1 //===- CanonicalType.h - C Language Family Type Representation --*- C++ -*-===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 //
9 // This file defines the CanQual class template, which provides access to
10 // canonical types.
11 //
12 //===----------------------------------------------------------------------===//
13
14 #ifndef LLVM_CLANG_AST_CANONICALTYPE_H
15 #define LLVM_CLANG_AST_CANONICALTYPE_H
16
17 #include "clang/AST/Type.h"
18 #include "clang/Basic/Diagnostic.h"
19 #include "clang/Basic/SourceLocation.h"
20 #include "llvm/ADT/ArrayRef.h"
21 #include "llvm/ADT/FoldingSet.h"
22 #include "llvm/ADT/iterator.h"
23 #include "llvm/Support/Casting.h"
24 #include "llvm/Support/PointerLikeTypeTraits.h"
25 #include <cassert>
26 #include <iterator>
27 #include <type_traits>
28
29 namespace clang {
30
31 template<typename T> class CanProxy;
32 template<typename T> struct CanProxyAdaptor;
33 class CXXRecordDecl;
34 class EnumDecl;
35 class Expr;
36 class IdentifierInfo;
37 class ObjCInterfaceDecl;
38 class RecordDecl;
39 class TagDecl;
40 class TemplateTypeParmDecl;
41
42 //----------------------------------------------------------------------------//
43 // Canonical, qualified type template
44 //----------------------------------------------------------------------------//
45
46 /// Represents a canonical, potentially-qualified type.
47 ///
48 /// The CanQual template is a lightweight smart pointer that provides access
49 /// to the canonical representation of a type, where all typedefs and other
50 /// syntactic sugar has been eliminated. A CanQualType may also have various
51 /// qualifiers (const, volatile, restrict) attached to it.
52 ///
53 /// The template type parameter @p T is one of the Type classes (PointerType,
54 /// BuiltinType, etc.). The type stored within @c CanQual<T> will be of that
55 /// type (or some subclass of that type). The typedef @c CanQualType is just
56 /// a shorthand for @c CanQual<Type>.
57 ///
58 /// An instance of @c CanQual<T> can be implicitly converted to a
59 /// @c CanQual<U> when T is derived from U, which essentially provides an
60 /// implicit upcast. For example, @c CanQual<LValueReferenceType> can be
61 /// converted to @c CanQual<ReferenceType>. Note that any @c CanQual type can
62 /// be implicitly converted to a QualType, but the reverse operation requires
63 /// a call to ASTContext::getCanonicalType().
64 template<typename T = Type>
65 class CanQual {
66 /// The actual, canonical type.
67 QualType Stored;
68
69 public:
70 /// Constructs a NULL canonical type.
71 CanQual() = default;
72
73 /// Converting constructor that permits implicit upcasting of
74 /// canonical type pointers.
75 template <typename U>
76 CanQual(const CanQual<U> &Other,
77 std::enable_if_t<std::is_base_of<T, U>::value, int> = 0);
78
79 /// Retrieve the underlying type pointer, which refers to a
80 /// canonical type.
81 ///
82 /// The underlying pointer must not be nullptr.
getTypePtr()83 const T *getTypePtr() const { return cast<T>(Stored.getTypePtr()); }
84
85 /// Retrieve the underlying type pointer, which refers to a
86 /// canonical type, or nullptr.
getTypePtrOrNull()87 const T *getTypePtrOrNull() const {
88 return cast_or_null<T>(Stored.getTypePtrOrNull());
89 }
90
91 /// Implicit conversion to a qualified type.
QualType()92 operator QualType() const { return Stored; }
93
94 /// Implicit conversion to bool.
95 explicit operator bool() const { return !isNull(); }
96
isNull()97 bool isNull() const {
98 return Stored.isNull();
99 }
100
split()101 SplitQualType split() const { return Stored.split(); }
102
103 /// Retrieve a canonical type pointer with a different static type,
104 /// upcasting or downcasting as needed.
105 ///
106 /// The getAs() function is typically used to try to downcast to a
107 /// more specific (canonical) type in the type system. For example:
108 ///
109 /// @code
110 /// void f(CanQual<Type> T) {
111 /// if (CanQual<PointerType> Ptr = T->getAs<PointerType>()) {
112 /// // look at Ptr's pointee type
113 /// }
114 /// }
115 /// @endcode
116 ///
117 /// \returns A proxy pointer to the same type, but with the specified
118 /// static type (@p U). If the dynamic type is not the specified static type
119 /// or a derived class thereof, a NULL canonical type.
