1
0
mirror of synced 2024-11-25 00:00:27 +01:00
ImHex/external/llvm/Demangle/MicrosoftDemangleNodes.cpp
Mary 413443aa95 Build LLVM demangler directly with our sources
This remove dep on LLVM library by building the demangler as part of the
project.

This should help with building on macOS.
2020-12-18 17:56:41 +01:00

654 lines
22 KiB
C++

//===- MicrosoftDemangle.cpp ----------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file defines a demangler for MSVC-style mangled symbols.
//
//===----------------------------------------------------------------------===//
#include "llvm/Demangle/MicrosoftDemangleNodes.h"
#include "llvm/Demangle/DemangleConfig.h"
#include "llvm/Demangle/Utility.h"
#include <cctype>
#include <string>
using namespace llvm;
using namespace ms_demangle;
#define OUTPUT_ENUM_CLASS_VALUE(Enum, Value, Desc) \
case Enum::Value: \
OS << Desc; \
break;
// Writes a space if the last token does not end with a punctuation.
static void outputSpaceIfNecessary(OutputStream &OS) {
if (OS.empty())
return;
char C = OS.back();
if (std::isalnum(C) || C == '>')
OS << " ";
}
static void outputSingleQualifier(OutputStream &OS, Qualifiers Q) {
switch (Q) {
case Q_Const:
OS << "const";
break;
case Q_Volatile:
OS << "volatile";
break;
case Q_Restrict:
OS << "__restrict";
break;
default:
break;
}
}
static bool outputQualifierIfPresent(OutputStream &OS, Qualifiers Q,
Qualifiers Mask, bool NeedSpace) {
if (!(Q & Mask))
return NeedSpace;
if (NeedSpace)
OS << " ";
outputSingleQualifier(OS, Mask);
return true;
}
static void outputQualifiers(OutputStream &OS, Qualifiers Q, bool SpaceBefore,
bool SpaceAfter) {
if (Q == Q_None)
return;
size_t Pos1 = OS.getCurrentPosition();
SpaceBefore = outputQualifierIfPresent(OS, Q, Q_Const, SpaceBefore);
SpaceBefore = outputQualifierIfPresent(OS, Q, Q_Volatile, SpaceBefore);
SpaceBefore = outputQualifierIfPresent(OS, Q, Q_Restrict, SpaceBefore);
size_t Pos2 = OS.getCurrentPosition();
if (SpaceAfter && Pos2 > Pos1)
OS << " ";
}
static void outputCallingConvention(OutputStream &OS, CallingConv CC) {
outputSpaceIfNecessary(OS);
switch (CC) {
case CallingConv::Cdecl:
OS << "__cdecl";
break;
case CallingConv::Fastcall:
OS << "__fastcall";
break;
case CallingConv::Pascal:
OS << "__pascal";
break;
case CallingConv::Regcall:
OS << "__regcall";
break;
case CallingConv::Stdcall:
OS << "__stdcall";
break;
case CallingConv::Thiscall:
OS << "__thiscall";
break;
case CallingConv::Eabi:
OS << "__eabi";
break;
case CallingConv::Vectorcall:
OS << "__vectorcall";
break;
case CallingConv::Clrcall:
OS << "__clrcall";
break;
default:
break;
}
}
std::string Node::toString(OutputFlags Flags) const {
OutputStream OS;
initializeOutputStream(nullptr, nullptr, OS, 1024);
this->output(OS, Flags);
OS << '\0';
return {OS.getBuffer()};
}
void PrimitiveTypeNode::outputPre(OutputStream &OS, OutputFlags Flags) const {
switch (PrimKind) {
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Void, "void");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Bool, "bool");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Char, "char");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Schar, "signed char");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Uchar, "unsigned char");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Char8, "char8_t");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Char16, "char16_t");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Char32, "char32_t");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Short, "short");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Ushort, "unsigned short");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Int, "int");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Uint, "unsigned int");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Long, "long");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Ulong, "unsigned long");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Int64, "__int64");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Uint64, "unsigned __int64");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Wchar, "wchar_t");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Float, "float");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Double, "double");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Ldouble, "long double");
