Type.h revision 5a24acfed51d1233e325f43af5b2147ad9c31e04
1//===--- Type.h - C Language Family Type Representation ---------*- C++ -*-===// 2// 3// The LLVM Compiler Infrastructure 4// 5// This file is distributed under the University of Illinois Open Source 6// License. See LICENSE.TXT for details. 7// 8//===----------------------------------------------------------------------===// 9// 10// This file defines the Type interface and subclasses. 11// 12//===----------------------------------------------------------------------===// 13 14#ifndef LLVM_CLANG_AST_TYPE_H 15#define LLVM_CLANG_AST_TYPE_H 16 17#include "clang/Basic/Diagnostic.h" 18#include "clang/Basic/IdentifierTable.h" 19#include "clang/Basic/Linkage.h" 20#include "clang/Basic/PartialDiagnostic.h" 21#include "clang/AST/NestedNameSpecifier.h" 22#include "clang/AST/TemplateName.h" 23#include "llvm/Support/Casting.h" 24#include "llvm/Support/type_traits.h" 25#include "llvm/ADT/APSInt.h" 26#include "llvm/ADT/FoldingSet.h" 27#include "llvm/ADT/PointerIntPair.h" 28#include "llvm/ADT/PointerUnion.h" 29 30using llvm::isa; 31using llvm::cast; 32using llvm::cast_or_null; 33using llvm::dyn_cast; 34using llvm::dyn_cast_or_null; 35namespace clang { 36 enum { 37 TypeAlignmentInBits = 3, 38 TypeAlignment = 1 << TypeAlignmentInBits 39 }; 40 class Type; 41 class ExtQuals; 42 class QualType; 43} 44 45namespace llvm { 46 template <typename T> 47 class PointerLikeTypeTraits; 48 template<> 49 class PointerLikeTypeTraits< ::clang::Type*> { 50 public: 51 static inline void *getAsVoidPointer(::clang::Type *P) { return P; } 52 static inline ::clang::Type *getFromVoidPointer(void *P) { 53 return static_cast< ::clang::Type*>(P); 54 } 55 enum { NumLowBitsAvailable = clang::TypeAlignmentInBits }; 56 }; 57 template<> 58 class PointerLikeTypeTraits< ::clang::ExtQuals*> { 59 public: 60 static inline void *getAsVoidPointer(::clang::ExtQuals *P) { return P; } 61 static inline ::clang::ExtQuals *getFromVoidPointer(void *P) { 62 return static_cast< ::clang::ExtQuals*>(P); 63 } 64 enum { NumLowBitsAvailable = clang::TypeAlignmentInBits }; 65 }; 66 67 template <> 68 struct isPodLike<clang::QualType> { static const bool value = true; }; 69} 70 71namespace clang { 72 class ASTContext; 73 class TypedefDecl; 74 class TemplateDecl; 75 class TemplateTypeParmDecl; 76 class NonTypeTemplateParmDecl; 77 class TemplateTemplateParmDecl; 78 class TagDecl; 79 class RecordDecl; 80 class CXXRecordDecl; 81 class EnumDecl; 82 class FieldDecl; 83 class ObjCInterfaceDecl; 84 class ObjCProtocolDecl; 85 class ObjCMethodDecl; 86 class UnresolvedUsingTypenameDecl; 87 class Expr; 88 class Stmt; 89 class SourceLocation; 90 class StmtIteratorBase; 91 class TemplateArgument; 92 class TemplateArgumentLoc; 93 class TemplateArgumentListInfo; 94 class Type; 95 class ElaboratedType; 96 struct PrintingPolicy; 97 98 template <typename> class CanQual; 99 typedef CanQual<Type> CanQualType; 100 101 // Provide forward declarations for all of the *Type classes 102#define TYPE(Class, Base) class Class##Type; 103#include "clang/AST/TypeNodes.def" 104 105/// Qualifiers - The collection of all-type qualifiers we support. 106/// Clang supports five independent qualifiers: 107/// * C99: const, volatile, and restrict 108/// * Embedded C (TR18037): address spaces 109/// * Objective C: the GC attributes (none, weak, or strong) 110class Qualifiers { 111public: 112 enum TQ { // NOTE: These flags must be kept in sync with DeclSpec::TQ. 113 Const = 0x1, 114 Restrict = 0x2, 115 Volatile = 0x4, 116 CVRMask = Const | Volatile | Restrict 117 }; 118 119 enum GC { 120 GCNone = 0, 121 Weak, 122 Strong 123 }; 124 125 enum { 126 /// The maximum supported address space number. 127 /// 24 bits should be enough for anyone. 128 MaxAddressSpace = 0xffffffu, 129 130 /// The width of the "fast" qualifier mask. 131 FastWidth = 2, 132 133 /// The fast qualifier mask. 134 FastMask = (1 << FastWidth) - 1 135 }; 136 137 Qualifiers() : Mask(0) {} 138 139 static Qualifiers fromFastMask(unsigned Mask) { 140 Qualifiers Qs; 141 Qs.addFastQualifiers(Mask); 142 return Qs; 143 } 144 145 static Qualifiers fromCVRMask(unsigned CVR) { 146 Qualifiers Qs; 147 Qs.addCVRQualifiers(CVR); 148 return Qs; 149 } 150 151 // Deserialize qualifiers from an opaque representation. 152 static Qualifiers fromOpaqueValue(unsigned opaque) { 153 Qualifiers Qs; 154 Qs.Mask = opaque; 155 return Qs; 156 } 157 158 // Serialize these qualifiers into an opaque representation. 159 unsigned getAsOpaqueValue() const { 160 return Mask; 161 } 162 163 bool hasConst() const { return Mask & Const; } 164 void setConst(bool flag) { 165 Mask = (Mask & ~Const) | (flag ? Const : 0); 166 } 167 void removeConst() { Mask &= ~Const; } 168 void addConst() { Mask |= Const; } 169 170 bool hasVolatile() const { return Mask & Volatile; } 171 void setVolatile(bool flag) { 172 Mask = (Mask & ~Volatile) | (flag ? Volatile : 0); 173 } 174 void removeVolatile() { Mask &= ~Volatile; } 175 void addVolatile() { Mask |= Volatile; } 176 177 bool hasRestrict() const { return Mask & Restrict; } 178 void setRestrict(bool flag) { 179 Mask = (Mask & ~Restrict) | (flag ? Restrict : 0); 180 } 181 void removeRestrict() { Mask &= ~Restrict; } 182 void addRestrict() { Mask |= Restrict; } 183 184 bool hasCVRQualifiers() const { return getCVRQualifiers(); } 185 unsigned getCVRQualifiers() const { return Mask & CVRMask; } 186 void setCVRQualifiers(unsigned mask) { 187 assert(!(mask & ~CVRMask) && "bitmask contains non-CVR bits"); 188 Mask = (Mask & ~CVRMask) | mask; 189 } 190 void removeCVRQualifiers(unsigned mask) { 191 assert(!(mask & ~CVRMask) && "bitmask contains non-CVR bits"); 192 Mask &= ~mask; 193 } 194 void removeCVRQualifiers() { 195 removeCVRQualifiers(CVRMask); 196 } 197 void addCVRQualifiers(unsigned mask) { 198 assert(!(mask & ~CVRMask) && "bitmask contains non-CVR bits"); 199 Mask |= mask; 200 } 201 202 bool hasObjCGCAttr() const { return Mask & GCAttrMask; } 203 GC getObjCGCAttr() const { return GC((Mask & GCAttrMask) >> GCAttrShift); } 204 void setObjCGCAttr(GC type) { 205 Mask = (Mask & ~GCAttrMask) | (type << GCAttrShift); 206 } 207 void removeObjCGCAttr() { setObjCGCAttr(GCNone); } 208 void addObjCGCAttr(GC type) { 209 assert(type); 210 setObjCGCAttr(type); 211 } 212 213 bool hasAddressSpace() const { return Mask & AddressSpaceMask; } 214 unsigned getAddressSpace() const { return Mask >> AddressSpaceShift; } 215 void setAddressSpace(unsigned space) { 216 assert(space <= MaxAddressSpace); 217 Mask = (Mask & ~AddressSpaceMask) 218 | (((uint32_t) space) << AddressSpaceShift); 219 } 220 void removeAddressSpace() { setAddressSpace(0); } 221 void addAddressSpace(unsigned space) { 222 assert(space); 223 setAddressSpace(space); 224 } 225 226 // Fast qualifiers are those that can be allocated directly 227 // on a QualType object. 228 bool hasFastQualifiers() const { return getFastQualifiers(); } 229 unsigned getFastQualifiers() const { return Mask & FastMask; } 230 void setFastQualifiers(unsigned mask) { 231 assert(!(mask & ~FastMask) && "bitmask contains non-fast qualifier bits"); 232 Mask = (Mask & ~FastMask) | mask; 233 } 234 void removeFastQualifiers(unsigned mask) { 235 assert(!(mask & ~FastMask) && "bitmask contains non-fast qualifier bits"); 236 Mask &= ~mask; 237 } 238 void removeFastQualifiers() { 239 removeFastQualifiers(FastMask); 240 } 241 void addFastQualifiers(unsigned mask) { 242 assert(!(mask & ~FastMask) && "bitmask contains non-fast qualifier bits"); 243 Mask |= mask; 244 } 245 246 /// hasNonFastQualifiers - Return true if the set contains any 247 /// qualifiers which require an ExtQuals node to be allocated. 248 bool hasNonFastQualifiers() const { return Mask & ~FastMask; } 249 Qualifiers getNonFastQualifiers() const { 250 Qualifiers Quals = *this; 251 Quals.setFastQualifiers(0); 252 return Quals; 253 } 254 255 /// hasQualifiers - Return true if the set contains any qualifiers. 256 bool hasQualifiers() const { return Mask; } 257 bool empty() const { return !Mask; } 258 259 /// \brief Add the qualifiers from the given set to this set. 260 void addQualifiers(Qualifiers Q) { 261 // If the other set doesn't have any non-boolean qualifiers, just 262 // bit-or it in. 263 if (!(Q.Mask & ~CVRMask)) 264 Mask |= Q.Mask; 265 else { 266 Mask |= (Q.Mask & CVRMask); 267 if (Q.hasAddressSpace()) 268 addAddressSpace(Q.getAddressSpace()); 269 if (Q.hasObjCGCAttr()) 270 addObjCGCAttr(Q.getObjCGCAttr()); 271 } 272 } 273 274 bool isSupersetOf(Qualifiers Other) const; 275 276 bool operator==(Qualifiers Other) const { return Mask == Other.Mask; } 277 bool operator!=(Qualifiers Other) const { return Mask != Other.Mask; } 278 279 operator bool() const { return hasQualifiers(); } 280 281 Qualifiers &operator+=(Qualifiers R) { 282 addQualifiers(R); 283 return *this; 284 } 285 286 // Union two qualifier sets. If an enumerated qualifier appears 287 // in both sets, use the one from the right. 288 friend Qualifiers operator+(Qualifiers L, Qualifiers R) { 289 L += R; 290 return L; 291 } 292 293 std::string getAsString() const; 294 std::string getAsString(const PrintingPolicy &Policy) const { 295 std::string Buffer; 296 getAsStringInternal(Buffer, Policy); 297 return Buffer; 298 } 299 void getAsStringInternal(std::string &S, const PrintingPolicy &Policy) const; 300 301 void Profile(llvm::FoldingSetNodeID &ID) const { 302 ID.AddInteger(Mask); 303 } 304 305private: 306 307 // bits: |0 1 2|3 .. 4|5 .. 31| 308 // |C R V|GCAttr|AddrSpace| 309 uint32_t Mask; 310 311 static const uint32_t GCAttrMask = 0x18; 312 static const uint32_t GCAttrShift = 3; 313 static const uint32_t AddressSpaceMask = ~(CVRMask | GCAttrMask); 314 static const uint32_t AddressSpaceShift = 5; 315}; 316 317 318/// ExtQuals - We can encode up to three bits in the low bits of a 319/// type pointer, but there are many more type qualifiers that we want 320/// to be able to apply to an arbitrary type. Therefore we have this 321/// struct, intended to be heap-allocated and used by QualType to 322/// store qualifiers. 323/// 324/// The current design tags the 'const' and 'restrict' qualifiers in 325/// two low bits on the QualType pointer; a third bit records whether 326/// the pointer is an ExtQuals node. 'const' was chosen because it is 327/// orders of magnitude more common than the other two qualifiers, in 328/// both library and user code. It's relatively rare to see 329/// 'restrict' in user code, but many standard C headers are saturated 330/// with 'restrict' declarations, so that representing them efficiently 331/// is a critical goal of this representation. 332class ExtQuals : public llvm::FoldingSetNode { 333 // NOTE: changing the fast qualifiers should be straightforward as 334 // long as you don't make 'const' non-fast. 335 // 1. Qualifiers: 336 // a) Modify the bitmasks (Qualifiers::TQ and DeclSpec::TQ). 337 // Fast qualifiers must occupy the low-order bits. 338 // b) Update Qualifiers::FastWidth and FastMask. 339 // 2. QualType: 340 // a) Update is{Volatile,Restrict}Qualified(), defined inline. 341 // b) Update remove{Volatile,Restrict}, defined near the end of 342 // this header. 343 // 3. ASTContext: 344 // a) Update get{Volatile,Restrict}Type. 345 346 /// Context - the context to which this set belongs. We save this 347 /// here so that QualifierCollector can use it to reapply extended 348 /// qualifiers to an arbitrary type without requiring a context to 349 /// be pushed through every single API dealing with qualifiers. 350 ASTContext& Context; 351 352 /// BaseType - the underlying type that this qualifies 353 const Type *BaseType; 354 355 /// Quals - the immutable set of qualifiers applied by this 356 /// node; always contains extended qualifiers. 357 Qualifiers Quals; 358 359public: 360 ExtQuals(ASTContext& Context, const Type *Base, Qualifiers Quals) 361 : Context(Context), BaseType(Base), Quals(Quals) 362 { 363 assert(Quals.hasNonFastQualifiers() 364 && "ExtQuals created with no fast qualifiers"); 365 assert(!Quals.hasFastQualifiers() 366 && "ExtQuals created with fast qualifiers"); 367 } 368 369 Qualifiers getQualifiers() const { return Quals; } 370 371 bool hasVolatile() const { return Quals.hasVolatile(); } 372 373 bool hasObjCGCAttr() const { return Quals.hasObjCGCAttr(); } 374 Qualifiers::GC getObjCGCAttr() const { return Quals.getObjCGCAttr(); } 375 376 bool hasAddressSpace() const { return Quals.hasAddressSpace(); } 377 unsigned getAddressSpace() const { return Quals.getAddressSpace(); } 378 379 const Type *getBaseType() const { return BaseType; } 380 381 ASTContext &getContext() const { return Context; } 382 383public: 384 void Profile(llvm::FoldingSetNodeID &ID) const { 385 Profile(ID, getBaseType(), Quals); 386 } 387 static void Profile(llvm::FoldingSetNodeID &ID, 388 const Type *BaseType, 389 Qualifiers Quals) { 390 assert(!Quals.hasFastQualifiers() && "fast qualifiers in ExtQuals hash!"); 391 ID.AddPointer(BaseType); 392 Quals.Profile(ID); 393 } 394}; 395 396/// CallingConv - Specifies the calling convention that a function uses. 397enum CallingConv { 398 CC_Default, 399 CC_C, // __attribute__((cdecl)) 400 CC_X86StdCall, // __attribute__((stdcall)) 401 CC_X86FastCall, // __attribute__((fastcall)) 402 CC_X86ThisCall // __attribute__((thiscall)) 403}; 404 405 406/// QualType - For efficiency, we don't store CV-qualified types as nodes on 407/// their own: instead each reference to a type stores the qualifiers. This 408/// greatly reduces the number of nodes we need to allocate for types (for 409/// example we only need one for 'int', 'const int', 'volatile int', 410/// 'const volatile int', etc). 411/// 412/// As an added efficiency bonus, instead of making this a pair, we 413/// just store the two bits we care about in the low bits of the 414/// pointer. To handle the packing/unpacking, we make QualType be a 415/// simple wrapper class that acts like a smart pointer. A third bit 416/// indicates whether there are extended qualifiers present, in which 417/// case the pointer points to a special structure. 418class QualType { 419 // Thankfully, these are efficiently composable. 420 llvm::PointerIntPair<llvm::PointerUnion<const Type*,const ExtQuals*>, 421 Qualifiers::FastWidth> Value; 422 423 const ExtQuals *getExtQualsUnsafe() const { 424 return Value.getPointer().get<const ExtQuals*>(); 425 } 426 427 const Type *getTypePtrUnsafe() const { 428 return Value.getPointer().get<const Type*>(); 429 } 430 431 QualType getUnqualifiedTypeSlow() const; 432 433 friend class QualifierCollector; 434public: 435 QualType() {} 436 437 QualType(const Type *Ptr, unsigned Quals) 438 : Value(Ptr, Quals) {} 439 QualType(const ExtQuals *Ptr, unsigned Quals) 440 : Value(Ptr, Quals) {} 441 442 unsigned getLocalFastQualifiers() const { return Value.getInt(); } 443 void setLocalFastQualifiers(unsigned Quals) { Value.setInt(Quals); } 444 445 /// Retrieves a pointer to the underlying (unqualified) type. 446 /// This should really return a const Type, but it's not worth 447 /// changing all the users right now. 448 Type *getTypePtr() const { 449 if (hasLocalNonFastQualifiers()) 450 return const_cast<Type*>(getExtQualsUnsafe()->getBaseType()); 451 return const_cast<Type*>(getTypePtrUnsafe()); 452 } 453 454 void *getAsOpaquePtr() const { return Value.getOpaqueValue(); } 455 static QualType getFromOpaquePtr(void *Ptr) { 456 QualType T; 457 T.Value.setFromOpaqueValue(Ptr); 458 return T; 459 } 460 461 Type &operator*() const { 462 return *getTypePtr(); 463 } 464 465 Type *operator->() const { 466 return getTypePtr(); 467 } 468 469 bool isCanonical() const; 470 bool isCanonicalAsParam() const; 471 472 /// isNull - Return true if this QualType doesn't point to a type yet. 473 bool isNull() const { 474 return Value.getPointer().isNull(); 475 } 476 477 /// \brief Determine whether this particular QualType instance has the 478 /// "const" qualifier set, without looking through typedefs that may have 479 /// added "const" at a different level. 480 bool isLocalConstQualified() const { 481 return (getLocalFastQualifiers() & Qualifiers::Const); 482 } 483 484 /// \brief Determine whether this type is const-qualified. 485 bool isConstQualified() const; 486 487 /// \brief Determine whether this particular QualType instance has the 488 /// "restrict" qualifier set, without looking through typedefs that may have 489 /// added "restrict" at a different level. 490 bool isLocalRestrictQualified() const { 491 return (getLocalFastQualifiers() & Qualifiers::Restrict); 492 } 493 494 /// \brief Determine whether this type is restrict-qualified. 495 bool isRestrictQualified() const; 496 497 /// \brief Determine whether this particular QualType instance has the 498 /// "volatile" qualifier set, without looking through typedefs that may have 499 /// added "volatile" at a different level. 