1 //===-- Type.cpp - Implement the Type class -------------------------------===//
3 // The LLVM Compiler Infrastructure
5 // This file was developed by the LLVM research group and is distributed under
6 // the University of Illinois Open Source License. See LICENSE.TXT for details.
8 //===----------------------------------------------------------------------===//
10 // This file implements the Type class for the VMCore library.
12 //===----------------------------------------------------------------------===//
14 #include "llvm/AbstractTypeUser.h"
15 #include "llvm/DerivedTypes.h"
16 #include "llvm/SymbolTable.h"
17 #include "llvm/Constants.h"
18 #include "llvm/ADT/DepthFirstIterator.h"
19 #include "llvm/ADT/StringExtras.h"
20 #include "llvm/ADT/SCCIterator.h"
21 #include "llvm/ADT/STLExtras.h"
22 #include "llvm/Support/MathExtras.h"
23 #include "llvm/Support/Compiler.h"
24 #include "llvm/Support/ManagedStatic.h"
25 #include "llvm/Support/Debug.h"
29 // DEBUG_MERGE_TYPES - Enable this #define to see how and when derived types are
30 // created and later destroyed, all in an effort to make sure that there is only
31 // a single canonical version of a type.
33 // #define DEBUG_MERGE_TYPES 1
35 AbstractTypeUser::~AbstractTypeUser() {}
38 //===----------------------------------------------------------------------===//
39 // Type PATypeHolder Implementation
40 //===----------------------------------------------------------------------===//
42 /// get - This implements the forwarding part of the union-find algorithm for
43 /// abstract types. Before every access to the Type*, we check to see if the
44 /// type we are pointing to is forwarding to a new type. If so, we drop our
45 /// reference to the type.
47 Type* PATypeHolder::get() const {
48 const Type *NewTy = Ty->getForwardedType();
49 if (!NewTy) return const_cast<Type*>(Ty);
50 return *const_cast<PATypeHolder*>(this) = NewTy;
53 //===----------------------------------------------------------------------===//
54 // Type Class Implementation
55 //===----------------------------------------------------------------------===//
57 // Concrete/Abstract TypeDescriptions - We lazily calculate type descriptions
58 // for types as they are needed. Because resolution of types must invalidate
59 // all of the abstract type descriptions, we keep them in a seperate map to make
61 static ManagedStatic<std::map<const Type*,
62 std::string> > ConcreteTypeDescriptions;
63 static ManagedStatic<std::map<const Type*,
64 std::string> > AbstractTypeDescriptions;
66 Type::Type(const char *Name, TypeID id)
67 : ID(id), Abstract(false), RefCount(0), ForwardType(0) {
68 assert(Name && Name[0] && "Should use other ctor if no name!");
69 (*ConcreteTypeDescriptions)[this] = Name;
73 const Type *Type::getPrimitiveType(TypeID IDNumber) {
75 case VoidTyID : return VoidTy;
76 case BoolTyID : return BoolTy;
77 case Int8TyID : return Int8Ty;
78 case Int16TyID : return Int16Ty;
79 case Int32TyID : return Int32Ty;
80 case Int64TyID : return Int64Ty;
81 case FloatTyID : return FloatTy;
82 case DoubleTyID: return DoubleTy;
83 case LabelTyID : return LabelTy;
89 /// isFPOrFPVector - Return true if this is a FP type or a vector of FP types.
91 bool Type::isFPOrFPVector() const {
92 if (ID == Type::FloatTyID || ID == Type::DoubleTyID) return true;
93 if (ID != Type::PackedTyID) return false;
95 return cast<PackedType>(this)->getElementType()->isFloatingPoint();
98 // canLosslesllyBitCastTo - Return true if this type can be converted to
99 // 'Ty' without any reinterpretation of bits. For example, uint to int.
101 bool Type::canLosslesslyBitCastTo(const Type *Ty) const {
102 // Identity cast means no change so return true
106 // They are not convertible unless they are at least first class types
107 if (!this->isFirstClassType() || !Ty->isFirstClassType())
110 // Packed -> Packed conversions are always lossless if the two packed types
111 // have the same size, otherwise not.
112 if (const PackedType *thisPTy = dyn_cast<PackedType>(this))
113 if (const PackedType *thatPTy = dyn_cast<PackedType>(Ty))
114 return thisPTy->getBitWidth() == thatPTy->getBitWidth();
116 // At this point we have only various mismatches of the first class types
117 // remaining and ptr->ptr. Just select the lossless conversions. Everything
118 // else is not lossless.
119 if (getTypeID() == Type::PointerTyID)
120 return isa<PointerType>(Ty);
121 return false; // Other types have no identity values
124 // getPrimitiveSize - Return the basic size of this type if it is a primitive
125 // type. These are fixed by LLVM and are not target dependent. This will
126 // return zero if the type does not have a size or is not a primitive type.
128 unsigned Type::getPrimitiveSize() const {
129 switch (getTypeID()) {
131 case Type::Int8TyID: return 1;
132 case Type::Int16TyID: return 2;
133 case Type::FloatTyID:
134 case Type::Int32TyID: return 4;
135 case Type::Int64TyID:
136 case Type::DoubleTyID: return 8;
141 unsigned Type::getPrimitiveSizeInBits() const {
142 switch (getTypeID()) {
143 case Type::BoolTyID: return 1;
144 case Type::Int8TyID: return 8;
145 case Type::Int16TyID: return 16;
146 case Type::FloatTyID:
147 case Type::Int32TyID:return 32;
148 case Type::Int64TyID:
149 case Type::DoubleTyID: return 64;
150 case Type::PackedTyID: {
151 const PackedType *PTy = cast<PackedType>(this);
152 return PTy->getBitWidth();
158 /// isSizedDerivedType - Derived types like structures and arrays are sized
159 /// iff all of the members of the type are sized as well. Since asking for
160 /// their size is relatively uncommon, move this operation out of line.
161 bool Type::isSizedDerivedType() const {
162 if (const ArrayType *ATy = dyn_cast<ArrayType>(this))
163 return ATy->getElementType()->isSized();
165 if (const PackedType *PTy = dyn_cast<PackedType>(this))
166 return PTy->getElementType()->isSized();
168 if (!isa<StructType>(this)) return false;
170 // Okay, our struct is sized if all of the elements are...
171 for (subtype_iterator I = subtype_begin(), E = subtype_end(); I != E; ++I)
172 if (!(*I)->isSized()) return false;
177 /// getForwardedTypeInternal - This method is used to implement the union-find
178 /// algorithm for when a type is being forwarded to another type.