120 template<typename U> CanProxy<U> getAs() const;
121
122 template<typename U> CanProxy<U> castAs() const;
123
124 /// Overloaded arrow operator that produces a canonical type
125 /// proxy.
126 CanProxy<T> operator->() const;
127
128 /// Retrieve all qualifiers.
getQualifiers()129 Qualifiers getQualifiers() const { return Stored.getLocalQualifiers(); }
130
131 /// Retrieve the const/volatile/restrict qualifiers.
getCVRQualifiers()132 unsigned getCVRQualifiers() const { return Stored.getLocalCVRQualifiers(); }
133
134 /// Determines whether this type has any qualifiers
hasQualifiers()135 bool hasQualifiers() const { return Stored.hasLocalQualifiers(); }
136
isConstQualified()137 bool isConstQualified() const {
138 return Stored.isLocalConstQualified();
139 }
140
isVolatileQualified()141 bool isVolatileQualified() const {
142 return Stored.isLocalVolatileQualified();
143 }
144
isRestrictQualified()145 bool isRestrictQualified() const {
146 return Stored.isLocalRestrictQualified();
147 }
148
149 /// Determines if this canonical type is furthermore
150 /// canonical as a parameter. The parameter-canonicalization
151 /// process decays arrays to pointers and drops top-level qualifiers.
isCanonicalAsParam()152 bool isCanonicalAsParam() const {
153 return Stored.isCanonicalAsParam();
154 }
155
156 /// Retrieve the unqualified form of this type.
157 CanQual<T> getUnqualifiedType() const;
158
159 /// Retrieves a version of this type with const applied.
160 /// Note that this does not always yield a canonical type.
withConst()161 QualType withConst() const {
162 return Stored.withConst();
163 }
164
165 /// Determines whether this canonical type is more qualified than
166 /// the @p Other canonical type.
isMoreQualifiedThan(CanQual<T> Other)167 bool isMoreQualifiedThan(CanQual<T> Other) const {
168 return Stored.isMoreQualifiedThan(Other.Stored);
169 }
170
171 /// Determines whether this canonical type is at least as qualified as
172 /// the @p Other canonical type.
isAtLeastAsQualifiedAs(CanQual<T> Other)173 bool isAtLeastAsQualifiedAs(CanQual<T> Other) const {
174 return Stored.isAtLeastAsQualifiedAs(Other.Stored);
175 }
176
177 /// If the canonical type is a reference type, returns the type that
178 /// it refers to; otherwise, returns the type itself.
179 CanQual<Type> getNonReferenceType() const;
180
181 /// Retrieve the internal representation of this canonical type.
getAsOpaquePtr()182 void *getAsOpaquePtr() const { return Stored.getAsOpaquePtr(); }
183
184 /// Construct a canonical type from its internal representation.
185 static CanQual<T> getFromOpaquePtr(void *Ptr);
186
187 /// Builds a canonical type from a QualType.
188 ///
189 /// This routine is inherently unsafe, because it requires the user to
190 /// ensure that the given type is a canonical type with the correct
191 // (dynamic) type.
192 static CanQual<T> CreateUnsafe(QualType Other);
193
dump()194 void dump() const { Stored.dump(); }
195
Profile(llvm::FoldingSetNodeID & ID)196 void Profile(llvm::FoldingSetNodeID &ID) const {
197 ID.AddPointer(getAsOpaquePtr());
198 }
199 };
200
201 template<typename T, typename U>
202 inline bool operator==(CanQual<T> x, CanQual<U> y) {
203 return x.getAsOpaquePtr() == y.getAsOpaquePtr();
204 }
205
206 template<typename T, typename U>
207 inline bool operator!=(CanQual<T> x, CanQual<U> y) {
208 return x.getAsOpaquePtr() != y.getAsOpaquePtr();
209 }
210
211 /// Represents a canonical, potentially-qualified type.
