//===--- APValue.cpp - Union class for APFloat/APSInt/Complex -------------===// // // 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 implements the APValue class. // //===----------------------------------------------------------------------===// #include "clang/AST/APValue.h" #include "Linkage.h" #include "clang/AST/ASTContext.h" #include "clang/AST/CharUnits.h" #include "clang/AST/DeclCXX.h" #include "clang/AST/Expr.h" #include "clang/AST/ExprCXX.h" #include "clang/AST/Type.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/raw_ostream.h" using namespace clang; /// The identity of a type_info object depends on the canonical unqualified /// type only. TypeInfoLValue::TypeInfoLValue(const Type *T) : T(T->getCanonicalTypeUnqualified().getTypePtr()) {} void TypeInfoLValue::print(llvm::raw_ostream &Out, const PrintingPolicy &Policy) const { Out << "typeid("; QualType(getType(), 0).print(Out, Policy); Out << ")"; } static_assert( 1 << llvm::PointerLikeTypeTraits::NumLowBitsAvailable <= alignof(Type), "Type is insufficiently aligned"); APValue::LValueBase::LValueBase(const ValueDecl *P, unsigned I, unsigned V) : Ptr(P ? cast(P->getCanonicalDecl()) : nullptr), Local{I, V} {} APValue::LValueBase::LValueBase(const Expr *P, unsigned I, unsigned V) : Ptr(P), Local{I, V} {} APValue::LValueBase APValue::LValueBase::getDynamicAlloc(DynamicAllocLValue LV, QualType Type) { LValueBase Base; Base.Ptr = LV; Base.DynamicAllocType = Type.getAsOpaquePtr(); return Base; } APValue::LValueBase APValue::LValueBase::getTypeInfo(TypeInfoLValue LV, QualType TypeInfo) { LValueBase Base; Base.Ptr = LV; Base.TypeInfoType = TypeInfo.getAsOpaquePtr(); return Base; } QualType APValue::LValueBase::getType() const { if (!*this) return QualType(); if (const ValueDecl *D = dyn_cast()) { // FIXME: It's unclear where we're supposed to take the type from, and // this actually matters for arrays of unknown bound. Eg: // // extern int arr[]; void f() { extern int arr[3]; }; // constexpr int *p = &arr[1]; // valid? // // For now, we take the most complete type we can find. for (auto *Redecl = cast(D->getMostRecentDecl()); Redecl; Redecl = cast_or_null(Redecl->getPreviousDecl())) { QualType T = Redecl->getType(); if (!T->isIncompleteArrayType()) return T; } return D->getType(); } if (is()) return getTypeInfoType(); if (is()) return getDynamicAllocType(); const Expr *Base = get(); // For a materialized temporary, the type of the temporary we materialized // may not be the type of the expression. if (const MaterializeTemporaryExpr *MTE = llvm::dyn_cast(Base)) { SmallVector CommaLHSs; SmallVector Adjustments; const Expr *Temp = MTE->getSubExpr(); const Expr *Inner = Temp->skipRValueSubobjectAdjustments(CommaLHSs, Adjustments); // Keep any cv-qualifiers from the reference if we generated a temporary // for it directly. Otherwise use the type after adjustment. if (!Adjustments.empty()) return Inner->getType(); } return Base->getType(); } unsigned APValue::LValueBase::getCallIndex() const { return (is() || is()) ? 0 : Local.CallIndex; } unsigned APValue::LValueBase::getVersion() const { return (is() || is()) ? 0 : Local.Version; } QualType APValue::LValueBase::getTypeInfoType() const { assert(is() && "not a type_info lvalue"); return QualType::getFromOpaquePtr(TypeInfoType); } QualType APValue::LValueBase::getDynamicAllocType() const { assert(is() && "not a dynamic allocation lvalue"); return QualType::getFromOpaquePtr(DynamicAllocType); } void APValue::LValueBase::Profile(llvm::FoldingSetNodeID &ID) const { ID.AddPointer(Ptr.getOpaqueValue()); if (is() || is()) return; ID.AddInteger(Local.CallIndex); ID.AddInteger(Local.Version); } namespace clang { bool operator==(const APValue::LValueBase &LHS, const APValue::LValueBase &RHS) { if (LHS.Ptr != RHS.Ptr) return false; if (LHS.is() || LHS.is()) return true; return LHS.Local.CallIndex == RHS.Local.CallIndex && LHS.Local.Version == RHS.Local.Version; } } APValue::LValuePathEntry::LValuePathEntry(BaseOrMemberType