//===- Metadata.cpp - Implement Metadata classes --------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements the Metadata classes. // //===----------------------------------------------------------------------===// #include "llvm/IR/Metadata.h" #include "LLVMContextImpl.h" #include "MetadataImpl.h" #include "SymbolTableListTraitsImpl.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SmallSet.h" #include "llvm/ADT/StringMap.h" #include "llvm/IR/ConstantRange.h" #include "llvm/IR/DebugInfoMetadata.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/LLVMContext.h" #include "llvm/IR/Module.h" #include "llvm/IR/ValueHandle.h" using namespace llvm; MetadataAsValue::MetadataAsValue(Type *Ty, Metadata *MD) : Value(Ty, MetadataAsValueVal), MD(MD) { track(); } MetadataAsValue::~MetadataAsValue() { getType()->getContext().pImpl->MetadataAsValues.erase(MD); untrack(); } /// Canonicalize metadata arguments to intrinsics. /// /// To support bitcode upgrades (and assembly semantic sugar) for \a /// MetadataAsValue, we need to canonicalize certain metadata. /// /// - nullptr is replaced by an empty MDNode. /// - An MDNode with a single null operand is replaced by an empty MDNode. /// - An MDNode whose only operand is a \a ConstantAsMetadata gets skipped. /// /// This maintains readability of bitcode from when metadata was a type of /// value, and these bridges were unnecessary. static Metadata *canonicalizeMetadataForValue(LLVMContext &Context, Metadata *MD) { if (!MD) // !{} return MDNode::get(Context, None); // Return early if this isn't a single-operand MDNode. auto *N = dyn_cast(MD); if (!N || N->getNumOperands() != 1) return MD; if (!N->getOperand(0)) // !{} return MDNode::get(Context, None); if (auto *C = dyn_cast(N->getOperand(0))) // Look through the MDNode. return C; return MD; } MetadataAsValue *MetadataAsValue::get(LLVMContext &Context, Metadata *MD) { MD = canonicalizeMetadataForValue(Context, MD); auto *&Entry = Context.pImpl->MetadataAsValues[MD]; if (!Entry) Entry = new MetadataAsValue(Type::getMetadataTy(Context), MD); return Entry; } MetadataAsValue *MetadataAsValue::getIfExists(LLVMContext &Context, Metadata *MD) { MD = canonicalizeMetadataForValue(Context, MD); auto &Store = Context.pImpl->MetadataAsValues; return Store.lookup(MD); } void MetadataAsValue::handleChangedMetadata(Metadata *MD) { LLVMContext &Context = getContext(); MD = canonicalizeMetadataForValue(Context, MD); auto &Store = Context.pImpl->MetadataAsValues; // Stop tracking the old metadata. Store.erase(this->MD); untrack(); this->MD = nullptr; // Start tracking MD, or RAUW if necessary. auto *&Entry = Store[MD]; if (Entry) { replaceAllUsesWith(Entry); delete this; return; } this->MD = MD; track(); Entry = this; } void MetadataAsValue::track() { if (MD) MetadataTracking::track(&MD, *MD, *this); } void MetadataAsValue::untrack() { if (MD) MetadataTracking::untrack(MD); } bool MetadataTracking::track(void *Ref, Metadata &MD, OwnerTy Owner) { assert(Ref && "Expected live reference"); assert((Owner || *static_cast(Ref) == &MD) && "Reference without owner must be direct"); if (auto *R = ReplaceableMetadataImpl::getOrCreate(MD)) { R->addRef(Ref, Owner); return true; } return false; } void MetadataTracking::untrack(void *Ref, Metadata &MD) { assert(Ref && "Expected live reference"); if (auto *R = ReplaceableMetadataImpl::getIfExists(MD)) R->dropRef(Ref); } bool MetadataTracking::retrack(void *Ref, Metadata &MD, void *New) { assert(Ref && "Expected live reference"); assert(New && "Expected live reference"); assert(Ref != New && "Expected change"); if (auto *R = ReplaceableMetadataImpl::getIfExists(MD)) { R->moveRef(Ref, New, MD); return true; } assert(!isReplaceable(MD) && "Expected un-replaceable metadata, since we didn't move a reference"); return false; } bool MetadataTracking::isReplaceable(const Metadata &MD) { return ReplaceableMetadataImpl::isReplaceable(MD); } void ReplaceableMetadataImpl::addRef(void *Ref, OwnerTy Owner) { bool WasInserted = UseMap.insert(std::make_pair(Ref, std::make_pair(Owner, NextIndex))) .second; (void)WasInserted; assert(WasInserted && "Expected to add a reference"); ++NextIndex; assert(NextIndex != 0 && "Unexpected overflow"); } void ReplaceableMetadataImpl::dropRef(void *Ref) { bool