179 const Type *Type::getForwardedTypeInternal() const {
180 assert(ForwardType && "This type is not being forwarded to another type!");
182 // Check to see if the forwarded type has been forwarded on. If so, collapse
183 // the forwarding links.
184 const Type *RealForwardedType = ForwardType->getForwardedType();
185 if (!RealForwardedType)
186 return ForwardType; // No it's not forwarded again
188 // Yes, it is forwarded again. First thing, add the reference to the new
190 if (RealForwardedType->isAbstract())
191 cast<DerivedType>(RealForwardedType)->addRef();
193 // Now drop the old reference. This could cause ForwardType to get deleted.
194 cast<DerivedType>(ForwardType)->dropRef();
196 // Return the updated type.
197 ForwardType = RealForwardedType;
201 void Type::refineAbstractType(const DerivedType *OldTy, const Type *NewTy) {
204 void Type::typeBecameConcrete(const DerivedType *AbsTy) {
209 // getTypeDescription - This is a recursive function that walks a type hierarchy
210 // calculating the description for a type.
212 static std::string getTypeDescription(const Type *Ty,
213 std::vector<const Type *> &TypeStack) {
214 if (isa<OpaqueType>(Ty)) { // Base case for the recursion
215 std::map<const Type*, std::string>::iterator I =
216 AbstractTypeDescriptions->lower_bound(Ty);
217 if (I != AbstractTypeDescriptions->end() && I->first == Ty)
219 std::string Desc = "opaque";
220 AbstractTypeDescriptions->insert(std::make_pair(Ty, Desc));
224 if (!Ty->isAbstract()) { // Base case for the recursion
225 std::map<const Type*, std::string>::iterator I =
226 ConcreteTypeDescriptions->find(Ty);
227 if (I != ConcreteTypeDescriptions->end()) return I->second;
230 // Check to see if the Type is already on the stack...
231 unsigned Slot = 0, CurSize = TypeStack.size();
232 while (Slot < CurSize && TypeStack[Slot] != Ty) ++Slot; // Scan for type
234 // This is another base case for the recursion. In this case, we know
235 // that we have looped back to a type that we have previously visited.
236 // Generate the appropriate upreference to handle this.
239 return "\\" + utostr(CurSize-Slot); // Here's the upreference
241 // Recursive case: derived types...
243 TypeStack.push_back(Ty); // Add us to the stack..
245 switch (Ty->getTypeID()) {
246 case Type::FunctionTyID: {
247 const FunctionType *FTy = cast<FunctionType>(Ty);
248 Result = FunctionType::getParamAttrsText(FTy->getParamAttrs(0));
251 Result += getTypeDescription(FTy->getReturnType(), TypeStack) + " (";
253 for (FunctionType::param_iterator I = FTy->param_begin(),
254 E = FTy->param_end(); I != E; ++I) {
255 if (I != FTy->param_begin())
257 const char *PA = FunctionType::getParamAttrsText(FTy->getParamAttrs(Idx));
263 Result += getTypeDescription(*I, TypeStack);
265 if (FTy->isVarArg()) {
266 if (FTy->getNumParams()) Result += ", ";
272 case Type::StructTyID: {
273 const StructType *STy = cast<StructType>(Ty);
278 for (StructType::element_iterator I = STy->element_begin(),
279 E = STy->element_end(); I != E; ++I) {
280 if (I != STy->element_begin())
282 Result += getTypeDescription(*I, TypeStack);
289 case Type::PointerTyID: {
290 const PointerType *PTy = cast<PointerType>(Ty);
291 Result = getTypeDescription(PTy->getElementType(), TypeStack) + " *";
294 case Type::ArrayTyID: {
295 const ArrayType *ATy = cast<ArrayType>(Ty);
296 unsigned NumElements = ATy->getNumElements();
298 Result += utostr(NumElements) + " x ";
299 Result += getTypeDescription(ATy->getElementType(), TypeStack) + "]";
302 case Type::PackedTyID: {
303 const PackedType *PTy = cast<PackedType>(Ty);
304 unsigned NumElements = PTy->getNumElements();
306 Result += utostr(NumElements) + " x ";
307 Result += getTypeDescription(PTy->getElementType(), TypeStack) + ">";
312 assert(0 && "Unhandled type in getTypeDescription!");
315 TypeStack.pop_back(); // Remove self from stack...
322 static const std::string &getOrCreateDesc(std::map<const Type*,std::string>&Map,
324 std::map<const Type*, std::string>::iterator I = Map.find(Ty);
325 if (I != Map.end()) return I->second;
327 std::vector<const Type *> TypeStack;
328 std::string Result = getTypeDescription(Ty, TypeStack);
329 return Map[Ty] = Result;
333 const std::string &Type::getDescription() const {
335 return getOrCreateDesc(*AbstractTypeDescriptions, this);
337 return getOrCreateDesc(*ConcreteTypeDescriptions, this);
341 bool StructType::indexValid(const Value *V) const {
342 // Structure indexes require 32-bit integer constants.
343 if (V->getType() == Type::Int32Ty)
344 if (const ConstantInt *CU = dyn_cast<ConstantInt>(V))
345 return CU->getZExtValue() < ContainedTys.size();
349 // getTypeAtIndex - Given an index value into the type, return the type of the
350 // element. For a structure type, this must be a constant value...