500 bool isLocalVolatileQualified() const { 501 return (hasLocalNonFastQualifiers() && getExtQualsUnsafe()->hasVolatile()); 502 } 503 504 /// \brief Determine whether this type is volatile-qualified. 505 bool isVolatileQualified() const; 506 507 /// \brief Determine whether this particular QualType instance has any 508 /// qualifiers, without looking through any typedefs that might add 509 /// qualifiers at a different level. 510 bool hasLocalQualifiers() const { 511 return getLocalFastQualifiers() || hasLocalNonFastQualifiers(); 512 } 513 514 /// \brief Determine whether this type has any qualifiers. 515 bool hasQualifiers() const; 516 517 /// \brief Determine whether this particular QualType instance has any 518 /// "non-fast" qualifiers, e.g., those that are stored in an ExtQualType 519 /// instance. 520 bool hasLocalNonFastQualifiers() const { 521 return Value.getPointer().is<const ExtQuals*>(); 522 } 523 524 /// \brief Retrieve the set of qualifiers local to this particular QualType 525 /// instance, not including any qualifiers acquired through typedefs or 526 /// other sugar. 527 Qualifiers getLocalQualifiers() const { 528 Qualifiers Quals; 529 if (hasLocalNonFastQualifiers()) 530 Quals = getExtQualsUnsafe()->getQualifiers(); 531 Quals.addFastQualifiers(getLocalFastQualifiers()); 532 return Quals; 533 } 534 535 /// \brief Retrieve the set of qualifiers applied to this type. 536 Qualifiers getQualifiers() const; 537 538 /// \brief Retrieve the set of CVR (const-volatile-restrict) qualifiers 539 /// local to this particular QualType instance, not including any qualifiers 540 /// acquired through typedefs or other sugar. 541 unsigned getLocalCVRQualifiers() const { 542 unsigned CVR = getLocalFastQualifiers(); 543 if (isLocalVolatileQualified()) 544 CVR |= Qualifiers::Volatile; 545 return CVR; 546 } 547 548 /// \brief Retrieve the set of CVR (const-volatile-restrict) qualifiers 549 /// applied to this type. 550 unsigned getCVRQualifiers() const; 551 552 /// \brief Retrieve the set of CVR (const-volatile-restrict) qualifiers 553 /// applied to this type, looking through any number of unqualified array 554 /// types to their element types' qualifiers. 555 unsigned getCVRQualifiersThroughArrayTypes() const; 556 557 bool isConstant(ASTContext& Ctx) const { 558 return QualType::isConstant(*this, Ctx); 559 } 560 561 // Don't promise in the API that anything besides 'const' can be 562 // easily added. 563 564 /// addConst - add the specified type qualifier to this QualType. 565 void addConst() { 566 addFastQualifiers(Qualifiers::Const); 567 } 568 QualType withConst() const { 569 return withFastQualifiers(Qualifiers::Const); 570 } 571 572 void addFastQualifiers(unsigned TQs) { 573 assert(!(TQs & ~Qualifiers::FastMask) 574 && "non-fast qualifier bits set in mask!"); 575 Value.setInt(Value.getInt() | TQs); 576 } 577 578 // FIXME: The remove* functions are semantically broken, because they might 579 // not remove a qualifier stored on a typedef. Most of the with* functions 580 // have the same problem. 581 void removeConst(); 582 void removeVolatile(); 583 void removeRestrict(); 584 void removeCVRQualifiers(unsigned Mask); 585 586 void removeFastQualifiers() { Value.setInt(0); } 587 void removeFastQualifiers(unsigned Mask) { 588 assert(!(Mask & ~Qualifiers::FastMask) && "mask has non-fast qualifiers"); 589 Value.setInt(Value.getInt() & ~Mask); 590 } 591 592 // Creates a type with the given qualifiers in addition to any 593 // qualifiers already on this type. 594 QualType withFastQualifiers(unsigned TQs) const { 595 QualType T = *this; 596 T.addFastQualifiers(TQs); 597 return T; 598 } 599 600 // Creates a type with exactly the given fast qualifiers, removing 601 // any existing fast qualifiers. 602 QualType withExactFastQualifiers(unsigned TQs) const { 603 return withoutFastQualifiers().withFastQualifiers(TQs); 604 } 605 606 // Removes fast qualifiers, but leaves any extended qualifiers in place. 607 QualType withoutFastQualifiers() const { 608 QualType T = *this; 609 T.removeFastQualifiers(); 610 return T; 611 } 612 613 /// \brief Return this type with all of the instance-specific qualifiers 614 /// removed, but without removing any qualifiers that may have been applied 615 /// through typedefs. 616 QualType getLocalUnqualifiedType() const { return QualType(getTypePtr(), 0); } 617 618 /// \brief Return the unqualified form of the given type, which might be 619 /// desugared to eliminate qualifiers introduced via typedefs. 620 QualType getUnqualifiedType() const { 621 QualType T = getLocalUnqualifiedType(); 622 if (!T.hasQualifiers()) 623 return T; 624 625 return getUnqualifiedTypeSlow(); 626 } 627 628 bool isMoreQualifiedThan(QualType Other) const; 629 bool isAtLeastAsQualifiedAs(QualType Other) const; 630 QualType getNonReferenceType() const; 631 632 /// \brief Determine the type of a (typically non-lvalue) expression with the 633 /// specified result type. 634 /// 635 /// This routine should be used for expressions for which the return type is 636 /// explicitly specified (e.g., in a cast or call) and isn't necessarily 637 /// an lvalue. It removes a top-level reference (since there are no 638 /// expressions of reference type) and deletes top-level cvr-qualifiers 639 /// from non-class types (in C++) or all types (in C). 640 QualType getNonLValueExprType(ASTContext &Context) const; 641 642 /// getDesugaredType - Return the specified type with any "sugar" removed from 643 /// the type. This takes off typedefs, typeof's etc. If the outer level of 644 /// the type is already concrete, it returns it unmodified. This is similar 645 /// to getting the canonical type, but it doesn't remove *all* typedefs. For 646 /// example, it returns "T*" as "T*", (not as "int*"), because the pointer is 647 /// concrete. 648 /// 649 /// Qualifiers are left in place. 650 QualType getDesugaredType() const { 651 return QualType::getDesugaredType(*this); 652 } 653 654 /// operator==/!= - Indicate whether the specified types and qualifiers are 655 /// identical. 656 friend bool operator==(const QualType &LHS, const QualType &RHS) { 657 return LHS.Value == RHS.Value; 658 } 659 friend bool operator!=(const QualType &LHS, const QualType &RHS) { 660 return LHS.Value != RHS.Value; 661 } 662 std::string getAsString() const; 663 664 std::string getAsString(const PrintingPolicy &Policy) const { 665 std::string S; 666 getAsStringInternal(S, Policy); 667 return S; 668 } 669 void getAsStringInternal(std::string &Str, 670 const PrintingPolicy &Policy) const; 671 672 void dump(const char *s) const; 673 void dump() const; 674 675 void Profile(llvm::FoldingSetNodeID &ID) const { 676 ID.AddPointer(getAsOpaquePtr()); 677 } 678 679 /// getAddressSpace - Return the address space of this type. 680 inline unsigned getAddressSpace() const; 681 682 /// GCAttrTypesAttr - Returns gc attribute of this type. 683 inline Qualifiers::GC getObjCGCAttr() const; 684 685 /// isObjCGCWeak true when Type is objc's weak. 686 bool isObjCGCWeak() const { 687 return getObjCGCAttr() == Qualifiers::Weak; 688 } 689 690 /// isObjCGCStrong true when Type is objc's strong. 691 bool isObjCGCStrong() const { 692 return getObjCGCAttr() == Qualifiers::Strong; 693 } 694 695private: 696 // These methods are implemented in a separate translation unit; 697 // "static"-ize them to avoid creating temporary QualTypes in the 698 // caller. 699 static bool isConstant(QualType T, ASTContext& Ctx); 700 static QualType getDesugaredType(QualType T); 701}; 702 703} // end clang. 704 705namespace llvm { 706/// Implement simplify_type for QualType, so that we can dyn_cast from QualType 707/// to a specific Type class. 708template<> struct simplify_type<const ::clang::QualType> { 709 typedef ::clang::Type* SimpleType; 710 static SimpleType getSimplifiedValue(const ::clang::QualType &Val) { 711 return Val.getTypePtr(); 712 } 713}; 714template<> struct simplify_type< ::clang::QualType> 715 : public simplify_type<const ::clang::QualType> {}; 716 717// Teach SmallPtrSet that QualType is "basically a pointer". 718template<> 719class PointerLikeTypeTraits<clang::QualType> { 720public: 721 static inline void *getAsVoidPointer(clang::QualType P) { 722 return P.getAsOpaquePtr(); 723 } 724 static inline clang::QualType getFromVoidPointer(void *P) { 725 return clang::QualType::getFromOpaquePtr(P); 726 } 727 // Various qualifiers go in low bits. 728 enum { NumLowBitsAvailable = 0 }; 729}; 730 731} // end namespace llvm 732 733namespace clang { 734 735/// Type - This is the base class of the type hierarchy. A central concept 736/// with types is that each type always has a canonical type. A canonical type 737/// is the type with any typedef names stripped out of it or the types it 738/// references. For example, consider: 739/// 740/// typedef int foo; 741/// typedef foo* bar; 742/// 'int *' 'foo *' 'bar' 743/// 744/// There will be a Type object created for 'int'. Since int is canonical, its 745/// canonicaltype pointer points to itself. There is also a Type for 'foo' (a 746/// TypedefType). Its CanonicalType pointer points to the 'int' Type. Next 747/// there is a PointerType that represents 'int*', which, like 'int', is 748/// canonical. Finally, there is a PointerType type for 'foo*' whose canonical 749/// type is 'int*', and there is a TypedefType for 'bar', whose canonical type 750/// is also 'int*'. 751/// 752/// Non-canonical types are useful for emitting diagnostics, without losing 753/// information about typedefs being used. Canonical types are useful for type 754/// comparisons (they allow by-pointer equality tests) and useful for reasoning 755/// about whether something has a particular form (e.g. is a function type), 756/// because they implicitly, recursively, strip all typedefs out of a type. 757/// 758/// Types, once created, are immutable. 759/// 760class Type { 761public: 762 enum TypeClass { 763#define TYPE(Class, Base) Class, 764#define LAST_TYPE(Class) TypeLast = Class, 765#define ABSTRACT_TYPE(Class, Base) 766#include "clang/AST/TypeNodes.def" 767 TagFirst = Record, TagLast = Enum 768 }; 769 770private: 771 Type(const Type&); // DO NOT IMPLEMENT. 772 void operator=(const Type&); // DO NOT IMPLEMENT. 773 774 QualType CanonicalType; 775 776 /// TypeClass bitfield - Enum that specifies what subclass this belongs to. 777 unsigned TC : 8; 778 779 /// Dependent - Whether this type is a dependent type (C++ [temp.dep.type]). 780 /// Note that this should stay at the end of the ivars for Type so that 781 /// subclasses can pack their bitfields into the same word. 782 bool Dependent : 1; 783 784 /// \brief Whether the linkage of this type is already known. 785 mutable bool LinkageKnown : 1; 786 787 /// \brief Linkage of this type. 788 mutable unsigned CachedLinkage : 2; 789 790 /// \brief FromPCH - Whether this type comes from a PCH file. 791 mutable bool FromPCH : 1; 792 793 /// \brief Set whether this type comes from a PCH file. 794 void setFromPCH(bool V = true) const { 795 FromPCH = V; 796 } 797 798protected: 799 /// \brief Compute the linkage of this type. 800 virtual Linkage getLinkageImpl() const; 801 802 enum { BitsRemainingInType = 19 }; 803 804 // silence VC++ warning C4355: 'this' : used in base member initializer list 805 Type *this_() { return this; } 806 Type(TypeClass tc, QualType Canonical, bool dependent) 807 : CanonicalType(Canonical.isNull() ? QualType(this_(), 0) : Canonical), 808 TC(tc), Dependent(dependent), LinkageKnown(false), 809 CachedLinkage(NoLinkage), FromPCH(false) {} 810 virtual ~Type(); 811 friend class ASTContext; 812 813public: 814 TypeClass getTypeClass() const { return static_cast<TypeClass>(TC); } 815 816 /// \brief Whether this type comes from a PCH file. 817 bool isFromPCH() const { return FromPCH; } 818 819 bool isCanonicalUnqualified() const { 820 return CanonicalType.getTypePtr() == this; 821 } 822 823 /// Types are partitioned into 3 broad categories (C99 6.2.5p1): 824 /// object types, function types, and incomplete types. 825 826 /// isIncompleteType - Return true if this is an incomplete type. 827 /// A type that can describe objects, but which lacks information needed to 828 /// determine its size (e.g. void, or a fwd declared struct). Clients of this 829 /// routine will need to determine if the size is actually required. 830 bool isIncompleteType() const; 831 832 /// isIncompleteOrObjectType - Return true if this is an incomplete or object 833 /// type, in other words, not a function type. 834 bool isIncompleteOrObjectType() const { 835 return !isFunctionType(); 836 } 837 838 /// isPODType - Return true if this is a plain-old-data type (C++ 3.9p10). 839 bool isPODType() const; 840 841 /// isLiteralType - Return true if this is a literal type 842 /// (C++0x [basic.types]p10) 843 bool isLiteralType() const; 844 845 /// isVariablyModifiedType (C99 6.7.5.2p2) - Return true for variable array 846 /// types that have a non-constant expression. This does not include "[]". 847 bool isVariablyModifiedType() const; 848 849 /// Helper methods to distinguish type categories. All type predicates 850 /// operate on the canonical type, ignoring typedefs and qualifiers. 851 852 /// isBuiltinType - returns true if the type is a builtin type. 853 bool isBuiltinType() const; 854 855 /// isSpecificBuiltinType - Test for a particular builtin type. 856 bool isSpecificBuiltinType(unsigned K) const; 857 858 /// isIntegerType() does *not* include complex integers (a GCC extension). 859 /// isComplexIntegerType() can be used to test for complex integers. 860 bool isIntegerType() const; // C99 6.2.5p17 (int, char, bool, enum) 861 bool isEnumeralType() const; 862 bool isBooleanType() const; 863 bool isCharType() const; 864 bool isWideCharType() const; 865 bool isAnyCharacterType() const; 866 bool isIntegralType(ASTContext &Ctx) const; 867 868 /// \brief Determine whether this type is an integral or enumeration type. 869 bool isIntegralOrEnumerationType() const; 870 871 /// Floating point categories. 872 bool isRealFloatingType() const; // C99 6.2.5p10 (float, double, long double) 873 /// isComplexType() does *not* include complex integers (a GCC extension). 874 /// isComplexIntegerType() can be used to test for complex integers. 875 bool isComplexType() const; // C99 6.2.5p11 (complex) 876 bool isAnyComplexType() const; // C99 6.2.5p11 (complex) + Complex Int. 877 bool isFloatingType() const; // C99 6.2.5p11 (real floating + complex) 878 bool isRealType() const; // C99 6.2.5p17 (real floating + integer) 879 bool isArithmeticType() const; // C99 6.2.5p18 (integer + floating) 880 bool isVoidType() const; // C99 6.2.5p19 881 bool isDerivedType() const; // C99 6.2.5p20 882 bool isScalarType() const; // C99 6.2.5p21 (arithmetic + pointers) 883 bool isAggregateType() const; 884 885 // Type Predicates: Check to see if this type is structurally the specified 886 // type, ignoring typedefs and qualifiers. 887 bool isFunctionType() const; 888 bool isFunctionNoProtoType() const { return getAs<FunctionNoProtoType>(); } 889 bool isFunctionProtoType() const { return getAs<FunctionProtoType>(); } 890 bool isPointerType() const; 891 bool isAnyPointerType() const; // Any C pointer or ObjC object pointer 892 bool isBlockPointerType() const; 893 bool isVoidPointerType() const; 894 bool isReferenceType() const; 895 bool isLValueReferenceType() const; 896 bool isRValueReferenceType() const; 897 bool isFunctionPointerType() const; 898 bool isMemberPointerType() const; 899 bool isMemberFunctionPointerType() const; 900 bool isArrayType() const; 901 bool isConstantArrayType() const; 902 bool isIncompleteArrayType() const; 903 bool isVariableArrayType() const; 904 bool isDependentSizedArrayType() const; 905 bool isRecordType() const; 906 bool isClassType() const; 907 bool isStructureType() const; 908 bool isStructureOrClassType() const; 909 bool isUnionType() const; 910 bool isComplexIntegerType() const; // GCC _Complex integer type. 911 bool isVectorType() const; // GCC vector type. 912 bool isExtVectorType() const; // Extended vector type. 913 bool isObjCObjectPointerType() const; // Pointer to *any* ObjC object. 914 // FIXME: change this to 'raw' interface type, so we can used 'interface' type 915 // for the common case. 916 bool isObjCObjectType() const; // NSString or typeof(*(id)0) 917 bool isObjCQualifiedInterfaceType() const; // NSString<foo> 918 bool isObjCQualifiedIdType() const; // id<foo> 919 bool isObjCQualifiedClassType() const; // Class<foo> 920 bool isObjCObjectOrInterfaceType() const; 921 bool isObjCIdType() const; // id 922 bool isObjCClassType() const; // Class 923 bool isObjCSelType() const; // Class 924 bool isObjCBuiltinType() const; // 'id' or 'Class' 925 bool isTemplateTypeParmType() const; // C++ template type parameter 926 bool isNullPtrType() const; // C++0x nullptr_t 927 928 /// isDependentType - Whether this type is a dependent type, meaning 929 /// that its definition somehow depends on a template parameter 930 /// (C++ [temp.dep.type]). 