212 using CanQualType = CanQual<Type>;
213
getCanonicalTypeUnqualified()214 inline CanQualType Type::getCanonicalTypeUnqualified() const {
215 return CanQualType::CreateUnsafe(getCanonicalTypeInternal());
216 }
217
218 inline const StreamingDiagnostic &operator<<(const StreamingDiagnostic &DB,
219 CanQualType T) {
220 DB << static_cast<QualType>(T);
221 return DB;
222 }
223
224 //----------------------------------------------------------------------------//
225 // Internal proxy classes used by canonical types
226 //----------------------------------------------------------------------------//
227
228 #define LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(Accessor) \
229 CanQualType Accessor() const { \
230 return CanQualType::CreateUnsafe(this->getTypePtr()->Accessor()); \
231 }
232
233 #define LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(Type, Accessor) \
234 Type Accessor() const { return this->getTypePtr()->Accessor(); }
235
236 /// Base class of all canonical proxy types, which is responsible for
237 /// storing the underlying canonical type and providing basic conversions.
238 template<typename T>
239 class CanProxyBase {
240 protected:
241 CanQual<T> Stored;
242
243 public:
244 /// Retrieve the pointer to the underlying Type
getTypePtr()245 const T *getTypePtr() const { return Stored.getTypePtr(); }
246
247 /// Implicit conversion to the underlying pointer.
248 ///
249 /// Also provides the ability to use canonical type proxies in a Boolean
250 // context,e.g.,
251 /// @code
252 /// if (CanQual<PointerType> Ptr = T->getAs<PointerType>()) { ... }
253 /// @endcode
254 operator const T*() const { return this->Stored.getTypePtrOrNull(); }
255
256 /// Try to convert the given canonical type to a specific structural
257 /// type.
getAs()258 template<typename U> CanProxy<U> getAs() const {
259 return this->Stored.template getAs<U>();
260 }
261
262 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(Type::TypeClass, getTypeClass)
263
264 // Type predicates
265 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjectType)
266 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIncompleteType)
267 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isSizelessType)
268 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isSizelessBuiltinType)
269 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIncompleteOrObjectType)
270 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isVariablyModifiedType)
271 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIntegerType)
272 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isEnumeralType)
273 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isBooleanType)
274 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isCharType)
275 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isWideCharType)
276 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIntegralType)
277 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIntegralOrEnumerationType)
278 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isRealFloatingType)
279 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isComplexType)
280 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isAnyComplexType)
281 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isFloatingType)
282 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isRealType)
283 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isArithmeticType)
284 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isVoidType)
285 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isDerivedType)
286 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isScalarType)
287 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isAggregateType)
288 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isAnyPointerType)
289 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isVoidPointerType)
290 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isFunctionPointerType)
291 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isMemberFunctionPointerType)
292 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isClassType)
293 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isStructureType)
294 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isInterfaceType)
295 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isStructureOrClassType)
296 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isUnionType)
297 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isComplexIntegerType)
298 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isNullPtrType)
299 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isDependentType)
300 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isOverloadableType)
301 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isArrayType)
302 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasPointerRepresentation)
303 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasObjCPointerRepresentation)
304 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasIntegerRepresentation)
305 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasSignedIntegerRepresentation)
306 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasUnsignedIntegerRepresentation)
307 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasFloatingRepresentation)
308 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isSignedIntegerType)
309 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isUnsignedIntegerType)
310 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isSignedIntegerOrEnumerationType)
311 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isUnsignedIntegerOrEnumerationType)
312 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isConstantSizeType)
313 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isSpecifierType)
314 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(CXXRecordDecl*, getAsCXXRecordDecl)
315
316 /// Retrieve the proxy-adaptor type.
317 ///
318 /// This arrow operator is used when CanProxyAdaptor has been specialized
319 /// for the given type T. In that case, we reference members of the
320 /// CanProxyAdaptor specialization. Otherwise, this operator will be hidden
321 /// by the arrow operator in the primary CanProxyAdaptor template.
322 const CanProxyAdaptor<T> *operator->() const {
323 return static_cast<const CanProxyAdaptor<T> *>(this);
324 }
325 };
326
327 /// Replaceable canonical proxy adaptor class that provides the link
328 /// between a canonical type and the accessors of the type.
