//===--- ParseInit.cpp - Initializer Parsing ------------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements initializer parsing as specified by C99 6.7.8. // //===----------------------------------------------------------------------===// #include "clang/Parse/Parser.h" #include "RAIIObjectsForParser.h" #include "clang/Parse/ParseDiagnostic.h" #include "clang/Sema/Designator.h" #include "clang/Sema/Scope.h" #include "llvm/ADT/SmallString.h" #include "llvm/Support/raw_ostream.h" using namespace clang; /// MayBeDesignationStart - Return true if the current token might be the start /// of a designator. If we can tell it is impossible that it is a designator, /// return false. bool Parser::MayBeDesignationStart() { switch (Tok.getKind()) { default: return false; case tok::period: // designator: '.' identifier return true; case tok::l_square: { // designator: array-designator if (!PP.getLangOpts().CPlusPlus11) return true; // C++11 lambda expressions and C99 designators can be ambiguous all the // way through the closing ']' and to the next character. Handle the easy // cases here, and fall back to tentative parsing if those fail. switch (PP.LookAhead(0).getKind()) { case tok::equal: case tok::r_square: // Definitely starts a lambda expression. return false; case tok::amp: case tok::kw_this: case tok::identifier: // We have to do additional analysis, because these could be the // start of a constant expression or a lambda capture list. break; default: // Anything not mentioned above cannot occur following a '[' in a // lambda expression. return true; } // Handle the complicated case below. break; } case tok::identifier: // designation: identifier ':' return PP.LookAhead(0).is(tok::colon); } // Parse up to (at most) the token after the closing ']' to determine // whether this is a C99 designator or a lambda. TentativeParsingAction Tentative(*this); LambdaIntroducer Intro; bool SkippedInits = false; Optional<unsigned> DiagID(ParseLambdaIntroducer(Intro, &SkippedInits)); if (DiagID) { // If this can't be a lambda capture list, it's a designator. Tentative.Revert(); return true; } // Once we hit the closing square bracket, we look at the next // token. If it's an '=', this is a designator. Otherwise, it's a // lambda expression. This decision favors lambdas over the older // GNU designator syntax, which allows one to omit the '=', but is // consistent with GCC. tok::TokenKind Kind = Tok.getKind(); // FIXME: If we didn't skip any inits, parse the lambda from here // rather than throwing away then reparsing the LambdaIntroducer. Tentative.Revert(); return Kind == tok::equal; } static void CheckArrayDesignatorSyntax(Parser &P, SourceLocation Loc, Designation &Desig) { // If we have exactly one array designator, this used the GNU // 'designation: array-designator' extension, otherwise there should be no // designators at all! if (Desig.getNumDesignators() == 1 && (Desig.getDesignator(0).isArrayDesignator() || Desig.getDesignator(0).isArrayRangeDesignator())) P.Diag(Loc, diag::ext_gnu_missing_equal_designator); else if (Desig.getNumDesignators() > 0) P.Diag(Loc, diag::err_expected_equal_designator); } /// ParseInitializerWithPotentialDesignator - Parse the 'initializer' production /// checking to see if the token stream starts with a designator. /// /// designation: /// designator-list '=' /// [GNU] array-designator /// [GNU] identifier ':' /// /// designator-list: /// designator /// designator-list designator /// /// designator: /// array-designator /// '.' identifier /// /// array-designator: /// '[' constant-expression ']' /// [GNU] '[' constant-expression '...' constant-expression ']' /// /// NOTE: [OBC] allows '[ objc-receiver objc-message-args ]' as an /// initializer (because it is an expression). We need to consider this case /// when parsing array designators. /// ExprResult Parser::ParseInitializerWithPotentialDesignator() { // If this is the old-style GNU extension: // designation ::= identifier ':' // Handle it as a field designator. Otherwise, this