931 bool isDependentType() const { return Dependent; } 932 bool isOverloadableType() const; 933 934 /// \brief Determine wither this type is a C++ elaborated-type-specifier. 935 bool isElaboratedTypeSpecifier() const; 936 937 /// hasPointerRepresentation - Whether this type is represented 938 /// natively as a pointer; this includes pointers, references, block 939 /// pointers, and Objective-C interface, qualified id, and qualified 940 /// interface types, as well as nullptr_t. 941 bool hasPointerRepresentation() const; 942 943 /// hasObjCPointerRepresentation - Whether this type can represent 944 /// an objective pointer type for the purpose of GC'ability 945 bool hasObjCPointerRepresentation() const; 946 947 /// \brief Determine whether this type has an integer representation 948 /// of some sort, e.g., it is an integer type or a vector. 949 bool hasIntegerRepresentation() const; 950 951 /// \brief Determine whether this type has an signed integer representation 952 /// of some sort, e.g., it is an signed integer type or a vector. 953 bool hasSignedIntegerRepresentation() const; 954 955 /// \brief Determine whether this type has an unsigned integer representation 956 /// of some sort, e.g., it is an unsigned integer type or a vector. 957 bool hasUnsignedIntegerRepresentation() const; 958 959 /// \brief Determine whether this type has a floating-point representation 960 /// of some sort, e.g., it is a floating-point type or a vector thereof. 961 bool hasFloatingRepresentation() const; 962 963 // Type Checking Functions: Check to see if this type is structurally the 964 // specified type, ignoring typedefs and qualifiers, and return a pointer to 965 // the best type we can. 966 const RecordType *getAsStructureType() const; 967 /// NOTE: getAs*ArrayType are methods on ASTContext. 968 const RecordType *getAsUnionType() const; 969 const ComplexType *getAsComplexIntegerType() const; // GCC complex int type. 970 // The following is a convenience method that returns an ObjCObjectPointerType 971 // for object declared using an interface. 972 const ObjCObjectPointerType *getAsObjCInterfacePointerType() const; 973 const ObjCObjectPointerType *getAsObjCQualifiedIdType() const; 974 const ObjCObjectType *getAsObjCQualifiedInterfaceType() const; 975 const CXXRecordDecl *getCXXRecordDeclForPointerType() const; 976 977 /// \brief Retrieves the CXXRecordDecl that this type refers to, either 978 /// because the type is a RecordType or because it is the injected-class-name 979 /// type of a class template or class template partial specialization. 980 CXXRecordDecl *getAsCXXRecordDecl() const; 981 982 // Member-template getAs<specific type>'. This scheme will eventually 983 // replace the specific getAsXXXX methods above. 984 // 985 // There are some specializations of this member template listed 986 // immediately following this class. 987 template <typename T> const T *getAs() const; 988 989 /// getArrayElementTypeNoTypeQual - If this is an array type, return the 990 /// element type of the array, potentially with type qualifiers missing. 991 /// This method should never be used when type qualifiers are meaningful. 992 const Type *getArrayElementTypeNoTypeQual() const; 993 994 /// getPointeeType - If this is a pointer, ObjC object pointer, or block 995 /// pointer, this returns the respective pointee. 996 QualType getPointeeType() const; 997 998 /// getUnqualifiedDesugaredType() - Return the specified type with 999 /// any "sugar" removed from the type, removing any typedefs, 1000 /// typeofs, etc., as well as any qualifiers. 1001 const Type *getUnqualifiedDesugaredType() const; 1002 1003 /// More type predicates useful for type checking/promotion 1004 bool isPromotableIntegerType() const; // C99 6.3.1.1p2 1005 1006 /// isSignedIntegerType - Return true if this is an integer type that is 1007 /// signed, according to C99 6.2.5p4 [char, signed char, short, int, long..], 1008 /// an enum decl which has a signed representation, or a vector of signed 1009 /// integer element type. 1010 bool isSignedIntegerType() const; 1011 1012 /// isUnsignedIntegerType - Return true if this is an integer type that is 1013 /// unsigned, according to C99 6.2.5p6 [which returns true for _Bool], an enum 1014 /// decl which has an unsigned representation, or a vector of unsigned integer 1015 /// element type. 1016 bool isUnsignedIntegerType() const; 1017 1018 /// isConstantSizeType - Return true if this is not a variable sized type, 1019 /// according to the rules of C99 6.7.5p3. It is not legal to call this on 1020 /// incomplete types. 1021 bool isConstantSizeType() const; 1022 1023 /// isSpecifierType - Returns true if this type can be represented by some 1024 /// set of type specifiers. 1025 bool isSpecifierType() const; 1026 1027 /// \brief Determine the linkage of this type. 1028 Linkage getLinkage() const; 1029 1030 /// \brief Note that the linkage is no longer known. 1031 void ClearLinkageCache(); 1032 1033 const char *getTypeClassName() const; 1034 1035 QualType getCanonicalTypeInternal() const { 1036 return CanonicalType; 1037 } 1038 CanQualType getCanonicalTypeUnqualified() const; // in CanonicalType.h 1039 void dump() const; 1040 static bool classof(const Type *) { return true; } 1041 1042 friend class PCHReader; 1043 friend class PCHWriter; 1044}; 1045 1046template <> inline const TypedefType *Type::getAs() const { 1047 return dyn_cast<TypedefType>(this); 1048} 1049 1050// We can do canonical leaf types faster, because we don't have to 1051// worry about preserving child type decoration. 1052#define TYPE(Class, Base) 1053#define LEAF_TYPE(Class) \ 1054template <> inline const Class##Type *Type::getAs() const { \ 1055 return dyn_cast<Class##Type>(CanonicalType); \ 1056} 1057#include "clang/AST/TypeNodes.def" 1058 1059 1060/// BuiltinType - This class is used for builtin types like 'int'. Builtin 1061/// types are always canonical and have a literal name field. 1062class BuiltinType : public Type { 1063public: 1064 enum Kind { 1065 Void, 1066 1067 Bool, // This is bool and/or _Bool. 1068 Char_U, // This is 'char' for targets where char is unsigned. 1069 UChar, // This is explicitly qualified unsigned char. 1070 Char16, // This is 'char16_t' for C++. 1071 Char32, // This is 'char32_t' for C++. 1072 UShort, 1073 UInt, 1074 ULong, 1075 ULongLong, 1076 UInt128, // __uint128_t 1077 1078 Char_S, // This is 'char' for targets where char is signed. 1079 SChar, // This is explicitly qualified signed char. 1080 WChar, // This is 'wchar_t' for C++. 1081 Short, 1082 Int, 1083 Long, 1084 LongLong, 1085 Int128, // __int128_t 1086 1087 Float, Double, LongDouble, 1088 1089 NullPtr, // This is the type of C++0x 'nullptr'. 1090 1091 Overload, // This represents the type of an overloaded function declaration. 1092 Dependent, // This represents the type of a type-dependent expression. 1093 1094 UndeducedAuto, // In C++0x, this represents the type of an auto variable 1095 // that has not been deduced yet. 1096 1097 /// The primitive Objective C 'id' type. The type pointed to by the 1098 /// user-visible 'id' type. Only ever shows up in an AST as the base 1099 /// type of an ObjCObjectType. 1100 ObjCId, 1101 1102 /// The primitive Objective C 'Class' type. The type pointed to by the 1103 /// user-visible 'Class' type. Only ever shows up in an AST as the 1104 /// base type of an ObjCObjectType. 1105 ObjCClass, 1106 1107 ObjCSel // This represents the ObjC 'SEL' type. 1108 }; 1109private: 1110 Kind TypeKind; 1111 1112protected: 1113 virtual Linkage getLinkageImpl() const; 1114 1115public: 1116 BuiltinType(Kind K) 1117 : Type(Builtin, QualType(), /*Dependent=*/(K == Dependent)), 1118 TypeKind(K) {} 1119 1120 Kind getKind() const { return TypeKind; } 1121 const char *getName(const LangOptions &LO) const; 1122 1123 bool isSugared() const { return false; } 1124 QualType desugar() const { return QualType(this, 0); } 1125 1126 bool isInteger() const { 1127 return TypeKind >= Bool && TypeKind <= Int128; 1128 } 1129 1130 bool isSignedInteger() const { 1131 return TypeKind >= Char_S && TypeKind <= Int128; 1132 } 1133 1134 bool isUnsignedInteger() const { 1135 return TypeKind >= Bool && TypeKind <= UInt128; 1136 } 1137 1138 bool isFloatingPoint() const { 1139 return TypeKind >= Float && TypeKind <= LongDouble; 1140 } 1141 1142 static bool classof(const Type *T) { return T->getTypeClass() == Builtin; } 1143 static bool classof(const BuiltinType *) { return true; } 1144}; 1145 1146/// ComplexType - C99 6.2.5p11 - Complex values. This supports the C99 complex 1147/// types (_Complex float etc) as well as the GCC integer complex extensions. 1148/// 1149class ComplexType : public Type, public llvm::FoldingSetNode { 1150 QualType ElementType; 1151 ComplexType(QualType Element, QualType CanonicalPtr) : 1152 Type(Complex, CanonicalPtr, Element->isDependentType()), 1153 ElementType(Element) { 1154 } 1155 friend class ASTContext; // ASTContext creates these. 1156 1157protected: 1158 virtual Linkage getLinkageImpl() const; 1159 1160public: 1161 QualType getElementType() const { return ElementType; } 1162 1163 bool isSugared() const { return false; } 1164 QualType desugar() const { return QualType(this, 0); } 1165 1166 void Profile(llvm::FoldingSetNodeID &ID) { 1167 Profile(ID, getElementType()); 1168 } 1169 static void Profile(llvm::FoldingSetNodeID &ID, QualType Element) { 1170 ID.AddPointer(Element.getAsOpaquePtr()); 1171 } 1172 1173 static bool classof(const Type *T) { return T->getTypeClass() == Complex; } 1174 static bool classof(const ComplexType *) { return true; } 1175}; 1176 1177/// PointerType - C99 6.7.5.1 - Pointer Declarators. 1178/// 1179class PointerType : public Type, public llvm::FoldingSetNode { 1180 QualType PointeeType; 1181 1182 PointerType(QualType Pointee, QualType CanonicalPtr) : 1183 Type(Pointer, CanonicalPtr, Pointee->isDependentType()), PointeeType(Pointee) { 1184 } 1185 friend class ASTContext; // ASTContext creates these. 1186 1187protected: 1188 virtual Linkage getLinkageImpl() const; 1189 1190public: 1191 1192 QualType getPointeeType() const { return PointeeType; } 1193 1194 bool isSugared() const { return false; } 1195 QualType desugar() const { return QualType(this, 0); } 1196 1197 void Profile(llvm::FoldingSetNodeID &ID) { 1198 Profile(ID, getPointeeType()); 1199 } 1200 static void Profile(llvm::FoldingSetNodeID &ID, QualType Pointee) { 1201 ID.AddPointer(Pointee.getAsOpaquePtr()); 1202 } 1203 1204 static bool classof(const Type *T) { return T->getTypeClass() == Pointer; } 1205 static bool classof(const PointerType *) { return true; } 1206}; 1207 1208/// BlockPointerType - pointer to a block type. 1209/// This type is to represent types syntactically represented as 1210/// "void (^)(int)", etc. Pointee is required to always be a function type. 1211/// 1212class BlockPointerType : public Type, public llvm::FoldingSetNode { 1213 QualType PointeeType; // Block is some kind of pointer type 1214 BlockPointerType(QualType Pointee, QualType CanonicalCls) : 1215 Type(BlockPointer, CanonicalCls, Pointee->isDependentType()), 1216 PointeeType(Pointee) { 1217 } 1218 friend class ASTContext; // ASTContext creates these. 1219 1220protected: 1221 virtual Linkage getLinkageImpl() const; 1222 1223public: 1224 1225 // Get the pointee type. Pointee is required to always be a function type. 1226 QualType getPointeeType() const { return PointeeType; } 1227 1228 bool isSugared() const { return false; } 1229 QualType desugar() const { return QualType(this, 0); } 1230 1231 void Profile(llvm::FoldingSetNodeID &ID) { 1232 Profile(ID, getPointeeType()); 1233 } 1234 static void Profile(llvm::FoldingSetNodeID &ID, QualType Pointee) { 1235 ID.AddPointer(Pointee.getAsOpaquePtr()); 1236 } 1237 1238 static bool classof(const Type *T) { 1239 return T->getTypeClass() == BlockPointer; 1240 } 1241 static bool classof(const BlockPointerType *) { return true; } 1242}; 1243 1244/// ReferenceType - Base for LValueReferenceType and RValueReferenceType 1245/// 1246class ReferenceType : public Type, public llvm::FoldingSetNode { 1247 QualType PointeeType; 1248 1249 /// True if the type was originally spelled with an lvalue sigil. 1250 /// This is never true of rvalue references but can also be false 1251 /// on lvalue references because of C++0x [dcl.typedef]p9, 1252 /// as follows: 1253 /// 1254 /// typedef int &ref; // lvalue, spelled lvalue 1255 /// typedef int &&rvref; // rvalue 1256 /// ref &a; // lvalue, inner ref, spelled lvalue 1257 /// ref &&a; // lvalue, inner ref 1258 /// rvref &a; // lvalue, inner ref, spelled lvalue 1259 /// rvref &&a; // rvalue, inner ref 1260 bool SpelledAsLValue; 1261 1262 /// True if the inner type is a reference type. This only happens 1263 /// in non-canonical forms. 1264 bool InnerRef; 1265 1266protected: 1267 ReferenceType(TypeClass tc, QualType Referencee, QualType CanonicalRef, 1268 bool SpelledAsLValue) : 1269 Type(tc, CanonicalRef, Referencee->isDependentType()), 1270 PointeeType(Referencee), SpelledAsLValue(SpelledAsLValue), 1271 InnerRef(Referencee->isReferenceType()) { 1272 } 1273 1274 virtual Linkage getLinkageImpl() const; 1275 1276public: 1277 bool isSpelledAsLValue() const { return SpelledAsLValue; } 1278 bool isInnerRef() const { return InnerRef; } 1279 1280 QualType getPointeeTypeAsWritten() const { return PointeeType; } 1281 QualType getPointeeType() const { 1282 // FIXME: this might strip inner qualifiers; okay? 1283 const ReferenceType *T = this; 1284 while (T->InnerRef) 1285 T = T->PointeeType->getAs<ReferenceType>(); 1286 return T->PointeeType; 1287 } 1288 1289 void Profile(llvm::FoldingSetNodeID &ID) { 1290 Profile(ID, PointeeType, SpelledAsLValue); 1291 } 1292 static void Profile(llvm::FoldingSetNodeID &ID, 1293 QualType Referencee, 1294 bool SpelledAsLValue) { 1295 ID.AddPointer(Referencee.getAsOpaquePtr()); 1296 ID.AddBoolean(SpelledAsLValue); 1297 } 1298 1299 static bool classof(const Type *T) { 1300 return T->getTypeClass() == LValueReference || 1301 T->getTypeClass() == RValueReference; 1302 } 1303 static bool classof(const ReferenceType *) { return true; } 1304}; 1305 1306/// LValueReferenceType - C++ [dcl.ref] - Lvalue reference 1307/// 1308class LValueReferenceType : public ReferenceType { 1309 LValueReferenceType(QualType Referencee, QualType CanonicalRef, 1310 bool SpelledAsLValue) : 1311 ReferenceType(LValueReference, Referencee, CanonicalRef, SpelledAsLValue) 1312 {} 1313 friend class ASTContext; // ASTContext creates these 1314public: 1315 bool isSugared() const { return false; } 1316 QualType desugar() const { return QualType(this, 0); } 1317 1318 static bool classof(const Type *T) { 1319 return T->getTypeClass() == LValueReference; 1320 } 1321 static bool classof(const LValueReferenceType *) { return true; } 1322}; 1323 1324/// RValueReferenceType - C++0x [dcl.ref] - Rvalue reference 1325/// 1326class RValueReferenceType : public ReferenceType { 1327 RValueReferenceType(QualType Referencee, QualType CanonicalRef) : 1328 ReferenceType(RValueReference, Referencee, CanonicalRef, false) { 1329 } 1330 friend class ASTContext; // ASTContext creates these 1331public: 1332 bool isSugared() const { return false; } 1333 QualType desugar() const { return QualType(this, 0); } 1334 1335 static bool classof(const Type *T) { 1336 return T->getTypeClass() == RValueReference; 1337 } 1338 static bool classof(const RValueReferenceType *) { return true; } 1339}; 1340 1341/// MemberPointerType - C++ 8.3.3 - Pointers to members 1342/// 1343class MemberPointerType : public Type, public llvm::FoldingSetNode { 1344 QualType PointeeType; 1345 /// The class of which the pointee is a member. Must ultimately be a 1346 /// RecordType, but could be a typedef or a template parameter too. 1347 const Type *Class; 1348 1349 MemberPointerType(QualType Pointee, const Type *Cls, QualType CanonicalPtr) : 1350 Type(MemberPointer, CanonicalPtr, 1351 Cls->isDependentType() || Pointee->isDependentType()), 1352 PointeeType(Pointee), Class(Cls) { 1353 } 1354 friend class ASTContext; // ASTContext creates these. 1355 1356protected: 1357 virtual Linkage getLinkageImpl() const; 1358 1359public: 1360 1361 QualType getPointeeType() const { return PointeeType; } 1362 1363 const Type *getClass() const { return Class; } 1364 1365 bool isSugared() const { return false; } 1366 QualType desugar() const { return QualType(this, 0); } 1367 1368 void Profile(llvm::FoldingSetNodeID &ID) { 1369 Profile(ID, getPointeeType(), getClass()); 1370 } 1371 static void Profile(llvm::FoldingSetNodeID &ID, QualType Pointee, 1372 const Type *Class) { 1373 ID.AddPointer(Pointee.getAsOpaquePtr()); 1374 ID.AddPointer(Class); 1375 } 1376 1377 static bool classof(const Type *T) { 1378 return T->getTypeClass() == MemberPointer; 1379 } 1380 static bool classof(const MemberPointerType *) { return true; } 1381}; 1382 1383/// ArrayType - C99 6.7.5.2 - Array Declarators. 