//===--- InlayHints.cpp ------------------------------------------*- C++-*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "InlayHints.h" #include "AST.h" #include "Config.h" #include "HeuristicResolver.h" #include "ParsedAST.h" #include "clang/AST/Decl.h" #include "clang/AST/DeclarationName.h" #include "clang/AST/ExprCXX.h" #include "clang/AST/RecursiveASTVisitor.h" #include "clang/Basic/SourceManager.h" #include "llvm/ADT/ScopeExit.h" namespace clang { namespace clangd { namespace { // For now, inlay hints are always anchored at the left or right of their range. enum class HintSide { Left, Right }; // Helper class to iterate over the designator names of an aggregate type. // // For an array type, yields [0], [1], [2]... // For aggregate classes, yields null for each base, then .field1, .field2, ... class AggregateDesignatorNames { public: AggregateDesignatorNames(QualType T) { if (!T.isNull()) { T = T.getCanonicalType(); if (T->isArrayType()) { IsArray = true; Valid = true; return; } if (const RecordDecl *RD = T->getAsRecordDecl()) { Valid = true; FieldsIt = RD->field_begin(); FieldsEnd = RD->field_end(); if (const auto *CRD = llvm::dyn_cast(RD)) { BasesIt = CRD->bases_begin(); BasesEnd = CRD->bases_end(); Valid = CRD->isAggregate(); } OneField = Valid && BasesIt == BasesEnd && FieldsIt != FieldsEnd && std::next(FieldsIt) == FieldsEnd; } } } // Returns false if the type was not an aggregate. operator bool() { return Valid; } // Advance to the next element in the aggregate. void next() { if (IsArray) ++Index; else if (BasesIt != BasesEnd) ++BasesIt; else if (FieldsIt != FieldsEnd) ++FieldsIt; } // Print the designator to Out. // Returns false if we could not produce a designator for this element. bool append(std::string &Out, bool ForSubobject) { if (IsArray) { Out.push_back('['); Out.append(std::to_string(Index)); Out.push_back(']'); return true; } if (BasesIt != BasesEnd) return false; // Bases can't be designated. Should we make one up? if (FieldsIt != FieldsEnd) { llvm::StringRef FieldName; if (const IdentifierInfo *II = FieldsIt->getIdentifier()) FieldName = II->getName(); // For certain objects, their subobjects may be named directly. if (ForSubobject && (FieldsIt->isAnonymousStructOrUnion() || // std::array x = {1,2,3}. Designators not strictly valid! (OneField && isReservedName(FieldName)))) return true; if (!FieldName.empty() && !isReservedName(FieldName)) { Out.push_back('.'); Out.append(FieldName.begin(), FieldName.end()); return true; } return false; } return false; } private: bool Valid = false; bool IsArray = false; bool OneField = false; // e.g. std::array { T __elements[N]; } unsigned Index = 0; CXXRecordDecl::base_class_const_iterator BasesIt; CXXRecordDecl::base_class_const_iterator BasesEnd; RecordDecl::field_iterator FieldsIt; RecordDecl::field_iterator FieldsEnd; }; // Collect designator labels describing the elements of an init list. // // This function contributes the designators of some (sub)object, which is // represented by the semantic InitListExpr Sem. // This includes any nested subobjects, but *only* if they are part of the same // original syntactic init list (due to brace elision). // In other words, it may descend into subobjects but not written init-lists. // // For example: struct Outer { Inner a,b; }; struct Inner { int x, y; } // Outer o{{1, 2}, 3}; // This function will be called with Sem = { {1, 2}, {3, ImplicitValue} } // It should generate designators '.a:' and '.b.x:'. // '.a:' is produced directly without recursing into the written sublist. // (The written sublist will have a separate collectDesignators() call later). // Recursion with Prefix='.b' and Sem = {3, ImplicitValue} produces '.b.x:'. void collectDesignators(const InitListExpr *Sem, llvm::DenseMap &Out, const llvm::DenseSet &NestedBraces, std::string &Prefix) { if (!Sem || Sem->isTransparent()) return; assert(Sem->isSemanticForm()); // The elements of the semantic form all correspond to direct subobjects of // the aggregate type. `Fields` iterates over these subobject names. AggregateDesignatorNames Fields(Sem->getType()); if (!Fields) return; for (const Expr *Init : Sem->inits()) { auto Next = llvm::make_scope_exit([&, Size(Prefix.size())] { Fields.next(); // Always advance to the next subobject name. Prefix.resize(Size); // Erase any designator we appended. }); if (llvm::isa(Init)) continue; // a "hole" for a subobject that was not explicitly initialized const auto *BraceElidedSubobject = llvm::dyn_cast(Init); if (BraceElidedSubobject && NestedBraces.contains(BraceElidedSubobject->getLBraceLoc())) BraceElidedSubobject = nullptr; // there were braces! if (!Fields.append(Prefix, BraceElidedSubobject != nullptr)) continue; // no designator available for this subobject if (BraceElidedSubobject) { // If the braces were elided, this aggregate subobject is initialized // inline in the same syntactic list. // Descend into the semantic list describing the subobject. // (NestedBraces are still correct, they're from the same syntactic list). collectDesignators(BraceElidedSubobject, Out, NestedBraces, Prefix); continue; } Out.try_emplace(Init->getBeginLoc(), Prefix); } } // Get designators describing the elements of a (syntactic) init list. // This does not produce designators for any explicitly-written nested lists. llvm::DenseMap getDesignators(const InitListExpr *Syn) { assert(Syn->isSyntacticForm()); // collectDesignators needs to know which InitListExprs in the semantic tree // were actually written, but InitListExpr::isExplicit() lies. // Instead, record where braces of sub-init-lists occur in the syntactic form. llvm::DenseSet NestedBraces; for (const Expr *Init : Syn->inits()) if (auto *Nested = llvm::dyn_cast(Init)) NestedBraces.insert(Nested->getLBraceLoc()); // Traverse the semantic form to find the designators. // We use their SourceLocation to correlate with the syntactic form later. llvm::DenseMap Designators; std::string EmptyPrefix; collectDesignators(Syn->isSemanticForm() ? Syn : Syn->getSemanticForm(), Designators, NestedBraces, EmptyPrefix); return Designators; } class InlayHintVisitor : public RecursiveASTVisitor { public: InlayHintVisitor(std::vector &Results, ParsedAST &AST, const Config &Cfg, llvm::Optional RestrictRange) : Results(Results), AST(AST.getASTContext()), Cfg(Cfg), RestrictRange(std::move(RestrictRange)), MainFileID(AST.getSourceManager().getMainFileID()), Resolver(AST.getHeuristicResolver()), TypeHintPolicy(this->AST.getPrintingPolicy()), StructuredBindingPolicy(this->AST.getPrintingPolicy()) { bool Invalid = false; llvm::StringRef Buf = AST.getSourceManager().getBufferData(MainFileID, &Invalid); MainFileBuf = Invalid ? StringRef{} : Buf; TypeHintPolicy.SuppressScope = true; // keep type names short TypeHintPolicy.AnonymousTagLocations = false; // do not print lambda locations // For structured bindings, print canonical types. This is important because // for bindings that use the tuple_element protocol, the non-canonical types // would be "tuple_element::type". // For "auto", we often prefer sugared types. // Not setting PrintCanonicalTypes for "auto" allows // SuppressDefaultTemplateArgs (set by default) to have an effect. StructuredBindingPolicy = TypeHintPolicy; StructuredBindingPolicy.PrintCanonicalTypes = true; } bool VisitCXXConstructExpr(CXXConstructExpr *E) { // Weed out constructor calls that don't look like a function call with // an argument list, by checking the validity of getParenOrBraceRange(). // Also weed out std::initializer_list constructors as there are no names // for the individual arguments. if (!E->getParenOrBraceRange().isValid() || E->isStdInitListInitialization()) { return true; } processCall(E->getParenOrBraceRange().getBegin(), E->getConstructor(), {E->getArgs(), E->getNumArgs()}); return true; } bool VisitCallExpr(CallExpr *E) { if (!Cfg.InlayHints.Parameters) return true; // Do not show parameter hints for operator calls written using operator // syntax or user-defined literals. (Among other reasons, the resulting // hints can look awkard, e.g. the expression can itself be a function // argument and then we'd get two hints side by side). if (isa(E) || isa(E)) return true; auto CalleeDecls = Resolver->resolveCalleeOfCallExpr(E); if (CalleeDecls.size() != 1) return true; const FunctionDecl *Callee = nullptr; if (const auto *FD = dyn_cast(CalleeDecls[0])) Callee = FD; else if (const auto *FTD = dyn_cast(CalleeDecls[0])) Callee = FTD->getTemplatedDecl(); if (!Callee) return true; processCall(E->getRParenLoc(), Callee, {E->getArgs(), E->getNumArgs()}); return true; } bool VisitFunctionDecl(FunctionDecl *D) { if (auto *FPT = llvm::dyn_cast(D->getType().getTypePtr())) { if (!FPT->hasTrailingReturn()) addReturnTypeHint(D, D->getFunctionTypeLoc().getRParenLoc()); } return true; } bool VisitLambdaExpr(LambdaExpr *E) { FunctionDecl *D = E->getCallOperator(); if (!E->hasExplicitResultType()) addReturnTypeHint(D, E->hasExplicitParameters() ? D->getFunctionTypeLoc().getRParenLoc() : E->getIntroducerRange().getEnd()); return true; } void addReturnTypeHint(FunctionDecl *D, SourceLocation Loc) { auto *AT = D->getReturnType()->getContainedAutoType(); if (!AT || AT->getDeducedType().isNull()) return; addTypeHint(Loc, D->getReturnType(), /*Prefix=*/"-> "); } bool VisitVarDecl(VarDecl *D) { // Do not show hints for the aggregate in a structured binding, // but show hints for the individual bindings. if (auto *DD = dyn_cast(D)) { for (auto *Binding : DD->bindings()) { addTypeHint(Binding->getLocation(), Binding->getType(), /*Prefix=*/": ", StructuredBindingPolicy); } return true; } if (D->getType()->getContainedAutoType()) { if (!D->getType()->isDependentType()) { // Our current approach is to place the hint on the variable // and accordingly print the full type // (e.g. for `const auto& x = 42`, print `const int&`). // Alternatively, we could place the hint on the `auto` // (and then just print the type deduced for the `auto`). addTypeHint(D->getLocation(), D->getType(), /*Prefix=*/": "); } } // Handle templates like `int foo(auto x)` with exactly one instantiation. if (auto *PVD = llvm::dyn_cast(D)) { if (D->getIdentifier() && PVD->getType()->isDependentType() && !getContainedAutoParamType(D->getTypeSourceInfo()->getTypeLoc()) .isNull()) { if (auto *IPVD = getOnlyParamInstantiation(PVD)) addTypeHint(D->getLocation(), IPVD->getType(), /*Prefix=*/": "); } } return true; } ParmVarDecl *getOnlyParamInstantiation(ParmVarDecl *D) { auto *TemplateFunction = llvm::dyn_cast(D->getDeclContext()); if (!TemplateFunction) return nullptr; auto *InstantiatedFunction = llvm::dyn_cast_or_null( getOnlyInstantiation(TemplateFunction)); if (!InstantiatedFunction) return nullptr; unsigned ParamIdx = 0; for (auto *Param : TemplateFunction->parameters()) { // Can't reason about param indexes in the presence of preceding packs. // And if this param is a pack, it may expand to multiple params. if (Param->isParameterPack()) return nullptr; if (Param == D) break; ++ParamIdx; } assert(ParamIdx < TemplateFunction->getNumParams() && "Couldn't find param in list?"); assert(ParamIdx < InstantiatedFunction->getNumParams() && "Instantiated function has fewer (non-pack) parameters?"); return InstantiatedFunction->getParamDecl(ParamIdx); } bool VisitInitListExpr(InitListExpr *Syn) { // We receive the syntactic form here (shouldVisitImplicitCode() is false). // This is the