329 ///
330 /// The CanProxyAdaptor is a replaceable class template that is instantiated
331 /// as part of each canonical proxy type. The primary template merely provides
332 /// redirection to the underlying type (T), e.g., @c PointerType. One can
333 /// provide specializations of this class template for each underlying type
334 /// that provide accessors returning canonical types (@c CanQualType) rather
335 /// than the more typical @c QualType, to propagate the notion of "canonical"
336 /// through the system.
337 template<typename T>
338 struct CanProxyAdaptor : CanProxyBase<T> {};
339
340 /// Canonical proxy type returned when retrieving the members of a
341 /// canonical type or as the result of the @c CanQual<T>::getAs member
342 /// function.
343 ///
344 /// The CanProxy type mainly exists as a proxy through which operator-> will
345 /// look to either map down to a raw T* (e.g., PointerType*) or to a proxy
346 /// type that provides canonical-type access to the fields of the type.
347 template<typename T>
348 class CanProxy : public CanProxyAdaptor<T> {
349 public:
350 /// Build a NULL proxy.
351 CanProxy() = default;
352
353 /// Build a proxy to the given canonical type.
CanProxy(CanQual<T> Stored)354 CanProxy(CanQual<T> Stored) { this->Stored = Stored; }
355
356 /// Implicit conversion to the stored canonical type.
357 operator CanQual<T>() const { return this->Stored; }
358 };
359
360 } // namespace clang
361
362 namespace llvm {
363
364 /// Implement simplify_type for CanQual<T>, so that we can dyn_cast from
365 /// CanQual<T> to a specific Type class. We're prefer isa/dyn_cast/cast/etc.
366 /// to return smart pointer (proxies?).
367 template<typename T>
368 struct simplify_type< ::clang::CanQual<T>> {
369 using SimpleType = const T *;
370
371 static SimpleType getSimplifiedValue(::clang::CanQual<T> Val) {
372 return Val.getTypePtr();
373 }
374 };
375
376 // Teach SmallPtrSet that CanQual<T> is "basically a pointer".
377 template<typename T>
378 struct PointerLikeTypeTraits<clang::CanQual<T>> {
379 static void *getAsVoidPointer(clang::CanQual<T> P) {
380 return P.getAsOpaquePtr();
381 }
382
383 static clang::CanQual<T> getFromVoidPointer(void *P) {
384 return clang::CanQual<T>::getFromOpaquePtr(P);
385 }
386
387 // qualifier information is encoded in the low bits.
388 static constexpr int NumLowBitsAvailable = 0;
389 };
390
391 } // namespace llvm
392
393 namespace clang {
394
395 //----------------------------------------------------------------------------//
396 // Canonical proxy adaptors for canonical type nodes.
397 //----------------------------------------------------------------------------//
398
399 /// Iterator adaptor that turns an iterator over canonical QualTypes
400 /// into an iterator over CanQualTypes.
401 template <typename InputIterator>
402 struct CanTypeIterator
403 : llvm::iterator_adaptor_base<
404 CanTypeIterator<InputIterator>, InputIterator,
405 typename std::iterator_traits<InputIterator>::iterator_category,
406 CanQualType,
407 typename std::iterator_traits<InputIterator>::difference_type,
408 CanProxy<Type>, CanQualType> {
409 CanTypeIterator() = default;
410 explicit CanTypeIterator(InputIterator Iter)
411 : CanTypeIterator::iterator_adaptor_base(std::move(Iter)) {}
412
413 CanQualType operator*() const { return CanQualType::CreateUnsafe(*this->I); }
414 CanProxy<Type> operator->() const;
415 };
416
417 template<>
418 struct CanProxyAdaptor<ComplexType> : public CanProxyBase<ComplexType> {
419 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getElementType)
420 };
421
422 template<>
423 struct CanProxyAdaptor<PointerType> : public CanProxyBase<PointerType> {
424 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType)
425 };
426
427 template<>
428 struct CanProxyAdaptor<BlockPointerType>
429 : public CanProxyBase<BlockPointerType> {
430 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType)
431 };
432
433 template<>
434 struct CanProxyAdaptor<ReferenceType> : public CanProxyBase<ReferenceType> {
435 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType)
436 };
437
438 template<>
439 struct CanProxyAdaptor<LValueReferenceType>
440 : public CanProxyBase<LValueReferenceType> {
441 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType)
442 };
443
444 template<>
445 struct CanProxyAdaptor<RValueReferenceType>
446 : public CanProxyBase<RValueReferenceType> {
447 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType)
448 };
449
450 template<>
451 struct CanProxyAdaptor<MemberPointerType>
452 : public CanProxyBase<MemberPointerType> {
453 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType)
454 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(const Type *, getClass)
455 };
456
457 // CanProxyAdaptors for arrays are intentionally unimplemented because
458 // they are not safe.
