1 //===- ASTContext.cpp - Context to hold long-lived AST nodes --------------===// 2 // 3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4 // See https://llvm.org/LICENSE.txt for license information. 5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6 // 7 //===----------------------------------------------------------------------===// 8 // 9 // This file implements the ASTContext interface. 10 // 11 //===----------------------------------------------------------------------===// 12 13 #include "clang/AST/ASTContext.h" 14 #include "CXXABI.h" 15 #include "Interp/Context.h" 16 #include "clang/AST/APValue.h" 17 #include "clang/AST/ASTConcept.h" 18 #include "clang/AST/ASTMutationListener.h" 19 #include "clang/AST/ASTTypeTraits.h" 20 #include "clang/AST/Attr.h" 21 #include "clang/AST/AttrIterator.h" 22 #include "clang/AST/CharUnits.h" 23 #include "clang/AST/Comment.h" 24 #include "clang/AST/Decl.h" 25 #include "clang/AST/DeclBase.h" 26 #include "clang/AST/DeclCXX.h" 27 #include "clang/AST/DeclContextInternals.h" 28 #include "clang/AST/DeclObjC.h" 29 #include "clang/AST/DeclOpenMP.h" 30 #include "clang/AST/DeclTemplate.h" 31 #include "clang/AST/DeclarationName.h" 32 #include "clang/AST/DependenceFlags.h" 33 #include "clang/AST/Expr.h" 34 #include "clang/AST/ExprCXX.h" 35 #include "clang/AST/ExprConcepts.h" 36 #include "clang/AST/ExternalASTSource.h" 37 #include "clang/AST/Mangle.h" 38 #include "clang/AST/MangleNumberingContext.h" 39 #include "clang/AST/NestedNameSpecifier.h" 40 #include "clang/AST/ParentMapContext.h" 41 #include "clang/AST/RawCommentList.h" 42 #include "clang/AST/RecordLayout.h" 43 #include "clang/AST/Stmt.h" 44 #include "clang/AST/TemplateBase.h" 45 #include "clang/AST/TemplateName.h" 46 #include "clang/AST/Type.h" 47 #include "clang/AST/TypeLoc.h" 48 #include "clang/AST/UnresolvedSet.h" 49 #include "clang/AST/VTableBuilder.h" 50 #include "clang/Basic/AddressSpaces.h" 51 #include "clang/Basic/Builtins.h" 52 #include "clang/Basic/CommentOptions.h" 53 #include "clang/Basic/ExceptionSpecificationType.h" 54 #include "clang/Basic/IdentifierTable.h" 55 #include "clang/Basic/LLVM.h" 56 #include "clang/Basic/LangOptions.h" 57 #include "clang/Basic/Linkage.h" 58 #include "clang/Basic/Module.h" 59 #include "clang/Basic/NoSanitizeList.h" 60 #include "clang/Basic/ObjCRuntime.h" 61 #include "clang/Basic/SourceLocation.h" 62 #include "clang/Basic/SourceManager.h" 63 #include "clang/Basic/Specifiers.h" 64 #include "clang/Basic/TargetCXXABI.h" 65 #include "clang/Basic/TargetInfo.h" 66 #include "clang/Basic/XRayLists.h" 67 #include "llvm/ADT/APFixedPoint.h" 68 #include "llvm/ADT/APInt.h" 69 #include "llvm/ADT/APSInt.h" 70 #include "llvm/ADT/ArrayRef.h" 71 #include "llvm/ADT/DenseMap.h" 72 #include "llvm/ADT/DenseSet.h" 73 #include "llvm/ADT/FoldingSet.h" 74 #include "llvm/ADT/None.h" 75 #include "llvm/ADT/Optional.h" 76 #include "llvm/ADT/PointerUnion.h" 77 #include "llvm/ADT/STLExtras.h" 78 #include "llvm/ADT/SmallPtrSet.h" 79 #include "llvm/ADT/SmallVector.h" 80 #include "llvm/ADT/StringExtras.h" 81 #include "llvm/ADT/StringRef.h" 82 #include "llvm/ADT/Triple.h" 83 #include "llvm/Support/Capacity.h" 84 #include "llvm/Support/Casting.h" 85 #include "llvm/Support/Compiler.h" 86 #include "llvm/Support/ErrorHandling.h" 87 #include "llvm/Support/MD5.h" 88 #include "llvm/Support/MathExtras.h" 89 #include "llvm/Support/raw_ostream.h" 90 #include <algorithm> 91 #include <cassert> 92 #include <cstddef> 93 #include <cstdint> 94 #include <cstdlib> 95 #include <map> 96 #include <memory> 97 #include <string> 98 #include <tuple> 99 #include <utility> 100 101 using namespace clang; 102 103 enum FloatingRank { 104 BFloat16Rank, 105 Float16Rank, 106 HalfRank, 107 FloatRank, 108 DoubleRank, 109 LongDoubleRank, 110 Float128Rank, 111 Ibm128Rank 112 }; 113 114 /// \returns location that is relevant when searching for Doc comments related 115 /// to \p D. 116 static SourceLocation getDeclLocForCommentSearch(const Decl *D, 117 SourceManager &SourceMgr) { 118 assert(D); 119 120 // User can not attach documentation to implicit declarations. 121 if (D->isImplicit()) 122 return {}; 123 124 // User can not attach documentation to implicit instantiations. 125 if (const auto *FD = dyn_cast<FunctionDecl>(D)) { 126 if (FD->getTemplateSpecializationKind() == TSK_ImplicitInstantiation) 127 return {}; 128 } 129 130 if (const auto *VD = dyn_cast<VarDecl>(D)) { 131 if (VD->isStaticDataMember() && 132 VD->getTemplateSpecializationKind() == TSK_ImplicitInstantiation) 133 return {}; 134 } 135 136 if (const auto *CRD = dyn_cast<CXXRecordDecl>(D)) { 137 if (CRD->getTemplateSpecializationKind() == TSK_ImplicitInstantiation) 138 return {}; 139 } 140 141 if (const auto *CTSD = dyn_cast<ClassTemplateSpecializationDecl>(D)) { 142 TemplateSpecializationKind TSK = CTSD->getSpecializationKind(); 143 if (TSK == TSK_ImplicitInstantiation || 144 TSK == TSK_Undeclared) 145 return {}; 146 } 147 148 if (const auto *ED = dyn_cast<EnumDecl>(D)) { 149 if (ED->getTemplateSpecializationKind() == TSK_ImplicitInstantiation) 150 return {}; 151 } 152 if (const auto *TD = dyn_cast<TagDecl>(D)) { 153 // When tag declaration (but not definition!) is part of the 154 // decl-specifier-seq of some other declaration, it doesn't get comment 155 if (TD->isEmbeddedInDeclarator() && !TD->isCompleteDefinition()) 156 return {}; 157 } 158 // TODO: handle comments for function parameters properly. 159 if (isa<ParmVarDecl>(D)) 160 return {}; 161 162 // TODO: we could look up template parameter documentation in the template 163 // documentation. 164 if (isa<TemplateTypeParmDecl>(D) || 165 isa<NonTypeTemplateParmDecl>(D) || 166 isa<TemplateTemplateParmDecl>(D)) 167 return {}; 168 169 // Find declaration location. 170 // For Objective-C declarations we generally don't expect to have multiple 171 // declarators, thus use declaration starting location as the "declaration 172 // location". 173 // For all other declarations multiple declarators are used quite frequently, 174 // so we use the location of the identifier as the "declaration location". 175 if (isa<ObjCMethodDecl>(D) || isa<ObjCContainerDecl>(D) || 176 isa<ObjCPropertyDecl>(D) || 177 isa<RedeclarableTemplateDecl>(D) || 178 isa<ClassTemplateSpecializationDecl>(D) || 179 // Allow association with Y across {} in `typedef struct X {} Y`. 180 isa<TypedefDecl>(D)) 181 return D->getBeginLoc(); 182 183 const SourceLocation DeclLoc = D->getLocation(); 184 if (DeclLoc.isMacroID()) { 185 if (isa<TypedefDecl>(D)) { 186 // If location of the typedef name is in a macro, it is because being 187 // declared via a macro. Try using declaration's starting location as 188 // the "declaration location". 189 return D->getBeginLoc(); 190 } 191 192 if (const auto *TD = dyn_cast<TagDecl>(D)) { 193 // If location of the tag decl is inside a macro, but the spelling of 194 // the tag name comes from a macro argument, it looks like a special 195 // macro like NS_ENUM is being used to define the tag decl. In that 196 // case, adjust the source location to the expansion loc so that we can 197 // attach the comment to the tag decl. 198 if (SourceMgr.isMacroArgExpansion(DeclLoc) && TD->isCompleteDefinition()) 199 return SourceMgr.getExpansionLoc(DeclLoc); 200 } 201 } 202 203 return DeclLoc; 204 } 205 206 RawComment *ASTContext::getRawCommentForDeclNoCacheImpl( 207 const Decl *D, const SourceLocation RepresentativeLocForDecl, 208 const std::map<unsigned, RawComment *> &CommentsInTheFile) const { 209 // If the declaration doesn't map directly to a location in a file, we 210 // can't find the comment. 211 if (RepresentativeLocForDecl.isInvalid() || 212 !RepresentativeLocForDecl.isFileID()) 213 return nullptr; 214 215 // If there are no comments anywhere, we won't find anything. 216 if (CommentsInTheFile.empty()) 217 return nullptr; 218 219 // Decompose the location for the declaration and find the beginning of the 220 // file buffer. 221 const std::pair<FileID, unsigned> DeclLocDecomp = 222 SourceMgr.getDecomposedLoc(RepresentativeLocForDecl); 223 224 // Slow path. 225 auto OffsetCommentBehindDecl = 226 CommentsInTheFile.lower_bound(DeclLocDecomp.second); 227 228 // First check whether we have a trailing comment. 229 if (OffsetCommentBehindDecl != CommentsInTheFile.end()) { 230 RawComment *CommentBehindDecl = OffsetCommentBehindDecl->second; 231 if ((CommentBehindDecl->isDocumentation() || 232 LangOpts.CommentOpts.ParseAllComments) && 233 CommentBehindDecl->isTrailingComment() && 234 (isa<FieldDecl>(D) || isa<EnumConstantDecl>(D) || isa<VarDecl>(D) || 235 isa<ObjCMethodDecl>(D) || isa<ObjCPropertyDecl>(D))) { 236 237 // Check that Doxygen trailing comment comes after the declaration, starts 238 // on the same line and in the same file as the declaration. 239 if (SourceMgr.getLineNumber(DeclLocDecomp.first, DeclLocDecomp.second) == 240 Comments.getCommentBeginLine(CommentBehindDecl, DeclLocDecomp.first, 241 OffsetCommentBehindDecl->first)) { 242 return CommentBehindDecl; 243 } 244 } 245 } 246 247 // The comment just after the declaration was not a trailing comment. 248 // Let's look at the previous comment. 249 if (OffsetCommentBehindDecl == CommentsInTheFile.begin()) 250 return nullptr; 251 252 auto OffsetCommentBeforeDecl = --OffsetCommentBehindDecl; 253 RawComment *CommentBeforeDecl = OffsetCommentBeforeDecl->second; 254 255 // Check that we actually have a non-member Doxygen comment. 256 if (!(CommentBeforeDecl->isDocumentation() || 257 LangOpts.CommentOpts.ParseAllComments) || 258 CommentBeforeDecl->isTrailingComment()) 259 return nullptr; 260 261 // Decompose the end of the comment. 262 const unsigned CommentEndOffset = 263 Comments.getCommentEndOffset(CommentBeforeDecl); 264 265 // Get the corresponding buffer. 266 bool Invalid = false; 267 const char *Buffer = SourceMgr.getBufferData(DeclLocDecomp.first, 268 &Invalid).data(); 269 if (Invalid) 270 return nullptr; 271 272 // Extract text between the comment and declaration. 273 StringRef Text(Buffer + CommentEndOffset, 274 DeclLocDecomp.second - CommentEndOffset); 275 276 // There should be no other declarations or preprocessor directives between 277 // comment and declaration. 278 if (Text.find_first_of(";{}#@") != StringRef::npos) 279 return nullptr; 280 281 return CommentBeforeDecl; 282 } 283 284 RawComment *ASTContext::getRawCommentForDeclNoCache(const Decl *D) const { 285 const SourceLocation DeclLoc = getDeclLocForCommentSearch(D, SourceMgr); 286 287 // If the declaration doesn't map directly to a location in a file, we 288 // can't find the comment. 289 if (DeclLoc.isInvalid() || !DeclLoc.isFileID()) 290 return nullptr; 291 292 if (ExternalSource && !CommentsLoaded) { 293 ExternalSource->ReadComments(); 294 CommentsLoaded = true; 295 } 296 297 if (Comments.empty()) 298 return nullptr; 299 300 const FileID File = SourceMgr.getDecomposedLoc(DeclLoc).first; 301 const auto CommentsInThisFile = Comments.getCommentsInFile(File); 302 if (!CommentsInThisFile || CommentsInThisFile->empty()) 303 return nullptr; 304 305 return getRawCommentForDeclNoCacheImpl(D, DeclLoc, *CommentsInThisFile); 306 } 307 308 void ASTContext::addComment(const RawComment &RC) { 309 assert(LangOpts.RetainCommentsFromSystemHeaders || 310 !SourceMgr.isInSystemHeader(RC.getSourceRange().getBegin())); 311 Comments.addComment(RC, LangOpts.CommentOpts, BumpAlloc); 312 } 313 314 /// If we have a 'templated' declaration for a template, adjust 'D' to 315 /// refer to the actual template. 316 /// If we have an implicit instantiation, adjust 'D' to refer to template. 317 static const Decl &adjustDeclToTemplate(const Decl &D) { 318 if (const auto *FD = dyn_cast<FunctionDecl>(&D)) { 319 // Is this function declaration part of a function template? 320 if (const FunctionTemplateDecl *FTD = FD->getDescribedFunctionTemplate()) 321 return *FTD; 322 323 // Nothing to do if function is not an implicit instantiation. 324 if (FD->getTemplateSpecializationKind() != TSK_ImplicitInstantiation) 325 return D; 326 327 // Function is an implicit instantiation of a function template? 328 if (const FunctionTemplateDecl *FTD = FD->getPrimaryTemplate()) 329 return *FTD; 330 331 // Function is instantiated from a member definition of a class template? 332 if (const FunctionDecl *MemberDecl = 333 FD->getInstantiatedFromMemberFunction()) 334 return *MemberDecl; 335 336 return D; 337 } 338 if (const auto *VD = dyn_cast<VarDecl>(&D)) { 339 // Static data member is instantiated from a member definition of a class 340 // template? 341 if (VD->isStaticDataMember()) 342 if (const VarDecl *MemberDecl = VD->getInstantiatedFromStaticDataMember()) 343 return *MemberDecl; 344 345 return D; 346 } 347 if (const auto *CRD = dyn_cast<CXXRecordDecl>(&D)) { 348 // Is this class declaration part of a class template? 349 if (const ClassTemplateDecl *CTD = CRD->getDescribedClassTemplate()) 350 return *CTD; 351 352 // Class is an implicit instantiation of a class template or partial 353 // specialization? 354 if (const auto *CTSD = dyn_cast<ClassTemplateSpecializationDecl>(CRD)) { 355 if (CTSD->getSpecializationKind() != TSK_ImplicitInstantiation) 356 return D; 357 llvm::PointerUnion<ClassTemplateDecl *, 358 ClassTemplatePartialSpecializationDecl *> 359 PU = CTSD->getSpecializedTemplateOrPartial(); 360 return PU.is<ClassTemplateDecl *>() 361 ? *static_cast<const Decl *>(PU.get<ClassTemplateDecl *>()) 362 : *static_cast<const Decl *>( 363 PU.get<ClassTemplatePartialSpecializationDecl *>()); 364 } 365 366 // Class is instantiated from a member definition of a class template? 367 if (const MemberSpecializationInfo *Info = 368 CRD->getMemberSpecializationInfo()) 369 return *Info->getInstantiatedFrom(); 370 371 return D; 372 } 373 if (const auto *ED = dyn_cast<EnumDecl>(&D)) { 374 // Enum is instantiated from a member definition of a class template? 375 if (const EnumDecl *MemberDecl = ED->getInstantiatedFromMemberEnum()) 376 return *MemberDecl; 377 378 return D; 379 } 380 // FIXME: Adjust alias templates? 381 return D; 382 } 383 384 const RawComment *ASTContext::getRawCommentForAnyRedecl( 385 const Decl *D, 386 const Decl **OriginalDecl) const { 387 if (!D) { 388 if (OriginalDecl) 389 OriginalDecl = nullptr; 390 return nullptr; 391 } 392 393 D = &adjustDeclToTemplate(*D); 394 395 // Any comment directly attached to D? 396 { 397 auto DeclComment = DeclRawComments.find(D); 398 if (DeclComment != DeclRawComments.end()) { 399 if (OriginalDecl) 400 *OriginalDecl = D; 401 return DeclComment->second; 402 } 403 } 404 405 // Any comment attached to any redeclaration of D? 406 const Decl *CanonicalD = D->getCanonicalDecl(); 407 if (!CanonicalD) 408 return nullptr; 409 410 { 411 auto RedeclComment = RedeclChainComments.find(CanonicalD); 412 if (RedeclComment != RedeclChainComments.end()) { 413 if (OriginalDecl) 414 *OriginalDecl = RedeclComment->second; 415 auto CommentAtRedecl = DeclRawComments.find(RedeclComment->second); 416 assert(CommentAtRedecl != DeclRawComments.end() && 417 "This decl is supposed to have comment attached."); 418 return CommentAtRedecl->second; 419 } 420 } 421 422 // Any redeclarations of D that we haven't checked for comments yet? 423 // We can't use DenseMap::iterator directly since it'd get invalid. 424 auto LastCheckedRedecl = [this, CanonicalD]() -> const Decl * { 425 auto LookupRes = CommentlessRedeclChains.find(CanonicalD); 426 if (LookupRes != CommentlessRedeclChains.end()) 427 return LookupRes->second; 428 return nullptr; 429 }(); 430 431 for (const auto Redecl : D->redecls()) { 432 assert(Redecl); 433 // Skip all redeclarations that have been checked previously. 434 if (LastCheckedRedecl) { 435 if (LastCheckedRedecl == Redecl) { 436 LastCheckedRedecl = nullptr; 437 } 438 continue; 439 } 440 const RawComment *RedeclComment = getRawCommentForDeclNoCache(Redecl); 441 if (RedeclComment) { 442 cacheRawCommentForDecl(*Redecl, *RedeclComment); 443 if (OriginalDecl) 444 *OriginalDecl = Redecl; 445 return RedeclComment; 446 } 447 CommentlessRedeclChains[CanonicalD] = Redecl; 448 } 449 450 if (OriginalDecl) 451 *OriginalDecl = nullptr; 452 return nullptr; 453 } 454 455 void ASTContext::cacheRawCommentForDecl(const Decl &OriginalD, 456 const RawComment &Comment) const { 457 assert(Comment.isDocumentation() || LangOpts.CommentOpts.ParseAllComments); 458 DeclRawComments.try_emplace(&OriginalD, &Comment); 459 const Decl *const CanonicalDecl = OriginalD.getCanonicalDecl(); 460 RedeclChainComments.try_emplace(CanonicalDecl, &OriginalD); 461 CommentlessRedeclChains.erase(CanonicalDecl); 462 } 463 464 static void addRedeclaredMethods(const ObjCMethodDecl *ObjCMethod, 465 SmallVectorImpl<const NamedDecl *> &Redeclared) { 466 const DeclContext *DC = ObjCMethod->getDeclContext(); 467 if (const auto *IMD = dyn_cast<ObjCImplDecl>(DC)) { 468 const ObjCInterfaceDecl *ID = IMD->getClassInterface(); 469 if (!ID) 470 return; 471 // Add redeclared method here. 472 for (const auto *Ext : ID->known_extensions()) { 473 if (ObjCMethodDecl *RedeclaredMethod = 474 Ext->getMethod(ObjCMethod->getSelector(), 475 ObjCMethod->isInstanceMethod())) 476 Redeclared.push_back(RedeclaredMethod); 477 } 478 } 479 } 480 481 void ASTContext::attachCommentsToJustParsedDecls(ArrayRef<Decl *> Decls, 482 const Preprocessor *PP) { 483 if (Comments.empty() || Decls.empty()) 484 return; 485 486 FileID File; 487 for (Decl *D : Decls) { 488 SourceLocation Loc = D->getLocation(); 489 if (Loc.isValid()) { 490 // See if there are any new comments that are not attached to a decl. 491 // The location doesn't have to be precise - we care only about the file. 492 File = SourceMgr.getDecomposedLoc(Loc).first; 493 break; 494 } 495 } 496 497 if (File.isInvalid()) 498 return; 499 500 auto CommentsInThisFile = Comments.getCommentsInFile(File); 501 if (!CommentsInThisFile || CommentsInThisFile->empty() || 502 CommentsInThisFile->rbegin()->second->isAttached()) 503 return; 504 505 // There is at least one comment not attached to a decl. 506 // Maybe it should be attached to one of Decls? 507 // 508 // Note that this way we pick up not only comments that precede the 509 // declaration, but also comments that *follow* the declaration -- thanks to 510 // the lookahead in the lexer: we've consumed the semicolon and looked 511 // ahead through comments. 512 513 for (const Decl *D : Decls) { 514 assert(D); 515 if (D->isInvalidDecl()) 516 continue; 517 518 D = &adjustDeclToTemplate(*D); 519 520 const SourceLocation DeclLoc = getDeclLocForCommentSearch(D, SourceMgr); 521 522 if (DeclLoc.isInvalid() || !DeclLoc.isFileID()) 523 continue; 524 525 if (DeclRawComments.count(D) > 0) 526 continue; 527 528 if (RawComment *const DocComment = 529 getRawCommentForDeclNoCacheImpl(D, DeclLoc, *CommentsInThisFile)) { 530 cacheRawCommentForDecl(*D, *DocComment); 531 comments::FullComment *FC = DocComment->parse(*this, PP, D); 532 ParsedComments[D->getCanonicalDecl()] = FC; 533 } 534 } 535 } 536 537 comments::FullComment *ASTContext::cloneFullComment(comments::FullComment *FC, 538 const Decl *D) const { 539 auto *ThisDeclInfo = new (*this) comments::DeclInfo; 540 ThisDeclInfo->CommentDecl = D; 541 ThisDeclInfo->IsFilled = false; 542 ThisDeclInfo->fill(); 543 ThisDeclInfo->CommentDecl = FC->getDecl(); 544 if (!ThisDeclInfo->TemplateParameters) 545 ThisDeclInfo->TemplateParameters = FC->getDeclInfo()->TemplateParameters; 546 comments::FullComment *CFC = 547 new (*this) comments::FullComment(FC->getBlocks(), 548 ThisDeclInfo); 549 return CFC; 550 } 551 552 comments::FullComment *ASTContext::getLocalCommentForDeclUncached(const Decl *D) const { 553 const RawComment *RC = getRawCommentForDeclNoCache(D); 554 return RC ? RC->parse(*this, nullptr, D) : nullptr; 555 } 556 557 comments::FullComment *ASTContext::getCommentForDecl( 558 const Decl *D, 559 const Preprocessor *PP) const { 560 if (!D || D->isInvalidDecl()) 561 return nullptr; 562 D = &adjustDeclToTemplate(*D); 563 564 const Decl *Canonical = D->getCanonicalDecl(); 565 llvm::DenseMap<const Decl *, comments::FullComment *>::iterator Pos = 566 ParsedComments.find(Canonical); 567 568 if (Pos != ParsedComments.end()) { 569 if (Canonical != D) { 570 comments::FullComment *FC = Pos->second; 571 comments::FullComment *CFC = cloneFullComment(FC, D); 572 return CFC; 573 } 574 return Pos->second; 575 } 576 577 const Decl *OriginalDecl = nullptr; 578 579 const RawComment *RC = getRawCommentForAnyRedecl(D, &OriginalDecl); 580 if (!RC) { 581 if (isa<ObjCMethodDecl>(D) || isa<FunctionDecl>(D)) { 582 SmallVector<const NamedDecl*, 8> Overridden; 583 const auto *OMD = dyn_cast<ObjCMethodDecl>(D); 584 if (OMD && OMD->isPropertyAccessor()) 585 if (const ObjCPropertyDecl *PDecl = OMD->findPropertyDecl()) 586 if (comments::FullComment *FC = getCommentForDecl(PDecl, PP)) 587 return cloneFullComment(FC, D); 588 if (OMD) 589 addRedeclaredMethods(OMD, Overridden); 590 getOverriddenMethods(dyn_cast<NamedDecl>(D), Overridden); 591 for (unsigned i = 0, e = Overridden.size(); i < e; i++) 592 if (comments::FullComment *FC = getCommentForDecl(Overridden[i], PP)) 593 return cloneFullComment(FC, D); 594 } 595 else if (const auto *TD = dyn_cast<TypedefNameDecl>(D)) { 596 // Attach any tag type's documentation to its typedef if latter 597 // does not have one of its own. 598 QualType QT = TD->getUnderlyingType(); 599 if (const auto *TT = QT->getAs<TagType>()) 600 if (const Decl *TD = TT->getDecl()) 601 if (comments::FullComment *FC = getCommentForDecl(TD, PP)) 602 return cloneFullComment(FC, D); 603 } 604 else if (const auto *IC = dyn_cast<ObjCInterfaceDecl>(D)) { 605 while (IC->getSuperClass()) { 606 IC = IC->getSuperClass(); 607 if (comments::FullComment *FC = getCommentForDecl(IC, PP)) 608 return cloneFullComment(FC, D); 609 } 610 } 611 else if (const auto *CD = dyn_cast<ObjCCategoryDecl>(D)) { 612 if (const ObjCInterfaceDecl *IC = CD->getClassInterface()) 613 if (comments::FullComment *FC = getCommentForDecl(IC, PP)) 614 return cloneFullComment(FC, D); 615 } 616 else if (const auto *RD = dyn_cast<CXXRecordDecl>(D)) { 617 if (!(RD = RD->getDefinition())) 618 return nullptr; 619 // Check non-virtual bases. 620 for (const auto &I : RD->bases()) { 621 if (I.isVirtual() || (I.getAccessSpecifier() != AS_public)) 622 continue; 623 QualType Ty = I.getType(); 624 if (Ty.isNull()) 625 continue; 626 if (const CXXRecordDecl *NonVirtualBase = Ty->getAsCXXRecordDecl()) { 627 if (!(NonVirtualBase= NonVirtualBase->getDefinition())) 628 continue; 629 630 if (comments::FullComment *FC = getCommentForDecl((NonVirtualBase), PP)) 631 return cloneFullComment(FC, D); 632 } 633 } 634 // Check virtual bases. 635 for (const auto &I : RD->vbases()) { 636 if (I.getAccessSpecifier() != AS_public) 637 continue; 638 QualType Ty = I.getType(); 639 if (Ty.isNull()) 640 continue; 641 if (const CXXRecordDecl *VirtualBase = Ty->getAsCXXRecordDecl()) { 642 if (!(VirtualBase= VirtualBase->getDefinition())) 643 continue; 644 if (comments::FullComment *FC = getCommentForDecl((VirtualBase), PP)) 645 return cloneFullComment(FC, D); 646 } 647 } 648 } 649 return nullptr; 650 } 651 652 // If the RawComment was attached to other redeclaration of this Decl, we 653 // should parse the comment in context of that other Decl. This is important 654 // because comments can contain references to parameter names which can be 655 // different across redeclarations. 656 if (D != OriginalDecl && OriginalDecl) 657 return getCommentForDecl(OriginalDecl, PP); 658 659 comments::FullComment *FC = RC->parse(*this, PP, D); 660 ParsedComments[Canonical] = FC; 661 return FC; 662 } 663 664 void 665 ASTContext::CanonicalTemplateTemplateParm::Profile(llvm::FoldingSetNodeID &ID, 666 const ASTContext &C, 667 TemplateTemplateParmDecl *Parm) { 668 ID.AddInteger(Parm->getDepth()); 669 ID.AddInteger(Parm->getPosition()); 670 ID.AddBoolean(Parm->isParameterPack()); 671 672 TemplateParameterList *Params = Parm->getTemplateParameters(); 673 ID.AddInteger(Params->size()); 674 for (TemplateParameterList::const_iterator P = Params->begin(), 675 PEnd = Params->end(); 676 P != PEnd; ++P) { 677 if (const auto *TTP = dyn_cast<TemplateTypeParmDecl>(*P)) { 678 ID.AddInteger(0); 679 ID.AddBoolean(TTP->isParameterPack()); 680 const TypeConstraint *TC = TTP->getTypeConstraint(); 681 ID.AddBoolean(TC != nullptr); 682 if (TC) 683 TC->getImmediatelyDeclaredConstraint()->Profile(ID, C, 684 /*Canonical=*/true); 685 if (TTP->isExpandedParameterPack()) { 686 ID.AddBoolean(true); 687 ID.AddInteger(TTP->getNumExpansionParameters()); 688 } else 689 ID.AddBoolean(false); 690 continue; 691 } 692 693 if (const auto *NTTP = dyn_cast<NonTypeTemplateParmDecl>(*P)) { 694 ID.AddInteger(1); 695 ID.AddBoolean(NTTP->isParameterPack()); 696 ID.AddPointer(NTTP->getType().getCanonicalType().getAsOpaquePtr()); 697 if (NTTP->isExpandedParameterPack()) { 698 ID.AddBoolean(true); 699 ID.AddInteger(NTTP->getNumExpansionTypes()); 700 for (unsigned I = 0, N = NTTP->getNumExpansionTypes(); I != N; ++I) { 701 QualType T = NTTP->getExpansionType(I); 702 ID.AddPointer(T.getCanonicalType().getAsOpaquePtr()); 703 } 704 } else 705 ID.AddBoolean(false); 706 continue; 707 } 708 709 auto *TTP = cast<TemplateTemplateParmDecl>(*P); 710 ID.AddInteger(2); 711 Profile(ID, C, TTP); 712 } 713 Expr *RequiresClause = Parm->getTemplateParameters()->getRequiresClause(); 714 ID.AddBoolean(RequiresClause != nullptr); 715 if (RequiresClause) 716 RequiresClause->Profile(ID, C, /*Canonical=*/true); 717 } 718 719 static Expr * 720 canonicalizeImmediatelyDeclaredConstraint(const ASTContext &C, Expr *IDC, 721 QualType ConstrainedType) { 722 // This is a bit ugly - we need to form a new immediately-declared 723 // constraint that references the new parameter; this would ideally 724 // require semantic analysis (e.g. template<C T> struct S {}; - the 725 // converted arguments of C<T> could be an argument pack if C is 726 // declared as template<typename... T> concept C = ...). 727 // We don't have semantic analysis here so we dig deep into the 728 // ready-made constraint expr and change the thing manually. 729 ConceptSpecializationExpr *CSE; 730 if (const auto *Fold = dyn_cast<CXXFoldExpr>(IDC)) 731 CSE = cast<ConceptSpecializationExpr>(Fold->getLHS()); 732 else 733 CSE = cast<ConceptSpecializationExpr>(IDC); 734 ArrayRef<TemplateArgument> OldConverted = CSE->getTemplateArguments(); 735 SmallVector<TemplateArgument, 3> NewConverted; 736 NewConverted.reserve(OldConverted.size()); 737 if (OldConverted.front().getKind() == TemplateArgument::Pack) { 738 // The case: 739 // template<typename... T> concept C = true; 740 // template<C<int> T> struct S; -> constraint is C<{T, int}> 741 NewConverted.push_back(ConstrainedType); 742 for (auto &Arg : OldConverted.front().pack_elements().drop_front(1)) 743 NewConverted.push_back(Arg); 744 TemplateArgument NewPack(NewConverted); 745 746 NewConverted.clear(); 747 NewConverted.push_back(NewPack); 748 assert(OldConverted.size() == 1 && 749 "Template parameter pack should be the last parameter"); 750 } else { 751 assert(OldConverted.front().getKind() == TemplateArgument::Type && 752 "Unexpected first argument kind for immediately-declared " 753 "constraint"); 754 NewConverted.push_back(ConstrainedType); 755 for (auto &Arg : OldConverted.drop_front(1)) 756 NewConverted.push_back(Arg); 757 } 758 Expr *NewIDC = ConceptSpecializationExpr::Create( 759 C, CSE->getNamedConcept(), NewConverted, nullptr, 760 CSE->isInstantiationDependent(), CSE->containsUnexpandedParameterPack()); 761 762 if (auto *OrigFold = dyn_cast<CXXFoldExpr>(IDC)) 763 NewIDC = new (C) CXXFoldExpr( 764 OrigFold->getType(), /*Callee*/nullptr, SourceLocation(), NewIDC, 765 BinaryOperatorKind::BO_LAnd, SourceLocation(), /*RHS=*/nullptr, 766 SourceLocation(), /*NumExpansions=*/None); 767 return NewIDC; 768 } 769 770 TemplateTemplateParmDecl * 771 ASTContext::getCanonicalTemplateTemplateParmDecl( 772 TemplateTemplateParmDecl *TTP) const { 773 // Check if we already have a canonical template template parameter. 774 llvm::FoldingSetNodeID ID; 775 CanonicalTemplateTemplateParm::Profile(ID, *this, TTP); 776 void *InsertPos = nullptr; 777 CanonicalTemplateTemplateParm *Canonical 778 = CanonTemplateTemplateParms.FindNodeOrInsertPos(ID, InsertPos); 779 if (Canonical) 780 return Canonical->getParam(); 781 782 // Build a canonical template parameter list. 783 TemplateParameterList *Params = TTP->getTemplateParameters(); 784 SmallVector<NamedDecl *, 4> CanonParams; 785 CanonParams.reserve(Params->size()); 786 for (TemplateParameterList::const_iterator P = Params->begin(), 787 PEnd = Params->end(); 788 P != PEnd; ++P) { 789 if (const auto *TTP = dyn_cast<TemplateTypeParmDecl>(*P)) { 790 TemplateTypeParmDecl *NewTTP = TemplateTypeParmDecl::Create(*this, 791 getTranslationUnitDecl(), SourceLocation(), SourceLocation(), 792 TTP->getDepth(), TTP->getIndex(), nullptr, false, 793 TTP->isParameterPack(), TTP->hasTypeConstraint(), 794 TTP->isExpandedParameterPack() ? 795 llvm::Optional<unsigned>(TTP->getNumExpansionParameters()) : None); 796 if (const auto *TC = TTP->getTypeConstraint()) { 797 QualType ParamAsArgument(NewTTP->getTypeForDecl(), 0); 798 Expr *NewIDC = canonicalizeImmediatelyDeclaredConstraint( 799 *this, TC->getImmediatelyDeclaredConstraint(), 800 ParamAsArgument); 801 TemplateArgumentListInfo CanonArgsAsWritten; 802 if (auto *Args = TC->getTemplateArgsAsWritten()) 803 for (const auto &ArgLoc : Args->arguments()) 804 CanonArgsAsWritten.addArgument( 805 TemplateArgumentLoc(ArgLoc.getArgument(), 806 TemplateArgumentLocInfo())); 807 NewTTP->setTypeConstraint( 808 NestedNameSpecifierLoc(), 809 DeclarationNameInfo(TC->getNamedConcept()->getDeclName(), 810 SourceLocation()), /*FoundDecl=*/nullptr, 811 // Actually canonicalizing a TemplateArgumentLoc is difficult so we 812 // simply omit the ArgsAsWritten 813 TC->getNamedConcept(), /*ArgsAsWritten=*/nullptr, NewIDC); 814 } 815 CanonParams.push_back(NewTTP); 816 } else if (const auto *NTTP = dyn_cast<NonTypeTemplateParmDecl>(*P)) { 817 QualType T = getCanonicalType(NTTP->getType()); 818 TypeSourceInfo *TInfo = getTrivialTypeSourceInfo(T); 819 NonTypeTemplateParmDecl *Param; 820 if (NTTP->isExpandedParameterPack()) { 821 SmallVector<QualType, 2> ExpandedTypes; 822 SmallVector<TypeSourceInfo *, 2> ExpandedTInfos; 823 for (unsigned I = 0, N = NTTP->getNumExpansionTypes(); I != N; ++I) { 824 ExpandedTypes.push_back(getCanonicalType(NTTP->getExpansionType(I))); 825 ExpandedTInfos.push_back( 826 getTrivialTypeSourceInfo(ExpandedTypes.back())); 827 } 828 829 Param = NonTypeTemplateParmDecl::Create(*this, getTranslationUnitDecl(), 830 SourceLocation(), 831 SourceLocation(), 832 NTTP->getDepth(), 833 NTTP->getPosition(), nullptr, 834 T, 835 TInfo, 836 ExpandedTypes, 837 ExpandedTInfos); 838 } else { 839 Param = NonTypeTemplateParmDecl::Create(*this, getTranslationUnitDecl(), 840 SourceLocation(), 841 SourceLocation(), 842 NTTP->getDepth(), 843 NTTP->getPosition(), nullptr, 844 T, 845 NTTP->isParameterPack(), 846 TInfo); 847 } 848 if (AutoType *AT = T->getContainedAutoType()) { 849 if (AT->isConstrained()) { 850 Param->setPlaceholderTypeConstraint( 851 canonicalizeImmediatelyDeclaredConstraint( 852 *this, NTTP->getPlaceholderTypeConstraint(), T)); 853 } 854 } 855 CanonParams.push_back(Param); 856 857 } else 858 CanonParams.push_back(getCanonicalTemplateTemplateParmDecl( 859 cast<TemplateTemplateParmDecl>(*P))); 860 } 861 862 Expr *CanonRequiresClause = nullptr; 863 if (Expr *RequiresClause = TTP->getTemplateParameters()->getRequiresClause()) 864 CanonRequiresClause = RequiresClause; 865 866 TemplateTemplateParmDecl *CanonTTP 867 = TemplateTemplateParmDecl::Create(*this, getTranslationUnitDecl(), 868 SourceLocation(), TTP->getDepth(), 869 TTP->getPosition(), 870 TTP->isParameterPack(), 871 nullptr, 872 TemplateParameterList::Create(*this, SourceLocation(), 873 SourceLocation(), 874 CanonParams, 875 SourceLocation(), 876 CanonRequiresClause)); 877 878 // Get the new insert position for the node we care about. 879 Canonical = CanonTemplateTemplateParms.FindNodeOrInsertPos(ID, InsertPos); 880 assert(!Canonical && "Shouldn't be in the map!"); 881 (void)Canonical; 882 883 // Create the canonical template template parameter entry. 884 Canonical = new (*this) CanonicalTemplateTemplateParm(CanonTTP); 885 CanonTemplateTemplateParms.InsertNode(Canonical, InsertPos); 886 return CanonTTP; 887 } 888 889 TargetCXXABI::Kind ASTContext::getCXXABIKind() const { 890 auto Kind = getTargetInfo().getCXXABI().getKind(); 891 return getLangOpts().CXXABI.getValueOr(Kind); 892 } 893 894 CXXABI *ASTContext::createCXXABI(const TargetInfo &T) { 895 if (!LangOpts.CPlusPlus) return nullptr; 896 897 switch (getCXXABIKind()) { 898 case TargetCXXABI::AppleARM64: 899 case TargetCXXABI::Fuchsia: 900 case TargetCXXABI::GenericARM: // Same as Itanium at this level 901 case TargetCXXABI::iOS: 902 case TargetCXXABI::WatchOS: 903 case TargetCXXABI::GenericAArch64: 904 case TargetCXXABI::GenericMIPS: 905 case TargetCXXABI::GenericItanium: 906 case TargetCXXABI::WebAssembly: 907 case TargetCXXABI::XL: 908 return CreateItaniumCXXABI(*this); 909 case TargetCXXABI::Microsoft: 910 return CreateMicrosoftCXXABI(*this); 911 } 912 llvm_unreachable("Invalid CXXABI type!"); 913 } 914 915 interp::Context &ASTContext::getInterpContext() { 916 if (!InterpContext) { 917 InterpContext.reset(new interp::Context(*this)); 918 } 919 return *InterpContext.get(); 920 } 921 922 ParentMapContext &ASTContext::getParentMapContext() { 923 if (!ParentMapCtx) 924 ParentMapCtx.reset(new ParentMapContext(*this)); 925 return *ParentMapCtx.get(); 926 } 927 928 static const LangASMap *getAddressSpaceMap(const TargetInfo &T, 929 const LangOptions &LOpts) { 930 if (LOpts.FakeAddressSpaceMap) { 931 // The fake address space map must have a distinct entry for each 932 // language-specific address space. 933 static const unsigned FakeAddrSpaceMap[] = { 934 0, // Default 935 1, // opencl_global 936 3, // opencl_local 937 2, // opencl_constant 938 0, // opencl_private 939 4, // opencl_generic 940 5, // opencl_global_device 941 6, // opencl_global_host 942 7, // cuda_device 943 8, // cuda_constant 944 9, // cuda_shared 945 1, // sycl_global 946 5, // sycl_global_device 947 6, // sycl_global_host 948 3, // sycl_local 949 0, // sycl_private 950 10, // ptr32_sptr 951 11, // ptr32_uptr 952 12 // ptr64 953 }; 954 return &FakeAddrSpaceMap; 955 } else { 956 return &T.getAddressSpaceMap(); 957 } 958 } 959 960 static bool isAddrSpaceMapManglingEnabled(const TargetInfo &TI, 961 const LangOptions &LangOpts) { 962 switch (LangOpts.getAddressSpaceMapMangling()) { 963 case LangOptions::ASMM_Target: 964 return TI.useAddressSpaceMapMangling(); 965 case LangOptions::ASMM_On: 966 return true; 967 case LangOptions::ASMM_Off: 968 return false; 969 } 970 llvm_unreachable("getAddressSpaceMapMangling() doesn't cover anything."); 971 } 972 973 ASTContext::ASTContext(LangOptions &LOpts, SourceManager &SM, 974 IdentifierTable &idents, SelectorTable &sels, 975 Builtin::Context &builtins, TranslationUnitKind TUKind) 976 : ConstantArrayTypes(this_()), FunctionProtoTypes(this_()), 977 TemplateSpecializationTypes(this_()), 978 DependentTemplateSpecializationTypes(this_()), AutoTypes(this_()), 979 SubstTemplateTemplateParmPacks(this_()), 980 CanonTemplateTemplateParms(this_()), SourceMgr(SM), LangOpts(LOpts), 981 NoSanitizeL(new NoSanitizeList(LangOpts.NoSanitizeFiles, SM)), 982 XRayFilter(new XRayFunctionFilter(LangOpts.XRayAlwaysInstrumentFiles, 983 LangOpts.XRayNeverInstrumentFiles, 984 LangOpts.XRayAttrListFiles, SM)), 985 ProfList(new ProfileList(LangOpts.ProfileListFiles, SM)), 986 PrintingPolicy(LOpts), Idents(idents), Selectors(sels), 987 BuiltinInfo(builtins), TUKind(TUKind), DeclarationNames(*this), 988 Comments(SM), CommentCommandTraits(BumpAlloc, LOpts.CommentOpts), 989 CompCategories(this_()), LastSDM(nullptr, 0) { 990 addTranslationUnitDecl(); 991 } 992 993 ASTContext::~ASTContext() { 994 // Release the DenseMaps associated with DeclContext objects. 995 // FIXME: Is this the ideal solution? 996 ReleaseDeclContextMaps(); 997 998 // Call all of the deallocation functions on all of their targets. 999 for (auto &Pair : Deallocations) 1000 (Pair.first)(Pair.second); 1001 1002 // ASTRecordLayout objects in ASTRecordLayouts must always be destroyed 1003 // because they can contain DenseMaps. 1004 for (llvm::DenseMap<const ObjCContainerDecl*, 1005 const ASTRecordLayout*>::iterator 1006 I = ObjCLayouts.begin(), E = ObjCLayouts.end(); I != E; ) 1007 // Increment in loop to prevent using deallocated memory. 1008 if (auto *R = const_cast<ASTRecordLayout *>((I++)->second)) 1009 R->Destroy(*this); 1010 1011 for (llvm::DenseMap<const RecordDecl*, const ASTRecordLayout*>::iterator 1012 I = ASTRecordLayouts.begin(), E = ASTRecordLayouts.end(); I != E; ) { 1013 // Increment in loop to prevent using deallocated memory. 1014 if (auto *R = const_cast<ASTRecordLayout *>((I++)->second)) 1015 R->Destroy(*this); 1016 } 1017 1018 for (llvm::DenseMap<const Decl*, AttrVec*>::iterator A = DeclAttrs.begin(), 1019 AEnd = DeclAttrs.end(); 1020 A != AEnd; ++A) 1021 A->second->~AttrVec(); 1022 1023 for (const auto &Value : ModuleInitializers) 1024 Value.second->~PerModuleInitializers(); 1025 } 1026 1027 void ASTContext::setTraversalScope(const std::vector<Decl *> &TopLevelDecls) { 1028 TraversalScope = TopLevelDecls; 1029 getParentMapContext().clear(); 1030 } 1031 1032 void ASTContext::AddDeallocation(void (*Callback)(void *), void *Data) const { 1033 Deallocations.push_back({Callback, Data}); 1034 } 1035 1036 void 1037 ASTContext::setExternalSource(IntrusiveRefCntPtr<ExternalASTSource> Source) { 1038 ExternalSource = std::move(Source); 1039 } 1040 1041 void ASTContext::PrintStats() const { 1042 llvm::errs() << "\n*** AST Context Stats:\n"; 1043 llvm::errs() << " " << Types.size() << " types total.\n"; 1044 1045 unsigned counts[] = { 1046 #define TYPE(Name, Parent) 0, 1047 #define ABSTRACT_TYPE(Name, Parent) 1048 #include "clang/AST/TypeNodes.inc" 1049 0 // Extra 1050 }; 1051 1052 for (unsigned i = 0, e = Types.size(); i != e; ++i) { 1053 Type *T = Types[i]; 1054 counts[(unsigned)T->getTypeClass()]++; 1055 } 1056 1057 unsigned Idx = 0; 1058 unsigned TotalBytes = 0; 1059 #define TYPE(Name, Parent) \ 1060 if (counts[Idx]) \ 1061 llvm::errs() << " " << counts[Idx] << " " << #Name \ 1062 << " types, " << sizeof(Name##Type) << " each " \ 1063 << "(" << counts[Idx] * sizeof(Name##Type) \ 1064 << " bytes)\n"; \ 1065 TotalBytes += counts[Idx] * sizeof(Name##Type); \ 1066 ++Idx; 1067 #define ABSTRACT_TYPE(Name, Parent) 1068 #include "clang/AST/TypeNodes.inc" 1069 1070 llvm::errs() << "Total bytes = " << TotalBytes << "\n"; 1071 1072 // Implicit special member functions. 1073 llvm::errs() << NumImplicitDefaultConstructorsDeclared << "/" 1074 << NumImplicitDefaultConstructors 1075 << " implicit default constructors created\n"; 1076 llvm::errs() << NumImplicitCopyConstructorsDeclared << "/" 1077 << NumImplicitCopyConstructors 1078 << " implicit copy constructors created\n"; 1079 if (getLangOpts().CPlusPlus) 1080 llvm::errs() << NumImplicitMoveConstructorsDeclared << "/" 1081 << NumImplicitMoveConstructors 1082 << " implicit move constructors created\n"; 1083 llvm::errs() << NumImplicitCopyAssignmentOperatorsDeclared << "/" 1084 << NumImplicitCopyAssignmentOperators 1085 << " implicit copy assignment operators created\n"; 1086 if (getLangOpts().CPlusPlus) 1087 llvm::errs() << NumImplicitMoveAssignmentOperatorsDeclared << "/" 1088 << NumImplicitMoveAssignmentOperators 1089 << " implicit move assignment operators created\n"; 1090 llvm::errs() << NumImplicitDestructorsDeclared << "/" 1091 << NumImplicitDestructors 1092 << " implicit destructors created\n"; 1093 1094 if (ExternalSource) { 1095 llvm::errs() << "\n"; 1096 ExternalSource->PrintStats(); 1097 } 1098 1099 BumpAlloc.PrintStats(); 1100 } 1101 1102 void ASTContext::mergeDefinitionIntoModule(NamedDecl *ND, Module *M, 1103 bool NotifyListeners) { 1104 if (NotifyListeners) 1105 if (auto *Listener = getASTMutationListener()) 1106 Listener->RedefinedHiddenDefinition(ND, M); 1107 1108 MergedDefModules[cast<NamedDecl>(ND->getCanonicalDecl())].push_back(M); 1109 } 1110 1111 void ASTContext::deduplicateMergedDefinitonsFor(NamedDecl *ND) { 1112 auto It = MergedDefModules.find(cast<NamedDecl>(ND->getCanonicalDecl())); 1113 if (It == MergedDefModules.end()) 1114 return; 1115 1116 auto &Merged = It->second; 1117 llvm::DenseSet<Module*> Found; 1118 for (Module *&M : Merged) 1119 if (!Found.insert(M).second) 1120 M = nullptr; 1121 Merged.erase(std::remove(Merged.begin(), Merged.end(), nullptr), Merged.end()); 1122 } 1123 1124 ArrayRef<Module *> 1125 ASTContext::getModulesWithMergedDefinition(const NamedDecl *Def) { 1126 auto MergedIt = 1127 MergedDefModules.find(cast<NamedDecl>(Def->getCanonicalDecl())); 1128 if (MergedIt == MergedDefModules.end()) 1129 return None; 1130 return MergedIt->second; 1131 } 1132 1133 void ASTContext::PerModuleInitializers::resolve(ASTContext &Ctx) { 1134 if (LazyInitializers.empty()) 1135 return; 1136 1137 auto *Source = Ctx.getExternalSource(); 1138 assert(Source && "lazy initializers but no external source"); 1139 1140 auto LazyInits = std::move(LazyInitializers); 1141 LazyInitializers.clear(); 1142 1143 for (auto ID : LazyInits) 1144 Initializers.push_back(Source->GetExternalDecl(ID)); 1145 1146 assert(LazyInitializers.empty() && 1147 "GetExternalDecl for lazy module initializer added more inits"); 1148 } 1149 1150 void ASTContext::addModuleInitializer(Module *M, Decl *D) { 1151 // One special case: if we add a module initializer that imports another 1152 // module, and that module's only initializer is an ImportDecl, simplify. 1153 if (const auto *ID = dyn_cast<ImportDecl>(D)) { 1154 auto It = ModuleInitializers.find(ID->getImportedModule()); 1155 1156 // Maybe the ImportDecl does nothing at all. (Common case.) 1157 if (It == ModuleInitializers.end()) 1158 return; 1159 1160 // Maybe the ImportDecl only imports another ImportDecl. 1161 auto &Imported = *It->second; 1162 if (Imported.Initializers.size() + Imported.LazyInitializers.size() == 1) { 1163 Imported.resolve(*this); 1164 auto *OnlyDecl = Imported.Initializers.front(); 1165 if (isa<ImportDecl>(OnlyDecl)) 1166 D = OnlyDecl; 1167 } 1168 } 1169 1170 auto *&Inits = ModuleInitializers[M]; 1171 if (!Inits) 1172 Inits = new (*this) PerModuleInitializers; 1173 Inits->Initializers.push_back(D); 1174 } 1175 1176 void ASTContext::addLazyModuleInitializers(Module *M, ArrayRef<uint32_t> IDs) { 1177 auto *&Inits = ModuleInitializers[M]; 1178 if (!Inits) 1179 Inits = new (*this) PerModuleInitializers; 1180 Inits->LazyInitializers.insert(Inits->LazyInitializers.end(), 1181 IDs.begin(), IDs.end()); 1182 } 1183 1184 ArrayRef<Decl *> ASTContext::getModuleInitializers(Module *M) { 1185 auto It = ModuleInitializers.find(M); 1186 if (It == ModuleInitializers.end()) 1187 return None; 1188 1189 auto *Inits = It->second; 1190 Inits->resolve(*this); 1191 return Inits->Initializers; 1192 } 1193 1194 ExternCContextDecl *ASTContext::getExternCContextDecl() const { 1195 if (!ExternCContext) 1196 ExternCContext = ExternCContextDecl::Create(*this, getTranslationUnitDecl()); 1197 1198 return ExternCContext; 1199 } 1200 1201 BuiltinTemplateDecl * 1202 ASTContext::buildBuiltinTemplateDecl(BuiltinTemplateKind BTK, 1203 const IdentifierInfo *II) const { 1204 auto *BuiltinTemplate = 1205 BuiltinTemplateDecl::Create(*this, getTranslationUnitDecl(), II, BTK); 1206 BuiltinTemplate->setImplicit(); 1207 getTranslationUnitDecl()->addDecl(BuiltinTemplate); 1208 1209 return BuiltinTemplate; 1210 } 1211 1212 BuiltinTemplateDecl * 1213 ASTContext::getMakeIntegerSeqDecl() const { 1214 if (!MakeIntegerSeqDecl) 1215 MakeIntegerSeqDecl = buildBuiltinTemplateDecl(BTK__make_integer_seq, 1216 getMakeIntegerSeqName()); 1217 return MakeIntegerSeqDecl; 1218 } 1219 1220 BuiltinTemplateDecl * 1221 ASTContext::getTypePackElementDecl() const { 1222 if (!TypePackElementDecl) 1223 TypePackElementDecl = buildBuiltinTemplateDecl(BTK__type_pack_element, 1224 getTypePackElementName()); 1225 return TypePackElementDecl; 1226 } 1227 1228 RecordDecl *ASTContext::buildImplicitRecord(StringRef Name, 1229 RecordDecl::TagKind TK) const { 1230 SourceLocation Loc; 1231 RecordDecl *NewDecl; 1232 if (getLangOpts().CPlusPlus) 1233 NewDecl = CXXRecordDecl::Create(*this, TK, getTranslationUnitDecl(), Loc, 1234 Loc, &Idents.get(Name)); 1235 else 1236 NewDecl = RecordDecl::Create(*this, TK, getTranslationUnitDecl(), Loc, Loc, 1237 &Idents.get(Name)); 1238 NewDecl->setImplicit(); 1239 NewDecl->addAttr(TypeVisibilityAttr::CreateImplicit( 1240 const_cast<ASTContext &>(*this), TypeVisibilityAttr::Default)); 1241 return NewDecl; 1242 } 1243 1244 TypedefDecl *ASTContext::buildImplicitTypedef(QualType T, 1245 StringRef Name) const { 1246 TypeSourceInfo *TInfo = getTrivialTypeSourceInfo(T); 1247 TypedefDecl *NewDecl = TypedefDecl::Create( 1248 const_cast<ASTContext &>(*this), getTranslationUnitDecl(), 1249 SourceLocation(), SourceLocation(), &Idents.get(Name), TInfo); 1250 NewDecl->setImplicit(); 1251 return NewDecl; 1252 } 1253 1254 TypedefDecl *ASTContext::getInt128Decl() const { 1255 if (!Int128Decl) 1256 Int128Decl = buildImplicitTypedef(Int128Ty, "__int128_t"); 1257 return Int128Decl; 1258 } 1259 1260 TypedefDecl *ASTContext::getUInt128Decl() const { 1261 if (!UInt128Decl) 1262 UInt128Decl = buildImplicitTypedef(UnsignedInt128Ty, "__uint128_t"); 1263 return UInt128Decl; 1264 } 1265 1266 void ASTContext::InitBuiltinType(CanQualType &R, BuiltinType::Kind K) { 1267 auto *Ty = new (*this, TypeAlignment) BuiltinType(K); 1268 R = CanQualType::CreateUnsafe(QualType(Ty, 0)); 1269 Types.push_back(Ty); 1270 } 1271 1272 void ASTContext::InitBuiltinTypes(const TargetInfo &Target, 1273 const TargetInfo *AuxTarget) { 1274 assert((!this->Target || this->Target == &Target) && 1275 "Incorrect target reinitialization"); 1276 assert(VoidTy.isNull() && "Context reinitialized?"); 1277 1278 this->Target = &Target; 1279 this->AuxTarget = AuxTarget; 1280 1281 ABI.reset(createCXXABI(Target)); 1282 AddrSpaceMap = getAddressSpaceMap(Target, LangOpts); 1283 AddrSpaceMapMangling = isAddrSpaceMapManglingEnabled(Target, LangOpts); 1284 1285 // C99 6.2.5p19. 1286 InitBuiltinType(VoidTy, BuiltinType::Void); 1287 1288 // C99 6.2.5p2. 1289 InitBuiltinType(BoolTy, BuiltinType::Bool); 1290 // C99 6.2.5p3. 1291 if (LangOpts.CharIsSigned) 1292 InitBuiltinType(CharTy, BuiltinType::Char_S); 1293 else 1294 InitBuiltinType(CharTy, BuiltinType::Char_U); 1295 // C99 6.2.5p4. 1296 InitBuiltinType(SignedCharTy, BuiltinType::SChar); 1297 InitBuiltinType(ShortTy, BuiltinType::Short); 1298 InitBuiltinType(IntTy, BuiltinType::Int); 1299 InitBuiltinType(LongTy, BuiltinType::Long); 1300 InitBuiltinType(LongLongTy, BuiltinType::LongLong); 1301 1302 // C99 6.2.5p6. 1303 InitBuiltinType(UnsignedCharTy, BuiltinType::UChar); 1304 InitBuiltinType(UnsignedShortTy, BuiltinType::UShort); 1305 InitBuiltinType(UnsignedIntTy, BuiltinType::UInt); 1306 InitBuiltinType(UnsignedLongTy, BuiltinType::ULong); 1307 InitBuiltinType(UnsignedLongLongTy, BuiltinType::ULongLong); 1308 1309 // C99 6.2.5p10. 1310 InitBuiltinType(FloatTy, BuiltinType::Float); 1311 InitBuiltinType(DoubleTy, BuiltinType::Double); 1312 InitBuiltinType(LongDoubleTy, BuiltinType::LongDouble); 1313 1314 // GNU extension, __float128 for IEEE quadruple precision 1315 InitBuiltinType(Float128Ty, BuiltinType::Float128); 1316 1317 // __ibm128 for IBM extended precision 1318 InitBuiltinType(Ibm128Ty, BuiltinType::Ibm128); 1319 1320 // C11 extension ISO/IEC TS 18661-3 1321 InitBuiltinType(Float16Ty, BuiltinType::Float16); 1322 1323 // ISO/IEC JTC1 SC22 WG14 N1169 Extension 1324 InitBuiltinType(ShortAccumTy, BuiltinType::ShortAccum); 1325 InitBuiltinType(AccumTy, BuiltinType::Accum); 1326 InitBuiltinType(LongAccumTy, BuiltinType::LongAccum); 1327 InitBuiltinType(UnsignedShortAccumTy, BuiltinType::UShortAccum); 1328 InitBuiltinType(UnsignedAccumTy, BuiltinType::UAccum); 1329 InitBuiltinType(UnsignedLongAccumTy, BuiltinType::ULongAccum); 1330 InitBuiltinType(ShortFractTy, BuiltinType::ShortFract); 1331 InitBuiltinType(FractTy, BuiltinType::Fract); 1332 InitBuiltinType(LongFractTy, BuiltinType::LongFract); 1333 InitBuiltinType(UnsignedShortFractTy, BuiltinType::UShortFract); 1334 InitBuiltinType(UnsignedFractTy, BuiltinType::UFract); 1335 InitBuiltinType(UnsignedLongFractTy, BuiltinType::ULongFract); 1336 InitBuiltinType(SatShortAccumTy, BuiltinType::SatShortAccum); 1337 InitBuiltinType(SatAccumTy, BuiltinType::SatAccum); 1338 InitBuiltinType(SatLongAccumTy, BuiltinType::SatLongAccum); 1339 InitBuiltinType(SatUnsignedShortAccumTy, BuiltinType::SatUShortAccum); 1340 InitBuiltinType(SatUnsignedAccumTy, BuiltinType::SatUAccum); 1341 InitBuiltinType(SatUnsignedLongAccumTy, BuiltinType::SatULongAccum); 1342 InitBuiltinType(SatShortFractTy, BuiltinType::SatShortFract); 1343 InitBuiltinType(SatFractTy, BuiltinType::SatFract); 1344 InitBuiltinType(SatLongFractTy, BuiltinType::SatLongFract); 1345 InitBuiltinType(SatUnsignedShortFractTy, BuiltinType::SatUShortFract); 1346 InitBuiltinType(SatUnsignedFractTy, BuiltinType::SatUFract); 1347 InitBuiltinType(SatUnsignedLongFractTy, BuiltinType::SatULongFract); 1348 1349 // GNU extension, 128-bit integers. 1350 InitBuiltinType(Int128Ty, BuiltinType::Int128); 1351 InitBuiltinType(UnsignedInt128Ty, BuiltinType::UInt128); 1352 1353 // C++ 3.9.1p5 1354 if (TargetInfo::isTypeSigned(Target.getWCharType())) 1355 InitBuiltinType(WCharTy, BuiltinType::WChar_S); 1356 else // -fshort-wchar makes wchar_t be unsigned. 1357 InitBuiltinType(WCharTy, BuiltinType::WChar_U); 1358 if (LangOpts.CPlusPlus && LangOpts.WChar) 1359 WideCharTy = WCharTy; 1360 else { 1361 // C99 (or C++ using -fno-wchar). 1362 WideCharTy = getFromTargetType(Target.getWCharType()); 1363 } 1364 1365 WIntTy = getFromTargetType(Target.getWIntType()); 1366 1367 // C++20 (proposed) 1368 InitBuiltinType(Char8Ty, BuiltinType::Char8); 1369 1370 if (LangOpts.CPlusPlus) // C++0x 3.9.1p5, extension for C++ 1371 InitBuiltinType(Char16Ty, BuiltinType::Char16); 1372 else // C99 1373 Char16Ty = getFromTargetType(Target.getChar16Type()); 1374 1375 if (LangOpts.CPlusPlus) // C++0x 3.9.1p5, extension for C++ 1376 InitBuiltinType(Char32Ty, BuiltinType::Char32); 1377 else // C99 1378 Char32Ty = getFromTargetType(Target.getChar32Type()); 1379 1380 // Placeholder type for type-dependent expressions whose type is 1381 // completely unknown. No code should ever check a type against 1382 // DependentTy and users should never see it; however, it is here to 1383 // help diagnose failures to properly check for type-dependent 1384 // expressions. 1385 InitBuiltinType(DependentTy, BuiltinType::Dependent); 1386 1387 // Placeholder type for functions. 1388 InitBuiltinType(OverloadTy, BuiltinType::Overload); 1389 1390 // Placeholder type for bound members. 1391 InitBuiltinType(BoundMemberTy, BuiltinType::BoundMember); 1392 1393 // Placeholder type for pseudo-objects. 1394 InitBuiltinType(PseudoObjectTy, BuiltinType::PseudoObject); 1395 1396 // "any" type; useful for debugger-like clients. 1397 InitBuiltinType(UnknownAnyTy, BuiltinType::UnknownAny); 1398 1399 // Placeholder type for unbridged ARC casts. 1400 InitBuiltinType(ARCUnbridgedCastTy, BuiltinType::ARCUnbridgedCast); 1401 1402 // Placeholder type for builtin functions. 1403 InitBuiltinType(BuiltinFnTy, BuiltinType::BuiltinFn); 1404 1405 // Placeholder type for OMP array sections. 1406 if (LangOpts.OpenMP) { 1407 InitBuiltinType(OMPArraySectionTy, BuiltinType::OMPArraySection); 1408 InitBuiltinType(OMPArrayShapingTy, BuiltinType::OMPArrayShaping); 1409 InitBuiltinType(OMPIteratorTy, BuiltinType::OMPIterator); 1410 } 1411 if (LangOpts.MatrixTypes) 1412 InitBuiltinType(IncompleteMatrixIdxTy, BuiltinType::IncompleteMatrixIdx); 1413 1414 // Builtin types for 'id', 'Class', and 'SEL'. 1415 InitBuiltinType(ObjCBuiltinIdTy, BuiltinType::ObjCId); 1416 InitBuiltinType(ObjCBuiltinClassTy, BuiltinType::ObjCClass); 1417 InitBuiltinType(ObjCBuiltinSelTy, BuiltinType::ObjCSel); 1418 1419 if (LangOpts.OpenCL) { 1420 #define IMAGE_TYPE(ImgType, Id, SingletonId, Access, Suffix) \ 1421 InitBuiltinType(SingletonId, BuiltinType::Id); 1422 #include "clang/Basic/OpenCLImageTypes.def" 1423 1424 InitBuiltinType(OCLSamplerTy, BuiltinType::OCLSampler); 1425 InitBuiltinType(OCLEventTy, BuiltinType::OCLEvent); 1426 InitBuiltinType(OCLClkEventTy, BuiltinType::OCLClkEvent); 1427 InitBuiltinType(OCLQueueTy, BuiltinType::OCLQueue); 1428 InitBuiltinType(OCLReserveIDTy, BuiltinType::OCLReserveID); 1429 1430 #define EXT_OPAQUE_TYPE(ExtType, Id, Ext) \ 1431 InitBuiltinType(Id##Ty, BuiltinType::Id); 1432 #include "clang/Basic/OpenCLExtensionTypes.def" 1433 } 1434 1435 if (Target.hasAArch64SVETypes()) { 1436 #define SVE_TYPE(Name, Id, SingletonId) \ 1437 InitBuiltinType(SingletonId, BuiltinType::Id); 1438 #include "clang/Basic/AArch64SVEACLETypes.def" 1439 } 1440 1441 if (Target.getTriple().isPPC64()) { 1442 #define PPC_VECTOR_MMA_TYPE(Name, Id, Size) \ 1443 InitBuiltinType(Id##Ty, BuiltinType::Id); 1444 #include "clang/Basic/PPCTypes.def" 1445 #define PPC_VECTOR_VSX_TYPE(Name, Id, Size) \ 1446 InitBuiltinType(Id##Ty, BuiltinType::Id); 1447 #include "clang/Basic/PPCTypes.def" 1448 } 1449 1450 if (Target.hasRISCVVTypes()) { 1451 #define RVV_TYPE(Name, Id, SingletonId) \ 1452 InitBuiltinType(SingletonId, BuiltinType::Id); 1453 #include "clang/Basic/RISCVVTypes.def" 1454 } 1455 1456 // Builtin type for __objc_yes and __objc_no 1457 ObjCBuiltinBoolTy = (Target.useSignedCharForObjCBool() ? 1458 SignedCharTy : BoolTy); 1459 1460 ObjCConstantStringType = QualType(); 1461 1462 ObjCSuperType = QualType(); 1463 1464 // void * type 1465 if (LangOpts.OpenCLGenericAddressSpace) { 1466 auto Q = VoidTy.getQualifiers(); 1467 Q.setAddressSpace(LangAS::opencl_generic); 1468 VoidPtrTy = getPointerType(getCanonicalType( 1469 getQualifiedType(VoidTy.getUnqualifiedType(), Q))); 1470 } else { 1471 VoidPtrTy = getPointerType(VoidTy); 1472 } 1473 1474 // nullptr type (C++0x 2.14.7) 1475 InitBuiltinType(NullPtrTy, BuiltinType::NullPtr); 1476 1477 // half type (OpenCL 6.1.1.1) / ARM NEON __fp16 1478 InitBuiltinType(HalfTy, BuiltinType::Half); 1479 1480 InitBuiltinType(BFloat16Ty, BuiltinType::BFloat16); 1481 1482 // Builtin type used to help define __builtin_va_list. 1483 VaListTagDecl = nullptr; 1484 1485 // MSVC predeclares struct _GUID, and we need it to create MSGuidDecls. 1486 if (LangOpts.MicrosoftExt || LangOpts.Borland) { 1487 MSGuidTagDecl = buildImplicitRecord("_GUID"); 1488 getTranslationUnitDecl()->addDecl(MSGuidTagDecl); 1489 } 1490 } 1491 1492 DiagnosticsEngine &ASTContext::getDiagnostics() const { 1493 return SourceMgr.getDiagnostics(); 1494 } 1495 1496 AttrVec& ASTContext::getDeclAttrs(const Decl *D) { 1497 AttrVec *&Result = DeclAttrs[D]; 1498 if (!Result) { 1499 void *Mem = Allocate(sizeof(AttrVec)); 1500 Result = new (Mem) AttrVec; 1501 } 1502 1503 return *Result; 1504 } 1505 1506 /// Erase the attributes corresponding to the given declaration. 