//===------------------------- ItaniumDemangle.h ----------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is dual licensed under the MIT and the University of Illinois Open // Source Licenses. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #ifndef LLVM_DEMANGLE_ITANIUMDEMANGLE_H #define LLVM_DEMANGLE_ITANIUMDEMANGLE_H // FIXME: (possibly) incomplete list of features that clang mangles that this // file does not yet support: // - C++ modules TS #include "llvm/Demangle/Compiler.h" #include "llvm/Demangle/StringView.h" #include "llvm/Demangle/Utility.h" #include <cassert> #include <cctype> #include <cstdio> #include <cstdlib> #include <cstring> #include <numeric> #include <utility> #define FOR_EACH_NODE_KIND(X) \ X(NodeArrayNode) \ X(DotSuffix) \ X(VendorExtQualType) \ X(QualType) \ X(ConversionOperatorType) \ X(PostfixQualifiedType) \ X(ElaboratedTypeSpefType) \ X(NameType) \ X(AbiTagAttr) \ X(EnableIfAttr) \ X(ObjCProtoName) \ X(PointerType) \ X(ReferenceType) \ X(PointerToMemberType) \ X(ArrayType) \ X(FunctionType) \ X(NoexceptSpec) \ X(DynamicExceptionSpec) \ X(FunctionEncoding) \ X(LiteralOperator) \ X(SpecialName) \ X(CtorVtableSpecialName) \ X(QualifiedName) \ X(NestedName) \ X(LocalName) \ X(VectorType) \ X(PixelVectorType) \ X(ParameterPack) \ X(TemplateArgumentPack) \ X(ParameterPackExpansion) \ X(TemplateArgs) \ X(ForwardTemplateReference) \ X(NameWithTemplateArgs) \ X(GlobalQualifiedName) \ X(StdQualifiedName) \ X(ExpandedSpecialSubstitution) \ X(SpecialSubstitution) \ X(CtorDtorName) \ X(DtorName) \ X(UnnamedTypeName) \ X(ClosureTypeName) \ X(StructuredBindingName) \ X(BinaryExpr) \ X(ArraySubscriptExpr) \ X(PostfixExpr) \ X(ConditionalExpr) \ X(MemberExpr) \ X(EnclosingExpr) \ X(CastExpr) \ X(SizeofParamPackExpr) \ X(CallExpr) \ X(NewExpr) \ X(DeleteExpr) \ X(PrefixExpr) \ X(FunctionParam) \ X(ConversionExpr) \ X(InitListExpr) \ X(FoldExpr) \ X(ThrowExpr) \ X(BoolExpr) \ X(IntegerCastExpr) \ X(IntegerLiteral) \ X(FloatLiteral) \ X(DoubleLiteral) \ X(LongDoubleLiteral) \ X(BracedExpr) \ X(BracedRangeExpr) namespace llvm { namespace itanium_demangle { // Base class of all AST nodes. The AST is built by the parser, then is // traversed by the printLeft/Right functions to produce a demangled string. class Node { public: enum Kind : unsigned char { #define ENUMERATOR(NodeKind) K ## NodeKind, FOR_EACH_NODE_KIND(ENUMERATOR) #undef ENUMERATOR }; /// Three-way bool to track a cached value. Unknown is possible if this node /// has an unexpanded parameter pack below it that may affect this cache. enum class Cache : unsigned char { Yes, No, Unknown, }; private: Kind K; // FIXME: Make these protected. public: /// Tracks if this node has a component on its right side, in which case we /// need to call printRight. Cache RHSComponentCache; /// Track if this node is a (possibly qualified) array type. This can affect /// how we format the output string. Cache ArrayCache; /// Track if this node is a (possibly qualified) function type. This can /// affect how we format the output string. Cache FunctionCache; public: Node(Kind K_, Cache RHSComponentCache_ = Cache::No, Cache ArrayCache_ = Cache::No, Cache FunctionCache_ = Cache::No) : K(K_), RHSComponentCache(RHSComponentCache_), ArrayCache(ArrayCache_), FunctionCache(FunctionCache_) {} /// Visit the most-derived object corresponding to this object. template<typename Fn> void visit(Fn F) const; // The following function is provided by all derived classes: // // Call F with arguments that, when passed to the constructor of this node, // would construct an equivalent node. //template<typename Fn> void match(Fn F) const; bool hasRHSComponent(OutputStream &S) const { if (RHSComponentCache != Cache::Unknown) return RHSComponentCache == Cache::Yes; return hasRHSComponentSlow(S); } bool hasArray(OutputStream &S) const { if (ArrayCache != Cache::Unknown) return ArrayCache == Cache::Yes; return hasArraySlow(S); } bool hasFunction(OutputStream &S) const { if (FunctionCache != Cache::Unknown) return FunctionCache == Cache::Yes; return hasFunctionSlow(S); } Kind getKind() const { return K; } virtual bool hasRHSComponentSlow(OutputStream &) const { return false; } virtual bool hasArraySlow(OutputStream &) const { return false; } virtual bool hasFunctionSlow(OutputStream &) const { return false; } // Dig through "glue" nodes like ParameterPack and ForwardTemplateReference to // get at a node that actually represents some concrete syntax. virtual const Node *getSyntaxNode(OutputStream &) const { return this; } void print(OutputStream &S) const { printLeft(S); if (RHSComponentCache != Cache::No) printRight(S); } // Print the "left" side of this Node into OutputStream. virtual void printLeft(OutputStream &) const = 0; // Print the "right". This distinction is necessary to represent C++ types // that appear on the RHS of their subtype, such as arrays or functions. // Since most types don't have such a component, provide a default // implementation. virtual void printRight(OutputStream &) const {} virtual StringView getBaseName() const { return StringView(); } // Silence compiler warnings, this dtor will never be called. virtual ~Node() = default; #ifndef NDEBUG LLVM_DUMP_METHOD void dump() const; #endif }; class NodeArray { Node **Elements; size_t NumElements; public: NodeArray() : Elements(nullptr), NumElements(0) {} NodeArray(Node **Elements_, size_t NumElements_) : Elements(Elements_), NumElements(NumElements_) {} bool empty() const { return NumElements == 0; } size_t size() const { return NumElements; } Node **begin() const { return Elements; } Node **end() const { return Elements + NumElements; } Node *operator[](size_t Idx) const { return Elements[Idx]; } void printWithComma(OutputStream &S) const { bool FirstElement = true; for (size_t Idx = 0; Idx != NumElements; ++Idx) { size_t BeforeComma = S.getCurrentPosition(); if (!FirstElement) S += ", "; size_t AfterComma = S.getCurrentPosition(); Elements[Idx]->print(S); // Elements[Idx] is an empty parameter pack expansion, we should erase the // comma we just printed. if (AfterComma == S.getCurrentPosition()) { S.setCurrentPosition(BeforeComma); continue; } FirstElement = false; } } }; struct NodeArrayNode : Node { NodeArray Array; NodeArrayNode(NodeArray Array_) : Node(KNodeArrayNode), Array(Array_) {} template<typename Fn> void match(Fn F) const { F(Array); } void printLeft(OutputStream &S) const override { Array.printWithComma(S); } }; class DotSuffix final : public Node { const Node *Prefix; const StringView Suffix; public: DotSuffix(const Node *Prefix_, StringView Suffix_) : Node(KDotSuffix), Prefix(Prefix_), Suffix(Suffix_) {} template<typename Fn> void match(Fn F) const { F(Prefix, Suffix); } void printLeft(OutputStream &s) const override { Prefix->print(s); s += " ("; s += Suffix; s += ")"; } }; class VendorExtQualType final : public Node { const Node *Ty; StringView Ext; public: VendorExtQualType(const Node *Ty_, StringView Ext_) : Node(KVendorExtQualType), Ty(Ty_), Ext(Ext_) {} template<typename Fn> void match(Fn F) const { F(Ty, Ext); } void printLeft(OutputStream &S) const override { Ty->print(S); S += " "; S += Ext; } }; enum FunctionRefQual : unsigned char { FrefQualNone, FrefQualLValue, FrefQualRValue, }; enum Qualifiers { QualNone = 0, QualConst = 0x1, QualVolatile = 0x2, QualRestrict = 0x4, }; inline Qualifiers operator|=(Qualifiers &Q1, Qualifiers Q2) { return Q1 = static_cast<Qualifiers>(Q1 | Q2); } class QualType : public Node { protected: const Qualifiers Quals; const Node *Child; void printQuals(OutputStream &S) const { if (Quals & QualConst) S += " const"; if (Quals & QualVolatile) S += " volatile"; if (Quals & QualRestrict) S += " restrict"; } public: QualType(const Node *Child_, Qualifiers Quals_) : Node(KQualType, Child_->RHSComponentCache, Child_->ArrayCache, Child_->FunctionCache), Quals(Quals_), Child(Child_) {} template<typename Fn> void match(Fn F) const { F(Child, Quals); } bool hasRHSComponentSlow(OutputStream &S) const override { return Child->hasRHSComponent(S); } bool hasArraySlow(OutputStream &S) const override { return Child->hasArray(S); } bool hasFunctionSlow(OutputStream &S) const override { return Child->hasFunction(S); } void printLeft(OutputStream &S) const override { Child->printLeft(S); printQuals(S); } void printRight(OutputStream &S) const override { Child->printRight(S); } }; class ConversionOperatorType final : public Node { const Node *Ty; public: ConversionOperatorType(const Node *Ty_) : Node(KConversionOperatorType), Ty(Ty_) {} template<typename Fn> void match(Fn F) const { F(Ty); } void printLeft(OutputStream &S) const override { S += "operator "; Ty->print(S); } }; class PostfixQualifiedType final : public Node { const Node *Ty; const StringView Postfix; public: PostfixQualifiedType(Node *Ty_, StringView Postfix_) : Node(KPostfixQualifiedType), Ty(Ty_), Postfix(Postfix_) {} template<typename Fn> void match(Fn F) const { F(Ty, Postfix); } void printLeft(OutputStream &s) const override { Ty->printLeft(s); s += Postfix; } }; class NameType final : public Node { const StringView Name; public: NameType(StringView Name_) : Node(KNameType), Name(Name_) {} template<typename Fn> void match(Fn F) const { F(Name); } StringView getName() const { return Name; } StringView getBaseName() const override { return Name; } void printLeft(OutputStream &s) const override { s += Name; } }; class ElaboratedTypeSpefType : public Node { StringView Kind; Node *Child; public: ElaboratedTypeSpefType(StringView Kind_, Node *Child_) : Node(KElaboratedTypeSpefType), Kind(Kind_), Child(Child_) {} template<typename Fn> void match(Fn F) const { F(Kind, Child); } void printLeft(OutputStream &S) const override { S += Kind; S += ' '; Child->print(S); } }; struct AbiTagAttr : Node { Node *Base; StringView Tag; AbiTagAttr(Node* Base_, StringView Tag_) : Node(KAbiTagAttr, Base_->RHSComponentCache, Base_->ArrayCache, Base_->FunctionCache), Base(Base_), Tag(Tag_) {} template<typename Fn> void match(Fn F) const { F(Base, Tag); } void printLeft(OutputStream &S) const override { Base->printLeft(S); S += "[abi:"; S += Tag; S += "]"; } }; class EnableIfAttr : public Node { NodeArray Conditions; public: EnableIfAttr(NodeArray Conditions_) : Node(KEnableIfAttr), Conditions(Conditions_) {} template<typename Fn> void match(Fn F) const { F(Conditions); } void printLeft(OutputStream &S) const override { S += " [enable_if:"; Conditions.printWithComma(S); S += ']'; } }; class ObjCProtoName : public Node { const Node *Ty; StringView Protocol; friend class PointerType; public: ObjCProtoName(const Node *Ty_, StringView Protocol_) : Node(KObjCProtoName), Ty(Ty_), Protocol(Protocol_) {} template<typename Fn> void match(Fn F) const { F(Ty, Protocol); } bool isObjCObject() const { return Ty->getKind() == KNameType && static_cast<const NameType *>(Ty)->getName() == "objc_object"; } void printLeft(OutputStream &S) const override { Ty->print(S); S += "<"; S += Protocol; S += ">"; } }; class PointerType final : public Node { const Node *Pointee; public: PointerType(const Node *Pointee_) : Node(KPointerType, Pointee_->RHSComponentCache), Pointee(Pointee_) {} template<typename Fn> void match(Fn F) const { F(Pointee); } bool hasRHSComponentSlow(OutputStream &S) const override { return Pointee->hasRHSComponent(S); } void printLeft(OutputStream &s) const override { // We rewrite objc_object<SomeProtocol>* into id<SomeProtocol>. if (Pointee->getKind() != KObjCProtoName || !static_cast<const ObjCProtoName *>(Pointee)->isObjCObject()) { Pointee->printLeft(s); if (Pointee->hasArray(s)) s += " "; if (Pointee->hasArray(s) || Pointee->hasFunction(s)) s += "("; s += "*"; } else { const auto *objcProto = static_cast<const ObjCProtoName *>(Pointee); s += "id<"; s += objcProto->Protocol; s += ">"; } } void printRight(OutputStream &s) const override { if (Pointee->getKind() != KObjCProtoName || !static_cast<const ObjCProtoName *>(Pointee)->isObjCObject()) { if (Pointee->hasArray(s) || Pointee->hasFunction(s)) s += ")"; Pointee->printRight(s); } } }; enum class ReferenceKind { LValue, RValue, }; // Represents either a LValue or an RValue reference type. class ReferenceType : public Node { const Node *Pointee; ReferenceKind RK; mutable bool Printing = false; // Dig through any refs to refs, collapsing the ReferenceTypes as we go. The // rule here is rvalue ref to rvalue ref collapses to a rvalue ref, and any // other combination collapses to a lvalue ref. std::pair<ReferenceKind, const Node *> collapse(OutputStream &S) const { auto SoFar = std::make_pair(RK, Pointee); for (;;) { const Node *SN = SoFar.second->getSyntaxNode(S); if (SN->getKind() != KReferenceType) break; auto *RT = static_cast<const ReferenceType *>(SN); SoFar.second = RT->Pointee; SoFar.first = std::min(SoFar.first, RT->RK); } return SoFar; } public: ReferenceType(const Node *Pointee_, ReferenceKind RK_) : Node(KReferenceType, Pointee_->RHSComponentCache), Pointee(Pointee_), RK(RK_) {} template<typename Fn> void match(Fn F) const { F(Pointee, RK); } bool hasRHSComponentSlow(OutputStream &S) const override { return Pointee->hasRHSComponent(S); } void printLeft(OutputStream &s) const override { if (Printing) return; SwapAndRestore<bool> SavePrinting(Printing, true); std::pair<ReferenceKind, const Node *> Collapsed = collapse(s); Collapsed.second->printLeft(s); if (Collapsed.second->hasArray(s)) s += " "; if (Collapsed.second->hasArray(s) || Collapsed.second->hasFunction(s)) s += "("; s += (Collapsed.first == ReferenceKind::LValue ? "&" : "&&"); } void printRight(OutputStream &s) const override { if (Printing) return; SwapAndRestore<bool> SavePrinting(Printing, true); std::pair<ReferenceKind, const Node *> Collapsed = collapse(s); if (Collapsed.second->hasArray(s) || Collapsed.second->hasFunction(s)) s += ")"; Collapsed.second->printRight(s); } }; class PointerToMemberType final : public Node { const Node *ClassType; const Node *MemberType; public: PointerToMemberType(const Node *ClassType_, const Node *MemberType_) : Node(KPointerToMemberType, MemberType_->RHSComponentCache), ClassType(ClassType_), MemberType(MemberType_) {} template<typename Fn> void match(Fn F) const { F(ClassType, MemberType); } bool hasRHSComponentSlow(OutputStream &S) const override { return MemberType->hasRHSComponent(S); } void printLeft(OutputStream &s) const override { MemberType->printLeft(s); if (MemberType->hasArray(s) || MemberType->hasFunction(s)) s += "("; else s += " "; ClassType->print(s); s += "::*"; } void printRight(OutputStream &s) const override { if (MemberType->hasArray(s) || MemberType->hasFunction(s)) s += ")"; MemberType->printRight(s); } }; class NodeOrString { const void *First; const void *Second; public: /* implicit */ NodeOrString(StringView Str) { const char *FirstChar = Str.begin(); const char *SecondChar = Str.end(); if (SecondChar == nullptr) { assert(FirstChar == SecondChar); ++FirstChar, ++SecondChar; } First = static_cast<const void *>(FirstChar); Second = static_cast<const void *>(SecondChar); } /* implicit */ NodeOrString(Node *N) : First(static_cast<const void *>(N)), Second(nullptr) {} NodeOrString() : First(nullptr), Second(nullptr) {} bool isString() const { return Second && First; } bool isNode() const { return First && !Second; } bool isEmpty() const { return !First && !Second; } StringView asString() const { assert(isString()); return StringView(static_cast<const char *>(First), static_cast<const char *>(Second)); } const Node *asNode() const { assert(isNode()); return static_cast<const Node *>(First); } }; class ArrayType final : public Node { const Node *Base; NodeOrString Dimension; public: ArrayType(const Node *Base_, NodeOrString Dimension_) : Node(KArrayType, /*RHSComponentCache=*/Cache::Yes, /*ArrayCache=*/Cache::Yes), Base(Base_), Dimension(Dimension_) {} template<typename Fn> void match(Fn F) const { F(Base, Dimension); } bool hasRHSComponentSlow(OutputStream &) const override { return true; } bool hasArraySlow(OutputStream &) const override { return true; } void printLeft(OutputStream &S) const override { Base->printLeft(S); } void printRight(OutputStream &S) const override { if (S.back() != ']') S += " "; S += "["; if (Dimension.isString()) S += Dimension.asString(); else if (Dimension.isNode()) Dimension.asNode()->print(S); S += "]"; Base->printRight(S); } }; class FunctionType final : public Node { const Node *Ret; NodeArray Params; Qualifiers CVQuals; FunctionRefQual RefQual; const Node *ExceptionSpec; public: FunctionType(const Node *Ret_, NodeArray Params_, Qualifiers CVQuals_, FunctionRefQual RefQual_, const Node *ExceptionSpec_) : Node(KFunctionType, /*RHSComponentCache=*/Cache::Yes, /*ArrayCache=*/Cache::No, /*FunctionCache=*/Cache::Yes), Ret(Ret_), Params(Params_), CVQuals(CVQuals_), RefQual(RefQual_), ExceptionSpec(ExceptionSpec_) {} template<typename Fn> void match(Fn F) const { F(Ret, Params, CVQuals, RefQual, ExceptionSpec); } bool hasRHSComponentSlow(OutputStream &) const override { return true; } bool hasFunctionSlow(OutputStream &) const override { return true; } // Handle C++'s ... quirky decl grammar by using the left & right // distinction. Consider: // int (*f(float))(char) {} // f is a function that takes a float and returns a pointer to a function // that takes a char and returns an int. If we're trying to print f, start // by printing out the return types's left, then print our parameters, then // finally print right of the return type. void printLeft(OutputStream &S) const override { Ret->printLeft(S); S += " "; } void printRight(OutputStream &S) const override { S += "("; Params.printWithComma(S); S += ")"; Ret->printRight(S); if (CVQuals & QualConst) S += " const"; if (CVQuals & QualVolatile) S += " volatile"; if (CVQuals & QualRestrict) S += " restrict"; if (RefQual == FrefQualLValue) S += " &"; else if (RefQual == FrefQualRValue) S += " &&"; if (ExceptionSpec != nullptr) { S += ' '; ExceptionSpec->print(S); } } }; class NoexceptSpec : public Node { const Node *E; public: NoexceptSpec(const Node *E_) : Node(KNoexceptSpec), E(E_) {} template<typename Fn> void match(Fn F) const { F(E); } void printLeft(OutputStream &S) const override { S += "noexcept("; E->print(S); S += ")"; } }; class DynamicExceptionSpec : public Node { NodeArray Types; public: DynamicExceptionSpec(NodeArray Types_) : Node(KDynamicExceptionSpec), Types(Types_) {} template<typename Fn> void match(Fn F) const { F(Types); } void printLeft(OutputStream &S) const override { S += "throw("; Types.printWithComma(S); S += ')'; } }; class FunctionEncoding final : public Node { const Node *Ret; const Node *Name; NodeArray Params; const Node *Attrs; Qualifiers CVQuals; FunctionRefQual RefQual; public: FunctionEncoding(const Node *Ret_, const Node *Name_, NodeArray Params_, const Node *Attrs_, Qualifiers CVQuals_, FunctionRefQual RefQual_) : Node(KFunctionEncoding, /*RHSComponentCache=*/Cache::Yes, /*ArrayCache=*/Cache::No, /*FunctionCache=*/Cache::Yes), Ret(Ret_), Name(Name_), Params(Params_), Attrs(Attrs_), CVQuals(CVQuals_), RefQual(RefQual_) {} template<typename Fn> void match(Fn F) const { F(Ret, Name, Params, Attrs, CVQuals, RefQual); } Qualifiers getCVQuals() const { return CVQuals; } FunctionRefQual getRefQual() const { return RefQual; } NodeArray getParams() const { return Params; } const Node *getReturnType() const { return Ret; } bool hasRHSComponentSlow(OutputStream &) const override { return true; } bool hasFunctionSlow(OutputStream &) const override { return true; } const Node *getName() const { return Name; } void printLeft(OutputStream &S) const override { if (Ret) { Ret->printLeft(S); if (!Ret->hasRHSComponent(S)) S += " "; } Name->print(S); } void printRight(OutputStream &S) const override { S += "("; Params.printWithComma(S); S += ")"; if (Ret) Ret->printRight(S); if (CVQuals & QualConst) S += " const"; if (CVQuals & QualVolatile) S += " volatile"; if (CVQuals & QualRestrict) S += " restrict"; if (RefQual == FrefQualLValue) S += " &"; else if (RefQual == FrefQualRValue) S += " &&"; if (Attrs != nullptr) Attrs->print(S); } }; class LiteralOperator : public Node { const Node *OpName; public: LiteralOperator(const Node *OpName_) : Node(KLiteralOperator), OpName(OpName_) {} template<typename Fn> void match(Fn F) const { F(OpName); } void printLeft(OutputStream &S) const override { S += "operator\"\" "; OpName->print(S); } }; class SpecialName final : public Node { const StringView Special; const Node *Child; public: SpecialName(StringView Special_, const Node *Child_) : Node(KSpecialName), Special(Special_), Child(Child_) {} template<typename Fn> void match(Fn F) const { F(Special, Child); } void printLeft(OutputStream &S) const override { S += Special; Child->print(S); } }; class CtorVtableSpecialName final : public Node { const Node *FirstType; const Node *SecondType; public: CtorVtableSpecialName(const Node *FirstType_, const Node *SecondType_) : Node(KCtorVtableSpecialName), FirstType(FirstType_), SecondType(SecondType_) {} template<typename Fn> void match(Fn F) const { F(FirstType, SecondType); } void printLeft(OutputStream &S) const override { S += "construction vtable for "; FirstType->print(S); S += "-in-"; SecondType->print(S); } }; struct NestedName : Node { Node *Qual; Node *Name; NestedName(Node *Qual_, Node *Name_) : Node(KNestedName), Qual(Qual_), Name(Name_) {} template<typename Fn> void match(Fn F) const { F(Qual, Name); } StringView getBaseName() const override { return Name->getBaseName(); } void printLeft(OutputStream &S) const override { Qual->print(S); S += "::"; Name->print(S); } }; struct LocalName : Node { Node *Encoding; Node *Entity; LocalName(Node *Encoding_, Node *Entity_) : Node(KLocalName), Encoding(Encoding_), Entity(Entity_) {} template<typename Fn> void match(Fn F) const { F(Encoding, Entity); } void printLeft(OutputStream &S) const override { Encoding->print(S); S += "::"; Entity->print(S); } }; class QualifiedName final : public Node { // qualifier::name const Node *Qualifier; const Node *Name; public: QualifiedName(const Node *Qualifier_, const Node *Name_) : Node(KQualifiedName), Qualifier(Qualifier_), Name(Name_) {} template<typename Fn> void match(Fn F) const { F(Qualifier, Name); } StringView getBaseName() const override { return Name->getBaseName(); } void printLeft(OutputStream &S) const override { Qualifier->print(S); S += "::"; Name->print(S); } }; class VectorType final : public Node { const Node *BaseType; const NodeOrString Dimension; public: VectorType(const Node *BaseType_, NodeOrString Dimension_) : Node(KVectorType), BaseType(BaseType_), Dimension(Dimension_) {} template<typename Fn> void match(Fn F) const { F(BaseType, Dimension); } void printLeft(OutputStream &S) const override { BaseType->print(S); S += " vector["; if (Dimension.isNode()) Dimension.asNode()->print(S); else if (Dimension.isString()) S += Dimension.asString(); S += "]"; } }; class PixelVectorType final : public Node { const NodeOrString Dimension; public: PixelVectorType(NodeOrString Dimension_) : Node(KPixelVectorType), Dimension(Dimension_) {} template<typename Fn> void match(Fn F) const { F(Dimension); } void printLeft(OutputStream &S) const override { // FIXME: This should demangle as "vector pixel". S += "pixel vector["; S += Dimension.asString(); S += "]"; } }; /// An unexpanded parameter pack (either in the expression or type context). If /// this AST is correct, this node will have a ParameterPackExpansion node above /// it. /// /// This node is created when some <template-args> are found that apply to an /// <encoding>, and is stored in the TemplateParams table. In order for this to /// appear in the final AST, it has to referenced via a <template-param> (ie, /// T_). class ParameterPack final : public Node { NodeArray Data; // Setup OutputStream for a pack expansion unless we're already expanding one. void initializePackExpansion(OutputStream &S) const { if (S.CurrentPackMax == std::numeric_limits<unsigned>::max()) { S.CurrentPackMax = static_cast<unsigned>(Data.size()); S.CurrentPackIndex = 0; } } public: ParameterPack(NodeArray Data_) : Node(KParameterPack), Data(Data_) { ArrayCache = FunctionCache = RHSComponentCache = Cache::Unknown; if (std::all_of(Data.begin(), Data.end(), [](Node* P) { return P->ArrayCache == Cache::No; })) ArrayCache = Cache::No; if (std::all_of(Data.begin(), Data.end(), [](Node* P) { return P->FunctionCache == Cache::No; })) FunctionCache = Cache::No; if (std::all_of(Data.begin(), Data.end(), [](Node* P) { return P->RHSComponentCache == Cache::No; })) RHSComponentCache = Cache::No; } template<typename Fn> void match(Fn F) const { F(Data); } bool hasRHSComponentSlow(OutputStream &S) const override { initializePackExpansion(S); size_t Idx = S.CurrentPackIndex; return Idx < Data.size() && Data[Idx]->hasRHSComponent(S); } bool hasArraySlow(OutputStream &S) const override { initializePackExpansion(S); size_t Idx = S.CurrentPackIndex; return Idx < Data.size() && Data[Idx]->hasArray(S); } bool hasFunctionSlow(OutputStream &S) const override { initializePackExpansion(S); size_t Idx = S.CurrentPackIndex; return Idx < Data.size() && Data[Idx]->hasFunction(S); } const Node *getSyntaxNode(OutputStream &S) const override { initializePackExpansion(S); size_t Idx = S.CurrentPackIndex; return Idx < Data.size() ? Data[Idx]->getSyntaxNode(S) : this; } void printLeft(OutputStream &S) const override { initializePackExpansion(S); size_t Idx = S.CurrentPackIndex; if (Idx < Data.size()) Data[Idx]->printLeft(S); } void printRight(OutputStream &S) const override { initializePackExpansion(S); size_t Idx = S.CurrentPackIndex; if (Idx < Data.size()) Data[Idx]->printRight(S); } }; /// A variadic template argument. This node represents an occurrence of /// J<something>E in some <template-args>. It isn't itself unexpanded, unless /// one of it's Elements is. The parser inserts a ParameterPack into the /// TemplateParams table if the <template-args> this pack belongs to apply to an /// <encoding>. class TemplateArgumentPack final : public Node { NodeArray Elements; public: TemplateArgumentPack(NodeArray Elements_) : Node(KTemplateArgumentPack), Elements(Elements_) {} template<typename Fn> void match(Fn F) const { F(Elements); } NodeArray getElements() const { return Elements; } void printLeft(OutputStream &S) const override { Elements.printWithComma(S); } }; /// A pack expansion. Below this node, there are some unexpanded ParameterPacks /// which each have Child->ParameterPackSize elements. class ParameterPackExpansion final : public Node { const Node *Child; public: ParameterPackExpansion(const Node *Child_) : Node(KParameterPackExpansion), Child(Child_) {} template<typename Fn> void match(Fn F) const { F(Child); } const Node *getChild() const { return Child; } void printLeft(OutputStream &S) const override { constexpr unsigned Max = std::numeric_limits<unsigned>::max(); SwapAndRestore<unsigned> SavePackIdx(S.CurrentPackIndex, Max); SwapAndRestore<unsigned> SavePackMax(S.CurrentPackMax, Max); size_t StreamPos = S.getCurrentPosition(); // Print the first element in the pack. If Child contains a ParameterPack, // it will set up S.CurrentPackMax and print the first element. Child->print(S); // No ParameterPack was found in Child. This can occur if we've found a pack // expansion on a <function-param>. if (S.CurrentPackMax == Max) { S += "..."; return; } // We found a ParameterPack, but it has no elements. Erase whatever we may // of printed. if (S.CurrentPackMax == 0) { S.setCurrentPosition(StreamPos); return; } // Else, iterate through the rest of the elements in the pack. for (unsigned I = 1, E = S.CurrentPackMax; I < E; ++I) { S += ", "; S.CurrentPackIndex = I; Child->print(S); } } }; class TemplateArgs final : public Node { NodeArray Params; public: TemplateArgs(NodeArray Params_) : Node(KTemplateArgs), Params(Params_) {} template<typename Fn> void match(Fn F) const { F(Params); } NodeArray getParams() { return Params; } void printLeft(OutputStream &S) const override { S += "<"; Params.printWithComma(S); if (S.back() == '>') S += " "; S += ">"; } }; /// A forward-reference to a template argument that was not known at the point /// where the template parameter name was parsed in a mangling. /// /// This is created when demangling the name of a specialization of a /// conversion function template: /// /// \code /// struct A { /// template<typename T> operator T*(); /// }; /// \endcode /// /// When demangling a specialization of the conversion function template, we /// encounter the name of the template (including the \c T) before we reach /// the template argument list, so we cannot substitute the parameter name /// for the corresponding argument while parsing. Instead, we create a /// \c ForwardTemplateReference node that is resolved after we parse the /// template arguments. struct ForwardTemplateReference : Node { size_t Index; Node *Ref = nullptr; // If we're currently printing this node. It is possible (though invalid) for // a forward template reference to refer to itself via a substitution. This // creates a cyclic AST, which will stack overflow printing. To fix this, bail // out if more than one print* function is active. mutable bool Printing = false; ForwardTemplateReference(size_t Index_) : Node(KForwardTemplateReference, Cache::Unknown, Cache::Unknown, Cache::Unknown), Index(Index_) {} // We don't provide a matcher for these, because the value of the node is // not determined by its construction parameters, and it generally needs // special handling. template<typename Fn> void match(Fn F) const = delete; bool hasRHSComponentSlow(OutputStream &S) const override { if (Printing) return false; SwapAndRestore<bool> SavePrinting(Printing, true); return Ref->hasRHSComponent(S); } bool hasArraySlow(OutputStream &S) const override { if (Printing) return false; SwapAndRestore<bool> SavePrinting(Printing, true); return Ref->hasArray(S); } bool hasFunctionSlow(OutputStream &S) const override { if (Printing) return false; SwapAndRestore<bool> SavePrinting(Printing, true); return Ref->hasFunction(S); } const Node *getSyntaxNode(OutputStream &S) const override { if (Printing) return this; SwapAndRestore<bool> SavePrinting(Printing, true); return Ref->getSyntaxNode(S); } void printLeft(OutputStream &S) const override { if (Printing) return; SwapAndRestore<bool> SavePrinting(Printing, true); Ref->printLeft(S); } void printRight(OutputStream &S) const override { if (Printing) return; SwapAndRestore<bool> SavePrinting(Printing, true); Ref->printRight(S); } }; struct NameWithTemplateArgs : Node { // name<template_args> Node *Name; Node *TemplateArgs; NameWithTemplateArgs(Node *Name_, Node *TemplateArgs_) : Node(KNameWithTemplateArgs), Name(Name_), TemplateArgs(TemplateArgs_) {} template<typename Fn> void match(Fn F) const { F(Name, TemplateArgs); } StringView getBaseName() const override { return Name->getBaseName(); } void printLeft(OutputStream &S) const override { Name->print(S); TemplateArgs->print(S); } }; class GlobalQualifiedName final : public Node { Node *Child; public: GlobalQualifiedName(Node* Child_) : Node(KGlobalQualifiedName), Child(Child_) {} template<typename Fn> void match(Fn F) const { F(Child); } StringView getBaseName() const override { return Child->getBaseName(); } void printLeft(OutputStream &S) const override { S += "::"; Child->print(S); } }; struct StdQualifiedName : Node { Node *Child; StdQualifiedName(Node *Child_) : Node(KStdQualifiedName), Child(Child_) {} template<typename Fn> void match(Fn F) const { F(Child); } StringView getBaseName() const override { return Child->getBaseName(); } void printLeft(OutputStream &S) const override { S += "std::"; Child->print(S); } }; enum class SpecialSubKind { allocator, basic_string, string, istream, ostream, iostream, }; class ExpandedSpecialSubstitution final : public Node { SpecialSubKind SSK; public: ExpandedSpecialSubstitution(SpecialSubKind SSK_) : Node(KExpandedSpecialSubstitution), SSK(SSK_) {} template<typename