352 const Type *StructType::getTypeAtIndex(const Value *V) const {
353 assert(indexValid(V) && "Invalid structure index!");
354 unsigned Idx = (unsigned)cast<ConstantInt>(V)->getZExtValue();
355 return ContainedTys[Idx];
359 //===----------------------------------------------------------------------===//
360 // Primitive 'Type' data
361 //===----------------------------------------------------------------------===//
363 #define DeclarePrimType(TY, Str) \
365 struct VISIBILITY_HIDDEN TY##Type : public Type { \
366 TY##Type() : Type(Str, Type::TY##TyID) {} \
369 static ManagedStatic<TY##Type> The##TY##Ty; \
370 Type *Type::TY##Ty = &*The##TY##Ty
372 DeclarePrimType(Void, "void");
373 DeclarePrimType(Bool, "bool");
374 DeclarePrimType(Int8, "i8");
375 DeclarePrimType(Int16, "i16");
376 DeclarePrimType(Int32, "i32");
377 DeclarePrimType(Int64, "i64");
378 DeclarePrimType(Float, "float");
379 DeclarePrimType(Double, "double");
380 DeclarePrimType(Label, "label");
381 #undef DeclarePrimType
384 //===----------------------------------------------------------------------===//
385 // Derived Type Constructors
386 //===----------------------------------------------------------------------===//
388 FunctionType::FunctionType(const Type *Result,
389 const std::vector<const Type*> &Params,
390 bool IsVarArgs, const ParamAttrsList &Attrs)
391 : DerivedType(FunctionTyID), isVarArgs(IsVarArgs) {
392 assert((Result->isFirstClassType() || Result == Type::VoidTy ||
393 isa<OpaqueType>(Result)) &&
394 "LLVM functions cannot return aggregates");
395 bool isAbstract = Result->isAbstract();
396 ContainedTys.reserve(Params.size()+1);
397 ContainedTys.push_back(PATypeHandle(Result, this));
399 for (unsigned i = 0; i != Params.size(); ++i) {
400 assert((Params[i]->isFirstClassType() || isa<OpaqueType>(Params[i])) &&
401 "Function arguments must be value types!");
403 ContainedTys.push_back(PATypeHandle(Params[i], this));
404 isAbstract |= Params[i]->isAbstract();
407 // Set the ParameterAttributes
409 ParamAttrs = new ParamAttrsList(Attrs);
413 // Calculate whether or not this type is abstract
414 setAbstract(isAbstract);
418 StructType::StructType(const std::vector<const Type*> &Types, bool isPacked)
419 : CompositeType(StructTyID) {
420 setSubclassData(isPacked);
421 ContainedTys.reserve(Types.size());
422 bool isAbstract = false;
423 for (unsigned i = 0; i < Types.size(); ++i) {
424 assert(Types[i] != Type::VoidTy && "Void type for structure field!!");
425 ContainedTys.push_back(PATypeHandle(Types[i], this));
426 isAbstract |= Types[i]->isAbstract();
429 // Calculate whether or not this type is abstract
430 setAbstract(isAbstract);
433 ArrayType::ArrayType(const Type *ElType, uint64_t NumEl)
434 : SequentialType(ArrayTyID, ElType) {
437 // Calculate whether or not this type is abstract
438 setAbstract(ElType->isAbstract());
441 PackedType::PackedType(const Type *ElType, unsigned NumEl)
442 : SequentialType(PackedTyID, ElType) {
445 assert(NumEl > 0 && "NumEl of a PackedType must be greater than 0");
446 assert((ElType->isIntegral() || ElType->isFloatingPoint()) &&
447 "Elements of a PackedType must be a primitive type");
451 PointerType::PointerType(const Type *E) : SequentialType(PointerTyID, E) {
452 // Calculate whether or not this type is abstract
453 setAbstract(E->isAbstract());
456 OpaqueType::OpaqueType() : DerivedType(OpaqueTyID) {
458 #ifdef DEBUG_MERGE_TYPES
459 DOUT << "Derived new type: " << *this << "\n";
463 // dropAllTypeUses - When this (abstract) type is resolved to be equal to
464 // another (more concrete) type, we must eliminate all references to other
465 // types, to avoid some circular reference problems.
466 void DerivedType::dropAllTypeUses() {
467 if (!ContainedTys.empty()) {
468 // The type must stay abstract. To do this, we insert a pointer to a type
469 // that will never get resolved, thus will always be abstract.
470 static Type *AlwaysOpaqueTy = OpaqueType::get();
471 static PATypeHolder Holder(AlwaysOpaqueTy);
472 ContainedTys[0] = AlwaysOpaqueTy;
474 // Change the rest of the types to be intty's. It doesn't matter what we
475 // pick so long as it doesn't point back to this type. We choose something
476 // concrete to avoid overhead for adding to AbstracTypeUser lists and stuff.
477 for (unsigned i = 1, e = ContainedTys.size(); i != e; ++i)
478 ContainedTys[i] = Type::Int32Ty;
484 /// TypePromotionGraph and graph traits - this is designed to allow us to do
485 /// efficient SCC processing of type graphs. This is the exact same as
486 /// GraphTraits<Type*>, except that we pretend that concrete types have no
487 /// children to avoid processing them.
488 struct TypePromotionGraph {
490 TypePromotionGraph(Type *T) : Ty(T) {}
494 template <> struct GraphTraits<TypePromotionGraph> {
495 typedef Type NodeType;
496 typedef Type::subtype_iterator ChildIteratorType;
498 static inline NodeType *getEntryNode(TypePromotionGraph G) { return G.Ty; }
499 static inline ChildIteratorType child_begin(NodeType *N) {
501 return N->subtype_begin();
502 else // No need to process children of concrete types.
503 return N->subtype_end();
505 static inline ChildIteratorType child_end(NodeType *N) {
506 return N->subtype_end();
512 // PromoteAbstractToConcrete - This is a recursive function that walks a type
513 // graph calculating whether or not a type is abstract.
515 void Type::PromoteAbstractToConcrete() {
516 if (!isAbstract()) return;
518 scc_iterator<TypePromotionGraph> SI = scc_begin(TypePromotionGraph(this));
519 scc_iterator<TypePromotionGraph> SE = scc_end (TypePromotionGraph(this));
521 for (; SI != SE; ++SI) {
522 std::vector<Type*> &SCC = *SI;
524 // Concrete types are leaves in the tree. Since an SCC will either be all
525 // abstract or all concrete, we only need to check one type.
526 if (SCC[0]->isAbstract()) {
527 if (isa<OpaqueType>(SCC[0]))
528 return; // Not going to be concrete, sorry.
530 // If all of the children of all of the types in this SCC are concrete,
531 // then this SCC is now concrete as well. If not, neither this SCC, nor
532 // any parent SCCs will be concrete, so we might as well just exit.
533 for (unsigned i = 0, e = SCC.size(); i != e; ++i)
534 for (Type::subtype_iterator CI = SCC[i]->subtype_begin(),
535 E = SCC[i]->subtype_end(); CI != E; ++CI)
536 if ((*CI)->isAbstract())
537 // If the child type is in our SCC, it doesn't make the entire SCC
538 // abstract unless there is a non-SCC abstract type.
539 if (std::find(SCC.begin(), SCC.end(), *CI) == SCC.end())
540 return; // Not going to be concrete, sorry.
542 // Okay, we just discovered this whole SCC is now concrete, mark it as
544 for (unsigned i = 0, e = SCC.size(); i != e; ++i) {
545 assert(SCC[i]->isAbstract() && "Why are we processing concrete types?");
547 SCC[i]->setAbstract(false);
550 for (unsigned i = 0, e = SCC.size(); i != e; ++i) {
551 assert(!SCC[i]->isAbstract() && "Concrete type became abstract?");
552 // The type just became concrete, notify all users!