1384/// 1385class ArrayType : public Type, public llvm::FoldingSetNode { 1386public: 1387 /// ArraySizeModifier - Capture whether this is a normal array (e.g. int X[4]) 1388 /// an array with a static size (e.g. int X[static 4]), or an array 1389 /// with a star size (e.g. int X[*]). 1390 /// 'static' is only allowed on function parameters. 1391 enum ArraySizeModifier { 1392 Normal, Static, Star 1393 }; 1394private: 1395 /// ElementType - The element type of the array. 1396 QualType ElementType; 1397 1398 // NOTE: VC++ treats enums as signed, avoid using the ArraySizeModifier enum 1399 /// NOTE: These fields are packed into the bitfields space in the Type class. 1400 unsigned SizeModifier : 2; 1401 1402 /// IndexTypeQuals - Capture qualifiers in declarations like: 1403 /// 'int X[static restrict 4]'. For function parameters only. 1404 unsigned IndexTypeQuals : 3; 1405 1406protected: 1407 // C++ [temp.dep.type]p1: 1408 // A type is dependent if it is... 1409 // - an array type constructed from any dependent type or whose 1410 // size is specified by a constant expression that is 1411 // value-dependent, 1412 ArrayType(TypeClass tc, QualType et, QualType can, 1413 ArraySizeModifier sm, unsigned tq) 1414 : Type(tc, can, et->isDependentType() || tc == DependentSizedArray), 1415 ElementType(et), SizeModifier(sm), IndexTypeQuals(tq) {} 1416 1417 friend class ASTContext; // ASTContext creates these. 1418 1419 virtual Linkage getLinkageImpl() const; 1420 1421public: 1422 QualType getElementType() const { return ElementType; } 1423 ArraySizeModifier getSizeModifier() const { 1424 return ArraySizeModifier(SizeModifier); 1425 } 1426 Qualifiers getIndexTypeQualifiers() const { 1427 return Qualifiers::fromCVRMask(IndexTypeQuals); 1428 } 1429 unsigned getIndexTypeCVRQualifiers() const { return IndexTypeQuals; } 1430 1431 static bool classof(const Type *T) { 1432 return T->getTypeClass() == ConstantArray || 1433 T->getTypeClass() == VariableArray || 1434 T->getTypeClass() == IncompleteArray || 1435 T->getTypeClass() == DependentSizedArray; 1436 } 1437 static bool classof(const ArrayType *) { return true; } 1438}; 1439 1440/// ConstantArrayType - This class represents the canonical version of 1441/// C arrays with a specified constant size. For example, the canonical 1442/// type for 'int A[4 + 4*100]' is a ConstantArrayType where the element 1443/// type is 'int' and the size is 404. 1444class ConstantArrayType : public ArrayType { 1445 llvm::APInt Size; // Allows us to unique the type. 1446 1447 ConstantArrayType(QualType et, QualType can, const llvm::APInt &size, 1448 ArraySizeModifier sm, unsigned tq) 1449 : ArrayType(ConstantArray, et, can, sm, tq), 1450 Size(size) {} 1451protected: 1452 ConstantArrayType(TypeClass tc, QualType et, QualType can, 1453 const llvm::APInt &size, ArraySizeModifier sm, unsigned tq) 1454 : ArrayType(tc, et, can, sm, tq), Size(size) {} 1455 friend class ASTContext; // ASTContext creates these. 1456public: 1457 const llvm::APInt &getSize() const { return Size; } 1458 bool isSugared() const { return false; } 1459 QualType desugar() const { return QualType(this, 0); } 1460 1461 void Profile(llvm::FoldingSetNodeID &ID) { 1462 Profile(ID, getElementType(), getSize(), 1463 getSizeModifier(), getIndexTypeCVRQualifiers()); 1464 } 1465 static void Profile(llvm::FoldingSetNodeID &ID, QualType ET, 1466 const llvm::APInt &ArraySize, ArraySizeModifier SizeMod, 1467 unsigned TypeQuals) { 1468 ID.AddPointer(ET.getAsOpaquePtr()); 1469 ID.AddInteger(ArraySize.getZExtValue()); 1470 ID.AddInteger(SizeMod); 1471 ID.AddInteger(TypeQuals); 1472 } 1473 static bool classof(const Type *T) { 1474 return T->getTypeClass() == ConstantArray; 1475 } 1476 static bool classof(const ConstantArrayType *) { return true; } 1477}; 1478 1479/// IncompleteArrayType - This class represents C arrays with an unspecified 1480/// size. For example 'int A[]' has an IncompleteArrayType where the element 1481/// type is 'int' and the size is unspecified. 1482class IncompleteArrayType : public ArrayType { 1483 1484 IncompleteArrayType(QualType et, QualType can, 1485 ArraySizeModifier sm, unsigned tq) 1486 : ArrayType(IncompleteArray, et, can, sm, tq) {} 1487 friend class ASTContext; // ASTContext creates these. 1488public: 1489 bool isSugared() const { return false; } 1490 QualType desugar() const { return QualType(this, 0); } 1491 1492 static bool classof(const Type *T) { 1493 return T->getTypeClass() == IncompleteArray; 1494 } 1495 static bool classof(const IncompleteArrayType *) { return true; } 1496 1497 friend class StmtIteratorBase; 1498 1499 void Profile(llvm::FoldingSetNodeID &ID) { 1500 Profile(ID, getElementType(), getSizeModifier(), 1501 getIndexTypeCVRQualifiers()); 1502 } 1503 1504 static void Profile(llvm::FoldingSetNodeID &ID, QualType ET, 1505 ArraySizeModifier SizeMod, unsigned TypeQuals) { 1506 ID.AddPointer(ET.getAsOpaquePtr()); 1507 ID.AddInteger(SizeMod); 1508 ID.AddInteger(TypeQuals); 1509 } 1510}; 1511 1512/// VariableArrayType - This class represents C arrays with a specified size 1513/// which is not an integer-constant-expression. For example, 'int s[x+foo()]'. 1514/// Since the size expression is an arbitrary expression, we store it as such. 1515/// 1516/// Note: VariableArrayType's aren't uniqued (since the expressions aren't) and 1517/// should not be: two lexically equivalent variable array types could mean 1518/// different things, for example, these variables do not have the same type 1519/// dynamically: 1520/// 1521/// void foo(int x) { 1522/// int Y[x]; 1523/// ++x; 1524/// int Z[x]; 1525/// } 1526/// 1527class VariableArrayType : public ArrayType { 1528 /// SizeExpr - An assignment expression. VLA's are only permitted within 1529 /// a function block. 1530 Stmt *SizeExpr; 1531 /// Brackets - The left and right array brackets. 1532 SourceRange Brackets; 1533 1534 VariableArrayType(QualType et, QualType can, Expr *e, 1535 ArraySizeModifier sm, unsigned tq, 1536 SourceRange brackets) 1537 : ArrayType(VariableArray, et, can, sm, tq), 1538 SizeExpr((Stmt*) e), Brackets(brackets) {} 1539 friend class ASTContext; // ASTContext creates these. 1540 1541public: 1542 Expr *getSizeExpr() const { 1543 // We use C-style casts instead of cast<> here because we do not wish 1544 // to have a dependency of Type.h on Stmt.h/Expr.h. 1545 return (Expr*) SizeExpr; 1546 } 1547 SourceRange getBracketsRange() const { return Brackets; } 1548 SourceLocation getLBracketLoc() const { return Brackets.getBegin(); } 1549 SourceLocation getRBracketLoc() const { return Brackets.getEnd(); } 1550 1551 bool isSugared() const { return false; } 1552 QualType desugar() const { return QualType(this, 0); } 1553 1554 static bool classof(const Type *T) { 1555 return T->getTypeClass() == VariableArray; 1556 } 1557 static bool classof(const VariableArrayType *) { return true; } 1558 1559 friend class StmtIteratorBase; 1560 1561 void Profile(llvm::FoldingSetNodeID &ID) { 1562 assert(0 && "Cannnot unique VariableArrayTypes."); 1563 } 1564}; 1565 1566/// DependentSizedArrayType - This type represents an array type in 1567/// C++ whose size is a value-dependent expression. For example: 1568/// 1569/// \code 1570/// template<typename T, int Size> 1571/// class array { 1572/// T data[Size]; 1573/// }; 1574/// \endcode 1575/// 1576/// For these types, we won't actually know what the array bound is 1577/// until template instantiation occurs, at which point this will 1578/// become either a ConstantArrayType or a VariableArrayType. 1579class DependentSizedArrayType : public ArrayType { 1580 ASTContext &Context; 1581 1582 /// \brief An assignment expression that will instantiate to the 1583 /// size of the array. 1584 /// 1585 /// The expression itself might be NULL, in which case the array 1586 /// type will have its size deduced from an initializer. 1587 Stmt *SizeExpr; 1588 1589 /// Brackets - The left and right array brackets. 1590 SourceRange Brackets; 1591 1592 DependentSizedArrayType(ASTContext &Context, QualType et, QualType can, 1593 Expr *e, ArraySizeModifier sm, unsigned tq, 1594 SourceRange brackets) 1595 : ArrayType(DependentSizedArray, et, can, sm, tq), 1596 Context(Context), SizeExpr((Stmt*) e), Brackets(brackets) {} 1597 friend class ASTContext; // ASTContext creates these. 1598 1599public: 1600 Expr *getSizeExpr() const { 1601 // We use C-style casts instead of cast<> here because we do not wish 1602 // to have a dependency of Type.h on Stmt.h/Expr.h. 1603 return (Expr*) SizeExpr; 1604 } 1605 SourceRange getBracketsRange() const { return Brackets; } 1606 SourceLocation getLBracketLoc() const { return Brackets.getBegin(); } 1607 SourceLocation getRBracketLoc() const { return Brackets.getEnd(); } 1608 1609 bool isSugared() const { return false; } 1610 QualType desugar() const { return QualType(this, 0); } 1611 1612 static bool classof(const Type *T) { 1613 return T->getTypeClass() == DependentSizedArray; 1614 } 1615 static bool classof(const DependentSizedArrayType *) { return true; } 1616 1617 friend class StmtIteratorBase; 1618 1619 1620 void Profile(llvm::FoldingSetNodeID &ID) { 1621 Profile(ID, Context, getElementType(), 1622 getSizeModifier(), getIndexTypeCVRQualifiers(), getSizeExpr()); 1623 } 1624 1625 static void Profile(llvm::FoldingSetNodeID &ID, ASTContext &Context, 1626 QualType ET, ArraySizeModifier SizeMod, 1627 unsigned TypeQuals, Expr *E); 1628}; 1629 1630/// DependentSizedExtVectorType - This type represent an extended vector type 1631/// where either the type or size is dependent. For example: 1632/// @code 1633/// template<typename T, int Size> 1634/// class vector { 1635/// typedef T __attribute__((ext_vector_type(Size))) type; 1636/// } 1637/// @endcode 1638class DependentSizedExtVectorType : public Type, public llvm::FoldingSetNode { 1639 ASTContext &Context; 1640 Expr *SizeExpr; 1641 /// ElementType - The element type of the array. 1642 QualType ElementType; 1643 SourceLocation loc; 1644 1645 DependentSizedExtVectorType(ASTContext &Context, QualType ElementType, 1646 QualType can, Expr *SizeExpr, SourceLocation loc) 1647 : Type (DependentSizedExtVector, can, true), 1648 Context(Context), SizeExpr(SizeExpr), ElementType(ElementType), 1649 loc(loc) {} 1650 friend class ASTContext; 1651 1652public: 1653 Expr *getSizeExpr() const { return SizeExpr; } 1654 QualType getElementType() const { return ElementType; } 1655 SourceLocation getAttributeLoc() const { return loc; } 1656 1657 bool isSugared() const { return false; } 1658 QualType desugar() const { return QualType(this, 0); } 1659 1660 static bool classof(const Type *T) { 1661 return T->getTypeClass() == DependentSizedExtVector; 1662 } 1663 static bool classof(const DependentSizedExtVectorType *) { return true; } 1664 1665 void Profile(llvm::FoldingSetNodeID &ID) { 1666 Profile(ID, Context, getElementType(), getSizeExpr()); 1667 } 1668 1669 static void Profile(llvm::FoldingSetNodeID &ID, ASTContext &Context, 1670 QualType ElementType, Expr *SizeExpr); 1671}; 1672 1673 1674/// VectorType - GCC generic vector type. This type is created using 1675/// __attribute__((vector_size(n)), where "n" specifies the vector size in 1676/// bytes; or from an Altivec __vector or vector declaration. 1677/// Since the constructor takes the number of vector elements, the 1678/// client is responsible for converting the size into the number of elements. 1679class VectorType : public Type, public llvm::FoldingSetNode { 1680public: 1681 enum AltiVecSpecific { 1682 NotAltiVec, // is not AltiVec vector 1683 AltiVec, // is AltiVec vector 1684 Pixel, // is AltiVec 'vector Pixel' 1685 Bool // is AltiVec 'vector bool ...' 1686 }; 1687protected: 1688 /// ElementType - The element type of the vector. 1689 QualType ElementType; 1690 1691 /// NumElements - The number of elements in the vector. 1692 unsigned NumElements; 1693 1694 AltiVecSpecific AltiVecSpec; 1695 1696 VectorType(QualType vecType, unsigned nElements, QualType canonType, 1697 AltiVecSpecific altiVecSpec) : 1698 Type(Vector, canonType, vecType->isDependentType()), 1699 ElementType(vecType), NumElements(nElements), AltiVecSpec(altiVecSpec) {} 1700 VectorType(TypeClass tc, QualType vecType, unsigned nElements, 1701 QualType canonType, AltiVecSpecific altiVecSpec) 1702 : Type(tc, canonType, vecType->isDependentType()), ElementType(vecType), 1703 NumElements(nElements), AltiVecSpec(altiVecSpec) {} 1704 friend class ASTContext; // ASTContext creates these. 1705 1706 virtual Linkage getLinkageImpl() const; 1707 1708public: 1709 1710 QualType getElementType() const { return ElementType; } 1711 unsigned getNumElements() const { return NumElements; } 1712 1713 bool isSugared() const { return false; } 1714 QualType desugar() const { return QualType(this, 0); } 1715 1716 AltiVecSpecific getAltiVecSpecific() const { return AltiVecSpec; } 1717 1718 void Profile(llvm::FoldingSetNodeID &ID) { 1719 Profile(ID, getElementType(), getNumElements(), getTypeClass(), AltiVecSpec); 1720 } 1721 static void Profile(llvm::FoldingSetNodeID &ID, QualType ElementType, 1722 unsigned NumElements, TypeClass TypeClass, 1723 unsigned AltiVecSpec) { 1724 ID.AddPointer(ElementType.getAsOpaquePtr()); 1725 ID.AddInteger(NumElements); 1726 ID.AddInteger(TypeClass); 1727 ID.AddInteger(AltiVecSpec); 1728 } 1729 1730 static bool classof(const Type *T) { 1731 return T->getTypeClass() == Vector || T->getTypeClass() == ExtVector; 1732 } 1733 static bool classof(const VectorType *) { return true; } 1734}; 1735 1736/// ExtVectorType - Extended vector type. This type is created using 1737/// __attribute__((ext_vector_type(n)), where "n" is the number of elements. 1738/// Unlike vector_size, ext_vector_type is only allowed on typedef's. This 1739/// class enables syntactic extensions, like Vector Components for accessing 1740/// points, colors, and textures (modeled after OpenGL Shading Language). 1741class ExtVectorType : public VectorType { 1742 ExtVectorType(QualType vecType, unsigned nElements, QualType canonType) : 1743 VectorType(ExtVector, vecType, nElements, canonType, NotAltiVec) {} 1744 friend class ASTContext; // ASTContext creates these. 1745public: 1746 static int getPointAccessorIdx(char c) { 1747 switch (c) { 1748 default: return -1; 1749 case 'x': return 0; 1750 case 'y': return 1; 1751 case 'z': return 2; 1752 case 'w': return 3; 1753 } 1754 } 1755 static int getNumericAccessorIdx(char c) { 1756 switch (c) { 1757 default: return -1; 1758 case '0': return 0; 1759 case '1': return 1; 1760 case '2': return 2; 1761 case '3': return 3; 1762 case '4': return 4; 1763 case '5': return 5; 1764 case '6': return 6; 1765 case '7': return 7; 1766 case '8': return 8; 1767 case '9': return 9; 1768 case 'A': 1769 case 'a': return 10; 1770 case 'B': 1771 case 'b': return 11; 1772 case 'C': 1773 case 'c': return 12; 1774 case 'D': 1775 case 'd': return 13; 1776 case 'E': 1777 case 'e': return 14; 1778 case 'F': 1779 case 'f': return 15; 1780 } 1781 } 1782 1783 static int getAccessorIdx(char c) { 1784 if (int idx = getPointAccessorIdx(c)+1) return idx-1; 1785 return getNumericAccessorIdx(c); 1786 } 1787 1788 bool isAccessorWithinNumElements(char c) const { 1789 if (int idx = getAccessorIdx(c)+1) 1790 return unsigned(idx-1) < NumElements; 1791 return false; 1792 } 1793 bool isSugared() const { return false; } 1794 QualType desugar() const { return QualType(this, 0); } 1795 1796 static bool classof(const Type *T) { 1797 return T->getTypeClass() == ExtVector; 1798 } 1799 static bool classof(const ExtVectorType *) { return true; } 1800}; 1801 1802/// FunctionType - C99 6.7.5.3 - Function Declarators. This is the common base 1803/// class of FunctionNoProtoType and FunctionProtoType. 1804/// 1805class FunctionType : public Type { 1806 virtual void ANCHOR(); // Key function for FunctionType. 1807 1808 /// SubClassData - This field is owned by the subclass, put here to pack 1809 /// tightly with the ivars in Type. 1810 bool SubClassData : 1; 1811 1812 /// TypeQuals - Used only by FunctionProtoType, put here to pack with the 1813 /// other bitfields. 1814 /// The qualifiers are part of FunctionProtoType because... 1815 /// 1816 /// C++ 8.3.5p4: The return type, the parameter type list and the 1817 /// cv-qualifier-seq, [...], are part of the function type. 1818 /// 1819 unsigned TypeQuals : 3; 1820 1821 /// NoReturn - Indicates if the function type is attribute noreturn. 1822 unsigned NoReturn : 1; 1823 1824 /// RegParm - How many arguments to pass inreg. 1825 unsigned RegParm : 3; 1826 1827 /// CallConv - The calling convention used by the function. 1828 unsigned CallConv : 3; 1829 1830 // The type returned by the function. 1831 QualType ResultType; 1832 1833 public: 1834 // This class is used for passing arround the information needed to 1835 // construct a call. It is not actually used for storage, just for 1836 // factoring together common arguments. 