Fn> void match(Fn F) const { F(SSK); } StringView getBaseName() const override { switch (SSK) { case SpecialSubKind::allocator: return StringView("allocator"); case SpecialSubKind::basic_string: return StringView("basic_string"); case SpecialSubKind::string: return StringView("basic_string"); case SpecialSubKind::istream: return StringView("basic_istream"); case SpecialSubKind::ostream: return StringView("basic_ostream"); case SpecialSubKind::iostream: return StringView("basic_iostream"); } LLVM_BUILTIN_UNREACHABLE; } void printLeft(OutputStream &S) const override { switch (SSK) { case SpecialSubKind::allocator: S += "std::allocator"; break; case SpecialSubKind::basic_string: S += "std::basic_string"; break; case SpecialSubKind::string: S += "std::basic_string<char, std::char_traits<char>, " "std::allocator<char> >"; break; case SpecialSubKind::istream: S += "std::basic_istream<char, std::char_traits<char> >"; break; case SpecialSubKind::ostream: S += "std::basic_ostream<char, std::char_traits<char> >"; break; case SpecialSubKind::iostream: S += "std::basic_iostream<char, std::char_traits<char> >"; break; } } }; class SpecialSubstitution final : public Node { public: SpecialSubKind SSK; SpecialSubstitution(SpecialSubKind SSK_) : Node(KSpecialSubstitution), SSK(SSK_) {} template<typename Fn> void match(Fn F) const { F(SSK); } StringView getBaseName() const override { switch (SSK) { case SpecialSubKind::allocator: return StringView("allocator"); case SpecialSubKind::basic_string: return StringView("basic_string"); case SpecialSubKind::string: return StringView("string"); case SpecialSubKind::istream: return StringView("istream"); case SpecialSubKind::ostream: return StringView("ostream"); case SpecialSubKind::iostream: return StringView("iostream"); } LLVM_BUILTIN_UNREACHABLE; } void printLeft(OutputStream &S) const override { switch (SSK) { case SpecialSubKind::allocator: S += "std::allocator"; break; case SpecialSubKind::basic_string: S += "std::basic_string"; break; case SpecialSubKind::string: S += "std::string"; break; case SpecialSubKind::istream: S += "std::istream"; break; case SpecialSubKind::ostream: S += "std::ostream"; break; case SpecialSubKind::iostream: S += "std::iostream"; break; } } }; class CtorDtorName final : public Node { const Node *Basename; const bool IsDtor; const int Variant; public: CtorDtorName(const Node *Basename_, bool IsDtor_, int Variant_) : Node(KCtorDtorName), Basename(Basename_), IsDtor(IsDtor_), Variant(Variant_) {} template<typename Fn> void match(Fn F) const { F(Basename, IsDtor, Variant); } void printLeft(OutputStream &S) const override { if (IsDtor) S += "~"; S += Basename->getBaseName(); } }; class DtorName : public Node { const Node *Base; public: DtorName(const Node *Base_) : Node(KDtorName), Base(Base_) {} template<typename Fn> void match(Fn F) const { F(Base); } void printLeft(OutputStream &S) const override { S += "~"; Base->printLeft(S); } }; class UnnamedTypeName : public Node { const StringView Count; public: UnnamedTypeName(StringView Count_) : Node(KUnnamedTypeName), Count(Count_) {} template<typename Fn> void match(Fn F) const { F(Count); } void printLeft(OutputStream &S) const override { S += "'unnamed"; S += Count; S += "\'"; } }; class ClosureTypeName : public Node { NodeArray Params; StringView Count; public: ClosureTypeName(NodeArray Params_, StringView Count_) : Node(KClosureTypeName), Params(Params_), Count(Count_) {} template<typename Fn> void match(Fn F) const { F(Params, Count); } void printLeft(OutputStream &S) const override { S += "\'lambda"; S += Count; S += "\'("; Params.printWithComma(S); S += ")"; } }; class StructuredBindingName : public Node { NodeArray Bindings; public: StructuredBindingName(NodeArray Bindings_) : Node(KStructuredBindingName), Bindings(Bindings_) {} template<typename Fn> void match(Fn F) const { F(Bindings); } void printLeft(OutputStream &S) const override { S += '['; Bindings.printWithComma(S); S += ']'; } }; // -- Expression Nodes -- class BinaryExpr : public Node { const Node *LHS; const StringView InfixOperator; const Node *RHS; public: BinaryExpr(const Node *LHS_, StringView InfixOperator_, const Node *RHS_) : Node(KBinaryExpr), LHS(LHS_), InfixOperator(InfixOperator_), RHS(RHS_) { } template<typename Fn> void match(Fn F) const { F(LHS, InfixOperator, RHS); } void printLeft(OutputStream &S) const override { // might be a template argument expression, then we need to disambiguate // with parens. if (InfixOperator == ">") S += "("; S += "("; LHS->print(S); S += ") "; S += InfixOperator; S += " ("; RHS->print(S); S += ")"; if (InfixOperator == ">") S += ")"; } }; class ArraySubscriptExpr : public Node { const Node *Op1; const Node *Op2; public: ArraySubscriptExpr(const Node *Op1_, const Node *Op2_) : Node(KArraySubscriptExpr), Op1(Op1_), Op2(Op2_) {} template<typename Fn> void match(Fn F) const { F(Op1, Op2); } void printLeft(OutputStream &S) const override { S += "("; Op1->print(S); S += ")["; Op2->print(S); S += "]"; } }; class PostfixExpr : public Node { const Node *Child; const StringView Operator; public: PostfixExpr(const Node *Child_, StringView Operator_) : Node(KPostfixExpr), Child(Child_), Operator(Operator_) {} template<typename Fn> void match(Fn F) const { F(Child, Operator); } void printLeft(OutputStream &S) const override { S += "("; Child->print(S); S += ")"; S += Operator; } }; class ConditionalExpr : public Node { const Node *Cond; const Node *Then; const Node *Else; public: ConditionalExpr(const Node *Cond_, const Node *Then_, const Node *Else_) : Node(KConditionalExpr), Cond(Cond_), Then(Then_), Else(Else_) {} template<typename Fn> void match(Fn F) const { F(Cond, Then, Else); } void printLeft(OutputStream &S) const override { S += "("; Cond->print(S); S += ") ? ("; Then->print(S); S += ") : ("; Else->print(S); S += ")"; } }; class MemberExpr : public Node { const Node *LHS; const StringView Kind; const Node *RHS; public: MemberExpr(const Node *LHS_, StringView Kind_, const Node *RHS_) : Node(KMemberExpr), LHS(LHS_), Kind(Kind_), RHS(RHS_) {} template<typename Fn> void match(Fn F) const { F(LHS, Kind, RHS); } void printLeft(OutputStream &S) const override { LHS->print(S); S += Kind; RHS->print(S); } }; class EnclosingExpr : public Node { const StringView Prefix; const Node *Infix; const StringView Postfix; public: EnclosingExpr(StringView Prefix_, Node *Infix_, StringView Postfix_) : Node(KEnclosingExpr), Prefix(Prefix_), Infix(Infix_), Postfix(Postfix_) {} template<typename Fn> void match(Fn F) const { F(Prefix, Infix, Postfix); } void printLeft(OutputStream &S) const override { S += Prefix; Infix->print(S); S += Postfix; } }; class CastExpr : public Node { // cast_kind<to>(from) const StringView CastKind; const Node *To; const Node *From; public: CastExpr(StringView CastKind_, const Node *To_, const Node *From_) : Node(KCastExpr), CastKind(CastKind_), To(To_), From(From_) {} template<typename Fn> void match(Fn F) const { F(CastKind, To, From); } void printLeft(OutputStream &S) const override { S += CastKind; S += "<"; To->printLeft(S); S += ">("; From->printLeft(S); S += ")"; } }; class SizeofParamPackExpr : public Node { const Node *Pack; public: SizeofParamPackExpr(const Node *Pack_) : Node(KSizeofParamPackExpr), Pack(Pack_) {} template<typename Fn> void match(Fn F) const { F(Pack); } void printLeft(OutputStream &S) const override { S += "sizeof...("; ParameterPackExpansion PPE(Pack); PPE.printLeft(S); S += ")"; } }; class CallExpr : public Node { const Node *Callee; NodeArray Args; public: CallExpr(const Node *Callee_, NodeArray Args_) : Node(KCallExpr), Callee(Callee_), Args(Args_) {} template<typename Fn> void match(Fn F) const { F(Callee, Args); } void printLeft(OutputStream &S) const override { Callee->print(S); S += "("; Args.printWithComma(S); S += ")"; } }; class NewExpr : public Node { // new (expr_list) type(init_list) NodeArray ExprList; Node *Type; NodeArray InitList; bool IsGlobal; // ::operator new ? bool IsArray; // new[] ? public: NewExpr(NodeArray ExprList_, Node *Type_, NodeArray InitList_, bool IsGlobal_, bool IsArray_) : Node(KNewExpr), ExprList(ExprList_), Type(Type_), InitList(InitList_), IsGlobal(IsGlobal_), IsArray(IsArray_) {} template<typename Fn> void match(Fn F) const { F(ExprList, Type, InitList, IsGlobal, IsArray); } void printLeft(OutputStream &S) const override { if (IsGlobal) S += "::operator "; S += "new"; if (IsArray) S += "[]"; S += ' '; if (!ExprList.empty()) { S += "("; ExprList.printWithComma(S); S += ")"; } Type->print(S); if (!InitList.empty()) { S += "("; InitList.printWithComma(S); S += ")"; } } }; class DeleteExpr : public Node { Node *Op; bool IsGlobal; bool IsArray; public: DeleteExpr(Node *Op_, bool IsGlobal_, bool IsArray_) : Node(KDeleteExpr), Op(Op_), IsGlobal(IsGlobal_), IsArray(IsArray_) {} template<typename Fn> void match(Fn F) const { F(Op, IsGlobal, IsArray); } void printLeft(OutputStream &S) const override { if (IsGlobal) S += "::"; S += "delete"; if (IsArray) S += "[] "; Op->print(S); } }; class PrefixExpr : public Node { StringView Prefix; Node *Child; public: PrefixExpr(StringView Prefix_, Node *Child_) : Node(KPrefixExpr), Prefix(Prefix_), Child(Child_) {} template<typename Fn> void match(Fn F) const { F(Prefix, Child); } void printLeft(OutputStream &S) const override { S += Prefix; S += "("; Child->print(S); S += ")"; } }; class FunctionParam : public Node { StringView Number; public: FunctionParam(StringView Number_) : Node(KFunctionParam), Number(Number_) {} template<typename Fn> void match(Fn F) const { F(Number); } void printLeft(OutputStream &S) const override { S += "fp"; S += Number; } }; class ConversionExpr : public Node { const Node *Type; NodeArray Expressions; public: ConversionExpr(const Node *Type_, NodeArray Expressions_) : Node(KConversionExpr), Type(Type_), Expressions(Expressions_) {} template<typename Fn> void match(Fn F) const { F(Type, Expressions); } void printLeft(OutputStream &S) const override { S += "("; Type->print(S); S += ")("; Expressions.printWithComma(S); S += ")"; } }; class InitListExpr : public Node { const Node *Ty; NodeArray Inits; public: InitListExpr(const Node *Ty_, NodeArray Inits_) : Node(KInitListExpr), Ty(Ty_), Inits(Inits_) {} template<typename Fn> void match(Fn F) const { F(Ty, Inits); } void printLeft(OutputStream &S) const override { if (Ty) Ty->print(S); S += '{'; Inits.printWithComma(S); S += '}'; } }; class BracedExpr : public Node { const Node *Elem; const Node *Init; bool IsArray; public: BracedExpr(const Node *Elem_, const Node *Init_, bool IsArray_) : Node(KBracedExpr), Elem(Elem_), Init(Init_), IsArray(IsArray_) {} template<typename Fn> void match(Fn F) const { F(Elem, Init, IsArray); } void printLeft(OutputStream &S) const override { if (IsArray) { S += '['; Elem->print(S); S += ']'; } else { S += '.'; Elem->print(S); } if (Init->getKind() != KBracedExpr && Init->getKind() != KBracedRangeExpr) S += " = "; Init->print(S); } }; class BracedRangeExpr : public Node { const Node *First; const Node *Last; const Node *Init; public: BracedRangeExpr(const Node *First_, const Node *Last_, const Node *Init_) : Node(KBracedRangeExpr), First(First_), Last(Last_), Init(Init_) {} template<typename Fn> void match(Fn F) const { F(First, Last, Init); } void printLeft(OutputStream &S) const override { S += '['; First->print(S); S += " ... "; Last->print(S); S += ']'; if (Init->getKind() != KBracedExpr && Init->getKind() != KBracedRangeExpr) S += " = "; Init->print(S); } }; class FoldExpr : public Node { const Node *Pack, *Init; StringView OperatorName; bool IsLeftFold; public: FoldExpr(bool IsLeftFold_, StringView OperatorName_, const Node *Pack_, const Node *Init_) : Node(KFoldExpr), Pack(Pack_), Init(Init_), OperatorName(OperatorName_), IsLeftFold(IsLeftFold_) {} template<typename Fn> void match(Fn F) const { F(IsLeftFold, OperatorName, Pack, Init); } void printLeft(OutputStream &S) const override { auto PrintPack = [&] { S += '('; ParameterPackExpansion(Pack).print(S); S += ')'; }; S += '('; if (IsLeftFold) { // init op ... op pack if (Init != nullptr) { Init->print(S); S += ' '; S += OperatorName; S += ' '; } // ... op pack S += "... "; S += OperatorName; S += ' '; PrintPack(); } else { // !IsLeftFold // pack op ... PrintPack(); S += ' '; S += OperatorName; S += " ..."; // pack op ... op init if (Init != nullptr) { S += ' '; S += OperatorName; S += ' '; Init->print(S); } } S += ')'; } }; class ThrowExpr : public Node { const Node *Op; public: ThrowExpr(const Node *Op_) : Node(KThrowExpr), Op(Op_) {} template<typename Fn> void match(Fn F) const { F(Op); } void printLeft(OutputStream &S) const override { S += "throw "; Op->print(S); } }; class BoolExpr : public Node { bool Value; public: BoolExpr(bool Value_) : Node(KBoolExpr), Value(Value_) {} template<typename Fn> void match(Fn F) const { F(Value); } void printLeft(OutputStream &S) const override { S += Value ? StringView("true") : StringView("false"); } }; class IntegerCastExpr : public Node { // ty(integer) const Node *Ty; StringView Integer; public: IntegerCastExpr(const Node *Ty_, StringView Integer_) : Node(KIntegerCastExpr), Ty(Ty_), Integer(Integer_) {} template<typename Fn> void match(Fn F) const { F(Ty, Integer); } void printLeft(OutputStream &S) const override { S += "("; Ty->print(S); S += ")"; S += Integer; } }; class IntegerLiteral : public Node { StringView Type; StringView Value; public: IntegerLiteral(StringView Type_, StringView Value_) : Node(KIntegerLiteral), Type(Type_), Value(Value_) {} template<typename Fn> void match(Fn F) const { F(Type, Value); } void printLeft(OutputStream &S) const override { if (Type.size() > 3) { S += "("; S += Type; S += ")"; } if (Value[0] == 'n') { S += "-"; S += Value.dropFront(1); } else S += Value; if (Type.size() <= 3) S += Type; } }; template <class Float> struct FloatData; namespace float_literal_impl { constexpr Node::Kind getFloatLiteralKind(float *) { return Node::KFloatLiteral; } constexpr Node::Kind getFloatLiteralKind(double *) { return Node::KDoubleLiteral; } constexpr Node::Kind getFloatLiteralKind(long double *) { return Node::KLongDoubleLiteral; } } template <class Float> class FloatLiteralImpl : public Node { const StringView Contents; static constexpr Kind KindForClass = float_literal_impl::getFloatLiteralKind((Float *)nullptr); public: FloatLiteralImpl(StringView Contents_) : Node(KindForClass), Contents(Contents_) {} template<typename Fn> void match(Fn F) const { F(Contents); } void printLeft(OutputStream &s) const override { const char *first = Contents.begin(); const char *last = Contents.end() + 1; const size_t N = FloatData<Float>::mangled_size; if (static_cast<std::size_t>(last - first) > N) { last = first + N; union { Float value; char buf[sizeof(Float)]; }; const char *t = first; char *e = buf; for (; t != last; ++t, ++e) { unsigned d1 = isdigit(*t) ? static_cast<unsigned>(*t - '0') : static_cast<unsigned>(*t - 'a' + 10); ++t; unsigned d0 = isdigit(*t) ? static_cast<unsigned>(*t - '0') : static_cast<unsigned>(*t - 'a' + 10); *e = static_cast<char>((d1 << 4) + d0); } #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ std::reverse(buf, e); #endif char num[FloatData<Float>::max_demangled_size] = {0}; int n = snprintf(num, sizeof(num), FloatData<Float>::spec, value); s += StringView(num, num + n); } } }; using FloatLiteral = FloatLiteralImpl<float>; using DoubleLiteral = FloatLiteralImpl<double>; using LongDoubleLiteral = FloatLiteralImpl<long double>; /// Visit the node. Calls \c F(P), where \c P is the node cast to the /// appropriate derived class. template<typename Fn> void Node::visit(Fn F) const { switch (K) { #define CASE(X) case K ## X: return F(static_cast<const X*>(this)); FOR_EACH_NODE_KIND(CASE) #undef CASE } assert(0 && "unknown mangling node kind"); } /// Determine the kind of a node from its type. template<typename NodeT> struct NodeKind; #define SPECIALIZATION(X) \ template<> struct NodeKind<X> { \ static constexpr Node::Kind Kind = Node::K##X; \ static constexpr const char *name() { return #X; } \ }; FOR_EACH_NODE_KIND(SPECIALIZATION) #undef SPECIALIZATION #undef FOR_EACH_NODE_KIND template <class T, size_t N> class PODSmallVector { static_assert(std::is_pod<T>::value, "T is required to be a plain old data type"); T* First; T* Last; T* Cap; T Inline[N]; bool isInline() const { return First == Inline; } void clearInline() { First = Inline; Last = Inline; Cap = Inline + N; } void reserve(size_t NewCap) { size_t S = size(); if (isInline()) { auto* Tmp = static_cast<T*>(std::malloc(NewCap * sizeof(T))); if (Tmp == nullptr) std::terminate(); std::copy(First, Last, Tmp); First = Tmp; } else { First = static_cast<T*>(std::realloc(First, NewCap * sizeof(T))); if (First == nullptr) std::terminate(); } Last = First + S; Cap = First + NewCap; } public: PODSmallVector() : First(Inline), Last(First), Cap(Inline + N) {} PODSmallVector(const PODSmallVector&) = delete; PODSmallVector& operator=(const PODSmallVector&) = delete; PODSmallVector(PODSmallVector&& Other) : PODSmallVector() { if (Other.isInline()) { std::copy(Other.begin(), Other.end(), First); Last = First + Other.size(); Other.clear(); return; } First = Other.First; Last = Other.Last; Cap = Other.Cap; Other.clearInline(); } PODSmallVector& operator=(PODSmallVector&& Other) { if (Other.isInline()) { if (!isInline()) { std::free(First); clearInline(); } std::copy(Other.begin(), Other.end(), First); Last = First + Other.size(); Other.clear(); return *this; } if (isInline()) { First = Other.First; Last = Other.Last; Cap = Other.Cap; Other.clearInline(); return *this; } std::swap(First, Other.First); std::swap(Last, Other.Last); std::swap(Cap, Other.Cap); Other.clear(); return *this; } void push_back(const T& Elem) { if (Last == Cap) reserve(size() * 2); *Last++ = Elem; } void pop_back() { assert(Last != First && "Popping empty vector!"); --Last; } void dropBack(size_t Index) { assert(Index <= size() && "dropBack() can't expand!"); Last = First + Index; } T* begin() { return First; } T* end() { return Last; } bool empty() const { return First == Last; } size_t size() const { return static_cast<size_t>(Last - First); } T& back() { assert(Last != First && "Calling back() on empty vector!"); return *(Last - 1); } T& operator[](size_t Index) { assert(Index < size() && "Invalid access!"); return *(begin() + Index); } void clear() { Last = First; } ~PODSmallVector() { if (!isInline()) std::free(First); } }; template <typename Derived, typename Alloc> struct AbstractManglingParser { const char *First; const char *Last; // Name stack, this is used by the parser to hold temporary names that were // parsed. The parser collapses multiple names into new nodes to construct // the AST. Once the parser is finished, names.size() == 1. PODSmallVector<Node *, 32> Names; // Substitution table. Itanium supports name substitutions as a means of // compression. The string "S42_" refers to the 44nd entry (base-36) in this // table. PODSmallVector<Node *, 32> Subs; // Template parameter table. Like the above, but referenced like "T42_". // This has a smaller size compared to Subs and Names because it can be // stored on the stack. PODSmallVector<Node *, 8> TemplateParams; // Set of unresolved forward <template-param> references. These can occur in a // conversion operator's type, and are resolved in the enclosing <encoding>. PODSmallVector<ForwardTemplateReference *, 4> ForwardTemplateRefs; bool TryToParseTemplateArgs = true; bool PermitForwardTemplateReferences = false; bool ParsingLambdaParams = false; Alloc ASTAllocator; AbstractManglingParser(const char *First_, const char *Last_) : First(First_), Last(Last_) {} Derived &getDerived() { return static_cast<Derived &>(*this); } void reset(const char *First_, const char *Last_) { First = First_; Last = Last_; Names.clear(); Subs.clear(); TemplateParams.clear(); ParsingLambdaParams = false; TryToParseTemplateArgs = true; PermitForwardTemplateReferences = false; ASTAllocator.reset(); } template <class T, class... Args> Node *make(Args &&... args) { return ASTAllocator.template makeNode<T>(std::forward<Args>(args)...); } template <class It> NodeArray makeNodeArray(It begin, It end) { size_t sz = static_cast<size_t>(end - begin); void *mem = ASTAllocator.allocateNodeArray(sz); Node **data = new (mem) Node *[sz]; std::copy(begin, end, data); return NodeArray(data, sz); } NodeArray popTrailingNodeArray(size_t FromPosition) { assert(FromPosition <= Names.size()); NodeArray res = makeNodeArray(Names.begin() + (long)FromPosition, Names.end()); Names.dropBack(FromPosition); return res; } bool consumeIf(StringView S) { if (StringView(First, Last).startsWith(S)) { First += S.size(); return true; } return false; } bool consumeIf(char C) { if (First != Last && *First == C) { ++First; return true; } return false; } char consume() { return First != Last ? *First++ : '\0'; } char look(unsigned Lookahead = 0) { if (static_cast<size_t>(Last - First) <= Lookahead) return '\0'; return First[Lookahead]; } size_t numLeft() const { return static_cast<size_t>(Last - First); } StringView parseNumber(bool AllowNegative = false); Qualifiers parseCVQualifiers(); bool parsePositiveInteger(size_t *Out); StringView parseBareSourceName(); bool parseSeqId(size_t *Out); Node *parseSubstitution(); Node *parseTemplateParam(); Node *parseTemplateArgs(bool TagTemplates = false); Node *parseTemplateArg(); /// Parse the <expr> production. Node *parseExpr(); Node *parsePrefixExpr(StringView Kind); Node *parseBinaryExpr(StringView Kind); Node *parseIntegerLiteral(StringView Lit); Node *parseExprPrimary(); template <class Float> Node *parseFloatingLiteral(); Node *parseFunctionParam(); Node *parseNewExpr(); Node *parseConversionExpr(); Node *parseBracedExpr(); Node *parseFoldExpr(); /// Parse the <type> production. Node *parseType(); Node *parseFunctionType(); Node *parseVectorType(); Node *parseDecltype(); Node *parseArrayType(); Node *parsePointerToMemberType(); Node *parseClassEnumType(); Node *parseQualifiedType(); Node *parseEncoding(); bool parseCallOffset(); Node *parseSpecialName(); /// Holds some extra information about a <name> that is being parsed. This /// information is only pertinent if the <name> refers to an <encoding>. struct NameState { bool CtorDtorConversion = false; bool EndsWithTemplateArgs = false; Qualifiers CVQualifiers = QualNone; FunctionRefQual ReferenceQualifier = FrefQualNone; size_t ForwardTemplateRefsBegin; NameState(AbstractManglingParser *Enclosing) : ForwardTemplateRefsBegin(Enclosing->ForwardTemplateRefs.size()) {} }; bool resolveForwardTemplateRefs(NameState &State) { size_t I = State.ForwardTemplateRefsBegin; size_t E = ForwardTemplateRefs.size(); for (; I < E; ++I) { size_t Idx = ForwardTemplateRefs[I]->Index; if (Idx >= TemplateParams.size()) return true; ForwardTemplateRefs[I]->Ref = TemplateParams[Idx]; } ForwardTemplateRefs.dropBack(State.ForwardTemplateRefsBegin); return false; } /// Parse the <name> production> Node *parseName(NameState *State = nullptr); Node *parseLocalName(NameState *State); Node *parseOperatorName(NameState *State); Node *parseUnqualifiedName(NameState *State); Node *parseUnnamedTypeName(NameState *State); Node *parseSourceName(NameState *State); Node *parseUnscopedName(NameState *State); Node *parseNestedName(NameState *State); Node *parseCtorDtorName(Node *&SoFar, NameState *State); Node *parseAbiTags(Node *N); /// Parse the <unresolved-name> production. Node *parseUnresolvedName(); Node *parseSimpleId(); Node *parseBaseUnresolvedName(); Node *parseUnresolvedType(); Node *parseDestructorName(); /// Top-level entry point into the parser. Node *parse(); }; const char* parse_discriminator(const char* first, const char* last); // <name> ::= <nested-name> // N // ::= <local-name> # See Scope Encoding below // Z // ::= <unscoped-template-name> <template-args> // ::= <unscoped-name> // // <unscoped-template-name> ::= <unscoped-name> // ::= <substitution> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseName(NameState *State) { consumeIf('L'); // extension if (look() == 'N') return getDerived().parseNestedName(State); if (look() == 'Z') return getDerived().parseLocalName(State); // ::= <unscoped-template-name> <template-args> if (look() == 'S' && look(1) != 't') { Node *S = getDerived().parseSubstitution(); if (S == nullptr) return nullptr; if (look() != 'I') return nullptr; Node *TA = getDerived().parseTemplateArgs(State != nullptr); if (TA == nullptr) return nullptr; if (State) State->EndsWithTemplateArgs = true; return make<NameWithTemplateArgs>(S, TA); } Node *N = getDerived().parseUnscopedName(State); if (N == nullptr) return nullptr; // ::= <unscoped-template-name> <template-args> if (look() == 'I') { Subs.push_back(N); Node *TA = getDerived().parseTemplateArgs(State != nullptr); if (TA == nullptr) return nullptr; if (State) State->EndsWithTemplateArgs = true; return make<NameWithTemplateArgs>(N, TA); } // ::= <unscoped-name> return N; } // <local-name> := Z <function encoding> E <entity name> [<discriminator>] // := Z <function encoding> E s [<discriminator>] // := Z <function encoding> Ed [ <parameter number> ] _ <entity name> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseLocalName(NameState *State) { if (!consumeIf('Z')) return nullptr; Node *Encoding = getDerived().parseEncoding(); if (Encoding == nullptr || !consumeIf('E')) return nullptr; if (consumeIf('s')) { First = parse_discriminator(First, Last); auto *StringLitName = make<NameType>("string literal"); if (!StringLitName) return nullptr; return make<LocalName>(Encoding, StringLitName); } if (consumeIf('d')) { parseNumber(true); if (!consumeIf('_')) return nullptr; Node *N = getDerived().parseName(State); if (N == nullptr) return nullptr; return make<LocalName>(Encoding, N); } Node *Entity = getDerived().parseName(State); if (Entity == nullptr) return nullptr; First = parse_discriminator(First, Last); return make<LocalName>(Encoding, Entity); } // <unscoped-name> ::= <unqualified-name> // ::= St <unqualified-name> # ::std:: // extension ::= StL<unqualified-name> template <typename Derived, typename Alloc> Node * AbstractManglingParser<Derived, Alloc>::parseUnscopedName(NameState *State) { if (consumeIf("StL") || consumeIf("St")) { Node *R = getDerived().parseUnqualifiedName(State); if (R == nullptr) return nullptr; return make<StdQualifiedName>(R); } return getDerived().parseUnqualifiedName(State); } // <unqualified-name> ::= <operator-name> [abi-tags] // ::= <ctor-dtor-name> // ::= <source-name> // ::= <unnamed-type-name> // ::= DC <source-name>+ E # structured binding declaration template <typename Derived, typename Alloc> Node * AbstractManglingParser<Derived, Alloc>::parseUnqualifiedName(NameState *State) { // <ctor-dtor-name>s are special-cased in parseNestedName(). Node *Result; if (look() == 'U') Result = getDerived().parseUnnamedTypeName(State); else if (look() >= '1' && look() <= '9') Result = getDerived().parseSourceName(State); else if (consumeIf("DC")) { size_t BindingsBegin = Names.size(); do { Node *Binding = getDerived().parseSourceName(State); if (Binding == nullptr) return nullptr; Names.push_back(Binding); } while (!consumeIf('E')); Result = make<StructuredBindingName>(popTrailingNodeArray(BindingsBegin)); } else Result = getDerived().parseOperatorName(State); if (Result != nullptr) Result = getDerived().parseAbiTags(Result); return Result; } // <unnamed-type-name> ::= Ut [<nonnegative number>] _ // ::= <closure-type-name> // // <closure-type-name> ::= Ul <lambda-sig> E [ <nonnegative number> ] _ // // <lambda-sig> ::= <parameter type>+ # Parameter types or "v" if the lambda has no parameters template <typename Derived, typename Alloc> Node * AbstractManglingParser<Derived, Alloc>::parseUnnamedTypeName(NameState *) { if (consumeIf("Ut")) { StringView Count = parseNumber(); if (!consumeIf('_')) return nullptr; return make<UnnamedTypeName>(Count); } if (consumeIf("Ul")) { NodeArray Params; SwapAndRestore<bool> SwapParams(ParsingLambdaParams, true); if (!consumeIf("vE")) { size_t ParamsBegin = Names.size(); do { Node *P = getDerived().parseType(); if (P == nullptr) return nullptr; Names.push_back(P); } while (!consumeIf('E')); Params = popTrailingNodeArray(ParamsBegin); } StringView Count = parseNumber(); if (!consumeIf('_')) return nullptr; return make<ClosureTypeName>(Params, Count); } return nullptr; } // <source-name> ::= <positive length number> <identifier> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseSourceName(NameState *) { size_t Length = 0; if (parsePositiveInteger(&Length)) return nullptr; if (numLeft() < Length || Length == 0) return nullptr; StringView Name(First, First + Length); First += Length; if (Name.startsWith("_GLOBAL__N")) return make<NameType>("(anonymous namespace)"); return make<NameType>(Name); } // <operator-name> ::= aa # && // ::= ad # & (unary) // ::= an # & // ::= aN # &= // ::= aS # = // ::= cl # () // ::= cm # , // ::= co # ~ // ::= cv <type> # (cast) // ::= da # delete[] // ::= de # * (unary) // ::= dl # delete // ::= dv # / // ::= dV # /= // ::= eo # ^ // ::= eO # ^= // ::= eq # == // ::= ge # >= // ::= gt # > // ::= ix # [] // ::= le # <= // ::= li <source-name> # operator "" // ::= ls # << // ::= lS # <<= // ::= lt # < // ::= mi # - // ::= mI # -= // ::= ml # * // ::= mL # *= // ::= mm # -- (postfix in <expression> context) // ::= na # new[] // ::= ne # != // ::= ng # - (unary) // ::= nt # ! // ::= nw # new // ::= oo # || // ::= or # | // ::= oR # |= // ::= pm # ->* // ::= pl # + // ::= pL # += // ::= pp # ++ (postfix in <expression> context) // ::= ps # + (unary) // ::= pt # -> // ::= qu # ? // ::= rm # % // ::= rM # %= // ::= rs # >> // ::= rS # >>= // ::= ss # <=> C++2a // ::= v <digit> <source-name> # vendor extended operator template <typename Derived, typename Alloc> Node * AbstractManglingParser<Derived, Alloc>::parseOperatorName(NameState *State) { switch (look()) { case 'a': switch (look(1)) { case 'a': First += 2; return make<NameType>("operator&&"); case 'd': case 'n': First += 2; return make<NameType>("operator&"); case 'N': First += 2; return make<NameType>("operator&="); case 'S': First += 2; return make<NameType>("operator="); } return nullptr; case 'c': switch (look(1)) { case 'l': First += 2; return make<NameType>("operator()"); case 'm': First += 2; return make<NameType>("operator,"); case 'o': First += 2; return make<NameType>("operator~"); // ::= cv <type> # (cast) case 'v': { First += 2; SwapAndRestore<bool> SaveTemplate(TryToParseTemplateArgs, false); // If we're parsing an encoding, State != nullptr and the conversion // operators' <type> could have a <template-param> that refers to some // <template-arg>s further ahead in the mangled name. SwapAndRestore<bool> SavePermit(PermitForwardTemplateReferences, PermitForwardTemplateReferences || State != nullptr); Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; if (State) State->CtorDtorConversion = true; return make<ConversionOperatorType>(Ty); } } return nullptr; case 'd': switch (look(1)) { case 'a': First += 2; return make<NameType>("operator delete[]"); case 'e': First += 2; return make<NameType>("operator*"); case 'l': First += 2; return make<NameType>("operator delete"); case 'v': First += 2; return make<NameType>("operator/"); case 'V': First += 2; return make<NameType>("operator/="); } return nullptr; case 'e': switch (look(1)) { case 'o': First += 2; return make<NameType>("operator^"); case 'O': First += 2; return make<NameType>("operator^="); case 'q': First += 2; return make<NameType>("operator=="); } return nullptr; case 'g': switch (look(1)) { case 'e': First += 2; return make<NameType>("operator>="); case 't': First += 2; return make<NameType>("operator>"); } return nullptr; case 'i': if (look(1) == 'x') { First += 2; return make<NameType>("operator[]"); } return nullptr; case 'l': switch (look(1)) { case 'e': First += 2; return make<NameType>("operator<="); // ::= li <source-name> # operator "" case 'i': { First += 2; Node *SN = getDerived().parseSourceName(State); if (SN == nullptr) return nullptr; return make<LiteralOperator>(SN); } case 's': First += 2; return make<NameType>("operator<<"); case 'S': First += 2; return make<NameType>("operator<<="); case 't': First += 2; return make<NameType>("operator<"); } return nullptr; case 'm': switch (look(1)) { case 'i': First += 2; return make<NameType>("operator-"); case 'I': First += 2; return make<NameType>("operator-="); case 'l': First += 2; return make<NameType>("operator*"); case 'L': First += 2; return make<NameType>("operator*="); case 'm': First += 2; return make<NameType>("operator--"); } return nullptr; case 'n': switch (look(1)) { case 'a': First += 2; return make<NameType>("operator new[]"); case 'e': First += 2; return make<NameType>("operator!