1 //===--- CodeComplete.cpp ----------------------------------------*- C++-*-===// 2 // 3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4 // See https://llvm.org/LICENSE.txt for license information. 5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6 // 7 //===----------------------------------------------------------------------===// 8 // 9 // Code completion has several moving parts: 10 // - AST-based completions are provided using the completion hooks in Sema. 11 // - external completions are retrieved from the index (using hints from Sema) 12 // - the two sources overlap, and must be merged and overloads bundled 13 // - results must be scored and ranked (see Quality.h) before rendering 14 // 15 // Signature help works in a similar way as code completion, but it is simpler: 16 // it's purely AST-based, and there are few candidates. 17 // 18 //===----------------------------------------------------------------------===// 19 20 #include "CodeComplete.h" 21 #include "AST.h" 22 #include "CodeCompletionStrings.h" 23 #include "Compiler.h" 24 #include "Diagnostics.h" 25 #include "ExpectedTypes.h" 26 #include "FileDistance.h" 27 #include "FuzzyMatch.h" 28 #include "Headers.h" 29 #include "Hover.h" 30 #include "Preamble.h" 31 #include "Protocol.h" 32 #include "Quality.h" 33 #include "SourceCode.h" 34 #include "TUScheduler.h" 35 #include "URI.h" 36 #include "index/Index.h" 37 #include "index/Symbol.h" 38 #include "index/SymbolOrigin.h" 39 #include "support/Logger.h" 40 #include "support/Threading.h" 41 #include "support/ThreadsafeFS.h" 42 #include "support/Trace.h" 43 #include "clang/AST/Decl.h" 44 #include "clang/AST/DeclBase.h" 45 #include "clang/Basic/CharInfo.h" 46 #include "clang/Basic/LangOptions.h" 47 #include "clang/Basic/SourceLocation.h" 48 #include "clang/Basic/TokenKinds.h" 49 #include "clang/Format/Format.h" 50 #include "clang/Frontend/CompilerInstance.h" 51 #include "clang/Frontend/FrontendActions.h" 52 #include "clang/Lex/ExternalPreprocessorSource.h" 53 #include "clang/Lex/Lexer.h" 54 #include "clang/Lex/Preprocessor.h" 55 #include "clang/Lex/PreprocessorOptions.h" 56 #include "clang/Sema/CodeCompleteConsumer.h" 57 #include "clang/Sema/DeclSpec.h" 58 #include "clang/Sema/Sema.h" 59 #include "llvm/ADT/ArrayRef.h" 60 #include "llvm/ADT/None.h" 61 #include "llvm/ADT/Optional.h" 62 #include "llvm/ADT/SmallVector.h" 63 #include "llvm/ADT/StringExtras.h" 64 #include "llvm/ADT/StringRef.h" 65 #include "llvm/Support/Compiler.h" 66 #include "llvm/Support/Debug.h" 67 #include "llvm/Support/Error.h" 68 #include "llvm/Support/Format.h" 69 #include "llvm/Support/FormatVariadic.h" 70 #include "llvm/Support/ScopedPrinter.h" 71 #include <algorithm> 72 #include <iterator> 73 74 // We log detailed candidate here if you run with -debug-only=codecomplete. 75 #define DEBUG_TYPE "CodeComplete" 76 77 namespace clang { 78 namespace clangd { 79 namespace { 80 81 CompletionItemKind toCompletionItemKind(index::SymbolKind Kind) { 82 using SK = index::SymbolKind; 83 switch (Kind) { 84 case SK::Unknown: 85 return CompletionItemKind::Missing; 86 case SK::Module: 87 case SK::Namespace: 88 case SK::NamespaceAlias: 89 return CompletionItemKind::Module; 90 case SK::Macro: 91 return CompletionItemKind::Text; 92 case SK::Enum: 93 return CompletionItemKind::Enum; 94 case SK::Struct: 95 return CompletionItemKind::Struct; 96 case SK::Class: 97 case SK::Protocol: 98 case SK::Extension: 99 case SK::Union: 100 return CompletionItemKind::Class; 101 case SK::TypeAlias: 102 // We use the same kind as the VSCode C++ extension. 103 // FIXME: pick a better option when we have one. 104 return CompletionItemKind::Interface; 105 case SK::Using: 106 return CompletionItemKind::Reference; 107 case SK::Function: 108 case SK::ConversionFunction: 109 return CompletionItemKind::Function; 110 case SK::Variable: 111 case SK::Parameter: 112 case SK::NonTypeTemplateParm: 113 return CompletionItemKind::Variable; 114 case SK::Field: 115 return CompletionItemKind::Field; 116 case SK::EnumConstant: 117 return CompletionItemKind::EnumMember; 118 case SK::InstanceMethod: 119 case SK::ClassMethod: 120 case SK::StaticMethod: 121 case SK::Destructor: 122 return CompletionItemKind::Method; 123 case SK::InstanceProperty: 124 case SK::ClassProperty: 125 case SK::StaticProperty: 126 return CompletionItemKind::Property; 127 case SK::Constructor: 128 return CompletionItemKind::Constructor; 129 case SK::TemplateTypeParm: 130 case SK::TemplateTemplateParm: 131 return CompletionItemKind::TypeParameter; 132 } 133 llvm_unreachable("Unhandled clang::index::SymbolKind."); 134 } 135 136 CompletionItemKind 137 toCompletionItemKind(CodeCompletionResult::ResultKind ResKind, 138 const NamedDecl *Decl, 139 CodeCompletionContext::Kind CtxKind) { 140 if (Decl) 141 return toCompletionItemKind(index::getSymbolInfo(Decl).Kind); 142 if (CtxKind == CodeCompletionContext::CCC_IncludedFile) 143 return CompletionItemKind::File; 144 switch (ResKind) { 145 case CodeCompletionResult::RK_Declaration: 146 llvm_unreachable("RK_Declaration without Decl"); 147 case CodeCompletionResult::RK_Keyword: 148 return CompletionItemKind::Keyword; 149 case CodeCompletionResult::RK_Macro: 150 return CompletionItemKind::Text; // unfortunately, there's no 'Macro' 151 // completion items in LSP. 152 case CodeCompletionResult::RK_Pattern: 153 return CompletionItemKind::Snippet; 154 } 155 llvm_unreachable("Unhandled CodeCompletionResult::ResultKind."); 156 } 157 158 // Identifier code completion result. 159 struct RawIdentifier { 160 llvm::StringRef Name; 161 unsigned References; // # of usages in file. 162 }; 163 164 /// A code completion result, in clang-native form. 165 /// It may be promoted to a CompletionItem if it's among the top-ranked results. 166 struct CompletionCandidate { 167 llvm::StringRef Name; // Used for filtering and sorting. 168 // We may have a result from Sema, from the index, or both. 169 const CodeCompletionResult *SemaResult = nullptr; 170 const Symbol *IndexResult = nullptr; 171 const RawIdentifier *IdentifierResult = nullptr; 172 llvm::SmallVector<llvm::StringRef, 1> RankedIncludeHeaders; 173 174 // Returns a token identifying the overload set this is part of. 175 // 0 indicates it's not part of any overload set. 176 size_t overloadSet(const CodeCompleteOptions &Opts, llvm::StringRef FileName, 177 IncludeInserter *Inserter) const { 178 if (!Opts.BundleOverloads.getValueOr(false)) 179 return 0; 180 181 // Depending on the index implementation, we can see different header 182 // strings (literal or URI) mapping to the same file. We still want to 183 // bundle those, so we must resolve the header to be included here. 184 std::string HeaderForHash; 185 if (Inserter) 186 if (auto Header = headerToInsertIfAllowed(Opts)) 187 if (auto HeaderFile = toHeaderFile(*Header, FileName)) 188 if (auto Spelled = 189 Inserter->calculateIncludePath(*HeaderFile, FileName)) 190 HeaderForHash = *Spelled; 191 192 llvm::SmallString<256> Scratch; 193 if (IndexResult) { 194 switch (IndexResult->SymInfo.Kind) { 195 case index::SymbolKind::ClassMethod: 196 case index::SymbolKind::InstanceMethod: 197 case index::SymbolKind::StaticMethod: 198 #ifndef NDEBUG 199 llvm_unreachable("Don't expect members from index in code completion"); 200 #else 201 LLVM_FALLTHROUGH; 202 #endif 203 case index::SymbolKind::Function: 204 // We can't group overloads together that need different #includes. 205 // This could break #include insertion. 206 return llvm::hash_combine( 207 (IndexResult->Scope + IndexResult->Name).toStringRef(Scratch), 208 HeaderForHash); 209 default: 210 return 0; 211 } 212 } 213 if (SemaResult) { 214 // We need to make sure we're consistent with the IndexResult case! 215 const NamedDecl *D = SemaResult->Declaration; 216 if (!D || !D->isFunctionOrFunctionTemplate()) 217 return 0; 218 { 219 llvm::raw_svector_ostream OS(Scratch); 220 D->printQualifiedName(OS); 221 } 222 return llvm::hash_combine(Scratch, HeaderForHash); 223 } 224 assert(IdentifierResult); 225 return 0; 226 } 227 228 // The best header to include if include insertion is allowed. 229 llvm::Optional<llvm::StringRef> 230 headerToInsertIfAllowed(const CodeCompleteOptions &Opts) const { 231 if (Opts.InsertIncludes == CodeCompleteOptions::NeverInsert || 232 RankedIncludeHeaders.empty()) 233 return None; 234 if (SemaResult && SemaResult->Declaration) { 235 // Avoid inserting new #include if the declaration is found in the current 236 // file e.g. the symbol is forward declared. 237 auto &SM = SemaResult->Declaration->getASTContext().getSourceManager(); 238 for (const Decl *RD : SemaResult->Declaration->redecls()) 239 if (SM.isInMainFile(SM.getExpansionLoc(RD->getBeginLoc()))) 240 return None; 241 } 242 return RankedIncludeHeaders[0]; 243 } 244 245 using Bundle = llvm::SmallVector<CompletionCandidate, 4>; 246 }; 247 using ScoredBundle = 248 std::pair<CompletionCandidate::Bundle, CodeCompletion::Scores>; 249 struct ScoredBundleGreater { 250 bool operator()(const ScoredBundle &L, const ScoredBundle &R) { 251 if (L.second.Total != R.second.Total) 252 return L.second.Total > R.second.Total; 253 return L.first.front().Name < 254 R.first.front().Name; // Earlier name is better. 255 } 256 }; 257 258 // Assembles a code completion out of a bundle of >=1 completion candidates. 259 // Many of the expensive strings are only computed at this point, once we know 260 // the candidate bundle is going to be returned. 261 // 262 // Many fields are the same for all candidates in a bundle (e.g. name), and are 263 // computed from the first candidate, in the constructor. 264 // Others vary per candidate, so add() must be called for remaining candidates. 