1507 void ASTContext::eraseDeclAttrs(const Decl *D) { 1508 llvm::DenseMap<const Decl*, AttrVec*>::iterator Pos = DeclAttrs.find(D); 1509 if (Pos != DeclAttrs.end()) { 1510 Pos->second->~AttrVec(); 1511 DeclAttrs.erase(Pos); 1512 } 1513 } 1514 1515 // FIXME: Remove ? 1516 MemberSpecializationInfo * 1517 ASTContext::getInstantiatedFromStaticDataMember(const VarDecl *Var) { 1518 assert(Var->isStaticDataMember() && "Not a static data member"); 1519 return getTemplateOrSpecializationInfo(Var) 1520 .dyn_cast<MemberSpecializationInfo *>(); 1521 } 1522 1523 ASTContext::TemplateOrSpecializationInfo 1524 ASTContext::getTemplateOrSpecializationInfo(const VarDecl *Var) { 1525 llvm::DenseMap<const VarDecl *, TemplateOrSpecializationInfo>::iterator Pos = 1526 TemplateOrInstantiation.find(Var); 1527 if (Pos == TemplateOrInstantiation.end()) 1528 return {}; 1529 1530 return Pos->second; 1531 } 1532 1533 void 1534 ASTContext::setInstantiatedFromStaticDataMember(VarDecl *Inst, VarDecl *Tmpl, 1535 TemplateSpecializationKind TSK, 1536 SourceLocation PointOfInstantiation) { 1537 assert(Inst->isStaticDataMember() && "Not a static data member"); 1538 assert(Tmpl->isStaticDataMember() && "Not a static data member"); 1539 setTemplateOrSpecializationInfo(Inst, new (*this) MemberSpecializationInfo( 1540 Tmpl, TSK, PointOfInstantiation)); 1541 } 1542 1543 void 1544 ASTContext::setTemplateOrSpecializationInfo(VarDecl *Inst, 1545 TemplateOrSpecializationInfo TSI) { 1546 assert(!TemplateOrInstantiation[Inst] && 1547 "Already noted what the variable was instantiated from"); 1548 TemplateOrInstantiation[Inst] = TSI; 1549 } 1550 1551 NamedDecl * 1552 ASTContext::getInstantiatedFromUsingDecl(NamedDecl *UUD) { 1553 auto Pos = InstantiatedFromUsingDecl.find(UUD); 1554 if (Pos == InstantiatedFromUsingDecl.end()) 1555 return nullptr; 1556 1557 return Pos->second; 1558 } 1559 1560 void 1561 ASTContext::setInstantiatedFromUsingDecl(NamedDecl *Inst, NamedDecl *Pattern) { 1562 assert((isa<UsingDecl>(Pattern) || 1563 isa<UnresolvedUsingValueDecl>(Pattern) || 1564 isa<UnresolvedUsingTypenameDecl>(Pattern)) && 1565 "pattern decl is not a using decl"); 1566 assert((isa<UsingDecl>(Inst) || 1567 isa<UnresolvedUsingValueDecl>(Inst) || 1568 isa<UnresolvedUsingTypenameDecl>(Inst)) && 1569 "instantiation did not produce a using decl"); 1570 assert(!InstantiatedFromUsingDecl[Inst] && "pattern already exists"); 1571 InstantiatedFromUsingDecl[Inst] = Pattern; 1572 } 1573 1574 UsingEnumDecl * 1575 ASTContext::getInstantiatedFromUsingEnumDecl(UsingEnumDecl *UUD) { 1576 auto Pos = InstantiatedFromUsingEnumDecl.find(UUD); 1577 if (Pos == InstantiatedFromUsingEnumDecl.end()) 1578 return nullptr; 1579 1580 return Pos->second; 1581 } 1582 1583 void ASTContext::setInstantiatedFromUsingEnumDecl(UsingEnumDecl *Inst, 1584 UsingEnumDecl *Pattern) { 1585 assert(!InstantiatedFromUsingEnumDecl[Inst] && "pattern already exists"); 1586 InstantiatedFromUsingEnumDecl[Inst] = Pattern; 1587 } 1588 1589 UsingShadowDecl * 1590 ASTContext::getInstantiatedFromUsingShadowDecl(UsingShadowDecl *Inst) { 1591 llvm::DenseMap<UsingShadowDecl*, UsingShadowDecl*>::const_iterator Pos 1592 = InstantiatedFromUsingShadowDecl.find(Inst); 1593 if (Pos == InstantiatedFromUsingShadowDecl.end()) 1594 return nullptr; 1595 1596 return Pos->second; 1597 } 1598 1599 void 1600 ASTContext::setInstantiatedFromUsingShadowDecl(UsingShadowDecl *Inst, 1601 UsingShadowDecl *Pattern) { 1602 assert(!InstantiatedFromUsingShadowDecl[Inst] && "pattern already exists"); 1603 InstantiatedFromUsingShadowDecl[Inst] = Pattern; 1604 } 1605 1606 FieldDecl *ASTContext::getInstantiatedFromUnnamedFieldDecl(FieldDecl *Field) { 1607 llvm::DenseMap<FieldDecl *, FieldDecl *>::iterator Pos 1608 = InstantiatedFromUnnamedFieldDecl.find(Field); 1609 if (Pos == InstantiatedFromUnnamedFieldDecl.end()) 1610 return nullptr; 1611 1612 return Pos->second; 1613 } 1614 1615 void ASTContext::setInstantiatedFromUnnamedFieldDecl(FieldDecl *Inst, 1616 FieldDecl *Tmpl) { 1617 assert(!Inst->getDeclName() && "Instantiated field decl is not unnamed"); 1618 assert(!Tmpl->getDeclName() && "Template field decl is not unnamed"); 1619 assert(!InstantiatedFromUnnamedFieldDecl[Inst] && 1620 "Already noted what unnamed field was instantiated from"); 1621 1622 InstantiatedFromUnnamedFieldDecl[Inst] = Tmpl; 1623 } 1624 1625 ASTContext::overridden_cxx_method_iterator 1626 ASTContext::overridden_methods_begin(const CXXMethodDecl *Method) const { 1627 return overridden_methods(Method).begin(); 1628 } 1629 1630 ASTContext::overridden_cxx_method_iterator 1631 ASTContext::overridden_methods_end(const CXXMethodDecl *Method) const { 1632 return overridden_methods(Method).end(); 1633 } 1634 1635 unsigned 1636 ASTContext::overridden_methods_size(const CXXMethodDecl *Method) const { 1637 auto Range = overridden_methods(Method); 1638 return Range.end() - Range.begin(); 1639 } 1640 1641 ASTContext::overridden_method_range 1642 ASTContext::overridden_methods(const CXXMethodDecl *Method) const { 1643 llvm::DenseMap<const CXXMethodDecl *, CXXMethodVector>::const_iterator Pos = 1644 OverriddenMethods.find(Method->getCanonicalDecl()); 1645 if (Pos == OverriddenMethods.end()) 1646 return overridden_method_range(nullptr, nullptr); 1647 return overridden_method_range(Pos->second.begin(), Pos->second.end()); 1648 } 1649 1650 void ASTContext::addOverriddenMethod(const CXXMethodDecl *Method, 1651 const CXXMethodDecl *Overridden) { 1652 assert(Method->isCanonicalDecl() && Overridden->isCanonicalDecl()); 1653 OverriddenMethods[Method].push_back(Overridden); 1654 } 1655 1656 void ASTContext::getOverriddenMethods( 1657 const NamedDecl *D, 1658 SmallVectorImpl<const NamedDecl *> &Overridden) const { 1659 assert(D); 1660 1661 if (const auto *CXXMethod = dyn_cast<CXXMethodDecl>(D)) { 1662 Overridden.append(overridden_methods_begin(CXXMethod), 1663 overridden_methods_end(CXXMethod)); 1664 return; 1665 } 1666 1667 const auto *Method = dyn_cast<ObjCMethodDecl>(D); 1668 if (!Method) 1669 return; 1670 1671 SmallVector<const ObjCMethodDecl *, 8> OverDecls; 1672 Method->getOverriddenMethods(OverDecls); 1673 Overridden.append(OverDecls.begin(), OverDecls.end()); 1674 } 1675 1676 void ASTContext::addedLocalImportDecl(ImportDecl *Import) { 1677 assert(!Import->getNextLocalImport() && 1678 "Import declaration already in the chain"); 1679 assert(!Import->isFromASTFile() && "Non-local import declaration"); 1680 if (!FirstLocalImport) { 1681 FirstLocalImport = Import; 1682 LastLocalImport = Import; 1683 return; 1684 } 1685 1686 LastLocalImport->setNextLocalImport(Import); 1687 LastLocalImport = Import; 1688 } 1689 1690 //===----------------------------------------------------------------------===// 1691 // Type Sizing and Analysis 1692 //===----------------------------------------------------------------------===// 1693 1694 /// getFloatTypeSemantics - Return the APFloat 'semantics' for the specified 1695 /// scalar floating point type. 1696 const llvm::fltSemantics &ASTContext::getFloatTypeSemantics(QualType T) const { 1697 switch (T->castAs<BuiltinType>()->getKind()) { 1698 default: 1699 llvm_unreachable("Not a floating point type!"); 1700 case BuiltinType::BFloat16: 1701 return Target->getBFloat16Format(); 1702 case BuiltinType::Float16: 1703 case BuiltinType::Half: 1704 return Target->getHalfFormat(); 1705 case BuiltinType::Float: return Target->getFloatFormat(); 1706 case BuiltinType::Double: return Target->getDoubleFormat(); 1707 case BuiltinType::Ibm128: 1708 return Target->getIbm128Format(); 1709 case BuiltinType::LongDouble: 1710 if (getLangOpts().OpenMP && getLangOpts().OpenMPIsDevice) 1711 return AuxTarget->getLongDoubleFormat(); 1712 return Target->getLongDoubleFormat(); 1713 case BuiltinType::Float128: 1714 if (getLangOpts().OpenMP && getLangOpts().OpenMPIsDevice) 1715 return AuxTarget->getFloat128Format(); 1716 return Target->getFloat128Format(); 1717 } 1718 } 1719 1720 CharUnits ASTContext::getDeclAlign(const Decl *D, bool ForAlignof) const { 1721 unsigned Align = Target->getCharWidth(); 1722 1723 bool UseAlignAttrOnly = false; 1724 if (unsigned AlignFromAttr = D->getMaxAlignment()) { 1725 Align = AlignFromAttr; 1726 1727 // __attribute__((aligned)) can increase or decrease alignment 1728 // *except* on a struct or struct member, where it only increases 1729 // alignment unless 'packed' is also specified. 1730 // 1731 // It is an error for alignas to decrease alignment, so we can 1732 // ignore that possibility; Sema should diagnose it. 1733 if (isa<FieldDecl>(D)) { 1734 UseAlignAttrOnly = D->hasAttr<PackedAttr>() || 1735 cast<FieldDecl>(D)->getParent()->hasAttr<PackedAttr>(); 1736 } else { 1737 UseAlignAttrOnly = true; 1738 } 1739 } 1740 else if (isa<FieldDecl>(D)) 1741 UseAlignAttrOnly = 1742 D->hasAttr<PackedAttr>() || 1743 cast<FieldDecl>(D)->getParent()->hasAttr<PackedAttr>(); 1744 1745 // If we're using the align attribute only, just ignore everything 1746 // else about the declaration and its type. 1747 if (UseAlignAttrOnly) { 1748 // do nothing 1749 } else if (const auto *VD = dyn_cast<ValueDecl>(D)) { 1750 QualType T = VD->getType(); 1751 if (const auto *RT = T->getAs<ReferenceType>()) { 1752 if (ForAlignof) 1753 T = RT->getPointeeType(); 1754 else 1755 T = getPointerType(RT->getPointeeType()); 1756 } 1757 QualType BaseT = getBaseElementType(T); 1758 if (T->isFunctionType()) 1759 Align = getTypeInfoImpl(T.getTypePtr()).Align; 1760 else if (!BaseT->isIncompleteType()) { 1761 // Adjust alignments of declarations with array type by the 1762 // large-array alignment on the target. 1763 if (const ArrayType *arrayType = getAsArrayType(T)) { 1764 unsigned MinWidth = Target->getLargeArrayMinWidth(); 1765 if (!ForAlignof && MinWidth) { 1766 if (isa<VariableArrayType>(arrayType)) 1767 Align = std::max(Align, Target->getLargeArrayAlign()); 1768 else if (isa<ConstantArrayType>(arrayType) && 1769 MinWidth <= getTypeSize(cast<ConstantArrayType>(arrayType))) 1770 Align = std::max(Align, Target->getLargeArrayAlign()); 1771 } 1772 } 1773 Align = std::max(Align, getPreferredTypeAlign(T.getTypePtr())); 1774 if (BaseT.getQualifiers().hasUnaligned()) 1775 Align = Target->getCharWidth(); 1776 if (const auto *VD = dyn_cast<VarDecl>(D)) { 1777 if (VD->hasGlobalStorage() && !ForAlignof) { 1778 uint64_t TypeSize = getTypeSize(T.getTypePtr()); 1779 Align = std::max(Align, getTargetInfo().getMinGlobalAlign(TypeSize)); 1780 } 1781 } 1782 } 1783 1784 // Fields can be subject to extra alignment constraints, like if 1785 // the field is packed, the struct is packed, or the struct has a 1786 // a max-field-alignment constraint (#pragma pack). So calculate 1787 // the actual alignment of the field within the struct, and then 1788 // (as we're expected to) constrain that by the alignment of the type. 1789 if (const auto *Field = dyn_cast<FieldDecl>(VD)) { 1790 const RecordDecl *Parent = Field->getParent(); 1791 // We can only produce a sensible answer if the record is valid. 1792 if (!Parent->isInvalidDecl()) { 1793 const ASTRecordLayout &Layout = getASTRecordLayout(Parent); 1794 1795 // Start with the record's overall alignment. 1796 unsigned FieldAlign = toBits(Layout.getAlignment()); 1797 1798 // Use the GCD of that and the offset within the record. 1799 uint64_t Offset = Layout.getFieldOffset(Field->getFieldIndex()); 1800 if (Offset > 0) { 1801 // Alignment is always a power of 2, so the GCD will be a power of 2, 1802 // which means we get to do this crazy thing instead of Euclid's. 1803 uint64_t LowBitOfOffset = Offset & (~Offset + 1); 1804 if (LowBitOfOffset < FieldAlign) 1805 FieldAlign = static_cast<unsigned>(LowBitOfOffset); 1806 } 1807 1808 Align = std::min(Align, FieldAlign); 1809 } 1810 } 1811 } 1812 1813 // Some targets have hard limitation on the maximum requestable alignment in 1814 // aligned attribute for static variables. 1815 const unsigned MaxAlignedAttr = getTargetInfo().getMaxAlignedAttribute(); 1816 const auto *VD = dyn_cast<VarDecl>(D); 1817 if (MaxAlignedAttr && VD && VD->getStorageClass() == SC_Static) 1818 Align = std::min(Align, MaxAlignedAttr); 1819 1820 return toCharUnitsFromBits(Align); 1821 } 1822 1823 CharUnits ASTContext::getExnObjectAlignment() const { 1824 return toCharUnitsFromBits(Target->getExnObjectAlignment()); 1825 } 1826 1827 // getTypeInfoDataSizeInChars - Return the size of a type, in 1828 // chars. If the type is a record, its data size is returned. This is 1829 // the size of the memcpy that's performed when assigning this type 1830 // using a trivial copy/move assignment operator. 1831 TypeInfoChars ASTContext::getTypeInfoDataSizeInChars(QualType T) const { 1832 TypeInfoChars Info = getTypeInfoInChars(T); 1833 1834 // In C++, objects can sometimes be allocated into the tail padding 1835 // of a base-class subobject. We decide whether that's possible 1836 // during class layout, so here we can just trust the layout results. 1837 if (getLangOpts().CPlusPlus) { 1838 if (const auto *RT = T->getAs<RecordType>()) { 1839 const ASTRecordLayout &layout = getASTRecordLayout(RT->getDecl()); 1840 Info.Width = layout.getDataSize(); 1841 } 1842 } 1843 1844 return Info; 1845 } 1846 1847 /// getConstantArrayInfoInChars - Performing the computation in CharUnits 1848 /// instead of in bits prevents overflowing the uint64_t for some large arrays. 1849 TypeInfoChars 1850 static getConstantArrayInfoInChars(const ASTContext &Context, 1851 const ConstantArrayType *CAT) { 1852 TypeInfoChars EltInfo = Context.getTypeInfoInChars(CAT->getElementType()); 1853 uint64_t Size = CAT->getSize().getZExtValue(); 1854 assert((Size == 0 || static_cast<uint64_t>(EltInfo.Width.getQuantity()) <= 1855 (uint64_t)(-1)/Size) && 1856 "Overflow in array type char size evaluation"); 1857 uint64_t Width = EltInfo.Width.getQuantity() * Size; 1858 unsigned Align = EltInfo.Align.getQuantity(); 1859 if (!Context.getTargetInfo().getCXXABI().isMicrosoft() || 1860 Context.getTargetInfo().getPointerWidth(0) == 64) 1861 Width = llvm::alignTo(Width, Align); 1862 return TypeInfoChars(CharUnits::fromQuantity(Width), 1863 CharUnits::fromQuantity(Align), 1864 EltInfo.AlignRequirement); 1865 } 1866 1867 TypeInfoChars ASTContext::getTypeInfoInChars(const Type *T) const { 1868 if (const auto *CAT = dyn_cast<ConstantArrayType>(T)) 1869 return getConstantArrayInfoInChars(*this, CAT); 1870 TypeInfo Info = getTypeInfo(T); 1871 return TypeInfoChars(toCharUnitsFromBits(Info.Width), 1872 toCharUnitsFromBits(Info.Align), Info.AlignRequirement); 1873 } 1874 1875 TypeInfoChars ASTContext::getTypeInfoInChars(QualType T) const { 1876 return getTypeInfoInChars(T.getTypePtr()); 1877 } 1878 1879 bool ASTContext::isAlignmentRequired(const Type *T) const { 1880 return getTypeInfo(T).AlignRequirement != AlignRequirementKind::None; 1881 } 1882 1883 bool ASTContext::isAlignmentRequired(QualType T) const { 1884 return isAlignmentRequired(T.getTypePtr()); 1885 } 1886 1887 unsigned ASTContext::getTypeAlignIfKnown(QualType T, 1888 bool NeedsPreferredAlignment) const { 1889 // An alignment on a typedef overrides anything else. 1890 if (const auto *TT = T->getAs<TypedefType>()) 1891 if (unsigned Align = TT->getDecl()->getMaxAlignment()) 1892 return Align; 1893 1894 // If we have an (array of) complete type, we're done. 1895 T = getBaseElementType(T); 1896 if (!T->isIncompleteType()) 1897 return NeedsPreferredAlignment ? getPreferredTypeAlign(T) : getTypeAlign(T); 1898 1899 // If we had an array type, its element type might be a typedef 1900 // type with an alignment attribute. 1901 if (const auto *TT = T->getAs<TypedefType>()) 1902 if (unsigned Align = TT->getDecl()->getMaxAlignment()) 1903 return Align; 1904 1905 // Otherwise, see if the declaration of the type had an attribute. 1906 if (const auto *TT = T->getAs<TagType>()) 1907 return TT->getDecl()->getMaxAlignment(); 1908 1909 return 0; 1910 } 1911 1912 TypeInfo ASTContext::getTypeInfo(const Type *T) const { 1913 TypeInfoMap::iterator I = MemoizedTypeInfo.find(T); 1914 if (I != MemoizedTypeInfo.end()) 1915 return I->second; 1916 1917 // This call can invalidate MemoizedTypeInfo[T], so we need a second lookup. 1918 TypeInfo TI = getTypeInfoImpl(T); 1919 MemoizedTypeInfo[T] = TI; 1920 return TI; 1921 } 1922 1923 /// getTypeInfoImpl - Return the size of the specified type, in bits. This 1924 /// method does not work on incomplete types. 1925 /// 1926 /// FIXME: Pointers into different addr spaces could have different sizes and 1927 /// alignment requirements: getPointerInfo should take an AddrSpace, this 1928 /// should take a QualType, &c. 1929 TypeInfo ASTContext::getTypeInfoImpl(const Type *T) const { 1930 uint64_t Width = 0; 1931 unsigned Align = 8; 1932 AlignRequirementKind AlignRequirement = AlignRequirementKind::None; 1933 unsigned AS = 0; 1934 switch (T->getTypeClass()) { 1935 #define TYPE(Class, Base) 1936 #define ABSTRACT_TYPE(Class, Base) 1937 #define NON_CANONICAL_TYPE(Class, Base) 1938 #define DEPENDENT_TYPE(Class, Base) case Type::Class: 1939 #define NON_CANONICAL_UNLESS_DEPENDENT_TYPE(Class, Base) \ 1940 case Type::Class: \ 1941 assert(!T->isDependentType() && "should not see dependent types here"); \ 1942 return getTypeInfo(cast<Class##Type>(T)->desugar().getTypePtr()); 1943 #include "clang/AST/TypeNodes.inc" 1944 llvm_unreachable("Should not see dependent types"); 1945 1946 case Type::FunctionNoProto: 1947 case Type::FunctionProto: 1948 // GCC extension: alignof(function) = 32 bits 1949 Width = 0; 1950 Align = 32; 1951 break; 1952 1953 case Type::IncompleteArray: 1954 case Type::VariableArray: 1955 case Type::ConstantArray: { 1956 // Model non-constant sized arrays as size zero, but track the alignment. 1957 uint64_t Size = 0; 1958 if (const auto *CAT = dyn_cast<ConstantArrayType>(T)) 1959 Size = CAT->getSize().getZExtValue(); 1960 1961 TypeInfo EltInfo = getTypeInfo(cast<ArrayType>(T)->getElementType()); 1962 assert((Size == 0 || EltInfo.Width <= (uint64_t)(-1) / Size) && 1963 "Overflow in array type bit size evaluation"); 1964 Width = EltInfo.Width * Size; 1965 Align = EltInfo.Align; 1966 AlignRequirement = EltInfo.AlignRequirement; 1967 if (!getTargetInfo().getCXXABI().isMicrosoft() || 1968 getTargetInfo().getPointerWidth(0) == 64) 1969 Width = llvm::alignTo(Width, Align); 1970 break; 1971 } 1972 1973 case Type::ExtVector: 1974 case Type::Vector: { 1975 const auto *VT = cast<VectorType>(T); 1976 TypeInfo EltInfo = getTypeInfo(VT->getElementType()); 1977 Width = EltInfo.Width * VT->getNumElements(); 1978 Align = Width; 1979 // If the alignment is not a power of 2, round up to the next power of 2. 1980 // This happens for non-power-of-2 length vectors. 1981 if (Align & (Align-1)) { 1982 Align = llvm::NextPowerOf2(Align); 1983 Width = llvm::alignTo(Width, Align); 1984 } 1985 // Adjust the alignment based on the target max. 1986 uint64_t TargetVectorAlign = Target->getMaxVectorAlign(); 1987 if (TargetVectorAlign && TargetVectorAlign < Align) 1988 Align = TargetVectorAlign; 1989 if (VT->getVectorKind() == VectorType::SveFixedLengthDataVector) 1990 // Adjust the alignment for fixed-length SVE vectors. This is important 1991 // for non-power-of-2 vector lengths. 1992 Align = 128; 1993 else if (VT->getVectorKind() == VectorType::SveFixedLengthPredicateVector) 1994 // Adjust the alignment for fixed-length SVE predicates. 1995 Align = 16; 1996 break; 1997 } 1998 1999 case Type::ConstantMatrix: { 2000 const auto *MT = cast<ConstantMatrixType>(T); 2001 TypeInfo ElementInfo = getTypeInfo(MT->getElementType()); 2002 // The internal layout of a matrix value is implementation defined. 2003 // Initially be ABI compatible with arrays with respect to alignment and 2004 // size. 2005 Width = ElementInfo.Width * MT->getNumRows() * MT->getNumColumns(); 2006 Align = ElementInfo.Align; 2007 break; 2008 } 2009 2010 case Type::Builtin: 2011 switch (cast<BuiltinType>(T)->getKind()) { 2012 default: llvm_unreachable("Unknown builtin type!"); 2013 case BuiltinType::Void: 2014 // GCC extension: alignof(void) = 8 bits. 2015 Width = 0; 2016 Align = 8; 2017 break; 2018 case BuiltinType::Bool: 2019 Width = Target->getBoolWidth(); 2020 Align = Target->getBoolAlign(); 2021 break; 2022 case BuiltinType::Char_S: 2023 case BuiltinType::Char_U: 2024 case BuiltinType::UChar: 2025 case BuiltinType::SChar: 2026 case BuiltinType::Char8: 2027 Width = Target->getCharWidth(); 2028 Align = Target->getCharAlign(); 2029 break; 2030 case BuiltinType::WChar_S: 2031 case BuiltinType::WChar_U: 2032 Width = Target->getWCharWidth(); 2033 Align = Target->getWCharAlign(); 2034 break; 2035 case BuiltinType::Char16: 2036 Width = Target->getChar16Width(); 2037 Align = Target->getChar16Align(); 2038 break; 2039 case BuiltinType::Char32: 2040 Width = Target->getChar32Width(); 2041 Align = Target->getChar32Align(); 2042 break; 2043 case BuiltinType::UShort: 2044 case BuiltinType::Short: 2045 Width = Target->getShortWidth(); 2046 Align = Target->getShortAlign(); 2047 break; 2048 case BuiltinType::UInt: 2049 case BuiltinType::Int: 2050 Width = Target->getIntWidth(); 2051 Align = Target->getIntAlign(); 2052 break; 2053 case BuiltinType::ULong: 2054 case BuiltinType::Long: 2055 Width = Target->getLongWidth(); 2056 Align = Target->getLongAlign(); 2057 break; 2058 case BuiltinType::ULongLong: 2059 case BuiltinType::LongLong: 2060 Width = Target->getLongLongWidth(); 2061 Align = Target->getLongLongAlign(); 2062 break; 2063 case BuiltinType::Int128: 2064 case BuiltinType::UInt128: 2065 Width = 128; 2066 Align = 128; // int128_t is 128-bit aligned on all targets. 2067 break; 2068 case BuiltinType::ShortAccum: 2069 case BuiltinType::UShortAccum: 2070 case BuiltinType::SatShortAccum: 2071 case BuiltinType::SatUShortAccum: 2072 Width = Target->getShortAccumWidth(); 2073 Align = Target->getShortAccumAlign(); 2074 break; 2075 case BuiltinType::Accum: 2076 case BuiltinType::UAccum: 2077 case BuiltinType::SatAccum: 2078 case BuiltinType::SatUAccum: 2079 Width = Target->getAccumWidth(); 2080 Align = Target->getAccumAlign(); 2081 break; 2082 case BuiltinType::LongAccum: 2083 case BuiltinType::ULongAccum: 2084 case BuiltinType::SatLongAccum: 2085 case BuiltinType::SatULongAccum: 2086 Width = Target->getLongAccumWidth(); 2087 Align = Target->getLongAccumAlign(); 2088 break; 2089 case BuiltinType::ShortFract: 2090 case BuiltinType::UShortFract: 2091 case BuiltinType::SatShortFract: 2092 case BuiltinType::SatUShortFract: 2093 Width = Target->getShortFractWidth(); 2094 Align = Target->getShortFractAlign(); 2095 break; 2096 case BuiltinType::Fract: 2097 case BuiltinType::UFract: 2098 case BuiltinType::SatFract: 2099 case BuiltinType::SatUFract: 2100 Width = Target->getFractWidth(); 2101 Align = Target->getFractAlign(); 2102 break; 2103 case BuiltinType::LongFract: 2104 case BuiltinType::ULongFract: 2105 case BuiltinType::SatLongFract: 2106 case BuiltinType::SatULongFract: 2107 Width = Target->getLongFractWidth(); 2108 Align = Target->getLongFractAlign(); 2109 break; 2110 case BuiltinType::BFloat16: 2111 Width = Target->getBFloat16Width(); 2112 Align = Target->getBFloat16Align(); 2113 break; 2114 case BuiltinType::Float16: 2115 case BuiltinType::Half: 2116 if (Target->hasFloat16Type() || !getLangOpts().OpenMP || 2117 !getLangOpts().OpenMPIsDevice) { 2118 Width = Target->getHalfWidth(); 2119 Align = Target->getHalfAlign(); 2120 } else { 2121 assert(getLangOpts().OpenMP && getLangOpts().OpenMPIsDevice && 2122 "Expected OpenMP device compilation."); 2123 Width = AuxTarget->getHalfWidth(); 2124 Align = AuxTarget->getHalfAlign(); 2125 } 2126 break; 2127 case BuiltinType::Float: 2128 Width = Target->getFloatWidth(); 2129 Align = Target->getFloatAlign(); 2130 break; 2131 case BuiltinType::Double: 2132 Width = Target->getDoubleWidth(); 2133 Align = Target->getDoubleAlign(); 2134 break; 2135 case BuiltinType::Ibm128: 2136 Width = Target->getIbm128Width(); 2137 Align = Target->getIbm128Align(); 2138 break; 2139 case BuiltinType::LongDouble: 2140 if (getLangOpts().OpenMP && getLangOpts().OpenMPIsDevice && 2141 (Target->getLongDoubleWidth() != AuxTarget->getLongDoubleWidth() || 2142 Target->getLongDoubleAlign() != AuxTarget->getLongDoubleAlign())) { 2143 Width = AuxTarget->getLongDoubleWidth(); 2144 Align = AuxTarget->getLongDoubleAlign(); 2145 } else { 2146 Width = Target->getLongDoubleWidth(); 2147 Align = Target->getLongDoubleAlign(); 2148 } 2149 break; 2150 case BuiltinType::Float128: 2151 if (Target->hasFloat128Type() || !getLangOpts().OpenMP || 2152 !getLangOpts().OpenMPIsDevice) { 2153 Width = Target->getFloat128Width(); 2154 Align = Target->getFloat128Align(); 2155 } else { 2156 assert(getLangOpts().OpenMP && getLangOpts().OpenMPIsDevice && 2157 "Expected OpenMP device compilation."); 2158 Width = AuxTarget->getFloat128Width(); 2159 Align = AuxTarget->getFloat128Align(); 2160 } 2161 break; 2162 case BuiltinType::NullPtr: 2163 Width = Target->getPointerWidth(0); // C++ 3.9.1p11: sizeof(nullptr_t) 2164 Align = Target->getPointerAlign(0); // == sizeof(void*) 2165 break; 2166 case BuiltinType::ObjCId: 2167 case BuiltinType::ObjCClass: 2168 case BuiltinType::ObjCSel: 2169 Width = Target->getPointerWidth(0); 2170 Align = Target->getPointerAlign(0); 2171 break; 2172 case BuiltinType::OCLSampler: 2173 case BuiltinType::OCLEvent: 2174 case BuiltinType::OCLClkEvent: 2175 case BuiltinType::OCLQueue: 2176 case BuiltinType::OCLReserveID: 2177 #define IMAGE_TYPE(ImgType, Id, SingletonId, Access, Suffix) \ 2178 case BuiltinType::Id: 2179 #include "clang/Basic/OpenCLImageTypes.def" 2180 #define EXT_OPAQUE_TYPE(ExtType, Id, Ext) \ 2181 case BuiltinType::Id: 2182 #include "clang/Basic/OpenCLExtensionTypes.def" 2183 AS = getTargetAddressSpace( 2184 Target->getOpenCLTypeAddrSpace(getOpenCLTypeKind(T))); 2185 Width = Target->getPointerWidth(AS); 2186 Align = Target->getPointerAlign(AS); 2187 break; 2188 // The SVE types are effectively target-specific. The length of an 2189 // SVE_VECTOR_TYPE is only known at runtime, but it is always a multiple 2190 // of 128 bits. There is one predicate bit for each vector byte, so the 2191 // length of an SVE_PREDICATE_TYPE is always a multiple of 16 bits. 2192 // 2193 // Because the length is only known at runtime, we use a dummy value 2194 // of 0 for the static length. The alignment values are those defined 2195 // by the Procedure Call Standard for the Arm Architecture. 2196 #define SVE_VECTOR_TYPE(Name, MangledName, Id, SingletonId, NumEls, ElBits, \ 2197 IsSigned, IsFP, IsBF) \ 2198 case BuiltinType::Id: \ 2199 Width = 0; \ 2200 Align = 128; \ 2201 break; 2202 #define SVE_PREDICATE_TYPE(Name, MangledName, Id, SingletonId, NumEls) \ 2203 case BuiltinType::Id: \ 2204 Width = 0; \ 2205 Align = 16; \ 2206 break; 2207 #include "clang/Basic/AArch64SVEACLETypes.def" 2208 #define PPC_VECTOR_TYPE(Name, Id, Size) \ 2209 case BuiltinType::Id: \ 2210 Width = Size; \ 2211 Align = Size; \ 2212 break; 2213 #include "clang/Basic/PPCTypes.def" 2214 #define RVV_VECTOR_TYPE(Name, Id, SingletonId, ElKind, ElBits, NF, IsSigned, \ 2215 IsFP) \ 2216 case BuiltinType::Id: \ 2217 Width = 0; \ 2218 Align = ElBits; \ 2219 break; 2220 #define RVV_PREDICATE_TYPE(Name, Id, SingletonId, ElKind) \ 2221 case BuiltinType::Id: \ 2222 Width = 0; \ 2223 Align = 8; \ 2224 break; 2225 #include "clang/Basic/RISCVVTypes.def" 2226 } 2227 break; 2228 case Type::ObjCObjectPointer: 2229 Width = Target->getPointerWidth(0); 2230 Align = Target->getPointerAlign(0); 2231 break; 2232 case Type::BlockPointer: 2233 AS = getTargetAddressSpace(cast<BlockPointerType>(T)->getPointeeType()); 2234 Width = Target->getPointerWidth(AS); 2235 Align = Target->getPointerAlign(AS); 2236 break; 2237 case Type::LValueReference: 2238 case Type::RValueReference: 2239 // alignof and sizeof should never enter this code path here, so we go 2240 // the pointer route. 2241 AS = getTargetAddressSpace(cast<ReferenceType>(T)->getPointeeType()); 2242 Width = Target->getPointerWidth(AS); 2243 Align = Target->getPointerAlign(AS); 2244 break; 2245 case Type::Pointer: 2246 AS = getTargetAddressSpace(cast<PointerType>(T)->getPointeeType()); 2247 Width = Target->getPointerWidth(AS); 2248 Align = Target->getPointerAlign(AS); 2249 break; 2250 case Type::MemberPointer: { 2251 const auto *MPT = cast<MemberPointerType>(T); 2252 CXXABI::MemberPointerInfo MPI = ABI->getMemberPointerInfo(MPT); 2253 Width = MPI.Width; 2254 Align = MPI.Align; 2255 break; 2256 } 2257 case Type::Complex: { 2258 // Complex types have the same alignment as their elements, but twice the 2259 // size. 2260 TypeInfo EltInfo = getTypeInfo(cast<ComplexType>(T)->getElementType()); 2261 Width = EltInfo.Width * 2; 2262 Align = EltInfo.Align; 2263 break; 2264 } 2265 case Type::ObjCObject: 2266 return getTypeInfo(cast<ObjCObjectType>(T)->getBaseType().getTypePtr()); 2267 case Type::Adjusted: 2268 case Type::Decayed: 2269 return getTypeInfo(cast<AdjustedType>(T)->getAdjustedType().getTypePtr()); 2270 case Type::ObjCInterface: { 2271 const auto *ObjCI = cast<ObjCInterfaceType>(T); 2272 if (ObjCI->getDecl()->isInvalidDecl()) { 2273 Width = 8; 2274 Align = 8; 2275 break; 2276 } 2277 const ASTRecordLayout &Layout = getASTObjCInterfaceLayout(ObjCI->getDecl()); 2278 Width = toBits(Layout.getSize()); 2279 Align = toBits(Layout.getAlignment()); 2280 break; 2281 } 2282 case Type::ExtInt: { 2283 const auto *EIT = cast<ExtIntType>(T); 2284 Align = 2285 std::min(static_cast<unsigned>(std::max( 2286 getCharWidth(), llvm::PowerOf2Ceil(EIT->getNumBits()))), 2287 Target->getLongLongAlign()); 2288 Width = llvm::alignTo(EIT->getNumBits(), Align); 2289 break; 2290 } 2291 case Type::Record: 2292 case Type::Enum: { 2293 const auto *TT = cast<TagType>(T); 2294 2295 if (TT->getDecl()->isInvalidDecl()) { 2296 Width = 8; 2297 Align = 8; 2298 break; 2299 } 2300 2301 if (const auto *ET = dyn_cast<EnumType>(TT)) { 2302 const EnumDecl *ED = ET->getDecl(); 2303 TypeInfo Info = 2304 getTypeInfo(ED->getIntegerType()->getUnqualifiedDesugaredType()); 2305 if (unsigned AttrAlign = ED->getMaxAlignment()) { 2306 Info.Align = AttrAlign; 2307 Info.AlignRequirement = AlignRequirementKind::RequiredByEnum; 2308 } 2309 return Info; 2310 } 2311 2312 const auto *RT = cast<RecordType>(TT); 2313 const RecordDecl *RD = RT->getDecl(); 2314 const ASTRecordLayout &Layout = getASTRecordLayout(RD); 2315 Width = toBits(Layout.getSize()); 2316 Align = toBits(Layout.getAlignment()); 2317 AlignRequirement = RD->hasAttr<AlignedAttr>() 2318 ? AlignRequirementKind::RequiredByRecord 2319 : AlignRequirementKind::None; 2320 break; 2321 } 2322 2323 case Type::SubstTemplateTypeParm: 2324 return getTypeInfo(cast<SubstTemplateTypeParmType>(T)-> 2325 getReplacementType().getTypePtr()); 2326 2327 case Type::Auto: 2328 case Type::DeducedTemplateSpecialization: { 2329 const auto *A = cast<DeducedType>(T); 2330 assert(!A->getDeducedType().isNull() && 2331 "cannot request the size of an undeduced or dependent auto type"); 2332 return getTypeInfo(A->getDeducedType().getTypePtr()); 2333 } 2334 2335 case Type::Paren: 2336 return getTypeInfo(cast<ParenType>(T)->getInnerType().getTypePtr()); 2337 2338 case Type::MacroQualified: 2339 return getTypeInfo( 2340 cast<MacroQualifiedType>(T)->getUnderlyingType().getTypePtr()); 2341 2342 case Type::ObjCTypeParam: 2343 return getTypeInfo(cast<ObjCTypeParamType>(T)->desugar().getTypePtr()); 2344 2345 case Type::Typedef: { 2346 const TypedefNameDecl *Typedef = cast<TypedefType>(T)->getDecl(); 2347 TypeInfo Info = getTypeInfo(Typedef->getUnderlyingType().getTypePtr()); 2348 // If the typedef has an aligned attribute on it, it overrides any computed 2349 // alignment we have. This violates the GCC documentation (which says that 2350 // attribute(aligned) can only round up) but matches its implementation. 2351 if (unsigned AttrAlign = Typedef->getMaxAlignment()) { 2352 Align = AttrAlign; 2353 AlignRequirement = AlignRequirementKind::RequiredByTypedef; 2354 } else { 2355 Align = Info.Align; 2356 AlignRequirement = Info.AlignRequirement; 2357 } 2358 Width = Info.Width; 2359 break; 2360 } 2361 2362 case Type::Elaborated: 2363 return getTypeInfo(cast<ElaboratedType>(T)->getNamedType().getTypePtr()); 2364 2365 case Type::Attributed: 2366 return getTypeInfo( 2367 cast<AttributedType>(T)->getEquivalentType().getTypePtr()); 2368 2369 case Type::Atomic: { 2370 // Start with the base type information. 2371 TypeInfo Info = getTypeInfo(cast<AtomicType>(T)->getValueType()); 2372 Width = Info.Width; 2373 Align = Info.Align; 2374 2375 if (!Width) { 2376 // An otherwise zero-sized type should still generate an 2377 // atomic operation. 2378 Width = Target->getCharWidth(); 2379 assert(Align); 2380 } else if (Width <= Target->getMaxAtomicPromoteWidth()) { 2381 // If the size of the type doesn't exceed the platform's max 2382 // atomic promotion width, make the size and alignment more 2383 // favorable to atomic operations: 2384 2385 // Round the size up to a power of 2. 2386 if (!llvm::isPowerOf2_64(Width)) 2387 Width = llvm::NextPowerOf2(Width); 2388 2389 // Set the alignment equal to the size. 2390 Align = static_cast<unsigned>(Width); 2391 } 2392 } 2393 break; 2394 2395 case Type::Pipe: 2396 Width = Target->getPointerWidth(getTargetAddressSpace(LangAS::opencl_global)); 2397 Align = Target->getPointerAlign(getTargetAddressSpace(LangAS::opencl_global)); 2398 break; 2399 } 2400 2401 assert(llvm::isPowerOf2_32(Align) && "Alignment must be power of 2"); 2402 return TypeInfo(Width, Align, AlignRequirement); 2403 } 2404 2405 unsigned ASTContext::getTypeUnadjustedAlign(const Type *T) const { 2406 UnadjustedAlignMap::iterator I = MemoizedUnadjustedAlign.find(T); 2407 if (I != MemoizedUnadjustedAlign.end()) 2408 return I->second; 2409 2410 unsigned UnadjustedAlign; 2411 if (const auto *RT = T->getAs<RecordType>()) { 2412 const RecordDecl *RD = RT->getDecl(); 2413 const ASTRecordLayout &Layout = getASTRecordLayout(RD); 2414 UnadjustedAlign = toBits(Layout.getUnadjustedAlignment()); 2415 } else if (const auto *ObjCI = T->getAs<ObjCInterfaceType>()) { 2416 const ASTRecordLayout &Layout = getASTObjCInterfaceLayout(ObjCI->getDecl()); 2417 UnadjustedAlign = toBits(Layout.getUnadjustedAlignment()); 2418 } else { 2419 UnadjustedAlign = getTypeAlign(T->getUnqualifiedDesugaredType()); 2420 } 2421 2422 MemoizedUnadjustedAlign[T] = UnadjustedAlign; 2423 return UnadjustedAlign; 2424 } 2425 2426 unsigned ASTContext::getOpenMPDefaultSimdAlign(QualType T) const { 2427 unsigned SimdAlign = getTargetInfo().getSimdDefaultAlign(); 2428 return SimdAlign; 2429 } 2430 2431 /// toCharUnitsFromBits - Convert a size in bits to a size in characters. 2432 CharUnits ASTContext::toCharUnitsFromBits(int64_t BitSize) const { 2433 return CharUnits::fromQuantity(BitSize / getCharWidth()); 2434 } 2435 2436 /// toBits - Convert a size in characters to a size in characters. 2437 int64_t ASTContext::toBits(CharUnits CharSize) const { 2438 return CharSize.getQuantity() * getCharWidth(); 2439 } 2440 2441 /// getTypeSizeInChars - Return the size of the specified type, in characters. 2442 /// This method does not work on incomplete types. 2443 CharUnits ASTContext::getTypeSizeInChars(QualType T) const { 2444 return getTypeInfoInChars(T).Width; 2445 } 2446 CharUnits ASTContext::getTypeSizeInChars(const Type *T) const { 2447 return getTypeInfoInChars(T).Width; 2448 } 2449 2450 /// getTypeAlignInChars - Return the ABI-specified alignment of a type, in 2451 /// characters. This method does not work on incomplete types. 2452 CharUnits ASTContext::getTypeAlignInChars(QualType T) const { 2453 return toCharUnitsFromBits(getTypeAlign(T)); 2454 } 2455 CharUnits ASTContext::getTypeAlignInChars(const Type *T) const { 2456 return toCharUnitsFromBits(getTypeAlign(T)); 2457 } 2458 2459 /// getTypeUnadjustedAlignInChars - Return the ABI-specified alignment of a 2460 /// type, in characters, before alignment adustments. This method does 2461 /// not work on incomplete types. 2462 CharUnits ASTContext::getTypeUnadjustedAlignInChars(QualType T) const { 2463 return toCharUnitsFromBits(getTypeUnadjustedAlign(T)); 2464 } 2465 CharUnits ASTContext::getTypeUnadjustedAlignInChars(const Type *T) const { 2466 return toCharUnitsFromBits(getTypeUnadjustedAlign(T)); 2467 } 2468 2469 /// getPreferredTypeAlign - Return the "preferred" alignment of the specified 2470 /// type for the current target in bits. This can be different than the ABI 2471 /// alignment in cases where it is beneficial for performance or backwards 2472 /// compatibility preserving to overalign a data type. (Note: despite the name, 2473 /// the preferred alignment is ABI-impacting, and not an optimization.) 2474 unsigned ASTContext::getPreferredTypeAlign(const Type *T) const { 2475 TypeInfo TI = getTypeInfo(T); 2476 unsigned ABIAlign = TI.Align; 2477 2478 T = T->getBaseElementTypeUnsafe(); 2479 2480 // The preferred alignment of member pointers is that of a pointer. 2481 if (T->isMemberPointerType()) 2482 return getPreferredTypeAlign(getPointerDiffType().getTypePtr()); 2483 2484 if (!Target->allowsLargerPreferedTypeAlignment()) 2485 return ABIAlign; 2486 2487 if (const auto *RT = T->getAs<RecordType>()) { 2488 const RecordDecl *RD = RT->getDecl(); 2489 2490 // When used as part of a typedef, or together with a 'packed' attribute, 2491 // the 'aligned' attribute can be used to decrease alignment. Note that the 2492 // 'packed' case is already taken into consideration when computing the 2493 // alignment, we only need to handle the typedef case here. 2494 if (TI.AlignRequirement == AlignRequirementKind::RequiredByTypedef || 2495 RD->isInvalidDecl()) 2496 return ABIAlign; 2497 2498 unsigned PreferredAlign = static_cast<unsigned>( 2499 toBits(getASTRecordLayout(RD).PreferredAlignment)); 2500 assert(PreferredAlign >= ABIAlign && 2501 "PreferredAlign should be at least as large as ABIAlign."); 2502 return PreferredAlign; 2503 } 2504 2505 // Double (and, for targets supporting AIX `power` alignment, long double) and 2506 // long long should be naturally aligned (despite requiring less alignment) if 2507 // possible. 2508 if (const auto *CT = T->getAs<ComplexType>()) 2509 T = CT->getElementType().getTypePtr(); 2510 if (const auto *ET = T->getAs<EnumType>()) 2511 T = ET->getDecl()->getIntegerType().getTypePtr(); 2512 if (T->isSpecificBuiltinType(BuiltinType::Double) || 2513 T->isSpecificBuiltinType(BuiltinType::LongLong) || 2514 T->isSpecificBuiltinType(BuiltinType::ULongLong) || 2515 (T->isSpecificBuiltinType(BuiltinType::LongDouble) && 2516 Target->defaultsToAIXPowerAlignment())) 2517 // Don't increase the alignment if an alignment attribute was specified on a 2518 // typedef declaration. 2519 if (!TI.isAlignRequired()) 2520 return std::max(ABIAlign, (unsigned)getTypeSize(T)); 2521 2522 return ABIAlign; 2523 } 2524 2525 /// getTargetDefaultAlignForAttributeAligned - Return the default alignment 2526 /// for __attribute__((aligned)) on this target, to be used if no alignment 2527 /// value is specified. 2528 unsigned ASTContext::getTargetDefaultAlignForAttributeAligned() const { 2529 return getTargetInfo().getDefaultAlignForAttributeAligned(); 2530 } 2531 2532 /// getAlignOfGlobalVar - Return the alignment in bits that should be given 2533 /// to a global variable of the specified type. 2534 unsigned ASTContext::getAlignOfGlobalVar(QualType T) const { 2535 uint64_t TypeSize = getTypeSize(T.getTypePtr()); 2536 return std::max(getPreferredTypeAlign(T), 2537 getTargetInfo().getMinGlobalAlign(TypeSize)); 2538 } 2539 2540 /// getAlignOfGlobalVarInChars - Return the alignment in characters that 2541 /// should be given to a global variable of the specified type. 2542 CharUnits ASTContext::getAlignOfGlobalVarInChars(QualType T) const { 2543 return toCharUnitsFromBits(getAlignOfGlobalVar(T)); 2544 } 2545 2546 CharUnits ASTContext::getOffsetOfBaseWithVBPtr(const CXXRecordDecl *RD) const { 2547 CharUnits Offset = CharUnits::Zero(); 2548 const ASTRecordLayout *Layout = &getASTRecordLayout(RD); 2549 while (const CXXRecordDecl *Base = Layout->getBaseSharingVBPtr()) { 2550 Offset += Layout->getBaseClassOffset(Base); 2551 Layout = &getASTRecordLayout(Base); 2552 } 2553 return Offset; 2554 } 2555 2556 CharUnits ASTContext::getMemberPointerPathAdjustment(const APValue &MP) const { 2557 const ValueDecl *MPD = MP.getMemberPointerDecl(); 2558 CharUnits ThisAdjustment = CharUnits::Zero(); 2559 ArrayRef<const CXXRecordDecl*> Path = MP.getMemberPointerPath(); 2560 bool DerivedMember = MP.isMemberPointerToDerivedMember(); 2561 const CXXRecordDecl *RD = cast<CXXRecordDecl>(MPD->getDeclContext()); 2562 for (unsigned I = 0, N = Path.size(); I != N; ++I) { 2563 const CXXRecordDecl *Base = RD; 2564 const CXXRecordDecl *Derived = Path[I]; 2565 if (DerivedMember) 2566 std::swap(Base, Derived); 2567 ThisAdjustment += getASTRecordLayout(Derived).getBaseClassOffset(Base); 2568 RD = Path[I]; 2569 } 2570 if (DerivedMember) 2571 ThisAdjustment = -ThisAdjustment; 2572 return ThisAdjustment; 2573 } 2574 2575 /// DeepCollectObjCIvars - 2576 /// This routine first collects all declared, but not synthesized, ivars in 2577 /// super class and then collects all ivars, including those synthesized for 2578 /// current class. This routine is used for implementation of current class 2579 /// when all ivars, declared and synthesized are known. 2580 void ASTContext::DeepCollectObjCIvars(const ObjCInterfaceDecl *OI, 2581 bool leafClass, 2582 SmallVectorImpl<const ObjCIvarDecl*> &Ivars) const { 2583 if (const ObjCInterfaceDecl *SuperClass = OI->getSuperClass()) 2584 DeepCollectObjCIvars(SuperClass, false, Ivars); 2585 if (!leafClass) { 2586 for (const auto *I : OI->ivars()) 2587 Ivars.push_back(I); 2588 } else { 2589 auto *IDecl = const_cast<ObjCInterfaceDecl *>(OI); 2590 for (const ObjCIvarDecl *Iv = IDecl->all_declared_ivar_begin(); Iv; 2591 Iv= Iv->getNextIvar()) 2592 Ivars.push_back(Iv); 2593 } 2594 } 2595 2596 /// CollectInheritedProtocols - Collect all protocols in current class and 2597 /// those inherited by it. 2598 void ASTContext::CollectInheritedProtocols(const Decl *CDecl, 2599 llvm::SmallPtrSet<ObjCProtocolDecl*, 8> &Protocols) { 2600 if (const auto *OI = dyn_cast<ObjCInterfaceDecl>(CDecl)) { 2601 // We can use protocol_iterator here instead of 2602 // all_referenced_protocol_iterator since we are walking all categories. 2603 for (auto *Proto : OI->all_referenced_protocols()) { 2604 CollectInheritedProtocols(Proto, Protocols); 2605 } 2606 2607 // Categories of this Interface. 2608 for (const auto *Cat : OI->visible_categories()) 2609 CollectInheritedProtocols(Cat, Protocols); 2610 2611 if (ObjCInterfaceDecl *SD = OI->getSuperClass()) 2612 while (SD) { 2613 CollectInheritedProtocols(SD, Protocols); 2614 SD = SD->getSuperClass(); 2615 } 2616 } else if (const auto *OC = dyn_cast<ObjCCategoryDecl>(CDecl)) { 2617 for (auto *Proto : OC->protocols()) { 2618 CollectInheritedProtocols(Proto, Protocols); 2619 } 2620 } else if (const auto *OP = dyn_cast<ObjCProtocolDecl>(CDecl)) { 2621 // Insert the protocol. 2622 if (!Protocols.insert( 2623 const_cast<ObjCProtocolDecl *>(OP->getCanonicalDecl())).second) 2624 return; 2625 2626 for (auto *Proto : OP->protocols()) 2627 CollectInheritedProtocols(Proto, Protocols); 2628 } 2629 } 2630 2631 static bool unionHasUniqueObjectRepresentations(const ASTContext &Context, 2632 const RecordDecl *RD) { 2633 assert(RD->isUnion() && "Must be union type"); 2634 CharUnits UnionSize = Context.getTypeSizeInChars(RD->getTypeForDecl()); 2635 2636 for (const auto *Field : RD->fields()) { 2637 if (!Context.hasUniqueObjectRepresentations(Field->getType())) 2638 return false; 2639 CharUnits FieldSize = Context.getTypeSizeInChars(Field->getType()); 2640 if (FieldSize != UnionSize) 2641 return false; 2642 } 2643 return !RD->field_empty(); 2644 } 2645 2646 static int64_t getSubobjectOffset(const FieldDecl *Field, 2647 const ASTContext &Context, 2648 const clang::ASTRecordLayout & /*Layout*/) { 2649 return Context.getFieldOffset(Field); 2650 } 2651 2652 static int64_t getSubobjectOffset(const CXXRecordDecl *RD, 2653 const ASTContext &Context, 2654 const clang::ASTRecordLayout &Layout) { 2655 return Context.toBits(Layout.getBaseClassOffset(RD)); 2656 } 2657 2658 static llvm::Optional<int64_t> 2659 structHasUniqueObjectRepresentations(const ASTContext &Context, 2660 const RecordDecl *RD); 2661 2662 static llvm::Optional<int64_t> 2663 getSubobjectSizeInBits(const FieldDecl *Field, const ASTContext &Context) { 2664 if (Field->getType()->isRecordType()) { 2665 const RecordDecl *RD = Field->getType()->getAsRecordDecl(); 2666 if (!RD->isUnion()) 2667 return structHasUniqueObjectRepresentations(Context, RD); 2668 } 2669 if (!Field->getType()->isReferenceType() && 2670 !Context.hasUniqueObjectRepresentations(Field->getType())) 2671 return llvm::None; 2672 2673 int64_t FieldSizeInBits = 2674 Context.toBits(Context.getTypeSizeInChars(Field->getType())); 2675 if (Field->isBitField()) { 2676 int64_t BitfieldSize = Field->getBitWidthValue(Context); 2677 if (BitfieldSize > FieldSizeInBits) 2678 return llvm::None; 2679 FieldSizeInBits = BitfieldSize; 2680 } 2681 return FieldSizeInBits; 2682 } 2683 2684 static llvm::Optional<int64_t> 2685 getSubobjectSizeInBits(const CXXRecordDecl *RD, const ASTContext &Context) { 2686 return structHasUniqueObjectRepresentations(Context, RD); 2687 } 2688 2689 template <typename RangeT> 2690 static llvm::Optional<int64_t> structSubobjectsHaveUniqueObjectRepresentations( 2691 const RangeT &Subobjects, int64_t CurOffsetInBits, 2692 const ASTContext &Context, const clang::ASTRecordLayout &Layout) { 2693 for (const auto *Subobject : Subobjects) { 2694 llvm::Optional<int64_t> SizeInBits = 2695 getSubobjectSizeInBits(Subobject, Context); 2696 if (!SizeInBits) 2697 return llvm::None; 2698 if (*SizeInBits != 0) { 2699 int64_t Offset = getSubobjectOffset(Subobject, Context, Layout); 2700 if (Offset != CurOffsetInBits) 2701 return llvm::None; 2702 CurOffsetInBits += *SizeInBits; 2703 } 2704 } 2705 return CurOffsetInBits; 2706 } 2707 2708 static llvm::Optional<int64_t> 2709 structHasUniqueObjectRepresentations(const ASTContext &Context, 2710 const RecordDecl *RD) { 2711 assert(!RD->isUnion() && "Must be struct/class type"); 2712 const auto &Layout = Context.getASTRecordLayout(RD); 2713 2714 int64_t CurOffsetInBits = 0; 2715 if (const auto *ClassDecl = dyn_cast<CXXRecordDecl>(RD)) { 2716 if (ClassDecl->isDynamicClass()) 2717 return llvm::None; 2718 2719 SmallVector<CXXRecordDecl *, 4> Bases; 2720 for (const auto &Base : ClassDecl->bases()) { 2721 // Empty types can be inherited from, and non-empty types can potentially 2722 // have tail padding, so just make sure there isn't an error. 2723 Bases.emplace_back(Base.getType()->getAsCXXRecordDecl()); 2724 } 2725 2726 llvm::sort(Bases, [&](const CXXRecordDecl *L, const CXXRecordDecl *R) { 2727 return Layout.getBaseClassOffset(L) < Layout.getBaseClassOffset(R); 2728 }); 2729 2730 llvm::Optional<int64_t> OffsetAfterBases = 2731 structSubobjectsHaveUniqueObjectRepresentations(Bases, CurOffsetInBits, 2732 Context, Layout); 2733 if (!OffsetAfterBases) 2734 return llvm::None; 2735 CurOffsetInBits = *OffsetAfterBases; 2736 } 2737 2738 llvm::Optional<int64_t> OffsetAfterFields = 2739 structSubobjectsHaveUniqueObjectRepresentations( 2740 RD->fields(), CurOffsetInBits, Context, Layout); 2741 if (!OffsetAfterFields) 2742 return llvm::None; 2743 CurOffsetInBits = *OffsetAfterFields; 2744 2745 return CurOffsetInBits; 2746 } 2747 2748 bool ASTContext::hasUniqueObjectRepresentations(QualType Ty) const { 2749 // C++17 [meta.unary.prop]: 2750 // The predicate condition for a template specialization 2751 // has_unique_object_representations<T> shall be 2752 // satisfied if and only if: 2753 // (9.1) - T is trivially copyable, and 2754 // (9.2) - any two objects of type T with the same value have the same 2755 // object representation, where two objects 2756 // of array or non-union class type are considered to have the same value 2757 // if their respective sequences of 2758 // direct subobjects have the same values, and two objects of union type 2759 // are considered to have the same 2760 // value if they have the same active member and the corresponding members 2761 // have the same value. 2762 // The set of scalar types for which this condition holds is 2763 // implementation-defined. [ Note: If a type has padding 2764 // bits, the condition does not hold; otherwise, the condition holds true 2765 // for unsigned integral types. -- end note ] 2766 assert(!Ty.isNull() && "Null QualType sent to unique object rep check"); 2767 2768 // Arrays are unique only if their element type is unique. 2769 if (Ty->isArrayType()) 2770 return hasUniqueObjectRepresentations(getBaseElementType(Ty)); 2771 2772 // (9.1) - T is trivially copyable... 2773 if (!Ty.isTriviallyCopyableType(*this)) 2774 return false; 2775 2776 // All integrals and enums are unique. 2777 if (Ty->isIntegralOrEnumerationType()) 2778 return true; 2779 2780 // All other pointers are unique. 2781 if (Ty->isPointerType()) 2782 return true; 2783 2784 if (Ty->isMemberPointerType()) { 2785 const auto *MPT = Ty->getAs<MemberPointerType>(); 2786 return !ABI->getMemberPointerInfo(MPT).HasPadding; 2787 } 2788 2789 if (Ty->isRecordType()) { 2790 const RecordDecl *Record = Ty->castAs<RecordType>()->getDecl(); 2791 2792 if (Record->isInvalidDecl()) 2793 return false; 2794 2795 if (Record->isUnion()) 2796 return unionHasUniqueObjectRepresentations(*this, Record); 2797 2798 Optional<int64_t> StructSize = 2799 structHasUniqueObjectRepresentations(*this, Record); 2800 2801 return StructSize && 2802 StructSize.getValue() == static_cast<int64_t>(getTypeSize(Ty)); 2803 } 2804 2805 // FIXME: More cases to handle here (list by rsmith): 2806 // vectors (careful about, eg, vector of 3 foo) 2807 // _Complex int and friends 2808 // _Atomic T 2809 // Obj-C block pointers 2810 // Obj-C object pointers 2811 // and perhaps OpenCL's various builtin types (pipe, sampler_t, event_t, 2812 // clk_event_t, queue_t, reserve_id_t) 2813 // There're also Obj-C class types and the Obj-C selector type, but I think it 2814 // makes sense for those to return false here. 2815 2816 return false; 2817 } 2818 2819 unsigned ASTContext::CountNonClassIvars(const ObjCInterfaceDecl *OI) const { 2820 unsigned count = 0; 2821 // Count ivars declared in class extension. 2822 for (const auto *Ext : OI->known_extensions()) 2823 count += Ext->ivar_size(); 2824 2825 // Count ivar defined in this class's implementation. This 2826 // includes synthesized ivars. 2827 if (ObjCImplementationDecl *ImplDecl = OI->getImplementation()) 2828 count += ImplDecl->ivar_size(); 2829 2830 return count; 2831 } 2832 2833 bool ASTContext::isSentinelNullExpr(const Expr *E) { 2834 if (!E) 2835 return false; 2836 2837 // nullptr_t is always treated as null. 2838 if (E->getType()->isNullPtrType()) return true; 2839 2840 if (E->getType()->isAnyPointerType() && 2841 E->IgnoreParenCasts()->isNullPointerConstant(*this, 2842 Expr::NPC_ValueDependentIsNull)) 2843 return true; 2844 2845 // Unfortunately, __null has type 'int'. 2846 if (isa<GNUNullExpr>(E)) return true; 2847 2848 return false; 2849 } 2850 2851 /// Get the implementation of ObjCInterfaceDecl, or nullptr if none 2852 /// exists. 2853 ObjCImplementationDecl *ASTContext::getObjCImplementation(ObjCInterfaceDecl *D) { 2854 llvm::DenseMap<ObjCContainerDecl*, ObjCImplDecl*>::iterator 2855 I = ObjCImpls.find(D); 2856 if (I != ObjCImpls.end()) 2857 return cast<ObjCImplementationDecl>(I->second); 2858 return nullptr; 2859 } 2860 2861 /// Get the implementation of ObjCCategoryDecl, or nullptr if none 2862 /// exists. 2863 ObjCCategoryImplDecl *ASTContext::getObjCImplementation(ObjCCategoryDecl *D) { 2864 llvm::DenseMap<ObjCContainerDecl*, ObjCImplDecl*>::iterator 2865 I = ObjCImpls.find(D); 2866 if (I != ObjCImpls.end()) 2867 return cast<ObjCCategoryImplDecl>(I->second); 2868 return nullptr; 2869 } 2870 2871 /// Set the implementation of ObjCInterfaceDecl. 2872 void ASTContext::setObjCImplementation(ObjCInterfaceDecl *IFaceD, 2873 ObjCImplementationDecl *ImplD) { 2874 assert(IFaceD && ImplD && "Passed null params"); 2875 ObjCImpls[IFaceD] = ImplD; 2876 } 2877 2878 /// Set the implementation of ObjCCategoryDecl. 2879 void ASTContext::setObjCImplementation(ObjCCategoryDecl *CatD, 2880 ObjCCategoryImplDecl *ImplD) { 2881 assert(CatD && ImplD && "Passed null params"); 2882 ObjCImpls[CatD] = ImplD; 2883 } 2884 2885 const ObjCMethodDecl * 2886 ASTContext::getObjCMethodRedeclaration(const ObjCMethodDecl *MD) const { 2887 return ObjCMethodRedecls.lookup(MD); 2888 } 2889 2890 void ASTContext::setObjCMethodRedeclaration(const ObjCMethodDecl *MD, 2891 const ObjCMethodDecl *Redecl) { 2892 assert(!getObjCMethodRedeclaration(MD) && "MD already has a redeclaration"); 2893 ObjCMethodRedecls[MD] = Redecl; 2894 } 2895 2896 const ObjCInterfaceDecl *ASTContext::getObjContainingInterface( 2897 const NamedDecl *ND) const { 2898 if (const auto *ID = dyn_cast<ObjCInterfaceDecl>(ND->getDeclContext())) 2899 return ID; 2900 if (const auto *CD = dyn_cast<ObjCCategoryDecl>(ND->getDeclContext())) 2901 return CD->getClassInterface(); 2902 if (const auto *IMD = dyn_cast<ObjCImplDecl>(ND->getDeclContext())) 2903 return IMD->getClassInterface(); 2904 2905 return nullptr; 2906 } 2907 2908 /// Get the copy initialization expression of VarDecl, or nullptr if 2909 /// none exists. 2910 BlockVarCopyInit ASTContext::getBlockVarCopyInit(const VarDecl *VD) const { 2911 assert(VD && "Passed null params"); 2912 assert(VD->hasAttr<BlocksAttr>() && 2913 "getBlockVarCopyInits - not __block var"); 2914 auto I = BlockVarCopyInits.find(VD); 2915 if (I != BlockVarCopyInits.end()) 2916 return I->second; 2917 return {nullptr, false}; 2918 } 2919 2920 /// Set the copy initialization expression of a block var decl. 2921 void ASTContext::setBlockVarCopyInit(const VarDecl*VD, Expr *CopyExpr, 2922 bool CanThrow) { 2923 assert(VD && CopyExpr && "Passed null params"); 2924 assert(VD->hasAttr<BlocksAttr>() && 2925 "setBlockVarCopyInits - not __block var"); 2926 BlockVarCopyInits[VD].setExprAndFlag(CopyExpr, CanThrow); 2927 } 2928 2929 TypeSourceInfo *ASTContext::CreateTypeSourceInfo(QualType T, 2930 unsigned DataSize) const { 2931 if (!DataSize) 2932 DataSize = TypeLoc::getFullDataSizeForType(T); 2933 else 2934 assert(DataSize == TypeLoc::getFullDataSizeForType(T) && 2935 "incorrect data size provided to CreateTypeSourceInfo!"); 2936 2937 auto *TInfo = 2938 (TypeSourceInfo*)BumpAlloc.Allocate(sizeof(TypeSourceInfo) + DataSize, 8); 2939 new (TInfo) TypeSourceInfo(T); 2940 return TInfo; 2941 } 2942 2943 TypeSourceInfo *ASTContext::getTrivialTypeSourceInfo(QualType T, 2944 SourceLocation L) const { 2945 TypeSourceInfo *DI = CreateTypeSourceInfo(T); 2946 DI->getTypeLoc().initialize(const_cast<ASTContext &>(*this), L); 2947 return DI; 2948 } 2949 2950 const ASTRecordLayout & 2951 ASTContext::getASTObjCInterfaceLayout(const ObjCInterfaceDecl *D) const { 2952 return getObjCLayout(D, nullptr); 2953 } 2954 2955 const ASTRecordLayout & 2956 ASTContext::getASTObjCImplementationLayout( 2957 const ObjCImplementationDecl *D) const { 2958 return getObjCLayout(D->getClassInterface(), D); 2959 } 2960 2961 //===----------------------------------------------------------------------===// 2962 // Type creation/memoization methods 2963 //===----------------------------------------------------------------------===// 2964 2965 QualType 2966 ASTContext::getExtQualType(const Type *baseType, Qualifiers quals) const { 2967 unsigned fastQuals = quals.getFastQualifiers(); 2968 quals.removeFastQualifiers(); 2969 2970 // Check if we've already instantiated this type. 2971 llvm::FoldingSetNodeID ID; 2972 ExtQuals::Profile(ID, baseType, quals); 2973 void *insertPos = nullptr; 2974 if (ExtQuals *eq = ExtQualNodes.FindNodeOrInsertPos(ID, insertPos)) { 2975 assert(eq->getQualifiers() == quals); 2976 return QualType(eq, fastQuals); 2977 } 2978 2979 // If the base type is not canonical, make the appropriate canonical type. 2980 QualType canon; 2981 if (!baseType->isCanonicalUnqualified()) { 2982 SplitQualType canonSplit = baseType->getCanonicalTypeInternal().split(); 2983 canonSplit.Quals.addConsistentQualifiers(quals); 2984 canon = getExtQualType(canonSplit.Ty, canonSplit.Quals); 2985 2986 // Re-find the insert position. 