1837 // If you add a field (say Foo), other than the obvious places (both, constructors, 1838 // compile failures), what you need to update is 1839 // * Operetor== 1840 // * getFoo 1841 // * withFoo 1842 // * functionType. Add Foo, getFoo. 1843 // * ASTContext::getFooType 1844 // * ASTContext::mergeFunctionTypes 1845 // * FunctionNoProtoType::Profile 1846 // * FunctionProtoType::Profile 1847 // * TypePrinter::PrintFunctionProto 1848 // * PCH read and write 1849 // * Codegen 1850 1851 class ExtInfo { 1852 public: 1853 // Constructor with no defaults. Use this when you know that you 1854 // have all the elements (when reading a PCH file for example). 1855 ExtInfo(bool noReturn, unsigned regParm, CallingConv cc) : 1856 NoReturn(noReturn), RegParm(regParm), CC(cc) {} 1857 1858 // Constructor with all defaults. Use when for example creating a 1859 // function know to use defaults. 1860 ExtInfo() : NoReturn(false), RegParm(0), CC(CC_Default) {} 1861 1862 bool getNoReturn() const { return NoReturn; } 1863 unsigned getRegParm() const { return RegParm; } 1864 CallingConv getCC() const { return CC; } 1865 1866 bool operator==(const ExtInfo &Other) const { 1867 return getNoReturn() == Other.getNoReturn() && 1868 getRegParm() == Other.getRegParm() && 1869 getCC() == Other.getCC(); 1870 } 1871 bool operator!=(const ExtInfo &Other) const { 1872 return !(*this == Other); 1873 } 1874 1875 // Note that we don't have setters. That is by design, use 1876 // the following with methods instead of mutating these objects. 1877 1878 ExtInfo withNoReturn(bool noReturn) const { 1879 return ExtInfo(noReturn, getRegParm(), getCC()); 1880 } 1881 1882 ExtInfo withRegParm(unsigned RegParm) const { 1883 return ExtInfo(getNoReturn(), RegParm, getCC()); 1884 } 1885 1886 ExtInfo withCallingConv(CallingConv cc) const { 1887 return ExtInfo(getNoReturn(), getRegParm(), cc); 1888 } 1889 1890 private: 1891 // True if we have __attribute__((noreturn)) 1892 bool NoReturn; 1893 // The value passed to __attribute__((regparm(x))) 1894 unsigned RegParm; 1895 // The calling convention as specified via 1896 // __attribute__((cdecl|stdcall|fastcall|thiscall)) 1897 CallingConv CC; 1898 }; 1899 1900protected: 1901 FunctionType(TypeClass tc, QualType res, bool SubclassInfo, 1902 unsigned typeQuals, QualType Canonical, bool Dependent, 1903 const ExtInfo &Info) 1904 : Type(tc, Canonical, Dependent), 1905 SubClassData(SubclassInfo), TypeQuals(typeQuals), 1906 NoReturn(Info.getNoReturn()), 1907 RegParm(Info.getRegParm()), CallConv(Info.getCC()), ResultType(res) {} 1908 bool getSubClassData() const { return SubClassData; } 1909 unsigned getTypeQuals() const { return TypeQuals; } 1910public: 1911 1912 QualType getResultType() const { return ResultType; } 1913 1914 unsigned getRegParmType() const { return RegParm; } 1915 bool getNoReturnAttr() const { return NoReturn; } 1916 CallingConv getCallConv() const { return (CallingConv)CallConv; } 1917 ExtInfo getExtInfo() const { 1918 return ExtInfo(NoReturn, RegParm, (CallingConv)CallConv); 1919 } 1920 1921 /// \brief Determine the type of an expression that calls a function of 1922 /// this type. 1923 QualType getCallResultType(ASTContext &Context) const { 1924 return getResultType().getNonLValueExprType(Context); 1925 } 1926 1927 static llvm::StringRef getNameForCallConv(CallingConv CC); 1928 1929 static bool classof(const Type *T) { 1930 return T->getTypeClass() == FunctionNoProto || 1931 T->getTypeClass() == FunctionProto; 1932 } 1933 static bool classof(const FunctionType *) { return true; } 1934}; 1935 1936/// FunctionNoProtoType - Represents a K&R-style 'int foo()' function, which has 1937/// no information available about its arguments. 1938class FunctionNoProtoType : public FunctionType, public llvm::FoldingSetNode { 1939 FunctionNoProtoType(QualType Result, QualType Canonical, 1940 const ExtInfo &Info) 1941 : FunctionType(FunctionNoProto, Result, false, 0, Canonical, 1942 /*Dependent=*/false, Info) {} 1943 friend class ASTContext; // ASTContext creates these. 1944 1945protected: 1946 virtual Linkage getLinkageImpl() const; 1947 1948public: 1949 // No additional state past what FunctionType provides. 1950 1951 bool isSugared() const { return false; } 1952 QualType desugar() const { return QualType(this, 0); } 1953 1954 void Profile(llvm::FoldingSetNodeID &ID) { 1955 Profile(ID, getResultType(), getExtInfo()); 1956 } 1957 static void Profile(llvm::FoldingSetNodeID &ID, QualType ResultType, 1958 const ExtInfo &Info) { 1959 ID.AddInteger(Info.getCC()); 1960 ID.AddInteger(Info.getRegParm()); 1961 ID.AddInteger(Info.getNoReturn()); 1962 ID.AddPointer(ResultType.getAsOpaquePtr()); 1963 } 1964 1965 static bool classof(const Type *T) { 1966 return T->getTypeClass() == FunctionNoProto; 1967 } 1968 static bool classof(const FunctionNoProtoType *) { return true; } 1969}; 1970 1971/// FunctionProtoType - Represents a prototype with argument type info, e.g. 1972/// 'int foo(int)' or 'int foo(void)'. 'void' is represented as having no 1973/// arguments, not as having a single void argument. Such a type can have an 1974/// exception specification, but this specification is not part of the canonical 1975/// type. 1976class FunctionProtoType : public FunctionType, public llvm::FoldingSetNode { 1977 /// hasAnyDependentType - Determine whether there are any dependent 1978 /// types within the arguments passed in. 1979 static bool hasAnyDependentType(const QualType *ArgArray, unsigned numArgs) { 1980 for (unsigned Idx = 0; Idx < numArgs; ++Idx) 1981 if (ArgArray[Idx]->isDependentType()) 1982 return true; 1983 1984 return false; 1985 } 1986 1987 FunctionProtoType(QualType Result, const QualType *ArgArray, unsigned numArgs, 1988 bool isVariadic, unsigned typeQuals, bool hasExs, 1989 bool hasAnyExs, const QualType *ExArray, 1990 unsigned numExs, QualType Canonical, 1991 const ExtInfo &Info) 1992 : FunctionType(FunctionProto, Result, isVariadic, typeQuals, Canonical, 1993 (Result->isDependentType() || 1994 hasAnyDependentType(ArgArray, numArgs)), 1995 Info), 1996 NumArgs(numArgs), NumExceptions(numExs), HasExceptionSpec(hasExs), 1997 AnyExceptionSpec(hasAnyExs) { 1998 // Fill in the trailing argument array. 1999 QualType *ArgInfo = reinterpret_cast<QualType*>(this+1); 2000 for (unsigned i = 0; i != numArgs; ++i) 2001 ArgInfo[i] = ArgArray[i]; 2002 // Fill in the exception array. 2003 QualType *Ex = ArgInfo + numArgs; 2004 for (unsigned i = 0; i != numExs; ++i) 2005 Ex[i] = ExArray[i]; 2006 } 2007 2008 /// NumArgs - The number of arguments this function has, not counting '...'. 2009 unsigned NumArgs : 20; 2010 2011 /// NumExceptions - The number of types in the exception spec, if any. 2012 unsigned NumExceptions : 10; 2013 2014 /// HasExceptionSpec - Whether this function has an exception spec at all. 2015 bool HasExceptionSpec : 1; 2016 2017 /// AnyExceptionSpec - Whether this function has a throw(...) spec. 2018 bool AnyExceptionSpec : 1; 2019 2020 /// ArgInfo - There is an variable size array after the class in memory that 2021 /// holds the argument types. 2022 2023 /// Exceptions - There is another variable size array after ArgInfo that 2024 /// holds the exception types. 2025 2026 friend class ASTContext; // ASTContext creates these. 2027 2028protected: 2029 virtual Linkage getLinkageImpl() const; 2030 2031public: 2032 unsigned getNumArgs() const { return NumArgs; } 2033 QualType getArgType(unsigned i) const { 2034 assert(i < NumArgs && "Invalid argument number!"); 2035 return arg_type_begin()[i]; 2036 } 2037 2038 bool hasExceptionSpec() const { return HasExceptionSpec; } 2039 bool hasAnyExceptionSpec() const { return AnyExceptionSpec; } 2040 unsigned getNumExceptions() const { return NumExceptions; } 2041 QualType getExceptionType(unsigned i) const { 2042 assert(i < NumExceptions && "Invalid exception number!"); 2043 return exception_begin()[i]; 2044 } 2045 bool hasEmptyExceptionSpec() const { 2046 return hasExceptionSpec() && !hasAnyExceptionSpec() && 2047 getNumExceptions() == 0; 2048 } 2049 2050 bool isVariadic() const { return getSubClassData(); } 2051 unsigned getTypeQuals() const { return FunctionType::getTypeQuals(); } 2052 2053 typedef const QualType *arg_type_iterator; 2054 arg_type_iterator arg_type_begin() const { 2055 return reinterpret_cast<const QualType *>(this+1); 2056 } 2057 arg_type_iterator arg_type_end() const { return arg_type_begin()+NumArgs; } 2058 2059 typedef const QualType *exception_iterator; 2060 exception_iterator exception_begin() const { 2061 // exceptions begin where arguments end 2062 return arg_type_end(); 2063 } 2064 exception_iterator exception_end() const { 2065 return exception_begin() + NumExceptions; 2066 } 2067 2068 bool isSugared() const { return false; } 2069 QualType desugar() const { return QualType(this, 0); } 2070 2071 static bool classof(const Type *T) { 2072 return T->getTypeClass() == FunctionProto; 2073 } 2074 static bool classof(const FunctionProtoType *) { return true; } 2075 2076 void Profile(llvm::FoldingSetNodeID &ID); 2077 static void Profile(llvm::FoldingSetNodeID &ID, QualType Result, 2078 arg_type_iterator ArgTys, unsigned NumArgs, 2079 bool isVariadic, unsigned TypeQuals, 2080 bool hasExceptionSpec, bool anyExceptionSpec, 2081 unsigned NumExceptions, exception_iterator Exs, 2082 const ExtInfo &ExtInfo); 2083}; 2084 2085 2086/// \brief Represents the dependent type named by a dependently-scoped 2087/// typename using declaration, e.g. 2088/// using typename Base<T>::foo; 2089/// Template instantiation turns these into the underlying type. 2090class UnresolvedUsingType : public Type { 2091 UnresolvedUsingTypenameDecl *Decl; 2092 2093 UnresolvedUsingType(const UnresolvedUsingTypenameDecl *D) 2094 : Type(UnresolvedUsing, QualType(), true), 2095 Decl(const_cast<UnresolvedUsingTypenameDecl*>(D)) {} 2096 friend class ASTContext; // ASTContext creates these. 2097public: 2098 2099 UnresolvedUsingTypenameDecl *getDecl() const { return Decl; } 2100 2101 bool isSugared() const { return false; } 2102 QualType desugar() const { return QualType(this, 0); } 2103 2104 static bool classof(const Type *T) { 2105 return T->getTypeClass() == UnresolvedUsing; 2106 } 2107 static bool classof(const UnresolvedUsingType *) { return true; } 2108 2109 void Profile(llvm::FoldingSetNodeID &ID) { 2110 return Profile(ID, Decl); 2111 } 2112 static void Profile(llvm::FoldingSetNodeID &ID, 2113 UnresolvedUsingTypenameDecl *D) { 2114 ID.AddPointer(D); 2115 } 2116}; 2117 2118 2119class TypedefType : public Type { 2120 TypedefDecl *Decl; 2121protected: 2122 TypedefType(TypeClass tc, const TypedefDecl *D, QualType can) 2123 : Type(tc, can, can->isDependentType()), 2124 Decl(const_cast<TypedefDecl*>(D)) { 2125 assert(!isa<TypedefType>(can) && "Invalid canonical type"); 2126 } 2127 friend class ASTContext; // ASTContext creates these. 2128public: 2129 2130 TypedefDecl *getDecl() const { return Decl; } 2131 2132 /// LookThroughTypedefs - Return the ultimate type this typedef corresponds to 2133 /// potentially looking through *all* consecutive typedefs. This returns the 2134 /// sum of the type qualifiers, so if you have: 2135 /// typedef const int A; 2136 /// typedef volatile A B; 2137 /// looking through the typedefs for B will give you "const volatile A". 2138 QualType LookThroughTypedefs() const; 2139 2140 bool isSugared() const { return true; } 2141 QualType desugar() const; 2142 2143 static bool classof(const Type *T) { return T->getTypeClass() == Typedef; } 2144 static bool classof(const TypedefType *) { return true; } 2145}; 2146 2147/// TypeOfExprType (GCC extension). 2148class TypeOfExprType : public Type { 2149 Expr *TOExpr; 2150 2151protected: 2152 TypeOfExprType(Expr *E, QualType can = QualType()); 2153 friend class ASTContext; // ASTContext creates these. 2154public: 2155 Expr *getUnderlyingExpr() const { return TOExpr; } 2156 2157 /// \brief Remove a single level of sugar. 2158 QualType desugar() const; 2159 2160 /// \brief Returns whether this type directly provides sugar. 2161 bool isSugared() const { return true; } 2162 2163 static bool classof(const Type *T) { return T->getTypeClass() == TypeOfExpr; } 2164 static bool classof(const TypeOfExprType *) { return true; } 2165}; 2166 2167/// \brief Internal representation of canonical, dependent 2168/// typeof(expr) types. 2169/// 2170/// This class is used internally by the ASTContext to manage 2171/// canonical, dependent types, only. Clients will only see instances 2172/// of this class via TypeOfExprType nodes. 2173class DependentTypeOfExprType 2174 : public TypeOfExprType, public llvm::FoldingSetNode { 2175 ASTContext &Context; 2176 2177public: 2178 DependentTypeOfExprType(ASTContext &Context, Expr *E) 2179 : TypeOfExprType(E), Context(Context) { } 2180 2181 bool isSugared() const { return false; } 2182 QualType desugar() const { return QualType(this, 0); } 2183 2184 void Profile(llvm::FoldingSetNodeID &ID) { 2185 Profile(ID, Context, getUnderlyingExpr()); 2186 } 2187 2188 static void Profile(llvm::FoldingSetNodeID &ID, ASTContext &Context, 2189 Expr *E); 2190}; 2191 2192/// TypeOfType (GCC extension). 2193class TypeOfType : public Type { 2194 QualType TOType; 2195 TypeOfType(QualType T, QualType can) 2196 : Type(TypeOf, can, T->isDependentType()), TOType(T) { 2197 assert(!isa<TypedefType>(can) && "Invalid canonical type"); 2198 } 2199 friend class ASTContext; // ASTContext creates these. 2200public: 2201 QualType getUnderlyingType() const { return TOType; } 2202 2203 /// \brief Remove a single level of sugar. 2204 QualType desugar() const { return getUnderlyingType(); } 2205 2206 /// \brief Returns whether this type directly provides sugar. 2207 bool isSugared() const { return true; } 2208 2209 static bool classof(const Type *T) { return T->getTypeClass() == TypeOf; } 2210 static bool classof(const TypeOfType *) { return true; } 2211}; 2212 2213/// DecltypeType (C++0x) 2214class DecltypeType : public Type { 2215 Expr *E; 2216 2217 // FIXME: We could get rid of UnderlyingType if we wanted to: We would have to 2218 // Move getDesugaredType to ASTContext so that it can call getDecltypeForExpr 2219 // from it. 2220 QualType UnderlyingType; 2221 2222protected: 2223 DecltypeType(Expr *E, QualType underlyingType, QualType can = QualType()); 2224 friend class ASTContext; // ASTContext creates these. 2225public: 2226 Expr *getUnderlyingExpr() const { return E; } 2227 QualType getUnderlyingType() const { return UnderlyingType; } 2228 2229 /// \brief Remove a single level of sugar. 2230 QualType desugar() const { return getUnderlyingType(); } 2231 2232 /// \brief Returns whether this type directly provides sugar. 2233 bool isSugared() const { return !isDependentType(); } 2234 2235 static bool classof(const Type *T) { return T->getTypeClass() == Decltype; } 2236 static bool classof(const DecltypeType *) { return true; } 2237}; 2238 2239/// \brief Internal representation of canonical, dependent 2240/// decltype(expr) types. 2241/// 2242/// This class is used internally by the ASTContext to manage 2243/// canonical, dependent types, only. Clients will only see instances 2244/// of this class via DecltypeType nodes. 2245class DependentDecltypeType : public DecltypeType, public llvm::FoldingSetNode { 2246 ASTContext &Context; 2247 2248public: 2249 DependentDecltypeType(ASTContext &Context, Expr *E); 2250 2251 bool isSugared() const { return false; } 2252 QualType desugar() const { return QualType(this, 0); } 2253 2254 void Profile(llvm::FoldingSetNodeID &ID) { 2255 Profile(ID, Context, getUnderlyingExpr()); 2256 } 2257 2258 static void Profile(llvm::FoldingSetNodeID &ID, ASTContext &Context, 2259 Expr *E); 2260}; 2261 2262class TagType : public Type { 2263 /// Stores the TagDecl associated with this type. The decl may point to any 2264 /// TagDecl that declares the entity. 2265 TagDecl * decl; 2266 2267protected: 2268 TagType(TypeClass TC, const TagDecl *D, QualType can); 2269 2270 virtual Linkage getLinkageImpl() const; 2271 2272public: 2273 TagDecl *getDecl() const; 2274 2275 /// @brief Determines whether this type is in the process of being 2276 /// defined. 2277 bool isBeingDefined() const; 2278 2279 static bool classof(const Type *T) { 2280 return T->getTypeClass() >= TagFirst && T->getTypeClass() <= TagLast; 2281 } 2282 static bool classof(const TagType *) { return true; } 2283 static bool classof(const RecordType *) { return true; } 2284 static bool classof(const EnumType *) { return true; } 2285}; 2286 2287/// RecordType - This is a helper class that allows the use of isa/cast/dyncast 2288/// to detect TagType objects of structs/unions/classes. 