="); case 'g': First += 2; return make<NameType>("operator-"); case 't': First += 2; return make<NameType>("operator!"); case 'w': First += 2; return make<NameType>("operator new"); } return nullptr; case 'o': switch (look(1)) { case 'o': First += 2; return make<NameType>("operator||"); case 'r': First += 2; return make<NameType>("operator|"); case 'R': First += 2; return make<NameType>("operator|="); } return nullptr; case 'p': switch (look(1)) { case 'm': First += 2; return make<NameType>("operator->*"); case 'l': First += 2; return make<NameType>("operator+"); case 'L': First += 2; return make<NameType>("operator+="); case 'p': First += 2; return make<NameType>("operator++"); case 's': First += 2; return make<NameType>("operator+"); case 't': First += 2; return make<NameType>("operator->"); } return nullptr; case 'q': if (look(1) == 'u') { First += 2; return make<NameType>("operator?"); } return nullptr; case 'r': switch (look(1)) { case 'm': First += 2; return make<NameType>("operator%"); case 'M': First += 2; return make<NameType>("operator%="); case 's': First += 2; return make<NameType>("operator>>"); case 'S': First += 2; return make<NameType>("operator>>="); } return nullptr; case 's': if (look(1) == 's') { First += 2; return make<NameType>("operator<=>"); } return nullptr; // ::= v <digit> <source-name> # vendor extended operator case 'v': if (std::isdigit(look(1))) { First += 2; Node *SN = getDerived().parseSourceName(State); if (SN == nullptr) return nullptr; return make<ConversionOperatorType>(SN); } return nullptr; } return nullptr; } // <ctor-dtor-name> ::= C1 # complete object constructor // ::= C2 # base object constructor // ::= C3 # complete object allocating constructor // extension ::= C5 # ? // ::= D0 # deleting destructor // ::= D1 # complete object destructor // ::= D2 # base object destructor // extension ::= D5 # ? template <typename Derived, typename Alloc> Node * AbstractManglingParser<Derived, Alloc>::parseCtorDtorName(Node *&SoFar, NameState *State) { if (SoFar->getKind() == Node::KSpecialSubstitution) { auto SSK = static_cast<SpecialSubstitution *>(SoFar)->SSK; switch (SSK) { case SpecialSubKind::string: case SpecialSubKind::istream: case SpecialSubKind::ostream: case SpecialSubKind::iostream: SoFar = make<ExpandedSpecialSubstitution>(SSK); if (!SoFar) return nullptr; break; default: break; } } if (consumeIf('C')) { bool IsInherited = consumeIf('I'); if (look() != '1' && look() != '2' && look() != '3' && look() != '5') return nullptr; int Variant = look() - '0'; ++First; if (State) State->CtorDtorConversion = true; if (IsInherited) { if (getDerived().parseName(State) == nullptr) return nullptr; } return make<CtorDtorName>(SoFar, false, Variant); } if (look() == 'D' && (look(1) == '0' || look(1) == '1' || look(1) == '2' || look(1) == '5')) { int Variant = look(1) - '0'; First += 2; if (State) State->CtorDtorConversion = true; return make<CtorDtorName>(SoFar, true, Variant); } return nullptr; } // <nested-name> ::= N [<CV-Qualifiers>] [<ref-qualifier>] <prefix> <unqualified-name> E // ::= N [<CV-Qualifiers>] [<ref-qualifier>] <template-prefix> <template-args> E // // <prefix> ::= <prefix> <unqualified-name> // ::= <template-prefix> <template-args> // ::= <template-param> // ::= <decltype> // ::= # empty // ::= <substitution> // ::= <prefix> <data-member-prefix> // extension ::= L // // <data-member-prefix> := <member source-name> [<template-args>] M // // <template-prefix> ::= <prefix> <template unqualified-name> // ::= <template-param> // ::= <substitution> template <typename Derived, typename Alloc> Node * AbstractManglingParser<Derived, Alloc>::parseNestedName(NameState *State) { if (!consumeIf('N')) return nullptr; Qualifiers CVTmp = parseCVQualifiers(); if (State) State->CVQualifiers = CVTmp; if (consumeIf('O')) { if (State) State->ReferenceQualifier = FrefQualRValue; } else if (consumeIf('R')) { if (State) State->ReferenceQualifier = FrefQualLValue; } else if (State) State->ReferenceQualifier = FrefQualNone; Node *SoFar = nullptr; auto PushComponent = [&](Node *Comp) { if (!Comp) return false; if (SoFar) SoFar = make<NestedName>(SoFar, Comp); else SoFar = Comp; if (State) State->EndsWithTemplateArgs = false; return SoFar != nullptr; }; if (consumeIf("St")) { SoFar = make<NameType>("std"); if (!SoFar) return nullptr; } while (!consumeIf('E')) { consumeIf('L'); // extension // <data-member-prefix> := <member source-name> [<template-args>] M if (consumeIf('M')) { if (SoFar == nullptr) return nullptr; continue; } // ::= <template-param> if (look() == 'T') { if (!PushComponent(getDerived().parseTemplateParam())) return nullptr; Subs.push_back(SoFar); continue; } // ::= <template-prefix> <template-args> if (look() == 'I') { Node *TA = getDerived().parseTemplateArgs(State != nullptr); if (TA == nullptr || SoFar == nullptr) return nullptr; SoFar = make<NameWithTemplateArgs>(SoFar, TA); if (!SoFar) return nullptr; if (State) State->EndsWithTemplateArgs = true; Subs.push_back(SoFar); continue; } // ::= <decltype> if (look() == 'D' && (look(1) == 't' || look(1) == 'T')) { if (!PushComponent(getDerived().parseDecltype())) return nullptr; Subs.push_back(SoFar); continue; } // ::= <substitution> if (look() == 'S' && look(1) != 't') { Node *S = getDerived().parseSubstitution(); if (!PushComponent(S)) return nullptr; if (SoFar != S) Subs.push_back(S); continue; } // Parse an <unqualified-name> thats actually a <ctor-dtor-name>. if (look() == 'C' || (look() == 'D' && look(1) != 'C')) { if (SoFar == nullptr) return nullptr; if (!PushComponent(getDerived().parseCtorDtorName(SoFar, State))) return nullptr; SoFar = getDerived().parseAbiTags(SoFar); if (SoFar == nullptr) return nullptr; Subs.push_back(SoFar); continue; } // ::= <prefix> <unqualified-name> if (!PushComponent(getDerived().parseUnqualifiedName(State))) return nullptr; Subs.push_back(SoFar); } if (SoFar == nullptr || Subs.empty()) return nullptr; Subs.pop_back(); return SoFar; } // <simple-id> ::= <source-name> [ <template-args> ] template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseSimpleId() { Node *SN = getDerived().parseSourceName(/*NameState=*/nullptr); if (SN == nullptr) return nullptr; if (look() == 'I') { Node *TA = getDerived().parseTemplateArgs(); if (TA == nullptr) return nullptr; return make<NameWithTemplateArgs>(SN, TA); } return SN; } // <destructor-name> ::= <unresolved-type> # e.g., ~T or ~decltype(f()) // ::= <simple-id> # e.g., ~A<2*N> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseDestructorName() { Node *Result; if (std::isdigit(look())) Result = getDerived().parseSimpleId(); else Result = getDerived().parseUnresolvedType(); if (Result == nullptr) return nullptr; return make<DtorName>(Result); } // <unresolved-type> ::= <template-param> // ::= <decltype> // ::= <substitution> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseUnresolvedType() { if (look() == 'T') { Node *TP = getDerived().parseTemplateParam(); if (TP == nullptr) return nullptr; Subs.push_back(TP); return TP; } if (look() == 'D') { Node *DT = getDerived().parseDecltype(); if (DT == nullptr) return nullptr; Subs.push_back(DT); return DT; } return getDerived().parseSubstitution(); } // <base-unresolved-name> ::= <simple-id> # unresolved name // extension ::= <operator-name> # unresolved operator-function-id // extension ::= <operator-name> <template-args> # unresolved operator template-id // ::= on <operator-name> # unresolved operator-function-id // ::= on <operator-name> <template-args> # unresolved operator template-id // ::= dn <destructor-name> # destructor or pseudo-destructor; // # e.g. ~X or ~X<N-1> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseBaseUnresolvedName() { if (std::isdigit(look())) return getDerived().parseSimpleId(); if (consumeIf("dn")) return getDerived().parseDestructorName(); consumeIf("on"); Node *Oper = getDerived().parseOperatorName(/*NameState=*/nullptr); if (Oper == nullptr) return nullptr; if (look() == 'I') { Node *TA = getDerived().parseTemplateArgs(); if (TA == nullptr) return nullptr; return make<NameWithTemplateArgs>(Oper, TA); } return Oper; } // <unresolved-name> // extension ::= srN <unresolved-type> [<template-args>] <unresolved-qualifier-level>* E <base-unresolved-name> // ::= [gs] <base-unresolved-name> # x or (with "gs") ::x // ::= [gs] sr <unresolved-qualifier-level>+ E <base-unresolved-name> // # A::x, N::y, A<T>::z; "gs" means leading "::" // ::= sr <unresolved-type> <base-unresolved-name> # T::x / decltype(p)::x // extension ::= sr <unresolved-type> <template-args> <base-unresolved-name> // # T::N::x /decltype(p)::N::x // (ignored) ::= srN <unresolved-type> <unresolved-qualifier-level>+ E <base-unresolved-name> // // <unresolved-qualifier-level> ::= <simple-id> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseUnresolvedName() { Node *SoFar = nullptr; // srN <unresolved-type> [<template-args>] <unresolved-qualifier-level>* E <base-unresolved-name> // srN <unresolved-type> <unresolved-qualifier-level>+ E <base-unresolved-name> if (consumeIf("srN")) { SoFar = getDerived().parseUnresolvedType(); if (SoFar == nullptr) return nullptr; if (look() == 'I') { Node *TA = getDerived().parseTemplateArgs(); if (TA == nullptr) return nullptr; SoFar = make<NameWithTemplateArgs>(SoFar, TA); if (!SoFar) return nullptr; } while (!consumeIf('E')) { Node *Qual = getDerived().parseSimpleId(); if (Qual == nullptr) return nullptr; SoFar = make<QualifiedName>(SoFar, Qual); if (!SoFar) return nullptr; } Node *Base = getDerived().parseBaseUnresolvedName(); if (Base == nullptr) return nullptr; return make<QualifiedName>(SoFar, Base); } bool Global = consumeIf("gs"); // [gs] <base-unresolved-name> # x or (with "gs") ::x if (!consumeIf("sr")) { SoFar = getDerived().parseBaseUnresolvedName(); if (SoFar == nullptr) return nullptr; if (Global) SoFar = make<GlobalQualifiedName>(SoFar); return SoFar; } // [gs] sr <unresolved-qualifier-level>+ E <base-unresolved-name> if (std::isdigit(look())) { do { Node *Qual = getDerived().parseSimpleId(); if (Qual == nullptr) return nullptr; if (SoFar) SoFar = make<QualifiedName>(SoFar, Qual); else if (Global) SoFar = make<GlobalQualifiedName>(Qual); else SoFar = Qual; if (!SoFar) return nullptr; } while (!consumeIf('E')); } // sr <unresolved-type> <base-unresolved-name> // sr <unresolved-type> <template-args> <base-unresolved-name> else { SoFar = getDerived().parseUnresolvedType(); if (SoFar == nullptr) return nullptr; if (look() == 'I') { Node *TA = getDerived().parseTemplateArgs(); if (TA == nullptr) return nullptr; SoFar = make<NameWithTemplateArgs>(SoFar, TA); if (!SoFar) return nullptr; } } assert(SoFar != nullptr); Node *Base = getDerived().parseBaseUnresolvedName(); if (Base == nullptr) return nullptr; return make<QualifiedName>(SoFar, Base); } // <abi-tags> ::= <abi-tag> [<abi-tags>] // <abi-tag> ::= B <source-name> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseAbiTags(Node *N) { while (consumeIf('B')) { StringView SN = parseBareSourceName(); if (SN.empty()) return nullptr; N = make<AbiTagAttr>(N, SN); if (!N) return nullptr; } return N; } // <number> ::= [n] <non-negative decimal integer> template <typename Alloc, typename Derived> StringView AbstractManglingParser<Alloc, Derived>::parseNumber(bool AllowNegative) { const char *Tmp = First; if (AllowNegative) consumeIf('n'); if (numLeft() == 0 || !std::isdigit(*First)) return StringView(); while (numLeft() != 0 && std::isdigit(*First)) ++First; return StringView(Tmp, First); } // <positive length number> ::= [0-9]* template <typename Alloc, typename Derived> bool AbstractManglingParser<Alloc, Derived>::parsePositiveInteger(size_t *Out) { *Out = 0; if (look() < '0' || look() > '9') return true; while (look() >= '0' && look() <= '9') { *Out *= 10; *Out += static_cast<size_t>(consume() - '0'); } return false; } template <typename Alloc, typename Derived> StringView AbstractManglingParser<Alloc, Derived>::parseBareSourceName() { size_t Int = 0; if (parsePositiveInteger(&Int) || numLeft() < Int) return StringView(); StringView R(First, First + Int); First += Int; return R; } // <function-type> ::= [<CV-qualifiers>] [<exception-spec>] [Dx] F [Y] <bare-function-type> [<ref-qualifier>] E // // <exception-spec> ::= Do # non-throwing exception-specification (e.g., noexcept, throw()) // ::= DO <expression> E # computed (instantiation-dependent) noexcept // ::= Dw <type>+ E # dynamic exception specification with instantiation-dependent types // // <ref-qualifier> ::= R # & ref-qualifier // <ref-qualifier> ::= O # && ref-qualifier template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseFunctionType() { Qualifiers CVQuals = parseCVQualifiers(); Node *ExceptionSpec = nullptr; if (consumeIf("Do")) { ExceptionSpec = make<NameType>("noexcept"); if (!ExceptionSpec) return nullptr; } else if (consumeIf("DO")) { Node *E = getDerived().parseExpr(); if (E == nullptr || !consumeIf('E')) return nullptr; ExceptionSpec = make<NoexceptSpec>(E); if (!ExceptionSpec) return nullptr; } else if (consumeIf("Dw")) { size_t SpecsBegin = Names.size(); while (!consumeIf('E')) { Node *T = getDerived().parseType(); if (T == nullptr) return nullptr; Names.push_back(T); } ExceptionSpec = make<DynamicExceptionSpec>(popTrailingNodeArray(SpecsBegin)); if (!ExceptionSpec) return nullptr; } consumeIf("Dx"); // transaction safe if (!consumeIf('F')) return nullptr; consumeIf('Y'); // extern "C" Node *ReturnType = getDerived().parseType(); if (ReturnType == nullptr) return nullptr; FunctionRefQual ReferenceQualifier = FrefQualNone; size_t ParamsBegin = Names.size(); while (true) { if (consumeIf('E')) break; if (consumeIf('v')) continue; if (consumeIf("RE")) { ReferenceQualifier = FrefQualLValue; break; } if (consumeIf("OE")) { ReferenceQualifier = FrefQualRValue; break; } Node *T = getDerived().parseType(); if (T == nullptr) return nullptr; Names.push_back(T); } NodeArray Params = popTrailingNodeArray(ParamsBegin); return make<FunctionType>(ReturnType, Params, CVQuals, ReferenceQualifier, ExceptionSpec); } // extension: // <vector-type> ::= Dv <positive dimension number> _ <extended element type> // ::= Dv [<dimension expression>] _ <element type> // <extended element type> ::= <element type> // ::= p # AltiVec vector pixel template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseVectorType() { if (!consumeIf("Dv")) return nullptr; if (look() >= '1' && look() <= '9') { StringView DimensionNumber = parseNumber(); if (!consumeIf('_')) return nullptr; if (consumeIf('p')) return make<PixelVectorType>(DimensionNumber); Node *ElemType = getDerived().parseType(); if (ElemType == nullptr) return nullptr; return make<VectorType>(ElemType, DimensionNumber); } if (!consumeIf('_')) { Node *DimExpr = getDerived().parseExpr(); if (!DimExpr) return nullptr; if (!consumeIf('_')) return nullptr; Node *ElemType = getDerived().parseType(); if (!ElemType) return nullptr; return make<VectorType>(ElemType, DimExpr); } Node *ElemType = getDerived().parseType(); if (!ElemType) return nullptr; return