265 struct CodeCompletionBuilder { 266 CodeCompletionBuilder(ASTContext *ASTCtx, const CompletionCandidate &C, 267 CodeCompletionString *SemaCCS, 268 llvm::ArrayRef<std::string> QueryScopes, 269 const IncludeInserter &Includes, 270 llvm::StringRef FileName, 271 CodeCompletionContext::Kind ContextKind, 272 const CodeCompleteOptions &Opts, 273 bool IsUsingDeclaration, tok::TokenKind NextTokenKind) 274 : ASTCtx(ASTCtx), ExtractDocumentation(Opts.IncludeComments), 275 EnableFunctionArgSnippets(Opts.EnableFunctionArgSnippets), 276 IsUsingDeclaration(IsUsingDeclaration), NextTokenKind(NextTokenKind) { 277 add(C, SemaCCS); 278 if (C.SemaResult) { 279 assert(ASTCtx); 280 Completion.Origin |= SymbolOrigin::AST; 281 Completion.Name = std::string(llvm::StringRef(SemaCCS->getTypedText())); 282 if (Completion.Scope.empty()) { 283 if ((C.SemaResult->Kind == CodeCompletionResult::RK_Declaration) || 284 (C.SemaResult->Kind == CodeCompletionResult::RK_Pattern)) 285 if (const auto *D = C.SemaResult->getDeclaration()) 286 if (const auto *ND = dyn_cast<NamedDecl>(D)) 287 Completion.Scope = std::string( 288 splitQualifiedName(printQualifiedName(*ND)).first); 289 } 290 Completion.Kind = toCompletionItemKind( 291 C.SemaResult->Kind, C.SemaResult->Declaration, ContextKind); 292 // Sema could provide more info on whether the completion was a file or 293 // folder. 294 if (Completion.Kind == CompletionItemKind::File && 295 Completion.Name.back() == '/') 296 Completion.Kind = CompletionItemKind::Folder; 297 for (const auto &FixIt : C.SemaResult->FixIts) { 298 Completion.FixIts.push_back(toTextEdit( 299 FixIt, ASTCtx->getSourceManager(), ASTCtx->getLangOpts())); 300 } 301 llvm::sort(Completion.FixIts, [](const TextEdit &X, const TextEdit &Y) { 302 return std::tie(X.range.start.line, X.range.start.character) < 303 std::tie(Y.range.start.line, Y.range.start.character); 304 }); 305 Completion.Deprecated |= 306 (C.SemaResult->Availability == CXAvailability_Deprecated); 307 } 308 if (C.IndexResult) { 309 Completion.Origin |= C.IndexResult->Origin; 310 if (Completion.Scope.empty()) 311 Completion.Scope = std::string(C.IndexResult->Scope); 312 if (Completion.Kind == CompletionItemKind::Missing) 313 Completion.Kind = toCompletionItemKind(C.IndexResult->SymInfo.Kind); 314 if (Completion.Name.empty()) 315 Completion.Name = std::string(C.IndexResult->Name); 316 // If the completion was visible to Sema, no qualifier is needed. This 317 // avoids unneeded qualifiers in cases like with `using ns::X`. 318 if (Completion.RequiredQualifier.empty() && !C.SemaResult) { 319 llvm::StringRef ShortestQualifier = C.IndexResult->Scope; 320 for (llvm::StringRef Scope : QueryScopes) { 321 llvm::StringRef Qualifier = C.IndexResult->Scope; 322 if (Qualifier.consume_front(Scope) && 323 Qualifier.size() < ShortestQualifier.size()) 324 ShortestQualifier = Qualifier; 325 } 326 Completion.RequiredQualifier = std::string(ShortestQualifier); 327 } 328 Completion.Deprecated |= (C.IndexResult->Flags & Symbol::Deprecated); 329 } 330 if (C.IdentifierResult) { 331 Completion.Origin |= SymbolOrigin::Identifier; 332 Completion.Kind = CompletionItemKind::Text; 333 Completion.Name = std::string(C.IdentifierResult->Name); 334 } 335 336 // Turn absolute path into a literal string that can be #included. 337 auto Inserted = [&](llvm::StringRef Header) 338 -> llvm::Expected<std::pair<std::string, bool>> { 339 auto ResolvedDeclaring = 340 URI::resolve(C.IndexResult->CanonicalDeclaration.FileURI, FileName); 341 if (!ResolvedDeclaring) 342 return ResolvedDeclaring.takeError(); 343 auto ResolvedInserted = toHeaderFile(Header, FileName); 344 if (!ResolvedInserted) 345 return ResolvedInserted.takeError(); 346 auto Spelled = Includes.calculateIncludePath(*ResolvedInserted, FileName); 347 if (!Spelled) 348 return error("Header not on include path"); 349 return std::make_pair( 350 std::move(*Spelled), 351 Includes.shouldInsertInclude(*ResolvedDeclaring, *ResolvedInserted)); 352 }; 353 bool ShouldInsert = C.headerToInsertIfAllowed(Opts).hasValue(); 354 // Calculate include paths and edits for all possible headers. 355 for (const auto &Inc : C.RankedIncludeHeaders) { 356 if (auto ToInclude = Inserted(Inc)) { 357 CodeCompletion::IncludeCandidate Include; 358 Include.Header = ToInclude->first; 359 if (ToInclude->second && ShouldInsert) 360 Include.Insertion = Includes.insert(ToInclude->first); 361 Completion.Includes.push_back(std::move(Include)); 362 } else 363 log("Failed to generate include insertion edits for adding header " 364 "(FileURI='{0}', IncludeHeader='{1}') into {2}: {3}", 365 C.IndexResult->CanonicalDeclaration.FileURI, Inc, FileName, 366 ToInclude.takeError()); 367 } 368 // Prefer includes that do not need edits (i.e. already exist). 369 std::stable_partition(Completion.Includes.begin(), 370 Completion.Includes.end(), 371 [](const CodeCompletion::IncludeCandidate &I) { 372 return !I.Insertion.hasValue(); 373 }); 374 } 375 376 void add(const CompletionCandidate &C, CodeCompletionString *SemaCCS) { 377 assert(bool(C.SemaResult) == bool(SemaCCS)); 378 Bundled.emplace_back(); 379 BundledEntry &S = Bundled.back(); 380 if (C.SemaResult) { 381 bool IsPattern = C.SemaResult->Kind == CodeCompletionResult::RK_Pattern; 382 getSignature(*SemaCCS, &S.Signature, &S.SnippetSuffix, 383 &Completion.RequiredQualifier, IsPattern); 384 S.ReturnType = getReturnType(*SemaCCS); 385 } else if (C.IndexResult) { 386 S.Signature = std::string(C.IndexResult->Signature); 387 S.SnippetSuffix = std::string(C.IndexResult->CompletionSnippetSuffix); 388 S.ReturnType = std::string(C.IndexResult->ReturnType); 389 } 390 if (ExtractDocumentation && !Completion.Documentation) { 391 auto SetDoc = [&](llvm::StringRef Doc) { 392 if (!Doc.empty()) { 393 Completion.Documentation.emplace(); 394 parseDocumentation(Doc, *Completion.Documentation); 395 } 396 }; 397 if (C.IndexResult) { 398 SetDoc(C.IndexResult->Documentation); 399 } else if (C.SemaResult) { 400 SetDoc(getDocComment(*ASTCtx, *C.SemaResult, 401 /*CommentsFromHeader=*/false)); 402 } 403 } 404 } 405 406 CodeCompletion build() { 407 Completion.ReturnType = summarizeReturnType(); 408 Completion.Signature = summarizeSignature(); 409 Completion.SnippetSuffix = summarizeSnippet(); 410 Completion.BundleSize = Bundled.size(); 411 return std::move(Completion); 412 } 413 414 private: 415 struct BundledEntry { 416 std::string SnippetSuffix; 417 std::string Signature; 418 std::string ReturnType; 419 }; 420 421 // If all BundledEntries have the same value for a property, return it. 422 template <std::string BundledEntry::*Member> 423 const std::string *onlyValue() const { 424 auto B = Bundled.begin(), E = Bundled.end(); 425 for (auto I = B + 1; I != E; ++I) 426 if (I->*Member != B->*Member) 427 return nullptr; 428 return &(B->*Member); 429 } 430 431 template <bool BundledEntry::*Member> const bool *onlyValue() const { 432 auto B = Bundled.begin(), E = Bundled.end(); 433 for (auto I = B + 1; I != E; ++I) 434 if (I->*Member != B->*Member) 435 return nullptr; 436 return &(B->*Member); 437 } 438 439 std::string summarizeReturnType() const { 440 if (auto *RT = onlyValue<&BundledEntry::ReturnType>()) 441 return *RT; 442 return ""; 443 } 444 445 std::string summarizeSnippet() const { 446 if (IsUsingDeclaration) 447 return ""; 448 // Suppress function argument snippets if args are already present. 449 if ((Completion.Kind == CompletionItemKind::Function || 450 Completion.Kind == CompletionItemKind::Method || 451 Completion.Kind == CompletionItemKind::Constructor) && 452 NextTokenKind == tok::l_paren) 453 return ""; 454 auto *Snippet = onlyValue<&BundledEntry::SnippetSuffix>(); 455 if (!Snippet) 456 // All bundles are function calls. 457 // FIXME(ibiryukov): sometimes add template arguments to a snippet, e.g. 458 // we need to complete 'forward<$1>($0)'. 459 return "($0)"; 460 if (EnableFunctionArgSnippets) 461 return *Snippet; 462 463 // Replace argument snippets with a simplified pattern. 464 if (Snippet->empty()) 465 return ""; 466 if (Completion.Kind == CompletionItemKind::Function || 467 Completion.Kind == CompletionItemKind::Method) { 468 // Functions snippets can be of 2 types: 469 // - containing only function arguments, e.g. 470 // foo(${1:int p1}, ${2:int p2}); 471 // We transform this pattern to '($0)' or '()'. 472 // - template arguments and function arguments, e.g. 473 // foo<${1:class}>(${2:int p1}). 474 // We transform this pattern to '<$1>()$0' or '<$0>()'. 475 476 bool EmptyArgs = llvm::StringRef(*Snippet).endswith("()"); 477 if (Snippet->front() == '<') 478 return EmptyArgs ? "<$1>()$0" : "<$1>($0)"; 479 if (Snippet->front() == '(') 480 return EmptyArgs ? "()" : "($0)"; 481 return *Snippet; // Not an arg snippet? 482 } 483 // 'CompletionItemKind::Interface' matches template type aliases. 484 if (Completion.Kind == CompletionItemKind::Interface || 485 Completion.Kind == CompletionItemKind::Class) { 486 if (Snippet->front() != '<') 487 return *Snippet; // Not an arg snippet? 488 489 // Classes and template using aliases can only have template arguments, 490 // e.g. Foo<${1:class}>. 491 if (llvm::StringRef(*Snippet).endswith("<>")) 492 return "<>"; // can happen with defaulted template arguments. 493 return "<$0>"; 494 } 495 return *Snippet; 496 } 497 498 std::string summarizeSignature() const { 499 if (auto *Signature = onlyValue<&BundledEntry::Signature>()) 500 return *Signature; 501 // All bundles are function calls. 502 return "(…)"; 503 } 504 505 // ASTCtx can be nullptr if not run with sema. 506 ASTContext *ASTCtx; 507 CodeCompletion Completion; 508 llvm::SmallVector<BundledEntry, 1> Bundled; 509 bool ExtractDocumentation; 510 bool EnableFunctionArgSnippets; 511 // No snippets will be generated for using declarations and when the function 512 // arguments are already present. 513 bool IsUsingDeclaration; 514 tok::TokenKind NextTokenKind; 515 }; 516 517 // Determine the symbol ID for a Sema code completion result, if possible. 518 SymbolID getSymbolID(const CodeCompletionResult &R, const SourceManager &SM) { 519 switch (R.Kind) { 520 case CodeCompletionResult::RK_Declaration: 521 case CodeCompletionResult::RK_Pattern: { 522 // Computing USR caches linkage, which may change after code completion. 523 if (hasUnstableLinkage(R.Declaration)) 524 return {}; 525 return clang::clangd::getSymbolID(R.Declaration); 526 } 527 case CodeCompletionResult::RK_Macro: 528 return clang::clangd::getSymbolID(R.Macro->getName(), R.MacroDefInfo, SM); 529 case CodeCompletionResult::RK_Keyword: 530 return {}; 531 } 532 llvm_unreachable("unknown CodeCompletionResult kind"); 533 } 534 535 // Scopes of the partial identifier we're trying to complete. 536 // It is used when we query the index for more completion results. 537 struct SpecifiedScope { 538 // The scopes we should look in, determined by Sema. 539 // 540 // If the qualifier was fully resolved, we look for completions in these 541 // scopes; if there is an unresolved part of the qualifier, it should be 542 // resolved within these scopes. 