2987 (void) ExtQualNodes.FindNodeOrInsertPos(ID, insertPos); 2988 } 2989 2990 auto *eq = new (*this, TypeAlignment) ExtQuals(baseType, canon, quals); 2991 ExtQualNodes.InsertNode(eq, insertPos); 2992 return QualType(eq, fastQuals); 2993 } 2994 2995 QualType ASTContext::getAddrSpaceQualType(QualType T, 2996 LangAS AddressSpace) const { 2997 QualType CanT = getCanonicalType(T); 2998 if (CanT.getAddressSpace() == AddressSpace) 2999 return T; 3000 3001 // If we are composing extended qualifiers together, merge together 3002 // into one ExtQuals node. 3003 QualifierCollector Quals; 3004 const Type *TypeNode = Quals.strip(T); 3005 3006 // If this type already has an address space specified, it cannot get 3007 // another one. 3008 assert(!Quals.hasAddressSpace() && 3009 "Type cannot be in multiple addr spaces!"); 3010 Quals.addAddressSpace(AddressSpace); 3011 3012 return getExtQualType(TypeNode, Quals); 3013 } 3014 3015 QualType ASTContext::removeAddrSpaceQualType(QualType T) const { 3016 // If the type is not qualified with an address space, just return it 3017 // immediately. 3018 if (!T.hasAddressSpace()) 3019 return T; 3020 3021 // If we are composing extended qualifiers together, merge together 3022 // into one ExtQuals node. 3023 QualifierCollector Quals; 3024 const Type *TypeNode; 3025 3026 while (T.hasAddressSpace()) { 3027 TypeNode = Quals.strip(T); 3028 3029 // If the type no longer has an address space after stripping qualifiers, 3030 // jump out. 3031 if (!QualType(TypeNode, 0).hasAddressSpace()) 3032 break; 3033 3034 // There might be sugar in the way. Strip it and try again. 3035 T = T.getSingleStepDesugaredType(*this); 3036 } 3037 3038 Quals.removeAddressSpace(); 3039 3040 // Removal of the address space can mean there are no longer any 3041 // non-fast qualifiers, so creating an ExtQualType isn't possible (asserts) 3042 // or required. 3043 if (Quals.hasNonFastQualifiers()) 3044 return getExtQualType(TypeNode, Quals); 3045 else 3046 return QualType(TypeNode, Quals.getFastQualifiers()); 3047 } 3048 3049 QualType ASTContext::getObjCGCQualType(QualType T, 3050 Qualifiers::GC GCAttr) const { 3051 QualType CanT = getCanonicalType(T); 3052 if (CanT.getObjCGCAttr() == GCAttr) 3053 return T; 3054 3055 if (const auto *ptr = T->getAs<PointerType>()) { 3056 QualType Pointee = ptr->getPointeeType(); 3057 if (Pointee->isAnyPointerType()) { 3058 QualType ResultType = getObjCGCQualType(Pointee, GCAttr); 3059 return getPointerType(ResultType); 3060 } 3061 } 3062 3063 // If we are composing extended qualifiers together, merge together 3064 // into one ExtQuals node. 3065 QualifierCollector Quals; 3066 const Type *TypeNode = Quals.strip(T); 3067 3068 // If this type already has an ObjCGC specified, it cannot get 3069 // another one. 3070 assert(!Quals.hasObjCGCAttr() && 3071 "Type cannot have multiple ObjCGCs!"); 3072 Quals.addObjCGCAttr(GCAttr); 3073 3074 return getExtQualType(TypeNode, Quals); 3075 } 3076 3077 QualType ASTContext::removePtrSizeAddrSpace(QualType T) const { 3078 if (const PointerType *Ptr = T->getAs<PointerType>()) { 3079 QualType Pointee = Ptr->getPointeeType(); 3080 if (isPtrSizeAddressSpace(Pointee.getAddressSpace())) { 3081 return getPointerType(removeAddrSpaceQualType(Pointee)); 3082 } 3083 } 3084 return T; 3085 } 3086 3087 const FunctionType *ASTContext::adjustFunctionType(const FunctionType *T, 3088 FunctionType::ExtInfo Info) { 3089 if (T->getExtInfo() == Info) 3090 return T; 3091 3092 QualType Result; 3093 if (const auto *FNPT = dyn_cast<FunctionNoProtoType>(T)) { 3094 Result = getFunctionNoProtoType(FNPT->getReturnType(), Info); 3095 } else { 3096 const auto *FPT = cast<FunctionProtoType>(T); 3097 FunctionProtoType::ExtProtoInfo EPI = FPT->getExtProtoInfo(); 3098 EPI.ExtInfo = Info; 3099 Result = getFunctionType(FPT->getReturnType(), FPT->getParamTypes(), EPI); 3100 } 3101 3102 return cast<FunctionType>(Result.getTypePtr()); 3103 } 3104 3105 void ASTContext::adjustDeducedFunctionResultType(FunctionDecl *FD, 3106 QualType ResultType) { 3107 FD = FD->getMostRecentDecl(); 3108 while (true) { 3109 const auto *FPT = FD->getType()->castAs<FunctionProtoType>(); 3110 FunctionProtoType::ExtProtoInfo EPI = FPT->getExtProtoInfo(); 3111 FD->setType(getFunctionType(ResultType, FPT->getParamTypes(), EPI)); 3112 if (FunctionDecl *Next = FD->getPreviousDecl()) 3113 FD = Next; 3114 else 3115 break; 3116 } 3117 if (ASTMutationListener *L = getASTMutationListener()) 3118 L->DeducedReturnType(FD, ResultType); 3119 } 3120 3121 /// Get a function type and produce the equivalent function type with the 3122 /// specified exception specification. Type sugar that can be present on a 3123 /// declaration of a function with an exception specification is permitted 3124 /// and preserved. Other type sugar (for instance, typedefs) is not. 3125 QualType ASTContext::getFunctionTypeWithExceptionSpec( 3126 QualType Orig, const FunctionProtoType::ExceptionSpecInfo &ESI) { 3127 // Might have some parens. 3128 if (const auto *PT = dyn_cast<ParenType>(Orig)) 3129 return getParenType( 3130 getFunctionTypeWithExceptionSpec(PT->getInnerType(), ESI)); 3131 3132 // Might be wrapped in a macro qualified type. 3133 if (const auto *MQT = dyn_cast<MacroQualifiedType>(Orig)) 3134 return getMacroQualifiedType( 3135 getFunctionTypeWithExceptionSpec(MQT->getUnderlyingType(), ESI), 3136 MQT->getMacroIdentifier()); 3137 3138 // Might have a calling-convention attribute. 3139 if (const auto *AT = dyn_cast<AttributedType>(Orig)) 3140 return getAttributedType( 3141 AT->getAttrKind(), 3142 getFunctionTypeWithExceptionSpec(AT->getModifiedType(), ESI), 3143 getFunctionTypeWithExceptionSpec(AT->getEquivalentType(), ESI)); 3144 3145 // Anything else must be a function type. Rebuild it with the new exception 3146 // specification. 3147 const auto *Proto = Orig->castAs<FunctionProtoType>(); 3148 return getFunctionType( 3149 Proto->getReturnType(), Proto->getParamTypes(), 3150 Proto->getExtProtoInfo().withExceptionSpec(ESI)); 3151 } 3152 3153 bool ASTContext::hasSameFunctionTypeIgnoringExceptionSpec(QualType T, 3154 QualType U) { 3155 return hasSameType(T, U) || 3156 (getLangOpts().CPlusPlus17 && 3157 hasSameType(getFunctionTypeWithExceptionSpec(T, EST_None), 3158 getFunctionTypeWithExceptionSpec(U, EST_None))); 3159 } 3160 3161 QualType ASTContext::getFunctionTypeWithoutPtrSizes(QualType T) { 3162 if (const auto *Proto = T->getAs<FunctionProtoType>()) { 3163 QualType RetTy = removePtrSizeAddrSpace(Proto->getReturnType()); 3164 SmallVector<QualType, 16> Args(Proto->param_types()); 3165 for (unsigned i = 0, n = Args.size(); i != n; ++i) 3166 Args[i] = removePtrSizeAddrSpace(Args[i]); 3167 return getFunctionType(RetTy, Args, Proto->getExtProtoInfo()); 3168 } 3169 3170 if (const FunctionNoProtoType *Proto = T->getAs<FunctionNoProtoType>()) { 3171 QualType RetTy = removePtrSizeAddrSpace(Proto->getReturnType()); 3172 return getFunctionNoProtoType(RetTy, Proto->getExtInfo()); 3173 } 3174 3175 return T; 3176 } 3177 3178 bool ASTContext::hasSameFunctionTypeIgnoringPtrSizes(QualType T, QualType U) { 3179 return hasSameType(T, U) || 3180 hasSameType(getFunctionTypeWithoutPtrSizes(T), 3181 getFunctionTypeWithoutPtrSizes(U)); 3182 } 3183 3184 void ASTContext::adjustExceptionSpec( 3185 FunctionDecl *FD, const FunctionProtoType::ExceptionSpecInfo &ESI, 3186 bool AsWritten) { 3187 // Update the type. 3188 QualType Updated = 3189 getFunctionTypeWithExceptionSpec(FD->getType(), ESI); 3190 FD->setType(Updated); 3191 3192 if (!AsWritten) 3193 return; 3194 3195 // Update the type in the type source information too. 3196 if (TypeSourceInfo *TSInfo = FD->getTypeSourceInfo()) { 3197 // If the type and the type-as-written differ, we may need to update 3198 // the type-as-written too. 3199 if (TSInfo->getType() != FD->getType()) 3200 Updated = getFunctionTypeWithExceptionSpec(TSInfo->getType(), ESI); 3201 3202 // FIXME: When we get proper type location information for exceptions, 3203 // we'll also have to rebuild the TypeSourceInfo. For now, we just patch 3204 // up the TypeSourceInfo; 3205 assert(TypeLoc::getFullDataSizeForType(Updated) == 3206 TypeLoc::getFullDataSizeForType(TSInfo->getType()) && 3207 "TypeLoc size mismatch from updating exception specification"); 3208 TSInfo->overrideType(Updated); 3209 } 3210 } 3211 3212 /// getComplexType - Return the uniqued reference to the type for a complex 3213 /// number with the specified element type. 3214 QualType ASTContext::getComplexType(QualType T) const { 3215 // Unique pointers, to guarantee there is only one pointer of a particular 3216 // structure. 3217 llvm::FoldingSetNodeID ID; 3218 ComplexType::Profile(ID, T); 3219 3220 void *InsertPos = nullptr; 3221 if (ComplexType *CT = ComplexTypes.FindNodeOrInsertPos(ID, InsertPos)) 3222 return QualType(CT, 0); 3223 3224 // If the pointee type isn't canonical, this won't be a canonical type either, 3225 // so fill in the canonical type field. 3226 QualType Canonical; 3227 if (!T.isCanonical()) { 3228 Canonical = getComplexType(getCanonicalType(T)); 3229 3230 // Get the new insert position for the node we care about. 3231 ComplexType *NewIP = ComplexTypes.FindNodeOrInsertPos(ID, InsertPos); 3232 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 3233 } 3234 auto *New = new (*this, TypeAlignment) ComplexType(T, Canonical); 3235 Types.push_back(New); 3236 ComplexTypes.InsertNode(New, InsertPos); 3237 return QualType(New, 0); 3238 } 3239 3240 /// getPointerType - Return the uniqued reference to the type for a pointer to 3241 /// the specified type. 3242 QualType ASTContext::getPointerType(QualType T) const { 3243 // Unique pointers, to guarantee there is only one pointer of a particular 3244 // structure. 3245 llvm::FoldingSetNodeID ID; 3246 PointerType::Profile(ID, T); 3247 3248 void *InsertPos = nullptr; 3249 if (PointerType *PT = PointerTypes.FindNodeOrInsertPos(ID, InsertPos)) 3250 return QualType(PT, 0); 3251 3252 // If the pointee type isn't canonical, this won't be a canonical type either, 3253 // so fill in the canonical type field. 3254 QualType Canonical; 3255 if (!T.isCanonical()) { 3256 Canonical = getPointerType(getCanonicalType(T)); 3257 3258 // Get the new insert position for the node we care about. 3259 PointerType *NewIP = PointerTypes.FindNodeOrInsertPos(ID, InsertPos); 3260 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 3261 } 3262 auto *New = new (*this, TypeAlignment) PointerType(T, Canonical); 3263 Types.push_back(New); 3264 PointerTypes.InsertNode(New, InsertPos); 3265 return QualType(New, 0); 3266 } 3267 3268 QualType ASTContext::getAdjustedType(QualType Orig, QualType New) const { 3269 llvm::FoldingSetNodeID ID; 3270 AdjustedType::Profile(ID, Orig, New); 3271 void *InsertPos = nullptr; 3272 AdjustedType *AT = AdjustedTypes.FindNodeOrInsertPos(ID, InsertPos); 3273 if (AT) 3274 return QualType(AT, 0); 3275 3276 QualType Canonical = getCanonicalType(New); 3277 3278 // Get the new insert position for the node we care about. 3279 AT = AdjustedTypes.FindNodeOrInsertPos(ID, InsertPos); 3280 assert(!AT && "Shouldn't be in the map!"); 3281 3282 AT = new (*this, TypeAlignment) 3283 AdjustedType(Type::Adjusted, Orig, New, Canonical); 3284 Types.push_back(AT); 3285 AdjustedTypes.InsertNode(AT, InsertPos); 3286 return QualType(AT, 0); 3287 } 3288 3289 QualType ASTContext::getDecayedType(QualType T) const { 3290 assert((T->isArrayType() || T->isFunctionType()) && "T does not decay"); 3291 3292 QualType Decayed; 3293 3294 // C99 6.7.5.3p7: 3295 // A declaration of a parameter as "array of type" shall be 3296 // adjusted to "qualified pointer to type", where the type 3297 // qualifiers (if any) are those specified within the [ and ] of 3298 // the array type derivation. 3299 if (T->isArrayType()) 3300 Decayed = getArrayDecayedType(T); 3301 3302 // C99 6.7.5.3p8: 3303 // A declaration of a parameter as "function returning type" 3304 // shall be adjusted to "pointer to function returning type", as 3305 // in 6.3.2.1. 3306 if (T->isFunctionType()) 3307 Decayed = getPointerType(T); 3308 3309 llvm::FoldingSetNodeID ID; 3310 AdjustedType::Profile(ID, T, Decayed); 3311 void *InsertPos = nullptr; 3312 AdjustedType *AT = AdjustedTypes.FindNodeOrInsertPos(ID, InsertPos); 3313 if (AT) 3314 return QualType(AT, 0); 3315 3316 QualType Canonical = getCanonicalType(Decayed); 3317 3318 // Get the new insert position for the node we care about. 3319 AT = AdjustedTypes.FindNodeOrInsertPos(ID, InsertPos); 3320 assert(!AT && "Shouldn't be in the map!"); 3321 3322 AT = new (*this, TypeAlignment) DecayedType(T, Decayed, Canonical); 3323 Types.push_back(AT); 3324 AdjustedTypes.InsertNode(AT, InsertPos); 3325 return QualType(AT, 0); 3326 } 3327 3328 /// getBlockPointerType - Return the uniqued reference to the type for 3329 /// a pointer to the specified block. 3330 QualType ASTContext::getBlockPointerType(QualType T) const { 3331 assert(T->isFunctionType() && "block of function types only"); 3332 // Unique pointers, to guarantee there is only one block of a particular 3333 // structure. 3334 llvm::FoldingSetNodeID ID; 3335 BlockPointerType::Profile(ID, T); 3336 3337 void *InsertPos = nullptr; 3338 if (BlockPointerType *PT = 3339 BlockPointerTypes.FindNodeOrInsertPos(ID, InsertPos)) 3340 return QualType(PT, 0); 3341 3342 // If the block pointee type isn't canonical, this won't be a canonical 3343 // type either so fill in the canonical type field. 3344 QualType Canonical; 3345 if (!T.isCanonical()) { 3346 Canonical = getBlockPointerType(getCanonicalType(T)); 3347 3348 // Get the new insert position for the node we care about. 3349 BlockPointerType *NewIP = 3350 BlockPointerTypes.FindNodeOrInsertPos(ID, InsertPos); 3351 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 3352 } 3353 auto *New = new (*this, TypeAlignment) BlockPointerType(T, Canonical); 3354 Types.push_back(New); 3355 BlockPointerTypes.InsertNode(New, InsertPos); 3356 return QualType(New, 0); 3357 } 3358 3359 /// getLValueReferenceType - Return the uniqued reference to the type for an 3360 /// lvalue reference to the specified type. 3361 QualType 3362 ASTContext::getLValueReferenceType(QualType T, bool SpelledAsLValue) const { 3363 assert(getCanonicalType(T) != OverloadTy && 3364 "Unresolved overloaded function type"); 3365 3366 // Unique pointers, to guarantee there is only one pointer of a particular 3367 // structure. 3368 llvm::FoldingSetNodeID ID; 3369 ReferenceType::Profile(ID, T, SpelledAsLValue); 3370 3371 void *InsertPos = nullptr; 3372 if (LValueReferenceType *RT = 3373 LValueReferenceTypes.FindNodeOrInsertPos(ID, InsertPos)) 3374 return QualType(RT, 0); 3375 3376 const auto *InnerRef = T->getAs<ReferenceType>(); 3377 3378 // If the referencee type isn't canonical, this won't be a canonical type 3379 // either, so fill in the canonical type field. 3380 QualType Canonical; 3381 if (!SpelledAsLValue || InnerRef || !T.isCanonical()) { 3382 QualType PointeeType = (InnerRef ? InnerRef->getPointeeType() : T); 3383 Canonical = getLValueReferenceType(getCanonicalType(PointeeType)); 3384 3385 // Get the new insert position for the node we care about. 3386 LValueReferenceType *NewIP = 3387 LValueReferenceTypes.FindNodeOrInsertPos(ID, InsertPos); 3388 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 3389 } 3390 3391 auto *New = new (*this, TypeAlignment) LValueReferenceType(T, Canonical, 3392 SpelledAsLValue); 3393 Types.push_back(New); 3394 LValueReferenceTypes.InsertNode(New, InsertPos); 3395 3396 return QualType(New, 0); 3397 } 3398 3399 /// getRValueReferenceType - Return the uniqued reference to the type for an 3400 /// rvalue reference to the specified type. 3401 QualType ASTContext::getRValueReferenceType(QualType T) const { 3402 // Unique pointers, to guarantee there is only one pointer of a particular 3403 // structure. 3404 llvm::FoldingSetNodeID ID; 3405 ReferenceType::Profile(ID, T, false); 3406 3407 void *InsertPos = nullptr; 3408 if (RValueReferenceType *RT = 3409 RValueReferenceTypes.FindNodeOrInsertPos(ID, InsertPos)) 3410 return QualType(RT, 0); 3411 3412 const auto *InnerRef = T->getAs<ReferenceType>(); 3413 3414 // If the referencee type isn't canonical, this won't be a canonical type 3415 // either, so fill in the canonical type field. 3416 QualType Canonical; 3417 if (InnerRef || !T.isCanonical()) { 3418 QualType PointeeType = (InnerRef ? InnerRef->getPointeeType() : T); 3419 Canonical = getRValueReferenceType(getCanonicalType(PointeeType)); 3420 3421 // Get the new insert position for the node we care about. 3422 RValueReferenceType *NewIP = 3423 RValueReferenceTypes.FindNodeOrInsertPos(ID, InsertPos); 3424 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 3425 } 3426 3427 auto *New = new (*this, TypeAlignment) RValueReferenceType(T, Canonical); 3428 Types.push_back(New); 3429 RValueReferenceTypes.InsertNode(New, InsertPos); 3430 return QualType(New, 0); 3431 } 3432 3433 /// getMemberPointerType - Return the uniqued reference to the type for a 3434 /// member pointer to the specified type, in the specified class. 3435 QualType ASTContext::getMemberPointerType(QualType T, const Type *Cls) const { 3436 // Unique pointers, to guarantee there is only one pointer of a particular 3437 // structure. 3438 llvm::FoldingSetNodeID ID; 3439 MemberPointerType::Profile(ID, T, Cls); 3440 3441 void *InsertPos = nullptr; 3442 if (MemberPointerType *PT = 3443 MemberPointerTypes.FindNodeOrInsertPos(ID, InsertPos)) 3444 return QualType(PT, 0); 3445 3446 // If the pointee or class type isn't canonical, this won't be a canonical 3447 // type either, so fill in the canonical type field. 3448 QualType Canonical; 3449 if (!T.isCanonical() || !Cls->isCanonicalUnqualified()) { 3450 Canonical = getMemberPointerType(getCanonicalType(T),getCanonicalType(Cls)); 3451 3452 // Get the new insert position for the node we care about. 3453 MemberPointerType *NewIP = 3454 MemberPointerTypes.FindNodeOrInsertPos(ID, InsertPos); 3455 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 3456 } 3457 auto *New = new (*this, TypeAlignment) MemberPointerType(T, Cls, Canonical); 3458 Types.push_back(New); 3459 MemberPointerTypes.InsertNode(New, InsertPos); 3460 return QualType(New, 0); 3461 } 3462 3463 /// getConstantArrayType - Return the unique reference to the type for an 3464 /// array of the specified element type. 3465 QualType ASTContext::getConstantArrayType(QualType EltTy, 3466 const llvm::APInt &ArySizeIn, 3467 const Expr *SizeExpr, 3468 ArrayType::ArraySizeModifier ASM, 3469 unsigned IndexTypeQuals) const { 3470 assert((EltTy->isDependentType() || 3471 EltTy->isIncompleteType() || EltTy->isConstantSizeType()) && 3472 "Constant array of VLAs is illegal!"); 3473 3474 // We only need the size as part of the type if it's instantiation-dependent. 3475 if (SizeExpr && !SizeExpr->isInstantiationDependent()) 3476 SizeExpr = nullptr; 3477 3478 // Convert the array size into a canonical width matching the pointer size for 3479 // the target. 3480 llvm::APInt ArySize(ArySizeIn); 3481 ArySize = ArySize.zextOrTrunc(Target->getMaxPointerWidth()); 3482 3483 llvm::FoldingSetNodeID ID; 3484 ConstantArrayType::Profile(ID, *this, EltTy, ArySize, SizeExpr, ASM, 3485 IndexTypeQuals); 3486 3487 void *InsertPos = nullptr; 3488 if (ConstantArrayType *ATP = 3489 ConstantArrayTypes.FindNodeOrInsertPos(ID, InsertPos)) 3490 return QualType(ATP, 0); 3491 3492 // If the element type isn't canonical or has qualifiers, or the array bound 3493 // is instantiation-dependent, this won't be a canonical type either, so fill 3494 // in the canonical type field. 3495 QualType Canon; 3496 if (!EltTy.isCanonical() || EltTy.hasLocalQualifiers() || SizeExpr) { 3497 SplitQualType canonSplit = getCanonicalType(EltTy).split(); 3498 Canon = getConstantArrayType(QualType(canonSplit.Ty, 0), ArySize, nullptr, 3499 ASM, IndexTypeQuals); 3500 Canon = getQualifiedType(Canon, canonSplit.Quals); 3501 3502 // Get the new insert position for the node we care about. 3503 ConstantArrayType *NewIP = 3504 ConstantArrayTypes.FindNodeOrInsertPos(ID, InsertPos); 3505 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 3506 } 3507 3508 void *Mem = Allocate( 3509 ConstantArrayType::totalSizeToAlloc<const Expr *>(SizeExpr ? 1 : 0), 3510 TypeAlignment); 3511 auto *New = new (Mem) 3512 ConstantArrayType(EltTy, Canon, ArySize, SizeExpr, ASM, IndexTypeQuals); 3513 ConstantArrayTypes.InsertNode(New, InsertPos); 3514 Types.push_back(New); 3515 return QualType(New, 0); 3516 } 3517 3518 /// getVariableArrayDecayedType - Turns the given type, which may be 3519 /// variably-modified, into the corresponding type with all the known 3520 /// sizes replaced with [*]. 3521 QualType ASTContext::getVariableArrayDecayedType(QualType type) const { 3522 // Vastly most common case. 3523 if (!type->isVariablyModifiedType()) return type; 3524 3525 QualType result; 3526 3527 SplitQualType split = type.getSplitDesugaredType(); 3528 const Type *ty = split.Ty; 3529 switch (ty->getTypeClass()) { 3530 #define TYPE(Class, Base) 3531 #define ABSTRACT_TYPE(Class, Base) 3532 #define NON_CANONICAL_TYPE(Class, Base) case Type::Class: 3533 #include "clang/AST/TypeNodes.inc" 3534 llvm_unreachable("didn't desugar past all non-canonical types?"); 3535 3536 // These types should never be variably-modified. 3537 case Type::Builtin: 3538 case Type::Complex: 3539 case Type::Vector: 3540 case Type::DependentVector: 3541 case Type::ExtVector: 3542 case Type::DependentSizedExtVector: 3543 case Type::ConstantMatrix: 3544 case Type::DependentSizedMatrix: 3545 case Type::DependentAddressSpace: 3546 case Type::ObjCObject: 3547 case Type::ObjCInterface: 3548 case Type::ObjCObjectPointer: 3549 case Type::Record: 3550 case Type::Enum: 3551 case Type::UnresolvedUsing: 3552 case Type::TypeOfExpr: 3553 case Type::TypeOf: 3554 case Type::Decltype: 3555 case Type::UnaryTransform: 3556 case Type::DependentName: 3557 case Type::InjectedClassName: 3558 case Type::TemplateSpecialization: 3559 case Type::DependentTemplateSpecialization: 3560 case Type::TemplateTypeParm: 3561 case Type::SubstTemplateTypeParmPack: 3562 case Type::Auto: 3563 case Type::DeducedTemplateSpecialization: 3564 case Type::PackExpansion: 3565 case Type::ExtInt: 3566 case Type::DependentExtInt: 3567 llvm_unreachable("type should never be variably-modified"); 3568 3569 // These types can be variably-modified but should never need to 3570 // further decay. 3571 case Type::FunctionNoProto: 3572 case Type::FunctionProto: 3573 case Type::BlockPointer: 3574 case Type::MemberPointer: 3575 case Type::Pipe: 3576 return type; 3577 3578 // These types can be variably-modified. All these modifications 3579 // preserve structure except as noted by comments. 3580 // TODO: if we ever care about optimizing VLAs, there are no-op 3581 // optimizations available here. 3582 case Type::Pointer: 3583 result = getPointerType(getVariableArrayDecayedType( 3584 cast<PointerType>(ty)->getPointeeType())); 3585 break; 3586 3587 case Type::LValueReference: { 3588 const auto *lv = cast<LValueReferenceType>(ty); 3589 result = getLValueReferenceType( 3590 getVariableArrayDecayedType(lv->getPointeeType()), 3591 lv->isSpelledAsLValue()); 3592 break; 3593 } 3594 3595 case Type::RValueReference: { 3596 const auto *lv = cast<RValueReferenceType>(ty); 3597 result = getRValueReferenceType( 3598 getVariableArrayDecayedType(lv->getPointeeType())); 3599 break; 3600 } 3601 3602 case Type::Atomic: { 3603 const auto *at = cast<AtomicType>(ty); 3604 result = getAtomicType(getVariableArrayDecayedType(at->getValueType())); 3605 break; 3606 } 3607 3608 case Type::ConstantArray: { 3609 const auto *cat = cast<ConstantArrayType>(ty); 3610 result = getConstantArrayType( 3611 getVariableArrayDecayedType(cat->getElementType()), 3612 cat->getSize(), 3613 cat->getSizeExpr(), 3614 cat->getSizeModifier(), 3615 cat->getIndexTypeCVRQualifiers()); 3616 break; 3617 } 3618 3619 case Type::DependentSizedArray: { 3620 const auto *dat = cast<DependentSizedArrayType>(ty); 3621 result = getDependentSizedArrayType( 3622 getVariableArrayDecayedType(dat->getElementType()), 3623 dat->getSizeExpr(), 3624 dat->getSizeModifier(), 3625 dat->getIndexTypeCVRQualifiers(), 3626 dat->getBracketsRange()); 3627 break; 3628 } 3629 3630 // Turn incomplete types into [*] types. 3631 case Type::IncompleteArray: { 3632 const auto *iat = cast<IncompleteArrayType>(ty); 3633 result = getVariableArrayType( 3634 getVariableArrayDecayedType(iat->getElementType()), 3635 /*size*/ nullptr, 3636 ArrayType::Normal, 3637 iat->getIndexTypeCVRQualifiers(), 3638 SourceRange()); 3639 break; 3640 } 3641 3642 // Turn VLA types into [*] types. 3643 case Type::VariableArray: { 3644 const auto *vat = cast<VariableArrayType>(ty); 3645 result = getVariableArrayType( 3646 getVariableArrayDecayedType(vat->getElementType()), 3647 /*size*/ nullptr, 3648 ArrayType::Star, 3649 vat->getIndexTypeCVRQualifiers(), 3650 vat->getBracketsRange()); 3651 break; 3652 } 3653 } 3654 3655 // Apply the top-level qualifiers from the original. 3656 return getQualifiedType(result, split.Quals); 3657 } 3658 3659 /// getVariableArrayType - Returns a non-unique reference to the type for a 3660 /// variable array of the specified element type. 3661 QualType ASTContext::getVariableArrayType(QualType EltTy, 3662 Expr *NumElts, 3663 ArrayType::ArraySizeModifier ASM, 3664 unsigned IndexTypeQuals, 3665 SourceRange Brackets) const { 3666 // Since we don't unique expressions, it isn't possible to unique VLA's 3667 // that have an expression provided for their size. 3668 QualType Canon; 3669 3670 // Be sure to pull qualifiers off the element type. 3671 if (!EltTy.isCanonical() || EltTy.hasLocalQualifiers()) { 3672 SplitQualType canonSplit = getCanonicalType(EltTy).split(); 3673 Canon = getVariableArrayType(QualType(canonSplit.Ty, 0), NumElts, ASM, 3674 IndexTypeQuals, Brackets); 3675 Canon = getQualifiedType(Canon, canonSplit.Quals); 3676 } 3677 3678 auto *New = new (*this, TypeAlignment) 3679 VariableArrayType(EltTy, Canon, NumElts, ASM, IndexTypeQuals, Brackets); 3680 3681 VariableArrayTypes.push_back(New); 3682 Types.push_back(New); 3683 return QualType(New, 0); 3684 } 3685 3686 /// getDependentSizedArrayType - Returns a non-unique reference to 3687 /// the type for a dependently-sized array of the specified element 3688 /// type. 3689 QualType ASTContext::getDependentSizedArrayType(QualType elementType, 3690 Expr *numElements, 3691 ArrayType::ArraySizeModifier ASM, 3692 unsigned elementTypeQuals, 3693 SourceRange brackets) const { 3694 assert((!numElements || numElements->isTypeDependent() || 3695 numElements->isValueDependent()) && 3696 "Size must be type- or value-dependent!"); 3697 3698 // Dependently-sized array types that do not have a specified number 3699 // of elements will have their sizes deduced from a dependent 3700 // initializer. We do no canonicalization here at all, which is okay 3701 // because they can't be used in most locations. 3702 if (!numElements) { 3703 auto *newType 3704 = new (*this, TypeAlignment) 3705 DependentSizedArrayType(*this, elementType, QualType(), 3706 numElements, ASM, elementTypeQuals, 3707 brackets); 3708 Types.push_back(newType); 3709 return QualType(newType, 0); 3710 } 3711 3712 // Otherwise, we actually build a new type every time, but we 3713 // also build a canonical type. 3714 3715 SplitQualType canonElementType = getCanonicalType(elementType).split(); 3716 3717 void *insertPos = nullptr; 3718 llvm::FoldingSetNodeID ID; 3719 DependentSizedArrayType::Profile(ID, *this, 3720 QualType(canonElementType.Ty, 0), 3721 ASM, elementTypeQuals, numElements); 3722 3723 // Look for an existing type with these properties. 3724 DependentSizedArrayType *canonTy = 3725 DependentSizedArrayTypes.FindNodeOrInsertPos(ID, insertPos); 3726 3727 // If we don't have one, build one. 3728 if (!canonTy) { 3729 canonTy = new (*this, TypeAlignment) 3730 DependentSizedArrayType(*this, QualType(canonElementType.Ty, 0), 3731 QualType(), numElements, ASM, elementTypeQuals, 3732 brackets); 3733 DependentSizedArrayTypes.InsertNode(canonTy, insertPos); 3734 Types.push_back(canonTy); 3735 } 3736 3737 // Apply qualifiers from the element type to the array. 3738 QualType canon = getQualifiedType(QualType(canonTy,0), 3739 canonElementType.Quals); 3740 3741 // If we didn't need extra canonicalization for the element type or the size 3742 // expression, then just use that as our result. 3743 if (QualType(canonElementType.Ty, 0) == elementType && 3744 canonTy->getSizeExpr() == numElements) 3745 return canon; 3746 3747 // Otherwise, we need to build a type which follows the spelling 3748 // of the element type. 3749 auto *sugaredType 3750 = new (*this, TypeAlignment) 3751 DependentSizedArrayType(*this, elementType, canon, numElements, 3752 ASM, elementTypeQuals, brackets); 3753 Types.push_back(sugaredType); 3754 return QualType(sugaredType, 0); 3755 } 3756 3757 QualType ASTContext::getIncompleteArrayType(QualType elementType, 3758 ArrayType::ArraySizeModifier ASM, 3759 unsigned elementTypeQuals) const { 3760 llvm::FoldingSetNodeID ID; 3761 IncompleteArrayType::Profile(ID, elementType, ASM, elementTypeQuals); 3762 3763 void *insertPos = nullptr; 3764 if (IncompleteArrayType *iat = 3765 IncompleteArrayTypes.FindNodeOrInsertPos(ID, insertPos)) 3766 return QualType(iat, 0); 3767 3768 // If the element type isn't canonical, this won't be a canonical type 3769 // either, so fill in the canonical type field. We also have to pull 3770 // qualifiers off the element type. 3771 QualType canon; 3772 3773 if (!elementType.isCanonical() || elementType.hasLocalQualifiers()) { 3774 SplitQualType canonSplit = getCanonicalType(elementType).split(); 3775 canon = getIncompleteArrayType(QualType(canonSplit.Ty, 0), 3776 ASM, elementTypeQuals); 3777 canon = getQualifiedType(canon, canonSplit.Quals); 3778 3779 // Get the new insert position for the node we care about. 3780 IncompleteArrayType *existing = 3781 IncompleteArrayTypes.FindNodeOrInsertPos(ID, insertPos); 3782 assert(!existing && "Shouldn't be in the map!"); (void) existing; 3783 } 3784 3785 auto *newType = new (*this, TypeAlignment) 3786 IncompleteArrayType(elementType, canon, ASM, elementTypeQuals); 3787 3788 IncompleteArrayTypes.InsertNode(newType, insertPos); 3789 Types.push_back(newType); 3790 return QualType(newType, 0); 3791 } 3792 3793 ASTContext::BuiltinVectorTypeInfo 3794 ASTContext::getBuiltinVectorTypeInfo(const BuiltinType *Ty) const { 3795 #define SVE_INT_ELTTY(BITS, ELTS, SIGNED, NUMVECTORS) \ 3796 {getIntTypeForBitwidth(BITS, SIGNED), llvm::ElementCount::getScalable(ELTS), \ 3797 NUMVECTORS}; 3798 3799 #define SVE_ELTTY(ELTTY, ELTS, NUMVECTORS) \ 3800 {ELTTY, llvm::ElementCount::getScalable(ELTS), NUMVECTORS}; 3801 3802 switch (Ty->getKind()) { 3803 default: 3804 llvm_unreachable("Unsupported builtin vector type"); 3805 case BuiltinType::SveInt8: 3806 return SVE_INT_ELTTY(8, 16, true, 1); 3807 case BuiltinType::SveUint8: 3808 return SVE_INT_ELTTY(8, 16, false, 1); 3809 case BuiltinType::SveInt8x2: 3810 return SVE_INT_ELTTY(8, 16, true, 2); 3811 case BuiltinType::SveUint8x2: 3812 return SVE_INT_ELTTY(8, 16, false, 2); 3813 case BuiltinType::SveInt8x3: 3814 return SVE_INT_ELTTY(8, 16, true, 3); 3815 case BuiltinType::SveUint8x3: 3816 return SVE_INT_ELTTY(8, 16, false, 3); 3817 case BuiltinType::SveInt8x4: 3818 return SVE_INT_ELTTY(8, 16, true, 4); 3819 case BuiltinType::SveUint8x4: 3820 return SVE_INT_ELTTY(8, 16, false, 4); 3821 case BuiltinType::SveInt16: 3822 return SVE_INT_ELTTY(16, 8, true, 1); 3823 case BuiltinType::SveUint16: 3824 return SVE_INT_ELTTY(16, 8, false, 1); 3825 case BuiltinType::SveInt16x2: 3826 return SVE_INT_ELTTY(16, 8, true, 2); 3827 case BuiltinType::SveUint16x2: 3828 return SVE_INT_ELTTY(16, 8, false, 2); 3829 case BuiltinType::SveInt16x3: 3830 return SVE_INT_ELTTY(16, 8, true, 3); 3831 case BuiltinType::SveUint16x3: 3832 return SVE_INT_ELTTY(16, 8, false, 3); 3833 case BuiltinType::SveInt16x4: 3834 return SVE_INT_ELTTY(16, 8, true, 4); 3835 case BuiltinType::SveUint16x4: 3836 return SVE_INT_ELTTY(16, 8, false, 4); 3837 case BuiltinType::SveInt32: 3838 return SVE_INT_ELTTY(32, 4, true, 1); 3839 case BuiltinType::SveUint32: 3840 return SVE_INT_ELTTY(32, 4, false, 1); 3841 case BuiltinType::SveInt32x2: 3842 return SVE_INT_ELTTY(32, 4, true, 2); 3843 case BuiltinType::SveUint32x2: 3844 return SVE_INT_ELTTY(32, 4, false, 2); 3845 case BuiltinType::SveInt32x3: 3846 return SVE_INT_ELTTY(32, 4, true, 3); 3847 case BuiltinType::SveUint32x3: 3848 return SVE_INT_ELTTY(32, 4, false, 3); 3849 case BuiltinType::SveInt32x4: 3850 return SVE_INT_ELTTY(32, 4, true, 4); 3851 case BuiltinType::SveUint32x4: 3852 return SVE_INT_ELTTY(32, 4, false, 4); 3853 case BuiltinType::SveInt64: 3854 return SVE_INT_ELTTY(64, 2, true, 1); 3855 case BuiltinType::SveUint64: 3856 return SVE_INT_ELTTY(64, 2, false, 1); 3857 case BuiltinType::SveInt64x2: 3858 return SVE_INT_ELTTY(64, 2, true, 2); 3859 case BuiltinType::SveUint64x2: 3860 return SVE_INT_ELTTY(64, 2, false, 2); 3861 case BuiltinType::SveInt64x3: 3862 return SVE_INT_ELTTY(64, 2, true, 3); 3863 case BuiltinType::SveUint64x3: 3864 return SVE_INT_ELTTY(64, 2, false, 3); 3865 case BuiltinType::SveInt64x4: 3866 return SVE_INT_ELTTY(64, 2, true, 4); 3867 case BuiltinType::SveUint64x4: 3868 return SVE_INT_ELTTY(64, 2, false, 4); 3869 case BuiltinType::SveBool: 3870 return SVE_ELTTY(BoolTy, 16, 1); 3871 case BuiltinType::SveFloat16: 3872 return SVE_ELTTY(HalfTy, 8, 1); 3873 case BuiltinType::SveFloat16x2: 3874 return SVE_ELTTY(HalfTy, 8, 2); 3875 case BuiltinType::SveFloat16x3: 3876 return SVE_ELTTY(HalfTy, 8, 3); 3877 case BuiltinType::SveFloat16x4: 3878 return SVE_ELTTY(HalfTy, 8, 4); 3879 case BuiltinType::SveFloat32: 3880 return SVE_ELTTY(FloatTy, 4, 1); 3881 case BuiltinType::SveFloat32x2: 3882 return SVE_ELTTY(FloatTy, 4, 2); 3883 case BuiltinType::SveFloat32x3: 3884 return SVE_ELTTY(FloatTy, 4, 3); 3885 case BuiltinType::SveFloat32x4: 3886 return SVE_ELTTY(FloatTy, 4, 4); 3887 case BuiltinType::SveFloat64: 3888 return SVE_ELTTY(DoubleTy, 2, 1); 3889 case BuiltinType::SveFloat64x2: 3890 return SVE_ELTTY(DoubleTy, 2, 2); 3891 case BuiltinType::SveFloat64x3: 3892 return SVE_ELTTY(DoubleTy, 2, 3); 3893 case BuiltinType::SveFloat64x4: 3894 return SVE_ELTTY(DoubleTy, 2, 4); 3895 case BuiltinType::SveBFloat16: 3896 return SVE_ELTTY(BFloat16Ty, 8, 1); 3897 case BuiltinType::SveBFloat16x2: 3898 return SVE_ELTTY(BFloat16Ty, 8, 2); 3899 case BuiltinType::SveBFloat16x3: 3900 return SVE_ELTTY(BFloat16Ty, 8, 3); 3901 case BuiltinType::SveBFloat16x4: 3902 return SVE_ELTTY(BFloat16Ty, 8, 4); 3903 #define RVV_VECTOR_TYPE_INT(Name, Id, SingletonId, NumEls, ElBits, NF, \ 3904 IsSigned) \ 3905 case BuiltinType::Id: \ 3906 return {getIntTypeForBitwidth(ElBits, IsSigned), \ 3907 llvm::ElementCount::getScalable(NumEls), NF}; 3908 #define RVV_VECTOR_TYPE_FLOAT(Name, Id, SingletonId, NumEls, ElBits, NF) \ 3909 case BuiltinType::Id: \ 3910 return {ElBits == 16 ? Float16Ty : (ElBits == 32 ? FloatTy : DoubleTy), \ 3911 llvm::ElementCount::getScalable(NumEls), NF}; 3912 #define RVV_PREDICATE_TYPE(Name, Id, SingletonId, NumEls) \ 3913 case BuiltinType::Id: \ 3914 return {BoolTy, llvm::ElementCount::getScalable(NumEls), 1}; 3915 #include "clang/Basic/RISCVVTypes.def" 3916 } 3917 } 3918 3919 /// getScalableVectorType - Return the unique reference to a scalable vector 3920 /// type of the specified element type and size. VectorType must be a built-in 3921 /// type. 3922 QualType ASTContext::getScalableVectorType(QualType EltTy, 3923 unsigned NumElts) const { 3924 if (Target->hasAArch64SVETypes()) { 3925 uint64_t EltTySize = getTypeSize(EltTy); 3926 #define SVE_VECTOR_TYPE(Name, MangledName, Id, SingletonId, NumEls, ElBits, \ 3927 IsSigned, IsFP, IsBF) \ 3928 if (!EltTy->isBooleanType() && \ 3929 ((EltTy->hasIntegerRepresentation() && \ 3930 EltTy->hasSignedIntegerRepresentation() == IsSigned) || \ 3931 (EltTy->hasFloatingRepresentation() && !EltTy->isBFloat16Type() && \ 3932 IsFP && !IsBF) || \ 3933 (EltTy->hasFloatingRepresentation() && EltTy->isBFloat16Type() && \ 3934 IsBF && !IsFP)) && \ 3935 EltTySize == ElBits && NumElts == NumEls) { \ 3936 return SingletonId; \ 3937 } 3938 #define SVE_PREDICATE_TYPE(Name, MangledName, Id, SingletonId, NumEls) \ 3939 if (EltTy->isBooleanType() && NumElts == NumEls) \ 3940 return SingletonId; 3941 #include "clang/Basic/AArch64SVEACLETypes.def" 3942 } else if (Target->hasRISCVVTypes()) { 3943 uint64_t EltTySize = getTypeSize(EltTy); 3944 #define RVV_VECTOR_TYPE(Name, Id, SingletonId, NumEls, ElBits, NF, IsSigned, \ 3945 IsFP) \ 3946 if (!EltTy->isBooleanType() && \ 3947 ((EltTy->hasIntegerRepresentation() && \ 3948 EltTy->hasSignedIntegerRepresentation() == IsSigned) || \ 3949 (EltTy->hasFloatingRepresentation() && IsFP)) && \ 3950 EltTySize == ElBits && NumElts == NumEls) \ 3951 return SingletonId; 3952 #define RVV_PREDICATE_TYPE(Name, Id, SingletonId, NumEls) \ 3953 if (EltTy->isBooleanType() && NumElts == NumEls) \ 3954 return SingletonId; 3955 #include "clang/Basic/RISCVVTypes.def" 3956 } 3957 return QualType(); 3958 } 3959 3960 /// getVectorType - Return the unique reference to a vector type of 3961 /// the specified element type and size. VectorType must be a built-in type. 3962 QualType ASTContext::getVectorType(QualType vecType, unsigned NumElts, 3963 VectorType::VectorKind VecKind) const { 3964 assert(vecType->isBuiltinType()); 3965 3966 // Check if we've already instantiated a vector of this type. 3967 llvm::FoldingSetNodeID ID; 3968 VectorType::Profile(ID, vecType, NumElts, Type::Vector, VecKind); 3969 3970 void *InsertPos = nullptr; 3971 if (VectorType *VTP = VectorTypes.FindNodeOrInsertPos(ID, InsertPos)) 3972 return QualType(VTP, 0); 3973 3974 // If the element type isn't canonical, this won't be a canonical type either, 3975 // so fill in the canonical type field. 3976 QualType Canonical; 3977 if (!vecType.isCanonical()) { 3978 Canonical = getVectorType(getCanonicalType(vecType), NumElts, VecKind); 3979 3980 // Get the new insert position for the node we care about. 3981 VectorType *NewIP = VectorTypes.FindNodeOrInsertPos(ID, InsertPos); 3982 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 3983 } 3984 auto *New = new (*this, TypeAlignment) 3985 VectorType(vecType, NumElts, Canonical, VecKind); 3986 VectorTypes.InsertNode(New, InsertPos); 3987 Types.push_back(New); 3988 return QualType(New, 0); 3989 } 3990 3991 QualType 3992 ASTContext::getDependentVectorType(QualType VecType, Expr *SizeExpr, 3993 SourceLocation AttrLoc, 3994 VectorType::VectorKind VecKind) const { 3995 llvm::FoldingSetNodeID ID; 3996 DependentVectorType::Profile(ID, *this, getCanonicalType(VecType), SizeExpr, 3997 VecKind); 3998 void *InsertPos = nullptr; 3999 DependentVectorType *Canon = 4000 DependentVectorTypes.FindNodeOrInsertPos(ID, InsertPos); 4001 DependentVectorType *New; 4002 4003 if (Canon) { 4004 New = new (*this, TypeAlignment) DependentVectorType( 4005 *this, VecType, QualType(Canon, 0), SizeExpr, AttrLoc, VecKind); 4006 } else { 4007 QualType CanonVecTy = getCanonicalType(VecType); 4008 if (CanonVecTy == VecType) { 4009 New = new (*this, TypeAlignment) DependentVectorType( 4010 *this, VecType, QualType(), SizeExpr, AttrLoc, VecKind); 4011 4012 DependentVectorType *CanonCheck = 4013 DependentVectorTypes.FindNodeOrInsertPos(ID, InsertPos); 4014 assert(!CanonCheck && 4015 "Dependent-sized vector_size canonical type broken"); 4016 (void)CanonCheck; 4017 DependentVectorTypes.InsertNode(New, InsertPos); 4018 } else { 4019 QualType CanonTy = getDependentVectorType(CanonVecTy, SizeExpr, 4020 SourceLocation(), VecKind); 4021 New = new (*this, TypeAlignment) DependentVectorType( 4022 *this, VecType, CanonTy, SizeExpr, AttrLoc, VecKind); 4023 } 4024 } 4025 4026 Types.push_back(New); 4027 return QualType(New, 0); 4028 } 4029 4030 /// getExtVectorType - Return the unique reference to an extended vector type of 4031 /// the specified element type and size. VectorType must be a built-in type. 4032 QualType 4033 ASTContext::getExtVectorType(QualType vecType, unsigned NumElts) const { 4034 assert(vecType->isBuiltinType() || vecType->isDependentType()); 4035 4036 // Check if we've already instantiated a vector of this type. 4037 llvm::FoldingSetNodeID ID; 4038 VectorType::Profile(ID, vecType, NumElts, Type::ExtVector, 4039 VectorType::GenericVector); 4040 void *InsertPos = nullptr; 4041 if (VectorType *VTP = VectorTypes.FindNodeOrInsertPos(ID, InsertPos)) 4042 return QualType(VTP, 0); 4043 4044 // If the element type isn't canonical, this won't be a canonical type either, 4045 // so fill in the canonical type field. 4046 QualType Canonical; 4047 if (!vecType.isCanonical()) { 4048 Canonical = getExtVectorType(getCanonicalType(vecType), NumElts); 4049 4050 // Get the new insert position for the node we care about. 4051 VectorType *NewIP = VectorTypes.FindNodeOrInsertPos(ID, InsertPos); 4052 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 4053 } 4054 auto *New = new (*this, TypeAlignment) 4055 ExtVectorType(vecType, NumElts, Canonical); 4056 VectorTypes.InsertNode(New, InsertPos); 4057 Types.push_back(New); 4058 return QualType(New, 0); 4059 } 4060 4061 QualType 4062 ASTContext::getDependentSizedExtVectorType(QualType vecType, 4063 Expr *SizeExpr, 4064 SourceLocation AttrLoc) const { 4065 llvm::FoldingSetNodeID ID; 4066 DependentSizedExtVectorType::Profile(ID, *this, getCanonicalType(vecType), 4067 SizeExpr); 4068 4069 void *InsertPos = nullptr; 4070 DependentSizedExtVectorType *Canon 4071 = DependentSizedExtVectorTypes.FindNodeOrInsertPos(ID, InsertPos); 4072 DependentSizedExtVectorType *New; 4073 if (Canon) { 4074 // We already have a canonical version of this array type; use it as 4075 // the canonical type for a newly-built type. 4076 New = new (*this, TypeAlignment) 4077 DependentSizedExtVectorType(*this, vecType, QualType(Canon, 0), 4078 SizeExpr, AttrLoc); 4079 } else { 4080 QualType CanonVecTy = getCanonicalType(vecType); 4081 if (CanonVecTy == vecType) { 4082 New = new (*this, TypeAlignment) 4083 DependentSizedExtVectorType(*this, vecType, QualType(), SizeExpr, 4084 AttrLoc); 4085 4086 DependentSizedExtVectorType *CanonCheck 4087 = DependentSizedExtVectorTypes.FindNodeOrInsertPos(ID, InsertPos); 4088 assert(!CanonCheck && "Dependent-sized ext_vector canonical type broken"); 4089 (void)CanonCheck; 4090 DependentSizedExtVectorTypes.InsertNode(New, InsertPos); 4091 } else { 4092 QualType CanonExtTy = getDependentSizedExtVectorType(CanonVecTy, SizeExpr, 4093 SourceLocation()); 4094 New = new (*this, TypeAlignment) DependentSizedExtVectorType( 4095 *this, vecType, CanonExtTy, SizeExpr, AttrLoc); 4096 } 4097 } 4098 4099 Types.push_back(New); 4100 return QualType(New, 0); 4101 } 4102 4103 QualType ASTContext::getConstantMatrixType(QualType ElementTy, unsigned NumRows, 4104 unsigned NumColumns) const { 4105 llvm::FoldingSetNodeID ID; 4106 ConstantMatrixType::Profile(ID, ElementTy, NumRows, NumColumns, 4107 Type::ConstantMatrix); 4108 4109 assert(MatrixType::isValidElementType(ElementTy) && 4110 "need a valid element type"); 4111 assert(ConstantMatrixType::isDimensionValid(NumRows) && 4112 ConstantMatrixType::isDimensionValid(NumColumns) && 4113 "need valid matrix dimensions"); 4114 void *InsertPos = nullptr; 4115 if (ConstantMatrixType *MTP = MatrixTypes.FindNodeOrInsertPos(ID, InsertPos)) 4116 return QualType(MTP, 0); 4117 4118 QualType Canonical; 4119 if (!ElementTy.isCanonical()) { 4120 Canonical = 4121 getConstantMatrixType(getCanonicalType(ElementTy), NumRows, NumColumns); 4122 4123 ConstantMatrixType *NewIP = MatrixTypes.FindNodeOrInsertPos(ID, InsertPos); 4124 assert(!NewIP && "Matrix type shouldn't already exist in the map"); 4125 (void)NewIP; 4126 } 4127 4128 auto *New = new (*this, TypeAlignment) 4129 ConstantMatrixType(ElementTy, NumRows, NumColumns, Canonical); 4130 MatrixTypes.InsertNode(New, InsertPos); 4131 Types.push_back(New); 4132 return QualType(New, 0); 4133 } 4134 4135 QualType ASTContext::getDependentSizedMatrixType(QualType ElementTy, 4136 Expr *RowExpr, 4137 Expr *ColumnExpr, 4138 SourceLocation AttrLoc) const { 4139 QualType CanonElementTy = getCanonicalType(ElementTy); 4140 llvm::FoldingSetNodeID ID; 4141 DependentSizedMatrixType::Profile(ID, *this, CanonElementTy, RowExpr, 4142 ColumnExpr); 4143 4144 void *InsertPos = nullptr; 4145 DependentSizedMatrixType *Canon = 4146 DependentSizedMatrixTypes.FindNodeOrInsertPos(ID, InsertPos); 4147 4148 if (!Canon) { 4149 Canon = new (*this, TypeAlignment) DependentSizedMatrixType( 4150 *this, CanonElementTy, QualType(), RowExpr, ColumnExpr, AttrLoc); 4151 #ifndef NDEBUG 4152 DependentSizedMatrixType *CanonCheck = 4153 DependentSizedMatrixTypes.FindNodeOrInsertPos(ID, InsertPos); 4154 assert(!CanonCheck && "Dependent-sized matrix canonical type broken"); 4155 #endif 4156 DependentSizedMatrixTypes.InsertNode(Canon, InsertPos); 4157 Types.push_back(Canon); 4158 } 4159 4160 // Already have a canonical version of the matrix type 4161 // 4162 // If it exactly matches the requested type, use it directly. 4163 if (Canon->getElementType() == ElementTy && Canon->getRowExpr() == RowExpr && 4164 Canon->getRowExpr() == ColumnExpr) 4165 return QualType(Canon, 0); 4166 4167 // Use Canon as the canonical type for newly-built type. 4168 DependentSizedMatrixType *New = new (*this, TypeAlignment) 4169 DependentSizedMatrixType(*this, ElementTy, QualType(Canon, 0), RowExpr, 4170 ColumnExpr, AttrLoc); 4171 Types.push_back(New); 4172 return QualType(New, 0); 4173 } 4174 4175 QualType ASTContext::getDependentAddressSpaceType(QualType PointeeType, 4176 Expr *AddrSpaceExpr, 4177 SourceLocation AttrLoc) const { 4178 assert(AddrSpaceExpr->isInstantiationDependent()); 4179 4180 QualType canonPointeeType = getCanonicalType(PointeeType); 4181 4182 void *insertPos = nullptr; 4183 llvm::FoldingSetNodeID ID; 4184 DependentAddressSpaceType::Profile(ID, *this, canonPointeeType, 4185 AddrSpaceExpr); 4186 4187 DependentAddressSpaceType *canonTy = 4188 DependentAddressSpaceTypes.FindNodeOrInsertPos(ID, insertPos); 4189 4190 if (!canonTy) { 4191 canonTy = new (*this, TypeAlignment) 4192 DependentAddressSpaceType(*this, canonPointeeType, 4193 QualType(), AddrSpaceExpr, AttrLoc); 4194 DependentAddressSpaceTypes.InsertNode(canonTy, insertPos); 4195 Types.push_back(canonTy); 4196 } 4197 4198 if (canonPointeeType == PointeeType && 4199 canonTy->getAddrSpaceExpr() == AddrSpaceExpr) 4200 return QualType(canonTy, 0); 4201 4202 auto *sugaredType 4203 = new (*this, TypeAlignment) 4204 DependentAddressSpaceType(*this, PointeeType, QualType(canonTy, 0), 4205 AddrSpaceExpr, AttrLoc); 4206 Types.push_back(sugaredType); 4207 return QualType(sugaredType, 0); 4208 } 4209 4210 /// Determine whether \p T is canonical as the result type of a function. 4211 static bool isCanonicalResultType(QualType T) { 4212 return T.isCanonical() && 4213 (T.getObjCLifetime() == Qualifiers::OCL_None || 4214 T.getObjCLifetime() == Qualifiers::OCL_ExplicitNone); 4215 } 4216 4217 /// getFunctionNoProtoType - Return a K&R style C function type like 'int()'. 4218 QualType 4219 ASTContext::getFunctionNoProtoType(QualType ResultTy, 4220 const FunctionType::ExtInfo &Info) const { 4221 // Unique functions, to guarantee there is only one function of a particular 4222 // structure. 4223 llvm::FoldingSetNodeID ID; 4224 FunctionNoProtoType::Profile(ID, ResultTy, Info); 4225 4226 void *InsertPos = nullptr; 4227 if (FunctionNoProtoType *FT = 4228 FunctionNoProtoTypes.FindNodeOrInsertPos(ID, InsertPos)) 4229 return QualType(FT, 0); 4230 4231 QualType Canonical; 4232 if (!isCanonicalResultType(ResultTy)) { 4233 Canonical = 4234 getFunctionNoProtoType(getCanonicalFunctionResultType(ResultTy), Info); 4235 4236 // Get the new insert position for the node we care about. 4237 FunctionNoProtoType *NewIP = 4238 FunctionNoProtoTypes.FindNodeOrInsertPos(ID, InsertPos); 4239 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 4240 } 4241 4242 auto *New = new (*this, TypeAlignment) 4243 FunctionNoProtoType(ResultTy, Canonical, Info); 4244 Types.push_back(New); 4245 FunctionNoProtoTypes.InsertNode(New, InsertPos); 4246 return QualType(New, 0); 4247 } 4248 4249 CanQualType 4250 ASTContext::getCanonicalFunctionResultType(QualType ResultType) const { 4251 CanQualType CanResultType = getCanonicalType(ResultType); 4252 4253 // Canonical result types do not have ARC lifetime qualifiers. 4254 if (CanResultType.getQualifiers().hasObjCLifetime()) { 4255 Qualifiers Qs = CanResultType.getQualifiers(); 4256 Qs.removeObjCLifetime(); 4257 return CanQualType::CreateUnsafe( 4258 getQualifiedType(CanResultType.getUnqualifiedType(), Qs)); 4259 } 4260 4261 return CanResultType; 4262 } 4263 4264 static bool isCanonicalExceptionSpecification( 4265 const FunctionProtoType::ExceptionSpecInfo &ESI, bool NoexceptInType) { 4266 if (ESI.Type == EST_None) 4267 return true; 4268 if (!NoexceptInType) 4269 return false; 4270 4271 // C++17 onwards: exception specification is part of the type, as a simple 4272 // boolean "can this function type throw". 4273 if (ESI.Type == EST_BasicNoexcept) 4274 return true; 4275 4276 // A noexcept(expr) specification is (possibly) canonical if expr is 4277 // value-dependent. 4278 if (ESI.Type == EST_DependentNoexcept) 4279 return true; 4280 4281 // A dynamic exception specification is canonical if it only contains pack 4282 // expansions (so we can't tell whether it's non-throwing) and all its 4283 // contained types are canonical. 4284 if (ESI.Type == EST_Dynamic) { 4285 bool AnyPackExpansions = false; 4286 for (QualType ET : ESI.Exceptions) { 4287 if (!ET.isCanonical()) 4288 return false; 4289 if (ET->getAs<PackExpansionType>()) 4290 AnyPackExpansions = true; 4291 } 4292 return AnyPackExpansions; 4293 } 4294 4295 return false; 4296 } 4297 4298 QualType ASTContext::getFunctionTypeInternal( 4299 QualType ResultTy, ArrayRef<QualType> ArgArray, 4300 const FunctionProtoType::ExtProtoInfo &EPI, bool OnlyWantCanonical) const { 4301 size_t NumArgs = ArgArray.size(); 4302 4303 // Unique functions, to guarantee there is only one function of a particular 4304 // structure. 4305 llvm::FoldingSetNodeID ID; 4306 FunctionProtoType::Profile(ID, ResultTy, ArgArray.begin(), NumArgs, EPI, 4307 *this, true); 4308 4309 QualType Canonical; 4310 bool Unique = false; 4311 4312 void *InsertPos = nullptr; 4313 if (FunctionProtoType *FPT = 4314 FunctionProtoTypes.FindNodeOrInsertPos(ID, InsertPos)) { 4315 QualType Existing = QualType(FPT, 0); 4316 4317 // If we find a pre-existing equivalent FunctionProtoType, we can just reuse 4318 // it so long as our exception specification doesn't contain a dependent 4319 // noexcept expression, or we're just looking for a canonical type. 4320 // Otherwise, we're going to need to create a type 4321 // sugar node to hold the concrete expression. 4322 if (OnlyWantCanonical || !isComputedNoexcept(EPI.ExceptionSpec.Type) || 4323 EPI.ExceptionSpec.NoexceptExpr == FPT->getNoexceptExpr()) 4324 return Existing; 4325 4326 // We need a new type sugar node for this one, to hold the new noexcept 4327 // expression. We do no canonicalization here, but that's OK since we don't 4328 // expect to see the same noexcept expression much more than once. 4329 Canonical = getCanonicalType(Existing); 4330 Unique = true; 4331 } 4332 4333 bool NoexceptInType = getLangOpts().CPlusPlus17; 4334 bool IsCanonicalExceptionSpec = 4335 isCanonicalExceptionSpecification(EPI.ExceptionSpec, NoexceptInType); 4336 4337 // Determine whether the type being created is already canonical or not. 4338 bool isCanonical = !Unique && IsCanonicalExceptionSpec && 4339 isCanonicalResultType(ResultTy) && !EPI.HasTrailingReturn; 4340 for (unsigned i = 0; i != NumArgs && isCanonical; ++i) 4341 if (!ArgArray[i].isCanonicalAsParam()) 4342 isCanonical = false; 4343 4344 if (OnlyWantCanonical) 4345 assert(isCanonical && 4346 "given non-canonical parameters constructing canonical type"); 4347 4348 // If this type isn't canonical, get the canonical version of it if we don't 4349 // already have it. The exception spec is only partially part of the 4350 // canonical type, and only in C++17 onwards. 4351 if (!isCanonical && Canonical.isNull()) { 4352 SmallVector<QualType, 16> CanonicalArgs; 4353 CanonicalArgs.reserve(NumArgs); 4354 for (unsigned i = 0; i != NumArgs; ++i) 4355 CanonicalArgs.push_back(getCanonicalParamType(ArgArray[i])); 4356 4357 llvm::SmallVector<QualType, 8> ExceptionTypeStorage; 4358 FunctionProtoType::ExtProtoInfo CanonicalEPI = EPI; 4359 CanonicalEPI.HasTrailingReturn = false; 4360 4361 if (IsCanonicalExceptionSpec) { 4362 // Exception spec is already OK. 4363 } else if (NoexceptInType) { 4364 switch (EPI.ExceptionSpec.Type) { 4365 case EST_Unparsed: case EST_Unevaluated: case EST_Uninstantiated: 4366 // We don't know yet. It shouldn't matter what we pick here; no-one 4367 // should ever look at this. 4368 LLVM_FALLTHROUGH; 4369 case EST_None: case EST_MSAny: case EST_NoexceptFalse: 4370 CanonicalEPI.ExceptionSpec.Type = EST_None; 4371 break; 4372 4373 // A dynamic exception specification is almost always "not noexcept", 4374 // with the exception that a pack expansion might expand to no types. 