BaseOrMember) { if (const Decl *D = BaseOrMember.getPointer()) BaseOrMember.setPointer(D->getCanonicalDecl()); Value = reinterpret_cast(BaseOrMember.getOpaqueValue()); } void APValue::LValuePathEntry::Profile(llvm::FoldingSetNodeID &ID) const { ID.AddInteger(Value); } APValue::LValuePathSerializationHelper::LValuePathSerializationHelper( ArrayRef Path, QualType ElemTy) : Ty((const void *)ElemTy.getTypePtrOrNull()), Path(Path) {} QualType APValue::LValuePathSerializationHelper::getType() { return QualType::getFromOpaquePtr(Ty); } namespace { struct LVBase { APValue::LValueBase Base; CharUnits Offset; unsigned PathLength; bool IsNullPtr : 1; bool IsOnePastTheEnd : 1; }; } void *APValue::LValueBase::getOpaqueValue() const { return Ptr.getOpaqueValue(); } bool APValue::LValueBase::isNull() const { return Ptr.isNull(); } APValue::LValueBase::operator bool () const { return static_cast(Ptr); } clang::APValue::LValueBase llvm::DenseMapInfo::getEmptyKey() { clang::APValue::LValueBase B; B.Ptr = DenseMapInfo::getEmptyKey(); return B; } clang::APValue::LValueBase llvm::DenseMapInfo::getTombstoneKey() { clang::APValue::LValueBase B; B.Ptr = DenseMapInfo::getTombstoneKey(); return B; } namespace clang { llvm::hash_code hash_value(const APValue::LValueBase &Base) { if (Base.is() || Base.is()) return llvm::hash_value(Base.getOpaqueValue()); return llvm::hash_combine(Base.getOpaqueValue(), Base.getCallIndex(), Base.getVersion()); } } unsigned llvm::DenseMapInfo::getHashValue( const clang::APValue::LValueBase &Base) { return hash_value(Base); } bool llvm::DenseMapInfo::isEqual( const clang::APValue::LValueBase &LHS, const clang::APValue::LValueBase &RHS) { return LHS == RHS; } struct APValue::LV : LVBase { static const unsigned InlinePathSpace = (DataSize - sizeof(LVBase)) / sizeof(LValuePathEntry); /// Path - The sequence of base classes, fields and array indices to follow to /// walk from Base to the subobject. When performing GCC-style folding, there /// may not be such a path. union { LValuePathEntry Path[InlinePathSpace]; LValuePathEntry *PathPtr; }; LV() { PathLength = (unsigned)-1; } ~LV() { resizePath(0); } void resizePath(unsigned Length) { if (Length == PathLength) return; if (hasPathPtr()) delete [] PathPtr; PathLength = Length; if (hasPathPtr()) PathPtr = new LValuePathEntry[Length]; } bool hasPath() const { return PathLength != (unsigned)-1; } bool hasPathPtr() const { return hasPath() && PathLength > InlinePathSpace; } LValuePathEntry *getPath() { return hasPathPtr() ? PathPtr : Path; } const LValuePathEntry *getPath() const { return hasPathPtr() ? PathPtr : Path; } }; namespace { struct MemberPointerBase { llvm::PointerIntPair MemberAndIsDerivedMember; unsigned PathLength; }; } struct APValue::MemberPointerData : MemberPointerBase { static const unsigned InlinePathSpace = (DataSize - sizeof(MemberPointerBase)) / sizeof(const CXXRecordDecl*); typedef const CXXRecordDecl *PathElem; union { PathElem Path[InlinePathSpace]; PathElem *PathPtr; }; MemberPointerData() { PathLength = 0; } ~MemberPointerData() { resizePath(0); } void resizePath(unsigned Length) { if (Length == PathLength) return; if (hasPathPtr()) delete [] PathPtr; PathLength = Length; if (hasPathPtr()) PathPtr = new PathElem[Length]; } bool hasPathPtr() const { return PathLength > InlinePathSpace; } PathElem *getPath() { return hasPathPtr() ? PathPtr : Path; } const PathElem *getPath() const { return hasPathPtr() ? PathPtr : Path; } }; // FIXME: Reduce the malloc traffic here. APValue::Arr::Arr(unsigned NumElts, unsigned Size) : Elts(new APValue[NumElts + (NumElts != Size ? 