OUTPUT_ENUM_CLASS_VALUE(PrimitiveKind, Nullptr, "std::nullptr_t");
}
outputQualifiers(OS, Quals, true, false);
}
void NodeArrayNode::output(OutputStream &OS, OutputFlags Flags) const {
output(OS, Flags, ", ");
}
void NodeArrayNode::output(OutputStream &OS, OutputFlags Flags,
StringView Separator) const {
if (Count == 0)
return;
if (Nodes[0])
Nodes[0]->output(OS, Flags);
for (size_t I = 1; I < Count; ++I) {
OS << Separator;
Nodes[I]->output(OS, Flags);
}
}
void EncodedStringLiteralNode::output(OutputStream &OS,
OutputFlags Flags) const {
switch (Char) {
case CharKind::Wchar:
OS << "L\"";
break;
case CharKind::Char:
OS << "\"";
break;
case CharKind::Char16:
OS << "u\"";
break;
case CharKind::Char32:
OS << "U\"";
break;
}
OS << DecodedString << "\"";
if (IsTruncated)
OS << "...";
}
void IntegerLiteralNode::output(OutputStream &OS, OutputFlags Flags) const {
if (IsNegative)
OS << '-';
OS << Value;
}
void TemplateParameterReferenceNode::output(OutputStream &OS,
OutputFlags Flags) const {
if (ThunkOffsetCount > 0)
OS << "{";
else if (Affinity == PointerAffinity::Pointer)
OS << "&";
if (Symbol) {
Symbol->output(OS, Flags);
if (ThunkOffsetCount > 0)
OS << ", ";
}
if (ThunkOffsetCount > 0)
OS << ThunkOffsets[0];
for (int I = 1; I < ThunkOffsetCount; ++I) {
OS << ", " << ThunkOffsets[I];
}
if (ThunkOffsetCount > 0)
OS << "}";
}
void IdentifierNode::outputTemplateParameters(OutputStream &OS,
OutputFlags Flags) const {
if (!TemplateParams)
return;
OS << "<";
TemplateParams->output(OS, Flags);
OS << ">";
}
void DynamicStructorIdentifierNode::output(OutputStream &OS,
OutputFlags Flags) const {
if (IsDestructor)
OS << "`dynamic atexit destructor for ";
else
OS << "`dynamic initializer for ";
if (Variable) {
OS << "`";
Variable->output(OS, Flags);
OS << "''";
} else {
OS << "'";
Name->output(OS, Flags);
OS << "''";
}
}
void NamedIdentifierNode::output(OutputStream &OS, OutputFlags Flags) const {
OS << Name;
outputTemplateParameters(OS, Flags);
}
void IntrinsicFunctionIdentifierNode::output(OutputStream &OS,
OutputFlags Flags) const {
switch (Operator) {
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, New, "operator new");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Delete, "operator delete");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Assign, "operator=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, RightShift, "operator>>");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, LeftShift, "operator<<");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, LogicalNot, "operator!");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Equals, "operator==");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, NotEquals, "operator!=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, ArraySubscript,
"operator[]");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Pointer, "operator->");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Increment, "operator++");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Decrement, "operator--");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Minus, "operator-");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Plus, "operator+");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Dereference, "operator*");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, BitwiseAnd, "operator&");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, MemberPointer,
