1 //===--------------------- SemaLookup.cpp - Name Lookup ------------------===// 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 name lookup for C, C++, Objective-C, and 10 // Objective-C++. 11 // 12 //===----------------------------------------------------------------------===// 13 14 #include "clang/AST/ASTContext.h" 15 #include "clang/AST/CXXInheritance.h" 16 #include "clang/AST/Decl.h" 17 #include "clang/AST/DeclCXX.h" 18 #include "clang/AST/DeclLookups.h" 19 #include "clang/AST/DeclObjC.h" 20 #include "clang/AST/DeclTemplate.h" 21 #include "clang/AST/Expr.h" 22 #include "clang/AST/ExprCXX.h" 23 #include "clang/Basic/Builtins.h" 24 #include "clang/Basic/FileManager.h" 25 #include "clang/Basic/LangOptions.h" 26 #include "clang/Lex/HeaderSearch.h" 27 #include "clang/Lex/ModuleLoader.h" 28 #include "clang/Lex/Preprocessor.h" 29 #include "clang/Sema/DeclSpec.h" 30 #include "clang/Sema/Lookup.h" 31 #include "clang/Sema/Overload.h" 32 #include "clang/Sema/Scope.h" 33 #include "clang/Sema/ScopeInfo.h" 34 #include "clang/Sema/Sema.h" 35 #include "clang/Sema/SemaInternal.h" 36 #include "clang/Sema/TemplateDeduction.h" 37 #include "clang/Sema/TypoCorrection.h" 38 #include "llvm/ADT/STLExtras.h" 39 #include "llvm/ADT/SmallPtrSet.h" 40 #include "llvm/ADT/TinyPtrVector.h" 41 #include "llvm/ADT/edit_distance.h" 42 #include "llvm/Support/ErrorHandling.h" 43 #include <algorithm> 44 #include <iterator> 45 #include <list> 46 #include <set> 47 #include <utility> 48 #include <vector> 49 50 #include "OpenCLBuiltins.inc" 51 52 using namespace clang; 53 using namespace sema; 54 55 namespace { 56 class UnqualUsingEntry { 57 const DeclContext *Nominated; 58 const DeclContext *CommonAncestor; 59 60 public: 61 UnqualUsingEntry(const DeclContext *Nominated, 62 const DeclContext *CommonAncestor) 63 : Nominated(Nominated), CommonAncestor(CommonAncestor) { 64 } 65 66 const DeclContext *getCommonAncestor() const { 67 return CommonAncestor; 68 } 69 70 const DeclContext *getNominatedNamespace() const { 71 return Nominated; 72 } 73 74 // Sort by the pointer value of the common ancestor. 75 struct Comparator { 76 bool operator()(const UnqualUsingEntry &L, const UnqualUsingEntry &R) { 77 return L.getCommonAncestor() < R.getCommonAncestor(); 78 } 79 80 bool operator()(const UnqualUsingEntry &E, const DeclContext *DC) { 81 return E.getCommonAncestor() < DC; 82 } 83 84 bool operator()(const DeclContext *DC, const UnqualUsingEntry &E) { 85 return DC < E.getCommonAncestor(); 86 } 87 }; 88 }; 89 90 /// A collection of using directives, as used by C++ unqualified 91 /// lookup. 92 class UnqualUsingDirectiveSet { 93 Sema &SemaRef; 94 95 typedef SmallVector<UnqualUsingEntry, 8> ListTy; 96 97 ListTy list; 98 llvm::SmallPtrSet<DeclContext*, 8> visited; 99 100 public: 101 UnqualUsingDirectiveSet(Sema &SemaRef) : SemaRef(SemaRef) {} 102 103 void visitScopeChain(Scope *S, Scope *InnermostFileScope) { 104 // C++ [namespace.udir]p1: 105 // During unqualified name lookup, the names appear as if they 106 // were declared in the nearest enclosing namespace which contains 107 // both the using-directive and the nominated namespace. 108 DeclContext *InnermostFileDC = InnermostFileScope->getEntity(); 109 assert(InnermostFileDC && InnermostFileDC->isFileContext()); 110 111 for (; S; S = S->getParent()) { 112 // C++ [namespace.udir]p1: 113 // A using-directive shall not appear in class scope, but may 114 // appear in namespace scope or in block scope. 115 DeclContext *Ctx = S->getEntity(); 116 if (Ctx && Ctx->isFileContext()) { 117 visit(Ctx, Ctx); 118 } else if (!Ctx || Ctx->isFunctionOrMethod()) { 119 for (auto *I : S->using_directives()) 120 if (SemaRef.isVisible(I)) 121 visit(I, InnermostFileDC); 122 } 123 } 124 } 125 126 // Visits a context and collect all of its using directives 127 // recursively. Treats all using directives as if they were 128 // declared in the context. 129 // 130 // A given context is only every visited once, so it is important 131 // that contexts be visited from the inside out in order to get 132 // the effective DCs right. 133 void visit(DeclContext *DC, DeclContext *EffectiveDC) { 134 if (!visited.insert(DC).second) 135 return; 136 137 addUsingDirectives(DC, EffectiveDC); 138 } 139 140 // Visits a using directive and collects all of its using 141 // directives recursively. Treats all using directives as if they 142 // were declared in the effective DC. 143 void visit(UsingDirectiveDecl *UD, DeclContext *EffectiveDC) { 144 DeclContext *NS = UD->getNominatedNamespace(); 145 if (!visited.insert(NS).second) 146 return; 147 148 addUsingDirective(UD, EffectiveDC); 149 addUsingDirectives(NS, EffectiveDC); 150 } 151 152 // Adds all the using directives in a context (and those nominated 153 // by its using directives, transitively) as if they appeared in 154 // the given effective context. 155 void addUsingDirectives(DeclContext *DC, DeclContext *EffectiveDC) { 156 SmallVector<DeclContext*, 4> queue; 157 while (true) { 158 for (auto UD : DC->using_directives()) { 159 DeclContext *NS = UD->getNominatedNamespace(); 160 if (SemaRef.isVisible(UD) && visited.insert(NS).second) { 161 addUsingDirective(UD, EffectiveDC); 162 queue.push_back(NS); 163 } 164 } 165 166 if (queue.empty()) 167 return; 168 169 DC = queue.pop_back_val(); 170 } 171 } 172 173 // Add a using directive as if it had been declared in the given 174 // context. This helps implement C++ [namespace.udir]p3: 175 // The using-directive is transitive: if a scope contains a 176 // using-directive that nominates a second namespace that itself 177 // contains using-directives, the effect is as if the 178 // using-directives from the second namespace also appeared in 179 // the first. 180 void addUsingDirective(UsingDirectiveDecl *UD, DeclContext *EffectiveDC) { 181 // Find the common ancestor between the effective context and 182 // the nominated namespace. 183 DeclContext *Common = UD->getNominatedNamespace(); 184 while (!Common->Encloses(EffectiveDC)) 185 Common = Common->getParent(); 186 Common = Common->getPrimaryContext(); 187 188 list.push_back(UnqualUsingEntry(UD->getNominatedNamespace(), Common)); 189 } 190 191 void done() { llvm::sort(list, UnqualUsingEntry::Comparator()); } 192 193 typedef ListTy::const_iterator const_iterator; 194 195 const_iterator begin() const { return list.begin(); } 196 const_iterator end() const { return list.end(); } 197 198 llvm::iterator_range<const_iterator> 199 getNamespacesFor(DeclContext *DC) const { 200 return llvm::make_range(std::equal_range(begin(), end(), 201 DC->getPrimaryContext(), 202 UnqualUsingEntry::Comparator())); 203 } 204 }; 205 } // end anonymous namespace 206 207 // Retrieve the set of identifier namespaces that correspond to a 208 // specific kind of name lookup. 209 static inline unsigned getIDNS(Sema::LookupNameKind NameKind, 210 bool CPlusPlus, 211 bool Redeclaration) { 212 unsigned IDNS = 0; 213 switch (NameKind) { 214 case Sema::LookupObjCImplicitSelfParam: 215 case Sema::LookupOrdinaryName: 216 case Sema::LookupRedeclarationWithLinkage: 217 case Sema::LookupLocalFriendName: 218 case Sema::LookupDestructorName: 219 IDNS = Decl::IDNS_Ordinary; 220 if (CPlusPlus) { 221 IDNS |= Decl::IDNS_Tag | Decl::IDNS_Member | Decl::IDNS_Namespace; 222 if (Redeclaration) 223 IDNS |= Decl::IDNS_TagFriend | Decl::IDNS_OrdinaryFriend; 224 } 225 if (Redeclaration) 226 IDNS |= Decl::IDNS_LocalExtern; 227 break; 228 229 case Sema::LookupOperatorName: 230 // Operator lookup is its own crazy thing; it is not the same 231 // as (e.g.) looking up an operator name for redeclaration. 232 assert(!Redeclaration && "cannot do redeclaration operator lookup"); 233 IDNS = Decl::IDNS_NonMemberOperator; 234 break; 235 236 case Sema::LookupTagName: 237 if (CPlusPlus) { 238 IDNS = Decl::IDNS_Type; 239 240 // When looking for a redeclaration of a tag name, we add: 241 // 1) TagFriend to find undeclared friend decls 242 // 2) Namespace because they can't "overload" with tag decls. 243 // 3) Tag because it includes class templates, which can't 244 // "overload" with tag decls. 245 if (Redeclaration) 246 IDNS |= Decl::IDNS_Tag | Decl::IDNS_TagFriend | Decl::IDNS_Namespace; 247 } else { 248 IDNS = Decl::IDNS_Tag; 249 } 250 break; 251 252 case Sema::LookupLabel: 253 IDNS = Decl::IDNS_Label; 254 break; 255 256 case Sema::LookupMemberName: 257 IDNS = Decl::IDNS_Member; 258 if (CPlusPlus) 259 IDNS |= Decl::IDNS_Tag | Decl::IDNS_Ordinary; 260 break; 261 262 case Sema::LookupNestedNameSpecifierName: 263 IDNS = Decl::IDNS_Type | Decl::IDNS_Namespace; 264 break; 265 266 case Sema::LookupNamespaceName: 267 IDNS = Decl::IDNS_Namespace; 268 break; 269 270 case Sema::LookupUsingDeclName: 271 assert(Redeclaration && "should only be used for redecl lookup"); 272 IDNS = Decl::IDNS_Ordinary | Decl::IDNS_Tag | Decl::IDNS_Member | 273 Decl::IDNS_Using | Decl::IDNS_TagFriend | Decl::IDNS_OrdinaryFriend | 274 Decl::IDNS_LocalExtern; 275 break; 276 277 case Sema::LookupObjCProtocolName: 278 IDNS = Decl::IDNS_ObjCProtocol; 279 break; 280 281 case Sema::LookupOMPReductionName: 282 IDNS = Decl::IDNS_OMPReduction; 283 break; 284 285 case Sema::LookupOMPMapperName: 286 IDNS = Decl::IDNS_OMPMapper; 287 break; 288 289 case Sema::LookupAnyName: 290 IDNS = Decl::IDNS_Ordinary | Decl::IDNS_Tag | Decl::IDNS_Member 291 | Decl::IDNS_Using | Decl::IDNS_Namespace | Decl::IDNS_ObjCProtocol 292 | Decl::IDNS_Type; 293 break; 294 } 295 return IDNS; 296 } 297 298 void LookupResult::configure() { 299 IDNS = getIDNS(LookupKind, getSema().getLangOpts().CPlusPlus, 300 isForRedeclaration()); 301 302 // If we're looking for one of the allocation or deallocation 303 // operators, make sure that the implicitly-declared new and delete 304 // operators can be found. 305 switch (NameInfo.getName().getCXXOverloadedOperator()) { 306 case OO_New: 307 case OO_Delete: 308 case OO_Array_New: 309 case OO_Array_Delete: 310 getSema().DeclareGlobalNewDelete(); 311 break; 312 313 default: 314 break; 315 } 316 317 // Compiler builtins are always visible, regardless of where they end 318 // up being declared. 319 if (IdentifierInfo *Id = NameInfo.getName().getAsIdentifierInfo()) { 320 if (unsigned BuiltinID = Id->getBuiltinID()) { 321 if (!getSema().Context.BuiltinInfo.isPredefinedLibFunction(BuiltinID)) 322 AllowHidden = true; 323 } 324 } 325 } 326 327 bool LookupResult::sanity() const { 328 // This function is never called by NDEBUG builds. 329 assert(ResultKind != NotFound || Decls.size() == 0); 330 assert(ResultKind != Found || Decls.size() == 1); 331 assert(ResultKind != FoundOverloaded || Decls.size() > 1 || 332 (Decls.size() == 1 && 333 isa<FunctionTemplateDecl>((*begin())->getUnderlyingDecl()))); 334 assert(ResultKind != FoundUnresolvedValue || sanityCheckUnresolved()); 335 assert(ResultKind != Ambiguous || Decls.size() > 1 || 336 (Decls.size() == 1 && (Ambiguity == AmbiguousBaseSubobjects || 337 Ambiguity == AmbiguousBaseSubobjectTypes))); 338 assert((Paths != nullptr) == (ResultKind == Ambiguous && 339 (Ambiguity == AmbiguousBaseSubobjectTypes || 340 Ambiguity == AmbiguousBaseSubobjects))); 341 return true; 342 } 343 344 // Necessary because CXXBasePaths is not complete in Sema.h 345 void LookupResult::deletePaths(CXXBasePaths *Paths) { 346 delete Paths; 347 } 348 349 /// Get a representative context for a declaration such that two declarations 350 /// will have the same context if they were found within the same scope. 351 static DeclContext *getContextForScopeMatching(Decl *D) { 352 // For function-local declarations, use that function as the context. This 353 // doesn't account for scopes within the function; the caller must deal with 354 // those. 355 DeclContext *DC = D->getLexicalDeclContext(); 356 if (DC->isFunctionOrMethod()) 357 return DC; 358 359 // Otherwise, look at the semantic context of the declaration. The 360 // declaration must have been found there. 361 return D->getDeclContext()->getRedeclContext(); 362 } 363 364 /// Determine whether \p D is a better lookup result than \p Existing, 365 /// given that they declare the same entity. 366 static bool isPreferredLookupResult(Sema &S, Sema::LookupNameKind Kind, 367 NamedDecl *D, NamedDecl *Existing) { 368 // When looking up redeclarations of a using declaration, prefer a using 369 // shadow declaration over any other declaration of the same entity. 370 if (Kind == Sema::LookupUsingDeclName && isa<UsingShadowDecl>(D) && 371 !isa<UsingShadowDecl>(Existing)) 372 return true; 373 374 auto *DUnderlying = D->getUnderlyingDecl(); 375 auto *EUnderlying = Existing->getUnderlyingDecl(); 376 377 // If they have different underlying declarations, prefer a typedef over the 378 // original type (this happens when two type declarations denote the same 379 // type), per a generous reading of C++ [dcl.typedef]p3 and p4. The typedef 380 // might carry additional semantic information, such as an alignment override. 381 // However, per C++ [dcl.typedef]p5, when looking up a tag name, prefer a tag 382 // declaration over a typedef. Also prefer a tag over a typedef for 383 // destructor name lookup because in some contexts we only accept a 384 // class-name in a destructor declaration. 385 if (DUnderlying->getCanonicalDecl() != EUnderlying->getCanonicalDecl()) { 386 assert(isa<TypeDecl>(DUnderlying) && isa<TypeDecl>(EUnderlying)); 387 bool HaveTag = isa<TagDecl>(EUnderlying); 388 bool WantTag = 389 Kind == Sema::LookupTagName || Kind == Sema::LookupDestructorName; 390 return HaveTag != WantTag; 391 } 392 393 // Pick the function with more default arguments. 394 // FIXME: In the presence of ambiguous default arguments, we should keep both, 395 // so we can diagnose the ambiguity if the default argument is needed. 396 // See C++ [over.match.best]p3. 397 if (auto *DFD = dyn_cast<FunctionDecl>(DUnderlying)) { 398 auto *EFD = cast<FunctionDecl>(EUnderlying); 399 unsigned DMin = DFD->getMinRequiredArguments(); 400 unsigned EMin = EFD->getMinRequiredArguments(); 401 // If D has more default arguments, it is preferred. 402 if (DMin != EMin) 403 return DMin < EMin; 404 // FIXME: When we track visibility for default function arguments, check 405 // that we pick the declaration with more visible default arguments. 406 } 407 408 // Pick the template with more default template arguments. 409 if (auto *DTD = dyn_cast<TemplateDecl>(DUnderlying)) { 410 auto *ETD = cast<TemplateDecl>(EUnderlying); 411 unsigned DMin = DTD->getTemplateParameters()->getMinRequiredArguments(); 412 unsigned EMin = ETD->getTemplateParameters()->getMinRequiredArguments(); 413 // If D has more default arguments, it is preferred. Note that default 414 // arguments (and their visibility) is monotonically increasing across the 415 // redeclaration chain, so this is a quick proxy for "is more recent". 416 if (DMin != EMin) 417 return DMin < EMin; 418 // If D has more *visible* default arguments, it is preferred. Note, an 419 // earlier default argument being visible does not imply that a later 420 // default argument is visible, so we can't just check the first one. 421 for (unsigned I = DMin, N = DTD->getTemplateParameters()->size(); 422 I != N; ++I) { 423 if (!S.hasVisibleDefaultArgument( 424 ETD->getTemplateParameters()->getParam(I)) && 425 S.hasVisibleDefaultArgument( 426 DTD->getTemplateParameters()->getParam(I))) 427 return true; 428 } 429 } 430 431 // VarDecl can have incomplete array types, prefer the one with more complete 432 // array type. 433 if (VarDecl *DVD = dyn_cast<VarDecl>(DUnderlying)) { 434 VarDecl *EVD = cast<VarDecl>(EUnderlying); 435 if (EVD->getType()->isIncompleteType() && 436 !DVD->getType()->isIncompleteType()) { 437 // Prefer the decl with a more complete type if visible. 438 return S.isVisible(DVD); 439 } 440 return false; // Avoid picking up a newer decl, just because it was newer. 441 } 442 443 // For most kinds of declaration, it doesn't really matter which one we pick. 444 if (!isa<FunctionDecl>(DUnderlying) && !isa<VarDecl>(DUnderlying)) { 445 // If the existing declaration is hidden, prefer the new one. Otherwise, 446 // keep what we've got. 447 return !S.isVisible(Existing); 448 } 449 450 // Pick the newer declaration; it might have a more precise type. 451 for (Decl *Prev = DUnderlying->getPreviousDecl(); Prev; 452 Prev = Prev->getPreviousDecl()) 453 if (Prev == EUnderlying) 454 return true; 455 return false; 456 } 457 458 /// Determine whether \p D can hide a tag declaration. 459 static bool canHideTag(NamedDecl *D) { 460 // C++ [basic.scope.declarative]p4: 461 // Given a set of declarations in a single declarative region [...] 462 // exactly one declaration shall declare a class name or enumeration name 463 // that is not a typedef name and the other declarations shall all refer to 464 // the same variable, non-static data member, or enumerator, or all refer 465 // to functions and function templates; in this case the class name or 466 // enumeration name is hidden. 467 // C++ [basic.scope.hiding]p2: 468 // A class name or enumeration name can be hidden by the name of a 469 // variable, data member, function, or enumerator declared in the same 470 // scope. 471 // An UnresolvedUsingValueDecl always instantiates to one of these. 472 D = D->getUnderlyingDecl(); 473 return isa<VarDecl>(D) || isa<EnumConstantDecl>(D) || isa<FunctionDecl>(D) || 474 isa<FunctionTemplateDecl>(D) || isa<FieldDecl>(D) || 475 isa<UnresolvedUsingValueDecl>(D); 476 } 477 478 /// Resolves the result kind of this lookup. 479 void LookupResult::resolveKind() { 480 unsigned N = Decls.size(); 481 482 // Fast case: no possible ambiguity. 483 if (N == 0) { 484 assert(ResultKind == NotFound || 485 ResultKind == NotFoundInCurrentInstantiation); 486 return; 487 } 488 489 // If there's a single decl, we need to examine it to decide what 490 // kind of lookup this is. 491 if (N == 1) { 492 NamedDecl *D = (*Decls.begin())->getUnderlyingDecl(); 493 if (isa<FunctionTemplateDecl>(D)) 494 ResultKind = FoundOverloaded; 495 else if (isa<UnresolvedUsingValueDecl>(D)) 496 ResultKind = FoundUnresolvedValue; 497 return; 498 } 499 500 // Don't do any extra resolution if we've already resolved as ambiguous. 501 if (ResultKind == Ambiguous) return; 502 503 llvm::SmallDenseMap<NamedDecl*, unsigned, 16> Unique; 504 llvm::SmallDenseMap<QualType, unsigned, 16> UniqueTypes; 505 506 bool Ambiguous = false; 507 bool HasTag = false, HasFunction = false; 508 bool HasFunctionTemplate = false, HasUnresolved = false; 509 NamedDecl *HasNonFunction = nullptr; 510 511 llvm::SmallVector<NamedDecl*, 4> EquivalentNonFunctions; 512 513 unsigned UniqueTagIndex = 0; 514 515 unsigned I = 0; 516 while (I < N) { 517 NamedDecl *D = Decls[I]->getUnderlyingDecl(); 518 D = cast<NamedDecl>(D->getCanonicalDecl()); 519 520 // Ignore an invalid declaration unless it's the only one left. 521 if (D->isInvalidDecl() && !(I == 0 && N == 1)) { 522 Decls[I] = Decls[--N]; 523 continue; 524 } 525 526 llvm::Optional<unsigned> ExistingI; 527 528 // Redeclarations of types via typedef can occur both within a scope 529 // and, through using declarations and directives, across scopes. There is 530 // no ambiguity if they all refer to the same type, so unique based on the 531 // canonical type. 532 if (TypeDecl *TD = dyn_cast<TypeDecl>(D)) { 533 QualType T = getSema().Context.getTypeDeclType(TD); 534 auto UniqueResult = UniqueTypes.insert( 535 std::make_pair(getSema().Context.getCanonicalType(T), I)); 536 if (!UniqueResult.second) { 537 // The type is not unique. 538 ExistingI = UniqueResult.first->second; 539 } 540 } 541 542 // For non-type declarations, check for a prior lookup result naming this 543 // canonical declaration. 544 if (!ExistingI) { 545 auto UniqueResult = Unique.insert(std::make_pair(D, I)); 546 if (!UniqueResult.second) { 547 // We've seen this entity before. 548 ExistingI = UniqueResult.first->second; 549 } 550 } 551 552 if (ExistingI) { 553 // This is not a unique lookup result. Pick one of the results and 554 // discard the other. 555 if (isPreferredLookupResult(getSema(), getLookupKind(), Decls[I], 556 Decls[*ExistingI])) 557 Decls[*ExistingI] = Decls[I]; 558 Decls[I] = Decls[--N]; 559 continue; 560 } 561 562 // Otherwise, do some decl type analysis and then continue. 563 564 if (isa<UnresolvedUsingValueDecl>(D)) { 565 HasUnresolved = true; 566 } else if (isa<TagDecl>(D)) { 567 if (HasTag) 568 Ambiguous = true; 569 UniqueTagIndex = I; 570 HasTag = true; 571 } else if (isa<FunctionTemplateDecl>(D)) { 572 HasFunction = true; 573 HasFunctionTemplate = true; 574 } else if (isa<FunctionDecl>(D)) { 575 HasFunction = true; 576 } else { 577 if (HasNonFunction) { 578 // If we're about to create an ambiguity between two declarations that 579 // are equivalent, but one is an internal linkage declaration from one 580 // module and the other is an internal linkage declaration from another 581 // module, just skip it. 582 if (getSema().isEquivalentInternalLinkageDeclaration(HasNonFunction, 583 D)) { 584 EquivalentNonFunctions.push_back(D); 585 Decls[I] = Decls[--N]; 586 continue; 587 } 588 589 Ambiguous = true; 590 } 591 HasNonFunction = D; 592 } 593 I++; 594 } 595 596 // C++ [basic.scope.hiding]p2: 597 // A class name or enumeration name can be hidden by the name of 598 // an object, function, or enumerator declared in the same 599 // scope. If a class or enumeration name and an object, function, 600 // or enumerator are declared in the same scope (in any order) 601 // with the same name, the class or enumeration name is hidden 602 // wherever the object, function, or enumerator name is visible. 603 // But it's still an error if there are distinct tag types found, 604 // even if they're not visible. (ref?) 605 if (N > 1 && HideTags && HasTag && !Ambiguous && 606 (HasFunction || HasNonFunction || HasUnresolved)) { 607 NamedDecl *OtherDecl = Decls[UniqueTagIndex ? 0 : N - 1]; 608 if (isa<TagDecl>(Decls[UniqueTagIndex]->getUnderlyingDecl()) && 609 getContextForScopeMatching(Decls[UniqueTagIndex])->Equals( 610 getContextForScopeMatching(OtherDecl)) && 611 canHideTag(OtherDecl)) 612 Decls[UniqueTagIndex] = Decls[--N]; 613 else 614 Ambiguous = true; 615 } 616 617 // FIXME: This diagnostic should really be delayed until we're done with 618 // the lookup result, in case the ambiguity is resolved by the caller. 619 if (!EquivalentNonFunctions.empty() && !Ambiguous) 620 getSema().diagnoseEquivalentInternalLinkageDeclarations( 621 getNameLoc(), HasNonFunction, EquivalentNonFunctions); 622 623 Decls.set_size(N); 624 625 if (HasNonFunction && (HasFunction || HasUnresolved)) 626 Ambiguous = true; 627 628 if (Ambiguous) 629 setAmbiguous(LookupResult::AmbiguousReference); 630 else if (HasUnresolved) 631 ResultKind = LookupResult::FoundUnresolvedValue; 632 else if (N > 1 || HasFunctionTemplate) 633 ResultKind = LookupResult::FoundOverloaded; 634 else 635 ResultKind = LookupResult::Found; 636 } 637 638 void LookupResult::addDeclsFromBasePaths(const CXXBasePaths &P) { 639 CXXBasePaths::const_paths_iterator I, E; 640 for (I = P.begin(), E = P.end(); I != E; ++I) 641 for (DeclContext::lookup_iterator DI = I->Decls.begin(), 642 DE = I->Decls.end(); DI != DE; ++DI) 643 addDecl(*DI); 644 } 645 646 void LookupResult::setAmbiguousBaseSubobjects(CXXBasePaths &P) { 647 Paths = new CXXBasePaths; 648 Paths->swap(P); 649 addDeclsFromBasePaths(*Paths); 650 resolveKind(); 651 setAmbiguous(AmbiguousBaseSubobjects); 652 } 653 654 void LookupResult::setAmbiguousBaseSubobjectTypes(CXXBasePaths &P) { 655 Paths = new CXXBasePaths; 656 Paths->swap(P); 657 addDeclsFromBasePaths(*Paths); 658 resolveKind(); 659 setAmbiguous(AmbiguousBaseSubobjectTypes); 660 } 661 662 void LookupResult::print(raw_ostream &Out) { 663 Out << Decls.size() << " result(s)"; 664 if (isAmbiguous()) Out << ", ambiguous"; 665 if (Paths) Out << ", base paths present"; 666 667 for (iterator I = begin(), E = end(); I != E; ++I) { 668 Out << "\n"; 669 (*I)->print(Out, 2); 670 } 671 } 672 673 LLVM_DUMP_METHOD void LookupResult::dump() { 674 llvm::errs() << "lookup results for " << getLookupName().getAsString() 675 << ":\n"; 676 for (NamedDecl *D : *this) 677 D->dump(); 678 } 679 680 /// Get the QualType instances of the return type and arguments for an OpenCL 681 /// builtin function signature. 682 /// \param Context (in) The Context instance. 683 /// \param OpenCLBuiltin (in) The signature currently handled. 684 /// \param GenTypeMaxCnt (out) Maximum number of types contained in a generic 685 /// type used as return type or as argument. 686 /// Only meaningful for generic types, otherwise equals 1. 687 /// \param RetTypes (out) List of the possible return types. 688 /// \param ArgTypes (out) List of the possible argument types. For each 689 /// argument, ArgTypes contains QualTypes for the Cartesian product 690 /// of (vector sizes) x (types) . 691 static void GetQualTypesForOpenCLBuiltin( 692 ASTContext &Context, const OpenCLBuiltinStruct &OpenCLBuiltin, 693 unsigned &GenTypeMaxCnt, SmallVector<QualType, 1> &RetTypes, 694 SmallVector<SmallVector<QualType, 1>, 5> &ArgTypes) { 695 // Get the QualType instances of the return types. 696 unsigned Sig = SignatureTable[OpenCLBuiltin.SigTableIndex]; 697 OCL2Qual(Context, TypeTable[Sig], RetTypes); 698 GenTypeMaxCnt = RetTypes.size(); 699 700 // Get the QualType instances of the arguments. 701 // First type is the return type, skip it. 702 for (unsigned Index = 1; Index < OpenCLBuiltin.NumTypes; Index++) { 703 SmallVector<QualType, 1> Ty; 704 OCL2Qual(Context, 705 TypeTable[SignatureTable[OpenCLBuiltin.SigTableIndex + Index]], Ty); 706 GenTypeMaxCnt = (Ty.size() > GenTypeMaxCnt) ? Ty.size() : GenTypeMaxCnt; 707 ArgTypes.push_back(std::move(Ty)); 708 } 709 } 710 711 /// Create a list of the candidate function overloads for an OpenCL builtin 712 /// function. 713 /// \param Context (in) The ASTContext instance. 714 /// \param GenTypeMaxCnt (in) Maximum number of types contained in a generic 715 /// type used as return type or as argument. 716 /// Only meaningful for generic types, otherwise equals 1. 717 /// \param FunctionList (out) List of FunctionTypes. 718 /// \param RetTypes (in) List of the possible return types. 719 /// \param ArgTypes (in) List of the possible types for the arguments. 