2289class RecordType : public TagType { 2290protected: 2291 explicit RecordType(const RecordDecl *D) 2292 : TagType(Record, reinterpret_cast<const TagDecl*>(D), QualType()) { } 2293 explicit RecordType(TypeClass TC, RecordDecl *D) 2294 : TagType(TC, reinterpret_cast<const TagDecl*>(D), QualType()) { } 2295 friend class ASTContext; // ASTContext creates these. 2296public: 2297 2298 RecordDecl *getDecl() const { 2299 return reinterpret_cast<RecordDecl*>(TagType::getDecl()); 2300 } 2301 2302 // FIXME: This predicate is a helper to QualType/Type. It needs to 2303 // recursively check all fields for const-ness. If any field is declared 2304 // const, it needs to return false. 2305 bool hasConstFields() const { return false; } 2306 2307 // FIXME: RecordType needs to check when it is created that all fields are in 2308 // the same address space, and return that. 2309 unsigned getAddressSpace() const { return 0; } 2310 2311 bool isSugared() const { return false; } 2312 QualType desugar() const { return QualType(this, 0); } 2313 2314 static bool classof(const TagType *T); 2315 static bool classof(const Type *T) { 2316 return isa<TagType>(T) && classof(cast<TagType>(T)); 2317 } 2318 static bool classof(const RecordType *) { return true; } 2319}; 2320 2321/// EnumType - This is a helper class that allows the use of isa/cast/dyncast 2322/// to detect TagType objects of enums. 2323class EnumType : public TagType { 2324 explicit EnumType(const EnumDecl *D) 2325 : TagType(Enum, reinterpret_cast<const TagDecl*>(D), QualType()) { } 2326 friend class ASTContext; // ASTContext creates these. 2327public: 2328 2329 EnumDecl *getDecl() const { 2330 return reinterpret_cast<EnumDecl*>(TagType::getDecl()); 2331 } 2332 2333 bool isSugared() const { return false; } 2334 QualType desugar() const { return QualType(this, 0); } 2335 2336 static bool classof(const TagType *T); 2337 static bool classof(const Type *T) { 2338 return isa<TagType>(T) && classof(cast<TagType>(T)); 2339 } 2340 static bool classof(const EnumType *) { return true; } 2341}; 2342 2343class TemplateTypeParmType : public Type, public llvm::FoldingSetNode { 2344 unsigned Depth : 15; 2345 unsigned Index : 16; 2346 unsigned ParameterPack : 1; 2347 IdentifierInfo *Name; 2348 2349 TemplateTypeParmType(unsigned D, unsigned I, bool PP, IdentifierInfo *N, 2350 QualType Canon) 2351 : Type(TemplateTypeParm, Canon, /*Dependent=*/true), 2352 Depth(D), Index(I), ParameterPack(PP), Name(N) { } 2353 2354 TemplateTypeParmType(unsigned D, unsigned I, bool PP) 2355 : Type(TemplateTypeParm, QualType(this, 0), /*Dependent=*/true), 2356 Depth(D), Index(I), ParameterPack(PP), Name(0) { } 2357 2358 friend class ASTContext; // ASTContext creates these 2359 2360public: 2361 unsigned getDepth() const { return Depth; } 2362 unsigned getIndex() const { return Index; } 2363 bool isParameterPack() const { return ParameterPack; } 2364 IdentifierInfo *getName() const { return Name; } 2365 2366 bool isSugared() const { return false; } 2367 QualType desugar() const { return QualType(this, 0); } 2368 2369 void Profile(llvm::FoldingSetNodeID &ID) { 2370 Profile(ID, Depth, Index, ParameterPack, Name); 2371 } 2372 2373 static void Profile(llvm::FoldingSetNodeID &ID, unsigned Depth, 2374 unsigned Index, bool ParameterPack, 2375 IdentifierInfo *Name) { 2376 ID.AddInteger(Depth); 2377 ID.AddInteger(Index); 2378 ID.AddBoolean(ParameterPack); 2379 ID.AddPointer(Name); 2380 } 2381 2382 static bool classof(const Type *T) { 2383 return T->getTypeClass() == TemplateTypeParm; 2384 } 2385 static bool classof(const TemplateTypeParmType *T) { return true; } 2386}; 2387 2388/// \brief Represents the result of substituting a type for a template 2389/// type parameter. 2390/// 2391/// Within an instantiated template, all template type parameters have 2392/// been replaced with these. They are used solely to record that a 2393/// type was originally written as a template type parameter; 2394/// therefore they are never canonical. 2395class SubstTemplateTypeParmType : public Type, public llvm::FoldingSetNode { 2396 // The original type parameter. 2397 const TemplateTypeParmType *Replaced; 2398 2399 SubstTemplateTypeParmType(const TemplateTypeParmType *Param, QualType Canon) 2400 : Type(SubstTemplateTypeParm, Canon, Canon->isDependentType()), 2401 Replaced(Param) { } 2402 2403 friend class ASTContext; 2404 2405public: 2406 IdentifierInfo *getName() const { return Replaced->getName(); } 2407 2408 /// Gets the template parameter that was substituted for. 2409 const TemplateTypeParmType *getReplacedParameter() const { 2410 return Replaced; 2411 } 2412 2413 /// Gets the type that was substituted for the template 2414 /// parameter. 2415 QualType getReplacementType() const { 2416 return getCanonicalTypeInternal(); 2417 } 2418 2419 bool isSugared() const { return true; } 2420 QualType desugar() const { return getReplacementType(); } 2421 2422 void Profile(llvm::FoldingSetNodeID &ID) { 2423 Profile(ID, getReplacedParameter(), getReplacementType()); 2424 } 2425 static void Profile(llvm::FoldingSetNodeID &ID, 2426 const TemplateTypeParmType *Replaced, 2427 QualType Replacement) { 2428 ID.AddPointer(Replaced); 2429 ID.AddPointer(Replacement.getAsOpaquePtr()); 2430 } 2431 2432 static bool classof(const Type *T) { 2433 return T->getTypeClass() == SubstTemplateTypeParm; 2434 } 2435 static bool classof(const SubstTemplateTypeParmType *T) { return true; } 2436}; 2437 2438/// \brief Represents the type of a template specialization as written 2439/// in the source code. 2440/// 2441/// Template specialization types represent the syntactic form of a 2442/// template-id that refers to a type, e.g., @c vector<int>. Some 2443/// template specialization types are syntactic sugar, whose canonical 2444/// type will point to some other type node that represents the 2445/// instantiation or class template specialization. For example, a 2446/// class template specialization type of @c vector<int> will refer to 2447/// a tag type for the instantiation 2448/// @c std::vector<int, std::allocator<int>>. 2449/// 2450/// Other template specialization types, for which the template name 2451/// is dependent, may be canonical types. These types are always 2452/// dependent. 2453class TemplateSpecializationType 2454 : public Type, public llvm::FoldingSetNode { 2455 /// \brief The name of the template being specialized. 2456 TemplateName Template; 2457 2458 /// \brief - The number of template arguments named in this class 2459 /// template specialization. 2460 unsigned NumArgs; 2461 2462 TemplateSpecializationType(TemplateName T, 2463 const TemplateArgument *Args, 2464 unsigned NumArgs, QualType Canon); 2465 2466 friend class ASTContext; // ASTContext creates these 2467 2468public: 2469 /// \brief Determine whether any of the given template arguments are 2470 /// dependent. 2471 static bool anyDependentTemplateArguments(const TemplateArgument *Args, 2472 unsigned NumArgs); 2473 2474 static bool anyDependentTemplateArguments(const TemplateArgumentLoc *Args, 2475 unsigned NumArgs); 2476 2477 static bool anyDependentTemplateArguments(const TemplateArgumentListInfo &); 2478 2479 /// \brief Print a template argument list, including the '<' and '>' 2480 /// enclosing the template arguments. 2481 static std::string PrintTemplateArgumentList(const TemplateArgument *Args, 2482 unsigned NumArgs, 2483 const PrintingPolicy &Policy); 2484 2485 static std::string PrintTemplateArgumentList(const TemplateArgumentLoc *Args, 2486 unsigned NumArgs, 2487 const PrintingPolicy &Policy); 2488 2489 static std::string PrintTemplateArgumentList(const TemplateArgumentListInfo &, 2490 const PrintingPolicy &Policy); 2491 2492 /// True if this template specialization type matches a current 2493 /// instantiation in the context in which it is found. 2494 bool isCurrentInstantiation() const { 2495 return isa<InjectedClassNameType>(getCanonicalTypeInternal()); 2496 } 2497 2498 typedef const TemplateArgument * iterator; 2499 2500 iterator begin() const { return getArgs(); } 2501 iterator end() const; // defined inline in TemplateBase.h 2502 2503 /// \brief Retrieve the name of the template that we are specializing. 2504 TemplateName getTemplateName() const { return Template; } 2505 2506 /// \brief Retrieve the template arguments. 2507 const TemplateArgument *getArgs() const { 2508 return reinterpret_cast<const TemplateArgument *>(this + 1); 2509 } 2510 2511 /// \brief Retrieve the number of template arguments. 2512 unsigned getNumArgs() const { return NumArgs; } 2513 2514 /// \brief Retrieve a specific template argument as a type. 2515 /// \precondition @c isArgType(Arg) 2516 const TemplateArgument &getArg(unsigned Idx) const; // in TemplateBase.h 2517 2518 bool isSugared() const { 2519 return !isDependentType() || isCurrentInstantiation(); 2520 } 2521 QualType desugar() const { return getCanonicalTypeInternal(); } 2522 2523 void Profile(llvm::FoldingSetNodeID &ID, ASTContext &Ctx) { 2524 Profile(ID, Template, getArgs(), NumArgs, Ctx); 2525 } 2526 2527 static void Profile(llvm::FoldingSetNodeID &ID, TemplateName T, 2528 const TemplateArgument *Args, 2529 unsigned NumArgs, 2530 ASTContext &Context); 2531 2532 static bool classof(const Type *T) { 2533 return T->getTypeClass() == TemplateSpecialization; 2534 } 2535 static bool classof(const TemplateSpecializationType *T) { return true; } 2536}; 2537 2538/// \brief The injected class name of a C++ class template or class 2539/// template partial specialization. Used to record that a type was 2540/// spelled with a bare identifier rather than as a template-id; the 2541/// equivalent for non-templated classes is just RecordType. 2542/// 2543/// Injected class name types are always dependent. Template 2544/// instantiation turns these into RecordTypes. 2545/// 2546/// Injected class name types are always canonical. This works 2547/// because it is impossible to compare an injected class name type 2548/// with the corresponding non-injected template type, for the same 2549/// reason that it is impossible to directly compare template 2550/// parameters from different dependent contexts: injected class name 2551/// types can only occur within the scope of a particular templated 2552/// declaration, and within that scope every template specialization 2553/// will canonicalize to the injected class name (when appropriate 2554/// according to the rules of the language). 2555class InjectedClassNameType : public Type { 2556 CXXRecordDecl *Decl; 2557 2558 /// The template specialization which this type represents. 2559 /// For example, in 2560 /// template <class T> class A { ... }; 2561 /// this is A<T>, whereas in 2562 /// template <class X, class Y> class A<B<X,Y> > { ... }; 2563 /// this is A<B<X,Y> >. 2564 /// 2565 /// It is always unqualified, always a template specialization type, 2566 /// and always dependent. 2567 QualType InjectedType; 2568 2569 friend class ASTContext; // ASTContext creates these. 2570 friend class PCHReader; // FIXME: ASTContext::getInjectedClassNameType is not 2571 // currently suitable for PCH reading, too much 2572 // interdependencies. 2573 InjectedClassNameType(CXXRecordDecl *D, QualType TST) 2574 : Type(InjectedClassName, QualType(), true), 2575 Decl(D), InjectedType(TST) { 2576 assert(isa<TemplateSpecializationType>(TST)); 2577 assert(!TST.hasQualifiers()); 2578 assert(TST->isDependentType()); 2579 } 2580 2581public: 2582 QualType getInjectedSpecializationType() const { return InjectedType; } 2583 const TemplateSpecializationType *getInjectedTST() const { 2584 return cast<TemplateSpecializationType>(InjectedType.getTypePtr()); 2585 } 2586 2587 CXXRecordDecl *getDecl() const; 2588 2589 bool isSugared() const { return false; } 2590 QualType desugar() const { return QualType(this, 0); } 2591 2592 static bool classof(const Type *T) { 2593 return T->getTypeClass() == InjectedClassName; 2594 } 2595 static bool classof(const InjectedClassNameType *T) { return true; } 2596}; 2597 2598/// \brief The kind of a tag type. 2599enum TagTypeKind { 2600 /// \brief The "struct" keyword. 2601 TTK_Struct, 2602 /// \brief The "union" keyword. 2603 TTK_Union, 2604 /// \brief The "class" keyword. 2605 TTK_Class, 2606 /// \brief The "enum" keyword. 2607 TTK_Enum 2608}; 2609 2610/// \brief The elaboration keyword that precedes a qualified type name or 2611/// introduces an elaborated-type-specifier. 2612enum ElaboratedTypeKeyword { 2613 /// \brief The "struct" keyword introduces the elaborated-type-specifier. 2614 ETK_Struct, 2615 /// \brief The "union" keyword introduces the elaborated-type-specifier. 2616 ETK_Union, 2617 /// \brief The "class" keyword introduces the elaborated-type-specifier. 2618 ETK_Class, 2619 /// \brief The "enum" keyword introduces the elaborated-type-specifier. 2620 ETK_Enum, 2621 /// \brief The "typename" keyword precedes the qualified type name, e.g., 2622 /// \c typename T::type. 2623 ETK_Typename, 2624 /// \brief No keyword precedes the qualified type name. 2625 ETK_None 2626}; 2627 2628/// A helper class for Type nodes having an ElaboratedTypeKeyword. 2629/// The keyword in stored in the free bits of the base class. 2630/// Also provides a few static helpers for converting and printing 2631/// elaborated type keyword and tag type kind enumerations. 2632class TypeWithKeyword : public Type { 2633 /// Keyword - Encodes an ElaboratedTypeKeyword enumeration constant. 2634 unsigned Keyword : 3; 2635 2636protected: 2637 TypeWithKeyword(ElaboratedTypeKeyword Keyword, TypeClass tc, 2638 QualType Canonical, bool dependent) 2639 : Type(tc, Canonical, dependent), Keyword(Keyword) {} 2640 2641public: 2642 virtual ~TypeWithKeyword(); // pin vtable to Type.cpp 2643 2644 ElaboratedTypeKeyword getKeyword() const { 2645 return static_cast<ElaboratedTypeKeyword>(Keyword); 2646 } 2647 2648 /// getKeywordForTypeSpec - Converts a type specifier (DeclSpec::TST) 2649 /// into an elaborated type keyword. 2650 static ElaboratedTypeKeyword getKeywordForTypeSpec(unsigned TypeSpec); 2651 2652 /// getTagTypeKindForTypeSpec - Converts a type specifier (DeclSpec::TST) 2653 /// into a tag type kind. It is an error to provide a type specifier 2654 /// which *isn't* a tag kind here. 2655 static TagTypeKind getTagTypeKindForTypeSpec(unsigned TypeSpec); 2656 2657 /// getKeywordForTagDeclKind - Converts a TagTypeKind into an 2658 /// elaborated type keyword. 2659 static ElaboratedTypeKeyword getKeywordForTagTypeKind(TagTypeKind Tag); 2660 2661 /// getTagTypeKindForKeyword - Converts an elaborated type keyword into 2662 // a TagTypeKind. It is an error to provide an elaborated type keyword 2663 /// which *isn't* a tag kind here. 2664 static TagTypeKind getTagTypeKindForKeyword(ElaboratedTypeKeyword Keyword); 2665 2666 static bool KeywordIsTagTypeKind(ElaboratedTypeKeyword Keyword); 2667 2668 static const char *getKeywordName(ElaboratedTypeKeyword Keyword); 2669 2670 static const char *getTagTypeKindName(TagTypeKind Kind) { 2671 return getKeywordName(getKeywordForTagTypeKind(Kind)); 2672 } 2673 2674 class CannotCastToThisType {}; 2675 static CannotCastToThisType classof(const Type *); 2676}; 2677 2678/// \brief Represents a type that was referred to using an elaborated type 2679/// keyword, e.g., struct S, or via a qualified name, e.g., N::M::type, 2680/// or both. 2681/// 2682/// This type is used to keep track of a type name as written in the 2683/// source code, including tag keywords and any nested-name-specifiers. 2684/// The type itself is always "sugar", used to express what was written 2685/// in the source code but containing no additional semantic information. 2686class ElaboratedType : public TypeWithKeyword, public llvm::FoldingSetNode { 2687 2688 /// \brief The nested name specifier containing the qualifier. 2689 NestedNameSpecifier *NNS; 2690 2691 /// \brief The type that this qualified name refers to. 2692 QualType NamedType; 2693 2694 ElaboratedType(ElaboratedTypeKeyword Keyword, NestedNameSpecifier *NNS, 2695 QualType NamedType, QualType CanonType) 2696 : TypeWithKeyword(Keyword, Elaborated, CanonType, 2697 NamedType->isDependentType()), 2698 NNS(NNS), NamedType(NamedType) { 2699 assert(!(Keyword == ETK_None && NNS == 0) && 2700 "ElaboratedType cannot have elaborated type keyword " 2701 "and name qualifier both null."); 2702 } 2703 2704 friend class ASTContext; // ASTContext creates these 2705 2706public: 2707 ~ElaboratedType(); 2708 2709 /// \brief Retrieve the qualification on this type. 2710 NestedNameSpecifier *getQualifier() const { return NNS; } 2711 2712 /// \brief Retrieve the type named by the qualified-id. 2713 QualType getNamedType() const { return NamedType; } 2714 2715 /// \brief Remove a single level of sugar. 2716 QualType desugar() const { return getNamedType(); } 2717 2718 /// \brief Returns whether this type directly provides sugar. 