1 : 0)]), NumElts(NumElts), ArrSize(Size) {} APValue::Arr::~Arr() { delete [] Elts; } APValue::StructData::StructData(unsigned NumBases, unsigned NumFields) : Elts(new APValue[NumBases+NumFields]), NumBases(NumBases), NumFields(NumFields) {} APValue::StructData::~StructData() { delete [] Elts; } APValue::UnionData::UnionData() : Field(nullptr), Value(new APValue) {} APValue::UnionData::~UnionData () { delete Value; } APValue::APValue(const APValue &RHS) : Kind(None) { switch (RHS.getKind()) { case None: case Indeterminate: Kind = RHS.getKind(); break; case Int: MakeInt(); setInt(RHS.getInt()); break; case Float: MakeFloat(); setFloat(RHS.getFloat()); break; case FixedPoint: { APFixedPoint FXCopy = RHS.getFixedPoint(); MakeFixedPoint(std::move(FXCopy)); break; } case Vector: MakeVector(); setVector(((const Vec *)(const char *)&RHS.Data)->Elts, RHS.getVectorLength()); break; case ComplexInt: MakeComplexInt(); setComplexInt(RHS.getComplexIntReal(), RHS.getComplexIntImag()); break; case ComplexFloat: MakeComplexFloat(); setComplexFloat(RHS.getComplexFloatReal(), RHS.getComplexFloatImag()); break; case LValue: MakeLValue(); if (RHS.hasLValuePath()) setLValue(RHS.getLValueBase(), RHS.getLValueOffset(), RHS.getLValuePath(), RHS.isLValueOnePastTheEnd(), RHS.isNullPointer()); else setLValue(RHS.getLValueBase(), RHS.getLValueOffset(), NoLValuePath(), RHS.isNullPointer()); break; case Array: MakeArray(RHS.getArrayInitializedElts(), RHS.getArraySize()); for (unsigned I = 0, N = RHS.getArrayInitializedElts(); I != N; ++I) getArrayInitializedElt(I) = RHS.getArrayInitializedElt(I); if (RHS.hasArrayFiller()) getArrayFiller() = RHS.getArrayFiller(); break; case Struct: MakeStruct(RHS.getStructNumBases(), RHS.getStructNumFields()); for (unsigned I = 0, N = RHS.getStructNumBases(); I != N; ++I) getStructBase(I) = RHS.getStructBase(I); for (unsigned I = 0, N = RHS.getStructNumFields(); I != N; ++I) getStructField(I) = RHS.getStructField(I); break; case Union: MakeUnion(); setUnion(RHS.getUnionField(), RHS.getUnionValue()); break; case MemberPointer: MakeMemberPointer(RHS.getMemberPointerDecl(), RHS.isMemberPointerToDerivedMember(), RHS.getMemberPointerPath()); break; case AddrLabelDiff: MakeAddrLabelDiff(); setAddrLabelDiff(RHS.getAddrLabelDiffLHS(), RHS.getAddrLabelDiffRHS()); break; } } APValue::APValue(APValue &&RHS) : Kind(RHS.Kind), Data(RHS.Data) { RHS.Kind = None; } APValue &APValue::operator=(const APValue &RHS) { if (this != &RHS) *this = APValue(RHS); return *this; } APValue &APValue::operator=(APValue &&RHS) { if (this != &RHS) { if (Kind != None && Kind != Indeterminate) DestroyDataAndMakeUninit(); Kind = RHS.Kind; Data = RHS.Data; RHS.Kind = None; } return *this; } void APValue::DestroyDataAndMakeUninit() { if (Kind == Int) ((APSInt *)(char *)&Data)->~APSInt(); else if (Kind == Float) ((APFloat *)(char *)&Data)->~APFloat(); else if (Kind == FixedPoint) ((APFixedPoint *)(char *)&Data)->~APFixedPoint(); else if (Kind == Vector) ((Vec *)(char *)&Data)->~Vec(); else if (Kind == ComplexInt) ((ComplexAPSInt *)(char *)&Data)->~ComplexAPSInt(); else if (Kind == ComplexFloat) ((ComplexAPFloat *)(char *)&Data)->~ComplexAPFloat(); else if (Kind == LValue) ((LV *)(char *)&Data)->~LV(); else if (Kind == Array) ((Arr *)(char *)&Data)->~Arr(); else if (Kind == Struct) ((StructData *)(char *)&Data)->~StructData(); else if (Kind == Union) ((UnionData *)(char *)&Data)->~UnionData(); else if (Kind == MemberPointer) ((MemberPointerData *)(char *)&Data)->~MemberPointerData(); else if (Kind == AddrLabelDiff) ((AddrLabelDiffData *)(char *)&Data)->~AddrLabelDiffData(); Kind = None; } bool APValue::needsCleanup() const { switch (getKind()) { case None: case Indeterminate: case AddrLabelDiff: return false; case Struct: case Union: case Array: case Vector: return true; case Int: return getInt().needsCleanup(); case Float: return getFloat().needsCleanup(); case FixedPoint: return getFixedPoint().getValue().needsCleanup(); case ComplexFloat: assert(getComplexFloatImag().needsCleanup() == getComplexFloatReal().needsCleanup() && "In _Complex float types, real and imaginary values always have the " "same size."); return getComplexFloatReal().needsCleanup(); case ComplexInt: assert(getComplexIntImag().needsCleanup() == getComplexIntReal().needsCleanup() && "In _Complex int types, real and imaginary