720 static void GetOpenCLBuiltinFctOverloads( 721 ASTContext &Context, unsigned GenTypeMaxCnt, 722 std::vector<QualType> &FunctionList, SmallVector<QualType, 1> &RetTypes, 723 SmallVector<SmallVector<QualType, 1>, 5> &ArgTypes) { 724 FunctionProtoType::ExtProtoInfo PI; 725 PI.Variadic = false; 726 727 // Create FunctionTypes for each (gen)type. 728 for (unsigned IGenType = 0; IGenType < GenTypeMaxCnt; IGenType++) { 729 SmallVector<QualType, 5> ArgList; 730 731 for (unsigned A = 0; A < ArgTypes.size(); A++) { 732 // Builtins such as "max" have an "sgentype" argument that represents 733 // the corresponding scalar type of a gentype. The number of gentypes 734 // must be a multiple of the number of sgentypes. 735 assert(GenTypeMaxCnt % ArgTypes[A].size() == 0 && 736 "argument type count not compatible with gentype type count"); 737 unsigned Idx = IGenType % ArgTypes[A].size(); 738 ArgList.push_back(ArgTypes[A][Idx]); 739 } 740 741 FunctionList.push_back(Context.getFunctionType( 742 RetTypes[(RetTypes.size() != 1) ? IGenType : 0], ArgList, PI)); 743 } 744 } 745 746 /// Add extensions to the function declaration. 747 /// \param S (in/out) The Sema instance. 748 /// \param BIDecl (in) Description of the builtin. 749 /// \param FDecl (in/out) FunctionDecl instance. 750 static void AddOpenCLExtensions(Sema &S, const OpenCLBuiltinStruct &BIDecl, 751 FunctionDecl *FDecl) { 752 // Fetch extension associated with a function prototype. 753 StringRef E = FunctionExtensionTable[BIDecl.Extension]; 754 if (E != "") 755 S.setOpenCLExtensionForDecl(FDecl, E); 756 } 757 758 /// When trying to resolve a function name, if isOpenCLBuiltin() returns a 759 /// non-null <Index, Len> pair, then the name is referencing an OpenCL 760 /// builtin function. Add all candidate signatures to the LookUpResult. 761 /// 762 /// \param S (in) The Sema instance. 763 /// \param LR (inout) The LookupResult instance. 764 /// \param II (in) The identifier being resolved. 765 /// \param FctIndex (in) Starting index in the BuiltinTable. 766 /// \param Len (in) The signature list has Len elements. 767 static void InsertOCLBuiltinDeclarationsFromTable(Sema &S, LookupResult &LR, 768 IdentifierInfo *II, 769 const unsigned FctIndex, 770 const unsigned Len) { 771 // The builtin function declaration uses generic types (gentype). 772 bool HasGenType = false; 773 774 // Maximum number of types contained in a generic type used as return type or 775 // as argument. Only meaningful for generic types, otherwise equals 1. 776 unsigned GenTypeMaxCnt; 777 778 for (unsigned SignatureIndex = 0; SignatureIndex < Len; SignatureIndex++) { 779 const OpenCLBuiltinStruct &OpenCLBuiltin = 780 BuiltinTable[FctIndex + SignatureIndex]; 781 ASTContext &Context = S.Context; 782 783 // Ignore this BIF if its version does not match the language options. 784 unsigned OpenCLVersion = Context.getLangOpts().OpenCLVersion; 785 if (Context.getLangOpts().OpenCLCPlusPlus) 786 OpenCLVersion = 200; 787 if (OpenCLVersion < OpenCLBuiltin.MinVersion) 788 continue; 789 if ((OpenCLBuiltin.MaxVersion != 0) && 790 (OpenCLVersion >= OpenCLBuiltin.MaxVersion)) 791 continue; 792 793 SmallVector<QualType, 1> RetTypes; 794 SmallVector<SmallVector<QualType, 1>, 5> ArgTypes; 795 796 // Obtain QualType lists for the function signature. 797 GetQualTypesForOpenCLBuiltin(Context, OpenCLBuiltin, GenTypeMaxCnt, 798 RetTypes, ArgTypes); 799 if (GenTypeMaxCnt > 1) { 800 HasGenType = true; 801 } 802 803 // Create function overload for each type combination. 804 std::vector<QualType> FunctionList; 805 GetOpenCLBuiltinFctOverloads(Context, GenTypeMaxCnt, FunctionList, RetTypes, 806 ArgTypes); 807 808 SourceLocation Loc = LR.getNameLoc(); 809 DeclContext *Parent = Context.getTranslationUnitDecl(); 810 FunctionDecl *NewOpenCLBuiltin; 811 812 for (unsigned Index = 0; Index < GenTypeMaxCnt; Index++) { 813 NewOpenCLBuiltin = FunctionDecl::Create( 814 Context, Parent, Loc, Loc, II, FunctionList[Index], 815 /*TInfo=*/nullptr, SC_Extern, false, 816 FunctionList[Index]->isFunctionProtoType()); 817 NewOpenCLBuiltin->setImplicit(); 818 819 // Create Decl objects for each parameter, adding them to the 820 // FunctionDecl. 821 if (const FunctionProtoType *FP = 822 dyn_cast<FunctionProtoType>(FunctionList[Index])) { 823 SmallVector<ParmVarDecl *, 16> ParmList; 824 for (unsigned IParm = 0, e = FP->getNumParams(); IParm != e; ++IParm) { 825 ParmVarDecl *Parm = ParmVarDecl::Create( 826 Context, NewOpenCLBuiltin, SourceLocation(), SourceLocation(), 827 nullptr, FP->getParamType(IParm), 828 /*TInfo=*/nullptr, SC_None, nullptr); 829 Parm->setScopeInfo(0, IParm); 830 ParmList.push_back(Parm); 831 } 832 NewOpenCLBuiltin->setParams(ParmList); 833 } 834 835 // Add function attributes. 836 if (OpenCLBuiltin.IsPure) 837 NewOpenCLBuiltin->addAttr(PureAttr::CreateImplicit(Context)); 838 if (OpenCLBuiltin.IsConst) 839 NewOpenCLBuiltin->addAttr(ConstAttr::CreateImplicit(Context)); 840 if (OpenCLBuiltin.IsConv) 841 NewOpenCLBuiltin->addAttr(ConvergentAttr::CreateImplicit(Context)); 842 843 if (!S.getLangOpts().OpenCLCPlusPlus) 844 NewOpenCLBuiltin->addAttr(OverloadableAttr::CreateImplicit(Context)); 845 846 AddOpenCLExtensions(S, OpenCLBuiltin, NewOpenCLBuiltin); 847 848 LR.addDecl(NewOpenCLBuiltin); 849 } 850 } 851 852 // If we added overloads, need to resolve the lookup result. 853 if (Len > 1 || HasGenType) 854 LR.resolveKind(); 855 } 856 857 /// Lookup a builtin function, when name lookup would otherwise 858 /// fail. 859 bool Sema::LookupBuiltin(LookupResult &R) { 860 Sema::LookupNameKind NameKind = R.getLookupKind(); 861 862 // If we didn't find a use of this identifier, and if the identifier 863 // corresponds to a compiler builtin, create the decl object for the builtin 864 // now, injecting it into translation unit scope, and return it. 865 if (NameKind == Sema::LookupOrdinaryName || 866 NameKind == Sema::LookupRedeclarationWithLinkage) { 867 IdentifierInfo *II = R.getLookupName().getAsIdentifierInfo(); 868 if (II) { 869 if (getLangOpts().CPlusPlus && NameKind == Sema::LookupOrdinaryName) { 870 if (II == getASTContext().getMakeIntegerSeqName()) { 871 R.addDecl(getASTContext().getMakeIntegerSeqDecl()); 872 return true; 873 } else if (II == getASTContext().getTypePackElementName()) { 874 R.addDecl(getASTContext().getTypePackElementDecl()); 875 return true; 876 } 877 } 878 879 // Check if this is an OpenCL Builtin, and if so, insert its overloads. 880 if (getLangOpts().OpenCL && getLangOpts().DeclareOpenCLBuiltins) { 881 auto Index = isOpenCLBuiltin(II->getName()); 882 if (Index.first) { 883 InsertOCLBuiltinDeclarationsFromTable(*this, R, II, Index.first - 1, 884 Index.second); 885 return true; 886 } 887 } 888 889 // If this is a builtin on this (or all) targets, create the decl. 890 if (unsigned BuiltinID = II->getBuiltinID()) { 891 // In C++ and OpenCL (spec v1.2 s6.9.f), we don't have any predefined 892 // library functions like 'malloc'. Instead, we'll just error. 893 if ((getLangOpts().CPlusPlus || getLangOpts().OpenCL) && 894 Context.BuiltinInfo.isPredefinedLibFunction(BuiltinID)) 895 return false; 896 897 if (NamedDecl *D = LazilyCreateBuiltin((IdentifierInfo *)II, 898 BuiltinID, TUScope, 899 R.isForRedeclaration(), 900 R.getNameLoc())) { 901 R.addDecl(D); 902 return true; 903 } 904 } 905 } 906 } 907 908 return false; 909 } 910 911 /// Determine whether we can declare a special member function within 912 /// the class at this point. 913 static bool CanDeclareSpecialMemberFunction(const CXXRecordDecl *Class) { 914 // We need to have a definition for the class. 915 if (!Class->getDefinition() || Class->isDependentContext()) 916 return false; 917 918 // We can't be in the middle of defining the class. 919 return !Class->isBeingDefined(); 920 } 921 922 void Sema::ForceDeclarationOfImplicitMembers(CXXRecordDecl *Class) { 923 if (!CanDeclareSpecialMemberFunction(Class)) 924 return; 925 926 // If the default constructor has not yet been declared, do so now. 927 if (Class->needsImplicitDefaultConstructor()) 928 DeclareImplicitDefaultConstructor(Class); 929 930 // If the copy constructor has not yet been declared, do so now. 931 if (Class->needsImplicitCopyConstructor()) 932 DeclareImplicitCopyConstructor(Class); 933 934 // If the copy assignment operator has not yet been declared, do so now. 935 if (Class->needsImplicitCopyAssignment()) 936 DeclareImplicitCopyAssignment(Class); 937 938 if (getLangOpts().CPlusPlus11) { 939 // If the move constructor has not yet been declared, do so now. 940 if (Class->needsImplicitMoveConstructor()) 941 DeclareImplicitMoveConstructor(Class); 942 943 // If the move assignment operator has not yet been declared, do so now. 944 if (Class->needsImplicitMoveAssignment()) 945 DeclareImplicitMoveAssignment(Class); 946 } 947 948 // If the destructor has not yet been declared, do so now. 949 if (Class->needsImplicitDestructor()) 950 DeclareImplicitDestructor(Class); 951 } 952 953 /// Determine whether this is the name of an implicitly-declared 954 /// special member function. 955 static bool isImplicitlyDeclaredMemberFunctionName(DeclarationName Name) { 956 switch (Name.getNameKind()) { 957 case DeclarationName::CXXConstructorName: 958 case DeclarationName::CXXDestructorName: 959 return true; 960 961 case DeclarationName::CXXOperatorName: 962 return Name.getCXXOverloadedOperator() == OO_Equal; 963 964 default: 965 break; 966 } 967 968 return false; 969 } 970 971 /// If there are any implicit member functions with the given name 972 /// that need to be declared in the given declaration context, do so. 973 static void DeclareImplicitMemberFunctionsWithName(Sema &S, 974 DeclarationName Name, 975 SourceLocation Loc, 976 const DeclContext *DC) { 977 if (!DC) 978 return; 979 980 switch (Name.getNameKind()) { 981 case DeclarationName::CXXConstructorName: 982 if (const CXXRecordDecl *Record = dyn_cast<CXXRecordDecl>(DC)) 983 if (Record->getDefinition() && CanDeclareSpecialMemberFunction(Record)) { 984 CXXRecordDecl *Class = const_cast<CXXRecordDecl *>(Record); 985 if (Record->needsImplicitDefaultConstructor()) 986 S.DeclareImplicitDefaultConstructor(Class); 987 if (Record->needsImplicitCopyConstructor()) 988 S.DeclareImplicitCopyConstructor(Class); 989 if (S.getLangOpts().CPlusPlus11 && 990 Record->needsImplicitMoveConstructor()) 991 S.DeclareImplicitMoveConstructor(Class); 992 } 993 break; 994 995 case DeclarationName::CXXDestructorName: 996 if (const CXXRecordDecl *Record = dyn_cast<CXXRecordDecl>(DC)) 997 if (Record->getDefinition() && Record->needsImplicitDestructor() && 998 CanDeclareSpecialMemberFunction(Record)) 999 S.DeclareImplicitDestructor(const_cast<CXXRecordDecl *>(Record)); 1000 break; 1001 1002 case DeclarationName::CXXOperatorName: 1003 if (Name.getCXXOverloadedOperator() != OO_Equal) 1004 break; 1005 1006 if (const CXXRecordDecl *Record = dyn_cast<CXXRecordDecl>(DC)) { 1007 if (Record->getDefinition() && CanDeclareSpecialMemberFunction(Record)) { 1008 CXXRecordDecl *Class = const_cast<CXXRecordDecl *>(Record); 1009 if (Record->needsImplicitCopyAssignment()) 1010 S.DeclareImplicitCopyAssignment(Class); 1011 if (S.getLangOpts().CPlusPlus11 && 1012 Record->needsImplicitMoveAssignment()) 1013 S.DeclareImplicitMoveAssignment(Class); 1014 } 1015 } 1016 break; 1017 1018 case DeclarationName::CXXDeductionGuideName: 1019 S.DeclareImplicitDeductionGuides(Name.getCXXDeductionGuideTemplate(), Loc); 1020 break; 1021 1022 default: 1023 break; 1024 } 1025 } 1026 1027 // Adds all qualifying matches for a name within a decl context to the 1028 // given lookup result. Returns true if any matches were found. 1029 static bool LookupDirect(Sema &S, LookupResult &R, const DeclContext *DC) { 1030 bool Found = false; 1031 1032 // Lazily declare C++ special member functions. 1033 if (S.getLangOpts().CPlusPlus) 1034 DeclareImplicitMemberFunctionsWithName(S, R.getLookupName(), R.getNameLoc(), 1035 DC); 1036 1037 // Perform lookup into this declaration context. 1038 DeclContext::lookup_result DR = DC->lookup(R.getLookupName()); 1039 for (NamedDecl *D : DR) { 1040 if ((D = R.getAcceptableDecl(D))) { 1041 R.addDecl(D); 1042 Found = true; 1043 } 1044 } 1045 1046 if (!Found && DC->isTranslationUnit() && S.LookupBuiltin(R)) 1047 return true; 1048 1049 if (R.getLookupName().getNameKind() 1050 != DeclarationName::CXXConversionFunctionName || 1051 R.getLookupName().getCXXNameType()->isDependentType() || 1052 !isa<CXXRecordDecl>(DC)) 1053 return Found; 1054 1055 // C++ [temp.mem]p6: 1056 // A specialization of a conversion function template is not found by 1057 // name lookup. Instead, any conversion function templates visible in the 1058 // context of the use are considered. [...] 1059 const CXXRecordDecl *Record = cast<CXXRecordDecl>(DC); 1060 if (!Record->isCompleteDefinition()) 1061 return Found; 1062 1063 // For conversion operators, 'operator auto' should only match 1064 // 'operator auto'. Since 'auto' is not a type, it shouldn't be considered 1065 // as a candidate for template substitution. 1066 auto *ContainedDeducedType = 1067 R.getLookupName().getCXXNameType()->getContainedDeducedType(); 1068 if (R.getLookupName().getNameKind() == 1069 DeclarationName::CXXConversionFunctionName && 1070 ContainedDeducedType && ContainedDeducedType->isUndeducedType()) 1071 return Found; 1072 1073 for (CXXRecordDecl::conversion_iterator U = Record->conversion_begin(), 1074 UEnd = Record->conversion_end(); U != UEnd; ++U) { 1075 FunctionTemplateDecl *ConvTemplate = dyn_cast<FunctionTemplateDecl>(*U); 1076 if (!ConvTemplate) 1077 continue; 1078 1079 // When we're performing lookup for the purposes of redeclaration, just 1080 // add the conversion function template. When we deduce template 1081 // arguments for specializations, we'll end up unifying the return 1082 // type of the new declaration with the type of the function template. 1083 if (R.isForRedeclaration()) { 1084 R.addDecl(ConvTemplate); 1085 Found = true; 1086 continue; 1087 } 1088 1089 // C++ [temp.mem]p6: 1090 // [...] For each such operator, if argument deduction succeeds 1091 // (14.9.2.3), the resulting specialization is used as if found by 1092 // name lookup. 1093 // 1094 // When referencing a conversion function for any purpose other than 1095 // a redeclaration (such that we'll be building an expression with the 1096 // result), perform template argument deduction and place the 1097 // specialization into the result set. We do this to avoid forcing all 1098 // callers to perform special deduction for conversion functions. 1099 TemplateDeductionInfo Info(R.getNameLoc()); 1100 FunctionDecl *Specialization = nullptr; 1101 1102 const FunctionProtoType *ConvProto 1103 = ConvTemplate->getTemplatedDecl()->getType()->getAs<FunctionProtoType>(); 1104 assert(ConvProto && "Nonsensical conversion function template type"); 1105 1106 // Compute the type of the function that we would expect the conversion 1107 // function to have, if it were to match the name given. 1108 // FIXME: Calling convention! 1109 FunctionProtoType::ExtProtoInfo EPI = ConvProto->getExtProtoInfo(); 1110 EPI.ExtInfo = EPI.ExtInfo.withCallingConv(CC_C); 1111 EPI.ExceptionSpec = EST_None; 1112 QualType ExpectedType 1113 = R.getSema().Context.getFunctionType(R.getLookupName().getCXXNameType(), 1114 None, EPI); 1115 1116 // Perform template argument deduction against the type that we would 1117 // expect the function to have. 1118 if (R.getSema().DeduceTemplateArguments(ConvTemplate, nullptr, ExpectedType, 1119 Specialization, Info) 1120 == Sema::TDK_Success) { 1121 R.addDecl(Specialization); 1122 Found = true; 1123 } 1124 } 1125 1126 return Found; 1127 } 1128 1129 // Performs C++ unqualified lookup into the given file context. 1130 static bool 1131 CppNamespaceLookup(Sema &S, LookupResult &R, ASTContext &Context, 1132 DeclContext *NS, UnqualUsingDirectiveSet &UDirs) { 1133 1134 assert(NS && NS->isFileContext() && "CppNamespaceLookup() requires namespace!"); 1135 1136 // Perform direct name lookup into the LookupCtx. 1137 bool Found = LookupDirect(S, R, NS); 1138 1139 // Perform direct name lookup into the namespaces nominated by the 1140 // using directives whose common ancestor is this namespace. 1141 for (const UnqualUsingEntry &UUE : UDirs.getNamespacesFor(NS)) 1142 if (LookupDirect(S, R, UUE.getNominatedNamespace())) 1143 Found = true; 1144 1145 R.resolveKind(); 1146 1147 return Found; 1148 } 1149 1150 static bool isNamespaceOrTranslationUnitScope(Scope *S) { 1151 if (DeclContext *Ctx = S->getEntity()) 1152 return Ctx->isFileContext(); 1153 return false; 1154 } 1155 1156 // Find the next outer declaration context from this scope. This 1157 // routine actually returns the semantic outer context, which may 1158 // differ from the lexical context (encoded directly in the Scope 1159 // stack) when we are parsing a member of a class template. In this 1160 // case, the second element of the pair will be true, to indicate that 1161 // name lookup should continue searching in this semantic context when 1162 // it leaves the current template parameter scope. 1163 static std::pair<DeclContext *, bool> findOuterContext(Scope *S) { 1164 DeclContext *DC = S->getEntity(); 1165 DeclContext *Lexical = nullptr; 1166 for (Scope *OuterS = S->getParent(); OuterS; 1167 OuterS = OuterS->getParent()) { 1168 if (OuterS->getEntity()) { 1169 Lexical = OuterS->getEntity(); 1170 break; 1171 } 1172 } 1173 1174 // C++ [temp.local]p8: 1175 // In the definition of a member of a class template that appears 1176 // outside of the namespace containing the class template 1177 // definition, the name of a template-parameter hides the name of 1178 // a member of this namespace. 1179 // 1180 // Example: 1181 // 1182 // namespace N { 1183 // class C { }; 1184 // 1185 // template<class T> class B { 1186 // void f(T); 1187 // }; 1188 // } 1189 // 1190 // template<class C> void N::B<C>::f(C) { 1191 // C b; // C is the template parameter, not N::C 1192 // } 1193 // 1194 // In this example, the lexical context we return is the 1195 // TranslationUnit, while the semantic context is the namespace N. 1196 if (!Lexical || !DC || !S->getParent() || 1197 !S->getParent()->isTemplateParamScope()) 1198 return std::make_pair(Lexical, false); 1199 1200 // Find the outermost template parameter scope. 1201 // For the example, this is the scope for the template parameters of 1202 // template<class C>. 1203 Scope *OutermostTemplateScope = S->getParent(); 1204 while (OutermostTemplateScope->getParent() && 1205 OutermostTemplateScope->getParent()->isTemplateParamScope()) 1206 OutermostTemplateScope = OutermostTemplateScope->getParent(); 1207 1208 // Find the namespace context in which the original scope occurs. In 1209 // the example, this is namespace N. 1210 DeclContext *Semantic = DC; 1211 while (!Semantic->isFileContext()) 1212 Semantic = Semantic->getParent(); 1213 1214 // Find the declaration context just outside of the template 1215 // parameter scope. This is the context in which the template is 1216 // being lexically declaration (a namespace context). In the 1217 // example, this is the global scope. 1218 if (Lexical->isFileContext() && !Lexical->Equals(Semantic) && 1219 Lexical->Encloses(Semantic)) 1220 return std::make_pair(Semantic, true); 1221 1222 return std::make_pair(Lexical, false); 1223 } 1224 1225 namespace { 1226 /// An RAII object to specify that we want to find block scope extern 1227 /// declarations. 1228 struct FindLocalExternScope { 1229 FindLocalExternScope(LookupResult &R) 1230 : R(R), OldFindLocalExtern(R.getIdentifierNamespace() & 1231 Decl::IDNS_LocalExtern) { 1232 R.setFindLocalExtern(R.getIdentifierNamespace() & 1233 (Decl::IDNS_Ordinary | Decl::IDNS_NonMemberOperator)); 1234 } 1235 void restore() { 1236 R.setFindLocalExtern(OldFindLocalExtern); 1237 } 1238 ~FindLocalExternScope() { 1239 restore(); 1240 } 1241 LookupResult &R; 1242 bool OldFindLocalExtern; 1243 }; 1244 } // end anonymous namespace 1245 1246 bool Sema::CppLookupName(LookupResult &R, Scope *S) { 1247 assert(getLangOpts().CPlusPlus && "Can perform only C++ lookup"); 1248 1249 DeclarationName Name = R.getLookupName(); 1250 Sema::LookupNameKind NameKind = R.getLookupKind(); 1251 1252 // If this is the name of an implicitly-declared special member function, 1253 // go through the scope stack to implicitly declare 1254 if (isImplicitlyDeclaredMemberFunctionName(Name)) { 1255 for (Scope *PreS = S; PreS; PreS = PreS->getParent()) 1256 if (DeclContext *DC = PreS->getEntity()) 1257 DeclareImplicitMemberFunctionsWithName(*this, Name, R.getNameLoc(), DC); 1258 } 1259 1260 // Implicitly declare member functions with the name we're looking for, if in 1261 // fact we are in a scope where it matters. 1262 1263 Scope *Initial = S; 1264 IdentifierResolver::iterator 1265 I = IdResolver.begin(Name), 1266 IEnd = IdResolver.end(); 1267 1268 // First we lookup local scope. 1269 // We don't consider using-directives, as per 7.3.4.p1 [namespace.udir] 1270 // ...During unqualified name lookup (3.4.1), the names appear as if 1271 // they were declared in the nearest enclosing namespace which contains 1272 // both the using-directive and the nominated namespace. 1273 // [Note: in this context, "contains" means "contains directly or 1274 // indirectly". 1275 // 1276 // For example: 1277 // namespace A { int i; } 1278 // void foo() { 1279 // int i; 1280 // { 1281 // using namespace A; 1282 // ++i; // finds local 'i', A::i appears at global scope 1283 // } 1284 // } 1285 // 1286 UnqualUsingDirectiveSet UDirs(*this); 1287 bool VisitedUsingDirectives = false; 1288 bool LeftStartingScope = false; 1289 DeclContext *OutsideOfTemplateParamDC = nullptr; 1290 1291 // When performing a scope lookup, we want to find local extern decls. 1292 FindLocalExternScope FindLocals(R); 1293 1294 for (; S && !isNamespaceOrTranslationUnitScope(S); S = S->getParent()) { 1295 DeclContext *Ctx = S->getEntity(); 1296 bool SearchNamespaceScope = true; 1297 // Check whether the IdResolver has anything in this scope. 1298 for (; I != IEnd && S->isDeclScope(*I); ++I) { 1299 if (NamedDecl *ND = R.getAcceptableDecl(*I)) { 1300 if (NameKind == LookupRedeclarationWithLinkage && 1301 !(*I)->isTemplateParameter()) { 1302 // If it's a template parameter, we still find it, so we can diagnose 1303 // the invalid redeclaration. 1304 1305 // Determine whether this (or a previous) declaration is 1306 // out-of-scope. 1307 if (!LeftStartingScope && !Initial->isDeclScope(*I)) 1308 LeftStartingScope = true; 1309 1310 // If we found something outside of our starting scope that 1311 // does not have linkage, skip it. 1312 if (LeftStartingScope && !((*I)->hasLinkage())) { 1313 R.setShadowed(); 1314 continue; 1315 } 1316 } else { 1317 // We found something in this scope, we should not look at the 1318 // namespace scope 1319 SearchNamespaceScope = false; 1320 } 1321 R.addDecl(ND); 1322 } 1323 } 1324 if (!SearchNamespaceScope) { 1325 R.resolveKind(); 1326 if (S->isClassScope()) 1327 if (CXXRecordDecl *Record = dyn_cast_or_null<CXXRecordDecl>(Ctx)) 1328 R.setNamingClass(Record); 1329 return true; 1330 } 1331 1332 if (NameKind == LookupLocalFriendName && !S->isClassScope()) { 1333 // C++11 [class.friend]p11: 1334 // If a friend declaration appears in a local class and the name 1335 // specified is an unqualified name, a prior declaration is 1336 // looked up without considering scopes that are outside the 1337 // innermost enclosing non-class scope. 1338 return false; 1339 } 1340 1341 if (!Ctx && S->isTemplateParamScope() && OutsideOfTemplateParamDC && 1342 S->getParent() && !S->getParent()->isTemplateParamScope()) { 1343 // We've just searched the last template parameter scope and 1344 // found nothing, so look into the contexts between the 1345 // lexical and semantic declaration contexts returned by 1346 // findOuterContext(). This implements the name lookup behavior 1347 // of C++ [temp.local]p8. 1348 Ctx = OutsideOfTemplateParamDC; 1349 OutsideOfTemplateParamDC = nullptr; 1350 } 1351 1352 if (Ctx) { 1353 DeclContext *OuterCtx; 1354 bool SearchAfterTemplateScope; 1355 std::tie(OuterCtx, SearchAfterTemplateScope) = findOuterContext(S); 1356 if (SearchAfterTemplateScope) 1357 OutsideOfTemplateParamDC = OuterCtx; 1358 1359 for (; Ctx && !Ctx->Equals(OuterCtx); Ctx = Ctx->getLookupParent()) { 1360 // We do not directly look into transparent contexts, since 1361 // those entities will be found in the nearest enclosing 1362 // non-transparent context. 1363 if (Ctx->isTransparentContext()) 1364 continue; 1365 1366 // We do not look directly into function or method contexts, 1367 // since all of the local variables and parameters of the 1368 // function/method are present within the Scope. 1369 if (Ctx->isFunctionOrMethod()) { 1370 // If we have an Objective-C instance method, look for ivars 1371 // in the corresponding interface. 1372 if (ObjCMethodDecl *Method = dyn_cast<ObjCMethodDecl>(Ctx)) { 1373 if (Method->isInstanceMethod() && Name.getAsIdentifierInfo()) 1374 if (ObjCInterfaceDecl *Class = Method->getClassInterface()) { 1375 ObjCInterfaceDecl *ClassDeclared; 1376 if (ObjCIvarDecl *Ivar = Class->lookupInstanceVariable( 1377 Name.getAsIdentifierInfo(), 1378 ClassDeclared)) { 1379 if (NamedDecl *ND = R.getAcceptableDecl(Ivar)) { 1380 R.addDecl(ND); 1381 R.resolveKind(); 1382 return true; 1383 } 1384 } 1385 } 1386 } 1387 1388 continue; 1389 } 1390 1391 // If this is a file context, we need to perform unqualified name 1392 // lookup considering using directives. 1393 if (Ctx->isFileContext()) { 1394 // If we haven't handled using directives yet, do so now. 1395 if (!VisitedUsingDirectives) { 1396 // Add using directives from this context up to the top level. 1397 for (DeclContext *UCtx = Ctx; UCtx; UCtx = UCtx->getParent()) { 1398 if (UCtx->isTransparentContext()) 1399 continue; 1400 1401 UDirs.visit(UCtx, UCtx); 1402 } 1403 1404 // Find the innermost file scope, so we can add using directives 1405 // from local scopes. 