553 cast<DerivedType>(SCC[i])->notifyUsesThatTypeBecameConcrete();
560 //===----------------------------------------------------------------------===//
561 // Type Structural Equality Testing
562 //===----------------------------------------------------------------------===//
564 // TypesEqual - Two types are considered structurally equal if they have the
565 // same "shape": Every level and element of the types have identical primitive
566 // ID's, and the graphs have the same edges/nodes in them. Nodes do not have to
567 // be pointer equals to be equivalent though. This uses an optimistic algorithm
568 // that assumes that two graphs are the same until proven otherwise.
570 static bool TypesEqual(const Type *Ty, const Type *Ty2,
571 std::map<const Type *, const Type *> &EqTypes) {
572 if (Ty == Ty2) return true;
573 if (Ty->getTypeID() != Ty2->getTypeID()) return false;
574 if (isa<OpaqueType>(Ty))
575 return false; // Two unequal opaque types are never equal
577 std::map<const Type*, const Type*>::iterator It = EqTypes.lower_bound(Ty);
578 if (It != EqTypes.end() && It->first == Ty)
579 return It->second == Ty2; // Looping back on a type, check for equality
581 // Otherwise, add the mapping to the table to make sure we don't get
582 // recursion on the types...
583 EqTypes.insert(It, std::make_pair(Ty, Ty2));
585 // Two really annoying special cases that breaks an otherwise nice simple
586 // algorithm is the fact that arraytypes have sizes that differentiates types,
587 // and that function types can be varargs or not. Consider this now.
589 if (const PointerType *PTy = dyn_cast<PointerType>(Ty)) {
590 return TypesEqual(PTy->getElementType(),
591 cast<PointerType>(Ty2)->getElementType(), EqTypes);
592 } else if (const StructType *STy = dyn_cast<StructType>(Ty)) {
593 const StructType *STy2 = cast<StructType>(Ty2);
594 if (STy->getNumElements() != STy2->getNumElements()) return false;
595 if (STy->isPacked() != STy2->isPacked()) return false;
596 for (unsigned i = 0, e = STy2->getNumElements(); i != e; ++i)
597 if (!TypesEqual(STy->getElementType(i), STy2->getElementType(i), EqTypes))
600 } else if (const ArrayType *ATy = dyn_cast<ArrayType>(Ty)) {
601 const ArrayType *ATy2 = cast<ArrayType>(Ty2);
602 return ATy->getNumElements() == ATy2->getNumElements() &&
603 TypesEqual(ATy->getElementType(), ATy2->getElementType(), EqTypes);
604 } else if (const PackedType *PTy = dyn_cast<PackedType>(Ty)) {
605 const PackedType *PTy2 = cast<PackedType>(Ty2);
606 return PTy->getNumElements() == PTy2->getNumElements() &&
607 TypesEqual(PTy->getElementType(), PTy2->getElementType(), EqTypes);
608 } else if (const FunctionType *FTy = dyn_cast<FunctionType>(Ty)) {
609 const FunctionType *FTy2 = cast<FunctionType>(Ty2);
610 if (FTy->isVarArg() != FTy2->isVarArg() ||
611 FTy->getNumParams() != FTy2->getNumParams() ||
612 !TypesEqual(FTy->getReturnType(), FTy2->getReturnType(), EqTypes))
614 for (unsigned i = 0, e = FTy2->getNumParams(); i != e; ++i)
615 if (!TypesEqual(FTy->getParamType(i), FTy2->getParamType(i), EqTypes))
619 assert(0 && "Unknown derived type!");
624 static bool TypesEqual(const Type *Ty, const Type *Ty2) {
625 std::map<const Type *, const Type *> EqTypes;
626 return TypesEqual(Ty, Ty2, EqTypes);
629 // AbstractTypeHasCycleThrough - Return true there is a path from CurTy to
630 // TargetTy in the type graph. We know that Ty is an abstract type, so if we
631 // ever reach a non-abstract type, we know that we don't need to search the
633 static bool AbstractTypeHasCycleThrough(const Type *TargetTy, const Type *CurTy,
634 std::set<const Type*> &VisitedTypes) {
635 if (TargetTy == CurTy) return true;
636 if (!CurTy->isAbstract()) return false;
638 if (!VisitedTypes.insert(CurTy).second)
639 return false; // Already been here.
641 for (Type::subtype_iterator I = CurTy->subtype_begin(),
642 E = CurTy->subtype_end(); I != E; ++I)
643 if (AbstractTypeHasCycleThrough(TargetTy, *I, VisitedTypes))
648 static bool ConcreteTypeHasCycleThrough(const Type *TargetTy, const Type *CurTy,
649 std::set<const Type*> &VisitedTypes) {
650 if (TargetTy == CurTy) return true;
652 if (!VisitedTypes.insert(CurTy).second)
653 return false; // Already been here.
655 for (Type::subtype_iterator I = CurTy->subtype_begin(),
656 E = CurTy->subtype_end(); I != E; ++I)
657 if (ConcreteTypeHasCycleThrough(TargetTy, *I, VisitedTypes))
662 /// TypeHasCycleThroughItself - Return true if the specified type has a cycle
664 static bool TypeHasCycleThroughItself(const Type *Ty) {
665 std::set<const Type*> VisitedTypes;
667 if (Ty->isAbstract()) { // Optimized case for abstract types.
668 for (Type::subtype_iterator I = Ty->subtype_begin(), E = Ty->subtype_end();
670 if (AbstractTypeHasCycleThrough(Ty, *I, VisitedTypes))
673 for (Type::subtype_iterator I = Ty->subtype_begin(), E = Ty->subtype_end();
675 if (ConcreteTypeHasCycleThrough(Ty, *I, VisitedTypes))
681 /// getSubElementHash - Generate a hash value for all of the SubType's of this
682 /// type. The hash value is guaranteed to be zero if any of the subtypes are
683 /// an opaque type. Otherwise we try to mix them in as well as possible, but do
684 /// not look at the subtype's subtype's.
685 static unsigned getSubElementHash(const Type *Ty) {
686 unsigned HashVal = 0;
687 for (Type::subtype_iterator I = Ty->subtype_begin(), E = Ty->subtype_end();
690 const Type *SubTy = I->get();
691 HashVal += SubTy->getTypeID();
692 switch (SubTy->getTypeID()) {
694 case Type::OpaqueTyID: return 0; // Opaque -> hash = 0 no matter what.