543 // 544 // Examples of qualified completion: 545 // 546 // "::vec" => {""} 547 // "using namespace std; ::vec^" => {"", "std::"} 548 // "namespace ns {using namespace std;} ns::^" => {"ns::", "std::"} 549 // "std::vec^" => {""} // "std" unresolved 550 // 551 // Examples of unqualified completion: 552 // 553 // "vec^" => {""} 554 // "using namespace std; vec^" => {"", "std::"} 555 // "using namespace std; namespace ns { vec^ }" => {"ns::", "std::", ""} 556 // 557 // "" for global namespace, "ns::" for normal namespace. 558 std::vector<std::string> AccessibleScopes; 559 // The full scope qualifier as typed by the user (without the leading "::"). 560 // Set if the qualifier is not fully resolved by Sema. 561 llvm::Optional<std::string> UnresolvedQualifier; 562 563 // Construct scopes being queried in indexes. The results are deduplicated. 564 // This method format the scopes to match the index request representation. 565 std::vector<std::string> scopesForIndexQuery() { 566 std::set<std::string> Results; 567 for (llvm::StringRef AS : AccessibleScopes) 568 Results.insert( 569 (AS + (UnresolvedQualifier ? *UnresolvedQualifier : "")).str()); 570 return {Results.begin(), Results.end()}; 571 } 572 }; 573 574 // Get all scopes that will be queried in indexes and whether symbols from 575 // any scope is allowed. The first scope in the list is the preferred scope 576 // (e.g. enclosing namespace). 577 std::pair<std::vector<std::string>, bool> 578 getQueryScopes(CodeCompletionContext &CCContext, const Sema &CCSema, 579 const CompletionPrefix &HeuristicPrefix, 580 const CodeCompleteOptions &Opts) { 581 SpecifiedScope Scopes; 582 for (auto *Context : CCContext.getVisitedContexts()) { 583 if (isa<TranslationUnitDecl>(Context)) 584 Scopes.AccessibleScopes.push_back(""); // global namespace 585 else if (isa<NamespaceDecl>(Context)) 586 Scopes.AccessibleScopes.push_back(printNamespaceScope(*Context)); 587 } 588 589 const CXXScopeSpec *SemaSpecifier = 590 CCContext.getCXXScopeSpecifier().getValueOr(nullptr); 591 // Case 1: unqualified completion. 592 if (!SemaSpecifier) { 593 // Case 2 (exception): sema saw no qualifier, but there appears to be one! 594 // This can happen e.g. in incomplete macro expansions. Use heuristics. 595 if (!HeuristicPrefix.Qualifier.empty()) { 596 vlog("Sema said no scope specifier, but we saw {0} in the source code", 597 HeuristicPrefix.Qualifier); 598 StringRef SpelledSpecifier = HeuristicPrefix.Qualifier; 599 if (SpelledSpecifier.consume_front("::")) 600 Scopes.AccessibleScopes = {""}; 601 Scopes.UnresolvedQualifier = std::string(SpelledSpecifier); 602 return {Scopes.scopesForIndexQuery(), false}; 603 } 604 // The enclosing namespace must be first, it gets a quality boost. 605 std::vector<std::string> EnclosingAtFront; 606 std::string EnclosingScope = printNamespaceScope(*CCSema.CurContext); 607 EnclosingAtFront.push_back(EnclosingScope); 608 for (auto &S : Scopes.scopesForIndexQuery()) { 609 if (EnclosingScope != S) 610 EnclosingAtFront.push_back(std::move(S)); 611 } 612 // Allow AllScopes completion as there is no explicit scope qualifier. 613 return {EnclosingAtFront, Opts.AllScopes}; 614 } 615 // Case 3: sema saw and resolved a scope qualifier. 616 if (SemaSpecifier && SemaSpecifier->isValid()) 617 return {Scopes.scopesForIndexQuery(), false}; 618 619 // Case 4: There was a qualifier, and Sema didn't resolve it. 620 Scopes.AccessibleScopes.push_back(""); // Make sure global scope is included. 621 llvm::StringRef SpelledSpecifier = Lexer::getSourceText( 622 CharSourceRange::getCharRange(SemaSpecifier->getRange()), 623 CCSema.SourceMgr, clang::LangOptions()); 624 if (SpelledSpecifier.consume_front("::")) 625 Scopes.AccessibleScopes = {""}; 626 Scopes.UnresolvedQualifier = std::string(SpelledSpecifier); 627 // Sema excludes the trailing "::". 628 if (!Scopes.UnresolvedQualifier->empty()) 629 *Scopes.UnresolvedQualifier += "::"; 630 631 return {Scopes.scopesForIndexQuery(), false}; 632 } 633 634 // Should we perform index-based completion in a context of the specified kind? 635 // FIXME: consider allowing completion, but restricting the result types. 636 bool contextAllowsIndex(enum CodeCompletionContext::Kind K) { 637 switch (K) { 638 case CodeCompletionContext::CCC_TopLevel: 639 case CodeCompletionContext::CCC_ObjCInterface: 640 case CodeCompletionContext::CCC_ObjCImplementation: 641 case CodeCompletionContext::CCC_ObjCIvarList: 642 case CodeCompletionContext::CCC_ClassStructUnion: 643 case CodeCompletionContext::CCC_Statement: 644 case CodeCompletionContext::CCC_Expression: 645 case CodeCompletionContext::CCC_ObjCMessageReceiver: 646 case CodeCompletionContext::CCC_EnumTag: 647 case CodeCompletionContext::CCC_UnionTag: 648 case CodeCompletionContext::CCC_ClassOrStructTag: 649 case CodeCompletionContext::CCC_ObjCProtocolName: 650 case CodeCompletionContext::CCC_Namespace: 651 case CodeCompletionContext::CCC_Type: 652 case CodeCompletionContext::CCC_ParenthesizedExpression: 653 case CodeCompletionContext::CCC_ObjCInterfaceName: 654 case CodeCompletionContext::CCC_ObjCCategoryName: 655 case CodeCompletionContext::CCC_Symbol: 656 case CodeCompletionContext::CCC_SymbolOrNewName: 657 return true; 658 case CodeCompletionContext::CCC_OtherWithMacros: 659 case CodeCompletionContext::CCC_DotMemberAccess: 660 case CodeCompletionContext::CCC_ArrowMemberAccess: 661 case CodeCompletionContext::CCC_ObjCPropertyAccess: 662 case CodeCompletionContext::CCC_MacroName: 663 case CodeCompletionContext::CCC_MacroNameUse: 664 case CodeCompletionContext::CCC_PreprocessorExpression: 665 case CodeCompletionContext::CCC_PreprocessorDirective: 666 case CodeCompletionContext::CCC_SelectorName: 667 case CodeCompletionContext::CCC_TypeQualifiers: 668 case CodeCompletionContext::CCC_ObjCInstanceMessage: 669 case CodeCompletionContext::CCC_ObjCClassMessage: 670 case CodeCompletionContext::CCC_IncludedFile: 671 // FIXME: Provide identifier based completions for the following contexts: 672 case CodeCompletionContext::CCC_Other: // Be conservative. 673 case CodeCompletionContext::CCC_NaturalLanguage: 674 case CodeCompletionContext::CCC_Recovery: 675 case CodeCompletionContext::CCC_NewName: 676 return false; 677 } 678 llvm_unreachable("unknown code completion context"); 679 } 680 681 static bool isInjectedClass(const NamedDecl &D) { 682 if (auto *R = dyn_cast_or_null<RecordDecl>(&D)) 683 if (R->isInjectedClassName()) 684 return true; 685 return false; 686 } 687 688 // Some member calls are excluded because they're so rarely useful. 689 static bool isExcludedMember(const NamedDecl &D) { 690 // Destructor completion is rarely useful, and works inconsistently. 691 // (s.^ completes ~string, but s.~st^ is an error). 692 if (D.getKind() == Decl::CXXDestructor) 693 return true; 694 // Injected name may be useful for A::foo(), but who writes A::A::foo()? 695 if (isInjectedClass(D)) 696 return true; 697 // Explicit calls to operators are also rare. 698 auto NameKind = D.getDeclName().getNameKind(); 699 if (NameKind == DeclarationName::CXXOperatorName || 700 NameKind == DeclarationName::CXXLiteralOperatorName || 701 NameKind == DeclarationName::CXXConversionFunctionName) 702 return true; 703 return false; 704 } 705 706 // The CompletionRecorder captures Sema code-complete output, including context. 707 // It filters out ignored results (but doesn't apply fuzzy-filtering yet). 708 // It doesn't do scoring or conversion to CompletionItem yet, as we want to 709 // merge with index results first. 710 // Generally the fields and methods of this object should only be used from 711 // within the callback. 712 struct CompletionRecorder : public CodeCompleteConsumer { 713 CompletionRecorder(const CodeCompleteOptions &Opts, 714 llvm::unique_function<void()> ResultsCallback) 715 : CodeCompleteConsumer(Opts.getClangCompleteOpts()), 716 CCContext(CodeCompletionContext::CCC_Other), Opts(Opts), 717 CCAllocator(std::make_shared<GlobalCodeCompletionAllocator>()), 718 CCTUInfo(CCAllocator), ResultsCallback(std::move(ResultsCallback)) { 719 assert(this->ResultsCallback); 720 } 721 722 std::vector<CodeCompletionResult> Results; 723 CodeCompletionContext CCContext; 724 Sema *CCSema = nullptr; // Sema that created the results. 725 // FIXME: Sema is scary. Can we store ASTContext and Preprocessor, instead? 726 727 void ProcessCodeCompleteResults(class Sema &S, CodeCompletionContext Context, 728 CodeCompletionResult *InResults, 729 unsigned NumResults) override final { 730 // Results from recovery mode are generally useless, and the callback after 731 // recovery (if any) is usually more interesting. To make sure we handle the 732 // future callback from sema, we just ignore all callbacks in recovery mode, 733 // as taking only results from recovery mode results in poor completion 734 // results. 735 // FIXME: in case there is no future sema completion callback after the 736 // recovery mode, we might still want to provide some results (e.g. trivial 737 // identifier-based completion). 738 if (Context.getKind() == CodeCompletionContext::CCC_Recovery) { 739 log("Code complete: Ignoring sema code complete callback with Recovery " 740 "context."); 741 return; 742 } 743 // If a callback is called without any sema result and the context does not 744 // support index-based completion, we simply skip it to give way to 745 // potential future callbacks with results. 746 if (NumResults == 0 && !contextAllowsIndex(Context.getKind())) 747 return; 748 if (CCSema) { 749 log("Multiple code complete callbacks (parser backtracked?). " 750 "Dropping results from context {0}, keeping results from {1}.", 751 getCompletionKindString(Context.getKind()), 752 getCompletionKindString(this->CCContext.getKind())); 753 return; 754 } 755 // Record the completion context. 756 CCSema = &S; 757 CCContext = Context; 758 759 // Retain the results we might want. 760 for (unsigned I = 0; I < NumResults; ++I) { 761 auto &Result = InResults[I]; 762 // Class members that are shadowed by subclasses are usually noise. 763 if (Result.Hidden && Result.Declaration && 764 Result.Declaration->isCXXClassMember()) 765 continue; 766 if (!Opts.IncludeIneligibleResults && 767 (Result.Availability == CXAvailability_NotAvailable || 768 Result.Availability == CXAvailability_NotAccessible)) 769 continue; 770 if (Result.Declaration && 771 !Context.getBaseType().isNull() // is this a member-access context? 