2719 bool isSugared() const { return true; } 2720 2721 void Profile(llvm::FoldingSetNodeID &ID) { 2722 Profile(ID, getKeyword(), NNS, NamedType); 2723 } 2724 2725 static void Profile(llvm::FoldingSetNodeID &ID, ElaboratedTypeKeyword Keyword, 2726 NestedNameSpecifier *NNS, QualType NamedType) { 2727 ID.AddInteger(Keyword); 2728 ID.AddPointer(NNS); 2729 NamedType.Profile(ID); 2730 } 2731 2732 static bool classof(const Type *T) { 2733 return T->getTypeClass() == Elaborated; 2734 } 2735 static bool classof(const ElaboratedType *T) { return true; } 2736}; 2737 2738/// \brief Represents a qualified type name for which the type name is 2739/// dependent. 2740/// 2741/// DependentNameType represents a class of dependent types that involve a 2742/// dependent nested-name-specifier (e.g., "T::") followed by a (dependent) 2743/// name of a type. The DependentNameType may start with a "typename" (for a 2744/// typename-specifier), "class", "struct", "union", or "enum" (for a 2745/// dependent elaborated-type-specifier), or nothing (in contexts where we 2746/// know that we must be referring to a type, e.g., in a base class specifier). 2747class DependentNameType : public TypeWithKeyword, public llvm::FoldingSetNode { 2748 2749 /// \brief The nested name specifier containing the qualifier. 2750 NestedNameSpecifier *NNS; 2751 2752 /// \brief The type that this typename specifier refers to. 2753 const IdentifierInfo *Name; 2754 2755 DependentNameType(ElaboratedTypeKeyword Keyword, NestedNameSpecifier *NNS, 2756 const IdentifierInfo *Name, QualType CanonType) 2757 : TypeWithKeyword(Keyword, DependentName, CanonType, true), 2758 NNS(NNS), Name(Name) { 2759 assert(NNS->isDependent() && 2760 "DependentNameType requires a dependent nested-name-specifier"); 2761 } 2762 2763 friend class ASTContext; // ASTContext creates these 2764 2765public: 2766 virtual ~DependentNameType(); 2767 2768 /// \brief Retrieve the qualification on this type. 2769 NestedNameSpecifier *getQualifier() const { return NNS; } 2770 2771 /// \brief Retrieve the type named by the typename specifier as an 2772 /// identifier. 2773 /// 2774 /// This routine will return a non-NULL identifier pointer when the 2775 /// form of the original typename was terminated by an identifier, 2776 /// e.g., "typename T::type". 2777 const IdentifierInfo *getIdentifier() const { 2778 return Name; 2779 } 2780 2781 bool isSugared() const { return false; } 2782 QualType desugar() const { return QualType(this, 0); } 2783 2784 void Profile(llvm::FoldingSetNodeID &ID) { 2785 Profile(ID, getKeyword(), NNS, Name); 2786 } 2787 2788 static void Profile(llvm::FoldingSetNodeID &ID, ElaboratedTypeKeyword Keyword, 2789 NestedNameSpecifier *NNS, const IdentifierInfo *Name) { 2790 ID.AddInteger(Keyword); 2791 ID.AddPointer(NNS); 2792 ID.AddPointer(Name); 2793 } 2794 2795 static bool classof(const Type *T) { 2796 return T->getTypeClass() == DependentName; 2797 } 2798 static bool classof(const DependentNameType *T) { return true; } 2799}; 2800 2801/// DependentTemplateSpecializationType - Represents a template 2802/// specialization type whose template cannot be resolved, e.g. 2803/// A<T>::template B<T> 2804class DependentTemplateSpecializationType : 2805 public TypeWithKeyword, public llvm::FoldingSetNode { 2806 2807 /// \brief The nested name specifier containing the qualifier. 2808 NestedNameSpecifier *NNS; 2809 2810 /// \brief The identifier of the template. 2811 const IdentifierInfo *Name; 2812 2813 /// \brief - The number of template arguments named in this class 2814 /// template specialization. 2815 unsigned NumArgs; 2816 2817 const TemplateArgument *getArgBuffer() const { 2818 return reinterpret_cast<const TemplateArgument*>(this+1); 2819 } 2820 TemplateArgument *getArgBuffer() { 2821 return reinterpret_cast<TemplateArgument*>(this+1); 2822 } 2823 2824 DependentTemplateSpecializationType(ElaboratedTypeKeyword Keyword, 2825 NestedNameSpecifier *NNS, 2826 const IdentifierInfo *Name, 2827 unsigned NumArgs, 2828 const TemplateArgument *Args, 2829 QualType Canon); 2830 2831 friend class ASTContext; // ASTContext creates these 2832 2833public: 2834 virtual ~DependentTemplateSpecializationType(); 2835 2836 NestedNameSpecifier *getQualifier() const { return NNS; } 2837 const IdentifierInfo *getIdentifier() const { return Name; } 2838 2839 /// \brief Retrieve the template arguments. 2840 const TemplateArgument *getArgs() const { 2841 return getArgBuffer(); 2842 } 2843 2844 /// \brief Retrieve the number of template arguments. 2845 unsigned getNumArgs() const { return NumArgs; } 2846 2847 const TemplateArgument &getArg(unsigned Idx) const; // in TemplateBase.h 2848 2849 typedef const TemplateArgument * iterator; 2850 iterator begin() const { return getArgs(); } 2851 iterator end() const; // inline in TemplateBase.h 2852 2853 bool isSugared() const { return false; } 2854 QualType desugar() const { return QualType(this, 0); } 2855 2856 void Profile(llvm::FoldingSetNodeID &ID, ASTContext &Context) { 2857 Profile(ID, Context, getKeyword(), NNS, Name, NumArgs, getArgs()); 2858 } 2859 2860 static void Profile(llvm::FoldingSetNodeID &ID, 2861 ASTContext &Context, 2862 ElaboratedTypeKeyword Keyword, 2863 NestedNameSpecifier *Qualifier, 2864 const IdentifierInfo *Name, 2865 unsigned NumArgs, 2866 const TemplateArgument *Args); 2867 2868 static bool classof(const Type *T) { 2869 return T->getTypeClass() == DependentTemplateSpecialization; 2870 } 2871 static bool classof(const DependentTemplateSpecializationType *T) { 2872 return true; 2873 } 2874}; 2875 2876/// ObjCObjectType - Represents a class type in Objective C. 2877/// Every Objective C type is a combination of a base type and a 2878/// list of protocols. 2879/// 2880/// Given the following declarations: 2881/// @class C; 2882/// @protocol P; 2883/// 2884/// 'C' is an ObjCInterfaceType C. It is sugar for an ObjCObjectType 2885/// with base C and no protocols. 2886/// 2887/// 'C<P>' is an ObjCObjectType with base C and protocol list [P]. 2888/// 2889/// 'id' is a TypedefType which is sugar for an ObjCPointerType whose 2890/// pointee is an ObjCObjectType with base BuiltinType::ObjCIdType 2891/// and no protocols. 2892/// 2893/// 'id<P>' is an ObjCPointerType whose pointee is an ObjCObjecType 2894/// with base BuiltinType::ObjCIdType and protocol list [P]. Eventually 2895/// this should get its own sugar class to better represent the source. 2896class ObjCObjectType : public Type { 2897 // Pad the bit count up so that NumProtocols is 2-byte aligned 2898 unsigned : BitsRemainingInType - 16; 2899 2900 /// \brief The number of protocols stored after the 2901 /// ObjCObjectPointerType node. 2902 /// 2903 /// These protocols are those written directly on the type. If 2904 /// protocol qualifiers ever become additive, the iterators will 2905 /// get kindof complicated. 2906 /// 2907 /// In the canonical object type, these are sorted alphabetically 2908 /// and uniqued. 2909 unsigned NumProtocols : 16; 2910 2911 /// Either a BuiltinType or an InterfaceType or sugar for either. 2912 QualType BaseType; 2913 2914 ObjCProtocolDecl * const *getProtocolStorage() const { 2915 return const_cast<ObjCObjectType*>(this)->getProtocolStorage(); 2916 } 2917 2918 ObjCProtocolDecl **getProtocolStorage(); 2919 2920protected: 2921 ObjCObjectType(QualType Canonical, QualType Base, 2922 ObjCProtocolDecl * const *Protocols, unsigned NumProtocols); 2923 2924 enum Nonce_ObjCInterface { Nonce_ObjCInterface }; 2925 ObjCObjectType(enum Nonce_ObjCInterface) 2926 : Type(ObjCInterface, QualType(), false), 2927 NumProtocols(0), 2928 BaseType(QualType(this_(), 0)) {} 2929 2930protected: 2931 Linkage getLinkageImpl() const; // key function 2932 2933public: 2934 /// getBaseType - Gets the base type of this object type. This is 2935 /// always (possibly sugar for) one of: 2936 /// - the 'id' builtin type (as opposed to the 'id' type visible to the 2937 /// user, which is a typedef for an ObjCPointerType) 2938 /// - the 'Class' builtin type (same caveat) 2939 /// - an ObjCObjectType (currently always an ObjCInterfaceType) 2940 QualType getBaseType() const { return BaseType; } 2941 2942 bool isObjCId() const { 2943 return getBaseType()->isSpecificBuiltinType(BuiltinType::ObjCId); 2944 } 2945 bool isObjCClass() const { 2946 return getBaseType()->isSpecificBuiltinType(BuiltinType::ObjCClass); 2947 } 2948 bool isObjCUnqualifiedId() const { return qual_empty() && isObjCId(); } 2949 bool isObjCUnqualifiedClass() const { return qual_empty() && isObjCClass(); } 2950 bool isObjCUnqualifiedIdOrClass() const { 2951 if (!qual_empty()) return false; 2952 if (const BuiltinType *T = getBaseType()->getAs<BuiltinType>()) 2953 return T->getKind() == BuiltinType::ObjCId || 2954 T->getKind() == BuiltinType::ObjCClass; 2955 return false; 2956 } 2957 bool isObjCQualifiedId() const { return !qual_empty() && isObjCId(); } 2958 bool isObjCQualifiedClass() const { return !qual_empty() && isObjCClass(); } 2959 2960 /// Gets the interface declaration for this object type, if the base type 2961 /// really is an interface. 2962 ObjCInterfaceDecl *getInterface() const; 2963 2964 typedef ObjCProtocolDecl * const *qual_iterator; 2965 2966 qual_iterator qual_begin() const { return getProtocolStorage(); } 2967 qual_iterator qual_end() const { return qual_begin() + getNumProtocols(); } 2968 2969 bool qual_empty() const { return getNumProtocols() == 0; } 2970 2971 /// getNumProtocols - Return the number of qualifying protocols in this 2972 /// interface type, or 0 if there are none. 2973 unsigned getNumProtocols() const { return NumProtocols; } 2974 2975 /// \brief Fetch a protocol by index. 2976 ObjCProtocolDecl *getProtocol(unsigned I) const { 2977 assert(I < getNumProtocols() && "Out-of-range protocol access"); 2978 return qual_begin()[I]; 2979 } 2980 2981 bool isSugared() const { return false; } 2982 QualType desugar() const { return QualType(this, 0); } 2983 2984 static bool classof(const Type *T) { 2985 return T->getTypeClass() == ObjCObject || 2986 T->getTypeClass() == ObjCInterface; 2987 } 2988 static bool classof(const ObjCObjectType *) { return true; } 2989}; 2990 2991/// ObjCObjectTypeImpl - A class providing a concrete implementation 2992/// of ObjCObjectType, so as to not increase the footprint of 2993/// ObjCInterfaceType. Code outside of ASTContext and the core type 2994/// system should not reference this type. 2995class ObjCObjectTypeImpl : public ObjCObjectType, public llvm::FoldingSetNode { 2996 friend class ASTContext; 2997 2998 // If anyone adds fields here, ObjCObjectType::getProtocolStorage() 2999 // will need to be modified. 3000 3001 ObjCObjectTypeImpl(QualType Canonical, QualType Base, 3002 ObjCProtocolDecl * const *Protocols, 3003 unsigned NumProtocols) 3004 : ObjCObjectType(Canonical, Base, Protocols, NumProtocols) {} 3005 3006public: 3007 void Profile(llvm::FoldingSetNodeID &ID); 3008 static void Profile(llvm::FoldingSetNodeID &ID, 3009 QualType Base, 3010 ObjCProtocolDecl *const *protocols, 3011 unsigned NumProtocols); 3012}; 3013 3014inline ObjCProtocolDecl **ObjCObjectType::getProtocolStorage() { 3015 return reinterpret_cast<ObjCProtocolDecl**>( 3016 static_cast<ObjCObjectTypeImpl*>(this) + 1); 3017} 3018 3019/// ObjCInterfaceType - Interfaces are the core concept in Objective-C for 3020/// object oriented design. They basically correspond to C++ classes. There 3021/// are two kinds of interface types, normal interfaces like "NSString" and 3022/// qualified interfaces, which are qualified with a protocol list like 3023/// "NSString<NSCopyable, NSAmazing>". 3024/// 3025/// ObjCInterfaceType guarantees the following properties when considered 3026/// as a subtype of its superclass, ObjCObjectType: 3027/// - There are no protocol qualifiers. To reinforce this, code which 3028/// tries to invoke the protocol methods via an ObjCInterfaceType will 3029/// fail to compile. 3030/// - It is its own base type. That is, if T is an ObjCInterfaceType*, 3031/// T->getBaseType() == QualType(T, 0). 3032class ObjCInterfaceType : public ObjCObjectType { 3033 ObjCInterfaceDecl *Decl; 3034 3035 ObjCInterfaceType(const ObjCInterfaceDecl *D) 3036 : ObjCObjectType(Nonce_ObjCInterface), 3037 Decl(const_cast<ObjCInterfaceDecl*>(D)) {} 3038 friend class ASTContext; // ASTContext creates these. 3039public: 3040 /// getDecl - Get the declaration of this interface. 3041 ObjCInterfaceDecl *getDecl() const { return Decl; } 3042 3043 bool isSugared() const { return false; } 3044 QualType desugar() const { return QualType(this, 0); } 3045 3046 static bool classof(const Type *T) { 3047 return T->getTypeClass() == ObjCInterface; 3048 } 3049 static bool classof(const ObjCInterfaceType *) { return true; } 3050 3051 // Nonsense to "hide" certain members of ObjCObjectType within this 3052 // class. People asking for protocols on an ObjCInterfaceType are 3053 // not going to get what they want: ObjCInterfaceTypes are 3054 // guaranteed to have no protocols. 3055 enum { 3056 qual_iterator, 3057 qual_begin, 3058 qual_end, 3059 getNumProtocols, 3060 getProtocol 3061 }; 3062}; 3063 3064inline ObjCInterfaceDecl *ObjCObjectType::getInterface() const { 3065 if (const ObjCInterfaceType *T = 3066 getBaseType()->getAs<ObjCInterfaceType>()) 3067 return T->getDecl(); 3068 return 0; 3069} 3070 3071/// ObjCObjectPointerType - Used to represent a pointer to an 3072/// Objective C object. These are constructed from pointer 3073/// declarators when the pointee type is an ObjCObjectType (or sugar 3074/// for one). In addition, the 'id' and 'Class' types are typedefs 3075/// for these, and the protocol-qualified types 'id<P>' and 'Class<P>' 3076/// are translated into these. 3077/// 3078/// Pointers to pointers to Objective C objects are still PointerTypes; 3079/// only the first level of pointer gets it own type implementation. 3080class ObjCObjectPointerType : public Type, public llvm::FoldingSetNode { 3081 QualType PointeeType; 3082 3083 ObjCObjectPointerType(QualType Canonical, QualType Pointee) 3084 : Type(ObjCObjectPointer, Canonical, false), 3085 PointeeType(Pointee) {} 3086 friend class ASTContext; // ASTContext creates these. 3087 3088protected: 3089 virtual Linkage getLinkageImpl() const; 3090 3091public: 3092 /// getPointeeType - Gets the type pointed to by this ObjC pointer. 3093 /// The result will always be an ObjCObjectType or sugar thereof. 3094 QualType getPointeeType() const { return PointeeType; } 3095 3096 /// getObjCObjectType - Gets the type pointed to by this ObjC 3097 /// pointer. This method always returns non-null. 3098 /// 3099 /// This method is equivalent to getPointeeType() except that 3100 /// it discards any typedefs (or other sugar) between this 3101 /// type and the "outermost" object type. So for: 3102 /// @class A; @protocol P; @protocol Q; 3103 /// typedef A<P> AP; 3104 /// typedef A A1; 3105 /// typedef A1<P> A1P; 3106 /// typedef A1P<Q> A1PQ; 3107 /// For 'A*', getObjectType() will return 'A'. 3108 /// For 'A<P>*', getObjectType() will return 'A<P>'. 3109 /// For 'AP*', getObjectType() will return 'A<P>'. 3110 /// For 'A1*', getObjectType() will return 'A'. 3111 /// For 'A1<P>*', getObjectType() will return 'A1<P>'. 3112 /// For 'A1P*', getObjectType() will return 'A1<P>'. 3113 /// For 'A1PQ*', getObjectType() will return 'A1<Q>', because 3114 /// adding protocols to a protocol-qualified base discards the 3115 /// old qualifiers (for now). But if it didn't, getObjectType() 3116 /// would return 'A1P<Q>' (and we'd have to make iterating over 3117 /// qualifiers more complicated). 3118 const ObjCObjectType *getObjectType() const { 3119 return PointeeType->getAs<ObjCObjectType>(); 3120 } 3121 3122 /// getInterfaceType - If this pointer points to an Objective C 3123 /// @interface type, gets the type for that interface. Any protocol 3124 /// qualifiers on the interface are ignored. 3125 /// 3126 /// \return null if the base type for this pointer is 'id' or 'Class' 3127 const ObjCInterfaceType *getInterfaceType() const { 3128 return getObjectType()->getBaseType()->getAs<ObjCInterfaceType>(); 3129 } 3130 3131 /// getInterfaceDecl - If this pointer points to an Objective @interface 3132 /// type, gets the declaration for that interface. 3133 /// 3134 /// \return null if the base type for this pointer is 'id' or 'Class' 3135 ObjCInterfaceDecl *getInterfaceDecl() const { 3136 return getObjectType()->getInterface(); 3137 } 3138 3139 /// isObjCIdType - True if this is equivalent to the 'id' type, i.e. if 3140 /// its object type is the primitive 'id' type with no protocols. 3141 bool isObjCIdType() const { 3142 return getObjectType()->isObjCUnqualifiedId(); 3143 } 3144 3145 /// isObjCClassType - True if this is equivalent to the 'Class' type, 3146 /// i.e. if its object tive is the primitive 'Class' type with no protocols. 3147 bool isObjCClassType() const { 3148 return getObjectType()->isObjCUnqualifiedClass(); 3149 } 3150 3151 /// isObjCQualifiedIdType - True if this is equivalent to 'id<P>' for some 3152 /// non-empty set of protocols. 