//===-- Type.cpp - Implement the Type class -------------------------------===// // // 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 Type class for the VMCore library. // //===----------------------------------------------------------------------===// #include "LLVMContextImpl.h" #include "llvm/ADT/SCCIterator.h" #include #include using namespace llvm; // DEBUG_MERGE_TYPES - Enable this #define to see how and when derived types are // created and later destroyed, all in an effort to make sure that there is only // a single canonical version of a type. // // #define DEBUG_MERGE_TYPES 1 AbstractTypeUser::~AbstractTypeUser() {} void AbstractTypeUser::setType(Value *V, const Type *NewTy) { V->VTy = NewTy; } //===----------------------------------------------------------------------===// // Type Class Implementation //===----------------------------------------------------------------------===// /// Because of the way Type subclasses are allocated, this function is necessary /// to use the correct kind of "delete" operator to deallocate the Type object. /// Some type objects (FunctionTy, StructTy) allocate additional space /// after the space for their derived type to hold the contained types array of /// PATypeHandles. Using this allocation scheme means all the PATypeHandles are /// allocated with the type object, decreasing allocations and eliminating the /// need for a std::vector to be used in the Type class itself. /// @brief Type destruction function void Type::destroy() const { // Nothing calls getForwardedType from here on. if (ForwardType && ForwardType->isAbstract()) { ForwardType->dropRef(); ForwardType = NULL; } // Structures and Functions allocate their contained types past the end of // the type object itself. These need to be destroyed differently than the // other types. if (this->isFunctionTy() || this->isStructTy()) { // First, make sure we destruct any PATypeHandles allocated by these // subclasses. They must be manually destructed. for (unsigned i = 0; i < NumContainedTys; ++i) ContainedTys[i].PATypeHandle::~PATypeHandle(); // Now call the destructor for the subclass directly because we're going // to delete this as an array of char. if (this->isFunctionTy()) static_cast(this)->FunctionType::~FunctionType(); else { assert(isStructTy()); static_cast(this)->StructType::~StructType(); } // Finally, remove the memory as an array deallocation of the chars it was // constructed from. operator delete(const_cast(this)); return; } if (const OpaqueType *opaque_this = dyn_cast(this)) { LLVMContextImpl *pImpl = this->getContext().pImpl; pImpl->OpaqueTypes.erase(opaque_this); } // For all the other type subclasses, there is either no contained types or // just one (all Sequentials). For Sequentials, the PATypeHandle is not // allocated past the type object, its included directly in the SequentialType // class. This means we can safely just do "normal" delete of this object and // all the destructors that need to run will be run. delete this; } const Type *Type::getPrimitiveType(LLVMContext &C, TypeID IDNumber) { switch (IDNumber) { case VoidTyID : return getVoidTy(C); case FloatTyID : return getFloatTy(C); case DoubleTyID : return getDoubleTy(C); case X86_FP80TyID : return getX86_FP80Ty(C); case FP128TyID : return getFP128Ty(C); case PPC_FP128TyID : return getPPC_FP128Ty(C); case LabelTyID : return getLabelTy(C); case MetadataTyID : return getMetadataTy(C); case X86_MMXTyID : return getX86_MMXTy(C); default: return 0; } } /// getScalarType - If this is a vector type, return the element type, /// otherwise return this. const Type *Type::getScalarType() const { if (const VectorType *VTy = dyn_cast(this)) return VTy->getElementType(); return this; } /// isIntegerTy - Return true if this is an IntegerType of the specified width. bool Type::isIntegerTy(unsigned Bitwidth) const { return isIntegerTy() && cast(this)->getBitWidth() == Bitwidth; } /// isIntOrIntVectorTy - Return true if this is an integer type or a vector of /// integer types. /// bool Type::isIntOrIntVectorTy() const { if (isIntegerTy()) return true; if (ID != Type::VectorTyID) return false; return cast(this)->getElementType()->isIntegerTy(); } /// isFPOrFPVectorTy - Return true if this is a FP type or a vector of FP types. /// bool Type::isFPOrFPVectorTy() const { if (ID == Type::FloatTyID || ID == Type::DoubleTyID || ID == Type::FP128TyID || ID == Type::X86_FP80TyID || ID == Type::PPC_FP128TyID) return true; if (ID != Type::VectorTyID) return false; return cast(this)->getElementType()->isFloatingPointTy(); } // canLosslesslyBitCastTo - Return true if this type can be converted to // 'Ty' without any reinterpretation of bits. For example, i8* to i32*. // bool Type::canLosslesslyBitCastTo(const Type *Ty) const { // Identity cast means no change so return true if (this == Ty) return true; // They