must be the start of a // normal expression. if (Tok.is(tok::identifier)) { const IdentifierInfo *FieldName = Tok.getIdentifierInfo(); SmallString<256> NewSyntax; llvm::raw_svector_ostream(NewSyntax) << '.' << FieldName->getName() << " = "; SourceLocation NameLoc = ConsumeToken(); // Eat the identifier. assert(Tok.is(tok::colon) && "MayBeDesignationStart not working properly!"); SourceLocation ColonLoc = ConsumeToken(); Diag(NameLoc, diag::ext_gnu_old_style_field_designator) << FixItHint::CreateReplacement(SourceRange(NameLoc, ColonLoc), NewSyntax.str()); Designation D; D.AddDesignator(Designator::getField(FieldName, SourceLocation(), NameLoc)); return Actions.ActOnDesignatedInitializer(D, ColonLoc, true, ParseInitializer()); } // Desig - This is initialized when we see our first designator. We may have // an objc message send with no designator, so we don't want to create this // eagerly. Designation Desig; // Parse each designator in the designator list until we find an initializer. while (Tok.is(tok::period) || Tok.is(tok::l_square)) { if (Tok.is(tok::period)) { // designator: '.' identifier SourceLocation DotLoc = ConsumeToken(); if (Tok.isNot(tok::identifier)) { Diag(Tok.getLocation(), diag::err_expected_field_designator); return ExprError(); } Desig.AddDesignator(Designator::getField(Tok.getIdentifierInfo(), DotLoc, Tok.getLocation())); ConsumeToken(); // Eat the identifier. continue; } // We must have either an array designator now or an objc message send. assert(Tok.is(tok::l_square) && "Unexpected token!"); // Handle the two forms of array designator: // array-designator: '[' constant-expression ']' // array-designator: '[' constant-expression '...' constant-expression ']' // // Also, we have to handle the case where the expression after the // designator an an objc message send: '[' objc-message-expr ']'. // Interesting cases are: // [foo bar] -> objc message send // [foo] -> array designator // [foo ... bar] -> array designator // [4][foo bar] -> obsolete GNU designation with objc message send. // // We do not need to check for an expression starting with [[ here. If it // contains an Objective-C message send, then it is not an ill-formed // attribute. If it is a lambda-expression within an array-designator, then // it will be rejected because a constant-expression cannot begin with a // lambda-expression. InMessageExpressionRAIIObject InMessage(*this, true); BalancedDelimiterTracker T(*this, tok::l_square); T.consumeOpen(); SourceLocation StartLoc = T.getOpenLocation(); ExprResult Idx; // If Objective-C is enabled and this is a typename (class message // send) or send to 'super', parse this as a message send // expression. We handle C++ and C separately, since C++ requires // much more complicated parsing. if (getLangOpts().ObjC1 && getLangOpts().CPlusPlus) { // Send to 'super'. if (Tok.is(tok::identifier) && Tok.getIdentifierInfo() == Ident_super && NextToken().isNot(tok::period) && getCurScope()->isInObjcMethodScope()) { CheckArrayDesignatorSyntax(*this, StartLoc, Desig); return ParseAssignmentExprWithObjCMessageExprStart(StartLoc, ConsumeToken(), ParsedType(), nullptr); } // Parse the receiver, which is either a type or an expression. bool IsExpr; void *TypeOrExpr; if (ParseObjCXXMessageReceiver(IsExpr, TypeOrExpr)) { SkipUntil(tok::r_square, StopAtSemi); return ExprError(); } // If the receiver was a type, we have a class message; parse // the rest of it. if (!IsExpr) { CheckArrayDesignatorSyntax(*this, StartLoc, Desig); return ParseAssignmentExprWithObjCMessageExprStart(StartLoc, SourceLocation(), ParsedType::getFromOpaquePtr(TypeOrExpr), nullptr); } // If the receiver was an expression, we still don't know // whether we have a message send or an array designator; just // adopt the expression for further analysis below. // FIXME: potentially-potentially evaluated expression above? Idx = ExprResult(static_cast<Expr*>(TypeOrExpr)); } else if (getLangOpts().ObjC1 && Tok.is(tok::identifier)) { IdentifierInfo *II = Tok.getIdentifierInfo(); SourceLocation IILoc = Tok.getLocation(); ParsedType ReceiverType; // Three cases. This is a message send to a type: [type foo] // This is a message send to super: [super foo] // This is a message sent to an expr: [super.bar foo] switch (Sema::ObjCMessageKind Kind = Actions.getObjCMessageKind(getCurScope(), II, IILoc, II == Ident_super, NextToken().is(tok::period), ReceiverType)) { case Sema::ObjCSuperMessage: case Sema::ObjCClassMessage: CheckArrayDesignatorSyntax(*this, StartLoc, Desig); if (Kind == Sema::ObjCSuperMessage) return ParseAssignmentExprWithObjCMessageExprStart(StartLoc, ConsumeToken(), ParsedType(), nullptr); ConsumeToken(); // the identifier if (!ReceiverType) { SkipUntil(tok::r_square, StopAtSemi); return ExprError(); } return ParseAssignmentExprWithObjCMessageExprStart(StartLoc, SourceLocation(), ReceiverType, nullptr); case Sema::ObjCInstanceMessage: // Fall through; we'll just parse the expression and // (possibly) treat this like an Objective-C message send // later. break; } } // Parse the index expression, if we haven't already gotten one // above (which can only happen in Objective-C++). // Note that we parse this as an assignment expression, not a constant // expression (allowing *=, =, etc) to handle the objc case. Sema needs // to validate that the expression is a constant. // FIXME: We also need to tell Sema that we're in a // potentially-potentially evaluated context. if (!Idx.get()) { Idx = ParseAssignmentExpression(); if (Idx.isInvalid()) { SkipUntil(tok::r_square, StopAtSemi); return Idx; } } // Given an expression, we could either have a designator (if the next // tokens are '...' or ']' or an objc message send. If this is an objc // message send, handle it now. An objc-message send is the start of // an assignment-expression production. if (getLangOpts().ObjC1 && Tok.isNot(tok::ellipsis) && Tok.isNot(tok::r_square)) { CheckArrayDesignatorSyntax(*this, Tok.getLocation(), Desig); return ParseAssignmentExprWithObjCMessageExprStart(StartLoc, SourceLocation(), ParsedType(), Idx.get()); } // If this is a normal array designator, remember it. if (Tok.isNot(tok::ellipsis)) { Desig.AddDesignator(Designator::getArray(Idx.get(), StartLoc)); } else { // Handle the gnu array range extension. Diag(Tok, diag::ext_gnu_array_range); SourceLocation EllipsisLoc = ConsumeToken(); ExprResult RHS(ParseConstantExpression()); if (RHS.isInvalid()) { SkipUntil(tok::r_square, StopAtSemi); return RHS; } Desig.AddDesignator(Designator::getArrayRange(Idx.get(), RHS.get(), StartLoc, EllipsisLoc)); } T.consumeClose(); Desig.getDesignator(Desig.getNumDesignators() - 1).setRBracketLoc( T.getCloseLocation()); } // Okay, we're done with the designator sequence. We know that there must be // at least one designator, because the only case we can get into this method // without a designator is when we have an objc message send. That case is // handled and returned from above. assert(!Desig.empty() && "Designator is empty?"); // Handle a normal designator sequence end, which is an equal. if (Tok.is(tok::equal)) { SourceLocation EqualLoc = ConsumeToken(); return Actions.ActOnDesignatedInitializer(Desig, EqualLoc, false, ParseInitializer()); } // We read some number of designators and found something that isn't an = or // an initializer. If we have exactly one array designator, this // is the GNU 'designation: array-designator' extension. Otherwise, it is a // parse error. if (Desig.getNumDesignators() == 1 && (Desig.getDesignator(0).isArrayDesignator() || Desig.getDesignator(0).isArrayRangeDesignator())) { Diag(Tok, diag::ext_gnu_missing_equal_designator) << FixItHint::CreateInsertion(Tok.getLocation(), "= "); return Actions.ActOnDesignatedInitializer(Desig, Tok.getLocation(), true, ParseInitializer()); } Diag(Tok, diag::err_expected_equal_designator); return ExprError(); } /// ParseBraceInitializer - Called when parsing an initializer that has a /// leading open brace. /// /// initializer: [C99 6.7.8] /// '{' initializer-list '}' /// '{' initializer-list ',' '}' /// [GNU] '{' '}' /// /// initializer-list: /// designation[opt] initializer ...