WasErased = UseMap.erase(Ref); (void)WasErased; assert(WasErased && "Expected to drop a reference"); } void ReplaceableMetadataImpl::moveRef(void *Ref, void *New, const Metadata &MD) { auto I = UseMap.find(Ref); assert(I != UseMap.end() && "Expected to move a reference"); auto OwnerAndIndex = I->second; UseMap.erase(I); bool WasInserted = UseMap.insert(std::make_pair(New, OwnerAndIndex)).second; (void)WasInserted; assert(WasInserted && "Expected to add a reference"); // Check that the references are direct if there's no owner. (void)MD; assert((OwnerAndIndex.first || *static_cast(Ref) == &MD) && "Reference without owner must be direct"); assert((OwnerAndIndex.first || *static_cast(New) == &MD) && "Reference without owner must be direct"); } void ReplaceableMetadataImpl::replaceAllUsesWith(Metadata *MD) { if (UseMap.empty()) return; // Copy out uses since UseMap will get touched below. typedef std::pair> UseTy; SmallVector Uses(UseMap.begin(), UseMap.end()); std::sort(Uses.begin(), Uses.end(), [](const UseTy &L, const UseTy &R) { return L.second.second < R.second.second; }); for (const auto &Pair : Uses) { // Check that this Ref hasn't disappeared after RAUW (when updating a // previous Ref). if (!UseMap.count(Pair.first)) continue; OwnerTy Owner = Pair.second.first; if (!Owner) { // Update unowned tracking references directly. Metadata *&Ref = *static_cast(Pair.first); Ref = MD; if (MD) MetadataTracking::track(Ref); UseMap.erase(Pair.first); continue; } // Check for MetadataAsValue. if (Owner.is()) { Owner.get()->handleChangedMetadata(MD); continue; } // There's a Metadata owner -- dispatch. Metadata *OwnerMD = Owner.get(); switch (OwnerMD->getMetadataID()) { #define HANDLE_METADATA_LEAF(CLASS) \ case Metadata::CLASS##Kind: \ cast(OwnerMD)->handleChangedOperand(Pair.first, MD); \ continue; #include "llvm/IR/Metadata.def" default: llvm_unreachable("Invalid metadata subclass"); } } assert(UseMap.empty() && "Expected all uses to be replaced"); } void ReplaceableMetadataImpl::resolveAllUses(bool ResolveUsers) { if (UseMap.empty()) return; if (!ResolveUsers) { UseMap.clear(); return; } // Copy out uses since UseMap could get touched below. typedef std::pair> UseTy; SmallVector Uses(UseMap.begin(), UseMap.end()); std::sort(Uses.begin(), Uses.end(), [](const UseTy &L, const UseTy &R) { return L.second.second < R.second.second; }); UseMap.clear(); for (const auto &Pair : Uses) { auto Owner = Pair.second.first; if (!Owner) continue; if (Owner.is()) continue; // Resolve MDNodes that point at this. auto *OwnerMD = dyn_cast(Owner.get()); if (!OwnerMD) continue; if (OwnerMD->isResolved()) continue; OwnerMD->decrementUnresolvedOperandCount(); } } ReplaceableMetadataImpl *ReplaceableMetadataImpl::getOrCreate(Metadata &MD) { if (auto *N = dyn_cast(&MD)) return N->isResolved() ? nullptr : N->Context.getOrCreateReplaceableUses(); return dyn_cast(&MD); } ReplaceableMetadataImpl *ReplaceableMetadataImpl::getIfExists(Metadata &MD) { if (auto *N = dyn_cast(&MD)) return N->isResolved() ? nullptr : N->Context.getReplaceableUses(); return dyn_cast(&MD); } bool ReplaceableMetadataImpl::isReplaceable(const Metadata &MD) { if (auto *N = dyn_cast(&MD)) return !N->isResolved(); return dyn_cast(&MD); } static Function *getLocalFunction(Value *V) { assert(V && "Expected value"); if (auto *A = dyn_cast(V)) return A->getParent(); if (BasicBlock *BB = cast(V)->getParent()) return BB->getParent(); return nullptr; } ValueAsMetadata *ValueAsMetadata::get(Value *V) { assert(V && "Unexpected null Value"); auto &Context = V->getContext(); auto *&Entry = Context.pImpl->ValuesAsMetadata[V]; if (!Entry) { assert((isa(V) || isa(V) || isa(V)) && "Expected constant or function-local value"); assert(!V->IsUsedByMD && "Expected this to be the only metadata use"); V->IsUsedByMD = true; if (auto *C = dyn_cast(V)) Entry = new ConstantAsMetadata(C); else Entry = new LocalAsMetadata(V); } return Entry; } ValueAsMetadata *ValueAsMetadata::getIfExists(Value *V) { assert(V && "Unexpected null Value"); return V->getContext().pImpl->ValuesAsMetadata.lookup(V); } void ValueAsMetadata::handleDeletion(Value *V) { assert(V && "Expected valid value"); auto &Store = V->getType()->getContext().pImpl->ValuesAsMetadata; auto I = Store.find(V); if (I == Store.end()) return; // Remove old entry from the map. ValueAsMetadata *MD = I->second; assert(MD && "Expected valid metadata"); assert(MD->getValue() == V && "Expected valid mapping"); Store.erase(I); // Delete the metadata. MD->replaceAllUsesWith(nullptr); delete MD; } void ValueAsMetadata::handleRAUW(Value *From, Value *To) { assert(From && "Expected valid value"); assert(To && "Expected valid value"); assert(From != To && "Expected changed value"); assert(From->getType() == To->getType() && "Unexpected type change"); LLVMContext &Context = From->getType()->getContext(); auto &Store = Context.pImpl->ValuesAsMetadata; auto I = Store.find(From); if (I == Store.end()) { assert(!From->IsUsedByMD && "Expected From not to be used by metadata"); return; } // Remove old entry from the map. assert(From->IsUsedByMD && "Expected From to be used by metadata"); From->IsUsedByMD = false; ValueAsMetadata *MD = I->second; assert(MD && "Expected valid metadata"); assert(MD->getValue() == From && "Expected valid mapping"); Store.erase(I); if (isa(MD)) { if (auto *C = dyn_cast(To)) { // Local became a constant. MD->replaceAllUsesWith(ConstantAsMetadata::get(C)); delete MD; return; } if (getLocalFunction(From) && getLocalFunction(To) && getLocalFunction(From) != getLocalFunction(To)) { // Function changed. MD->replaceAllUsesWith(nullptr); delete MD; return; } } else if (!isa(To)) { // Changed to function-local value. MD->replaceAllUsesWith(nullptr); delete MD; return; } auto *&Entry = Store[To]; if (Entry) { // The target already exists. MD->replaceAllUsesWith(Entry); delete MD; return; } // Update MD in place (and update the map entry). assert(!To->IsUsedByMD && "Expected this to be the only metadata use"); To->IsUsedByMD = true; MD->V = To; Entry = MD; } //===----------------------------------------------------------------------===// // MDString implementation. // MDString *MDString::get(LLVMContext &Context, StringRef Str) { auto &Store = Context.pImpl->MDStringCache; auto I = Store.emplace_second(Str); auto &MapEntry = I.first->getValue(); if (!I.second) return &MapEntry; MapEntry.Entry = &*I.first; return &MapEntry; } StringRef MDString::getString() const { assert(Entry && "Expected to find string map entry"); return Entry->first(); } //===----------------------------------------------------------------------===// // MDNode implementation. // // Assert that the MDNode types will not be unaligned by the objects // prepended to them. #define HANDLE_MDNODE_LEAF(CLASS) \ static_assert( \ llvm::AlignOf::Alignment >= llvm::AlignOf::Alignment, \ "Alignment is insufficient after objects prepended to " #CLASS); #include "llvm/IR/Metadata.def" void *MDNode::operator new(size_t Size, unsigned NumOps) { size_t OpSize = NumOps * sizeof(MDOperand); // uint64_t is the most aligned type we need support (ensured by static_assert // above) OpSize = alignTo(OpSize, llvm::alignOf()); void *Ptr = reinterpret_cast(::operator new(OpSize + Size)) + OpSize; MDOperand *O = static_cast(Ptr); for (MDOperand *E = O - NumOps; O != E; --O) (void)new (O - 1) MDOperand; return Ptr; } void MDNode::operator delete(void *Mem) { MDNode *N = static_cast(Mem); size_t OpSize = N->NumOperands * sizeof(MDOperand); OpSize = alignTo(OpSize, llvm::alignOf()); MDOperand *O = static_cast(Mem); for (MDOperand *E = O - N->NumOperands; O != E; --O) (O - 1)->~MDOperand(); ::operator delete(reinterpret_cast(Mem) - OpSize); } MDNode::MDNode(LLVMContext &Context, unsigned ID, StorageType Storage, ArrayRef Ops1, ArrayRef Ops2) : Metadata(ID, Storage), NumOperands(Ops1.size() + Ops2.size()), NumUnresolved(0), Context(Context) { unsigned Op = 0; for (Metadata *MD : Ops1) setOperand(Op++, MD); for (Metadata *MD : Ops2) setOperand(Op++, MD); if (!isUniqued()) return; // Count the unresolved operands. If there are any, RAUW support will be // added lazily on first reference. countUnresolvedOperands(); } TempMDNode MDNode::clone() const { switch (getMetadataID()) { default: llvm_unreachable("Invalid MDNode subclass"); #define HANDLE_MDNODE_LEAF(CLASS) \ case CLASS##Kind: \ return cast(this)->cloneImpl(); #include "llvm/IR/Metadata.def" } } static bool isOperandUnresolved(Metadata *Op) { if (auto *N = dyn_cast_or_null(Op)) return !N->isResolved(); return false; } void