1406 Scope *InnermostFileScope = S; 1407 while (InnermostFileScope && 1408 !isNamespaceOrTranslationUnitScope(InnermostFileScope)) 1409 InnermostFileScope = InnermostFileScope->getParent(); 1410 UDirs.visitScopeChain(Initial, InnermostFileScope); 1411 1412 UDirs.done(); 1413 1414 VisitedUsingDirectives = true; 1415 } 1416 1417 if (CppNamespaceLookup(*this, R, Context, Ctx, UDirs)) { 1418 R.resolveKind(); 1419 return true; 1420 } 1421 1422 continue; 1423 } 1424 1425 // Perform qualified name lookup into this context. 1426 // FIXME: In some cases, we know that every name that could be found by 1427 // this qualified name lookup will also be on the identifier chain. For 1428 // example, inside a class without any base classes, we never need to 1429 // perform qualified lookup because all of the members are on top of the 1430 // identifier chain. 1431 if (LookupQualifiedName(R, Ctx, /*InUnqualifiedLookup=*/true)) 1432 return true; 1433 } 1434 } 1435 } 1436 1437 // Stop if we ran out of scopes. 1438 // FIXME: This really, really shouldn't be happening. 1439 if (!S) return false; 1440 1441 // If we are looking for members, no need to look into global/namespace scope. 1442 if (NameKind == LookupMemberName) 1443 return false; 1444 1445 // Collect UsingDirectiveDecls in all scopes, and recursively all 1446 // nominated namespaces by those using-directives. 1447 // 1448 // FIXME: Cache this sorted list in Scope structure, and DeclContext, so we 1449 // don't build it for each lookup! 1450 if (!VisitedUsingDirectives) { 1451 UDirs.visitScopeChain(Initial, S); 1452 UDirs.done(); 1453 } 1454 1455 // If we're not performing redeclaration lookup, do not look for local 1456 // extern declarations outside of a function scope. 1457 if (!R.isForRedeclaration()) 1458 FindLocals.restore(); 1459 1460 // Lookup namespace scope, and global scope. 1461 // Unqualified name lookup in C++ requires looking into scopes 1462 // that aren't strictly lexical, and therefore we walk through the 1463 // context as well as walking through the scopes. 1464 for (; S; S = S->getParent()) { 1465 // Check whether the IdResolver has anything in this scope. 1466 bool Found = false; 1467 for (; I != IEnd && S->isDeclScope(*I); ++I) { 1468 if (NamedDecl *ND = R.getAcceptableDecl(*I)) { 1469 // We found something. Look for anything else in our scope 1470 // with this same name and in an acceptable identifier 1471 // namespace, so that we can construct an overload set if we 1472 // need to. 1473 Found = true; 1474 R.addDecl(ND); 1475 } 1476 } 1477 1478 if (Found && S->isTemplateParamScope()) { 1479 R.resolveKind(); 1480 return true; 1481 } 1482 1483 DeclContext *Ctx = S->getEntity(); 1484 if (!Ctx && S->isTemplateParamScope() && OutsideOfTemplateParamDC && 1485 S->getParent() && !S->getParent()->isTemplateParamScope()) { 1486 // We've just searched the last template parameter scope and 1487 // found nothing, so look into the contexts between the 1488 // lexical and semantic declaration contexts returned by 1489 // findOuterContext(). This implements the name lookup behavior 1490 // of C++ [temp.local]p8. 1491 Ctx = OutsideOfTemplateParamDC; 1492 OutsideOfTemplateParamDC = nullptr; 1493 } 1494 1495 if (Ctx) { 1496 DeclContext *OuterCtx; 1497 bool SearchAfterTemplateScope; 1498 std::tie(OuterCtx, SearchAfterTemplateScope) = findOuterContext(S); 1499 if (SearchAfterTemplateScope) 1500 OutsideOfTemplateParamDC = OuterCtx; 1501 1502 for (; Ctx && !Ctx->Equals(OuterCtx); Ctx = Ctx->getLookupParent()) { 1503 // We do not directly look into transparent contexts, since 1504 // those entities will be found in the nearest enclosing 1505 // non-transparent context. 1506 if (Ctx->isTransparentContext()) 1507 continue; 1508 1509 // If we have a context, and it's not a context stashed in the 1510 // template parameter scope for an out-of-line definition, also 1511 // look into that context. 1512 if (!(Found && S->isTemplateParamScope())) { 1513 assert(Ctx->isFileContext() && 1514 "We should have been looking only at file context here already."); 1515 1516 // Look into context considering using-directives. 1517 if (CppNamespaceLookup(*this, R, Context, Ctx, UDirs)) 1518 Found = true; 1519 } 1520 1521 if (Found) { 1522 R.resolveKind(); 1523 return true; 1524 } 1525 1526 if (R.isForRedeclaration() && !Ctx->isTransparentContext()) 1527 return false; 1528 } 1529 } 1530 1531 if (R.isForRedeclaration() && Ctx && !Ctx->isTransparentContext()) 1532 return false; 1533 } 1534 1535 return !R.empty(); 1536 } 1537 1538 void Sema::makeMergedDefinitionVisible(NamedDecl *ND) { 1539 if (auto *M = getCurrentModule()) 1540 Context.mergeDefinitionIntoModule(ND, M); 1541 else 1542 // We're not building a module; just make the definition visible. 1543 ND->setVisibleDespiteOwningModule(); 1544 1545 // If ND is a template declaration, make the template parameters 1546 // visible too. They're not (necessarily) within a mergeable DeclContext. 1547 if (auto *TD = dyn_cast<TemplateDecl>(ND)) 1548 for (auto *Param : *TD->getTemplateParameters()) 1549 makeMergedDefinitionVisible(Param); 1550 } 1551 1552 /// Find the module in which the given declaration was defined. 1553 static Module *getDefiningModule(Sema &S, Decl *Entity) { 1554 if (FunctionDecl *FD = dyn_cast<FunctionDecl>(Entity)) { 1555 // If this function was instantiated from a template, the defining module is 1556 // the module containing the pattern. 1557 if (FunctionDecl *Pattern = FD->getTemplateInstantiationPattern()) 1558 Entity = Pattern; 1559 } else if (CXXRecordDecl *RD = dyn_cast<CXXRecordDecl>(Entity)) { 1560 if (CXXRecordDecl *Pattern = RD->getTemplateInstantiationPattern()) 1561 Entity = Pattern; 1562 } else if (EnumDecl *ED = dyn_cast<EnumDecl>(Entity)) { 1563 if (auto *Pattern = ED->getTemplateInstantiationPattern()) 1564 Entity = Pattern; 1565 } else if (VarDecl *VD = dyn_cast<VarDecl>(Entity)) { 1566 if (VarDecl *Pattern = VD->getTemplateInstantiationPattern()) 1567 Entity = Pattern; 1568 } 1569 1570 // Walk up to the containing context. That might also have been instantiated 1571 // from a template. 1572 DeclContext *Context = Entity->getLexicalDeclContext(); 1573 if (Context->isFileContext()) 1574 return S.getOwningModule(Entity); 1575 return getDefiningModule(S, cast<Decl>(Context)); 1576 } 1577 1578 llvm::DenseSet<Module*> &Sema::getLookupModules() { 1579 unsigned N = CodeSynthesisContexts.size(); 1580 for (unsigned I = CodeSynthesisContextLookupModules.size(); 1581 I != N; ++I) { 1582 Module *M = CodeSynthesisContexts[I].Entity ? 1583 getDefiningModule(*this, CodeSynthesisContexts[I].Entity) : 1584 nullptr; 1585 if (M && !LookupModulesCache.insert(M).second) 1586 M = nullptr; 1587 CodeSynthesisContextLookupModules.push_back(M); 1588 } 1589 return LookupModulesCache; 1590 } 1591 1592 /// Determine whether the module M is part of the current module from the 1593 /// perspective of a module-private visibility check. 1594 static bool isInCurrentModule(const Module *M, const LangOptions &LangOpts) { 1595 // If M is the global module fragment of a module that we've not yet finished 1596 // parsing, then it must be part of the current module. 1597 return M->getTopLevelModuleName() == LangOpts.CurrentModule || 1598 (M->Kind == Module::GlobalModuleFragment && !M->Parent); 1599 } 1600 1601 bool Sema::hasVisibleMergedDefinition(NamedDecl *Def) { 1602 for (const Module *Merged : Context.getModulesWithMergedDefinition(Def)) 1603 if (isModuleVisible(Merged)) 1604 return true; 1605 return false; 1606 } 1607 1608 bool Sema::hasMergedDefinitionInCurrentModule(NamedDecl *Def) { 1609 for (const Module *Merged : Context.getModulesWithMergedDefinition(Def)) 1610 if (isInCurrentModule(Merged, getLangOpts())) 1611 return true; 1612 return false; 1613 } 1614 1615 template<typename ParmDecl> 1616 static bool 1617 hasVisibleDefaultArgument(Sema &S, const ParmDecl *D, 1618 llvm::SmallVectorImpl<Module *> *Modules) { 1619 if (!D->hasDefaultArgument()) 1620 return false; 1621 1622 while (D) { 1623 auto &DefaultArg = D->getDefaultArgStorage(); 1624 if (!DefaultArg.isInherited() && S.isVisible(D)) 1625 return true; 1626 1627 if (!DefaultArg.isInherited() && Modules) { 1628 auto *NonConstD = const_cast<ParmDecl*>(D); 1629 Modules->push_back(S.getOwningModule(NonConstD)); 1630 } 1631 1632 // If there was a previous default argument, maybe its parameter is visible. 1633 D = DefaultArg.getInheritedFrom(); 1634 } 1635 return false; 1636 } 1637 1638 bool Sema::hasVisibleDefaultArgument(const NamedDecl *D, 1639 llvm::SmallVectorImpl<Module *> *Modules) { 1640 if (auto *P = dyn_cast<TemplateTypeParmDecl>(D)) 1641 return ::hasVisibleDefaultArgument(*this, P, Modules); 1642 if (auto *P = dyn_cast<NonTypeTemplateParmDecl>(D)) 1643 return ::hasVisibleDefaultArgument(*this, P, Modules); 1644 return ::hasVisibleDefaultArgument(*this, cast<TemplateTemplateParmDecl>(D), 1645 Modules); 1646 } 1647 1648 template<typename Filter> 1649 static bool hasVisibleDeclarationImpl(Sema &S, const NamedDecl *D, 1650 llvm::SmallVectorImpl<Module *> *Modules, 1651 Filter F) { 1652 bool HasFilteredRedecls = false; 1653 1654 for (auto *Redecl : D->redecls()) { 1655 auto *R = cast<NamedDecl>(Redecl); 1656 if (!F(R)) 1657 continue; 1658 1659 if (S.isVisible(R)) 1660 return true; 1661 1662 HasFilteredRedecls = true; 1663 1664 if (Modules) 1665 Modules->push_back(R->getOwningModule()); 1666 } 1667 1668 // Only return false if there is at least one redecl that is not filtered out. 1669 if (HasFilteredRedecls) 1670 return false; 1671 1672 return true; 1673 } 1674 1675 bool Sema::hasVisibleExplicitSpecialization( 1676 const NamedDecl *D, llvm::SmallVectorImpl<Module *> *Modules) { 1677 return hasVisibleDeclarationImpl(*this, D, Modules, [](const NamedDecl *D) { 1678 if (auto *RD = dyn_cast<CXXRecordDecl>(D)) 1679 return RD->getTemplateSpecializationKind() == TSK_ExplicitSpecialization; 1680 if (auto *FD = dyn_cast<FunctionDecl>(D)) 1681 return FD->getTemplateSpecializationKind() == TSK_ExplicitSpecialization; 1682 if (auto *VD = dyn_cast<VarDecl>(D)) 1683 return VD->getTemplateSpecializationKind() == TSK_ExplicitSpecialization; 1684 llvm_unreachable("unknown explicit specialization kind"); 1685 }); 1686 } 1687 1688 bool Sema::hasVisibleMemberSpecialization( 1689 const NamedDecl *D, llvm::SmallVectorImpl<Module *> *Modules) { 1690 assert(isa<CXXRecordDecl>(D->getDeclContext()) && 1691 "not a member specialization"); 1692 return hasVisibleDeclarationImpl(*this, D, Modules, [](const NamedDecl *D) { 1693 // If the specialization is declared at namespace scope, then it's a member 1694 // specialization declaration. If it's lexically inside the class 1695 // definition then it was instantiated. 1696 // 1697 // FIXME: This is a hack. There should be a better way to determine this. 1698 // FIXME: What about MS-style explicit specializations declared within a 1699 // class definition? 1700 return D->getLexicalDeclContext()->isFileContext(); 1701 }); 1702 } 1703 1704 /// Determine whether a declaration is visible to name lookup. 1705 /// 1706 /// This routine determines whether the declaration D is visible in the current 1707 /// lookup context, taking into account the current template instantiation 1708 /// stack. During template instantiation, a declaration is visible if it is 1709 /// visible from a module containing any entity on the template instantiation 1710 /// path (by instantiating a template, you allow it to see the declarations that 1711 /// your module can see, including those later on in your module). 1712 bool LookupResult::isVisibleSlow(Sema &SemaRef, NamedDecl *D) { 1713 assert(!D->isUnconditionallyVisible() && 1714 "should not call this: not in slow case"); 1715 1716 Module *DeclModule = SemaRef.getOwningModule(D); 1717 assert(DeclModule && "hidden decl has no owning module"); 1718 1719 // If the owning module is visible, the decl is visible. 1720 if (SemaRef.isModuleVisible(DeclModule, D->isModulePrivate())) 1721 return true; 1722 1723 // Determine whether a decl context is a file context for the purpose of 1724 // visibility. This looks through some (export and linkage spec) transparent 1725 // contexts, but not others (enums). 1726 auto IsEffectivelyFileContext = [](const DeclContext *DC) { 1727 return DC->isFileContext() || isa<LinkageSpecDecl>(DC) || 1728 isa<ExportDecl>(DC); 1729 }; 1730 1731 // If this declaration is not at namespace scope 1732 // then it is visible if its lexical parent has a visible definition. 1733 DeclContext *DC = D->getLexicalDeclContext(); 1734 if (DC && !IsEffectivelyFileContext(DC)) { 1735 // For a parameter, check whether our current template declaration's 1736 // lexical context is visible, not whether there's some other visible 1737 // definition of it, because parameters aren't "within" the definition. 1738 // 1739 // In C++ we need to check for a visible definition due to ODR merging, 1740 // and in C we must not because each declaration of a function gets its own 1741 // set of declarations for tags in prototype scope. 1742 bool VisibleWithinParent; 1743 if (D->isTemplateParameter()) { 1744 bool SearchDefinitions = true; 1745 if (const auto *DCD = dyn_cast<Decl>(DC)) { 1746 if (const auto *TD = DCD->getDescribedTemplate()) { 1747 TemplateParameterList *TPL = TD->getTemplateParameters(); 1748 auto Index = getDepthAndIndex(D).second; 1749 SearchDefinitions = Index >= TPL->size() || TPL->getParam(Index) != D; 1750 } 1751 } 1752 if (SearchDefinitions) 1753 VisibleWithinParent = SemaRef.hasVisibleDefinition(cast<NamedDecl>(DC)); 1754 else 1755 VisibleWithinParent = isVisible(SemaRef, cast<NamedDecl>(DC)); 1756 } else if (isa<ParmVarDecl>(D) || 1757 (isa<FunctionDecl>(DC) && !SemaRef.getLangOpts().CPlusPlus)) 1758 VisibleWithinParent = isVisible(SemaRef, cast<NamedDecl>(DC)); 1759 else if (D->isModulePrivate()) { 1760 // A module-private declaration is only visible if an enclosing lexical 1761 // parent was merged with another definition in the current module. 1762 VisibleWithinParent = false; 1763 do { 1764 if (SemaRef.hasMergedDefinitionInCurrentModule(cast<NamedDecl>(DC))) { 1765 VisibleWithinParent = true; 1766 break; 1767 } 1768 DC = DC->getLexicalParent(); 1769 } while (!IsEffectivelyFileContext(DC)); 1770 } else { 1771 VisibleWithinParent = SemaRef.hasVisibleDefinition(cast<NamedDecl>(DC)); 1772 } 1773 1774 if (VisibleWithinParent && SemaRef.CodeSynthesisContexts.empty() && 1775 // FIXME: Do something better in this case. 1776 !SemaRef.getLangOpts().ModulesLocalVisibility) { 1777 // Cache the fact that this declaration is implicitly visible because 1778 // its parent has a visible definition. 1779 D->setVisibleDespiteOwningModule(); 1780 } 1781 return VisibleWithinParent; 1782 } 1783 1784 return false; 1785 } 1786 1787 bool Sema::isModuleVisible(const Module *M, bool ModulePrivate) { 1788 // The module might be ordinarily visible. For a module-private query, that 1789 // means it is part of the current module. For any other query, that means it 1790 // is in our visible module set. 1791 if (ModulePrivate) { 1792 if (isInCurrentModule(M, getLangOpts())) 1793 return true; 1794 } else { 1795 if (VisibleModules.isVisible(M)) 1796 return true; 1797 } 1798 1799 // Otherwise, it might be visible by virtue of the query being within a 1800 // template instantiation or similar that is permitted to look inside M. 1801 1802 // Find the extra places where we need to look. 1803 const auto &LookupModules = getLookupModules(); 1804 if (LookupModules.empty()) 1805 return false; 1806 1807 // If our lookup set contains the module, it's visible. 1808 if (LookupModules.count(M)) 1809 return true; 1810 1811 // For a module-private query, that's everywhere we get to look. 1812 if (ModulePrivate) 1813 return false; 1814 1815 // Check whether M is transitively exported to an import of the lookup set. 1816 return llvm::any_of(LookupModules, [&](const Module *LookupM) { 1817 return LookupM->isModuleVisible(M); 1818 }); 1819 } 1820 1821 bool Sema::isVisibleSlow(const NamedDecl *D) { 1822 return LookupResult::isVisible(*this, const_cast<NamedDecl*>(D)); 1823 } 1824 1825 bool Sema::shouldLinkPossiblyHiddenDecl(LookupResult &R, const NamedDecl *New) { 1826 // FIXME: If there are both visible and hidden declarations, we need to take 1827 // into account whether redeclaration is possible. Example: 1828 // 1829 // Non-imported module: 1830 // int f(T); // #1 1831 // Some TU: 1832 // static int f(U); // #2, not a redeclaration of #1 1833 // int f(T); // #3, finds both, should link with #1 if T != U, but 1834 // // with #2 if T == U; neither should be ambiguous. 1835 for (auto *D : R) { 1836 if (isVisible(D)) 1837 return true; 1838 assert(D->isExternallyDeclarable() && 1839 "should not have hidden, non-externally-declarable result here"); 1840 } 1841 1842 // This function is called once "New" is essentially complete, but before a 1843 // previous declaration is attached. We can't query the linkage of "New" in 1844 // general, because attaching the previous declaration can change the 1845 // linkage of New to match the previous declaration. 1846 // 1847 // However, because we've just determined that there is no *visible* prior 1848 // declaration, we can compute the linkage here. There are two possibilities: 1849 // 1850 // * This is not a redeclaration; it's safe to compute the linkage now. 1851 // 1852 // * This is a redeclaration of a prior declaration that is externally 1853 // redeclarable. In that case, the linkage of the declaration is not 1854 // changed by attaching the prior declaration, because both are externally 1855 // declarable (and thus ExternalLinkage or VisibleNoLinkage). 1856 // 1857 // FIXME: This is subtle and fragile. 1858 return New->isExternallyDeclarable(); 1859 } 1860 1861 /// Retrieve the visible declaration corresponding to D, if any. 1862 /// 1863 /// This routine determines whether the declaration D is visible in the current 1864 /// module, with the current imports. If not, it checks whether any 1865 /// redeclaration of D is visible, and if so, returns that declaration. 1866 /// 1867 /// \returns D, or a visible previous declaration of D, whichever is more recent 1868 /// and visible. If no declaration of D is visible, returns null. 1869 static NamedDecl *findAcceptableDecl(Sema &SemaRef, NamedDecl *D, 1870 unsigned IDNS) { 1871 assert(!LookupResult::isVisible(SemaRef, D) && "not in slow case"); 1872 1873 for (auto RD : D->redecls()) { 1874 // Don't bother with extra checks if we already know this one isn't visible. 1875 if (RD == D) 1876 continue; 1877 1878 auto ND = cast<NamedDecl>(RD); 1879 // FIXME: This is wrong in the case where the previous declaration is not 1880 // visible in the same scope as D. This needs to be done much more 1881 // carefully. 1882 if (ND->isInIdentifierNamespace(IDNS) && 1883 LookupResult::isVisible(SemaRef, ND)) 1884 return ND; 1885 } 1886 1887 return nullptr; 1888 } 1889 1890 bool Sema::hasVisibleDeclarationSlow(const NamedDecl *D, 1891 llvm::SmallVectorImpl<Module *> *Modules) { 1892 assert(!isVisible(D) && "not in slow case"); 1893 return hasVisibleDeclarationImpl(*this, D, Modules, 1894 [](const NamedDecl *) { return true; }); 1895 } 1896 1897 NamedDecl *LookupResult::getAcceptableDeclSlow(NamedDecl *D) const { 1898 if (auto *ND = dyn_cast<NamespaceDecl>(D)) { 1899 // Namespaces are a bit of a special case: we expect there to be a lot of 1900 // redeclarations of some namespaces, all declarations of a namespace are 1901 // essentially interchangeable, all declarations are found by name lookup 1902 // if any is, and namespaces are never looked up during template 1903 // instantiation. So we benefit from caching the check in this case, and 1904 // it is correct to do so. 1905 auto *Key = ND->getCanonicalDecl(); 1906 if (auto *Acceptable = getSema().VisibleNamespaceCache.lookup(Key)) 1907 return Acceptable; 1908 auto *Acceptable = isVisible(getSema(), Key) 1909 ? Key 1910 : findAcceptableDecl(getSema(), Key, IDNS); 1911 if (Acceptable) 1912 getSema().VisibleNamespaceCache.insert(std::make_pair(Key, Acceptable)); 1913 return Acceptable; 1914 } 1915 1916 return findAcceptableDecl(getSema(), D, IDNS); 1917 } 1918 1919 /// Perform unqualified name lookup starting from a given 1920 /// scope. 1921 /// 1922 /// Unqualified name lookup (C++ [basic.lookup.unqual], C99 6.2.1) is 1923 /// used to find names within the current scope. For example, 'x' in 1924 /// @code 1925 /// int x; 1926 /// int f() { 1927 /// return x; // unqualified name look finds 'x' in the global scope 1928 /// } 1929 /// @endcode 1930 /// 1931 /// Different lookup criteria can find different names. For example, a 1932 /// particular scope can have both a struct and a function of the same 1933 /// name, and each can be found by certain lookup criteria. For more 1934 /// information about lookup criteria, see the documentation for the 1935 /// class LookupCriteria. 1936 /// 1937 /// @param S The scope from which unqualified name lookup will 1938 /// begin. If the lookup criteria permits, name lookup may also search 1939 /// in the parent scopes. 1940 /// 1941 /// @param [in,out] R Specifies the lookup to perform (e.g., the name to 1942 /// look up and the lookup kind), and is updated with the results of lookup 1943 /// including zero or more declarations and possibly additional information 1944 /// used to diagnose ambiguities. 1945 /// 1946 /// @returns \c true if lookup succeeded and false otherwise. 1947 bool Sema::LookupName(LookupResult &R, Scope *S, bool AllowBuiltinCreation) { 1948 DeclarationName Name = R.getLookupName(); 1949 if (!Name) return false; 1950 1951 LookupNameKind NameKind = R.getLookupKind(); 1952 1953 if (!getLangOpts().CPlusPlus) { 1954 // Unqualified name lookup in C/Objective-C is purely lexical, so 1955 // search in the declarations attached to the name. 1956 if (NameKind == Sema::LookupRedeclarationWithLinkage) { 1957 // Find the nearest non-transparent declaration scope. 1958 while (!(S->getFlags() & Scope::DeclScope) || 1959 (S->getEntity() && S->getEntity()->isTransparentContext())) 1960 S = S->getParent(); 1961 } 1962 1963 // When performing a scope lookup, we want to find local extern decls. 1964 FindLocalExternScope FindLocals(R); 1965 1966 // Scan up the scope chain looking for a decl that matches this 1967 // identifier that is in the appropriate namespace. This search 1968 // should not take long, as shadowing of names is uncommon, and 1969 // deep shadowing is extremely uncommon. 1970 bool LeftStartingScope = false; 1971 1972 for (IdentifierResolver::iterator I = IdResolver.begin(Name), 1973 IEnd = IdResolver.end(); 1974 I != IEnd; ++I) 1975 if (NamedDecl *D = R.getAcceptableDecl(*I)) { 1976 if (NameKind == LookupRedeclarationWithLinkage) { 1977 // Determine whether this (or a previous) declaration is 1978 // out-of-scope. 1979 if (!LeftStartingScope && !S->isDeclScope(*I)) 1980 LeftStartingScope = true; 1981 1982 // If we found something outside of our starting scope that 1983 // does not have linkage, skip it. 1984 if (LeftStartingScope && !((*I)->hasLinkage())) { 1985 R.setShadowed(); 1986 continue; 1987 } 1988 } 1989 else if (NameKind == LookupObjCImplicitSelfParam && 1990 !isa<ImplicitParamDecl>(*I)) 1991 continue; 1992 1993 R.addDecl(D); 1994 1995 // Check whether there are any other declarations with the same name 1996 // and in the same scope. 1997 if (I != IEnd) { 1998 // Find the scope in which this declaration was declared (if it 1999 // actually exists in a Scope). 2000 while (S && !S->isDeclScope(D)) 2001 S = S->getParent(); 2002 2003 // If the scope containing the declaration is the translation unit, 2004 // then we'll need to perform our checks based on the matching 2005 // DeclContexts rather than matching scopes. 2006 if (S && isNamespaceOrTranslationUnitScope(S)) 2007 S = nullptr; 2008 2009 // Compute the DeclContext, if we need it. 2010 DeclContext *DC = nullptr; 2011 if (!S) 2012 DC = (*I)->getDeclContext()->getRedeclContext(); 2013 2014 IdentifierResolver::iterator LastI = I; 2015 for (++LastI; LastI != IEnd; ++LastI) { 2016 if (S) { 2017 // Match based on scope. 2018 if (!S->isDeclScope(*LastI)) 2019 break; 2020 } else { 2021 // Match based on DeclContext. 2022 DeclContext *LastDC 2023 = (*LastI)->getDeclContext()->getRedeclContext(); 2024 if (!LastDC->Equals(DC)) 2025 break; 2026 } 2027 2028 // If the declaration is in the right namespace and visible, add it. 2029 if (NamedDecl *LastD = R.getAcceptableDecl(*LastI)) 2030 R.addDecl(LastD); 2031 } 2032 2033 R.resolveKind(); 2034 } 2035 2036 return true; 2037 } 2038 } else { 2039 // Perform C++ unqualified name lookup. 2040 if (CppLookupName(R, S)) 2041 return true; 2042 } 2043 2044 // If we didn't find a use of this identifier, and if the identifier 2045 // corresponds to a compiler builtin, create the decl object for the builtin 2046 // now, injecting it into translation unit scope, and return it. 2047 if (AllowBuiltinCreation && LookupBuiltin(R)) 2048 return true; 2049 2050 // If we didn't find a use of this identifier, the ExternalSource 2051 // may be able to handle the situation. 2052 // Note: some lookup failures are expected! 2053 // See e.g. R.isForRedeclaration(). 2054 return (ExternalSource && ExternalSource->LookupUnqualified(R, S)); 2055 } 2056 2057 /// Perform qualified name lookup in the namespaces nominated by 2058 /// using directives by the given context. 2059 /// 2060 /// C++98 [namespace.qual]p2: 2061 /// Given X::m (where X is a user-declared namespace), or given \::m 2062 /// (where X is the global namespace), let S be the set of all 2063 /// declarations of m in X and in the transitive closure of all 2064 /// namespaces nominated by using-directives in X and its used 2065 /// namespaces, except that using-directives are ignored in any 2066 /// namespace, including X, directly containing one or more 2067 /// declarations of m. No namespace is searched more than once in 2068 /// the lookup of a name. If S is the empty set, the program is 2069 /// ill-formed. Otherwise, if S has exactly one member, or if the 2070 /// context of the reference is a using-declaration 2071 /// (namespace.udecl), S is the required set of declarations of 2072 /// m. Otherwise if the use of m is not one that allows a unique 2073 /// declaration to be chosen from S, the program is ill-formed. 