values must have the " "same size."); return getComplexIntReal().needsCleanup(); case LValue: return reinterpret_cast(&Data)->hasPathPtr(); case MemberPointer: return reinterpret_cast(&Data)->hasPathPtr(); } llvm_unreachable("Unknown APValue kind!"); } void APValue::swap(APValue &RHS) { std::swap(Kind, RHS.Kind); std::swap(Data, RHS.Data); } /// Profile the value of an APInt, excluding its bit-width. static void profileIntValue(llvm::FoldingSetNodeID &ID, const llvm::APInt &V) { for (unsigned I = 0, N = V.getBitWidth(); I < N; I += 32) ID.AddInteger((uint32_t)V.extractBitsAsZExtValue(std::min(32u, N - I), I)); } void APValue::Profile(llvm::FoldingSetNodeID &ID) const { // Note that our profiling assumes that only APValues of the same type are // ever compared. As a result, we don't consider collisions that could only // happen if the types are different. (For example, structs with different // numbers of members could profile the same.) ID.AddInteger(Kind); switch (Kind) { case None: case Indeterminate: return; case AddrLabelDiff: ID.AddPointer(getAddrLabelDiffLHS()->getLabel()->getCanonicalDecl()); ID.AddPointer(getAddrLabelDiffRHS()->getLabel()->getCanonicalDecl()); return; case Struct: for (unsigned I = 0, N = getStructNumBases(); I != N; ++I) getStructBase(I).Profile(ID); for (unsigned I = 0, N = getStructNumFields(); I != N; ++I) getStructField(I).Profile(ID); return; case Union: if (!getUnionField()) { ID.AddInteger(0); return; } ID.AddInteger(getUnionField()->getFieldIndex() + 1); getUnionValue().Profile(ID); return; case Array: { if (getArraySize() == 0) return; // The profile should not depend on whether the array is expanded or // not, but we don't want to profile the array filler many times for // a large array. So treat all equal trailing elements as the filler. // Elements are profiled in reverse order to support this, and the // first profiled element is followed by a count. For example: // // ['a', 'c', 'x', 'x', 'x'] is profiled as // [5, 'x', 3, 'c', 'a'] llvm::FoldingSetNodeID FillerID; (hasArrayFiller() ? getArrayFiller() : getArrayInitializedElt(getArrayInitializedElts() - 1)) .Profile(FillerID); ID.AddNodeID(FillerID); unsigned NumFillers = getArraySize() - getArrayInitializedElts(); unsigned N = getArrayInitializedElts(); // Count the number of elements equal to the last one. This loop ends // by adding an integer indicating the number of such elements, with // N set to the number of elements left to profile. while (true) { if (N == 0) { // All elements are fillers. assert(NumFillers == getArraySize()); ID.AddInteger(NumFillers); break; } // No need to check if the last element is equal to the last // element. if (N != getArraySize()) { llvm::FoldingSetNodeID ElemID; getArrayInitializedElt(N - 1).Profile(ElemID); if (ElemID != FillerID) { ID.AddInteger(NumFillers); ID.AddNodeID(ElemID); --N; break; } } // This is a filler. ++NumFillers; --N; } // Emit the remaining elements. for (; N != 0; --N) getArrayInitializedElt(N - 1).Profile(ID); return; } case Vector: for (unsigned I = 0, N = getVectorLength(); I != N; ++I) getVectorElt(I).Profile(ID); return; case Int: profileIntValue(ID, getInt()); return; case Float: profileIntValue(ID, getFloat().bitcastToAPInt()); return; case FixedPoint: profileIntValue(ID, getFixedPoint().getValue()); return; case ComplexFloat: profileIntValue(ID, getComplexFloatReal().bitcastToAPInt()); profileIntValue(ID, getComplexFloatImag().bitcastToAPInt()); return; case ComplexInt: profileIntValue(ID, getComplexIntReal()); profileIntValue(ID, getComplexIntImag()); return; case LValue: getLValueBase().Profile(ID); ID.AddInteger(getLValueOffset().getQuantity()); ID.AddInteger((isNullPointer() ? 1 : 0) | (isLValueOnePastTheEnd() ? 2 : 0) | (hasLValuePath() ? 