3153 bool isObjCQualifiedIdType() const { 3154 return getObjectType()->isObjCQualifiedId(); 3155 } 3156 3157 /// isObjCQualifiedClassType - True if this is equivalent to 'Class<P>' for 3158 /// some non-empty set of protocols. 3159 bool isObjCQualifiedClassType() const { 3160 return getObjectType()->isObjCQualifiedClass(); 3161 } 3162 3163 /// An iterator over the qualifiers on the object type. Provided 3164 /// for convenience. This will always iterate over the full set of 3165 /// protocols on a type, not just those provided directly. 3166 typedef ObjCObjectType::qual_iterator qual_iterator; 3167 3168 qual_iterator qual_begin() const { 3169 return getObjectType()->qual_begin(); 3170 } 3171 qual_iterator qual_end() const { 3172 return getObjectType()->qual_end(); 3173 } 3174 bool qual_empty() const { return getObjectType()->qual_empty(); } 3175 3176 /// getNumProtocols - Return the number of qualifying protocols on 3177 /// the object type. 3178 unsigned getNumProtocols() const { 3179 return getObjectType()->getNumProtocols(); 3180 } 3181 3182 /// \brief Retrieve a qualifying protocol by index on the object 3183 /// type. 3184 ObjCProtocolDecl *getProtocol(unsigned I) const { 3185 return getObjectType()->getProtocol(I); 3186 } 3187 3188 bool isSugared() const { return false; } 3189 QualType desugar() const { return QualType(this, 0); } 3190 3191 void Profile(llvm::FoldingSetNodeID &ID) { 3192 Profile(ID, getPointeeType()); 3193 } 3194 static void Profile(llvm::FoldingSetNodeID &ID, QualType T) { 3195 ID.AddPointer(T.getAsOpaquePtr()); 3196 } 3197 static bool classof(const Type *T) { 3198 return T->getTypeClass() == ObjCObjectPointer; 3199 } 3200 static bool classof(const ObjCObjectPointerType *) { return true; } 3201}; 3202 3203/// A qualifier set is used to build a set of qualifiers. 3204class QualifierCollector : public Qualifiers { 3205 ASTContext *Context; 3206 3207public: 3208 QualifierCollector(Qualifiers Qs = Qualifiers()) 3209 : Qualifiers(Qs), Context(0) {} 3210 QualifierCollector(ASTContext &Context, Qualifiers Qs = Qualifiers()) 3211 : Qualifiers(Qs), Context(&Context) {} 3212 3213 void setContext(ASTContext &C) { Context = &C; } 3214 3215 /// Collect any qualifiers on the given type and return an 3216 /// unqualified type. 3217 const Type *strip(QualType QT) { 3218 addFastQualifiers(QT.getLocalFastQualifiers()); 3219 if (QT.hasLocalNonFastQualifiers()) { 3220 const ExtQuals *EQ = QT.getExtQualsUnsafe(); 3221 Context = &EQ->getContext(); 3222 addQualifiers(EQ->getQualifiers()); 3223 return EQ->getBaseType(); 3224 } 3225 return QT.getTypePtrUnsafe(); 3226 } 3227 3228 /// Apply the collected qualifiers to the given type. 3229 QualType apply(QualType QT) const; 3230 3231 /// Apply the collected qualifiers to the given type. 3232 QualType apply(const Type* T) const; 3233 3234}; 3235 3236 3237// Inline function definitions. 3238 3239inline bool QualType::isCanonical() const { 3240 const Type *T = getTypePtr(); 3241 if (hasLocalQualifiers()) 3242 return T->isCanonicalUnqualified() && !isa<ArrayType>(T); 3243 return T->isCanonicalUnqualified(); 3244} 3245 3246inline bool QualType::isCanonicalAsParam() const { 3247 if (hasLocalQualifiers()) return false; 3248 const Type *T = getTypePtr(); 3249 return T->isCanonicalUnqualified() && 3250 !isa<FunctionType>(T) && !isa<ArrayType>(T); 3251} 3252 3253inline bool QualType::isConstQualified() const { 3254 return isLocalConstQualified() || 3255 getTypePtr()->getCanonicalTypeInternal().isLocalConstQualified(); 3256} 3257 3258inline bool QualType::isRestrictQualified() const { 3259 return isLocalRestrictQualified() || 3260 getTypePtr()->getCanonicalTypeInternal().isLocalRestrictQualified(); 3261} 3262 3263 3264inline bool QualType::isVolatileQualified() const { 3265 return isLocalVolatileQualified() || 3266 getTypePtr()->getCanonicalTypeInternal().isLocalVolatileQualified(); 3267} 3268 3269inline bool QualType::hasQualifiers() const { 3270 return hasLocalQualifiers() || 3271 getTypePtr()->getCanonicalTypeInternal().hasLocalQualifiers(); 3272} 3273 3274inline Qualifiers QualType::getQualifiers() const { 3275 Qualifiers Quals = getLocalQualifiers(); 3276 Quals.addQualifiers( 3277 getTypePtr()->getCanonicalTypeInternal().getLocalQualifiers()); 3278 return Quals; 3279} 3280 3281inline unsigned QualType::getCVRQualifiers() const { 3282 return getLocalCVRQualifiers() | 3283 getTypePtr()->getCanonicalTypeInternal().getLocalCVRQualifiers(); 3284} 3285 3286/// getCVRQualifiersThroughArrayTypes - If there are CVR qualifiers for this 3287/// type, returns them. Otherwise, if this is an array type, recurses 3288/// on the element type until some qualifiers have been found or a non-array 3289/// type reached. 3290inline unsigned QualType::getCVRQualifiersThroughArrayTypes() const { 3291 if (unsigned Quals = getCVRQualifiers()) 3292 return Quals; 3293 QualType CT = getTypePtr()->getCanonicalTypeInternal(); 3294 if (const ArrayType *AT = dyn_cast<ArrayType>(CT)) 3295 return AT->getElementType().getCVRQualifiersThroughArrayTypes(); 3296 return 0; 3297} 3298 3299inline void QualType::removeConst() { 3300 removeFastQualifiers(Qualifiers::Const); 3301} 3302 3303inline void QualType::removeRestrict() { 3304 removeFastQualifiers(Qualifiers::Restrict); 3305} 3306 3307inline void QualType::removeVolatile() { 3308 QualifierCollector Qc; 3309 const Type *Ty = Qc.strip(*this); 3310 if (Qc.hasVolatile()) { 3311 Qc.removeVolatile(); 3312 *this = Qc.apply(Ty); 3313 } 3314} 3315 3316inline void QualType::removeCVRQualifiers(unsigned Mask) { 3317 assert(!(Mask & ~Qualifiers::CVRMask) && "mask has non-CVR bits"); 3318 3319 // Fast path: we don't need to touch the slow qualifiers. 3320 if (!(Mask & ~Qualifiers::FastMask)) { 3321 removeFastQualifiers(Mask); 3322 return; 3323 } 3324 3325 QualifierCollector Qc; 3326 const Type *Ty = Qc.strip(*this); 3327 Qc.removeCVRQualifiers(Mask); 3328 *this = Qc.apply(Ty); 3329} 3330 3331/// getAddressSpace - Return the address space of this type. 3332inline unsigned QualType::getAddressSpace() const { 3333 if (hasLocalNonFastQualifiers()) { 3334 const ExtQuals *EQ = getExtQualsUnsafe(); 3335 if (EQ->hasAddressSpace()) 3336 return EQ->getAddressSpace(); 3337 } 3338 3339 QualType CT = getTypePtr()->getCanonicalTypeInternal(); 3340 if (CT.hasLocalNonFastQualifiers()) { 3341 const ExtQuals *EQ = CT.getExtQualsUnsafe(); 3342 if (EQ->hasAddressSpace()) 3343 return EQ->getAddressSpace(); 3344 } 3345 3346 if (const ArrayType *AT = dyn_cast<ArrayType>(CT)) 3347 return AT->getElementType().getAddressSpace(); 3348 if (const RecordType *RT = dyn_cast<RecordType>(CT)) 3349 return RT->getAddressSpace(); 3350 return 0; 3351} 3352 3353/// getObjCGCAttr - Return the gc attribute of this type. 3354inline Qualifiers::GC QualType::getObjCGCAttr() const { 3355 if (hasLocalNonFastQualifiers()) { 3356 const ExtQuals *EQ = getExtQualsUnsafe(); 3357 if (EQ->hasObjCGCAttr()) 3358 return EQ->getObjCGCAttr(); 3359 } 3360 3361 QualType CT = getTypePtr()->getCanonicalTypeInternal(); 3362 if (CT.hasLocalNonFastQualifiers()) { 3363 const ExtQuals *EQ = CT.getExtQualsUnsafe(); 3364 if (EQ->hasObjCGCAttr()) 3365 return EQ->getObjCGCAttr(); 3366 } 3367 3368 if (const ArrayType *AT = dyn_cast<ArrayType>(CT)) 3369 return AT->getElementType().getObjCGCAttr(); 3370 if (const ObjCObjectPointerType *PT = CT->getAs<ObjCObjectPointerType>()) 3371 return PT->getPointeeType().getObjCGCAttr(); 3372 // We most look at all pointer types, not just pointer to interface types. 3373 if (const PointerType *PT = CT->getAs<PointerType>()) 3374 return PT->getPointeeType().getObjCGCAttr(); 3375 return Qualifiers::GCNone; 3376} 3377 3378inline FunctionType::ExtInfo getFunctionExtInfo(const Type &t) { 3379 if (const PointerType *PT = t.getAs<PointerType>()) { 3380 if (const FunctionType *FT = PT->getPointeeType()->getAs<FunctionType>()) 3381 return FT->getExtInfo(); 3382 } else if (const FunctionType *FT = t.getAs<FunctionType>()) 3383 return FT->getExtInfo(); 3384 3385 return FunctionType::ExtInfo(); 3386} 3387 3388inline FunctionType::ExtInfo getFunctionExtInfo(QualType t) { 3389 return getFunctionExtInfo(*t); 3390} 3391 3392/// \brief Determine whether this set of qualifiers is a superset of the given 3393/// set of qualifiers. 3394inline bool Qualifiers::isSupersetOf(Qualifiers Other) const { 3395 return Mask != Other.Mask && (Mask | Other.Mask) == Mask; 3396} 3397 3398/// isMoreQualifiedThan - Determine whether this type is more 3399/// qualified than the Other type. For example, "const volatile int" 3400/// is more qualified than "const int", "volatile int", and 3401/// "int". However, it is not more qualified than "const volatile 3402/// int". 3403inline bool QualType::isMoreQualifiedThan(QualType Other) const { 3404 // FIXME: work on arbitrary qualifiers 3405 unsigned MyQuals = this->getCVRQualifiersThroughArrayTypes(); 3406 unsigned OtherQuals = Other.getCVRQualifiersThroughArrayTypes(); 3407 if (getAddressSpace() != Other.getAddressSpace()) 3408 return false; 3409 return MyQuals != OtherQuals && (MyQuals | OtherQuals) == MyQuals; 3410} 3411 3412/// isAtLeastAsQualifiedAs - Determine whether this type is at last 3413/// as qualified as the Other type. For example, "const volatile 3414/// int" is at least as qualified as "const int", "volatile int", 3415/// "int", and "const volatile int". 3416inline bool QualType::isAtLeastAsQualifiedAs(QualType Other) const { 3417 // FIXME: work on arbitrary qualifiers 3418 unsigned MyQuals = this->getCVRQualifiersThroughArrayTypes(); 3419 unsigned OtherQuals = Other.getCVRQualifiersThroughArrayTypes(); 3420 if (getAddressSpace() != Other.getAddressSpace()) 3421 return false; 3422 return (MyQuals | OtherQuals) == MyQuals; 3423} 3424 3425/// getNonReferenceType - If Type is a reference type (e.g., const 3426/// int&), returns the type that the reference refers to ("const 3427/// int"). Otherwise, returns the type itself. This routine is used 3428/// throughout Sema to implement C++ 5p6: 3429/// 3430/// If an expression initially has the type "reference to T" (8.3.2, 3431/// 8.5.3), the type is adjusted to "T" prior to any further 3432/// analysis, the expression designates the object or function 3433/// denoted by the reference, and the expression is an lvalue. 3434inline QualType QualType::getNonReferenceType() const { 3435 if (const ReferenceType *RefType = (*this)->getAs<ReferenceType>()) 3436 return RefType->getPointeeType(); 3437 else 3438 return *this; 3439} 3440 3441inline bool Type::isFunctionType() const { 3442 return isa<FunctionType>(CanonicalType); 3443} 3444inline bool Type::isPointerType() const { 3445 return isa<PointerType>(CanonicalType); 3446} 3447inline bool Type::isAnyPointerType() const { 3448 return isPointerType() || isObjCObjectPointerType(); 3449} 3450inline bool Type::isBlockPointerType() const { 3451 return isa<BlockPointerType>(CanonicalType); 3452} 3453inline bool Type::isReferenceType() const { 3454 return isa<ReferenceType>(CanonicalType); 3455} 3456inline bool Type::isLValueReferenceType() const { 3457 return isa<LValueReferenceType>(CanonicalType); 3458} 3459inline bool Type::isRValueReferenceType() const { 3460 return isa<RValueReferenceType>(CanonicalType); 3461} 3462inline bool Type::isFunctionPointerType() const { 3463 if (const PointerType* T = getAs<PointerType>()) 3464 return T->getPointeeType()->isFunctionType(); 3465 else 3466 return false; 3467} 3468inline bool Type::isMemberPointerType() const { 3469 return isa<MemberPointerType>(CanonicalType); 3470} 3471inline bool Type::isMemberFunctionPointerType() const { 3472 if (const MemberPointerType* T = getAs<MemberPointerType>()) 3473 return T->getPointeeType()->isFunctionType(); 3474 else 3475 return false; 3476} 3477inline bool Type::isArrayType() const { 3478 return isa<ArrayType>(CanonicalType); 3479} 3480inline bool Type::isConstantArrayType() const { 3481 return isa<ConstantArrayType>(CanonicalType); 3482} 3483inline bool Type::isIncompleteArrayType() const { 3484 return isa<IncompleteArrayType>(CanonicalType); 3485} 3486inline bool Type::isVariableArrayType() const { 3487 return isa<VariableArrayType>(CanonicalType); 3488} 3489inline bool Type::isDependentSizedArrayType() const { 3490 return isa<DependentSizedArrayType>(CanonicalType); 3491} 3492inline bool Type::isRecordType() const { 3493 return isa<RecordType>(CanonicalType); 3494} 3495inline bool Type::isAnyComplexType() const { 3496 return isa<ComplexType>(CanonicalType); 3497} 3498inline bool Type::isVectorType() const { 3499 return isa<VectorType>(CanonicalType); 3500} 3501inline bool Type::isExtVectorType() const { 3502 return isa<ExtVectorType>(CanonicalType); 3503} 3504inline bool Type::isObjCObjectPointerType() const { 3505 return isa<ObjCObjectPointerType>(CanonicalType); 3506} 3507inline bool Type::isObjCObjectType() const { 3508 return isa<ObjCObjectType>(CanonicalType); 3509} 3510inline bool Type::isObjCObjectOrInterfaceType() const { 3511 return isa<ObjCInterfaceType>(CanonicalType) || 3512 isa<ObjCObjectType>(CanonicalType); 3513} 3514 3515inline bool Type::isObjCQualifiedIdType() const { 3516 if (const ObjCObjectPointerType *OPT = getAs<ObjCObjectPointerType>()) 3517 return OPT->isObjCQualifiedIdType(); 3518 return false; 3519} 3520inline bool Type::isObjCQualifiedClassType() const { 3521 if (const ObjCObjectPointerType *OPT = getAs<ObjCObjectPointerType>()) 3522 return OPT->isObjCQualifiedClassType(); 3523 return false; 3524} 3525inline bool Type::isObjCIdType() const { 3526 if (const ObjCObjectPointerType *OPT = getAs<ObjCObjectPointerType>()) 3527 return OPT->isObjCIdType(); 3528 return false; 3529} 3530inline bool Type::isObjCClassType() const { 3531 if (const ObjCObjectPointerType *OPT = getAs<ObjCObjectPointerType>()) 3532 return OPT->isObjCClassType(); 3533 return false; 3534} 3535inline bool Type::isObjCSelType() const { 3536 if (const PointerType *OPT = getAs<PointerType>()) 3537 return OPT->getPointeeType()->isSpecificBuiltinType(BuiltinType::ObjCSel); 3538 return false; 3539} 3540inline bool Type::isObjCBuiltinType() const { 3541 return isObjCIdType() || isObjCClassType() || isObjCSelType(); 3542} 3543inline bool Type::isTemplateTypeParmType() const { 3544 return isa<TemplateTypeParmType>(CanonicalType); 3545} 3546 3547inline bool Type::isBuiltinType() const { 3548 return getAs<BuiltinType>(); 3549} 3550 3551inline bool Type::isSpecificBuiltinType(unsigned K) const { 3552 if (const BuiltinType *BT = getAs<BuiltinType>()) 3553 if (BT->getKind() == (BuiltinType::Kind) K) 3554 return true; 3555 return false; 3556} 3557 3558/// \brief Determines whether this is a type for which one can define 3559/// an overloaded operator. 3560inline bool Type::isOverloadableType() const { 3561 return isDependentType() || isRecordType() || isEnumeralType(); 3562} 3563 3564inline bool Type::hasPointerRepresentation() const { 3565 return (isPointerType() || isReferenceType() || isBlockPointerType() || 3566 isObjCObjectPointerType() || isNullPtrType()); 3567} 3568 3569inline bool Type::hasObjCPointerRepresentation() const { 3570 return isObjCObjectPointerType(); 3571} 3572 3573/// Insertion operator for diagnostics. This allows sending QualType's into a 3574/// diagnostic with <<. 3575inline const DiagnosticBuilder &operator<<(const DiagnosticBuilder &DB, 3576 QualType T) { 3577 DB.AddTaggedVal(reinterpret_cast<intptr_t>(T.getAsOpaquePtr()), 3578 Diagnostic::ak_qualtype); 3579 return DB; 3580} 3581 3582/// Insertion operator for partial diagnostics. This allows sending QualType's 3583/// into a diagnostic with <<. 3584inline const PartialDiagnostic &operator<<(const PartialDiagnostic &PD, 3585 QualType T) { 3586 PD.AddTaggedVal(reinterpret_cast<intptr_t>(T.getAsOpaquePtr()), 3587 Diagnostic::ak_qualtype); 3588 return PD; 3589} 3590 3591// Helper class template that is used by Type::getAs to ensure that one does 3592// not try to look through a qualified type to get to an array type. 3593template<typename T, 3594 bool isArrayType = (llvm::is_same<T, ArrayType>::value || 3595 llvm::is_base_of<ArrayType, T>::value)> 3596struct ArrayType_cannot_be_used_with_getAs { }; 3597 3598template<typename T> 3599struct ArrayType_cannot_be_used_with_getAs<T, true>; 3600 3601/// Member-template getAs<specific type>'. 3602template <typename T> const T *Type::getAs() const { 3603 ArrayType_cannot_be_used_with_getAs<T> at; 3604 (void)at; 3605 3606 // If this is directly a T type, return it. 3607 if (const T *Ty = dyn_cast<T>(this)) 3608 return Ty; 3609 3610 // If the canonical form of this type isn't the right kind, reject it. 3611 if (!isa<T>(CanonicalType)) 3612 return 0; 3613 3614 // If this is a typedef for the type, strip the typedef off without 3615 // losing all typedef information. 3616 return cast<T>(getUnqualifiedDesugaredType()); 3617} 3618 3619} // end namespace clang 3620 3621#endif 3622