695 case Type::FunctionTyID:
696 HashVal ^= cast<FunctionType>(SubTy)->getNumParams()*2 +
697 cast<FunctionType>(SubTy)->isVarArg();
699 case Type::ArrayTyID:
700 HashVal ^= cast<ArrayType>(SubTy)->getNumElements();
702 case Type::PackedTyID:
703 HashVal ^= cast<PackedType>(SubTy)->getNumElements();
705 case Type::StructTyID:
706 HashVal ^= cast<StructType>(SubTy)->getNumElements();
710 return HashVal ? HashVal : 1; // Do not return zero unless opaque subty.
713 //===----------------------------------------------------------------------===//
714 // Derived Type Factory Functions
715 //===----------------------------------------------------------------------===//
720 /// TypesByHash - Keep track of types by their structure hash value. Note
721 /// that we only keep track of types that have cycles through themselves in
724 std::multimap<unsigned, PATypeHolder> TypesByHash;
727 void RemoveFromTypesByHash(unsigned Hash, const Type *Ty) {
728 std::multimap<unsigned, PATypeHolder>::iterator I =
729 TypesByHash.lower_bound(Hash);
730 for (; I != TypesByHash.end() && I->first == Hash; ++I) {
731 if (I->second == Ty) {
732 TypesByHash.erase(I);
737 // This must be do to an opaque type that was resolved. Switch down to hash
739 assert(Hash && "Didn't find type entry!");
740 RemoveFromTypesByHash(0, Ty);
743 /// TypeBecameConcrete - When Ty gets a notification that TheType just became
744 /// concrete, drop uses and make Ty non-abstract if we should.
745 void TypeBecameConcrete(DerivedType *Ty, const DerivedType *TheType) {
746 // If the element just became concrete, remove 'ty' from the abstract
747 // type user list for the type. Do this for as many times as Ty uses
749 for (Type::subtype_iterator I = Ty->subtype_begin(), E = Ty->subtype_end();
751 if (I->get() == TheType)
752 TheType->removeAbstractTypeUser(Ty);
754 // If the type is currently thought to be abstract, rescan all of our
755 // subtypes to see if the type has just become concrete! Note that this
756 // may send out notifications to AbstractTypeUsers that types become
758 if (Ty->isAbstract())
759 Ty->PromoteAbstractToConcrete();
765 // TypeMap - Make sure that only one instance of a particular type may be
766 // created on any given run of the compiler... note that this involves updating
767 // our map if an abstract type gets refined somehow.
770 template<class ValType, class TypeClass>
771 class TypeMap : public TypeMapBase {
772 std::map<ValType, PATypeHolder> Map;
774 typedef typename std::map<ValType, PATypeHolder>::iterator iterator;
775 ~TypeMap() { print("ON EXIT"); }
777 inline TypeClass *get(const ValType &V) {
778 iterator I = Map.find(V);
779 return I != Map.end() ? cast<TypeClass>((Type*)I->second.get()) : 0;
782 inline void add(const ValType &V, TypeClass *Ty) {
783 Map.insert(std::make_pair(V, Ty));
785 // If this type has a cycle, remember it.
786 TypesByHash.insert(std::make_pair(ValType::hashTypeStructure(Ty), Ty));
790 void clear(std::vector<Type *> &DerivedTypes) {
791 for (typename std::map<ValType, PATypeHolder>::iterator I = Map.begin(),
792 E = Map.end(); I != E; ++I)
793 DerivedTypes.push_back(I->second.get());
798 /// RefineAbstractType - This method is called after we have merged a type
799 /// with another one. We must now either merge the type away with
800 /// some other type or reinstall it in the map with it's new configuration.
801 void RefineAbstractType(TypeClass *Ty, const DerivedType *OldType,
802 const Type *NewType) {
803 #ifdef DEBUG_MERGE_TYPES
804 DOUT << "RefineAbstractType(" << (void*)OldType << "[" << *OldType
805 << "], " << (void*)NewType << " [" << *NewType << "])\n";
808 // Otherwise, we are changing one subelement type into another. Clearly the
809 // OldType must have been abstract, making us abstract.
810 assert(Ty->isAbstract() && "Refining a non-abstract type!");
811 assert(OldType != NewType);
813 // Make a temporary type holder for the type so that it doesn't disappear on
814 // us when we erase the entry from the map.
815 PATypeHolder TyHolder = Ty;
817 // The old record is now out-of-date, because one of the children has been
818 // updated. Remove the obsolete entry from the map.
819 unsigned NumErased = Map.erase(ValType::get(Ty));
820 assert(NumErased && "Element not found!");
822 // Remember the structural hash for the type before we start hacking on it,
823 // in case we need it later.
824 unsigned OldTypeHash = ValType::hashTypeStructure(Ty);
826 // Find the type element we are refining... and change it now!
827 for (unsigned i = 0, e = Ty->ContainedTys.size(); i != e; ++i)
828 if (Ty->ContainedTys[i] == OldType)
829 Ty->ContainedTys[i] = NewType;
830 unsigned NewTypeHash = ValType::hashTypeStructure(Ty);
832 // If there are no cycles going through this node, we can do a simple,
833 // efficient lookup in the map, instead of an inefficient nasty linear
835 if (!TypeHasCycleThroughItself(Ty)) {
836 typename std::map<ValType, PATypeHolder>::iterator I;
839 tie(I, Inserted) = Map.insert(std::make_pair(ValType::get(Ty), Ty));
841 // Refined to a different type altogether?
842 RemoveFromTypesByHash(OldTypeHash, Ty);
844 // We already have this type in the table. Get rid of the newly refined
846 TypeClass *NewTy = cast<TypeClass>((Type*)I->second.get());
847 Ty->refineAbstractTypeTo(NewTy);
851 // Now we check to see if there is an existing entry in the table which is
852 // structurally identical to the newly refined type. If so, this type
853 // gets refined to the pre-existing type.
855 std::multimap<unsigned, PATypeHolder>::iterator I, E, Entry;
856 tie(I, E) = TypesByHash.equal_range(NewTypeHash);
858 for (; I != E; ++I) {
859 if (I->second == Ty) {
860 // Remember the position of the old type if we see it in our scan.
863 if (TypesEqual(Ty, I->second)) {
864 TypeClass *NewTy = cast<TypeClass>((Type*)I->second.get());
866 // Remove the old entry form TypesByHash. If the hash values differ
867 // now, remove it from the old place. Otherwise, continue scanning
868 // withing this hashcode to reduce work.
869 if (NewTypeHash != OldTypeHash) {
870 RemoveFromTypesByHash(OldTypeHash, Ty);
873 // Find the location of Ty in the TypesByHash structure if we
874 // haven't seen it already.
875 while (I->second != Ty) {
877 assert(I != E && "Structure doesn't contain type??");
881 TypesByHash.erase(Entry);
883 Ty->refineAbstractTypeTo(NewTy);
889 // If there is no existing type of the same structure, we reinsert an
890 // updated record into the map.