4375 case EST_Dynamic: { 4376 bool AnyPacks = false; 4377 for (QualType ET : EPI.ExceptionSpec.Exceptions) { 4378 if (ET->getAs<PackExpansionType>()) 4379 AnyPacks = true; 4380 ExceptionTypeStorage.push_back(getCanonicalType(ET)); 4381 } 4382 if (!AnyPacks) 4383 CanonicalEPI.ExceptionSpec.Type = EST_None; 4384 else { 4385 CanonicalEPI.ExceptionSpec.Type = EST_Dynamic; 4386 CanonicalEPI.ExceptionSpec.Exceptions = ExceptionTypeStorage; 4387 } 4388 break; 4389 } 4390 4391 case EST_DynamicNone: 4392 case EST_BasicNoexcept: 4393 case EST_NoexceptTrue: 4394 case EST_NoThrow: 4395 CanonicalEPI.ExceptionSpec.Type = EST_BasicNoexcept; 4396 break; 4397 4398 case EST_DependentNoexcept: 4399 llvm_unreachable("dependent noexcept is already canonical"); 4400 } 4401 } else { 4402 CanonicalEPI.ExceptionSpec = FunctionProtoType::ExceptionSpecInfo(); 4403 } 4404 4405 // Adjust the canonical function result type. 4406 CanQualType CanResultTy = getCanonicalFunctionResultType(ResultTy); 4407 Canonical = 4408 getFunctionTypeInternal(CanResultTy, CanonicalArgs, CanonicalEPI, true); 4409 4410 // Get the new insert position for the node we care about. 4411 FunctionProtoType *NewIP = 4412 FunctionProtoTypes.FindNodeOrInsertPos(ID, InsertPos); 4413 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 4414 } 4415 4416 // Compute the needed size to hold this FunctionProtoType and the 4417 // various trailing objects. 4418 auto ESH = FunctionProtoType::getExceptionSpecSize( 4419 EPI.ExceptionSpec.Type, EPI.ExceptionSpec.Exceptions.size()); 4420 size_t Size = FunctionProtoType::totalSizeToAlloc< 4421 QualType, SourceLocation, FunctionType::FunctionTypeExtraBitfields, 4422 FunctionType::ExceptionType, Expr *, FunctionDecl *, 4423 FunctionProtoType::ExtParameterInfo, Qualifiers>( 4424 NumArgs, EPI.Variadic, 4425 FunctionProtoType::hasExtraBitfields(EPI.ExceptionSpec.Type), 4426 ESH.NumExceptionType, ESH.NumExprPtr, ESH.NumFunctionDeclPtr, 4427 EPI.ExtParameterInfos ? NumArgs : 0, 4428 EPI.TypeQuals.hasNonFastQualifiers() ? 1 : 0); 4429 4430 auto *FTP = (FunctionProtoType *)Allocate(Size, TypeAlignment); 4431 FunctionProtoType::ExtProtoInfo newEPI = EPI; 4432 new (FTP) FunctionProtoType(ResultTy, ArgArray, Canonical, newEPI); 4433 Types.push_back(FTP); 4434 if (!Unique) 4435 FunctionProtoTypes.InsertNode(FTP, InsertPos); 4436 return QualType(FTP, 0); 4437 } 4438 4439 QualType ASTContext::getPipeType(QualType T, bool ReadOnly) const { 4440 llvm::FoldingSetNodeID ID; 4441 PipeType::Profile(ID, T, ReadOnly); 4442 4443 void *InsertPos = nullptr; 4444 if (PipeType *PT = PipeTypes.FindNodeOrInsertPos(ID, InsertPos)) 4445 return QualType(PT, 0); 4446 4447 // If the pipe element type isn't canonical, this won't be a canonical type 4448 // either, so fill in the canonical type field. 4449 QualType Canonical; 4450 if (!T.isCanonical()) { 4451 Canonical = getPipeType(getCanonicalType(T), ReadOnly); 4452 4453 // Get the new insert position for the node we care about. 4454 PipeType *NewIP = PipeTypes.FindNodeOrInsertPos(ID, InsertPos); 4455 assert(!NewIP && "Shouldn't be in the map!"); 4456 (void)NewIP; 4457 } 4458 auto *New = new (*this, TypeAlignment) PipeType(T, Canonical, ReadOnly); 4459 Types.push_back(New); 4460 PipeTypes.InsertNode(New, InsertPos); 4461 return QualType(New, 0); 4462 } 4463 4464 QualType ASTContext::adjustStringLiteralBaseType(QualType Ty) const { 4465 // OpenCL v1.1 s6.5.3: a string literal is in the constant address space. 4466 return LangOpts.OpenCL ? getAddrSpaceQualType(Ty, LangAS::opencl_constant) 4467 : Ty; 4468 } 4469 4470 QualType ASTContext::getReadPipeType(QualType T) const { 4471 return getPipeType(T, true); 4472 } 4473 4474 QualType ASTContext::getWritePipeType(QualType T) const { 4475 return getPipeType(T, false); 4476 } 4477 4478 QualType ASTContext::getExtIntType(bool IsUnsigned, unsigned NumBits) const { 4479 llvm::FoldingSetNodeID ID; 4480 ExtIntType::Profile(ID, IsUnsigned, NumBits); 4481 4482 void *InsertPos = nullptr; 4483 if (ExtIntType *EIT = ExtIntTypes.FindNodeOrInsertPos(ID, InsertPos)) 4484 return QualType(EIT, 0); 4485 4486 auto *New = new (*this, TypeAlignment) ExtIntType(IsUnsigned, NumBits); 4487 ExtIntTypes.InsertNode(New, InsertPos); 4488 Types.push_back(New); 4489 return QualType(New, 0); 4490 } 4491 4492 QualType ASTContext::getDependentExtIntType(bool IsUnsigned, 4493 Expr *NumBitsExpr) const { 4494 assert(NumBitsExpr->isInstantiationDependent() && "Only good for dependent"); 4495 llvm::FoldingSetNodeID ID; 4496 DependentExtIntType::Profile(ID, *this, IsUnsigned, NumBitsExpr); 4497 4498 void *InsertPos = nullptr; 4499 if (DependentExtIntType *Existing = 4500 DependentExtIntTypes.FindNodeOrInsertPos(ID, InsertPos)) 4501 return QualType(Existing, 0); 4502 4503 auto *New = new (*this, TypeAlignment) 4504 DependentExtIntType(*this, IsUnsigned, NumBitsExpr); 4505 DependentExtIntTypes.InsertNode(New, InsertPos); 4506 4507 Types.push_back(New); 4508 return QualType(New, 0); 4509 } 4510 4511 #ifndef NDEBUG 4512 static bool NeedsInjectedClassNameType(const RecordDecl *D) { 4513 if (!isa<CXXRecordDecl>(D)) return false; 4514 const auto *RD = cast<CXXRecordDecl>(D); 4515 if (isa<ClassTemplatePartialSpecializationDecl>(RD)) 4516 return true; 4517 if (RD->getDescribedClassTemplate() && 4518 !isa<ClassTemplateSpecializationDecl>(RD)) 4519 return true; 4520 return false; 4521 } 4522 #endif 4523 4524 /// getInjectedClassNameType - Return the unique reference to the 4525 /// injected class name type for the specified templated declaration. 4526 QualType ASTContext::getInjectedClassNameType(CXXRecordDecl *Decl, 4527 QualType TST) const { 4528 assert(NeedsInjectedClassNameType(Decl)); 4529 if (Decl->TypeForDecl) { 4530 assert(isa<InjectedClassNameType>(Decl->TypeForDecl)); 4531 } else if (CXXRecordDecl *PrevDecl = Decl->getPreviousDecl()) { 4532 assert(PrevDecl->TypeForDecl && "previous declaration has no type"); 4533 Decl->TypeForDecl = PrevDecl->TypeForDecl; 4534 assert(isa<InjectedClassNameType>(Decl->TypeForDecl)); 4535 } else { 4536 Type *newType = 4537 new (*this, TypeAlignment) InjectedClassNameType(Decl, TST); 4538 Decl->TypeForDecl = newType; 4539 Types.push_back(newType); 4540 } 4541 return QualType(Decl->TypeForDecl, 0); 4542 } 4543 4544 /// getTypeDeclType - Return the unique reference to the type for the 4545 /// specified type declaration. 4546 QualType ASTContext::getTypeDeclTypeSlow(const TypeDecl *Decl) const { 4547 assert(Decl && "Passed null for Decl param"); 4548 assert(!Decl->TypeForDecl && "TypeForDecl present in slow case"); 4549 4550 if (const auto *Typedef = dyn_cast<TypedefNameDecl>(Decl)) 4551 return getTypedefType(Typedef); 4552 4553 assert(!isa<TemplateTypeParmDecl>(Decl) && 4554 "Template type parameter types are always available."); 4555 4556 if (const auto *Record = dyn_cast<RecordDecl>(Decl)) { 4557 assert(Record->isFirstDecl() && "struct/union has previous declaration"); 4558 assert(!NeedsInjectedClassNameType(Record)); 4559 return getRecordType(Record); 4560 } else if (const auto *Enum = dyn_cast<EnumDecl>(Decl)) { 4561 assert(Enum->isFirstDecl() && "enum has previous declaration"); 4562 return getEnumType(Enum); 4563 } else if (const auto *Using = dyn_cast<UnresolvedUsingTypenameDecl>(Decl)) { 4564 Type *newType = new (*this, TypeAlignment) UnresolvedUsingType(Using); 4565 Decl->TypeForDecl = newType; 4566 Types.push_back(newType); 4567 } else 4568 llvm_unreachable("TypeDecl without a type?"); 4569 4570 return QualType(Decl->TypeForDecl, 0); 4571 } 4572 4573 /// getTypedefType - Return the unique reference to the type for the 4574 /// specified typedef name decl. 4575 QualType ASTContext::getTypedefType(const TypedefNameDecl *Decl, 4576 QualType Underlying) const { 4577 if (Decl->TypeForDecl) return QualType(Decl->TypeForDecl, 0); 4578 4579 if (Underlying.isNull()) 4580 Underlying = Decl->getUnderlyingType(); 4581 QualType Canonical = getCanonicalType(Underlying); 4582 auto *newType = new (*this, TypeAlignment) 4583 TypedefType(Type::Typedef, Decl, Underlying, Canonical); 4584 Decl->TypeForDecl = newType; 4585 Types.push_back(newType); 4586 return QualType(newType, 0); 4587 } 4588 4589 QualType ASTContext::getRecordType(const RecordDecl *Decl) const { 4590 if (Decl->TypeForDecl) return QualType(Decl->TypeForDecl, 0); 4591 4592 if (const RecordDecl *PrevDecl = Decl->getPreviousDecl()) 4593 if (PrevDecl->TypeForDecl) 4594 return QualType(Decl->TypeForDecl = PrevDecl->TypeForDecl, 0); 4595 4596 auto *newType = new (*this, TypeAlignment) RecordType(Decl); 4597 Decl->TypeForDecl = newType; 4598 Types.push_back(newType); 4599 return QualType(newType, 0); 4600 } 4601 4602 QualType ASTContext::getEnumType(const EnumDecl *Decl) const { 4603 if (Decl->TypeForDecl) return QualType(Decl->TypeForDecl, 0); 4604 4605 if (const EnumDecl *PrevDecl = Decl->getPreviousDecl()) 4606 if (PrevDecl->TypeForDecl) 4607 return QualType(Decl->TypeForDecl = PrevDecl->TypeForDecl, 0); 4608 4609 auto *newType = new (*this, TypeAlignment) EnumType(Decl); 4610 Decl->TypeForDecl = newType; 4611 Types.push_back(newType); 4612 return QualType(newType, 0); 4613 } 4614 4615 QualType ASTContext::getAttributedType(attr::Kind attrKind, 4616 QualType modifiedType, 4617 QualType equivalentType) { 4618 llvm::FoldingSetNodeID id; 4619 AttributedType::Profile(id, attrKind, modifiedType, equivalentType); 4620 4621 void *insertPos = nullptr; 4622 AttributedType *type = AttributedTypes.FindNodeOrInsertPos(id, insertPos); 4623 if (type) return QualType(type, 0); 4624 4625 QualType canon = getCanonicalType(equivalentType); 4626 type = new (*this, TypeAlignment) 4627 AttributedType(canon, attrKind, modifiedType, equivalentType); 4628 4629 Types.push_back(type); 4630 AttributedTypes.InsertNode(type, insertPos); 4631 4632 return QualType(type, 0); 4633 } 4634 4635 /// Retrieve a substitution-result type. 4636 QualType 4637 ASTContext::getSubstTemplateTypeParmType(const TemplateTypeParmType *Parm, 4638 QualType Replacement) const { 4639 assert(Replacement.isCanonical() 4640 && "replacement types must always be canonical"); 4641 4642 llvm::FoldingSetNodeID ID; 4643 SubstTemplateTypeParmType::Profile(ID, Parm, Replacement); 4644 void *InsertPos = nullptr; 4645 SubstTemplateTypeParmType *SubstParm 4646 = SubstTemplateTypeParmTypes.FindNodeOrInsertPos(ID, InsertPos); 4647 4648 if (!SubstParm) { 4649 SubstParm = new (*this, TypeAlignment) 4650 SubstTemplateTypeParmType(Parm, Replacement); 4651 Types.push_back(SubstParm); 4652 SubstTemplateTypeParmTypes.InsertNode(SubstParm, InsertPos); 4653 } 4654 4655 return QualType(SubstParm, 0); 4656 } 4657 4658 /// Retrieve a 4659 QualType ASTContext::getSubstTemplateTypeParmPackType( 4660 const TemplateTypeParmType *Parm, 4661 const TemplateArgument &ArgPack) { 4662 #ifndef NDEBUG 4663 for (const auto &P : ArgPack.pack_elements()) { 4664 assert(P.getKind() == TemplateArgument::Type &&"Pack contains a non-type"); 4665 assert(P.getAsType().isCanonical() && "Pack contains non-canonical type"); 4666 } 4667 #endif 4668 4669 llvm::FoldingSetNodeID ID; 4670 SubstTemplateTypeParmPackType::Profile(ID, Parm, ArgPack); 4671 void *InsertPos = nullptr; 4672 if (SubstTemplateTypeParmPackType *SubstParm 4673 = SubstTemplateTypeParmPackTypes.FindNodeOrInsertPos(ID, InsertPos)) 4674 return QualType(SubstParm, 0); 4675 4676 QualType Canon; 4677 if (!Parm->isCanonicalUnqualified()) { 4678 Canon = getCanonicalType(QualType(Parm, 0)); 4679 Canon = getSubstTemplateTypeParmPackType(cast<TemplateTypeParmType>(Canon), 4680 ArgPack); 4681 SubstTemplateTypeParmPackTypes.FindNodeOrInsertPos(ID, InsertPos); 4682 } 4683 4684 auto *SubstParm 4685 = new (*this, TypeAlignment) SubstTemplateTypeParmPackType(Parm, Canon, 4686 ArgPack); 4687 Types.push_back(SubstParm); 4688 SubstTemplateTypeParmPackTypes.InsertNode(SubstParm, InsertPos); 4689 return QualType(SubstParm, 0); 4690 } 4691 4692 /// Retrieve the template type parameter type for a template 4693 /// parameter or parameter pack with the given depth, index, and (optionally) 4694 /// name. 4695 QualType ASTContext::getTemplateTypeParmType(unsigned Depth, unsigned Index, 4696 bool ParameterPack, 4697 TemplateTypeParmDecl *TTPDecl) const { 4698 llvm::FoldingSetNodeID ID; 4699 TemplateTypeParmType::Profile(ID, Depth, Index, ParameterPack, TTPDecl); 4700 void *InsertPos = nullptr; 4701 TemplateTypeParmType *TypeParm 4702 = TemplateTypeParmTypes.FindNodeOrInsertPos(ID, InsertPos); 4703 4704 if (TypeParm) 4705 return QualType(TypeParm, 0); 4706 4707 if (TTPDecl) { 4708 QualType Canon = getTemplateTypeParmType(Depth, Index, ParameterPack); 4709 TypeParm = new (*this, TypeAlignment) TemplateTypeParmType(TTPDecl, Canon); 4710 4711 TemplateTypeParmType *TypeCheck 4712 = TemplateTypeParmTypes.FindNodeOrInsertPos(ID, InsertPos); 4713 assert(!TypeCheck && "Template type parameter canonical type broken"); 4714 (void)TypeCheck; 4715 } else 4716 TypeParm = new (*this, TypeAlignment) 4717 TemplateTypeParmType(Depth, Index, ParameterPack); 4718 4719 Types.push_back(TypeParm); 4720 TemplateTypeParmTypes.InsertNode(TypeParm, InsertPos); 4721 4722 return QualType(TypeParm, 0); 4723 } 4724 4725 TypeSourceInfo * 4726 ASTContext::getTemplateSpecializationTypeInfo(TemplateName Name, 4727 SourceLocation NameLoc, 4728 const TemplateArgumentListInfo &Args, 4729 QualType Underlying) const { 4730 assert(!Name.getAsDependentTemplateName() && 4731 "No dependent template names here!"); 4732 QualType TST = getTemplateSpecializationType(Name, Args, Underlying); 4733 4734 TypeSourceInfo *DI = CreateTypeSourceInfo(TST); 4735 TemplateSpecializationTypeLoc TL = 4736 DI->getTypeLoc().castAs<TemplateSpecializationTypeLoc>(); 4737 TL.setTemplateKeywordLoc(SourceLocation()); 4738 TL.setTemplateNameLoc(NameLoc); 4739 TL.setLAngleLoc(Args.getLAngleLoc()); 4740 TL.setRAngleLoc(Args.getRAngleLoc()); 4741 for (unsigned i = 0, e = TL.getNumArgs(); i != e; ++i) 4742 TL.setArgLocInfo(i, Args[i].getLocInfo()); 4743 return DI; 4744 } 4745 4746 QualType 4747 ASTContext::getTemplateSpecializationType(TemplateName Template, 4748 const TemplateArgumentListInfo &Args, 4749 QualType Underlying) const { 4750 assert(!Template.getAsDependentTemplateName() && 4751 "No dependent template names here!"); 4752 4753 SmallVector<TemplateArgument, 4> ArgVec; 4754 ArgVec.reserve(Args.size()); 4755 for (const TemplateArgumentLoc &Arg : Args.arguments()) 4756 ArgVec.push_back(Arg.getArgument()); 4757 4758 return getTemplateSpecializationType(Template, ArgVec, Underlying); 4759 } 4760 4761 #ifndef NDEBUG 4762 static bool hasAnyPackExpansions(ArrayRef<TemplateArgument> Args) { 4763 for (const TemplateArgument &Arg : Args) 4764 if (Arg.isPackExpansion()) 4765 return true; 4766 4767 return true; 4768 } 4769 #endif 4770 4771 QualType 4772 ASTContext::getTemplateSpecializationType(TemplateName Template, 4773 ArrayRef<TemplateArgument> Args, 4774 QualType Underlying) const { 4775 assert(!Template.getAsDependentTemplateName() && 4776 "No dependent template names here!"); 4777 // Look through qualified template names. 4778 if (QualifiedTemplateName *QTN = Template.getAsQualifiedTemplateName()) 4779 Template = TemplateName(QTN->getTemplateDecl()); 4780 4781 bool IsTypeAlias = 4782 Template.getAsTemplateDecl() && 4783 isa<TypeAliasTemplateDecl>(Template.getAsTemplateDecl()); 4784 QualType CanonType; 4785 if (!Underlying.isNull()) 4786 CanonType = getCanonicalType(Underlying); 4787 else { 4788 // We can get here with an alias template when the specialization contains 4789 // a pack expansion that does not match up with a parameter pack. 4790 assert((!IsTypeAlias || hasAnyPackExpansions(Args)) && 4791 "Caller must compute aliased type"); 4792 IsTypeAlias = false; 4793 CanonType = getCanonicalTemplateSpecializationType(Template, Args); 4794 } 4795 4796 // Allocate the (non-canonical) template specialization type, but don't 4797 // try to unique it: these types typically have location information that 4798 // we don't unique and don't want to lose. 4799 void *Mem = Allocate(sizeof(TemplateSpecializationType) + 4800 sizeof(TemplateArgument) * Args.size() + 4801 (IsTypeAlias? sizeof(QualType) : 0), 4802 TypeAlignment); 4803 auto *Spec 4804 = new (Mem) TemplateSpecializationType(Template, Args, CanonType, 4805 IsTypeAlias ? Underlying : QualType()); 4806 4807 Types.push_back(Spec); 4808 return QualType(Spec, 0); 4809 } 4810 4811 QualType ASTContext::getCanonicalTemplateSpecializationType( 4812 TemplateName Template, ArrayRef<TemplateArgument> Args) const { 4813 assert(!Template.getAsDependentTemplateName() && 4814 "No dependent template names here!"); 4815 4816 // Look through qualified template names. 4817 if (QualifiedTemplateName *QTN = Template.getAsQualifiedTemplateName()) 4818 Template = TemplateName(QTN->getTemplateDecl()); 4819 4820 // Build the canonical template specialization type. 4821 TemplateName CanonTemplate = getCanonicalTemplateName(Template); 4822 SmallVector<TemplateArgument, 4> CanonArgs; 4823 unsigned NumArgs = Args.size(); 4824 CanonArgs.reserve(NumArgs); 4825 for (const TemplateArgument &Arg : Args) 4826 CanonArgs.push_back(getCanonicalTemplateArgument(Arg)); 4827 4828 // Determine whether this canonical template specialization type already 4829 // exists. 4830 llvm::FoldingSetNodeID ID; 4831 TemplateSpecializationType::Profile(ID, CanonTemplate, 4832 CanonArgs, *this); 4833 4834 void *InsertPos = nullptr; 4835 TemplateSpecializationType *Spec 4836 = TemplateSpecializationTypes.FindNodeOrInsertPos(ID, InsertPos); 4837 4838 if (!Spec) { 4839 // Allocate a new canonical template specialization type. 4840 void *Mem = Allocate((sizeof(TemplateSpecializationType) + 4841 sizeof(TemplateArgument) * NumArgs), 4842 TypeAlignment); 4843 Spec = new (Mem) TemplateSpecializationType(CanonTemplate, 4844 CanonArgs, 4845 QualType(), QualType()); 4846 Types.push_back(Spec); 4847 TemplateSpecializationTypes.InsertNode(Spec, InsertPos); 4848 } 4849 4850 assert(Spec->isDependentType() && 4851 "Non-dependent template-id type must have a canonical type"); 4852 return QualType(Spec, 0); 4853 } 4854 4855 QualType ASTContext::getElaboratedType(ElaboratedTypeKeyword Keyword, 4856 NestedNameSpecifier *NNS, 4857 QualType NamedType, 4858 TagDecl *OwnedTagDecl) const { 4859 llvm::FoldingSetNodeID ID; 4860 ElaboratedType::Profile(ID, Keyword, NNS, NamedType, OwnedTagDecl); 4861 4862 void *InsertPos = nullptr; 4863 ElaboratedType *T = ElaboratedTypes.FindNodeOrInsertPos(ID, InsertPos); 4864 if (T) 4865 return QualType(T, 0); 4866 4867 QualType Canon = NamedType; 4868 if (!Canon.isCanonical()) { 4869 Canon = getCanonicalType(NamedType); 4870 ElaboratedType *CheckT = ElaboratedTypes.FindNodeOrInsertPos(ID, InsertPos); 4871 assert(!CheckT && "Elaborated canonical type broken"); 4872 (void)CheckT; 4873 } 4874 4875 void *Mem = Allocate(ElaboratedType::totalSizeToAlloc<TagDecl *>(!!OwnedTagDecl), 4876 TypeAlignment); 4877 T = new (Mem) ElaboratedType(Keyword, NNS, NamedType, Canon, OwnedTagDecl); 4878 4879 Types.push_back(T); 4880 ElaboratedTypes.InsertNode(T, InsertPos); 4881 return QualType(T, 0); 4882 } 4883 4884 QualType 4885 ASTContext::getParenType(QualType InnerType) const { 4886 llvm::FoldingSetNodeID ID; 4887 ParenType::Profile(ID, InnerType); 4888 4889 void *InsertPos = nullptr; 4890 ParenType *T = ParenTypes.FindNodeOrInsertPos(ID, InsertPos); 4891 if (T) 4892 return QualType(T, 0); 4893 4894 QualType Canon = InnerType; 4895 if (!Canon.isCanonical()) { 4896 Canon = getCanonicalType(InnerType); 4897 ParenType *CheckT = ParenTypes.FindNodeOrInsertPos(ID, InsertPos); 4898 assert(!CheckT && "Paren canonical type broken"); 4899 (void)CheckT; 4900 } 4901 4902 T = new (*this, TypeAlignment) ParenType(InnerType, Canon); 4903 Types.push_back(T); 4904 ParenTypes.InsertNode(T, InsertPos); 4905 return QualType(T, 0); 4906 } 4907 4908 QualType 4909 ASTContext::getMacroQualifiedType(QualType UnderlyingTy, 4910 const IdentifierInfo *MacroII) const { 4911 QualType Canon = UnderlyingTy; 4912 if (!Canon.isCanonical()) 4913 Canon = getCanonicalType(UnderlyingTy); 4914 4915 auto *newType = new (*this, TypeAlignment) 4916 MacroQualifiedType(UnderlyingTy, Canon, MacroII); 4917 Types.push_back(newType); 4918 return QualType(newType, 0); 4919 } 4920 4921 QualType ASTContext::getDependentNameType(ElaboratedTypeKeyword Keyword, 4922 NestedNameSpecifier *NNS, 4923 const IdentifierInfo *Name, 4924 QualType Canon) const { 4925 if (Canon.isNull()) { 4926 NestedNameSpecifier *CanonNNS = getCanonicalNestedNameSpecifier(NNS); 4927 if (CanonNNS != NNS) 4928 Canon = getDependentNameType(Keyword, CanonNNS, Name); 4929 } 4930 4931 llvm::FoldingSetNodeID ID; 4932 DependentNameType::Profile(ID, Keyword, NNS, Name); 4933 4934 void *InsertPos = nullptr; 4935 DependentNameType *T 4936 = DependentNameTypes.FindNodeOrInsertPos(ID, InsertPos); 4937 if (T) 4938 return QualType(T, 0); 4939 4940 T = new (*this, TypeAlignment) DependentNameType(Keyword, NNS, Name, Canon); 4941 Types.push_back(T); 4942 DependentNameTypes.InsertNode(T, InsertPos); 4943 return QualType(T, 0); 4944 } 4945 4946 QualType 4947 ASTContext::getDependentTemplateSpecializationType( 4948 ElaboratedTypeKeyword Keyword, 4949 NestedNameSpecifier *NNS, 4950 const IdentifierInfo *Name, 4951 const TemplateArgumentListInfo &Args) const { 4952 // TODO: avoid this copy 4953 SmallVector<TemplateArgument, 16> ArgCopy; 4954 for (unsigned I = 0, E = Args.size(); I != E; ++I) 4955 ArgCopy.push_back(Args[I].getArgument()); 4956 return getDependentTemplateSpecializationType(Keyword, NNS, Name, ArgCopy); 4957 } 4958 4959 QualType 4960 ASTContext::getDependentTemplateSpecializationType( 4961 ElaboratedTypeKeyword Keyword, 4962 NestedNameSpecifier *NNS, 4963 const IdentifierInfo *Name, 4964 ArrayRef<TemplateArgument> Args) const { 4965 assert((!NNS || NNS->isDependent()) && 4966 "nested-name-specifier must be dependent"); 4967 4968 llvm::FoldingSetNodeID ID; 4969 DependentTemplateSpecializationType::Profile(ID, *this, Keyword, NNS, 4970 Name, Args); 4971 4972 void *InsertPos = nullptr; 4973 DependentTemplateSpecializationType *T 4974 = DependentTemplateSpecializationTypes.FindNodeOrInsertPos(ID, InsertPos); 4975 if (T) 4976 return QualType(T, 0); 4977 4978 NestedNameSpecifier *CanonNNS = getCanonicalNestedNameSpecifier(NNS); 4979 4980 ElaboratedTypeKeyword CanonKeyword = Keyword; 4981 if (Keyword == ETK_None) CanonKeyword = ETK_Typename; 4982 4983 bool AnyNonCanonArgs = false; 4984 unsigned NumArgs = Args.size(); 4985 SmallVector<TemplateArgument, 16> CanonArgs(NumArgs); 4986 for (unsigned I = 0; I != NumArgs; ++I) { 4987 CanonArgs[I] = getCanonicalTemplateArgument(Args[I]); 4988 if (!CanonArgs[I].structurallyEquals(Args[I])) 4989 AnyNonCanonArgs = true; 4990 } 4991 4992 QualType Canon; 4993 if (AnyNonCanonArgs || CanonNNS != NNS || CanonKeyword != Keyword) { 4994 Canon = getDependentTemplateSpecializationType(CanonKeyword, CanonNNS, 4995 Name, 4996 CanonArgs); 4997 4998 // Find the insert position again. 4999 DependentTemplateSpecializationTypes.FindNodeOrInsertPos(ID, InsertPos); 5000 } 5001 5002 void *Mem = Allocate((sizeof(DependentTemplateSpecializationType) + 5003 sizeof(TemplateArgument) * NumArgs), 5004 TypeAlignment); 5005 T = new (Mem) DependentTemplateSpecializationType(Keyword, NNS, 5006 Name, Args, Canon); 5007 Types.push_back(T); 5008 DependentTemplateSpecializationTypes.InsertNode(T, InsertPos); 5009 return QualType(T, 0); 5010 } 5011 5012 TemplateArgument ASTContext::getInjectedTemplateArg(NamedDecl *Param) { 5013 TemplateArgument Arg; 5014 if (const auto *TTP = dyn_cast<TemplateTypeParmDecl>(Param)) { 5015 QualType ArgType = getTypeDeclType(TTP); 5016 if (TTP->isParameterPack()) 5017 ArgType = getPackExpansionType(ArgType, None); 5018 5019 Arg = TemplateArgument(ArgType); 5020 } else if (auto *NTTP = dyn_cast<NonTypeTemplateParmDecl>(Param)) { 5021 QualType T = 5022 NTTP->getType().getNonPackExpansionType().getNonLValueExprType(*this); 5023 // For class NTTPs, ensure we include the 'const' so the type matches that 5024 // of a real template argument. 5025 // FIXME: It would be more faithful to model this as something like an 5026 // lvalue-to-rvalue conversion applied to a const-qualified lvalue. 5027 if (T->isRecordType()) 5028 T.addConst(); 5029 Expr *E = new (*this) DeclRefExpr( 5030 *this, NTTP, /*enclosing*/ false, T, 5031 Expr::getValueKindForType(NTTP->getType()), NTTP->getLocation()); 5032 5033 if (NTTP->isParameterPack()) 5034 E = new (*this) PackExpansionExpr(DependentTy, E, NTTP->getLocation(), 5035 None); 5036 Arg = TemplateArgument(E); 5037 } else { 5038 auto *TTP = cast<TemplateTemplateParmDecl>(Param); 5039 if (TTP->isParameterPack()) 5040 Arg = TemplateArgument(TemplateName(TTP), Optional<unsigned>()); 5041 else 5042 Arg = TemplateArgument(TemplateName(TTP)); 5043 } 5044 5045 if (Param->isTemplateParameterPack()) 5046 Arg = TemplateArgument::CreatePackCopy(*this, Arg); 5047 5048 return Arg; 5049 } 5050 5051 void 5052 ASTContext::getInjectedTemplateArgs(const TemplateParameterList *Params, 5053 SmallVectorImpl<TemplateArgument> &Args) { 5054 Args.reserve(Args.size() + Params->size()); 5055 5056 for (NamedDecl *Param : *Params) 5057 Args.push_back(getInjectedTemplateArg(Param)); 5058 } 5059 5060 QualType ASTContext::getPackExpansionType(QualType Pattern, 5061 Optional<unsigned> NumExpansions, 5062 bool ExpectPackInType) { 5063 assert((!ExpectPackInType || Pattern->containsUnexpandedParameterPack()) && 5064 "Pack expansions must expand one or more parameter packs"); 5065 5066 llvm::FoldingSetNodeID ID; 5067 PackExpansionType::Profile(ID, Pattern, NumExpansions); 5068 5069 void *InsertPos = nullptr; 5070 PackExpansionType *T = PackExpansionTypes.FindNodeOrInsertPos(ID, InsertPos); 5071 if (T) 5072 return QualType(T, 0); 5073 5074 QualType Canon; 5075 if (!Pattern.isCanonical()) { 5076 Canon = getPackExpansionType(getCanonicalType(Pattern), NumExpansions, 5077 /*ExpectPackInType=*/false); 5078 5079 // Find the insert position again, in case we inserted an element into 5080 // PackExpansionTypes and invalidated our insert position. 5081 PackExpansionTypes.FindNodeOrInsertPos(ID, InsertPos); 5082 } 5083 5084 T = new (*this, TypeAlignment) 5085 PackExpansionType(Pattern, Canon, NumExpansions); 5086 Types.push_back(T); 5087 PackExpansionTypes.InsertNode(T, InsertPos); 5088 return QualType(T, 0); 5089 } 5090 5091 /// CmpProtocolNames - Comparison predicate for sorting protocols 5092 /// alphabetically. 5093 static int CmpProtocolNames(ObjCProtocolDecl *const *LHS, 5094 ObjCProtocolDecl *const *RHS) { 5095 return DeclarationName::compare((*LHS)->getDeclName(), (*RHS)->getDeclName()); 5096 } 5097 5098 static bool areSortedAndUniqued(ArrayRef<ObjCProtocolDecl *> Protocols) { 5099 if (Protocols.empty()) return true; 5100 5101 if (Protocols[0]->getCanonicalDecl() != Protocols[0]) 5102 return false; 5103 5104 for (unsigned i = 1; i != Protocols.size(); ++i) 5105 if (CmpProtocolNames(&Protocols[i - 1], &Protocols[i]) >= 0 || 5106 Protocols[i]->getCanonicalDecl() != Protocols[i]) 5107 return false; 5108 return true; 5109 } 5110 5111 static void 5112 SortAndUniqueProtocols(SmallVectorImpl<ObjCProtocolDecl *> &Protocols) { 5113 // Sort protocols, keyed by name. 5114 llvm::array_pod_sort(Protocols.begin(), Protocols.end(), CmpProtocolNames); 5115 5116 // Canonicalize. 5117 for (ObjCProtocolDecl *&P : Protocols) 5118 P = P->getCanonicalDecl(); 5119 5120 // Remove duplicates. 5121 auto ProtocolsEnd = std::unique(Protocols.begin(), Protocols.end()); 5122 Protocols.erase(ProtocolsEnd, Protocols.end()); 5123 } 5124 5125 QualType ASTContext::getObjCObjectType(QualType BaseType, 5126 ObjCProtocolDecl * const *Protocols, 5127 unsigned NumProtocols) const { 5128 return getObjCObjectType(BaseType, {}, 5129 llvm::makeArrayRef(Protocols, NumProtocols), 5130 /*isKindOf=*/false); 5131 } 5132 5133 QualType ASTContext::getObjCObjectType( 5134 QualType baseType, 5135 ArrayRef<QualType> typeArgs, 5136 ArrayRef<ObjCProtocolDecl *> protocols, 5137 bool isKindOf) const { 5138 // If the base type is an interface and there aren't any protocols or 5139 // type arguments to add, then the interface type will do just fine. 5140 if (typeArgs.empty() && protocols.empty() && !isKindOf && 5141 isa<ObjCInterfaceType>(baseType)) 5142 return baseType; 5143 5144 // Look in the folding set for an existing type. 5145 llvm::FoldingSetNodeID ID; 5146 ObjCObjectTypeImpl::Profile(ID, baseType, typeArgs, protocols, isKindOf); 5147 void *InsertPos = nullptr; 5148 if (ObjCObjectType *QT = ObjCObjectTypes.FindNodeOrInsertPos(ID, InsertPos)) 5149 return QualType(QT, 0); 5150 5151 // Determine the type arguments to be used for canonicalization, 5152 // which may be explicitly specified here or written on the base 5153 // type. 5154 ArrayRef<QualType> effectiveTypeArgs = typeArgs; 5155 if (effectiveTypeArgs.empty()) { 5156 if (const auto *baseObject = baseType->getAs<ObjCObjectType>()) 5157 effectiveTypeArgs = baseObject->getTypeArgs(); 5158 } 5159 5160 // Build the canonical type, which has the canonical base type and a 5161 // sorted-and-uniqued list of protocols and the type arguments 5162 // canonicalized. 5163 QualType canonical; 5164 bool typeArgsAreCanonical = std::all_of(effectiveTypeArgs.begin(), 5165 effectiveTypeArgs.end(), 5166 [&](QualType type) { 5167 return type.isCanonical(); 5168 }); 5169 bool protocolsSorted = areSortedAndUniqued(protocols); 5170 if (!typeArgsAreCanonical || !protocolsSorted || !baseType.isCanonical()) { 5171 // Determine the canonical type arguments. 5172 ArrayRef<QualType> canonTypeArgs; 5173 SmallVector<QualType, 4> canonTypeArgsVec; 5174 if (!typeArgsAreCanonical) { 5175 canonTypeArgsVec.reserve(effectiveTypeArgs.size()); 5176 for (auto typeArg : effectiveTypeArgs) 5177 canonTypeArgsVec.push_back(getCanonicalType(typeArg)); 5178 canonTypeArgs = canonTypeArgsVec; 5179 } else { 5180 canonTypeArgs = effectiveTypeArgs; 5181 } 5182 5183 ArrayRef<ObjCProtocolDecl *> canonProtocols; 5184 SmallVector<ObjCProtocolDecl*, 8> canonProtocolsVec; 5185 if (!protocolsSorted) { 5186 canonProtocolsVec.append(protocols.begin(), protocols.end()); 5187 SortAndUniqueProtocols(canonProtocolsVec); 5188 canonProtocols = canonProtocolsVec; 5189 } else { 5190 canonProtocols = protocols; 5191 } 5192 5193 canonical = getObjCObjectType(getCanonicalType(baseType), canonTypeArgs, 5194 canonProtocols, isKindOf); 5195 5196 // Regenerate InsertPos. 5197 ObjCObjectTypes.FindNodeOrInsertPos(ID, InsertPos); 5198 } 5199 5200 unsigned size = sizeof(ObjCObjectTypeImpl); 5201 size += typeArgs.size() * sizeof(QualType); 5202 size += protocols.size() * sizeof(ObjCProtocolDecl *); 5203 void *mem = Allocate(size, TypeAlignment); 5204 auto *T = 5205 new (mem) ObjCObjectTypeImpl(canonical, baseType, typeArgs, protocols, 5206 isKindOf); 5207 5208 Types.push_back(T); 5209 ObjCObjectTypes.InsertNode(T, InsertPos); 5210 return QualType(T, 0); 5211 } 5212 5213 /// Apply Objective-C protocol qualifiers to the given type. 5214 /// If this is for the canonical type of a type parameter, we can apply 5215 /// protocol qualifiers on the ObjCObjectPointerType. 5216 QualType 5217 ASTContext::applyObjCProtocolQualifiers(QualType type, 5218 ArrayRef<ObjCProtocolDecl *> protocols, bool &hasError, 5219 bool allowOnPointerType) const { 5220 hasError = false; 5221 5222 if (const auto *objT = dyn_cast<ObjCTypeParamType>(type.getTypePtr())) { 5223 return getObjCTypeParamType(objT->getDecl(), protocols); 5224 } 5225 5226 // Apply protocol qualifiers to ObjCObjectPointerType. 5227 if (allowOnPointerType) { 5228 if (const auto *objPtr = 5229 dyn_cast<ObjCObjectPointerType>(type.getTypePtr())) { 5230 const ObjCObjectType *objT = objPtr->getObjectType(); 5231 // Merge protocol lists and construct ObjCObjectType. 5232 SmallVector<ObjCProtocolDecl*, 8> protocolsVec; 5233 protocolsVec.append(objT->qual_begin(), 5234 objT->qual_end()); 5235 protocolsVec.append(protocols.begin(), protocols.end()); 5236 ArrayRef<ObjCProtocolDecl *> protocols = protocolsVec; 5237 type = getObjCObjectType( 5238 objT->getBaseType(), 5239 objT->getTypeArgsAsWritten(), 5240 protocols, 5241 objT->isKindOfTypeAsWritten()); 5242 return getObjCObjectPointerType(type); 5243 } 5244 } 5245 5246 // Apply protocol qualifiers to ObjCObjectType. 5247 if (const auto *objT = dyn_cast<ObjCObjectType>(type.getTypePtr())){ 5248 // FIXME: Check for protocols to which the class type is already 5249 // known to conform. 5250 5251 return getObjCObjectType(objT->getBaseType(), 5252 objT->getTypeArgsAsWritten(), 5253 protocols, 5254 objT->isKindOfTypeAsWritten()); 5255 } 5256 5257 // If the canonical type is ObjCObjectType, ... 5258 if (type->isObjCObjectType()) { 5259 // Silently overwrite any existing protocol qualifiers. 5260 // TODO: determine whether that's the right thing to do. 5261 5262 // FIXME: Check for protocols to which the class type is already 5263 // known to conform. 5264 return getObjCObjectType(type, {}, protocols, false); 5265 } 5266 5267 // id<protocol-list> 5268 if (type->isObjCIdType()) { 5269 const auto *objPtr = type->castAs<ObjCObjectPointerType>(); 5270 type = getObjCObjectType(ObjCBuiltinIdTy, {}, protocols, 5271 objPtr->isKindOfType()); 5272 return getObjCObjectPointerType(type); 5273 } 5274 5275 // Class<protocol-list> 5276 if (type->isObjCClassType()) { 5277 const auto *objPtr = type->castAs<ObjCObjectPointerType>(); 5278 type = getObjCObjectType(ObjCBuiltinClassTy, {}, protocols, 5279 objPtr->isKindOfType()); 5280 return getObjCObjectPointerType(type); 5281 } 5282 5283 hasError = true; 5284 return type; 5285 } 5286 5287 QualType 5288 ASTContext::getObjCTypeParamType(const ObjCTypeParamDecl *Decl, 5289 ArrayRef<ObjCProtocolDecl *> protocols) const { 5290 // Look in the folding set for an existing type. 5291 llvm::FoldingSetNodeID ID; 5292 ObjCTypeParamType::Profile(ID, Decl, Decl->getUnderlyingType(), protocols); 5293 void *InsertPos = nullptr; 5294 if (ObjCTypeParamType *TypeParam = 5295 ObjCTypeParamTypes.FindNodeOrInsertPos(ID, InsertPos)) 5296 return QualType(TypeParam, 0); 5297 5298 // We canonicalize to the underlying type. 5299 QualType Canonical = getCanonicalType(Decl->getUnderlyingType()); 5300 if (!protocols.empty()) { 5301 // Apply the protocol qualifers. 5302 bool hasError; 5303 Canonical = getCanonicalType(applyObjCProtocolQualifiers( 5304 Canonical, protocols, hasError, true /*allowOnPointerType*/)); 5305 assert(!hasError && "Error when apply protocol qualifier to bound type"); 5306 } 5307 5308 unsigned size = sizeof(ObjCTypeParamType); 5309 size += protocols.size() * sizeof(ObjCProtocolDecl *); 5310 void *mem = Allocate(size, TypeAlignment); 5311 auto *newType = new (mem) ObjCTypeParamType(Decl, Canonical, protocols); 5312 5313 Types.push_back(newType); 5314 ObjCTypeParamTypes.InsertNode(newType, InsertPos); 5315 return QualType(newType, 0); 5316 } 5317 5318 void ASTContext::adjustObjCTypeParamBoundType(const ObjCTypeParamDecl *Orig, 5319 ObjCTypeParamDecl *New) const { 5320 New->setTypeSourceInfo(getTrivialTypeSourceInfo(Orig->getUnderlyingType())); 5321 // Update TypeForDecl after updating TypeSourceInfo. 5322 auto NewTypeParamTy = cast<ObjCTypeParamType>(New->getTypeForDecl()); 5323 SmallVector<ObjCProtocolDecl *, 8> protocols; 5324 protocols.append(NewTypeParamTy->qual_begin(), NewTypeParamTy->qual_end()); 5325 QualType UpdatedTy = getObjCTypeParamType(New, protocols); 5326 New->setTypeForDecl(UpdatedTy.getTypePtr()); 5327 } 5328 5329 /// ObjCObjectAdoptsQTypeProtocols - Checks that protocols in IC's 5330 /// protocol list adopt all protocols in QT's qualified-id protocol 5331 /// list. 5332 bool ASTContext::ObjCObjectAdoptsQTypeProtocols(QualType QT, 5333 ObjCInterfaceDecl *IC) { 5334 if (!QT->isObjCQualifiedIdType()) 5335 return false; 5336 5337 if (const auto *OPT = QT->getAs<ObjCObjectPointerType>()) { 5338 // If both the right and left sides have qualifiers. 5339 for (auto *Proto : OPT->quals()) { 5340 if (!IC->ClassImplementsProtocol(Proto, false)) 5341 return false; 5342 } 5343 return true; 5344 } 5345 return false; 5346 } 5347 5348 /// QIdProtocolsAdoptObjCObjectProtocols - Checks that protocols in 5349 /// QT's qualified-id protocol list adopt all protocols in IDecl's list 5350 /// of protocols. 5351 bool ASTContext::QIdProtocolsAdoptObjCObjectProtocols(QualType QT, 5352 ObjCInterfaceDecl *IDecl) { 5353 if (!QT->isObjCQualifiedIdType()) 5354 return false; 5355 const auto *OPT = QT->getAs<ObjCObjectPointerType>(); 5356 if (!OPT) 5357 return false; 5358 if (!IDecl->hasDefinition()) 5359 return false; 5360 llvm::SmallPtrSet<ObjCProtocolDecl *, 8> InheritedProtocols; 5361 CollectInheritedProtocols(IDecl, InheritedProtocols); 5362 if (InheritedProtocols.empty()) 5363 return false; 5364 // Check that if every protocol in list of id<plist> conforms to a protocol 5365 // of IDecl's, then bridge casting is ok. 5366 bool Conforms = false; 5367 for (auto *Proto : OPT->quals()) { 5368 Conforms = false; 5369 for (auto *PI : InheritedProtocols) { 5370 if (ProtocolCompatibleWithProtocol(Proto, PI)) { 5371 Conforms = true; 5372 break; 5373 } 5374 } 5375 if (!Conforms) 5376 break; 5377 } 5378 if (Conforms) 5379 return true; 5380 5381 for (auto *PI : InheritedProtocols) { 5382 // If both the right and left sides have qualifiers. 5383 bool Adopts = false; 5384 for (auto *Proto : OPT->quals()) { 5385 // return 'true' if 'PI' is in the inheritance hierarchy of Proto 5386 if ((Adopts = ProtocolCompatibleWithProtocol(PI, Proto))) 5387 break; 5388 } 5389 if (!Adopts) 5390 return false; 5391 } 5392 return true; 5393 } 5394 5395 /// getObjCObjectPointerType - Return a ObjCObjectPointerType type for 5396 /// the given object type. 5397 QualType ASTContext::getObjCObjectPointerType(QualType ObjectT) const { 5398 llvm::FoldingSetNodeID ID; 5399 ObjCObjectPointerType::Profile(ID, ObjectT); 5400 5401 void *InsertPos = nullptr; 5402 if (ObjCObjectPointerType *QT = 5403 ObjCObjectPointerTypes.FindNodeOrInsertPos(ID, InsertPos)) 5404 return QualType(QT, 0); 5405 5406 // Find the canonical object type. 5407 QualType Canonical; 5408 if (!ObjectT.isCanonical()) { 5409 Canonical = getObjCObjectPointerType(getCanonicalType(ObjectT)); 5410 5411 // Regenerate InsertPos. 5412 ObjCObjectPointerTypes.FindNodeOrInsertPos(ID, InsertPos); 5413 } 5414 5415 // No match. 5416 void *Mem = Allocate(sizeof(ObjCObjectPointerType), TypeAlignment); 5417 auto *QType = 5418 new (Mem) ObjCObjectPointerType(Canonical, ObjectT); 5419 5420 Types.push_back(QType); 5421 ObjCObjectPointerTypes.InsertNode(QType, InsertPos); 5422 return QualType(QType, 0); 5423 } 5424 5425 /// getObjCInterfaceType - Return the unique reference to the type for the 5426 /// specified ObjC interface decl. The list of protocols is optional. 5427 QualType ASTContext::getObjCInterfaceType(const ObjCInterfaceDecl *Decl, 5428 ObjCInterfaceDecl *PrevDecl) const { 5429 if (Decl->TypeForDecl) 5430 return QualType(Decl->TypeForDecl, 0); 5431 5432 if (PrevDecl) { 5433 assert(PrevDecl->TypeForDecl && "previous decl has no TypeForDecl"); 5434 Decl->TypeForDecl = PrevDecl->TypeForDecl; 5435 return QualType(PrevDecl->TypeForDecl, 0); 5436 } 5437 5438 // Prefer the definition, if there is one. 5439 if (const ObjCInterfaceDecl *Def = Decl->getDefinition()) 5440 Decl = Def; 5441 5442 void *Mem = Allocate(sizeof(ObjCInterfaceType), TypeAlignment); 5443 auto *T = new (Mem) ObjCInterfaceType(Decl); 5444 Decl->TypeForDecl = T; 5445 Types.push_back(T); 5446 return QualType(T, 0); 5447 } 5448 5449 /// getTypeOfExprType - Unlike many "get<Type>" functions, we can't unique 5450 /// TypeOfExprType AST's (since expression's are never shared). For example, 5451 /// multiple declarations that refer to "typeof(x)" all contain different 5452 /// DeclRefExpr's. This doesn't effect the type checker, since it operates 5453 /// on canonical type's (which are always unique). 5454 QualType ASTContext::getTypeOfExprType(Expr *tofExpr) const { 5455 TypeOfExprType *toe; 5456 if (tofExpr->isTypeDependent()) { 5457 llvm::FoldingSetNodeID ID; 5458 DependentTypeOfExprType::Profile(ID, *this, tofExpr); 5459 5460 void *InsertPos = nullptr; 5461 DependentTypeOfExprType *Canon 5462 = DependentTypeOfExprTypes.FindNodeOrInsertPos(ID, InsertPos); 5463 if (Canon) { 5464 // We already have a "canonical" version of an identical, dependent 5465 // typeof(expr) type. Use that as our canonical type. 5466 toe = new (*this, TypeAlignment) TypeOfExprType(tofExpr, 5467 QualType((TypeOfExprType*)Canon, 0)); 5468 } else { 5469 // Build a new, canonical typeof(expr) type. 5470 Canon 5471 = new (*this, TypeAlignment) DependentTypeOfExprType(*this, tofExpr); 5472 DependentTypeOfExprTypes.InsertNode(Canon, InsertPos); 5473 toe = Canon; 5474 } 5475 } else { 5476 QualType Canonical = getCanonicalType(tofExpr->getType()); 5477 toe = new (*this, TypeAlignment) TypeOfExprType(tofExpr, Canonical); 5478 } 5479 Types.push_back(toe); 5480 return QualType(toe, 0); 5481 } 5482 5483 /// getTypeOfType - Unlike many "get<Type>" functions, we don't unique 5484 /// TypeOfType nodes. The only motivation to unique these nodes would be 5485 /// memory savings. Since typeof(t) is fairly uncommon, space shouldn't be 5486 /// an issue. This doesn't affect the type checker, since it operates 5487 /// on canonical types (which are always unique). 5488 QualType ASTContext::getTypeOfType(QualType tofType) const { 5489 QualType Canonical = getCanonicalType(tofType); 5490 auto *tot = new (*this, TypeAlignment) TypeOfType(tofType, Canonical); 5491 Types.push_back(tot); 5492 return QualType(tot, 0); 5493 } 5494 5495 /// getReferenceQualifiedType - Given an expr, will return the type for 5496 /// that expression, as in [dcl.type.simple]p4 but without taking id-expressions 5497 /// and class member access into account. 5498 QualType ASTContext::getReferenceQualifiedType(const Expr *E) const { 5499 // C++11 [dcl.type.simple]p4: 5500 // [...] 5501 QualType T = E->getType(); 5502 switch (E->getValueKind()) { 5503 // - otherwise, if e is an xvalue, decltype(e) is T&&, where T is the 5504 // type of e; 5505 case VK_XValue: 5506 return getRValueReferenceType(T); 5507 // - otherwise, if e is an lvalue, decltype(e) is T&, where T is the 5508 // type of e; 5509 case VK_LValue: 5510 return getLValueReferenceType(T); 5511 // - otherwise, decltype(e) is the type of e. 5512 case VK_PRValue: 5513 return T; 5514 } 5515 llvm_unreachable("Unknown value kind"); 5516 } 5517 5518 /// Unlike many "get<Type>" functions, we don't unique DecltypeType 5519 /// nodes. This would never be helpful, since each such type has its own 5520 /// expression, and would not give a significant memory saving, since there 5521 /// is an Expr tree under each such type. 5522 QualType ASTContext::getDecltypeType(Expr *e, QualType UnderlyingType) const { 5523 DecltypeType *dt; 5524 5525 // C++11 [temp.type]p2: 5526 // If an expression e involves a template parameter, decltype(e) denotes a 5527 // unique dependent type. Two such decltype-specifiers refer to the same 5528 // type only if their expressions are equivalent (14.5.6.1). 5529 if (e->isInstantiationDependent()) { 5530 llvm::FoldingSetNodeID ID; 5531 DependentDecltypeType::Profile(ID, *this, e); 5532 5533 void *InsertPos = nullptr; 5534 DependentDecltypeType *Canon 5535 = DependentDecltypeTypes.FindNodeOrInsertPos(ID, InsertPos); 5536 if (!Canon) { 5537 // Build a new, canonical decltype(expr) type. 5538 Canon = new (*this, TypeAlignment) DependentDecltypeType(*this, e); 5539 DependentDecltypeTypes.InsertNode(Canon, InsertPos); 5540 } 5541 dt = new (*this, TypeAlignment) 5542 DecltypeType(e, UnderlyingType, QualType((DecltypeType *)Canon, 0)); 5543 } else { 5544 dt = new (*this, TypeAlignment) 5545 DecltypeType(e, UnderlyingType, getCanonicalType(UnderlyingType)); 5546 } 5547 Types.push_back(dt); 5548 return QualType(dt, 0); 5549 } 5550 5551 /// getUnaryTransformationType - We don't unique these, since the memory 5552 /// savings are minimal and these are rare. 5553 QualType ASTContext::getUnaryTransformType(QualType BaseType, 5554 QualType UnderlyingType, 5555 UnaryTransformType::UTTKind Kind) 5556 const { 5557 UnaryTransformType *ut = nullptr; 5558 5559 if (BaseType->isDependentType()) { 5560 // Look in the folding set for an existing type. 5561 llvm::FoldingSetNodeID ID; 5562 DependentUnaryTransformType::Profile(ID, getCanonicalType(BaseType), Kind); 5563 5564 void *InsertPos = nullptr; 5565 DependentUnaryTransformType *Canon 5566 = DependentUnaryTransformTypes.FindNodeOrInsertPos(ID, InsertPos); 5567 5568 if (!Canon) { 5569 // Build a new, canonical __underlying_type(type) type. 5570 Canon = new (*this, TypeAlignment) 5571 DependentUnaryTransformType(*this, getCanonicalType(BaseType), 5572 Kind); 5573 DependentUnaryTransformTypes.InsertNode(Canon, InsertPos); 5574 } 5575 ut = new (*this, TypeAlignment) UnaryTransformType (BaseType, 5576 QualType(), Kind, 5577 QualType(Canon, 0)); 5578 } else { 5579 QualType CanonType = getCanonicalType(UnderlyingType); 5580 ut = new (*this, TypeAlignment) UnaryTransformType (BaseType, 5581 UnderlyingType, Kind, 5582 CanonType); 5583 } 5584 Types.push_back(ut); 5585 return QualType(ut, 0); 5586 } 5587 5588 /// getAutoType - Return the uniqued reference to the 'auto' type which has been 5589 /// deduced to the given type, or to the canonical undeduced 'auto' type, or the 5590 /// canonical deduced-but-dependent 'auto' type. 5591 QualType 5592 ASTContext::getAutoType(QualType DeducedType, AutoTypeKeyword Keyword, 5593 bool IsDependent, bool IsPack, 5594 ConceptDecl *TypeConstraintConcept, 5595 ArrayRef<TemplateArgument> TypeConstraintArgs) const { 5596 assert((!IsPack || IsDependent) && "only use IsPack for a dependent pack"); 5597 if (DeducedType.isNull() && Keyword == AutoTypeKeyword::Auto && 5598 !TypeConstraintConcept && !IsDependent) 5599 return getAutoDeductType(); 5600 5601 // Look in the folding set for an existing type. 5602 void *InsertPos = nullptr; 5603 llvm::FoldingSetNodeID ID; 5604 AutoType::Profile(ID, *this, DeducedType, Keyword, IsDependent, 5605 TypeConstraintConcept, TypeConstraintArgs); 5606 if (AutoType *AT = AutoTypes.FindNodeOrInsertPos(ID, InsertPos)) 5607 return QualType(AT, 0); 5608 5609 void *Mem = Allocate(sizeof(AutoType) + 5610 sizeof(TemplateArgument) * TypeConstraintArgs.size(), 5611 TypeAlignment); 5612 auto *AT = new (Mem) AutoType( 5613 DeducedType, Keyword, 5614 (IsDependent ? TypeDependence::DependentInstantiation 5615 : TypeDependence::None) | 5616 (IsPack ? TypeDependence::UnexpandedPack : TypeDependence::None), 5617 TypeConstraintConcept, TypeConstraintArgs); 5618 Types.push_back(AT); 5619 if (InsertPos) 5620 AutoTypes.InsertNode(AT, InsertPos); 5621 return QualType(AT, 0); 5622 } 5623 5624 /// Return the uniqued reference to the deduced template specialization type 5625 /// which has been deduced to the given type, or to the canonical undeduced 5626 /// such type, or the canonical deduced-but-dependent such type. 5627 QualType ASTContext::getDeducedTemplateSpecializationType( 5628 TemplateName Template, QualType DeducedType, bool IsDependent) const { 5629 // Look in the folding set for an existing type. 5630 void *InsertPos = nullptr; 5631 llvm::FoldingSetNodeID ID; 5632 DeducedTemplateSpecializationType::Profile(ID, Template, DeducedType, 5633 IsDependent); 5634 if (DeducedTemplateSpecializationType *DTST = 5635 DeducedTemplateSpecializationTypes.FindNodeOrInsertPos(ID, InsertPos)) 5636 return QualType(DTST, 0); 5637 5638 auto *DTST = new (*this, TypeAlignment) 5639 DeducedTemplateSpecializationType(Template, DeducedType, IsDependent); 5640 Types.push_back(DTST); 5641 if (InsertPos) 5642 DeducedTemplateSpecializationTypes.InsertNode(DTST, InsertPos); 5643 return QualType(DTST, 0); 5644 } 5645 5646 /// getAtomicType - Return the uniqued reference to the atomic type for 5647 /// the given value type. 5648 QualType ASTContext::getAtomicType(QualType T) const { 5649 // Unique pointers, to guarantee there is only one pointer of a particular 5650 // structure. 5651 llvm::FoldingSetNodeID ID; 5652 AtomicType::Profile(ID, T); 5653 5654 void *InsertPos = nullptr; 5655 if (AtomicType *AT = AtomicTypes.FindNodeOrInsertPos(ID, InsertPos)) 5656 return QualType(AT, 0); 5657 5658 // If the atomic value type isn't canonical, this won't be a canonical type 5659 // either, so fill in the canonical type field. 5660 QualType Canonical; 5661 if (!T.isCanonical()) { 5662 Canonical = getAtomicType(getCanonicalType(T)); 5663 5664 // Get the new insert position for the node we care about. 5665 AtomicType *NewIP = AtomicTypes.FindNodeOrInsertPos(ID, InsertPos); 5666 assert(!NewIP && "Shouldn't be in the map!"); (void)NewIP; 5667 } 5668 auto *New = new (*this, TypeAlignment) AtomicType(T, Canonical); 5669 Types.push_back(New); 5670 AtomicTypes.InsertNode(New, InsertPos); 5671 return QualType(New, 0); 5672 } 5673 5674 /// getAutoDeductType - Get type pattern for deducing against 'auto'. 5675 QualType ASTContext::getAutoDeductType() const { 5676 if (AutoDeductTy.isNull()) 5677 AutoDeductTy = QualType(new (*this, TypeAlignment) 5678 AutoType(QualType(), AutoTypeKeyword::Auto, 5679 TypeDependence::None, 5680 /*concept*/ nullptr, /*args*/ {}), 5681 0); 5682 return AutoDeductTy; 5683 } 5684 5685 /// getAutoRRefDeductType - Get type pattern for deducing against 'auto &&'. 5686 QualType ASTContext::getAutoRRefDeductType() const { 5687 if (AutoRRefDeductTy.isNull()) 5688 AutoRRefDeductTy = getRValueReferenceType(getAutoDeductType()); 5689 assert(!AutoRRefDeductTy.isNull() && "can't build 'auto &&' pattern"); 5690 return AutoRRefDeductTy; 5691 } 5692 5693 /// getTagDeclType - Return the unique reference to the type for the 5694 /// specified TagDecl (struct/union/class/enum) decl. 5695 QualType ASTContext::getTagDeclType(const TagDecl *Decl) const { 5696 assert(Decl); 5697 // FIXME: What is the design on getTagDeclType when it requires casting 5698 // away const? mutable? 5699 return getTypeDeclType(const_cast<TagDecl*>(Decl)); 5700 } 5701 5702 /// getSizeType - Return the unique type for "size_t" (C99 7.17), the result 5703 /// of the sizeof operator (C99 6.5.3.4p4). The value is target dependent and 5704 /// needs to agree with the definition in <stddef.h>. 5705 CanQualType ASTContext::getSizeType() const { 5706 return getFromTargetType(Target->getSizeType()); 5707 } 5708 5709 /// Return the unique signed counterpart of the integer type 5710 /// corresponding to size_t. 5711 CanQualType ASTContext::getSignedSizeType() const { 5712 return getFromTargetType(Target->getSignedSizeType()); 5713 } 5714 5715 /// getIntMaxType - Return the unique type for "intmax_t" (C99 7.18.1.5). 5716 CanQualType ASTContext::getIntMaxType() const { 5717 return getFromTargetType(Target->getIntMaxType()); 5718 } 5719 5720 /// getUIntMaxType - Return the unique type for "uintmax_t" (C99 7.18.1.5). 5721 CanQualType ASTContext::getUIntMaxType() const { 5722 return getFromTargetType(Target->getUIntMaxType()); 5723 } 5724 5725 /// getSignedWCharType - Return the type of "signed wchar_t". 5726 /// Used when in C++, as a GCC extension. 5727 QualType ASTContext::getSignedWCharType() const { 5728 // FIXME: derive from "Target" ? 5729 return WCharTy; 5730 } 5731 5732 /// getUnsignedWCharType - Return the type of "unsigned wchar_t". 5733 /// Used when in C++, as a GCC extension. 5734 QualType ASTContext::getUnsignedWCharType() const { 5735 // FIXME: derive from "Target" ? 5736 return UnsignedIntTy; 5737 } 5738 5739 QualType ASTContext::getIntPtrType() const { 5740 return getFromTargetType(Target->getIntPtrType()); 5741 } 5742 5743 QualType ASTContext::getUIntPtrType() const { 5744 return getCorrespondingUnsignedType(getIntPtrType()); 5745 } 5746 5747 /// getPointerDiffType - Return the unique type for "ptrdiff_t" (C99 7.17) 5748 /// defined in <stddef.h>. Pointer - pointer requires this (C99 6.5.6p9). 5749 QualType ASTContext::getPointerDiffType() const { 5750 return getFromTargetType(Target->getPtrDiffType(0)); 5751 } 5752 5753 /// Return the unique unsigned counterpart of "ptrdiff_t" 5754 /// integer type. The standard (C11 7.21.6.1p7) refers to this type 5755 /// in the definition of %tu format specifier. 5756 QualType ASTContext::getUnsignedPointerDiffType() const { 5757 return getFromTargetType(Target->getUnsignedPtrDiffType(0)); 5758 } 5759 5760 /// Return the unique type for "pid_t" defined in 5761 /// <sys/types.h>. We need this to compute the correct type for vfork(). 5762 QualType ASTContext::getProcessIDType() const { 5763 return getFromTargetType(Target->getProcessIDType()); 5764 } 5765 5766 //===----------------------------------------------------------------------===// 5767 // Type Operators 5768 //===----------------------------------------------------------------------===// 5769 5770 CanQualType ASTContext::getCanonicalParamType(QualType T) const { 5771 // Push qualifiers into arrays, and then discard any remaining 5772 // qualifiers. 5773 T = getCanonicalType(T); 5774 T = getVariableArrayDecayedType(T); 5775 const Type *Ty = T.getTypePtr(); 5776 QualType Result; 5777 if (isa<ArrayType>(Ty)) { 5778 Result = getArrayDecayedType(QualType(Ty,0)); 5779 } else if (isa<FunctionType>(Ty)) { 5780 Result = getPointerType(QualType(Ty, 0)); 5781 } else { 5782 Result = QualType(Ty, 0); 5783 } 5784 5785 return CanQualType::CreateUnsafe(Result); 5786 } 5787 5788 QualType ASTContext::getUnqualifiedArrayType(QualType type, 5789 Qualifiers &quals) { 5790 SplitQualType splitType = type.getSplitUnqualifiedType(); 5791 5792 // FIXME: getSplitUnqualifiedType() actually walks all the way to 5793 // the unqualified desugared type and then drops it on the floor. 5794 // We then have to strip that sugar back off with 5795 // getUnqualifiedDesugaredType(), which is silly. 5796 const auto *AT = 5797 dyn_cast<ArrayType>(splitType.Ty->getUnqualifiedDesugaredType()); 5798 5799 // If we don't have an array, just use the results in splitType. 5800 if (!AT) { 5801 quals = splitType.Quals; 5802 return QualType(splitType.Ty, 0); 5803 } 5804 5805 // Otherwise, recurse on the array's element type. 5806 QualType elementType = AT->getElementType(); 5807 QualType unqualElementType = getUnqualifiedArrayType(elementType, quals); 5808 5809 // If that didn't change the element type, AT has no qualifiers, so we 5810 // can just use the results in splitType. 5811 if (elementType == unqualElementType) { 5812 assert(quals.empty()); // from the recursive call 5813 quals = splitType.Quals; 5814 return QualType(splitType.Ty, 0); 5815 } 5816 5817 // Otherwise, add in the qualifiers from the outermost type, then 5818 // build the type back up. 5819 quals.addConsistentQualifiers(splitType.Quals); 5820 5821 if (const auto *CAT = dyn_cast<ConstantArrayType>(AT)) { 5822 return getConstantArrayType(unqualElementType, CAT->getSize(), 5823 CAT->getSizeExpr(), CAT->getSizeModifier(), 0); 5824 } 5825 5826 if (const auto *IAT = dyn_cast<IncompleteArrayType>(AT)) { 5827 return getIncompleteArrayType(unqualElementType, IAT->getSizeModifier(), 0); 5828 } 5829 5830 if (const auto *VAT = dyn_cast<VariableArrayType>(AT)) { 5831 return getVariableArrayType(unqualElementType, 5832 VAT->getSizeExpr(), 5833 VAT->getSizeModifier(), 5834 VAT->getIndexTypeCVRQualifiers(), 5835 VAT->getBracketsRange()); 5836 } 5837 5838 const auto *DSAT = cast<DependentSizedArrayType>(AT); 5839 return getDependentSizedArrayType(unqualElementType, DSAT->getSizeExpr(), 5840 DSAT->getSizeModifier(), 0, 5841 SourceRange()); 5842 } 5843 5844 /// Attempt to unwrap two types that may both be array types with the same bound 5845 /// (or both be array types of unknown bound) for the purpose of comparing the 5846 /// cv-decomposition of two types per C++ [conv.qual]. 