772 && isExcludedMember(*Result.Declaration)) 773 continue; 774 // Skip injected class name when no class scope is not explicitly set. 775 // E.g. show injected A::A in `using A::A^` but not in "A^". 776 if (Result.Declaration && !Context.getCXXScopeSpecifier().hasValue() && 777 isInjectedClass(*Result.Declaration)) 778 continue; 779 // We choose to never append '::' to completion results in clangd. 780 Result.StartsNestedNameSpecifier = false; 781 Results.push_back(Result); 782 } 783 ResultsCallback(); 784 } 785 786 CodeCompletionAllocator &getAllocator() override { return *CCAllocator; } 787 CodeCompletionTUInfo &getCodeCompletionTUInfo() override { return CCTUInfo; } 788 789 // Returns the filtering/sorting name for Result, which must be from Results. 790 // Returned string is owned by this recorder (or the AST). 791 llvm::StringRef getName(const CodeCompletionResult &Result) { 792 switch (Result.Kind) { 793 case CodeCompletionResult::RK_Declaration: 794 if (auto *ID = Result.Declaration->getIdentifier()) 795 return ID->getName(); 796 break; 797 case CodeCompletionResult::RK_Keyword: 798 return Result.Keyword; 799 case CodeCompletionResult::RK_Macro: 800 return Result.Macro->getName(); 801 case CodeCompletionResult::RK_Pattern: 802 return Result.Pattern->getTypedText(); 803 } 804 auto *CCS = codeCompletionString(Result); 805 return CCS->getTypedText(); 806 } 807 808 // Build a CodeCompletion string for R, which must be from Results. 809 // The CCS will be owned by this recorder. 810 CodeCompletionString *codeCompletionString(const CodeCompletionResult &R) { 811 // CodeCompletionResult doesn't seem to be const-correct. We own it, anyway. 812 return const_cast<CodeCompletionResult &>(R).CreateCodeCompletionString( 813 *CCSema, CCContext, *CCAllocator, CCTUInfo, 814 /*IncludeBriefComments=*/false); 815 } 816 817 private: 818 CodeCompleteOptions Opts; 819 std::shared_ptr<GlobalCodeCompletionAllocator> CCAllocator; 820 CodeCompletionTUInfo CCTUInfo; 821 llvm::unique_function<void()> ResultsCallback; 822 }; 823 824 struct ScoredSignature { 825 // When set, requires documentation to be requested from the index with this 826 // ID. 827 llvm::Optional<SymbolID> IDForDoc; 828 SignatureInformation Signature; 829 SignatureQualitySignals Quality; 830 }; 831 832 class SignatureHelpCollector final : public CodeCompleteConsumer { 833 public: 834 SignatureHelpCollector(const clang::CodeCompleteOptions &CodeCompleteOpts, 835 const SymbolIndex *Index, SignatureHelp &SigHelp) 836 : CodeCompleteConsumer(CodeCompleteOpts), SigHelp(SigHelp), 837 Allocator(std::make_shared<clang::GlobalCodeCompletionAllocator>()), 838 CCTUInfo(Allocator), Index(Index) {} 839 840 void ProcessOverloadCandidates(Sema &S, unsigned CurrentArg, 841 OverloadCandidate *Candidates, 842 unsigned NumCandidates, 843 SourceLocation OpenParLoc) override { 844 assert(!OpenParLoc.isInvalid()); 845 SourceManager &SrcMgr = S.getSourceManager(); 846 OpenParLoc = SrcMgr.getFileLoc(OpenParLoc); 847 if (SrcMgr.isInMainFile(OpenParLoc)) 848 SigHelp.argListStart = sourceLocToPosition(SrcMgr, OpenParLoc); 849 else 850 elog("Location oustide main file in signature help: {0}", 851 OpenParLoc.printToString(SrcMgr)); 852 853 std::vector<ScoredSignature> ScoredSignatures; 854 SigHelp.signatures.reserve(NumCandidates); 855 ScoredSignatures.reserve(NumCandidates); 856 // FIXME(rwols): How can we determine the "active overload candidate"? 857 // Right now the overloaded candidates seem to be provided in a "best fit" 858 // order, so I'm not too worried about this. 859 SigHelp.activeSignature = 0; 860 assert(CurrentArg <= (unsigned)std::numeric_limits<int>::max() && 861 "too many arguments"); 862 SigHelp.activeParameter = static_cast<int>(CurrentArg); 863 for (unsigned I = 0; I < NumCandidates; ++I) { 864 OverloadCandidate Candidate = Candidates[I]; 865 // We want to avoid showing instantiated signatures, because they may be 866 // long in some cases (e.g. when 'T' is substituted with 'std::string', we 867 // would get 'std::basic_string<char>'). 868 if (auto *Func = Candidate.getFunction()) { 869 if (auto *Pattern = Func->getTemplateInstantiationPattern()) 870 Candidate = OverloadCandidate(Pattern); 871 } 872 873 const auto *CCS = Candidate.CreateSignatureString( 874 CurrentArg, S, *Allocator, CCTUInfo, true); 875 assert(CCS && "Expected the CodeCompletionString to be non-null"); 876 ScoredSignatures.push_back(processOverloadCandidate( 877 Candidate, *CCS, 878 Candidate.getFunction() 879 ? getDeclComment(S.getASTContext(), *Candidate.getFunction()) 880 : "")); 881 } 882 883 // Sema does not load the docs from the preamble, so we need to fetch extra 884 // docs from the index instead. 885 llvm::DenseMap<SymbolID, std::string> FetchedDocs; 886 if (Index) { 887 LookupRequest IndexRequest; 888 for (const auto &S : ScoredSignatures) { 889 if (!S.IDForDoc) 890 continue; 891 IndexRequest.IDs.insert(*S.IDForDoc); 892 } 893 Index->lookup(IndexRequest, [&](const Symbol &S) { 894 if (!S.Documentation.empty()) 895 FetchedDocs[S.ID] = std::string(S.Documentation); 896 }); 897 log("SigHelp: requested docs for {0} symbols from the index, got {1} " 898 "symbols with non-empty docs in the response", 899 IndexRequest.IDs.size(), FetchedDocs.size()); 900 } 901 902 llvm::sort(ScoredSignatures, [](const ScoredSignature &L, 903 const ScoredSignature &R) { 904 // Ordering follows: 905 // - Less number of parameters is better. 906 // - Function is better than FunctionType which is better than 907 // Function Template. 908 // - High score is better. 909 // - Shorter signature is better. 910 // - Alphabetically smaller is better. 911 if (L.Quality.NumberOfParameters != R.Quality.NumberOfParameters) 912 return L.Quality.NumberOfParameters < R.Quality.NumberOfParameters; 913 if (L.Quality.NumberOfOptionalParameters != 914 R.Quality.NumberOfOptionalParameters) 915 return L.Quality.NumberOfOptionalParameters < 916 R.Quality.NumberOfOptionalParameters; 917 if (L.Quality.Kind != R.Quality.Kind) { 918 using OC = CodeCompleteConsumer::OverloadCandidate; 919 switch (L.Quality.Kind) { 920 case OC::CK_Function: 921 return true; 922 case OC::CK_FunctionType: 923 return R.Quality.Kind != OC::CK_Function; 924 case OC::CK_FunctionTemplate: 925 return false; 926 } 927 llvm_unreachable("Unknown overload candidate type."); 928 } 929 if (L.Signature.label.size() != R.Signature.label.size()) 930 return L.Signature.label.size() < R.Signature.label.size(); 931 return L.Signature.label < R.Signature.label; 932 }); 933 934 for (auto &SS : ScoredSignatures) { 935 auto IndexDocIt = 936 SS.IDForDoc ? FetchedDocs.find(*SS.IDForDoc) : FetchedDocs.end(); 937 if (IndexDocIt != FetchedDocs.end()) 938 SS.Signature.documentation = IndexDocIt->second; 939 940 SigHelp.signatures.push_back(std::move(SS.Signature)); 941 } 942 } 943 944 GlobalCodeCompletionAllocator &getAllocator() override { return *Allocator; } 945 946 CodeCompletionTUInfo &getCodeCompletionTUInfo() override { return CCTUInfo; } 947 948 private: 949 void processParameterChunk(llvm::StringRef ChunkText, 950 SignatureInformation &Signature) const { 951 // (!) this is O(n), should still be fast compared to building ASTs. 952 unsigned ParamStartOffset = lspLength(Signature.label); 953 unsigned ParamEndOffset = ParamStartOffset + lspLength(ChunkText); 954 // A piece of text that describes the parameter that corresponds to 955 // the code-completion location within a function call, message send, 956 // macro invocation, etc. 957 Signature.label += ChunkText; 958 ParameterInformation Info; 959 Info.labelOffsets.emplace(ParamStartOffset, ParamEndOffset); 960 // FIXME: only set 'labelOffsets' when all clients migrate out of it. 961 Info.labelString = std::string(ChunkText); 962 963 Signature.parameters.push_back(std::move(Info)); 964 } 965 966 void processOptionalChunk(const CodeCompletionString &CCS, 967 SignatureInformation &Signature, 968 SignatureQualitySignals &Signal) const { 969 for (const auto &Chunk : CCS) { 970 switch (Chunk.Kind) { 971 case CodeCompletionString::CK_Optional: 972 assert(Chunk.Optional && 973 "Expected the optional code completion string to be non-null."); 974 processOptionalChunk(*Chunk.Optional, Signature, Signal); 975 break; 976 case CodeCompletionString::CK_VerticalSpace: 977 break; 978 case CodeCompletionString::CK_CurrentParameter: 979 case CodeCompletionString::CK_Placeholder: 980 processParameterChunk(Chunk.Text, Signature); 981 Signal.NumberOfOptionalParameters++; 982 break; 983 default: 984 Signature.label += Chunk.Text; 985 break; 986 } 987 } 988 } 989 990 // FIXME(ioeric): consider moving CodeCompletionString logic here to 991 // CompletionString.h. 992 ScoredSignature processOverloadCandidate(const OverloadCandidate &Candidate, 993 const CodeCompletionString &CCS, 994 llvm::StringRef DocComment) const { 995 SignatureInformation Signature; 996 SignatureQualitySignals Signal; 997 const char *ReturnType = nullptr; 998 999 Signature.documentation = formatDocumentation(CCS, DocComment); 1000 Signal.Kind = Candidate.getKind(); 1001 1002 for (const auto &Chunk : CCS) { 1003 switch (Chunk.Kind) { 1004 case CodeCompletionString::CK_ResultType: 1005 // A piece of text that describes the type of an entity or, 1006 // for functions and methods, the return type. 1007 assert(!ReturnType && "Unexpected CK_ResultType"); 1008 ReturnType = Chunk.Text; 1009 break; 1010 case CodeCompletionString::CK_CurrentParameter: 1011 case CodeCompletionString::CK_Placeholder: 1012 processParameterChunk(Chunk.Text, Signature); 1013 Signal.NumberOfParameters++; 1014 break; 1015 case CodeCompletionString::CK_Optional: { 1016 // The rest of the parameters are defaulted/optional. 1017 assert(Chunk.Optional && 1018 "Expected the optional code completion string to be non-null."); 1019 processOptionalChunk(*Chunk.Optional, Signature, Signal); 1020 break; 1021 } 1022 case CodeCompletionString::CK_VerticalSpace: 1023 break; 1024 default: 1025 Signature.label += Chunk.Text; 1026 break; 1027 } 1028 } 1029 if (ReturnType) { 1030 Signature.label += " -> "; 1031 Signature.label += ReturnType; 1032 } 1033 dlog("Signal for {0}: {1}", Signature, Signal); 1034 ScoredSignature Result; 1035 Result.Signature = std::move(Signature); 1036 Result.Quality = Signal; 1037 const FunctionDecl *Func = Candidate.getFunction(); 1038 if (Func && Result.Signature.documentation.empty()) { 1039 // Computing USR caches linkage, which may change after code completion. 