891 Map.insert(std::make_pair(ValType::get(Ty), Ty));
894 // If the hash codes differ, update TypesByHash
895 if (NewTypeHash != OldTypeHash) {
896 RemoveFromTypesByHash(OldTypeHash, Ty);
897 TypesByHash.insert(std::make_pair(NewTypeHash, Ty));
900 // If the type is currently thought to be abstract, rescan all of our
901 // subtypes to see if the type has just become concrete! Note that this
902 // may send out notifications to AbstractTypeUsers that types become
904 if (Ty->isAbstract())
905 Ty->PromoteAbstractToConcrete();
908 void print(const char *Arg) const {
909 #ifdef DEBUG_MERGE_TYPES
910 DOUT << "TypeMap<>::" << Arg << " table contents:\n";
912 for (typename std::map<ValType, PATypeHolder>::const_iterator I
913 = Map.begin(), E = Map.end(); I != E; ++I)
914 DOUT << " " << (++i) << ". " << (void*)I->second.get() << " "
915 << *I->second.get() << "\n";
919 void dump() const { print("dump output"); }
924 //===----------------------------------------------------------------------===//
925 // Function Type Factory and Value Class...
928 // FunctionValType - Define a class to hold the key that goes into the TypeMap
931 class FunctionValType {
933 std::vector<const Type*> ArgTypes;
934 std::vector<FunctionType::ParameterAttributes> ParamAttrs;
937 FunctionValType(const Type *ret, const std::vector<const Type*> &args,
938 bool IVA, const FunctionType::ParamAttrsList &attrs)
939 : RetTy(ret), isVarArg(IVA) {
940 for (unsigned i = 0; i < args.size(); ++i)
941 ArgTypes.push_back(args[i]);
942 for (unsigned i = 0; i < attrs.size(); ++i)
943 ParamAttrs.push_back(attrs[i]);
946 static FunctionValType get(const FunctionType *FT);
948 static unsigned hashTypeStructure(const FunctionType *FT) {
949 return FT->getNumParams()*64+FT->getNumAttrs()*2+FT->isVarArg();
952 // Subclass should override this... to update self as usual
953 void doRefinement(const DerivedType *OldType, const Type *NewType) {
954 if (RetTy == OldType) RetTy = NewType;
955 for (unsigned i = 0, e = ArgTypes.size(); i != e; ++i)
956 if (ArgTypes[i] == OldType) ArgTypes[i] = NewType;
959 inline bool operator<(const FunctionValType &MTV) const {
960 if (RetTy < MTV.RetTy) return true;
961 if (RetTy > MTV.RetTy) return false;
962 if (isVarArg < MTV.isVarArg) return true;
963 if (isVarArg > MTV.isVarArg) return false;
964 if (ArgTypes < MTV.ArgTypes) return true;
965 return ArgTypes == MTV.ArgTypes && ParamAttrs < MTV.ParamAttrs;
970 // Define the actual map itself now...
971 static ManagedStatic<TypeMap<FunctionValType, FunctionType> > FunctionTypes;
973 FunctionValType FunctionValType::get(const FunctionType *FT) {
974 // Build up a FunctionValType
975 std::vector<const Type *> ParamTypes;
976 std::vector<FunctionType::ParameterAttributes> ParamAttrs;
977 ParamTypes.reserve(FT->getNumParams());
978 for (unsigned i = 0, e = FT->getNumParams(); i != e; ++i)
979 ParamTypes.push_back(FT->getParamType(i));
980 for (unsigned i = 0, e = FT->getNumAttrs(); i != e; ++i)
981 ParamAttrs.push_back(FT->getParamAttrs(i));
982 return FunctionValType(FT->getReturnType(), ParamTypes, FT->isVarArg(),
987 // FunctionType::get - The factory function for the FunctionType class...
988 FunctionType *FunctionType::get(const Type *ReturnType,
989 const std::vector<const Type*> &Params,
991 const std::vector<ParameterAttributes> &Attrs) {
993 for (unsigned i = 0, e = Attrs.size(); i < e; ++i)
994 if (Attrs[i] != FunctionType::NoAttributeSet) {
998 const std::vector<FunctionType::ParameterAttributes> NullAttrs;
999 const std::vector<FunctionType::ParameterAttributes> *TheAttrs = &Attrs;
1001 TheAttrs = &NullAttrs;
1002 FunctionValType VT(ReturnType, Params, isVarArg, *TheAttrs);
1003 FunctionType *MT = FunctionTypes->get(VT);
1006 MT = new FunctionType(ReturnType, Params, isVarArg, *TheAttrs);
1007 FunctionTypes->add(VT, MT);
1009 #ifdef DEBUG_MERGE_TYPES
1010 DOUT << "Derived new type: " << MT << "\n";
1015 FunctionType::ParameterAttributes
1016 FunctionType::getParamAttrs(unsigned Idx) const {
1018 return ParameterAttributes(0);
1019 if (Idx > ParamAttrs->size())
1020 return ParameterAttributes(0);
1021 return (*ParamAttrs)[Idx];
1024 const char *FunctionType::getParamAttrsText(ParameterAttributes Attr) {
1026 default: assert(0 && "Invalid ParameterAttribute value");
1028 case ZExtAttribute: return "@zext";
1029 case SExtAttribute: return "@sext";
1033 //===----------------------------------------------------------------------===//
1034 // Array Type Factory...
1037 class ArrayValType {
1041 ArrayValType(const Type *val, uint64_t sz) : ValTy(val), Size(sz) {}
1043 static ArrayValType get(const ArrayType *AT) {
1044 return ArrayValType(AT->getElementType(), AT->getNumElements());
1047 static unsigned hashTypeStructure(const ArrayType *AT) {
1048 return (unsigned)AT->getNumElements();
1051 // Subclass should override this... to update self as usual
1052 void doRefinement(const DerivedType *OldType, const Type *NewType) {
1053 assert(ValTy == OldType);
1057 inline bool operator<(const ArrayValType &MTV) const {
1058 if (Size < MTV.Size) return true;
1059 return Size == MTV.Size && ValTy < MTV.ValTy;
1063 static ManagedStatic<TypeMap<ArrayValType, ArrayType> > ArrayTypes;
1066 ArrayType *ArrayType::get(const Type *ElementType, uint64_t NumElements) {
1067 assert(ElementType && "Can't get array of null types!");
1069 ArrayValType AVT(ElementType, NumElements);
1070 ArrayType *AT = ArrayTypes->get(AVT);
1071 if (AT) return AT; // Found a match, return it!
