//===--- Compiler.cpp - Code generator for expressions ---*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "Compiler.h" #include "ByteCodeEmitter.h" #include "Context.h" #include "FixedPoint.h" #include "Floating.h" #include "Function.h" #include "InterpShared.h" #include "PrimType.h" #include "Program.h" #include "clang/AST/Attr.h" using namespace clang; using namespace clang::interp; using APSInt = llvm::APSInt; namespace clang { namespace interp { static std::optional getBoolValue(const Expr *E) { if (const auto *CE = dyn_cast_if_present(E); CE && CE->hasAPValueResult() && CE->getResultAPValueKind() == APValue::ValueKind::Int) { return CE->getResultAsAPSInt().getBoolValue(); } return std::nullopt; } /// Scope used to handle temporaries in toplevel variable declarations. template class DeclScope final : public LocalScope { public: DeclScope(Compiler *Ctx, const ValueDecl *VD) : LocalScope(Ctx, VD), Scope(Ctx->P), OldInitializingDecl(Ctx->InitializingDecl) { Ctx->InitializingDecl = VD; Ctx->InitStack.push_back(InitLink::Decl(VD)); } ~DeclScope() { this->Ctx->InitializingDecl = OldInitializingDecl; this->Ctx->InitStack.pop_back(); } private: Program::DeclScope Scope; const ValueDecl *OldInitializingDecl; }; /// Scope used to handle initialization methods. template class OptionScope final { public: /// Root constructor, compiling or discarding primitives. OptionScope(Compiler *Ctx, bool NewDiscardResult, bool NewInitializing) : Ctx(Ctx), OldDiscardResult(Ctx->DiscardResult), OldInitializing(Ctx->Initializing) { Ctx->DiscardResult = NewDiscardResult; Ctx->Initializing = NewInitializing; } ~OptionScope() { Ctx->DiscardResult = OldDiscardResult; Ctx->Initializing = OldInitializing; } private: /// Parent context. Compiler *Ctx; /// Old discard flag to restore. bool OldDiscardResult; bool OldInitializing; }; template bool InitLink::emit(Compiler *Ctx, const Expr *E) const { switch (Kind) { case K_This: return Ctx->emitThis(E); case K_Field: // We're assuming there's a base pointer on the stack already. return Ctx->emitGetPtrFieldPop(Offset, E); case K_Temp: return Ctx->emitGetPtrLocal(Offset, E); case K_Decl: return Ctx->visitDeclRef(D, E); case K_Elem: if (!Ctx->emitConstUint32(Offset, E)) return false; return Ctx->emitArrayElemPtrPopUint32(E); case K_RVO: return Ctx->emitRVOPtr(E); case K_InitList: return true; default: llvm_unreachable("Unhandled InitLink kind"); } return true; } /// Scope managing label targets. template class LabelScope { public: virtual ~LabelScope() {} protected: LabelScope(Compiler *Ctx) : Ctx(Ctx) {} /// Compiler instance. Compiler *Ctx; }; /// Sets the context for break/continue statements. template class LoopScope final : public LabelScope { public: using LabelTy = typename Compiler::LabelTy; using OptLabelTy = typename Compiler::OptLabelTy; LoopScope(Compiler *Ctx, LabelTy BreakLabel, LabelTy ContinueLabel) : LabelScope(Ctx), OldBreakLabel(Ctx->BreakLabel), OldContinueLabel(Ctx->ContinueLabel), OldBreakVarScope(Ctx->BreakVarScope), OldContinueVarScope(Ctx->ContinueVarScope) { this->Ctx->BreakLabel = BreakLabel; this->Ctx->ContinueLabel = ContinueLabel; this->Ctx->BreakVarScope = this->Ctx->VarScope; this->Ctx->ContinueVarScope = this->Ctx->VarScope; } ~LoopScope() { this->Ctx->BreakLabel = OldBreakLabel; this->Ctx->ContinueLabel = OldContinueLabel; this->Ctx->ContinueVarScope = OldContinueVarScope; this->Ctx->BreakVarScope = OldBreakVarScope; } private: OptLabelTy OldBreakLabel; OptLabelTy OldContinueLabel; VariableScope *OldBreakVarScope; VariableScope *OldContinueVarScope; }; // Sets the context for a switch scope, mapping labels. template class SwitchScope final : public LabelScope { public: using LabelTy = typename Compiler::LabelTy; using OptLabelTy = typename Compiler::OptLabelTy; using CaseMap = typename Compiler::CaseMap; SwitchScope(Compiler *Ctx, CaseMap &&CaseLabels, LabelTy BreakLabel, OptLabelTy DefaultLabel) : LabelScope(Ctx), OldBreakLabel(Ctx->BreakLabel), OldDefaultLabel(this->Ctx->DefaultLabel), OldCaseLabels(std::move(this->Ctx->CaseLabels)), OldLabelVarScope(Ctx->BreakVarScope) { this->Ctx->BreakLabel = BreakLabel; this->Ctx->DefaultLabel = DefaultLabel; this->Ctx->CaseLabels = std::move(CaseLabels); this->Ctx->BreakVarScope = this->Ctx->VarScope; } ~SwitchScope() { this->Ctx->BreakLabel = OldBreakLabel; this->Ctx->DefaultLabel = OldDefaultLabel; this->Ctx->CaseLabels = std::move(OldCaseLabels); this->Ctx->BreakVarScope = OldLabelVarScope; } private: OptLabelTy OldBreakLabel; OptLabelTy OldDefaultLabel; CaseMap OldCaseLabels; VariableScope *OldLabelVarScope; }; template class StmtExprScope final { public: StmtExprScope(Compiler *Ctx) : Ctx(Ctx), OldFlag(Ctx->InStmtExpr) { Ctx->InStmtExpr = true; } ~StmtExprScope() { Ctx->InStmtExpr = OldFlag; } private: Compiler *Ctx; bool OldFlag; }; } // namespace interp } // namespace clang template bool Compiler::VisitCastExpr(const CastExpr *CE) { const Expr *SubExpr = CE->getSubExpr(); if (DiscardResult) return this->delegate(SubExpr); switch (CE->getCastKind()) { case CK_LValueToRValue: { if (SubExpr->getType().isVolatileQualified()) return this->emitInvalidCast(CastKind::Volatile, /*Fatal=*/true, CE); std::optional SubExprT = classify(SubExpr->getType()); // Prepare storage for the result. if (!Initializing && !SubExprT) { std::optional LocalIndex = allocateLocal(SubExpr); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, CE)) return false; } if (!this->visit(SubExpr)) return false; if (SubExprT) return this->emitLoadPop(*SubExprT, CE); // If the subexpr type is not primitive, we need to perform a copy here. // This happens for example in C when dereferencing a pointer of struct // type. return this->emitMemcpy(CE); } case CK_DerivedToBaseMemberPointer: { assert(classifyPrim(CE->getType()) == PT_MemberPtr); assert(classifyPrim(SubExpr->getType()) == PT_MemberPtr); const auto *FromMP = SubExpr->getType()->castAs(); const auto *ToMP = CE->getType()->castAs(); unsigned DerivedOffset = Ctx.collectBaseOffset(ToMP->getMostRecentCXXRecordDecl(), FromMP->getMostRecentCXXRecordDecl()); if (!this->delegate(SubExpr)) return false; return this->emitGetMemberPtrBasePop(DerivedOffset, CE); } case CK_BaseToDerivedMemberPointer: { assert(classifyPrim(CE) == PT_MemberPtr); assert(classifyPrim(SubExpr) == PT_MemberPtr); const auto *FromMP = SubExpr->getType()->castAs(); const auto *ToMP = CE->getType()->castAs(); unsigned DerivedOffset = Ctx.collectBaseOffset(FromMP->getMostRecentCXXRecordDecl(), ToMP->getMostRecentCXXRecordDecl()); if (!this->delegate(SubExpr)) return false; return this->emitGetMemberPtrBasePop(-DerivedOffset, CE); } case CK_UncheckedDerivedToBase: case CK_DerivedToBase: { if (!this->delegate(SubExpr)) return false; const auto extractRecordDecl = [](QualType Ty) -> const CXXRecordDecl * { if (const auto *PT = dyn_cast(Ty)) return PT->getPointeeType()->getAsCXXRecordDecl(); return Ty->getAsCXXRecordDecl(); }; // FIXME: We can express a series of non-virtual casts as a single // GetPtrBasePop op. QualType CurType = SubExpr->getType(); for (const CXXBaseSpecifier *B : CE->path()) { if (B->isVirtual()) { if (!this->emitGetPtrVirtBasePop(extractRecordDecl(B->getType()), CE)) return false; CurType = B->getType(); } else { unsigned DerivedOffset = collectBaseOffset(B->getType(), CurType); if (!this->emitGetPtrBasePop( DerivedOffset, /*NullOK=*/CE->getType()->isPointerType(), CE)) return false; CurType = B->getType(); } } return true; } case CK_BaseToDerived: { if (!this->delegate(SubExpr)) return false; unsigned DerivedOffset = collectBaseOffset(SubExpr->getType(), CE->getType()); const Type *TargetType = CE->getType().getTypePtr(); if (TargetType->isPointerOrReferenceType()) TargetType = TargetType->getPointeeType().getTypePtr(); return this->emitGetPtrDerivedPop(DerivedOffset, /*NullOK=*/CE->getType()->isPointerType(), TargetType, CE); } case CK_FloatingCast: { // HLSL uses CK_FloatingCast to cast between vectors. if (!SubExpr->getType()->isFloatingType() || !CE->getType()->isFloatingType()) return false; if (!this->visit(SubExpr)) return false; const auto *TargetSemantics = &Ctx.getFloatSemantics(CE->getType()); return this->emitCastFP(TargetSemantics, getRoundingMode(CE), CE); } case CK_IntegralToFloating: { if (!CE->getType()->isRealFloatingType()) return false; if (!this->visit(SubExpr)) return false; const auto *TargetSemantics = &Ctx.getFloatSemantics(CE->getType()); return this->emitCastIntegralFloating( classifyPrim(SubExpr), TargetSemantics, getFPOptions(CE), CE); } case CK_FloatingToBoolean: { if (!SubExpr->getType()->isRealFloatingType() || !CE->getType()->isBooleanType()) return false; if (const auto *FL = dyn_cast(SubExpr)) return this->emitConstBool(FL->getValue().isNonZero(), CE); if (!this->visit(SubExpr)) return false; return this->emitCastFloatingIntegralBool(getFPOptions(CE), CE); } case CK_FloatingToIntegral: { if (!this->visit(SubExpr)) return false; PrimType ToT = classifyPrim(CE); if (ToT == PT_IntAP) return this->emitCastFloatingIntegralAP(Ctx.getBitWidth(CE->getType()), getFPOptions(CE), CE); if (ToT == PT_IntAPS) return this->emitCastFloatingIntegralAPS(Ctx.getBitWidth(CE->getType()), getFPOptions(CE), CE); return this->emitCastFloatingIntegral(ToT, getFPOptions(CE), CE); } case CK_NullToPointer: case CK_NullToMemberPointer: { if (!this->discard(SubExpr)) return false; const Descriptor *Desc = nullptr; const QualType PointeeType = CE->getType()->getPointeeType(); if (!PointeeType.isNull()) { if (std::optional T = classify(PointeeType)) Desc = P.createDescriptor(SubExpr, *T); else Desc = P.createDescriptor(SubExpr, PointeeType.getTypePtr(), std::nullopt, /*IsConst=*/true); } uint64_t Val = Ctx.getASTContext().getTargetNullPointerValue(CE->getType()); return this->emitNull(classifyPrim(CE->getType()), Val, Desc, CE); } case CK_PointerToIntegral: { if (!this->visit(SubExpr)) return false; // If SubExpr doesn't result in a pointer, make it one. if (PrimType FromT = classifyPrim(SubExpr->getType()); FromT != PT_Ptr) { assert(isPtrType(FromT)); if (!this->emitDecayPtr(FromT, PT_Ptr, CE)) return false; } PrimType T = classifyPrim(CE->getType()); if (T == PT_IntAP) return this->emitCastPointerIntegralAP(Ctx.getBitWidth(CE->getType()), CE); if (T == PT_IntAPS) return this->emitCastPointerIntegralAPS(Ctx.getBitWidth(CE->getType()), CE); return this->emitCastPointerIntegral(T, CE); } case CK_ArrayToPointerDecay: { if (!this->visit(SubExpr)) return false; return this->emitArrayDecay(CE); } case CK_IntegralToPointer: { QualType IntType = SubExpr->getType(); assert(IntType->isIntegralOrEnumerationType()); if (!this->visit(SubExpr)) return false; // FIXME: I think the discard is wrong since the int->ptr cast might cause a // diagnostic. PrimType T = classifyPrim(IntType); QualType PtrType = CE->getType(); const Descriptor *Desc; if (std::optional T = classify(PtrType->getPointeeType())) Desc = P.createDescriptor(SubExpr, *T); else if (PtrType->getPointeeType()->isVoidType()) Desc = nullptr; else Desc = P.createDescriptor(CE, PtrType->getPointeeType().getTypePtr(), Descriptor::InlineDescMD, /*IsConst=*/true); if (!this->emitGetIntPtr(T, Desc, CE)) return false; PrimType DestPtrT = classifyPrim(PtrType); if (DestPtrT == PT_Ptr) return true; // In case we're converting the integer to a non-Pointer. return this->emitDecayPtr(PT_Ptr, DestPtrT, CE); } case CK_AtomicToNonAtomic: case CK_ConstructorConversion: case CK_FunctionToPointerDecay: case CK_NonAtomicToAtomic: case CK_NoOp: case CK_UserDefinedConversion: case CK_AddressSpaceConversion: case CK_CPointerToObjCPointerCast: return this->delegate(SubExpr); case CK_BitCast: { // Reject bitcasts to atomic types. if (CE->getType()->isAtomicType()) { if (!this->discard(SubExpr)) return false; return this->emitInvalidCast(CastKind::Reinterpret, /*Fatal=*/true, CE); } QualType SubExprTy = SubExpr->getType(); std::optional FromT = classify(SubExprTy); // Casts from integer/vector to vector. if (CE->getType()->isVectorType()) return this->emitBuiltinBitCast(CE); std::optional ToT = classify(CE->getType()); if (!FromT || !ToT) return false; assert(isPtrType(*FromT)); assert(isPtrType(*ToT)); if (FromT == ToT) { if (CE->getType()->isVoidPointerType()) return this->delegate(SubExpr); if (!this->visit(SubExpr)) return false; if (CE->getType()->isFunctionPointerType()) return true; if (FromT == PT_Ptr) return this->emitPtrPtrCast(SubExprTy->isVoidPointerType(), CE); return true; } if (!this->visit(SubExpr)) return false; return this->emitDecayPtr(*FromT, *ToT, CE); } case CK_IntegralToBoolean: case CK_FixedPointToBoolean: { // HLSL uses this to cast to one-element vectors. std::optional FromT = classify(SubExpr->getType()); if (!FromT) return false; if (const auto *IL = dyn_cast(SubExpr)) return this->emitConst(IL->getValue(), CE); if (!this->visit(SubExpr)) return false; return this->emitCast(*FromT, classifyPrim(CE), CE); } case CK_BooleanToSignedIntegral: case CK_IntegralCast: { std::optional FromT = classify(SubExpr->getType()); std::optional ToT = classify(CE->getType()); if (!FromT || !ToT) return false; // Try to emit a casted known constant value directly. if (const auto *IL = dyn_cast(SubExpr)) { if (ToT != PT_IntAP && ToT != PT_IntAPS && FromT != PT_IntAP && FromT != PT_IntAPS && !CE->getType()->isEnumeralType()) return this->emitConst(IL->getValue(), CE); if (!this->emitConst(IL->getValue(), SubExpr)) return false; } else { if (!this->visit(SubExpr)) return false; } // Possibly diagnose casts to enum types if the target type does not // have a fixed size. if (Ctx.getLangOpts().CPlusPlus && CE->getType()->isEnumeralType()) { if (const auto *ET = CE->getType().getCanonicalType()->castAs(); !ET->getDecl()->isFixed()) { if (!this->emitCheckEnumValue(*FromT, ET->getDecl(), CE)) return false; } } if (ToT == PT_IntAP) { if (!this->emitCastAP(*FromT, Ctx.getBitWidth(CE->getType()), CE)) return false; } else if (ToT == PT_IntAPS) { if (!this->emitCastAPS(*FromT, Ctx.getBitWidth(CE->getType()), CE)) return false; } else { if (FromT == ToT) return true; if (!this->emitCast(*FromT, *ToT, CE)) return false; } if (CE->getCastKind() == CK_BooleanToSignedIntegral) return this->emitNeg(*ToT, CE); return true; } case CK_PointerToBoolean: case CK_MemberPointerToBoolean: { PrimType PtrT = classifyPrim(SubExpr->getType()); if (!this->visit(SubExpr)) return false; return this->emitIsNonNull(PtrT, CE); } case CK_IntegralComplexToBoolean: case CK_FloatingComplexToBoolean: { if (!this->visit(SubExpr)) return false; return this->emitComplexBoolCast(SubExpr); } case CK_IntegralComplexToReal: case CK_FloatingComplexToReal: return this->emitComplexReal(SubExpr); case CK_IntegralRealToComplex: case CK_FloatingRealToComplex: { // We're creating a complex value here, so we need to // allocate storage for it. if (!Initializing) { std::optional LocalIndex = allocateTemporary(CE); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, CE)) return false; } PrimType T = classifyPrim(SubExpr->getType()); // Init the complex value to {SubExpr, 0}. if (!this->visitArrayElemInit(0, SubExpr, T)) return false; // Zero-init the second element. if (!this->visitZeroInitializer(T, SubExpr->getType(), SubExpr)) return false; return this->emitInitElem(T, 1, SubExpr); } case CK_IntegralComplexCast: case CK_FloatingComplexCast: case CK_IntegralComplexToFloatingComplex: case CK_FloatingComplexToIntegralComplex: { assert(CE->getType()->isAnyComplexType()); assert(SubExpr->getType()->isAnyComplexType()); if (!Initializing) { std::optional LocalIndex = allocateLocal(CE); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, CE)) return false; } // Location for the SubExpr. // Since SubExpr is of complex type, visiting it results in a pointer // anyway, so we just create a temporary pointer variable. unsigned SubExprOffset = allocateLocalPrimitive(SubExpr, PT_Ptr, /*IsConst=*/true); if (!this->visit(SubExpr)) return false; if (!this->emitSetLocal(PT_Ptr, SubExprOffset, CE)) return false; PrimType SourceElemT = classifyComplexElementType(SubExpr->getType()); QualType DestElemType = CE->getType()->getAs()->getElementType(); PrimType DestElemT = classifyPrim(DestElemType); // Cast both elements individually. for (unsigned I = 0; I != 2; ++I) { if (!this->emitGetLocal(PT_Ptr, SubExprOffset, CE)) return false; if (!this->emitArrayElemPop(SourceElemT, I, CE)) return false; // Do the cast. if (!this->emitPrimCast(SourceElemT, DestElemT, DestElemType, CE)) return false; // Save the value. if (!this->emitInitElem(DestElemT, I, CE)) return false; } return true; } case CK_VectorSplat: { assert(!classify(CE->getType())); assert(classify(SubExpr->getType())); assert(CE->getType()->isVectorType()); if (!Initializing) { std::optional LocalIndex = allocateLocal(CE); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, CE)) return false; } const auto *VT = CE->getType()->getAs(); PrimType ElemT = classifyPrim(SubExpr->getType()); unsigned ElemOffset = allocateLocalPrimitive(SubExpr, ElemT, /*IsConst=*/true); // Prepare a local variable for the scalar value. if (!this->visit(SubExpr)) return false; if (classifyPrim(SubExpr) == PT_Ptr && !this->emitLoadPop(ElemT, CE)) return false; if (!this->emitSetLocal(ElemT, ElemOffset, CE)) return false; for (unsigned I = 0; I != VT->getNumElements(); ++I) { if (!this->emitGetLocal(ElemT, ElemOffset, CE)) return false; if (!this->emitInitElem(ElemT, I, CE)) return false; } return true; } case CK_HLSLVectorTruncation: { assert(SubExpr->getType()->isVectorType()); if (std::optional ResultT = classify(CE)) { assert(!DiscardResult); // Result must be either a float or integer. Take the first element. if (!this->visit(SubExpr)) return false; return this->emitArrayElemPop(*ResultT, 0, CE); } // Otherwise, this truncates from one vector type to another. assert(CE->getType()->isVectorType()); if (!Initializing) { std::optional LocalIndex = allocateTemporary(CE); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, CE)) return false; } unsigned ToSize = CE->getType()->getAs()->getNumElements(); assert(SubExpr->getType()->getAs()->getNumElements() > ToSize); if (!this->visit(SubExpr)) return false; return this->emitCopyArray(classifyVectorElementType(CE->getType()), 0, 0, ToSize, CE); }; case CK_IntegralToFixedPoint: { if (!this->visit(SubExpr)) return false; auto Sem = Ctx.getASTContext().getFixedPointSemantics(CE->getType()).toOpaqueInt(); return this->emitCastIntegralFixedPoint(classifyPrim(SubExpr->getType()), Sem, CE); } case CK_FloatingToFixedPoint: { if (!this->visit(SubExpr)) return false; auto Sem = Ctx.getASTContext().getFixedPointSemantics(CE->getType()).toOpaqueInt(); return this->emitCastFloatingFixedPoint(Sem, CE); } case CK_FixedPointToFloating: { if (!this->visit(SubExpr)) return false; const auto *TargetSemantics = &Ctx.getFloatSemantics(CE->getType()); return this->emitCastFixedPointFloating(TargetSemantics, CE); } case CK_FixedPointToIntegral: { if (!this->visit(SubExpr)) return false; return this->emitCastFixedPointIntegral(classifyPrim(CE->getType()), CE); } case CK_FixedPointCast: { if (!this->visit(SubExpr)) return false; auto Sem = Ctx.getASTContext().getFixedPointSemantics(CE->getType()).toOpaqueInt(); return this->emitCastFixedPoint(Sem, CE); } case CK_ToVoid: return discard(SubExpr); default: return this->emitInvalid(CE); } llvm_unreachable("Unhandled clang::CastKind enum"); } template bool Compiler::VisitBuiltinBitCastExpr(const BuiltinBitCastExpr *E) { return this->emitBuiltinBitCast(E); } template bool