5847 /// 5848 /// \param AllowPiMismatch Allow the Pi1 and Pi2 to differ as described in 5849 /// C++20 [conv.qual], if permitted by the current language mode. 5850 void ASTContext::UnwrapSimilarArrayTypes(QualType &T1, QualType &T2, 5851 bool AllowPiMismatch) { 5852 while (true) { 5853 auto *AT1 = getAsArrayType(T1); 5854 if (!AT1) 5855 return; 5856 5857 auto *AT2 = getAsArrayType(T2); 5858 if (!AT2) 5859 return; 5860 5861 // If we don't have two array types with the same constant bound nor two 5862 // incomplete array types, we've unwrapped everything we can. 5863 // C++20 also permits one type to be a constant array type and the other 5864 // to be an incomplete array type. 5865 // FIXME: Consider also unwrapping array of unknown bound and VLA. 5866 if (auto *CAT1 = dyn_cast<ConstantArrayType>(AT1)) { 5867 auto *CAT2 = dyn_cast<ConstantArrayType>(AT2); 5868 if (!((CAT2 && CAT1->getSize() == CAT2->getSize()) || 5869 (AllowPiMismatch && getLangOpts().CPlusPlus20 && 5870 isa<IncompleteArrayType>(AT2)))) 5871 return; 5872 } else if (isa<IncompleteArrayType>(AT1)) { 5873 if (!(isa<IncompleteArrayType>(AT2) || 5874 (AllowPiMismatch && getLangOpts().CPlusPlus20 && 5875 isa<ConstantArrayType>(AT2)))) 5876 return; 5877 } else { 5878 return; 5879 } 5880 5881 T1 = AT1->getElementType(); 5882 T2 = AT2->getElementType(); 5883 } 5884 } 5885 5886 /// Attempt to unwrap two types that may be similar (C++ [conv.qual]). 5887 /// 5888 /// If T1 and T2 are both pointer types of the same kind, or both array types 5889 /// with the same bound, unwraps layers from T1 and T2 until a pointer type is 5890 /// unwrapped. Top-level qualifiers on T1 and T2 are ignored. 5891 /// 5892 /// This function will typically be called in a loop that successively 5893 /// "unwraps" pointer and pointer-to-member types to compare them at each 5894 /// level. 5895 /// 5896 /// \param AllowPiMismatch Allow the Pi1 and Pi2 to differ as described in 5897 /// C++20 [conv.qual], if permitted by the current language mode. 5898 /// 5899 /// \return \c true if a pointer type was unwrapped, \c false if we reached a 5900 /// pair of types that can't be unwrapped further. 5901 bool ASTContext::UnwrapSimilarTypes(QualType &T1, QualType &T2, 5902 bool AllowPiMismatch) { 5903 UnwrapSimilarArrayTypes(T1, T2, AllowPiMismatch); 5904 5905 const auto *T1PtrType = T1->getAs<PointerType>(); 5906 const auto *T2PtrType = T2->getAs<PointerType>(); 5907 if (T1PtrType && T2PtrType) { 5908 T1 = T1PtrType->getPointeeType(); 5909 T2 = T2PtrType->getPointeeType(); 5910 return true; 5911 } 5912 5913 const auto *T1MPType = T1->getAs<MemberPointerType>(); 5914 const auto *T2MPType = T2->getAs<MemberPointerType>(); 5915 if (T1MPType && T2MPType && 5916 hasSameUnqualifiedType(QualType(T1MPType->getClass(), 0), 5917 QualType(T2MPType->getClass(), 0))) { 5918 T1 = T1MPType->getPointeeType(); 5919 T2 = T2MPType->getPointeeType(); 5920 return true; 5921 } 5922 5923 if (getLangOpts().ObjC) { 5924 const auto *T1OPType = T1->getAs<ObjCObjectPointerType>(); 5925 const auto *T2OPType = T2->getAs<ObjCObjectPointerType>(); 5926 if (T1OPType && T2OPType) { 5927 T1 = T1OPType->getPointeeType(); 5928 T2 = T2OPType->getPointeeType(); 5929 return true; 5930 } 5931 } 5932 5933 // FIXME: Block pointers, too? 5934 5935 return false; 5936 } 5937 5938 bool ASTContext::hasSimilarType(QualType T1, QualType T2) { 5939 while (true) { 5940 Qualifiers Quals; 5941 T1 = getUnqualifiedArrayType(T1, Quals); 5942 T2 = getUnqualifiedArrayType(T2, Quals); 5943 if (hasSameType(T1, T2)) 5944 return true; 5945 if (!UnwrapSimilarTypes(T1, T2)) 5946 return false; 5947 } 5948 } 5949 5950 bool ASTContext::hasCvrSimilarType(QualType T1, QualType T2) { 5951 while (true) { 5952 Qualifiers Quals1, Quals2; 5953 T1 = getUnqualifiedArrayType(T1, Quals1); 5954 T2 = getUnqualifiedArrayType(T2, Quals2); 5955 5956 Quals1.removeCVRQualifiers(); 5957 Quals2.removeCVRQualifiers(); 5958 if (Quals1 != Quals2) 5959 return false; 5960 5961 if (hasSameType(T1, T2)) 5962 return true; 5963 5964 if (!UnwrapSimilarTypes(T1, T2, /*AllowPiMismatch*/ false)) 5965 return false; 5966 } 5967 } 5968 5969 DeclarationNameInfo 5970 ASTContext::getNameForTemplate(TemplateName Name, 5971 SourceLocation NameLoc) const { 5972 switch (Name.getKind()) { 5973 case TemplateName::QualifiedTemplate: 5974 case TemplateName::Template: 5975 // DNInfo work in progress: CHECKME: what about DNLoc? 5976 return DeclarationNameInfo(Name.getAsTemplateDecl()->getDeclName(), 5977 NameLoc); 5978 5979 case TemplateName::OverloadedTemplate: { 5980 OverloadedTemplateStorage *Storage = Name.getAsOverloadedTemplate(); 5981 // DNInfo work in progress: CHECKME: what about DNLoc? 5982 return DeclarationNameInfo((*Storage->begin())->getDeclName(), NameLoc); 5983 } 5984 5985 case TemplateName::AssumedTemplate: { 5986 AssumedTemplateStorage *Storage = Name.getAsAssumedTemplateName(); 5987 return DeclarationNameInfo(Storage->getDeclName(), NameLoc); 5988 } 5989 5990 case TemplateName::DependentTemplate: { 5991 DependentTemplateName *DTN = Name.getAsDependentTemplateName(); 5992 DeclarationName DName; 5993 if (DTN->isIdentifier()) { 5994 DName = DeclarationNames.getIdentifier(DTN->getIdentifier()); 5995 return DeclarationNameInfo(DName, NameLoc); 5996 } else { 5997 DName = DeclarationNames.getCXXOperatorName(DTN->getOperator()); 5998 // DNInfo work in progress: FIXME: source locations? 5999 DeclarationNameLoc DNLoc = 6000 DeclarationNameLoc::makeCXXOperatorNameLoc(SourceRange()); 6001 return DeclarationNameInfo(DName, NameLoc, DNLoc); 6002 } 6003 } 6004 6005 case TemplateName::SubstTemplateTemplateParm: { 6006 SubstTemplateTemplateParmStorage *subst 6007 = Name.getAsSubstTemplateTemplateParm(); 6008 return DeclarationNameInfo(subst->getParameter()->getDeclName(), 6009 NameLoc); 6010 } 6011 6012 case TemplateName::SubstTemplateTemplateParmPack: { 6013 SubstTemplateTemplateParmPackStorage *subst 6014 = Name.getAsSubstTemplateTemplateParmPack(); 6015 return DeclarationNameInfo(subst->getParameterPack()->getDeclName(), 6016 NameLoc); 6017 } 6018 } 6019 6020 llvm_unreachable("bad template name kind!"); 6021 } 6022 6023 TemplateName ASTContext::getCanonicalTemplateName(TemplateName Name) const { 6024 switch (Name.getKind()) { 6025 case TemplateName::QualifiedTemplate: 6026 case TemplateName::Template: { 6027 TemplateDecl *Template = Name.getAsTemplateDecl(); 6028 if (auto *TTP = dyn_cast<TemplateTemplateParmDecl>(Template)) 6029 Template = getCanonicalTemplateTemplateParmDecl(TTP); 6030 6031 // The canonical template name is the canonical template declaration. 6032 return TemplateName(cast<TemplateDecl>(Template->getCanonicalDecl())); 6033 } 6034 6035 case TemplateName::OverloadedTemplate: 6036 case TemplateName::AssumedTemplate: 6037 llvm_unreachable("cannot canonicalize unresolved template"); 6038 6039 case TemplateName::DependentTemplate: { 6040 DependentTemplateName *DTN = Name.getAsDependentTemplateName(); 6041 assert(DTN && "Non-dependent template names must refer to template decls."); 6042 return DTN->CanonicalTemplateName; 6043 } 6044 6045 case TemplateName::SubstTemplateTemplateParm: { 6046 SubstTemplateTemplateParmStorage *subst 6047 = Name.getAsSubstTemplateTemplateParm(); 6048 return getCanonicalTemplateName(subst->getReplacement()); 6049 } 6050 6051 case TemplateName::SubstTemplateTemplateParmPack: { 6052 SubstTemplateTemplateParmPackStorage *subst 6053 = Name.getAsSubstTemplateTemplateParmPack(); 6054 TemplateTemplateParmDecl *canonParameter 6055 = getCanonicalTemplateTemplateParmDecl(subst->getParameterPack()); 6056 TemplateArgument canonArgPack 6057 = getCanonicalTemplateArgument(subst->getArgumentPack()); 6058 return getSubstTemplateTemplateParmPack(canonParameter, canonArgPack); 6059 } 6060 } 6061 6062 llvm_unreachable("bad template name!"); 6063 } 6064 6065 bool ASTContext::hasSameTemplateName(TemplateName X, TemplateName Y) { 6066 X = getCanonicalTemplateName(X); 6067 Y = getCanonicalTemplateName(Y); 6068 return X.getAsVoidPointer() == Y.getAsVoidPointer(); 6069 } 6070 6071 TemplateArgument 6072 ASTContext::getCanonicalTemplateArgument(const TemplateArgument &Arg) const { 6073 switch (Arg.getKind()) { 6074 case TemplateArgument::Null: 6075 return Arg; 6076 6077 case TemplateArgument::Expression: 6078 return Arg; 6079 6080 case TemplateArgument::Declaration: { 6081 auto *D = cast<ValueDecl>(Arg.getAsDecl()->getCanonicalDecl()); 6082 return TemplateArgument(D, Arg.getParamTypeForDecl()); 6083 } 6084 6085 case TemplateArgument::NullPtr: 6086 return TemplateArgument(getCanonicalType(Arg.getNullPtrType()), 6087 /*isNullPtr*/true); 6088 6089 case TemplateArgument::Template: 6090 return TemplateArgument(getCanonicalTemplateName(Arg.getAsTemplate())); 6091 6092 case TemplateArgument::TemplateExpansion: 6093 return TemplateArgument(getCanonicalTemplateName( 6094 Arg.getAsTemplateOrTemplatePattern()), 6095 Arg.getNumTemplateExpansions()); 6096 6097 case TemplateArgument::Integral: 6098 return TemplateArgument(Arg, getCanonicalType(Arg.getIntegralType())); 6099 6100 case TemplateArgument::Type: 6101 return TemplateArgument(getCanonicalType(Arg.getAsType())); 6102 6103 case TemplateArgument::Pack: { 6104 if (Arg.pack_size() == 0) 6105 return Arg; 6106 6107 auto *CanonArgs = new (*this) TemplateArgument[Arg.pack_size()]; 6108 unsigned Idx = 0; 6109 for (TemplateArgument::pack_iterator A = Arg.pack_begin(), 6110 AEnd = Arg.pack_end(); 6111 A != AEnd; (void)++A, ++Idx) 6112 CanonArgs[Idx] = getCanonicalTemplateArgument(*A); 6113 6114 return TemplateArgument(llvm::makeArrayRef(CanonArgs, Arg.pack_size())); 6115 } 6116 } 6117 6118 // Silence GCC warning 6119 llvm_unreachable("Unhandled template argument kind"); 6120 } 6121 6122 NestedNameSpecifier * 6123 ASTContext::getCanonicalNestedNameSpecifier(NestedNameSpecifier *NNS) const { 6124 if (!NNS) 6125 return nullptr; 6126 6127 switch (NNS->getKind()) { 6128 case NestedNameSpecifier::Identifier: 6129 // Canonicalize the prefix but keep the identifier the same. 6130 return NestedNameSpecifier::Create(*this, 6131 getCanonicalNestedNameSpecifier(NNS->getPrefix()), 6132 NNS->getAsIdentifier()); 6133 6134 case NestedNameSpecifier::Namespace: 6135 // A namespace is canonical; build a nested-name-specifier with 6136 // this namespace and no prefix. 6137 return NestedNameSpecifier::Create(*this, nullptr, 6138 NNS->getAsNamespace()->getOriginalNamespace()); 6139 6140 case NestedNameSpecifier::NamespaceAlias: 6141 // A namespace is canonical; build a nested-name-specifier with 6142 // this namespace and no prefix. 6143 return NestedNameSpecifier::Create(*this, nullptr, 6144 NNS->getAsNamespaceAlias()->getNamespace() 6145 ->getOriginalNamespace()); 6146 6147 // The difference between TypeSpec and TypeSpecWithTemplate is that the 6148 // latter will have the 'template' keyword when printed. 6149 case NestedNameSpecifier::TypeSpec: 6150 case NestedNameSpecifier::TypeSpecWithTemplate: { 6151 const Type *T = getCanonicalType(NNS->getAsType()); 6152 6153 // If we have some kind of dependent-named type (e.g., "typename T::type"), 6154 // break it apart into its prefix and identifier, then reconsititute those 6155 // as the canonical nested-name-specifier. This is required to canonicalize 6156 // a dependent nested-name-specifier involving typedefs of dependent-name 6157 // types, e.g., 6158 // typedef typename T::type T1; 6159 // typedef typename T1::type T2; 6160 if (const auto *DNT = T->getAs<DependentNameType>()) 6161 return NestedNameSpecifier::Create( 6162 *this, DNT->getQualifier(), 6163 const_cast<IdentifierInfo *>(DNT->getIdentifier())); 6164 if (const auto *DTST = T->getAs<DependentTemplateSpecializationType>()) 6165 return NestedNameSpecifier::Create(*this, DTST->getQualifier(), true, 6166 const_cast<Type *>(T)); 6167 6168 // TODO: Set 'Template' parameter to true for other template types. 6169 return NestedNameSpecifier::Create(*this, nullptr, false, 6170 const_cast<Type *>(T)); 6171 } 6172 6173 case NestedNameSpecifier::Global: 6174 case NestedNameSpecifier::Super: 6175 // The global specifier and __super specifer are canonical and unique. 6176 return NNS; 6177 } 6178 6179 llvm_unreachable("Invalid NestedNameSpecifier::Kind!"); 6180 } 6181 6182 const ArrayType *ASTContext::getAsArrayType(QualType T) const { 6183 // Handle the non-qualified case efficiently. 6184 if (!T.hasLocalQualifiers()) { 6185 // Handle the common positive case fast. 6186 if (const auto *AT = dyn_cast<ArrayType>(T)) 6187 return AT; 6188 } 6189 6190 // Handle the common negative case fast. 6191 if (!isa<ArrayType>(T.getCanonicalType())) 6192 return nullptr; 6193 6194 // Apply any qualifiers from the array type to the element type. This 6195 // implements C99 6.7.3p8: "If the specification of an array type includes 6196 // any type qualifiers, the element type is so qualified, not the array type." 6197 6198 // If we get here, we either have type qualifiers on the type, or we have 6199 // sugar such as a typedef in the way. If we have type qualifiers on the type 6200 // we must propagate them down into the element type. 6201 6202 SplitQualType split = T.getSplitDesugaredType(); 6203 Qualifiers qs = split.Quals; 6204 6205 // If we have a simple case, just return now. 6206 const auto *ATy = dyn_cast<ArrayType>(split.Ty); 6207 if (!ATy || qs.empty()) 6208 return ATy; 6209 6210 // Otherwise, we have an array and we have qualifiers on it. Push the 6211 // qualifiers into the array element type and return a new array type. 6212 QualType NewEltTy = getQualifiedType(ATy->getElementType(), qs); 6213 6214 if (const auto *CAT = dyn_cast<ConstantArrayType>(ATy)) 6215 return cast<ArrayType>(getConstantArrayType(NewEltTy, CAT->getSize(), 6216 CAT->getSizeExpr(), 6217 CAT->getSizeModifier(), 6218 CAT->getIndexTypeCVRQualifiers())); 6219 if (const auto *IAT = dyn_cast<IncompleteArrayType>(ATy)) 6220 return cast<ArrayType>(getIncompleteArrayType(NewEltTy, 6221 IAT->getSizeModifier(), 6222 IAT->getIndexTypeCVRQualifiers())); 6223 6224 if (const auto *DSAT = dyn_cast<DependentSizedArrayType>(ATy)) 6225 return cast<ArrayType>( 6226 getDependentSizedArrayType(NewEltTy, 6227 DSAT->getSizeExpr(), 6228 DSAT->getSizeModifier(), 6229 DSAT->getIndexTypeCVRQualifiers(), 6230 DSAT->getBracketsRange())); 6231 6232 const auto *VAT = cast<VariableArrayType>(ATy); 6233 return cast<ArrayType>(getVariableArrayType(NewEltTy, 6234 VAT->getSizeExpr(), 6235 VAT->getSizeModifier(), 6236 VAT->getIndexTypeCVRQualifiers(), 6237 VAT->getBracketsRange())); 6238 } 6239 6240 QualType ASTContext::getAdjustedParameterType(QualType T) const { 6241 if (T->isArrayType() || T->isFunctionType()) 6242 return getDecayedType(T); 6243 return T; 6244 } 6245 6246 QualType ASTContext::getSignatureParameterType(QualType T) const { 6247 T = getVariableArrayDecayedType(T); 6248 T = getAdjustedParameterType(T); 6249 return T.getUnqualifiedType(); 6250 } 6251 6252 QualType ASTContext::getExceptionObjectType(QualType T) const { 6253 // C++ [except.throw]p3: 6254 // A throw-expression initializes a temporary object, called the exception 6255 // object, the type of which is determined by removing any top-level 6256 // cv-qualifiers from the static type of the operand of throw and adjusting 6257 // the type from "array of T" or "function returning T" to "pointer to T" 6258 // or "pointer to function returning T", [...] 6259 T = getVariableArrayDecayedType(T); 6260 if (T->isArrayType() || T->isFunctionType()) 6261 T = getDecayedType(T); 6262 return T.getUnqualifiedType(); 6263 } 6264 6265 /// getArrayDecayedType - Return the properly qualified result of decaying the 6266 /// specified array type to a pointer. This operation is non-trivial when 6267 /// handling typedefs etc. The canonical type of "T" must be an array type, 6268 /// this returns a pointer to a properly qualified element of the array. 6269 /// 6270 /// See C99 6.7.5.3p7 and C99 6.3.2.1p3. 6271 QualType ASTContext::getArrayDecayedType(QualType Ty) const { 6272 // Get the element type with 'getAsArrayType' so that we don't lose any 6273 // typedefs in the element type of the array. This also handles propagation 6274 // of type qualifiers from the array type into the element type if present 6275 // (C99 6.7.3p8). 6276 const ArrayType *PrettyArrayType = getAsArrayType(Ty); 6277 assert(PrettyArrayType && "Not an array type!"); 6278 6279 QualType PtrTy = getPointerType(PrettyArrayType->getElementType()); 6280 6281 // int x[restrict 4] -> int *restrict 6282 QualType Result = getQualifiedType(PtrTy, 6283 PrettyArrayType->getIndexTypeQualifiers()); 6284 6285 // int x[_Nullable] -> int * _Nullable 6286 if (auto Nullability = Ty->getNullability(*this)) { 6287 Result = const_cast<ASTContext *>(this)->getAttributedType( 6288 AttributedType::getNullabilityAttrKind(*Nullability), Result, Result); 6289 } 6290 return Result; 6291 } 6292 6293 QualType ASTContext::getBaseElementType(const ArrayType *array) const { 6294 return getBaseElementType(array->getElementType()); 6295 } 6296 6297 QualType ASTContext::getBaseElementType(QualType type) const { 6298 Qualifiers qs; 6299 while (true) { 6300 SplitQualType split = type.getSplitDesugaredType(); 6301 const ArrayType *array = split.Ty->getAsArrayTypeUnsafe(); 6302 if (!array) break; 6303 6304 type = array->getElementType(); 6305 qs.addConsistentQualifiers(split.Quals); 6306 } 6307 6308 return getQualifiedType(type, qs); 6309 } 6310 6311 /// getConstantArrayElementCount - Returns number of constant array elements. 6312 uint64_t 6313 ASTContext::getConstantArrayElementCount(const ConstantArrayType *CA) const { 6314 uint64_t ElementCount = 1; 6315 do { 6316 ElementCount *= CA->getSize().getZExtValue(); 6317 CA = dyn_cast_or_null<ConstantArrayType>( 6318 CA->getElementType()->getAsArrayTypeUnsafe()); 6319 } while (CA); 6320 return ElementCount; 6321 } 6322 6323 /// getFloatingRank - Return a relative rank for floating point types. 6324 /// This routine will assert if passed a built-in type that isn't a float. 6325 static FloatingRank getFloatingRank(QualType T) { 6326 if (const auto *CT = T->getAs<ComplexType>()) 6327 return getFloatingRank(CT->getElementType()); 6328 6329 switch (T->castAs<BuiltinType>()->getKind()) { 6330 default: llvm_unreachable("getFloatingRank(): not a floating type"); 6331 case BuiltinType::Float16: return Float16Rank; 6332 case BuiltinType::Half: return HalfRank; 6333 case BuiltinType::Float: return FloatRank; 6334 case BuiltinType::Double: return DoubleRank; 6335 case BuiltinType::LongDouble: return LongDoubleRank; 6336 case BuiltinType::Float128: return Float128Rank; 6337 case BuiltinType::BFloat16: return BFloat16Rank; 6338 case BuiltinType::Ibm128: return Ibm128Rank; 6339 } 6340 } 6341 6342 /// getFloatingTypeOfSizeWithinDomain - Returns a real floating 6343 /// point or a complex type (based on typeDomain/typeSize). 6344 /// 'typeDomain' is a real floating point or complex type. 6345 /// 'typeSize' is a real floating point or complex type. 6346 QualType ASTContext::getFloatingTypeOfSizeWithinDomain(QualType Size, 6347 QualType Domain) const { 6348 FloatingRank EltRank = getFloatingRank(Size); 6349 if (Domain->isComplexType()) { 6350 switch (EltRank) { 6351 case BFloat16Rank: llvm_unreachable("Complex bfloat16 is not supported"); 6352 case Float16Rank: 6353 case HalfRank: llvm_unreachable("Complex half is not supported"); 6354 case Ibm128Rank: return getComplexType(Ibm128Ty); 6355 case FloatRank: return getComplexType(FloatTy); 6356 case DoubleRank: return getComplexType(DoubleTy); 6357 case LongDoubleRank: return getComplexType(LongDoubleTy); 6358 case Float128Rank: return getComplexType(Float128Ty); 6359 } 6360 } 6361 6362 assert(Domain->isRealFloatingType() && "Unknown domain!"); 6363 switch (EltRank) { 6364 case Float16Rank: return HalfTy; 6365 case BFloat16Rank: return BFloat16Ty; 6366 case HalfRank: return HalfTy; 6367 case FloatRank: return FloatTy; 6368 case DoubleRank: return DoubleTy; 6369 case LongDoubleRank: return LongDoubleTy; 6370 case Float128Rank: return Float128Ty; 6371 case Ibm128Rank: 6372 return Ibm128Ty; 6373 } 6374 llvm_unreachable("getFloatingRank(): illegal value for rank"); 6375 } 6376 6377 /// getFloatingTypeOrder - Compare the rank of the two specified floating 6378 /// point types, ignoring the domain of the type (i.e. 'double' == 6379 /// '_Complex double'). If LHS > RHS, return 1. If LHS == RHS, return 0. If 6380 /// LHS < RHS, return -1. 6381 int ASTContext::getFloatingTypeOrder(QualType LHS, QualType RHS) const { 6382 FloatingRank LHSR = getFloatingRank(LHS); 6383 FloatingRank RHSR = getFloatingRank(RHS); 6384 6385 if (LHSR == RHSR) 6386 return 0; 6387 if (LHSR > RHSR) 6388 return 1; 6389 return -1; 6390 } 6391 6392 int ASTContext::getFloatingTypeSemanticOrder(QualType LHS, QualType RHS) const { 6393 if (&getFloatTypeSemantics(LHS) == &getFloatTypeSemantics(RHS)) 6394 return 0; 6395 return getFloatingTypeOrder(LHS, RHS); 6396 } 6397 6398 /// getIntegerRank - Return an integer conversion rank (C99 6.3.1.1p1). This 6399 /// routine will assert if passed a built-in type that isn't an integer or enum, 6400 /// or if it is not canonicalized. 6401 unsigned ASTContext::getIntegerRank(const Type *T) const { 6402 assert(T->isCanonicalUnqualified() && "T should be canonicalized"); 6403 6404 // Results in this 'losing' to any type of the same size, but winning if 6405 // larger. 6406 if (const auto *EIT = dyn_cast<ExtIntType>(T)) 6407 return 0 + (EIT->getNumBits() << 3); 6408 6409 switch (cast<BuiltinType>(T)->getKind()) { 6410 default: llvm_unreachable("getIntegerRank(): not a built-in integer"); 6411 case BuiltinType::Bool: 6412 return 1 + (getIntWidth(BoolTy) << 3); 6413 case BuiltinType::Char_S: 6414 case BuiltinType::Char_U: 6415 case BuiltinType::SChar: 6416 case BuiltinType::UChar: 6417 return 2 + (getIntWidth(CharTy) << 3); 6418 case BuiltinType::Short: 6419 case BuiltinType::UShort: 6420 return 3 + (getIntWidth(ShortTy) << 3); 6421 case BuiltinType::Int: 6422 case BuiltinType::UInt: 6423 return 4 + (getIntWidth(IntTy) << 3); 6424 case BuiltinType::Long: 6425 case BuiltinType::ULong: 6426 return 5 + (getIntWidth(LongTy) << 3); 6427 case BuiltinType::LongLong: 6428 case BuiltinType::ULongLong: 6429 return 6 + (getIntWidth(LongLongTy) << 3); 6430 case BuiltinType::Int128: 6431 case BuiltinType::UInt128: 6432 return 7 + (getIntWidth(Int128Ty) << 3); 6433 } 6434 } 6435 6436 /// Whether this is a promotable bitfield reference according 6437 /// to C99 6.3.1.1p2, bullet 2 (and GCC extensions). 6438 /// 6439 /// \returns the type this bit-field will promote to, or NULL if no 6440 /// promotion occurs. 6441 QualType ASTContext::isPromotableBitField(Expr *E) const { 6442 if (E->isTypeDependent() || E->isValueDependent()) 6443 return {}; 6444 6445 // C++ [conv.prom]p5: 6446 // If the bit-field has an enumerated type, it is treated as any other 6447 // value of that type for promotion purposes. 6448 if (getLangOpts().CPlusPlus && E->getType()->isEnumeralType()) 6449 return {}; 6450 6451 // FIXME: We should not do this unless E->refersToBitField() is true. This 6452 // matters in C where getSourceBitField() will find bit-fields for various 6453 // cases where the source expression is not a bit-field designator. 6454 6455 FieldDecl *Field = E->getSourceBitField(); // FIXME: conditional bit-fields? 6456 if (!Field) 6457 return {}; 6458 6459 QualType FT = Field->getType(); 6460 6461 uint64_t BitWidth = Field->getBitWidthValue(*this); 6462 uint64_t IntSize = getTypeSize(IntTy); 6463 // C++ [conv.prom]p5: 6464 // A prvalue for an integral bit-field can be converted to a prvalue of type 6465 // int if int can represent all the values of the bit-field; otherwise, it 6466 // can be converted to unsigned int if unsigned int can represent all the 6467 // values of the bit-field. If the bit-field is larger yet, no integral 6468 // promotion applies to it. 6469 // C11 6.3.1.1/2: 6470 // [For a bit-field of type _Bool, int, signed int, or unsigned int:] 6471 // If an int can represent all values of the original type (as restricted by 6472 // the width, for a bit-field), the value is converted to an int; otherwise, 6473 // it is converted to an unsigned int. 6474 // 6475 // FIXME: C does not permit promotion of a 'long : 3' bitfield to int. 6476 // We perform that promotion here to match GCC and C++. 6477 // FIXME: C does not permit promotion of an enum bit-field whose rank is 6478 // greater than that of 'int'. We perform that promotion to match GCC. 6479 if (BitWidth < IntSize) 6480 return IntTy; 6481 6482 if (BitWidth == IntSize) 6483 return FT->isSignedIntegerType() ? IntTy : UnsignedIntTy; 6484 6485 // Bit-fields wider than int are not subject to promotions, and therefore act 6486 // like the base type. GCC has some weird bugs in this area that we 6487 // deliberately do not follow (GCC follows a pre-standard resolution to 6488 // C's DR315 which treats bit-width as being part of the type, and this leaks 6489 // into their semantics in some cases). 6490 return {}; 6491 } 6492 6493 /// getPromotedIntegerType - Returns the type that Promotable will 6494 /// promote to: C99 6.3.1.1p2, assuming that Promotable is a promotable 6495 /// integer type. 6496 QualType ASTContext::getPromotedIntegerType(QualType Promotable) const { 6497 assert(!Promotable.isNull()); 6498 assert(Promotable->isPromotableIntegerType()); 6499 if (const auto *ET = Promotable->getAs<EnumType>()) 6500 return ET->getDecl()->getPromotionType(); 6501 6502 if (const auto *BT = Promotable->getAs<BuiltinType>()) { 6503 // C++ [conv.prom]: A prvalue of type char16_t, char32_t, or wchar_t 6504 // (3.9.1) can be converted to a prvalue of the first of the following 6505 // types that can represent all the values of its underlying type: 6506 // int, unsigned int, long int, unsigned long int, long long int, or 6507 // unsigned long long int [...] 6508 // FIXME: Is there some better way to compute this? 6509 if (BT->getKind() == BuiltinType::WChar_S || 6510 BT->getKind() == BuiltinType::WChar_U || 6511 BT->getKind() == BuiltinType::Char8 || 6512 BT->getKind() == BuiltinType::Char16 || 6513 BT->getKind() == BuiltinType::Char32) { 6514 bool FromIsSigned = BT->getKind() == BuiltinType::WChar_S; 6515 uint64_t FromSize = getTypeSize(BT); 6516 QualType PromoteTypes[] = { IntTy, UnsignedIntTy, LongTy, UnsignedLongTy, 6517 LongLongTy, UnsignedLongLongTy }; 6518 for (size_t Idx = 0; Idx < llvm::array_lengthof(PromoteTypes); ++Idx) { 6519 uint64_t ToSize = getTypeSize(PromoteTypes[Idx]); 6520 if (FromSize < ToSize || 6521 (FromSize == ToSize && 6522 FromIsSigned == PromoteTypes[Idx]->isSignedIntegerType())) 6523 return PromoteTypes[Idx]; 6524 } 6525 llvm_unreachable("char type should fit into long long"); 6526 } 6527 } 6528 6529 // At this point, we should have a signed or unsigned integer type. 6530 if (Promotable->isSignedIntegerType()) 6531 return IntTy; 6532 uint64_t PromotableSize = getIntWidth(Promotable); 6533 uint64_t IntSize = getIntWidth(IntTy); 6534 assert(Promotable->isUnsignedIntegerType() && PromotableSize <= IntSize); 6535 return (PromotableSize != IntSize) ? IntTy : UnsignedIntTy; 6536 } 6537 6538 /// Recurses in pointer/array types until it finds an objc retainable 6539 /// type and returns its ownership. 6540 Qualifiers::ObjCLifetime ASTContext::getInnerObjCOwnership(QualType T) const { 6541 while (!T.isNull()) { 6542 if (T.getObjCLifetime() != Qualifiers::OCL_None) 6543 return T.getObjCLifetime(); 6544 if (T->isArrayType()) 6545 T = getBaseElementType(T); 6546 else if (const auto *PT = T->getAs<PointerType>()) 6547 T = PT->getPointeeType(); 6548 else if (const auto *RT = T->getAs<ReferenceType>()) 6549 T = RT->getPointeeType(); 6550 else 6551 break; 6552 } 6553 6554 return Qualifiers::OCL_None; 6555 } 6556 6557 static const Type *getIntegerTypeForEnum(const EnumType *ET) { 6558 // Incomplete enum types are not treated as integer types. 6559 // FIXME: In C++, enum types are never integer types. 6560 if (ET->getDecl()->isComplete() && !ET->getDecl()->isScoped()) 6561 return ET->getDecl()->getIntegerType().getTypePtr(); 6562 return nullptr; 6563 } 6564 6565 /// getIntegerTypeOrder - Returns the highest ranked integer type: 6566 /// C99 6.3.1.8p1. If LHS > RHS, return 1. If LHS == RHS, return 0. If 6567 /// LHS < RHS, return -1. 6568 int ASTContext::getIntegerTypeOrder(QualType LHS, QualType RHS) const { 6569 const Type *LHSC = getCanonicalType(LHS).getTypePtr(); 6570 const Type *RHSC = getCanonicalType(RHS).getTypePtr(); 6571 6572 // Unwrap enums to their underlying type. 6573 if (const auto *ET = dyn_cast<EnumType>(LHSC)) 6574 LHSC = getIntegerTypeForEnum(ET); 6575 if (const auto *ET = dyn_cast<EnumType>(RHSC)) 6576 RHSC = getIntegerTypeForEnum(ET); 6577 6578 if (LHSC == RHSC) return 0; 6579 6580 bool LHSUnsigned = LHSC->isUnsignedIntegerType(); 6581 bool RHSUnsigned = RHSC->isUnsignedIntegerType(); 6582 6583 unsigned LHSRank = getIntegerRank(LHSC); 6584 unsigned RHSRank = getIntegerRank(RHSC); 6585 6586 if (LHSUnsigned == RHSUnsigned) { // Both signed or both unsigned. 6587 if (LHSRank == RHSRank) return 0; 6588 return LHSRank > RHSRank ? 1 : -1; 6589 } 6590 6591 // Otherwise, the LHS is signed and the RHS is unsigned or visa versa. 6592 if (LHSUnsigned) { 6593 // If the unsigned [LHS] type is larger, return it. 6594 if (LHSRank >= RHSRank) 6595 return 1; 6596 6597 // If the signed type can represent all values of the unsigned type, it 6598 // wins. Because we are dealing with 2's complement and types that are 6599 // powers of two larger than each other, this is always safe. 6600 return -1; 6601 } 6602 6603 // If the unsigned [RHS] type is larger, return it. 6604 if (RHSRank >= LHSRank) 6605 return -1; 6606 6607 // If the signed type can represent all values of the unsigned type, it 6608 // wins. Because we are dealing with 2's complement and types that are 6609 // powers of two larger than each other, this is always safe. 6610 return 1; 6611 } 6612 6613 TypedefDecl *ASTContext::getCFConstantStringDecl() const { 6614 if (CFConstantStringTypeDecl) 6615 return CFConstantStringTypeDecl; 6616 6617 assert(!CFConstantStringTagDecl && 6618 "tag and typedef should be initialized together"); 6619 CFConstantStringTagDecl = buildImplicitRecord("__NSConstantString_tag"); 6620 CFConstantStringTagDecl->startDefinition(); 6621 6622 struct { 6623 QualType Type; 6624 const char *Name; 6625 } Fields[5]; 6626 unsigned Count = 0; 6627 6628 /// Objective-C ABI 6629 /// 6630 /// typedef struct __NSConstantString_tag { 6631 /// const int *isa; 6632 /// int flags; 6633 /// const char *str; 6634 /// long length; 6635 /// } __NSConstantString; 6636 /// 6637 /// Swift ABI (4.1, 4.2) 6638 /// 6639 /// typedef struct __NSConstantString_tag { 6640 /// uintptr_t _cfisa; 6641 /// uintptr_t _swift_rc; 6642 /// _Atomic(uint64_t) _cfinfoa; 6643 /// const char *_ptr; 6644 /// uint32_t _length; 6645 /// } __NSConstantString; 6646 /// 6647 /// Swift ABI (5.0) 6648 /// 6649 /// typedef struct __NSConstantString_tag { 6650 /// uintptr_t _cfisa; 6651 /// uintptr_t _swift_rc; 6652 /// _Atomic(uint64_t) _cfinfoa; 6653 /// const char *_ptr; 6654 /// uintptr_t _length; 6655 /// } __NSConstantString; 6656 6657 const auto CFRuntime = getLangOpts().CFRuntime; 6658 if (static_cast<unsigned>(CFRuntime) < 6659 static_cast<unsigned>(LangOptions::CoreFoundationABI::Swift)) { 6660 Fields[Count++] = { getPointerType(IntTy.withConst()), "isa" }; 6661 Fields[Count++] = { IntTy, "flags" }; 6662 Fields[Count++] = { getPointerType(CharTy.withConst()), "str" }; 6663 Fields[Count++] = { LongTy, "length" }; 6664 } else { 6665 Fields[Count++] = { getUIntPtrType(), "_cfisa" }; 6666 Fields[Count++] = { getUIntPtrType(), "_swift_rc" }; 6667 Fields[Count++] = { getFromTargetType(Target->getUInt64Type()), "_swift_rc" }; 6668 Fields[Count++] = { getPointerType(CharTy.withConst()), "_ptr" }; 6669 if (CFRuntime == LangOptions::CoreFoundationABI::Swift4_1 || 6670 CFRuntime == LangOptions::CoreFoundationABI::Swift4_2) 6671 Fields[Count++] = { IntTy, "_ptr" }; 6672 else 6673 Fields[Count++] = { getUIntPtrType(), "_ptr" }; 6674 } 6675 6676 // Create fields 6677 for (unsigned i = 0; i < Count; ++i) { 6678 FieldDecl *Field = 6679 FieldDecl::Create(*this, CFConstantStringTagDecl, SourceLocation(), 6680 SourceLocation(), &Idents.get(Fields[i].Name), 6681 Fields[i].Type, /*TInfo=*/nullptr, 6682 /*BitWidth=*/nullptr, /*Mutable=*/false, ICIS_NoInit); 6683 Field->setAccess(AS_public); 6684 CFConstantStringTagDecl->addDecl(Field); 6685 } 6686 6687 CFConstantStringTagDecl->completeDefinition(); 6688 // This type is designed to be compatible with NSConstantString, but cannot 6689 // use the same name, since NSConstantString is an interface. 6690 auto tagType = getTagDeclType(CFConstantStringTagDecl); 6691 CFConstantStringTypeDecl = 6692 buildImplicitTypedef(tagType, "__NSConstantString"); 6693 6694 return CFConstantStringTypeDecl; 6695 } 6696 6697 RecordDecl *ASTContext::getCFConstantStringTagDecl() const { 6698 if (!CFConstantStringTagDecl) 6699 getCFConstantStringDecl(); // Build the tag and the typedef. 6700 return CFConstantStringTagDecl; 6701 } 6702 6703 // getCFConstantStringType - Return the type used for constant CFStrings. 6704 QualType ASTContext::getCFConstantStringType() const { 6705 return getTypedefType(getCFConstantStringDecl()); 6706 } 6707 6708 QualType ASTContext::getObjCSuperType() const { 6709 if (ObjCSuperType.isNull()) { 6710 RecordDecl *ObjCSuperTypeDecl = buildImplicitRecord("objc_super"); 6711 getTranslationUnitDecl()->addDecl(ObjCSuperTypeDecl); 6712 ObjCSuperType = getTagDeclType(ObjCSuperTypeDecl); 6713 } 6714 return ObjCSuperType; 6715 } 6716 6717 void ASTContext::setCFConstantStringType(QualType T) { 6718 const auto *TD = T->castAs<TypedefType>(); 6719 CFConstantStringTypeDecl = cast<TypedefDecl>(TD->getDecl()); 6720 const auto *TagType = 6721 CFConstantStringTypeDecl->getUnderlyingType()->castAs<RecordType>(); 6722 CFConstantStringTagDecl = TagType->getDecl(); 6723 } 6724 6725 QualType ASTContext::getBlockDescriptorType() const { 6726 if (BlockDescriptorType) 6727 return getTagDeclType(BlockDescriptorType); 6728 6729 RecordDecl *RD; 6730 // FIXME: Needs the FlagAppleBlock bit. 6731 RD = buildImplicitRecord("__block_descriptor"); 6732 RD->startDefinition(); 6733 6734 QualType FieldTypes[] = { 6735 UnsignedLongTy, 6736 UnsignedLongTy, 6737 }; 6738 6739 static const char *const FieldNames[] = { 6740 "reserved", 6741 "Size" 6742 }; 6743 6744 for (size_t i = 0; i < 2; ++i) { 6745 FieldDecl *Field = FieldDecl::Create( 6746 *this, RD, SourceLocation(), SourceLocation(), 6747 &Idents.get(FieldNames[i]), FieldTypes[i], /*TInfo=*/nullptr, 6748 /*BitWidth=*/nullptr, /*Mutable=*/false, ICIS_NoInit); 6749 Field->setAccess(AS_public); 6750 RD->addDecl(Field); 6751 } 6752 6753 RD->completeDefinition(); 6754 6755 BlockDescriptorType = RD; 6756 6757 return getTagDeclType(BlockDescriptorType); 6758 } 6759 6760 QualType ASTContext::getBlockDescriptorExtendedType() const { 6761 if (BlockDescriptorExtendedType) 6762 return getTagDeclType(BlockDescriptorExtendedType); 6763 6764 RecordDecl *RD; 6765 // FIXME: Needs the FlagAppleBlock bit. 6766 RD = buildImplicitRecord("__block_descriptor_withcopydispose"); 6767 RD->startDefinition(); 6768 6769 QualType FieldTypes[] = { 6770 UnsignedLongTy, 6771 UnsignedLongTy, 6772 getPointerType(VoidPtrTy), 6773 getPointerType(VoidPtrTy) 6774 }; 6775 6776 static const char *const FieldNames[] = { 6777 "reserved", 6778 "Size", 6779 "CopyFuncPtr", 6780 "DestroyFuncPtr" 6781 }; 6782 6783 for (size_t i = 0; i < 4; ++i) { 6784 FieldDecl *Field = FieldDecl::Create( 6785 *this, RD, SourceLocation(), SourceLocation(), 6786 &Idents.get(FieldNames[i]), FieldTypes[i], /*TInfo=*/nullptr, 6787 /*BitWidth=*/nullptr, 6788 /*Mutable=*/false, ICIS_NoInit); 6789 Field->setAccess(AS_public); 6790 RD->addDecl(Field); 6791 } 6792 6793 RD->completeDefinition(); 6794 6795 BlockDescriptorExtendedType = RD; 6796 return getTagDeclType(BlockDescriptorExtendedType); 6797 } 6798 6799 OpenCLTypeKind ASTContext::getOpenCLTypeKind(const Type *T) const { 6800 const auto *BT = dyn_cast<BuiltinType>(T); 6801 6802 if (!BT) { 6803 if (isa<PipeType>(T)) 6804 return OCLTK_Pipe; 6805 6806 return OCLTK_Default; 6807 } 6808 6809 switch (BT->getKind()) { 6810 #define IMAGE_TYPE(ImgType, Id, SingletonId, Access, Suffix) \ 6811 case BuiltinType::Id: \ 6812 return OCLTK_Image; 6813 #include "clang/Basic/OpenCLImageTypes.def" 6814 6815 case BuiltinType::OCLClkEvent: 6816 return OCLTK_ClkEvent; 6817 6818 case BuiltinType::OCLEvent: 6819 return OCLTK_Event; 6820 6821 case BuiltinType::OCLQueue: 6822 return OCLTK_Queue; 6823 6824 case BuiltinType::OCLReserveID: 6825 return OCLTK_ReserveID; 6826 6827 case BuiltinType::OCLSampler: 6828 return OCLTK_Sampler; 6829 6830 default: 6831 return OCLTK_Default; 6832 } 6833 } 6834 6835 LangAS ASTContext::getOpenCLTypeAddrSpace(const Type *T) const { 6836 return Target->getOpenCLTypeAddrSpace(getOpenCLTypeKind(T)); 6837 } 6838 6839 /// BlockRequiresCopying - Returns true if byref variable "D" of type "Ty" 6840 /// requires copy/dispose. Note that this must match the logic 6841 /// in buildByrefHelpers. 6842 bool ASTContext::BlockRequiresCopying(QualType Ty, 6843 const VarDecl *D) { 6844 if (const CXXRecordDecl *record = Ty->getAsCXXRecordDecl()) { 6845 const Expr *copyExpr = getBlockVarCopyInit(D).getCopyExpr(); 6846 if (!copyExpr && record->hasTrivialDestructor()) return false; 6847 6848 return true; 6849 } 6850 6851 // The block needs copy/destroy helpers if Ty is non-trivial to destructively 6852 // move or destroy. 6853 if (Ty.isNonTrivialToPrimitiveDestructiveMove() || Ty.isDestructedType()) 6854 return true; 6855 6856 if (!Ty->isObjCRetainableType()) return false; 6857 6858 Qualifiers qs = Ty.getQualifiers(); 6859 6860 // If we have lifetime, that dominates. 6861 if (Qualifiers::ObjCLifetime lifetime = qs.getObjCLifetime()) { 6862 switch (lifetime) { 6863 case Qualifiers::OCL_None: llvm_unreachable("impossible"); 6864 6865 // These are just bits as far as the runtime is concerned. 6866 case Qualifiers::OCL_ExplicitNone: 6867 case Qualifiers::OCL_Autoreleasing: 6868 return false; 6869 6870 // These cases should have been taken care of when checking the type's 6871 // non-triviality. 6872 case Qualifiers::OCL_Weak: 6873 case Qualifiers::OCL_Strong: 6874 llvm_unreachable("impossible"); 6875 } 6876 llvm_unreachable("fell out of lifetime switch!"); 6877 } 6878 return (Ty->isBlockPointerType() || isObjCNSObjectType(Ty) || 6879 Ty->isObjCObjectPointerType()); 6880 } 6881 6882 bool ASTContext::getByrefLifetime(QualType Ty, 6883 Qualifiers::ObjCLifetime &LifeTime, 6884 bool &HasByrefExtendedLayout) const { 6885 if (!getLangOpts().ObjC || 6886 getLangOpts().getGC() != LangOptions::NonGC) 6887 return false; 6888 6889 HasByrefExtendedLayout = false; 6890 if (Ty->isRecordType()) { 6891 HasByrefExtendedLayout = true; 6892 LifeTime = Qualifiers::OCL_None; 6893 } else if ((LifeTime = Ty.getObjCLifetime())) { 6894 // Honor the ARC qualifiers. 6895 } else if (Ty->isObjCObjectPointerType() || Ty->isBlockPointerType()) { 6896 // The MRR rule. 6897 LifeTime = Qualifiers::OCL_ExplicitNone; 6898 } else { 6899 LifeTime = Qualifiers::OCL_None; 6900 } 6901 return true; 6902 } 6903 6904 CanQualType ASTContext::getNSUIntegerType() const { 6905 assert(Target && "Expected target to be initialized"); 6906 const llvm::Triple &T = Target->getTriple(); 6907 // Windows is LLP64 rather than LP64 6908 if (T.isOSWindows() && T.isArch64Bit()) 6909 return UnsignedLongLongTy; 6910 return UnsignedLongTy; 6911 } 6912 6913 CanQualType ASTContext::getNSIntegerType() const { 6914 assert(Target && "Expected target to be initialized"); 6915 const llvm::Triple &T = Target->getTriple(); 6916 // Windows is LLP64 rather than LP64 6917 if (T.isOSWindows() && T.isArch64Bit()) 6918 return LongLongTy; 6919 return LongTy; 6920 } 6921 6922 TypedefDecl *ASTContext::getObjCInstanceTypeDecl() { 6923 if (!ObjCInstanceTypeDecl) 6924 ObjCInstanceTypeDecl = 6925 buildImplicitTypedef(getObjCIdType(), "instancetype"); 6926 return ObjCInstanceTypeDecl; 6927 } 6928 6929 // This returns true if a type has been typedefed to BOOL: 6930 // typedef <type> BOOL; 6931 static bool isTypeTypedefedAsBOOL(QualType T) { 6932 if (const auto *TT = dyn_cast<TypedefType>(T)) 6933 if (IdentifierInfo *II = TT->getDecl()->getIdentifier()) 6934 return II->isStr("BOOL"); 6935 6936 return false; 6937 } 6938 6939 /// getObjCEncodingTypeSize returns size of type for objective-c encoding 6940 /// purpose. 6941 CharUnits ASTContext::getObjCEncodingTypeSize(QualType type) const { 6942 if (!type->isIncompleteArrayType() && type->isIncompleteType()) 6943 return CharUnits::Zero(); 6944 6945 CharUnits sz = getTypeSizeInChars(type); 6946 6947 // Make all integer and enum types at least as large as an int 6948 if (sz.isPositive() && type->isIntegralOrEnumerationType()) 6949 sz = std::max(sz, getTypeSizeInChars(IntTy)); 6950 // Treat arrays as pointers, since that's how they're passed in. 6951 else if (type->isArrayType()) 6952 sz = getTypeSizeInChars(VoidPtrTy); 6953 return sz; 6954 } 6955 6956 bool ASTContext::isMSStaticDataMemberInlineDefinition(const VarDecl *VD) const { 6957 return getTargetInfo().getCXXABI().isMicrosoft() && 6958 VD->isStaticDataMember() && 6959 VD->getType()->isIntegralOrEnumerationType() && 6960 !VD->getFirstDecl()->isOutOfLine() && VD->getFirstDecl()->hasInit(); 6961 } 6962 6963 ASTContext::InlineVariableDefinitionKind 6964 ASTContext::getInlineVariableDefinitionKind(const VarDecl *VD) const { 6965 if (!VD->isInline()) 6966 return InlineVariableDefinitionKind::None; 6967 6968 // In almost all cases, it's a weak definition. 6969 auto *First = VD->getFirstDecl(); 6970 if (First->isInlineSpecified() || !First->isStaticDataMember()) 6971 return InlineVariableDefinitionKind::Weak; 6972 6973 // If there's a file-context declaration in this translation unit, it's a 6974 // non-discardable definition. 6975 for (auto *D : VD->redecls()) 6976 if (D->getLexicalDeclContext()->isFileContext() && 6977 !D->isInlineSpecified() && (D->isConstexpr() || First->isConstexpr())) 6978 return InlineVariableDefinitionKind::Strong; 6979 6980 // If we've not seen one yet, we don't know. 6981 return InlineVariableDefinitionKind::WeakUnknown; 6982 } 6983 6984 static std::string charUnitsToString(const CharUnits &CU) { 6985 return llvm::itostr(CU.getQuantity()); 6986 } 6987 6988 /// getObjCEncodingForBlock - Return the encoded type for this block 6989 /// declaration. 6990 std::string ASTContext::getObjCEncodingForBlock(const BlockExpr *Expr) const { 6991 std::string S; 6992 6993 const BlockDecl *Decl = Expr->getBlockDecl(); 6994 QualType BlockTy = 6995 Expr->getType()->castAs<BlockPointerType>()->getPointeeType(); 6996 QualType BlockReturnTy = BlockTy->castAs<FunctionType>()->getReturnType(); 6997 // Encode result type. 6998 if (getLangOpts().EncodeExtendedBlockSig) 6999 getObjCEncodingForMethodParameter(Decl::OBJC_TQ_None, BlockReturnTy, S, 7000 true /*Extended*/); 7001 else 7002 getObjCEncodingForType(BlockReturnTy, S); 7003 // Compute size of all parameters. 7004 // Start with computing size of a pointer in number of bytes. 7005 // FIXME: There might(should) be a better way of doing this computation! 7006 CharUnits PtrSize = getTypeSizeInChars(VoidPtrTy); 7007 CharUnits ParmOffset = PtrSize; 7008 for (auto PI : Decl->parameters()) { 7009 QualType PType = PI->getType(); 7010 CharUnits sz = getObjCEncodingTypeSize(PType); 7011 if (sz.isZero()) 7012 continue; 7013 assert(sz.isPositive() && "BlockExpr - Incomplete param type"); 7014 ParmOffset += sz; 7015 } 7016 // Size of the argument frame 7017 S += charUnitsToString(ParmOffset); 7018 // Block pointer and offset. 7019 S += "@?0"; 7020 7021 // Argument types. 7022 ParmOffset = PtrSize; 7023 for (auto PVDecl : Decl->parameters()) { 7024 QualType PType = PVDecl->getOriginalType(); 7025 if (const auto *AT = 7026 dyn_cast<ArrayType>(PType->getCanonicalTypeInternal())) { 7027 // Use array's original type only if it has known number of 7028 // elements. 7029 if (!isa<ConstantArrayType>(AT)) 7030 PType = PVDecl->getType(); 7031 } else if (PType->isFunctionType()) 7032 PType = PVDecl->getType(); 7033 if (getLangOpts().EncodeExtendedBlockSig) 7034 getObjCEncodingForMethodParameter(Decl::OBJC_TQ_None, PType, 7035 S, true /*Extended*/); 7036 else 7037 getObjCEncodingForType(PType, S); 7038 S += charUnitsToString(ParmOffset); 7039 ParmOffset += getObjCEncodingTypeSize(PType); 7040 } 7041 7042 return S; 7043 } 7044 7045 std::string 7046 ASTContext::getObjCEncodingForFunctionDecl(const FunctionDecl *Decl) const { 7047 std::string S; 7048 // Encode result type. 7049 getObjCEncodingForType(Decl->getReturnType(), S); 7050 CharUnits ParmOffset; 7051 // Compute size of all parameters. 7052 for (auto PI : Decl->parameters()) { 7053 QualType PType = PI->getType(); 7054 CharUnits sz = getObjCEncodingTypeSize(PType); 7055 if (sz.isZero()) 7056 continue; 7057 7058 assert(sz.isPositive() && 7059 "getObjCEncodingForFunctionDecl - Incomplete param type"); 7060 ParmOffset += sz; 7061 } 7062 S += charUnitsToString(ParmOffset); 7063 ParmOffset = CharUnits::Zero(); 7064 7065 // Argument types. 7066 for (auto PVDecl : Decl->parameters()) { 7067 QualType PType = PVDecl->getOriginalType(); 7068 if (const auto *AT = 7069 dyn_cast<ArrayType>(PType->getCanonicalTypeInternal())) { 7070 // Use array's original type only if it has known number of 7071 // elements. 7072 if (!isa<ConstantArrayType>(AT)) 7073 PType = PVDecl->getType(); 7074 } else if (PType->isFunctionType()) 7075 PType = PVDecl->getType(); 7076 getObjCEncodingForType(PType, S); 7077 S += charUnitsToString(ParmOffset); 7078 ParmOffset += getObjCEncodingTypeSize(PType); 7079 } 7080 7081 return S; 7082 } 7083 7084 /// getObjCEncodingForMethodParameter - Return the encoded type for a single 7085 /// method parameter or return type. If Extended, include class names and 7086 /// block object types. 7087 void ASTContext::getObjCEncodingForMethodParameter(Decl::ObjCDeclQualifier QT, 7088 QualType T, std::string& S, 7089 bool Extended) const { 7090 // Encode type qualifier, 'in', 'inout', etc. for the parameter. 7091 getObjCEncodingForTypeQualifier(QT, S); 7092 // Encode parameter type. 7093 ObjCEncOptions Options = ObjCEncOptions() 7094 .setExpandPointedToStructures() 7095 .setExpandStructures() 7096 .setIsOutermostType(); 7097 if (Extended) 7098 Options.setEncodeBlockParameters().setEncodeClassNames(); 7099 getObjCEncodingForTypeImpl(T, S, Options, /*Field=*/nullptr); 7100 } 7101 7102 /// getObjCEncodingForMethodDecl - Return the encoded type for this method 7103 /// declaration. 7104 std::string ASTContext::getObjCEncodingForMethodDecl(const ObjCMethodDecl *Decl, 7105 bool Extended) const { 7106 // FIXME: This is not very efficient. 7107 // Encode return type. 7108 std::string S; 7109 getObjCEncodingForMethodParameter(Decl->getObjCDeclQualifier(), 7110 Decl->getReturnType(), S, Extended); 7111 // Compute size of all parameters. 7112 // Start with computing size of a pointer in number of bytes. 7113 // FIXME: There might(should) be a better way of doing this computation! 7114 CharUnits PtrSize = getTypeSizeInChars(VoidPtrTy); 7115 // The first two arguments (self and _cmd) are pointers; account for 7116 // their size. 7117 CharUnits ParmOffset = 2 * PtrSize; 7118 for (ObjCMethodDecl::param_const_iterator PI = Decl->param_begin(), 7119 E = Decl->sel_param_end(); PI != E; ++PI) { 7120 QualType PType = (*PI)->getType(); 7121 CharUnits sz = getObjCEncodingTypeSize(PType); 7122 if (sz.isZero()) 7123 continue; 7124 7125 assert(sz.isPositive() && 7126 "getObjCEncodingForMethodDecl - Incomplete param type"); 7127 ParmOffset += sz; 7128 } 7129 S += charUnitsToString(ParmOffset); 7130 S += "@0:"; 7131 S += charUnitsToString(PtrSize); 7132 7133 // Argument types. 7134 ParmOffset = 2 * PtrSize; 7135 for (ObjCMethodDecl::param_const_iterator PI = Decl->param_begin(), 7136 E = Decl->sel_param_end(); PI != E; ++PI) { 7137 const ParmVarDecl *PVDecl = *PI; 7138 QualType PType = PVDecl->getOriginalType(); 7139 if (const auto *AT = 7140 dyn_cast<ArrayType>(PType->getCanonicalTypeInternal())) { 7141 // Use array's original type only if it has known number of 7142 // elements. 7143 if (!isa<ConstantArrayType>(AT)) 7144 PType = PVDecl->getType(); 7145 } else if (PType->isFunctionType()) 7146 PType = PVDecl->getType(); 7147 getObjCEncodingForMethodParameter(PVDecl->getObjCDeclQualifier(), 7148 PType, S, Extended); 7149 S += charUnitsToString(ParmOffset); 7150 ParmOffset += getObjCEncodingTypeSize(PType); 7151 } 7152 7153 return S; 7154 } 7155 7156 ObjCPropertyImplDecl * 7157 ASTContext::getObjCPropertyImplDeclForPropertyDecl( 7158 const ObjCPropertyDecl *PD, 7159 const Decl *Container) const { 7160 if (!Container) 7161 return nullptr; 7162 if (const auto *CID = dyn_cast<ObjCCategoryImplDecl>(Container)) { 7163 for (auto *PID : CID->property_impls()) 7164 if (PID->getPropertyDecl() == PD) 7165 return PID; 7166 } else { 7167 const auto *OID = cast<ObjCImplementationDecl>(Container); 7168 for (auto *PID : OID->property_impls()) 7169 if (PID->getPropertyDecl() == PD) 7170 return PID; 7171 } 7172 return nullptr; 7173 } 7174 7175 /// getObjCEncodingForPropertyDecl - Return the encoded type for this 7176 /// property declaration. If non-NULL, Container must be either an 7177 /// ObjCCategoryImplDecl or ObjCImplementationDecl; it should only be 7178 /// NULL when getting encodings for protocol properties. 7179 /// Property attributes are stored as a comma-delimited C string. The simple 7180 /// attributes readonly and bycopy are encoded as single characters. The 7181 /// parametrized attributes, getter=name, setter=name, and ivar=name, are 7182 /// encoded as single characters, followed by an identifier. Property types 7183 /// are also encoded as a parametrized attribute. The characters used to encode 7184 /// these attributes are defined by the following enumeration: 7185 /// @code 7186 /// enum PropertyAttributes { 7187 /// kPropertyReadOnly = 'R', // property is read-only. 7188 /// kPropertyBycopy = 'C', // property is a copy of the value last assigned 7189 /// kPropertyByref = '&', // property is a reference to the value last assigned 7190 /// kPropertyDynamic = 'D', // property is dynamic 7191 /// kPropertyGetter = 'G', // followed by getter selector name 7192 /// kPropertySetter = 'S', // followed by setter selector name 7193 /// kPropertyInstanceVariable = 'V' // followed by instance variable name 7194 /// kPropertyType = 'T' // followed by old-style type encoding. 7195 /// kPropertyWeak = 'W' // 'weak' property 7196 /// kPropertyStrong = 'P' // property GC'able 7197 /// kPropertyNonAtomic = 'N' // property non-atomic 7198 /// }; 7199 /// @endcode 7200 std::string 7201 ASTContext::getObjCEncodingForPropertyDecl(const ObjCPropertyDecl *PD, 7202 const Decl *Container) const { 7203 // Collect information from the property implementation decl(s). 7204 bool Dynamic = false; 7205 ObjCPropertyImplDecl *SynthesizePID = nullptr; 7206 7207 if (ObjCPropertyImplDecl *PropertyImpDecl = 7208 getObjCPropertyImplDeclForPropertyDecl(PD, Container)) { 7209 if (PropertyImpDecl->getPropertyImplementation() == ObjCPropertyImplDecl::Dynamic) 7210 Dynamic = true; 7211 else 7212 SynthesizePID = PropertyImpDecl; 7213 } 7214 7215 // FIXME: This is not very efficient. 7216 std::string S = "T"; 7217 7218 // Encode result type. 7219 // GCC has some special rules regarding encoding of properties which 7220 // closely resembles encoding of ivars. 7221 getObjCEncodingForPropertyType(PD->getType(), S); 7222 7223 if (PD->isReadOnly()) { 7224 S += ",R"; 7225 if (PD->getPropertyAttributes() & ObjCPropertyAttribute::kind_copy) 7226 S += ",C"; 7227 if (PD->getPropertyAttributes() & ObjCPropertyAttribute::kind_retain) 7228 S += ",&"; 7229 if (PD->getPropertyAttributes() & ObjCPropertyAttribute::kind_weak) 7230 S += ",W"; 7231 } else { 7232 switch (PD->getSetterKind()) { 7233 case ObjCPropertyDecl::Assign: break; 7234 case ObjCPropertyDecl::Copy: S += ",C"; break; 7235 case ObjCPropertyDecl::Retain: S += ",&"; break; 7236 case ObjCPropertyDecl::Weak: S += ",W"; break; 7237 } 7238 } 7239 7240 // It really isn't clear at all what this means, since properties 7241 // are "dynamic by default". 7242 if (Dynamic) 7243 S += ",D"; 7244 7245 if (PD->getPropertyAttributes() & ObjCPropertyAttribute::kind_nonatomic) 7246 S += ",N"; 7247 7248 if (PD->getPropertyAttributes() & ObjCPropertyAttribute::kind_getter) { 7249 S += ",G"; 7250 S += PD->getGetterName().getAsString(); 7251 } 7252 7253 if (PD->getPropertyAttributes() & ObjCPropertyAttribute::kind_setter) { 7254 S += ",S"; 7255 S += PD->getSetterName().getAsString(); 7256 } 7257 7258 if (SynthesizePID) { 7259 const ObjCIvarDecl *OID = SynthesizePID->getPropertyIvarDecl(); 7260 S += ",V"; 7261 S += OID->getNameAsString(); 7262 } 7263 7264 // FIXME: OBJCGC: weak & strong 7265 return S; 7266 } 7267 7268 /// getLegacyIntegralTypeEncoding - 7269 /// Another legacy compatibility encoding: 32-bit longs are encoded as 7270 /// 'l' or 'L' , but not always. For typedefs, we need to use 7271 /// 'i' or 'I' instead if encoding a struct field, or a pointer! 7272 void ASTContext::getLegacyIntegralTypeEncoding (QualType &PointeeTy) const { 7273 if (isa<TypedefType>(PointeeTy.getTypePtr())) { 7274 if (const auto *BT = PointeeTy->getAs<BuiltinType>()) { 7275 if (BT->getKind() == BuiltinType::ULong && getIntWidth(PointeeTy) == 32) 7276 PointeeTy = UnsignedIntTy; 7277 else 7278 if (BT->getKind() == BuiltinType::Long && getIntWidth(PointeeTy) == 32) 7279 PointeeTy = IntTy; 7280 } 7281 } 7282 } 7283 7284 void ASTContext::getObjCEncodingForType(QualType T, std::string& S, 7285 const FieldDecl *Field, 7286 QualType *NotEncodedT) const { 7287 // We follow the behavior of gcc, expanding structures which are 7288 // directly pointed to, and expanding embedded structures. Note that 7289 // these rules are sufficient to prevent recursive encoding of the 7290 // same type. 7291 getObjCEncodingForTypeImpl(T, S, 7292 ObjCEncOptions() 7293 .setExpandPointedToStructures() 7294 .setExpandStructures() 7295 .setIsOutermostType(), 7296 Field, NotEncodedT); 7297 } 7298 7299 void ASTContext::getObjCEncodingForPropertyType(QualType T, 7300 std::string& S) const { 7301 // Encode result type. 7302 // GCC has some special rules regarding encoding of properties which 7303 // closely resembles encoding of ivars. 