1073 // Value not found. Derive a new type!
1074 ArrayTypes->add(AVT, AT = new ArrayType(ElementType, NumElements));
1076 #ifdef DEBUG_MERGE_TYPES
1077 DOUT << "Derived new type: " << *AT << "\n";
1083 //===----------------------------------------------------------------------===//
1084 // Packed Type Factory...
1087 class PackedValType {
1091 PackedValType(const Type *val, int sz) : ValTy(val), Size(sz) {}
1093 static PackedValType get(const PackedType *PT) {
1094 return PackedValType(PT->getElementType(), PT->getNumElements());
1097 static unsigned hashTypeStructure(const PackedType *PT) {
1098 return PT->getNumElements();
1101 // Subclass should override this... to update self as usual
1102 void doRefinement(const DerivedType *OldType, const Type *NewType) {
1103 assert(ValTy == OldType);
1107 inline bool operator<(const PackedValType &MTV) const {
1108 if (Size < MTV.Size) return true;
1109 return Size == MTV.Size && ValTy < MTV.ValTy;
1113 static ManagedStatic<TypeMap<PackedValType, PackedType> > PackedTypes;
1116 PackedType *PackedType::get(const Type *ElementType, unsigned NumElements) {
1117 assert(ElementType && "Can't get packed of null types!");
1118 assert(isPowerOf2_32(NumElements) && "Vector length should be a power of 2!");
1120 PackedValType PVT(ElementType, NumElements);
1121 PackedType *PT = PackedTypes->get(PVT);
1122 if (PT) return PT; // Found a match, return it!
1124 // Value not found. Derive a new type!
1125 PackedTypes->add(PVT, PT = new PackedType(ElementType, NumElements));
1127 #ifdef DEBUG_MERGE_TYPES
1128 DOUT << "Derived new type: " << *PT << "\n";
1133 //===----------------------------------------------------------------------===//
1134 // Struct Type Factory...
1138 // StructValType - Define a class to hold the key that goes into the TypeMap
1140 class StructValType {
1141 std::vector<const Type*> ElTypes;
1144 StructValType(const std::vector<const Type*> &args, bool isPacked)
1145 : ElTypes(args), packed(isPacked) {}
1147 static StructValType get(const StructType *ST) {
1148 std::vector<const Type *> ElTypes;
1149 ElTypes.reserve(ST->getNumElements());
1150 for (unsigned i = 0, e = ST->getNumElements(); i != e; ++i)
1151 ElTypes.push_back(ST->getElementType(i));
1153 return StructValType(ElTypes, ST->isPacked());
1156 static unsigned hashTypeStructure(const StructType *ST) {
1157 return ST->getNumElements();
1160 // Subclass should override this... to update self as usual
1161 void doRefinement(const DerivedType *OldType, const Type *NewType) {
1162 for (unsigned i = 0; i < ElTypes.size(); ++i)
1163 if (ElTypes[i] == OldType) ElTypes[i] = NewType;
1166 inline bool operator<(const StructValType &STV) const {
1167 if (ElTypes < STV.ElTypes) return true;
1168 else if (ElTypes > STV.ElTypes) return false;
1169 else return (int)packed < (int)STV.packed;
1174 static ManagedStatic<TypeMap<StructValType, StructType> > StructTypes;
1176 StructType *StructType::get(const std::vector<const Type*> &ETypes,
1178 StructValType STV(ETypes, isPacked);
1179 StructType *ST = StructTypes->get(STV);
1182 // Value not found. Derive a new type!
1183 StructTypes->add(STV, ST = new StructType(ETypes, isPacked));
1185 #ifdef DEBUG_MERGE_TYPES
1186 DOUT << "Derived new type: " << *ST << "\n";
1193 //===----------------------------------------------------------------------===//
1194 // Pointer Type Factory...
1197 // PointerValType - Define a class to hold the key that goes into the TypeMap
1200 class PointerValType {
1203 PointerValType(const Type *val) : ValTy(val) {}
1205 static PointerValType get(const PointerType *PT) {
1206 return PointerValType(PT->getElementType());
1209 static unsigned hashTypeStructure(const PointerType *PT) {
1210 return getSubElementHash(PT);
1213 // Subclass should override this... to update self as usual
1214 void doRefinement(const DerivedType *OldType, const Type *NewType) {
1215 assert(ValTy == OldType);
1219 bool operator<(const PointerValType &MTV) const {
1220 return ValTy < MTV.ValTy;
1225 static ManagedStatic<TypeMap<PointerValType, PointerType> > PointerTypes;
1227 PointerType *PointerType::get(const Type *ValueType) {
1228 assert(ValueType && "Can't get a pointer to <null> type!");
1229 assert(ValueType != Type::VoidTy &&
1230 "Pointer to void is not valid, use sbyte* instead!");
1231 assert(ValueType != Type::LabelTy && "Pointer to label is not valid!");
1232 PointerValType PVT(ValueType);
1234 PointerType *PT = PointerTypes->get(PVT);
1237 // Value not found. Derive a new type!
1238 PointerTypes->add(PVT, PT = new PointerType(ValueType));
1240 #ifdef DEBUG_MERGE_TYPES
1241 DOUT << "Derived new type: " << *PT << "\n";
1246 //===----------------------------------------------------------------------===//
1247 // Derived Type Refinement Functions
1248 //===----------------------------------------------------------------------===//
1250 // removeAbstractTypeUser - Notify an abstract type that a user of the class
1251 // no longer has a handle to the type. This function is called primarily by
1252 // the PATypeHandle class. When there are no users of the abstract type, it
1253 // is annihilated, because there is no way to get a reference to it ever again.
1255 void Type::removeAbstractTypeUser(AbstractTypeUser *U) const {
1256 // Search from back to front because we will notify users from back to
1257 // front. Also, it is likely that there will be a stack like behavior to
1258 // users that register and unregister users.
1261 for (i = AbstractTypeUsers.size(); AbstractTypeUsers[i-1] != U; --i)
1262 assert(i != 0 && "AbstractTypeUser not in user list!");
1264 --i; // Convert to be in range 0 <= i < size()
1265 assert(i < AbstractTypeUsers.size() && "Index out of range!"); // Wraparound?
1267 AbstractTypeUsers.erase(AbstractTypeUsers.begin()+i);
1269 #ifdef DEBUG_MERGE_TYPES
1270 DOUT << " remAbstractTypeUser[" << (void*)this << ", "
1271 << *this << "][" << i << "] User = " << U << "\n";
1274 if (AbstractTypeUsers.empty() && getRefCount() == 0 && isAbstract()) {
1275 #ifdef DEBUG_MERGE_TYPES
1276 DOUT << "DELETEing unused abstract type: <" << *this
1277 << ">[" << (void*)this << "]" << "\n";
1279 delete this; // No users of this abstract type!