MDNode::countUnresolvedOperands() { assert(NumUnresolved == 0 && "Expected unresolved ops to be uncounted"); assert(isUniqued() && "Expected this to be uniqued"); NumUnresolved = std::count_if(op_begin(), op_end(), isOperandUnresolved); } void MDNode::makeUniqued() { assert(isTemporary() && "Expected this to be temporary"); assert(!isResolved() && "Expected this to be unresolved"); // Enable uniquing callbacks. for (auto &Op : mutable_operands()) Op.reset(Op.get(), this); // Make this 'uniqued'. Storage = Uniqued; countUnresolvedOperands(); if (!NumUnresolved) { dropReplaceableUses(); assert(isResolved() && "Expected this to be resolved"); } assert(isUniqued() && "Expected this to be uniqued"); } void MDNode::makeDistinct() { assert(isTemporary() && "Expected this to be temporary"); assert(!isResolved() && "Expected this to be unresolved"); // Drop RAUW support and store as a distinct node. dropReplaceableUses(); storeDistinctInContext(); assert(isDistinct() && "Expected this to be distinct"); assert(isResolved() && "Expected this to be resolved"); } void MDNode::resolve() { assert(isUniqued() && "Expected this to be uniqued"); assert(!isResolved() && "Expected this to be unresolved"); NumUnresolved = 0; dropReplaceableUses(); assert(isResolved() && "Expected this to be resolved"); } void MDNode::dropReplaceableUses() { assert(!NumUnresolved && "Unexpected unresolved operand"); // Drop any RAUW support. if (Context.hasReplaceableUses()) Context.takeReplaceableUses()->resolveAllUses(); } void MDNode::resolveAfterOperandChange(Metadata *Old, Metadata *New) { assert(isUniqued() && "Expected this to be uniqued"); assert(NumUnresolved != 0 && "Expected unresolved operands"); // Check if an operand was resolved. if (!isOperandUnresolved(Old)) { if (isOperandUnresolved(New)) // An operand was un-resolved! ++NumUnresolved; } else if (!isOperandUnresolved(New)) decrementUnresolvedOperandCount(); } void MDNode::decrementUnresolvedOperandCount() { assert(!isResolved() && "Expected this to be unresolved"); if (isTemporary()) return; assert(isUniqued() && "Expected this to be uniqued"); if (--NumUnresolved) return; // Last unresolved operand has just been resolved. dropReplaceableUses(); assert(isResolved() && "Expected this to become resolved"); } void MDNode::resolveCycles() { if (isResolved()) return; // Resolve this node immediately. resolve(); // Resolve all operands. for (const auto &Op : operands()) { auto *N = dyn_cast_or_null(Op); if (!N) continue; assert(!N->isTemporary() && "Expected all forward declarations to be resolved"); if (!N->isResolved()) N->resolveCycles(); } } static bool hasSelfReference(MDNode *N) { for (Metadata *MD : N->operands()) if (MD == N) return true; return false; } MDNode *MDNode::replaceWithPermanentImpl() { switch (getMetadataID()) { default: // If this type isn't uniquable, replace with a distinct node. return replaceWithDistinctImpl(); #define HANDLE_MDNODE_LEAF_UNIQUABLE(CLASS) \ case CLASS##Kind: \ break; #include "llvm/IR/Metadata.def" } // Even if this type is uniquable, self-references have to be distinct. if (hasSelfReference(this)) return replaceWithDistinctImpl(); return replaceWithUniquedImpl(); } MDNode *MDNode::replaceWithUniquedImpl() { // Try to uniquify in place. MDNode *UniquedNode = uniquify(); if (UniquedNode == this) { makeUniqued(); return this; } // Collision, so RAUW instead. replaceAllUsesWith(UniquedNode); deleteAsSubclass(); return UniquedNode; } MDNode *MDNode::replaceWithDistinctImpl() { makeDistinct(); return this; } void MDTuple::recalculateHash() { setHash(MDTupleInfo::KeyTy::calculateHash(this)); } void MDNode::dropAllReferences() { for (unsigned I = 0, E = NumOperands; I != E; ++I) setOperand(I, nullptr); if (Context.hasReplaceableUses()) { Context.getReplaceableUses()->resolveAllUses(/* ResolveUsers */ false); (void)Context.takeReplaceableUses(); } } void MDNode::handleChangedOperand(void *Ref, Metadata *New) { unsigned Op = static_cast(Ref) - op_begin(); assert(Op < getNumOperands() && "Expected valid operand"); if (!isUniqued()) { // This node is not uniqued. Just set the operand and be done with it. setOperand(Op, New); return; } // This node is uniqued. eraseFromStore(); Metadata *Old = getOperand(Op); setOperand(Op, New); // Drop