one we will ultimately attach designators to. // It may have subobject initializers inlined without braces. The *semantic* // form of the init-list has nested init-lists for these. // getDesignators will look at the semantic form to determine the labels. assert(Syn->isSyntacticForm() && "RAV should not visit implicit code!"); if (!Cfg.InlayHints.Designators) return true; if (Syn->isIdiomaticZeroInitializer(AST.getLangOpts())) return true; llvm::DenseMap Designators = getDesignators(Syn); for (const Expr *Init : Syn->inits()) { if (llvm::isa(Init)) continue; auto It = Designators.find(Init->getBeginLoc()); if (It != Designators.end() && !isPrecededByParamNameComment(Init, It->second)) addDesignatorHint(Init->getSourceRange(), It->second); } return true; } // FIXME: Handle RecoveryExpr to try to hint some invalid calls. private: using NameVec = SmallVector; // The purpose of Anchor is to deal with macros. It should be the call's // opening or closing parenthesis or brace. (Always using the opening would // make more sense but CallExpr only exposes the closing.) We heuristically // assume that if this location does not come from a macro definition, then // the entire argument list likely appears in the main file and can be hinted. void processCall(SourceLocation Anchor, const FunctionDecl *Callee, llvm::ArrayRef Args) { if (!Cfg.InlayHints.Parameters || Args.size() == 0 || !Callee) return; // If the anchor location comes from a macro defintion, there's nowhere to // put hints. if (!AST.getSourceManager().getTopMacroCallerLoc(Anchor).isFileID()) return; // The parameter name of a move or copy constructor is not very interesting. if (auto *Ctor = dyn_cast(Callee)) if (Ctor->isCopyOrMoveConstructor()) return; // Don't show hints for variadic parameters. size_t FixedParamCount = getFixedParamCount(Callee); size_t ArgCount = std::min(FixedParamCount, Args.size()); auto Params = Callee->parameters(); NameVec ParameterNames = chooseParameterNames(Callee, ArgCount); // Exclude setters (i.e. functions with one argument whose name begins with // "set"), as their parameter name is also not likely to be interesting. if (isSetter(Callee, ParameterNames)) return; for (size_t I = 0; I < ArgCount; ++I) { StringRef Name = ParameterNames[I]; bool NameHint = shouldHintName(Args[I], Name); bool ReferenceHint = shouldHintReference(Params[I]); if (NameHint || ReferenceHint) { addInlayHint(Args[I]->getSourceRange(), HintSide::Left, InlayHintKind::ParameterHint, ReferenceHint ? "&" : "", NameHint ? Name : "", ": "); } } } static bool isSetter(const FunctionDecl *Callee, const NameVec &ParamNames) { if (ParamNames.size() != 1) return false; StringRef Name = getSimpleName(*Callee); if (!Name.startswith_insensitive("set")) return false; // In addition to checking that the function has one parameter and its // name starts with "set", also check that the part after "set" matches // the name of the parameter (ignoring case). The idea here is that if // the parameter name differs, it may contain extra information that // may be useful to show in a hint, as in: // void setTimeout(int timeoutMillis); // This currently doesn't handle cases where params use snake_case // and functions don't, e.g. // void setExceptionHandler(EHFunc exception_handler); // We could improve this by replacing `equals_insensitive` with some // `sloppy_equals` which ignores case and also skips underscores. StringRef WhatItIsSetting = Name.substr(3).ltrim("_"); return WhatItIsSetting.equals_insensitive(ParamNames[0]); } bool shouldHintName(const Expr *Arg, StringRef ParamName) { if (ParamName.empty()) return false; // If the argument expression is a single name and it matches the // parameter name exactly, omit the name hint. if (ParamName == getSpelledIdentifier(Arg)) return false; // Exclude