1040 if (!hasUnstableLinkage(Func)) 1041 Result.IDForDoc = clangd::getSymbolID(Func); 1042 } 1043 return Result; 1044 } 1045 1046 SignatureHelp &SigHelp; 1047 std::shared_ptr<clang::GlobalCodeCompletionAllocator> Allocator; 1048 CodeCompletionTUInfo CCTUInfo; 1049 const SymbolIndex *Index; 1050 }; // SignatureHelpCollector 1051 1052 struct SemaCompleteInput { 1053 PathRef FileName; 1054 size_t Offset; 1055 const PreambleData &Preamble; 1056 const llvm::Optional<PreamblePatch> Patch; 1057 const ParseInputs &ParseInput; 1058 }; 1059 1060 void loadMainFilePreambleMacros(const Preprocessor &PP, 1061 const PreambleData &Preamble) { 1062 // The ExternalPreprocessorSource has our macros, if we know where to look. 1063 // We can read all the macros using PreambleMacros->ReadDefinedMacros(), 1064 // but this includes transitively included files, so may deserialize a lot. 1065 ExternalPreprocessorSource *PreambleMacros = PP.getExternalSource(); 1066 // As we have the names of the macros, we can look up their IdentifierInfo 1067 // and then use this to load just the macros we want. 1068 IdentifierInfoLookup *PreambleIdentifiers = 1069 PP.getIdentifierTable().getExternalIdentifierLookup(); 1070 if (!PreambleIdentifiers || !PreambleMacros) 1071 return; 1072 for (const auto &MacroName : Preamble.Macros.Names) 1073 if (auto *II = PreambleIdentifiers->get(MacroName.getKey())) 1074 if (II->isOutOfDate()) 1075 PreambleMacros->updateOutOfDateIdentifier(*II); 1076 } 1077 1078 // Invokes Sema code completion on a file. 1079 // If \p Includes is set, it will be updated based on the compiler invocation. 1080 bool semaCodeComplete(std::unique_ptr<CodeCompleteConsumer> Consumer, 1081 const clang::CodeCompleteOptions &Options, 1082 const SemaCompleteInput &Input, 1083 IncludeStructure *Includes = nullptr) { 1084 trace::Span Tracer("Sema completion"); 1085 1086 IgnoreDiagnostics IgnoreDiags; 1087 auto CI = buildCompilerInvocation(Input.ParseInput, IgnoreDiags); 1088 if (!CI) { 1089 elog("Couldn't create CompilerInvocation"); 1090 return false; 1091 } 1092 auto &FrontendOpts = CI->getFrontendOpts(); 1093 FrontendOpts.SkipFunctionBodies = true; 1094 // Disable typo correction in Sema. 1095 CI->getLangOpts()->SpellChecking = false; 1096 // Code completion won't trigger in delayed template bodies. 1097 // This is on-by-default in windows to allow parsing SDK headers; we're only 1098 // disabling it for the main-file (not preamble). 1099 CI->getLangOpts()->DelayedTemplateParsing = false; 1100 // Setup code completion. 1101 FrontendOpts.CodeCompleteOpts = Options; 1102 FrontendOpts.CodeCompletionAt.FileName = std::string(Input.FileName); 1103 std::tie(FrontendOpts.CodeCompletionAt.Line, 1104 FrontendOpts.CodeCompletionAt.Column) = 1105 offsetToClangLineColumn(Input.ParseInput.Contents, Input.Offset); 1106 1107 std::unique_ptr<llvm::MemoryBuffer> ContentsBuffer = 1108 llvm::MemoryBuffer::getMemBufferCopy(Input.ParseInput.Contents, 1109 Input.FileName); 1110 // The diagnostic options must be set before creating a CompilerInstance. 1111 CI->getDiagnosticOpts().IgnoreWarnings = true; 1112 // We reuse the preamble whether it's valid or not. This is a 1113 // correctness/performance tradeoff: building without a preamble is slow, and 1114 // completion is latency-sensitive. 1115 // However, if we're completing *inside* the preamble section of the draft, 1116 // overriding the preamble will break sema completion. Fortunately we can just 1117 // skip all includes in this case; these completions are really simple. 1118 PreambleBounds PreambleRegion = 1119 ComputePreambleBounds(*CI->getLangOpts(), *ContentsBuffer, 0); 1120 bool CompletingInPreamble = PreambleRegion.Size > Input.Offset; 1121 if (Input.Patch) 1122 Input.Patch->apply(*CI); 1123 // NOTE: we must call BeginSourceFile after prepareCompilerInstance. Otherwise 1124 // the remapped buffers do not get freed. 1125 llvm::IntrusiveRefCntPtr<llvm::vfs::FileSystem> VFS = 1126 Input.ParseInput.TFS->view(Input.ParseInput.CompileCommand.Directory); 1127 if (Input.Preamble.StatCache) 1128 VFS = Input.Preamble.StatCache->getConsumingFS(std::move(VFS)); 1129 auto Clang = prepareCompilerInstance( 1130 std::move(CI), !CompletingInPreamble ? &Input.Preamble.Preamble : nullptr, 1131 std::move(ContentsBuffer), std::move(VFS), IgnoreDiags); 1132 Clang->getPreprocessorOpts().SingleFileParseMode = CompletingInPreamble; 1133 Clang->setCodeCompletionConsumer(Consumer.release()); 1134 1135 SyntaxOnlyAction Action; 1136 if (!Action.BeginSourceFile(*Clang, Clang->getFrontendOpts().Inputs[0])) { 1137 log("BeginSourceFile() failed when running codeComplete for {0}", 1138 Input.FileName); 1139 return false; 1140 } 1141 // Macros can be defined within the preamble region of the main file. 1142 // They don't fall nicely into our index/Sema dichotomy: 1143 // - they're not indexed for completion (they're not available across files) 1144 // - but Sema code complete won't see them: as part of the preamble, they're 1145 // deserialized only when mentioned. 1146 // Force them to be deserialized so SemaCodeComplete sees them. 1147 loadMainFilePreambleMacros(Clang->getPreprocessor(), Input.Preamble); 1148 if (Includes) 1149 Clang->getPreprocessor().addPPCallbacks( 1150 collectIncludeStructureCallback(Clang->getSourceManager(), Includes)); 1151 if (llvm::Error Err = Action.Execute()) { 1152 log("Execute() failed when running codeComplete for {0}: {1}", 1153 Input.FileName, toString(std::move(Err))); 1154 return false; 1155 } 1156 Action.EndSourceFile(); 1157 1158 return true; 1159 } 1160 1161 // Should we allow index completions in the specified context? 1162 bool allowIndex(CodeCompletionContext &CC) { 1163 if (!contextAllowsIndex(CC.getKind())) 1164 return false; 1165 // We also avoid ClassName::bar (but allow namespace::bar). 1166 auto Scope = CC.getCXXScopeSpecifier(); 1167 if (!Scope) 1168 return true; 1169 NestedNameSpecifier *NameSpec = (*Scope)->getScopeRep(); 1170 if (!NameSpec) 1171 return true; 1172 // We only query the index when qualifier is a namespace. 1173 // If it's a class, we rely solely on sema completions. 1174 switch (NameSpec->getKind()) { 1175 case NestedNameSpecifier::Global: 1176 case NestedNameSpecifier::Namespace: 1177 case NestedNameSpecifier::NamespaceAlias: 1178 return true; 1179 case NestedNameSpecifier::Super: 1180 case NestedNameSpecifier::TypeSpec: 1181 case NestedNameSpecifier::TypeSpecWithTemplate: 1182 // Unresolved inside a template. 1183 case NestedNameSpecifier::Identifier: 1184 return false; 1185 } 1186 llvm_unreachable("invalid NestedNameSpecifier kind"); 1187 } 1188 1189 std::future<SymbolSlab> startAsyncFuzzyFind(const SymbolIndex &Index, 1190 const FuzzyFindRequest &Req) { 1191 return runAsync<SymbolSlab>([&Index, Req]() { 1192 trace::Span Tracer("Async fuzzyFind"); 1193 SymbolSlab::Builder Syms; 1194 Index.fuzzyFind(Req, [&Syms](const Symbol &Sym) { Syms.insert(Sym); }); 1195 return std::move(Syms).build(); 1196 }); 1197 } 1198 1199 // Creates a `FuzzyFindRequest` based on the cached index request from the 1200 // last completion, if any, and the speculated completion filter text in the 1201 // source code. 1202 FuzzyFindRequest speculativeFuzzyFindRequestForCompletion( 1203 FuzzyFindRequest CachedReq, const CompletionPrefix &HeuristicPrefix) { 1204 CachedReq.Query = std::string(HeuristicPrefix.Name); 1205 return CachedReq; 1206 } 1207 1208 // Runs Sema-based (AST) and Index-based completion, returns merged results. 1209 // 1210 // There are a few tricky considerations: 1211 // - the AST provides information needed for the index query (e.g. which 1212 // namespaces to search in). So Sema must start first. 1213 // - we only want to return the top results (Opts.Limit). 1214 // Building CompletionItems for everything else is wasteful, so we want to 1215 // preserve the "native" format until we're done with scoring. 1216 // - the data underlying Sema completion items is owned by the AST and various 1217 // other arenas, which must stay alive for us to build CompletionItems. 1218 // - we may get duplicate results from Sema and the Index, we need to merge. 1219 // 1220 // So we start Sema completion first, and do all our work in its callback. 1221 // We use the Sema context information to query the index. 1222 // Then we merge the two result sets, producing items that are Sema/Index/Both. 1223 // These items are scored, and the top N are synthesized into the LSP response. 1224 // Finally, we can clean up the data structures created by Sema completion. 1225 // 1226 // Main collaborators are: 1227 // - semaCodeComplete sets up the compiler machinery to run code completion. 1228 // - CompletionRecorder captures Sema completion results, including context. 1229 // - SymbolIndex (Opts.Index) provides index completion results as Symbols 1230 // - CompletionCandidates are the result of merging Sema and Index results. 1231 // Each candidate points to an underlying CodeCompletionResult (Sema), a 1232 // Symbol (Index), or both. It computes the result quality score. 1233 // CompletionCandidate also does conversion to CompletionItem (at the end). 1234 // - FuzzyMatcher scores how the candidate matches the partial identifier. 1235 // This score is combined with the result quality score for the final score. 1236 // - TopN determines the results with the best score. 1237 class CodeCompleteFlow { 1238 PathRef FileName; 1239 IncludeStructure Includes; // Complete once the compiler runs. 1240 SpeculativeFuzzyFind *SpecFuzzyFind; // Can be nullptr. 1241 const CodeCompleteOptions &Opts; 1242 1243 // Sema takes ownership of Recorder. Recorder is valid until Sema cleanup. 1244 CompletionRecorder *Recorder = nullptr; 1245 CodeCompletionContext::Kind CCContextKind = CodeCompletionContext::CCC_Other; 1246 bool IsUsingDeclaration = false; 1247 // The snippets will not be generated if the token following completion 1248 // location is an opening parenthesis (tok::l_paren) because this would add 1249 // extra parenthesis. 