2074 /// 2075 /// C++98 [namespace.qual]p5: 2076 /// During the lookup of a qualified namespace member name, if the 2077 /// lookup finds more than one declaration of the member, and if one 2078 /// declaration introduces a class name or enumeration name and the 2079 /// other declarations either introduce the same object, the same 2080 /// enumerator or a set of functions, the non-type name hides the 2081 /// class or enumeration name if and only if the declarations are 2082 /// from the same namespace; otherwise (the declarations are from 2083 /// different namespaces), the program is ill-formed. 2084 static bool LookupQualifiedNameInUsingDirectives(Sema &S, LookupResult &R, 2085 DeclContext *StartDC) { 2086 assert(StartDC->isFileContext() && "start context is not a file context"); 2087 2088 // We have not yet looked into these namespaces, much less added 2089 // their "using-children" to the queue. 2090 SmallVector<NamespaceDecl*, 8> Queue; 2091 2092 // We have at least added all these contexts to the queue. 2093 llvm::SmallPtrSet<DeclContext*, 8> Visited; 2094 Visited.insert(StartDC); 2095 2096 // We have already looked into the initial namespace; seed the queue 2097 // with its using-children. 2098 for (auto *I : StartDC->using_directives()) { 2099 NamespaceDecl *ND = I->getNominatedNamespace()->getOriginalNamespace(); 2100 if (S.isVisible(I) && Visited.insert(ND).second) 2101 Queue.push_back(ND); 2102 } 2103 2104 // The easiest way to implement the restriction in [namespace.qual]p5 2105 // is to check whether any of the individual results found a tag 2106 // and, if so, to declare an ambiguity if the final result is not 2107 // a tag. 2108 bool FoundTag = false; 2109 bool FoundNonTag = false; 2110 2111 LookupResult LocalR(LookupResult::Temporary, R); 2112 2113 bool Found = false; 2114 while (!Queue.empty()) { 2115 NamespaceDecl *ND = Queue.pop_back_val(); 2116 2117 // We go through some convolutions here to avoid copying results 2118 // between LookupResults. 2119 bool UseLocal = !R.empty(); 2120 LookupResult &DirectR = UseLocal ? LocalR : R; 2121 bool FoundDirect = LookupDirect(S, DirectR, ND); 2122 2123 if (FoundDirect) { 2124 // First do any local hiding. 2125 DirectR.resolveKind(); 2126 2127 // If the local result is a tag, remember that. 2128 if (DirectR.isSingleTagDecl()) 2129 FoundTag = true; 2130 else 2131 FoundNonTag = true; 2132 2133 // Append the local results to the total results if necessary. 2134 if (UseLocal) { 2135 R.addAllDecls(LocalR); 2136 LocalR.clear(); 2137 } 2138 } 2139 2140 // If we find names in this namespace, ignore its using directives. 2141 if (FoundDirect) { 2142 Found = true; 2143 continue; 2144 } 2145 2146 for (auto I : ND->using_directives()) { 2147 NamespaceDecl *Nom = I->getNominatedNamespace(); 2148 if (S.isVisible(I) && Visited.insert(Nom).second) 2149 Queue.push_back(Nom); 2150 } 2151 } 2152 2153 if (Found) { 2154 if (FoundTag && FoundNonTag) 2155 R.setAmbiguousQualifiedTagHiding(); 2156 else 2157 R.resolveKind(); 2158 } 2159 2160 return Found; 2161 } 2162 2163 /// Callback that looks for any member of a class with the given name. 2164 static bool LookupAnyMember(const CXXBaseSpecifier *Specifier, 2165 CXXBasePath &Path, DeclarationName Name) { 2166 RecordDecl *BaseRecord = Specifier->getType()->castAs<RecordType>()->getDecl(); 2167 2168 Path.Decls = BaseRecord->lookup(Name); 2169 return !Path.Decls.empty(); 2170 } 2171 2172 /// Determine whether the given set of member declarations contains only 2173 /// static members, nested types, and enumerators. 2174 template<typename InputIterator> 2175 static bool HasOnlyStaticMembers(InputIterator First, InputIterator Last) { 2176 Decl *D = (*First)->getUnderlyingDecl(); 2177 if (isa<VarDecl>(D) || isa<TypeDecl>(D) || isa<EnumConstantDecl>(D)) 2178 return true; 2179 2180 if (isa<CXXMethodDecl>(D)) { 2181 // Determine whether all of the methods are static. 2182 bool AllMethodsAreStatic = true; 2183 for(; First != Last; ++First) { 2184 D = (*First)->getUnderlyingDecl(); 2185 2186 if (!isa<CXXMethodDecl>(D)) { 2187 assert(isa<TagDecl>(D) && "Non-function must be a tag decl"); 2188 break; 2189 } 2190 2191 if (!cast<CXXMethodDecl>(D)->isStatic()) { 2192 AllMethodsAreStatic = false; 2193 break; 2194 } 2195 } 2196 2197 if (AllMethodsAreStatic) 2198 return true; 2199 } 2200 2201 return false; 2202 } 2203 2204 /// Perform qualified name lookup into a given context. 2205 /// 2206 /// Qualified name lookup (C++ [basic.lookup.qual]) is used to find 2207 /// names when the context of those names is explicit specified, e.g., 2208 /// "std::vector" or "x->member", or as part of unqualified name lookup. 2209 /// 2210 /// Different lookup criteria can find different names. For example, a 2211 /// particular scope can have both a struct and a function of the same 2212 /// name, and each can be found by certain lookup criteria. For more 2213 /// information about lookup criteria, see the documentation for the 2214 /// class LookupCriteria. 2215 /// 2216 /// \param R captures both the lookup criteria and any lookup results found. 2217 /// 2218 /// \param LookupCtx The context in which qualified name lookup will 2219 /// search. If the lookup criteria permits, name lookup may also search 2220 /// in the parent contexts or (for C++ classes) base classes. 2221 /// 2222 /// \param InUnqualifiedLookup true if this is qualified name lookup that 2223 /// occurs as part of unqualified name lookup. 2224 /// 2225 /// \returns true if lookup succeeded, false if it failed. 2226 bool Sema::LookupQualifiedName(LookupResult &R, DeclContext *LookupCtx, 2227 bool InUnqualifiedLookup) { 2228 assert(LookupCtx && "Sema::LookupQualifiedName requires a lookup context"); 2229 2230 if (!R.getLookupName()) 2231 return false; 2232 2233 // Make sure that the declaration context is complete. 2234 assert((!isa<TagDecl>(LookupCtx) || 2235 LookupCtx->isDependentContext() || 2236 cast<TagDecl>(LookupCtx)->isCompleteDefinition() || 2237 cast<TagDecl>(LookupCtx)->isBeingDefined()) && 2238 "Declaration context must already be complete!"); 2239 2240 struct QualifiedLookupInScope { 2241 bool oldVal; 2242 DeclContext *Context; 2243 // Set flag in DeclContext informing debugger that we're looking for qualified name 2244 QualifiedLookupInScope(DeclContext *ctx) : Context(ctx) { 2245 oldVal = ctx->setUseQualifiedLookup(); 2246 } 2247 ~QualifiedLookupInScope() { 2248 Context->setUseQualifiedLookup(oldVal); 2249 } 2250 } QL(LookupCtx); 2251 2252 if (LookupDirect(*this, R, LookupCtx)) { 2253 R.resolveKind(); 2254 if (isa<CXXRecordDecl>(LookupCtx)) 2255 R.setNamingClass(cast<CXXRecordDecl>(LookupCtx)); 2256 return true; 2257 } 2258 2259 // Don't descend into implied contexts for redeclarations. 2260 // C++98 [namespace.qual]p6: 2261 // In a declaration for a namespace member in which the 2262 // declarator-id is a qualified-id, given that the qualified-id 2263 // for the namespace member has the form 2264 // nested-name-specifier unqualified-id 2265 // the unqualified-id shall name a member of the namespace 2266 // designated by the nested-name-specifier. 2267 // See also [class.mfct]p5 and [class.static.data]p2. 2268 if (R.isForRedeclaration()) 2269 return false; 2270 2271 // If this is a namespace, look it up in the implied namespaces. 2272 if (LookupCtx->isFileContext()) 2273 return LookupQualifiedNameInUsingDirectives(*this, R, LookupCtx); 2274 2275 // If this isn't a C++ class, we aren't allowed to look into base 2276 // classes, we're done. 2277 CXXRecordDecl *LookupRec = dyn_cast<CXXRecordDecl>(LookupCtx); 2278 if (!LookupRec || !LookupRec->getDefinition()) 2279 return false; 2280 2281 // If we're performing qualified name lookup into a dependent class, 2282 // then we are actually looking into a current instantiation. If we have any 2283 // dependent base classes, then we either have to delay lookup until 2284 // template instantiation time (at which point all bases will be available) 2285 // or we have to fail. 2286 if (!InUnqualifiedLookup && LookupRec->isDependentContext() && 2287 LookupRec->hasAnyDependentBases()) { 2288 R.setNotFoundInCurrentInstantiation(); 2289 return false; 2290 } 2291 2292 // Perform lookup into our base classes. 2293 CXXBasePaths Paths; 2294 Paths.setOrigin(LookupRec); 2295 2296 // Look for this member in our base classes 2297 bool (*BaseCallback)(const CXXBaseSpecifier *Specifier, CXXBasePath &Path, 2298 DeclarationName Name) = nullptr; 2299 switch (R.getLookupKind()) { 2300 case LookupObjCImplicitSelfParam: 2301 case LookupOrdinaryName: 2302 case LookupMemberName: 2303 case LookupRedeclarationWithLinkage: 2304 case LookupLocalFriendName: 2305 case LookupDestructorName: 2306 BaseCallback = &CXXRecordDecl::FindOrdinaryMember; 2307 break; 2308 2309 case LookupTagName: 2310 BaseCallback = &CXXRecordDecl::FindTagMember; 2311 break; 2312 2313 case LookupAnyName: 2314 BaseCallback = &LookupAnyMember; 2315 break; 2316 2317 case LookupOMPReductionName: 2318 BaseCallback = &CXXRecordDecl::FindOMPReductionMember; 2319 break; 2320 2321 case LookupOMPMapperName: 2322 BaseCallback = &CXXRecordDecl::FindOMPMapperMember; 2323 break; 2324 2325 case LookupUsingDeclName: 2326 // This lookup is for redeclarations only. 2327 2328 case LookupOperatorName: 2329 case LookupNamespaceName: 2330 case LookupObjCProtocolName: 2331 case LookupLabel: 2332 // These lookups will never find a member in a C++ class (or base class). 2333 return false; 2334 2335 case LookupNestedNameSpecifierName: 2336 BaseCallback = &CXXRecordDecl::FindNestedNameSpecifierMember; 2337 break; 2338 } 2339 2340 DeclarationName Name = R.getLookupName(); 2341 if (!LookupRec->lookupInBases( 2342 [=](const CXXBaseSpecifier *Specifier, CXXBasePath &Path) { 2343 return BaseCallback(Specifier, Path, Name); 2344 }, 2345 Paths)) 2346 return false; 2347 2348 R.setNamingClass(LookupRec); 2349 2350 // C++ [class.member.lookup]p2: 2351 // [...] If the resulting set of declarations are not all from 2352 // sub-objects of the same type, or the set has a nonstatic member 2353 // and includes members from distinct sub-objects, there is an 2354 // ambiguity and the program is ill-formed. Otherwise that set is 2355 // the result of the lookup. 2356 QualType SubobjectType; 2357 int SubobjectNumber = 0; 2358 AccessSpecifier SubobjectAccess = AS_none; 2359 2360 for (CXXBasePaths::paths_iterator Path = Paths.begin(), PathEnd = Paths.end(); 2361 Path != PathEnd; ++Path) { 2362 const CXXBasePathElement &PathElement = Path->back(); 2363 2364 // Pick the best (i.e. most permissive i.e. numerically lowest) access 2365 // across all paths. 2366 SubobjectAccess = std::min(SubobjectAccess, Path->Access); 2367 2368 // Determine whether we're looking at a distinct sub-object or not. 2369 if (SubobjectType.isNull()) { 2370 // This is the first subobject we've looked at. Record its type. 2371 SubobjectType = Context.getCanonicalType(PathElement.Base->getType()); 2372 SubobjectNumber = PathElement.SubobjectNumber; 2373 continue; 2374 } 2375 2376 if (SubobjectType 2377 != Context.getCanonicalType(PathElement.Base->getType())) { 2378 // We found members of the given name in two subobjects of 2379 // different types. If the declaration sets aren't the same, this 2380 // lookup is ambiguous. 2381 if (HasOnlyStaticMembers(Path->Decls.begin(), Path->Decls.end())) { 2382 CXXBasePaths::paths_iterator FirstPath = Paths.begin(); 2383 DeclContext::lookup_iterator FirstD = FirstPath->Decls.begin(); 2384 DeclContext::lookup_iterator CurrentD = Path->Decls.begin(); 2385 2386 // Get the decl that we should use for deduplicating this lookup. 2387 auto GetRepresentativeDecl = [&](NamedDecl *D) -> Decl * { 2388 // C++ [temp.local]p3: 2389 // A lookup that finds an injected-class-name (10.2) can result in 2390 // an ambiguity in certain cases (for example, if it is found in 2391 // more than one base class). If all of the injected-class-names 2392 // that are found refer to specializations of the same class 2393 // template, and if the name is used as a template-name, the 2394 // reference refers to the class template itself and not a 2395 // specialization thereof, and is not ambiguous. 2396 if (R.isTemplateNameLookup()) 2397 if (auto *TD = getAsTemplateNameDecl(D)) 2398 D = TD; 2399 return D->getUnderlyingDecl()->getCanonicalDecl(); 2400 }; 2401 2402 while (FirstD != FirstPath->Decls.end() && 2403 CurrentD != Path->Decls.end()) { 2404 if (GetRepresentativeDecl(*FirstD) != 2405 GetRepresentativeDecl(*CurrentD)) 2406 break; 2407 2408 ++FirstD; 2409 ++CurrentD; 2410 } 2411 2412 if (FirstD == FirstPath->Decls.end() && 2413 CurrentD == Path->Decls.end()) 2414 continue; 2415 } 2416 2417 R.setAmbiguousBaseSubobjectTypes(Paths); 2418 return true; 2419 } 2420 2421 if (SubobjectNumber != PathElement.SubobjectNumber) { 2422 // We have a different subobject of the same type. 2423 2424 // C++ [class.member.lookup]p5: 2425 // A static member, a nested type or an enumerator defined in 2426 // a base class T can unambiguously be found even if an object 2427 // has more than one base class subobject of type T. 2428 if (HasOnlyStaticMembers(Path->Decls.begin(), Path->Decls.end())) 2429 continue; 2430 2431 // We have found a nonstatic member name in multiple, distinct 2432 // subobjects. Name lookup is ambiguous. 2433 R.setAmbiguousBaseSubobjects(Paths); 2434 return true; 2435 } 2436 } 2437 2438 // Lookup in a base class succeeded; return these results. 2439 2440 for (auto *D : Paths.front().Decls) { 2441 AccessSpecifier AS = CXXRecordDecl::MergeAccess(SubobjectAccess, 2442 D->getAccess()); 2443 R.addDecl(D, AS); 2444 } 2445 R.resolveKind(); 2446 return true; 2447 } 2448 2449 /// Performs qualified name lookup or special type of lookup for 2450 /// "__super::" scope specifier. 2451 /// 2452 /// This routine is a convenience overload meant to be called from contexts 2453 /// that need to perform a qualified name lookup with an optional C++ scope 2454 /// specifier that might require special kind of lookup. 2455 /// 2456 /// \param R captures both the lookup criteria and any lookup results found. 2457 /// 2458 /// \param LookupCtx The context in which qualified name lookup will 2459 /// search. 2460 /// 2461 /// \param SS An optional C++ scope-specifier. 2462 /// 2463 /// \returns true if lookup succeeded, false if it failed. 2464 bool Sema::LookupQualifiedName(LookupResult &R, DeclContext *LookupCtx, 2465 CXXScopeSpec &SS) { 2466 auto *NNS = SS.getScopeRep(); 2467 if (NNS && NNS->getKind() == NestedNameSpecifier::Super) 2468 return LookupInSuper(R, NNS->getAsRecordDecl()); 2469 else 2470 2471 return LookupQualifiedName(R, LookupCtx); 2472 } 2473 2474 /// Performs name lookup for a name that was parsed in the 2475 /// source code, and may contain a C++ scope specifier. 2476 /// 2477 /// This routine is a convenience routine meant to be called from 2478 /// contexts that receive a name and an optional C++ scope specifier 2479 /// (e.g., "N::M::x"). It will then perform either qualified or 2480 /// unqualified name lookup (with LookupQualifiedName or LookupName, 2481 /// respectively) on the given name and return those results. It will 2482 /// perform a special type of lookup for "__super::" scope specifier. 2483 /// 2484 /// @param S The scope from which unqualified name lookup will 2485 /// begin. 2486 /// 2487 /// @param SS An optional C++ scope-specifier, e.g., "::N::M". 2488 /// 2489 /// @param EnteringContext Indicates whether we are going to enter the 2490 /// context of the scope-specifier SS (if present). 2491 /// 2492 /// @returns True if any decls were found (but possibly ambiguous) 2493 bool Sema::LookupParsedName(LookupResult &R, Scope *S, CXXScopeSpec *SS, 2494 bool AllowBuiltinCreation, bool EnteringContext) { 2495 if (SS && SS->isInvalid()) { 2496 // When the scope specifier is invalid, don't even look for 2497 // anything. 2498 return false; 2499 } 2500 2501 if (SS && SS->isSet()) { 2502 NestedNameSpecifier *NNS = SS->getScopeRep(); 2503 if (NNS->getKind() == NestedNameSpecifier::Super) 2504 return LookupInSuper(R, NNS->getAsRecordDecl()); 2505 2506 if (DeclContext *DC = computeDeclContext(*SS, EnteringContext)) { 2507 // We have resolved the scope specifier to a particular declaration 2508 // contex, and will perform name lookup in that context. 2509 if (!DC->isDependentContext() && RequireCompleteDeclContext(*SS, DC)) 2510 return false; 2511 2512 R.setContextRange(SS->getRange()); 2513 return LookupQualifiedName(R, DC); 2514 } 2515 2516 // We could not resolve the scope specified to a specific declaration 2517 // context, which means that SS refers to an unknown specialization. 2518 // Name lookup can't find anything in this case. 2519 R.setNotFoundInCurrentInstantiation(); 2520 R.setContextRange(SS->getRange()); 2521 return false; 2522 } 2523 2524 // Perform unqualified name lookup starting in the given scope. 2525 return LookupName(R, S, AllowBuiltinCreation); 2526 } 2527 2528 /// Perform qualified name lookup into all base classes of the given 2529 /// class. 2530 /// 2531 /// \param R captures both the lookup criteria and any lookup results found. 2532 /// 2533 /// \param Class The context in which qualified name lookup will 2534 /// search. Name lookup will search in all base classes merging the results. 2535 /// 2536 /// @returns True if any decls were found (but possibly ambiguous) 2537 bool Sema::LookupInSuper(LookupResult &R, CXXRecordDecl *Class) { 2538 // The access-control rules we use here are essentially the rules for 2539 // doing a lookup in Class that just magically skipped the direct 2540 // members of Class itself. That is, the naming class is Class, and the 2541 // access includes the access of the base. 2542 for (const auto &BaseSpec : Class->bases()) { 2543 CXXRecordDecl *RD = cast<CXXRecordDecl>( 2544 BaseSpec.getType()->castAs<RecordType>()->getDecl()); 2545 LookupResult Result(*this, R.getLookupNameInfo(), R.getLookupKind()); 2546 Result.setBaseObjectType(Context.getRecordType(Class)); 2547 LookupQualifiedName(Result, RD); 2548 2549 // Copy the lookup results into the target, merging the base's access into 2550 // the path access. 2551 for (auto I = Result.begin(), E = Result.end(); I != E; ++I) { 2552 R.addDecl(I.getDecl(), 2553 CXXRecordDecl::MergeAccess(BaseSpec.getAccessSpecifier(), 2554 I.getAccess())); 2555 } 2556 2557 Result.suppressDiagnostics(); 2558 } 2559 2560 R.resolveKind(); 2561 R.setNamingClass(Class); 2562 2563 return !R.empty(); 2564 } 2565 2566 /// Produce a diagnostic describing the ambiguity that resulted 2567 /// from name lookup. 2568 /// 2569 /// \param Result The result of the ambiguous lookup to be diagnosed. 2570 void Sema::DiagnoseAmbiguousLookup(LookupResult &Result) { 2571 assert(Result.isAmbiguous() && "Lookup result must be ambiguous"); 2572 2573 DeclarationName Name = Result.getLookupName(); 2574 SourceLocation NameLoc = Result.getNameLoc(); 2575 SourceRange LookupRange = Result.getContextRange(); 2576 2577 switch (Result.getAmbiguityKind()) { 2578 case LookupResult::AmbiguousBaseSubobjects: { 2579 CXXBasePaths *Paths = Result.getBasePaths(); 2580 QualType SubobjectType = Paths->front().back().Base->getType(); 2581 Diag(NameLoc, diag::err_ambiguous_member_multiple_subobjects) 2582 << Name << SubobjectType << getAmbiguousPathsDisplayString(*Paths) 2583 << LookupRange; 2584 2585 DeclContext::lookup_iterator Found = Paths->front().Decls.begin(); 2586 while (isa<CXXMethodDecl>(*Found) && 2587 cast<CXXMethodDecl>(*Found)->isStatic()) 2588 ++Found; 2589 2590 Diag((*Found)->getLocation(), diag::note_ambiguous_member_found); 2591 break; 2592 } 2593 2594 case LookupResult::AmbiguousBaseSubobjectTypes: { 2595 Diag(NameLoc, diag::err_ambiguous_member_multiple_subobject_types) 2596 << Name << LookupRange; 2597 2598 CXXBasePaths *Paths = Result.getBasePaths(); 2599 std::set<Decl *> DeclsPrinted; 2600 for (CXXBasePaths::paths_iterator Path = Paths->begin(), 2601 PathEnd = Paths->end(); 2602 Path != PathEnd; ++Path) { 2603 Decl *D = Path->Decls.front(); 2604 if (DeclsPrinted.insert(D).second) 2605 Diag(D->getLocation(), diag::note_ambiguous_member_found); 2606 } 2607 break; 2608 } 2609 2610 case LookupResult::AmbiguousTagHiding: { 2611 Diag(NameLoc, diag::err_ambiguous_tag_hiding) << Name << LookupRange; 2612 2613 llvm::SmallPtrSet<NamedDecl*, 8> TagDecls; 2614 2615 for (auto *D : Result) 2616 if (TagDecl *TD = dyn_cast<TagDecl>(D)) { 2617 TagDecls.insert(TD); 2618 Diag(TD->getLocation(), diag::note_hidden_tag); 2619 } 2620 2621 for (auto *D : Result) 2622 if (!isa<TagDecl>(D)) 2623 Diag(D->getLocation(), diag::note_hiding_object); 2624 2625 // For recovery purposes, go ahead and implement the hiding. 2626 LookupResult::Filter F = Result.makeFilter(); 2627 while (F.hasNext()) { 2628 if (TagDecls.count(F.next())) 2629 F.erase(); 2630 } 2631 F.done(); 2632 break; 2633 } 2634 2635 case LookupResult::AmbiguousReference: { 2636 Diag(NameLoc, diag::err_ambiguous_reference) << Name << LookupRange; 2637 2638 for (auto *D : Result) 2639 Diag(D->getLocation(), diag::note_ambiguous_candidate) << D; 2640 break; 2641 } 2642 } 2643 } 2644 2645 namespace { 2646 struct AssociatedLookup { 2647 AssociatedLookup(Sema &S, SourceLocation InstantiationLoc, 2648 Sema::AssociatedNamespaceSet &Namespaces, 2649 Sema::AssociatedClassSet &Classes) 2650 : S(S), Namespaces(Namespaces), Classes(Classes), 2651 InstantiationLoc(InstantiationLoc) { 2652 } 2653 2654 bool addClassTransitive(CXXRecordDecl *RD) { 2655 Classes.insert(RD); 2656 return ClassesTransitive.insert(RD); 2657 } 2658 2659 Sema &S; 2660 Sema::AssociatedNamespaceSet &Namespaces; 2661 Sema::AssociatedClassSet &Classes; 2662 SourceLocation InstantiationLoc; 2663 2664 private: 2665 Sema::AssociatedClassSet ClassesTransitive; 2666 }; 2667 } // end anonymous namespace 2668 2669 static void 2670 addAssociatedClassesAndNamespaces(AssociatedLookup &Result, QualType T); 2671 2672 // Given the declaration context \param Ctx of a class, class template or 2673 // enumeration, add the associated namespaces to \param Namespaces as described 2674 // in [basic.lookup.argdep]p2. 2675 static void CollectEnclosingNamespace(Sema::AssociatedNamespaceSet &Namespaces, 2676 DeclContext *Ctx) { 2677 // The exact wording has been changed in C++14 as a result of 2678 // CWG 1691 (see also CWG 1690 and CWG 1692). We apply it unconditionally 2679 // to all language versions since it is possible to return a local type 2680 // from a lambda in C++11. 2681 // 2682 // C++14 [basic.lookup.argdep]p2: 2683 // If T is a class type [...]. Its associated namespaces are the innermost 2684 // enclosing namespaces of its associated classes. [...] 2685 // 2686 // If T is an enumeration type, its associated namespace is the innermost 2687 // enclosing namespace of its declaration. [...] 2688 2689 // We additionally skip inline namespaces. The innermost non-inline namespace 2690 // contains all names of all its nested inline namespaces anyway, so we can 2691 // replace the entire inline namespace tree with its root. 2692 while (!Ctx->isFileContext() || Ctx->isInlineNamespace()) 2693 Ctx = Ctx->getParent(); 2694 2695 Namespaces.insert(Ctx->getPrimaryContext()); 2696 } 2697 2698 // Add the associated classes and namespaces for argument-dependent 2699 // lookup that involves a template argument (C++ [basic.lookup.argdep]p2). 2700 static void 2701 addAssociatedClassesAndNamespaces(AssociatedLookup &Result, 2702 const TemplateArgument &Arg) { 2703 // C++ [basic.lookup.argdep]p2, last bullet: 2704 // -- [...] ; 2705 switch (Arg.getKind()) { 2706 case TemplateArgument::Null: 2707 break; 2708 2709 case TemplateArgument::Type: 2710 // [...] the namespaces and classes associated with the types of the 2711 // template arguments provided for template type parameters (excluding 2712 // template template parameters) 2713 addAssociatedClassesAndNamespaces(Result, Arg.getAsType()); 2714 break; 2715 2716 case TemplateArgument::Template: 2717 case TemplateArgument::TemplateExpansion: { 2718 // [...] the namespaces in which any template template arguments are 2719 // defined; and the classes in which any member templates used as 2720 // template template arguments are defined. 2721 TemplateName Template = Arg.getAsTemplateOrTemplatePattern(); 2722 if (ClassTemplateDecl *ClassTemplate 2723 = dyn_cast<ClassTemplateDecl>(Template.getAsTemplateDecl())) { 2724 DeclContext *Ctx = ClassTemplate->getDeclContext(); 2725 if (CXXRecordDecl *EnclosingClass = dyn_cast<CXXRecordDecl>(Ctx)) 2726 Result.Classes.insert(EnclosingClass); 2727 // Add the associated namespace for this class. 2728 CollectEnclosingNamespace(Result.Namespaces, Ctx); 2729 } 2730 break; 2731 } 2732 2733 case TemplateArgument::Declaration: 2734 case TemplateArgument::Integral: 2735 case TemplateArgument::Expression: 2736 case TemplateArgument::NullPtr: 2737 // [Note: non-type template arguments do not contribute to the set of 2738 // associated namespaces. ] 2739 break; 2740 2741 case TemplateArgument::Pack: 2742 for (const auto &P : Arg.pack_elements()) 2743 addAssociatedClassesAndNamespaces(Result, P); 2744 break; 2745 } 2746 } 2747 2748 // Add the associated classes and namespaces for argument-dependent lookup 2749 // with an argument of class type (C++ [basic.lookup.argdep]p2). 2750 static void 2751 addAssociatedClassesAndNamespaces(AssociatedLookup &Result, 2752 CXXRecordDecl *Class) { 2753 2754 // Just silently ignore anything whose name is __va_list_tag. 2755 if (Class->getDeclName() == Result.S.VAListTagName) 2756 return; 2757 2758 // C++ [basic.lookup.argdep]p2: 2759 // [...] 2760 // -- If T is a class type (including unions), its associated 2761 // classes are: the class itself; the class of which it is a 2762 // member, if any; and its direct and indirect base classes. 2763 // Its associated namespaces are the innermost enclosing 2764 // namespaces of its associated classes. 2765 2766 // Add the class of which it is a member, if any. 2767 DeclContext *Ctx = Class->getDeclContext(); 2768 if (CXXRecordDecl *EnclosingClass = dyn_cast<CXXRecordDecl>(Ctx)) 2769 Result.Classes.insert(EnclosingClass); 2770 2771 // Add the associated namespace for this class. 