1284 // refineAbstractTypeTo - This function is used when it is discovered that
1285 // the 'this' abstract type is actually equivalent to the NewType specified.
1286 // This causes all users of 'this' to switch to reference the more concrete type
1287 // NewType and for 'this' to be deleted.
1289 void DerivedType::refineAbstractTypeTo(const Type *NewType) {
1290 assert(isAbstract() && "refineAbstractTypeTo: Current type is not abstract!");
1291 assert(this != NewType && "Can't refine to myself!");
1292 assert(ForwardType == 0 && "This type has already been refined!");
1294 // The descriptions may be out of date. Conservatively clear them all!
1295 AbstractTypeDescriptions->clear();
1297 #ifdef DEBUG_MERGE_TYPES
1298 DOUT << "REFINING abstract type [" << (void*)this << " "
1299 << *this << "] to [" << (void*)NewType << " "
1300 << *NewType << "]!\n";
1303 // Make sure to put the type to be refined to into a holder so that if IT gets
1304 // refined, that we will not continue using a dead reference...
1306 PATypeHolder NewTy(NewType);
1308 // Any PATypeHolders referring to this type will now automatically forward to
1309 // the type we are resolved to.
1310 ForwardType = NewType;
1311 if (NewType->isAbstract())
1312 cast<DerivedType>(NewType)->addRef();
1314 // Add a self use of the current type so that we don't delete ourself until
1315 // after the function exits.
1317 PATypeHolder CurrentTy(this);
1319 // To make the situation simpler, we ask the subclass to remove this type from
1320 // the type map, and to replace any type uses with uses of non-abstract types.
1321 // This dramatically limits the amount of recursive type trouble we can find
1325 // Iterate over all of the uses of this type, invoking callback. Each user
1326 // should remove itself from our use list automatically. We have to check to
1327 // make sure that NewTy doesn't _become_ 'this'. If it does, resolving types
1328 // will not cause users to drop off of the use list. If we resolve to ourself
1331 while (!AbstractTypeUsers.empty() && NewTy != this) {
1332 AbstractTypeUser *User = AbstractTypeUsers.back();
1334 unsigned OldSize = AbstractTypeUsers.size();
1335 #ifdef DEBUG_MERGE_TYPES
1336 DOUT << " REFINING user " << OldSize-1 << "[" << (void*)User
1337 << "] of abstract type [" << (void*)this << " "
1338 << *this << "] to [" << (void*)NewTy.get() << " "
1339 << *NewTy << "]!\n";
1341 User->refineAbstractType(this, NewTy);
1343 assert(AbstractTypeUsers.size() != OldSize &&
1344 "AbsTyUser did not remove self from user list!");
1347 // If we were successful removing all users from the type, 'this' will be
1348 // deleted when the last PATypeHolder is destroyed or updated from this type.
1349 // This may occur on exit of this function, as the CurrentTy object is
1353 // notifyUsesThatTypeBecameConcrete - Notify AbstractTypeUsers of this type that
1354 // the current type has transitioned from being abstract to being concrete.
1356 void DerivedType::notifyUsesThatTypeBecameConcrete() {
1357 #ifdef DEBUG_MERGE_TYPES
1358 DOUT << "typeIsREFINED type: " << (void*)this << " " << *this << "\n";
1361 unsigned OldSize = AbstractTypeUsers.size();
1362 while (!AbstractTypeUsers.empty()) {
1363 AbstractTypeUser *ATU = AbstractTypeUsers.back();
1364 ATU->typeBecameConcrete(this);
1366 assert(AbstractTypeUsers.size() < OldSize-- &&
1367 "AbstractTypeUser did not remove itself from the use list!");
1371 // refineAbstractType - Called when a contained type is found to be more
1372 // concrete - this could potentially change us from an abstract type to a
1375 void FunctionType::refineAbstractType(const DerivedType *OldType,
1376 const Type *NewType) {
1377 FunctionTypes->RefineAbstractType(this, OldType, NewType);
1380 void FunctionType::typeBecameConcrete(const DerivedType *AbsTy) {
1381 FunctionTypes->TypeBecameConcrete(this, AbsTy);
1385 // refineAbstractType - Called when a contained type is found to be more
1386 // concrete - this could potentially change us from an abstract type to a
1389 void ArrayType::refineAbstractType(const DerivedType *OldType,
1390 const Type *NewType) {
1391 ArrayTypes->RefineAbstractType(this, OldType, NewType);
1394 void ArrayType::typeBecameConcrete(const DerivedType *AbsTy) {
1395 ArrayTypes->TypeBecameConcrete(this, AbsTy);
1398 // refineAbstractType - Called when a contained type is found to be more
1399 // concrete - this could potentially change us from an abstract type to a
1402 void PackedType::refineAbstractType(const DerivedType *OldType,
1403 const Type *NewType) {
1404 PackedTypes->RefineAbstractType(this, OldType, NewType);
1407 void PackedType::typeBecameConcrete(const DerivedType *AbsTy) {
1408 PackedTypes->TypeBecameConcrete(this, AbsTy);
1411 // refineAbstractType - Called when a contained type is found to be more
1412 // concrete - this could potentially change us from an abstract type to a
1415 void StructType::refineAbstractType(const DerivedType *OldType,
1416 const Type *NewType) {
1417 StructTypes->RefineAbstractType(this, OldType, NewType);
1420 void StructType::typeBecameConcrete(const DerivedType *AbsTy) {
1421 StructTypes->TypeBecameConcrete(this, AbsTy);
1424 // refineAbstractType - Called when a contained type is found to be more
1425 // concrete - this could potentially change us from an abstract type to a
1428 void PointerType::refineAbstractType(const DerivedType *OldType,
1429 const Type *NewType) {
1430 PointerTypes->RefineAbstractType(this, OldType, NewType);
1433 void PointerType::typeBecameConcrete(const DerivedType *AbsTy) {
1434 PointerTypes->TypeBecameConcrete(this, AbsTy);
1437 bool SequentialType::indexValid(const Value *V) const {
1438 const Type *Ty = V->getType();
1439 switch (Ty->getTypeID()) {
1440 case Type::Int32TyID:
1441 case Type::Int64TyID:
1449 std::ostream &operator<<(std::ostream &OS, const Type *T) {
1451 OS << "<null> value!\n";
1457 std::ostream &operator<<(std::ostream &OS, const Type &T) {