"operator->*");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Divide, "operator/");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Modulus, "operator%");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, LessThan, "operator<");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, LessThanEqual, "operator<=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, GreaterThan, "operator>");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, GreaterThanEqual,
"operator>=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Comma, "operator,");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Parens, "operator()");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, BitwiseNot, "operator~");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, BitwiseXor, "operator^");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, BitwiseOr, "operator|");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, LogicalAnd, "operator&&");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, LogicalOr, "operator||");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, TimesEqual, "operator*=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, PlusEqual, "operator+=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, MinusEqual, "operator-=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, DivEqual, "operator/=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, ModEqual, "operator%=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, RshEqual, "operator>>=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, LshEqual, "operator<<=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, BitwiseAndEqual,
"operator&=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, BitwiseOrEqual,
"operator|=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, BitwiseXorEqual,
"operator^=");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, VbaseDtor, "`vbase dtor'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, VecDelDtor,
"`vector deleting dtor'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, DefaultCtorClosure,
"`default ctor closure'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, ScalarDelDtor,
"`scalar deleting dtor'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, VecCtorIter,
"`vector ctor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, VecDtorIter,
"`vector dtor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, VecVbaseCtorIter,
"`vector vbase ctor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, VdispMap,
"`virtual displacement map'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, EHVecCtorIter,
"`eh vector ctor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, EHVecDtorIter,
"`eh vector dtor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, EHVecVbaseCtorIter,
"`eh vector vbase ctor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, CopyCtorClosure,
"`copy ctor closure'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, LocalVftableCtorClosure,
"`local vftable ctor closure'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, ArrayNew, "operator new[]");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, ArrayDelete,
"operator delete[]");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, ManVectorCtorIter,
"`managed vector ctor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, ManVectorDtorIter,
"`managed vector dtor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, EHVectorCopyCtorIter,
"`EH vector copy ctor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, EHVectorVbaseCopyCtorIter,
"`EH vector vbase copy ctor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, VectorCopyCtorIter,
"`vector copy ctor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, VectorVbaseCopyCtorIter,
"`vector vbase copy constructor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, ManVectorVbaseCopyCtorIter,
"`managed vector vbase copy constructor iterator'");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, CoAwait,