4 : 0)); if (hasLValuePath()) { ID.AddInteger(getLValuePath().size()); // For uniqueness, we only need to profile the entries corresponding // to union members, but we don't have the type here so we don't know // how to interpret the entries. for (LValuePathEntry E : getLValuePath()) E.Profile(ID); } return; case MemberPointer: ID.AddPointer(getMemberPointerDecl()); ID.AddInteger(isMemberPointerToDerivedMember()); for (const CXXRecordDecl *D : getMemberPointerPath()) ID.AddPointer(D); return; } llvm_unreachable("Unknown APValue kind!"); } static double GetApproxValue(const llvm::APFloat &F) { llvm::APFloat V = F; bool ignored; V.convert(llvm::APFloat::IEEEdouble(), llvm::APFloat::rmNearestTiesToEven, &ignored); return V.convertToDouble(); } static bool TryPrintAsStringLiteral(raw_ostream &Out, const PrintingPolicy &Policy, const ArrayType *ATy, ArrayRef Inits) { if (Inits.empty()) return false; QualType Ty = ATy->getElementType(); if (!Ty->isAnyCharacterType()) return false; // Nothing we can do about a sequence that is not null-terminated if (!Inits.back().isInt() || !Inits.back().getInt().isZero()) return false; Inits = Inits.drop_back(); llvm::SmallString<40> Buf; Buf.push_back('"'); // Better than printing a two-digit sequence of 10 integers. constexpr size_t MaxN = 36; StringRef Ellipsis; if (Inits.size() > MaxN && !Policy.EntireContentsOfLargeArray) { Ellipsis = "[...]"; Inits = Inits.take_front(std::min(MaxN - Ellipsis.size() / 2, Inits.size())); } for (auto &Val : Inits) { if (!Val.isInt()) return false; int64_t Char64 = Val.getInt().getExtValue(); if (!isASCII(Char64)) return false; // Bye bye, see you in integers. auto Ch = static_cast(Char64); // The diagnostic message is 'quoted' StringRef Escaped = escapeCStyle(Ch); if (Escaped.empty()) { if (!isPrintable(Ch)) return false; Buf.emplace_back(Ch); } else { Buf.append(Escaped); } } Buf.append(Ellipsis); Buf.push_back('"'); if (Ty->isWideCharType()) Out << 'L'; else if (Ty->isChar8Type()) Out << "u8"; else if (Ty->isChar16Type()) Out << 'u'; else if (Ty->isChar32Type()) Out << 'U'; Out << Buf; return true; } void APValue::printPretty(raw_ostream &Out, const ASTContext &Ctx, QualType Ty) const { printPretty(Out, Ctx.getPrintingPolicy(), Ty, &Ctx); } void APValue::printPretty(raw_ostream &Out, const PrintingPolicy &Policy, QualType Ty, const ASTContext *Ctx) const { // There are no objects of type 'void', but values of this type can be // returned from functions. if (Ty->isVoidType()) { Out << "void()"; return; } if (const auto *AT = Ty->getAs()) Ty = AT->getValueType(); switch (getKind()) { case APValue::None: Out << ""; return; case APValue::Indeterminate: Out << ""; return; case APValue::Int: if (Ty->isBooleanType()) Out << (getInt().getBoolValue() ? "true" : "false"); else Out << getInt(); return; case APValue::Float: Out << GetApproxValue(getFloat()); return; case APValue::FixedPoint: Out << getFixedPoint(); return; case APValue::Vector: { Out << '{'; QualType ElemTy = Ty->castAs()->getElementType(); getVectorElt(0).printPretty(Out, Policy, ElemTy, Ctx); for (unsigned i = 1; i != getVectorLength(); ++i) { Out << ", "; getVectorElt(i).printPretty(Out, Policy, ElemTy, Ctx); } Out << '}'; return; } case APValue::ComplexInt: Out << getComplexIntReal() << "+" << getComplexIntImag() << "i"; return; case APValue::ComplexFloat: Out << GetApproxValue(getComplexFloatReal()) << "+" << GetApproxValue(getComplexFloatImag()) << "i"; return; case APValue::LValue: { bool IsReference = Ty->isReferenceType(); QualType InnerTy = IsReference ? Ty.getNonReferenceType() : Ty->getPointeeType(); if (InnerTy.isNull()) InnerTy = Ty; LValueBase Base = getLValueBase(); if (!Base) { if (isNullPointer()) { Out << (Policy.Nullptr ? "nullptr" : "0"); } else if (IsReference) { Out << "*(" << InnerTy.stream(Policy) << "*)" << getLValueOffset().getQuantity(); } else { Out << "(" << Ty.stream(Policy) << ")" << getLValueOffset().getQuantity(); } return; } if (!hasLValuePath()) { // No lvalue path: just print the offset. CharUnits O = getLValueOffset(); CharUnits S = Ctx ? Ctx->getTypeSizeInCharsIfKnown(InnerTy).value_or( CharUnits::Zero()) : CharUnits::Zero(); if (!O.isZero()) { if (IsReference) Out << "*("; if (S.isZero() || O % S) { Out << "(char*)"; S = CharUnits::One(); } Out << '&'; } else if (!IsReference) { Out << '&'; } if (const ValueDecl *VD = Base.dyn_cast()) Out << *VD; else if (TypeInfoLValue TI = Base.dyn_cast()) { TI.print(Out, Policy); } else if (DynamicAllocLValue DA = Base.dyn_cast()) { Out << "{*new " << Base.getDynamicAllocType().stream(Policy) << "#" << DA.getIndex() << "}"; } else { assert(Base.get() != nullptr && "Expecting non-null Expr"); Base.get()->printPretty(Out, nullptr, Policy); } if (!O.isZero()) { Out << " + " << (O / S); if (IsReference) Out << ')'; } return; } // We have an lvalue path. Print it out nicely. if (!IsReference) Out << '&'; else if (isLValueOnePastTheEnd()) Out << "*(&"; QualType ElemTy = Base.getType(); if (const ValueDecl *VD = Base.dyn_cast()) { Out << *VD; } else if (TypeInfoLValue TI = Base.dyn_cast()) { TI.print(Out, Policy); } else if (DynamicAllocLValue DA = Base.dyn_cast()) { Out << "{*new " << Base.getDynamicAllocType().stream(Policy) << "#" << DA.getIndex() << "}"; } else { const Expr *E = Base.get(); assert(E != nullptr && "Expecting non-null Expr"); E->printPretty(Out, nullptr, Policy); } ArrayRef Path = getLValuePath(); const CXXRecordDecl *CastToBase = nullptr; for (unsigned I = 0, N = Path.size(); I != N; ++I) { if (ElemTy->isRecordType()) { // The lvalue refers to a class type, so the next path entry is a base // or member. const Decl *BaseOrMember = Path[I].getAsBaseOrMember().getPointer(); if (const CXXRecordDecl *RD = dyn_cast(BaseOrMember)) { CastToBase = RD; // Leave ElemTy referring to the most-derived class. The actual type // doesn't matter except for array types. } else { const ValueDecl *VD = cast(BaseOrMember); Out << "."; if (CastToBase) Out << *CastToBase << "::"; Out << *VD; ElemTy = VD->getType(); } } else if (ElemTy->isAnyComplexType()) { // The lvalue refers to a complex type Out << (Path[I].getAsArrayIndex() == 0 ? ".real" : ".imag"); ElemTy = ElemTy->castAs()->getElementType(); } else { // The lvalue must refer to an array. Out << '[' << Path[I].getAsArrayIndex() << ']'; ElemTy = ElemTy->castAsArrayTypeUnsafe()->getElementType(); } } // Handle formatting of one-past-the-end lvalues. if (isLValueOnePastTheEnd()) { // FIXME: If CastToBase is non-0, we should prefix the output with // "(CastToBase*)". Out << " + 1"; if (IsReference) Out << ')'; } return; } case APValue::Array: { const ArrayType *AT = Ty->castAsArrayTypeUnsafe(); unsigned N = getArrayInitializedElts(); if (N != 0 && TryPrintAsStringLiteral(Out, Policy, AT, {&getArrayInitializedElt(0), N})) return; QualType ElemTy = AT->getElementType(); Out << '{'; unsigned I = 0; switch (N) { case 0: for (; I != N; ++I) { Out << ", "; if (I == 10 && !Policy.EntireContentsOfLargeArray) { Out << "...}"; return; } [[fallthrough]]; default: getArrayInitializedElt(I).printPretty(Out, Policy, ElemTy, Ctx); } } Out << '}'; return; } case APValue::Struct: { Out << '{'; const RecordDecl *RD = Ty->castAs()->getDecl(); bool First = true; if (unsigned N = getStructNumBases()) { const CXXRecordDecl *CD = cast(RD); CXXRecordDecl::base_class_const_iterator BI = CD->bases_begin(); for (unsigned I = 0; I != N; ++I, ++BI) { assert(BI != CD->bases_end()); if (!First) Out << ", "; getStructBase(I).printPretty(Out, Policy, BI->getType(), Ctx); First = false; } } for (const auto *FI : RD->fields()) { if (!First) Out << ", "; if (FI->isUnnamedBitField()) continue; getStructField(FI->getFieldIndex()). printPretty(Out, Policy, FI->getType(), Ctx); First = false; } Out << '}'; return; } case APValue::Union: Out << '{'; if (const FieldDecl *FD = getUnionField()) { Out << "." << *FD << " = "; getUnionValue().printPretty(Out, Policy, FD->getType(), Ctx); } Out << '}'; return; case APValue::MemberPointer: // FIXME: This is not enough to unambiguously identify the member in a // multiple-inheritance scenario. if (const ValueDecl *VD = getMemberPointerDecl()) { Out << '&' << *cast(VD->getDeclContext()) << "::" << *VD; return; } Out << "0"; return; case APValue::AddrLabelDiff: Out << "&&" << getAddrLabelDiffLHS()->getLabel()->getName(); Out << " - "; Out << "&&" << getAddrLabelDiffRHS()->getLabel()->getName(); return; } llvm_unreachable("Unknown APValue kind!"); } std::string APValue::getAsString(const ASTContext &Ctx, QualType Ty) const { std::string Result; llvm::raw_string_ostream Out(Result); printPretty(Out, Ctx, Ty); Out.flush(); return Result; } bool APValue::toIntegralConstant(APSInt &Result, QualType SrcTy, const ASTContext &Ctx) const { if (isInt()) { Result = getInt(); return true; } if (isLValue() && isNullPointer()) { Result = Ctx.MakeIntValue(Ctx.getTargetNullPointerValue(SrcTy), SrcTy); return true; } if (isLValue() && !getLValueBase()) { Result = Ctx.MakeIntValue(getLValueOffset().getQuantity(), SrcTy); return true; } return false; } const APValue::LValueBase APValue::getLValueBase() const { assert(isLValue() && "Invalid accessor"); return ((const LV *)(const void *)&Data)->Base; } bool APValue::isLValueOnePastTheEnd() const { assert(isLValue() && "Invalid accessor"); return ((const LV *)(const void *)&Data)->IsOnePastTheEnd; } CharUnits &APValue::getLValueOffset() { assert(isLValue() && "Invalid accessor"); return ((LV *)(void *)&Data)->Offset; } bool APValue::hasLValuePath() const { assert(isLValue() && "Invalid accessor"); return ((const LV *)(const char *)&Data)->hasPath(); } ArrayRef APValue::getLValuePath() const { assert(isLValue() && hasLValuePath() && "Invalid accessor"); const LV &LVal = *((const LV *)(const char *)&Data); return llvm::ArrayRef(LVal.getPath(), LVal.PathLength); } unsigned APValue::getLValueCallIndex() const { assert(isLValue() && "Invalid accessor"); return ((const LV *)(const char *)&Data)->Base.getCallIndex(); } unsigned APValue::getLValueVersion() const { assert(isLValue() && "Invalid accessor"); return ((const LV *)(const char *)&Data)->Base.getVersion(); } bool APValue::isNullPointer() const { assert(isLValue() && "Invalid usage"); return ((const LV *)(const char *)&Data)->IsNullPtr; } void APValue::setLValue(LValueBase B, const CharUnits &O, NoLValuePath, bool IsNullPtr) { assert(isLValue() && "Invalid accessor"); LV &LVal = *((LV *)(char *)&Data); LVal.Base = B; LVal.IsOnePastTheEnd = false; LVal.Offset = O; LVal.resizePath((unsigned)-1); LVal.IsNullPtr = IsNullPtr; } MutableArrayRef APValue::setLValueUninit(LValueBase B, const CharUnits &O, unsigned Size, bool IsOnePastTheEnd, bool IsNullPtr) { assert(isLValue() && "Invalid accessor"); LV &LVal = *((LV *)(char *)&Data); LVal.Base = B; LVal.IsOnePastTheEnd = IsOnePastTheEnd; LVal.Offset = O; LVal.IsNullPtr = IsNullPtr; LVal.resizePath(Size); return {LVal.getPath(), Size}; } void APValue::setLValue(LValueBase B, const CharUnits &O, ArrayRef Path, bool IsOnePastTheEnd, bool IsNullPtr) { MutableArrayRef InternalPath = setLValueUninit(B, O, Path.size(), IsOnePastTheEnd, IsNullPtr); if (Path.size()) { memcpy(InternalPath.data(), Path.data(), Path.size() * sizeof(LValuePathEntry)); } } void APValue::setUnion(const FieldDecl *Field, const APValue &Value) { assert(isUnion() && "Invalid accessor"); ((UnionData *)(char *)&Data)->Field = Field ? Field->getCanonicalDecl() : nullptr; *((UnionData *)(char *)&Data)->Value = Value; } const ValueDecl *APValue::getMemberPointerDecl() const { assert(isMemberPointer() && "Invalid accessor"); const MemberPointerData &MPD = *((const MemberPointerData *)(const char *)&Data); return MPD.MemberAndIsDerivedMember.getPointer(); } bool APValue::isMemberPointerToDerivedMember() const { assert(isMemberPointer() && "Invalid accessor"); const MemberPointerData &MPD = *((const MemberPointerData *)(const char *)&Data); return MPD.MemberAndIsDerivedMember.getInt(); } ArrayRef APValue::getMemberPointerPath() const { assert(isMemberPointer() && "Invalid accessor"); const MemberPointerData &MPD = *((const MemberPointerData *)(const char *)&Data); return