uniquing for self-reference cycles. if (New == this) { if (!isResolved()) resolve(); storeDistinctInContext(); return; } // Re-unique the node. auto *Uniqued = uniquify(); if (Uniqued == this) { if (!isResolved()) resolveAfterOperandChange(Old, New); return; } // Collision. if (!isResolved()) { // Still unresolved, so RAUW. // // First, clear out all operands to prevent any recursion (similar to // dropAllReferences(), but we still need the use-list). for (unsigned O = 0, E = getNumOperands(); O != E; ++O) setOperand(O, nullptr); if (Context.hasReplaceableUses()) Context.getReplaceableUses()->replaceAllUsesWith(Uniqued); deleteAsSubclass(); return; } // Store in non-uniqued form if RAUW isn't possible. storeDistinctInContext(); } void MDNode::deleteAsSubclass() { switch (getMetadataID()) { default: llvm_unreachable("Invalid subclass of MDNode"); #define HANDLE_MDNODE_LEAF(CLASS) \ case CLASS##Kind: \ delete cast(this); \ break; #include "llvm/IR/Metadata.def" } } template static T *uniquifyImpl(T *N, DenseSet &Store) { if (T *U = getUniqued(Store, N)) return U; Store.insert(N); return N; } template struct MDNode::HasCachedHash { typedef char Yes[1]; typedef char No[2]; template struct SFINAE {}; template static Yes &check(SFINAE *); template static No &check(...); static const bool value = sizeof(check(nullptr)) == sizeof(Yes); }; MDNode *MDNode::uniquify() { assert(!hasSelfReference(this) && "Cannot uniquify a self-referencing node"); // Try to insert into uniquing store. switch (getMetadataID()) { default: llvm_unreachable("Invalid or non-uniquable subclass of MDNode"); #define HANDLE_MDNODE_LEAF_UNIQUABLE(CLASS) \ case CLASS##Kind: { \ CLASS *SubclassThis = cast(this); \ std::integral_constant::value> \ ShouldRecalculateHash; \ dispatchRecalculateHash(SubclassThis, ShouldRecalculateHash); \ return uniquifyImpl(SubclassThis, getContext().pImpl->CLASS##s); \ } #include "llvm/IR/Metadata.def" } } void MDNode::eraseFromStore() { switch (getMetadataID()) { default: llvm_unreachable("Invalid or non-uniquable subclass of MDNode"); #define HANDLE_MDNODE_LEAF_UNIQUABLE(CLASS) \ case CLASS##Kind: \ getContext().pImpl->CLASS##s.erase(cast(this)); \ break; #include "llvm/IR/Metadata.def" } } MDTuple *MDTuple::getImpl(LLVMContext &Context, ArrayRef MDs, StorageType Storage, bool ShouldCreate) { unsigned Hash = 0; if (Storage == Uniqued) { MDTupleInfo::KeyTy Key(MDs); if (auto *N = getUniqued(Context.pImpl->MDTuples, Key)) return N; if (!ShouldCreate) return nullptr; Hash = Key.getHash(); } else { assert(ShouldCreate && "Expected non-uniqued nodes to always be created"); } return storeImpl(new (MDs.size()) MDTuple(Context, Storage, Hash, MDs), Storage, Context.pImpl->MDTuples); } void MDNode::deleteTemporary(MDNode *N) { assert(N->isTemporary() && "Expected temporary node"); N->replaceAllUsesWith(nullptr); N->deleteAsSubclass(); } void MDNode::storeDistinctInContext() { assert(!Context.hasReplaceableUses() && "Unexpected replaceable uses"); assert(!NumUnresolved && "Unexpected unresolved nodes"); Storage = Distinct; assert(isResolved() && "Expected this to be resolved"); // Reset the hash. switch (getMetadataID()) { default: llvm_unreachable("Invalid subclass of MDNode"); #define HANDLE_MDNODE_LEAF(CLASS) \ case CLASS##Kind: { \ std::integral_constant::value> ShouldResetHash; \ dispatchResetHash(cast(this), ShouldResetHash); \ break; \ } #include "llvm/IR/Metadata.def" } getContext().pImpl->DistinctMDNodes.push_back(this); } void MDNode::replaceOperandWith(unsigned I, Metadata *New) { if (getOperand(I) == New) return; if (!isUniqued()) { setOperand(I, New); return; } handleChangedOperand(mutable_begin() + I, New); } void MDNode::setOperand(unsigned I, Metadata *New) { assert(I < NumOperands); mutable_begin()[I].reset(New, isUniqued() ? this : nullptr); } /// Get a node or a self-reference that looks like it. /// /// Special handling for finding self-references, for use by \a /// MDNode::concatenate() and \a MDNode::intersect() to maintain behaviour from /// when self-referencing nodes were still uniqued. If the first operand has /// the same operands as \c Ops, return the first operand instead. static MDNode *getOrSelfReference(LLVMContext &Context, ArrayRef Ops) { if (!Ops.empty()) if (MDNode *N = dyn_cast_or_null(Ops[0])) if (N->getNumOperands() == Ops.size() && N == N->getOperand(0)) { for (unsigned I = 1, E = Ops.size(); I != E; ++I) if (Ops[I] != N->getOperand(I)) return MDNode::get(Context, Ops); return N; } return MDNode::get(Context, Ops); } MDNode *MDNode::concatenate(MDNode *A, MDNode *B) { if (!A) return B; if (!B) return A; SmallVector MDs; MDs.reserve(A->getNumOperands() + B->getNumOperands()); MDs.append(A->op_begin(), A->op_end()); MDs.append(B->op_begin(), B->op_end()); // FIXME: This preserves long-standing behaviour, but is it really the right // behaviour? Or was that an unintended side-effect of node uniquing? return getOrSelfReference(A->getContext(), MDs); } MDNode *MDNode::intersect(MDNode *A, MDNode *B) { if (!A || !B) return nullptr; SmallVector MDs; for (Metadata *MD : A->operands()) if (std::find(B->op_begin(), B->op_end(), MD) != B->op_end()) MDs.push_back(MD); // FIXME: This preserves long-standing behaviour, but is it really the right // behaviour? Or was that an unintended side-effect of node uniquing? return getOrSelfReference(A->getContext(), MDs); } MDNode *MDNode::getMostGenericAliasScope(MDNode *A, MDNode *B) { if (!A || !B) return nullptr; SmallVector MDs(B->op_begin(), B->op_end()); for (Metadata *MD : A->operands()) if (std::find(B->op_begin(), B->op_end(), MD) == B->op_end()) MDs.push_back(MD); // FIXME: This preserves long-standing behaviour, but is it really the right // behaviour? Or was that an unintended side-effect of node uniquing? return getOrSelfReference(A->getContext(), MDs); } MDNode *MDNode::getMostGenericFPMath(MDNode *A, MDNode *B) { if (!A || !B) return nullptr; APFloat AVal = mdconst::extract(A->getOperand(0))->getValueAPF(); APFloat BVal = mdconst::extract(B->getOperand(0))->getValueAPF(); if (AVal.compare(BVal) == APFloat::cmpLessThan) return A; return B; } static bool isContiguous(const ConstantRange &A, const ConstantRange &B) { return A.getUpper() == B.getLower() || A.getLower() == B.getUpper(); } static bool canBeMerged(const ConstantRange &A, const ConstantRange &B) { return !A.intersectWith(B).isEmptySet() || isContiguous(A, B); } static bool tryMergeRange(SmallVectorImpl &EndPoints, ConstantInt *Low, ConstantInt *High) { ConstantRange NewRange(Low->getValue(), High->getValue()); unsigned Size = EndPoints.size(); APInt LB = EndPoints[Size - 2]->getValue(); APInt LE = EndPoints[Size - 1]->getValue(); ConstantRange LastRange(LB, LE); if (canBeMerged(NewRange, LastRange)) { ConstantRange Union = LastRange.unionWith(NewRange); Type *Ty = High->getType(); EndPoints[Size - 2] = cast(ConstantInt::get(Ty, Union.getLower())); EndPoints[Size - 1] = cast(ConstantInt::get(Ty, Union.getUpper())); return true; } return false; } static void addRange(SmallVectorImpl &EndPoints, ConstantInt *Low, ConstantInt *High) { if (!EndPoints.empty()) if (tryMergeRange(EndPoints, Low, High)) return; EndPoints.push_back(Low); EndPoints.push_back(High); } MDNode *MDNode::getMostGenericRange(MDNode *A, MDNode *B) { // Given two ranges, we want to compute the union of the ranges. This // is slightly complitade by having to combine the intervals and merge // the ones that overlap. if (!A || !B) return nullptr; if (A == B) return A; // First, walk both lists in older of the lower boundary of each interval. // At each step, try to merge the new interval to the last one we adedd. SmallVector EndPoints; int AI = 0; int BI = 0; int AN = A->getNumOperands() / 2; int BN = B->getNumOperands() / 2; while (AI < AN && BI < BN) { ConstantInt *ALow = mdconst::extract(A->getOperand(2 * AI)); ConstantInt *BLow = mdconst::extract(B->getOperand(2 * BI)); if (ALow->getValue().slt(BLow->getValue())) { addRange(EndPoints, ALow, mdconst::extract(A->getOperand(2 * AI + 1))); ++AI; } else { addRange(EndPoints, BLow, mdconst::extract(B->getOperand(2 * BI + 1))); ++BI; } } while (AI < AN) { addRange(EndPoints, mdconst::extract(A->getOperand(2 * AI)), mdconst::extract(A->getOperand(2 * AI + 1))); ++AI; } while (BI < BN) { addRange(EndPoints, mdconst::extract(B->getOperand(2 * BI)), mdconst::extract(B->getOperand(2 * BI + 1))); ++BI; } // If we have more than 2 ranges (4 endpoints) we have to try to merge // the last and first ones. unsigned Size = EndPoints.size(); if (Size > 4) { ConstantInt *FB = EndPoints[0]; ConstantInt *FE = EndPoints[1]; if (tryMergeRange(EndPoints, FB, FE)) { for (unsigned i = 0; i < Size - 2; ++i) { EndPoints[i] = EndPoints[i + 2]; } EndPoints.resize(Size - 2); } } // If in the end we have a single range, it is possible that it is now the // full range. Just drop the metadata in that case. if (EndPoints.size() == 2) { ConstantRange Range(EndPoints[0]->getValue(), EndPoints[1]->getValue()); if (Range.isFullSet()) return nullptr; } SmallVector MDs; MDs.reserve(EndPoints.size()); for (auto *I : EndPoints) MDs.push_back(ConstantAsMetadata::get(I)); return MDNode::get(A->getContext(), MDs); } MDNode *MDNode::getMostGenericAlignmentOrDereferenceable(MDNode *A, MDNode *B) { if (!A || !B) return nullptr; ConstantInt *AVal = mdconst::extract(A->getOperand(0)); ConstantInt *BVal = mdconst::extract(B->getOperand(0)); if (AVal->getZExtValue() < BVal->getZExtValue()) return A; return B; } //===----------------------------------------------------------------------===// // NamedMDNode implementation. // static SmallVector &getNMDOps(void *Operands) { return *(SmallVector *)Operands; } NamedMDNode::NamedMDNode(const Twine &N) : Name(N.str()), Parent(nullptr), Operands(new SmallVector()) {} NamedMDNode::~NamedMDNode() { dropAllReferences(); delete &getNMDOps(Operands); } unsigned NamedMDNode::getNumOperands() const { return (unsigned)getNMDOps(Operands).size(); } MDNode *NamedMDNode::getOperand(unsigned i) const { assert(i < getNumOperands() && "Invalid Operand number!"); auto *N = getNMDOps(Operands)[i].get(); return cast_or_null(N); } void NamedMDNode::addOperand(MDNode *M) { getNMDOps(Operands).emplace_back(M); } void NamedMDNode::setOperand(unsigned I, MDNode *New) { assert(I < getNumOperands() && "Invalid operand number"); getNMDOps(Operands)[I].reset(New); } void NamedMDNode::eraseFromParent() { getParent()->eraseNamedMetadata(this); } void NamedMDNode::dropAllReferences() { getNMDOps(Operands).clear(); } StringRef NamedMDNode::getName() const { return StringRef(Name); } //===----------------------------------------------------------------------===// // Instruction Metadata method implementations. // void MDAttachmentMap::set(unsigned ID, MDNode &MD) { for (auto &I : Attachments) if (I.first == ID) { I.second.reset(&MD); return; } Attachments.emplace_back(std::piecewise_construct, std::make_tuple(ID), std::make_tuple(&MD)); } void MDAttachmentMap::erase(unsigned ID) { if (empty()) return; // Common case is one/last value. if (Attachments.back().first == ID) { Attachments.pop_back(); return; } for (auto I = Attachments.begin(), E = std::prev(Attachments.end()); I != E; ++I) if (I->first == ID) { *I = std::move(Attachments.back()); Attachments.pop_back(); return; } } MDNode *MDAttachmentMap::lookup(unsigned ID) const { for (const auto &I : Attachments) if (I.first == ID) return I.second; return nullptr; } void MDAttachmentMap::getAll( SmallVectorImpl> &Result) const { Result.append(Attachments.begin(), Attachments.end()); // Sort the resulting array so it is stable. if (Result.size() > 1) array_pod_sort(Result.begin(), Result.end()); } void Instruction::setMetadata(StringRef Kind, MDNode *Node) { if (!Node && !hasMetadata()) return; setMetadata(getContext().getMDKindID(Kind), Node); } MDNode *Instruction::getMetadataImpl(StringRef Kind) const { return getMetadataImpl(getContext().getMDKindID(Kind)); } void Instruction::dropUnknownNonDebugMetadata(ArrayRef KnownIDs) { SmallSet KnownSet; KnownSet.insert(KnownIDs.begin(), KnownIDs.end()); if (!hasMetadataHashEntry()) return; // Nothing to remove! auto &InstructionMetadata = getContext().pImpl->InstructionMetadata; if (KnownSet.empty()) { // Just drop our entry at the store. InstructionMetadata.erase(this); setHasMetadataHashEntry(false); return; } auto &Info = InstructionMetadata[this]; Info.remove_if([&KnownSet](const std::pair &I) { return !KnownSet.count(I.first); }); if (Info.empty()) { // Drop our entry at the store. InstructionMetadata.erase(this); setHasMetadataHashEntry(false); } } void Instruction::setMetadata(unsigned KindID, MDNode *Node) { if (!Node && !hasMetadata()) return; // Handle 'dbg' as a special case since it is not stored in the hash table. if (KindID == LLVMContext::MD_dbg) { DbgLoc = DebugLoc(Node); return; } // Handle the case when we're adding/updating metadata on an instruction. if (Node) { auto &Info = getContext().pImpl->InstructionMetadata[this]; assert(!Info.empty() == hasMetadataHashEntry() && "HasMetadata bit is wonked"); if (Info.empty()) setHasMetadataHashEntry(true); Info.set(KindID, *Node); return; } // Otherwise, we're removing metadata from an instruction. assert((hasMetadataHashEntry() == (getContext().pImpl->InstructionMetadata.count(this) > 0)) && "HasMetadata bit out of date!"); if (!hasMetadataHashEntry()) return; // Nothing to remove! auto &Info = getContext().pImpl->InstructionMetadata[this]; // Handle removal of an existing value. Info.erase(KindID); if (!Info.empty()) return; getContext().pImpl->InstructionMetadata.erase(this); setHasMetadataHashEntry(false); } void Instruction::setAAMetadata(const AAMDNodes &N) { setMetadata(LLVMContext::MD_tbaa, N.TBAA); setMetadata(LLVMContext::MD_alias_scope, N.Scope); setMetadata(LLVMContext::MD_noalias, N.NoAlias); } MDNode *Instruction::getMetadataImpl(unsigned KindID) const { // Handle 'dbg' as a special case since it is not stored in the hash table. if (KindID == LLVMContext::MD_dbg) return DbgLoc.getAsMDNode(); if (!hasMetadataHashEntry()) return nullptr; auto &Info = getContext().pImpl->InstructionMetadata[this]; assert(!Info.empty() && "bit out of sync with hash table"); return Info.lookup(KindID); } void Instruction::getAllMetadataImpl( SmallVectorImpl> &Result) const { Result.clear(); // Handle 'dbg' as a special case since it is not stored in the hash table. if (DbgLoc) { Result.push_back( std::make_pair((unsigned)LLVMContext::MD_dbg, DbgLoc.getAsMDNode())); if (!hasMetadataHashEntry()) return; } assert(hasMetadataHashEntry() && getContext().pImpl->InstructionMetadata.count(this) && "Shouldn't have called this"); const auto &Info = getContext().pImpl->InstructionMetadata.find(this)->second; assert(!Info.empty() && "Shouldn't have called this"); Info.getAll(Result); } void Instruction::getAllMetadataOtherThanDebugLocImpl( SmallVectorImpl> &Result) const { Result.clear(); assert(hasMetadataHashEntry() && getContext().pImpl->InstructionMetadata.count(this) && "Shouldn't have called this"); const auto &Info = getContext().pImpl->InstructionMetadata.find(this)->second; assert(!Info.empty() && "Shouldn't have called this"); Info.getAll(Result); } void Instruction::clearMetadataHashEntries() { assert(hasMetadataHashEntry() && "Caller should check"); getContext().pImpl->InstructionMetadata.erase(this); setHasMetadataHashEntry(false); } MDNode *Function::getMetadata(unsigned KindID) const { if (!hasMetadata()) return nullptr; return getContext().pImpl->FunctionMetadata[this].lookup(KindID); } MDNode *Function::getMetadata(StringRef Kind) const { if (!hasMetadata()) return nullptr; return getMetadata(getContext().getMDKindID(Kind)); } void Function::setMetadata(unsigned KindID, MDNode *MD) { if (MD) { if (!hasMetadata()) setHasMetadataHashEntry(true); getContext().pImpl->FunctionMetadata[this].set(KindID, *MD); return; } // Nothing to unset. if (!hasMetadata()) return; auto &Store = getContext().pImpl->FunctionMetadata[this]; Store.erase(KindID); if (Store.empty()) clearMetadata(); } void Function::setMetadata(StringRef Kind, MDNode *MD) { if (!MD && !hasMetadata()) return; setMetadata(getContext().getMDKindID(Kind), MD); } void Function::getAllMetadata( SmallVectorImpl> &MDs) const { MDs.clear(); if (!hasMetadata()) return; getContext().pImpl->FunctionMetadata[this].getAll(MDs); } void Function::dropUnknownMetadata(ArrayRef KnownIDs) { if (!hasMetadata()) return; if (KnownIDs.empty()) { clearMetadata(); return; } SmallSet KnownSet; KnownSet.insert(KnownIDs.begin(), KnownIDs.end()); auto &Store = getContext().pImpl->FunctionMetadata[this]; assert(!Store.empty()); Store.remove_if([&KnownSet](const std::pair &I) { return !KnownSet.count(I.first); }); if (Store.empty()) clearMetadata(); } void Function::clearMetadata() { if (!hasMetadata()) return; getContext().pImpl->FunctionMetadata.erase(this); setHasMetadataHashEntry(false); } void Function::setSubprogram(DISubprogram *SP) { setMetadata(LLVMContext::MD_dbg, SP); } DISubprogram *Function::getSubprogram() const { return cast_or_null(getMetadata(LLVMContext::MD_dbg)); }