are not convertible unless they are at least first class types if (!this->isFirstClassType() || !Ty->isFirstClassType()) return false; // Vector -> Vector conversions are always lossless if the two vector types // have the same size, otherwise not. Also, 64-bit vector types can be // converted to x86mmx. if (const VectorType *thisPTy = dyn_cast(this)) { if (const VectorType *thatPTy = dyn_cast(Ty)) return thisPTy->getBitWidth() == thatPTy->getBitWidth(); if (Ty->getTypeID() == Type::X86_MMXTyID && thisPTy->getBitWidth() == 64) return true; } if (this->getTypeID() == Type::X86_MMXTyID) if (const VectorType *thatPTy = dyn_cast(Ty)) if (thatPTy->getBitWidth() == 64) return true; // At this point we have only various mismatches of the first class types // remaining and ptr->ptr. Just select the lossless conversions. Everything // else is not lossless. if (this->isPointerTy()) return Ty->isPointerTy(); return false; // Other types have no identity values } bool Type::isEmptyTy() const { const ArrayType *ATy = dyn_cast(this); if (ATy) { unsigned NumElements = ATy->getNumElements(); return NumElements == 0 || ATy->getElementType()->isEmptyTy(); } const StructType *STy = dyn_cast(this); if (STy) { unsigned NumElements = STy->getNumElements(); for (unsigned i = 0; i < NumElements; ++i) if (!STy->getElementType(i)->isEmptyTy()) return false; return true; } return false; } unsigned Type::getPrimitiveSizeInBits() const { switch (getTypeID()) { case Type::FloatTyID: return 32; case Type::DoubleTyID: return 64; case Type::X86_FP80TyID: return 80; case Type::FP128TyID: return 128; case Type::PPC_FP128TyID: return 128; case Type::X86_MMXTyID: return 64; case Type::IntegerTyID: return cast(this)->getBitWidth(); case Type::VectorTyID: return cast(this)->getBitWidth(); default: return 0; } } /// getScalarSizeInBits - If this is a vector type, return the /// getPrimitiveSizeInBits value for the element type. Otherwise return the /// getPrimitiveSizeInBits value for this type. unsigned Type::getScalarSizeInBits() const { return getScalarType()->getPrimitiveSizeInBits(); } /// getFPMantissaWidth - Return the width of the mantissa of this type. This /// is only valid on floating point types. If the FP type does not /// have a stable mantissa (e.g. ppc long double), this method returns -1. int Type::getFPMantissaWidth() const { if (const VectorType *VTy = dyn_cast(this)) return VTy->getElementType()->getFPMantissaWidth(); assert(isFloatingPointTy() && "Not a floating point type!"); if (ID == FloatTyID) return 24; if (ID == DoubleTyID) return 53; if (ID == X86_FP80TyID) return 64; if (ID == FP128TyID) return 113; assert(ID == PPC_FP128TyID && "unknown fp type"); return -1; } /// isSizedDerivedType - Derived types like structures and arrays are sized /// iff all of the members of the type are sized as well. Since asking for /// their size is relatively uncommon, move this operation out of line. bool Type::isSizedDerivedType() const { if (this->isIntegerTy()) return true; if (const ArrayType *ATy = dyn_cast(this)) return ATy->getElementType()->isSized(); if (const VectorType *VTy = dyn_cast(this)) return VTy->getElementType()->isSized(); if (!this->isStructTy()) return false; // Okay, our struct is sized if all of the elements are... for (subtype_iterator I = subtype_begin(), E = subtype_end(); I != E; ++I) if (!(*I)->isSized()) return false; return true; } /// getForwardedTypeInternal - This method is used to implement the union-find /// algorithm for when a type is being forwarded to another type. const Type *Type::getForwardedTypeInternal() const { assert(ForwardType && "This type is not being forwarded to another type!"); // Check to see if the forwarded type has been forwarded on. If so, collapse // the forwarding links. const Type *RealForwardedType = ForwardType->getForwardedType(); if (!RealForwardedType) return ForwardType; // No it's not forwarded again // Yes, it is forwarded again. First thing, add the reference to the new // forward type. if (RealForwardedType->isAbstract()) RealForwardedType->addRef(); // Now drop the old reference. This could cause ForwardType to get deleted. // ForwardType must be abstract because only abstract types can have their own // ForwardTypes. ForwardType->dropRef(); // Return the updated type. ForwardType = RealForwardedType; return ForwardType; } void Type::refineAbstractType(const DerivedType *OldTy, const Type *NewTy) { llvm_unreachable("Attempting to refine a derived type!"); } void Type::typeBecameConcrete(const DerivedType *AbsTy) { llvm_unreachable("DerivedType is already a concrete type!"); } std::string Type::getDescription() const { LLVMContextImpl *pImpl = getContext().pImpl; TypePrinting &Map = isAbstract() ? pImpl->AbstractTypeDescriptions : pImpl->ConcreteTypeDescriptions; std::string DescStr; raw_string_ostream