2772 CollectEnclosingNamespace(Result.Namespaces, Ctx); 2773 2774 // -- If T is a template-id, its associated namespaces and classes are 2775 // the namespace in which the template is defined; for member 2776 // templates, the member template's class; the namespaces and classes 2777 // associated with the types of the template arguments provided for 2778 // template type parameters (excluding template template parameters); the 2779 // namespaces in which any template template arguments are defined; and 2780 // the classes in which any member templates used as template template 2781 // arguments are defined. [Note: non-type template arguments do not 2782 // contribute to the set of associated namespaces. ] 2783 if (ClassTemplateSpecializationDecl *Spec 2784 = dyn_cast<ClassTemplateSpecializationDecl>(Class)) { 2785 DeclContext *Ctx = Spec->getSpecializedTemplate()->getDeclContext(); 2786 if (CXXRecordDecl *EnclosingClass = dyn_cast<CXXRecordDecl>(Ctx)) 2787 Result.Classes.insert(EnclosingClass); 2788 // Add the associated namespace for this class. 2789 CollectEnclosingNamespace(Result.Namespaces, Ctx); 2790 2791 const TemplateArgumentList &TemplateArgs = Spec->getTemplateArgs(); 2792 for (unsigned I = 0, N = TemplateArgs.size(); I != N; ++I) 2793 addAssociatedClassesAndNamespaces(Result, TemplateArgs[I]); 2794 } 2795 2796 // Add the class itself. If we've already transitively visited this class, 2797 // we don't need to visit base classes. 2798 if (!Result.addClassTransitive(Class)) 2799 return; 2800 2801 // Only recurse into base classes for complete types. 2802 if (!Result.S.isCompleteType(Result.InstantiationLoc, 2803 Result.S.Context.getRecordType(Class))) 2804 return; 2805 2806 // Add direct and indirect base classes along with their associated 2807 // namespaces. 2808 SmallVector<CXXRecordDecl *, 32> Bases; 2809 Bases.push_back(Class); 2810 while (!Bases.empty()) { 2811 // Pop this class off the stack. 2812 Class = Bases.pop_back_val(); 2813 2814 // Visit the base classes. 2815 for (const auto &Base : Class->bases()) { 2816 const RecordType *BaseType = Base.getType()->getAs<RecordType>(); 2817 // In dependent contexts, we do ADL twice, and the first time around, 2818 // the base type might be a dependent TemplateSpecializationType, or a 2819 // TemplateTypeParmType. If that happens, simply ignore it. 2820 // FIXME: If we want to support export, we probably need to add the 2821 // namespace of the template in a TemplateSpecializationType, or even 2822 // the classes and namespaces of known non-dependent arguments. 2823 if (!BaseType) 2824 continue; 2825 CXXRecordDecl *BaseDecl = cast<CXXRecordDecl>(BaseType->getDecl()); 2826 if (Result.addClassTransitive(BaseDecl)) { 2827 // Find the associated namespace for this base class. 2828 DeclContext *BaseCtx = BaseDecl->getDeclContext(); 2829 CollectEnclosingNamespace(Result.Namespaces, BaseCtx); 2830 2831 // Make sure we visit the bases of this base class. 2832 if (BaseDecl->bases_begin() != BaseDecl->bases_end()) 2833 Bases.push_back(BaseDecl); 2834 } 2835 } 2836 } 2837 } 2838 2839 // Add the associated classes and namespaces for 2840 // argument-dependent lookup with an argument of type T 2841 // (C++ [basic.lookup.koenig]p2). 2842 static void 2843 addAssociatedClassesAndNamespaces(AssociatedLookup &Result, QualType Ty) { 2844 // C++ [basic.lookup.koenig]p2: 2845 // 2846 // For each argument type T in the function call, there is a set 2847 // of zero or more associated namespaces and a set of zero or more 2848 // associated classes to be considered. The sets of namespaces and 2849 // classes is determined entirely by the types of the function 2850 // arguments (and the namespace of any template template 2851 // argument). Typedef names and using-declarations used to specify 2852 // the types do not contribute to this set. The sets of namespaces 2853 // and classes are determined in the following way: 2854 2855 SmallVector<const Type *, 16> Queue; 2856 const Type *T = Ty->getCanonicalTypeInternal().getTypePtr(); 2857 2858 while (true) { 2859 switch (T->getTypeClass()) { 2860 2861 #define TYPE(Class, Base) 2862 #define DEPENDENT_TYPE(Class, Base) case Type::Class: 2863 #define NON_CANONICAL_TYPE(Class, Base) case Type::Class: 2864 #define NON_CANONICAL_UNLESS_DEPENDENT_TYPE(Class, Base) case Type::Class: 2865 #define ABSTRACT_TYPE(Class, Base) 2866 #include "clang/AST/TypeNodes.inc" 2867 // T is canonical. We can also ignore dependent types because 2868 // we don't need to do ADL at the definition point, but if we 2869 // wanted to implement template export (or if we find some other 2870 // use for associated classes and namespaces...) this would be 2871 // wrong. 2872 break; 2873 2874 // -- If T is a pointer to U or an array of U, its associated 2875 // namespaces and classes are those associated with U. 2876 case Type::Pointer: 2877 T = cast<PointerType>(T)->getPointeeType().getTypePtr(); 2878 continue; 2879 case Type::ConstantArray: 2880 case Type::IncompleteArray: 2881 case Type::VariableArray: 2882 T = cast<ArrayType>(T)->getElementType().getTypePtr(); 2883 continue; 2884 2885 // -- If T is a fundamental type, its associated sets of 2886 // namespaces and classes are both empty. 2887 case Type::Builtin: 2888 break; 2889 2890 // -- If T is a class type (including unions), its associated 2891 // classes are: the class itself; the class of which it is 2892 // a member, if any; and its direct and indirect base classes. 2893 // Its associated namespaces are the innermost enclosing 2894 // namespaces of its associated classes. 2895 case Type::Record: { 2896 CXXRecordDecl *Class = 2897 cast<CXXRecordDecl>(cast<RecordType>(T)->getDecl()); 2898 addAssociatedClassesAndNamespaces(Result, Class); 2899 break; 2900 } 2901 2902 // -- If T is an enumeration type, its associated namespace 2903 // is the innermost enclosing namespace of its declaration. 2904 // If it is a class member, its associated class is the 2905 // member’s class; else it has no associated class. 2906 case Type::Enum: { 2907 EnumDecl *Enum = cast<EnumType>(T)->getDecl(); 2908 2909 DeclContext *Ctx = Enum->getDeclContext(); 2910 if (CXXRecordDecl *EnclosingClass = dyn_cast<CXXRecordDecl>(Ctx)) 2911 Result.Classes.insert(EnclosingClass); 2912 2913 // Add the associated namespace for this enumeration. 2914 CollectEnclosingNamespace(Result.Namespaces, Ctx); 2915 2916 break; 2917 } 2918 2919 // -- If T is a function type, its associated namespaces and 2920 // classes are those associated with the function parameter 2921 // types and those associated with the return type. 2922 case Type::FunctionProto: { 2923 const FunctionProtoType *Proto = cast<FunctionProtoType>(T); 2924 for (const auto &Arg : Proto->param_types()) 2925 Queue.push_back(Arg.getTypePtr()); 2926 // fallthrough 2927 LLVM_FALLTHROUGH; 2928 } 2929 case Type::FunctionNoProto: { 2930 const FunctionType *FnType = cast<FunctionType>(T); 2931 T = FnType->getReturnType().getTypePtr(); 2932 continue; 2933 } 2934 2935 // -- If T is a pointer to a member function of a class X, its 2936 // associated namespaces and classes are those associated 2937 // with the function parameter types and return type, 2938 // together with those associated with X. 2939 // 2940 // -- If T is a pointer to a data member of class X, its 2941 // associated namespaces and classes are those associated 2942 // with the member type together with those associated with 2943 // X. 2944 case Type::MemberPointer: { 2945 const MemberPointerType *MemberPtr = cast<MemberPointerType>(T); 2946 2947 // Queue up the class type into which this points. 2948 Queue.push_back(MemberPtr->getClass()); 2949 2950 // And directly continue with the pointee type. 2951 T = MemberPtr->getPointeeType().getTypePtr(); 2952 continue; 2953 } 2954 2955 // As an extension, treat this like a normal pointer. 2956 case Type::BlockPointer: 2957 T = cast<BlockPointerType>(T)->getPointeeType().getTypePtr(); 2958 continue; 2959 2960 // References aren't covered by the standard, but that's such an 2961 // obvious defect that we cover them anyway. 2962 case Type::LValueReference: 2963 case Type::RValueReference: 2964 T = cast<ReferenceType>(T)->getPointeeType().getTypePtr(); 2965 continue; 2966 2967 // These are fundamental types. 2968 case Type::Vector: 2969 case Type::ExtVector: 2970 case Type::ConstantMatrix: 2971 case Type::Complex: 2972 case Type::ExtInt: 2973 break; 2974 2975 // Non-deduced auto types only get here for error cases. 2976 case Type::Auto: 2977 case Type::DeducedTemplateSpecialization: 2978 break; 2979 2980 // If T is an Objective-C object or interface type, or a pointer to an 2981 // object or interface type, the associated namespace is the global 2982 // namespace. 2983 case Type::ObjCObject: 2984 case Type::ObjCInterface: 2985 case Type::ObjCObjectPointer: 2986 Result.Namespaces.insert(Result.S.Context.getTranslationUnitDecl()); 2987 break; 2988 2989 // Atomic types are just wrappers; use the associations of the 2990 // contained type. 2991 case Type::Atomic: 2992 T = cast<AtomicType>(T)->getValueType().getTypePtr(); 2993 continue; 2994 case Type::Pipe: 2995 T = cast<PipeType>(T)->getElementType().getTypePtr(); 2996 continue; 2997 } 2998 2999 if (Queue.empty()) 3000 break; 3001 T = Queue.pop_back_val(); 3002 } 3003 } 3004 3005 /// Find the associated classes and namespaces for 3006 /// argument-dependent lookup for a call with the given set of 3007 /// arguments. 3008 /// 3009 /// This routine computes the sets of associated classes and associated 3010 /// namespaces searched by argument-dependent lookup 3011 /// (C++ [basic.lookup.argdep]) for a given set of arguments. 3012 void Sema::FindAssociatedClassesAndNamespaces( 3013 SourceLocation InstantiationLoc, ArrayRef<Expr *> Args, 3014 AssociatedNamespaceSet &AssociatedNamespaces, 3015 AssociatedClassSet &AssociatedClasses) { 3016 AssociatedNamespaces.clear(); 3017 AssociatedClasses.clear(); 3018 3019 AssociatedLookup Result(*this, InstantiationLoc, 3020 AssociatedNamespaces, AssociatedClasses); 3021 3022 // C++ [basic.lookup.koenig]p2: 3023 // For each argument type T in the function call, there is a set 3024 // of zero or more associated namespaces and a set of zero or more 3025 // associated classes to be considered. The sets of namespaces and 3026 // classes is determined entirely by the types of the function 3027 // arguments (and the namespace of any template template 3028 // argument). 3029 for (unsigned ArgIdx = 0; ArgIdx != Args.size(); ++ArgIdx) { 3030 Expr *Arg = Args[ArgIdx]; 3031 3032 if (Arg->getType() != Context.OverloadTy) { 3033 addAssociatedClassesAndNamespaces(Result, Arg->getType()); 3034 continue; 3035 } 3036 3037 // [...] In addition, if the argument is the name or address of a 3038 // set of overloaded functions and/or function templates, its 3039 // associated classes and namespaces are the union of those 3040 // associated with each of the members of the set: the namespace 3041 // in which the function or function template is defined and the 3042 // classes and namespaces associated with its (non-dependent) 3043 // parameter types and return type. 3044 OverloadExpr *OE = OverloadExpr::find(Arg).Expression; 3045 3046 for (const NamedDecl *D : OE->decls()) { 3047 // Look through any using declarations to find the underlying function. 3048 const FunctionDecl *FDecl = D->getUnderlyingDecl()->getAsFunction(); 3049 3050 // Add the classes and namespaces associated with the parameter 3051 // types and return type of this function. 3052 addAssociatedClassesAndNamespaces(Result, FDecl->getType()); 3053 } 3054 } 3055 } 3056 3057 NamedDecl *Sema::LookupSingleName(Scope *S, DeclarationName Name, 3058 SourceLocation Loc, 3059 LookupNameKind NameKind, 3060 RedeclarationKind Redecl) { 3061 LookupResult R(*this, Name, Loc, NameKind, Redecl); 3062 LookupName(R, S); 3063 return R.getAsSingle<NamedDecl>(); 3064 } 3065 3066 /// Find the protocol with the given name, if any. 3067 ObjCProtocolDecl *Sema::LookupProtocol(IdentifierInfo *II, 3068 SourceLocation IdLoc, 3069 RedeclarationKind Redecl) { 3070 Decl *D = LookupSingleName(TUScope, II, IdLoc, 3071 LookupObjCProtocolName, Redecl); 3072 return cast_or_null<ObjCProtocolDecl>(D); 3073 } 3074 3075 void Sema::LookupOverloadedOperatorName(OverloadedOperatorKind Op, Scope *S, 3076 QualType T1, QualType T2, 3077 UnresolvedSetImpl &Functions) { 3078 // C++ [over.match.oper]p3: 3079 // -- The set of non-member candidates is the result of the 3080 // unqualified lookup of operator@ in the context of the 3081 // expression according to the usual rules for name lookup in 3082 // unqualified function calls (3.4.2) except that all member 3083 // functions are ignored. 3084 DeclarationName OpName = Context.DeclarationNames.getCXXOperatorName(Op); 3085 LookupResult Operators(*this, OpName, SourceLocation(), LookupOperatorName); 3086 LookupName(Operators, S); 3087 3088 assert(!Operators.isAmbiguous() && "Operator lookup cannot be ambiguous"); 3089 Functions.append(Operators.begin(), Operators.end()); 3090 } 3091 3092 Sema::SpecialMemberOverloadResult Sema::LookupSpecialMember(CXXRecordDecl *RD, 3093 CXXSpecialMember SM, 3094 bool ConstArg, 3095 bool VolatileArg, 3096 bool RValueThis, 3097 bool ConstThis, 3098 bool VolatileThis) { 3099 assert(CanDeclareSpecialMemberFunction(RD) && 3100 "doing special member lookup into record that isn't fully complete"); 3101 RD = RD->getDefinition(); 3102 if (RValueThis || ConstThis || VolatileThis) 3103 assert((SM == CXXCopyAssignment || SM == CXXMoveAssignment) && 3104 "constructors and destructors always have unqualified lvalue this"); 3105 if (ConstArg || VolatileArg) 3106 assert((SM != CXXDefaultConstructor && SM != CXXDestructor) && 3107 "parameter-less special members can't have qualified arguments"); 3108 3109 // FIXME: Get the caller to pass in a location for the lookup. 3110 SourceLocation LookupLoc = RD->getLocation(); 3111 3112 llvm::FoldingSetNodeID ID; 3113 ID.AddPointer(RD); 3114 ID.AddInteger(SM); 3115 ID.AddInteger(ConstArg); 3116 ID.AddInteger(VolatileArg); 3117 ID.AddInteger(RValueThis); 3118 ID.AddInteger(ConstThis); 3119 ID.AddInteger(VolatileThis); 3120 3121 void *InsertPoint; 3122 SpecialMemberOverloadResultEntry *Result = 3123 SpecialMemberCache.FindNodeOrInsertPos(ID, InsertPoint); 3124 3125 // This was already cached 3126 if (Result) 3127 return *Result; 3128 3129 Result = BumpAlloc.Allocate<SpecialMemberOverloadResultEntry>(); 3130 Result = new (Result) SpecialMemberOverloadResultEntry(ID); 3131 SpecialMemberCache.InsertNode(Result, InsertPoint); 3132 3133 if (SM == CXXDestructor) { 3134 if (RD->needsImplicitDestructor()) { 3135 runWithSufficientStackSpace(RD->getLocation(), [&] { 3136 DeclareImplicitDestructor(RD); 3137 }); 3138 } 3139 CXXDestructorDecl *DD = RD->getDestructor(); 3140 Result->setMethod(DD); 3141 Result->setKind(DD && !DD->isDeleted() 3142 ? SpecialMemberOverloadResult::Success 3143 : SpecialMemberOverloadResult::NoMemberOrDeleted); 3144 return *Result; 3145 } 3146 3147 // Prepare for overload resolution. Here we construct a synthetic argument 3148 // if necessary and make sure that implicit functions are declared. 3149 CanQualType CanTy = Context.getCanonicalType(Context.getTagDeclType(RD)); 3150 DeclarationName Name; 3151 Expr *Arg = nullptr; 3152 unsigned NumArgs; 3153 3154 QualType ArgType = CanTy; 3155 ExprValueKind VK = VK_LValue; 3156 3157 if (SM == CXXDefaultConstructor) { 3158 Name = Context.DeclarationNames.getCXXConstructorName(CanTy); 3159 NumArgs = 0; 3160 if (RD->needsImplicitDefaultConstructor()) { 3161 runWithSufficientStackSpace(RD->getLocation(), [&] { 3162 DeclareImplicitDefaultConstructor(RD); 3163 }); 3164 } 3165 } else { 3166 if (SM == CXXCopyConstructor || SM == CXXMoveConstructor) { 3167 Name = Context.DeclarationNames.getCXXConstructorName(CanTy); 3168 if (RD->needsImplicitCopyConstructor()) { 3169 runWithSufficientStackSpace(RD->getLocation(), [&] { 3170 DeclareImplicitCopyConstructor(RD); 3171 }); 3172 } 3173 if (getLangOpts().CPlusPlus11 && RD->needsImplicitMoveConstructor()) { 3174 runWithSufficientStackSpace(RD->getLocation(), [&] { 3175 DeclareImplicitMoveConstructor(RD); 3176 }); 3177 } 3178 } else { 3179 Name = Context.DeclarationNames.getCXXOperatorName(OO_Equal); 3180 if (RD->needsImplicitCopyAssignment()) { 3181 runWithSufficientStackSpace(RD->getLocation(), [&] { 3182 DeclareImplicitCopyAssignment(RD); 3183 }); 3184 } 3185 if (getLangOpts().CPlusPlus11 && RD->needsImplicitMoveAssignment()) { 3186 runWithSufficientStackSpace(RD->getLocation(), [&] { 3187 DeclareImplicitMoveAssignment(RD); 3188 }); 3189 } 3190 } 3191 3192 if (ConstArg) 3193 ArgType.addConst(); 3194 if (VolatileArg) 3195 ArgType.addVolatile(); 3196 3197 // This isn't /really/ specified by the standard, but it's implied 3198 // we should be working from an RValue in the case of move to ensure 3199 // that we prefer to bind to rvalue references, and an LValue in the 3200 // case of copy to ensure we don't bind to rvalue references. 3201 // Possibly an XValue is actually correct in the case of move, but 3202 // there is no semantic difference for class types in this restricted 3203 // case. 3204 if (SM == CXXCopyConstructor || SM == CXXCopyAssignment) 3205 VK = VK_LValue; 3206 else 3207 VK = VK_RValue; 3208 } 3209 3210 OpaqueValueExpr FakeArg(LookupLoc, ArgType, VK); 3211 3212 if (SM != CXXDefaultConstructor) { 3213 NumArgs = 1; 3214 Arg = &FakeArg; 3215 } 3216 3217 // Create the object argument 3218 QualType ThisTy = CanTy; 3219 if (ConstThis) 3220 ThisTy.addConst(); 3221 if (VolatileThis) 3222 ThisTy.addVolatile(); 3223 Expr::Classification Classification = 3224 OpaqueValueExpr(LookupLoc, ThisTy, 3225 RValueThis ? VK_RValue : VK_LValue).Classify(Context); 3226 3227 // Now we perform lookup on the name we computed earlier and do overload 3228 // resolution. Lookup is only performed directly into the class since there 3229 // will always be a (possibly implicit) declaration to shadow any others. 3230 OverloadCandidateSet OCS(LookupLoc, OverloadCandidateSet::CSK_Normal); 3231 DeclContext::lookup_result R = RD->lookup(Name); 3232 3233 if (R.empty()) { 3234 // We might have no default constructor because we have a lambda's closure 3235 // type, rather than because there's some other declared constructor. 3236 // Every class has a copy/move constructor, copy/move assignment, and 3237 // destructor. 3238 assert(SM == CXXDefaultConstructor && 3239 "lookup for a constructor or assignment operator was empty"); 3240 Result->setMethod(nullptr); 3241 Result->setKind(SpecialMemberOverloadResult::NoMemberOrDeleted); 3242 return *Result; 3243 } 3244 3245 // Copy the candidates as our processing of them may load new declarations 3246 // from an external source and invalidate lookup_result. 3247 SmallVector<NamedDecl *, 8> Candidates(R.begin(), R.end()); 3248 3249 for (NamedDecl *CandDecl : Candidates) { 3250 if (CandDecl->isInvalidDecl()) 3251 continue; 3252 3253 DeclAccessPair Cand = DeclAccessPair::make(CandDecl, AS_public); 3254 auto CtorInfo = getConstructorInfo(Cand); 3255 if (CXXMethodDecl *M = dyn_cast<CXXMethodDecl>(Cand->getUnderlyingDecl())) { 3256 if (SM == CXXCopyAssignment || SM == CXXMoveAssignment) 3257 AddMethodCandidate(M, Cand, RD, ThisTy, Classification, 3258 llvm::makeArrayRef(&Arg, NumArgs), OCS, true); 3259 else if (CtorInfo) 3260 AddOverloadCandidate(CtorInfo.Constructor, CtorInfo.FoundDecl, 3261 llvm::makeArrayRef(&Arg, NumArgs), OCS, 3262 /*SuppressUserConversions*/ true); 3263 else 3264 AddOverloadCandidate(M, Cand, llvm::makeArrayRef(&Arg, NumArgs), OCS, 3265 /*SuppressUserConversions*/ true); 3266 } else if (FunctionTemplateDecl *Tmpl = 3267 dyn_cast<FunctionTemplateDecl>(Cand->getUnderlyingDecl())) { 3268 if (SM == CXXCopyAssignment || SM == CXXMoveAssignment) 3269 AddMethodTemplateCandidate( 3270 Tmpl, Cand, RD, nullptr, ThisTy, Classification, 3271 llvm::makeArrayRef(&Arg, NumArgs), OCS, true); 3272 else if (CtorInfo) 3273 AddTemplateOverloadCandidate( 3274 CtorInfo.ConstructorTmpl, CtorInfo.FoundDecl, nullptr, 3275 llvm::makeArrayRef(&Arg, NumArgs), OCS, true); 3276 else 3277 AddTemplateOverloadCandidate( 3278 Tmpl, Cand, nullptr, llvm::makeArrayRef(&Arg, NumArgs), OCS, true); 3279 } else { 3280 assert(isa<UsingDecl>(Cand.getDecl()) && 3281 "illegal Kind of operator = Decl"); 3282 } 3283 } 3284 3285 OverloadCandidateSet::iterator Best; 3286 switch (OCS.BestViableFunction(*this, LookupLoc, Best)) { 3287 case OR_Success: 3288 Result->setMethod(cast<CXXMethodDecl>(Best->Function)); 3289 Result->setKind(SpecialMemberOverloadResult::Success); 3290 break; 3291 3292 case OR_Deleted: 3293 Result->setMethod(cast<CXXMethodDecl>(Best->Function)); 3294 Result->setKind(SpecialMemberOverloadResult::NoMemberOrDeleted); 3295 break; 3296 3297 case OR_Ambiguous: 3298 Result->setMethod(nullptr); 3299 Result->setKind(SpecialMemberOverloadResult::Ambiguous); 3300 break; 3301 3302 case OR_No_Viable_Function: 3303 Result->setMethod(nullptr); 3304 Result->setKind(SpecialMemberOverloadResult::NoMemberOrDeleted); 3305 break; 3306 } 3307 3308 return *Result; 3309 } 3310 3311 /// Look up the default constructor for the given class. 3312 CXXConstructorDecl *Sema::LookupDefaultConstructor(CXXRecordDecl *Class) { 3313 SpecialMemberOverloadResult Result = 3314 LookupSpecialMember(Class, CXXDefaultConstructor, false, false, false, 3315 false, false); 3316 3317 return cast_or_null<CXXConstructorDecl>(Result.getMethod()); 3318 } 3319 3320 /// Look up the copying constructor for the given class. 3321 CXXConstructorDecl *Sema::LookupCopyingConstructor(CXXRecordDecl *Class, 3322 unsigned Quals) { 3323 assert(!(Quals & ~(Qualifiers::Const | Qualifiers::Volatile)) && 3324 "non-const, non-volatile qualifiers for copy ctor arg"); 3325 SpecialMemberOverloadResult Result = 3326 LookupSpecialMember(Class, CXXCopyConstructor, Quals & Qualifiers::Const, 3327 Quals & Qualifiers::Volatile, false, false, false); 3328 3329 return cast_or_null<CXXConstructorDecl>(Result.getMethod()); 3330 } 3331 3332 /// Look up the moving constructor for the given class. 3333 CXXConstructorDecl *Sema::LookupMovingConstructor(CXXRecordDecl *Class, 3334 unsigned Quals) { 3335 SpecialMemberOverloadResult Result = 3336 LookupSpecialMember(Class, CXXMoveConstructor, Quals & Qualifiers::Const, 3337 Quals & Qualifiers::Volatile, false, false, false); 3338 3339 return cast_or_null<CXXConstructorDecl>(Result.getMethod()); 3340 } 3341 3342 /// Look up the constructors for the given class. 3343 DeclContext::lookup_result Sema::LookupConstructors(CXXRecordDecl *Class) { 3344 // If the implicit constructors have not yet been declared, do so now. 3345 if (CanDeclareSpecialMemberFunction(Class)) { 3346 runWithSufficientStackSpace(Class->getLocation(), [&] { 3347 if (Class->needsImplicitDefaultConstructor()) 3348 DeclareImplicitDefaultConstructor(Class); 3349 if (Class->needsImplicitCopyConstructor()) 3350 DeclareImplicitCopyConstructor(Class); 3351 if (getLangOpts().CPlusPlus11 && Class->needsImplicitMoveConstructor()) 3352 DeclareImplicitMoveConstructor(Class); 3353 }); 3354 } 3355 3356 CanQualType T = Context.getCanonicalType(Context.getTypeDeclType(Class)); 3357 DeclarationName Name = Context.DeclarationNames.getCXXConstructorName(T); 3358 return Class->lookup(Name); 3359 } 3360 3361 /// Look up the copying assignment operator for the given class. 3362 CXXMethodDecl *Sema::LookupCopyingAssignment(CXXRecordDecl *Class, 3363 unsigned Quals, bool RValueThis, 3364 unsigned ThisQuals) { 3365 assert(!(Quals & ~(Qualifiers::Const | Qualifiers::Volatile)) && 3366 "non-const, non-volatile qualifiers for copy assignment arg"); 3367 assert(!(ThisQuals & ~(Qualifiers::Const | Qualifiers::Volatile)) && 3368 "non-const, non-volatile qualifiers for copy assignment this"); 3369 SpecialMemberOverloadResult Result = 3370 LookupSpecialMember(Class, CXXCopyAssignment, Quals & Qualifiers::Const, 3371 Quals & Qualifiers::Volatile, RValueThis, 3372 ThisQuals & Qualifiers::Const, 3373 ThisQuals & Qualifiers::Volatile); 3374 3375 return Result.getMethod(); 3376 } 3377 3378 /// Look up the moving assignment operator for the given class. 3379 CXXMethodDecl *Sema::LookupMovingAssignment(CXXRecordDecl *Class, 3380 unsigned Quals, 3381 bool RValueThis, 3382 unsigned ThisQuals) { 3383 assert(!(ThisQuals & ~(Qualifiers::Const | Qualifiers::Volatile)) && 3384 "non-const, non-volatile qualifiers for copy assignment this"); 3385 SpecialMemberOverloadResult Result = 3386 LookupSpecialMember(Class, CXXMoveAssignment, Quals & Qualifiers::Const, 3387 Quals & Qualifiers::Volatile, RValueThis, 3388 ThisQuals & Qualifiers::Const, 3389 ThisQuals & Qualifiers::Volatile); 3390 3391 return Result.getMethod(); 3392 } 3393 3394 /// Look for the destructor of the given class. 3395 /// 3396 /// During semantic analysis, this routine should be used in lieu of 3397 /// CXXRecordDecl::getDestructor(). 3398 /// 3399 /// \returns The destructor for this class. 3400 CXXDestructorDecl *Sema::LookupDestructor(CXXRecordDecl *Class) { 3401 return cast<CXXDestructorDecl>(LookupSpecialMember(Class, CXXDestructor, 3402 false, false, false, 3403 false, false).getMethod()); 3404 } 3405 3406 /// LookupLiteralOperator - Determine which literal operator should be used for 3407 /// a user-defined literal, per C++11 [lex.ext]. 3408 /// 3409 /// Normal overload resolution is not used to select which literal operator to 3410 /// call for a user-defined literal. Look up the provided literal operator name, 3411 /// and filter the results to the appropriate set for the given argument types. 3412 Sema::LiteralOperatorLookupResult 3413 Sema::LookupLiteralOperator(Scope *S, LookupResult &R, 3414 ArrayRef<QualType> ArgTys, 3415 bool AllowRaw, bool AllowTemplate, 3416 bool AllowStringTemplate, bool DiagnoseMissing) { 3417 LookupName(R, S); 3418 assert(R.getResultKind() != LookupResult::Ambiguous && 3419 "literal operator lookup can't be ambiguous"); 3420 3421 // Filter the lookup results appropriately. 