7304 getObjCEncodingForTypeImpl(T, S, 7305 ObjCEncOptions() 7306 .setExpandPointedToStructures() 7307 .setExpandStructures() 7308 .setIsOutermostType() 7309 .setEncodingProperty(), 7310 /*Field=*/nullptr); 7311 } 7312 7313 static char getObjCEncodingForPrimitiveType(const ASTContext *C, 7314 const BuiltinType *BT) { 7315 BuiltinType::Kind kind = BT->getKind(); 7316 switch (kind) { 7317 case BuiltinType::Void: return 'v'; 7318 case BuiltinType::Bool: return 'B'; 7319 case BuiltinType::Char8: 7320 case BuiltinType::Char_U: 7321 case BuiltinType::UChar: return 'C'; 7322 case BuiltinType::Char16: 7323 case BuiltinType::UShort: return 'S'; 7324 case BuiltinType::Char32: 7325 case BuiltinType::UInt: return 'I'; 7326 case BuiltinType::ULong: 7327 return C->getTargetInfo().getLongWidth() == 32 ? 'L' : 'Q'; 7328 case BuiltinType::UInt128: return 'T'; 7329 case BuiltinType::ULongLong: return 'Q'; 7330 case BuiltinType::Char_S: 7331 case BuiltinType::SChar: return 'c'; 7332 case BuiltinType::Short: return 's'; 7333 case BuiltinType::WChar_S: 7334 case BuiltinType::WChar_U: 7335 case BuiltinType::Int: return 'i'; 7336 case BuiltinType::Long: 7337 return C->getTargetInfo().getLongWidth() == 32 ? 'l' : 'q'; 7338 case BuiltinType::LongLong: return 'q'; 7339 case BuiltinType::Int128: return 't'; 7340 case BuiltinType::Float: return 'f'; 7341 case BuiltinType::Double: return 'd'; 7342 case BuiltinType::LongDouble: return 'D'; 7343 case BuiltinType::NullPtr: return '*'; // like char* 7344 7345 case BuiltinType::BFloat16: 7346 case BuiltinType::Float16: 7347 case BuiltinType::Float128: 7348 case BuiltinType::Ibm128: 7349 case BuiltinType::Half: 7350 case BuiltinType::ShortAccum: 7351 case BuiltinType::Accum: 7352 case BuiltinType::LongAccum: 7353 case BuiltinType::UShortAccum: 7354 case BuiltinType::UAccum: 7355 case BuiltinType::ULongAccum: 7356 case BuiltinType::ShortFract: 7357 case BuiltinType::Fract: 7358 case BuiltinType::LongFract: 7359 case BuiltinType::UShortFract: 7360 case BuiltinType::UFract: 7361 case BuiltinType::ULongFract: 7362 case BuiltinType::SatShortAccum: 7363 case BuiltinType::SatAccum: 7364 case BuiltinType::SatLongAccum: 7365 case BuiltinType::SatUShortAccum: 7366 case BuiltinType::SatUAccum: 7367 case BuiltinType::SatULongAccum: 7368 case BuiltinType::SatShortFract: 7369 case BuiltinType::SatFract: 7370 case BuiltinType::SatLongFract: 7371 case BuiltinType::SatUShortFract: 7372 case BuiltinType::SatUFract: 7373 case BuiltinType::SatULongFract: 7374 // FIXME: potentially need @encodes for these! 7375 return ' '; 7376 7377 #define SVE_TYPE(Name, Id, SingletonId) \ 7378 case BuiltinType::Id: 7379 #include "clang/Basic/AArch64SVEACLETypes.def" 7380 #define RVV_TYPE(Name, Id, SingletonId) case BuiltinType::Id: 7381 #include "clang/Basic/RISCVVTypes.def" 7382 { 7383 DiagnosticsEngine &Diags = C->getDiagnostics(); 7384 unsigned DiagID = Diags.getCustomDiagID(DiagnosticsEngine::Error, 7385 "cannot yet @encode type %0"); 7386 Diags.Report(DiagID) << BT->getName(C->getPrintingPolicy()); 7387 return ' '; 7388 } 7389 7390 case BuiltinType::ObjCId: 7391 case BuiltinType::ObjCClass: 7392 case BuiltinType::ObjCSel: 7393 llvm_unreachable("@encoding ObjC primitive type"); 7394 7395 // OpenCL and placeholder types don't need @encodings. 7396 #define IMAGE_TYPE(ImgType, Id, SingletonId, Access, Suffix) \ 7397 case BuiltinType::Id: 7398 #include "clang/Basic/OpenCLImageTypes.def" 7399 #define EXT_OPAQUE_TYPE(ExtType, Id, Ext) \ 7400 case BuiltinType::Id: 7401 #include "clang/Basic/OpenCLExtensionTypes.def" 7402 case BuiltinType::OCLEvent: 7403 case BuiltinType::OCLClkEvent: 7404 case BuiltinType::OCLQueue: 7405 case BuiltinType::OCLReserveID: 7406 case BuiltinType::OCLSampler: 7407 case BuiltinType::Dependent: 7408 #define PPC_VECTOR_TYPE(Name, Id, Size) \ 7409 case BuiltinType::Id: 7410 #include "clang/Basic/PPCTypes.def" 7411 #define BUILTIN_TYPE(KIND, ID) 7412 #define PLACEHOLDER_TYPE(KIND, ID) \ 7413 case BuiltinType::KIND: 7414 #include "clang/AST/BuiltinTypes.def" 7415 llvm_unreachable("invalid builtin type for @encode"); 7416 } 7417 llvm_unreachable("invalid BuiltinType::Kind value"); 7418 } 7419 7420 static char ObjCEncodingForEnumType(const ASTContext *C, const EnumType *ET) { 7421 EnumDecl *Enum = ET->getDecl(); 7422 7423 // The encoding of an non-fixed enum type is always 'i', regardless of size. 7424 if (!Enum->isFixed()) 7425 return 'i'; 7426 7427 // The encoding of a fixed enum type matches its fixed underlying type. 7428 const auto *BT = Enum->getIntegerType()->castAs<BuiltinType>(); 7429 return getObjCEncodingForPrimitiveType(C, BT); 7430 } 7431 7432 static void EncodeBitField(const ASTContext *Ctx, std::string& S, 7433 QualType T, const FieldDecl *FD) { 7434 assert(FD->isBitField() && "not a bitfield - getObjCEncodingForTypeImpl"); 7435 S += 'b'; 7436 // The NeXT runtime encodes bit fields as b followed by the number of bits. 7437 // The GNU runtime requires more information; bitfields are encoded as b, 7438 // then the offset (in bits) of the first element, then the type of the 7439 // bitfield, then the size in bits. For example, in this structure: 7440 // 7441 // struct 7442 // { 7443 // int integer; 7444 // int flags:2; 7445 // }; 7446 // On a 32-bit system, the encoding for flags would be b2 for the NeXT 7447 // runtime, but b32i2 for the GNU runtime. The reason for this extra 7448 // information is not especially sensible, but we're stuck with it for 7449 // compatibility with GCC, although providing it breaks anything that 7450 // actually uses runtime introspection and wants to work on both runtimes... 7451 if (Ctx->getLangOpts().ObjCRuntime.isGNUFamily()) { 7452 uint64_t Offset; 7453 7454 if (const auto *IVD = dyn_cast<ObjCIvarDecl>(FD)) { 7455 Offset = Ctx->lookupFieldBitOffset(IVD->getContainingInterface(), nullptr, 7456 IVD); 7457 } else { 7458 const RecordDecl *RD = FD->getParent(); 7459 const ASTRecordLayout &RL = Ctx->getASTRecordLayout(RD); 7460 Offset = RL.getFieldOffset(FD->getFieldIndex()); 7461 } 7462 7463 S += llvm::utostr(Offset); 7464 7465 if (const auto *ET = T->getAs<EnumType>()) 7466 S += ObjCEncodingForEnumType(Ctx, ET); 7467 else { 7468 const auto *BT = T->castAs<BuiltinType>(); 7469 S += getObjCEncodingForPrimitiveType(Ctx, BT); 7470 } 7471 } 7472 S += llvm::utostr(FD->getBitWidthValue(*Ctx)); 7473 } 7474 7475 // Helper function for determining whether the encoded type string would include 7476 // a template specialization type. 7477 static bool hasTemplateSpecializationInEncodedString(const Type *T, 7478 bool VisitBasesAndFields) { 7479 T = T->getBaseElementTypeUnsafe(); 7480 7481 if (auto *PT = T->getAs<PointerType>()) 7482 return hasTemplateSpecializationInEncodedString( 7483 PT->getPointeeType().getTypePtr(), false); 7484 7485 auto *CXXRD = T->getAsCXXRecordDecl(); 7486 7487 if (!CXXRD) 7488 return false; 7489 7490 if (isa<ClassTemplateSpecializationDecl>(CXXRD)) 7491 return true; 7492 7493 if (!CXXRD->hasDefinition() || !VisitBasesAndFields) 7494 return false; 7495 7496 for (auto B : CXXRD->bases()) 7497 if (hasTemplateSpecializationInEncodedString(B.getType().getTypePtr(), 7498 true)) 7499 return true; 7500 7501 for (auto *FD : CXXRD->fields()) 7502 if (hasTemplateSpecializationInEncodedString(FD->getType().getTypePtr(), 7503 true)) 7504 return true; 7505 7506 return false; 7507 } 7508 7509 // FIXME: Use SmallString for accumulating string. 7510 void ASTContext::getObjCEncodingForTypeImpl(QualType T, std::string &S, 7511 const ObjCEncOptions Options, 7512 const FieldDecl *FD, 7513 QualType *NotEncodedT) const { 7514 CanQualType CT = getCanonicalType(T); 7515 switch (CT->getTypeClass()) { 7516 case Type::Builtin: 7517 case Type::Enum: 7518 if (FD && FD->isBitField()) 7519 return EncodeBitField(this, S, T, FD); 7520 if (const auto *BT = dyn_cast<BuiltinType>(CT)) 7521 S += getObjCEncodingForPrimitiveType(this, BT); 7522 else 7523 S += ObjCEncodingForEnumType(this, cast<EnumType>(CT)); 7524 return; 7525 7526 case Type::Complex: 7527 S += 'j'; 7528 getObjCEncodingForTypeImpl(T->castAs<ComplexType>()->getElementType(), S, 7529 ObjCEncOptions(), 7530 /*Field=*/nullptr); 7531 return; 7532 7533 case Type::Atomic: 7534 S += 'A'; 7535 getObjCEncodingForTypeImpl(T->castAs<AtomicType>()->getValueType(), S, 7536 ObjCEncOptions(), 7537 /*Field=*/nullptr); 7538 return; 7539 7540 // encoding for pointer or reference types. 7541 case Type::Pointer: 7542 case Type::LValueReference: 7543 case Type::RValueReference: { 7544 QualType PointeeTy; 7545 if (isa<PointerType>(CT)) { 7546 const auto *PT = T->castAs<PointerType>(); 7547 if (PT->isObjCSelType()) { 7548 S += ':'; 7549 return; 7550 } 7551 PointeeTy = PT->getPointeeType(); 7552 } else { 7553 PointeeTy = T->castAs<ReferenceType>()->getPointeeType(); 7554 } 7555 7556 bool isReadOnly = false; 7557 // For historical/compatibility reasons, the read-only qualifier of the 7558 // pointee gets emitted _before_ the '^'. The read-only qualifier of 7559 // the pointer itself gets ignored, _unless_ we are looking at a typedef! 7560 // Also, do not emit the 'r' for anything but the outermost type! 7561 if (isa<TypedefType>(T.getTypePtr())) { 7562 if (Options.IsOutermostType() && T.isConstQualified()) { 7563 isReadOnly = true; 7564 S += 'r'; 7565 } 7566 } else if (Options.IsOutermostType()) { 7567 QualType P = PointeeTy; 7568 while (auto PT = P->getAs<PointerType>()) 7569 P = PT->getPointeeType(); 7570 if (P.isConstQualified()) { 7571 isReadOnly = true; 7572 S += 'r'; 7573 } 7574 } 7575 if (isReadOnly) { 7576 // Another legacy compatibility encoding. Some ObjC qualifier and type 7577 // combinations need to be rearranged. 7578 // Rewrite "in const" from "nr" to "rn" 7579 if (StringRef(S).endswith("nr")) 7580 S.replace(S.end()-2, S.end(), "rn"); 7581 } 7582 7583 if (PointeeTy->isCharType()) { 7584 // char pointer types should be encoded as '*' unless it is a 7585 // type that has been typedef'd to 'BOOL'. 7586 if (!isTypeTypedefedAsBOOL(PointeeTy)) { 7587 S += '*'; 7588 return; 7589 } 7590 } else if (const auto *RTy = PointeeTy->getAs<RecordType>()) { 7591 // GCC binary compat: Need to convert "struct objc_class *" to "#". 7592 if (RTy->getDecl()->getIdentifier() == &Idents.get("objc_class")) { 7593 S += '#'; 7594 return; 7595 } 7596 // GCC binary compat: Need to convert "struct objc_object *" to "@". 7597 if (RTy->getDecl()->getIdentifier() == &Idents.get("objc_object")) { 7598 S += '@'; 7599 return; 7600 } 7601 // If the encoded string for the class includes template names, just emit 7602 // "^v" for pointers to the class. 7603 if (getLangOpts().CPlusPlus && 7604 (!getLangOpts().EncodeCXXClassTemplateSpec && 7605 hasTemplateSpecializationInEncodedString( 7606 RTy, Options.ExpandPointedToStructures()))) { 7607 S += "^v"; 7608 return; 7609 } 7610 // fall through... 7611 } 7612 S += '^'; 7613 getLegacyIntegralTypeEncoding(PointeeTy); 7614 7615 ObjCEncOptions NewOptions; 7616 if (Options.ExpandPointedToStructures()) 7617 NewOptions.setExpandStructures(); 7618 getObjCEncodingForTypeImpl(PointeeTy, S, NewOptions, 7619 /*Field=*/nullptr, NotEncodedT); 7620 return; 7621 } 7622 7623 case Type::ConstantArray: 7624 case Type::IncompleteArray: 7625 case Type::VariableArray: { 7626 const auto *AT = cast<ArrayType>(CT); 7627 7628 if (isa<IncompleteArrayType>(AT) && !Options.IsStructField()) { 7629 // Incomplete arrays are encoded as a pointer to the array element. 7630 S += '^'; 7631 7632 getObjCEncodingForTypeImpl( 7633 AT->getElementType(), S, 7634 Options.keepingOnly(ObjCEncOptions().setExpandStructures()), FD); 7635 } else { 7636 S += '['; 7637 7638 if (const auto *CAT = dyn_cast<ConstantArrayType>(AT)) 7639 S += llvm::utostr(CAT->getSize().getZExtValue()); 7640 else { 7641 //Variable length arrays are encoded as a regular array with 0 elements. 7642 assert((isa<VariableArrayType>(AT) || isa<IncompleteArrayType>(AT)) && 7643 "Unknown array type!"); 7644 S += '0'; 7645 } 7646 7647 getObjCEncodingForTypeImpl( 7648 AT->getElementType(), S, 7649 Options.keepingOnly(ObjCEncOptions().setExpandStructures()), FD, 7650 NotEncodedT); 7651 S += ']'; 7652 } 7653 return; 7654 } 7655 7656 case Type::FunctionNoProto: 7657 case Type::FunctionProto: 7658 S += '?'; 7659 return; 7660 7661 case Type::Record: { 7662 RecordDecl *RDecl = cast<RecordType>(CT)->getDecl(); 7663 S += RDecl->isUnion() ? '(' : '{'; 7664 // Anonymous structures print as '?' 7665 if (const IdentifierInfo *II = RDecl->getIdentifier()) { 7666 S += II->getName(); 7667 if (const auto *Spec = dyn_cast<ClassTemplateSpecializationDecl>(RDecl)) { 7668 const TemplateArgumentList &TemplateArgs = Spec->getTemplateArgs(); 7669 llvm::raw_string_ostream OS(S); 7670 printTemplateArgumentList(OS, TemplateArgs.asArray(), 7671 getPrintingPolicy()); 7672 } 7673 } else { 7674 S += '?'; 7675 } 7676 if (Options.ExpandStructures()) { 7677 S += '='; 7678 if (!RDecl->isUnion()) { 7679 getObjCEncodingForStructureImpl(RDecl, S, FD, true, NotEncodedT); 7680 } else { 7681 for (const auto *Field : RDecl->fields()) { 7682 if (FD) { 7683 S += '"'; 7684 S += Field->getNameAsString(); 7685 S += '"'; 7686 } 7687 7688 // Special case bit-fields. 7689 if (Field->isBitField()) { 7690 getObjCEncodingForTypeImpl(Field->getType(), S, 7691 ObjCEncOptions().setExpandStructures(), 7692 Field); 7693 } else { 7694 QualType qt = Field->getType(); 7695 getLegacyIntegralTypeEncoding(qt); 7696 getObjCEncodingForTypeImpl( 7697 qt, S, 7698 ObjCEncOptions().setExpandStructures().setIsStructField(), FD, 7699 NotEncodedT); 7700 } 7701 } 7702 } 7703 } 7704 S += RDecl->isUnion() ? ')' : '}'; 7705 return; 7706 } 7707 7708 case Type::BlockPointer: { 7709 const auto *BT = T->castAs<BlockPointerType>(); 7710 S += "@?"; // Unlike a pointer-to-function, which is "^?". 7711 if (Options.EncodeBlockParameters()) { 7712 const auto *FT = BT->getPointeeType()->castAs<FunctionType>(); 7713 7714 S += '<'; 7715 // Block return type 7716 getObjCEncodingForTypeImpl(FT->getReturnType(), S, 7717 Options.forComponentType(), FD, NotEncodedT); 7718 // Block self 7719 S += "@?"; 7720 // Block parameters 7721 if (const auto *FPT = dyn_cast<FunctionProtoType>(FT)) { 7722 for (const auto &I : FPT->param_types()) 7723 getObjCEncodingForTypeImpl(I, S, Options.forComponentType(), FD, 7724 NotEncodedT); 7725 } 7726 S += '>'; 7727 } 7728 return; 7729 } 7730 7731 case Type::ObjCObject: { 7732 // hack to match legacy encoding of *id and *Class 7733 QualType Ty = getObjCObjectPointerType(CT); 7734 if (Ty->isObjCIdType()) { 7735 S += "{objc_object=}"; 7736 return; 7737 } 7738 else if (Ty->isObjCClassType()) { 7739 S += "{objc_class=}"; 7740 return; 7741 } 7742 // TODO: Double check to make sure this intentionally falls through. 7743 LLVM_FALLTHROUGH; 7744 } 7745 7746 case Type::ObjCInterface: { 7747 // Ignore protocol qualifiers when mangling at this level. 7748 // @encode(class_name) 7749 ObjCInterfaceDecl *OI = T->castAs<ObjCObjectType>()->getInterface(); 7750 S += '{'; 7751 S += OI->getObjCRuntimeNameAsString(); 7752 if (Options.ExpandStructures()) { 7753 S += '='; 7754 SmallVector<const ObjCIvarDecl*, 32> Ivars; 7755 DeepCollectObjCIvars(OI, true, Ivars); 7756 for (unsigned i = 0, e = Ivars.size(); i != e; ++i) { 7757 const FieldDecl *Field = Ivars[i]; 7758 if (Field->isBitField()) 7759 getObjCEncodingForTypeImpl(Field->getType(), S, 7760 ObjCEncOptions().setExpandStructures(), 7761 Field); 7762 else 7763 getObjCEncodingForTypeImpl(Field->getType(), S, 7764 ObjCEncOptions().setExpandStructures(), FD, 7765 NotEncodedT); 7766 } 7767 } 7768 S += '}'; 7769 return; 7770 } 7771 7772 case Type::ObjCObjectPointer: { 7773 const auto *OPT = T->castAs<ObjCObjectPointerType>(); 7774 if (OPT->isObjCIdType()) { 7775 S += '@'; 7776 return; 7777 } 7778 7779 if (OPT->isObjCClassType() || OPT->isObjCQualifiedClassType()) { 7780 // FIXME: Consider if we need to output qualifiers for 'Class<p>'. 7781 // Since this is a binary compatibility issue, need to consult with 7782 // runtime folks. Fortunately, this is a *very* obscure construct. 7783 S += '#'; 7784 return; 7785 } 7786 7787 if (OPT->isObjCQualifiedIdType()) { 7788 getObjCEncodingForTypeImpl( 7789 getObjCIdType(), S, 7790 Options.keepingOnly(ObjCEncOptions() 7791 .setExpandPointedToStructures() 7792 .setExpandStructures()), 7793 FD); 7794 if (FD || Options.EncodingProperty() || Options.EncodeClassNames()) { 7795 // Note that we do extended encoding of protocol qualifier list 7796 // Only when doing ivar or property encoding. 7797 S += '"'; 7798 for (const auto *I : OPT->quals()) { 7799 S += '<'; 7800 S += I->getObjCRuntimeNameAsString(); 7801 S += '>'; 7802 } 7803 S += '"'; 7804 } 7805 return; 7806 } 7807 7808 S += '@'; 7809 if (OPT->getInterfaceDecl() && 7810 (FD || Options.EncodingProperty() || Options.EncodeClassNames())) { 7811 S += '"'; 7812 S += OPT->getInterfaceDecl()->getObjCRuntimeNameAsString(); 7813 for (const auto *I : OPT->quals()) { 7814 S += '<'; 7815 S += I->getObjCRuntimeNameAsString(); 7816 S += '>'; 7817 } 7818 S += '"'; 7819 } 7820 return; 7821 } 7822 7823 // gcc just blithely ignores member pointers. 7824 // FIXME: we should do better than that. 'M' is available. 7825 case Type::MemberPointer: 7826 // This matches gcc's encoding, even though technically it is insufficient. 7827 //FIXME. We should do a better job than gcc. 7828 case Type::Vector: 7829 case Type::ExtVector: 7830 // Until we have a coherent encoding of these three types, issue warning. 7831 if (NotEncodedT) 7832 *NotEncodedT = T; 7833 return; 7834 7835 case Type::ConstantMatrix: 7836 if (NotEncodedT) 7837 *NotEncodedT = T; 7838 return; 7839 7840 // We could see an undeduced auto type here during error recovery. 7841 // Just ignore it. 7842 case Type::Auto: 7843 case Type::DeducedTemplateSpecialization: 7844 return; 7845 7846 case Type::Pipe: 7847 case Type::ExtInt: 7848 #define ABSTRACT_TYPE(KIND, BASE) 7849 #define TYPE(KIND, BASE) 7850 #define DEPENDENT_TYPE(KIND, BASE) \ 7851 case Type::KIND: 7852 #define NON_CANONICAL_TYPE(KIND, BASE) \ 7853 case Type::KIND: 7854 #define NON_CANONICAL_UNLESS_DEPENDENT_TYPE(KIND, BASE) \ 7855 case Type::KIND: 7856 #include "clang/AST/TypeNodes.inc" 7857 llvm_unreachable("@encode for dependent type!"); 7858 } 7859 llvm_unreachable("bad type kind!"); 7860 } 7861 7862 void ASTContext::getObjCEncodingForStructureImpl(RecordDecl *RDecl, 7863 std::string &S, 7864 const FieldDecl *FD, 7865 bool includeVBases, 7866 QualType *NotEncodedT) const { 7867 assert(RDecl && "Expected non-null RecordDecl"); 7868 assert(!RDecl->isUnion() && "Should not be called for unions"); 7869 if (!RDecl->getDefinition() || RDecl->getDefinition()->isInvalidDecl()) 7870 return; 7871 7872 const auto *CXXRec = dyn_cast<CXXRecordDecl>(RDecl); 7873 std::multimap<uint64_t, NamedDecl *> FieldOrBaseOffsets; 7874 const ASTRecordLayout &layout = getASTRecordLayout(RDecl); 7875 7876 if (CXXRec) { 7877 for (const auto &BI : CXXRec->bases()) { 7878 if (!BI.isVirtual()) { 7879 CXXRecordDecl *base = BI.getType()->getAsCXXRecordDecl(); 7880 if (base->isEmpty()) 7881 continue; 7882 uint64_t offs = toBits(layout.getBaseClassOffset(base)); 7883 FieldOrBaseOffsets.insert(FieldOrBaseOffsets.upper_bound(offs), 7884 std::make_pair(offs, base)); 7885 } 7886 } 7887 } 7888 7889 unsigned i = 0; 7890 for (FieldDecl *Field : RDecl->fields()) { 7891 if (!Field->isZeroLengthBitField(*this) && Field->isZeroSize(*this)) 7892 continue; 7893 uint64_t offs = layout.getFieldOffset(i); 7894 FieldOrBaseOffsets.insert(FieldOrBaseOffsets.upper_bound(offs), 7895 std::make_pair(offs, Field)); 7896 ++i; 7897 } 7898 7899 if (CXXRec && includeVBases) { 7900 for (const auto &BI : CXXRec->vbases()) { 7901 CXXRecordDecl *base = BI.getType()->getAsCXXRecordDecl(); 7902 if (base->isEmpty()) 7903 continue; 7904 uint64_t offs = toBits(layout.getVBaseClassOffset(base)); 7905 if (offs >= uint64_t(toBits(layout.getNonVirtualSize())) && 7906 FieldOrBaseOffsets.find(offs) == FieldOrBaseOffsets.end()) 7907 FieldOrBaseOffsets.insert(FieldOrBaseOffsets.end(), 7908 std::make_pair(offs, base)); 7909 } 7910 } 7911 7912 CharUnits size; 7913 if (CXXRec) { 7914 size = includeVBases ? layout.getSize() : layout.getNonVirtualSize(); 7915 } else { 7916 size = layout.getSize(); 7917 } 7918 7919 #ifndef NDEBUG 7920 uint64_t CurOffs = 0; 7921 #endif 7922 std::multimap<uint64_t, NamedDecl *>::iterator 7923 CurLayObj = FieldOrBaseOffsets.begin(); 7924 7925 if (CXXRec && CXXRec->isDynamicClass() && 7926 (CurLayObj == FieldOrBaseOffsets.end() || CurLayObj->first != 0)) { 7927 if (FD) { 7928 S += "\"_vptr$"; 7929 std::string recname = CXXRec->getNameAsString(); 7930 if (recname.empty()) recname = "?"; 7931 S += recname; 7932 S += '"'; 7933 } 7934 S += "^^?"; 7935 #ifndef NDEBUG 7936 CurOffs += getTypeSize(VoidPtrTy); 7937 #endif 7938 } 7939 7940 if (!RDecl->hasFlexibleArrayMember()) { 7941 // Mark the end of the structure. 7942 uint64_t offs = toBits(size); 7943 FieldOrBaseOffsets.insert(FieldOrBaseOffsets.upper_bound(offs), 7944 std::make_pair(offs, nullptr)); 7945 } 7946 7947 for (; CurLayObj != FieldOrBaseOffsets.end(); ++CurLayObj) { 7948 #ifndef NDEBUG 7949 assert(CurOffs <= CurLayObj->first); 7950 if (CurOffs < CurLayObj->first) { 7951 uint64_t padding = CurLayObj->first - CurOffs; 7952 // FIXME: There doesn't seem to be a way to indicate in the encoding that 7953 // packing/alignment of members is different that normal, in which case 7954 // the encoding will be out-of-sync with the real layout. 7955 // If the runtime switches to just consider the size of types without 7956 // taking into account alignment, we could make padding explicit in the 7957 // encoding (e.g. using arrays of chars). The encoding strings would be 7958 // longer then though. 7959 CurOffs += padding; 7960 } 7961 #endif 7962 7963 NamedDecl *dcl = CurLayObj->second; 7964 if (!dcl) 7965 break; // reached end of structure. 7966 7967 if (auto *base = dyn_cast<CXXRecordDecl>(dcl)) { 7968 // We expand the bases without their virtual bases since those are going 7969 // in the initial structure. Note that this differs from gcc which 7970 // expands virtual bases each time one is encountered in the hierarchy, 7971 // making the encoding type bigger than it really is. 7972 getObjCEncodingForStructureImpl(base, S, FD, /*includeVBases*/false, 7973 NotEncodedT); 7974 assert(!base->isEmpty()); 7975 #ifndef NDEBUG 7976 CurOffs += toBits(getASTRecordLayout(base).getNonVirtualSize()); 7977 #endif 7978 } else { 7979 const auto *field = cast<FieldDecl>(dcl); 7980 if (FD) { 7981 S += '"'; 7982 S += field->getNameAsString(); 7983 S += '"'; 7984 } 7985 7986 if (field->isBitField()) { 7987 EncodeBitField(this, S, field->getType(), field); 7988 #ifndef NDEBUG 7989 CurOffs += field->getBitWidthValue(*this); 7990 #endif 7991 } else { 7992 QualType qt = field->getType(); 7993 getLegacyIntegralTypeEncoding(qt); 7994 getObjCEncodingForTypeImpl( 7995 qt, S, ObjCEncOptions().setExpandStructures().setIsStructField(), 7996 FD, NotEncodedT); 7997 #ifndef NDEBUG 7998 CurOffs += getTypeSize(field->getType()); 7999 #endif 8000 } 8001 } 8002 } 8003 } 8004 8005 void ASTContext::getObjCEncodingForTypeQualifier(Decl::ObjCDeclQualifier QT, 8006 std::string& S) const { 8007 if (QT & Decl::OBJC_TQ_In) 8008 S += 'n'; 8009 if (QT & Decl::OBJC_TQ_Inout) 8010 S += 'N'; 8011 if (QT & Decl::OBJC_TQ_Out) 8012 S += 'o'; 8013 if (QT & Decl::OBJC_TQ_Bycopy) 8014 S += 'O'; 8015 if (QT & Decl::OBJC_TQ_Byref) 8016 S += 'R'; 8017 if (QT & Decl::OBJC_TQ_Oneway) 8018 S += 'V'; 8019 } 8020 8021 TypedefDecl *ASTContext::getObjCIdDecl() const { 8022 if (!ObjCIdDecl) { 8023 QualType T = getObjCObjectType(ObjCBuiltinIdTy, {}, {}); 8024 T = getObjCObjectPointerType(T); 8025 ObjCIdDecl = buildImplicitTypedef(T, "id"); 8026 } 8027 return ObjCIdDecl; 8028 } 8029 8030 TypedefDecl *ASTContext::getObjCSelDecl() const { 8031 if (!ObjCSelDecl) { 8032 QualType T = getPointerType(ObjCBuiltinSelTy); 8033 ObjCSelDecl = buildImplicitTypedef(T, "SEL"); 8034 } 8035 return ObjCSelDecl; 8036 } 8037 8038 TypedefDecl *ASTContext::getObjCClassDecl() const { 8039 if (!ObjCClassDecl) { 8040 QualType T = getObjCObjectType(ObjCBuiltinClassTy, {}, {}); 8041 T = getObjCObjectPointerType(T); 8042 ObjCClassDecl = buildImplicitTypedef(T, "Class"); 8043 } 8044 return ObjCClassDecl; 8045 } 8046 8047 ObjCInterfaceDecl *ASTContext::getObjCProtocolDecl() const { 8048 if (!ObjCProtocolClassDecl) { 8049 ObjCProtocolClassDecl 8050 = ObjCInterfaceDecl::Create(*this, getTranslationUnitDecl(), 8051 SourceLocation(), 8052 &Idents.get("Protocol"), 8053 /*typeParamList=*/nullptr, 8054 /*PrevDecl=*/nullptr, 8055 SourceLocation(), true); 8056 } 8057 8058 return ObjCProtocolClassDecl; 8059 } 8060 8061 //===----------------------------------------------------------------------===// 8062 // __builtin_va_list Construction Functions 8063 //===----------------------------------------------------------------------===// 8064 8065 static TypedefDecl *CreateCharPtrNamedVaListDecl(const ASTContext *Context, 8066 StringRef Name) { 8067 // typedef char* __builtin[_ms]_va_list; 8068 QualType T = Context->getPointerType(Context->CharTy); 8069 return Context->buildImplicitTypedef(T, Name); 8070 } 8071 8072 static TypedefDecl *CreateMSVaListDecl(const ASTContext *Context) { 8073 return CreateCharPtrNamedVaListDecl(Context, "__builtin_ms_va_list"); 8074 } 8075 8076 static TypedefDecl *CreateCharPtrBuiltinVaListDecl(const ASTContext *Context) { 8077 return CreateCharPtrNamedVaListDecl(Context, "__builtin_va_list"); 8078 } 8079 8080 static TypedefDecl *CreateVoidPtrBuiltinVaListDecl(const ASTContext *Context) { 8081 // typedef void* __builtin_va_list; 8082 QualType T = Context->getPointerType(Context->VoidTy); 8083 return Context->buildImplicitTypedef(T, "__builtin_va_list"); 8084 } 8085 8086 static TypedefDecl * 8087 CreateAArch64ABIBuiltinVaListDecl(const ASTContext *Context) { 8088 RecordDecl *VaListTagDecl = Context->buildImplicitRecord("__va_list"); 8089 // namespace std { struct __va_list { 8090 // Note that we create the namespace even in C. This is intentional so that 8091 // the type is consistent between C and C++, which is important in cases where 8092 // the types need to match between translation units (e.g. with 8093 // -fsanitize=cfi-icall). Ideally we wouldn't have created this namespace at 8094 // all, but it's now part of the ABI (e.g. in mangled names), so we can't 8095 // change it. 8096 auto *NS = NamespaceDecl::Create( 8097 const_cast<ASTContext &>(*Context), Context->getTranslationUnitDecl(), 8098 /*Inline*/ false, SourceLocation(), SourceLocation(), 8099 &Context->Idents.get("std"), 8100 /*PrevDecl*/ nullptr); 8101 NS->setImplicit(); 8102 VaListTagDecl->setDeclContext(NS); 8103 8104 VaListTagDecl->startDefinition(); 8105 8106 const size_t NumFields = 5; 8107 QualType FieldTypes[NumFields]; 8108 const char *FieldNames[NumFields]; 8109 8110 // void *__stack; 8111 FieldTypes[0] = Context->getPointerType(Context->VoidTy); 8112 FieldNames[0] = "__stack"; 8113 8114 // void *__gr_top; 8115 FieldTypes[1] = Context->getPointerType(Context->VoidTy); 8116 FieldNames[1] = "__gr_top"; 8117 8118 // void *__vr_top; 8119 FieldTypes[2] = Context->getPointerType(Context->VoidTy); 8120 FieldNames[2] = "__vr_top"; 8121 8122 // int __gr_offs; 8123 FieldTypes[3] = Context->IntTy; 8124 FieldNames[3] = "__gr_offs"; 8125 8126 // int __vr_offs; 8127 FieldTypes[4] = Context->IntTy; 8128 FieldNames[4] = "__vr_offs"; 8129 8130 // Create fields 8131 for (unsigned i = 0; i < NumFields; ++i) { 8132 FieldDecl *Field = FieldDecl::Create(const_cast<ASTContext &>(*Context), 8133 VaListTagDecl, 8134 SourceLocation(), 8135 SourceLocation(), 8136 &Context->Idents.get(FieldNames[i]), 8137 FieldTypes[i], /*TInfo=*/nullptr, 8138 /*BitWidth=*/nullptr, 8139 /*Mutable=*/false, 8140 ICIS_NoInit); 8141 Field->setAccess(AS_public); 8142 VaListTagDecl->addDecl(Field); 8143 } 8144 VaListTagDecl->completeDefinition(); 8145 Context->VaListTagDecl = VaListTagDecl; 8146 QualType VaListTagType = Context->getRecordType(VaListTagDecl); 8147 8148 // } __builtin_va_list; 8149 return Context->buildImplicitTypedef(VaListTagType, "__builtin_va_list"); 8150 } 8151 8152 static TypedefDecl *CreatePowerABIBuiltinVaListDecl(const ASTContext *Context) { 8153 // typedef struct __va_list_tag { 8154 RecordDecl *VaListTagDecl; 8155 8156 VaListTagDecl = Context->buildImplicitRecord("__va_list_tag"); 8157 VaListTagDecl->startDefinition(); 8158 8159 const size_t NumFields = 5; 8160 QualType FieldTypes[NumFields]; 8161 const char *FieldNames[NumFields]; 8162 8163 // unsigned char gpr; 8164 FieldTypes[0] = Context->UnsignedCharTy; 8165 FieldNames[0] = "gpr"; 8166 8167 // unsigned char fpr; 8168 FieldTypes[1] = Context->UnsignedCharTy; 8169 FieldNames[1] = "fpr"; 8170 8171 // unsigned short reserved; 8172 FieldTypes[2] = Context->UnsignedShortTy; 8173 FieldNames[2] = "reserved"; 8174 8175 // void* overflow_arg_area; 8176 FieldTypes[3] = Context->getPointerType(Context->VoidTy); 8177 FieldNames[3] = "overflow_arg_area"; 8178 8179 // void* reg_save_area; 8180 FieldTypes[4] = Context->getPointerType(Context->VoidTy); 8181 FieldNames[4] = "reg_save_area"; 8182 8183 // Create fields 8184 for (unsigned i = 0; i < NumFields; ++i) { 8185 FieldDecl *Field = FieldDecl::Create(*Context, VaListTagDecl, 8186 SourceLocation(), 8187 SourceLocation(), 8188 &Context->Idents.get(FieldNames[i]), 8189 FieldTypes[i], /*TInfo=*/nullptr, 8190 /*BitWidth=*/nullptr, 8191 /*Mutable=*/false, 8192 ICIS_NoInit); 8193 Field->setAccess(AS_public); 8194 VaListTagDecl->addDecl(Field); 8195 } 8196 VaListTagDecl->completeDefinition(); 8197 Context->VaListTagDecl = VaListTagDecl; 8198 QualType VaListTagType = Context->getRecordType(VaListTagDecl); 8199 8200 // } __va_list_tag; 8201 TypedefDecl *VaListTagTypedefDecl = 8202 Context->buildImplicitTypedef(VaListTagType, "__va_list_tag"); 8203 8204 QualType VaListTagTypedefType = 8205 Context->getTypedefType(VaListTagTypedefDecl); 8206 8207 // typedef __va_list_tag __builtin_va_list[1]; 8208 llvm::APInt Size(Context->getTypeSize(Context->getSizeType()), 1); 8209 QualType VaListTagArrayType 8210 = Context->getConstantArrayType(VaListTagTypedefType, 8211 Size, nullptr, ArrayType::Normal, 0); 8212 return Context->buildImplicitTypedef(VaListTagArrayType, "__builtin_va_list"); 8213 } 8214 8215 static TypedefDecl * 8216 CreateX86_64ABIBuiltinVaListDecl(const ASTContext *Context) { 8217 // struct __va_list_tag { 8218 RecordDecl *VaListTagDecl; 8219 VaListTagDecl = Context->buildImplicitRecord("__va_list_tag"); 8220 VaListTagDecl->startDefinition(); 8221 8222 const size_t NumFields = 4; 8223 QualType FieldTypes[NumFields]; 8224 const char *FieldNames[NumFields]; 8225 8226 // unsigned gp_offset; 8227 FieldTypes[0] = Context->UnsignedIntTy; 8228 FieldNames[0] = "gp_offset"; 8229 8230 // unsigned fp_offset; 8231 FieldTypes[1] = Context->UnsignedIntTy; 8232 FieldNames[1] = "fp_offset"; 8233 8234 // void* overflow_arg_area; 8235 FieldTypes[2] = Context->getPointerType(Context->VoidTy); 8236 FieldNames[2] = "overflow_arg_area"; 8237 8238 // void* reg_save_area; 8239 FieldTypes[3] = Context->getPointerType(Context->VoidTy); 8240 FieldNames[3] = "reg_save_area"; 8241 8242 // Create fields 8243 for (unsigned i = 0; i < NumFields; ++i) { 8244 FieldDecl *Field = FieldDecl::Create(const_cast<ASTContext &>(*Context), 8245 VaListTagDecl, 8246 SourceLocation(), 8247 SourceLocation(), 8248 &Context->Idents.get(FieldNames[i]), 8249 FieldTypes[i], /*TInfo=*/nullptr, 8250 /*BitWidth=*/nullptr, 8251 /*Mutable=*/false, 8252 ICIS_NoInit); 8253 Field->setAccess(AS_public); 8254 VaListTagDecl->addDecl(Field); 8255 } 8256 VaListTagDecl->completeDefinition(); 8257 Context->VaListTagDecl = VaListTagDecl; 8258 QualType VaListTagType = Context->getRecordType(VaListTagDecl); 8259 8260 // }; 8261 8262 // typedef struct __va_list_tag __builtin_va_list[1]; 8263 llvm::APInt Size(Context->getTypeSize(Context->getSizeType()), 1); 8264 QualType VaListTagArrayType = Context->getConstantArrayType( 8265 VaListTagType, Size, nullptr, ArrayType::Normal, 0); 8266 return Context->buildImplicitTypedef(VaListTagArrayType, "__builtin_va_list"); 8267 } 8268 8269 static TypedefDecl *CreatePNaClABIBuiltinVaListDecl(const ASTContext *Context) { 8270 // typedef int __builtin_va_list[4]; 8271 llvm::APInt Size(Context->getTypeSize(Context->getSizeType()), 4); 8272 QualType IntArrayType = Context->getConstantArrayType( 8273 Context->IntTy, Size, nullptr, ArrayType::Normal, 0); 8274 return Context->buildImplicitTypedef(IntArrayType, "__builtin_va_list"); 8275 } 8276 8277 static TypedefDecl * 8278 CreateAAPCSABIBuiltinVaListDecl(const ASTContext *Context) { 8279 // struct __va_list 8280 RecordDecl *VaListDecl = Context->buildImplicitRecord("__va_list"); 8281 if (Context->getLangOpts().CPlusPlus) { 8282 // namespace std { struct __va_list { 8283 NamespaceDecl *NS; 8284 NS = NamespaceDecl::Create(const_cast<ASTContext &>(*Context), 8285 Context->getTranslationUnitDecl(), 8286 /*Inline*/false, SourceLocation(), 8287 SourceLocation(), &Context->Idents.get("std"), 8288 /*PrevDecl*/ nullptr); 8289 NS->setImplicit(); 8290 VaListDecl->setDeclContext(NS); 8291 } 8292 8293 VaListDecl->startDefinition(); 8294 8295 // void * __ap; 8296 FieldDecl *Field = FieldDecl::Create(const_cast<ASTContext &>(*Context), 8297 VaListDecl, 8298 SourceLocation(), 8299 SourceLocation(), 8300 &Context->Idents.get("__ap"), 8301 Context->getPointerType(Context->VoidTy), 8302 /*TInfo=*/nullptr, 8303 /*BitWidth=*/nullptr, 8304 /*Mutable=*/false, 8305 ICIS_NoInit); 8306 Field->setAccess(AS_public); 8307 VaListDecl->addDecl(Field); 8308 8309 // }; 8310 VaListDecl->completeDefinition(); 8311 Context->VaListTagDecl = VaListDecl; 8312 8313 // typedef struct __va_list __builtin_va_list; 8314 QualType T = Context->getRecordType(VaListDecl); 8315 return Context->buildImplicitTypedef(T, "__builtin_va_list"); 8316 } 8317 8318 static TypedefDecl * 8319 CreateSystemZBuiltinVaListDecl(const ASTContext *Context) { 8320 // struct __va_list_tag { 8321 RecordDecl *VaListTagDecl; 8322 VaListTagDecl = Context->buildImplicitRecord("__va_list_tag"); 8323 VaListTagDecl->startDefinition(); 8324 8325 const size_t NumFields = 4; 8326 QualType FieldTypes[NumFields]; 8327 const char *FieldNames[NumFields]; 8328 8329 // long __gpr; 8330 FieldTypes[0] = Context->LongTy; 8331 FieldNames[0] = "__gpr"; 8332 8333 // long __fpr; 8334 FieldTypes[1] = Context->LongTy; 8335 FieldNames[1] = "__fpr"; 8336 8337 // void *__overflow_arg_area; 8338 FieldTypes[2] = Context->getPointerType(Context->VoidTy); 8339 FieldNames[2] = "__overflow_arg_area"; 8340 8341 // void *__reg_save_area; 8342 FieldTypes[3] = Context->getPointerType(Context->VoidTy); 8343 FieldNames[3] = "__reg_save_area"; 8344 8345 // Create fields 8346 for (unsigned i = 0; i < NumFields; ++i) { 8347 FieldDecl *Field = FieldDecl::Create(const_cast<ASTContext &>(*Context), 8348 VaListTagDecl, 8349 SourceLocation(), 8350 SourceLocation(), 8351 &Context->Idents.get(FieldNames[i]), 8352 FieldTypes[i], /*TInfo=*/nullptr, 8353 /*BitWidth=*/nullptr, 8354 /*Mutable=*/false, 8355 ICIS_NoInit); 8356 Field->setAccess(AS_public); 8357 VaListTagDecl->addDecl(Field); 8358 } 8359 VaListTagDecl->completeDefinition(); 8360 Context->VaListTagDecl = VaListTagDecl; 8361 QualType VaListTagType = Context->getRecordType(VaListTagDecl); 8362 8363 // }; 8364 8365 // typedef __va_list_tag __builtin_va_list[1]; 8366 llvm::APInt Size(Context->getTypeSize(Context->getSizeType()), 1); 8367 QualType VaListTagArrayType = Context->getConstantArrayType( 8368 VaListTagType, Size, nullptr, ArrayType::Normal, 0); 8369 8370 return Context->buildImplicitTypedef(VaListTagArrayType, "__builtin_va_list"); 8371 } 8372 8373 static TypedefDecl *CreateHexagonBuiltinVaListDecl(const ASTContext *Context) { 8374 // typedef struct __va_list_tag { 8375 RecordDecl *VaListTagDecl; 8376 VaListTagDecl = Context->buildImplicitRecord("__va_list_tag"); 8377 VaListTagDecl->startDefinition(); 8378 8379 const size_t NumFields = 3; 8380 QualType FieldTypes[NumFields]; 8381 const char *FieldNames[NumFields]; 8382 8383 // void *CurrentSavedRegisterArea; 8384 FieldTypes[0] = Context->getPointerType(Context->VoidTy); 8385 FieldNames[0] = "__current_saved_reg_area_pointer"; 8386 8387 // void *SavedRegAreaEnd; 8388 FieldTypes[1] = Context->getPointerType(Context->VoidTy); 8389 FieldNames[1] = "__saved_reg_area_end_pointer"; 8390 8391 // void *OverflowArea; 8392 FieldTypes[2] = Context->getPointerType(Context->VoidTy); 8393 FieldNames[2] = "__overflow_area_pointer"; 8394 8395 // Create fields 8396 for (unsigned i = 0; i < NumFields; ++i) { 8397 FieldDecl *Field = FieldDecl::Create( 8398 const_cast<ASTContext &>(*Context), VaListTagDecl, SourceLocation(), 8399 SourceLocation(), &Context->Idents.get(FieldNames[i]), FieldTypes[i], 8400 /*TInfo=*/0, 8401 /*BitWidth=*/0, 8402 /*Mutable=*/false, ICIS_NoInit); 8403 Field->setAccess(AS_public); 8404 VaListTagDecl->addDecl(Field); 8405 } 8406 VaListTagDecl->completeDefinition(); 8407 Context->VaListTagDecl = VaListTagDecl; 8408 QualType VaListTagType = Context->getRecordType(VaListTagDecl); 8409 8410 // } __va_list_tag; 8411 TypedefDecl *VaListTagTypedefDecl = 8412 Context->buildImplicitTypedef(VaListTagType, "__va_list_tag"); 8413 8414 QualType VaListTagTypedefType = Context->getTypedefType(VaListTagTypedefDecl); 8415 8416 // typedef __va_list_tag __builtin_va_list[1]; 8417 llvm::APInt Size(Context->getTypeSize(Context->getSizeType()), 1); 8418 QualType VaListTagArrayType = Context->getConstantArrayType( 8419 VaListTagTypedefType, Size, nullptr, ArrayType::Normal, 0); 8420 8421 return Context->buildImplicitTypedef(VaListTagArrayType, "__builtin_va_list"); 8422 } 8423 8424 static TypedefDecl *CreateVaListDecl(const ASTContext *Context, 8425 TargetInfo::BuiltinVaListKind Kind) { 8426 switch (Kind) { 8427 case TargetInfo::CharPtrBuiltinVaList: 8428 return CreateCharPtrBuiltinVaListDecl(Context); 8429 case TargetInfo::VoidPtrBuiltinVaList: 8430 return CreateVoidPtrBuiltinVaListDecl(Context); 8431 case TargetInfo::AArch64ABIBuiltinVaList: 8432 return CreateAArch64ABIBuiltinVaListDecl(Context); 8433 case TargetInfo::PowerABIBuiltinVaList: 8434 return CreatePowerABIBuiltinVaListDecl(Context); 8435 case TargetInfo::X86_64ABIBuiltinVaList: 8436 return CreateX86_64ABIBuiltinVaListDecl(Context); 8437 case TargetInfo::PNaClABIBuiltinVaList: 8438 return CreatePNaClABIBuiltinVaListDecl(Context); 8439 case TargetInfo::AAPCSABIBuiltinVaList: 8440 return CreateAAPCSABIBuiltinVaListDecl(Context); 8441 case TargetInfo::SystemZBuiltinVaList: 8442 return CreateSystemZBuiltinVaListDecl(Context); 8443 case TargetInfo::HexagonBuiltinVaList: 8444 return CreateHexagonBuiltinVaListDecl(Context); 8445 } 8446 8447 llvm_unreachable("Unhandled __builtin_va_list type kind"); 8448 } 8449 8450 TypedefDecl *ASTContext::getBuiltinVaListDecl() const { 8451 if (!BuiltinVaListDecl) { 8452 BuiltinVaListDecl = CreateVaListDecl(this, Target->getBuiltinVaListKind()); 8453 assert(BuiltinVaListDecl->isImplicit()); 8454 } 8455 8456 return BuiltinVaListDecl; 8457 } 8458 8459 Decl *ASTContext::getVaListTagDecl() const { 8460 // Force the creation of VaListTagDecl by building the __builtin_va_list 8461 // declaration. 8462 if (!VaListTagDecl) 8463 (void)getBuiltinVaListDecl(); 8464 8465 return VaListTagDecl; 8466 } 8467 8468 TypedefDecl *ASTContext::getBuiltinMSVaListDecl() const { 8469 if (!BuiltinMSVaListDecl) 8470 BuiltinMSVaListDecl = CreateMSVaListDecl(this); 8471 8472 return BuiltinMSVaListDecl; 8473 } 8474 8475 bool ASTContext::canBuiltinBeRedeclared(const FunctionDecl *FD) const { 8476 return BuiltinInfo.canBeRedeclared(FD->getBuiltinID()); 8477 } 8478 8479 void ASTContext::setObjCConstantStringInterface(ObjCInterfaceDecl *Decl) { 8480 assert(ObjCConstantStringType.isNull() && 8481 "'NSConstantString' type already set!"); 8482 8483 ObjCConstantStringType = getObjCInterfaceType(Decl); 8484 } 8485 8486 /// Retrieve the template name that corresponds to a non-empty 8487 /// lookup. 8488 TemplateName 8489 ASTContext::getOverloadedTemplateName(UnresolvedSetIterator Begin, 8490 UnresolvedSetIterator End) const { 8491 unsigned size = End - Begin; 8492 assert(size > 1 && "set is not overloaded!"); 8493 8494 void *memory = Allocate(sizeof(OverloadedTemplateStorage) + 8495 size * sizeof(FunctionTemplateDecl*)); 8496 auto *OT = new (memory) OverloadedTemplateStorage(size); 8497 8498 NamedDecl **Storage = OT->getStorage(); 8499 for (UnresolvedSetIterator I = Begin; I != End; ++I) { 8500 NamedDecl *D = *I; 8501 assert(isa<FunctionTemplateDecl>(D) || 8502 isa<UnresolvedUsingValueDecl>(D) || 8503 (isa<UsingShadowDecl>(D) && 8504 isa<FunctionTemplateDecl>(D->getUnderlyingDecl()))); 8505 *Storage++ = D; 8506 } 8507 8508 return TemplateName(OT); 8509 } 8510 8511 /// Retrieve a template name representing an unqualified-id that has been 8512 /// assumed to name a template for ADL purposes. 8513 TemplateName ASTContext::getAssumedTemplateName(DeclarationName Name) const { 8514 auto *OT = new (*this) AssumedTemplateStorage(Name); 8515 return TemplateName(OT); 8516 } 8517 8518 /// Retrieve the template name that represents a qualified 8519 /// template name such as \c std::vector. 8520 TemplateName 8521 ASTContext::getQualifiedTemplateName(NestedNameSpecifier *NNS, 8522 bool TemplateKeyword, 8523 TemplateDecl *Template) const { 8524 assert(NNS && "Missing nested-name-specifier in qualified template name"); 8525 8526 // FIXME: Canonicalization? 8527 llvm::FoldingSetNodeID ID; 8528 QualifiedTemplateName::Profile(ID, NNS, TemplateKeyword, Template); 8529 8530 void *InsertPos = nullptr; 8531 QualifiedTemplateName *QTN = 8532 QualifiedTemplateNames.FindNodeOrInsertPos(ID, InsertPos); 8533 if (!QTN) { 8534 QTN = new (*this, alignof(QualifiedTemplateName)) 8535 QualifiedTemplateName(NNS, TemplateKeyword, Template); 8536 QualifiedTemplateNames.InsertNode(QTN, InsertPos); 8537 } 8538 8539 return TemplateName(QTN); 8540 } 8541 8542 /// Retrieve the template name that represents a dependent 8543 /// template name such as \c MetaFun::template apply. 8544 TemplateName 8545 ASTContext::getDependentTemplateName(NestedNameSpecifier *NNS, 8546 const IdentifierInfo *Name) const { 8547 assert((!NNS || NNS->isDependent()) && 8548 "Nested name specifier must be dependent"); 8549 8550 llvm::FoldingSetNodeID ID; 8551 DependentTemplateName::Profile(ID, NNS, Name); 8552 8553 void *InsertPos = nullptr; 8554 DependentTemplateName *QTN = 8555 DependentTemplateNames.FindNodeOrInsertPos(ID, InsertPos); 8556 8557 if (QTN) 8558 return TemplateName(QTN); 8559 8560 NestedNameSpecifier *CanonNNS = getCanonicalNestedNameSpecifier(NNS); 8561 if (CanonNNS == NNS) { 8562 QTN = new (*this, alignof(DependentTemplateName)) 8563 DependentTemplateName(NNS, Name); 8564 } else { 8565 TemplateName Canon = getDependentTemplateName(CanonNNS, Name); 8566 QTN = new (*this, alignof(DependentTemplateName)) 8567 DependentTemplateName(NNS, Name, Canon); 8568 DependentTemplateName *CheckQTN = 8569 DependentTemplateNames.FindNodeOrInsertPos(ID, InsertPos); 8570 assert(!CheckQTN && "Dependent type name canonicalization broken"); 8571 (void)CheckQTN; 8572 } 8573 8574 DependentTemplateNames.InsertNode(QTN, InsertPos); 8575 return TemplateName(QTN); 8576 } 8577 8578 /// Retrieve the template name that represents a dependent 8579 /// template name such as \c MetaFun::template operator+. 8580 TemplateName 8581 ASTContext::getDependentTemplateName(NestedNameSpecifier *NNS, 8582 OverloadedOperatorKind Operator) const { 8583 assert((!NNS || NNS->isDependent()) && 8584 "Nested name specifier must be dependent"); 8585 8586 llvm::FoldingSetNodeID ID; 8587 DependentTemplateName::Profile(ID, NNS, Operator); 8588 8589 void *InsertPos = nullptr; 8590 DependentTemplateName *QTN 8591 = DependentTemplateNames.FindNodeOrInsertPos(ID, InsertPos); 8592 8593 if (QTN) 8594 return TemplateName(QTN); 8595 8596 NestedNameSpecifier *CanonNNS = getCanonicalNestedNameSpecifier(NNS); 8597 if (CanonNNS == NNS) { 8598 QTN = new (*this, alignof(DependentTemplateName)) 8599 DependentTemplateName(NNS, Operator); 8600 } else { 8601 TemplateName Canon = getDependentTemplateName(CanonNNS, Operator); 8602 QTN = new (*this, alignof(DependentTemplateName)) 8603 DependentTemplateName(NNS, Operator, Canon); 8604 8605 DependentTemplateName *CheckQTN 8606 = DependentTemplateNames.FindNodeOrInsertPos(ID, InsertPos); 8607 assert(!CheckQTN && "Dependent template name canonicalization broken"); 8608 (void)CheckQTN; 8609 } 8610 8611 DependentTemplateNames.InsertNode(QTN, InsertPos); 8612 return TemplateName(QTN); 8613 } 8614 8615 TemplateName 8616 ASTContext::getSubstTemplateTemplateParm(TemplateTemplateParmDecl *param, 8617 TemplateName replacement) const { 8618 llvm::FoldingSetNodeID ID; 8619 SubstTemplateTemplateParmStorage::Profile(ID, param, replacement); 8620 8621 void *insertPos = nullptr; 8622 SubstTemplateTemplateParmStorage *subst 8623 = SubstTemplateTemplateParms.FindNodeOrInsertPos(ID, insertPos); 8624 8625 if (!subst) { 8626 subst = new (*this) SubstTemplateTemplateParmStorage(param, replacement); 8627 SubstTemplateTemplateParms.InsertNode(subst, insertPos); 8628 } 8629 8630 return TemplateName(subst); 8631 } 8632 8633 TemplateName 8634 ASTContext::getSubstTemplateTemplateParmPack(TemplateTemplateParmDecl *Param, 8635 const TemplateArgument &ArgPack) const { 8636 auto &Self = const_cast<ASTContext &>(*this); 8637 llvm::FoldingSetNodeID ID; 8638 SubstTemplateTemplateParmPackStorage::Profile(ID, Self, Param, ArgPack); 8639 8640 void *InsertPos = nullptr; 8641 SubstTemplateTemplateParmPackStorage *Subst 8642 = SubstTemplateTemplateParmPacks.FindNodeOrInsertPos(ID, InsertPos); 8643 8644 if (!Subst) { 8645 Subst = new (*this) SubstTemplateTemplateParmPackStorage(Param, 8646 ArgPack.pack_size(), 8647 ArgPack.pack_begin()); 8648 SubstTemplateTemplateParmPacks.InsertNode(Subst, InsertPos); 8649 } 8650 8651 return TemplateName(Subst); 8652 } 8653 8654 /// getFromTargetType - Given one of the integer types provided by 8655 /// TargetInfo, produce the corresponding type. The unsigned @p Type 8656 /// is actually a value of type @c TargetInfo::IntType. 8657 CanQualType ASTContext::getFromTargetType(unsigned Type) const { 8658 switch (Type) { 8659 case TargetInfo::NoInt: return {}; 8660 case TargetInfo::SignedChar: return SignedCharTy; 8661 case TargetInfo::UnsignedChar: return UnsignedCharTy; 8662 case TargetInfo::SignedShort: return ShortTy; 8663 case TargetInfo::UnsignedShort: return UnsignedShortTy; 8664 case TargetInfo::SignedInt: return IntTy; 8665 case TargetInfo::UnsignedInt: return UnsignedIntTy; 8666 case TargetInfo::SignedLong: return LongTy; 8667 case TargetInfo::UnsignedLong: return UnsignedLongTy; 8668 case TargetInfo::SignedLongLong: return LongLongTy; 8669 case TargetInfo::UnsignedLongLong: return UnsignedLongLongTy; 8670 } 8671 8672 llvm_unreachable("Unhandled TargetInfo::IntType value"); 8673 } 8674 8675 //===----------------------------------------------------------------------===// 8676 // Type Predicates. 8677 //===----------------------------------------------------------------------===// 8678 8679 /// getObjCGCAttr - Returns one of GCNone, Weak or Strong objc's 8680 /// garbage collection attribute. 8681 /// 8682 Qualifiers::GC ASTContext::getObjCGCAttrKind(QualType Ty) const { 8683 if (getLangOpts().getGC() == LangOptions::NonGC) 8684 return Qualifiers::GCNone; 8685 8686 assert(getLangOpts().ObjC); 8687 Qualifiers::GC GCAttrs = Ty.getObjCGCAttr(); 8688 8689 // Default behaviour under objective-C's gc is for ObjC pointers 8690 // (or pointers to them) be treated as though they were declared 8691 // as __strong. 8692 if (GCAttrs == Qualifiers::GCNone) { 8693 if (Ty->isObjCObjectPointerType() || Ty->isBlockPointerType()) 8694 return Qualifiers::Strong; 8695 else if (Ty->isPointerType()) 8696 return getObjCGCAttrKind(Ty->castAs<PointerType>()->getPointeeType()); 8697 } else { 8698 // It's not valid to set GC attributes on anything that isn't a 8699 // pointer. 8700 #ifndef NDEBUG 8701 QualType CT = Ty->getCanonicalTypeInternal(); 8702 while (const auto *AT = dyn_cast<ArrayType>(CT)) 8703 CT = AT->getElementType(); 8704 assert(CT->isAnyPointerType() || CT->isBlockPointerType()); 8705 #endif 8706 } 8707 return GCAttrs; 8708 } 8709 8710 //===----------------------------------------------------------------------===// 8711 // Type Compatibility Testing 8712 //===----------------------------------------------------------------------===// 8713 8714 /// areCompatVectorTypes - Return true if the two specified vector types are 8715 /// compatible. 8716 static bool areCompatVectorTypes(const VectorType *LHS, 8717 const VectorType *RHS) { 8718 assert(LHS->isCanonicalUnqualified() && RHS->isCanonicalUnqualified()); 8719 return LHS->getElementType() == RHS->getElementType() && 8720 LHS->getNumElements() == RHS->getNumElements(); 8721 } 8722 8723 /// areCompatMatrixTypes - Return true if the two specified matrix types are 8724 /// compatible. 8725 static bool areCompatMatrixTypes(const ConstantMatrixType *LHS, 8726 const ConstantMatrixType *RHS) { 8727 assert(LHS->isCanonicalUnqualified() && RHS->isCanonicalUnqualified()); 8728 return LHS->getElementType() == RHS->getElementType() && 8729 LHS->getNumRows() == RHS->getNumRows() && 8730 LHS->getNumColumns() == RHS->getNumColumns(); 8731 } 8732 8733 bool ASTContext::areCompatibleVectorTypes(QualType FirstVec, 8734 QualType SecondVec) { 8735 assert(FirstVec->isVectorType() && "FirstVec should be a vector type"); 8736 assert(SecondVec->isVectorType() && "SecondVec should be a vector type"); 8737 8738 if (hasSameUnqualifiedType(FirstVec, SecondVec)) 8739 return true; 8740 8741 // Treat Neon vector types and most AltiVec vector types as if they are the 8742 // equivalent GCC vector types. 8743 const auto *First = FirstVec->castAs<VectorType>(); 8744 const auto *Second = SecondVec->castAs<VectorType>(); 8745 if (First->getNumElements() == Second->getNumElements() && 8746 hasSameType(First->getElementType(), Second->getElementType()) && 8747 First->getVectorKind() != VectorType::AltiVecPixel && 8748 First->getVectorKind() != VectorType::AltiVecBool && 8749 Second->getVectorKind() != VectorType::AltiVecPixel && 8750 Second->getVectorKind() != VectorType::AltiVecBool && 8751 First->getVectorKind() != VectorType::SveFixedLengthDataVector && 8752 First->getVectorKind() != VectorType::SveFixedLengthPredicateVector && 8753 Second->getVectorKind() != VectorType::SveFixedLengthDataVector && 8754 Second->getVectorKind() != VectorType::SveFixedLengthPredicateVector) 8755 return true; 8756 8757 return false; 8758 } 8759 8760 /// getSVETypeSize - Return SVE vector or predicate register size. 8761 static uint64_t getSVETypeSize(ASTContext &Context, const BuiltinType *Ty) { 8762 assert(Ty->isVLSTBuiltinType() && "Invalid SVE Type"); 8763 return Ty->getKind() == BuiltinType::SveBool 8764 ? Context.getLangOpts().ArmSveVectorBits / Context.getCharWidth() 8765 : Context.getLangOpts().ArmSveVectorBits; 8766 } 8767 8768 bool ASTContext::areCompatibleSveTypes(QualType FirstType, 8769 QualType SecondType) { 8770 assert(((FirstType->isSizelessBuiltinType() && SecondType->isVectorType()) || 8771 (FirstType->isVectorType() && SecondType->isSizelessBuiltinType())) && 8772 "Expected SVE builtin type and vector type!"); 8773 8774 auto IsValidCast = [this](QualType FirstType, QualType SecondType) { 8775 if (const auto *BT = FirstType->getAs<BuiltinType>()) { 8776 if (const auto *VT = SecondType->getAs<VectorType>()) { 8777 // Predicates have the same representation as uint8 so we also have to 8778 // check the kind to make these types incompatible. 8779 if (VT->getVectorKind() == VectorType::SveFixedLengthPredicateVector) 8780 return BT->getKind() == BuiltinType::SveBool; 8781 else if (VT->getVectorKind() == VectorType::SveFixedLengthDataVector) 8782 return VT->getElementType().getCanonicalType() == 8783 FirstType->getSveEltType(*this); 8784 else if (VT->getVectorKind() == VectorType::GenericVector) 8785 return getTypeSize(SecondType) == getSVETypeSize(*this, BT) && 8786 hasSameType(VT->getElementType(), 8787 getBuiltinVectorTypeInfo(BT).ElementType); 8788 } 8789 } 8790 return false; 8791 }; 8792 8793 return IsValidCast(FirstType, SecondType) || 8794 IsValidCast(SecondType, FirstType); 8795 } 8796 8797 bool ASTContext::areLaxCompatibleSveTypes(QualType FirstType, 8798 QualType SecondType) { 8799 assert(((FirstType->isSizelessBuiltinType() && SecondType->isVectorType()) || 8800 (FirstType->isVectorType() && SecondType->isSizelessBuiltinType())) && 8801 "Expected SVE builtin type and vector type!"); 8802 8803 auto IsLaxCompatible = [this](QualType FirstType, QualType SecondType) { 8804 const auto *BT = FirstType->getAs<BuiltinType>(); 8805 if (!BT) 8806 return false; 8807 8808 const auto *VecTy = SecondType->getAs<VectorType>(); 8809 if (VecTy && 8810 (VecTy->getVectorKind() == VectorType::SveFixedLengthDataVector || 8811 VecTy->getVectorKind() == VectorType::GenericVector)) { 8812 const LangOptions::LaxVectorConversionKind LVCKind = 8813 getLangOpts().getLaxVectorConversions(); 8814 8815 // Can not convert between sve predicates and sve vectors because of 8816 // different size. 8817 if (BT->getKind() == BuiltinType::SveBool && 8818 VecTy->getVectorKind() == VectorType::SveFixedLengthDataVector) 8819 return false; 8820 8821 // If __ARM_FEATURE_SVE_BITS != N do not allow GNU vector lax conversion. 8822 // "Whenever __ARM_FEATURE_SVE_BITS==N, GNUT implicitly 8823 // converts to VLAT and VLAT implicitly converts to GNUT." 8824 // ACLE Spec Version 00bet6, 3.7.3.2. Behavior common to vectors and 8825 // predicates. 8826 if (VecTy->getVectorKind() == VectorType::GenericVector && 8827 getTypeSize(SecondType) != getSVETypeSize(*this, BT)) 8828 return false; 8829 8830 // If -flax-vector-conversions=all is specified, the types are 8831 // certainly compatible. 8832 if (LVCKind == LangOptions::LaxVectorConversionKind::All) 8833 return true; 8834 8835 // If -flax-vector-conversions=integer is specified, the types are 8836 // compatible if the elements are integer types. 8837 if (LVCKind == LangOptions::LaxVectorConversionKind::Integer) 8838 return VecTy->getElementType().getCanonicalType()->isIntegerType() && 8839 FirstType->getSveEltType(*this)->isIntegerType(); 8840 } 8841 8842 return false; 8843 }; 8844 8845 return IsLaxCompatible(FirstType, SecondType) || 8846 IsLaxCompatible(SecondType, FirstType); 8847 } 8848 8849 bool ASTContext::hasDirectOwnershipQualifier(QualType Ty) const { 8850 while (true) { 8851 // __strong id 8852 if (const AttributedType *Attr = dyn_cast<AttributedType>(Ty)) { 8853 if (Attr->getAttrKind() == attr::ObjCOwnership) 8854 return true; 8855 8856 Ty = Attr->getModifiedType(); 8857 8858 // X *__strong (...) 8859 } else if (const ParenType *Paren = dyn_cast<ParenType>(Ty)) { 8860 Ty = Paren->getInnerType(); 8861 8862 // We do not want to look through typedefs, typeof(expr), 8863 // typeof(type), or any other way that the type is somehow 8864 // abstracted. 