make<VectorType>(ElemType, StringView()); } // <decltype> ::= Dt <expression> E # decltype of an id-expression or class member access (C++0x) // ::= DT <expression> E # decltype of an expression (C++0x) template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseDecltype() { if (!consumeIf('D')) return nullptr; if (!consumeIf('t') && !consumeIf('T')) return nullptr; Node *E = getDerived().parseExpr(); if (E == nullptr) return nullptr; if (!consumeIf('E')) return nullptr; return make<EnclosingExpr>("decltype(", E, ")"); } // <array-type> ::= A <positive dimension number> _ <element type> // ::= A [<dimension expression>] _ <element type> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseArrayType() { if (!consumeIf('A')) return nullptr; NodeOrString Dimension; if (std::isdigit(look())) { Dimension = parseNumber(); if (!consumeIf('_')) return nullptr; } else if (!consumeIf('_')) { Node *DimExpr = getDerived().parseExpr(); if (DimExpr == nullptr) return nullptr; if (!consumeIf('_')) return nullptr; Dimension = DimExpr; } Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; return make<ArrayType>(Ty, Dimension); } // <pointer-to-member-type> ::= M <class type> <member type> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parsePointerToMemberType() { if (!consumeIf('M')) return nullptr; Node *ClassType = getDerived().parseType(); if (ClassType == nullptr) return nullptr; Node *MemberType = getDerived().parseType(); if (MemberType == nullptr) return nullptr; return make<PointerToMemberType>(ClassType, MemberType); } // <class-enum-type> ::= <name> # non-dependent type name, dependent type name, or dependent typename-specifier // ::= Ts <name> # dependent elaborated type specifier using 'struct' or 'class' // ::= Tu <name> # dependent elaborated type specifier using 'union' // ::= Te <name> # dependent elaborated type specifier using 'enum' template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseClassEnumType() { StringView ElabSpef; if (consumeIf("Ts")) ElabSpef = "struct"; else if (consumeIf("Tu")) ElabSpef = "union"; else if (consumeIf("Te")) ElabSpef = "enum"; Node *Name = getDerived().parseName(); if (Name == nullptr) return nullptr; if (!ElabSpef.empty()) return make<ElaboratedTypeSpefType>(ElabSpef, Name); return Name; } // <qualified-type> ::= <qualifiers> <type> // <qualifiers> ::= <extended-qualifier>* <CV-qualifiers> // <extended-qualifier> ::= U <source-name> [<template-args>] # vendor extended type qualifier template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseQualifiedType() { if (consumeIf('U')) { StringView Qual = parseBareSourceName(); if (Qual.empty()) return nullptr; // FIXME parse the optional <template-args> here! // extension ::= U <objc-name> <objc-type> # objc-type<identifier> if (Qual.startsWith("objcproto")) { StringView ProtoSourceName = Qual.dropFront(std::strlen("objcproto")); StringView Proto; { SwapAndRestore<const char *> SaveFirst(First, ProtoSourceName.begin()), SaveLast(Last, ProtoSourceName.end()); Proto = parseBareSourceName(); } if (Proto.empty()) return nullptr; Node *Child = getDerived().parseQualifiedType(); if (Child == nullptr) return nullptr; return make<ObjCProtoName>(Child, Proto); } Node *Child = getDerived().parseQualifiedType(); if (Child == nullptr) return nullptr; return make<VendorExtQualType>(Child, Qual); } Qualifiers Quals = parseCVQualifiers(); Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; if (Quals != QualNone) Ty = make<QualType>(Ty, Quals); return Ty; } // <type> ::= <builtin-type> // ::= <qualified-type> // ::= <function-type> // ::= <class-enum-type> // ::= <array-type> // ::= <pointer-to-member-type> // ::= <template-param> // ::= <template-template-param> <template-args> // ::= <decltype> // ::= P <type> # pointer // ::= R <type> # l-value reference // ::= O <type> # r-value reference (C++11) // ::= C <type> # complex pair (C99) // ::= G <type> # imaginary (C99) // ::= <substitution> # See Compression below // extension ::= U <objc-name> <objc-type> # objc-type<identifier> // extension ::= <vector-type> # <vector-type> starts with Dv // // <objc-name> ::= <k0 number> objcproto <k1 number> <identifier> # k0 = 9 + <number of digits in k1> + k1 // <objc-type> ::= <source-name> # PU<11+>objcproto 11objc_object<source-name> 11objc_object -> id<source-name> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseType() { Node *Result = nullptr; switch (look()) { // ::= <qualified-type> case 'r': case 'V': case 'K': { unsigned AfterQuals = 0; if (look(AfterQuals) == 'r') ++AfterQuals; if (look(AfterQuals) == 'V') ++AfterQuals; if (look(AfterQuals) == 'K') ++AfterQuals; if (look(AfterQuals) == 'F' || (look(AfterQuals) == 'D' && (look(AfterQuals + 1) == 'o' || look(AfterQuals + 1) == 'O' || look(AfterQuals + 1) == 'w' || look(AfterQuals + 1) == 'x'))) { Result = getDerived().parseFunctionType(); break; } LLVM_FALLTHROUGH; } case 'U': { Result = getDerived().parseQualifiedType(); break; } // <builtin-type> ::= v # void case 'v': ++First; return make<NameType>("void"); // ::= w # wchar_t case 'w': ++First; return make<NameType>("wchar_t"); // ::= b # bool case 'b': ++First; return make<NameType>("bool"); // ::= c # char case 'c': ++First; return make<NameType>("char"); // ::= a # signed char case 'a': ++First; return make<NameType>("signed char"); // ::= h # unsigned char case 'h': ++First; return make<NameType>("unsigned char"); // ::= s # short case 's': ++First; return make<NameType>("short"); // ::= t # unsigned short case 't': ++First; return make<NameType>("unsigned short"); // ::= i # int case 'i': ++First; return make<NameType>("int"); // ::= j # unsigned int case 'j': ++First; return make<NameType>("unsigned int"); // ::= l # long case 'l': ++First; return make<NameType>("long"); // ::= m # unsigned long case 'm': ++First; return make<NameType>("unsigned long"); // ::= x # long long, __int64 case 'x': ++First; return make<NameType>("long long"); // ::= y # unsigned long long, __int64 case 'y': ++First; return make<NameType>("unsigned long long"); // ::= n # __int128 case 'n': ++First; return make<NameType>("__int128"); // ::= o # unsigned __int128 case 'o': ++First; return make<NameType>("unsigned __int128"); // ::= f # float case 'f': ++First; return make<NameType>("float"); // ::= d # double case 'd': ++First; return make<NameType>("double"); // ::= e # long double, __float80 case 'e': ++First; return make<NameType>("long double"); // ::= g # __float128 case 'g': ++First; return make<NameType>("__float128"); // ::= z # ellipsis case 'z': ++First; return make<NameType>("..."); // <builtin-type> ::= u <source-name> # vendor extended type case 'u': { ++First; StringView Res = parseBareSourceName(); if (Res.empty()) return nullptr; return make<NameType>(Res); } case 'D': switch (look(1)) { // ::= Dd # IEEE 754r decimal floating point (64 bits) case 'd': First += 2; return make<NameType>("decimal64"); // ::= De # IEEE 754r decimal floating point (128 bits) case 'e': First += 2; return make<NameType>("decimal128"); // ::= Df # IEEE 754r decimal floating point (32 bits) case 'f': First += 2; return make<NameType>("decimal32"); // ::= Dh # IEEE 754r half-precision floating point (16 bits) case 'h': First += 2; return make<NameType>("decimal16"); // ::= Di # char32_t case 'i': First += 2; return make<NameType>("char32_t"); // ::= Ds # char16_t case 's': First += 2; return make<NameType>("char16_t"); // ::= Da # auto (in dependent new-expressions) case 'a': First += 2; return make<NameType>("auto"); // ::= Dc # decltype(auto) case 'c': First += 2; return make<NameType>("decltype(auto)"); // ::= Dn # std::nullptr_t (i.e., decltype(nullptr)) case 'n': First += 2; return make<NameType>("std::nullptr_t"); // ::= <decltype> case 't': case 'T': { Result = getDerived().parseDecltype(); break; } // extension ::= <vector-type> # <vector-type> starts with Dv case 'v': { Result = getDerived().parseVectorType(); break; } // ::= Dp <type> # pack expansion (C++0x) case 'p': { First += 2; Node *Child = getDerived().parseType(); if (!Child) return nullptr; Result = make<ParameterPackExpansion>(Child); break; } // Exception specifier on a function type. case 'o': case 'O': case 'w': // Transaction safe function type. case 'x': Result = getDerived().parseFunctionType(); break; } break; // ::= <function-type> case 'F': { Result = getDerived().parseFunctionType(); break; } // ::= <array-type> case 'A': { Result = getDerived().parseArrayType(); break; } // ::= <pointer-to-member-type> case 'M': { Result = getDerived().parsePointerToMemberType(); break; } // ::= <template-param> case 'T': { // This could be an elaborate type specifier on a <class-enum-type>. if (look(1) == 's' || look(1) == 'u' || look(1) == 'e') { Result = getDerived().parseClassEnumType(); break; } Result = getDerived().parseTemplateParam(); if (Result == nullptr) return nullptr; // Result could be either of: // <type> ::= <template-param> // <type> ::= <template-template-param> <template-args> // // <template-template-param> ::= <template-param> // ::= <substitution> // // If this is followed by some <template-args>, and we're permitted to // parse them, take the second production. if (TryToParseTemplateArgs && look() == 'I') { Node *TA = getDerived().parseTemplateArgs(); if (TA == nullptr) return nullptr; Result = make<NameWithTemplateArgs>(Result, TA); } break; } // ::= P <type> # pointer case 'P': { ++First; Node *Ptr = getDerived().parseType(); if (Ptr == nullptr) return nullptr; Result = make<PointerType>(Ptr); break; } // ::= R <type> # l-value reference case 'R': { ++First; Node *Ref = getDerived().parseType(); if (Ref == nullptr) return nullptr; Result = make<ReferenceType>(Ref, ReferenceKind::LValue); break; } // ::= O <type> # r-value reference (C++11) case 'O': { ++First; Node *Ref = getDerived().parseType(); if (Ref == nullptr) return nullptr; Result = make<ReferenceType>(Ref, ReferenceKind::RValue); break; } // ::= C <type> # complex pair (C99) case 'C': { ++First; Node *P = getDerived().parseType(); if (P == nullptr) return nullptr; Result = make<PostfixQualifiedType>(P, " complex"); break; } // ::= G <type> # imaginary (C99) case 'G': { ++First; Node *P = getDerived().parseType(); if (P == nullptr) return P; Result = make<PostfixQualifiedType>(P, " imaginary"); break; } // ::= <substitution> # See Compression below case 'S': { if (look(1) && look(1) != 't') { Node *Sub = getDerived().parseSubstitution(); if (Sub == nullptr) return nullptr; // Sub could be either of: // <type> ::= <substitution> // <type> ::= <template-template-param> <template-args> // // <template-template-param> ::= <template-param> // ::= <substitution> // // If this is followed by some <template-args>, and we're permitted to // parse them, take the second production. if (TryToParseTemplateArgs && look() == 'I') { Node *TA = getDerived().parseTemplateArgs(); if (TA == nullptr) return nullptr; Result = make<NameWithTemplateArgs>(Sub, TA); break; } // If all we parsed was a substitution, don't re-insert into the // substitution table. return Sub; } LLVM_FALLTHROUGH; } // ::= <class-enum-type> default: { Result = getDerived().parseClassEnumType(); break; } } // If we parsed a type, insert it into the substitution table. Note that all // <builtin-type>s and <substitution>s have already bailed out, because they // don't get substitutions. if (Result != nullptr) Subs.push_back(Result); return Result; } template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parsePrefixExpr(StringView Kind) { Node *E = getDerived().parseExpr(); if (E == nullptr) return nullptr; return make<PrefixExpr>(Kind, E); } template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseBinaryExpr(StringView Kind) { Node *LHS = getDerived().parseExpr(); if (LHS == nullptr) return nullptr; Node *RHS = getDerived().parseExpr(); if (RHS == nullptr) return nullptr; return make<BinaryExpr>(LHS, Kind, RHS); } template <typename Derived, typename Alloc> Node * AbstractManglingParser<Derived, Alloc>::parseIntegerLiteral(StringView Lit) { StringView Tmp = parseNumber(true); if (!Tmp.empty() && consumeIf('E')) return make<IntegerLiteral>(Lit, Tmp); return nullptr; } // <CV-Qualifiers> ::= [r] [V] [K] template <typename Alloc, typename Derived> Qualifiers AbstractManglingParser<Alloc, Derived>::parseCVQualifiers() { Qualifiers CVR = QualNone; if (consumeIf('r')) CVR |= QualRestrict; if (consumeIf('V')) CVR |= QualVolatile; if (consumeIf('K')) CVR |= QualConst; return CVR; } // <function-param> ::= fp <top-level CV-Qualifiers> _ # L == 0, first parameter // ::= fp <top-level CV-Qualifiers> <parameter-2 non-negative number> _ # L == 0, second and later parameters // ::= fL <L-1 non-negative number> p <top-level CV-Qualifiers> _ # L > 0, first parameter // ::= fL <L-1 non-negative number> p <top-level CV-Qualifiers> <parameter-2 non-negative number> _ # L > 0, second and later parameters template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseFunctionParam() { if (consumeIf("fp")) { parseCVQualifiers(); StringView Num = parseNumber(); if (!consumeIf('_')) return nullptr; return make<FunctionParam>(Num); } if (consumeIf("fL")) { if (parseNumber().empty()) return nullptr; if (!consumeIf('p')) return nullptr; parseCVQualifiers(); StringView Num = parseNumber(); if (!consumeIf('_')) return nullptr; return make<FunctionParam>(Num); } return nullptr; } // [gs] nw <expression>* _ <type> E # new (expr-list) type // [gs] nw <expression>* _ <type> <initializer> # new (expr-list) type (init) // [gs] na <expression>* _ <type> E # new[] (expr-list) type // [gs] na <expression>* _ <type> <initializer> # new[] (expr-list) type (init) // <initializer> ::= pi <expression>* E # parenthesized initialization template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseNewExpr() { bool Global = consumeIf("gs"); bool IsArray = look(1) == 'a'; if (!consumeIf("nw") && !consumeIf("na")) return nullptr; size_t Exprs = Names.size(); while (!consumeIf('_')) { Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return nullptr; Names.push_back(Ex); } NodeArray ExprList = popTrailingNodeArray(Exprs); Node *Ty = getDerived().parseType(); if (Ty == nullptr) return Ty; if (consumeIf("pi")) { size_t InitsBegin = Names.size(); while (!consumeIf('E')) { Node *Init = getDerived().parseExpr(); if (Init == nullptr) return Init; Names.push_back(Init); } NodeArray Inits = popTrailingNodeArray(InitsBegin); return make<NewExpr>(ExprList, Ty, Inits, Global, IsArray); } else if (!consumeIf('E')) return nullptr; return make<NewExpr>(ExprList, Ty, NodeArray(), Global, IsArray); } // cv <type> <expression> # conversion with one argument // cv <type> _ <expression>* E # conversion with a different number of arguments template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseConversionExpr() { if (!consumeIf("cv")) return nullptr; Node *Ty; { SwapAndRestore<bool> SaveTemp(TryToParseTemplateArgs, false); Ty = getDerived().parseType(); } if (Ty == nullptr) return nullptr; if (consumeIf('_')) { size_t ExprsBegin = Names.size(); while (!consumeIf('E')) { Node *E = getDerived().parseExpr(); if (E == nullptr) return E; Names.push_back(E); } NodeArray Exprs = popTrailingNodeArray(ExprsBegin); return make<ConversionExpr>(Ty, Exprs); } Node *E[1] = {getDerived().parseExpr()}; if (E[0] == nullptr) return nullptr; return make<ConversionExpr>(Ty, makeNodeArray(E, E + 1)); } // <expr-primary> ::= L <type> <value number> E # integer literal // ::= L <type> <value float> E # floating literal // ::= L <string type> E # string literal // ::= L <nullptr type> E # nullptr literal (i.e., "LDnE") // FIXME: ::= L <type> <real-part float> _ <imag-part float> E # complex floating point literal (C 2000) // ::= L <mangled-name> E # external name template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseExprPrimary() { if (!consumeIf('L')) return nullptr; switch (look()) { case 'w': ++First; return getDerived().parseIntegerLiteral("wchar_t"); case 'b': if (consumeIf("b0E")) return make<BoolExpr>(0); if (consumeIf("b1E")) return make<BoolExpr>(1); return nullptr; case 'c': ++First; return getDerived().parseIntegerLiteral("char"); case 'a': ++First; return getDerived().parseIntegerLiteral("signed char"); case 'h': ++First; return getDerived().parseIntegerLiteral("unsigned char"); case 's': ++First; return getDerived().parseIntegerLiteral("short"); case 't': ++First; return getDerived().parseIntegerLiteral("unsigned short"); case 'i': ++First; return getDerived().parseIntegerLiteral(""); case 'j': ++First; return getDerived().parseIntegerLiteral("u"); case 'l': ++First; return getDerived().parseIntegerLiteral("l"); case 'm': ++First; return getDerived().parseIntegerLiteral("ul"); case 'x': ++First; return getDerived().parseIntegerLiteral("ll"); case 'y': ++First; return getDerived().parseIntegerLiteral("ull"); case 'n': ++First; return getDerived().parseIntegerLiteral("__int128"); case 'o': ++First; return getDerived().parseIntegerLiteral("unsigned __int128"); case 'f': ++First; return getDerived().template parseFloatingLiteral<float>(); case 'd': ++First; return getDerived().template parseFloatingLiteral<double>(); case 'e': ++First; return getDerived().template parseFloatingLiteral<long double>(); case '_': if (consumeIf("_Z")) { Node *R = getDerived().parseEncoding(); if (R != nullptr && consumeIf('E')) return R; } return nullptr; case 'T': // Invalid mangled name per // http://sourcerytools.com/pipermail/cxx-abi-dev/2011-August/002422.html return nullptr; default: { // might be named type Node *T = getDerived().parseType(); if (T == nullptr) return nullptr; StringView N = parseNumber(); if (!N.empty()) { if (!consumeIf('E')) return nullptr; return make<IntegerCastExpr>(T, N); } if (consumeIf('E')) return T; return nullptr; } } } // <braced-expression> ::= <expression> // ::= di <field source-name> <braced-expression> # .name = expr // ::= dx <index expression> <braced-expression> # [expr] = expr // ::= dX <range begin expression> <range end expression> <braced-expression> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseBracedExpr() { if (look() == 'd') { switch (look(1)) { case 'i': { First += 2; Node *Field = getDerived().parseSourceName(/*NameState=*/nullptr); if (Field == nullptr) return nullptr; Node *Init = getDerived().parseBracedExpr(); if (Init == nullptr) return nullptr; return make<BracedExpr>(Field, Init, /*isArray=*/false); } case 'x': { First += 2; Node *Index = getDerived().parseExpr(); if (Index == nullptr) return nullptr; Node *Init = getDerived().parseBracedExpr(); if (Init == nullptr) return nullptr; return make<BracedExpr>(Index, Init, /*isArray=*/true); } case 'X': { First += 2; Node *RangeBegin = getDerived().parseExpr(); if (RangeBegin == nullptr) return nullptr; Node *RangeEnd = getDerived().parseExpr(); if (RangeEnd == nullptr) return nullptr; Node *Init = getDerived().parseBracedExpr(); if (Init == nullptr) return nullptr; return make<BracedRangeExpr>(RangeBegin, RangeEnd, Init); } } } return getDerived().parseExpr(); } // (not yet in the spec) // <fold-expr> ::= fL <binary-operator-name> <expression> <expression> // ::= fR <binary-operator-name> <expression> <expression> // ::= fl <binary-operator-name> <expression> // ::= fr <binary-operator-name> <expression> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseFoldExpr() { if (!consumeIf('f')) return nullptr; char FoldKind = look(); bool IsLeftFold, HasInitializer; HasInitializer = FoldKind == 'L' || FoldKind == 'R'; if (FoldKind == 'l' || FoldKind == 'L') IsLeftFold = true; else if (FoldKind == 'r' || FoldKind == 'R') IsLeftFold = false; else return nullptr; ++First; // FIXME: This map is duplicated in parseOperatorName and parseExpr. StringView OperatorName; if (consumeIf("aa")) OperatorName = "&&"; else if (consumeIf("an")) OperatorName = "&"; else if (consumeIf("aN")) OperatorName = "&="; else if (consumeIf("aS")) OperatorName = "="; else if (consumeIf("cm")) OperatorName = ","; else if (consumeIf("ds")) OperatorName = ".*"; else if (consumeIf("dv")) OperatorName = "/"; else if (consumeIf("dV")) OperatorName = "/="; else if (consumeIf("eo")) OperatorName = "^"; else if (consumeIf("eO")) OperatorName = "^="; else if (consumeIf("eq")) OperatorName = "=="; else if (consumeIf("ge")) OperatorName = ">="; else if (consumeIf("gt")) OperatorName = ">"; else if (consumeIf("le")) OperatorName = "<="; else if (consumeIf("ls")) OperatorName = "<<"; else if (consumeIf("lS")) OperatorName = "<<="; else if (consumeIf("lt")) OperatorName = "<"; else if (consumeIf("mi")) OperatorName = "-"; else if (consumeIf("mI")) OperatorName = "-="; else if (consumeIf("ml")) OperatorName = "*"; else if (consumeIf("mL")) OperatorName = "*="; else if (consumeIf("ne")) OperatorName = "!="; else if (consumeIf("oo")) OperatorName = "||"; else if (consumeIf("or")) OperatorName = "|"; else if (consumeIf("oR")) OperatorName = "|="; else if (consumeIf("pl")) OperatorName = "+"; else if (consumeIf("pL")) OperatorName = "+="; else if (consumeIf("rm")) OperatorName = "%"; else if (consumeIf("rM")) OperatorName = "%="; else if (consumeIf("rs")) OperatorName = ">>"; else if (consumeIf("rS")) OperatorName = ">>="; else return nullptr; Node *Pack = getDerived().parseExpr(), *Init = nullptr; if (Pack == nullptr) return nullptr; if (HasInitializer) { Init = getDerived().parseExpr(); if (Init == nullptr) return nullptr; } if (IsLeftFold && Init) std::swap(Pack, Init); return make<FoldExpr>(IsLeftFold, OperatorName, Pack, Init); } // <expression> ::= <unary operator-name> <expression> // ::= <binary operator-name> <expression> <expression> // ::= <ternary operator-name> <expression> <expression> <expression> // ::= cl <expression>+ E # call // ::= cv <type> <expression> # conversion with one argument // ::= cv <type> _ <expression>* E # conversion with a different number of arguments // ::= [gs] nw <expression>* _ <type> E # new (expr-list) type // ::= [gs] nw <expression>* _ <type> <initializer> # new (expr-list) type (init) // ::= [gs] na <expression>* _ <type> E # new[] (expr-list) type // ::= [gs] na <expression>* _ <type> <initializer> # new[] (expr-list) type (init) // ::= [gs] dl <expression> # delete expression // ::= [gs] da <expression> # delete[] expression // ::= pp_ <expression> # prefix ++ // ::= mm_ <expression> # prefix -- // ::= ti <type> # typeid (type) // ::= te <expression> # typeid (expression) // ::= dc <type> <expression> # dynamic_cast<type> (expression) // ::= sc <type> <expression> # static_cast<type> (expression) // ::= cc <type> <expression> # const_cast<type> (expression) // ::= rc <type> <expression> # reinterpret_cast<type> (expression) // ::= st <type> # sizeof (a type) // ::= sz <expression> # sizeof (an expression) // ::= at <type> # alignof (a type) // ::= az <expression> # alignof (an expression) // ::= nx <expression> # noexcept (expression) // ::= <template-param> // ::= <function-param> // ::= dt <expression> <unresolved-name> # expr.name // ::= pt <expression> <unresolved-name> # expr->name // ::= ds <expression> <expression> # expr.*expr // ::= sZ <template-param> # size of a parameter pack // ::= sZ <function-param> # size of a function parameter pack // ::= sP <template-arg>* E # sizeof...(T), size of a captured template parameter pack from an alias template // ::= sp <expression> # pack expansion // ::= tw <expression> # throw expression // ::= tr # throw with no operand (rethrow) // ::= <unresolved-name> # f(p), N::f(p), ::f(p), // # freestanding dependent name (e.g., T::x), // # objectless nonstatic member reference // ::= fL <binary-operator-name> <expression> <expression> // ::= fR <binary-operator-name> <expression> <expression> // ::= fl <binary-operator-name> <expression> // ::= fr <binary-operator-name> <expression> // ::= <expr-primary> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseExpr() { bool Global = consumeIf("gs"); if (numLeft() < 2) return nullptr; switch (*First) { case 'L': return getDerived().parseExprPrimary(); case 'T': return getDerived().parseTemplateParam(); case 'f': { // Disambiguate a fold expression from a <function-param>. if (look(1) == 'p' || (look(1) == 'L' && std::isdigit(look(2)))) return getDerived().parseFunctionParam(); return getDerived().parseFoldExpr(); } case 'a': switch (First[1]) { case 'a': First += 2; return getDerived().parseBinaryExpr("&&"); case 'd': First += 2; return getDerived().parsePrefixExpr("&"); case 'n': First += 2; return getDerived().parseBinaryExpr("&"); case 'N': First += 2; return getDerived().parseBinaryExpr("&="); case 'S': First += 2; return getDerived().parseBinaryExpr("="); case 't': { First += 2; Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; return make<EnclosingExpr>("alignof (", Ty, ")"); } case 'z': { First += 2; Node *Ty = getDerived().parseExpr(); if (Ty == nullptr) return nullptr; return make<EnclosingExpr>("alignof (", Ty, ")"); } } return nullptr; case 'c': switch (First[1]) { // cc <type> <expression> # const_cast<type>(expression) case 'c': { First += 2; Node *Ty = getDerived().parseType(); if (Ty == nullptr) return Ty; Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return Ex; return make<CastExpr>("const_cast", Ty, Ex); } // cl <expression>+ E # call case 'l': { First += 2; Node *Callee = getDerived().parseExpr(); if (Callee == nullptr) return Callee; size_t ExprsBegin = Names.size(); while (!consumeIf('E')) { Node *E = getDerived().parseExpr(); if (E == nullptr) return E; Names.push_back(E); } return make<CallExpr>(Callee, popTrailingNodeArray(ExprsBegin)); } case 'm': First += 2; return getDerived().parseBinaryExpr(","); case 'o': First += 2; return getDerived().parsePrefixExpr("~"); case 'v': return getDerived().parseConversionExpr(); } return nullptr; case 'd': switch (First[1]) { case 'a': { First += 2; Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return Ex; return make<DeleteExpr>(Ex, Global, /*is_array=*/true); } case 'c': { First += 2; Node *T = getDerived().parseType(); if (T == nullptr) return T; Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return Ex; return make<CastExpr>("dynamic_cast", T, Ex); } case 'e': First += 2; return getDerived().parsePrefixExpr("*"); case 'l': { First += 2; Node *E = getDerived().parseExpr(); if (E == nullptr) return E; return make<DeleteExpr>(E, Global, /*is_array=*/false); } case 'n': return getDerived().parseUnresolvedName(); case 's': { First += 2; Node *LHS = getDerived().parseExpr(); if (LHS == nullptr) return nullptr; Node *RHS = getDerived().parseExpr(); if (RHS == nullptr) return nullptr; return make<MemberExpr>(LHS, ".*", RHS); } case 't': { First += 2; Node *LHS = getDerived().parseExpr(); if (LHS == nullptr) return LHS; Node *RHS = getDerived().parseExpr(); if (RHS == nullptr) return nullptr; return make<MemberExpr>(LHS, ".", RHS); } case 'v': First += 2; return getDerived().parseBinaryExpr("/"); case 'V': First += 2; return getDerived().parseBinaryExpr("/="); } return nullptr; case 'e': switch (First[1]) { case 'o': First += 2; return getDerived().parseBinaryExpr("^"); case 'O': First += 2; return getDerived().parseBinaryExpr("^="); case 'q': First += 2; return getDerived().parseBinaryExpr("=="); } return nullptr; case 'g': switch (First[1]) { case 'e': First += 2; return getDerived().parseBinaryExpr(">="); case 't': First += 2; return getDerived().parseBinaryExpr(">"); } return nullptr; case 'i': switch (First[1]) { case 'x': { First += 2; Node *Base = getDerived().parseExpr(); if (Base == nullptr) return nullptr; Node *Index = getDerived().parseExpr(); if (Index == nullptr) return Index; return make<ArraySubscriptExpr>(Base, Index); } case 'l': { First += 2; size_t InitsBegin = Names.size(); while (!consumeIf('E')) { Node *E = getDerived().parseBracedExpr(); if (E == nullptr) return nullptr; Names.push_back(E); } return make<InitListExpr>(nullptr, popTrailingNodeArray(InitsBegin)); } } return nullptr; case 'l': switch (First[1]) { case 'e': First += 2; return getDerived().parseBinaryExpr("<="); case 's': First += 2; return getDerived().parseBinaryExpr("<<"); case 'S': First += 2; return getDerived().parseBinaryExpr("<<="); case 't': First += 2; return getDerived().parseBinaryExpr("<"); } return nullptr; case 'm': switch (First[1]) { case 'i': First += 2; return getDerived().parseBinaryExpr("-"); case 'I': First += 2; return getDerived().parseBinaryExpr("-="); case 'l': First += 2; return getDerived().parseBinaryExpr("*"); case 'L': First += 2; return getDerived().parseBinaryExpr("*="); case 'm': First += 2; if (consumeIf('_')) return getDerived().parsePrefixExpr("--"); Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return nullptr; return make<PostfixExpr>(Ex, "--"); } return nullptr; case 'n': switch (First[1]) { case 'a': case 'w': return getDerived().parseNewExpr(); case 'e': First += 2; return getDerived().parseBinaryExpr("!="); case 'g': First += 2; return getDerived().parsePrefixExpr("-"); case 't': First += 2; return getDerived().parsePrefixExpr("!"); case 'x': First += 2; Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return Ex; return make<EnclosingExpr>("noexcept (", Ex, ")"); } return nullptr; case 'o': switch (First[1]) { case 'n': return getDerived().parseUnresolvedName(); case 'o': First += 2; return getDerived().parseBinaryExpr("||"); case 'r': First += 2; return getDerived().parseBinaryExpr("|"); case 'R': First += 2; return getDerived().parseBinaryExpr("|="); } return nullptr; case 'p': switch (First[1]) { case 'm': First += 2; return getDerived().parseBinaryExpr("->*"); case 'l': First += 2; return getDerived().parseBinaryExpr("+"); case 'L': First += 2; return getDerived().parseBinaryExpr("+="); case 'p': { First += 2; if (consumeIf('_')) return getDerived().parsePrefixExpr("++"); Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return Ex; return make<PostfixExpr>(Ex, "++"); } case 's': First += 2; return getDerived().parsePrefixExpr("+"); case 't': { First += 2; Node *L = getDerived().parseExpr(); if (L == nullptr) return nullptr; Node *R = getDerived().parseExpr(); if (R == nullptr) return nullptr; return make<MemberExpr>(L, "->", R); } } return nullptr; case 'q': if (First[1] == 'u') { First += 2; Node *Cond = getDerived().parseExpr(); if (Cond == nullptr) return nullptr; Node *LHS = getDerived().parseExpr(); if (LHS == nullptr) return nullptr; Node *RHS = getDerived().parseExpr(); if (RHS == nullptr) return nullptr; return make<ConditionalExpr>(Cond, LHS, RHS); } return nullptr; case 'r': switch (First[1]) { case 'c': { First += 2; Node *T = getDerived().parseType(); if (T == nullptr) return T; Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return Ex; return make<CastExpr>("reinterpret_cast", T, Ex); } case 'm': First += 2; return getDerived().parseBinaryExpr("%"); case 'M': First += 2; return getDerived().parseBinaryExpr("%="); case 's': First += 2; return getDerived().parseBinaryExpr(">>"); case 'S': First += 2; return getDerived().parseBinaryExpr(">>="); } return nullptr; case 's': switch (First[1]) { case 'c': { First += 2; Node *T = getDerived().parseType(); if (T == nullptr) return T; Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return Ex; return make<CastExpr>("static_cast", T, Ex); } case 'p': { First += 2; Node *Child = getDerived().parseExpr(); if (Child == nullptr) return nullptr; return make<ParameterPackExpansion>(Child); } case 'r': return getDerived().parseUnresolvedName(); case 't': { First += 2; Node *Ty = getDerived().parseType(); if (Ty == nullptr) return Ty; return make<EnclosingExpr>("sizeof (", Ty, ")"); } case 'z': { First += 2; Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return Ex; return make<EnclosingExpr>("sizeof (", Ex, ")"); } case 'Z': First += 2; if (look() == 'T') { Node *R = getDerived().parseTemplateParam(); if (R == nullptr) return nullptr; return make<SizeofParamPackExpr>(R); } else if (look() == 'f') { Node *FP = getDerived().parseFunctionParam(); if (FP == nullptr) return