DescOS(DescStr); Map.print(this, DescOS); return DescOS.str(); } bool StructType::indexValid(const Value *V) const { // Structure indexes require 32-bit integer constants. if (V->getType()->isIntegerTy(32)) if (const ConstantInt *CU = dyn_cast(V)) return indexValid(CU->getZExtValue()); return false; } bool StructType::indexValid(unsigned V) const { return V < NumContainedTys; } // getTypeAtIndex - Given an index value into the type, return the type of the // element. For a structure type, this must be a constant value... // const Type *StructType::getTypeAtIndex(const Value *V) const { unsigned Idx = (unsigned)cast(V)->getZExtValue(); return getTypeAtIndex(Idx); } const Type *StructType::getTypeAtIndex(unsigned Idx) const { assert(indexValid(Idx) && "Invalid structure index!"); return ContainedTys[Idx]; } //===----------------------------------------------------------------------===// // Primitive 'Type' data //===----------------------------------------------------------------------===// const Type *Type::getVoidTy(LLVMContext &C) { return &C.pImpl->VoidTy; } const Type *Type::getLabelTy(LLVMContext &C) { return &C.pImpl->LabelTy; } const Type *Type::getFloatTy(LLVMContext &C) { return &C.pImpl->FloatTy; } const Type *Type::getDoubleTy(LLVMContext &C) { return &C.pImpl->DoubleTy; } const Type *Type::getMetadataTy(LLVMContext &C) { return &C.pImpl->MetadataTy; } const Type *Type::getX86_FP80Ty(LLVMContext &C) { return &C.pImpl->X86_FP80Ty; } const Type *Type::getFP128Ty(LLVMContext &C) { return &C.pImpl->FP128Ty; } const Type *Type::getPPC_FP128Ty(LLVMContext &C) { return &C.pImpl->PPC_FP128Ty; } const Type *Type::getX86_MMXTy(LLVMContext &C) { return &C.pImpl->X86_MMXTy; } const IntegerType *Type::getIntNTy(LLVMContext &C, unsigned N) { return IntegerType::get(C, N); } const IntegerType *Type::getInt1Ty(LLVMContext &C) { return &C.pImpl->Int1Ty; } const IntegerType *Type::getInt8Ty(LLVMContext &C) { return &C.pImpl->Int8Ty; } const IntegerType *Type::getInt16Ty(LLVMContext &C) { return &C.pImpl->Int16Ty; } const IntegerType *Type::getInt32Ty(LLVMContext &C) { return &C.pImpl->Int32Ty; } const IntegerType *Type::getInt64Ty(LLVMContext &C) { return &C.pImpl->Int64Ty; } const PointerType *Type::getFloatPtrTy(LLVMContext &C, unsigned AS) { return getFloatTy(C)->getPointerTo(AS); } const PointerType *Type::getDoublePtrTy(LLVMContext &C, unsigned AS) { return getDoubleTy(C)->getPointerTo(AS); } const PointerType *Type::getX86_FP80PtrTy(LLVMContext &C, unsigned AS) { return getX86_FP80Ty(C)->getPointerTo(AS); } const PointerType *Type::getFP128PtrTy(LLVMContext &C, unsigned AS) { return getFP128Ty(C)->getPointerTo(AS); } const PointerType *Type::getPPC_FP128PtrTy(LLVMContext &C, unsigned AS) { return getPPC_FP128Ty(C)->getPointerTo(AS); } const PointerType *Type::getX86_MMXPtrTy(LLVMContext &C, unsigned AS) { return getX86_MMXTy(C)->getPointerTo(AS); } const PointerType *Type::getIntNPtrTy(LLVMContext &C, unsigned N, unsigned AS) { return getIntNTy(C, N)->getPointerTo(AS); } const PointerType *Type::getInt1PtrTy(LLVMContext &C, unsigned AS) { return getInt1Ty(C)->getPointerTo(AS); } const PointerType *Type::getInt8PtrTy(LLVMContext &C, unsigned AS) { return getInt8Ty(C)->getPointerTo(AS); } const PointerType *Type::getInt16PtrTy(LLVMContext &C, unsigned AS) { return getInt16Ty(C)->getPointerTo(AS); } const PointerType *Type::getInt32PtrTy(LLVMContext &C, unsigned AS) { return getInt32Ty(C)->getPointerTo(AS); } const PointerType *Type::getInt64PtrTy(LLVMContext &C, unsigned AS) { return getInt64Ty(C)->getPointerTo(AS); } //===----------------------------------------------------------------------===// // Derived Type Constructors //===----------------------------------------------------------------------===// /// isValidReturnType - Return true if the specified type is valid as a return /// type. bool FunctionType::isValidReturnType(const Type *RetTy) { return !RetTy->isFunctionTy() && !RetTy->isLabelTy() && !RetTy->isMetadataTy(); } /// isValidArgumentType - Return true if the specified type is valid as an /// argument type. bool FunctionType::isValidArgumentType(const Type *ArgTy) { return ArgTy->isFirstClassType() || ArgTy->isOpaqueTy(); } FunctionType::FunctionType(const Type *Result, ArrayRef Params, bool IsVarArgs) : DerivedType(Result->getContext(), FunctionTyID) { ContainedTys = reinterpret_cast(this+1); NumContainedTys = Params.size() + 1; // + 1 for result type assert(isValidReturnType(Result) && "invalid return type for function"); setSubclassData(IsVarArgs); bool isAbstract = Result->isAbstract(); new (&ContainedTys[0]) PATypeHandle(Result, this); for (unsigned i = 0; i != Params.size(); ++i) { assert(isValidArgumentType(Params[i]) && "Not a valid type for function argument!"); new (&ContainedTys[i+1]) PATypeHandle(Params[i], this); isAbstract |= Params[i]->isAbstract(); } // Calculate