llvm::ArrayRef(MPD.getPath(), MPD.PathLength); } void APValue::MakeLValue() { assert(isAbsent() && "Bad state change"); static_assert(sizeof(LV) <= DataSize, "LV too big"); new ((void *)(char *)&Data) LV(); Kind = LValue; } void APValue::MakeArray(unsigned InitElts, unsigned Size) { assert(isAbsent() && "Bad state change"); new ((void *)(char *)&Data) Arr(InitElts, Size); Kind = Array; } MutableArrayRef setLValueUninit(APValue::LValueBase B, const CharUnits &O, unsigned Size, bool OnePastTheEnd, bool IsNullPtr); MutableArrayRef APValue::setMemberPointerUninit(const ValueDecl *Member, bool IsDerivedMember, unsigned Size) { assert(isAbsent() && "Bad state change"); MemberPointerData *MPD = new ((void *)(char *)&Data) MemberPointerData; Kind = MemberPointer; MPD->MemberAndIsDerivedMember.setPointer( Member ? cast(Member->getCanonicalDecl()) : nullptr); MPD->MemberAndIsDerivedMember.setInt(IsDerivedMember); MPD->resizePath(Size); return {MPD->getPath(), MPD->PathLength}; } void APValue::MakeMemberPointer(const ValueDecl *Member, bool IsDerivedMember, ArrayRef Path) { MutableArrayRef InternalPath = setMemberPointerUninit(Member, IsDerivedMember, Path.size()); for (unsigned I = 0; I != Path.size(); ++I) InternalPath[I] = Path[I]->getCanonicalDecl(); } LinkageInfo LinkageComputer::getLVForValue(const APValue &V, LVComputationKind computation) { LinkageInfo LV = LinkageInfo::external(); auto MergeLV = [&](LinkageInfo MergeLV) { LV.merge(MergeLV); return LV.getLinkage() == Linkage::Internal; }; auto Merge = [&](const APValue &V) { return MergeLV(getLVForValue(V, computation)); }; switch (V.getKind()) { case APValue::None: case APValue::Indeterminate: case APValue::Int: case APValue::Float: case APValue::FixedPoint: case APValue::ComplexInt: case APValue::ComplexFloat: case APValue::Vector: break; case APValue::AddrLabelDiff: // Even for an inline function, it's not reasonable to treat a difference // between the addresses of labels as an external value. return LinkageInfo::internal(); case APValue::Struct: { for (unsigned I = 0, N = V.getStructNumBases(); I != N; ++I) if (Merge(V.getStructBase(I))) break; for (unsigned I = 0, N = V.getStructNumFields(); I != N; ++I) if (Merge(V.getStructField(I))) break; break; } case APValue::Union: if (V.getUnionField()) Merge(V.getUnionValue()); break; case APValue::Array: { for (unsigned I = 0, N = V.getArrayInitializedElts(); I != N; ++I) if (Merge(V.getArrayInitializedElt(I))) break; if (V.hasArrayFiller()) Merge(V.getArrayFiller()); break; } case APValue::LValue: { if (!V.getLValueBase()) { // Null or absolute address: this is external. } else if (const auto *VD = V.getLValueBase().dyn_cast()) { if (VD && MergeLV(getLVForDecl(VD, computation))) break; } else if (const auto TI = V.getLValueBase().dyn_cast()) { if (MergeLV(getLVForType(*TI.getType(), computation))) break; } else if (const Expr *E = V.getLValueBase().dyn_cast()) { // Almost all expression bases are internal. The exception is // lifetime-extended temporaries. // FIXME: These should be modeled as having the // LifetimeExtendedTemporaryDecl itself as the base. // FIXME: If we permit Objective-C object literals in template arguments, // they should not imply internal linkage. auto *MTE = dyn_cast(E); if (!MTE || MTE->getStorageDuration() == SD_FullExpression) return LinkageInfo::internal(); if (MergeLV(getLVForDecl(MTE->getExtendingDecl(), computation))) break; } else { assert(V.getLValueBase().is() && "unexpected LValueBase kind"); return LinkageInfo::internal(); } // The lvalue path doesn't matter: pointers to all subobjects always have // the same visibility as pointers to the complete object. break; } case APValue::MemberPointer: if (const NamedDecl *D = V.getMemberPointerDecl()) MergeLV(getLVForDecl(D, computation)); // Note that we could have a base-to-derived conversion here to a member of // a derived class with less linkage/visibility. That's covered by the // linkage and visibility of the value's type. break; } return LV; }