Compiler::VisitIntegerLiteral(const IntegerLiteral *LE) { if (DiscardResult) return true; return this->emitConst(LE->getValue(), LE); } template bool Compiler::VisitFloatingLiteral(const FloatingLiteral *E) { if (DiscardResult) return true; APFloat F = E->getValue(); return this->emitFloat(F, E); } template bool Compiler::VisitImaginaryLiteral(const ImaginaryLiteral *E) { assert(E->getType()->isAnyComplexType()); if (DiscardResult) return true; if (!Initializing) { std::optional LocalIndex = allocateTemporary(E); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } const Expr *SubExpr = E->getSubExpr(); PrimType SubExprT = classifyPrim(SubExpr->getType()); if (!this->visitZeroInitializer(SubExprT, SubExpr->getType(), SubExpr)) return false; if (!this->emitInitElem(SubExprT, 0, SubExpr)) return false; return this->visitArrayElemInit(1, SubExpr, SubExprT); } template bool Compiler::VisitFixedPointLiteral(const FixedPointLiteral *E) { assert(E->getType()->isFixedPointType()); assert(classifyPrim(E) == PT_FixedPoint); if (DiscardResult) return true; auto Sem = Ctx.getASTContext().getFixedPointSemantics(E->getType()); APInt Value = E->getValue(); return this->emitConstFixedPoint(FixedPoint(Value, Sem), E); } template bool Compiler::VisitParenExpr(const ParenExpr *E) { return this->delegate(E->getSubExpr()); } template bool Compiler::VisitBinaryOperator(const BinaryOperator *BO) { // Need short-circuiting for these. if (BO->isLogicalOp() && !BO->getType()->isVectorType()) return this->VisitLogicalBinOp(BO); const Expr *LHS = BO->getLHS(); const Expr *RHS = BO->getRHS(); // Handle comma operators. Just discard the LHS // and delegate to RHS. if (BO->isCommaOp()) { if (!this->discard(LHS)) return false; if (RHS->getType()->isVoidType()) return this->discard(RHS); return this->delegate(RHS); } if (BO->getType()->isAnyComplexType()) return this->VisitComplexBinOp(BO); if (BO->getType()->isVectorType()) return this->VisitVectorBinOp(BO); if ((LHS->getType()->isAnyComplexType() || RHS->getType()->isAnyComplexType()) && BO->isComparisonOp()) return this->emitComplexComparison(LHS, RHS, BO); if (LHS->getType()->isFixedPointType() || RHS->getType()->isFixedPointType()) return this->VisitFixedPointBinOp(BO); if (BO->isPtrMemOp()) { if (!this->visit(LHS)) return false; if (!this->visit(RHS)) return false; if (!this->emitToMemberPtr(BO)) return false; if (classifyPrim(BO) == PT_MemberPtr) return true; if (!this->emitCastMemberPtrPtr(BO)) return false; return DiscardResult ? this->emitPopPtr(BO) : true; } // Typecheck the args. std::optional LT = classify(LHS); std::optional RT = classify(RHS); std::optional T = classify(BO->getType()); // Special case for C++'s three-way/spaceship operator <=>, which // returns a std::{strong,weak,partial}_ordering (which is a class, so doesn't // have a PrimType). if (!T && BO->getOpcode() == BO_Cmp) { if (DiscardResult) return true; const ComparisonCategoryInfo *CmpInfo = Ctx.getASTContext().CompCategories.lookupInfoForType(BO->getType()); assert(CmpInfo); // We need a temporary variable holding our return value. if (!Initializing) { std::optional ResultIndex = this->allocateLocal(BO); if (!this->emitGetPtrLocal(*ResultIndex, BO)) return false; } if (!visit(LHS) || !visit(RHS)) return false; return this->emitCMP3(*LT, CmpInfo, BO); } if (!LT || !RT || !T) return false; // Pointer arithmetic special case. if (BO->getOpcode() == BO_Add || BO->getOpcode() == BO_Sub) { if (isPtrType(*T) || (isPtrType(*LT) && isPtrType(*RT))) return this->VisitPointerArithBinOp(BO); } // Assignments require us to evalute the RHS first. if (BO->getOpcode() == BO_Assign) { if (!visit(RHS) || !visit(LHS)) return false; // We don't support assignments in C. if (!Ctx.getLangOpts().CPlusPlus && !this->emitInvalid(BO)) return false; if (!this->emitFlip(*LT, *RT, BO)) return false; } else { if (!visit(LHS) || !visit(RHS)) return false; } // For languages such as C, cast the result of one // of our comparision opcodes to T (which is usually int). auto MaybeCastToBool = [this, T, BO](bool Result) { if (!Result) return false; if (DiscardResult) return this->emitPop(*T, BO); if (T != PT_Bool) return this->emitCast(PT_Bool, *T, BO); return true; }; auto Discard = [this, T, BO](bool Result) { if (!Result) return false; return DiscardResult ? this->emitPop(*T, BO) : true; }; switch (BO->getOpcode()) { case BO_EQ: return MaybeCastToBool(this->emitEQ(*LT, BO)); case BO_NE: return MaybeCastToBool(this->emitNE(*LT, BO)); case BO_LT: return MaybeCastToBool(this->emitLT(*LT, BO)); case BO_LE: return MaybeCastToBool(this->emitLE(*LT, BO)); case BO_GT: return MaybeCastToBool(this->emitGT(*LT, BO)); case BO_GE: return MaybeCastToBool(this->emitGE(*LT, BO)); case BO_Sub: if (BO->getType()->isFloatingType()) return Discard(this->emitSubf(getFPOptions(BO), BO)); return Discard(this->emitSub(*T, BO)); case BO_Add: if (BO->getType()->isFloatingType()) return Discard(this->emitAddf(getFPOptions(BO), BO)); return Discard(this->emitAdd(*T, BO)); case BO_Mul: if (BO->getType()->isFloatingType()) return Discard(this->emitMulf(getFPOptions(BO), BO)); return Discard(this->emitMul(*T, BO)); case BO_Rem: return Discard(this->emitRem(*T, BO)); case BO_Div: if (BO->getType()->isFloatingType()) return Discard(this->emitDivf(getFPOptions(BO), BO)); return Discard(this->emitDiv(*T, BO)); case BO_Assign: if (DiscardResult) return LHS->refersToBitField() ? this->emitStoreBitFieldPop(*T, BO) : this->emitStorePop(*T, BO); if (LHS->refersToBitField()) { if (!this->emitStoreBitField(*T, BO)) return false; } else { if (!this->emitStore(*T, BO)) return false; } // Assignments aren't necessarily lvalues in C. // Load from them in that case. if (!BO->isLValue()) return this->emitLoadPop(*T, BO); return true; case BO_And: return Discard(this->emitBitAnd(*T, BO)); case BO_Or: return Discard(this->emitBitOr(*T, BO)); case BO_Shl: return Discard(this->emitShl(*LT, *RT, BO)); case BO_Shr: return Discard(this->emitShr(*LT, *RT, BO)); case BO_Xor: return Discard(this->emitBitXor(*T, BO)); case BO_LOr: case BO_LAnd: llvm_unreachable("Already handled earlier"); default: return false; } llvm_unreachable("Unhandled binary op"); } /// Perform addition/subtraction of a pointer and an integer or /// subtraction of two pointers. template bool Compiler::VisitPointerArithBinOp(const BinaryOperator *E) { BinaryOperatorKind Op = E->getOpcode(); const Expr *LHS = E->getLHS(); const Expr *RHS = E->getRHS(); if ((Op != BO_Add && Op != BO_Sub) || (!LHS->getType()->isPointerType() && !RHS->getType()->isPointerType())) return false; std::optional LT = classify(LHS); std::optional RT = classify(RHS); if (!LT || !RT) return false; // Visit the given pointer expression and optionally convert to a PT_Ptr. auto visitAsPointer = [&](const Expr *E, PrimType T) -> bool { if (!this->visit(E)) return false; if (T != PT_Ptr) return this->emitDecayPtr(T, PT_Ptr, E); return true; }; if (LHS->getType()->isPointerType() && RHS->getType()->isPointerType()) { if (Op != BO_Sub) return false; assert(E->getType()->isIntegerType()); if (!visitAsPointer(RHS, *RT) || !visitAsPointer(LHS, *LT)) return false; PrimType IntT = classifyPrim(E->getType()); if (!this->emitSubPtr(IntT, E)) return false; return DiscardResult ? this->emitPop(IntT, E) : true; } PrimType OffsetType; if (LHS->getType()->isIntegerType()) { if (!visitAsPointer(RHS, *RT)) return false; if (!this->visit(LHS)) return false; OffsetType = *LT; } else if (RHS->getType()->isIntegerType()) { if (!visitAsPointer(LHS, *LT)) return false; if (!this->visit(RHS)) return false; OffsetType = *RT; } else { return false; } // Do the operation and optionally transform to // result pointer type. if (Op == BO_Add) { if (!this->emitAddOffset(OffsetType, E)) return false; if (classifyPrim(E) != PT_Ptr) return this->emitDecayPtr(PT_Ptr, classifyPrim(E), E); return true; } else if (Op == BO_Sub) { if (!this->emitSubOffset(OffsetType, E)) return false; if (classifyPrim(E) != PT_Ptr) return this->emitDecayPtr(PT_Ptr, classifyPrim(E), E); return true; } return false; } template bool Compiler::VisitLogicalBinOp(const BinaryOperator *E) { assert(E->isLogicalOp()); BinaryOperatorKind Op = E->getOpcode(); const Expr *LHS = E->getLHS(); const Expr *RHS = E->getRHS(); std::optional T = classify(E->getType()); if (Op == BO_LOr) { // Logical OR. Visit LHS and only evaluate RHS if LHS was FALSE. LabelTy LabelTrue = this->getLabel(); LabelTy LabelEnd = this->getLabel(); if (!this->visitBool(LHS)) return false; if (!this->jumpTrue(LabelTrue)) return false; if (!this->visitBool(RHS)) return false; if (!this->jump(LabelEnd)) return false; this->emitLabel(LabelTrue); this->emitConstBool(true, E); this->fallthrough(LabelEnd); this->emitLabel(LabelEnd); } else { assert(Op == BO_LAnd); // Logical AND. // Visit LHS. Only visit RHS if LHS was TRUE. LabelTy LabelFalse = this->getLabel(); LabelTy LabelEnd = this->getLabel(); if (!this->visitBool(LHS)) return false; if (!this->jumpFalse(LabelFalse)) return false; if (!this->visitBool(RHS)) return false; if (!this->jump(LabelEnd)) return false; this->emitLabel(LabelFalse); this->emitConstBool(false, E); this->fallthrough(LabelEnd); this->emitLabel(LabelEnd); } if (DiscardResult) return this->emitPopBool(E); // For C, cast back to integer type. assert(T); if (T != PT_Bool) return this->emitCast(PT_Bool, *T, E); return true; } template bool Compiler::VisitComplexBinOp(const BinaryOperator *E) { // Prepare storage for result. if (!Initializing) { std::optional LocalIndex = allocateTemporary(E); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } // Both LHS and RHS might _not_ be of complex type, but one of them // needs to be. const Expr *LHS = E->getLHS(); const Expr *RHS = E->getRHS(); PrimType ResultElemT = this->classifyComplexElementType(E->getType()); unsigned ResultOffset = ~0u; if (!DiscardResult) ResultOffset = this->allocateLocalPrimitive(E, PT_Ptr, /*IsConst=*/true); // Save result pointer in ResultOffset if (!this->DiscardResult) { if (!this->emitDupPtr(E)) return false; if (!this->emitSetLocal(PT_Ptr, ResultOffset, E)) return false; } QualType LHSType = LHS->getType(); if (const auto *AT = LHSType->getAs()) LHSType = AT->getValueType(); QualType RHSType = RHS->getType(); if (const auto *AT = RHSType->getAs()) RHSType = AT->getValueType(); bool LHSIsComplex = LHSType->isAnyComplexType(); unsigned LHSOffset; bool RHSIsComplex = RHSType->isAnyComplexType(); // For ComplexComplex Mul, we have special ops to make their implementation // easier. BinaryOperatorKind Op = E->getOpcode(); if (Op == BO_Mul && LHSIsComplex && RHSIsComplex) { assert(classifyPrim(LHSType->getAs()->getElementType()) == classifyPrim(RHSType->getAs()->getElementType())); PrimType ElemT = classifyPrim(LHSType->getAs()->getElementType()); if (!this->visit(LHS)) return false; if (!this->visit(RHS)) return false; return this->emitMulc(ElemT, E); } if (Op == BO_Div && RHSIsComplex) { QualType ElemQT = RHSType->getAs()->getElementType(); PrimType ElemT = classifyPrim(ElemQT); // If the LHS is not complex, we still need to do the full complex // division, so just stub create a complex value and stub it out with // the LHS and a zero. if (!LHSIsComplex) { // This is using the RHS type for the fake-complex LHS. std::optional LocalIndex = allocateTemporary(RHS); if (!LocalIndex) return false; LHSOffset = *LocalIndex; if (!this->emitGetPtrLocal(LHSOffset, E)) return false; if (!this->visit(LHS)) return false; // real is LHS if (!this->emitInitElem(ElemT, 0, E)) return false; // imag is zero if (!this->visitZeroInitializer(ElemT, ElemQT, E)) return false; if (!this->emitInitElem(ElemT, 1, E)) return false; } else { if (!this->visit(LHS)) return false; } if (!this->visit(RHS)) return false; return this->emitDivc(ElemT, E); } // Evaluate LHS and save value to LHSOffset. if (LHSType->isAnyComplexType()) { LHSOffset = this->allocateLocalPrimitive(LHS, PT_Ptr, /*IsConst=*/true); if (!this->visit(LHS)) return false; if (!this->emitSetLocal(PT_Ptr, LHSOffset, E)) return false; } else { PrimType LHST = classifyPrim(LHSType); LHSOffset = this->allocateLocalPrimitive(LHS, LHST, /*IsConst=*/true); if (!this->visit(LHS)) return false; if (!this->emitSetLocal(LHST, LHSOffset, E)) return false; } // Same with RHS. unsigned RHSOffset; if (RHSType->isAnyComplexType()) { RHSOffset = this->allocateLocalPrimitive(RHS, PT_Ptr, /*IsConst=*/true); if (!this->visit(RHS)) return false; if (!this->emitSetLocal(PT_Ptr, RHSOffset, E)) return false; } else { PrimType RHST = classifyPrim(RHSType); RHSOffset = this->allocateLocalPrimitive(RHS, RHST, /*IsConst=*/true); if (!this->visit(RHS)) return false; if (!this->emitSetLocal(RHST, RHSOffset, E)) return false; } // For both LHS and RHS, either load the value from the complex pointer, or // directly from the local variable. For index 1 (i.e. the imaginary part), // just load 0 and do the operation anyway. auto loadComplexValue = [this](bool IsComplex, bool LoadZero, unsigned ElemIndex, unsigned Offset, const Expr *E) -> bool { if (IsComplex) { if (!this->emitGetLocal(PT_Ptr, Offset, E)) return false; return this->emitArrayElemPop(classifyComplexElementType(E->getType()), ElemIndex, E); } if (ElemIndex == 0 || !LoadZero) return this->emitGetLocal(classifyPrim(E->getType()), Offset, E); return this->visitZeroInitializer(classifyPrim(E->getType()), E->getType(), E); }; // Now we can get pointers to the LHS and RHS from the offsets above. for (unsigned ElemIndex = 0; ElemIndex != 2; ++ElemIndex) { // Result pointer for the store later. if (!this->DiscardResult) { if (!this->emitGetLocal(PT_Ptr, ResultOffset, E)) return false; } // The actual operation. switch (Op) { case BO_Add: if (!loadComplexValue(LHSIsComplex, true, ElemIndex, LHSOffset, LHS)) return false; if (!loadComplexValue(RHSIsComplex, true, ElemIndex, RHSOffset, RHS)) return false; if (ResultElemT == PT_Float) { if (!this->emitAddf(getFPOptions(E), E)) return false; } else { if (!this->emitAdd(ResultElemT, E)) return false; } break; case BO_Sub: if (!loadComplexValue(LHSIsComplex, true, ElemIndex, LHSOffset, LHS)) return false; if (!loadComplexValue(RHSIsComplex, true, ElemIndex, RHSOffset, RHS)) return false; if (ResultElemT == PT_Float) { if (!this->emitSubf(getFPOptions(E), E)) return false; } else { if (!this->emitSub(ResultElemT, E)) return false; } break; case BO_Mul: if (!loadComplexValue(LHSIsComplex, false, ElemIndex, LHSOffset, LHS)) return false; if (!loadComplexValue(RHSIsComplex, false, ElemIndex, RHSOffset, RHS)) return false; if (ResultElemT == PT_Float) { if (!this->emitMulf(getFPOptions(E), E)) return false; } else { if (!this->emitMul(ResultElemT, E)) return false; } break; case BO_Div: assert(!RHSIsComplex); if (!loadComplexValue(LHSIsComplex, false, ElemIndex, LHSOffset, LHS)) return false; if (!loadComplexValue(RHSIsComplex, false, ElemIndex, RHSOffset, RHS)) return false; if (ResultElemT == PT_Float) { if (!this->emitDivf(getFPOptions(E), E)) return false; } else { if (!this->emitDiv(ResultElemT, E)) return false; } break; default: return false; } if (!this->DiscardResult) { // Initialize array element with the value we just computed. if (!this->emitInitElemPop(ResultElemT, ElemIndex, E)) return false; } else { if (!this->emitPop(ResultElemT, E)) return false; } } return true; } template bool Compiler::VisitVectorBinOp(const BinaryOperator *E) { assert(!E->isCommaOp() && "Comma op should be handled in VisitBinaryOperator"); assert(E->getType()->isVectorType()); assert(E->getLHS()->getType()->isVectorType()); assert(E->getRHS()->getType()->isVectorType()); // Prepare storage for result. if (!Initializing && !E->isCompoundAssignmentOp()) { std::optional LocalIndex = allocateTemporary(E); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } const Expr *LHS = E->getLHS(); const Expr *RHS = E->getRHS(); const auto *VecTy = E->getType()->getAs(); auto Op = E->isCompoundAssignmentOp() ? BinaryOperator::getOpForCompoundAssignment(E->getOpcode()) : E->getOpcode(); PrimType ElemT = this->classifyVectorElementType(LHS->getType()); PrimType RHSElemT = this->classifyVectorElementType(RHS->getType()); PrimType ResultElemT = this->classifyVectorElementType(E->getType()); // Evaluate LHS and save value to LHSOffset. unsigned LHSOffset = this->allocateLocalPrimitive(LHS, PT_Ptr, /*IsConst=*/true); if (!this->visit(LHS)) return false; if (!this->emitSetLocal(PT_Ptr, LHSOffset, E)) return false; // Evaluate RHS and save value to RHSOffset. unsigned RHSOffset = this->allocateLocalPrimitive(RHS, PT_Ptr, /*IsConst=*/true); if (!this->visit(RHS)) return false; if (!this->emitSetLocal(PT_Ptr, RHSOffset, E)) return false; if (E->isCompoundAssignmentOp() && !this->emitGetLocal(PT_Ptr, LHSOffset, E)) return false; // BitAdd/BitOr/BitXor/Shl/Shr doesn't support bool type, we need perform the // integer promotion. bool NeedIntPromot = ElemT == PT_Bool && (E->isBitwiseOp() || E->isShiftOp()); QualType PromotTy = Ctx.getASTContext().getPromotedIntegerType(Ctx.getASTContext().BoolTy); PrimType PromotT = classifyPrim(PromotTy); PrimType OpT = NeedIntPromot ? PromotT : ElemT; auto getElem = [=](unsigned Offset, PrimType ElemT, unsigned Index) { if (!this->emitGetLocal(PT_Ptr, Offset, E)) return false; if (!this->emitArrayElemPop(ElemT, Index, E)) return false; if (E->isLogicalOp()) { if (!this->emitPrimCast(ElemT, PT_Bool, Ctx.getASTContext().BoolTy, E)) return false; if (!this->emitPrimCast(PT_Bool, ResultElemT, VecTy->getElementType(), E)) return false; } else if (NeedIntPromot) { if (!this->emitPrimCast(ElemT, PromotT, PromotTy, E)) return false; } return true; }; #define EMIT_ARITH_OP(OP) \ { \ if (ElemT == PT_Float) { \ if (!this->emit##OP##f(getFPOptions(E), E)) \ return false; \ } else { \ if (!this->emit##OP(ElemT, E)) \ return false; \ } \ break; \ } for (unsigned I = 0; I != VecTy->getNumElements(); ++I) { if (!getElem(LHSOffset, ElemT, I)) return false; if (!getElem(RHSOffset, RHSElemT, I)) return false; switch (Op) { case BO_Add: EMIT_ARITH_OP(Add) case BO_Sub: EMIT_ARITH_OP(Sub) case BO_Mul: EMIT_ARITH_OP(Mul) case BO_Div: EMIT_ARITH_OP(Div) case BO_Rem: if (!this->emitRem(ElemT, E)) return false; break; case BO_And: if (!this->emitBitAnd(OpT, E)) return false; break; case BO_Or: if (!this->emitBitOr(OpT, E)) return false; break; case BO_Xor: if (!this->emitBitXor(OpT, E)) return false; break; case BO_Shl: if (!this->emitShl(OpT, RHSElemT, E)) return false; break; case BO_Shr: if (!this->emitShr(OpT, RHSElemT, E)) return false; break; case BO_EQ: if (!this->emitEQ(ElemT, E)) return false; break; case BO_NE: if (!this->emitNE(ElemT, E)) return false; break; case BO_LE: if (!this->emitLE(ElemT, E)) return false; break; case BO_LT: if (!this->emitLT(ElemT, E)) return false; break; case BO_GE: if (!this->emitGE(ElemT, E)) return false; break; case BO_GT: if (!this->emitGT(ElemT, E)) return false; break; case BO_LAnd: // a && b is equivalent to a!=0 & b!=0 if (!this->emitBitAnd(ResultElemT, E)) return false; break; case BO_LOr: // a || b is equivalent to a!=0 | b!