argument expressions preceded by a /*paramName*/. if (isPrecededByParamNameComment(Arg, ParamName)) return false; return true; } bool shouldHintReference(const ParmVarDecl *Param) { // If the parameter is a non-const reference type, print an inlay hint auto Type = Param->getType(); return Type->isLValueReferenceType() && !Type.getNonReferenceType().isConstQualified(); } // Checks if "E" is spelled in the main file and preceded by a C-style comment // whose contents match ParamName (allowing for whitespace and an optional "=" // at the end. bool isPrecededByParamNameComment(const Expr *E, StringRef ParamName) { auto &SM = AST.getSourceManager(); auto ExprStartLoc = SM.getTopMacroCallerLoc(E->getBeginLoc()); auto Decomposed = SM.getDecomposedLoc(ExprStartLoc); if (Decomposed.first != MainFileID) return false; StringRef SourcePrefix = MainFileBuf.substr(0, Decomposed.second); // Allow whitespace between comment and expression. SourcePrefix = SourcePrefix.rtrim(); // Check for comment ending. if (!SourcePrefix.consume_back("*/")) return false; // Ignore some punctuation and whitespace around comment. // In particular this allows designators to match nicely. llvm::StringLiteral IgnoreChars = " =."; SourcePrefix = SourcePrefix.rtrim(IgnoreChars); ParamName = ParamName.trim(IgnoreChars); // Other than that, the comment must contain exactly ParamName. if (!SourcePrefix.consume_back(ParamName)) return false; SourcePrefix = SourcePrefix.rtrim(IgnoreChars); return SourcePrefix.endswith("/*"); } // If "E" spells a single unqualified identifier, return that name. // Otherwise, return an empty string. static StringRef getSpelledIdentifier(const Expr *E) { E = E->IgnoreUnlessSpelledInSource(); if (auto *DRE = dyn_cast(E)) if (!DRE->getQualifier()) return getSimpleName(*DRE->getDecl()); if (auto *ME = dyn_cast(E)) if (!ME->getQualifier() && ME->isImplicitAccess()) return getSimpleName(*ME->getMemberDecl()); return {}; } NameVec chooseParameterNames(const FunctionDecl *Callee, size_t ArgCount) { // The current strategy here is to use all the parameter names from the // canonical declaration, unless they're all empty, in which case we // use all the parameter names from the definition (in present in the // translation unit). // We could try a bit harder, e.g.: // - try all re-declarations, not just canonical + definition // - fall back arg-by-arg rather than wholesale NameVec ParameterNames = getParameterNamesForDecl(Callee, ArgCount); if (llvm::all_of(ParameterNames, std::mem_fn(&StringRef::empty))) { if (const FunctionDecl *Def = Callee->getDefinition()) { ParameterNames = getParameterNamesForDecl(Def, ArgCount); } } assert(ParameterNames.size() == ArgCount); // Standard library functions often have parameter names that start // with underscores, which makes the hints noisy, so strip them out. for (auto &Name : ParameterNames) stripLeadingUnderscores(Name); return ParameterNames; } static void stripLeadingUnderscores(StringRef &Name) { Name = Name.ltrim('_'); } // Return the number of fixed parameters Function has, that is, not counting // parameters that are variadic (instantiated from a parameter pack) or // C-style varargs. static size_t getFixedParamCount(const FunctionDecl *Function) { if (FunctionTemplateDecl *Template = Function->getPrimaryTemplate()) { FunctionDecl *F = Template->getTemplatedDecl(); size_t Result = 0; for (ParmVarDecl *Parm : F->parameters()) { if (Parm->isParameterPack()) { break; } ++Result; } return Result; } // C-style varargs don't need special handling, they're already // not included in getNumParams(). return Function->getNumParams(); } static StringRef getSimpleName(const NamedDecl &D) { if (IdentifierInfo *Ident = D.getDeclName().getAsIdentifierInfo()) { return Ident->getName(); } return StringRef(); } NameVec