8865 } else { 8866 return false; 8867 } 8868 } 8869 } 8870 8871 //===----------------------------------------------------------------------===// 8872 // ObjCQualifiedIdTypesAreCompatible - Compatibility testing for qualified id's. 8873 //===----------------------------------------------------------------------===// 8874 8875 /// ProtocolCompatibleWithProtocol - return 'true' if 'lProto' is in the 8876 /// inheritance hierarchy of 'rProto'. 8877 bool 8878 ASTContext::ProtocolCompatibleWithProtocol(ObjCProtocolDecl *lProto, 8879 ObjCProtocolDecl *rProto) const { 8880 if (declaresSameEntity(lProto, rProto)) 8881 return true; 8882 for (auto *PI : rProto->protocols()) 8883 if (ProtocolCompatibleWithProtocol(lProto, PI)) 8884 return true; 8885 return false; 8886 } 8887 8888 /// ObjCQualifiedClassTypesAreCompatible - compare Class<pr,...> and 8889 /// Class<pr1, ...>. 8890 bool ASTContext::ObjCQualifiedClassTypesAreCompatible( 8891 const ObjCObjectPointerType *lhs, const ObjCObjectPointerType *rhs) { 8892 for (auto *lhsProto : lhs->quals()) { 8893 bool match = false; 8894 for (auto *rhsProto : rhs->quals()) { 8895 if (ProtocolCompatibleWithProtocol(lhsProto, rhsProto)) { 8896 match = true; 8897 break; 8898 } 8899 } 8900 if (!match) 8901 return false; 8902 } 8903 return true; 8904 } 8905 8906 /// ObjCQualifiedIdTypesAreCompatible - We know that one of lhs/rhs is an 8907 /// ObjCQualifiedIDType. 8908 bool ASTContext::ObjCQualifiedIdTypesAreCompatible( 8909 const ObjCObjectPointerType *lhs, const ObjCObjectPointerType *rhs, 8910 bool compare) { 8911 // Allow id<P..> and an 'id' in all cases. 8912 if (lhs->isObjCIdType() || rhs->isObjCIdType()) 8913 return true; 8914 8915 // Don't allow id<P..> to convert to Class or Class<P..> in either direction. 8916 if (lhs->isObjCClassType() || lhs->isObjCQualifiedClassType() || 8917 rhs->isObjCClassType() || rhs->isObjCQualifiedClassType()) 8918 return false; 8919 8920 if (lhs->isObjCQualifiedIdType()) { 8921 if (rhs->qual_empty()) { 8922 // If the RHS is a unqualified interface pointer "NSString*", 8923 // make sure we check the class hierarchy. 8924 if (ObjCInterfaceDecl *rhsID = rhs->getInterfaceDecl()) { 8925 for (auto *I : lhs->quals()) { 8926 // when comparing an id<P> on lhs with a static type on rhs, 8927 // see if static class implements all of id's protocols, directly or 8928 // through its super class and categories. 8929 if (!rhsID->ClassImplementsProtocol(I, true)) 8930 return false; 8931 } 8932 } 8933 // If there are no qualifiers and no interface, we have an 'id'. 8934 return true; 8935 } 8936 // Both the right and left sides have qualifiers. 8937 for (auto *lhsProto : lhs->quals()) { 8938 bool match = false; 8939 8940 // when comparing an id<P> on lhs with a static type on rhs, 8941 // see if static class implements all of id's protocols, directly or 8942 // through its super class and categories. 8943 for (auto *rhsProto : rhs->quals()) { 8944 if (ProtocolCompatibleWithProtocol(lhsProto, rhsProto) || 8945 (compare && ProtocolCompatibleWithProtocol(rhsProto, lhsProto))) { 8946 match = true; 8947 break; 8948 } 8949 } 8950 // If the RHS is a qualified interface pointer "NSString<P>*", 8951 // make sure we check the class hierarchy. 8952 if (ObjCInterfaceDecl *rhsID = rhs->getInterfaceDecl()) { 8953 for (auto *I : lhs->quals()) { 8954 // when comparing an id<P> on lhs with a static type on rhs, 8955 // see if static class implements all of id's protocols, directly or 8956 // through its super class and categories. 8957 if (rhsID->ClassImplementsProtocol(I, true)) { 8958 match = true; 8959 break; 8960 } 8961 } 8962 } 8963 if (!match) 8964 return false; 8965 } 8966 8967 return true; 8968 } 8969 8970 assert(rhs->isObjCQualifiedIdType() && "One of the LHS/RHS should be id<x>"); 8971 8972 if (lhs->getInterfaceType()) { 8973 // If both the right and left sides have qualifiers. 8974 for (auto *lhsProto : lhs->quals()) { 8975 bool match = false; 8976 8977 // when comparing an id<P> on rhs with a static type on lhs, 8978 // see if static class implements all of id's protocols, directly or 8979 // through its super class and categories. 8980 // First, lhs protocols in the qualifier list must be found, direct 8981 // or indirect in rhs's qualifier list or it is a mismatch. 8982 for (auto *rhsProto : rhs->quals()) { 8983 if (ProtocolCompatibleWithProtocol(lhsProto, rhsProto) || 8984 (compare && ProtocolCompatibleWithProtocol(rhsProto, lhsProto))) { 8985 match = true; 8986 break; 8987 } 8988 } 8989 if (!match) 8990 return false; 8991 } 8992 8993 // Static class's protocols, or its super class or category protocols 8994 // must be found, direct or indirect in rhs's qualifier list or it is a mismatch. 8995 if (ObjCInterfaceDecl *lhsID = lhs->getInterfaceDecl()) { 8996 llvm::SmallPtrSet<ObjCProtocolDecl *, 8> LHSInheritedProtocols; 8997 CollectInheritedProtocols(lhsID, LHSInheritedProtocols); 8998 // This is rather dubious but matches gcc's behavior. If lhs has 8999 // no type qualifier and its class has no static protocol(s) 9000 // assume that it is mismatch. 9001 if (LHSInheritedProtocols.empty() && lhs->qual_empty()) 9002 return false; 9003 for (auto *lhsProto : LHSInheritedProtocols) { 9004 bool match = false; 9005 for (auto *rhsProto : rhs->quals()) { 9006 if (ProtocolCompatibleWithProtocol(lhsProto, rhsProto) || 9007 (compare && ProtocolCompatibleWithProtocol(rhsProto, lhsProto))) { 9008 match = true; 9009 break; 9010 } 9011 } 9012 if (!match) 9013 return false; 9014 } 9015 } 9016 return true; 9017 } 9018 return false; 9019 } 9020 9021 /// canAssignObjCInterfaces - Return true if the two interface types are 9022 /// compatible for assignment from RHS to LHS. This handles validation of any 9023 /// protocol qualifiers on the LHS or RHS. 9024 bool ASTContext::canAssignObjCInterfaces(const ObjCObjectPointerType *LHSOPT, 9025 const ObjCObjectPointerType *RHSOPT) { 9026 const ObjCObjectType* LHS = LHSOPT->getObjectType(); 9027 const ObjCObjectType* RHS = RHSOPT->getObjectType(); 9028 9029 // If either type represents the built-in 'id' type, return true. 9030 if (LHS->isObjCUnqualifiedId() || RHS->isObjCUnqualifiedId()) 9031 return true; 9032 9033 // Function object that propagates a successful result or handles 9034 // __kindof types. 9035 auto finish = [&](bool succeeded) -> bool { 9036 if (succeeded) 9037 return true; 9038 9039 if (!RHS->isKindOfType()) 9040 return false; 9041 9042 // Strip off __kindof and protocol qualifiers, then check whether 9043 // we can assign the other way. 9044 return canAssignObjCInterfaces(RHSOPT->stripObjCKindOfTypeAndQuals(*this), 9045 LHSOPT->stripObjCKindOfTypeAndQuals(*this)); 9046 }; 9047 9048 // Casts from or to id<P> are allowed when the other side has compatible 9049 // protocols. 9050 if (LHS->isObjCQualifiedId() || RHS->isObjCQualifiedId()) { 9051 return finish(ObjCQualifiedIdTypesAreCompatible(LHSOPT, RHSOPT, false)); 9052 } 9053 9054 // Verify protocol compatibility for casts from Class<P1> to Class<P2>. 9055 if (LHS->isObjCQualifiedClass() && RHS->isObjCQualifiedClass()) { 9056 return finish(ObjCQualifiedClassTypesAreCompatible(LHSOPT, RHSOPT)); 9057 } 9058 9059 // Casts from Class to Class<Foo>, or vice-versa, are allowed. 9060 if (LHS->isObjCClass() && RHS->isObjCClass()) { 9061 return true; 9062 } 9063 9064 // If we have 2 user-defined types, fall into that path. 9065 if (LHS->getInterface() && RHS->getInterface()) { 9066 return finish(canAssignObjCInterfaces(LHS, RHS)); 9067 } 9068 9069 return false; 9070 } 9071 9072 /// canAssignObjCInterfacesInBlockPointer - This routine is specifically written 9073 /// for providing type-safety for objective-c pointers used to pass/return 9074 /// arguments in block literals. When passed as arguments, passing 'A*' where 9075 /// 'id' is expected is not OK. Passing 'Sub *" where 'Super *" is expected is 9076 /// not OK. For the return type, the opposite is not OK. 9077 bool ASTContext::canAssignObjCInterfacesInBlockPointer( 9078 const ObjCObjectPointerType *LHSOPT, 9079 const ObjCObjectPointerType *RHSOPT, 9080 bool BlockReturnType) { 9081 9082 // Function object that propagates a successful result or handles 9083 // __kindof types. 9084 auto finish = [&](bool succeeded) -> bool { 9085 if (succeeded) 9086 return true; 9087 9088 const ObjCObjectPointerType *Expected = BlockReturnType ? RHSOPT : LHSOPT; 9089 if (!Expected->isKindOfType()) 9090 return false; 9091 9092 // Strip off __kindof and protocol qualifiers, then check whether 9093 // we can assign the other way. 9094 return canAssignObjCInterfacesInBlockPointer( 9095 RHSOPT->stripObjCKindOfTypeAndQuals(*this), 9096 LHSOPT->stripObjCKindOfTypeAndQuals(*this), 9097 BlockReturnType); 9098 }; 9099 9100 if (RHSOPT->isObjCBuiltinType() || LHSOPT->isObjCIdType()) 9101 return true; 9102 9103 if (LHSOPT->isObjCBuiltinType()) { 9104 return finish(RHSOPT->isObjCBuiltinType() || 9105 RHSOPT->isObjCQualifiedIdType()); 9106 } 9107 9108 if (LHSOPT->isObjCQualifiedIdType() || RHSOPT->isObjCQualifiedIdType()) { 9109 if (getLangOpts().CompatibilityQualifiedIdBlockParamTypeChecking) 9110 // Use for block parameters previous type checking for compatibility. 9111 return finish(ObjCQualifiedIdTypesAreCompatible(LHSOPT, RHSOPT, false) || 9112 // Or corrected type checking as in non-compat mode. 9113 (!BlockReturnType && 9114 ObjCQualifiedIdTypesAreCompatible(RHSOPT, LHSOPT, false))); 9115 else 9116 return finish(ObjCQualifiedIdTypesAreCompatible( 9117 (BlockReturnType ? LHSOPT : RHSOPT), 9118 (BlockReturnType ? RHSOPT : LHSOPT), false)); 9119 } 9120 9121 const ObjCInterfaceType* LHS = LHSOPT->getInterfaceType(); 9122 const ObjCInterfaceType* RHS = RHSOPT->getInterfaceType(); 9123 if (LHS && RHS) { // We have 2 user-defined types. 9124 if (LHS != RHS) { 9125 if (LHS->getDecl()->isSuperClassOf(RHS->getDecl())) 9126 return finish(BlockReturnType); 9127 if (RHS->getDecl()->isSuperClassOf(LHS->getDecl())) 9128 return finish(!BlockReturnType); 9129 } 9130 else 9131 return true; 9132 } 9133 return false; 9134 } 9135 9136 /// Comparison routine for Objective-C protocols to be used with 9137 /// llvm::array_pod_sort. 9138 static int compareObjCProtocolsByName(ObjCProtocolDecl * const *lhs, 9139 ObjCProtocolDecl * const *rhs) { 9140 return (*lhs)->getName().compare((*rhs)->getName()); 9141 } 9142 9143 /// getIntersectionOfProtocols - This routine finds the intersection of set 9144 /// of protocols inherited from two distinct objective-c pointer objects with 9145 /// the given common base. 9146 /// It is used to build composite qualifier list of the composite type of 9147 /// the conditional expression involving two objective-c pointer objects. 9148 static 9149 void getIntersectionOfProtocols(ASTContext &Context, 9150 const ObjCInterfaceDecl *CommonBase, 9151 const ObjCObjectPointerType *LHSOPT, 9152 const ObjCObjectPointerType *RHSOPT, 9153 SmallVectorImpl<ObjCProtocolDecl *> &IntersectionSet) { 9154 9155 const ObjCObjectType* LHS = LHSOPT->getObjectType(); 9156 const ObjCObjectType* RHS = RHSOPT->getObjectType(); 9157 assert(LHS->getInterface() && "LHS must have an interface base"); 9158 assert(RHS->getInterface() && "RHS must have an interface base"); 9159 9160 // Add all of the protocols for the LHS. 9161 llvm::SmallPtrSet<ObjCProtocolDecl *, 8> LHSProtocolSet; 9162 9163 // Start with the protocol qualifiers. 9164 for (auto proto : LHS->quals()) { 9165 Context.CollectInheritedProtocols(proto, LHSProtocolSet); 9166 } 9167 9168 // Also add the protocols associated with the LHS interface. 9169 Context.CollectInheritedProtocols(LHS->getInterface(), LHSProtocolSet); 9170 9171 // Add all of the protocols for the RHS. 9172 llvm::SmallPtrSet<ObjCProtocolDecl *, 8> RHSProtocolSet; 9173 9174 // Start with the protocol qualifiers. 9175 for (auto proto : RHS->quals()) { 9176 Context.CollectInheritedProtocols(proto, RHSProtocolSet); 9177 } 9178 9179 // Also add the protocols associated with the RHS interface. 9180 Context.CollectInheritedProtocols(RHS->getInterface(), RHSProtocolSet); 9181 9182 // Compute the intersection of the collected protocol sets. 9183 for (auto proto : LHSProtocolSet) { 9184 if (RHSProtocolSet.count(proto)) 9185 IntersectionSet.push_back(proto); 9186 } 9187 9188 // Compute the set of protocols that is implied by either the common type or 9189 // the protocols within the intersection. 9190 llvm::SmallPtrSet<ObjCProtocolDecl *, 8> ImpliedProtocols; 9191 Context.CollectInheritedProtocols(CommonBase, ImpliedProtocols); 9192 9193 // Remove any implied protocols from the list of inherited protocols. 9194 if (!ImpliedProtocols.empty()) { 9195 IntersectionSet.erase( 9196 std::remove_if(IntersectionSet.begin(), 9197 IntersectionSet.end(), 9198 [&](ObjCProtocolDecl *proto) -> bool { 9199 return ImpliedProtocols.count(proto) > 0; 9200 }), 9201 IntersectionSet.end()); 9202 } 9203 9204 // Sort the remaining protocols by name. 9205 llvm::array_pod_sort(IntersectionSet.begin(), IntersectionSet.end(), 9206 compareObjCProtocolsByName); 9207 } 9208 9209 /// Determine whether the first type is a subtype of the second. 9210 static bool canAssignObjCObjectTypes(ASTContext &ctx, QualType lhs, 9211 QualType rhs) { 9212 // Common case: two object pointers. 9213 const auto *lhsOPT = lhs->getAs<ObjCObjectPointerType>(); 9214 const auto *rhsOPT = rhs->getAs<ObjCObjectPointerType>(); 9215 if (lhsOPT && rhsOPT) 9216 return ctx.canAssignObjCInterfaces(lhsOPT, rhsOPT); 9217 9218 // Two block pointers. 9219 const auto *lhsBlock = lhs->getAs<BlockPointerType>(); 9220 const auto *rhsBlock = rhs->getAs<BlockPointerType>(); 9221 if (lhsBlock && rhsBlock) 9222 return ctx.typesAreBlockPointerCompatible(lhs, rhs); 9223 9224 // If either is an unqualified 'id' and the other is a block, it's 9225 // acceptable. 9226 if ((lhsOPT && lhsOPT->isObjCIdType() && rhsBlock) || 9227 (rhsOPT && rhsOPT->isObjCIdType() && lhsBlock)) 9228 return true; 9229 9230 return false; 9231 } 9232 9233 // Check that the given Objective-C type argument lists are equivalent. 9234 static bool sameObjCTypeArgs(ASTContext &ctx, 9235 const ObjCInterfaceDecl *iface, 9236 ArrayRef<QualType> lhsArgs, 9237 ArrayRef<QualType> rhsArgs, 9238 bool stripKindOf) { 9239 if (lhsArgs.size() != rhsArgs.size()) 9240 return false; 9241 9242 ObjCTypeParamList *typeParams = iface->getTypeParamList(); 9243 for (unsigned i = 0, n = lhsArgs.size(); i != n; ++i) { 9244 if (ctx.hasSameType(lhsArgs[i], rhsArgs[i])) 9245 continue; 9246 9247 switch (typeParams->begin()[i]->getVariance()) { 9248 case ObjCTypeParamVariance::Invariant: 9249 if (!stripKindOf || 9250 !ctx.hasSameType(lhsArgs[i].stripObjCKindOfType(ctx), 9251 rhsArgs[i].stripObjCKindOfType(ctx))) { 9252 return false; 9253 } 9254 break; 9255 9256 case ObjCTypeParamVariance::Covariant: 9257 if (!canAssignObjCObjectTypes(ctx, lhsArgs[i], rhsArgs[i])) 9258 return false; 9259 break; 9260 9261 case ObjCTypeParamVariance::Contravariant: 9262 if (!canAssignObjCObjectTypes(ctx, rhsArgs[i], lhsArgs[i])) 9263 return false; 9264 break; 9265 } 9266 } 9267 9268 return true; 9269 } 9270 9271 QualType ASTContext::areCommonBaseCompatible( 9272 const ObjCObjectPointerType *Lptr, 9273 const ObjCObjectPointerType *Rptr) { 9274 const ObjCObjectType *LHS = Lptr->getObjectType(); 9275 const ObjCObjectType *RHS = Rptr->getObjectType(); 9276 const ObjCInterfaceDecl* LDecl = LHS->getInterface(); 9277 const ObjCInterfaceDecl* RDecl = RHS->getInterface(); 9278 9279 if (!LDecl || !RDecl) 9280 return {}; 9281 9282 // When either LHS or RHS is a kindof type, we should return a kindof type. 9283 // For example, for common base of kindof(ASub1) and kindof(ASub2), we return 9284 // kindof(A). 9285 bool anyKindOf = LHS->isKindOfType() || RHS->isKindOfType(); 9286 9287 // Follow the left-hand side up the class hierarchy until we either hit a 9288 // root or find the RHS. Record the ancestors in case we don't find it. 9289 llvm::SmallDenseMap<const ObjCInterfaceDecl *, const ObjCObjectType *, 4> 9290 LHSAncestors; 9291 while (true) { 9292 // Record this ancestor. We'll need this if the common type isn't in the 9293 // path from the LHS to the root. 9294 LHSAncestors[LHS->getInterface()->getCanonicalDecl()] = LHS; 9295 9296 if (declaresSameEntity(LHS->getInterface(), RDecl)) { 9297 // Get the type arguments. 9298 ArrayRef<QualType> LHSTypeArgs = LHS->getTypeArgsAsWritten(); 9299 bool anyChanges = false; 9300 if (LHS->isSpecialized() && RHS->isSpecialized()) { 9301 // Both have type arguments, compare them. 9302 if (!sameObjCTypeArgs(*this, LHS->getInterface(), 9303 LHS->getTypeArgs(), RHS->getTypeArgs(), 9304 /*stripKindOf=*/true)) 9305 return {}; 9306 } else if (LHS->isSpecialized() != RHS->isSpecialized()) { 9307 // If only one has type arguments, the result will not have type 9308 // arguments. 9309 LHSTypeArgs = {}; 9310 anyChanges = true; 9311 } 9312 9313 // Compute the intersection of protocols. 9314 SmallVector<ObjCProtocolDecl *, 8> Protocols; 9315 getIntersectionOfProtocols(*this, LHS->getInterface(), Lptr, Rptr, 9316 Protocols); 9317 if (!Protocols.empty()) 9318 anyChanges = true; 9319 9320 // If anything in the LHS will have changed, build a new result type. 9321 // If we need to return a kindof type but LHS is not a kindof type, we 9322 // build a new result type. 9323 if (anyChanges || LHS->isKindOfType() != anyKindOf) { 9324 QualType Result = getObjCInterfaceType(LHS->getInterface()); 9325 Result = getObjCObjectType(Result, LHSTypeArgs, Protocols, 9326 anyKindOf || LHS->isKindOfType()); 9327 return getObjCObjectPointerType(Result); 9328 } 9329 9330 return getObjCObjectPointerType(QualType(LHS, 0)); 9331 } 9332 9333 // Find the superclass. 9334 QualType LHSSuperType = LHS->getSuperClassType(); 9335 if (LHSSuperType.isNull()) 9336 break; 9337 9338 LHS = LHSSuperType->castAs<ObjCObjectType>(); 9339 } 9340 9341 // We didn't find anything by following the LHS to its root; now check 9342 // the RHS against the cached set of ancestors. 9343 while (true) { 9344 auto KnownLHS = LHSAncestors.find(RHS->getInterface()->getCanonicalDecl()); 9345 if (KnownLHS != LHSAncestors.end()) { 9346 LHS = KnownLHS->second; 9347 9348 // Get the type arguments. 9349 ArrayRef<QualType> RHSTypeArgs = RHS->getTypeArgsAsWritten(); 9350 bool anyChanges = false; 9351 if (LHS->isSpecialized() && RHS->isSpecialized()) { 9352 // Both have type arguments, compare them. 9353 if (!sameObjCTypeArgs(*this, LHS->getInterface(), 9354 LHS->getTypeArgs(), RHS->getTypeArgs(), 9355 /*stripKindOf=*/true)) 9356 return {}; 9357 } else if (LHS->isSpecialized() != RHS->isSpecialized()) { 9358 // If only one has type arguments, the result will not have type 9359 // arguments. 9360 RHSTypeArgs = {}; 9361 anyChanges = true; 9362 } 9363 9364 // Compute the intersection of protocols. 9365 SmallVector<ObjCProtocolDecl *, 8> Protocols; 9366 getIntersectionOfProtocols(*this, RHS->getInterface(), Lptr, Rptr, 9367 Protocols); 9368 if (!Protocols.empty()) 9369 anyChanges = true; 9370 9371 // If we need to return a kindof type but RHS is not a kindof type, we 9372 // build a new result type. 9373 if (anyChanges || RHS->isKindOfType() != anyKindOf) { 9374 QualType Result = getObjCInterfaceType(RHS->getInterface()); 9375 Result = getObjCObjectType(Result, RHSTypeArgs, Protocols, 9376 anyKindOf || RHS->isKindOfType()); 9377 return getObjCObjectPointerType(Result); 9378 } 9379 9380 return getObjCObjectPointerType(QualType(RHS, 0)); 9381 } 9382 9383 // Find the superclass of the RHS. 9384 QualType RHSSuperType = RHS->getSuperClassType(); 9385 if (RHSSuperType.isNull()) 9386 break; 9387 9388 RHS = RHSSuperType->castAs<ObjCObjectType>(); 9389 } 9390 9391 return {}; 9392 } 9393 9394 bool ASTContext::canAssignObjCInterfaces(const ObjCObjectType *LHS, 9395 const ObjCObjectType *RHS) { 9396 assert(LHS->getInterface() && "LHS is not an interface type"); 9397 assert(RHS->getInterface() && "RHS is not an interface type"); 9398 9399 // Verify that the base decls are compatible: the RHS must be a subclass of 9400 // the LHS. 9401 ObjCInterfaceDecl *LHSInterface = LHS->getInterface(); 9402 bool IsSuperClass = LHSInterface->isSuperClassOf(RHS->getInterface()); 9403 if (!IsSuperClass) 9404 return false; 9405 9406 // If the LHS has protocol qualifiers, determine whether all of them are 9407 // satisfied by the RHS (i.e., the RHS has a superset of the protocols in the 9408 // LHS). 9409 if (LHS->getNumProtocols() > 0) { 9410 // OK if conversion of LHS to SuperClass results in narrowing of types 9411 // ; i.e., SuperClass may implement at least one of the protocols 9412 // in LHS's protocol list. Example, SuperObj<P1> = lhs<P1,P2> is ok. 9413 // But not SuperObj<P1,P2,P3> = lhs<P1,P2>. 9414 llvm::SmallPtrSet<ObjCProtocolDecl *, 8> SuperClassInheritedProtocols; 9415 CollectInheritedProtocols(RHS->getInterface(), SuperClassInheritedProtocols); 9416 // Also, if RHS has explicit quelifiers, include them for comparing with LHS's 9417 // qualifiers. 9418 for (auto *RHSPI : RHS->quals()) 9419 CollectInheritedProtocols(RHSPI, SuperClassInheritedProtocols); 9420 // If there is no protocols associated with RHS, it is not a match. 9421 if (SuperClassInheritedProtocols.empty()) 9422 return false; 9423 9424 for (const auto *LHSProto : LHS->quals()) { 9425 bool SuperImplementsProtocol = false; 9426 for (auto *SuperClassProto : SuperClassInheritedProtocols) 9427 if (SuperClassProto->lookupProtocolNamed(LHSProto->getIdentifier())) { 9428 SuperImplementsProtocol = true; 9429 break; 9430 } 9431 if (!SuperImplementsProtocol) 9432 return false; 9433 } 9434 } 9435 9436 // If the LHS is specialized, we may need to check type arguments. 9437 if (LHS->isSpecialized()) { 9438 // Follow the superclass chain until we've matched the LHS class in the 9439 // hierarchy. This substitutes type arguments through. 9440 const ObjCObjectType *RHSSuper = RHS; 9441 while (!declaresSameEntity(RHSSuper->getInterface(), LHSInterface)) 9442 RHSSuper = RHSSuper->getSuperClassType()->castAs<ObjCObjectType>(); 9443 9444 // If the RHS is specializd, compare type arguments. 9445 if (RHSSuper->isSpecialized() && 9446 !sameObjCTypeArgs(*this, LHS->getInterface(), 9447 LHS->getTypeArgs(), RHSSuper->getTypeArgs(), 9448 /*stripKindOf=*/true)) { 9449 return false; 9450 } 9451 } 9452 9453 return true; 9454 } 9455 9456 bool ASTContext::areComparableObjCPointerTypes(QualType LHS, QualType RHS) { 9457 // get the "pointed to" types 9458 const auto *LHSOPT = LHS->getAs<ObjCObjectPointerType>(); 9459 const auto *RHSOPT = RHS->getAs<ObjCObjectPointerType>(); 9460 9461 if (!LHSOPT || !RHSOPT) 9462 return false; 9463 9464 return canAssignObjCInterfaces(LHSOPT, RHSOPT) || 9465 canAssignObjCInterfaces(RHSOPT, LHSOPT); 9466 } 9467 9468 bool ASTContext::canBindObjCObjectType(QualType To, QualType From) { 9469 return canAssignObjCInterfaces( 9470 getObjCObjectPointerType(To)->castAs<ObjCObjectPointerType>(), 9471 getObjCObjectPointerType(From)->castAs<ObjCObjectPointerType>()); 9472 } 9473 9474 /// typesAreCompatible - C99 6.7.3p9: For two qualified types to be compatible, 9475 /// both shall have the identically qualified version of a compatible type. 9476 /// C99 6.2.7p1: Two types have compatible types if their types are the 9477 /// same. See 6.7.[2,3,5] for additional rules. 9478 bool ASTContext::typesAreCompatible(QualType LHS, QualType RHS, 9479 bool CompareUnqualified) { 9480 if (getLangOpts().CPlusPlus) 9481 return hasSameType(LHS, RHS); 9482 9483 return !mergeTypes(LHS, RHS, false, CompareUnqualified).isNull(); 9484 } 9485 9486 bool ASTContext::propertyTypesAreCompatible(QualType LHS, QualType RHS) { 9487 return typesAreCompatible(LHS, RHS); 9488 } 9489 9490 bool ASTContext::typesAreBlockPointerCompatible(QualType LHS, QualType RHS) { 9491 return !mergeTypes(LHS, RHS, true).isNull(); 9492 } 9493 9494 /// mergeTransparentUnionType - if T is a transparent union type and a member 9495 /// of T is compatible with SubType, return the merged type, else return 9496 /// QualType() 9497 QualType ASTContext::mergeTransparentUnionType(QualType T, QualType SubType, 9498 bool OfBlockPointer, 9499 bool Unqualified) { 9500 if (const RecordType *UT = T->getAsUnionType()) { 9501 RecordDecl *UD = UT->getDecl(); 9502 if (UD->hasAttr<TransparentUnionAttr>()) { 9503 for (const auto *I : UD->fields()) { 9504 QualType ET = I->getType().getUnqualifiedType(); 9505 QualType MT = mergeTypes(ET, SubType, OfBlockPointer, Unqualified); 9506 if (!MT.isNull()) 9507 return MT; 9508 } 9509 } 9510 } 9511 9512 return {}; 9513 } 9514 9515 /// mergeFunctionParameterTypes - merge two types which appear as function 9516 /// parameter types 9517 QualType ASTContext::mergeFunctionParameterTypes(QualType lhs, QualType rhs, 9518 bool OfBlockPointer, 9519 bool Unqualified) { 9520 // GNU extension: two types are compatible if they appear as a function 9521 // argument, one of the types is a transparent union type and the other 9522 // type is compatible with a union member 9523 QualType lmerge = mergeTransparentUnionType(lhs, rhs, OfBlockPointer, 9524 Unqualified); 9525 if (!lmerge.isNull()) 9526 return lmerge; 9527 9528 QualType rmerge = mergeTransparentUnionType(rhs, lhs, OfBlockPointer, 9529 Unqualified); 9530 if (!rmerge.isNull()) 9531 return rmerge; 9532 9533 return mergeTypes(lhs, rhs, OfBlockPointer, Unqualified); 9534 } 9535 9536 QualType ASTContext::mergeFunctionTypes(QualType lhs, QualType rhs, 9537 bool OfBlockPointer, bool Unqualified, 9538 bool AllowCXX) { 9539 const auto *lbase = lhs->castAs<FunctionType>(); 9540 const auto *rbase = rhs->castAs<FunctionType>(); 9541 const auto *lproto = dyn_cast<FunctionProtoType>(lbase); 9542 const auto *rproto = dyn_cast<FunctionProtoType>(rbase); 9543 bool allLTypes = true; 9544 bool allRTypes = true; 9545 9546 // Check return type 9547 QualType retType; 9548 if (OfBlockPointer) { 9549 QualType RHS = rbase->getReturnType(); 9550 QualType LHS = lbase->getReturnType(); 9551 bool UnqualifiedResult = Unqualified; 9552 if (!UnqualifiedResult) 9553 UnqualifiedResult = (!RHS.hasQualifiers() && LHS.hasQualifiers()); 9554 retType = mergeTypes(LHS, RHS, true, UnqualifiedResult, true); 9555 } 9556 else 9557 retType = mergeTypes(lbase->getReturnType(), rbase->getReturnType(), false, 9558 Unqualified); 9559 if (retType.isNull()) 9560 return {}; 9561 9562 if (Unqualified) 9563 retType = retType.getUnqualifiedType(); 9564 9565 CanQualType LRetType = getCanonicalType(lbase->getReturnType()); 9566 CanQualType RRetType = getCanonicalType(rbase->getReturnType()); 9567 if (Unqualified) { 9568 LRetType = LRetType.getUnqualifiedType(); 9569 RRetType = RRetType.getUnqualifiedType(); 9570 } 9571 9572 if (getCanonicalType(retType) != LRetType) 9573 allLTypes = false; 9574 if (getCanonicalType(retType) != RRetType) 9575 allRTypes = false; 9576 9577 // FIXME: double check this 9578 // FIXME: should we error if lbase->getRegParmAttr() != 0 && 9579 // rbase->getRegParmAttr() != 0 && 9580 // lbase->getRegParmAttr() != rbase->getRegParmAttr()? 9581 FunctionType::ExtInfo lbaseInfo = lbase->getExtInfo(); 9582 FunctionType::ExtInfo rbaseInfo = rbase->getExtInfo(); 9583 9584 // Compatible functions must have compatible calling conventions 9585 if (lbaseInfo.getCC() != rbaseInfo.getCC()) 9586 return {}; 9587 9588 // Regparm is part of the calling convention. 9589 if (lbaseInfo.getHasRegParm() != rbaseInfo.getHasRegParm()) 9590 return {}; 9591 if (lbaseInfo.getRegParm() != rbaseInfo.getRegParm()) 9592 return {}; 9593 9594 if (lbaseInfo.getProducesResult() != rbaseInfo.getProducesResult()) 9595 return {}; 9596 if (lbaseInfo.getNoCallerSavedRegs() != rbaseInfo.getNoCallerSavedRegs()) 9597 return {}; 9598 if (lbaseInfo.getNoCfCheck() != rbaseInfo.getNoCfCheck()) 9599 return {}; 9600 9601 // FIXME: some uses, e.g. conditional exprs, really want this to be 'both'. 9602 bool NoReturn = lbaseInfo.getNoReturn() || rbaseInfo.getNoReturn(); 9603 9604 if (lbaseInfo.getNoReturn() != NoReturn) 9605 allLTypes = false; 9606 if (rbaseInfo.getNoReturn() != NoReturn) 9607 allRTypes = false; 9608 9609 FunctionType::ExtInfo einfo = lbaseInfo.withNoReturn(NoReturn); 9610 9611 if (lproto && rproto) { // two C99 style function prototypes 9612 assert((AllowCXX || 9613 (!lproto->hasExceptionSpec() && !rproto->hasExceptionSpec())) && 9614 "C++ shouldn't be here"); 9615 // Compatible functions must have the same number of parameters 9616 if (lproto->getNumParams() != rproto->getNumParams()) 9617 return {}; 9618 9619 // Variadic and non-variadic functions aren't compatible 9620 if (lproto->isVariadic() != rproto->isVariadic()) 9621 return {}; 9622 9623 if (lproto->getMethodQuals() != rproto->getMethodQuals()) 9624 return {}; 9625 9626 SmallVector<FunctionProtoType::ExtParameterInfo, 4> newParamInfos; 9627 bool canUseLeft, canUseRight; 9628 if (!mergeExtParameterInfo(lproto, rproto, canUseLeft, canUseRight, 9629 newParamInfos)) 9630 return {}; 9631 9632 if (!canUseLeft) 9633 allLTypes = false; 9634 if (!canUseRight) 9635 allRTypes = false; 9636 9637 // Check parameter type compatibility 9638 SmallVector<QualType, 10> types; 9639 for (unsigned i = 0, n = lproto->getNumParams(); i < n; i++) { 9640 QualType lParamType = lproto->getParamType(i).getUnqualifiedType(); 9641 QualType rParamType = rproto->getParamType(i).getUnqualifiedType(); 9642 QualType paramType = mergeFunctionParameterTypes( 9643 lParamType, rParamType, OfBlockPointer, Unqualified); 9644 if (paramType.isNull()) 9645 return {}; 9646 9647 if (Unqualified) 9648 paramType = paramType.getUnqualifiedType(); 9649 9650 types.push_back(paramType); 9651 if (Unqualified) { 9652 lParamType = lParamType.getUnqualifiedType(); 9653 rParamType = rParamType.getUnqualifiedType(); 9654 } 9655 9656 if (getCanonicalType(paramType) != getCanonicalType(lParamType)) 9657 allLTypes = false; 9658 if (getCanonicalType(paramType) != getCanonicalType(rParamType)) 9659 allRTypes = false; 9660 } 9661 9662 if (allLTypes) return lhs; 9663 if (allRTypes) return rhs; 9664 9665 FunctionProtoType::ExtProtoInfo EPI = lproto->getExtProtoInfo(); 9666 EPI.ExtInfo = einfo; 9667 EPI.ExtParameterInfos = 9668 newParamInfos.empty() ? nullptr : newParamInfos.data(); 9669 return getFunctionType(retType, types, EPI); 9670 } 9671 9672 if (lproto) allRTypes = false; 9673 if (rproto) allLTypes = false; 9674 9675 const FunctionProtoType *proto = lproto ? lproto : rproto; 9676 if (proto) { 9677 assert((AllowCXX || !proto->hasExceptionSpec()) && "C++ shouldn't be here"); 9678 if (proto->isVariadic()) 9679 return {}; 9680 // Check that the types are compatible with the types that 9681 // would result from default argument promotions (C99 6.7.5.3p15). 9682 // The only types actually affected are promotable integer 9683 // types and floats, which would be passed as a different 9684 // type depending on whether the prototype is visible. 9685 for (unsigned i = 0, n = proto->getNumParams(); i < n; ++i) { 9686 QualType paramTy = proto->getParamType(i); 9687 9688 // Look at the converted type of enum types, since that is the type used 9689 // to pass enum values. 9690 if (const auto *Enum = paramTy->getAs<EnumType>()) { 9691 paramTy = Enum->getDecl()->getIntegerType(); 9692 if (paramTy.isNull()) 9693 return {}; 9694 } 9695 9696 if (paramTy->isPromotableIntegerType() || 9697 getCanonicalType(paramTy).getUnqualifiedType() == FloatTy) 9698 return {}; 9699 } 9700 9701 if (allLTypes) return lhs; 9702 if (allRTypes) return rhs; 9703 9704 FunctionProtoType::ExtProtoInfo EPI = proto->getExtProtoInfo(); 9705 EPI.ExtInfo = einfo; 9706 return getFunctionType(retType, proto->getParamTypes(), EPI); 9707 } 9708 9709 if (allLTypes) return lhs; 9710 if (allRTypes) return rhs; 9711 return getFunctionNoProtoType(retType, einfo); 9712 } 9713 9714 /// Given that we have an enum type and a non-enum type, try to merge them. 9715 static QualType mergeEnumWithInteger(ASTContext &Context, const EnumType *ET, 9716 QualType other, bool isBlockReturnType) { 9717 // C99 6.7.2.2p4: Each enumerated type shall be compatible with char, 9718 // a signed integer type, or an unsigned integer type. 9719 // Compatibility is based on the underlying type, not the promotion 9720 // type. 9721 QualType underlyingType = ET->getDecl()->getIntegerType(); 9722 if (underlyingType.isNull()) 9723 return {}; 9724 if (Context.hasSameType(underlyingType, other)) 9725 return other; 9726 9727 // In block return types, we're more permissive and accept any 9728 // integral type of the same size. 9729 if (isBlockReturnType && other->isIntegerType() && 9730 Context.getTypeSize(underlyingType) == Context.getTypeSize(other)) 9731 return other; 9732 9733 return {}; 9734 } 9735 9736 QualType ASTContext::mergeTypes(QualType LHS, QualType RHS, 9737 bool OfBlockPointer, 9738 bool Unqualified, bool BlockReturnType) { 9739 // For C++ we will not reach this code with reference types (see below), 9740 // for OpenMP variant call overloading we might. 9741 // 9742 // C++ [expr]: If an expression initially has the type "reference to T", the 9743 // type is adjusted to "T" prior to any further analysis, the expression 9744 // designates the object or function denoted by the reference, and the 9745 // expression is an lvalue unless the reference is an rvalue reference and 9746 // the expression is a function call (possibly inside parentheses). 9747 if (LangOpts.OpenMP && LHS->getAs<ReferenceType>() && 9748 RHS->getAs<ReferenceType>() && LHS->getTypeClass() == RHS->getTypeClass()) 9749 return mergeTypes(LHS->getAs<ReferenceType>()->getPointeeType(), 9750 RHS->getAs<ReferenceType>()->getPointeeType(), 9751 OfBlockPointer, Unqualified, BlockReturnType); 9752 if (LHS->getAs<ReferenceType>() || RHS->getAs<ReferenceType>()) 9753 return {}; 9754 9755 if (Unqualified) { 9756 LHS = LHS.getUnqualifiedType(); 9757 RHS = RHS.getUnqualifiedType(); 9758 } 9759 9760 QualType LHSCan = getCanonicalType(LHS), 9761 RHSCan = getCanonicalType(RHS); 9762 9763 // If two types are identical, they are compatible. 9764 if (LHSCan == RHSCan) 9765 return LHS; 9766 9767 // If the qualifiers are different, the types aren't compatible... mostly. 9768 Qualifiers LQuals = LHSCan.getLocalQualifiers(); 9769 Qualifiers RQuals = RHSCan.getLocalQualifiers(); 9770 if (LQuals != RQuals) { 9771 // If any of these qualifiers are different, we have a type 9772 // mismatch. 9773 if (LQuals.getCVRQualifiers() != RQuals.getCVRQualifiers() || 9774 LQuals.getAddressSpace() != RQuals.getAddressSpace() || 9775 LQuals.getObjCLifetime() != RQuals.getObjCLifetime() || 9776 LQuals.hasUnaligned() != RQuals.hasUnaligned()) 9777 return {}; 9778 9779 // Exactly one GC qualifier difference is allowed: __strong is 9780 // okay if the other type has no GC qualifier but is an Objective 9781 // C object pointer (i.e. implicitly strong by default). We fix 9782 // this by pretending that the unqualified type was actually 9783 // qualified __strong. 9784 Qualifiers::GC GC_L = LQuals.getObjCGCAttr(); 9785 Qualifiers::GC GC_R = RQuals.getObjCGCAttr(); 9786 assert((GC_L != GC_R) && "unequal qualifier sets had only equal elements"); 9787 9788 if (GC_L == Qualifiers::Weak || GC_R == Qualifiers::Weak) 9789 return {}; 9790 9791 if (GC_L == Qualifiers::Strong && RHSCan->isObjCObjectPointerType()) { 9792 return mergeTypes(LHS, getObjCGCQualType(RHS, Qualifiers::Strong)); 9793 } 9794 if (GC_R == Qualifiers::Strong && LHSCan->isObjCObjectPointerType()) { 9795 return mergeTypes(getObjCGCQualType(LHS, Qualifiers::Strong), RHS); 9796 } 9797 return {}; 9798 } 9799 9800 // Okay, qualifiers are equal. 9801 9802 Type::TypeClass LHSClass = LHSCan->getTypeClass(); 9803 Type::TypeClass RHSClass = RHSCan->getTypeClass(); 9804 9805 // We want to consider the two function types to be the same for these 9806 // comparisons, just force one to the other. 9807 if (LHSClass == Type::FunctionProto) LHSClass = Type::FunctionNoProto; 9808 if (RHSClass == Type::FunctionProto) RHSClass = Type::FunctionNoProto; 9809 9810 // Same as above for arrays 9811 if (LHSClass == Type::VariableArray || LHSClass == Type::IncompleteArray) 9812 LHSClass = Type::ConstantArray; 9813 if (RHSClass == Type::VariableArray || RHSClass == Type::IncompleteArray) 9814 RHSClass = Type::ConstantArray; 9815 9816 // ObjCInterfaces are just specialized ObjCObjects. 9817 if (LHSClass == Type::ObjCInterface) LHSClass = Type::ObjCObject; 9818 if (RHSClass == Type::ObjCInterface) RHSClass = Type::ObjCObject; 9819 9820 // Canonicalize ExtVector -> Vector. 9821 if (LHSClass == Type::ExtVector) LHSClass = Type::Vector; 9822 if (RHSClass == Type::ExtVector) RHSClass = Type::Vector; 9823 9824 // If the canonical type classes don't match. 9825 if (LHSClass != RHSClass) { 9826 // Note that we only have special rules for turning block enum 9827 // returns into block int returns, not vice-versa. 9828 if (const auto *ETy = LHS->getAs<EnumType>()) { 9829 return mergeEnumWithInteger(*this, ETy, RHS, false); 9830 } 9831 if (const EnumType* ETy = RHS->getAs<EnumType>()) { 9832 return mergeEnumWithInteger(*this, ETy, LHS, BlockReturnType); 9833 } 9834 // allow block pointer type to match an 'id' type. 9835 if (OfBlockPointer && !BlockReturnType) { 9836 if (LHS->isObjCIdType() && RHS->isBlockPointerType()) 9837 return LHS; 9838 if (RHS->isObjCIdType() && LHS->isBlockPointerType()) 9839 return RHS; 9840 } 9841 9842 return {}; 9843 } 9844 9845 // The canonical type classes match. 9846 switch (LHSClass) { 9847 #define TYPE(Class, Base) 9848 #define ABSTRACT_TYPE(Class, Base) 9849 #define NON_CANONICAL_UNLESS_DEPENDENT_TYPE(Class, Base) case Type::Class: 9850 #define NON_CANONICAL_TYPE(Class, Base) case Type::Class: 9851 #define DEPENDENT_TYPE(Class, Base) case Type::Class: 9852 #include "clang/AST/TypeNodes.inc" 9853 llvm_unreachable("Non-canonical and dependent types shouldn't get here"); 9854 9855 case Type::Auto: 9856 case Type::DeducedTemplateSpecialization: 9857 case Type::LValueReference: 9858 case Type::RValueReference: 9859 case Type::MemberPointer: 9860 llvm_unreachable("C++ should never be in mergeTypes"); 9861 9862 case Type::ObjCInterface: 9863 case Type::IncompleteArray: 9864 case Type::VariableArray: 9865 case Type::FunctionProto: 9866 case Type::ExtVector: 9867 llvm_unreachable("Types are eliminated above"); 9868 9869 case Type::Pointer: 9870 { 9871 // Merge two pointer types, while trying to preserve typedef info 9872 QualType LHSPointee = LHS->castAs<PointerType>()->getPointeeType(); 9873 QualType RHSPointee = RHS->castAs<PointerType>()->getPointeeType(); 9874 if (Unqualified) { 9875 LHSPointee = LHSPointee.getUnqualifiedType(); 9876 RHSPointee = RHSPointee.getUnqualifiedType(); 9877 } 9878 QualType ResultType = mergeTypes(LHSPointee, RHSPointee, false, 9879 Unqualified); 9880 if (ResultType.isNull()) 9881 return {}; 9882 if (getCanonicalType(LHSPointee) == getCanonicalType(ResultType)) 9883 return LHS; 9884 if (getCanonicalType(RHSPointee) == getCanonicalType(ResultType)) 9885 return RHS; 9886 return getPointerType(ResultType); 9887 } 9888 case Type::BlockPointer: 9889 { 9890 // Merge two block pointer types, while trying to preserve typedef info 9891 QualType LHSPointee = LHS->castAs<BlockPointerType>()->getPointeeType(); 9892 QualType RHSPointee = RHS->castAs<BlockPointerType>()->getPointeeType(); 9893 if (Unqualified) { 9894 LHSPointee = LHSPointee.getUnqualifiedType(); 9895 RHSPointee = RHSPointee.getUnqualifiedType(); 9896 } 9897 if (getLangOpts().OpenCL) { 9898 Qualifiers LHSPteeQual = LHSPointee.getQualifiers(); 9899 Qualifiers RHSPteeQual = RHSPointee.getQualifiers(); 9900 // Blocks can't be an expression in a ternary operator (OpenCL v2.0 9901 // 6.12.5) thus the following check is asymmetric. 9902 if (!LHSPteeQual.isAddressSpaceSupersetOf(RHSPteeQual)) 9903 return {}; 9904 LHSPteeQual.removeAddressSpace(); 9905 RHSPteeQual.removeAddressSpace(); 9906 LHSPointee = 9907 QualType(LHSPointee.getTypePtr(), LHSPteeQual.getAsOpaqueValue()); 9908 RHSPointee = 9909 QualType(RHSPointee.getTypePtr(), RHSPteeQual.getAsOpaqueValue()); 9910 } 9911 QualType ResultType = mergeTypes(LHSPointee, RHSPointee, OfBlockPointer, 9912 Unqualified); 9913 if (ResultType.isNull()) 9914 return {}; 9915 if (getCanonicalType(LHSPointee) == getCanonicalType(ResultType)) 9916 return LHS; 9917 if (getCanonicalType(RHSPointee) == getCanonicalType(ResultType)) 9918 return RHS; 9919 return getBlockPointerType(ResultType); 9920 } 9921 case Type::Atomic: 9922 { 9923 // Merge two pointer types, while trying to preserve typedef info 9924 QualType LHSValue = LHS->castAs<AtomicType>()->getValueType(); 9925 QualType RHSValue = RHS->castAs<AtomicType>()->getValueType(); 9926 if (Unqualified) { 9927 LHSValue = LHSValue.getUnqualifiedType(); 9928 RHSValue = RHSValue.getUnqualifiedType(); 9929 } 9930 QualType ResultType = mergeTypes(LHSValue, RHSValue, false, 9931 Unqualified); 9932 if (ResultType.isNull()) 9933 return {}; 9934 if (getCanonicalType(LHSValue) == getCanonicalType(ResultType)) 9935 return LHS; 9936 if (getCanonicalType(RHSValue) == getCanonicalType(ResultType)) 9937 return RHS; 9938 return getAtomicType(ResultType); 9939 } 9940 case Type::ConstantArray: 9941 { 9942 const ConstantArrayType* LCAT = getAsConstantArrayType(LHS); 9943 const ConstantArrayType* RCAT = getAsConstantArrayType(RHS); 9944 if (LCAT && RCAT && RCAT->getSize() != LCAT->getSize()) 9945 return {}; 9946 9947 QualType LHSElem = getAsArrayType(LHS)->getElementType(); 9948 QualType RHSElem = getAsArrayType(RHS)->getElementType(); 9949 if (Unqualified) { 9950 LHSElem = LHSElem.getUnqualifiedType(); 9951 RHSElem = RHSElem.getUnqualifiedType(); 9952 } 9953 9954 QualType ResultType = mergeTypes(LHSElem, RHSElem, false, Unqualified); 9955 if (ResultType.isNull()) 9956 return {}; 9957 9958 const VariableArrayType* LVAT = getAsVariableArrayType(LHS); 9959 const VariableArrayType* RVAT = getAsVariableArrayType(RHS); 9960 9961 // If either side is a variable array, and both are complete, check whether 9962 // the current dimension is definite. 9963 if (LVAT || RVAT) { 9964 auto SizeFetch = [this](const VariableArrayType* VAT, 9965 const ConstantArrayType* CAT) 9966 -> std::pair<bool,llvm::APInt> { 9967 if (VAT) { 9968 Optional<llvm::APSInt> TheInt; 9969 Expr *E = VAT->getSizeExpr(); 9970 if (E && (TheInt = E->getIntegerConstantExpr(*this))) 9971 return std::make_pair(true, *TheInt); 9972 return std::make_pair(false, llvm::APSInt()); 9973 } 9974 if (CAT) 9975 return std::make_pair(true, CAT->getSize()); 9976 return std::make_pair(false, llvm::APInt()); 9977 }; 9978 9979 bool HaveLSize, HaveRSize; 9980 llvm::APInt LSize, RSize; 9981 std::tie(HaveLSize, LSize) = SizeFetch(LVAT, LCAT); 9982 std::tie(HaveRSize, RSize) = SizeFetch(RVAT, RCAT); 9983 if (HaveLSize && HaveRSize && !llvm::APInt::isSameValue(LSize, RSize)) 9984 return {}; // Definite, but unequal, array dimension 9985 } 9986 9987 if (LCAT && getCanonicalType(LHSElem) == getCanonicalType(ResultType)) 9988 return LHS; 9989 if (RCAT && getCanonicalType(RHSElem) == getCanonicalType(ResultType)) 9990 return RHS; 9991 if (LCAT) 9992 return getConstantArrayType(ResultType, LCAT->getSize(), 9993 LCAT->getSizeExpr(), 9994 ArrayType::ArraySizeModifier(), 0); 9995 if (RCAT) 9996 return getConstantArrayType(ResultType, RCAT->getSize(), 9997 RCAT->getSizeExpr(), 9998 ArrayType::ArraySizeModifier(), 0); 9999 if (LVAT && getCanonicalType(LHSElem) == getCanonicalType(ResultType)) 10000 return LHS; 10001 if (RVAT && getCanonicalType(RHSElem) == getCanonicalType(ResultType)) 10002 return RHS; 10003 if (LVAT) { 10004 // FIXME: This isn't correct! But tricky to implement because 10005 // the array's size has to be the size of LHS, but the type 10006 // has to be different. 10007 return LHS; 10008 } 10009 if (RVAT) { 10010 // FIXME: This isn't correct! But tricky to implement because 10011 // the array's size has to be the size of RHS, but the type 10012 // has to be different. 10013 return RHS; 10014 } 10015 if (getCanonicalType(LHSElem) == getCanonicalType(ResultType)) return LHS; 10016 if (getCanonicalType(RHSElem) == getCanonicalType(ResultType)) return RHS; 10017 return getIncompleteArrayType(ResultType, 10018 ArrayType::ArraySizeModifier(), 0); 10019 } 10020 case Type::FunctionNoProto: 10021 return mergeFunctionTypes(LHS, RHS, OfBlockPointer, Unqualified); 10022 case Type::Record: 10023 case Type::Enum: 10024 return {}; 10025 case Type::Builtin: 10026 // Only exactly equal builtin types are compatible, which is tested above. 10027 return {}; 10028 case Type::Complex: 10029 // Distinct complex types are incompatible. 10030 return {}; 10031 case Type::Vector: 10032 // FIXME: The merged type should be an ExtVector! 10033 if (areCompatVectorTypes(LHSCan->castAs<VectorType>(), 10034 RHSCan->castAs<VectorType>())) 10035 return LHS; 10036 return {}; 10037 case Type::ConstantMatrix: 10038 if (areCompatMatrixTypes(LHSCan->castAs<ConstantMatrixType>(), 10039 RHSCan->castAs<ConstantMatrixType>())) 10040 return LHS; 10041 return {}; 10042 case Type::ObjCObject: { 10043 // Check if the types are assignment compatible. 10044 // FIXME: This should be type compatibility, e.g. whether 10045 // "LHS x; RHS x;" at global scope is legal. 10046 if (canAssignObjCInterfaces(LHS->castAs<ObjCObjectType>(), 10047 RHS->castAs<ObjCObjectType>())) 10048 return LHS; 10049 return {}; 10050 } 10051 case Type::ObjCObjectPointer: 10052 if (OfBlockPointer) { 10053 if (canAssignObjCInterfacesInBlockPointer( 10054 LHS->castAs<ObjCObjectPointerType>(), 10055 RHS->castAs<ObjCObjectPointerType>(), BlockReturnType)) 10056 return LHS; 10057 return {}; 10058 } 10059 if (canAssignObjCInterfaces(LHS->castAs<ObjCObjectPointerType>(), 10060 RHS->castAs<ObjCObjectPointerType>())) 10061 return LHS; 10062 return {}; 10063 case Type::Pipe: 10064 assert(LHS != RHS && 10065 "Equivalent pipe types should have already been handled!"); 10066 return {}; 10067 case Type::ExtInt: { 10068 // Merge two ext-int types, while trying to preserve typedef info. 10069 bool LHSUnsigned = LHS->castAs<ExtIntType>()->isUnsigned(); 10070 bool RHSUnsigned = RHS->castAs<ExtIntType>()->isUnsigned(); 10071 unsigned LHSBits = LHS->castAs<ExtIntType>()->getNumBits(); 10072 unsigned RHSBits = RHS->castAs<ExtIntType>()->getNumBits(); 10073 10074 // Like unsigned/int, shouldn't have a type if they don't match. 10075 if (LHSUnsigned != RHSUnsigned) 10076 return {}; 10077 10078 if (LHSBits != RHSBits) 10079 return {}; 10080 return LHS; 10081 } 10082 } 10083 10084 llvm_unreachable("Invalid Type::Class!"); 10085 } 10086 10087 bool ASTContext::mergeExtParameterInfo( 10088 const FunctionProtoType *FirstFnType, const FunctionProtoType *SecondFnType, 10089 bool &CanUseFirst, bool &CanUseSecond, 10090 SmallVectorImpl<FunctionProtoType::ExtParameterInfo> &NewParamInfos) { 10091 assert(NewParamInfos.empty() && "param info list not empty"); 10092 CanUseFirst = CanUseSecond = true; 10093 bool FirstHasInfo = FirstFnType->hasExtParameterInfos(); 10094 bool SecondHasInfo = SecondFnType->hasExtParameterInfos(); 10095 10096 // Fast path: if the first type doesn't have ext parameter infos, 10097 // we match if and only if the second type also doesn't have them. 10098 if (!FirstHasInfo && !SecondHasInfo) 10099 return true; 10100 10101 bool NeedParamInfo = false; 10102 size_t E = FirstHasInfo ? FirstFnType->getExtParameterInfos().size() 10103 : SecondFnType->getExtParameterInfos().size(); 10104 10105 for (size_t I = 0; I < E; ++I) { 10106 FunctionProtoType::ExtParameterInfo FirstParam, SecondParam; 10107 if (FirstHasInfo) 10108 FirstParam = FirstFnType->getExtParameterInfo(I); 10109 if (SecondHasInfo) 10110 SecondParam = SecondFnType->getExtParameterInfo(I); 10111 10112 // Cannot merge unless everything except the noescape flag matches. 10113 if (FirstParam.withIsNoEscape(false) != SecondParam.withIsNoEscape(false)) 10114 return false; 10115 10116 bool FirstNoEscape = FirstParam.isNoEscape(); 10117 bool SecondNoEscape = SecondParam.isNoEscape(); 10118 bool IsNoEscape = FirstNoEscape && SecondNoEscape; 10119 NewParamInfos.push_back(FirstParam.withIsNoEscape(IsNoEscape)); 10120 if (NewParamInfos.back().getOpaqueValue()) 10121 NeedParamInfo = true; 10122 if (FirstNoEscape != IsNoEscape) 10123 CanUseFirst = false; 10124 if (SecondNoEscape != IsNoEscape) 10125 CanUseSecond = false; 10126 } 10127 10128 if (!NeedParamInfo) 10129 NewParamInfos.clear(); 10130 10131 return true; 10132 } 10133 10134 void ASTContext::ResetObjCLayout(const ObjCContainerDecl *CD) { 10135 ObjCLayouts[CD] = nullptr; 10136 } 10137 10138 /// mergeObjCGCQualifiers - This routine merges ObjC's GC attribute of 'LHS' and 10139 /// 'RHS' attributes and returns the merged version; including for function 10140 /// return types. 10141 QualType ASTContext::mergeObjCGCQualifiers(QualType LHS, QualType RHS) { 10142 QualType LHSCan = getCanonicalType(LHS), 10143 RHSCan = getCanonicalType(RHS); 10144 // If two types are identical, they are compatible. 10145 if (LHSCan == RHSCan) 10146 return LHS; 10147 if (RHSCan->isFunctionType()) { 10148 if (!LHSCan->isFunctionType()) 10149 return {}; 10150 QualType OldReturnType = 10151 cast<FunctionType>(RHSCan.getTypePtr())->getReturnType(); 10152 QualType NewReturnType = 10153 cast<FunctionType>(LHSCan.getTypePtr())->getReturnType(); 10154 QualType ResReturnType = 10155 mergeObjCGCQualifiers(NewReturnType, OldReturnType); 10156 if (ResReturnType.isNull()) 10157 return {}; 10158 if (ResReturnType == NewReturnType || ResReturnType == OldReturnType) { 10159 // id foo(); ... __strong id foo(); or: __strong id foo(); ... id foo(); 10160 // In either case, use OldReturnType to build the new function type. 10161 const auto *F = LHS->castAs<FunctionType>(); 10162 if (const auto *FPT = cast<FunctionProtoType>(F)) { 10163 FunctionProtoType::ExtProtoInfo EPI = FPT->getExtProtoInfo(); 10164 EPI.ExtInfo = getFunctionExtInfo(LHS); 10165 QualType ResultType = 10166 getFunctionType(OldReturnType, FPT->getParamTypes(), EPI); 10167 return ResultType; 10168 } 10169 } 10170 return {}; 10171 } 10172 10173 // If the qualifiers are different, the types can still be merged. 10174 Qualifiers LQuals = LHSCan.getLocalQualifiers(); 10175 Qualifiers RQuals = RHSCan.getLocalQualifiers(); 10176 if (LQuals != RQuals) { 10177 // If any of these qualifiers are different, we have a type mismatch. 10178 if (LQuals.getCVRQualifiers() != RQuals.getCVRQualifiers() || 10179 LQuals.getAddressSpace() != RQuals.getAddressSpace()) 10180 return {}; 10181 10182 // Exactly one GC qualifier difference is allowed: __strong is 10183 // okay if the other type has no GC qualifier but is an Objective 10184 // C object pointer (i.e. implicitly strong by default). We fix 10185 // this by pretending that the unqualified type was actually 10186 // qualified __strong. 10187 Qualifiers::GC GC_L = LQuals.getObjCGCAttr(); 10188 Qualifiers::GC GC_R = RQuals.getObjCGCAttr(); 10189 assert((GC_L != GC_R) && "unequal qualifier sets had only equal elements"); 10190 10191 if (GC_L == Qualifiers::Weak || GC_R == Qualifiers::Weak) 10192 return {}; 10193 10194 if (GC_L == Qualifiers::Strong) 10195 return LHS; 10196 if (GC_R == Qualifiers::Strong) 10197 return RHS; 10198 return {}; 10199 } 10200 10201 if (LHSCan->isObjCObjectPointerType() && RHSCan->isObjCObjectPointerType()) { 10202 QualType LHSBaseQT = LHS->castAs<ObjCObjectPointerType>()->getPointeeType(); 10203 QualType RHSBaseQT = RHS->castAs<ObjCObjectPointerType>()->getPointeeType(); 10204 QualType ResQT = mergeObjCGCQualifiers(LHSBaseQT, RHSBaseQT); 10205 if (ResQT == LHSBaseQT) 10206 return LHS; 10207 if (ResQT == RHSBaseQT) 10208 return RHS; 10209 } 10210 return {}; 10211 } 10212 10213 //===----------------------------------------------------------------------===// 10214 // Integer Predicates 10215 //===----------------------------------------------------------------------===// 10216 10217 unsigned ASTContext::getIntWidth(QualType T) const { 10218 if (const auto *ET = T->getAs<EnumType>()) 10219 T = ET->getDecl()->getIntegerType(); 10220 if (T->isBooleanType()) 10221 return 1; 10222 if(const auto *EIT = T->getAs<ExtIntType>()) 10223 return EIT->getNumBits(); 10224 // For builtin types, just use the standard type sizing method 10225 return (unsigned)getTypeSize(T); 10226 } 10227 10228 QualType ASTContext::getCorrespondingUnsignedType(QualType T) const { 10229 assert((T->hasSignedIntegerRepresentation() || T->isSignedFixedPointType()) && 10230 "Unexpected type"); 10231 10232 // Turn <4 x signed int> -> <4 x unsigned int> 10233 if (const auto *VTy = T->getAs<VectorType>()) 10234 return getVectorType(getCorrespondingUnsignedType(VTy->getElementType()), 10235 VTy->getNumElements(), VTy->getVectorKind()); 10236 10237 // For _ExtInt, return an unsigned _ExtInt with same width. 10238 if (const auto *EITy = T->getAs<ExtIntType>()) 10239 return getExtIntType(/*IsUnsigned=*/true, EITy->getNumBits()); 10240 10241 // For enums, get the underlying integer type of the enum, and let the general 10242 // integer type signchanging code handle it. 10243 if (const auto *ETy = T->getAs<EnumType>()) 10244 T = ETy->getDecl()->getIntegerType(); 10245 10246 switch (T->castAs<BuiltinType>()->getKind()) { 10247 case BuiltinType::Char_S: 10248 case BuiltinType::SChar: 10249 return UnsignedCharTy; 10250 case BuiltinType::Short: 10251 return UnsignedShortTy; 10252 case BuiltinType::Int: 10253 return UnsignedIntTy; 10254 case BuiltinType::Long: 10255 return UnsignedLongTy; 10256 case BuiltinType::LongLong: 10257 return UnsignedLongLongTy; 10258 case BuiltinType::Int128: 10259 return UnsignedInt128Ty; 10260 // wchar_t is special. It is either signed or not, but when it's signed, 10261 // there's no matching "unsigned wchar_t". Therefore we return the unsigned 10262 // version of it's underlying type instead. 10263 case BuiltinType::WChar_S: 10264 return getUnsignedWCharType(); 10265 10266 case BuiltinType::ShortAccum: 10267 return UnsignedShortAccumTy; 10268 case BuiltinType::Accum: 10269 return UnsignedAccumTy; 10270 case BuiltinType::LongAccum: 10271 return UnsignedLongAccumTy; 10272 case BuiltinType::SatShortAccum: 10273 return SatUnsignedShortAccumTy; 10274 case BuiltinType::SatAccum: 10275 return SatUnsignedAccumTy; 10276 case BuiltinType::SatLongAccum: 10277 return SatUnsignedLongAccumTy; 10278 case BuiltinType::ShortFract: 10279 return UnsignedShortFractTy; 10280 case BuiltinType::Fract: 10281 return UnsignedFractTy; 10282 case BuiltinType::LongFract: 10283 return UnsignedLongFractTy; 10284 case BuiltinType::SatShortFract: 10285 return SatUnsignedShortFractTy; 10286 case BuiltinType::SatFract: 10287 return SatUnsignedFractTy; 10288 case BuiltinType::SatLongFract: 10289 return SatUnsignedLongFractTy; 10290 default: 10291 llvm_unreachable("Unexpected signed integer or fixed point type"); 10292 } 10293 } 10294 10295 QualType ASTContext::getCorrespondingSignedType(QualType T) const { 10296 assert((T->hasUnsignedIntegerRepresentation() || 10297 T->isUnsignedFixedPointType()) && 10298 "Unexpected type"); 10299 10300 // Turn <4 x unsigned int> -> <4 x signed int> 10301 if (const auto *VTy = T->getAs<VectorType>()) 10302 return getVectorType(getCorrespondingSignedType(VTy->getElementType()), 10303 VTy->getNumElements(), VTy->getVectorKind()); 10304 10305 // For _ExtInt, return a signed _ExtInt with same width. 