=0 if (!this->emitBitOr(ResultElemT, E)) return false; break; default: return this->emitInvalid(E); } // The result of the comparison is a vector of the same width and number // of elements as the comparison operands with a signed integral element // type. // // https://gcc.gnu.org/onlinedocs/gcc/Vector-Extensions.html if (E->isComparisonOp()) { if (!this->emitPrimCast(PT_Bool, ResultElemT, VecTy->getElementType(), E)) return false; if (!this->emitNeg(ResultElemT, E)) return false; } // If we performed an integer promotion, we need to cast the compute result // into result vector element type. if (NeedIntPromot && !this->emitPrimCast(PromotT, ResultElemT, VecTy->getElementType(), E)) return false; // Initialize array element with the value we just computed. if (!this->emitInitElem(ResultElemT, I, E)) return false; } if (DiscardResult && E->isCompoundAssignmentOp() && !this->emitPopPtr(E)) return false; return true; } template bool Compiler::VisitFixedPointBinOp(const BinaryOperator *E) { const Expr *LHS = E->getLHS(); const Expr *RHS = E->getRHS(); const ASTContext &ASTCtx = Ctx.getASTContext(); assert(LHS->getType()->isFixedPointType() || RHS->getType()->isFixedPointType()); auto LHSSema = ASTCtx.getFixedPointSemantics(LHS->getType()); auto LHSSemaInt = LHSSema.toOpaqueInt(); auto RHSSema = ASTCtx.getFixedPointSemantics(RHS->getType()); auto RHSSemaInt = RHSSema.toOpaqueInt(); if (!this->visit(LHS)) return false; if (!LHS->getType()->isFixedPointType()) { if (!this->emitCastIntegralFixedPoint(classifyPrim(LHS->getType()), LHSSemaInt, E)) return false; } if (!this->visit(RHS)) return false; if (!RHS->getType()->isFixedPointType()) { if (!this->emitCastIntegralFixedPoint(classifyPrim(RHS->getType()), RHSSemaInt, E)) return false; } // Convert the result to the target semantics. auto ConvertResult = [&](bool R) -> bool { if (!R) return false; auto ResultSema = ASTCtx.getFixedPointSemantics(E->getType()).toOpaqueInt(); auto CommonSema = LHSSema.getCommonSemantics(RHSSema).toOpaqueInt(); if (ResultSema != CommonSema) return this->emitCastFixedPoint(ResultSema, E); return true; }; auto MaybeCastToBool = [&](bool Result) { if (!Result) return false; PrimType T = classifyPrim(E); if (DiscardResult) return this->emitPop(T, E); if (T != PT_Bool) return this->emitCast(PT_Bool, T, E); return true; }; switch (E->getOpcode()) { case BO_EQ: return MaybeCastToBool(this->emitEQFixedPoint(E)); case BO_NE: return MaybeCastToBool(this->emitNEFixedPoint(E)); case BO_LT: return MaybeCastToBool(this->emitLTFixedPoint(E)); case BO_LE: return MaybeCastToBool(this->emitLEFixedPoint(E)); case BO_GT: return MaybeCastToBool(this->emitGTFixedPoint(E)); case BO_GE: return MaybeCastToBool(this->emitGEFixedPoint(E)); case BO_Add: return ConvertResult(this->emitAddFixedPoint(E)); case BO_Sub: return ConvertResult(this->emitSubFixedPoint(E)); case BO_Mul: return ConvertResult(this->emitMulFixedPoint(E)); case BO_Div: return ConvertResult(this->emitDivFixedPoint(E)); case BO_Shl: return ConvertResult(this->emitShiftFixedPoint(/*Left=*/true, E)); case BO_Shr: return ConvertResult(this->emitShiftFixedPoint(/*Left=*/false, E)); default: return this->emitInvalid(E); } llvm_unreachable("unhandled binop opcode"); } template bool Compiler::VisitFixedPointUnaryOperator(const UnaryOperator *E) { const Expr *SubExpr = E->getSubExpr(); assert(SubExpr->getType()->isFixedPointType()); switch (E->getOpcode()) { case UO_Plus: return this->delegate(SubExpr); case UO_Minus: if (!this->visit(SubExpr)) return false; return this->emitNegFixedPoint(E); default: return false; } llvm_unreachable("Unhandled unary opcode"); } template bool Compiler::VisitImplicitValueInitExpr( const ImplicitValueInitExpr *E) { QualType QT = E->getType(); if (std::optional T = classify(QT)) return this->visitZeroInitializer(*T, QT, E); if (QT->isRecordType()) { const RecordDecl *RD = QT->getAsRecordDecl(); assert(RD); if (RD->isInvalidDecl()) return false; if (const auto *CXXRD = dyn_cast(RD); CXXRD && CXXRD->getNumVBases() > 0) { // TODO: Diagnose. return false; } const Record *R = getRecord(QT); if (!R) return false; assert(Initializing); return this->visitZeroRecordInitializer(R, E); } if (QT->isIncompleteArrayType()) return true; if (QT->isArrayType()) return this->visitZeroArrayInitializer(QT, E); if (const auto *ComplexTy = E->getType()->getAs()) { assert(Initializing); QualType ElemQT = ComplexTy->getElementType(); PrimType ElemT = classifyPrim(ElemQT); for (unsigned I = 0; I < 2; ++I) { if (!this->visitZeroInitializer(ElemT, ElemQT, E)) return false; if (!this->emitInitElem(ElemT, I, E)) return false; } return true; } if (const auto *VecT = E->getType()->getAs()) { unsigned NumVecElements = VecT->getNumElements(); QualType ElemQT = VecT->getElementType(); PrimType ElemT = classifyPrim(ElemQT); for (unsigned I = 0; I < NumVecElements; ++I) { if (!this->visitZeroInitializer(ElemT, ElemQT, E)) return false; if (!this->emitInitElem(ElemT, I, E)) return false; } return true; } return false; } template bool Compiler::VisitArraySubscriptExpr(const ArraySubscriptExpr *E) { const Expr *LHS = E->getLHS(); const Expr *RHS = E->getRHS(); const Expr *Index = E->getIdx(); const Expr *Base = E->getBase(); // C++17's rules require us to evaluate the LHS first, regardless of which // side is the base. bool Success = true; for (const Expr *SubExpr : {LHS, RHS}) { if (!this->visit(SubExpr)) { Success = false; continue; } // Expand the base if this is a subscript on a // pointer expression. if (SubExpr == Base && Base->getType()->isPointerType()) { if (!this->emitExpandPtr(E)) Success = false; } } if (!Success) return false; std::optional IndexT = classify(Index->getType()); // In error-recovery cases, the index expression has a dependent type. if (!IndexT) return this->emitError(E); // If the index is first, we need to change that. if (LHS == Index) { if (!this->emitFlip(PT_Ptr, *IndexT, E)) return false; } if (!this->emitArrayElemPtrPop(*IndexT, E)) return false; if (DiscardResult) return this->emitPopPtr(E); return true; } template bool Compiler::visitInitList(ArrayRef Inits, const Expr *ArrayFiller, const Expr *E) { InitLinkScope ILS(this, InitLink::InitList()); QualType QT = E->getType(); if (const auto *AT = QT->getAs()) QT = AT->getValueType(); if (QT->isVoidType()) { if (Inits.size() == 0) return true; return this->emitInvalid(E); } // Handle discarding first. if (DiscardResult) { for (const Expr *Init : Inits) { if (!this->discard(Init)) return false; } return true; } // Primitive values. if (std::optional T = classify(QT)) { assert(!DiscardResult); if (Inits.size() == 0) return this->visitZeroInitializer(*T, QT, E); assert(Inits.size() == 1); return this->delegate(Inits[0]); } if (QT->isRecordType()) { const Record *R = getRecord(QT); if (Inits.size() == 1 && E->getType() == Inits[0]->getType()) return this->delegate(Inits[0]); auto initPrimitiveField = [=](const Record::Field *FieldToInit, const Expr *Init, PrimType T) -> bool { InitStackScope ISS(this, isa(Init)); InitLinkScope ILS(this, InitLink::Field(FieldToInit->Offset)); if (!this->visit(Init)) return false; if (FieldToInit->isBitField()) return this->emitInitBitField(T, FieldToInit, E); return this->emitInitField(T, FieldToInit->Offset, E); }; auto initCompositeField = [=](const Record::Field *FieldToInit, const Expr *Init) -> bool { InitStackScope ISS(this, isa(Init)); InitLinkScope ILS(this, InitLink::Field(FieldToInit->Offset)); // Non-primitive case. Get a pointer to the field-to-initialize // on the stack and recurse into visitInitializer(). if (!this->emitGetPtrField(FieldToInit->Offset, Init)) return false; if (!this->visitInitializer(Init)) return false; return this->emitPopPtr(E); }; if (R->isUnion()) { if (Inits.size() == 0) { if (!this->visitZeroRecordInitializer(R, E)) return false; } else { const Expr *Init = Inits[0]; const FieldDecl *FToInit = nullptr; if (const auto *ILE = dyn_cast(E)) FToInit = ILE->getInitializedFieldInUnion(); else FToInit = cast(E)->getInitializedFieldInUnion(); const Record::Field *FieldToInit = R->getField(FToInit); if (std::optional T = classify(Init)) { if (!initPrimitiveField(FieldToInit, Init, *T)) return false; } else { if (!initCompositeField(FieldToInit, Init)) return false; } } return this->emitFinishInit(E); } assert(!R->isUnion()); unsigned InitIndex = 0; for (const Expr *Init : Inits) { // Skip unnamed bitfields. while (InitIndex < R->getNumFields() && R->getField(InitIndex)->isUnnamedBitField()) ++InitIndex; if (std::optional T = classify(Init)) { const Record::Field *FieldToInit = R->getField(InitIndex); if (!initPrimitiveField(FieldToInit, Init, *T)) return false; ++InitIndex; } else { // Initializer for a direct base class. if (const Record::Base *B = R->getBase(Init->getType())) { if (!this->emitGetPtrBase(B->Offset, Init)) return false; if (!this->visitInitializer(Init)) return false; if (!this->emitFinishInitPop(E)) return false; // Base initializers don't increase InitIndex, since they don't count // into the Record's fields. } else { const Record::Field *FieldToInit = R->getField(InitIndex); if (!initCompositeField(FieldToInit, Init)) return false; ++InitIndex; } } } return this->emitFinishInit(E); } if (QT->isArrayType()) { if (Inits.size() == 1 && QT == Inits[0]->getType()) return this->delegate(Inits[0]); const ConstantArrayType *CAT = Ctx.getASTContext().getAsConstantArrayType(QT); uint64_t NumElems = CAT->getZExtSize(); if (!this->emitCheckArraySize(NumElems, E)) return false; std::optional InitT = classify(CAT->getElementType()); unsigned ElementIndex = 0; for (const Expr *Init : Inits) { if (const auto *EmbedS = dyn_cast(Init->IgnoreParenImpCasts())) { PrimType TargetT = classifyPrim(Init->getType()); auto Eval = [&](const Expr *Init, unsigned ElemIndex) { PrimType InitT = classifyPrim(Init->getType()); if (!this->visit(Init)) return false; if (InitT != TargetT) { if (!this->emitCast(InitT, TargetT, E)) return false; } return this->emitInitElem(TargetT, ElemIndex, Init); }; if (!EmbedS->doForEachDataElement(Eval, ElementIndex)) return false; } else { if (!this->visitArrayElemInit(ElementIndex, Init, InitT)) return false; ++ElementIndex; } } // Expand the filler expression. // FIXME: This should go away. if (ArrayFiller) { for (; ElementIndex != NumElems; ++ElementIndex) { if (!this->visitArrayElemInit(ElementIndex, ArrayFiller, InitT)) return false; } } return this->emitFinishInit(E); } if (const auto *ComplexTy = QT->getAs()) { unsigned NumInits = Inits.size(); if (NumInits == 1) return this->delegate(Inits[0]); QualType ElemQT = ComplexTy->getElementType(); PrimType ElemT = classifyPrim(ElemQT); if (NumInits == 0) { // Zero-initialize both elements. for (unsigned I = 0; I < 2; ++I) { if (!this->visitZeroInitializer(ElemT, ElemQT, E)) return false; if (!this->emitInitElem(ElemT, I, E)) return false; } } else if (NumInits == 2) { unsigned InitIndex = 0; for (const Expr *Init : Inits) { if (!this->visit(Init)) return false; if (!this->emitInitElem(ElemT, InitIndex, E)) return false; ++InitIndex; } } return true; } if (const auto *VecT = QT->getAs()) { unsigned NumVecElements = VecT->getNumElements(); assert(NumVecElements >= Inits.size()); QualType ElemQT = VecT->getElementType(); PrimType ElemT = classifyPrim(ElemQT); // All initializer elements. unsigned InitIndex = 0; for (const Expr *Init : Inits) { if (!this->visit(Init)) return false; // If the initializer is of vector type itself, we have to deconstruct // that and initialize all the target fields from the initializer fields. if (const auto *InitVecT = Init->getType()->getAs()) { if (!this->emitCopyArray(ElemT, 0, InitIndex, InitVecT->getNumElements(), E)) return false; InitIndex += InitVecT->getNumElements(); } else { if (!this->emitInitElem(ElemT, InitIndex, E)) return false; ++InitIndex; } } assert(InitIndex <= NumVecElements); // Fill the rest with zeroes. for (; InitIndex != NumVecElements; ++InitIndex) { if (!this->visitZeroInitializer(ElemT, ElemQT, E)) return false; if (!this->emitInitElem(ElemT, InitIndex, E)) return false; } return true; } return false; } /// Pointer to the array(not the element!) must be on the stack when calling /// this. template bool Compiler::visitArrayElemInit(unsigned ElemIndex, const Expr *Init, std::optional InitT) { if (InitT) { // Visit the primitive element like normal. if (!this->visit(Init)) return false; return this->emitInitElem(*InitT, ElemIndex, Init); } InitLinkScope ILS(this, InitLink::Elem(ElemIndex)); // Advance the pointer currently on the stack to the given // dimension. if (!this->emitConstUint32(ElemIndex, Init)) return false; if (!this->emitArrayElemPtrUint32(Init)) return false; if (!this->visitInitializer(Init)) return false; return this->emitFinishInitPop(Init); } template bool Compiler::visitCallArgs(ArrayRef Args, const FunctionDecl *FuncDecl) { assert(VarScope->getKind() == ScopeKind::Call); llvm::BitVector NonNullArgs = collectNonNullArgs(FuncDecl, Args); unsigned ArgIndex = 0; for (const Expr *Arg : Args) { if (std::optional T = classify(Arg)) { if (!this->visit(Arg)) return false; } else { std::optional LocalIndex = allocateLocal( Arg, Arg->getType(), /*ExtendingDecl=*/nullptr, ScopeKind::Call); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, Arg)) return false; InitLinkScope ILS(this, InitLink::Temp(*LocalIndex)); if (!this->visitInitializer(Arg)) return false; } if (FuncDecl && NonNullArgs[ArgIndex]) { PrimType ArgT = classify(Arg).value_or(PT_Ptr); if (ArgT == PT_Ptr) { if (!this->emitCheckNonNullArg(ArgT, Arg)) return false; } } ++ArgIndex; } return true; } template bool Compiler::VisitInitListExpr(const InitListExpr *E) { return this->visitInitList(E->inits(), E->getArrayFiller(), E); } template bool Compiler::VisitCXXParenListInitExpr( const CXXParenListInitExpr *E) { return this->visitInitList(E->getInitExprs(), E->getArrayFiller(), E); } template bool Compiler::VisitSubstNonTypeTemplateParmExpr( const SubstNonTypeTemplateParmExpr *E) { return this->delegate(E->getReplacement()); } template bool Compiler::VisitConstantExpr(const ConstantExpr *E) { std::optional T = classify(E->getType()); if (T && E->hasAPValueResult()) { // Try to emit the APValue directly, without visiting the subexpr. // This will only fail if we can't emit the APValue, so won't emit any // diagnostics or any double values. if (DiscardResult) return true; if (this->visitAPValue(E->getAPValueResult(), *T, E)) return true; } return this->delegate(E->getSubExpr()); } template bool Compiler::VisitEmbedExpr(const EmbedExpr *E) { auto It = E->begin(); return this->visit(*It); } static CharUnits AlignOfType(QualType T, const ASTContext &ASTCtx, UnaryExprOrTypeTrait Kind) { bool AlignOfReturnsPreferred = ASTCtx.getLangOpts().getClangABICompat() <= LangOptions::ClangABI::Ver7; // C++ [expr.alignof]p3: // When alignof is applied to a reference type, the result is the // alignment of the referenced type. if (const auto *Ref = T->getAs()) T = Ref->getPointeeType(); if (T.getQualifiers().hasUnaligned()) return CharUnits::One(); // __alignof is defined to return the preferred alignment. // Before 8, clang returned the preferred alignment for alignof and // _Alignof as well. if (Kind == UETT_PreferredAlignOf || AlignOfReturnsPreferred) return ASTCtx.toCharUnitsFromBits(ASTCtx.getPreferredTypeAlign(T)); return ASTCtx.getTypeAlignInChars(T); } template bool Compiler::VisitUnaryExprOrTypeTraitExpr( const UnaryExprOrTypeTraitExpr *E) { UnaryExprOrTypeTrait Kind = E->getKind(); const ASTContext &ASTCtx = Ctx.getASTContext(); if (Kind == UETT_SizeOf || Kind == UETT_DataSizeOf) { QualType ArgType = E->getTypeOfArgument(); // C++ [expr.sizeof]p2: "When applied to a reference or a reference type, // the result is the size of the referenced type." if (const auto *Ref = ArgType->getAs()) ArgType = Ref->getPointeeType(); CharUnits Size; if (ArgType->isVoidType() || ArgType->isFunctionType()) Size = CharUnits::One(); else { if (ArgType->isDependentType() || !ArgType->isConstantSizeType()) return this->emitInvalid(E); if (Kind == UETT_SizeOf) Size = ASTCtx.getTypeSizeInChars(ArgType); else Size = ASTCtx.getTypeInfoDataSizeInChars(ArgType).Width; } if (DiscardResult) return true; return this->emitConst(Size.getQuantity(), E); } if (Kind == UETT_CountOf) { QualType Ty = E->getTypeOfArgument(); assert(Ty->isArrayType()); // We don't need to worry about array element qualifiers, so getting the // unsafe array type is fine. if (const auto *CAT = dyn_cast(Ty->getAsArrayTypeUnsafe())) { if (DiscardResult) return true; return this->emitConst(CAT->getSize(), E); } assert(!Ty->isConstantSizeType()); // If it's a variable-length array type, we need to check whether it is a // multidimensional array. If so, we need to check the size expression of // the VLA to see if it's a constant size. If so, we can return that value. const auto *VAT = ASTCtx.getAsVariableArrayType(Ty); assert(VAT); if (VAT->getElementType()->isArrayType()) { std::optional Res = VAT->getSizeExpr()->getIntegerConstantExpr(ASTCtx); if (Res) { if (DiscardResult) return true; return this->emitConst(*Res, E); } } } if (Kind == UETT_AlignOf || Kind == UETT_PreferredAlignOf) { CharUnits Size; if (E->isArgumentType()) { QualType ArgType = E->getTypeOfArgument(); Size = AlignOfType(ArgType, ASTCtx, Kind); } else { // Argument is an expression, not a type. const Expr *Arg = E->getArgumentExpr()->IgnoreParens(); // The kinds of expressions that we have special-case logic here for // should be kept up to date with the special checks for those // expressions in Sema. // alignof decl is always accepted, even if it doesn't make sense: we // default to 1 in those cases. if (const auto *DRE = dyn_cast(Arg)) Size = ASTCtx.getDeclAlign(DRE->getDecl(), /*RefAsPointee*/ true); else if (const auto *ME = dyn_cast(Arg)) Size = ASTCtx.getDeclAlign(ME->getMemberDecl(), /*RefAsPointee*/ true); else Size = AlignOfType(Arg->getType(), ASTCtx, Kind); } if (DiscardResult) return true; return this->emitConst(Size.getQuantity(), E); } if (Kind == UETT_VectorElements) { if (const auto *VT = E->getTypeOfArgument()->getAs()) return this->emitConst(VT->getNumElements(), E); assert(E->getTypeOfArgument()->isSizelessVectorType()); return this->emitSizelessVectorElementSize(E); } if (Kind == UETT_VecStep) { if (const auto *VT = E->getTypeOfArgument()->getAs()) { unsigned N = VT->getNumElements(); // The vec_step built-in functions that take a 3-component // vector return 4. (OpenCL 1.1 spec 6.11.12) if (N == 3) N = 4; return this->emitConst(N, E); } return this->emitConst(1, E); } if (Kind == UETT_OpenMPRequiredSimdAlign) { assert(E->isArgumentType()); unsigned Bits = ASTCtx.getOpenMPDefaultSimdAlign(E->getArgumentType()); return this->emitConst(ASTCtx.toCharUnitsFromBits(Bits).getQuantity(), E); } if (Kind == UETT_PtrAuthTypeDiscriminator) { if (E->getArgumentType()->isDependentType()) return this->emitInvalid(E); return this->emitConst( const_cast(ASTCtx).getPointerAuthTypeDiscriminator( E->getArgumentType()), E); } return false; } template bool Compiler::VisitMemberExpr(const MemberExpr *E) { // 'Base.Member' const Expr *Base = E->getBase(); const ValueDecl *Member = E->getMemberDecl(); if (DiscardResult) return this->discard(Base); // MemberExprs are almost always lvalues, in which case we don't need to // do the load. But sometimes they aren't. const auto maybeLoadValue = [&]() -> bool { if (E->isGLValue()) return true; if (std::optional T = classify(E)) return this->emitLoadPop(*T, E); return false; }; if (const auto *VD = dyn_cast(Member)) { // I am almost confident in saying that a var decl must be static // and therefore registered as a global variable. But this will probably // turn out to be wrong some time in the future, as always. if (auto GlobalIndex = P.getGlobal(VD)) return this->emitGetPtrGlobal(*GlobalIndex, E) && maybeLoadValue(); return false; } if (!isa(Member)) { if (!this->discard(Base) && !this->emitSideEffect(E)) return false; return this->visitDeclRef(Member, E); } if (Initializing) { if (!this->delegate(Base)) return false; } else { if (!this->visit(Base)) return false; } // Base above gives us a pointer on the stack. const auto *FD = cast(Member); const RecordDecl *RD = FD->getParent(); const Record *R = getRecord(RD); if (!R) return false; const Record::Field *F = R->getField(FD); // Leave a pointer to the field on the stack. if (F->Decl->getType()->isReferenceType()) return this->emitGetFieldPop(PT_Ptr, F->Offset, E) && maybeLoadValue(); return this->emitGetPtrFieldPop(F->Offset, E) && maybeLoadValue(); } template bool Compiler::VisitArrayInitIndexExpr(const ArrayInitIndexExpr *E) { // ArrayIndex might not be set if a ArrayInitIndexExpr is being evaluated // stand-alone, e.g. via EvaluateAsInt(). if (!ArrayIndex) return false; return this->emitConst(*ArrayIndex, E); } template bool Compiler::VisitArrayInitLoopExpr(const ArrayInitLoopExpr *E) { assert(Initializing); assert(!DiscardResult); // We visit the common opaque expression here once so we have its value // cached. if (!this->discard(E->getCommonExpr())) return false; // TODO: This compiles to quite a lot of bytecode if the array is larger. // Investigate compiling this to a loop. const Expr *SubExpr = E->getSubExpr(); size_t Size = E->getArraySize().getZExtValue(); std::optional SubExprT = classify(SubExpr); // So, every iteration, we execute an assignment here // where the LHS is on the stack (the target array) // and the RHS is our SubExpr. for (size_t I = 0; I != Size; ++I) { ArrayIndexScope IndexScope(this, I); BlockScope BS(this); if (!this->visitArrayElemInit(I, SubExpr, SubExprT)) return false; if (!BS.destroyLocals()) return false; } return true; } template bool Compiler::VisitOpaqueValueExpr(const OpaqueValueExpr *E) { const Expr *SourceExpr = E->getSourceExpr(); if (!SourceExpr) return false; if (Initializing) return this->visitInitializer(SourceExpr); PrimType SubExprT = classify(SourceExpr).value_or(PT_Ptr); if (auto It = OpaqueExprs.find(E); It != OpaqueExprs.end()) return this->emitGetLocal(SubExprT, It->second, E); if (!this->visit(SourceExpr)) return false; // At this point we either have the evaluated source expression or a pointer // to an object on the stack. We want to create a local variable that stores // this value. unsigned LocalIndex = allocateLocalPrimitive(E, SubExprT, /*IsConst=*/true); if (!this->emitSetLocal(SubExprT, LocalIndex, E)) return false; // Here the local variable is created but the value is removed from the stack, // so we put it back if the caller needs it. if (!DiscardResult) { if (!this->emitGetLocal(SubExprT, LocalIndex, E)) return false; } // This is cleaned up when the local variable is destroyed. OpaqueExprs.insert({E, LocalIndex}); return true; } template bool Compiler::VisitAbstractConditionalOperator( const AbstractConditionalOperator *E) { const Expr *Condition = E->getCond(); const Expr *TrueExpr = E->getTrueExpr(); const Expr *FalseExpr = E->getFalseExpr(); auto visitChildExpr = [&](const Expr *E) -> bool { LocalScope S(this); if (!this->delegate(E)) return false; return S.destroyLocals(); }; if (std::optional BoolValue = getBoolValue(Condition)) { if (BoolValue) return visitChildExpr(TrueExpr); return visitChildExpr(FalseExpr); } bool IsBcpCall = false; if (const auto *CE = dyn_cast(Condition->IgnoreParenCasts()); CE && CE->getBuiltinCallee() == Builtin::BI__builtin_constant_p) { IsBcpCall = true; } LabelTy LabelEnd = this->getLabel(); // Label after the operator. LabelTy LabelFalse = this->getLabel(); // Label for the false expr. if (IsBcpCall) { if (!this->emitStartSpeculation(E)) return false; } if (!this->visitBool(Condition)) { // If the condition failed and we're checking for undefined behavior // (which only happens with EvalEmitter) check the TrueExpr and FalseExpr // as well. if (this->checkingForUndefinedBehavior()) { if (!this->discard(TrueExpr)) return false; if (!this->discard(FalseExpr)) return false; } return false; } if (!this->jumpFalse(LabelFalse)) return false; if (!visitChildExpr(TrueExpr)) return false; if (!this->jump(LabelEnd)) return false; this->emitLabel(LabelFalse); if (!visitChildExpr(FalseExpr)) return false; this->fallthrough(LabelEnd); this->emitLabel(LabelEnd); if (IsBcpCall) return this->emitEndSpeculation(E); return true; } template bool Compiler::VisitStringLiteral(const StringLiteral *E) { if (DiscardResult) return true; if (!Initializing) { unsigned StringIndex = P.createGlobalString(E); return this->emitGetPtrGlobal(StringIndex, E); } // We are initializing an array on the stack. const ConstantArrayType *CAT = Ctx.getASTContext().getAsConstantArrayType(E->getType()); assert(CAT && "a string literal that's not a constant array?"); // If the initializer string is too long, a diagnostic has already been // emitted. Read only the array length from the string literal. unsigned ArraySize = CAT->getZExtSize(); unsigned N = std::min(ArraySize, E->getLength()); unsigned CharWidth = E->getCharByteWidth(); for (unsigned I = 0; I != N; ++I) { uint32_t CodeUnit = E->getCodeUnit(I); if (CharWidth == 1) { this->emitConstSint8(CodeUnit, E); this->emitInitElemSint8(I, E); } else if (CharWidth == 2) { this->emitConstUint16(CodeUnit, E); this->emitInitElemUint16(I, E); } else if (CharWidth == 4) { this->emitConstUint32(CodeUnit, E); this->emitInitElemUint32(I, E); } else { llvm_unreachable("unsupported character width"); } } // Fill up the rest of the char array with NUL bytes. for (unsigned I = N; I != ArraySize; ++I) { if (CharWidth == 1) { this->emitConstSint8(0, E); this->emitInitElemSint8(I, E); } else if (CharWidth == 2) { this->emitConstUint16(0, E); this->emitInitElemUint16(I, E); } else if (CharWidth == 4) { this->emitConstUint32(0, E); this->emitInitElemUint32(I, E); } else { llvm_unreachable("unsupported character width"); } } return true; } template bool Compiler::VisitObjCStringLiteral(const ObjCStringLiteral *E) { if (DiscardResult) return true; return this->emitDummyPtr(E, E); } template bool Compiler::VisitObjCEncodeExpr(const ObjCEncodeExpr *E) { auto &A = Ctx.getASTContext(); std::string Str; A.getObjCEncodingForType(E->getEncodedType(), Str); StringLiteral *SL = StringLiteral::Create(A, Str, StringLiteralKind::Ordinary, /*Pascal=*/false, E->getType(), E->getAtLoc()); return this->delegate(SL); } template bool Compiler::VisitSYCLUniqueStableNameExpr( const SYCLUniqueStableNameExpr *E) { if (DiscardResult) return true; assert(!Initializing); auto &A = Ctx.getASTContext(); std::string ResultStr = E->ComputeName(A); QualType CharTy = A.CharTy.withConst(); APInt Size(A.getTypeSize(A.getSizeType()), ResultStr.size() + 1); QualType ArrayTy = A.getConstantArrayType(CharTy, Size, nullptr, ArraySizeModifier::Normal, 0); StringLiteral *SL = StringLiteral::Create(A, ResultStr, StringLiteralKind::Ordinary, /*Pascal=*/false, ArrayTy, E->getLocation()); unsigned StringIndex = P.createGlobalString(SL); return this->emitGetPtrGlobal(StringIndex, E); } template bool Compiler::VisitCharacterLiteral(const CharacterLiteral *E) { if (DiscardResult) return true; return this->emitConst(E->getValue(), E); } template bool Compiler::VisitFloatCompoundAssignOperator( const CompoundAssignOperator *E) { const Expr *LHS = E->getLHS(); const Expr *RHS = E->getRHS(); QualType LHSType = LHS->getType(); QualType LHSComputationType = E->getComputationLHSType(); QualType ResultType = E->getComputationResultType(); std::optional LT = classify(LHSComputationType); std::optional RT = classify(ResultType); assert(ResultType->isFloatingType()); if (!LT || !RT) return false; PrimType LHST = classifyPrim(LHSType); // C++17 onwards require that we evaluate the RHS first. // Compute RHS and save it in a temporary variable so we can // load it again later. if (!visit(RHS)) return false; unsigned TempOffset = this->allocateLocalPrimitive(E, *RT, /*IsConst=*/true); if (!this->emitSetLocal(*RT, TempOffset, E)) return false; // First, visit LHS. if (!visit(LHS)) return false; if (!this->emitLoad(LHST, E)) return false; // If necessary, convert LHS to its computation type. if (!this->emitPrimCast(LHST, classifyPrim(LHSComputationType), LHSComputationType, E)) return false; // Now load RHS. if (!this->emitGetLocal(*RT, TempOffset, E)) return false; switch (E->getOpcode()) { case BO_AddAssign: if (!this->emitAddf(getFPOptions(E), E)) return false; break; case BO_SubAssign: if (!this->emitSubf(getFPOptions(E), E)) return false; break; case BO_MulAssign: if (!this->emitMulf(getFPOptions(E), E)) return false; break; case BO_DivAssign: if (!this->emitDivf(getFPOptions(E), E)) return false; break; default: return false; } if (!this->emitPrimCast(classifyPrim(ResultType), LHST, LHS->getType(), E)) return false; if (DiscardResult) return this->emitStorePop(LHST, E); return this->emitStore(LHST, E); } template bool Compiler::VisitPointerCompoundAssignOperator( const CompoundAssignOperator *E) { BinaryOperatorKind Op = E->getOpcode(); const Expr *LHS = E->getLHS(); const Expr *RHS = E->getRHS(); std::optional LT = classify(LHS->getType()); std::optional RT = classify(RHS->getType()); if (Op != BO_AddAssign && Op != BO_SubAssign) return false; if (!LT || !RT) return false; if (!visit(LHS)) return false; if (!this->emitLoad(*LT, LHS)) return false; if (!visit(RHS)) return false; if (Op == BO_AddAssign) { if (!this->emitAddOffset(*RT, E)) return false; } else { if (!this->emitSubOffset(*RT, E)) return false; } if (DiscardResult) return this->emitStorePopPtr(E); return this->emitStorePtr(E); } template bool Compiler::VisitCompoundAssignOperator( const CompoundAssignOperator *E) { if (E->getType()->isVectorType()) return VisitVectorBinOp(E); const Expr *LHS = E->getLHS(); const Expr *RHS = E->getRHS(); std::optional LHSComputationT = classify(E->getComputationLHSType()); std::optional LT = classify(LHS->getType()); std::optional RT = classify(RHS->getType()); std::optional ResultT = classify(E->getType()); if (!Ctx.getLangOpts().CPlusPlus14) return this->visit(RHS) && this->visit(LHS) && this->emitError(E); if (!LT || !RT || !ResultT || !LHSComputationT) return false; // Handle floating point operations separately here, since they // require special care. if (ResultT == PT_Float || RT == PT_Float) return VisitFloatCompoundAssignOperator(E); if (E->getType()->isPointerType()) return VisitPointerCompoundAssignOperator(E); assert(!E->getType()->isPointerType() && "Handled above"); assert(!E->getType()->isFloatingType() && "Handled above"); // C++17 onwards require that we evaluate the RHS first. // Compute RHS and save it in a temporary variable so we can // load it again later. // FIXME: Compound assignments are unsequenced in C, so we might // have to figure out how to reject them. if (!visit(RHS)) return false; unsigned TempOffset = this->allocateLocalPrimitive(E, *RT, /*IsConst=*/true); if (!this->emitSetLocal(*RT, TempOffset, E)) return false; // Get LHS pointer, load its value and cast it to the // computation type if necessary. if (!visit(LHS)) return false; if (!this->emitLoad(*LT, E)) return false; if (LT != LHSComputationT) { if (!this->emitCast(*LT, *LHSComputationT, E)) return false; } // Get the RHS value on the stack. if (!this->emitGetLocal(*RT, TempOffset, E)) return false; // Perform operation. switch (E->getOpcode()) { case BO_AddAssign: if (!this->emitAdd(*LHSComputationT, E)) return false; break; case BO_SubAssign: if (!this->emitSub(*LHSComputationT, E)) return false; break; case BO_MulAssign: if (!this->emitMul(*LHSComputationT, E)) return false; break; case BO_DivAssign: if (!this->emitDiv(*LHSComputationT, E)) return false; break; case BO_RemAssign: if (!this->emitRem(*LHSComputationT, E)) return false; break; case BO_ShlAssign: if (!this->emitShl(*LHSComputationT, *RT, E)) return false; break; case BO_ShrAssign: if (!this->emitShr(*LHSComputationT, *RT, E)) return false; break; case BO_AndAssign: if (!this->emitBitAnd(*LHSComputationT, E)) return false; break; case BO_XorAssign: if (!this->emitBitXor(*LHSComputationT, E)) return false; break; case BO_OrAssign: if (!this->emitBitOr(*LHSComputationT, E)) return false; break; default: llvm_unreachable("Unimplemented compound assign operator"); } // And now cast from LHSComputationT to ResultT. if (ResultT != LHSComputationT) { if (!this->emitCast(*LHSComputationT, *ResultT, E)) return false; } // And store the result in LHS. if (DiscardResult) { if (LHS->refersToBitField()) return this->emitStoreBitFieldPop(*ResultT, E); return this->emitStorePop(*ResultT, E); } if (LHS->refersToBitField()) return this->emitStoreBitField(*ResultT, E); return this->emitStore(*ResultT, E); } template bool Compiler::VisitExprWithCleanups(const ExprWithCleanups *E) { LocalScope ES(this); const Expr *SubExpr = E->getSubExpr(); return this->delegate(SubExpr) && ES.destroyLocals(E); } template bool Compiler::VisitMaterializeTemporaryExpr( const MaterializeTemporaryExpr *E) { const Expr *SubExpr = E->getSubExpr(); if (Initializing) { // We already have a value, just initialize that. return this->delegate(SubExpr); } // If we don't end up using the materialized temporary anyway, don't // bother creating it. if (DiscardResult) return this->discard(SubExpr); // When we're initializing a global variable *or* the storage duration of // the temporary is explicitly static, create a global variable. std::optional SubExprT = classify(SubExpr); bool IsStatic = E->getStorageDuration() == SD_Static; if (IsStatic) { std::optional GlobalIndex = P.createGlobal(E); if (!GlobalIndex) return false; const LifetimeExtendedTemporaryDecl *TempDecl = E->getLifetimeExtendedTemporaryDecl(); if (IsStatic) assert(TempDecl); if (SubExprT) { if (!this->visit(SubExpr)) return false; if (IsStatic) { if (!this->emitInitGlobalTemp(*SubExprT, *GlobalIndex, TempDecl, E)) return false; } else { if (!this->emitInitGlobal(*SubExprT, *GlobalIndex, E)) return false; } return this->emitGetPtrGlobal(*GlobalIndex, E); } if (!this->checkLiteralType(SubExpr)) return false; // Non-primitive values. if (!this->emitGetPtrGlobal(*GlobalIndex, E)) return false; if (!this->visitInitializer(SubExpr)) return false; if (IsStatic) return this->emitInitGlobalTempComp(TempDecl, E); return true; } // For everyhing else, use local variables. if (SubExprT) { bool IsConst = SubExpr->getType().isConstQualified(); unsigned LocalIndex = allocateLocalPrimitive(E, *SubExprT, IsConst, E->getExtendingDecl()); if (!this->visit(SubExpr)) return false; if (!this->emitSetLocal(*SubExprT, LocalIndex, E)) return false; return this->emitGetPtrLocal(LocalIndex, E); } else { if (!this->checkLiteralType(SubExpr)) return false; const Expr *Inner = E->getSubExpr()->skipRValueSubobjectAdjustments(); if (std::optional LocalIndex = allocateLocal(E, Inner->getType(), E->getExtendingDecl())) { InitLinkScope ILS(this, InitLink::Temp(*LocalIndex)); if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; return this->visitInitializer(SubExpr) && this->emitFinishInit(E); } } return false; } template bool Compiler::VisitCXXBindTemporaryExpr( const CXXBindTemporaryExpr *E) { const Expr *SubExpr = E->getSubExpr(); if (Initializing) return this->delegate(SubExpr); // Make sure we create a temporary even if we're discarding, since that will // make sure we will also call the destructor. if (!this->visit(SubExpr)) return false; if (DiscardResult) return this->emitPopPtr(E); return true; } template bool Compiler::VisitCompoundLiteralExpr(const CompoundLiteralExpr *E) { const Expr *Init = E->getInitializer(); if (DiscardResult) return this->discard(Init); if (Initializing) { // We already have a value, just initialize that. return this->visitInitializer(Init) && this->emitFinishInit(E); } std::optional T = classify(E->getType()); if (E->isFileScope()) { // Avoid creating a variable if this is a primitive RValue anyway. if (T && !E->isLValue()) return this->delegate(Init); if (std::optional GlobalIndex = P.createGlobal(E)) { if (!this->emitGetPtrGlobal(*GlobalIndex, E)) return false; if (T) { if (!this->visit(Init)) return false; return this->emitInitGlobal(*T, *GlobalIndex, E); } return this->visitInitializer(Init) && this->emitFinishInit(E); } return false; } // Otherwise, use a local variable. if (T && !E->isLValue()) { // For primitive types, we just visit the initializer. return this->delegate(Init); } unsigned LocalIndex; if (T) LocalIndex = this->allocateLocalPrimitive(Init, *T, /*IsConst=*/false); else if (std::optional MaybeIndex = this->allocateLocal(Init)) LocalIndex = *MaybeIndex; else return false; if (!this->emitGetPtrLocal(LocalIndex, E)) return false; if (T) return this->visit(Init) && this->emitInit(*T, E); return this->visitInitializer(Init) && this->emitFinishInit(E); } template bool Compiler::VisitTypeTraitExpr(const TypeTraitExpr *E) { if (DiscardResult) return true; if (E->isStoredAsBoolean()) { if (E->getType()->isBooleanType()) return this->emitConstBool(E->getBoolValue(), E); return this->emitConst(E->getBoolValue(), E); } PrimType T = classifyPrim(E->getType()); return this->visitAPValue(E->getAPValue(), T, E); } template bool Compiler::VisitArrayTypeTraitExpr(const ArrayTypeTraitExpr *E) { if (DiscardResult) return true; return this->emitConst(E->getValue(), E); } template bool Compiler::VisitLambdaExpr(const LambdaExpr *E) { if (DiscardResult) return true; assert(Initializing); const Record *R = P.getOrCreateRecord(E->getLambdaClass()); if (!R) return false; auto *CaptureInitIt = E->capture_init_begin(); // Initialize all fields (which represent lambda captures) of the // record with their initializers. for (const Record::Field &F : R->fields()) { const Expr *Init = *CaptureInitIt; if (!Init || Init->containsErrors()) continue; ++CaptureInitIt; if (std::optional T = classify(Init)) { if (!this->visit(Init)) return false; if (!this->emitInitField(*T, F.Offset, E)) return false; } else { if (!this->emitGetPtrField(F.Offset, E)) return false; if (!this->visitInitializer(Init)) return false; if (!this->emitPopPtr(E)) return false; } } return true; } template bool Compiler::VisitPredefinedExpr(const PredefinedExpr *E) { if (DiscardResult) return true; if (!Initializing) { unsigned StringIndex = P.createGlobalString(E->getFunctionName(), E); return this->emitGetPtrGlobal(StringIndex, E); } return this->delegate(E->getFunctionName()); } template bool Compiler::VisitCXXThrowExpr(const CXXThrowExpr *E) { if (E->getSubExpr() && !this->discard(E->getSubExpr())) return false; return this->emitInvalid(E); } template bool Compiler::VisitCXXReinterpretCastExpr( const CXXReinterpretCastExpr *E) { const Expr *SubExpr = E->getSubExpr(); std::optional FromT = classify(SubExpr); std::optional ToT = classify(E); if (!FromT || !ToT) return this->emitInvalidCast(CastKind::Reinterpret, /*Fatal=*/true, E); if (FromT == PT_Ptr || ToT == PT_Ptr) { // Both types could be PT_Ptr because their expressions are glvalues. std::optional PointeeFromT; if (SubExpr->getType()->isPointerOrReferenceType()) PointeeFromT = classify(SubExpr->getType()->getPointeeType()); else PointeeFromT = classify(SubExpr->getType()); std::optional PointeeToT; if (E->getType()->isPointerOrReferenceType()) PointeeToT = classify(E->getType()->getPointeeType()); else PointeeToT = classify(E->getType()); bool Fatal = true; if (PointeeToT && PointeeFromT) { if (isIntegralType(*PointeeFromT) && isIntegralType(*PointeeToT)) Fatal = false; } else { Fatal = SubExpr->getType().getTypePtr() != E->getType().getTypePtr(); } if (!this->emitInvalidCast(CastKind::Reinterpret, Fatal, E)) return