whether or not this type is abstract setAbstract(isAbstract); } StructType::StructType(LLVMContext &C, ArrayRef Types, bool isPacked) : CompositeType(C, StructTyID) { ContainedTys = reinterpret_cast(this + 1); NumContainedTys = Types.size(); setSubclassData(isPacked); bool isAbstract = false; for (unsigned i = 0; i < Types.size(); ++i) { assert(Types[i] && " type for structure field!"); assert(isValidElementType(Types[i]) && "Invalid type for structure element!"); new (&ContainedTys[i]) PATypeHandle(Types[i], this); isAbstract |= Types[i]->isAbstract(); } // Calculate whether or not this type is abstract setAbstract(isAbstract); } ArrayType::ArrayType(const Type *ElType, uint64_t NumEl) : SequentialType(ArrayTyID, ElType) { NumElements = NumEl; // Calculate whether or not this type is abstract setAbstract(ElType->isAbstract()); } VectorType::VectorType(const Type *ElType, unsigned NumEl) : SequentialType(VectorTyID, ElType) { NumElements = NumEl; setAbstract(ElType->isAbstract()); assert(NumEl > 0 && "NumEl of a VectorType must be greater than 0"); assert(isValidElementType(ElType) && "Elements of a VectorType must be a primitive type"); } PointerType::PointerType(const Type *E, unsigned AddrSpace) : SequentialType(PointerTyID, E) { setSubclassData(AddrSpace); // Calculate whether or not this type is abstract setAbstract(E->isAbstract()); } OpaqueType::OpaqueType(LLVMContext &C) : DerivedType(C, OpaqueTyID) { setAbstract(true); #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "Derived new type: " << *this << "\n"); #endif } void PATypeHolder::destroy() { Ty = 0; } // dropAllTypeUses - When this (abstract) type is resolved to be equal to // another (more concrete) type, we must eliminate all references to other // types, to avoid some circular reference problems. void DerivedType::dropAllTypeUses() { if (NumContainedTys != 0) { // The type must stay abstract. To do this, we insert a pointer to a type // that will never get resolved, thus will always be abstract. ContainedTys[0] = getContext().pImpl->AlwaysOpaqueTy; // Change the rest of the types to be Int32Ty's. It doesn't matter what we // pick so long as it doesn't point back to this type. We choose something // concrete to avoid overhead for adding to AbstractTypeUser lists and // stuff. const Type *ConcreteTy = Type::getInt32Ty(getContext()); for (unsigned i = 1, e = NumContainedTys; i != e; ++i) ContainedTys[i] = ConcreteTy; } } namespace { /// TypePromotionGraph and graph traits - this is designed to allow us to do /// efficient SCC processing of type graphs. This is the exact same as /// GraphTraits, except that we pretend that concrete types have no /// children to avoid processing them. struct TypePromotionGraph { Type *Ty; TypePromotionGraph(Type *T) : Ty(T) {} }; } namespace llvm { template <> struct GraphTraits { typedef Type NodeType; typedef Type::subtype_iterator ChildIteratorType; static inline NodeType *getEntryNode(TypePromotionGraph G) { return G.Ty; } static inline ChildIteratorType child_begin(NodeType *N) { if (N->isAbstract()) return N->subtype_begin(); // No need to process children of concrete types. return N->subtype_end(); } static inline ChildIteratorType child_end(NodeType *N) { return N->subtype_end(); } }; } // PromoteAbstractToConcrete - This is a recursive function that walks a type // graph calculating whether or not a type is abstract. // void Type::PromoteAbstractToConcrete() { if (!isAbstract()) return; scc_iterator SI = scc_begin(TypePromotionGraph(this)); scc_iterator SE = scc_end (TypePromotionGraph(this)); for (; SI != SE; ++SI) { std::vector &SCC = *SI; // Concrete types are leaves in the tree. Since an SCC will either be all // abstract or all concrete, we only need to check one type. if (!SCC[0]->isAbstract()) continue; if (SCC[0]->isOpaqueTy()) return; // Not going to be concrete, sorry. // If all of the children of all of the types in this SCC are concrete, // then this SCC is now concrete as well. If not, neither this SCC, nor // any parent SCCs will be concrete, so we might as well just exit. for (unsigned i = 0, e = SCC.size(); i != e; ++i) for (Type::subtype_iterator CI = SCC[i]->subtype_begin(), E = SCC[i]->subtype_end(); CI != E; ++CI) if ((*CI)->isAbstract()) // If the child type is in our SCC, it doesn't make the entire SCC // abstract unless there is a non-SCC abstract type. if (std::find(SCC.begin(), SCC.end(), *CI) == SCC.end()) return; // Not going to be concrete, sorry. // Okay, we just discovered this whole SCC is now concrete, mark it as // such! for (unsigned i = 0, e = SCC.size(); i != e; ++i) { assert(SCC[i]->isAbstract() && "Why are we processing concrete types?"); SCC[i]->setAbstract(false); } for (unsigned i = 0, e = SCC.size(); i != e; ++i) { assert(!SCC[i]->isAbstract() && "Concrete type became abstract?"); // The type