1250 tok::TokenKind NextTokenKind = tok::eof; 1251 // Counters for logging. 1252 int NSema = 0, NIndex = 0, NSemaAndIndex = 0, NIdent = 0; 1253 bool Incomplete = false; // Would more be available with a higher limit? 1254 CompletionPrefix HeuristicPrefix; 1255 llvm::Optional<FuzzyMatcher> Filter; // Initialized once Sema runs. 1256 Range ReplacedRange; 1257 std::vector<std::string> QueryScopes; // Initialized once Sema runs. 1258 // Initialized once QueryScopes is initialized, if there are scopes. 1259 llvm::Optional<ScopeDistance> ScopeProximity; 1260 llvm::Optional<OpaqueType> PreferredType; // Initialized once Sema runs. 1261 // Whether to query symbols from any scope. Initialized once Sema runs. 1262 bool AllScopes = false; 1263 llvm::StringSet<> ContextWords; 1264 // Include-insertion and proximity scoring rely on the include structure. 1265 // This is available after Sema has run. 1266 llvm::Optional<IncludeInserter> Inserter; // Available during runWithSema. 1267 llvm::Optional<URIDistance> FileProximity; // Initialized once Sema runs. 1268 /// Speculative request based on the cached request and the filter text before 1269 /// the cursor. 1270 /// Initialized right before sema run. This is only set if `SpecFuzzyFind` is 1271 /// set and contains a cached request. 1272 llvm::Optional<FuzzyFindRequest> SpecReq; 1273 1274 public: 1275 // A CodeCompleteFlow object is only useful for calling run() exactly once. 1276 CodeCompleteFlow(PathRef FileName, const IncludeStructure &Includes, 1277 SpeculativeFuzzyFind *SpecFuzzyFind, 1278 const CodeCompleteOptions &Opts) 1279 : FileName(FileName), Includes(Includes), SpecFuzzyFind(SpecFuzzyFind), 1280 Opts(Opts) {} 1281 1282 CodeCompleteResult run(const SemaCompleteInput &SemaCCInput) && { 1283 trace::Span Tracer("CodeCompleteFlow"); 1284 HeuristicPrefix = guessCompletionPrefix(SemaCCInput.ParseInput.Contents, 1285 SemaCCInput.Offset); 1286 populateContextWords(SemaCCInput.ParseInput.Contents); 1287 if (Opts.Index && SpecFuzzyFind && SpecFuzzyFind->CachedReq.hasValue()) { 1288 assert(!SpecFuzzyFind->Result.valid()); 1289 SpecReq = speculativeFuzzyFindRequestForCompletion( 1290 *SpecFuzzyFind->CachedReq, HeuristicPrefix); 1291 SpecFuzzyFind->Result = startAsyncFuzzyFind(*Opts.Index, *SpecReq); 1292 } 1293 1294 // We run Sema code completion first. It builds an AST and calculates: 1295 // - completion results based on the AST. 1296 // - partial identifier and context. We need these for the index query. 1297 CodeCompleteResult Output; 1298 auto RecorderOwner = std::make_unique<CompletionRecorder>(Opts, [&]() { 1299 assert(Recorder && "Recorder is not set"); 1300 CCContextKind = Recorder->CCContext.getKind(); 1301 IsUsingDeclaration = Recorder->CCContext.isUsingDeclaration(); 1302 auto Style = getFormatStyleForFile(SemaCCInput.FileName, 1303 SemaCCInput.ParseInput.Contents, 1304 *SemaCCInput.ParseInput.TFS); 1305 const auto NextToken = Lexer::findNextToken( 1306 Recorder->CCSema->getPreprocessor().getCodeCompletionLoc(), 1307 Recorder->CCSema->getSourceManager(), Recorder->CCSema->LangOpts); 1308 if (NextToken) 1309 NextTokenKind = NextToken->getKind(); 1310 // If preprocessor was run, inclusions from preprocessor callback should 1311 // already be added to Includes. 1312 Inserter.emplace( 1313 SemaCCInput.FileName, SemaCCInput.ParseInput.Contents, Style, 1314 SemaCCInput.ParseInput.CompileCommand.Directory, 1315 &Recorder->CCSema->getPreprocessor().getHeaderSearchInfo()); 1316 for (const auto &Inc : Includes.MainFileIncludes) 1317 Inserter->addExisting(Inc); 1318 1319 // Most of the cost of file proximity is in initializing the FileDistance 1320 // structures based on the observed includes, once per query. Conceptually 1321 // that happens here (though the per-URI-scheme initialization is lazy). 1322 // The per-result proximity scoring is (amortized) very cheap. 1323 FileDistanceOptions ProxOpts{}; // Use defaults. 1324 const auto &SM = Recorder->CCSema->getSourceManager(); 1325 llvm::StringMap<SourceParams> ProxSources; 1326 for (auto &Entry : Includes.includeDepth( 1327 SM.getFileEntryForID(SM.getMainFileID())->getName())) { 1328 auto &Source = ProxSources[Entry.getKey()]; 1329 Source.Cost = Entry.getValue() * ProxOpts.IncludeCost; 1330 // Symbols near our transitive includes are good, but only consider 1331 // things in the same directory or below it. Otherwise there can be 1332 // many false positives. 1333 if (Entry.getValue() > 0) 1334 Source.MaxUpTraversals = 1; 1335 } 1336 FileProximity.emplace(ProxSources, ProxOpts); 1337 1338 Output = runWithSema(); 1339 Inserter.reset(); // Make sure this doesn't out-live Clang. 1340 SPAN_ATTACH(Tracer, "sema_completion_kind", 1341 getCompletionKindString(CCContextKind)); 1342 log("Code complete: sema context {0}, query scopes [{1}] (AnyScope={2}), " 1343 "expected type {3}{4}", 1344 getCompletionKindString(CCContextKind), 1345 llvm::join(QueryScopes.begin(), QueryScopes.end(), ","), AllScopes, 1346 PreferredType ? Recorder->CCContext.getPreferredType().getAsString() 1347 : "<none>", 1348 IsUsingDeclaration ? ", inside using declaration" : ""); 1349 }); 1350 1351 Recorder = RecorderOwner.get(); 1352 1353 semaCodeComplete(std::move(RecorderOwner), Opts.getClangCompleteOpts(), 1354 SemaCCInput, &Includes); 1355 logResults(Output, Tracer); 1356 return Output; 1357 } 1358 1359 void logResults(const CodeCompleteResult &Output, const trace::Span &Tracer) { 1360 SPAN_ATTACH(Tracer, "sema_results", NSema); 1361 SPAN_ATTACH(Tracer, "index_results", NIndex); 1362 SPAN_ATTACH(Tracer, "merged_results", NSemaAndIndex); 1363 SPAN_ATTACH(Tracer, "identifier_results", NIdent); 1364 SPAN_ATTACH(Tracer, "returned_results", int64_t(Output.Completions.size())); 1365 SPAN_ATTACH(Tracer, "incomplete", Output.HasMore); 1366 log("Code complete: {0} results from Sema, {1} from Index, " 1367 "{2} matched, {3} from identifiers, {4} returned{5}.", 1368 NSema, NIndex, NSemaAndIndex, NIdent, Output.Completions.size(), 1369 Output.HasMore ? " (incomplete)" : ""); 1370 assert(!Opts.Limit || Output.Completions.size() <= Opts.Limit); 1371 // We don't assert that isIncomplete means we hit a limit. 1372 // Indexes may choose to impose their own limits even if we don't have one. 1373 } 1374 1375 CodeCompleteResult runWithoutSema(llvm::StringRef Content, size_t Offset, 1376 const ThreadsafeFS &TFS) && { 1377 trace::Span Tracer("CodeCompleteWithoutSema"); 1378 // Fill in fields normally set by runWithSema() 1379 HeuristicPrefix = guessCompletionPrefix(Content, Offset); 1380 populateContextWords(Content); 1381 CCContextKind = CodeCompletionContext::CCC_Recovery; 1382 IsUsingDeclaration = false; 1383 Filter = FuzzyMatcher(HeuristicPrefix.Name); 1384 auto Pos = offsetToPosition(Content, Offset); 1385 ReplacedRange.start = ReplacedRange.end = Pos; 1386 ReplacedRange.start.character -= HeuristicPrefix.Name.size(); 1387 1388 llvm::StringMap<SourceParams> ProxSources; 1389 ProxSources[FileName].Cost = 0; 1390 FileProximity.emplace(ProxSources); 1391 1392 auto Style = getFormatStyleForFile(FileName, Content, TFS); 1393 // This will only insert verbatim headers. 1394 Inserter.emplace(FileName, Content, Style, 1395 /*BuildDir=*/"", /*HeaderSearchInfo=*/nullptr); 1396 1397 auto Identifiers = collectIdentifiers(Content, Style); 1398 std::vector<RawIdentifier> IdentifierResults; 1399 for (const auto &IDAndCount : Identifiers) { 1400 RawIdentifier ID; 1401 ID.Name = IDAndCount.first(); 1402 ID.References = IDAndCount.second; 1403 // Avoid treating typed filter as an identifier. 1404 if (ID.Name == HeuristicPrefix.Name) 1405 --ID.References; 1406 if (ID.References > 0) 1407 IdentifierResults.push_back(std::move(ID)); 1408 } 1409 1410 // Simplified version of getQueryScopes(): 1411 // - accessible scopes are determined heuristically. 1412 // - all-scopes query if no qualifier was typed (and it's allowed). 1413 SpecifiedScope Scopes; 1414 Scopes.AccessibleScopes = visibleNamespaces( 1415 Content.take_front(Offset), format::getFormattingLangOpts(Style)); 1416 for (std::string &S : Scopes.AccessibleScopes) 1417 if (!S.empty()) 1418 S.append("::"); // visibleNamespaces doesn't include trailing ::. 1419 if (HeuristicPrefix.Qualifier.empty()) 1420 AllScopes = Opts.AllScopes; 1421 else if (HeuristicPrefix.Qualifier.startswith("::")) { 1422 Scopes.AccessibleScopes = {""}; 1423 Scopes.UnresolvedQualifier = 1424 std::string(HeuristicPrefix.Qualifier.drop_front(2)); 1425 } else 1426 Scopes.UnresolvedQualifier = std::string(HeuristicPrefix.Qualifier); 1427 // First scope is the (modified) enclosing scope. 1428 QueryScopes = Scopes.scopesForIndexQuery(); 1429 ScopeProximity.emplace(QueryScopes); 1430 1431 SymbolSlab IndexResults = Opts.Index ? queryIndex() : SymbolSlab(); 1432 1433 CodeCompleteResult Output = toCodeCompleteResult(mergeResults( 1434 /*SemaResults=*/{}, IndexResults, IdentifierResults)); 1435 Output.RanParser = false; 1436 logResults(Output, Tracer); 1437 return Output; 1438 } 1439 1440 private: 1441 void populateContextWords(llvm::StringRef Content) { 1442 // Take last 3 lines before the completion point. 1443 unsigned RangeEnd = HeuristicPrefix.Qualifier.begin() - Content.data(), 1444 RangeBegin = RangeEnd; 1445 for (size_t I = 0; I < 3 && RangeBegin > 0; ++I) { 1446 auto PrevNL = Content.rfind('\n', RangeBegin); 1447 if (PrevNL == StringRef::npos) { 1448 RangeBegin = 0; 1449 break; 1450 } 1451 RangeBegin = PrevNL; 1452 } 1453 1454 ContextWords = collectWords(Content.slice(RangeBegin, RangeEnd)); 1455 dlog("Completion context words: {0}", 1456 llvm::join(ContextWords.keys(), ", ")); 1457 } 1458 1459 // This is called by run() once Sema code completion is done, but before the 1460 // Sema data structures are torn down. It does all the real work. 1461 CodeCompleteResult runWithSema() { 1462 const auto &CodeCompletionRange = CharSourceRange::getCharRange( 1463 Recorder->CCSema->getPreprocessor().getCodeCompletionTokenRange()); 1464 // When we are getting completions with an empty identifier, for example 1465 // std::vector<int> asdf; 1466 // asdf.^; 1467 // Then the range will be invalid and we will be doing insertion, use 1468 // current cursor position in such cases as range. 