getParameterNamesForDecl(const FunctionDecl *Function, size_t ArgCount) { NameVec Result; for (size_t I = 0; I < ArgCount; ++I) { const ParmVarDecl *Parm = Function->getParamDecl(I); assert(Parm); Result.emplace_back(getSimpleName(*Parm)); } return Result; } // We pass HintSide rather than SourceLocation because we want to ensure // it is in the same file as the common file range. void addInlayHint(SourceRange R, HintSide Side, InlayHintKind Kind, llvm::StringRef Prefix, llvm::StringRef Label, llvm::StringRef Suffix) { // We shouldn't get as far as adding a hint if the category is disabled. // We'd like to disable as much of the analysis as possible above instead. // Assert in debug mode but add a dynamic check in production. assert(Cfg.InlayHints.Enabled && "Shouldn't get here if disabled!"); switch (Kind) { #define CHECK_KIND(Enumerator, ConfigProperty) \ case InlayHintKind::Enumerator: \ assert(Cfg.InlayHints.ConfigProperty && \ "Shouldn't get here if kind is disabled!"); \ if (!Cfg.InlayHints.ConfigProperty) \ return; \ break CHECK_KIND(ParameterHint, Parameters); CHECK_KIND(TypeHint, DeducedTypes); CHECK_KIND(DesignatorHint, Designators); #undef CHECK_KIND } auto FileRange = toHalfOpenFileRange(AST.getSourceManager(), AST.getLangOpts(), R); if (!FileRange) return; Range LSPRange{ sourceLocToPosition(AST.getSourceManager(), FileRange->getBegin()), sourceLocToPosition(AST.getSourceManager(), FileRange->getEnd())}; Position LSPPos = Side == HintSide::Left ? LSPRange.start : LSPRange.end; if (RestrictRange && (LSPPos < RestrictRange->start || !(LSPPos < RestrictRange->end))) return; // The hint may be in a file other than the main file (for example, a header // file that was included after the preamble), do not show in that case. if (!AST.getSourceManager().isWrittenInMainFile(FileRange->getBegin())) return; Results.push_back( InlayHint{LSPPos, LSPRange, Kind, (Prefix + Label + Suffix).str()}); } void addTypeHint(SourceRange R, QualType T, llvm::StringRef Prefix) { addTypeHint(R, T, Prefix, TypeHintPolicy); } void addTypeHint(SourceRange R, QualType T, llvm::StringRef Prefix, const PrintingPolicy &Policy) { if (!Cfg.InlayHints.DeducedTypes || T.isNull()) return; std::string TypeName = T.getAsString(Policy); if (TypeName.length() < TypeNameLimit) addInlayHint(R, HintSide::Right, InlayHintKind::TypeHint, Prefix, TypeName, /*Suffix=*/""); } void addDesignatorHint(SourceRange R, llvm::StringRef Text) { addInlayHint(R, HintSide::Left, InlayHintKind::DesignatorHint, /*Prefix=*/"", Text, /*Suffix=*/"="); } std::vector &Results; ASTContext &AST; const Config &Cfg; llvm::Optional RestrictRange; FileID MainFileID; StringRef MainFileBuf; const HeuristicResolver *Resolver; // We want to suppress default template arguments, but otherwise print // canonical types. Unfortunately, they're conflicting policies so we can't // have both. For regular types, suppressing template arguments is more // important, whereas printing canonical types is crucial for structured // bindings, so we use two separate policies. (See the constructor where // the policies are initialized for more details.) PrintingPolicy TypeHintPolicy; PrintingPolicy StructuredBindingPolicy; static const size_t TypeNameLimit = 32; }; } // namespace std::vector inlayHints(ParsedAST &AST, llvm::Optional RestrictRange) { std::vector Results; const auto &Cfg = Config::current(); if (!Cfg.InlayHints.Enabled) return Results; InlayHintVisitor Visitor(Results, AST, Cfg, std::move(RestrictRange)); Visitor.TraverseAST(AST.getASTContext()); // De-duplicate hints. Duplicates can sometimes occur due to e.g. explicit // template instantiations. llvm::sort(Results); Results.erase(std::unique(Results.begin(), Results.end()), Results.end()); return Results; } } // namespace clangd } // namespace clang