3422 LookupResult::Filter F = R.makeFilter(); 3423 3424 bool FoundRaw = false; 3425 bool FoundTemplate = false; 3426 bool FoundStringTemplate = false; 3427 bool FoundExactMatch = false; 3428 3429 while (F.hasNext()) { 3430 Decl *D = F.next(); 3431 if (UsingShadowDecl *USD = dyn_cast<UsingShadowDecl>(D)) 3432 D = USD->getTargetDecl(); 3433 3434 // If the declaration we found is invalid, skip it. 3435 if (D->isInvalidDecl()) { 3436 F.erase(); 3437 continue; 3438 } 3439 3440 bool IsRaw = false; 3441 bool IsTemplate = false; 3442 bool IsStringTemplate = false; 3443 bool IsExactMatch = false; 3444 3445 if (FunctionDecl *FD = dyn_cast<FunctionDecl>(D)) { 3446 if (FD->getNumParams() == 1 && 3447 FD->getParamDecl(0)->getType()->getAs<PointerType>()) 3448 IsRaw = true; 3449 else if (FD->getNumParams() == ArgTys.size()) { 3450 IsExactMatch = true; 3451 for (unsigned ArgIdx = 0; ArgIdx != ArgTys.size(); ++ArgIdx) { 3452 QualType ParamTy = FD->getParamDecl(ArgIdx)->getType(); 3453 if (!Context.hasSameUnqualifiedType(ArgTys[ArgIdx], ParamTy)) { 3454 IsExactMatch = false; 3455 break; 3456 } 3457 } 3458 } 3459 } 3460 if (FunctionTemplateDecl *FD = dyn_cast<FunctionTemplateDecl>(D)) { 3461 TemplateParameterList *Params = FD->getTemplateParameters(); 3462 if (Params->size() == 1) 3463 IsTemplate = true; 3464 else 3465 IsStringTemplate = true; 3466 } 3467 3468 if (IsExactMatch) { 3469 FoundExactMatch = true; 3470 AllowRaw = false; 3471 AllowTemplate = false; 3472 AllowStringTemplate = false; 3473 if (FoundRaw || FoundTemplate || FoundStringTemplate) { 3474 // Go through again and remove the raw and template decls we've 3475 // already found. 3476 F.restart(); 3477 FoundRaw = FoundTemplate = FoundStringTemplate = false; 3478 } 3479 } else if (AllowRaw && IsRaw) { 3480 FoundRaw = true; 3481 } else if (AllowTemplate && IsTemplate) { 3482 FoundTemplate = true; 3483 } else if (AllowStringTemplate && IsStringTemplate) { 3484 FoundStringTemplate = true; 3485 } else { 3486 F.erase(); 3487 } 3488 } 3489 3490 F.done(); 3491 3492 // C++11 [lex.ext]p3, p4: If S contains a literal operator with a matching 3493 // parameter type, that is used in preference to a raw literal operator 3494 // or literal operator template. 3495 if (FoundExactMatch) 3496 return LOLR_Cooked; 3497 3498 // C++11 [lex.ext]p3, p4: S shall contain a raw literal operator or a literal 3499 // operator template, but not both. 3500 if (FoundRaw && FoundTemplate) { 3501 Diag(R.getNameLoc(), diag::err_ovl_ambiguous_call) << R.getLookupName(); 3502 for (LookupResult::iterator I = R.begin(), E = R.end(); I != E; ++I) 3503 NoteOverloadCandidate(*I, (*I)->getUnderlyingDecl()->getAsFunction()); 3504 return LOLR_Error; 3505 } 3506 3507 if (FoundRaw) 3508 return LOLR_Raw; 3509 3510 if (FoundTemplate) 3511 return LOLR_Template; 3512 3513 if (FoundStringTemplate) 3514 return LOLR_StringTemplate; 3515 3516 // Didn't find anything we could use. 3517 if (DiagnoseMissing) { 3518 Diag(R.getNameLoc(), diag::err_ovl_no_viable_literal_operator) 3519 << R.getLookupName() << (int)ArgTys.size() << ArgTys[0] 3520 << (ArgTys.size() == 2 ? ArgTys[1] : QualType()) << AllowRaw 3521 << (AllowTemplate || AllowStringTemplate); 3522 return LOLR_Error; 3523 } 3524 3525 return LOLR_ErrorNoDiagnostic; 3526 } 3527 3528 void ADLResult::insert(NamedDecl *New) { 3529 NamedDecl *&Old = Decls[cast<NamedDecl>(New->getCanonicalDecl())]; 3530 3531 // If we haven't yet seen a decl for this key, or the last decl 3532 // was exactly this one, we're done. 3533 if (Old == nullptr || Old == New) { 3534 Old = New; 3535 return; 3536 } 3537 3538 // Otherwise, decide which is a more recent redeclaration. 3539 FunctionDecl *OldFD = Old->getAsFunction(); 3540 FunctionDecl *NewFD = New->getAsFunction(); 3541 3542 FunctionDecl *Cursor = NewFD; 3543 while (true) { 3544 Cursor = Cursor->getPreviousDecl(); 3545 3546 // If we got to the end without finding OldFD, OldFD is the newer 3547 // declaration; leave things as they are. 3548 if (!Cursor) return; 3549 3550 // If we do find OldFD, then NewFD is newer. 3551 if (Cursor == OldFD) break; 3552 3553 // Otherwise, keep looking. 3554 } 3555 3556 Old = New; 3557 } 3558 3559 void Sema::ArgumentDependentLookup(DeclarationName Name, SourceLocation Loc, 3560 ArrayRef<Expr *> Args, ADLResult &Result) { 3561 // Find all of the associated namespaces and classes based on the 3562 // arguments we have. 3563 AssociatedNamespaceSet AssociatedNamespaces; 3564 AssociatedClassSet AssociatedClasses; 3565 FindAssociatedClassesAndNamespaces(Loc, Args, 3566 AssociatedNamespaces, 3567 AssociatedClasses); 3568 3569 // C++ [basic.lookup.argdep]p3: 3570 // Let X be the lookup set produced by unqualified lookup (3.4.1) 3571 // and let Y be the lookup set produced by argument dependent 3572 // lookup (defined as follows). If X contains [...] then Y is 3573 // empty. Otherwise Y is the set of declarations found in the 3574 // namespaces associated with the argument types as described 3575 // below. The set of declarations found by the lookup of the name 3576 // is the union of X and Y. 3577 // 3578 // Here, we compute Y and add its members to the overloaded 3579 // candidate set. 3580 for (auto *NS : AssociatedNamespaces) { 3581 // When considering an associated namespace, the lookup is the 3582 // same as the lookup performed when the associated namespace is 3583 // used as a qualifier (3.4.3.2) except that: 3584 // 3585 // -- Any using-directives in the associated namespace are 3586 // ignored. 3587 // 3588 // -- Any namespace-scope friend functions declared in 3589 // associated classes are visible within their respective 3590 // namespaces even if they are not visible during an ordinary 3591 // lookup (11.4). 3592 DeclContext::lookup_result R = NS->lookup(Name); 3593 for (auto *D : R) { 3594 auto *Underlying = D; 3595 if (auto *USD = dyn_cast<UsingShadowDecl>(D)) 3596 Underlying = USD->getTargetDecl(); 3597 3598 if (!isa<FunctionDecl>(Underlying) && 3599 !isa<FunctionTemplateDecl>(Underlying)) 3600 continue; 3601 3602 // The declaration is visible to argument-dependent lookup if either 3603 // it's ordinarily visible or declared as a friend in an associated 3604 // class. 3605 bool Visible = false; 3606 for (D = D->getMostRecentDecl(); D; 3607 D = cast_or_null<NamedDecl>(D->getPreviousDecl())) { 3608 if (D->getIdentifierNamespace() & Decl::IDNS_Ordinary) { 3609 if (isVisible(D)) { 3610 Visible = true; 3611 break; 3612 } 3613 } else if (D->getFriendObjectKind()) { 3614 auto *RD = cast<CXXRecordDecl>(D->getLexicalDeclContext()); 3615 if (AssociatedClasses.count(RD) && isVisible(D)) { 3616 Visible = true; 3617 break; 3618 } 3619 } 3620 } 3621 3622 // FIXME: Preserve D as the FoundDecl. 3623 if (Visible) 3624 Result.insert(Underlying); 3625 } 3626 } 3627 } 3628 3629 //---------------------------------------------------------------------------- 3630 // Search for all visible declarations. 3631 //---------------------------------------------------------------------------- 3632 VisibleDeclConsumer::~VisibleDeclConsumer() { } 3633 3634 bool VisibleDeclConsumer::includeHiddenDecls() const { return false; } 3635 3636 namespace { 3637 3638 class ShadowContextRAII; 3639 3640 class VisibleDeclsRecord { 3641 public: 3642 /// An entry in the shadow map, which is optimized to store a 3643 /// single declaration (the common case) but can also store a list 3644 /// of declarations. 3645 typedef llvm::TinyPtrVector<NamedDecl*> ShadowMapEntry; 3646 3647 private: 3648 /// A mapping from declaration names to the declarations that have 3649 /// this name within a particular scope. 3650 typedef llvm::DenseMap<DeclarationName, ShadowMapEntry> ShadowMap; 3651 3652 /// A list of shadow maps, which is used to model name hiding. 3653 std::list<ShadowMap> ShadowMaps; 3654 3655 /// The declaration contexts we have already visited. 3656 llvm::SmallPtrSet<DeclContext *, 8> VisitedContexts; 3657 3658 friend class ShadowContextRAII; 3659 3660 public: 3661 /// Determine whether we have already visited this context 3662 /// (and, if not, note that we are going to visit that context now). 3663 bool visitedContext(DeclContext *Ctx) { 3664 return !VisitedContexts.insert(Ctx).second; 3665 } 3666 3667 bool alreadyVisitedContext(DeclContext *Ctx) { 3668 return VisitedContexts.count(Ctx); 3669 } 3670 3671 /// Determine whether the given declaration is hidden in the 3672 /// current scope. 3673 /// 3674 /// \returns the declaration that hides the given declaration, or 3675 /// NULL if no such declaration exists. 3676 NamedDecl *checkHidden(NamedDecl *ND); 3677 3678 /// Add a declaration to the current shadow map. 3679 void add(NamedDecl *ND) { 3680 ShadowMaps.back()[ND->getDeclName()].push_back(ND); 3681 } 3682 }; 3683 3684 /// RAII object that records when we've entered a shadow context. 3685 class ShadowContextRAII { 3686 VisibleDeclsRecord &Visible; 3687 3688 typedef VisibleDeclsRecord::ShadowMap ShadowMap; 3689 3690 public: 3691 ShadowContextRAII(VisibleDeclsRecord &Visible) : Visible(Visible) { 3692 Visible.ShadowMaps.emplace_back(); 3693 } 3694 3695 ~ShadowContextRAII() { 3696 Visible.ShadowMaps.pop_back(); 3697 } 3698 }; 3699 3700 } // end anonymous namespace 3701 3702 NamedDecl *VisibleDeclsRecord::checkHidden(NamedDecl *ND) { 3703 unsigned IDNS = ND->getIdentifierNamespace(); 3704 std::list<ShadowMap>::reverse_iterator SM = ShadowMaps.rbegin(); 3705 for (std::list<ShadowMap>::reverse_iterator SMEnd = ShadowMaps.rend(); 3706 SM != SMEnd; ++SM) { 3707 ShadowMap::iterator Pos = SM->find(ND->getDeclName()); 3708 if (Pos == SM->end()) 3709 continue; 3710 3711 for (auto *D : Pos->second) { 3712 // A tag declaration does not hide a non-tag declaration. 3713 if (D->hasTagIdentifierNamespace() && 3714 (IDNS & (Decl::IDNS_Member | Decl::IDNS_Ordinary | 3715 Decl::IDNS_ObjCProtocol))) 3716 continue; 3717 3718 // Protocols are in distinct namespaces from everything else. 3719 if (((D->getIdentifierNamespace() & Decl::IDNS_ObjCProtocol) 3720 || (IDNS & Decl::IDNS_ObjCProtocol)) && 3721 D->getIdentifierNamespace() != IDNS) 3722 continue; 3723 3724 // Functions and function templates in the same scope overload 3725 // rather than hide. FIXME: Look for hiding based on function 3726 // signatures! 3727 if (D->getUnderlyingDecl()->isFunctionOrFunctionTemplate() && 3728 ND->getUnderlyingDecl()->isFunctionOrFunctionTemplate() && 3729 SM == ShadowMaps.rbegin()) 3730 continue; 3731 3732 // A shadow declaration that's created by a resolved using declaration 3733 // is not hidden by the same using declaration. 3734 if (isa<UsingShadowDecl>(ND) && isa<UsingDecl>(D) && 3735 cast<UsingShadowDecl>(ND)->getUsingDecl() == D) 3736 continue; 3737 3738 // We've found a declaration that hides this one. 3739 return D; 3740 } 3741 } 3742 3743 return nullptr; 3744 } 3745 3746 namespace { 3747 class LookupVisibleHelper { 3748 public: 3749 LookupVisibleHelper(VisibleDeclConsumer &Consumer, bool IncludeDependentBases, 3750 bool LoadExternal) 3751 : Consumer(Consumer), IncludeDependentBases(IncludeDependentBases), 3752 LoadExternal(LoadExternal) {} 3753 3754 void lookupVisibleDecls(Sema &SemaRef, Scope *S, Sema::LookupNameKind Kind, 3755 bool IncludeGlobalScope) { 3756 // Determine the set of using directives available during 3757 // unqualified name lookup. 3758 Scope *Initial = S; 3759 UnqualUsingDirectiveSet UDirs(SemaRef); 3760 if (SemaRef.getLangOpts().CPlusPlus) { 3761 // Find the first namespace or translation-unit scope. 3762 while (S && !isNamespaceOrTranslationUnitScope(S)) 3763 S = S->getParent(); 3764 3765 UDirs.visitScopeChain(Initial, S); 3766 } 3767 UDirs.done(); 3768 3769 // Look for visible declarations. 3770 LookupResult Result(SemaRef, DeclarationName(), SourceLocation(), Kind); 3771 Result.setAllowHidden(Consumer.includeHiddenDecls()); 3772 if (!IncludeGlobalScope) 3773 Visited.visitedContext(SemaRef.getASTContext().getTranslationUnitDecl()); 3774 ShadowContextRAII Shadow(Visited); 3775 lookupInScope(Initial, Result, UDirs); 3776 } 3777 3778 void lookupVisibleDecls(Sema &SemaRef, DeclContext *Ctx, 3779 Sema::LookupNameKind Kind, bool IncludeGlobalScope) { 3780 LookupResult Result(SemaRef, DeclarationName(), SourceLocation(), Kind); 3781 Result.setAllowHidden(Consumer.includeHiddenDecls()); 3782 if (!IncludeGlobalScope) 3783 Visited.visitedContext(SemaRef.getASTContext().getTranslationUnitDecl()); 3784 3785 ShadowContextRAII Shadow(Visited); 3786 lookupInDeclContext(Ctx, Result, /*QualifiedNameLookup=*/true, 3787 /*InBaseClass=*/false); 3788 } 3789 3790 private: 3791 void lookupInDeclContext(DeclContext *Ctx, LookupResult &Result, 3792 bool QualifiedNameLookup, bool InBaseClass) { 3793 if (!Ctx) 3794 return; 3795 3796 // Make sure we don't visit the same context twice. 3797 if (Visited.visitedContext(Ctx->getPrimaryContext())) 3798 return; 3799 3800 Consumer.EnteredContext(Ctx); 3801 3802 // Outside C++, lookup results for the TU live on identifiers. 3803 if (isa<TranslationUnitDecl>(Ctx) && 3804 !Result.getSema().getLangOpts().CPlusPlus) { 3805 auto &S = Result.getSema(); 3806 auto &Idents = S.Context.Idents; 3807 3808 // Ensure all external identifiers are in the identifier table. 3809 if (LoadExternal) 3810 if (IdentifierInfoLookup *External = 3811 Idents.getExternalIdentifierLookup()) { 3812 std::unique_ptr<IdentifierIterator> Iter(External->getIdentifiers()); 3813 for (StringRef Name = Iter->Next(); !Name.empty(); 3814 Name = Iter->Next()) 3815 Idents.get(Name); 3816 } 3817 3818 // Walk all lookup results in the TU for each identifier. 3819 for (const auto &Ident : Idents) { 3820 for (auto I = S.IdResolver.begin(Ident.getValue()), 3821 E = S.IdResolver.end(); 3822 I != E; ++I) { 3823 if (S.IdResolver.isDeclInScope(*I, Ctx)) { 3824 if (NamedDecl *ND = Result.getAcceptableDecl(*I)) { 3825 Consumer.FoundDecl(ND, Visited.checkHidden(ND), Ctx, InBaseClass); 3826 Visited.add(ND); 3827 } 3828 } 3829 } 3830 } 3831 3832 return; 3833 } 3834 3835 if (CXXRecordDecl *Class = dyn_cast<CXXRecordDecl>(Ctx)) 3836 Result.getSema().ForceDeclarationOfImplicitMembers(Class); 3837 3838 // We sometimes skip loading namespace-level results (they tend to be huge). 3839 bool Load = LoadExternal || 3840 !(isa<TranslationUnitDecl>(Ctx) || isa<NamespaceDecl>(Ctx)); 3841 // Enumerate all of the results in this context. 3842 for (DeclContextLookupResult R : 3843 Load ? Ctx->lookups() 3844 : Ctx->noload_lookups(/*PreserveInternalState=*/false)) { 3845 for (auto *D : R) { 3846 if (auto *ND = Result.getAcceptableDecl(D)) { 3847 Consumer.FoundDecl(ND, Visited.checkHidden(ND), Ctx, InBaseClass); 3848 Visited.add(ND); 3849 } 3850 } 3851 } 3852 3853 // Traverse using directives for qualified name lookup. 3854 if (QualifiedNameLookup) { 3855 ShadowContextRAII Shadow(Visited); 3856 for (auto I : Ctx->using_directives()) { 3857 if (!Result.getSema().isVisible(I)) 3858 continue; 3859 lookupInDeclContext(I->getNominatedNamespace(), Result, 3860 QualifiedNameLookup, InBaseClass); 3861 } 3862 } 3863 3864 // Traverse the contexts of inherited C++ classes. 3865 if (CXXRecordDecl *Record = dyn_cast<CXXRecordDecl>(Ctx)) { 3866 if (!Record->hasDefinition()) 3867 return; 3868 3869 for (const auto &B : Record->bases()) { 3870 QualType BaseType = B.getType(); 3871 3872 RecordDecl *RD; 3873 if (BaseType->isDependentType()) { 3874 if (!IncludeDependentBases) { 3875 // Don't look into dependent bases, because name lookup can't look 3876 // there anyway. 3877 continue; 3878 } 3879 const auto *TST = BaseType->getAs<TemplateSpecializationType>(); 3880 if (!TST) 3881 continue; 3882 TemplateName TN = TST->getTemplateName(); 3883 const auto *TD = 3884 dyn_cast_or_null<ClassTemplateDecl>(TN.getAsTemplateDecl()); 3885 if (!TD) 3886 continue; 3887 RD = TD->getTemplatedDecl(); 3888 } else { 3889 const auto *Record = BaseType->getAs<RecordType>(); 3890 if (!Record) 3891 continue; 3892 RD = Record->getDecl(); 3893 } 3894 3895 // FIXME: It would be nice to be able to determine whether referencing 3896 // a particular member would be ambiguous. For example, given 3897 // 3898 // struct A { int member; }; 3899 // struct B { int member; }; 3900 // struct C : A, B { }; 3901 // 3902 // void f(C *c) { c->### } 3903 // 3904 // accessing 'member' would result in an ambiguity. However, we 3905 // could be smart enough to qualify the member with the base 3906 // class, e.g., 3907 // 3908 // c->B::member 3909 // 3910 // or 3911 // 3912 // c->A::member 3913 3914 // Find results in this base class (and its bases). 3915 ShadowContextRAII Shadow(Visited); 3916 lookupInDeclContext(RD, Result, QualifiedNameLookup, 3917 /*InBaseClass=*/true); 3918 } 3919 } 3920 3921 // Traverse the contexts of Objective-C classes. 3922 if (ObjCInterfaceDecl *IFace = dyn_cast<ObjCInterfaceDecl>(Ctx)) { 3923 // Traverse categories. 3924 for (auto *Cat : IFace->visible_categories()) { 3925 ShadowContextRAII Shadow(Visited); 3926 lookupInDeclContext(Cat, Result, QualifiedNameLookup, 3927 /*InBaseClass=*/false); 3928 } 3929 3930 // Traverse protocols. 3931 for (auto *I : IFace->all_referenced_protocols()) { 3932 ShadowContextRAII Shadow(Visited); 3933 lookupInDeclContext(I, Result, QualifiedNameLookup, 3934 /*InBaseClass=*/false); 3935 } 3936 3937 // Traverse the superclass. 3938 if (IFace->getSuperClass()) { 3939 ShadowContextRAII Shadow(Visited); 3940 lookupInDeclContext(IFace->getSuperClass(), Result, QualifiedNameLookup, 3941 /*InBaseClass=*/true); 3942 } 3943 3944 // If there is an implementation, traverse it. We do this to find 3945 // synthesized ivars. 3946 if (IFace->getImplementation()) { 3947 ShadowContextRAII Shadow(Visited); 3948 lookupInDeclContext(IFace->getImplementation(), Result, 3949 QualifiedNameLookup, InBaseClass); 3950 } 3951 } else if (ObjCProtocolDecl *Protocol = dyn_cast<ObjCProtocolDecl>(Ctx)) { 3952 for (auto *I : Protocol->protocols()) { 3953 ShadowContextRAII Shadow(Visited); 3954 lookupInDeclContext(I, Result, QualifiedNameLookup, 3955 /*InBaseClass=*/false); 3956 } 3957 } else if (ObjCCategoryDecl *Category = dyn_cast<ObjCCategoryDecl>(Ctx)) { 3958 for (auto *I : Category->protocols()) { 3959 ShadowContextRAII Shadow(Visited); 3960 lookupInDeclContext(I, Result, QualifiedNameLookup, 3961 /*InBaseClass=*/false); 3962 } 3963 3964 // If there is an implementation, traverse it. 3965 if (Category->getImplementation()) { 3966 ShadowContextRAII Shadow(Visited); 3967 lookupInDeclContext(Category->getImplementation(), Result, 3968 QualifiedNameLookup, /*InBaseClass=*/true); 3969 } 3970 } 3971 } 3972 3973 void lookupInScope(Scope *S, LookupResult &Result, 3974 UnqualUsingDirectiveSet &UDirs) { 3975 // No clients run in this mode and it's not supported. Please add tests and 3976 // remove the assertion if you start relying on it. 3977 assert(!IncludeDependentBases && "Unsupported flag for lookupInScope"); 3978 3979 if (!S) 3980 return; 3981 3982 if (!S->getEntity() || 3983 (!S->getParent() && !Visited.alreadyVisitedContext(S->getEntity())) || 3984 (S->getEntity())->isFunctionOrMethod()) { 3985 FindLocalExternScope FindLocals(Result); 3986 // Walk through the declarations in this Scope. The consumer might add new 3987 // decls to the scope as part of deserialization, so make a copy first. 3988 SmallVector<Decl *, 8> ScopeDecls(S->decls().begin(), S->decls().end()); 3989 for (Decl *D : ScopeDecls) { 3990 if (NamedDecl *ND = dyn_cast<NamedDecl>(D)) 3991 if ((ND = Result.getAcceptableDecl(ND))) { 3992 Consumer.FoundDecl(ND, Visited.checkHidden(ND), nullptr, false); 3993 Visited.add(ND); 3994 } 3995 } 3996 } 3997 3998 // FIXME: C++ [temp.local]p8 3999 DeclContext *Entity = nullptr; 4000 if (S->getEntity()) { 4001 // Look into this scope's declaration context, along with any of its 4002 // parent lookup contexts (e.g., enclosing classes), up to the point 4003 // where we hit the context stored in the next outer scope. 4004 Entity = S->getEntity(); 4005 DeclContext *OuterCtx = findOuterContext(S).first; // FIXME 4006 4007 for (DeclContext *Ctx = Entity; Ctx && !Ctx->Equals(OuterCtx); 4008 Ctx = Ctx->getLookupParent()) { 4009 if (ObjCMethodDecl *Method = dyn_cast<ObjCMethodDecl>(Ctx)) { 4010 if (Method->isInstanceMethod()) { 4011 // For instance methods, look for ivars in the method's interface. 4012 LookupResult IvarResult(Result.getSema(), Result.getLookupName(), 4013 Result.getNameLoc(), 4014 Sema::LookupMemberName); 4015 if (ObjCInterfaceDecl *IFace = Method->getClassInterface()) { 4016 lookupInDeclContext(IFace, IvarResult, 4017 /*QualifiedNameLookup=*/false, 4018 /*InBaseClass=*/false); 4019 } 4020 } 4021 4022 // We've already performed all of the name lookup that we need 4023 // to for Objective-C methods; the next context will be the 4024 // outer scope. 4025 break; 4026 } 4027 4028 if (Ctx->isFunctionOrMethod()) 4029 continue; 4030 4031 lookupInDeclContext(Ctx, Result, /*QualifiedNameLookup=*/false, 4032 /*InBaseClass=*/false); 4033 } 4034 } else if (!S->getParent()) { 4035 // Look into the translation unit scope. We walk through the translation 4036 // unit's declaration context, because the Scope itself won't have all of 4037 // the declarations if we loaded a precompiled header. 4038 // FIXME: We would like the translation unit's Scope object to point to 4039 // the translation unit, so we don't need this special "if" branch. 4040 // However, doing so would force the normal C++ name-lookup code to look 4041 // into the translation unit decl when the IdentifierInfo chains would 4042 // suffice. Once we fix that problem (which is part of a more general 4043 // "don't look in DeclContexts unless we have to" optimization), we can 4044 // eliminate this. 4045 Entity = Result.getSema().Context.getTranslationUnitDecl(); 4046 lookupInDeclContext(Entity, Result, /*QualifiedNameLookup=*/false, 4047 /*InBaseClass=*/false); 4048 } 4049 4050 if (Entity) { 4051 // Lookup visible declarations in any namespaces found by using 4052 // directives. 4053 for (const UnqualUsingEntry &UUE : UDirs.getNamespacesFor(Entity)) 4054 lookupInDeclContext( 4055 const_cast<DeclContext *>(UUE.getNominatedNamespace()), Result, 4056 /*QualifiedNameLookup=*/false, 4057 /*InBaseClass=*/false); 4058 } 4059 4060 // Lookup names in the parent scope. 4061 ShadowContextRAII Shadow(Visited); 4062 lookupInScope(S->getParent(), Result, UDirs); 4063 } 4064 4065 private: 4066 VisibleDeclsRecord Visited; 4067 VisibleDeclConsumer &Consumer; 4068 bool IncludeDependentBases; 4069 bool LoadExternal; 4070 }; 4071 } // namespace 4072 4073 void Sema::LookupVisibleDecls(Scope *S, LookupNameKind Kind, 4074 VisibleDeclConsumer &Consumer, 4075 bool IncludeGlobalScope, bool LoadExternal) { 4076 LookupVisibleHelper H(Consumer, /*IncludeDependentBases=*/false, 4077 LoadExternal); 4078 H.lookupVisibleDecls(*this, S, Kind, IncludeGlobalScope); 4079 } 4080 4081 void Sema::LookupVisibleDecls(DeclContext *Ctx, LookupNameKind Kind, 4082 VisibleDeclConsumer &Consumer, 4083 bool IncludeGlobalScope, 4084 bool IncludeDependentBases, bool LoadExternal) { 4085 LookupVisibleHelper H(Consumer, IncludeDependentBases, LoadExternal); 4086 H.lookupVisibleDecls(*this, Ctx, Kind, IncludeGlobalScope); 4087 } 4088 4089 /// LookupOrCreateLabel - Do a name lookup of a label with the specified name. 4090 /// If GnuLabelLoc is a valid source location, then this is a definition 4091 /// of an __label__ label name, otherwise it is a normal label definition 4092 /// or use. 4093 LabelDecl *Sema::LookupOrCreateLabel(IdentifierInfo *II, SourceLocation Loc, 4094 SourceLocation GnuLabelLoc) { 4095 // Do a lookup to see if we have a label with this name already. 4096 NamedDecl *Res = nullptr; 4097 4098 if (GnuLabelLoc.isValid()) { 4099 // Local label definitions always shadow existing labels. 4100 Res = LabelDecl::Create(Context, CurContext, Loc, II, GnuLabelLoc); 4101 Scope *S = CurScope; 4102 PushOnScopeChains(Res, S, true); 4103 return cast<LabelDecl>(Res); 4104 } 4105 4106 // Not a GNU local label. 4107 Res = LookupSingleName(CurScope, II, Loc, LookupLabel, NotForRedeclaration); 4108 // If we found a label, check to see if it is in the same context as us. 4109 // When in a Block, we don't want to reuse a label in an enclosing function. 4110 if (Res && Res->getDeclContext() != CurContext) 4111 Res = nullptr; 4112 if (!Res) { 4113 // If not forward referenced or defined already, create the backing decl. 4114 Res = LabelDecl::Create(Context, CurContext, Loc, II); 4115 Scope *S = CurScope->getFnParent(); 4116 assert(S && "Not in a function?"); 4117 PushOnScopeChains(Res, S, true); 4118 } 4119 return cast<LabelDecl>(Res); 4120 } 4121 4122 //===----------------------------------------------------------------------===// 4123 // Typo correction 4124 //===----------------------------------------------------------------------===// 4125 4126 static bool isCandidateViable(CorrectionCandidateCallback &CCC, 4127 TypoCorrection &Candidate) { 4128 Candidate.setCallbackDistance(CCC.RankCandidate(Candidate)); 4129 return Candidate.getEditDistance(false) != TypoCorrection::InvalidDistance; 4130 } 4131 4132 static void LookupPotentialTypoResult(Sema &SemaRef, 4133 LookupResult &Res, 4134 IdentifierInfo *Name, 4135 Scope *S, CXXScopeSpec *SS, 4136 DeclContext *MemberContext, 4137 bool EnteringContext, 4138 bool isObjCIvarLookup, 4139 bool FindHidden); 4140 4141 /// Check whether the declarations found for a typo correction are 4142 /// visible. Set the correction's RequiresImport flag to true if none of the 4143 /// declarations are visible, false otherwise. 4144 static void checkCorrectionVisibility(Sema &SemaRef, TypoCorrection &TC) { 4145 TypoCorrection::decl_iterator DI = TC.begin(), DE = TC.end(); 4146 4147 for (/**/; DI != DE; ++DI) 4148 if (!LookupResult::isVisible(SemaRef, *DI)) 4149 break; 4150 // No filtering needed if all decls are visible. 4151 if (DI == DE) { 4152 TC.setRequiresImport(false); 4153 return; 4154 } 4155 4156 llvm::SmallVector<NamedDecl*, 4> NewDecls(TC.begin(), DI); 4157 bool AnyVisibleDecls = !NewDecls.empty(); 4158 4159 for (/**/; DI != DE; ++DI) { 4160 if (LookupResult::isVisible(SemaRef, *DI)) { 4161 if (!AnyVisibleDecls) { 4162 // Found a visible decl, discard all hidden ones. 4163 AnyVisibleDecls = true; 4164 NewDecls.clear(); 4165 } 4166 NewDecls.push_back(*DI); 4167 } else if (!AnyVisibleDecls && !