just became concrete, notify all users! cast(SCC[i])->notifyUsesThatTypeBecameConcrete(); } } } //===----------------------------------------------------------------------===// // Type Structural Equality Testing //===----------------------------------------------------------------------===// // TypesEqual - Two types are considered structurally equal if they have the // same "shape": Every level and element of the types have identical primitive // ID's, and the graphs have the same edges/nodes in them. Nodes do not have to // be pointer equals to be equivalent though. This uses an optimistic algorithm // that assumes that two graphs are the same until proven otherwise. // static bool TypesEqual(const Type *Ty, const Type *Ty2, std::map &EqTypes) { if (Ty == Ty2) return true; if (Ty->getTypeID() != Ty2->getTypeID()) return false; if (Ty->isOpaqueTy()) return false; // Two unequal opaque types are never equal std::map::iterator It = EqTypes.find(Ty); if (It != EqTypes.end()) return It->second == Ty2; // Looping back on a type, check for equality // Otherwise, add the mapping to the table to make sure we don't get // recursion on the types... EqTypes.insert(It, std::make_pair(Ty, Ty2)); // Two really annoying special cases that breaks an otherwise nice simple // algorithm is the fact that arraytypes have sizes that differentiates types, // and that function types can be varargs or not. Consider this now. // if (const IntegerType *ITy = dyn_cast(Ty)) { const IntegerType *ITy2 = cast(Ty2); return ITy->getBitWidth() == ITy2->getBitWidth(); } if (const PointerType *PTy = dyn_cast(Ty)) { const PointerType *PTy2 = cast(Ty2); return PTy->getAddressSpace() == PTy2->getAddressSpace() && TypesEqual(PTy->getElementType(), PTy2->getElementType(), EqTypes); } if (const StructType *STy = dyn_cast(Ty)) { const StructType *STy2 = cast(Ty2); if (STy->getNumElements() != STy2->getNumElements()) return false; if (STy->isPacked() != STy2->isPacked()) return false; for (unsigned i = 0, e = STy2->getNumElements(); i != e; ++i) if (!TypesEqual(STy->getElementType(i), STy2->getElementType(i), EqTypes)) return false; return true; } if (const ArrayType *ATy = dyn_cast(Ty)) { const ArrayType *ATy2 = cast(Ty2); return ATy->getNumElements() == ATy2->getNumElements() && TypesEqual(ATy->getElementType(), ATy2->getElementType(), EqTypes); } if (const VectorType *PTy = dyn_cast(Ty)) { const VectorType *PTy2 = cast(Ty2); return PTy->getNumElements() == PTy2->getNumElements() && TypesEqual(PTy->getElementType(), PTy2->getElementType(), EqTypes); } if (const FunctionType *FTy = dyn_cast(Ty)) { const FunctionType *FTy2 = cast(Ty2); if (FTy->isVarArg() != FTy2->isVarArg() || FTy->getNumParams() != FTy2->getNumParams() || !TypesEqual(FTy->getReturnType(), FTy2->getReturnType(), EqTypes)) return false; for (unsigned i = 0, e = FTy2->getNumParams(); i != e; ++i) { if (!TypesEqual(FTy->getParamType(i), FTy2->getParamType(i), EqTypes)) return false; } return true; } llvm_unreachable("Unknown derived type!"); return false; } namespace llvm { // in namespace llvm so findable by ADL static bool TypesEqual(const Type *Ty, const Type *Ty2) { std::map EqTypes; return ::TypesEqual(Ty, Ty2, EqTypes); } } // AbstractTypeHasCycleThrough - Return true there is a path from CurTy to // TargetTy in the type graph. We know that Ty is an abstract type, so if we // ever reach a non-abstract type, we know that we don't need to search the // subgraph. static bool AbstractTypeHasCycleThrough(const Type *TargetTy, const Type *CurTy, SmallPtrSet &VisitedTypes) { if (TargetTy == CurTy) return true; if (!CurTy->isAbstract()) return false; if (!VisitedTypes.insert(CurTy)) return false; // Already been here. for (Type::subtype_iterator I = CurTy->subtype_begin(), E = CurTy->subtype_end(); I != E; ++I) if (AbstractTypeHasCycleThrough(TargetTy, *I, VisitedTypes)) return true; return false; } static bool ConcreteTypeHasCycleThrough(const Type *TargetTy, const Type *CurTy, SmallPtrSet &VisitedTypes) { if (TargetTy == CurTy) return true; if (!VisitedTypes.insert(CurTy)) return false; // Already been here. for (Type::subtype_iterator I = CurTy->subtype_begin(), E = CurTy->subtype_end(); I != E; ++I) if (ConcreteTypeHasCycleThrough(TargetTy, *I, VisitedTypes)) return true; return false; } /// TypeHasCycleThroughItself - Return true if the specified type has /// a cycle back to itself. namespace llvm { // in namespace llvm so it's findable by ADL static bool TypeHasCycleThroughItself(const Type *Ty) { SmallPtrSet VisitedTypes; if (Ty->isAbstract()) { // Optimized case for abstract types. for (Type::subtype_iterator I = Ty->subtype_begin(), E = Ty->subtype_end(); I != E; ++I) if (AbstractTypeHasCycleThrough(Ty, *I, VisitedTypes)) return true; } else { for (Type::subtype_iterator I = Ty->subtype_begin(), E = Ty->subtype_end(); I != E; ++I) if (ConcreteTypeHasCycleThrough(Ty, *I, VisitedTypes)) return true; } return false; } } //===----------------------------------------------------------------------===// // Function Type Factory and Value Class... // const IntegerType *IntegerType::get(LLVMContext &C, unsigned NumBits) { assert(NumBits >= MIN_INT_BITS && "bitwidth too small"); assert(NumBits <= MAX_INT_BITS && "bitwidth too large"); // Check for the built-in integer types switch (NumBits) { case 1: return cast(Type::getInt1Ty(C)); case 8: return cast(Type::getInt8Ty(C)); case 16: return cast(Type::getInt16Ty(C)); case 32: return cast(Type::getInt32Ty(C)); case 64: return cast(Type::getInt64Ty(C)); default: break; } LLVMContextImpl *pImpl = C.pImpl; IntegerValType IVT(NumBits); IntegerType *ITy = 0; // First, see if the type is already in the table, for which // a reader lock suffices. ITy = pImpl->IntegerTypes.get(IVT); if (!ITy) { // Value not found. Derive a new type! ITy = new IntegerType(C, NumBits); pImpl->IntegerTypes.add(IVT, ITy); } #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "Derived new type: " << *ITy << "\n"); #endif return ITy; } bool IntegerType::isPowerOf2ByteWidth() const { unsigned BitWidth = getBitWidth(); return (BitWidth > 7) && isPowerOf2_32(BitWidth); } APInt IntegerType::getMask() const { return APInt::getAllOnesValue(getBitWidth()); } FunctionValType FunctionValType::get(const FunctionType *FT) { // Build up a FunctionValType std::vector ParamTypes; ParamTypes.reserve(FT->getNumParams()); for (unsigned i = 0, e = FT->getNumParams(); i != e; ++i) ParamTypes.push_back(FT->getParamType(i)); return FunctionValType(FT->getReturnType(), ParamTypes, FT->isVarArg()); } FunctionType *FunctionType::get(const Type *Result, bool isVarArg) { return get(Result, ArrayRef(), isVarArg); } // FunctionType::get - The factory function for the FunctionType class... FunctionType *FunctionType::get(const Type *ReturnType, ArrayRef Params, bool isVarArg) { FunctionValType VT(ReturnType, Params, isVarArg); FunctionType *FT = 0; LLVMContextImpl *pImpl = ReturnType->getContext().pImpl; FT = pImpl->FunctionTypes.get(VT); if (!FT) { FT = (FunctionType*) operator new(sizeof(FunctionType) + sizeof(PATypeHandle)*(Params.size()+1)); new (FT) FunctionType(ReturnType, Params, isVarArg); pImpl->FunctionTypes.add(VT, FT); } #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "Derived new type: " << FT << "\n"); #endif return FT; } ArrayType *ArrayType::get(const Type *ElementType, uint64_t NumElements) { assert(ElementType && "Can't get array of types!"); assert(isValidElementType(ElementType) && "Invalid type for array element!"); ArrayValType AVT(ElementType, NumElements); ArrayType *AT = 0; LLVMContextImpl *pImpl = ElementType->getContext().pImpl; AT = pImpl->ArrayTypes.get(AVT); if (!AT) { // Value not found. Derive a new type! pImpl->ArrayTypes.add(AVT, AT = new ArrayType(ElementType, NumElements)); } #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "Derived new type: " << *AT << "\n"); #endif return AT; } bool ArrayType::isValidElementType(const Type *ElemTy) { return !ElemTy->isVoidTy() && !ElemTy->isLabelTy() && !ElemTy->isMetadataTy() && !ElemTy->isFunctionTy(); } VectorType *VectorType::get(const Type *ElementType, unsigned NumElements) { assert(ElementType && "Can't get vector of types!"); VectorValType PVT(ElementType, NumElements); VectorType *PT = 0; LLVMContextImpl *pImpl = ElementType->getContext().pImpl; PT = pImpl->VectorTypes.get(PVT); if (!PT) { pImpl->VectorTypes.add(PVT, PT = new VectorType(ElementType, NumElements)); } #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "Derived new type: " << *PT << "\n"); #endif return PT; } bool VectorType::isValidElementType(const Type *ElemTy) { return ElemTy->isIntegerTy() || ElemTy->isFloatingPointTy() || ElemTy->isOpaqueTy(); } //===----------------------------------------------------------------------===// // Struct Type Factory. // StructType *StructType::get(LLVMContext &Context, bool isPacked) { return get(Context, llvm::ArrayRef(), isPacked); } StructType *StructType::get(LLVMContext &Context, ArrayRef ETypes, bool isPacked) { StructValType STV(ETypes, isPacked); StructType *ST = 0; LLVMContextImpl *pImpl = Context.pImpl; ST = pImpl->StructTypes.get(STV); if (!ST) { // Value not found. Derive a new type! ST = (StructType*) operator new(sizeof(StructType) + sizeof(PATypeHandle) * ETypes.size()); new (ST) StructType(Context, ETypes, isPacked); pImpl->StructTypes.add(STV, ST); } #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "Derived new type: " << *ST << "\n"); #endif return ST; } StructType *StructType::get(LLVMContext &Context, const Type *type, ...) { va_list ap; std::vector StructFields; va_start(ap, type); while (type) { StructFields.push_back(type); type = va_arg(ap, llvm::Type*); } return