETURNED, CallSiteReturned) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_ARGUMENT, CallSiteArgument) \ } \ return *AA; \ } #define CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS) \ CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) { \ CLASS *AA = nullptr; \ switch (IRP.getPositionKind()) { \ SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid") \ SWITCH_PK_INV(CLASS, IRP_ARGUMENT, "argument") \ SWITCH_PK_INV(CLASS, IRP_FLOAT, "floating") \ SWITCH_PK_INV(CLASS, IRP_RETURNED, "returned") \ SWITCH_PK_INV(CLASS, IRP_CALL_SITE_RETURNED, "call site returned") \ SWITCH_PK_INV(CLASS, IRP_CALL_SITE_ARGUMENT, "call site argument") \ SWITCH_PK_INV(CLASS, IRP_CALL_SITE, "call site") \ SWITCH_PK_CREATE(CLASS, IRP, IRP_FUNCTION, Function) \ } \ return *AA; \ } #define CREATE_NON_RET_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS) \ CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) { \ CLASS *AA = nullptr; \ switch (IRP.getPositionKind()) { \ SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid") \ SWITCH_PK_INV(CLASS, IRP_RETURNED, "returned") \ SWITCH_PK_CREATE(CLASS, IRP, IRP_FUNCTION, Function) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE, CallSite) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_FLOAT, Floating) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_ARGUMENT, Argument) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_RETURNED, CallSiteReturned) \ SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_ARGUMENT, CallSiteArgument) \ } \ return *AA; \ } CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoUnwind) CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoSync) CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoRecurse) CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAWillReturn) CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoReturn) CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAReturnedValues) CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAMemoryLocation) CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AACallEdges) CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAAssumptionInfo) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANonNull) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoAlias) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAPrivatizablePtr) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AADereferenceable) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAAlign) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAInstanceInfo) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoCapture) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAValueConstantRange) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAPotentialConstantValues) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAPotentialValues) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoUndef) CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAPointerInfo) CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAValueSimplify) CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAIsDead) CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoFree) CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAHeapToStack) CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAReachability) CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAUndefinedBehavior) CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAFunctionReachability) CREATE_NON_RET_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAMemoryBehavior) #undef CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION #undef CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION #undef CREATE_NON_RET_ABSTRACT_ATTRIBUTE_FOR_POSITION #undef CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION #undef CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION #undef SWITCH_PK_CREATE #undef SWITCH_PK_INV