(*DI)->isModulePrivate()) 4168 NewDecls.push_back(*DI); 4169 } 4170 4171 if (NewDecls.empty()) 4172 TC = TypoCorrection(); 4173 else { 4174 TC.setCorrectionDecls(NewDecls); 4175 TC.setRequiresImport(!AnyVisibleDecls); 4176 } 4177 } 4178 4179 // Fill the supplied vector with the IdentifierInfo pointers for each piece of 4180 // the given NestedNameSpecifier (i.e. given a NestedNameSpecifier "foo::bar::", 4181 // fill the vector with the IdentifierInfo pointers for "foo" and "bar"). 4182 static void getNestedNameSpecifierIdentifiers( 4183 NestedNameSpecifier *NNS, 4184 SmallVectorImpl<const IdentifierInfo*> &Identifiers) { 4185 if (NestedNameSpecifier *Prefix = NNS->getPrefix()) 4186 getNestedNameSpecifierIdentifiers(Prefix, Identifiers); 4187 else 4188 Identifiers.clear(); 4189 4190 const IdentifierInfo *II = nullptr; 4191 4192 switch (NNS->getKind()) { 4193 case NestedNameSpecifier::Identifier: 4194 II = NNS->getAsIdentifier(); 4195 break; 4196 4197 case NestedNameSpecifier::Namespace: 4198 if (NNS->getAsNamespace()->isAnonymousNamespace()) 4199 return; 4200 II = NNS->getAsNamespace()->getIdentifier(); 4201 break; 4202 4203 case NestedNameSpecifier::NamespaceAlias: 4204 II = NNS->getAsNamespaceAlias()->getIdentifier(); 4205 break; 4206 4207 case NestedNameSpecifier::TypeSpecWithTemplate: 4208 case NestedNameSpecifier::TypeSpec: 4209 II = QualType(NNS->getAsType(), 0).getBaseTypeIdentifier(); 4210 break; 4211 4212 case NestedNameSpecifier::Global: 4213 case NestedNameSpecifier::Super: 4214 return; 4215 } 4216 4217 if (II) 4218 Identifiers.push_back(II); 4219 } 4220 4221 void TypoCorrectionConsumer::FoundDecl(NamedDecl *ND, NamedDecl *Hiding, 4222 DeclContext *Ctx, bool InBaseClass) { 4223 // Don't consider hidden names for typo correction. 4224 if (Hiding) 4225 return; 4226 4227 // Only consider entities with identifiers for names, ignoring 4228 // special names (constructors, overloaded operators, selectors, 4229 // etc.). 4230 IdentifierInfo *Name = ND->getIdentifier(); 4231 if (!Name) 4232 return; 4233 4234 // Only consider visible declarations and declarations from modules with 4235 // names that exactly match. 4236 if (!LookupResult::isVisible(SemaRef, ND) && Name != Typo) 4237 return; 4238 4239 FoundName(Name->getName()); 4240 } 4241 4242 void TypoCorrectionConsumer::FoundName(StringRef Name) { 4243 // Compute the edit distance between the typo and the name of this 4244 // entity, and add the identifier to the list of results. 4245 addName(Name, nullptr); 4246 } 4247 4248 void TypoCorrectionConsumer::addKeywordResult(StringRef Keyword) { 4249 // Compute the edit distance between the typo and this keyword, 4250 // and add the keyword to the list of results. 4251 addName(Keyword, nullptr, nullptr, true); 4252 } 4253 4254 void TypoCorrectionConsumer::addName(StringRef Name, NamedDecl *ND, 4255 NestedNameSpecifier *NNS, bool isKeyword) { 4256 // Use a simple length-based heuristic to determine the minimum possible 4257 // edit distance. If the minimum isn't good enough, bail out early. 4258 StringRef TypoStr = Typo->getName(); 4259 unsigned MinED = abs((int)Name.size() - (int)TypoStr.size()); 4260 if (MinED && TypoStr.size() / MinED < 3) 4261 return; 4262 4263 // Compute an upper bound on the allowable edit distance, so that the 4264 // edit-distance algorithm can short-circuit. 4265 unsigned UpperBound = (TypoStr.size() + 2) / 3; 4266 unsigned ED = TypoStr.edit_distance(Name, true, UpperBound); 4267 if (ED > UpperBound) return; 4268 4269 TypoCorrection TC(&SemaRef.Context.Idents.get(Name), ND, NNS, ED); 4270 if (isKeyword) TC.makeKeyword(); 4271 TC.setCorrectionRange(nullptr, Result.getLookupNameInfo()); 4272 addCorrection(TC); 4273 } 4274 4275 static const unsigned MaxTypoDistanceResultSets = 5; 4276 4277 void TypoCorrectionConsumer::addCorrection(TypoCorrection Correction) { 4278 StringRef TypoStr = Typo->getName(); 4279 StringRef Name = Correction.getCorrectionAsIdentifierInfo()->getName(); 4280 4281 // For very short typos, ignore potential corrections that have a different 4282 // base identifier from the typo or which have a normalized edit distance 4283 // longer than the typo itself. 4284 if (TypoStr.size() < 3 && 4285 (Name != TypoStr || Correction.getEditDistance(true) > TypoStr.size())) 4286 return; 4287 4288 // If the correction is resolved but is not viable, ignore it. 4289 if (Correction.isResolved()) { 4290 checkCorrectionVisibility(SemaRef, Correction); 4291 if (!Correction || !isCandidateViable(*CorrectionValidator, Correction)) 4292 return; 4293 } 4294 4295 TypoResultList &CList = 4296 CorrectionResults[Correction.getEditDistance(false)][Name]; 4297 4298 if (!CList.empty() && !CList.back().isResolved()) 4299 CList.pop_back(); 4300 if (NamedDecl *NewND = Correction.getCorrectionDecl()) { 4301 std::string CorrectionStr = Correction.getAsString(SemaRef.getLangOpts()); 4302 for (TypoResultList::iterator RI = CList.begin(), RIEnd = CList.end(); 4303 RI != RIEnd; ++RI) { 4304 // If the Correction refers to a decl already in the result list, 4305 // replace the existing result if the string representation of Correction 4306 // comes before the current result alphabetically, then stop as there is 4307 // nothing more to be done to add Correction to the candidate set. 4308 if (RI->getCorrectionDecl() == NewND) { 4309 if (CorrectionStr < RI->getAsString(SemaRef.getLangOpts())) 4310 *RI = Correction; 4311 return; 4312 } 4313 } 4314 } 4315 if (CList.empty() || Correction.isResolved()) 4316 CList.push_back(Correction); 4317 4318 while (CorrectionResults.size() > MaxTypoDistanceResultSets) 4319 CorrectionResults.erase(std::prev(CorrectionResults.end())); 4320 } 4321 4322 void TypoCorrectionConsumer::addNamespaces( 4323 const llvm::MapVector<NamespaceDecl *, bool> &KnownNamespaces) { 4324 SearchNamespaces = true; 4325 4326 for (auto KNPair : KnownNamespaces) 4327 Namespaces.addNameSpecifier(KNPair.first); 4328 4329 bool SSIsTemplate = false; 4330 if (NestedNameSpecifier *NNS = 4331 (SS && SS->isValid()) ? SS->getScopeRep() : nullptr) { 4332 if (const Type *T = NNS->getAsType()) 4333 SSIsTemplate = T->getTypeClass() == Type::TemplateSpecialization; 4334 } 4335 // Do not transform this into an iterator-based loop. The loop body can 4336 // trigger the creation of further types (through lazy deserialization) and 4337 // invalid iterators into this list. 4338 auto &Types = SemaRef.getASTContext().getTypes(); 4339 for (unsigned I = 0; I != Types.size(); ++I) { 4340 const auto *TI = Types[I]; 4341 if (CXXRecordDecl *CD = TI->getAsCXXRecordDecl()) { 4342 CD = CD->getCanonicalDecl(); 4343 if (!CD->isDependentType() && !CD->isAnonymousStructOrUnion() && 4344 !CD->isUnion() && CD->getIdentifier() && 4345 (SSIsTemplate || !isa<ClassTemplateSpecializationDecl>(CD)) && 4346 (CD->isBeingDefined() || CD->isCompleteDefinition())) 4347 Namespaces.addNameSpecifier(CD); 4348 } 4349 } 4350 } 4351 4352 const TypoCorrection &TypoCorrectionConsumer::getNextCorrection() { 4353 if (++CurrentTCIndex < ValidatedCorrections.size()) 4354 return ValidatedCorrections[CurrentTCIndex]; 4355 4356 CurrentTCIndex = ValidatedCorrections.size(); 4357 while (!CorrectionResults.empty()) { 4358 auto DI = CorrectionResults.begin(); 4359 if (DI->second.empty()) { 4360 CorrectionResults.erase(DI); 4361 continue; 4362 } 4363 4364 auto RI = DI->second.begin(); 4365 if (RI->second.empty()) { 4366 DI->second.erase(RI); 4367 performQualifiedLookups(); 4368 continue; 4369 } 4370 4371 TypoCorrection TC = RI->second.pop_back_val(); 4372 if (TC.isResolved() || TC.requiresImport() || resolveCorrection(TC)) { 4373 ValidatedCorrections.push_back(TC); 4374 return ValidatedCorrections[CurrentTCIndex]; 4375 } 4376 } 4377 return ValidatedCorrections[0]; // The empty correction. 4378 } 4379 4380 bool TypoCorrectionConsumer::resolveCorrection(TypoCorrection &Candidate) { 4381 IdentifierInfo *Name = Candidate.getCorrectionAsIdentifierInfo(); 4382 DeclContext *TempMemberContext = MemberContext; 4383 CXXScopeSpec *TempSS = SS.get(); 4384 retry_lookup: 4385 LookupPotentialTypoResult(SemaRef, Result, Name, S, TempSS, TempMemberContext, 4386 EnteringContext, 4387 CorrectionValidator->IsObjCIvarLookup, 4388 Name == Typo && !Candidate.WillReplaceSpecifier()); 4389 switch (Result.getResultKind()) { 4390 case LookupResult::NotFound: 4391 case LookupResult::NotFoundInCurrentInstantiation: 4392 case LookupResult::FoundUnresolvedValue: 4393 if (TempSS) { 4394 // Immediately retry the lookup without the given CXXScopeSpec 4395 TempSS = nullptr; 4396 Candidate.WillReplaceSpecifier(true); 4397 goto retry_lookup; 4398 } 4399 if (TempMemberContext) { 4400 if (SS && !TempSS) 4401 TempSS = SS.get(); 4402 TempMemberContext = nullptr; 4403 goto retry_lookup; 4404 } 4405 if (SearchNamespaces) 4406 QualifiedResults.push_back(Candidate); 4407 break; 4408 4409 case LookupResult::Ambiguous: 4410 // We don't deal with ambiguities. 4411 break; 4412 4413 case LookupResult::Found: 4414 case LookupResult::FoundOverloaded: 4415 // Store all of the Decls for overloaded symbols 4416 for (auto *TRD : Result) 4417 Candidate.addCorrectionDecl(TRD); 4418 checkCorrectionVisibility(SemaRef, Candidate); 4419 if (!isCandidateViable(*CorrectionValidator, Candidate)) { 4420 if (SearchNamespaces) 4421 QualifiedResults.push_back(Candidate); 4422 break; 4423 } 4424 Candidate.setCorrectionRange(SS.get(), Result.getLookupNameInfo()); 4425 return true; 4426 } 4427 return false; 4428 } 4429 4430 void TypoCorrectionConsumer::performQualifiedLookups() { 4431 unsigned TypoLen = Typo->getName().size(); 4432 for (const TypoCorrection &QR : QualifiedResults) { 4433 for (const auto &NSI : Namespaces) { 4434 DeclContext *Ctx = NSI.DeclCtx; 4435 const Type *NSType = NSI.NameSpecifier->getAsType(); 4436 4437 // If the current NestedNameSpecifier refers to a class and the 4438 // current correction candidate is the name of that class, then skip 4439 // it as it is unlikely a qualified version of the class' constructor 4440 // is an appropriate correction. 4441 if (CXXRecordDecl *NSDecl = NSType ? NSType->getAsCXXRecordDecl() : 4442 nullptr) { 4443 if (NSDecl->getIdentifier() == QR.getCorrectionAsIdentifierInfo()) 4444 continue; 4445 } 4446 4447 TypoCorrection TC(QR); 4448 TC.ClearCorrectionDecls(); 4449 TC.setCorrectionSpecifier(NSI.NameSpecifier); 4450 TC.setQualifierDistance(NSI.EditDistance); 4451 TC.setCallbackDistance(0); // Reset the callback distance 4452 4453 // If the current correction candidate and namespace combination are 4454 // too far away from the original typo based on the normalized edit 4455 // distance, then skip performing a qualified name lookup. 4456 unsigned TmpED = TC.getEditDistance(true); 4457 if (QR.getCorrectionAsIdentifierInfo() != Typo && TmpED && 4458 TypoLen / TmpED < 3) 4459 continue; 4460 4461 Result.clear(); 4462 Result.setLookupName(QR.getCorrectionAsIdentifierInfo()); 4463 if (!SemaRef.LookupQualifiedName(Result, Ctx)) 4464 continue; 4465 4466 // Any corrections added below will be validated in subsequent 4467 // iterations of the main while() loop over the Consumer's contents. 4468 switch (Result.getResultKind()) { 4469 case LookupResult::Found: 4470 case LookupResult::FoundOverloaded: { 4471 if (SS && SS->isValid()) { 4472 std::string NewQualified = TC.getAsString(SemaRef.getLangOpts()); 4473 std::string OldQualified; 4474 llvm::raw_string_ostream OldOStream(OldQualified); 4475 SS->getScopeRep()->print(OldOStream, SemaRef.getPrintingPolicy()); 4476 OldOStream << Typo->getName(); 4477 // If correction candidate would be an identical written qualified 4478 // identifier, then the existing CXXScopeSpec probably included a 4479 // typedef that didn't get accounted for properly. 4480 if (OldOStream.str() == NewQualified) 4481 break; 4482 } 4483 for (LookupResult::iterator TRD = Result.begin(), TRDEnd = Result.end(); 4484 TRD != TRDEnd; ++TRD) { 4485 if (SemaRef.CheckMemberAccess(TC.getCorrectionRange().getBegin(), 4486 NSType ? NSType->getAsCXXRecordDecl() 4487 : nullptr, 4488 TRD.getPair()) == Sema::AR_accessible) 4489 TC.addCorrectionDecl(*TRD); 4490 } 4491 if (TC.isResolved()) { 4492 TC.setCorrectionRange(SS.get(), Result.getLookupNameInfo()); 4493 addCorrection(TC); 4494 } 4495 break; 4496 } 4497 case LookupResult::NotFound: 4498 case LookupResult::NotFoundInCurrentInstantiation: 4499 case LookupResult::Ambiguous: 4500 case LookupResult::FoundUnresolvedValue: 4501 break; 4502 } 4503 } 4504 } 4505 QualifiedResults.clear(); 4506 } 4507 4508 TypoCorrectionConsumer::NamespaceSpecifierSet::NamespaceSpecifierSet( 4509 ASTContext &Context, DeclContext *CurContext, CXXScopeSpec *CurScopeSpec) 4510 : Context(Context), CurContextChain(buildContextChain(CurContext)) { 4511 if (NestedNameSpecifier *NNS = 4512 CurScopeSpec ? CurScopeSpec->getScopeRep() : nullptr) { 4513 llvm::raw_string_ostream SpecifierOStream(CurNameSpecifier); 4514 NNS->print(SpecifierOStream, Context.getPrintingPolicy()); 4515 4516 getNestedNameSpecifierIdentifiers(NNS, CurNameSpecifierIdentifiers); 4517 } 4518 // Build the list of identifiers that would be used for an absolute 4519 // (from the global context) NestedNameSpecifier referring to the current 4520 // context. 4521 for (DeclContext *C : llvm::reverse(CurContextChain)) { 4522 if (auto *ND = dyn_cast_or_null<NamespaceDecl>(C)) 4523 CurContextIdentifiers.push_back(ND->getIdentifier()); 4524 } 4525 4526 // Add the global context as a NestedNameSpecifier 4527 SpecifierInfo SI = {cast<DeclContext>(Context.getTranslationUnitDecl()), 4528 NestedNameSpecifier::GlobalSpecifier(Context), 1}; 4529 DistanceMap[1].push_back(SI); 4530 } 4531 4532 auto TypoCorrectionConsumer::NamespaceSpecifierSet::buildContextChain( 4533 DeclContext *Start) -> DeclContextList { 4534 assert(Start && "Building a context chain from a null context"); 4535 DeclContextList Chain; 4536 for (DeclContext *DC = Start->getPrimaryContext(); DC != nullptr; 4537 DC = DC->getLookupParent()) { 4538 NamespaceDecl *ND = dyn_cast_or_null<NamespaceDecl>(DC); 4539 if (!DC->isInlineNamespace() && !DC->isTransparentContext() && 4540 !(ND && ND->isAnonymousNamespace())) 4541 Chain.push_back(DC->getPrimaryContext()); 4542 } 4543 return Chain; 4544 } 4545 4546 unsigned 4547 TypoCorrectionConsumer::NamespaceSpecifierSet::buildNestedNameSpecifier( 4548 DeclContextList &DeclChain, NestedNameSpecifier *&NNS) { 4549 unsigned NumSpecifiers = 0; 4550 for (DeclContext *C : llvm::reverse(DeclChain)) { 4551 if (auto *ND = dyn_cast_or_null<NamespaceDecl>(C)) { 4552 NNS = NestedNameSpecifier::Create(Context, NNS, ND); 4553 ++NumSpecifiers; 4554 } else if (auto *RD = dyn_cast_or_null<RecordDecl>(C)) { 4555 NNS = NestedNameSpecifier::Create(Context, NNS, RD->isTemplateDecl(), 4556 RD->getTypeForDecl()); 4557 ++NumSpecifiers; 4558 } 4559 } 4560 return NumSpecifiers; 4561 } 4562 4563 void TypoCorrectionConsumer::NamespaceSpecifierSet::addNameSpecifier( 4564 DeclContext *Ctx) { 4565 NestedNameSpecifier *NNS = nullptr; 4566 unsigned NumSpecifiers = 0; 4567 DeclContextList NamespaceDeclChain(buildContextChain(Ctx)); 4568 DeclContextList FullNamespaceDeclChain(NamespaceDeclChain); 4569 4570 // Eliminate common elements from the two DeclContext chains. 4571 for (DeclContext *C : llvm::reverse(CurContextChain)) { 4572 if (NamespaceDeclChain.empty() || NamespaceDeclChain.back() != C) 4573 break; 4574 NamespaceDeclChain.pop_back(); 4575 } 4576 4577 // Build the NestedNameSpecifier from what is left of the NamespaceDeclChain 4578 NumSpecifiers = buildNestedNameSpecifier(NamespaceDeclChain, NNS); 4579 4580 // Add an explicit leading '::' specifier if needed. 4581 if (NamespaceDeclChain.empty()) { 4582 // Rebuild the NestedNameSpecifier as a globally-qualified specifier. 4583 NNS = NestedNameSpecifier::GlobalSpecifier(Context); 4584 NumSpecifiers = 4585 buildNestedNameSpecifier(FullNamespaceDeclChain, NNS); 4586 } else if (NamedDecl *ND = 4587 dyn_cast_or_null<NamedDecl>(NamespaceDeclChain.back())) { 4588 IdentifierInfo *Name = ND->getIdentifier(); 4589 bool SameNameSpecifier = false; 4590 if (std::find(CurNameSpecifierIdentifiers.begin(), 4591 CurNameSpecifierIdentifiers.end(), 4592 Name) != CurNameSpecifierIdentifiers.end()) { 4593 std::string NewNameSpecifier; 4594 llvm::raw_string_ostream SpecifierOStream(NewNameSpecifier); 4595 SmallVector<const IdentifierInfo *, 4> NewNameSpecifierIdentifiers; 4596 getNestedNameSpecifierIdentifiers(NNS, NewNameSpecifierIdentifiers); 4597 NNS->print(SpecifierOStream, Context.getPrintingPolicy()); 4598 SpecifierOStream.flush(); 4599 SameNameSpecifier = NewNameSpecifier == CurNameSpecifier; 4600 } 4601 if (SameNameSpecifier || llvm::find(CurContextIdentifiers, Name) != 4602 CurContextIdentifiers.end()) { 4603 // Rebuild the NestedNameSpecifier as a globally-qualified specifier. 4604 NNS = NestedNameSpecifier::GlobalSpecifier(Context); 4605 NumSpecifiers = 4606 buildNestedNameSpecifier(FullNamespaceDeclChain, NNS); 4607 } 4608 } 4609 4610 // If the built NestedNameSpecifier would be replacing an existing 4611 // NestedNameSpecifier, use the number of component identifiers that 4612 // would need to be changed as the edit distance instead of the number 4613 // of components in the built NestedNameSpecifier. 4614 if (NNS && !CurNameSpecifierIdentifiers.empty()) { 4615 SmallVector<const IdentifierInfo*, 4> NewNameSpecifierIdentifiers; 4616 getNestedNameSpecifierIdentifiers(NNS, NewNameSpecifierIdentifiers); 4617 NumSpecifiers = llvm::ComputeEditDistance( 4618 llvm::makeArrayRef(CurNameSpecifierIdentifiers), 4619 llvm::makeArrayRef(NewNameSpecifierIdentifiers)); 4620 } 4621 4622 SpecifierInfo SI = {Ctx, NNS, NumSpecifiers}; 4623 DistanceMap[NumSpecifiers].push_back(SI); 4624 } 4625 4626 /// Perform name lookup for a possible result for typo correction. 4627 static void LookupPotentialTypoResult(Sema &SemaRef, 4628 LookupResult &Res, 4629 IdentifierInfo *Name, 4630 Scope *S, CXXScopeSpec *SS, 4631 DeclContext *MemberContext, 4632 bool EnteringContext, 4633 bool isObjCIvarLookup, 4634 bool FindHidden) { 4635 Res.suppressDiagnostics(); 4636 Res.clear(); 4637 Res.setLookupName(Name); 4638 Res.setAllowHidden(FindHidden); 4639 if (MemberContext) { 4640 if (ObjCInterfaceDecl *Class = dyn_cast<ObjCInterfaceDecl>(MemberContext)) { 4641 if (isObjCIvarLookup) { 4642 if (ObjCIvarDecl *Ivar = Class->lookupInstanceVariable(Name)) { 4643 Res.addDecl(Ivar); 4644 Res.resolveKind(); 4645 return; 4646 } 4647 } 4648 4649 if (ObjCPropertyDecl *Prop = Class->FindPropertyDeclaration( 4650 Name, ObjCPropertyQueryKind::OBJC_PR_query_instance)) { 4651 Res.addDecl(Prop); 4652 Res.resolveKind(); 4653 return; 4654 } 4655 } 4656 4657 SemaRef.LookupQualifiedName(Res, MemberContext); 4658 return; 4659 } 4660 4661 SemaRef.LookupParsedName(Res, S, SS, /*AllowBuiltinCreation=*/false, 4662 EnteringContext); 4663 4664 // Fake ivar lookup; this should really be part of 4665 // LookupParsedName. 4666 if (ObjCMethodDecl *Method = SemaRef.getCurMethodDecl()) { 4667 if (Method->isInstanceMethod() && Method->getClassInterface() && 4668 (Res.empty() || 4669 (Res.isSingleResult() && 4670 Res.getFoundDecl()->isDefinedOutsideFunctionOrMethod()))) { 4671 if (ObjCIvarDecl *IV 4672 = Method->getClassInterface()->lookupInstanceVariable(Name)) { 4673 Res.addDecl(IV); 4674 Res.resolveKind(); 4675 } 4676 } 4677 } 4678 } 4679 4680 /// Add keywords to the consumer as possible typo corrections. 4681 static void AddKeywordsToConsumer(Sema &SemaRef, 4682 TypoCorrectionConsumer &Consumer, 4683 Scope *S, CorrectionCandidateCallback &CCC, 4684 bool AfterNestedNameSpecifier) { 4685 if (AfterNestedNameSpecifier) { 4686 // For 'X::', we know exactly which keywords can appear next. 4687 Consumer.addKeywordResult("template"); 4688 if (CCC.WantExpressionKeywords) 4689 Consumer.addKeywordResult("operator"); 4690 return; 4691 } 4692 4693 if (CCC.WantObjCSuper) 4694 Consumer.addKeywordResult("super"); 4695 4696 if (CCC.WantTypeSpecifiers) { 4697 // Add type-specifier keywords to the set of results. 4698 static const char *const CTypeSpecs[] = { 4699 "char", "const", "double", "enum", "float", "int", "long", "short", 4700 "signed", "struct", "union", "unsigned", "void", "volatile", 4701 "_Complex", "_Imaginary", 4702 // storage-specifiers as well 4703 "extern", "inline", "static", "typedef" 4704 }; 4705 4706 const unsigned NumCTypeSpecs = llvm::array_lengthof(CTypeSpecs); 4707 for (unsigned I = 0; I != NumCTypeSpecs; ++I) 4708 Consumer.addKeywordResult(CTypeSpecs[I]); 4709 4710 if (SemaRef.getLangOpts().C99) 4711 Consumer.addKeywordResult("restrict"); 4712 if (SemaRef.getLangOpts().Bool || SemaRef.getLangOpts().CPlusPlus) 4713 Consumer.addKeywordResult("bool"); 4714 else if (SemaRef.getLangOpts().C99) 4715 Consumer.addKeywordResult("_Bool"); 4716 4717 if (SemaRef.getLangOpts().CPlusPlus) { 4718 Consumer.addKeywordResult("class"); 4719 Consumer.addKeywordResult("typename"); 4720 Consumer.addKeywordResult("wchar_t"); 4721 4722 if (SemaRef.getLangOpts().CPlusPlus11) { 4723 Consumer.addKeywordResult("char16_t"); 4724 Consumer.addKeywordResult("char32_t"); 4725 Consumer.addKeywordResult("constexpr"); 4726 Consumer.addKeywordResult("decltype"); 4727 Consumer.addKeywordResult("thread_local"); 4728 } 4729 } 4730 4731 if (SemaRef.getLangOpts().GNUKeywords) 4732 Consumer.addKeywordResult("typeof"); 4733 } else if (CCC.WantFunctionLikeCasts) { 4734 static const char *const CastableTypeSpecs[] = { 4735 "char", "double", "float", "int", "long", "short", 4736 "signed", "unsigned", "void" 4737 }; 4738 for (auto *kw : CastableTypeSpecs) 4739 Consumer.addKeywordResult(kw); 4740 } 4741 4742 if (CCC.WantCXXNamedCasts && SemaRef.getLangOpts().CPlusPlus) { 4743 Consumer.addKeywordResult("const_cast"); 4744 Consumer.addKeywordResult("dynamic_cast"); 4745 Consumer.addKeywordResult("reinterpret_cast"); 4746 Consumer.addKeywordResult("static_cast"); 4747 } 4748 4749 if (CCC.WantExpressionKeywords) { 4750 Consumer.addKeywordResult("sizeof"); 4751 if (SemaRef.getLangOpts().Bool || SemaRef.getLangOpts().CPlusPlus) { 4752 Consumer.addKeywordResult("false"); 4753 Consumer.addKeywordResult("true"); 4754 } 4755 4756 if (SemaRef.getLangOpts().CPlusPlus) { 4757 static const char *const CXXExprs[] = { 4758 "delete", "new", "operator", "throw", "typeid" 4759 }; 4760 const unsigned NumCXXExprs = llvm::array_lengthof(CXXExprs); 4761 for (unsigned I = 0; I != NumCXXExprs; ++I) 4762 Consumer.addKeywordResult(CXXExprs[I]); 4763 4764 if (isa<CXXMethodDecl>(SemaRef.CurContext) && 4765 cast<CXXMethodDecl>(SemaRef.CurContext)->isInstance()) 4766 Consumer.addKeywordResult("this"); 4767 4768 if (SemaRef.getLangOpts().CPlusPlus11) { 4769 Consumer.addKeywordResult("alignof"); 4770 Consumer.addKeywordResult("nullptr"); 4771 } 4772 } 4773 4774 if (SemaRef.getLangOpts().C11) { 4775 // FIXME: We should not suggest _Alignof if the alignof macro 4776 // is present. 4777 Consumer.addKeywordResult("_Alignof"); 4778 } 4779 } 4780 4781 if (CCC.WantRemainingKeywords) { 4782 if (SemaRef.getCurFunctionOrMethodDecl() || SemaRef.getCurBlock()) { 4783 // Statements. 4784 static const char *const CStmts[] = { 4785 "do", "else", "for", "goto", "if", "return", "switch", "while" }; 4786 const unsigned NumCStmts = llvm::array_lengthof(CStmts); 4787 for (unsigned I = 0; I != NumCStmts; ++I) 4788 Consumer.addKeywordResult(CStmts[I]); 4789 4790 if (SemaRef.getLangOpts().CPlusPlus) { 4791 Consumer.addKeywordResult("catch"); 4792 Consumer.addKeywordResult("try"); 4793 } 4794 4795 if (S && S->getBreakParent()) 4796 Consumer.addKeywordResult("break"); 4797 4798 if (S && S->getContinueParent()) 4799 Consumer.addKeywordResult("continue"); 4800 4801 if (SemaRef.getCurFunction() && 4802 !SemaRef.getCurFunction()->SwitchStack.empty()) { 4803 Consumer.addKeywordResult("case"); 4804 Consumer.addKeywordResult("default"); 4805 } 4806 } else { 4807 if (SemaRef.getLangOpts().CPlusPlus) { 4808 Consumer.addKeywordResult("namespace"); 4809 Consumer.addKeywordResult("template"); 4810 } 4811 4812 if (S && S->isClassScope()) { 4813 Consumer.addKeywordResult("explicit"); 4814 Consumer.addKeywordResult("friend"); 4815 Consumer.addKeywordResult("mutable"); 4816 Consumer.addKeywordResult("private"); 4817 Consumer.addKeywordResult("protected"); 4818 Consumer.addKeywordResult("public"); 4819 Consumer.addKeywordResult("virtual"); 4820 } 4821 } 4822 4823 if (SemaRef.getLangOpts().CPlusPlus) { 4824 Consumer.addKeywordResult("using"); 4825 4826 if (SemaRef.getLangOpts().CPlusPlus11) 4827 Consumer.addKeywordResult("static_assert"); 4828 } 4829 } 4830 } 4831 4832 std::unique_ptr<TypoCorrectionConsumer> Sema::makeTypoCorrectionConsumer( 4833 const DeclarationNameInfo &TypoName, Sema::LookupNameKind LookupKind, 4834 Scope *S, CXXScopeSpec *SS, CorrectionCandidateCallback &CCC, 4835 DeclContext *MemberContext, bool EnteringContext, 4836 const ObjCObjectPointerType *OPT, bool ErrorRecovery) { 4837 4838 if (Diags.hasFatalErrorOccurred() || !getLangOpts().SpellChecking || 4839 DisableTypoCorrection) 4840 return nullptr; 4841 4842 // In Microsoft mode, don't perform typo correction in a template member 4843 // function dependent context because it interferes with the "lookup into 4844 // dependent bases of class templates" feature. 4845 if (getLangOpts().MSVCCompat && CurContext->isDependentContext() && 4846 isa<CXXMethodDecl>(CurContext)) 4847 return nullptr; 4848 4849 // We only attempt to correct typos for identifiers. 4850 IdentifierInfo *Typo = TypoName.getName().getAsIdentifierInfo(); 4851 if (!Typo) 4852 return nullptr; 4853 4854 // If the scope specifier itself was invalid, don't try to correct 4855 // typos. 4856 if (SS && SS->isInvalid()) 4857 return nullptr; 4858 4859 // Never try to correct typos during any kind of code synthesis. 4860 if (!CodeSynthesisContexts.empty()) 4861 return nullptr; 4862 4863 // Don't try to correct 'super'. 4864 if (S && S->isInObjcMethodScope() && Typo == getSuperIdentifier()) 4865 return nullptr; 4866 4867 // Abort if typo correction already failed for this specific typo. 4868 IdentifierSourceLocations::iterator locs = TypoCorrectionFailures.find(Typo); 4869 if (locs != TypoCorrectionFailures.end() && 4870 locs->second.count(TypoName.getLoc())) 4871 return nullptr; 4872 4873 // Don't try to correct the identifier "vector" when in AltiVec mode. 4874 // TODO: Figure out why typo correction misbehaves in this case, fix it, and 4875 // remove this workaround. 