false; if (E->getCastKind() == CK_LValueBitCast) return this->delegate(SubExpr); return this->VisitCastExpr(E); } // Try to actually do the cast. bool Fatal = (ToT != FromT); if (!this->emitInvalidCast(CastKind::Reinterpret, Fatal, E)) return false; return this->VisitCastExpr(E); } template bool Compiler::VisitCXXDynamicCastExpr(const CXXDynamicCastExpr *E) { if (!Ctx.getLangOpts().CPlusPlus20) { if (!this->emitInvalidCast(CastKind::Dynamic, /*Fatal=*/false, E)) return false; } return this->VisitCastExpr(E); } template bool Compiler::VisitCXXNoexceptExpr(const CXXNoexceptExpr *E) { assert(E->getType()->isBooleanType()); if (DiscardResult) return true; return this->emitConstBool(E->getValue(), E); } template bool Compiler::VisitCXXConstructExpr(const CXXConstructExpr *E) { QualType T = E->getType(); assert(!classify(T)); if (T->isRecordType()) { const CXXConstructorDecl *Ctor = E->getConstructor(); // Trivial copy/move constructor. Avoid copy. if (Ctor->isDefaulted() && Ctor->isCopyOrMoveConstructor() && Ctor->isTrivial() && E->getArg(0)->isTemporaryObject(Ctx.getASTContext(), T->getAsCXXRecordDecl())) return this->visitInitializer(E->getArg(0)); // If we're discarding a construct expression, we still need // to allocate a variable and call the constructor and destructor. if (DiscardResult) { if (Ctor->isTrivial()) return true; assert(!Initializing); std::optional LocalIndex = allocateLocal(E); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } // Zero initialization. if (E->requiresZeroInitialization()) { const Record *R = getRecord(E->getType()); if (!this->visitZeroRecordInitializer(R, E)) return false; // If the constructor is trivial anyway, we're done. if (Ctor->isTrivial()) return true; } const Function *Func = getFunction(Ctor); if (!Func) return false; assert(Func->hasThisPointer()); assert(!Func->hasRVO()); // The This pointer is already on the stack because this is an initializer, // but we need to dup() so the call() below has its own copy. if (!this->emitDupPtr(E)) return false; // Constructor arguments. for (const auto *Arg : E->arguments()) { if (!this->visit(Arg)) return false; } if (Func->isVariadic()) { uint32_t VarArgSize = 0; unsigned NumParams = Func->getNumWrittenParams(); for (unsigned I = NumParams, N = E->getNumArgs(); I != N; ++I) { VarArgSize += align(primSize(classify(E->getArg(I)->getType()).value_or(PT_Ptr))); } if (!this->emitCallVar(Func, VarArgSize, E)) return false; } else { if (!this->emitCall(Func, 0, E)) { // When discarding, we don't need the result anyway, so clean up // the instance dup we did earlier in case surrounding code wants // to keep evaluating. if (DiscardResult) (void)this->emitPopPtr(E); return false; } } if (DiscardResult) return this->emitPopPtr(E); return this->emitFinishInit(E); } if (T->isArrayType()) { const ConstantArrayType *CAT = Ctx.getASTContext().getAsConstantArrayType(E->getType()); if (!CAT) return false; size_t NumElems = CAT->getZExtSize(); const Function *Func = getFunction(E->getConstructor()); if (!Func) return false; // FIXME(perf): We're calling the constructor once per array element here, // in the old intepreter we had a special-case for trivial constructors. for (size_t I = 0; I != NumElems; ++I) { if (!this->emitConstUint64(I, E)) return false; if (!this->emitArrayElemPtrUint64(E)) return false; // Constructor arguments. for (const auto *Arg : E->arguments()) { if (!this->visit(Arg)) return false; } if (!this->emitCall(Func, 0, E)) return false; } return true; } return false; } template bool Compiler::VisitSourceLocExpr(const SourceLocExpr *E) { if (DiscardResult) return true; const APValue Val = E->EvaluateInContext(Ctx.getASTContext(), SourceLocDefaultExpr); // Things like __builtin_LINE(). if (E->getType()->isIntegerType()) { assert(Val.isInt()); const APSInt &I = Val.getInt(); return this->emitConst(I, E); } // Otherwise, the APValue is an LValue, with only one element. // Theoretically, we don't need the APValue at all of course. assert(E->getType()->isPointerType()); assert(Val.isLValue()); const APValue::LValueBase &Base = Val.getLValueBase(); if (const Expr *LValueExpr = Base.dyn_cast()) return this->visit(LValueExpr); // Otherwise, we have a decl (which is the case for // __builtin_source_location). assert(Base.is()); assert(Val.getLValuePath().size() == 0); const auto *BaseDecl = Base.dyn_cast(); assert(BaseDecl); auto *UGCD = cast(BaseDecl); std::optional GlobalIndex = P.getOrCreateGlobal(UGCD); if (!GlobalIndex) return false; if (!this->emitGetPtrGlobal(*GlobalIndex, E)) return false; const Record *R = getRecord(E->getType()); const APValue &V = UGCD->getValue(); for (unsigned I = 0, N = R->getNumFields(); I != N; ++I) { const Record::Field *F = R->getField(I); const APValue &FieldValue = V.getStructField(I); PrimType FieldT = classifyPrim(F->Decl->getType()); if (!this->visitAPValue(FieldValue, FieldT, E)) return false; if (!this->emitInitField(FieldT, F->Offset, E)) return false; } // Leave the pointer to the global on the stack. return true; } template bool Compiler::VisitOffsetOfExpr(const OffsetOfExpr *E) { unsigned N = E->getNumComponents(); if (N == 0) return false; for (unsigned I = 0; I != N; ++I) { const OffsetOfNode &Node = E->getComponent(I); if (Node.getKind() == OffsetOfNode::Array) { const Expr *ArrayIndexExpr = E->getIndexExpr(Node.getArrayExprIndex()); PrimType IndexT = classifyPrim(ArrayIndexExpr->getType()); if (DiscardResult) { if (!this->discard(ArrayIndexExpr)) return false; continue; } if (!this->visit(ArrayIndexExpr)) return false; // Cast to Sint64. if (IndexT != PT_Sint64) { if (!this->emitCast(IndexT, PT_Sint64, E)) return false; } } } if (DiscardResult) return true; PrimType T = classifyPrim(E->getType()); return this->emitOffsetOf(T, E, E); } template bool Compiler::VisitCXXScalarValueInitExpr( const CXXScalarValueInitExpr *E) { QualType Ty = E->getType(); if (DiscardResult || Ty->isVoidType()) return true; if (std::optional T = classify(Ty)) return this->visitZeroInitializer(*T, Ty, E); if (const auto *CT = Ty->getAs()) { if (!Initializing) { std::optional LocalIndex = allocateLocal(E); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } // Initialize both fields to 0. QualType ElemQT = CT->getElementType(); PrimType ElemT = classifyPrim(ElemQT); for (unsigned I = 0; I != 2; ++I) { if (!this->visitZeroInitializer(ElemT, ElemQT, E)) return false; if (!this->emitInitElem(ElemT, I, E)) return false; } return true; } if (const auto *VT = Ty->getAs()) { // FIXME: Code duplication with the _Complex case above. if (!Initializing) { std::optional LocalIndex = allocateLocal(E); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } // Initialize all fields to 0. QualType ElemQT = VT->getElementType(); PrimType ElemT = classifyPrim(ElemQT); for (unsigned I = 0, N = VT->getNumElements(); I != N; ++I) { if (!this->visitZeroInitializer(ElemT, ElemQT, E)) return false; if (!this->emitInitElem(ElemT, I, E)) return false; } return true; } return false; } template bool Compiler::VisitSizeOfPackExpr(const SizeOfPackExpr *E) { return this->emitConst(E->getPackLength(), E); } template bool Compiler::VisitGenericSelectionExpr( const GenericSelectionExpr *E) { return this->delegate(E->getResultExpr()); } template bool Compiler::VisitChooseExpr(const ChooseExpr *E) { return this->delegate(E->getChosenSubExpr()); } template bool Compiler::VisitObjCBoolLiteralExpr(const ObjCBoolLiteralExpr *E) { if (DiscardResult) return true; return this->emitConst(E->getValue(), E); } template bool Compiler::VisitCXXInheritedCtorInitExpr( const CXXInheritedCtorInitExpr *E) { const CXXConstructorDecl *Ctor = E->getConstructor(); assert(!Ctor->isTrivial() && "Trivial CXXInheritedCtorInitExpr, implement. (possible?)"); const Function *F = this->getFunction(Ctor); assert(F); assert(!F->hasRVO()); assert(F->hasThisPointer()); if (!this->emitDupPtr(SourceInfo{})) return false; // Forward all arguments of the current function (which should be a // constructor itself) to the inherited ctor. // This is necessary because the calling code has pushed the pointer // of the correct base for us already, but the arguments need // to come after. unsigned Offset = align(primSize(PT_Ptr)); // instance pointer. for (const ParmVarDecl *PD : Ctor->parameters()) { PrimType PT = this->classify(PD->getType()).value_or(PT_Ptr); if (!this->emitGetParam(PT, Offset, E)) return false; Offset += align(primSize(PT)); } return this->emitCall(F, 0, E); } // FIXME: This function has become rather unwieldy, especially // the part where we initialize an array allocation of dynamic size. template bool Compiler::VisitCXXNewExpr(const CXXNewExpr *E) { assert(classifyPrim(E->getType()) == PT_Ptr); const Expr *Init = E->getInitializer(); QualType ElementType = E->getAllocatedType(); std::optional ElemT = classify(ElementType); unsigned PlacementArgs = E->getNumPlacementArgs(); const FunctionDecl *OperatorNew = E->getOperatorNew(); const Expr *PlacementDest = nullptr; bool IsNoThrow = false; if (PlacementArgs != 0) { // FIXME: There is no restriction on this, but it's not clear that any // other form makes any sense. We get here for cases such as: // // new (std::align_val_t{N}) X(int) // // (which should presumably be valid only if N is a multiple of // alignof(int), and in any case can't be deallocated unless N is // alignof(X) and X has new-extended alignment). if (PlacementArgs == 1) { const Expr *Arg1 = E->getPlacementArg(0); if (Arg1->getType()->isNothrowT()) { if (!this->discard(Arg1)) return false; IsNoThrow = true; } else { // Invalid unless we have C++26 or are in a std:: function. if (!this->emitInvalidNewDeleteExpr(E, E)) return false; // If we have a placement-new destination, we'll later use that instead // of allocating. if (OperatorNew->isReservedGlobalPlacementOperator()) PlacementDest = Arg1; } } else { // Always invalid. return this->emitInvalid(E); } } else if (!OperatorNew ->isUsableAsGlobalAllocationFunctionInConstantEvaluation()) return this->emitInvalidNewDeleteExpr(E, E); const Descriptor *Desc; if (!PlacementDest) { if (ElemT) { if (E->isArray()) Desc = nullptr; // We're not going to use it in this case. else Desc = P.createDescriptor(E, *ElemT, /*SourceTy=*/nullptr, Descriptor::InlineDescMD); } else { Desc = P.createDescriptor( E, ElementType.getTypePtr(), E->isArray() ? std::nullopt : Descriptor::InlineDescMD, /*IsConst=*/false, /*IsTemporary=*/false, /*IsMutable=*/false, /*IsVolatile=*/false, Init); } } if (E->isArray()) { std::optional ArraySizeExpr = E->getArraySize(); if (!ArraySizeExpr) return false; const Expr *Stripped = *ArraySizeExpr; for (; auto *ICE = dyn_cast(Stripped); Stripped = ICE->getSubExpr()) if (ICE->getCastKind() != CK_NoOp && ICE->getCastKind() != CK_IntegralCast) break; PrimType SizeT = classifyPrim(Stripped->getType()); // Save evaluated array size to a variable. unsigned ArrayLen = allocateLocalPrimitive(Stripped, SizeT, /*IsConst=*/false); if (!this->visit(Stripped)) return false; if (!this->emitSetLocal(SizeT, ArrayLen, E)) return false; if (PlacementDest) { if (!this->visit(PlacementDest)) return false; if (!this->emitStartLifetime(E)) return false; if (!this->emitGetLocal(SizeT, ArrayLen, E)) return false; if (!this->emitCheckNewTypeMismatchArray(SizeT, E, E)) return false; } else { if (!this->emitGetLocal(SizeT, ArrayLen, E)) return false; if (ElemT) { // N primitive elements. if (!this->emitAllocN(SizeT, *ElemT, E, IsNoThrow, E)) return false; } else { // N Composite elements. if (!this->emitAllocCN(SizeT, Desc, IsNoThrow, E)) return false; } } if (Init) { QualType InitType = Init->getType(); size_t StaticInitElems = 0; const Expr *DynamicInit = nullptr; if (const ConstantArrayType *CAT = Ctx.getASTContext().getAsConstantArrayType(InitType)) { StaticInitElems = CAT->getZExtSize(); if (!this->visitInitializer(Init)) return false; if (const auto *ILE = dyn_cast(Init); ILE && ILE->hasArrayFiller()) DynamicInit = ILE->getArrayFiller(); } // The initializer initializes a certain number of elements, S. // However, the complete number of elements, N, might be larger than that. // In this case, we need to get an initializer for the remaining elements. // There are to cases: // 1) For the form 'new Struct[n];', the initializer is a // CXXConstructExpr and its type is an IncompleteArrayType. // 2) For the form 'new Struct[n]{1,2,3}', the initializer is an // InitListExpr and the initializer for the remaining elements // is the array filler. if (DynamicInit || InitType->isIncompleteArrayType()) { const Function *CtorFunc = nullptr; if (const auto *CE = dyn_cast(Init)) { CtorFunc = getFunction(CE->getConstructor()); if (!CtorFunc) return false; } else if (!DynamicInit) DynamicInit = Init; LabelTy EndLabel = this->getLabel(); LabelTy StartLabel = this->getLabel(); // In the nothrow case, the alloc above might have returned nullptr. // Don't call any constructors that case. if (IsNoThrow) { if (!this->emitDupPtr(E)) return false; if (!this->emitNullPtr(0, nullptr, E)) return false; if (!this->emitEQPtr(E)) return false; if (!this->jumpTrue(EndLabel)) return false; } // Create loop variables. unsigned Iter = allocateLocalPrimitive(Stripped, SizeT, /*IsConst=*/false); if (!this->emitConst(StaticInitElems, SizeT, E)) return false; if (!this->emitSetLocal(SizeT, Iter, E)) return false; this->fallthrough(StartLabel); this->emitLabel(StartLabel); // Condition. Iter < ArrayLen? if (!this->emitGetLocal(SizeT, Iter, E)) return false; if (!this->emitGetLocal(SizeT, ArrayLen, E)) return false; if (!this->emitLT(SizeT, E)) return false; if (!this->jumpFalse(EndLabel)) return false; // Pointer to the allocated array is already on the stack. if (!this->emitGetLocal(SizeT, Iter, E)) return false; if (!this->emitArrayElemPtr(SizeT, E)) return false; if (isa_and_nonnull(DynamicInit) && DynamicInit->getType()->isArrayType()) { QualType ElemType = DynamicInit->getType()->getAsArrayTypeUnsafe()->getElementType(); PrimType InitT = classifyPrim(ElemType); if (!this->visitZeroInitializer(InitT, ElemType, E)) return false; if (!this->emitStorePop(InitT, E)) return false; } else if (DynamicInit) { if (std::optional InitT = classify(DynamicInit)) { if (!this->visit(DynamicInit)) return false; if (!this->emitStorePop(*InitT, E)) return false; } else { if (!this->visitInitializer(DynamicInit)) return false; if (!this->emitPopPtr(E)) return false; } } else { assert(CtorFunc); if (!this->emitCall(CtorFunc, 0, E)) return false; } // ++Iter; if (!this->emitGetPtrLocal(Iter, E)) return false; if (!this->emitIncPop(SizeT, false, E)) return false; if (!this->jump(StartLabel)) return false; this->fallthrough(EndLabel); this->emitLabel(EndLabel); } } } else { // Non-array. if (PlacementDest) { if (!this->visit(PlacementDest)) return false; if (!this->emitStartLifetime(E)) return false; if (!this->emitCheckNewTypeMismatch(E, E)) return false; } else { // Allocate just one element. if (!this->emitAlloc(Desc, E)) return false; } if (Init) { if (ElemT) { if (!this->visit(Init)) return false; if (!this->emitInit(*ElemT, E)) return false; } else { // Composite. if (!this->visitInitializer(Init)) return false; } } } if (DiscardResult) return this->emitPopPtr(E); return true; } template bool Compiler::VisitCXXDeleteExpr(const CXXDeleteExpr *E) { const Expr *Arg = E->getArgument(); const FunctionDecl *OperatorDelete = E->getOperatorDelete(); if (!OperatorDelete->isUsableAsGlobalAllocationFunctionInConstantEvaluation()) return this->emitInvalidNewDeleteExpr(E, E); // Arg must be an lvalue. if (!this->visit(Arg)) return false; return this->emitFree(E->isArrayForm(), E->isGlobalDelete(), E); } template bool Compiler::VisitBlockExpr(const BlockExpr *E) { if (DiscardResult) return true; const Function *Func = nullptr; if (auto F = Ctx.getOrCreateObjCBlock(E)) Func = F; if (!Func) return false; return this->emitGetFnPtr(Func, E); } template bool Compiler::VisitCXXTypeidExpr(const CXXTypeidExpr *E) { const Type *TypeInfoType = E->getType().getTypePtr(); auto canonType = [](const Type *T) { return T->getCanonicalTypeUnqualified().getTypePtr(); }; if (!E->isPotentiallyEvaluated()) { if (DiscardResult) return true; if (E->isTypeOperand()) return this->emitGetTypeid( canonType(E->getTypeOperand(Ctx.getASTContext()).getTypePtr()), TypeInfoType, E); return this->emitGetTypeid( canonType(E->getExprOperand()->getType().getTypePtr()), TypeInfoType, E); } // Otherwise, we need to evaluate the expression operand. assert(E->getExprOperand()); assert(E->getExprOperand()->isLValue()); if (!Ctx.getLangOpts().CPlusPlus20 && !this->emitDiagTypeid(E)) return false; if (!this->visit(E->getExprOperand())) return false; if (!this->emitGetTypeidPtr(TypeInfoType, E)) return false; if (DiscardResult) return this->emitPopPtr(E); return true; } template bool Compiler::VisitExpressionTraitExpr(const ExpressionTraitExpr *E) { assert(Ctx.getLangOpts().CPlusPlus); return this->emitConstBool(E->getValue(), E); } template bool Compiler::VisitCXXUuidofExpr(const CXXUuidofExpr *E) { if (DiscardResult) return true; assert(!Initializing); const MSGuidDecl *GuidDecl = E->getGuidDecl(); const RecordDecl *RD = GuidDecl->getType()->getAsRecordDecl(); assert(RD); // If the definiton of the result type is incomplete, just return a dummy. // If (and when) that is read from, we will fail, but not now. if (!RD->isCompleteDefinition()) return this->emitDummyPtr(GuidDecl, E); std::optional GlobalIndex = P.getOrCreateGlobal(GuidDecl); if (!GlobalIndex) return false; if (!this->emitGetPtrGlobal(*GlobalIndex, E)) return false; assert(this->getRecord(E->getType())); const APValue &V = GuidDecl->getAsAPValue(); if (V.getKind() == APValue::None) return true; assert(V.isStruct()); assert(V.getStructNumBases() == 0); if (!this->visitAPValueInitializer(V, E, E->getType())) return false; return this->emitFinishInit(E); } template bool Compiler::VisitRequiresExpr(const RequiresExpr *E) { assert(classifyPrim(E->getType()) == PT_Bool); if (DiscardResult) return true; return this->emitConstBool(E->isSatisfied(), E); } template bool Compiler::VisitConceptSpecializationExpr( const ConceptSpecializationExpr *E) { assert(classifyPrim(E->getType()) == PT_Bool); if (DiscardResult) return true; return this->emitConstBool(E->isSatisfied(), E); } template bool Compiler::VisitCXXRewrittenBinaryOperator( const CXXRewrittenBinaryOperator *E) { return this->delegate(E->getSemanticForm()); } template bool Compiler::VisitPseudoObjectExpr(const PseudoObjectExpr *E) { for (const Expr *SemE : E->semantics()) { if (auto *OVE = dyn_cast(SemE)) { if (SemE == E->getResultExpr()) return false; if (OVE->isUnique()) continue; if (!this->discard(OVE)) return false; } else if (SemE == E->getResultExpr()) { if (!this->delegate(SemE)) return false; } else { if (!this->discard(SemE)) return false; } } return true; } template bool Compiler::VisitPackIndexingExpr(const PackIndexingExpr *E) { return this->delegate(E->getSelectedExpr()); } template bool Compiler::VisitRecoveryExpr(const RecoveryExpr *E) { return this->emitError(E); } template bool Compiler::VisitAddrLabelExpr(const AddrLabelExpr *E) { assert(E->getType()->isVoidPointerType()); unsigned Offset = allocateLocalPrimitive(E->getLabel(), PT_Ptr, /*IsConst=*/true); return this->emitGetLocal(PT_Ptr, Offset, E); } template bool Compiler::VisitConvertVectorExpr(const ConvertVectorExpr *E) { assert(Initializing); const auto *VT = E->getType()->castAs(); QualType ElemType = VT->getElementType(); PrimType ElemT = classifyPrim(ElemType); const Expr *Src = E->getSrcExpr(); QualType SrcType = Src->getType(); PrimType SrcElemT = classifyVectorElementType(SrcType); unsigned SrcOffset = this->allocateLocalPrimitive(Src, PT_Ptr, /*IsConst=*/true); if (!this->visit(Src)) return false; if (!this->emitSetLocal(PT_Ptr, SrcOffset, E)) return false; for (unsigned I = 0; I != VT->getNumElements(); ++I) { if (!this->emitGetLocal(PT_Ptr, SrcOffset, E)) return false; if (!this->emitArrayElemPop(SrcElemT, I, E)) return false; // Cast to the desired result element type. if (SrcElemT != ElemT) { if (!this->emitPrimCast(SrcElemT, ElemT, ElemType, E)) return false; } else if (ElemType->isFloatingType() && SrcType != ElemType) { const auto *TargetSemantics = &Ctx.getFloatSemantics(ElemType); if (!this->emitCastFP(TargetSemantics, getRoundingMode(E), E)) return false; } if (!this->emitInitElem(ElemT, I, E)) return false; } return true; } template bool Compiler::VisitShuffleVectorExpr(const ShuffleVectorExpr *E) { assert(Initializing); assert(E->getNumSubExprs() > 2); const Expr *Vecs[] = {E->getExpr(0), E->getExpr(1)}; const VectorType *VT = Vecs[0]->getType()->castAs(); PrimType ElemT = classifyPrim(VT->getElementType()); unsigned NumInputElems = VT->getNumElements(); unsigned NumOutputElems = E->getNumSubExprs() - 2; assert(NumOutputElems > 0); // Save both input vectors to a local variable. unsigned VectorOffsets[2]; for (unsigned I = 0; I != 2; ++I) { VectorOffsets[I] = this->allocateLocalPrimitive(Vecs[I], PT_Ptr, /*IsConst=*/true); if (!this->visit(Vecs[I])) return false; if (!this->emitSetLocal(PT_Ptr, VectorOffsets[I], E)) return false; } for (unsigned I = 0; I != NumOutputElems; ++I) { APSInt ShuffleIndex = E->getShuffleMaskIdx(I); assert(ShuffleIndex >= -1); if (ShuffleIndex == -1) return this->emitInvalidShuffleVectorIndex(I, E); assert(ShuffleIndex < (NumInputElems * 2)); if (!this->emitGetLocal(PT_Ptr, VectorOffsets[ShuffleIndex >= NumInputElems], E)) return false; unsigned InputVectorIndex = ShuffleIndex.getZExtValue() % NumInputElems; if (!this->emitArrayElemPop(ElemT, InputVectorIndex, E)) return false; if (!this->emitInitElem(ElemT, I, E)) return false; } return true; } template bool Compiler::VisitExtVectorElementExpr( const ExtVectorElementExpr *E) { const Expr *Base = E->getBase(); assert( Base->getType()->isVectorType() || Base->getType()->getAs()->getPointeeType()->isVectorType()); SmallVector Indices; E->getEncodedElementAccess(Indices); if (Indices.size() == 1) { if (!this->visit(Base)) return false; if (E->isGLValue()) { if (!this->emitConstUint32(Indices[0], E)) return false; return this->emitArrayElemPtrPop(PT_Uint32, E); } // Else, also load the value. return this->emitArrayElemPop(classifyPrim(E->getType()), Indices[0], E); } // Create a local variable for the base. unsigned BaseOffset = allocateLocalPrimitive(Base, PT_Ptr, /*IsConst=*/true); if (!this->visit(Base)) return false; if (!this->emitSetLocal(PT_Ptr, BaseOffset, E)) return false; // Now the vector variable for the return value. if (!Initializing) { std::optional ResultIndex; ResultIndex = allocateLocal(E); if (!ResultIndex) return false; if (!this->emitGetPtrLocal(*ResultIndex, E)) return false; } assert(Indices.size() == E->getType()->getAs()->getNumElements()); PrimType ElemT = classifyPrim(E->getType()->getAs()->getElementType()); uint32_t DstIndex = 0; for (uint32_t I : Indices) { if (!this->emitGetLocal(PT_Ptr, BaseOffset, E)) return false; if (!this->emitArrayElemPop(ElemT, I, E)) return false; if (!this->emitInitElem(ElemT, DstIndex, E)) return false; ++DstIndex; } // Leave the result pointer on the stack. assert(!DiscardResult); return true; } template bool Compiler::VisitObjCBoxedExpr(const ObjCBoxedExpr *E) { const Expr *SubExpr = E->getSubExpr(); if (!E->isExpressibleAsConstantInitializer()) return this->discard(SubExpr) && this->emitInvalid(E); if (DiscardResult) return true; assert(classifyPrim(E) == PT_Ptr); return this->emitDummyPtr(E, E); } template bool Compiler::VisitCXXStdInitializerListExpr( const CXXStdInitializerListExpr *E) { const Expr *SubExpr = E->getSubExpr(); const ConstantArrayType *ArrayType = Ctx.getASTContext().getAsConstantArrayType(SubExpr->getType()); const Record *R = getRecord(E->getType()); assert(Initializing); assert(SubExpr->isGLValue()); if (!this->visit(SubExpr)) return false; if (!this->emitConstUint8(0, E)) return false; if (!this->emitArrayElemPtrPopUint8(E)) return false; if (!this->emitInitFieldPtr(R->getField(0u)->Offset, E)) return false; PrimType SecondFieldT = classifyPrim(R->getField(1u)->Decl->getType()); if (isIntegralType(SecondFieldT)) { if (!this->emitConst(static_cast(ArrayType->getSize()), SecondFieldT, E)) return false; return this->emitInitField(SecondFieldT, R->getField(1u)->Offset, E); } assert(SecondFieldT == PT_Ptr); if (!this->emitGetFieldPtr(R->getField(0u)->Offset, E)) return false; if (!this->emitExpandPtr(E)) return false; if (!this->emitConst(static_cast(ArrayType->getSize()), PT_Uint64, E)) return false; if (!this->emitArrayElemPtrPop(PT_Uint64, E)) return false; return this->emitInitFieldPtr(R->getField(1u)->Offset, E); } template bool Compiler::VisitStmtExpr(const StmtExpr *E) { BlockScope BS(this); StmtExprScope SS(this); const CompoundStmt *CS = E->getSubStmt(); const Stmt *Result = CS->getStmtExprResult(); for (const Stmt *S : CS->body()) { if (S != Result) { if (!this->visitStmt(S)) return false; continue; } assert(S == Result); if (const Expr *ResultExpr = dyn_cast(S)) return this->delegate(ResultExpr); return this->emitUnsupported(E); } return BS.destroyLocals(); } template bool Compiler::discard(const Expr *E) { OptionScope Scope(this, /*NewDiscardResult=*/true, /*NewInitializing=*/false); return this->Visit(E); } template bool Compiler::delegate(const Expr *E) { // We're basically doing: // OptionScope Scope(this, DicardResult, Initializing); // but that's unnecessary of course. return this->Visit(E); } template bool Compiler::visit(const Expr *E) { if (E->getType().isNull()) return false; if (E->getType()->isVoidType()) return this->discard(E); // Create local variable to hold the return value. if (!E->isGLValue() && !E->getType()->isAnyComplexType() && !classify(E->getType())) { std::optional LocalIndex = allocateLocal(E); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; InitLinkScope ILS(this, InitLink::Temp(*LocalIndex)); return this->visitInitializer(E); } // Otherwise,we have a primitive return value, produce the value directly // and push it on the stack. OptionScope Scope(this, /*NewDiscardResult=*/false, /*NewInitializing=*/false); return this->Visit(E); } template bool Compiler::visitInitializer(const Expr *E) { assert(!classify(E->getType())); OptionScope Scope(this, /*NewDiscardResult=*/false, /*NewInitializing=*/true); return this->Visit(E); } template bool Compiler::visitBool(const Expr *E) { std::optional T = classify(E->getType()); if (!T) { // Convert complex values to bool. if (E->getType()->isAnyComplexType()) { if (!this->visit(E)) return false; return this->emitComplexBoolCast(E); } return false; } if (!this->visit(E)) return false; if (T == PT_Bool) return true; // Convert pointers to bool. if (T == PT_Ptr) return this->emitIsNonNullPtr(E); // Or Floats. if (T == PT_Float) return this->emitCastFloatingIntegralBool(getFPOptions(E), E); // Or anything else we can. return this->emitCast(*T, PT_Bool, E); } template bool Compiler::visitZeroInitializer(PrimType T, QualType QT, const Expr *E) { if (const auto *AT = QT->getAs()) QT = AT->getValueType(); switch (T) { case PT_Bool: return this->emitZeroBool(E); case PT_Sint8: return this->emitZeroSint8(E); case PT_Uint8: return this->emitZeroUint8(E); case PT_Sint16: return this->emitZeroSint16(E); case PT_Uint16: return this->emitZeroUint16(E); case PT_Sint32: return this->emitZeroSint32(E); case PT_Uint32: return this->emitZeroUint32(E); case PT_Sint64: return this->emitZeroSint64(E); case PT_Uint64: return this->emitZeroUint64(E); case PT_IntAP: return this->emitZeroIntAP(Ctx.getBitWidth(QT), E); case PT_IntAPS: return this->emitZeroIntAPS(Ctx.getBitWidth(QT), E); case PT_Ptr: return this->emitNullPtr(Ctx.getASTContext().getTargetNullPointerValue(QT), nullptr, E); case PT_MemberPtr: return this->emitNullMemberPtr(0, nullptr, E); case PT_Float: { APFloat F = APFloat::getZero(Ctx.getFloatSemantics(QT)); return this->emitFloat(F, E); } case PT_FixedPoint: { auto Sem = Ctx.getASTContext().getFixedPointSemantics(E->getType()); return this->emitConstFixedPoint(FixedPoint::zero(Sem), E); } } llvm_unreachable("unknown primitive type"); } template bool Compiler::visitZeroRecordInitializer(const Record *R, const Expr *E) { assert(E); assert(R); // Fields for (const Record::Field &Field : R->fields()) { if (Field.isUnnamedBitField()) continue; const Descriptor *D = Field.Desc; if (D->isPrimitive()) { QualType QT = D->getType(); PrimType T = classifyPrim(D->getType()); if (!this->visitZeroInitializer(T, QT, E)) return false; if (!this->emitInitField(T, Field.Offset, E)) return false; if (R->isUnion()) break; continue; } if (!this->emitGetPtrField(Field.Offset, E)) return false; if (D->isPrimitiveArray()) { QualType ET = D->getElemQualType(); PrimType T = classifyPrim(ET); for (uint32_t I = 0, N = D->getNumElems(); I != N; ++I) { if (!this->visitZeroInitializer(T, ET, E)) return false; if (!this->emitInitElem(T, I, E)) return false; } } else if (D->isCompositeArray()) { // Can't be a vector or complex field. if (!this->visitZeroArrayInitializer(D->getType(), E)) return false; } else if (D->isRecord()) { if (!this->visitZeroRecordInitializer(D->ElemRecord, E)) return false; } else return false; if (!this->emitFinishInitPop(E)) return false; // C++11 [dcl.init]p5: If T is a (possibly cv-qualified) union type, the // object's first non-static named data member is zero-initialized if (R->isUnion()) break; } for (const Record::Base &B : R->bases()) { if (!this->emitGetPtrBase(B.Offset, E)) return false; if (!this->visitZeroRecordInitializer(B.R, E)) return false; if (!this->emitFinishInitPop(E)) return false; } // FIXME: Virtual bases. return true; } template bool Compiler::visitZeroArrayInitializer(QualType T, const Expr *E) { assert(T->isArrayType() || T->isAnyComplexType() || T->isVectorType()); const ArrayType *AT = T->getAsArrayTypeUnsafe(); QualType ElemType = AT->getElementType(); size_t NumElems = cast(AT)->getZExtSize(); if (std::optional ElemT = classify(ElemType)) { for (size_t I = 0; I != NumElems; ++I) { if (!this->visitZeroInitializer(*ElemT, ElemType, E)) return false; if (!this->emitInitElem(*ElemT, I, E)) return false; } return true; } else if (ElemType->isRecordType()) { const Record *R = getRecord(ElemType); for (size_t I = 0; I != NumElems; ++I) { if (!this->emitConstUint32(I, E)) return false; if (!this->emitArrayElemPtr(PT_Uint32, E)) return false; if (!this->visitZeroRecordInitializer(R, E)) return false; if (!this->emitPopPtr(E)) return false; } return true; } else if (ElemType->isArrayType()) { for (size_t I = 0; I != NumElems; ++I) { if (!this->emitConstUint32(I, E)) return false; if (!this->emitArrayElemPtr(PT_Uint32, E)) return false; if (!this->visitZeroArrayInitializer(ElemType, E)) return false; if (!this->emitPopPtr(E)) return false; } return true; } return false; } template template bool Compiler::emitConst(T Value, PrimType Ty, const Expr *E) { switch (Ty) { case PT_Sint8: return this->emitConstSint8(Value, E); case PT_Uint8: return this->emitConstUint8(Value, E); case PT_Sint16: return this->emitConstSint16(Value, E); case PT_Uint16: return this->emitConstUint16(Value, E); case PT_Sint32: return this->emitConstSint32(Value, E); case PT_Uint32: return this->emitConstUint32(Value, E); case PT_Sint64: return this->emitConstSint64(Value, E); case PT_Uint64: return this->emitConstUint64(Value, E); case PT_Bool: return this->emitConstBool(Value, E); case PT_Ptr: case PT_MemberPtr: case PT_Float: case PT_IntAP: case PT_IntAPS: case PT_FixedPoint: llvm_unreachable("Invalid integral type"); break; } llvm_unreachable("unknown primitive type"); } template template bool Compiler::emitConst(T Value, const Expr *E) { return this->emitConst(Value, classifyPrim(E->getType()), E); } template bool Compiler::emitConst(const APSInt &Value, PrimType Ty, const Expr *E) { if (Ty == PT_IntAPS) return this->emitConstIntAPS(Value, E); if (Ty == PT_IntAP) return this->emitConstIntAP(Value, E); if (Value.isSigned()) return this->emitConst(Value.getSExtValue(), Ty, E); return this->emitConst(Value.getZExtValue(), Ty, E); } template bool Compiler::emitConst(const APSInt &Value, const Expr *E) { return this->emitConst(Value, classifyPrim(E->getType()), E); } template unsigned Compiler::allocateLocalPrimitive( DeclTy &&Src, PrimType Ty, bool IsConst, const ValueDecl *ExtendingDecl, ScopeKind SC, bool IsConstexprUnknown) { // Make sure we don't accidentally register the same decl twice. if (const auto *VD = dyn_cast_if_present(Src.dyn_cast())) { assert(!P.getGlobal(VD)); assert(!Locals.contains(VD)); (void)VD; } // FIXME: There are cases where Src.is() is wrong, e.g. // (int){12} in C. Consider using Expr::isTemporaryObject() instead // or isa(). Descriptor *D = P.createDescriptor(Src, Ty, nullptr, Descriptor::InlineDescMD, IsConst, isa(Src)); D->IsConstexprUnknown = IsConstexprUnknown; Scope::Local Local = this->createLocal(D); if (auto *VD = dyn_cast_if_present(Src.dyn_cast())) Locals.insert({VD, Local}); if (ExtendingDecl) VarScope->addExtended(Local, ExtendingDecl); else VarScope->addForScopeKind(Local, SC); return Local.Offset; } template std::optional Compiler::allocateLocal(DeclTy &&Src, QualType Ty, const ValueDecl *ExtendingDecl, ScopeKind SC, bool IsConstexprUnknown) { // Make sure we don't accidentally register the same decl twice. if ([[maybe_unused]] const auto *VD = dyn_cast_if_present(Src.dyn_cast())) { assert(!P.getGlobal(VD)); assert(!Locals.contains(VD)); } const ValueDecl *Key = nullptr; const Expr *Init = nullptr; bool IsTemporary = false; if (auto *VD = dyn_cast_if_present(Src.dyn_cast())) { Key = VD; Ty = VD->getType(); if (const auto *VarD = dyn_cast(VD)) Init = VarD->getInit(); } if (auto *E = Src.dyn_cast()) { IsTemporary = true; if (Ty.isNull()) Ty = E->getType(); } Descriptor *D = P.createDescriptor( Src, Ty.getTypePtr(), Descriptor::InlineDescMD, Ty.isConstQualified(), IsTemporary, /*IsMutable=*/false, /*IsVolatile=*/false, Init); if (!D) return std::nullopt; D->IsConstexprUnknown = IsConstexprUnknown; Scope::Local Local = this->createLocal(D); if (Key) Locals.insert({Key, Local}); if (ExtendingDecl) VarScope->addExtended(Local, ExtendingDecl); else VarScope->addForScopeKind(Local, SC); return Local.Offset; } template std::optional Compiler::allocateTemporary(const Expr *E) { QualType Ty = E->getType(); assert(!Ty->isRecordType()); Descriptor *D = P.createDescriptor( E, Ty.getTypePtr(), Descriptor::InlineDescMD, Ty.isConstQualified(), /*IsTemporary=*/true); if (!D) return std::nullopt; Scope::Local Local = this->createLocal(D); VariableScope *S = VarScope; assert(S); // Attach to topmost scope. while (S->getParent()) S = S->getParent(); assert(S && !S->getParent()); S->addLocal(Local); return Local.Offset; } template const RecordType *Compiler::getRecordTy(QualType Ty) { if (const PointerType *PT = dyn_cast(Ty)) return PT->getPointeeType()->getAs(); return Ty->getAs(); } template Record *Compiler::getRecord(QualType Ty) { if (const auto *RecordTy = getRecordTy(Ty)) return getRecord(RecordTy->getDecl()); return nullptr; } template Record *Compiler::getRecord(const RecordDecl *RD) { return P.getOrCreateRecord(RD); } template const Function *Compiler::getFunction(const FunctionDecl *FD) { return Ctx.getOrCreateFunction(FD); } template bool Compiler::visitExpr(const Expr *E, bool DestroyToplevelScope) { LocalScope RootScope(this); // If we won't destroy the toplevel scope, check for memory leaks first. if (!DestroyToplevelScope) { if (!this->emitCheckAllocations(E)) return false; } auto maybeDestroyLocals = [&]() -> bool { if (DestroyToplevelScope) return RootScope.destroyLocals() && this->emitCheckAllocations(E); return this->emitCheckAllocations(E); }; // Void expressions. if (E->getType()->isVoidType()) { if (!visit(E)) return false; return this->emitRetVoid(E) && maybeDestroyLocals(); } // Expressions with a primitive return type. if (std::optional T = classify(E)) { if (!visit(E)) return false; return this->emitRet(*T, E) && maybeDestroyLocals(); } // Expressions with a composite return type. // For us, that means everything we don't // have a PrimType for. if (std::optional LocalOffset = this->allocateLocal(E)) { InitLinkScope ILS(this, InitLink::Temp(*LocalOffset)); if (!this->emitGetPtrLocal(*LocalOffset, E)) return false; if (!visitInitializer(E)) return false; if (!this->emitFinishInit(E)) return false; // We are destroying the locals AFTER the Ret op. // The Ret op needs to copy the (alive) values, but the // destructors may still turn the entire expression invalid. return this->emitRetValue(E) && maybeDestroyLocals(); } return maybeDestroyLocals() && this->emitCheckAllocations(E) && false; } template VarCreationState Compiler::visitDecl(const VarDecl *VD, bool IsConstexprUnknown) { auto R = this->visitVarDecl(VD, /*Toplevel=*/true, IsConstexprUnknown); if (R.notCreated()) return R; if (R) return true; if (!R && Context::shouldBeGloballyIndexed(VD)) { if (auto GlobalIndex = P.getGlobal(VD)) { Block *GlobalBlock = P.getGlobal(*GlobalIndex); GlobalInlineDescriptor &GD = *reinterpret_cast(GlobalBlock->rawData()); GD.InitState = GlobalInitState::InitializerFailed; GlobalBlock->invokeDtor(); } } return R; } /// Toplevel visitDeclAndReturn(). /// We get here from evaluateAsInitializer(). /// We need to evaluate the initializer and return its value. template bool Compiler::visitDeclAndReturn(const VarDecl *VD, bool ConstantContext) { // We only create variables if we're evaluating in a constant context. // Otherwise, just evaluate the initializer and return it. if (!ConstantContext) { DeclScope LS(this, VD); const Expr *Init = VD->getInit(); if (!this->visit(Init)) return false; return this->emitRet(classify(Init).value_or(PT_Ptr), VD) && LS.destroyLocals() && this->emitCheckAllocations(VD); } LocalScope VDScope(this, VD); if (!this->visitVarDecl(VD, /*Toplevel=*/true)) return false; std::optional VarT = classify(VD->getType()); if (Context::shouldBeGloballyIndexed(VD)) { auto GlobalIndex = P.getGlobal(VD); assert(GlobalIndex); // visitVarDecl() didn't return false. if (VarT) { if (!this->emitGetGlobalUnchecked(*VarT, *GlobalIndex, VD)) return false; } else { if (!this->emitGetPtrGlobal(*GlobalIndex, VD)) return false; } } else { auto Local = Locals.find(VD); assert(Local != Locals.end()); // Same here. if (VarT) { if (!this->emitGetLocal(*VarT, Local->second.Offset, VD)) return false; } else { if (!this->emitGetPtrLocal(Local->second.Offset, VD)) return false; } } // Return the value. if (!this->emitRet(VarT.value_or(PT_Ptr), VD)) { // If the Ret above failed and this is a global variable, mark it as // uninitialized, even everything else succeeded. if (Context::shouldBeGloballyIndexed(VD)) { auto GlobalIndex = P.getGlobal(VD); assert(GlobalIndex); Block *GlobalBlock = P.getGlobal(*GlobalIndex); GlobalInlineDescriptor &GD = *reinterpret_cast(GlobalBlock->rawData()); GD.InitState = GlobalInitState::InitializerFailed; GlobalBlock->invokeDtor(); } return false; } return VDScope.destroyLocals() && this->emitCheckAllocations(VD); } template VarCreationState