nullptr; return make<EnclosingExpr>("sizeof... (", FP, ")"); } return nullptr; case 'P': { First += 2; size_t ArgsBegin = Names.size(); while (!consumeIf('E')) { Node *Arg = getDerived().parseTemplateArg(); if (Arg == nullptr) return nullptr; Names.push_back(Arg); } auto *Pack = make<NodeArrayNode>(popTrailingNodeArray(ArgsBegin)); if (!Pack) return nullptr; return make<EnclosingExpr>("sizeof... (", Pack, ")"); } } return nullptr; case 't': switch (First[1]) { case 'e': { First += 2; Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return Ex; return make<EnclosingExpr>("typeid (", Ex, ")"); } case 'i': { First += 2; Node *Ty = getDerived().parseType(); if (Ty == nullptr) return Ty; return make<EnclosingExpr>("typeid (", Ty, ")"); } case 'l': { First += 2; Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; size_t InitsBegin = Names.size(); while (!consumeIf('E')) { Node *E = getDerived().parseBracedExpr(); if (E == nullptr) return nullptr; Names.push_back(E); } return make<InitListExpr>(Ty, popTrailingNodeArray(InitsBegin)); } case 'r': First += 2; return make<NameType>("throw"); case 'w': { First += 2; Node *Ex = getDerived().parseExpr(); if (Ex == nullptr) return nullptr; return make<ThrowExpr>(Ex); } } return nullptr; case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': return getDerived().parseUnresolvedName(); } return nullptr; } // <call-offset> ::= h <nv-offset> _ // ::= v <v-offset> _ // // <nv-offset> ::= <offset number> // # non-virtual base override // // <v-offset> ::= <offset number> _ <virtual offset number> // # virtual base override, with vcall offset template <typename Alloc, typename Derived> bool AbstractManglingParser<Alloc, Derived>::parseCallOffset() { // Just scan through the call offset, we never add this information into the // output. if (consumeIf('h')) return parseNumber(true).empty() || !consumeIf('_'); if (consumeIf('v')) return parseNumber(true).empty() || !consumeIf('_') || parseNumber(true).empty() || !consumeIf('_'); return true; } // <special-name> ::= TV <type> # virtual table // ::= TT <type> # VTT structure (construction vtable index) // ::= TI <type> # typeinfo structure // ::= TS <type> # typeinfo name (null-terminated byte string) // ::= Tc <call-offset> <call-offset> <base encoding> // # base is the nominal target function of thunk // # first call-offset is 'this' adjustment // # second call-offset is result adjustment // ::= T <call-offset> <base encoding> // # base is the nominal target function of thunk // ::= GV <object name> # Guard variable for one-time initialization // # No <type> // ::= TW <object name> # Thread-local wrapper // ::= TH <object name> # Thread-local initialization // ::= GR <object name> _ # First temporary // ::= GR <object name> <seq-id> _ # Subsequent temporaries // extension ::= TC <first type> <number> _ <second type> # construction vtable for second-in-first // extension ::= GR <object name> # reference temporary for object template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseSpecialName() { switch (look()) { case 'T': switch (look(1)) { // TV <type> # virtual table case 'V': { First += 2; Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; return make<SpecialName>("vtable for ", Ty); } // TT <type> # VTT structure (construction vtable index) case 'T': { First += 2; Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; return make<SpecialName>("VTT for ", Ty); } // TI <type> # typeinfo structure case 'I': { First += 2; Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; return make<SpecialName>("typeinfo for ", Ty); } // TS <type> # typeinfo name (null-terminated byte string) case 'S': { First += 2; Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; return make<SpecialName>("typeinfo name for ", Ty); } // Tc <call-offset> <call-offset> <base encoding> case 'c': { First += 2; if (parseCallOffset() || parseCallOffset()) return nullptr; Node *Encoding = getDerived().parseEncoding(); if (Encoding == nullptr) return nullptr; return make<SpecialName>("covariant return thunk to ", Encoding); } // extension ::= TC <first type> <number> _ <second type> // # construction vtable for second-in-first case 'C': { First += 2; Node *FirstType = getDerived().parseType(); if (FirstType == nullptr) return nullptr; if (parseNumber(true).empty() || !consumeIf('_')) return nullptr; Node *SecondType = getDerived().parseType(); if (SecondType == nullptr) return nullptr; return make<CtorVtableSpecialName>(SecondType, FirstType); } // TW <object name> # Thread-local wrapper case 'W': { First += 2; Node *Name = getDerived().parseName(); if (Name == nullptr) return nullptr; return make<SpecialName>("thread-local wrapper routine for ", Name); } // TH <object name> # Thread-local initialization case 'H': { First += 2; Node *Name = getDerived().parseName(); if (Name == nullptr) return nullptr; return make<SpecialName>("thread-local initialization routine for ", Name); } // T <call-offset> <base encoding> default: { ++First; bool IsVirt = look() == 'v'; if (parseCallOffset()) return nullptr; Node *BaseEncoding = getDerived().parseEncoding(); if (BaseEncoding == nullptr) return nullptr; if (IsVirt) return make<SpecialName>("virtual thunk to ", BaseEncoding); else return make<SpecialName>("non-virtual thunk to ", BaseEncoding); } } case 'G': switch (look(1)) { // GV <object name> # Guard variable for one-time initialization case 'V': { First += 2; Node *Name = getDerived().parseName(); if (Name == nullptr) return nullptr; return make<SpecialName>("guard variable for ", Name); } // GR <object name> # reference temporary for object // GR <object name> _ # First temporary // GR <object name> <seq-id> _ # Subsequent temporaries case 'R': { First += 2; Node *Name = getDerived().parseName(); if (Name == nullptr) return nullptr; size_t Count; bool ParsedSeqId = !parseSeqId(&Count); if (!consumeIf('_') && ParsedSeqId) return nullptr; return make<SpecialName>("reference temporary for ", Name); } } } return nullptr; } // <encoding> ::= <function name> <bare-function-type> // ::= <data name> // ::= <special-name> template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseEncoding() { if (look() == 'G' || look() == 'T') return getDerived().parseSpecialName(); auto IsEndOfEncoding = [&] { // The set of chars that can potentially follow an <encoding> (none of which // can start a <type>). Enumerating these allows us to avoid speculative // parsing. return numLeft() == 0 || look() == 'E' || look() == '.' || look() == '_'; }; NameState NameInfo(this); Node *Name = getDerived().parseName(&NameInfo); if (Name == nullptr) return nullptr; if (resolveForwardTemplateRefs(NameInfo)) return nullptr; if (IsEndOfEncoding()) return Name; Node *Attrs = nullptr; if (consumeIf("Ua9enable_ifI")) { size_t BeforeArgs = Names.size(); while (!consumeIf('E')) { Node *Arg = getDerived().parseTemplateArg(); if (Arg == nullptr) return nullptr; Names.push_back(Arg); } Attrs = make<EnableIfAttr>(popTrailingNodeArray(BeforeArgs)); if (!Attrs) return nullptr; } Node *ReturnType = nullptr; if (!NameInfo.CtorDtorConversion && NameInfo.EndsWithTemplateArgs) { ReturnType = getDerived().parseType(); if (ReturnType == nullptr) return nullptr; } if (consumeIf('v')) return make<FunctionEncoding>(ReturnType, Name, NodeArray(), Attrs, NameInfo.CVQualifiers, NameInfo.ReferenceQualifier); size_t ParamsBegin = Names.size(); do { Node *Ty = getDerived().parseType(); if (Ty == nullptr) return nullptr; Names.push_back(Ty); } while (!IsEndOfEncoding()); return make<FunctionEncoding>(ReturnType, Name, popTrailingNodeArray(ParamsBegin), Attrs, NameInfo.CVQualifiers, NameInfo.ReferenceQualifier); } template <class Float> struct FloatData; template <> struct FloatData<float> { static const size_t mangled_size = 8; static const size_t max_demangled_size = 24; static constexpr const char* spec = "%af"; }; template <> struct FloatData<double> { static const size_t mangled_size = 16; static const size_t max_demangled_size = 32; static constexpr const char* spec = "%a"; }; template <> struct FloatData<long double> { #if defined(__mips__) && defined(__mips_n64) || defined(__aarch64__) || \ defined(__wasm__) static const size_t mangled_size = 32; #elif defined(__arm__) || defined(__mips__) || defined(__hexagon__) static const size_t mangled_size = 16; #else static const size_t mangled_size = 20; // May need to be adjusted to 16 or 24 on other platforms #endif static const size_t max_demangled_size = 40; static constexpr const char *spec = "%LaL"; }; template <typename Alloc, typename Derived> template <class Float> Node *AbstractManglingParser<Alloc, Derived>::parseFloatingLiteral() { const size_t N = FloatData<Float>::mangled_size; if (numLeft() <= N) return nullptr; StringView Data(First, First + N); for (char C : Data) if (!std::isxdigit(C)) return nullptr; First += N; if (!consumeIf('E')) return nullptr; return make<FloatLiteralImpl<Float>>(Data); } // <seq-id> ::= <0-9A-Z>+ template <typename Alloc, typename Derived> bool AbstractManglingParser<Alloc, Derived>::parseSeqId(size_t *Out) { if (!(look() >= '0' && look() <= '9') && !(look() >= 'A' && look() <= 'Z')) return true; size_t Id = 0; while (true) { if (look() >= '0' && look() <= '9') { Id *= 36; Id += static_cast<size_t>(look() - '0'); } else if (look() >= 'A' && look() <= 'Z') { Id *= 36; Id += static_cast<size_t>(look() - 'A') + 10; } else { *Out = Id; return false; } ++First; } } // <substitution> ::= S <seq-id> _ // ::= S_ // <substitution> ::= Sa # ::std::allocator // <substitution> ::= Sb # ::std::basic_string // <substitution> ::= Ss # ::std::basic_string < char, // ::std::char_traits<char>, // ::std::allocator<char> > // <substitution> ::= Si # ::std::basic_istream<char, std::char_traits<char> > // <substitution> ::= So # ::std::basic_ostream<char, std::char_traits<char> > // <substitution> ::= Sd # ::std::basic_iostream<char, std::char_traits<char> > template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseSubstitution() { if (!consumeIf('S')) return nullptr; if (std::islower(look())) { Node *SpecialSub; switch (look()) { case 'a': ++First; SpecialSub = make<SpecialSubstitution>(SpecialSubKind::allocator); break; case 'b': ++First; SpecialSub = make<SpecialSubstitution>(SpecialSubKind::basic_string); break; case 's': ++First; SpecialSub = make<SpecialSubstitution>(SpecialSubKind::string); break; case 'i': ++First; SpecialSub = make<SpecialSubstitution>(SpecialSubKind::istream); break; case 'o': ++First; SpecialSub = make<SpecialSubstitution>(SpecialSubKind::ostream); break; case 'd': ++First; SpecialSub = make<SpecialSubstitution>(SpecialSubKind::iostream); break; default: return nullptr; } if (!SpecialSub) return nullptr; // Itanium C++ ABI 5.1.2: If a name that would use a built-in <substitution> // has ABI tags, the tags are appended to the substitution; the result is a // substitutable component. Node *WithTags = getDerived().parseAbiTags(SpecialSub); if (WithTags != SpecialSub) { Subs.push_back(WithTags); SpecialSub = WithTags; } return SpecialSub; } // ::= S_ if (consumeIf('_')) { if (Subs.empty()) return nullptr; return Subs[0]; } // ::= S <seq-id> _ size_t Index = 0; if (parseSeqId(&Index)) return nullptr; ++Index; if (!consumeIf('_') || Index >= Subs.size()) return nullptr; return Subs[Index]; } // <template-param> ::= T_ # first template parameter // ::= T <parameter-2 non-negative number> _ template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseTemplateParam() { if (!consumeIf('T')) return nullptr; size_t Index = 0; if (!consumeIf('_')) { if (parsePositiveInteger(&Index)) return nullptr; ++Index; if (!consumeIf('_')) return nullptr; } // Itanium ABI 5.1.8: In a generic lambda, uses of auto in the parameter list // are mangled as the corresponding artificial template type parameter. if (ParsingLambdaParams) return make<NameType>("auto"); // If we're in a context where this <template-param> refers to a // <template-arg> further ahead in the mangled name (currently just conversion // operator types), then we should only look it up in the right context. if (PermitForwardTemplateReferences) { Node *ForwardRef = make<ForwardTemplateReference>(Index); if (!ForwardRef) return nullptr; assert(ForwardRef->getKind() == Node::KForwardTemplateReference); ForwardTemplateRefs.push_back( static_cast<ForwardTemplateReference *>(ForwardRef)); return ForwardRef; } if (Index >= TemplateParams.size()) return nullptr; return TemplateParams[Index]; } // <template-arg> ::= <type> # type or template // ::= X <expression> E # expression // ::= <expr-primary> # simple expressions // ::= J <template-arg>* E # argument pack // ::= LZ <encoding> E # extension template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parseTemplateArg() { switch (look()) { case 'X': { ++First; Node *Arg = getDerived().parseExpr(); if (Arg == nullptr || !consumeIf('E')) return nullptr; return Arg; } case 'J': { ++First; size_t ArgsBegin = Names.size(); while (!consumeIf('E')) { Node *Arg = getDerived().parseTemplateArg(); if (Arg == nullptr) return nullptr; Names.push_back(Arg); } NodeArray Args = popTrailingNodeArray(ArgsBegin); return make<TemplateArgumentPack>(Args); } case 'L': { // ::= LZ <encoding> E # extension if (look(1) == 'Z') { First += 2; Node *Arg = getDerived().parseEncoding(); if (Arg == nullptr || !consumeIf('E')) return nullptr; return Arg; } // ::= <expr-primary> # simple expressions return getDerived().parseExprPrimary(); } default: return getDerived().parseType(); } } // <template-args> ::= I <template-arg>* E // extension, the abi says <template-arg>+ template <typename Derived, typename Alloc> Node * AbstractManglingParser<Derived, Alloc>::parseTemplateArgs(bool TagTemplates) { if (!consumeIf('I')) return nullptr; // <template-params> refer to the innermost <template-args>. Clear out any // outer args that we may have inserted into TemplateParams. if (TagTemplates) TemplateParams.clear(); size_t ArgsBegin = Names.size(); while (!consumeIf('E')) { if (TagTemplates) { auto OldParams = std::move(TemplateParams); Node *Arg = getDerived().parseTemplateArg(); TemplateParams = std::move(OldParams); if (Arg == nullptr) return nullptr; Names.push_back(Arg); Node *TableEntry = Arg; if (Arg->getKind() == Node::KTemplateArgumentPack) { TableEntry = make<ParameterPack>( static_cast<TemplateArgumentPack*>(TableEntry)->getElements()); if (!TableEntry) return nullptr; } TemplateParams.push_back(TableEntry); } else { Node *Arg = getDerived().parseTemplateArg(); if (Arg == nullptr) return nullptr; Names.push_back(Arg); } } return make<TemplateArgs>(popTrailingNodeArray(ArgsBegin)); } // <mangled-name> ::= _Z <encoding> // ::= <type> // extension ::= ___Z <encoding> _block_invoke // extension ::= ___Z <encoding> _block_invoke<decimal-digit>+ // extension ::= ___Z <encoding> _block_invoke_<decimal-digit>+ template <typename Derived, typename Alloc> Node *AbstractManglingParser<Derived, Alloc>::parse() { if (consumeIf("_Z")) { Node *Encoding = getDerived().parseEncoding(); if (Encoding == nullptr) return nullptr; if (look() == '.') { Encoding = make<DotSuffix>(Encoding, StringView(First, Last)); First = Last; } if (numLeft() != 0) return nullptr; return Encoding; } if (consumeIf("___Z")) { Node *Encoding = getDerived().parseEncoding(); if (Encoding == nullptr || !consumeIf("_block_invoke")) return nullptr; bool RequireNumber = consumeIf('_'); if (parseNumber().empty() && RequireNumber) return nullptr; if (look() == '.') First = Last; if (numLeft() != 0) return nullptr; return make<SpecialName>("invocation function for block in ", Encoding); } Node *Ty = getDerived().parseType(); if (numLeft() != 0) return nullptr; return Ty; } template <typename Alloc> struct ManglingParser : AbstractManglingParser<ManglingParser<Alloc>, Alloc> { using AbstractManglingParser<ManglingParser<Alloc>, Alloc>::AbstractManglingParser; }; } // namespace itanium_demangle } // namespace llvm #endif // LLVM_DEMANGLE_ITANIUMDEMANGLE_H