4876 if ((getLangOpts().AltiVec || getLangOpts().ZVector) && Typo->isStr("vector")) 4877 return nullptr; 4878 4879 // Provide a stop gap for files that are just seriously broken. Trying 4880 // to correct all typos can turn into a HUGE performance penalty, causing 4881 // some files to take minutes to get rejected by the parser. 4882 unsigned Limit = getDiagnostics().getDiagnosticOptions().SpellCheckingLimit; 4883 if (Limit && TyposCorrected >= Limit) 4884 return nullptr; 4885 ++TyposCorrected; 4886 4887 // If we're handling a missing symbol error, using modules, and the 4888 // special search all modules option is used, look for a missing import. 4889 if (ErrorRecovery && getLangOpts().Modules && 4890 getLangOpts().ModulesSearchAll) { 4891 // The following has the side effect of loading the missing module. 4892 getModuleLoader().lookupMissingImports(Typo->getName(), 4893 TypoName.getBeginLoc()); 4894 } 4895 4896 // Extend the lifetime of the callback. We delayed this until here 4897 // to avoid allocations in the hot path (which is where no typo correction 4898 // occurs). Note that CorrectionCandidateCallback is polymorphic and 4899 // initially stack-allocated. 4900 std::unique_ptr<CorrectionCandidateCallback> ClonedCCC = CCC.clone(); 4901 auto Consumer = std::make_unique<TypoCorrectionConsumer>( 4902 *this, TypoName, LookupKind, S, SS, std::move(ClonedCCC), MemberContext, 4903 EnteringContext); 4904 4905 // Perform name lookup to find visible, similarly-named entities. 4906 bool IsUnqualifiedLookup = false; 4907 DeclContext *QualifiedDC = MemberContext; 4908 if (MemberContext) { 4909 LookupVisibleDecls(MemberContext, LookupKind, *Consumer); 4910 4911 // Look in qualified interfaces. 4912 if (OPT) { 4913 for (auto *I : OPT->quals()) 4914 LookupVisibleDecls(I, LookupKind, *Consumer); 4915 } 4916 } else if (SS && SS->isSet()) { 4917 QualifiedDC = computeDeclContext(*SS, EnteringContext); 4918 if (!QualifiedDC) 4919 return nullptr; 4920 4921 LookupVisibleDecls(QualifiedDC, LookupKind, *Consumer); 4922 } else { 4923 IsUnqualifiedLookup = true; 4924 } 4925 4926 // Determine whether we are going to search in the various namespaces for 4927 // corrections. 4928 bool SearchNamespaces 4929 = getLangOpts().CPlusPlus && 4930 (IsUnqualifiedLookup || (SS && SS->isSet())); 4931 4932 if (IsUnqualifiedLookup || SearchNamespaces) { 4933 // For unqualified lookup, look through all of the names that we have 4934 // seen in this translation unit. 4935 // FIXME: Re-add the ability to skip very unlikely potential corrections. 4936 for (const auto &I : Context.Idents) 4937 Consumer->FoundName(I.getKey()); 4938 4939 // Walk through identifiers in external identifier sources. 4940 // FIXME: Re-add the ability to skip very unlikely potential corrections. 4941 if (IdentifierInfoLookup *External 4942 = Context.Idents.getExternalIdentifierLookup()) { 4943 std::unique_ptr<IdentifierIterator> Iter(External->getIdentifiers()); 4944 do { 4945 StringRef Name = Iter->Next(); 4946 if (Name.empty()) 4947 break; 4948 4949 Consumer->FoundName(Name); 4950 } while (true); 4951 } 4952 } 4953 4954 AddKeywordsToConsumer(*this, *Consumer, S, 4955 *Consumer->getCorrectionValidator(), 4956 SS && SS->isNotEmpty()); 4957 4958 // Build the NestedNameSpecifiers for the KnownNamespaces, if we're going 4959 // to search those namespaces. 4960 if (SearchNamespaces) { 4961 // Load any externally-known namespaces. 4962 if (ExternalSource && !LoadedExternalKnownNamespaces) { 4963 SmallVector<NamespaceDecl *, 4> ExternalKnownNamespaces; 4964 LoadedExternalKnownNamespaces = true; 4965 ExternalSource->ReadKnownNamespaces(ExternalKnownNamespaces); 4966 for (auto *N : ExternalKnownNamespaces) 4967 KnownNamespaces[N] = true; 4968 } 4969 4970 Consumer->addNamespaces(KnownNamespaces); 4971 } 4972 4973 return Consumer; 4974 } 4975 4976 /// Try to "correct" a typo in the source code by finding 4977 /// visible declarations whose names are similar to the name that was 4978 /// present in the source code. 4979 /// 4980 /// \param TypoName the \c DeclarationNameInfo structure that contains 4981 /// the name that was present in the source code along with its location. 4982 /// 4983 /// \param LookupKind the name-lookup criteria used to search for the name. 4984 /// 4985 /// \param S the scope in which name lookup occurs. 4986 /// 4987 /// \param SS the nested-name-specifier that precedes the name we're 4988 /// looking for, if present. 4989 /// 4990 /// \param CCC A CorrectionCandidateCallback object that provides further 4991 /// validation of typo correction candidates. It also provides flags for 4992 /// determining the set of keywords permitted. 4993 /// 4994 /// \param MemberContext if non-NULL, the context in which to look for 4995 /// a member access expression. 4996 /// 4997 /// \param EnteringContext whether we're entering the context described by 4998 /// the nested-name-specifier SS. 4999 /// 5000 /// \param OPT when non-NULL, the search for visible declarations will 5001 /// also walk the protocols in the qualified interfaces of \p OPT. 5002 /// 5003 /// \returns a \c TypoCorrection containing the corrected name if the typo 5004 /// along with information such as the \c NamedDecl where the corrected name 5005 /// was declared, and any additional \c NestedNameSpecifier needed to access 5006 /// it (C++ only). The \c TypoCorrection is empty if there is no correction. 5007 TypoCorrection Sema::CorrectTypo(const DeclarationNameInfo &TypoName, 5008 Sema::LookupNameKind LookupKind, 5009 Scope *S, CXXScopeSpec *SS, 5010 CorrectionCandidateCallback &CCC, 5011 CorrectTypoKind Mode, 5012 DeclContext *MemberContext, 5013 bool EnteringContext, 5014 const ObjCObjectPointerType *OPT, 5015 bool RecordFailure) { 5016 // Always let the ExternalSource have the first chance at correction, even 5017 // if we would otherwise have given up. 5018 if (ExternalSource) { 5019 if (TypoCorrection Correction = 5020 ExternalSource->CorrectTypo(TypoName, LookupKind, S, SS, CCC, 5021 MemberContext, EnteringContext, OPT)) 5022 return Correction; 5023 } 5024 5025 // Ugly hack equivalent to CTC == CTC_ObjCMessageReceiver; 5026 // WantObjCSuper is only true for CTC_ObjCMessageReceiver and for 5027 // some instances of CTC_Unknown, while WantRemainingKeywords is true 5028 // for CTC_Unknown but not for CTC_ObjCMessageReceiver. 5029 bool ObjCMessageReceiver = CCC.WantObjCSuper && !CCC.WantRemainingKeywords; 5030 5031 IdentifierInfo *Typo = TypoName.getName().getAsIdentifierInfo(); 5032 auto Consumer = makeTypoCorrectionConsumer(TypoName, LookupKind, S, SS, CCC, 5033 MemberContext, EnteringContext, 5034 OPT, Mode == CTK_ErrorRecovery); 5035 5036 if (!Consumer) 5037 return TypoCorrection(); 5038 5039 // If we haven't found anything, we're done. 5040 if (Consumer->empty()) 5041 return FailedCorrection(Typo, TypoName.getLoc(), RecordFailure); 5042 5043 // Make sure the best edit distance (prior to adding any namespace qualifiers) 5044 // is not more that about a third of the length of the typo's identifier. 5045 unsigned ED = Consumer->getBestEditDistance(true); 5046 unsigned TypoLen = Typo->getName().size(); 5047 if (ED > 0 && TypoLen / ED < 3) 5048 return FailedCorrection(Typo, TypoName.getLoc(), RecordFailure); 5049 5050 TypoCorrection BestTC = Consumer->getNextCorrection(); 5051 TypoCorrection SecondBestTC = Consumer->getNextCorrection(); 5052 if (!BestTC) 5053 return FailedCorrection(Typo, TypoName.getLoc(), RecordFailure); 5054 5055 ED = BestTC.getEditDistance(); 5056 5057 if (TypoLen >= 3 && ED > 0 && TypoLen / ED < 3) { 5058 // If this was an unqualified lookup and we believe the callback 5059 // object wouldn't have filtered out possible corrections, note 5060 // that no correction was found. 5061 return FailedCorrection(Typo, TypoName.getLoc(), RecordFailure); 5062 } 5063 5064 // If only a single name remains, return that result. 5065 if (!SecondBestTC || 5066 SecondBestTC.getEditDistance(false) > BestTC.getEditDistance(false)) { 5067 const TypoCorrection &Result = BestTC; 5068 5069 // Don't correct to a keyword that's the same as the typo; the keyword 5070 // wasn't actually in scope. 5071 if (ED == 0 && Result.isKeyword()) 5072 return FailedCorrection(Typo, TypoName.getLoc(), RecordFailure); 5073 5074 TypoCorrection TC = Result; 5075 TC.setCorrectionRange(SS, TypoName); 5076 checkCorrectionVisibility(*this, TC); 5077 return TC; 5078 } else if (SecondBestTC && ObjCMessageReceiver) { 5079 // Prefer 'super' when we're completing in a message-receiver 5080 // context. 5081 5082 if (BestTC.getCorrection().getAsString() != "super") { 5083 if (SecondBestTC.getCorrection().getAsString() == "super") 5084 BestTC = SecondBestTC; 5085 else if ((*Consumer)["super"].front().isKeyword()) 5086 BestTC = (*Consumer)["super"].front(); 5087 } 5088 // Don't correct to a keyword that's the same as the typo; the keyword 5089 // wasn't actually in scope. 5090 if (BestTC.getEditDistance() == 0 || 5091 BestTC.getCorrection().getAsString() != "super") 5092 return FailedCorrection(Typo, TypoName.getLoc(), RecordFailure); 5093 5094 BestTC.setCorrectionRange(SS, TypoName); 5095 return BestTC; 5096 } 5097 5098 // Record the failure's location if needed and return an empty correction. If 5099 // this was an unqualified lookup and we believe the callback object did not 5100 // filter out possible corrections, also cache the failure for the typo. 5101 return FailedCorrection(Typo, TypoName.getLoc(), RecordFailure && !SecondBestTC); 5102 } 5103 5104 /// Try to "correct" a typo in the source code by finding 5105 /// visible declarations whose names are similar to the name that was 5106 /// present in the source code. 5107 /// 5108 /// \param TypoName the \c DeclarationNameInfo structure that contains 5109 /// the name that was present in the source code along with its location. 5110 /// 5111 /// \param LookupKind the name-lookup criteria used to search for the name. 5112 /// 5113 /// \param S the scope in which name lookup occurs. 5114 /// 5115 /// \param SS the nested-name-specifier that precedes the name we're 5116 /// looking for, if present. 5117 /// 5118 /// \param CCC A CorrectionCandidateCallback object that provides further 5119 /// validation of typo correction candidates. It also provides flags for 5120 /// determining the set of keywords permitted. 5121 /// 5122 /// \param TDG A TypoDiagnosticGenerator functor that will be used to print 5123 /// diagnostics when the actual typo correction is attempted. 5124 /// 5125 /// \param TRC A TypoRecoveryCallback functor that will be used to build an 5126 /// Expr from a typo correction candidate. 5127 /// 5128 /// \param MemberContext if non-NULL, the context in which to look for 5129 /// a member access expression. 5130 /// 5131 /// \param EnteringContext whether we're entering the context described by 5132 /// the nested-name-specifier SS. 5133 /// 5134 /// \param OPT when non-NULL, the search for visible declarations will 5135 /// also walk the protocols in the qualified interfaces of \p OPT. 5136 /// 5137 /// \returns a new \c TypoExpr that will later be replaced in the AST with an 5138 /// Expr representing the result of performing typo correction, or nullptr if 5139 /// typo correction is not possible. If nullptr is returned, no diagnostics will 5140 /// be emitted and it is the responsibility of the caller to emit any that are 5141 /// needed. 5142 TypoExpr *Sema::CorrectTypoDelayed( 5143 const DeclarationNameInfo &TypoName, Sema::LookupNameKind LookupKind, 5144 Scope *S, CXXScopeSpec *SS, CorrectionCandidateCallback &CCC, 5145 TypoDiagnosticGenerator TDG, TypoRecoveryCallback TRC, CorrectTypoKind Mode, 5146 DeclContext *MemberContext, bool EnteringContext, 5147 const ObjCObjectPointerType *OPT) { 5148 auto Consumer = makeTypoCorrectionConsumer(TypoName, LookupKind, S, SS, CCC, 5149 MemberContext, EnteringContext, 5150 OPT, Mode == CTK_ErrorRecovery); 5151 5152 // Give the external sema source a chance to correct the typo. 5153 TypoCorrection ExternalTypo; 5154 if (ExternalSource && Consumer) { 5155 ExternalTypo = ExternalSource->CorrectTypo( 5156 TypoName, LookupKind, S, SS, *Consumer->getCorrectionValidator(), 5157 MemberContext, EnteringContext, OPT); 5158 if (ExternalTypo) 5159 Consumer->addCorrection(ExternalTypo); 5160 } 5161 5162 if (!Consumer || Consumer->empty()) 5163 return nullptr; 5164 5165 // Make sure the best edit distance (prior to adding any namespace qualifiers) 5166 // is not more that about a third of the length of the typo's identifier. 5167 unsigned ED = Consumer->getBestEditDistance(true); 5168 IdentifierInfo *Typo = TypoName.getName().getAsIdentifierInfo(); 5169 if (!ExternalTypo && ED > 0 && Typo->getName().size() / ED < 3) 5170 return nullptr; 5171 ExprEvalContexts.back().NumTypos++; 5172 return createDelayedTypo(std::move(Consumer), std::move(TDG), std::move(TRC), 5173 TypoName.getLoc()); 5174 } 5175 5176 void TypoCorrection::addCorrectionDecl(NamedDecl *CDecl) { 5177 if (!CDecl) return; 5178 5179 if (isKeyword()) 5180 CorrectionDecls.clear(); 5181 5182 CorrectionDecls.push_back(CDecl); 5183 5184 if (!CorrectionName) 5185 CorrectionName = CDecl->getDeclName(); 5186 } 5187 5188 std::string TypoCorrection::getAsString(const LangOptions &LO) const { 5189 if (CorrectionNameSpec) { 5190 std::string tmpBuffer; 5191 llvm::raw_string_ostream PrefixOStream(tmpBuffer); 5192 CorrectionNameSpec->print(PrefixOStream, PrintingPolicy(LO)); 5193 PrefixOStream << CorrectionName; 5194 return PrefixOStream.str(); 5195 } 5196 5197 return CorrectionName.getAsString(); 5198 } 5199 5200 bool CorrectionCandidateCallback::ValidateCandidate( 5201 const TypoCorrection &candidate) { 5202 if (!candidate.isResolved()) 5203 return true; 5204 5205 if (candidate.isKeyword()) 5206 return WantTypeSpecifiers || WantExpressionKeywords || WantCXXNamedCasts || 5207 WantRemainingKeywords || WantObjCSuper; 5208 5209 bool HasNonType = false; 5210 bool HasStaticMethod = false; 5211 bool HasNonStaticMethod = false; 5212 for (Decl *D : candidate) { 5213 if (FunctionTemplateDecl *FTD = dyn_cast<FunctionTemplateDecl>(D)) 5214 D = FTD->getTemplatedDecl(); 5215 if (CXXMethodDecl *Method = dyn_cast<CXXMethodDecl>(D)) { 5216 if (Method->isStatic()) 5217 HasStaticMethod = true; 5218 else 5219 HasNonStaticMethod = true; 5220 } 5221 if (!isa<TypeDecl>(D)) 5222 HasNonType = true; 5223 } 5224 5225 if (IsAddressOfOperand && HasNonStaticMethod && !HasStaticMethod && 5226 !candidate.getCorrectionSpecifier()) 5227 return false; 5228 5229 return WantTypeSpecifiers || HasNonType; 5230 } 5231 5232 FunctionCallFilterCCC::FunctionCallFilterCCC(Sema &SemaRef, unsigned NumArgs, 5233 bool HasExplicitTemplateArgs, 5234 MemberExpr *ME) 5235 : NumArgs(NumArgs), HasExplicitTemplateArgs(HasExplicitTemplateArgs), 5236 CurContext(SemaRef.CurContext), MemberFn(ME) { 5237 WantTypeSpecifiers = false; 5238 WantFunctionLikeCasts = SemaRef.getLangOpts().CPlusPlus && 5239 !HasExplicitTemplateArgs && NumArgs == 1; 5240 WantCXXNamedCasts = HasExplicitTemplateArgs && NumArgs == 1; 5241 WantRemainingKeywords = false; 5242 } 5243 5244 bool FunctionCallFilterCCC::ValidateCandidate(const TypoCorrection &candidate) { 5245 if (!candidate.getCorrectionDecl()) 5246 return candidate.isKeyword(); 5247 5248 for (auto *C : candidate) { 5249 FunctionDecl *FD = nullptr; 5250 NamedDecl *ND = C->getUnderlyingDecl(); 5251 if (FunctionTemplateDecl *FTD = dyn_cast<FunctionTemplateDecl>(ND)) 5252 FD = FTD->getTemplatedDecl(); 5253 if (!HasExplicitTemplateArgs && !FD) { 5254 if (!(FD = dyn_cast<FunctionDecl>(ND)) && isa<ValueDecl>(ND)) { 5255 // If the Decl is neither a function nor a template function, 5256 // determine if it is a pointer or reference to a function. If so, 5257 // check against the number of arguments expected for the pointee. 5258 QualType ValType = cast<ValueDecl>(ND)->getType(); 5259 if (ValType.isNull()) 5260 continue; 5261 if (ValType->isAnyPointerType() || ValType->isReferenceType()) 5262 ValType = ValType->getPointeeType(); 5263 if (const FunctionProtoType *FPT = ValType->getAs<FunctionProtoType>()) 5264 if (FPT->getNumParams() == NumArgs) 5265 return true; 5266 } 5267 } 5268 5269 // A typo for a function-style cast can look like a function call in C++. 5270 if ((HasExplicitTemplateArgs ? getAsTypeTemplateDecl(ND) != nullptr 5271 : isa<TypeDecl>(ND)) && 5272 CurContext->getParentASTContext().getLangOpts().CPlusPlus) 5273 // Only a class or class template can take two or more arguments. 5274 return NumArgs <= 1 || HasExplicitTemplateArgs || isa<CXXRecordDecl>(ND); 5275 5276 // Skip the current candidate if it is not a FunctionDecl or does not accept 5277 // the current number of arguments. 5278 if (!FD || !(FD->getNumParams() >= NumArgs && 5279 FD->getMinRequiredArguments() <= NumArgs)) 5280 continue; 5281 5282 // If the current candidate is a non-static C++ method, skip the candidate 5283 // unless the method being corrected--or the current DeclContext, if the 5284 // function being corrected is not a method--is a method in the same class 5285 // or a descendent class of the candidate's parent class. 5286 if (CXXMethodDecl *MD = dyn_cast<CXXMethodDecl>(FD)) { 5287 if (MemberFn || !MD->isStatic()) { 5288 CXXMethodDecl *CurMD = 5289 MemberFn 5290 ? dyn_cast_or_null<CXXMethodDecl>(MemberFn->getMemberDecl()) 5291 : dyn_cast_or_null<CXXMethodDecl>(CurContext); 5292 CXXRecordDecl *CurRD = 5293 CurMD ? CurMD->getParent()->getCanonicalDecl() : nullptr; 5294 CXXRecordDecl *RD = MD->getParent()->getCanonicalDecl(); 5295 if (!CurRD || (CurRD != RD && !CurRD->isDerivedFrom(RD))) 5296 continue; 5297 } 5298 } 5299 return true; 5300 } 5301 return false; 5302 } 5303 5304 void Sema::diagnoseTypo(const TypoCorrection &Correction, 5305 const PartialDiagnostic &TypoDiag, 5306 bool ErrorRecovery) { 5307 diagnoseTypo(Correction, TypoDiag, PDiag(diag::note_previous_decl), 5308 ErrorRecovery); 5309 } 5310 5311 /// Find which declaration we should import to provide the definition of 5312 /// the given declaration. 5313 static NamedDecl *getDefinitionToImport(NamedDecl *D) { 5314 if (VarDecl *VD = dyn_cast<VarDecl>(D)) 5315 return VD->getDefinition(); 5316 if (FunctionDecl *FD = dyn_cast<FunctionDecl>(D)) 5317 return FD->getDefinition(); 5318 if (TagDecl *TD = dyn_cast<TagDecl>(D)) 5319 return TD->getDefinition(); 5320 // The first definition for this ObjCInterfaceDecl might be in the TU 5321 // and not associated with any module. Use the one we know to be complete 5322 // and have just seen in a module. 5323 if (ObjCInterfaceDecl *ID = dyn_cast<ObjCInterfaceDecl>(D)) 5324 return ID; 5325 if (ObjCProtocolDecl *PD = dyn_cast<ObjCProtocolDecl>(D)) 5326 return PD->getDefinition(); 5327 if (TemplateDecl *TD = dyn_cast<TemplateDecl>(D)) 5328 if (NamedDecl *TTD = TD->getTemplatedDecl()) 5329 return getDefinitionToImport(TTD); 5330 return nullptr; 5331 } 5332 5333 void Sema::diagnoseMissingImport(SourceLocation Loc, NamedDecl *Decl, 5334 MissingImportKind MIK, bool Recover) { 5335 // Suggest importing a module providing the definition of this entity, if 5336 // possible. 5337 NamedDecl *Def = getDefinitionToImport(Decl); 5338 if (!Def) 5339 Def = Decl; 5340 5341 Module *Owner = getOwningModule(Def); 5342 assert(Owner && "definition of hidden declaration is not in a module"); 5343 5344 llvm::SmallVector<Module*, 8> OwningModules; 5345 OwningModules.push_back(Owner); 5346 auto Merged = Context.getModulesWithMergedDefinition(Def); 5347 OwningModules.insert(OwningModules.end(), Merged.begin(), Merged.end()); 5348 5349 diagnoseMissingImport(Loc, Def, Def->getLocation(), OwningModules, MIK, 5350 Recover); 5351 } 5352 5353 /// Get a "quoted.h" or <angled.h> include path to use in a diagnostic 5354 /// suggesting the addition of a #include of the specified file. 5355 static std::string getHeaderNameForHeader(Preprocessor &PP, const FileEntry *E, 5356 llvm::StringRef IncludingFile) { 5357 bool IsSystem = false; 5358 auto Path = PP.getHeaderSearchInfo().suggestPathToFileForDiagnostics( 5359 E, IncludingFile, &IsSystem); 5360 return (IsSystem ? '<' : '"') + Path + (IsSystem ? '>' : '"'); 5361 } 5362 5363 void Sema::diagnoseMissingImport(SourceLocation UseLoc, NamedDecl *Decl, 5364 SourceLocation DeclLoc, 5365 ArrayRef<Module *> Modules, 5366 MissingImportKind MIK, bool Recover) { 5367 assert(!Modules.empty()); 5368 5369 auto NotePrevious = [&] { 5370 // FIXME: Suppress the note backtrace even under 5371 // -fdiagnostics-show-note-include-stack. We don't care how this 5372 // declaration was previously reached. 5373 Diag(DeclLoc, diag::note_unreachable_entity) << (int)MIK; 5374 }; 5375 5376 // Weed out duplicates from module list. 5377 llvm::SmallVector<Module*, 8> UniqueModules; 5378 llvm::SmallDenseSet<Module*, 8> UniqueModuleSet; 5379 for (auto *M : Modules) { 5380 if (M->Kind == Module::GlobalModuleFragment) 5381 continue; 5382 if (UniqueModuleSet.insert(M).second) 5383 UniqueModules.push_back(M); 5384 } 5385 5386 // Try to find a suitable header-name to #include. 5387 std::string HeaderName; 5388 if (const FileEntry *Header = 5389 PP.getHeaderToIncludeForDiagnostics(UseLoc, DeclLoc)) { 5390 if (const FileEntry *FE = 5391 SourceMgr.getFileEntryForID(SourceMgr.getFileID(UseLoc))) 5392 HeaderName = getHeaderNameForHeader(PP, Header, FE->tryGetRealPathName()); 5393 } 5394 5395 // If we have a #include we should suggest, or if all definition locations 5396 // were in global module fragments, don't suggest an import. 5397 if (!HeaderName.empty() || UniqueModules.empty()) { 5398 // FIXME: Find a smart place to suggest inserting a #include, and add 5399 // a FixItHint there. 5400 Diag(UseLoc, diag::err_module_unimported_use_header) 5401 << (int)MIK << Decl << !HeaderName.empty() << HeaderName; 5402 // Produce a note showing where the entity was declared. 5403 NotePrevious(); 5404 if (Recover) 5405 createImplicitModuleImportForErrorRecovery(UseLoc, Modules[0]); 5406 return; 5407 } 5408 5409 Modules = UniqueModules; 5410 5411 if (Modules.size() > 1) { 5412 std::string ModuleList; 5413 unsigned N = 0; 5414 for (Module *M : Modules) { 5415 ModuleList += "\n "; 5416 if (++N == 5 && N != Modules.size()) { 5417 ModuleList += "[...]"; 5418 break; 5419 } 5420 ModuleList += M->getFullModuleName(); 5421 } 5422 5423 Diag(UseLoc, diag::err_module_unimported_use_multiple) 5424 << (int)MIK << Decl << ModuleList; 5425 } else { 5426 // FIXME: Add a FixItHint that imports the corresponding module. 5427 Diag(UseLoc, diag::err_module_unimported_use) 5428 << (int)MIK << Decl << Modules[0]->getFullModuleName(); 5429 } 5430 5431 NotePrevious(); 5432 5433 // Try to recover by implicitly importing this module. 5434 if (Recover) 5435 createImplicitModuleImportForErrorRecovery(UseLoc, Modules[0]); 5436 } 5437 5438 /// Diagnose a successfully-corrected typo. Separated from the correction 5439 /// itself to allow external validation of the result, etc. 5440 /// 5441 /// \param Correction The result of performing typo correction. 5442 /// \param TypoDiag The diagnostic to produce. This will have the corrected 5443 /// string added to it (and usually also a fixit). 5444 /// \param PrevNote A note to use when indicating the location of the entity to 5445 /// which we are correcting. Will have the correction string added to it. 5446 /// \param ErrorRecovery If \c true (the default), the caller is going to 5447 /// recover from the typo as if the corrected string had been typed. 5448 /// In this case, \c PDiag must be an error, and we will attach a fixit 5449 /// to it. 5450 void Sema::diagnoseTypo(const TypoCorrection &Correction, 5451 const PartialDiagnostic &TypoDiag, 5452 const PartialDiagnostic &PrevNote, 5453 bool ErrorRecovery) { 5454 std::string CorrectedStr = Correction.getAsString(getLangOpts()); 5455 std::string CorrectedQuotedStr = Correction.getQuoted(getLangOpts()); 5456 FixItHint FixTypo = FixItHint::CreateReplacement( 5457 Correction.getCorrectionRange(), CorrectedStr); 5458 5459 // Maybe we're just missing a module import. 5460 if (Correction.requiresImport()) { 5461 NamedDecl *Decl = Correction.getFoundDecl(); 5462 assert(Decl && "import required but no declaration to import"); 5463 5464 diagnoseMissingImport(Correction.getCorrectionRange().getBegin(), Decl, 5465 MissingImportKind::Declaration, ErrorRecovery); 5466 return; 5467 } 5468 5469 Diag(Correction.getCorrectionRange().getBegin(), TypoDiag) 5470 << CorrectedQuotedStr << (ErrorRecovery ? FixTypo : FixItHint()); 5471 5472 NamedDecl *ChosenDecl = 5473 Correction.isKeyword() ? nullptr : Correction.getFoundDecl(); 5474 if (PrevNote.getDiagID() && ChosenDecl) 5475 Diag(ChosenDecl->getLocation(), PrevNote) 5476 << CorrectedQuotedStr << (ErrorRecovery ? FixItHint() : FixTypo); 5477 5478 // Add any extra diagnostics. 5479 for (const PartialDiagnostic &PD : Correction.getExtraDiagnostics()) 5480 Diag(Correction.getCorrectionRange().getBegin(), PD); 5481 } 5482 5483 TypoExpr *Sema::createDelayedTypo(std::unique_ptr<TypoCorrectionConsumer> TCC, 5484 TypoDiagnosticGenerator TDG, 5485 TypoRecoveryCallback TRC, 5486 SourceLocation TypoLoc) { 5487 assert(TCC && "createDelayedTypo requires a valid TypoCorrectionConsumer"); 5488 auto TE = new (Context) TypoExpr(Context.DependentTy, TypoLoc); 5489 auto &State = DelayedTypos[TE]; 5490 State.Consumer = std::move(TCC); 5491 State.DiagHandler = std::move(TDG); 5492 State.RecoveryHandler = std::move(TRC); 5493 if (TE) 5494 TypoExprs.push_back(TE); 5495 return TE; 5496 } 5497 5498 const Sema::TypoExprState &Sema::getTypoExprState(TypoExpr *TE) const { 5499 auto Entry = DelayedTypos.find(TE); 5500 assert(Entry != DelayedTypos.end() && 5501 "Failed to get the state for a TypoExpr!"); 5502 return Entry->second; 5503 } 5504 5505 void Sema::clearDelayedTypo(TypoExpr *TE) { 5506 DelayedTypos.erase(TE); 5507 } 5508 5509 void Sema::ActOnPragmaDump(Scope *S, SourceLocation IILoc, IdentifierInfo *II) { 5510 DeclarationNameInfo Name(II, IILoc); 5511 LookupResult R(*this, Name, LookupAnyName, Sema::NotForRedeclaration); 5512 R.suppressDiagnostics(); 5513 R.setHideTags(false); 5514 LookupName(R, S); 5515 R.dump(); 5516 } 5517