1469 if (CodeCompletionRange.isValid()) { 1470 ReplacedRange = halfOpenToRange(Recorder->CCSema->getSourceManager(), 1471 CodeCompletionRange); 1472 } else { 1473 const auto &Pos = sourceLocToPosition( 1474 Recorder->CCSema->getSourceManager(), 1475 Recorder->CCSema->getPreprocessor().getCodeCompletionLoc()); 1476 ReplacedRange.start = ReplacedRange.end = Pos; 1477 } 1478 Filter = FuzzyMatcher( 1479 Recorder->CCSema->getPreprocessor().getCodeCompletionFilter()); 1480 std::tie(QueryScopes, AllScopes) = getQueryScopes( 1481 Recorder->CCContext, *Recorder->CCSema, HeuristicPrefix, Opts); 1482 if (!QueryScopes.empty()) 1483 ScopeProximity.emplace(QueryScopes); 1484 PreferredType = 1485 OpaqueType::fromType(Recorder->CCSema->getASTContext(), 1486 Recorder->CCContext.getPreferredType()); 1487 // Sema provides the needed context to query the index. 1488 // FIXME: in addition to querying for extra/overlapping symbols, we should 1489 // explicitly request symbols corresponding to Sema results. 1490 // We can use their signals even if the index can't suggest them. 1491 // We must copy index results to preserve them, but there are at most Limit. 1492 auto IndexResults = (Opts.Index && allowIndex(Recorder->CCContext)) 1493 ? queryIndex() 1494 : SymbolSlab(); 1495 trace::Span Tracer("Populate CodeCompleteResult"); 1496 // Merge Sema and Index results, score them, and pick the winners. 1497 auto Top = 1498 mergeResults(Recorder->Results, IndexResults, /*Identifiers*/ {}); 1499 return toCodeCompleteResult(Top); 1500 } 1501 1502 CodeCompleteResult 1503 toCodeCompleteResult(const std::vector<ScoredBundle> &Scored) { 1504 CodeCompleteResult Output; 1505 1506 // Convert the results to final form, assembling the expensive strings. 1507 for (auto &C : Scored) { 1508 Output.Completions.push_back(toCodeCompletion(C.first)); 1509 Output.Completions.back().Score = C.second; 1510 Output.Completions.back().CompletionTokenRange = ReplacedRange; 1511 } 1512 Output.HasMore = Incomplete; 1513 Output.Context = CCContextKind; 1514 Output.CompletionRange = ReplacedRange; 1515 return Output; 1516 } 1517 1518 SymbolSlab queryIndex() { 1519 trace::Span Tracer("Query index"); 1520 SPAN_ATTACH(Tracer, "limit", int64_t(Opts.Limit)); 1521 1522 // Build the query. 1523 FuzzyFindRequest Req; 1524 if (Opts.Limit) 1525 Req.Limit = Opts.Limit; 1526 Req.Query = std::string(Filter->pattern()); 1527 Req.RestrictForCodeCompletion = true; 1528 Req.Scopes = QueryScopes; 1529 Req.AnyScope = AllScopes; 1530 // FIXME: we should send multiple weighted paths here. 1531 Req.ProximityPaths.push_back(std::string(FileName)); 1532 if (PreferredType) 1533 Req.PreferredTypes.push_back(std::string(PreferredType->raw())); 1534 vlog("Code complete: fuzzyFind({0:2})", toJSON(Req)); 1535 1536 if (SpecFuzzyFind) 1537 SpecFuzzyFind->NewReq = Req; 1538 if (SpecFuzzyFind && SpecFuzzyFind->Result.valid() && (*SpecReq == Req)) { 1539 vlog("Code complete: speculative fuzzy request matches the actual index " 1540 "request. Waiting for the speculative index results."); 1541 SPAN_ATTACH(Tracer, "Speculative results", true); 1542 1543 trace::Span WaitSpec("Wait speculative results"); 1544 return SpecFuzzyFind->Result.get(); 1545 } 1546 1547 SPAN_ATTACH(Tracer, "Speculative results", false); 1548 1549 // Run the query against the index. 1550 SymbolSlab::Builder ResultsBuilder; 1551 if (Opts.Index->fuzzyFind( 1552 Req, [&](const Symbol &Sym) { ResultsBuilder.insert(Sym); })) 1553 Incomplete = true; 1554 return std::move(ResultsBuilder).build(); 1555 } 1556 1557 // Merges Sema and Index results where possible, to form CompletionCandidates. 1558 // \p Identifiers is raw identifiers that can also be completion candidates. 1559 // Identifiers are not merged with results from index or sema. 1560 // Groups overloads if desired, to form CompletionCandidate::Bundles. The 1561 // bundles are scored and top results are returned, best to worst. 1562 std::vector<ScoredBundle> 1563 mergeResults(const std::vector<CodeCompletionResult> &SemaResults, 1564 const SymbolSlab &IndexResults, 1565 const std::vector<RawIdentifier> &IdentifierResults) { 1566 trace::Span Tracer("Merge and score results"); 1567 std::vector<CompletionCandidate::Bundle> Bundles; 1568 llvm::DenseMap<size_t, size_t> BundleLookup; 1569 auto AddToBundles = [&](const CodeCompletionResult *SemaResult, 1570 const Symbol *IndexResult, 1571 const RawIdentifier *IdentifierResult) { 1572 CompletionCandidate C; 1573 C.SemaResult = SemaResult; 1574 C.IndexResult = IndexResult; 1575 C.IdentifierResult = IdentifierResult; 1576 if (C.IndexResult) { 1577 C.Name = IndexResult->Name; 1578 C.RankedIncludeHeaders = getRankedIncludes(*C.IndexResult); 1579 } else if (C.SemaResult) { 1580 C.Name = Recorder->getName(*SemaResult); 1581 } else { 1582 assert(IdentifierResult); 1583 C.Name = IdentifierResult->Name; 1584 } 1585 if (auto OverloadSet = C.overloadSet( 1586 Opts, FileName, Inserter ? Inserter.getPointer() : nullptr)) { 1587 auto Ret = BundleLookup.try_emplace(OverloadSet, Bundles.size()); 1588 if (Ret.second) 1589 Bundles.emplace_back(); 1590 Bundles[Ret.first->second].push_back(std::move(C)); 1591 } else { 1592 Bundles.emplace_back(); 1593 Bundles.back().push_back(std::move(C)); 1594 } 1595 }; 1596 llvm::DenseSet<const Symbol *> UsedIndexResults; 1597 auto CorrespondingIndexResult = 1598 [&](const CodeCompletionResult &SemaResult) -> const Symbol * { 1599 if (auto SymID = 1600 getSymbolID(SemaResult, Recorder->CCSema->getSourceManager())) { 1601 auto I = IndexResults.find(SymID); 1602 if (I != IndexResults.end()) { 1603 UsedIndexResults.insert(&*I); 1604 return &*I; 1605 } 1606 } 1607 return nullptr; 1608 }; 1609 // Emit all Sema results, merging them with Index results if possible. 1610 for (auto &SemaResult : SemaResults) 1611 AddToBundles(&SemaResult, CorrespondingIndexResult(SemaResult), nullptr); 1612 // Now emit any Index-only results. 1613 for (const auto &IndexResult : IndexResults) { 1614 if (UsedIndexResults.count(&IndexResult)) 1615 continue; 1616 AddToBundles(/*SemaResult=*/nullptr, &IndexResult, nullptr); 1617 } 1618 // Emit identifier results. 1619 for (const auto &Ident : IdentifierResults) 1620 AddToBundles(/*SemaResult=*/nullptr, /*IndexResult=*/nullptr, &Ident); 1621 // We only keep the best N results at any time, in "native" format. 1622 TopN<ScoredBundle, ScoredBundleGreater> Top( 1623 Opts.Limit == 0 ? std::numeric_limits<size_t>::max() : Opts.Limit); 1624 for (auto &Bundle : Bundles) 1625 addCandidate(Top, std::move(Bundle)); 1626 return std::move(Top).items(); 1627 } 1628 1629 llvm::Optional<float> fuzzyScore(const CompletionCandidate &C) { 1630 // Macros can be very spammy, so we only support prefix completion. 1631 if (((C.SemaResult && 1632 C.SemaResult->Kind == CodeCompletionResult::RK_Macro) || 1633 (C.IndexResult && 1634 C.IndexResult->SymInfo.Kind == index::SymbolKind::Macro)) && 1635 !C.Name.startswith_lower(Filter->pattern())) 1636 return None; 1637 return Filter->match(C.Name); 1638 } 1639 1640 CodeCompletion::Scores 1641 evaluateCompletion(const SymbolQualitySignals &Quality, 1642 const SymbolRelevanceSignals &Relevance) { 1643 using RM = CodeCompleteOptions::CodeCompletionRankingModel; 1644 CodeCompletion::Scores Scores; 1645 switch (Opts.RankingModel) { 1646 case RM::Heuristics: 1647 Scores.Quality = Quality.evaluateHeuristics(); 1648 Scores.Relevance = Relevance.evaluateHeuristics(); 1649 Scores.Total = 1650 evaluateSymbolAndRelevance(Scores.Quality, Scores.Relevance); 1651 // NameMatch is in fact a multiplier on total score, so rescoring is 1652 // sound. 1653 Scores.ExcludingName = Relevance.NameMatch 1654 ? Scores.Total / Relevance.NameMatch 1655 : Scores.Quality; 1656 return Scores; 1657 1658 case RM::DecisionForest: 1659 DecisionForestScores DFScores = Opts.DecisionForestScorer( 1660 Quality, Relevance, Opts.DecisionForestBase); 1661 Scores.ExcludingName = DFScores.ExcludingName; 1662 Scores.Total = DFScores.Total; 1663 return Scores; 1664 } 1665 llvm_unreachable("Unhandled CodeCompletion ranking model."); 1666 } 1667 1668 // Scores a candidate and adds it to the TopN structure. 1669 void addCandidate(TopN<ScoredBundle, ScoredBundleGreater> &Candidates, 1670 CompletionCandidate::Bundle Bundle) { 1671 SymbolQualitySignals Quality; 1672 SymbolRelevanceSignals Relevance; 1673 Relevance.Context = CCContextKind; 1674 Relevance.Name = Bundle.front().Name; 1675 Relevance.FilterLength = HeuristicPrefix.Name.size(); 1676 Relevance.Query = SymbolRelevanceSignals::CodeComplete; 1677 Relevance.FileProximityMatch = FileProximity.getPointer(); 1678 if (ScopeProximity) 1679 Relevance.ScopeProximityMatch = ScopeProximity.getPointer(); 1680 if (PreferredType) 1681 Relevance.HadContextType = true; 1682 Relevance.ContextWords = &ContextWords; 1683 1684 auto &First = Bundle.front(); 1685 if (auto FuzzyScore = fuzzyScore(First)) 1686 Relevance.NameMatch = *FuzzyScore; 1687 else 1688 return; 1689 SymbolOrigin Origin = SymbolOrigin::Unknown; 1690 bool FromIndex = false; 1691 for (const auto &Candidate : Bundle) { 1692 if (Candidate.IndexResult) { 1693 Quality.merge(*Candidate.IndexResult); 1694 Relevance.merge(*Candidate.IndexResult); 1695 Origin |= Candidate.IndexResult->Origin; 1696 FromIndex = true; 1697 if (!Candidate.IndexResult->Type.empty()) 1698 Relevance.HadSymbolType |= true; 1699 if (PreferredType && 1700 PreferredType->raw() == Candidate.IndexResult->Type) { 1701 Relevance.TypeMatchesPreferred = true; 1702 } 1703 } 1704 if (Candidate.SemaResult) { 1705 Quality.merge(*Candidate.SemaResult); 1706 Relevance.merge(*Candidate.SemaResult); 1707 if (PreferredType) { 1708 if (auto CompletionType = OpaqueType::fromCompletionResult( 1709 Recorder->CCSema->getASTContext(), *Candidate.SemaResult)) { 1710 Relevance.HadSymbolType |= true; 1711 if (PreferredType == CompletionType) 1712 Relevance.TypeMatchesPreferred = true; 1713 } 1714 } 1715 Origin |= SymbolOrigin::AST; 1716 } 1717 if (Candidate.IdentifierResult) { 1718 Quality.References = Candidate.IdentifierResult->References; 1719 Relevance.Scope = SymbolRelevanceSignals::FileScope; 1720 Origin |= SymbolOrigin::Identifier; 1721 } 1722 } 1723 1724 CodeCompletion::Scores Scores = evaluateCompletion(Quality, Relevance); 1725 if (Opts.RecordCCResult) 1726 Opts.RecordCCResult(toCodeCompletion(Bundle), Quality, Relevance, 1727 Scores.Total); 1728 1729 dlog("CodeComplete: {0} ({1}) = {2}\n{3}{4}\n", First.Name, 1730 llvm::to_string(Origin), Scores.Total, llvm::to_string(Quality), 1731 llvm::to_string(Relevance)); 1732 1733 NSema += bool(Origin & SymbolOrigin::AST); 1734 NIndex += FromIndex; 1735 NSemaAndIndex += bool(Origin & SymbolOrigin::AST) && FromIndex; 1736 NIdent += bool(Origin & SymbolOrigin::Identifier); 1737 if (Candidates.push({std::move(Bundle), Scores})) 1738 Incomplete = true; 1739 } 1740 1741 CodeCompletion toCodeCompletion(const CompletionCandidate::Bundle &Bundle) { 1742 llvm::Optional<CodeCompletionBuilder> Builder; 1743 for (const auto &Item : Bundle) { 1744 CodeCompletionString *SemaCCS = 1745 Item.SemaResult ? Recorder->codeCompletionString(*Item.SemaResult) 1746 : nullptr; 1747 if (!Builder) 1748 Builder.emplace(Recorder ? &Recorder->CCSema->getASTContext() : nullptr, 1749 Item, SemaCCS, QueryScopes, *Inserter, FileName, 1750 CCContextKind, Opts, IsUsingDeclaration, NextTokenKind); 1751 else 1752 Builder->add(Item, SemaCCS); 1753 } 1754 return Builder->build(); 1755 } 1756 }; 1757 1758 } // namespace 1759 1760 clang::CodeCompleteOptions CodeCompleteOptions::getClangCompleteOpts() const { 1761 clang::CodeCompleteOptions Result; 1762 Result.IncludeCodePatterns = EnableSnippets && IncludeCodePatterns; 1763 Result.IncludeMacros = IncludeMacros; 1764 Result.IncludeGlobals = true; 1765 // We choose to include full comments and not do doxygen parsing in 1766 // completion. 