"operator co_await");
OUTPUT_ENUM_CLASS_VALUE(IntrinsicFunctionKind, Spaceship, "operator<=>");
case IntrinsicFunctionKind::MaxIntrinsic:
case IntrinsicFunctionKind::None:
break;
}
outputTemplateParameters(OS, Flags);
}
void LocalStaticGuardIdentifierNode::output(OutputStream &OS,
OutputFlags Flags) const {
if (IsThread)
OS << "`local static thread guard'";
else
OS << "`local static guard'";
if (ScopeIndex > 0)
OS << "{" << ScopeIndex << "}";
}
void ConversionOperatorIdentifierNode::output(OutputStream &OS,
OutputFlags Flags) const {
OS << "operator";
outputTemplateParameters(OS, Flags);
OS << " ";
TargetType->output(OS, Flags);
}
void StructorIdentifierNode::output(OutputStream &OS, OutputFlags Flags) const {
if (IsDestructor)
OS << "~";
Class->output(OS, Flags);
outputTemplateParameters(OS, Flags);
}
void LiteralOperatorIdentifierNode::output(OutputStream &OS,
OutputFlags Flags) const {
OS << "operator \"\"" << Name;
outputTemplateParameters(OS, Flags);
}
void FunctionSignatureNode::outputPre(OutputStream &OS,
OutputFlags Flags) const {
if (!(Flags & OF_NoAccessSpecifier)) {
if (FunctionClass & FC_Public)
OS << "public: ";
if (FunctionClass & FC_Protected)
OS << "protected: ";
if (FunctionClass & FC_Private)
OS << "private: ";
}
if (!(Flags & OF_NoMemberType)) {
if (!(FunctionClass & FC_Global)) {
if (FunctionClass & FC_Static)
OS << "static ";
}
if (FunctionClass & FC_Virtual)
OS << "virtual ";
if (FunctionClass & FC_ExternC)
OS << "extern \"C\" ";
}
if (!(Flags & OF_NoReturnType) && ReturnType) {
ReturnType->outputPre(OS, Flags);
OS << " ";
}
if (!(Flags & OF_NoCallingConvention))
outputCallingConvention(OS, CallConvention);
}
void FunctionSignatureNode::outputPost(OutputStream &OS,
OutputFlags Flags) const {
if (!(FunctionClass & FC_NoParameterList)) {
OS << "(";
if (Params)
Params->output(OS, Flags);
else
OS << "void";
if (IsVariadic) {
if (OS.back() != '(')
OS << ", ";
OS << "...";
}
OS << ")";
}
if (Quals & Q_Const)
OS << " const";
if (Quals & Q_Volatile)
OS << " volatile";
if (Quals & Q_Restrict)
OS << " __restrict";
if (Quals & Q_Unaligned)
OS << " __unaligned";
if (IsNoexcept)
OS << " noexcept";
if (RefQualifier == FunctionRefQualifier::Reference)
OS << " &";
else if (RefQualifier == FunctionRefQualifier::RValueReference)
OS << " &&";
if (!(Flags & OF_NoReturnType) && ReturnType)
ReturnType->outputPost(OS, Flags);
}
void ThunkSignatureNode::outputPre(OutputStream &OS, OutputFlags Flags) const {
OS << "[thunk]: ";
FunctionSignatureNode::outputPre(OS, Flags);
}
void ThunkSignatureNode::outputPost(OutputStream &OS, OutputFlags Flags) const {
if (FunctionClass & FC_StaticThisAdjust) {
OS << "`adjustor{" << ThisAdjust.StaticOffset << "}'";
} else if (FunctionClass & FC_VirtualThisAdjust) {
if (FunctionClass & FC_VirtualThisAdjustEx) {
OS << "`vtordispex{" << ThisAdjust.VBPtrOffset << ", "
<< ThisAdjust.VBOffsetOffset << ", " << ThisAdjust.VtordispOffset
<< ", " << ThisAdjust.StaticOffset << "}'";
} else {
OS << "`vtordisp{" << ThisAdjust.VtordispOffset << ", "
<< ThisAdjust.StaticOffset << "}'";
}
}
FunctionSignatureNode::outputPost(OS, Flags);
}
void PointerTypeNode::outputPre(OutputStream &OS, OutputFlags Flags) const {
if (Pointee->kind() == NodeKind::FunctionSignature) {
// If this is a pointer to a function, don't output the calling convention.
// It needs to go inside the parentheses.
const FunctionSignatureNode *Sig =
static_cast<const FunctionSignatureNode *>(Pointee);
Sig->outputPre(OS, OF_NoCallingConvention);
} else
Pointee->outputPre(OS, Flags);
outputSpaceIfNecessary(OS);
if (Quals & Q_Unaligned)
OS << "__unaligned ";
if (Pointee->kind() == NodeKind::ArrayType) {
OS << "(";
} else if (Pointee->kind() == NodeKind::FunctionSignature) {
OS << "(";
const FunctionSignatureNode *Sig =
static_cast<const FunctionSignatureNode *>(Pointee);
outputCallingConvention(OS, Sig->CallConvention);