llvm::StructType::get(Context, StructFields); } bool StructType::isValidElementType(const Type *ElemTy) { return !ElemTy->isVoidTy() && !ElemTy->isLabelTy() && !ElemTy->isMetadataTy() && !ElemTy->isFunctionTy(); } //===----------------------------------------------------------------------===// // Pointer Type Factory... // PointerType *PointerType::get(const Type *ValueType, unsigned AddressSpace) { assert(ValueType && "Can't get a pointer to type!"); assert(ValueType->getTypeID() != VoidTyID && "Pointer to void is not valid, use i8* instead!"); assert(isValidElementType(ValueType) && "Invalid type for pointer element!"); PointerValType PVT(ValueType, AddressSpace); PointerType *PT = 0; LLVMContextImpl *pImpl = ValueType->getContext().pImpl; PT = pImpl->PointerTypes.get(PVT); if (!PT) { // Value not found. Derive a new type! pImpl->PointerTypes.add(PVT, PT = new PointerType(ValueType, AddressSpace)); } #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "Derived new type: " << *PT << "\n"); #endif return PT; } const PointerType *Type::getPointerTo(unsigned addrs) const { return PointerType::get(this, addrs); } bool PointerType::isValidElementType(const Type *ElemTy) { return !ElemTy->isVoidTy() && !ElemTy->isLabelTy() && !ElemTy->isMetadataTy(); } //===----------------------------------------------------------------------===// // Opaque Type Factory... // OpaqueType *OpaqueType::get(LLVMContext &C) { OpaqueType *OT = new OpaqueType(C); // All opaque types are distinct. LLVMContextImpl *pImpl = C.pImpl; pImpl->OpaqueTypes.insert(OT); return OT; } //===----------------------------------------------------------------------===// // Derived Type Refinement Functions //===----------------------------------------------------------------------===// // addAbstractTypeUser - Notify an abstract type that there is a new user of // it. This function is called primarily by the PATypeHandle class. void Type::addAbstractTypeUser(AbstractTypeUser *U) const { assert(isAbstract() && "addAbstractTypeUser: Current type not abstract!"); AbstractTypeUsers.push_back(U); } // removeAbstractTypeUser - Notify an abstract type that a user of the class // no longer has a handle to the type. This function is called primarily by // the PATypeHandle class. When there are no users of the abstract type, it // is annihilated, because there is no way to get a reference to it ever again. // void Type::removeAbstractTypeUser(AbstractTypeUser *U) const { // Search from back to front because we will notify users from back to // front. Also, it is likely that there will be a stack like behavior to // users that register and unregister users. // unsigned i; for (i = AbstractTypeUsers.size(); AbstractTypeUsers[i-1] != U; --i) assert(i != 0 && "AbstractTypeUser not in user list!"); --i; // Convert to be in range 0 <= i < size() assert(i < AbstractTypeUsers.size() && "Index out of range!"); // Wraparound? AbstractTypeUsers.erase(AbstractTypeUsers.begin()+i); #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << " remAbstractTypeUser[" << (void*)this << ", " << *this << "][" << i << "] User = " << U << "\n"); #endif if (AbstractTypeUsers.empty() && getRefCount() == 0 && isAbstract()) { #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "DELETEing unused abstract type: <" << *this << ">[" << (void*)this << "]" << "\n"); #endif this->destroy(); } } // refineAbstractTypeTo - This function is used when it is discovered // that the 'this' abstract type is actually equivalent to the NewType // specified. This causes all users of 'this' to switch to reference the more // concrete type NewType and for 'this' to be deleted. Only used for internal // callers. // void DerivedType::refineAbstractTypeTo(const Type *NewType) { assert(isAbstract() && "refineAbstractTypeTo: Current type is not abstract!"); assert(this != NewType && "Can't refine to myself!"); assert(ForwardType == 0 && "This type has already been refined!"); LLVMContextImpl *pImpl = getContext().pImpl; // The descriptions may be out of date. Conservatively clear them all! pImpl->AbstractTypeDescriptions.clear(); #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "REFINING abstract type [" << (void*)this << " " << *this << "] to [" << (void*)NewType << " " << *NewType << "]!