1767 // FIXME: ideally, we should support doxygen in some form, e.g. do markdown 1768 // formatting of the comments. 1769 Result.IncludeBriefComments = false; 1770 1771 // When an is used, Sema is responsible for completing the main file, 1772 // the index can provide results from the preamble. 1773 // Tell Sema not to deserialize the preamble to look for results. 1774 Result.LoadExternal = !Index; 1775 Result.IncludeFixIts = IncludeFixIts; 1776 1777 return Result; 1778 } 1779 1780 CompletionPrefix guessCompletionPrefix(llvm::StringRef Content, 1781 unsigned Offset) { 1782 assert(Offset <= Content.size()); 1783 StringRef Rest = Content.take_front(Offset); 1784 CompletionPrefix Result; 1785 1786 // Consume the unqualified name. We only handle ASCII characters. 1787 // isIdentifierBody will let us match "0invalid", but we don't mind. 1788 while (!Rest.empty() && isIdentifierBody(Rest.back())) 1789 Rest = Rest.drop_back(); 1790 Result.Name = Content.slice(Rest.size(), Offset); 1791 1792 // Consume qualifiers. 1793 while (Rest.consume_back("::") && !Rest.endswith(":")) // reject :::: 1794 while (!Rest.empty() && isIdentifierBody(Rest.back())) 1795 Rest = Rest.drop_back(); 1796 Result.Qualifier = 1797 Content.slice(Rest.size(), Result.Name.begin() - Content.begin()); 1798 1799 return Result; 1800 } 1801 1802 CodeCompleteResult codeComplete(PathRef FileName, Position Pos, 1803 const PreambleData *Preamble, 1804 const ParseInputs &ParseInput, 1805 CodeCompleteOptions Opts, 1806 SpeculativeFuzzyFind *SpecFuzzyFind) { 1807 auto Offset = positionToOffset(ParseInput.Contents, Pos); 1808 if (!Offset) { 1809 elog("Code completion position was invalid {0}", Offset.takeError()); 1810 return CodeCompleteResult(); 1811 } 1812 auto Flow = CodeCompleteFlow( 1813 FileName, Preamble ? Preamble->Includes : IncludeStructure(), 1814 SpecFuzzyFind, Opts); 1815 return (!Preamble || Opts.RunParser == CodeCompleteOptions::NeverParse) 1816 ? std::move(Flow).runWithoutSema(ParseInput.Contents, *Offset, 1817 *ParseInput.TFS) 1818 : std::move(Flow).run({FileName, *Offset, *Preamble, 1819 // We want to serve code completions with 1820 // low latency, so don't bother patching. 1821 /*PreamblePatch=*/llvm::None, ParseInput}); 1822 } 1823 1824 SignatureHelp signatureHelp(PathRef FileName, Position Pos, 1825 const PreambleData &Preamble, 1826 const ParseInputs &ParseInput) { 1827 auto Offset = positionToOffset(ParseInput.Contents, Pos); 1828 if (!Offset) { 1829 elog("Signature help position was invalid {0}", Offset.takeError()); 1830 return SignatureHelp(); 1831 } 1832 SignatureHelp Result; 1833 clang::CodeCompleteOptions Options; 1834 Options.IncludeGlobals = false; 1835 Options.IncludeMacros = false; 1836 Options.IncludeCodePatterns = false; 1837 Options.IncludeBriefComments = false; 1838 semaCodeComplete( 1839 std::make_unique<SignatureHelpCollector>(Options, ParseInput.Index, 1840 Result), 1841 Options, 1842 {FileName, *Offset, Preamble, 1843 PreamblePatch::create(FileName, ParseInput, Preamble), ParseInput}); 1844 return Result; 1845 } 1846 1847 bool isIndexedForCodeCompletion(const NamedDecl &ND, ASTContext &ASTCtx) { 1848 auto InTopLevelScope = [](const NamedDecl &ND) { 1849 switch (ND.getDeclContext()->getDeclKind()) { 1850 case Decl::TranslationUnit: 1851 case Decl::Namespace: 1852 case Decl::LinkageSpec: 1853 return true; 1854 default: 1855 break; 1856 }; 1857 return false; 1858 }; 1859 // We only complete symbol's name, which is the same as the name of the 1860 // *primary* template in case of template specializations. 1861 if (isExplicitTemplateSpecialization(&ND)) 1862 return false; 1863 1864 if (InTopLevelScope(ND)) 1865 return true; 1866 1867 if (const auto *EnumDecl = dyn_cast<clang::EnumDecl>(ND.getDeclContext())) 1868 return InTopLevelScope(*EnumDecl) && !EnumDecl->isScoped(); 1869 1870 return false; 1871 } 1872 1873 // FIXME: find a home for this (that can depend on both markup and Protocol). 1874 static MarkupContent renderDoc(const markup::Document &Doc, MarkupKind Kind) { 1875 MarkupContent Result; 1876 Result.kind = Kind; 1877 switch (Kind) { 1878 case MarkupKind::PlainText: 1879 Result.value.append(Doc.asPlainText()); 1880 break; 1881 case MarkupKind::Markdown: 1882 Result.value.append(Doc.asMarkdown()); 1883 break; 1884 } 1885 return Result; 1886 } 1887 1888 CompletionItem CodeCompletion::render(const CodeCompleteOptions &Opts) const { 1889 CompletionItem LSP; 1890 const auto *InsertInclude = Includes.empty() ? nullptr : &Includes[0]; 1891 LSP.label = ((InsertInclude && InsertInclude->Insertion) 1892 ? Opts.IncludeIndicator.Insert 1893 : Opts.IncludeIndicator.NoInsert) + 1894 (Opts.ShowOrigins ? "[" + llvm::to_string(Origin) + "]" : "") + 1895 RequiredQualifier + Name + Signature; 1896 1897 LSP.kind = Kind; 1898 LSP.detail = BundleSize > 1 1899 ? std::string(llvm::formatv("[{0} overloads]", BundleSize)) 1900 : ReturnType; 1901 LSP.deprecated = Deprecated; 1902 // Combine header information and documentation in LSP `documentation` field. 1903 // This is not quite right semantically, but tends to display well in editors. 1904 if (InsertInclude || Documentation) { 1905 markup::Document Doc; 1906 if (InsertInclude) 1907 Doc.addParagraph().appendText("From ").appendCode(InsertInclude->Header); 1908 if (Documentation) 1909 Doc.append(*Documentation); 1910 LSP.documentation = renderDoc(Doc, Opts.DocumentationFormat); 1911 } 1912 LSP.sortText = sortText(Score.Total, Name); 1913 LSP.filterText = Name; 1914 LSP.textEdit = {CompletionTokenRange, RequiredQualifier + Name}; 1915 // Merge continuous additionalTextEdits into main edit. The main motivation 1916 // behind this is to help LSP clients, it seems most of them are confused when 1917 // they are provided with additionalTextEdits that are consecutive to main 1918 // edit. 1919 // Note that we store additional text edits from back to front in a line. That 1920 // is mainly to help LSP clients again, so that changes do not effect each 1921 // other. 1922 for (const auto &FixIt : FixIts) { 1923 if (FixIt.range.end == LSP.textEdit->range.start) { 1924 LSP.textEdit->newText = FixIt.newText + LSP.textEdit->newText; 1925 LSP.textEdit->range.start = FixIt.range.start; 1926 } else { 1927 LSP.additionalTextEdits.push_back(FixIt); 1928 } 1929 } 1930 if (Opts.EnableSnippets) 1931 LSP.textEdit->newText += SnippetSuffix; 1932 1933 // FIXME(kadircet): Do not even fill insertText after making sure textEdit is 1934 // compatible with most of the editors. 1935 LSP.insertText = LSP.textEdit->newText; 1936 LSP.insertTextFormat = Opts.EnableSnippets ? InsertTextFormat::Snippet 1937 : InsertTextFormat::PlainText; 1938 if (InsertInclude && InsertInclude->Insertion) 1939 LSP.additionalTextEdits.push_back(*InsertInclude->Insertion); 1940 1941 LSP.score = Score.ExcludingName; 1942 1943 return LSP; 1944 } 1945 1946 llvm::raw_ostream &operator<<(llvm::raw_ostream &OS, const CodeCompletion &C) { 1947 // For now just lean on CompletionItem. 1948 return OS << C.render(CodeCompleteOptions()); 1949 } 1950 1951 llvm::raw_ostream &operator<<(llvm::raw_ostream &OS, 1952 const CodeCompleteResult &R) { 1953 OS << "CodeCompleteResult: " << R.Completions.size() << (R.HasMore ? "+" : "") 1954 << " (" << getCompletionKindString(R.Context) << ")" 1955 << " items:\n"; 1956 for (const auto &C : R.Completions) 1957 OS << C << "\n"; 1958 return OS; 1959 } 1960 1961 // Heuristically detect whether the `Line` is an unterminated include filename. 1962 bool isIncludeFile(llvm::StringRef Line) { 1963 Line = Line.ltrim(); 1964 if (!Line.consume_front("#")) 1965 return false; 1966 Line = Line.ltrim(); 1967 if (!(Line.consume_front("include_next") || Line.consume_front("include") || 1968 Line.consume_front("import"))) 1969 return false; 1970 Line = Line.ltrim(); 1971 if (Line.consume_front("<")) 1972 return Line.count('>') == 0; 1973 if (Line.consume_front("\"")) 1974 return Line.count('"') == 0; 1975 return false; 1976 } 1977 1978 bool allowImplicitCompletion(llvm::StringRef Content, unsigned Offset) { 1979 // Look at last line before completion point only. 1980 Content = Content.take_front(Offset); 1981 auto Pos = Content.rfind('\n'); 1982 if (Pos != llvm::StringRef::npos) 1983 Content = Content.substr(Pos + 1); 1984 1985 // Complete after scope operators. 1986 if (Content.endswith(".") || Content.endswith("->") || Content.endswith("::")) 1987 return true; 1988 // Complete after `#include <` and #include `<foo/`. 1989 if ((Content.endswith("<") || Content.endswith("\"") || 1990 Content.endswith("/")) && 1991 isIncludeFile(Content)) 1992 return true; 1993 1994 // Complete words. Give non-ascii characters the benefit of the doubt. 1995 return !Content.empty() && 1996 (isIdentifierBody(Content.back()) || !llvm::isASCII(Content.back())); 1997 } 1998 1999 } // namespace clangd 2000 } // namespace clang 2001