10306 if (const auto *EITy = T->getAs<ExtIntType>()) 10307 return getExtIntType(/*IsUnsigned=*/false, EITy->getNumBits()); 10308 10309 // For enums, get the underlying integer type of the enum, and let the general 10310 // integer type signchanging code handle it. 10311 if (const auto *ETy = T->getAs<EnumType>()) 10312 T = ETy->getDecl()->getIntegerType(); 10313 10314 switch (T->castAs<BuiltinType>()->getKind()) { 10315 case BuiltinType::Char_U: 10316 case BuiltinType::UChar: 10317 return SignedCharTy; 10318 case BuiltinType::UShort: 10319 return ShortTy; 10320 case BuiltinType::UInt: 10321 return IntTy; 10322 case BuiltinType::ULong: 10323 return LongTy; 10324 case BuiltinType::ULongLong: 10325 return LongLongTy; 10326 case BuiltinType::UInt128: 10327 return Int128Ty; 10328 // wchar_t is special. It is either unsigned or not, but when it's unsigned, 10329 // there's no matching "signed wchar_t". Therefore we return the signed 10330 // version of it's underlying type instead. 10331 case BuiltinType::WChar_U: 10332 return getSignedWCharType(); 10333 10334 case BuiltinType::UShortAccum: 10335 return ShortAccumTy; 10336 case BuiltinType::UAccum: 10337 return AccumTy; 10338 case BuiltinType::ULongAccum: 10339 return LongAccumTy; 10340 case BuiltinType::SatUShortAccum: 10341 return SatShortAccumTy; 10342 case BuiltinType::SatUAccum: 10343 return SatAccumTy; 10344 case BuiltinType::SatULongAccum: 10345 return SatLongAccumTy; 10346 case BuiltinType::UShortFract: 10347 return ShortFractTy; 10348 case BuiltinType::UFract: 10349 return FractTy; 10350 case BuiltinType::ULongFract: 10351 return LongFractTy; 10352 case BuiltinType::SatUShortFract: 10353 return SatShortFractTy; 10354 case BuiltinType::SatUFract: 10355 return SatFractTy; 10356 case BuiltinType::SatULongFract: 10357 return SatLongFractTy; 10358 default: 10359 llvm_unreachable("Unexpected unsigned integer or fixed point type"); 10360 } 10361 } 10362 10363 ASTMutationListener::~ASTMutationListener() = default; 10364 10365 void ASTMutationListener::DeducedReturnType(const FunctionDecl *FD, 10366 QualType ReturnType) {} 10367 10368 //===----------------------------------------------------------------------===// 10369 // Builtin Type Computation 10370 //===----------------------------------------------------------------------===// 10371 10372 /// DecodeTypeFromStr - This decodes one type descriptor from Str, advancing the 10373 /// pointer over the consumed characters. This returns the resultant type. If 10374 /// AllowTypeModifiers is false then modifier like * are not parsed, just basic 10375 /// types. This allows "v2i*" to be parsed as a pointer to a v2i instead of 10376 /// a vector of "i*". 10377 /// 10378 /// RequiresICE is filled in on return to indicate whether the value is required 10379 /// to be an Integer Constant Expression. 10380 static QualType DecodeTypeFromStr(const char *&Str, const ASTContext &Context, 10381 ASTContext::GetBuiltinTypeError &Error, 10382 bool &RequiresICE, 10383 bool AllowTypeModifiers) { 10384 // Modifiers. 10385 int HowLong = 0; 10386 bool Signed = false, Unsigned = false; 10387 RequiresICE = false; 10388 10389 // Read the prefixed modifiers first. 10390 bool Done = false; 10391 #ifndef NDEBUG 10392 bool IsSpecial = false; 10393 #endif 10394 while (!Done) { 10395 switch (*Str++) { 10396 default: Done = true; --Str; break; 10397 case 'I': 10398 RequiresICE = true; 10399 break; 10400 case 'S': 10401 assert(!Unsigned && "Can't use both 'S' and 'U' modifiers!"); 10402 assert(!Signed && "Can't use 'S' modifier multiple times!"); 10403 Signed = true; 10404 break; 10405 case 'U': 10406 assert(!Signed && "Can't use both 'S' and 'U' modifiers!"); 10407 assert(!Unsigned && "Can't use 'U' modifier multiple times!"); 10408 Unsigned = true; 10409 break; 10410 case 'L': 10411 assert(!IsSpecial && "Can't use 'L' with 'W', 'N', 'Z' or 'O' modifiers"); 10412 assert(HowLong <= 2 && "Can't have LLLL modifier"); 10413 ++HowLong; 10414 break; 10415 case 'N': 10416 // 'N' behaves like 'L' for all non LP64 targets and 'int' otherwise. 10417 assert(!IsSpecial && "Can't use two 'N', 'W', 'Z' or 'O' modifiers!"); 10418 assert(HowLong == 0 && "Can't use both 'L' and 'N' modifiers!"); 10419 #ifndef NDEBUG 10420 IsSpecial = true; 10421 #endif 10422 if (Context.getTargetInfo().getLongWidth() == 32) 10423 ++HowLong; 10424 break; 10425 case 'W': 10426 // This modifier represents int64 type. 10427 assert(!IsSpecial && "Can't use two 'N', 'W', 'Z' or 'O' modifiers!"); 10428 assert(HowLong == 0 && "Can't use both 'L' and 'W' modifiers!"); 10429 #ifndef NDEBUG 10430 IsSpecial = true; 10431 #endif 10432 switch (Context.getTargetInfo().getInt64Type()) { 10433 default: 10434 llvm_unreachable("Unexpected integer type"); 10435 case TargetInfo::SignedLong: 10436 HowLong = 1; 10437 break; 10438 case TargetInfo::SignedLongLong: 10439 HowLong = 2; 10440 break; 10441 } 10442 break; 10443 case 'Z': 10444 // This modifier represents int32 type. 10445 assert(!IsSpecial && "Can't use two 'N', 'W', 'Z' or 'O' modifiers!"); 10446 assert(HowLong == 0 && "Can't use both 'L' and 'Z' modifiers!"); 10447 #ifndef NDEBUG 10448 IsSpecial = true; 10449 #endif 10450 switch (Context.getTargetInfo().getIntTypeByWidth(32, true)) { 10451 default: 10452 llvm_unreachable("Unexpected integer type"); 10453 case TargetInfo::SignedInt: 10454 HowLong = 0; 10455 break; 10456 case TargetInfo::SignedLong: 10457 HowLong = 1; 10458 break; 10459 case TargetInfo::SignedLongLong: 10460 HowLong = 2; 10461 break; 10462 } 10463 break; 10464 case 'O': 10465 assert(!IsSpecial && "Can't use two 'N', 'W', 'Z' or 'O' modifiers!"); 10466 assert(HowLong == 0 && "Can't use both 'L' and 'O' modifiers!"); 10467 #ifndef NDEBUG 10468 IsSpecial = true; 10469 #endif 10470 if (Context.getLangOpts().OpenCL) 10471 HowLong = 1; 10472 else 10473 HowLong = 2; 10474 break; 10475 } 10476 } 10477 10478 QualType Type; 10479 10480 // Read the base type. 10481 switch (*Str++) { 10482 default: llvm_unreachable("Unknown builtin type letter!"); 10483 case 'x': 10484 assert(HowLong == 0 && !Signed && !Unsigned && 10485 "Bad modifiers used with 'x'!"); 10486 Type = Context.Float16Ty; 10487 break; 10488 case 'y': 10489 assert(HowLong == 0 && !Signed && !Unsigned && 10490 "Bad modifiers used with 'y'!"); 10491 Type = Context.BFloat16Ty; 10492 break; 10493 case 'v': 10494 assert(HowLong == 0 && !Signed && !Unsigned && 10495 "Bad modifiers used with 'v'!"); 10496 Type = Context.VoidTy; 10497 break; 10498 case 'h': 10499 assert(HowLong == 0 && !Signed && !Unsigned && 10500 "Bad modifiers used with 'h'!"); 10501 Type = Context.HalfTy; 10502 break; 10503 case 'f': 10504 assert(HowLong == 0 && !Signed && !Unsigned && 10505 "Bad modifiers used with 'f'!"); 10506 Type = Context.FloatTy; 10507 break; 10508 case 'd': 10509 assert(HowLong < 3 && !Signed && !Unsigned && 10510 "Bad modifiers used with 'd'!"); 10511 if (HowLong == 1) 10512 Type = Context.LongDoubleTy; 10513 else if (HowLong == 2) 10514 Type = Context.Float128Ty; 10515 else 10516 Type = Context.DoubleTy; 10517 break; 10518 case 's': 10519 assert(HowLong == 0 && "Bad modifiers used with 's'!"); 10520 if (Unsigned) 10521 Type = Context.UnsignedShortTy; 10522 else 10523 Type = Context.ShortTy; 10524 break; 10525 case 'i': 10526 if (HowLong == 3) 10527 Type = Unsigned ? Context.UnsignedInt128Ty : Context.Int128Ty; 10528 else if (HowLong == 2) 10529 Type = Unsigned ? Context.UnsignedLongLongTy : Context.LongLongTy; 10530 else if (HowLong == 1) 10531 Type = Unsigned ? Context.UnsignedLongTy : Context.LongTy; 10532 else 10533 Type = Unsigned ? Context.UnsignedIntTy : Context.IntTy; 10534 break; 10535 case 'c': 10536 assert(HowLong == 0 && "Bad modifiers used with 'c'!"); 10537 if (Signed) 10538 Type = Context.SignedCharTy; 10539 else if (Unsigned) 10540 Type = Context.UnsignedCharTy; 10541 else 10542 Type = Context.CharTy; 10543 break; 10544 case 'b': // boolean 10545 assert(HowLong == 0 && !Signed && !Unsigned && "Bad modifiers for 'b'!"); 10546 Type = Context.BoolTy; 10547 break; 10548 case 'z': // size_t. 10549 assert(HowLong == 0 && !Signed && !Unsigned && "Bad modifiers for 'z'!"); 10550 Type = Context.getSizeType(); 10551 break; 10552 case 'w': // wchar_t. 10553 assert(HowLong == 0 && !Signed && !Unsigned && "Bad modifiers for 'w'!"); 10554 Type = Context.getWideCharType(); 10555 break; 10556 case 'F': 10557 Type = Context.getCFConstantStringType(); 10558 break; 10559 case 'G': 10560 Type = Context.getObjCIdType(); 10561 break; 10562 case 'H': 10563 Type = Context.getObjCSelType(); 10564 break; 10565 case 'M': 10566 Type = Context.getObjCSuperType(); 10567 break; 10568 case 'a': 10569 Type = Context.getBuiltinVaListType(); 10570 assert(!Type.isNull() && "builtin va list type not initialized!"); 10571 break; 10572 case 'A': 10573 // This is a "reference" to a va_list; however, what exactly 10574 // this means depends on how va_list is defined. There are two 10575 // different kinds of va_list: ones passed by value, and ones 10576 // passed by reference. An example of a by-value va_list is 10577 // x86, where va_list is a char*. An example of by-ref va_list 10578 // is x86-64, where va_list is a __va_list_tag[1]. For x86, 10579 // we want this argument to be a char*&; for x86-64, we want 10580 // it to be a __va_list_tag*. 10581 Type = Context.getBuiltinVaListType(); 10582 assert(!Type.isNull() && "builtin va list type not initialized!"); 10583 if (Type->isArrayType()) 10584 Type = Context.getArrayDecayedType(Type); 10585 else 10586 Type = Context.getLValueReferenceType(Type); 10587 break; 10588 case 'q': { 10589 char *End; 10590 unsigned NumElements = strtoul(Str, &End, 10); 10591 assert(End != Str && "Missing vector size"); 10592 Str = End; 10593 10594 QualType ElementType = DecodeTypeFromStr(Str, Context, Error, 10595 RequiresICE, false); 10596 assert(!RequiresICE && "Can't require vector ICE"); 10597 10598 Type = Context.getScalableVectorType(ElementType, NumElements); 10599 break; 10600 } 10601 case 'V': { 10602 char *End; 10603 unsigned NumElements = strtoul(Str, &End, 10); 10604 assert(End != Str && "Missing vector size"); 10605 Str = End; 10606 10607 QualType ElementType = DecodeTypeFromStr(Str, Context, Error, 10608 RequiresICE, false); 10609 assert(!RequiresICE && "Can't require vector ICE"); 10610 10611 // TODO: No way to make AltiVec vectors in builtins yet. 10612 Type = Context.getVectorType(ElementType, NumElements, 10613 VectorType::GenericVector); 10614 break; 10615 } 10616 case 'E': { 10617 char *End; 10618 10619 unsigned NumElements = strtoul(Str, &End, 10); 10620 assert(End != Str && "Missing vector size"); 10621 10622 Str = End; 10623 10624 QualType ElementType = DecodeTypeFromStr(Str, Context, Error, RequiresICE, 10625 false); 10626 Type = Context.getExtVectorType(ElementType, NumElements); 10627 break; 10628 } 10629 case 'X': { 10630 QualType ElementType = DecodeTypeFromStr(Str, Context, Error, RequiresICE, 10631 false); 10632 assert(!RequiresICE && "Can't require complex ICE"); 10633 Type = Context.getComplexType(ElementType); 10634 break; 10635 } 10636 case 'Y': 10637 Type = Context.getPointerDiffType(); 10638 break; 10639 case 'P': 10640 Type = Context.getFILEType(); 10641 if (Type.isNull()) { 10642 Error = ASTContext::GE_Missing_stdio; 10643 return {}; 10644 } 10645 break; 10646 case 'J': 10647 if (Signed) 10648 Type = Context.getsigjmp_bufType(); 10649 else 10650 Type = Context.getjmp_bufType(); 10651 10652 if (Type.isNull()) { 10653 Error = ASTContext::GE_Missing_setjmp; 10654 return {}; 10655 } 10656 break; 10657 case 'K': 10658 assert(HowLong == 0 && !Signed && !Unsigned && "Bad modifiers for 'K'!"); 10659 Type = Context.getucontext_tType(); 10660 10661 if (Type.isNull()) { 10662 Error = ASTContext::GE_Missing_ucontext; 10663 return {}; 10664 } 10665 break; 10666 case 'p': 10667 Type = Context.getProcessIDType(); 10668 break; 10669 } 10670 10671 // If there are modifiers and if we're allowed to parse them, go for it. 10672 Done = !AllowTypeModifiers; 10673 while (!Done) { 10674 switch (char c = *Str++) { 10675 default: Done = true; --Str; break; 10676 case '*': 10677 case '&': { 10678 // Both pointers and references can have their pointee types 10679 // qualified with an address space. 10680 char *End; 10681 unsigned AddrSpace = strtoul(Str, &End, 10); 10682 if (End != Str) { 10683 // Note AddrSpace == 0 is not the same as an unspecified address space. 10684 Type = Context.getAddrSpaceQualType( 10685 Type, 10686 Context.getLangASForBuiltinAddressSpace(AddrSpace)); 10687 Str = End; 10688 } 10689 if (c == '*') 10690 Type = Context.getPointerType(Type); 10691 else 10692 Type = Context.getLValueReferenceType(Type); 10693 break; 10694 } 10695 // FIXME: There's no way to have a built-in with an rvalue ref arg. 10696 case 'C': 10697 Type = Type.withConst(); 10698 break; 10699 case 'D': 10700 Type = Context.getVolatileType(Type); 10701 break; 10702 case 'R': 10703 Type = Type.withRestrict(); 10704 break; 10705 } 10706 } 10707 10708 assert((!RequiresICE || Type->isIntegralOrEnumerationType()) && 10709 "Integer constant 'I' type must be an integer"); 10710 10711 return Type; 10712 } 10713 10714 // On some targets such as PowerPC, some of the builtins are defined with custom 10715 // type descriptors for target-dependent types. These descriptors are decoded in 10716 // other functions, but it may be useful to be able to fall back to default 10717 // descriptor decoding to define builtins mixing target-dependent and target- 10718 // independent types. This function allows decoding one type descriptor with 10719 // default decoding. 10720 QualType ASTContext::DecodeTypeStr(const char *&Str, const ASTContext &Context, 10721 GetBuiltinTypeError &Error, bool &RequireICE, 10722 bool AllowTypeModifiers) const { 10723 return DecodeTypeFromStr(Str, Context, Error, RequireICE, AllowTypeModifiers); 10724 } 10725 10726 /// GetBuiltinType - Return the type for the specified builtin. 10727 QualType ASTContext::GetBuiltinType(unsigned Id, 10728 GetBuiltinTypeError &Error, 10729 unsigned *IntegerConstantArgs) const { 10730 const char *TypeStr = BuiltinInfo.getTypeString(Id); 10731 if (TypeStr[0] == '\0') { 10732 Error = GE_Missing_type; 10733 return {}; 10734 } 10735 10736 SmallVector<QualType, 8> ArgTypes; 10737 10738 bool RequiresICE = false; 10739 Error = GE_None; 10740 QualType ResType = DecodeTypeFromStr(TypeStr, *this, Error, 10741 RequiresICE, true); 10742 if (Error != GE_None) 10743 return {}; 10744 10745 assert(!RequiresICE && "Result of intrinsic cannot be required to be an ICE"); 10746 10747 while (TypeStr[0] && TypeStr[0] != '.') { 10748 QualType Ty = DecodeTypeFromStr(TypeStr, *this, Error, RequiresICE, true); 10749 if (Error != GE_None) 10750 return {}; 10751 10752 // If this argument is required to be an IntegerConstantExpression and the 10753 // caller cares, fill in the bitmask we return. 10754 if (RequiresICE && IntegerConstantArgs) 10755 *IntegerConstantArgs |= 1 << ArgTypes.size(); 10756 10757 // Do array -> pointer decay. The builtin should use the decayed type. 10758 if (Ty->isArrayType()) 10759 Ty = getArrayDecayedType(Ty); 10760 10761 ArgTypes.push_back(Ty); 10762 } 10763 10764 if (Id == Builtin::BI__GetExceptionInfo) 10765 return {}; 10766 10767 assert((TypeStr[0] != '.' || TypeStr[1] == 0) && 10768 "'.' should only occur at end of builtin type list!"); 10769 10770 bool Variadic = (TypeStr[0] == '.'); 10771 10772 FunctionType::ExtInfo EI(getDefaultCallingConvention( 10773 Variadic, /*IsCXXMethod=*/false, /*IsBuiltin=*/true)); 10774 if (BuiltinInfo.isNoReturn(Id)) EI = EI.withNoReturn(true); 10775 10776 10777 // We really shouldn't be making a no-proto type here. 10778 if (ArgTypes.empty() && Variadic && !getLangOpts().CPlusPlus) 10779 return getFunctionNoProtoType(ResType, EI); 10780 10781 FunctionProtoType::ExtProtoInfo EPI; 10782 EPI.ExtInfo = EI; 10783 EPI.Variadic = Variadic; 10784 if (getLangOpts().CPlusPlus && BuiltinInfo.isNoThrow(Id)) 10785 EPI.ExceptionSpec.Type = 10786 getLangOpts().CPlusPlus11 ? EST_BasicNoexcept : EST_DynamicNone; 10787 10788 return getFunctionType(ResType, ArgTypes, EPI); 10789 } 10790 10791 static GVALinkage basicGVALinkageForFunction(const ASTContext &Context, 10792 const FunctionDecl *FD) { 10793 if (!FD->isExternallyVisible()) 10794 return GVA_Internal; 10795 10796 // Non-user-provided functions get emitted as weak definitions with every 10797 // use, no matter whether they've been explicitly instantiated etc. 10798 if (const auto *MD = dyn_cast<CXXMethodDecl>(FD)) 10799 if (!MD->isUserProvided()) 10800 return GVA_DiscardableODR; 10801 10802 GVALinkage External; 10803 switch (FD->getTemplateSpecializationKind()) { 10804 case TSK_Undeclared: 10805 case TSK_ExplicitSpecialization: 10806 External = GVA_StrongExternal; 10807 break; 10808 10809 case TSK_ExplicitInstantiationDefinition: 10810 return GVA_StrongODR; 10811 10812 // C++11 [temp.explicit]p10: 10813 // [ Note: The intent is that an inline function that is the subject of 10814 // an explicit instantiation declaration will still be implicitly 10815 // instantiated when used so that the body can be considered for 10816 // inlining, but that no out-of-line copy of the inline function would be 10817 // generated in the translation unit. -- end note ] 10818 case TSK_ExplicitInstantiationDeclaration: 10819 return GVA_AvailableExternally; 10820 10821 case TSK_ImplicitInstantiation: 10822 External = GVA_DiscardableODR; 10823 break; 10824 } 10825 10826 if (!FD->isInlined()) 10827 return External; 10828 10829 if ((!Context.getLangOpts().CPlusPlus && 10830 !Context.getTargetInfo().getCXXABI().isMicrosoft() && 10831 !FD->hasAttr<DLLExportAttr>()) || 10832 FD->hasAttr<GNUInlineAttr>()) { 10833 // FIXME: This doesn't match gcc's behavior for dllexport inline functions. 10834 10835 // GNU or C99 inline semantics. Determine whether this symbol should be 10836 // externally visible. 10837 if (FD->isInlineDefinitionExternallyVisible()) 10838 return External; 10839 10840 // C99 inline semantics, where the symbol is not externally visible. 10841 return GVA_AvailableExternally; 10842 } 10843 10844 // Functions specified with extern and inline in -fms-compatibility mode 10845 // forcibly get emitted. While the body of the function cannot be later 10846 // replaced, the function definition cannot be discarded. 10847 if (FD->isMSExternInline()) 10848 return GVA_StrongODR; 10849 10850 return GVA_DiscardableODR; 10851 } 10852 10853 static GVALinkage adjustGVALinkageForAttributes(const ASTContext &Context, 10854 const Decl *D, GVALinkage L) { 10855 // See http://msdn.microsoft.com/en-us/library/xa0d9ste.aspx 10856 // dllexport/dllimport on inline functions. 10857 if (D->hasAttr<DLLImportAttr>()) { 10858 if (L == GVA_DiscardableODR || L == GVA_StrongODR) 10859 return GVA_AvailableExternally; 10860 } else if (D->hasAttr<DLLExportAttr>()) { 10861 if (L == GVA_DiscardableODR) 10862 return GVA_StrongODR; 10863 } else if (Context.getLangOpts().CUDA && Context.getLangOpts().CUDAIsDevice) { 10864 // Device-side functions with __global__ attribute must always be 10865 // visible externally so they can be launched from host. 10866 if (D->hasAttr<CUDAGlobalAttr>() && 10867 (L == GVA_DiscardableODR || L == GVA_Internal)) 10868 return GVA_StrongODR; 10869 // Single source offloading languages like CUDA/HIP need to be able to 10870 // access static device variables from host code of the same compilation 10871 // unit. This is done by externalizing the static variable with a shared 10872 // name between the host and device compilation which is the same for the 10873 // same compilation unit whereas different among different compilation 10874 // units. 10875 if (Context.shouldExternalizeStaticVar(D)) 10876 return GVA_StrongExternal; 10877 } 10878 return L; 10879 } 10880 10881 /// Adjust the GVALinkage for a declaration based on what an external AST source 10882 /// knows about whether there can be other definitions of this declaration. 10883 static GVALinkage 10884 adjustGVALinkageForExternalDefinitionKind(const ASTContext &Ctx, const Decl *D, 10885 GVALinkage L) { 10886 ExternalASTSource *Source = Ctx.getExternalSource(); 10887 if (!Source) 10888 return L; 10889 10890 switch (Source->hasExternalDefinitions(D)) { 10891 case ExternalASTSource::EK_Never: 10892 // Other translation units rely on us to provide the definition. 10893 if (L == GVA_DiscardableODR) 10894 return GVA_StrongODR; 10895 break; 10896 10897 case ExternalASTSource::EK_Always: 10898 return GVA_AvailableExternally; 10899 10900 case ExternalASTSource::EK_ReplyHazy: 10901 break; 10902 } 10903 return L; 10904 } 10905 10906 GVALinkage ASTContext::GetGVALinkageForFunction(const FunctionDecl *FD) const { 10907 return adjustGVALinkageForExternalDefinitionKind(*this, FD, 10908 adjustGVALinkageForAttributes(*this, FD, 10909 basicGVALinkageForFunction(*this, FD))); 10910 } 10911 10912 static GVALinkage basicGVALinkageForVariable(const ASTContext &Context, 10913 const VarDecl *VD) { 10914 if (!VD->isExternallyVisible()) 10915 return GVA_Internal; 10916 10917 if (VD->isStaticLocal()) { 10918 const DeclContext *LexicalContext = VD->getParentFunctionOrMethod(); 10919 while (LexicalContext && !isa<FunctionDecl>(LexicalContext)) 10920 LexicalContext = LexicalContext->getLexicalParent(); 10921 10922 // ObjC Blocks can create local variables that don't have a FunctionDecl 10923 // LexicalContext. 10924 if (!LexicalContext) 10925 return GVA_DiscardableODR; 10926 10927 // Otherwise, let the static local variable inherit its linkage from the 10928 // nearest enclosing function. 10929 auto StaticLocalLinkage = 10930 Context.GetGVALinkageForFunction(cast<FunctionDecl>(LexicalContext)); 10931 10932 // Itanium ABI 5.2.2: "Each COMDAT group [for a static local variable] must 10933 // be emitted in any object with references to the symbol for the object it 10934 // contains, whether inline or out-of-line." 10935 // Similar behavior is observed with MSVC. An alternative ABI could use 10936 // StrongODR/AvailableExternally to match the function, but none are 10937 // known/supported currently. 10938 if (StaticLocalLinkage == GVA_StrongODR || 10939 StaticLocalLinkage == GVA_AvailableExternally) 10940 return GVA_DiscardableODR; 10941 return StaticLocalLinkage; 10942 } 10943 10944 // MSVC treats in-class initialized static data members as definitions. 10945 // By giving them non-strong linkage, out-of-line definitions won't 10946 // cause link errors. 10947 if (Context.isMSStaticDataMemberInlineDefinition(VD)) 10948 return GVA_DiscardableODR; 10949 10950 // Most non-template variables have strong linkage; inline variables are 10951 // linkonce_odr or (occasionally, for compatibility) weak_odr. 10952 GVALinkage StrongLinkage; 10953 switch (Context.getInlineVariableDefinitionKind(VD)) { 10954 case ASTContext::InlineVariableDefinitionKind::None: 10955 StrongLinkage = GVA_StrongExternal; 10956 break; 10957 case ASTContext::InlineVariableDefinitionKind::Weak: 10958 case ASTContext::InlineVariableDefinitionKind::WeakUnknown: 10959 StrongLinkage = GVA_DiscardableODR; 10960 break; 10961 case ASTContext::InlineVariableDefinitionKind::Strong: 10962 StrongLinkage = GVA_StrongODR; 10963 break; 10964 } 10965 10966 switch (VD->getTemplateSpecializationKind()) { 10967 case TSK_Undeclared: 10968 return StrongLinkage; 10969 10970 case TSK_ExplicitSpecialization: 10971 return Context.getTargetInfo().getCXXABI().isMicrosoft() && 10972 VD->isStaticDataMember() 10973 ? GVA_StrongODR 10974 : StrongLinkage; 10975 10976 case TSK_ExplicitInstantiationDefinition: 10977 return GVA_StrongODR; 10978 10979 case TSK_ExplicitInstantiationDeclaration: 10980 return GVA_AvailableExternally; 10981 10982 case TSK_ImplicitInstantiation: 10983 return GVA_DiscardableODR; 10984 } 10985 10986 llvm_unreachable("Invalid Linkage!"); 10987 } 10988 10989 GVALinkage ASTContext::GetGVALinkageForVariable(const VarDecl *VD) { 10990 return adjustGVALinkageForExternalDefinitionKind(*this, VD, 10991 adjustGVALinkageForAttributes(*this, VD, 10992 basicGVALinkageForVariable(*this, VD))); 10993 } 10994 10995 bool ASTContext::DeclMustBeEmitted(const Decl *D) { 10996 if (const auto *VD = dyn_cast<VarDecl>(D)) { 10997 if (!VD->isFileVarDecl()) 10998 return false; 10999 // Global named register variables (GNU extension) are never emitted. 11000 if (VD->getStorageClass() == SC_Register) 11001 return false; 11002 if (VD->getDescribedVarTemplate() || 11003 isa<VarTemplatePartialSpecializationDecl>(VD)) 11004 return false; 11005 } else if (const auto *FD = dyn_cast<FunctionDecl>(D)) { 11006 // We never need to emit an uninstantiated function template. 11007 if (FD->getTemplatedKind() == FunctionDecl::TK_FunctionTemplate) 11008 return false; 11009 } else if (isa<PragmaCommentDecl>(D)) 11010 return true; 11011 else if (isa<PragmaDetectMismatchDecl>(D)) 11012 return true; 11013 else if (isa<OMPRequiresDecl>(D)) 11014 return true; 11015 else if (isa<OMPThreadPrivateDecl>(D)) 11016 return !D->getDeclContext()->isDependentContext(); 11017 else if (isa<OMPAllocateDecl>(D)) 11018 return !D->getDeclContext()->isDependentContext(); 11019 else if (isa<OMPDeclareReductionDecl>(D) || isa<OMPDeclareMapperDecl>(D)) 11020 return !D->getDeclContext()->isDependentContext(); 11021 else if (isa<ImportDecl>(D)) 11022 return true; 11023 else 11024 return false; 11025 11026 // If this is a member of a class template, we do not need to emit it. 11027 if (D->getDeclContext()->isDependentContext()) 11028 return false; 11029 11030 // Weak references don't produce any output by themselves. 11031 if (D->hasAttr<WeakRefAttr>()) 11032 return false; 11033 11034 // Aliases and used decls are required. 11035 if (D->hasAttr<AliasAttr>() || D->hasAttr<UsedAttr>()) 11036 return true; 11037 11038 if (const auto *FD = dyn_cast<FunctionDecl>(D)) { 11039 // Forward declarations aren't required. 11040 if (!FD->doesThisDeclarationHaveABody()) 11041 return FD->doesDeclarationForceExternallyVisibleDefinition(); 11042 11043 // Constructors and destructors are required. 11044 if (FD->hasAttr<ConstructorAttr>() || FD->hasAttr<DestructorAttr>()) 11045 return true; 11046 11047 // The key function for a class is required. This rule only comes 11048 // into play when inline functions can be key functions, though. 11049 if (getTargetInfo().getCXXABI().canKeyFunctionBeInline()) { 11050 if (const auto *MD = dyn_cast<CXXMethodDecl>(FD)) { 11051 const CXXRecordDecl *RD = MD->getParent(); 11052 if (MD->isOutOfLine() && RD->isDynamicClass()) { 11053 const CXXMethodDecl *KeyFunc = getCurrentKeyFunction(RD); 11054 if (KeyFunc && KeyFunc->getCanonicalDecl() == MD->getCanonicalDecl()) 11055 return true; 11056 } 11057 } 11058 } 11059 11060 GVALinkage Linkage = GetGVALinkageForFunction(FD); 11061 11062 // static, static inline, always_inline, and extern inline functions can 11063 // always be deferred. Normal inline functions can be deferred in C99/C++. 11064 // Implicit template instantiations can also be deferred in C++. 11065 return !isDiscardableGVALinkage(Linkage); 11066 } 11067 11068 const auto *VD = cast<VarDecl>(D); 11069 assert(VD->isFileVarDecl() && "Expected file scoped var"); 11070 11071 // If the decl is marked as `declare target to`, it should be emitted for the 11072 // host and for the device. 11073 if (LangOpts.OpenMP && 11074 OMPDeclareTargetDeclAttr::isDeclareTargetDeclaration(VD)) 11075 return true; 11076 11077 if (VD->isThisDeclarationADefinition() == VarDecl::DeclarationOnly && 11078 !isMSStaticDataMemberInlineDefinition(VD)) 11079 return false; 11080 11081 // Variables that can be needed in other TUs are required. 11082 auto Linkage = GetGVALinkageForVariable(VD); 11083 if (!isDiscardableGVALinkage(Linkage)) 11084 return true; 11085 11086 // We never need to emit a variable that is available in another TU. 11087 if (Linkage == GVA_AvailableExternally) 11088 return false; 11089 11090 // Variables that have destruction with side-effects are required. 11091 if (VD->needsDestruction(*this)) 11092 return true; 11093 11094 // Variables that have initialization with side-effects are required. 11095 if (VD->getInit() && VD->getInit()->HasSideEffects(*this) && 11096 // We can get a value-dependent initializer during error recovery. 11097 (VD->getInit()->isValueDependent() || !VD->evaluateValue())) 11098 return true; 11099 11100 // Likewise, variables with tuple-like bindings are required if their 11101 // bindings have side-effects. 11102 if (const auto *DD = dyn_cast<DecompositionDecl>(VD)) 11103 for (const auto *BD : DD->bindings()) 11104 if (const auto *BindingVD = BD->getHoldingVar()) 11105 if (DeclMustBeEmitted(BindingVD)) 11106 return true; 11107 11108 return false; 11109 } 11110 11111 void ASTContext::forEachMultiversionedFunctionVersion( 11112 const FunctionDecl *FD, 11113 llvm::function_ref<void(FunctionDecl *)> Pred) const { 11114 assert(FD->isMultiVersion() && "Only valid for multiversioned functions"); 11115 llvm::SmallDenseSet<const FunctionDecl*, 4> SeenDecls; 11116 FD = FD->getMostRecentDecl(); 11117 // FIXME: The order of traversal here matters and depends on the order of 11118 // lookup results, which happens to be (mostly) oldest-to-newest, but we 11119 // shouldn't rely on that. 11120 for (auto *CurDecl : 11121 FD->getDeclContext()->getRedeclContext()->lookup(FD->getDeclName())) { 11122 FunctionDecl *CurFD = CurDecl->getAsFunction()->getMostRecentDecl(); 11123 if (CurFD && hasSameType(CurFD->getType(), FD->getType()) && 11124 std::end(SeenDecls) == llvm::find(SeenDecls, CurFD)) { 11125 SeenDecls.insert(CurFD); 11126 Pred(CurFD); 11127 } 11128 } 11129 } 11130 11131 CallingConv ASTContext::getDefaultCallingConvention(bool IsVariadic, 11132 bool IsCXXMethod, 11133 bool IsBuiltin) const { 11134 // Pass through to the C++ ABI object 11135 if (IsCXXMethod) 11136 return ABI->getDefaultMethodCallConv(IsVariadic); 11137 11138 // Builtins ignore user-specified default calling convention and remain the 11139 // Target's default calling convention. 11140 if (!IsBuiltin) { 11141 switch (LangOpts.getDefaultCallingConv()) { 11142 case LangOptions::DCC_None: 11143 break; 11144 case LangOptions::DCC_CDecl: 11145 return CC_C; 11146 case LangOptions::DCC_FastCall: 11147 if (getTargetInfo().hasFeature("sse2") && !IsVariadic) 11148 return CC_X86FastCall; 11149 break; 11150 case LangOptions::DCC_StdCall: 11151 if (!IsVariadic) 11152 return CC_X86StdCall; 11153 break; 11154 case LangOptions::DCC_VectorCall: 11155 // __vectorcall cannot be applied to variadic functions. 11156 if (!IsVariadic) 11157 return CC_X86VectorCall; 11158 break; 11159 case LangOptions::DCC_RegCall: 11160 // __regcall cannot be applied to variadic functions. 11161 if (!IsVariadic) 11162 return CC_X86RegCall; 11163 break; 11164 } 11165 } 11166 return Target->getDefaultCallingConv(); 11167 } 11168 11169 bool ASTContext::isNearlyEmpty(const CXXRecordDecl *RD) const { 11170 // Pass through to the C++ ABI object 11171 return ABI->isNearlyEmpty(RD); 11172 } 11173 11174 VTableContextBase *ASTContext::getVTableContext() { 11175 if (!VTContext.get()) { 11176 auto ABI = Target->getCXXABI(); 11177 if (ABI.isMicrosoft()) 11178 VTContext.reset(new MicrosoftVTableContext(*this)); 11179 else { 11180 auto ComponentLayout = getLangOpts().RelativeCXXABIVTables 11181 ? ItaniumVTableContext::Relative 11182 : ItaniumVTableContext::Pointer; 11183 VTContext.reset(new ItaniumVTableContext(*this, ComponentLayout)); 11184 } 11185 } 11186 return VTContext.get(); 11187 } 11188 11189 MangleContext *ASTContext::createMangleContext(const TargetInfo *T) { 11190 if (!T) 11191 T = Target; 11192 switch (T->getCXXABI().getKind()) { 11193 case TargetCXXABI::AppleARM64: 11194 case TargetCXXABI::Fuchsia: 11195 case TargetCXXABI::GenericAArch64: 11196 case TargetCXXABI::GenericItanium: 11197 case TargetCXXABI::GenericARM: 11198 case TargetCXXABI::GenericMIPS: 11199 case TargetCXXABI::iOS: 11200 case TargetCXXABI::WebAssembly: 11201 case TargetCXXABI::WatchOS: 11202 case TargetCXXABI::XL: 11203 return ItaniumMangleContext::create(*this, getDiagnostics()); 11204 case TargetCXXABI::Microsoft: 11205 return MicrosoftMangleContext::create(*this, getDiagnostics()); 11206 } 11207 llvm_unreachable("Unsupported ABI"); 11208 } 11209 11210 MangleContext *ASTContext::createDeviceMangleContext(const TargetInfo &T) { 11211 assert(T.getCXXABI().getKind() != TargetCXXABI::Microsoft && 11212 "Device mangle context does not support Microsoft mangling."); 11213 switch (T.getCXXABI().getKind()) { 11214 case TargetCXXABI::AppleARM64: 11215 case TargetCXXABI::Fuchsia: 11216 case TargetCXXABI::GenericAArch64: 11217 case TargetCXXABI::GenericItanium: 11218 case TargetCXXABI::GenericARM: 11219 case TargetCXXABI::GenericMIPS: 11220 case TargetCXXABI::iOS: 11221 case TargetCXXABI::WebAssembly: 11222 case TargetCXXABI::WatchOS: 11223 case TargetCXXABI::XL: 11224 return ItaniumMangleContext::create( 11225 *this, getDiagnostics(), 11226 [](ASTContext &, const NamedDecl *ND) -> llvm::Optional<unsigned> { 11227 if (const auto *RD = dyn_cast<CXXRecordDecl>(ND)) 11228 return RD->getDeviceLambdaManglingNumber(); 11229 return llvm::None; 11230 }); 11231 case TargetCXXABI::Microsoft: 11232 return MicrosoftMangleContext::create(*this, getDiagnostics()); 11233 } 11234 llvm_unreachable("Unsupported ABI"); 11235 } 11236 11237 CXXABI::~CXXABI() = default; 11238 11239 size_t ASTContext::getSideTableAllocatedMemory() const { 11240 return ASTRecordLayouts.getMemorySize() + 11241 llvm::capacity_in_bytes(ObjCLayouts) + 11242 llvm::capacity_in_bytes(KeyFunctions) + 11243 llvm::capacity_in_bytes(ObjCImpls) + 11244 llvm::capacity_in_bytes(BlockVarCopyInits) + 11245 llvm::capacity_in_bytes(DeclAttrs) + 11246 llvm::capacity_in_bytes(TemplateOrInstantiation) + 11247 llvm::capacity_in_bytes(InstantiatedFromUsingDecl) + 11248 llvm::capacity_in_bytes(InstantiatedFromUsingShadowDecl) + 11249 llvm::capacity_in_bytes(InstantiatedFromUnnamedFieldDecl) + 11250 llvm::capacity_in_bytes(OverriddenMethods) + 11251 llvm::capacity_in_bytes(Types) + 11252 llvm::capacity_in_bytes(VariableArrayTypes); 11253 } 11254 11255 /// getIntTypeForBitwidth - 11256 /// sets integer QualTy according to specified details: 11257 /// bitwidth, signed/unsigned. 11258 /// Returns empty type if there is no appropriate target types. 11259 QualType ASTContext::getIntTypeForBitwidth(unsigned DestWidth, 11260 unsigned Signed) const { 11261 TargetInfo::IntType Ty = getTargetInfo().getIntTypeByWidth(DestWidth, Signed); 11262 CanQualType QualTy = getFromTargetType(Ty); 11263 if (!QualTy && DestWidth == 128) 11264 return Signed ? Int128Ty : UnsignedInt128Ty; 11265 return QualTy; 11266 } 11267 11268 /// getRealTypeForBitwidth - 11269 /// sets floating point QualTy according to specified bitwidth. 11270 /// Returns empty type if there is no appropriate target types. 11271 QualType ASTContext::getRealTypeForBitwidth(unsigned DestWidth, 11272 FloatModeKind ExplicitType) const { 11273 FloatModeKind Ty = 11274 getTargetInfo().getRealTypeByWidth(DestWidth, ExplicitType); 11275 switch (Ty) { 11276 case FloatModeKind::Float: 11277 return FloatTy; 11278 case FloatModeKind::Double: 11279 return DoubleTy; 11280 case FloatModeKind::LongDouble: 11281 return LongDoubleTy; 11282 case FloatModeKind::Float128: 11283 return Float128Ty; 11284 case FloatModeKind::Ibm128: 11285 return Ibm128Ty; 11286 case FloatModeKind::NoFloat: 11287 return {}; 11288 } 11289 11290 llvm_unreachable("Unhandled TargetInfo::RealType value"); 11291 } 11292 11293 void ASTContext::setManglingNumber(const NamedDecl *ND, unsigned Number) { 11294 if (Number > 1) 11295 MangleNumbers[ND] = Number; 11296 } 11297 11298 unsigned ASTContext::getManglingNumber(const NamedDecl *ND) const { 11299 auto I = MangleNumbers.find(ND); 11300 return I != MangleNumbers.end() ? I->second : 1; 11301 } 11302 11303 void ASTContext::setStaticLocalNumber(const VarDecl *VD, unsigned Number) { 11304 if (Number > 1) 11305 StaticLocalNumbers[VD] = Number; 11306 } 11307 11308 unsigned ASTContext::getStaticLocalNumber(const VarDecl *VD) const { 11309 auto I = StaticLocalNumbers.find(VD); 11310 return I != StaticLocalNumbers.end() ? I->second : 1; 11311 } 11312 11313 MangleNumberingContext & 11314 ASTContext::getManglingNumberContext(const DeclContext *DC) { 11315 assert(LangOpts.CPlusPlus); // We don't need mangling numbers for plain C. 11316 std::unique_ptr<MangleNumberingContext> &MCtx = MangleNumberingContexts[DC]; 11317 if (!MCtx) 11318 MCtx = createMangleNumberingContext(); 11319 return *MCtx; 11320 } 11321 11322 MangleNumberingContext & 11323 ASTContext::getManglingNumberContext(NeedExtraManglingDecl_t, const Decl *D) { 11324 assert(LangOpts.CPlusPlus); // We don't need mangling numbers for plain C. 11325 std::unique_ptr<MangleNumberingContext> &MCtx = 11326 ExtraMangleNumberingContexts[D]; 11327 if (!MCtx) 11328 MCtx = createMangleNumberingContext(); 11329 return *MCtx; 11330 } 11331 11332 std::unique_ptr<MangleNumberingContext> 11333 ASTContext::createMangleNumberingContext() const { 11334 return ABI->createMangleNumberingContext(); 11335 } 11336 11337 const CXXConstructorDecl * 11338 ASTContext::getCopyConstructorForExceptionObject(CXXRecordDecl *RD) { 11339 return ABI->getCopyConstructorForExceptionObject( 11340 cast<CXXRecordDecl>(RD->getFirstDecl())); 11341 } 11342 11343 void ASTContext::addCopyConstructorForExceptionObject(CXXRecordDecl *RD, 11344 CXXConstructorDecl *CD) { 11345 return ABI->addCopyConstructorForExceptionObject( 11346 cast<CXXRecordDecl>(RD->getFirstDecl()), 11347 cast<CXXConstructorDecl>(CD->getFirstDecl())); 11348 } 11349 11350 void ASTContext::addTypedefNameForUnnamedTagDecl(TagDecl *TD, 11351 TypedefNameDecl *DD) { 11352 return ABI->addTypedefNameForUnnamedTagDecl(TD, DD); 11353 } 11354 11355 TypedefNameDecl * 11356 ASTContext::getTypedefNameForUnnamedTagDecl(const TagDecl *TD) { 11357 return ABI->getTypedefNameForUnnamedTagDecl(TD); 11358 } 11359 11360 void ASTContext::addDeclaratorForUnnamedTagDecl(TagDecl *TD, 11361 DeclaratorDecl *DD) { 11362 return ABI->addDeclaratorForUnnamedTagDecl(TD, DD); 11363 } 11364 11365 DeclaratorDecl *ASTContext::getDeclaratorForUnnamedTagDecl(const TagDecl *TD) { 11366 return ABI->getDeclaratorForUnnamedTagDecl(TD); 11367 } 11368 11369 void ASTContext::setParameterIndex(const ParmVarDecl *D, unsigned int index) { 11370 ParamIndices[D] = index; 11371 } 11372 11373 unsigned ASTContext::getParameterIndex(const ParmVarDecl *D) const { 11374 ParameterIndexTable::const_iterator I = ParamIndices.find(D); 11375 assert(I != ParamIndices.end() && 11376 "ParmIndices lacks entry set by ParmVarDecl"); 11377 return I->second; 11378 } 11379 11380 QualType ASTContext::getStringLiteralArrayType(QualType EltTy, 11381 unsigned Length) const { 11382 // A C++ string literal has a const-qualified element type (C++ 2.13.4p1). 11383 if (getLangOpts().CPlusPlus || getLangOpts().ConstStrings) 11384 EltTy = EltTy.withConst(); 11385 11386 EltTy = adjustStringLiteralBaseType(EltTy); 11387 11388 // Get an array type for the string, according to C99 6.4.5. This includes 11389 // the null terminator character. 11390 return getConstantArrayType(EltTy, llvm::APInt(32, Length + 1), nullptr, 11391 ArrayType::Normal, /*IndexTypeQuals*/ 0); 11392 } 11393 11394 StringLiteral * 11395 ASTContext::getPredefinedStringLiteralFromCache(StringRef Key) const { 11396 StringLiteral *&Result = StringLiteralCache[Key]; 11397 if (!Result) 11398 Result = StringLiteral::Create( 11399 *this, Key, StringLiteral::Ascii, 11400 /*Pascal*/ false, getStringLiteralArrayType(CharTy, Key.size()), 11401 SourceLocation()); 11402 return Result; 11403 } 11404 11405 MSGuidDecl * 11406 ASTContext::getMSGuidDecl(MSGuidDecl::Parts Parts) const { 11407 assert(MSGuidTagDecl && "building MS GUID without MS extensions?"); 11408 11409 llvm::FoldingSetNodeID ID; 11410 MSGuidDecl::Profile(ID, Parts); 11411 11412 void *InsertPos; 11413 if (MSGuidDecl *Existing = MSGuidDecls.FindNodeOrInsertPos(ID, InsertPos)) 11414 return Existing; 11415 11416 QualType GUIDType = getMSGuidType().withConst(); 11417 MSGuidDecl *New = MSGuidDecl::Create(*this, GUIDType, Parts); 11418 MSGuidDecls.InsertNode(New, InsertPos); 11419 return New; 11420 } 11421 11422 TemplateParamObjectDecl * 11423 ASTContext::getTemplateParamObjectDecl(QualType T, const APValue &V) const { 11424 assert(T->isRecordType() && "template param object of unexpected type"); 11425 11426 // C++ [temp.param]p8: 11427 // [...] a static storage duration object of type 'const T' [...] 11428 T.addConst(); 11429 11430 llvm::FoldingSetNodeID ID; 11431 TemplateParamObjectDecl::Profile(ID, T, V); 11432 11433 void *InsertPos; 11434 if (TemplateParamObjectDecl *Existing = 11435 TemplateParamObjectDecls.FindNodeOrInsertPos(ID, InsertPos)) 11436 return Existing; 11437 11438 TemplateParamObjectDecl *New = TemplateParamObjectDecl::Create(*this, T, V); 11439 TemplateParamObjectDecls.InsertNode(New, InsertPos); 11440 return New; 11441 } 11442 11443 bool ASTContext::AtomicUsesUnsupportedLibcall(const AtomicExpr *E) const { 11444 const llvm::Triple &T = getTargetInfo().getTriple(); 11445 if (!T.isOSDarwin()) 11446 return false; 11447 11448 if (!(T.isiOS() && T.isOSVersionLT(7)) && 11449 !(T.isMacOSX() && T.isOSVersionLT(10, 9))) 11450 return false; 11451 11452 QualType AtomicTy = E->getPtr()->getType()->getPointeeType(); 11453 CharUnits sizeChars = getTypeSizeInChars(AtomicTy); 11454 uint64_t Size = sizeChars.getQuantity(); 11455 CharUnits alignChars = getTypeAlignInChars(AtomicTy); 11456 unsigned Align = alignChars.getQuantity(); 11457 unsigned MaxInlineWidthInBits = getTargetInfo().getMaxAtomicInlineWidth(); 11458 return (Size != Align || toBits(sizeChars) > MaxInlineWidthInBits); 11459 } 11460 11461 bool 11462 ASTContext::ObjCMethodsAreEqual(const ObjCMethodDecl *MethodDecl, 11463 const ObjCMethodDecl *MethodImpl) { 11464 // No point trying to match an unavailable/deprecated mothod. 11465 if (MethodDecl->hasAttr<UnavailableAttr>() 11466 || MethodDecl->hasAttr<DeprecatedAttr>()) 11467 return false; 11468 if (MethodDecl->getObjCDeclQualifier() != 11469 MethodImpl->getObjCDeclQualifier()) 11470 return false; 11471 if (!hasSameType(MethodDecl->getReturnType(), MethodImpl->getReturnType())) 11472 return false; 11473 11474 if (MethodDecl->param_size() != MethodImpl->param_size()) 11475 return false; 11476 11477 for (ObjCMethodDecl::param_const_iterator IM = MethodImpl->param_begin(), 11478 IF = MethodDecl->param_begin(), EM = MethodImpl->param_end(), 11479 EF = MethodDecl->param_end(); 11480 IM != EM && IF != EF; ++IM, ++IF) { 11481 const ParmVarDecl *DeclVar = (*IF); 11482 const ParmVarDecl *ImplVar = (*IM); 11483 if (ImplVar->getObjCDeclQualifier() != DeclVar->getObjCDeclQualifier()) 11484 return false; 11485 if (!hasSameType(DeclVar->getType(), ImplVar->getType())) 11486 return false; 11487 } 11488 11489 return (MethodDecl->isVariadic() == MethodImpl->isVariadic()); 11490 } 11491 11492 uint64_t ASTContext::getTargetNullPointerValue(QualType QT) const { 11493 LangAS AS; 11494 if (QT->getUnqualifiedDesugaredType()->isNullPtrType()) 11495 AS = LangAS::Default; 11496 else 11497 AS = QT->getPointeeType().getAddressSpace(); 11498 11499 return getTargetInfo().getNullPointerValue(AS); 11500 } 11501 11502 unsigned ASTContext::getTargetAddressSpace(LangAS AS) const { 11503 if (isTargetAddressSpace(AS)) 11504 return toTargetAddressSpace(AS); 11505 else 11506 return (*AddrSpaceMap)[(unsigned)AS]; 11507 } 11508 11509 QualType ASTContext::getCorrespondingSaturatedType(QualType Ty) const { 11510 assert(Ty->isFixedPointType()); 11511 11512 if (Ty->isSaturatedFixedPointType()) return Ty; 11513 11514 switch (Ty->castAs<BuiltinType>()->getKind()) { 11515 default: 11516 llvm_unreachable("Not a fixed point type!"); 11517 case BuiltinType::ShortAccum: 11518 return SatShortAccumTy; 11519 case BuiltinType::Accum: 11520 return SatAccumTy; 11521 case BuiltinType::LongAccum: 11522 return SatLongAccumTy; 11523 case BuiltinType::UShortAccum: 11524 return SatUnsignedShortAccumTy; 11525 case BuiltinType::UAccum: 11526 return SatUnsignedAccumTy; 11527 case BuiltinType::ULongAccum: 11528 return SatUnsignedLongAccumTy; 11529 case BuiltinType::ShortFract: 11530 return SatShortFractTy; 11531 case BuiltinType::Fract: 11532 return SatFractTy; 11533 case BuiltinType::LongFract: 11534 return SatLongFractTy; 11535 case BuiltinType::UShortFract: 11536 return SatUnsignedShortFractTy; 11537 case BuiltinType::UFract: 11538 return SatUnsignedFractTy; 11539 case BuiltinType::ULongFract: 11540 return SatUnsignedLongFractTy; 11541 } 11542 } 11543 11544 LangAS ASTContext::getLangASForBuiltinAddressSpace(unsigned AS) const { 11545 if (LangOpts.OpenCL) 11546 return getTargetInfo().getOpenCLBuiltinAddressSpace(AS); 11547 11548 if (LangOpts.CUDA) 11549 return getTargetInfo().getCUDABuiltinAddressSpace(AS); 11550 11551 return getLangASFromTargetAS(AS); 11552 } 11553 11554 // Explicitly instantiate this in case a Redeclarable<T> is used from a TU that 11555 // doesn't include ASTContext.h 11556 template 11557 clang::LazyGenerationalUpdatePtr< 11558 const Decl *, Decl *, &ExternalASTSource::CompleteRedeclChain>::ValueType 11559 clang::LazyGenerationalUpdatePtr< 11560 const Decl *, Decl *, &ExternalASTSource::CompleteRedeclChain>::makeValue( 11561 const clang::ASTContext &Ctx, Decl *Value); 11562 11563 unsigned char ASTContext::getFixedPointScale(QualType Ty) const { 11564 assert(Ty->isFixedPointType()); 11565 11566 const TargetInfo &Target = getTargetInfo(); 11567 switch (Ty->castAs<BuiltinType>()->getKind()) { 11568 default: 11569 llvm_unreachable("Not a fixed point type!"); 11570 case BuiltinType::ShortAccum: 11571 case BuiltinType::SatShortAccum: 11572 return Target.getShortAccumScale(); 11573 case BuiltinType::Accum: 11574 case BuiltinType::SatAccum: 11575 return Target.getAccumScale(); 11576 case BuiltinType::LongAccum: 11577 case BuiltinType::SatLongAccum: 11578 return Target.getLongAccumScale(); 11579 case BuiltinType::UShortAccum: 11580 case BuiltinType::SatUShortAccum: 11581 return Target.getUnsignedShortAccumScale(); 11582 case BuiltinType::UAccum: 11583 case BuiltinType::SatUAccum: 11584 return Target.getUnsignedAccumScale(); 11585 case BuiltinType::ULongAccum: 11586 case BuiltinType::SatULongAccum: 11587 return Target.getUnsignedLongAccumScale(); 11588 case BuiltinType::ShortFract: 11589 case BuiltinType::SatShortFract: 11590 return Target.getShortFractScale(); 11591 case BuiltinType::Fract: 11592 case BuiltinType::SatFract: 11593 return Target.getFractScale(); 11594 case BuiltinType::LongFract: 11595 case BuiltinType::SatLongFract: 11596 return Target.getLongFractScale(); 11597 case BuiltinType::UShortFract: 11598 case BuiltinType::SatUShortFract: 11599 return Target.getUnsignedShortFractScale(); 11600 case BuiltinType::UFract: 11601 case BuiltinType::SatUFract: 11602 return Target.getUnsignedFractScale(); 11603 case BuiltinType::ULongFract: 11604 case BuiltinType::SatULongFract: 11605 return Target.getUnsignedLongFractScale(); 11606 } 11607 } 11608 11609 unsigned char ASTContext::getFixedPointIBits(QualType Ty) const { 11610 assert(Ty->isFixedPointType()); 11611 11612 const TargetInfo &Target = getTargetInfo(); 11613 switch (Ty->castAs<BuiltinType>()->getKind()) { 11614 default: 11615 llvm_unreachable("Not a fixed point type!"); 11616 case BuiltinType::ShortAccum: 11617 case BuiltinType::SatShortAccum: 11618 return Target.getShortAccumIBits(); 11619 case BuiltinType::Accum: 11620 case BuiltinType::SatAccum: 11621 return Target.getAccumIBits(); 11622 case BuiltinType::LongAccum: 11623 case BuiltinType::SatLongAccum: 11624 return Target.getLongAccumIBits(); 11625 case BuiltinType::UShortAccum: 11626 case BuiltinType::SatUShortAccum: 11627 return Target.getUnsignedShortAccumIBits(); 11628 case BuiltinType::UAccum: 11629 case BuiltinType::SatUAccum: 11630 return Target.getUnsignedAccumIBits(); 11631 case BuiltinType::ULongAccum: 11632 case BuiltinType::SatULongAccum: 11633 return Target.getUnsignedLongAccumIBits(); 11634 case BuiltinType::ShortFract: 11635 case BuiltinType::SatShortFract: 11636 case BuiltinType::Fract: 11637 case BuiltinType::SatFract: 11638 case BuiltinType::LongFract: 11639 case BuiltinType::SatLongFract: 11640 case BuiltinType::UShortFract: 11641 case BuiltinType::SatUShortFract: 11642 case BuiltinType::UFract: 11643 case BuiltinType::SatUFract: 11644 case BuiltinType::ULongFract: 11645 case BuiltinType::SatULongFract: 11646 return 0; 11647 } 11648 } 11649 11650 llvm::FixedPointSemantics 11651 ASTContext::getFixedPointSemantics(QualType Ty) const { 11652 assert((Ty->isFixedPointType() || Ty->isIntegerType()) && 11653 "Can only get the fixed point semantics for a " 11654 "fixed point or integer type."); 11655 if (Ty->isIntegerType()) 11656 return llvm::FixedPointSemantics::GetIntegerSemantics( 11657 getIntWidth(Ty), Ty->isSignedIntegerType()); 11658 11659 bool isSigned = Ty->isSignedFixedPointType(); 11660 return llvm::FixedPointSemantics( 11661 static_cast<unsigned>(getTypeSize(Ty)), getFixedPointScale(Ty), isSigned, 11662 Ty->isSaturatedFixedPointType(), 11663 !isSigned && getTargetInfo().doUnsignedFixedPointTypesHavePadding()); 11664 } 11665 11666 llvm::APFixedPoint ASTContext::getFixedPointMax(QualType Ty) const { 11667 assert(Ty->isFixedPointType()); 11668 return llvm::APFixedPoint::getMax(getFixedPointSemantics(Ty)); 11669 } 11670 11671 llvm::APFixedPoint ASTContext::getFixedPointMin(QualType Ty) const { 11672 assert(Ty->isFixedPointType()); 11673 return llvm::APFixedPoint::getMin(getFixedPointSemantics(Ty)); 11674 } 11675 11676 QualType ASTContext::getCorrespondingSignedFixedPointType(QualType Ty) const { 11677 assert(Ty->isUnsignedFixedPointType() && 11678 "Expected unsigned fixed point type"); 11679 11680 switch (Ty->castAs<BuiltinType>()->getKind()) { 11681 case BuiltinType::UShortAccum: 11682 return ShortAccumTy; 11683 case BuiltinType::UAccum: 11684 return AccumTy; 11685 case BuiltinType::ULongAccum: 11686 return LongAccumTy; 11687 case BuiltinType::SatUShortAccum: 11688 return SatShortAccumTy; 11689 case BuiltinType::SatUAccum: 11690 return SatAccumTy; 11691 case BuiltinType::SatULongAccum: 11692 return SatLongAccumTy; 11693 case BuiltinType::UShortFract: 11694 return ShortFractTy; 11695 case BuiltinType::UFract: 11696 return FractTy; 11697 case BuiltinType::ULongFract: 11698 return LongFractTy; 11699 case BuiltinType::SatUShortFract: 11700 return SatShortFractTy; 11701 case BuiltinType::SatUFract: 11702 return SatFractTy; 11703 case BuiltinType::SatULongFract: 11704 return SatLongFractTy; 11705 default: 11706 llvm_unreachable("Unexpected unsigned fixed point type"); 11707 } 11708 } 11709 11710 ParsedTargetAttr 11711 ASTContext::filterFunctionTargetAttrs(const TargetAttr *TD) const { 11712 assert(TD != nullptr); 11713 ParsedTargetAttr ParsedAttr = TD->parse(); 11714 11715 ParsedAttr.Features.erase( 11716 llvm::remove_if(ParsedAttr.Features, 11717 [&](const std::string &Feat) { 11718 return !Target->isValidFeatureName( 11719 StringRef{Feat}.substr(1)); 11720 }), 11721 ParsedAttr.Features.end()); 11722 return ParsedAttr; 11723 } 11724 11725 void ASTContext::getFunctionFeatureMap(llvm::StringMap<bool> &FeatureMap, 11726 const FunctionDecl *FD) const { 11727 if (FD) 11728 getFunctionFeatureMap(FeatureMap, GlobalDecl().getWithDecl(FD)); 11729 else 11730 Target->initFeatureMap(FeatureMap, getDiagnostics(), 11731 Target->getTargetOpts().CPU, 11732 Target->getTargetOpts().Features); 11733 } 11734 11735 // Fills in the supplied string map with the set of target features for the 11736 // passed in function. 11737 void ASTContext::getFunctionFeatureMap(llvm::StringMap<bool> &FeatureMap, 11738 GlobalDecl GD) const { 11739 StringRef TargetCPU = Target->getTargetOpts().CPU; 11740 const FunctionDecl *FD = GD.getDecl()->getAsFunction(); 11741 if (const auto *TD = FD->getAttr<TargetAttr>()) { 11742 ParsedTargetAttr ParsedAttr = filterFunctionTargetAttrs(TD); 11743 11744 // Make a copy of the features as passed on the command line into the 11745 // beginning of the additional features from the function to override. 11746 ParsedAttr.Features.insert( 11747 ParsedAttr.Features.begin(), 11748 Target->getTargetOpts().FeaturesAsWritten.begin(), 11749 Target->getTargetOpts().FeaturesAsWritten.end()); 11750 11751 if (ParsedAttr.Architecture != "" && 11752 Target->isValidCPUName(ParsedAttr.Architecture)) 11753 TargetCPU = ParsedAttr.Architecture; 11754 11755 // Now populate the feature map, first with the TargetCPU which is either 11756 // the default or a new one from the target attribute string. Then we'll use 11757 // the passed in features (FeaturesAsWritten) along with the new ones from 11758 // the attribute. 11759 Target->initFeatureMap(FeatureMap, getDiagnostics(), TargetCPU, 11760 ParsedAttr.Features); 11761 } else if (const auto *SD = FD->getAttr<CPUSpecificAttr>()) { 11762 llvm::SmallVector<StringRef, 32> FeaturesTmp; 11763 Target->getCPUSpecificCPUDispatchFeatures( 11764 SD->getCPUName(GD.getMultiVersionIndex())->getName(), FeaturesTmp); 11765 std::vector<std::string> Features(FeaturesTmp.begin(), FeaturesTmp.end()); 11766 Target->initFeatureMap(FeatureMap, getDiagnostics(), TargetCPU, Features); 11767 } else { 11768 FeatureMap = Target->getTargetOpts().FeatureMap; 11769 } 11770 } 11771 11772 OMPTraitInfo &ASTContext::getNewOMPTraitInfo() { 11773 OMPTraitInfoVector.emplace_back(new OMPTraitInfo()); 11774 return *OMPTraitInfoVector.back(); 11775 } 11776 11777 const StreamingDiagnostic &clang:: 11778 operator<<(const StreamingDiagnostic &DB, 11779 const ASTContext::SectionInfo &Section) { 11780 if (Section.Decl) 11781 return DB << Section.Decl; 11782 return DB << "a prior #pragma section"; 11783 } 11784 11785 bool ASTContext::mayExternalizeStaticVar(const Decl *D) const { 11786 bool IsStaticVar = 11787 isa<VarDecl>(D) && cast<VarDecl>(D)->getStorageClass() == SC_Static; 11788 bool IsExplicitDeviceVar = (D->hasAttr<CUDADeviceAttr>() && 11789 !D->getAttr<CUDADeviceAttr>()->isImplicit()) || 11790 (D->hasAttr<CUDAConstantAttr>() && 11791 !D->getAttr<CUDAConstantAttr>()->isImplicit()); 11792 // CUDA/HIP: static managed variables need to be externalized since it is 11793 // a declaration in IR, therefore cannot have internal linkage. 11794 return IsStaticVar && 11795 (D->hasAttr<HIPManagedAttr>() || IsExplicitDeviceVar); 11796 } 11797 11798 bool ASTContext::shouldExternalizeStaticVar(const Decl *D) const { 11799 return mayExternalizeStaticVar(D) && 11800 (D->hasAttr<HIPManagedAttr>() || 11801 CUDADeviceVarODRUsedByHost.count(cast<VarDecl>(D))); 11802 } 11803 11804 StringRef ASTContext::getCUIDHash() const { 11805 if (!CUIDHash.empty()) 11806 return CUIDHash; 11807 if (LangOpts.CUID.empty()) 11808 return StringRef(); 11809 CUIDHash = llvm::utohexstr(llvm::MD5Hash(LangOpts.CUID), /*LowerCase=*/true); 11810 return CUIDHash; 11811 } 11812