459 template<> struct CanProxyAdaptor<ArrayType>;
460 template<> struct CanProxyAdaptor<ConstantArrayType>;
461 template<> struct CanProxyAdaptor<IncompleteArrayType>;
462 template<> struct CanProxyAdaptor<VariableArrayType>;
463 template<> struct CanProxyAdaptor<DependentSizedArrayType>;
464
465 template<>
466 struct CanProxyAdaptor<DependentSizedExtVectorType>
467 : public CanProxyBase<DependentSizedExtVectorType> {
468 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getElementType)
469 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(const Expr *, getSizeExpr)
470 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(SourceLocation, getAttributeLoc)
471 };
472
473 template<>
474 struct CanProxyAdaptor<VectorType> : public CanProxyBase<VectorType> {
475 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getElementType)
476 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumElements)
477 };
478
479 template<>
480 struct CanProxyAdaptor<ExtVectorType> : public CanProxyBase<ExtVectorType> {
481 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getElementType)
482 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumElements)
483 };
484
485 template<>
486 struct CanProxyAdaptor<FunctionType> : public CanProxyBase<FunctionType> {
487 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getReturnType)
488 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(FunctionType::ExtInfo, getExtInfo)
489 };
490
491 template<>
492 struct CanProxyAdaptor<FunctionNoProtoType>
493 : public CanProxyBase<FunctionNoProtoType> {
494 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getReturnType)
495 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(FunctionType::ExtInfo, getExtInfo)
496 };
497
498 template<>
499 struct CanProxyAdaptor<FunctionProtoType>
500 : public CanProxyBase<FunctionProtoType> {
501 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getReturnType)
502 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(FunctionType::ExtInfo, getExtInfo)
503 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumParams)
504 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasExtParameterInfos)
505 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(
506 ArrayRef<FunctionProtoType::ExtParameterInfo>, getExtParameterInfos)
507
508 CanQualType getParamType(unsigned i) const {
509 return CanQualType::CreateUnsafe(this->getTypePtr()->getParamType(i));
510 }
511
512 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isVariadic)
513 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(Qualifiers, getMethodQuals)
514
515 using param_type_iterator =
516 CanTypeIterator<FunctionProtoType::param_type_iterator>;
517
518 param_type_iterator param_type_begin() const {
519 return param_type_iterator(this->getTypePtr()->param_type_begin());
520 }
521
522 param_type_iterator param_type_end() const {
523 return param_type_iterator(this->getTypePtr()->param_type_end());
524 }
525
526 // Note: canonical function types never have exception specifications
527 };
528
529 template<>
530 struct CanProxyAdaptor<TypeOfType> : public CanProxyBase<TypeOfType> {
531 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getUnmodifiedType)
532 };
533
534 template<>
535 struct CanProxyAdaptor<DecltypeType> : public CanProxyBase<DecltypeType> {
536 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(Expr *, getUnderlyingExpr)
537 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getUnderlyingType)
538 };
539
540 template <>
541 struct CanProxyAdaptor<UnaryTransformType>
542 : public CanProxyBase<UnaryTransformType> {
543 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getBaseType)
544 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getUnderlyingType)
545 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(UnaryTransformType::UTTKind, getUTTKind)
546 };
547
548 template<>
549 struct CanProxyAdaptor<TagType> : public CanProxyBase<TagType> {
550 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(TagDecl *, getDecl)
551 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isBeingDefined)
552 };
553
554 template<>
555 struct CanProxyAdaptor<RecordType> : public CanProxyBase<RecordType> {
556 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(RecordDecl *, getDecl)
557 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isBeingDefined)
558 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasConstFields)
559 };
560
561 template<>
562 struct CanProxyAdaptor<EnumType> : public CanProxyBase<EnumType> {
563 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(EnumDecl *, getDecl)
564 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isBeingDefined)
565 };
566
567 template<>
568 struct CanProxyAdaptor<TemplateTypeParmType>