[opt] /// initializer-list ',' designation[opt] initializer ...[opt] /// ExprResult Parser::ParseBraceInitializer() { InMessageExpressionRAIIObject InMessage(*this, false); BalancedDelimiterTracker T(*this, tok::l_brace); T.consumeOpen(); SourceLocation LBraceLoc = T.getOpenLocation(); /// InitExprs - This is the actual list of expressions contained in the /// initializer. ExprVector InitExprs; if (Tok.is(tok::r_brace)) { // Empty initializers are a C++ feature and a GNU extension to C. if (!getLangOpts().CPlusPlus) Diag(LBraceLoc, diag::ext_gnu_empty_initializer); // Match the '}'. return Actions.ActOnInitList(LBraceLoc, None, ConsumeBrace()); } bool InitExprsOk = true; while (1) { // Handle Microsoft __if_exists/if_not_exists if necessary. if (getLangOpts().MicrosoftExt && (Tok.is(tok::kw___if_exists) || Tok.is(tok::kw___if_not_exists))) { if (ParseMicrosoftIfExistsBraceInitializer(InitExprs, InitExprsOk)) { if (Tok.isNot(tok::comma)) break; ConsumeToken(); } if (Tok.is(tok::r_brace)) break; continue; } // Parse: designation[opt] initializer // If we know that this cannot be a designation, just parse the nested // initializer directly. ExprResult SubElt; if (MayBeDesignationStart()) SubElt = ParseInitializerWithPotentialDesignator(); else SubElt = ParseInitializer(); if (Tok.is(tok::ellipsis)) SubElt = Actions.ActOnPackExpansion(SubElt.get(), ConsumeToken()); // If we couldn't parse the subelement, bail out. if (!SubElt.isInvalid()) { InitExprs.push_back(SubElt.get()); } else { InitExprsOk = false; // We have two ways to try to recover from this error: if the code looks // grammatically ok (i.e. we have a comma coming up) try to continue // parsing the rest of the initializer. This allows us to emit // diagnostics for later elements that we find. If we don't see a comma, // assume there is a parse error, and just skip to recover. // FIXME: This comment doesn't sound right. If there is a r_brace // immediately, it can't be an error, since there is no other way of // leaving this loop except through this if. if (Tok.isNot(tok::comma)) { SkipUntil(tok::r_brace, StopBeforeMatch); break; } } // If we don't have a comma continued list, we're done. if (Tok.isNot(tok::comma)) break; // TODO: save comma locations if some client cares. ConsumeToken(); // Handle trailing comma. if (Tok.is(tok::r_brace)) break; } bool closed = !T.consumeClose(); if (InitExprsOk && closed) return Actions.ActOnInitList(LBraceLoc, InitExprs, T.getCloseLocation()); return ExprError(); // an error occurred. } // Return true if a comma (or closing brace) is necessary after the // __if_exists/if_not_exists statement. bool Parser::ParseMicrosoftIfExistsBraceInitializer(ExprVector &InitExprs, bool &InitExprsOk) { bool trailingComma = false; IfExistsCondition Result; if (ParseMicrosoftIfExistsCondition(Result)) return false; BalancedDelimiterTracker Braces(*this, tok::l_brace); if (Braces.consumeOpen()) { Diag(Tok, diag::err_expected) << tok::l_brace; return false; } switch (Result.Behavior) { case IEB_Parse: // Parse the declarations below. break; case IEB_Dependent: Diag(Result.KeywordLoc, diag::warn_microsoft_dependent_exists) << Result.IsIfExists; // Fall through to skip. case IEB_Skip: Braces.skipToEnd(); return false; } while (!isEofOrEom()) { trailingComma = false; // If we know that this cannot be a designation, just parse the nested // initializer directly. ExprResult SubElt; if (MayBeDesignationStart()) SubElt = ParseInitializerWithPotentialDesignator(); else SubElt = ParseInitializer(); if (Tok.is(tok::ellipsis)) SubElt = Actions.ActOnPackExpansion(SubElt.get(), ConsumeToken()); // If we couldn't parse the subelement, bail out. if (!SubElt.isInvalid()) InitExprs.push_back(SubElt.get()); else InitExprsOk = false; if (Tok.is(tok::comma)) { ConsumeToken(); trailingComma = true; } if (Tok.is(tok::r_brace)) break; } Braces.consumeClose(); return !trailingComma; }