Compiler::visitVarDecl(const VarDecl *VD, bool Toplevel, bool IsConstexprUnknown) { // We don't know what to do with these, so just return false. if (VD->getType().isNull()) return false; // This case is EvalEmitter-only. If we won't create any instructions for the // initializer anyway, don't bother creating the variable in the first place. if (!this->isActive()) return VarCreationState::NotCreated(); const Expr *Init = VD->getInit(); std::optional VarT = classify(VD->getType()); if (Init && Init->isValueDependent()) return false; if (Context::shouldBeGloballyIndexed(VD)) { auto checkDecl = [&]() -> bool { bool NeedsOp = !Toplevel && VD->isLocalVarDecl() && VD->isStaticLocal(); return !NeedsOp || this->emitCheckDecl(VD, VD); }; auto initGlobal = [&](unsigned GlobalIndex) -> bool { assert(Init); if (VarT) { if (!this->visit(Init)) return checkDecl() && false; return checkDecl() && this->emitInitGlobal(*VarT, GlobalIndex, VD); } if (!checkDecl()) return false; if (!this->emitGetPtrGlobal(GlobalIndex, Init)) return false; if (!visitInitializer(Init)) return false; return this->emitFinishInitGlobal(Init); }; DeclScope LocalScope(this, VD); // We've already seen and initialized this global. if (std::optional GlobalIndex = P.getGlobal(VD)) { if (P.getPtrGlobal(*GlobalIndex).isInitialized()) return checkDecl(); // The previous attempt at initialization might've been unsuccessful, // so let's try this one. return Init && checkDecl() && initGlobal(*GlobalIndex); } std::optional GlobalIndex = P.createGlobal(VD, Init); if (!GlobalIndex) return false; return !Init || (checkDecl() && initGlobal(*GlobalIndex)); } // Local variables. InitLinkScope ILS(this, InitLink::Decl(VD)); if (VarT) { unsigned Offset = this->allocateLocalPrimitive( VD, *VarT, VD->getType().isConstQualified(), nullptr, ScopeKind::Block, IsConstexprUnknown); if (Init) { // If this is a toplevel declaration, create a scope for the // initializer. if (Toplevel) { LocalScope Scope(this); if (!this->visit(Init)) return false; return this->emitSetLocal(*VarT, Offset, VD) && Scope.destroyLocals(); } else { if (!this->visit(Init)) return false; return this->emitSetLocal(*VarT, Offset, VD); } } } else { if (std::optional Offset = this->allocateLocal( VD, VD->getType(), nullptr, ScopeKind::Block, IsConstexprUnknown)) { if (!Init) return true; if (!this->emitGetPtrLocal(*Offset, Init)) return false; if (!visitInitializer(Init)) return false; return this->emitFinishInitPop(Init); } return false; } return true; } template bool Compiler::visitAPValue(const APValue &Val, PrimType ValType, const Expr *E) { assert(!DiscardResult); if (Val.isInt()) return this->emitConst(Val.getInt(), ValType, E); else if (Val.isFloat()) { APFloat F = Val.getFloat(); return this->emitFloat(F, E); } if (Val.isLValue()) { if (Val.isNullPointer()) return this->emitNull(ValType, 0, nullptr, E); APValue::LValueBase Base = Val.getLValueBase(); if (const Expr *BaseExpr = Base.dyn_cast()) return this->visit(BaseExpr); else if (const auto *VD = Base.dyn_cast()) { return this->visitDeclRef(VD, E); } } else if (Val.isMemberPointer()) { if (const ValueDecl *MemberDecl = Val.getMemberPointerDecl()) return this->emitGetMemberPtr(MemberDecl, E); return this->emitNullMemberPtr(0, nullptr, E); } return false; } template bool Compiler::visitAPValueInitializer(const APValue &Val, const Expr *E, QualType T) { if (Val.isStruct()) { const Record *R = this->getRecord(T); assert(R); for (unsigned I = 0, N = Val.getStructNumFields(); I != N; ++I) { const APValue &F = Val.getStructField(I); const Record::Field *RF = R->getField(I); QualType FieldType = RF->Decl->getType(); if (std::optional PT = classify(FieldType)) { if (!this->visitAPValue(F, *PT, E)) return false; if (!this->emitInitField(*PT, RF->Offset, E)) return false; } else { if (!this->emitGetPtrField(RF->Offset, E)) return false; if (!this->visitAPValueInitializer(F, E, FieldType)) return false; if (!this->emitPopPtr(E)) return false; } } return true; } else if (Val.isUnion()) { const FieldDecl *UnionField = Val.getUnionField(); const Record *R = this->getRecord(UnionField->getParent()); assert(R); const APValue &F = Val.getUnionValue(); const Record::Field *RF = R->getField(UnionField); PrimType T = classifyPrim(RF->Decl->getType()); if (!this->visitAPValue(F, T, E)) return false; return this->emitInitField(T, RF->Offset, E); } else if (Val.isArray()) { const auto *ArrType = T->getAsArrayTypeUnsafe(); QualType ElemType = ArrType->getElementType(); for (unsigned A = 0, AN = Val.getArraySize(); A != AN; ++A) { const APValue &Elem = Val.getArrayInitializedElt(A); if (std::optional ElemT = classify(ElemType)) { if (!this->visitAPValue(Elem, *ElemT, E)) return false; if (!this->emitInitElem(*ElemT, A, E)) return false; } else { if (!this->emitConstUint32(A, E)) return false; if (!this->emitArrayElemPtrUint32(E)) return false; if (!this->visitAPValueInitializer(Elem, E, ElemType)) return false; if (!this->emitPopPtr(E)) return false; } } return true; } // TODO: Other types. return false; } template bool Compiler::VisitBuiltinCallExpr(const CallExpr *E, unsigned BuiltinID) { if (BuiltinID == Builtin::BI__builtin_constant_p) { // Void argument is always invalid and harder to handle later. if (E->getArg(0)->getType()->isVoidType()) { if (DiscardResult) return true; return this->emitConst(0, E); } if (!this->emitStartSpeculation(E)) return false; LabelTy EndLabel = this->getLabel(); if (!this->speculate(E, EndLabel)) return false; this->fallthrough(EndLabel); if (!this->emitEndSpeculation(E)) return false; if (DiscardResult) return this->emitPop(classifyPrim(E), E); return true; } // For these, we're expected to ultimately return an APValue pointing // to the CallExpr. This is needed to get the correct codegen. if (BuiltinID == Builtin::BI__builtin___CFStringMakeConstantString || BuiltinID == Builtin::BI__builtin___NSStringMakeConstantString || BuiltinID == Builtin::BI__builtin_ptrauth_sign_constant || BuiltinID == Builtin::BI__builtin_function_start) { if (DiscardResult) return true; return this->emitDummyPtr(E, E); } QualType ReturnType = E->getType(); std::optional ReturnT = classify(E); // Non-primitive return type. Prepare storage. if (!Initializing && !ReturnT && !ReturnType->isVoidType()) { std::optional LocalIndex = allocateLocal(E); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } if (!Context::isUnevaluatedBuiltin(BuiltinID)) { // Put arguments on the stack. for (const auto *Arg : E->arguments()) { if (!this->visit(Arg)) return false; } } if (!this->emitCallBI(E, BuiltinID, E)) return false; if (DiscardResult && !ReturnType->isVoidType()) { assert(ReturnT); return this->emitPop(*ReturnT, E); } return true; } static const Expr *stripDerivedToBaseCasts(const Expr *E) { if (const auto *PE = dyn_cast(E)) return stripDerivedToBaseCasts(PE->getSubExpr()); if (const auto *CE = dyn_cast(E); CE && (CE->getCastKind() == CK_DerivedToBase || CE->getCastKind() == CK_NoOp)) return stripDerivedToBaseCasts(CE->getSubExpr()); return E; } template bool Compiler::VisitCallExpr(const CallExpr *E) { const FunctionDecl *FuncDecl = E->getDirectCallee(); if (FuncDecl) { if (unsigned BuiltinID = FuncDecl->getBuiltinID()) return VisitBuiltinCallExpr(E, BuiltinID); // Calls to replaceable operator new/operator delete. if (FuncDecl->isUsableAsGlobalAllocationFunctionInConstantEvaluation()) { if (FuncDecl->getDeclName().isAnyOperatorNew()) { return VisitBuiltinCallExpr(E, Builtin::BI__builtin_operator_new); } else { assert(FuncDecl->getDeclName().getCXXOverloadedOperator() == OO_Delete); return VisitBuiltinCallExpr(E, Builtin::BI__builtin_operator_delete); } } // Explicit calls to trivial destructors if (const auto *DD = dyn_cast(FuncDecl); DD && DD->isTrivial()) { const auto *MemberCall = cast(E); if (!this->visit(MemberCall->getImplicitObjectArgument())) return false; return this->emitCheckDestruction(E) && this->emitEndLifetime(E) && this->emitPopPtr(E); } } BlockScope CallScope(this, ScopeKind::Call); QualType ReturnType = E->getCallReturnType(Ctx.getASTContext()); std::optional T = classify(ReturnType); bool HasRVO = !ReturnType->isVoidType() && !T; if (HasRVO) { if (DiscardResult) { // If we need to discard the return value but the function returns its // value via an RVO pointer, we need to create one such pointer just // for this call. if (std::optional LocalIndex = allocateLocal(E)) { if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } } else { // We need the result. Prepare a pointer to return or // dup the current one. if (!Initializing) { if (std::optional LocalIndex = allocateLocal(E)) { if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } } if (!this->emitDupPtr(E)) return false; } } SmallVector Args(ArrayRef(E->getArgs(), E->getNumArgs())); bool IsAssignmentOperatorCall = false; if (const auto *OCE = dyn_cast(E); OCE && OCE->isAssignmentOp()) { // Just like with regular assignments, we need to special-case assignment // operators here and evaluate the RHS (the second arg) before the LHS (the // first arg). We fix this by using a Flip op later. assert(Args.size() == 2); IsAssignmentOperatorCall = true; std::reverse(Args.begin(), Args.end()); } // Calling a static operator will still // pass the instance, but we don't need it. // Discard it here. if (isa(E)) { if (const auto *MD = dyn_cast_if_present(FuncDecl); MD && MD->isStatic()) { if (!this->discard(E->getArg(0))) return false; // Drop first arg. Args.erase(Args.begin()); } } bool Devirtualized = false; std::optional CalleeOffset; // Add the (optional, implicit) This pointer. if (const auto *MC = dyn_cast(E)) { if (!FuncDecl && classifyPrim(E->getCallee()) == PT_MemberPtr) { // If we end up creating a CallPtr op for this, we need the base of the // member pointer as the instance pointer, and later extract the function // decl as the function pointer. const Expr *Callee = E->getCallee(); CalleeOffset = this->allocateLocalPrimitive(Callee, PT_MemberPtr, /*IsConst=*/true); if (!this->visit(Callee)) return false; if (!this->emitSetLocal(PT_MemberPtr, *CalleeOffset, E)) return false; if (!this->emitGetLocal(PT_MemberPtr, *CalleeOffset, E)) return false; if (!this->emitGetMemberPtrBase(E)) return false; } else { const auto *InstancePtr = MC->getImplicitObjectArgument(); if (isa_and_nonnull(CompilingFunction) || isa_and_nonnull(CompilingFunction)) { const auto *Stripped = stripDerivedToBaseCasts(InstancePtr); if (isa(Stripped)) { FuncDecl = cast(FuncDecl)->getCorrespondingMethodInClass( Stripped->getType()->getPointeeType()->getAsCXXRecordDecl()); Devirtualized = true; if (!this->visit(Stripped)) return false; } else { if (!this->visit(InstancePtr)) return false; } } else { if (!this->visit(InstancePtr)) return false; } } } else if (const auto *PD = dyn_cast(E->getCallee())) { if (!this->emitCheckPseudoDtor(E)) return false; const Expr *Base = PD->getBase(); if (!Base->isGLValue()) return this->discard(Base); if (!this->visit(Base)) return false; return this->emitEndLifetimePop(E); } else if (!FuncDecl) { const Expr *Callee = E->getCallee(); CalleeOffset = this->allocateLocalPrimitive(Callee, PT_Ptr, /*IsConst=*/true); if (!this->visit(Callee)) return false; if (!this->emitSetLocal(PT_Ptr, *CalleeOffset, E)) return false; } if (!this->visitCallArgs(Args, FuncDecl)) return false; // Undo the argument reversal we did earlier. if (IsAssignmentOperatorCall) { assert(Args.size() == 2); PrimType Arg1T = classify(Args[0]).value_or(PT_Ptr); PrimType Arg2T = classify(Args[1]).value_or(PT_Ptr); if (!this->emitFlip(Arg2T, Arg1T, E)) return false; } if (FuncDecl) { const Function *Func = getFunction(FuncDecl); if (!Func) return false; assert(HasRVO == Func->hasRVO()); bool HasQualifier = false; if (const auto *ME = dyn_cast(E->getCallee())) HasQualifier = ME->hasQualifier(); bool IsVirtual = false; if (const auto *MD = dyn_cast(FuncDecl)) IsVirtual = !Devirtualized && MD->isVirtual(); // In any case call the function. The return value will end up on the stack // and if the function has RVO, we already have the pointer on the stack to // write the result into. if (IsVirtual && !HasQualifier) { uint32_t VarArgSize = 0; unsigned NumParams = Func->getNumWrittenParams() + isa(E); for (unsigned I = NumParams, N = E->getNumArgs(); I != N; ++I) VarArgSize += align(primSize(classify(E->getArg(I)).value_or(PT_Ptr))); if (!this->emitCallVirt(Func, VarArgSize, E)) return false; } else if (Func->isVariadic()) { uint32_t VarArgSize = 0; unsigned NumParams = Func->getNumWrittenParams() + isa(E); for (unsigned I = NumParams, N = E->getNumArgs(); I != N; ++I) VarArgSize += align(primSize(classify(E->getArg(I)).value_or(PT_Ptr))); if (!this->emitCallVar(Func, VarArgSize, E)) return false; } else { if (!this->emitCall(Func, 0, E)) return false; } } else { // Indirect call. Visit the callee, which will leave a FunctionPointer on // the stack. Cleanup of the returned value if necessary will be done after // the function call completed. // Sum the size of all args from the call expr. uint32_t ArgSize = 0; for (unsigned I = 0, N = E->getNumArgs(); I != N; ++I) ArgSize += align(primSize(classify(E->getArg(I)).value_or(PT_Ptr))); // Get the callee, either from a member pointer or function pointer saved in // CalleeOffset. if (isa(E) && CalleeOffset) { if (!this->emitGetLocal(PT_MemberPtr, *CalleeOffset, E)) return false; if (!this->emitGetMemberPtrDecl(E)) return false; } else { if (!this->emitGetLocal(PT_Ptr, *CalleeOffset, E)) return false; } if (!this->emitCallPtr(ArgSize, E, E)) return false; } // Cleanup for discarded return values. if (DiscardResult && !ReturnType->isVoidType() && T) return this->emitPop(*T, E) && CallScope.destroyLocals(); return CallScope.destroyLocals(); } template bool Compiler::VisitCXXDefaultInitExpr(const CXXDefaultInitExpr *E) { SourceLocScope SLS(this, E); return this->delegate(E->getExpr()); } template bool Compiler::VisitCXXDefaultArgExpr(const CXXDefaultArgExpr *E) { SourceLocScope SLS(this, E); return this->delegate(E->getExpr()); } template bool Compiler::VisitCXXBoolLiteralExpr(const CXXBoolLiteralExpr *E) { if (DiscardResult) return true; return this->emitConstBool(E->getValue(), E); } template bool Compiler::VisitCXXNullPtrLiteralExpr( const CXXNullPtrLiteralExpr *E) { if (DiscardResult) return true; uint64_t Val = Ctx.getASTContext().getTargetNullPointerValue(E->getType()); return this->emitNullPtr(Val, nullptr, E); } template bool Compiler::VisitGNUNullExpr(const GNUNullExpr *E) { if (DiscardResult) return true; assert(E->getType()->isIntegerType()); PrimType T = classifyPrim(E->getType()); return this->emitZero(T, E); } template bool Compiler::VisitCXXThisExpr(const CXXThisExpr *E) { if (DiscardResult) return true; if (this->LambdaThisCapture.Offset > 0) { if (this->LambdaThisCapture.IsPtr) return this->emitGetThisFieldPtr(this->LambdaThisCapture.Offset, E); return this->emitGetPtrThisField(this->LambdaThisCapture.Offset, E); } // In some circumstances, the 'this' pointer does not actually refer to the // instance pointer of the current function frame, but e.g. to the declaration // currently being initialized. Here we emit the necessary instruction(s) for // this scenario. if (!InitStackActive) return this->emitThis(E); if (!InitStack.empty()) { // If our init stack is, for example: // 0 Stack: 3 (decl) // 1 Stack: 6 (init list) // 2 Stack: 1 (field) // 3 Stack: 6 (init list) // 4 Stack: 1 (field) // // We want to find the LAST element in it that's an init list, // which is marked with the K_InitList marker. The index right // before that points to an init list. We need to find the // elements before the K_InitList element that point to a base // (e.g. a decl or This), optionally followed by field, elem, etc. // In the example above, we want to emit elements [0..2]. unsigned StartIndex = 0; unsigned EndIndex = 0; // Find the init list. for (StartIndex = InitStack.size() - 1; StartIndex > 0; --StartIndex) { if (InitStack[StartIndex].Kind == InitLink::K_InitList || InitStack[StartIndex].Kind == InitLink::K_This) { EndIndex = StartIndex; --StartIndex; break; } } // Walk backwards to find the base. for (; StartIndex > 0; --StartIndex) { if (InitStack[StartIndex].Kind == InitLink::K_InitList) continue; if (InitStack[StartIndex].Kind != InitLink::K_Field && InitStack[StartIndex].Kind != InitLink::K_Elem) break; } // Emit the instructions. for (unsigned I = StartIndex; I != EndIndex; ++I) { if (InitStack[I].Kind == InitLink::K_InitList) continue; if (!InitStack[I].template emit(this, E)) return false; } return true; } return this->emitThis(E); } template bool Compiler::visitStmt(const Stmt *S) { switch (S->getStmtClass()) { case Stmt::CompoundStmtClass: return visitCompoundStmt(cast(S)); case Stmt::DeclStmtClass: return visitDeclStmt(cast(S), /*EvaluateConditionDecl=*/true); case Stmt::ReturnStmtClass: return visitReturnStmt(cast(S)); case Stmt::IfStmtClass: return visitIfStmt(cast(S)); case Stmt::WhileStmtClass: return visitWhileStmt(cast(S)); case Stmt::DoStmtClass: return visitDoStmt(cast(S)); case Stmt::ForStmtClass: return visitForStmt(cast(S)); case Stmt::CXXForRangeStmtClass: return visitCXXForRangeStmt(cast(S)); case Stmt::BreakStmtClass: return visitBreakStmt(cast(S)); case Stmt::ContinueStmtClass: return visitContinueStmt(cast(S)); case Stmt::SwitchStmtClass: return visitSwitchStmt(cast(S)); case Stmt::CaseStmtClass: return visitCaseStmt(cast(S)); case Stmt::DefaultStmtClass: return visitDefaultStmt(cast(S)); case Stmt::AttributedStmtClass: return visitAttributedStmt(cast(S)); case Stmt::CXXTryStmtClass: return visitCXXTryStmt(cast(S)); case Stmt::NullStmtClass: return true; // Always invalid statements. case Stmt::GCCAsmStmtClass: case Stmt::MSAsmStmtClass: case Stmt::GotoStmtClass: return this->emitInvalid(S); case Stmt::LabelStmtClass: return this->visitStmt(cast(S)->getSubStmt()); default: { if (const auto *E = dyn_cast(S)) return this->discard(E); return false; } } } template bool Compiler::visitCompoundStmt(const CompoundStmt *S) { BlockScope Scope(this); for (const auto *InnerStmt : S->body()) if (!visitStmt(InnerStmt)) return false; return Scope.destroyLocals(); } template bool Compiler::maybeEmitDeferredVarInit(const VarDecl *VD) { if (auto *DD = dyn_cast_if_present(VD)) { for (auto *BD : DD->flat_bindings()) if (auto *KD = BD->getHoldingVar(); KD && !this->visitVarDecl(KD)) return false; } return true; } template bool Compiler::visitDeclStmt(const DeclStmt *DS, bool EvaluateConditionDecl) { for (const auto *D : DS->decls()) { if (isa(D)) continue; const auto *VD = dyn_cast(D); if (!VD) return false; if (!this->visitVarDecl(VD)) return false; // Register decomposition decl holding vars. if (EvaluateConditionDecl && !this->maybeEmitDeferredVarInit(VD)) return false; } return true; } template bool Compiler::visitReturnStmt(const ReturnStmt *RS) { if (this->InStmtExpr) return this->emitUnsupported(RS); if (const Expr *RE = RS->getRetValue()) { LocalScope RetScope(this); if (ReturnType) { // Primitive types are simply returned. if (!this->visit(RE)) return false; this->emitCleanup(); return this->emitRet(*ReturnType, RS); } else if (RE->getType()->isVoidType()) { if (!this->visit(RE)) return false; } else { InitLinkScope ILS(this, InitLink::RVO()); // RVO - construct the value in the return location. if (!this->emitRVOPtr(RE)) return false; if (!this->visitInitializer(RE)) return false; if (!this->emitPopPtr(RE)) return false; this->emitCleanup(); return this->emitRetVoid(RS); } } // Void return. this->emitCleanup(); return