\n"); #endif // Make sure to put the type to be refined to into a holder so that if IT gets // refined, that we will not continue using a dead reference... // PATypeHolder NewTy(NewType); // Any PATypeHolders referring to this type will now automatically forward to // the type we are resolved to. ForwardType = NewType; if (ForwardType->isAbstract()) ForwardType->addRef(); // Add a self use of the current type so that we don't delete ourself until // after the function exits. // PATypeHolder CurrentTy(this); // To make the situation simpler, we ask the subclass to remove this type from // the type map, and to replace any type uses with uses of non-abstract types. // This dramatically limits the amount of recursive type trouble we can find // ourselves in. dropAllTypeUses(); // Iterate over all of the uses of this type, invoking callback. Each user // should remove itself from our use list automatically. We have to check to // make sure that NewTy doesn't _become_ 'this'. If it does, resolving types // will not cause users to drop off of the use list. If we resolve to ourself // we succeed! // while (!AbstractTypeUsers.empty() && NewTy != this) { AbstractTypeUser *User = AbstractTypeUsers.back(); unsigned OldSize = AbstractTypeUsers.size(); (void)OldSize; #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << " REFINING user " << OldSize-1 << "[" << (void*)User << "] of abstract type [" << (void*)this << " " << *this << "] to [" << (void*)NewTy.get() << " " << *NewTy << "]!\n"); #endif User->refineAbstractType(this, NewTy); assert(AbstractTypeUsers.size() != OldSize && "AbsTyUser did not remove self from user list!"); } // If we were successful removing all users from the type, 'this' will be // deleted when the last PATypeHolder is destroyed or updated from this type. // This may occur on exit of this function, as the CurrentTy object is // destroyed. } // notifyUsesThatTypeBecameConcrete - Notify AbstractTypeUsers of this type that // the current type has transitioned from being abstract to being concrete. // void DerivedType::notifyUsesThatTypeBecameConcrete() { #ifdef DEBUG_MERGE_TYPES DEBUG(dbgs() << "typeIsREFINED type: " << (void*)this << " " << *this <<"\n"); #endif unsigned OldSize = AbstractTypeUsers.size(); (void)OldSize; while (!AbstractTypeUsers.empty()) { AbstractTypeUser *ATU = AbstractTypeUsers.back(); ATU->typeBecameConcrete(this); assert(AbstractTypeUsers.size() < OldSize-- && "AbstractTypeUser did not remove itself from the use list!"); } } // refineAbstractType - Called when a contained type is found to be more // concrete - this could potentially change us from an abstract type to a // concrete type. // void FunctionType::refineAbstractType(const DerivedType *OldType, const Type *NewType) { LLVMContextImpl *pImpl = OldType->getContext().pImpl; pImpl->FunctionTypes.RefineAbstractType(this, OldType, NewType); } void FunctionType::typeBecameConcrete(const DerivedType *AbsTy) { LLVMContextImpl *pImpl = AbsTy->getContext().pImpl; pImpl->FunctionTypes.TypeBecameConcrete(this, AbsTy); } // refineAbstractType - Called when a contained type is found to be more // concrete - this could potentially change us from an abstract type to a // concrete type. // void ArrayType::refineAbstractType(const DerivedType *OldType, const Type *NewType) { LLVMContextImpl *pImpl = OldType->getContext().pImpl; pImpl->ArrayTypes.RefineAbstractType(this, OldType, NewType); } void ArrayType::typeBecameConcrete(const DerivedType *AbsTy) { LLVMContextImpl *pImpl = AbsTy->getContext().pImpl; pImpl->ArrayTypes.TypeBecameConcrete(this, AbsTy); } // refineAbstractType - Called when a contained type is found to be more // concrete - this could potentially change us from an abstract type to a // concrete type. // void VectorType::refineAbstractType(const DerivedType *OldType, const Type *NewType) { LLVMContextImpl *pImpl = OldType->getContext().pImpl; pImpl->VectorTypes.RefineAbstractType(this, OldType, NewType); } void VectorType::typeBecameConcrete(const DerivedType *AbsTy) { LLVMContextImpl *pImpl = AbsTy->getContext().pImpl; pImpl->VectorTypes.TypeBecameConcrete(this, AbsTy); } // refineAbstractType - Called when a contained type is found to be more // concrete - this could potentially change us from an abstract type to a // concrete type. // void StructType::refineAbstractType(const DerivedType *OldType, const Type *NewType) { LLVMContextImpl *pImpl = OldType->getContext().pImpl; pImpl->StructTypes.RefineAbstractType(this, OldType, NewType); } void StructType::typeBecameConcrete(const DerivedType *AbsTy) { LLVMContextImpl *pImpl = AbsTy->getContext().pImpl; pImpl->StructTypes.TypeBecameConcrete(this, AbsTy); } // refineAbstractType - Called when a contained type is found to be more // concrete - this could potentially change us from an abstract type to a // concrete type. // void PointerType::refineAbstractType(const DerivedType *OldType, const Type *NewType) { LLVMContextImpl *pImpl = OldType->getContext().pImpl; pImpl->PointerTypes.RefineAbstractType(this, OldType, NewType); } void PointerType::typeBecameConcrete(const DerivedType *AbsTy) { LLVMContextImpl *pImpl = AbsTy->getContext().pImpl; pImpl->PointerTypes.TypeBecameConcrete(this, AbsTy); } bool SequentialType::indexValid(const Value *V) const { if (V->getType()->isIntegerTy()) return true; return false; } namespace llvm { raw_ostream &operator<<(raw_ostream &OS, const Type &T) { T.print(OS); return OS; } }