OS << " ";
}
if (ClassParent) {
ClassParent->output(OS, Flags);
OS << "::";
}
switch (Affinity) {
case PointerAffinity::Pointer:
OS << "*";
break;
case PointerAffinity::Reference:
OS << "&";
break;
case PointerAffinity::RValueReference:
OS << "&&";
break;
default:
assert(false);
}
outputQualifiers(OS, Quals, false, false);
}
void PointerTypeNode::outputPost(OutputStream &OS, OutputFlags Flags) const {
if (Pointee->kind() == NodeKind::ArrayType ||
Pointee->kind() == NodeKind::FunctionSignature)
OS << ")";
Pointee->outputPost(OS, Flags);
}
void TagTypeNode::outputPre(OutputStream &OS, OutputFlags Flags) const {
if (!(Flags & OF_NoTagSpecifier)) {
switch (Tag) {
OUTPUT_ENUM_CLASS_VALUE(TagKind, Class, "class");
OUTPUT_ENUM_CLASS_VALUE(TagKind, Struct, "struct");
OUTPUT_ENUM_CLASS_VALUE(TagKind, Union, "union");
OUTPUT_ENUM_CLASS_VALUE(TagKind, Enum, "enum");
}
OS << " ";
}
QualifiedName->output(OS, Flags);
outputQualifiers(OS, Quals, true, false);
}
void TagTypeNode::outputPost(OutputStream &OS, OutputFlags Flags) const {}
void ArrayTypeNode::outputPre(OutputStream &OS, OutputFlags Flags) const {
ElementType->outputPre(OS, Flags);
outputQualifiers(OS, Quals, true, false);
}
void ArrayTypeNode::outputOneDimension(OutputStream &OS, OutputFlags Flags,
Node *N) const {
assert(N->kind() == NodeKind::IntegerLiteral);
IntegerLiteralNode *ILN = static_cast<IntegerLiteralNode *>(N);
if (ILN->Value != 0)
ILN->output(OS, Flags);
}
void ArrayTypeNode::outputDimensionsImpl(OutputStream &OS,
OutputFlags Flags) const {
if (Dimensions->Count == 0)
return;
outputOneDimension(OS, Flags, Dimensions->Nodes[0]);
for (size_t I = 1; I < Dimensions->Count; ++I) {
OS << "][";
outputOneDimension(OS, Flags, Dimensions->Nodes[I]);
}
}
void ArrayTypeNode::outputPost(OutputStream &OS, OutputFlags Flags) const {
OS << "[";
outputDimensionsImpl(OS, Flags);
OS << "]";
ElementType->outputPost(OS, Flags);
}
void SymbolNode::output(OutputStream &OS, OutputFlags Flags) const {
Name->output(OS, Flags);
}
void FunctionSymbolNode::output(OutputStream &OS, OutputFlags Flags) const {
Signature->outputPre(OS, Flags);
outputSpaceIfNecessary(OS);
Name->output(OS, Flags);
Signature->outputPost(OS, Flags);
}
void VariableSymbolNode::output(OutputStream &OS, OutputFlags Flags) const {
const char *AccessSpec = nullptr;
bool IsStatic = true;
switch (SC) {
case StorageClass::PrivateStatic:
AccessSpec = "private";
break;
case StorageClass::PublicStatic:
AccessSpec = "public";
break;
case StorageClass::ProtectedStatic:
AccessSpec = "protected";
break;
default:
IsStatic = false;
break;
}
if (!(Flags & OF_NoAccessSpecifier) && AccessSpec)
OS << AccessSpec << ": ";
if (!(Flags & OF_NoMemberType) && IsStatic)
OS << "static ";
if (Type) {
Type->outputPre(OS, Flags);
outputSpaceIfNecessary(OS);
}
Name->output(OS, Flags);
if (Type)
Type->outputPost(OS, Flags);
}
void CustomTypeNode::outputPre(OutputStream &OS, OutputFlags Flags) const {
Identifier->output(OS, Flags);
}
void CustomTypeNode::outputPost(OutputStream &OS, OutputFlags Flags) const {}
void QualifiedNameNode::output(OutputStream &OS, OutputFlags Flags) const {
Components->output(OS, Flags, "::");
}
void RttiBaseClassDescriptorNode::output(OutputStream &OS,
OutputFlags Flags) const {
OS << "`RTTI Base Class Descriptor at (";
OS << NVOffset << ", " << VBPtrOffset << ", " << VBTableOffset << ", "
<< this->Flags;
OS << ")'";
}
void LocalStaticGuardVariableNode::output(OutputStream &OS,
OutputFlags Flags) const {
Name->output(OS, Flags);
}
void VcallThunkIdentifierNode::output(OutputStream &OS,
OutputFlags Flags) const {
OS << "`vcall'{" << OffsetInVTable << ", {flat}}";
}
void SpecialTableSymbolNode::output(OutputStream &OS, OutputFlags Flags) const {
outputQualifiers(OS, Quals, false, true);
Name->output(OS, Flags);
if (TargetName) {
OS << "{for `";
TargetName->output(OS, Flags);
OS << "'}";
}
return;
}