569 : public CanProxyBase<TemplateTypeParmType> {
570 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getDepth)
571 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getIndex)
572 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isParameterPack)
573 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(TemplateTypeParmDecl *, getDecl)
574 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(IdentifierInfo *, getIdentifier)
575 };
576
577 template<>
578 struct CanProxyAdaptor<ObjCObjectType>
579 : public CanProxyBase<ObjCObjectType> {
580 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getBaseType)
581 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(const ObjCInterfaceDecl *,
582 getInterface)
583 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCUnqualifiedId)
584 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCUnqualifiedClass)
585 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCQualifiedId)
586 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCQualifiedClass)
587
588 using qual_iterator = ObjCObjectPointerType::qual_iterator;
589
590 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(qual_iterator, qual_begin)
591 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(qual_iterator, qual_end)
592 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, qual_empty)
593 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumProtocols)
594 };
595
596 template<>
597 struct CanProxyAdaptor<ObjCObjectPointerType>
598 : public CanProxyBase<ObjCObjectPointerType> {
599 LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType)
600 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(const ObjCInterfaceType *,
601 getInterfaceType)
602 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCIdType)
603 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCClassType)
604 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCQualifiedIdType)
605 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCQualifiedClassType)
606
607 using qual_iterator = ObjCObjectPointerType::qual_iterator;
608
609 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(qual_iterator, qual_begin)
610 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(qual_iterator, qual_end)
611 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, qual_empty)
612 LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumProtocols)
613 };
614
615 //----------------------------------------------------------------------------//
616 // Method and function definitions
617 //----------------------------------------------------------------------------//
618 template<typename T>
619 inline CanQual<T> CanQual<T>::getUnqualifiedType() const {
620 return CanQual<T>::CreateUnsafe(Stored.getLocalUnqualifiedType());
621 }
622
623 template<typename T>
624 inline CanQual<Type> CanQual<T>::getNonReferenceType() const {
625 if (CanQual<ReferenceType> RefType = getAs<ReferenceType>())
626 return RefType->getPointeeType();
627 else
628 return *this;
629 }
630
631 template<typename T>
632 CanQual<T> CanQual<T>::getFromOpaquePtr(void *Ptr) {
633 CanQual<T> Result;
634 Result.Stored = QualType::getFromOpaquePtr(Ptr);
635 assert((!Result || Result.Stored.getAsOpaquePtr() == (void*)-1 ||
636 Result.Stored.isCanonical()) && "Type is not canonical!");
637 return Result;
638 }
639
640 template<typename T>
641 CanQual<T> CanQual<T>::CreateUnsafe(QualType Other) {
642 assert((Other.isNull() || Other.isCanonical()) && "Type is not canonical!");
643 assert((Other.isNull() || isa<T>(Other.getTypePtr())) &&
644 "Dynamic type does not meet the static type's requires");
645 CanQual<T> Result;
646 Result.Stored = Other;
647 return Result;
648 }
649
650 template<typename T>
651 template<typename U>
652 CanProxy<U> CanQual<T>::getAs() const {
653 static_assert(!TypeIsArrayType<T>::value,
654 "ArrayType cannot be used with getAs!");
655
656 if (Stored.isNull())
657 return CanProxy<U>();
658
659 if (isa<U>(Stored.getTypePtr()))
660 return CanQual<U>::CreateUnsafe(Stored);
661
662 return CanProxy<U>();
663 }
664
665 template<typename T>
666 template<typename U>
667 CanProxy<U> CanQual<T>::castAs() const {
668 static_assert(!TypeIsArrayType<U>::value,
669 "ArrayType cannot be used with castAs!");
670
671 assert(!Stored.isNull() && isa<U>(Stored.getTypePtr()));
672 return CanQual<U>::CreateUnsafe(Stored);
673 }
674
675 template<typename T>
676 CanProxy<T> CanQual<T>::operator->() const {
677 return CanProxy<T>(*this);
678 }
679
680 template <typename InputIterator>
681 CanProxy<Type> CanTypeIterator<InputIterator>::operator->() const {
682 return CanProxy<Type>(*this);
683 }
684
685 } // namespace clang
686
687 #endif // LLVM_CLANG_AST_CANONICALTYPE_H
688