this->emitRetVoid(RS); } template bool Compiler::visitIfStmt(const IfStmt *IS) { auto visitChildStmt = [&](const Stmt *S) -> bool { LocalScope SScope(this); if (!visitStmt(S)) return false; return SScope.destroyLocals(); }; if (auto *CondInit = IS->getInit()) if (!visitStmt(CondInit)) return false; if (const DeclStmt *CondDecl = IS->getConditionVariableDeclStmt()) if (!visitDeclStmt(CondDecl)) return false; // Save ourselves compiling some code and the jumps, etc. if the condition is // stataically known to be either true or false. We could look at more cases // here, but I think all the ones that actually happen are using a // ConstantExpr. if (std::optional BoolValue = getBoolValue(IS->getCond())) { if (*BoolValue) return visitChildStmt(IS->getThen()); else if (const Stmt *Else = IS->getElse()) return visitChildStmt(Else); return true; } // Otherwise, compile the condition. if (IS->isNonNegatedConsteval()) { if (!this->emitIsConstantContext(IS)) return false; } else if (IS->isNegatedConsteval()) { if (!this->emitIsConstantContext(IS)) return false; if (!this->emitInv(IS)) return false; } else { if (!this->visitBool(IS->getCond())) return false; } if (!this->maybeEmitDeferredVarInit(IS->getConditionVariable())) return false; if (const Stmt *Else = IS->getElse()) { LabelTy LabelElse = this->getLabel(); LabelTy LabelEnd = this->getLabel(); if (!this->jumpFalse(LabelElse)) return false; if (!visitChildStmt(IS->getThen())) return false; if (!this->jump(LabelEnd)) return false; this->emitLabel(LabelElse); if (!visitChildStmt(Else)) return false; this->emitLabel(LabelEnd); } else { LabelTy LabelEnd = this->getLabel(); if (!this->jumpFalse(LabelEnd)) return false; if (!visitChildStmt(IS->getThen())) return false; this->emitLabel(LabelEnd); } return true; } template bool Compiler::visitWhileStmt(const WhileStmt *S) { const Expr *Cond = S->getCond(); const Stmt *Body = S->getBody(); LabelTy CondLabel = this->getLabel(); // Label before the condition. LabelTy EndLabel = this->getLabel(); // Label after the loop. LoopScope LS(this, EndLabel, CondLabel); this->fallthrough(CondLabel); this->emitLabel(CondLabel); { LocalScope CondScope(this); if (const DeclStmt *CondDecl = S->getConditionVariableDeclStmt()) if (!visitDeclStmt(CondDecl)) return false; if (!this->visitBool(Cond)) return false; if (!this->maybeEmitDeferredVarInit(S->getConditionVariable())) return false; if (!this->jumpFalse(EndLabel)) return false; if (!this->visitStmt(Body)) return false; if (!CondScope.destroyLocals()) return false; } if (!this->jump(CondLabel)) return false; this->fallthrough(EndLabel); this->emitLabel(EndLabel); return true; } template bool Compiler::visitDoStmt(const DoStmt *S) { const Expr *Cond = S->getCond(); const Stmt *Body = S->getBody(); LabelTy StartLabel = this->getLabel(); LabelTy EndLabel = this->getLabel(); LabelTy CondLabel = this->getLabel(); LoopScope LS(this, EndLabel, CondLabel); this->fallthrough(StartLabel); this->emitLabel(StartLabel); { LocalScope CondScope(this); if (!this->visitStmt(Body)) return false; this->fallthrough(CondLabel); this->emitLabel(CondLabel); if (!this->visitBool(Cond)) return false; if (!CondScope.destroyLocals()) return false; } if (!this->jumpTrue(StartLabel)) return false; this->fallthrough(EndLabel); this->emitLabel(EndLabel); return true; } template bool Compiler::visitForStmt(const ForStmt *S) { // for (Init; Cond; Inc) { Body } const Stmt *Init = S->getInit(); const Expr *Cond = S->getCond(); const Expr *Inc = S->getInc(); const Stmt *Body = S->getBody(); LabelTy EndLabel = this->getLabel(); LabelTy CondLabel = this->getLabel(); LabelTy IncLabel = this->getLabel(); LoopScope LS(this, EndLabel, IncLabel); if (Init && !this->visitStmt(Init)) return false; this->fallthrough(CondLabel); this->emitLabel(CondLabel); // Start of loop body. LocalScope CondScope(this); if (const DeclStmt *CondDecl = S->getConditionVariableDeclStmt()) if (!visitDeclStmt(CondDecl)) return false; if (Cond) { if (!this->visitBool(Cond)) return false; if (!this->jumpFalse(EndLabel)) return false; } if (!this->maybeEmitDeferredVarInit(S->getConditionVariable())) return false; if (Body && !this->visitStmt(Body)) return false; this->fallthrough(IncLabel); this->emitLabel(IncLabel); if (Inc && !this->discard(Inc)) return false; if (!CondScope.destroyLocals()) return false; if (!this->jump(CondLabel)) return false; // End of loop body. this->emitLabel(EndLabel); // If we jumped out of the loop above, we still need to clean up the condition // scope. return CondScope.destroyLocals(); } template bool Compiler::visitCXXForRangeStmt(const CXXForRangeStmt *S) { const Stmt *Init = S->getInit(); const Expr *Cond = S->getCond(); const Expr *Inc = S->getInc(); const Stmt *Body = S->getBody(); const Stmt *BeginStmt = S->getBeginStmt(); const Stmt *RangeStmt = S->getRangeStmt(); const Stmt *EndStmt = S->getEndStmt(); LabelTy EndLabel = this->getLabel(); LabelTy CondLabel = this->getLabel(); LabelTy IncLabel = this->getLabel(); LoopScope LS(this, EndLabel, IncLabel); // Emit declarations needed in the loop. if (Init && !this->visitStmt(Init)) return false; if (!this->visitStmt(RangeStmt)) return false; if (!this->visitStmt(BeginStmt)) return false; if (!this->visitStmt(EndStmt)) return false; // Now the condition as well as the loop variable assignment. this->fallthrough(CondLabel); this->emitLabel(CondLabel); if (!this->visitBool(Cond)) return false; if (!this->jumpFalse(EndLabel)) return false; if (!this->visitDeclStmt(S->getLoopVarStmt(), /*EvaluateConditionDecl=*/true)) return false; // Body. { if (!this->visitStmt(Body)) return false; this->fallthrough(IncLabel); this->emitLabel(IncLabel); if (!this->discard(Inc)) return false; } if (!this->jump(CondLabel)) return false; this->fallthrough(EndLabel); this->emitLabel(EndLabel); return true; } template bool Compiler::visitBreakStmt(const BreakStmt *S) { if (!BreakLabel) return false; for (VariableScope *C = VarScope; C != BreakVarScope; C = C->getParent()) C->emitDestruction(); return this->jump(*BreakLabel); } template bool Compiler::visitContinueStmt(const ContinueStmt *S) { if (!ContinueLabel) return false; for (VariableScope *C = VarScope; C && C->getParent() != ContinueVarScope; C = C->getParent()) C->emitDestruction(); return this->jump(*ContinueLabel); } template bool Compiler::visitSwitchStmt(const SwitchStmt *S) { const Expr *Cond = S->getCond(); if (Cond->containsErrors()) return false; PrimType CondT = this->classifyPrim(Cond->getType()); LocalScope LS(this); LabelTy EndLabel = this->getLabel(); OptLabelTy DefaultLabel = std::nullopt; unsigned CondVar = this->allocateLocalPrimitive(Cond, CondT, /*IsConst=*/true); if (const auto *CondInit = S->getInit()) if (!visitStmt(CondInit)) return false; if (const DeclStmt *CondDecl = S->getConditionVariableDeclStmt()) if (!visitDeclStmt(CondDecl)) return false; // Initialize condition variable. if (!this->visit(Cond)) return false; if (!this->emitSetLocal(CondT, CondVar, S)) return false; if (!this->maybeEmitDeferredVarInit(S->getConditionVariable())) return false; CaseMap CaseLabels; // Create labels and comparison ops for all case statements. for (const SwitchCase *SC = S->getSwitchCaseList(); SC; SC = SC->getNextSwitchCase()) { if (const auto *CS = dyn_cast(SC)) { // FIXME: Implement ranges. if (CS->caseStmtIsGNURange()) return false; CaseLabels[SC] = this->getLabel(); const Expr *Value = CS->getLHS(); PrimType ValueT = this->classifyPrim(Value->getType()); // Compare the case statement's value to the switch condition. if (!this->emitGetLocal(CondT, CondVar, CS)) return false; if (!this->visit(Value)) return false; // Compare and jump to the case label. if (!this->emitEQ(ValueT, S)) return false; if (!this->jumpTrue(CaseLabels[CS])) return false; } else { assert(!DefaultLabel); DefaultLabel = this->getLabel(); } } // If none of the conditions above were true, fall through to the default // statement or jump after the switch statement. if (DefaultLabel) { if (!this->jump(*DefaultLabel)) return false; } else { if (!this->jump(EndLabel)) return false; } SwitchScope SS(this, std::move(CaseLabels), EndLabel, DefaultLabel); if (!this->visitStmt(S->getBody())) return false; this->emitLabel(EndLabel); return LS.destroyLocals(); } template bool Compiler::visitCaseStmt(const CaseStmt *S) { this->emitLabel(CaseLabels[S]); return this->visitStmt(S->getSubStmt()); } template bool Compiler::visitDefaultStmt(const DefaultStmt *S) { this->emitLabel(*DefaultLabel); return this->visitStmt(S->getSubStmt()); } template bool Compiler::visitAttributedStmt(const AttributedStmt *S) { if (this->Ctx.getLangOpts().CXXAssumptions && !this->Ctx.getLangOpts().MSVCCompat) { for (const Attr *A : S->getAttrs()) { auto *AA = dyn_cast(A); if (!AA) continue; assert(isa(S->getSubStmt())); const Expr *Assumption = AA->getAssumption(); if (Assumption->isValueDependent()) return false; if (Assumption->HasSideEffects(this->Ctx.getASTContext())) continue; // Evaluate assumption. if (!this->visitBool(Assumption)) return false; if (!this->emitAssume(Assumption)) return false; } } // Ignore other attributes. return this->visitStmt(S->getSubStmt()); } template bool Compiler::visitCXXTryStmt(const CXXTryStmt *S) { // Ignore all handlers. return this->visitStmt(S->getTryBlock()); } template bool Compiler::emitLambdaStaticInvokerBody(const CXXMethodDecl *MD) { assert(MD->isLambdaStaticInvoker()); assert(MD->hasBody()); assert(cast(MD->getBody())->body_empty()); const CXXRecordDecl *ClosureClass = MD->getParent(); const CXXMethodDecl *LambdaCallOp = ClosureClass->getLambdaCallOperator(); assert(ClosureClass->captures_begin() == ClosureClass->captures_end()); const Function *Func = this->getFunction(LambdaCallOp); if (!Func) return false; assert(Func->hasThisPointer()); assert(Func->getNumParams() == (MD->getNumParams() + 1 + Func->hasRVO())); if (Func->hasRVO()) { if (!this->emitRVOPtr(MD)) return false; } // The lambda call operator needs an instance pointer, but we don't have // one here, and we don't need one either because the lambda cannot have // any captures, as verified above. Emit a null pointer. This is then // special-cased when interpreting to not emit any misleading diagnostics. if (!this->emitNullPtr(0, nullptr, MD)) return false; // Forward all arguments from the static invoker to the lambda call operator. for (const ParmVarDecl *PVD : MD->parameters()) { auto It = this->Params.find(PVD); assert(It != this->Params.end()); // We do the lvalue-to-rvalue conversion manually here, so no need // to care about references. PrimType ParamType = this->classify(PVD->getType()).value_or(PT_Ptr); if (!this->emitGetParam(ParamType, It->second.Offset, MD)) return false; } if (!this->emitCall(Func, 0, LambdaCallOp)) return false; this->emitCleanup(); if (ReturnType) return this->emitRet(*ReturnType, MD); // Nothing to do, since we emitted the RVO pointer above. return this->emitRetVoid(MD); } template bool Compiler::checkLiteralType(const Expr *E) { if (Ctx.getLangOpts().CPlusPlus23) return true; if (!E->isPRValue() || E->getType()->isLiteralType(Ctx.getASTContext())) return true; return this->emitCheckLiteralType(E->getType().getTypePtr(), E); } template bool Compiler::compileConstructor(const CXXConstructorDecl *Ctor) { assert(!ReturnType); auto emitFieldInitializer = [&](const Record::Field *F, unsigned FieldOffset, const Expr *InitExpr) -> bool { // We don't know what to do with these, so just return false. if (InitExpr->getType().isNull()) return false; if (std::optional T = this->classify(InitExpr)) { if (!this->visit(InitExpr)) return false; if (F->isBitField()) return this->emitInitThisBitField(*T, F, FieldOffset, InitExpr); return this->emitInitThisField(*T, FieldOffset, InitExpr); } // Non-primitive case. Get a pointer to the field-to-initialize // on the stack and call visitInitialzer() for it. InitLinkScope FieldScope(this, InitLink::Field(F->Offset)); if (!this->emitGetPtrThisField(FieldOffset, InitExpr)) return false; if (!this->visitInitializer(InitExpr)) return false; return this->emitFinishInitPop(InitExpr); }; const RecordDecl *RD = Ctor->getParent(); const Record *R = this->getRecord(RD); if (!R) return false; if (R->isUnion() && Ctor->isCopyOrMoveConstructor()) { if (R->getNumFields() == 0) return this->emitRetVoid(Ctor); // union copy and move ctors are special. assert(cast(Ctor->getBody())->body_empty()); if (!this->emitThis(Ctor)) return false; auto PVD = Ctor->getParamDecl(0); ParamOffset PO = this->Params[PVD]; // Must exist. if (!this->emitGetParam(PT_Ptr, PO.Offset, Ctor)) return false; return this->emitMemcpy(Ctor) && this->emitPopPtr(Ctor) && this->emitRetVoid(Ctor); } InitLinkScope InitScope(this, InitLink::This()); for (const auto *Init : Ctor->inits()) { // Scope needed for the initializers. BlockScope Scope(this); const Expr *InitExpr = Init->getInit(); if (const FieldDecl *Member = Init->getMember()) { const Record::Field *F = R->getField(Member); if (!emitFieldInitializer(F, F->Offset, InitExpr)) return false; } else if (const Type *Base = Init->getBaseClass()) { const auto *BaseDecl = Base->getAsCXXRecordDecl(); assert(BaseDecl); if (Init->isBaseVirtual()) { assert(R->getVirtualBase(BaseDecl)); if (!this->emitGetPtrThisVirtBase(BaseDecl, InitExpr)) return false; } else { // Base class initializer. // Get This Base and call initializer on it. const Record::Base *B = R->getBase(BaseDecl); assert(B); if (!this->emitGetPtrThisBase(B->Offset, InitExpr)) return false; } if (!this->visitInitializer(InitExpr)) return false; if (!this->emitFinishInitPop(InitExpr)) return false; } else if (const IndirectFieldDecl *IFD = Init->getIndirectMember()) { assert(IFD->getChainingSize() >= 2); unsigned NestedFieldOffset = 0; const Record::Field *NestedField = nullptr; for (const NamedDecl *ND : IFD->chain()) { const auto *FD = cast(ND); const Record *FieldRecord = this->P.getOrCreateRecord(FD->getParent()); assert(FieldRecord); NestedField = FieldRecord->getField(FD); assert(NestedField); NestedFieldOffset += NestedField->Offset; } assert(NestedField); if (!emitFieldInitializer(NestedField, NestedFieldOffset, InitExpr)) return false; // Mark all chain links as initialized. unsigned InitFieldOffset = 0; for (const NamedDecl *ND : IFD->chain().drop_back()) { const auto *FD = cast(ND); const Record *FieldRecord = this->P.getOrCreateRecord(FD->getParent()); assert(FieldRecord); NestedField = FieldRecord->getField(FD); InitFieldOffset += NestedField->Offset; assert(NestedField); if (!this->emitGetPtrThisField(InitFieldOffset, InitExpr)) return false; if (!this->emitFinishInitPop(InitExpr)) return false; } } else { assert(Init->isDelegatingInitializer()); if (!this->emitThis(InitExpr)) return false; if (!this->visitInitializer(Init->getInit())) return false; if (!this->emitPopPtr(InitExpr)) return false; } if (!Scope.destroyLocals()) return false; } if (const auto *Body = Ctor->getBody()) if (!visitStmt(Body)) return false; return this->emitRetVoid(SourceInfo{}); } template bool Compiler::compileDestructor(const CXXDestructorDecl *Dtor) { const RecordDecl *RD = Dtor->getParent(); const Record *R = this->getRecord(RD); if (!R) return false; if (!Dtor->isTrivial() && Dtor->getBody()) { if (!this->visitStmt(Dtor->getBody())) return false; } if (!this->emitThis(Dtor)) return false; if (!this->emitCheckDestruction(Dtor)) return false; assert(R); if (!R->isUnion()) { // First, destroy all fields. for (const Record::Field &Field : llvm::reverse(R->fields())) { const Descriptor *D = Field.Desc; if (!D->isPrimitive() && !D->isPrimitiveArray()) { if (!this->emitGetPtrField(Field.Offset, SourceInfo{})) return false; if (!this->emitDestruction(D, SourceInfo{})) return false; if (!this->emitPopPtr(SourceInfo{})) return false; } } } for (const Record::Base &Base : llvm::reverse(R->bases())) { if (Base.R->isAnonymousUnion()) continue; if (!this->emitGetPtrBase(Base.Offset, SourceInfo{})) return false; if (!this->emitRecordDestruction(Base.R, {})) return false; if (!this->emitPopPtr(SourceInfo{})) return false; } // FIXME: Virtual bases. return this->emitPopPtr(Dtor) && this->emitRetVoid(Dtor); } template bool Compiler::compileUnionAssignmentOperator( const CXXMethodDecl *MD) { if (!this->emitThis(MD)) return false; auto PVD = MD->getParamDecl(0); ParamOffset PO = this->Params[PVD]; // Must exist. if (!this->emitGetParam(PT_Ptr, PO.Offset, MD)) return false; return this->emitMemcpy(MD) && this->emitRet(PT_Ptr, MD); } template bool Compiler::visitFunc(const FunctionDecl *F) { // Classify the return type. ReturnType = this->classify(F->getReturnType()); this->CompilingFunction = F; if (const auto *Ctor = dyn_cast(F)) return this->compileConstructor(Ctor); if (const auto *Dtor = dyn_cast(F)) return this->compileDestructor(Dtor); // Emit custom code if this is a lambda static invoker. if (const auto *MD = dyn_cast(F)) { const RecordDecl *RD = MD->getParent(); if (RD->isUnion() && (MD->isCopyAssignmentOperator() || MD->isMoveAssignmentOperator())) return this->compileUnionAssignmentOperator(MD); if (MD->isLambdaStaticInvoker()) return this->emitLambdaStaticInvokerBody(MD); } // Regular functions. if (const auto *Body = F->getBody()) if (!visitStmt(Body)) return false; // Emit a guard return to protect against a code path missing one. if (F->getReturnType()->isVoidType()) return this->emitRetVoid(SourceInfo{}); return this->emitNoRet(SourceInfo{}); } template bool Compiler::VisitUnaryOperator(const UnaryOperator *E) { const Expr *SubExpr = E->getSubExpr(); if (SubExpr->getType()->isAnyComplexType()) return this->VisitComplexUnaryOperator(E); if (SubExpr->getType()->isVectorType()) return this->VisitVectorUnaryOperator(E); if (SubExpr->getType()->isFixedPointType()) return this->VisitFixedPointUnaryOperator(E); std::optional T = classify(SubExpr->getType()); switch (E->getOpcode()) { case UO_PostInc: { // x++ if (!Ctx.getLangOpts().CPlusPlus14) return this->emitInvalid(E); if (!T) return this->emitError(E); if (!this->visit(SubExpr)) return false; if (T == PT_Ptr) { if (!this->emitIncPtr(E)) return false; return DiscardResult ? this->emitPopPtr(E) : true; } if (T == PT_Float) { return DiscardResult ? this->emitIncfPop(getFPOptions(E), E) : this->emitIncf(getFPOptions(E), E); } return DiscardResult ? this->emitIncPop(*T, E->canOverflow(), E) : this->emitInc(*T, E->canOverflow(), E); } case UO_PostDec: { // x-- if (!Ctx.getLangOpts().CPlusPlus14) return this->emitInvalid(E); if (!T) return this->emitError(E); if (!this->visit(SubExpr)) return false; if (T == PT_Ptr) { if (!this->emitDecPtr(E)) return false; return DiscardResult ? this->emitPopPtr(E) : true; } if (T == PT_Float) { return DiscardResult ? this->emitDecfPop(getFPOptions(E), E) : this->emitDecf(getFPOptions(E), E); } return DiscardResult ? this->emitDecPop(*T, E->canOverflow(), E) : this->emitDec(*T, E->canOverflow(), E); } case UO_PreInc: { // ++x if (!Ctx.getLangOpts().CPlusPlus14) return this->emitInvalid(E); if (!T) return this->emitError(E); if (!this->visit(SubExpr)) return false; if (T == PT_Ptr) { if (!this->emitLoadPtr(E)) return false; if (!this->emitConstUint8(1, E)) return false; if (!this->emitAddOffsetUint8(E)) return false; return DiscardResult ? this->emitStorePopPtr(E) : this->emitStorePtr(E); } // Post-inc and pre-inc are the same if the value is to be discarded. if (DiscardResult) { if (T == PT_Float) return this->emitIncfPop(getFPOptions(E), E); return this->emitIncPop(*T, E->canOverflow(), E); } if (T == PT_Float) { const auto &TargetSemantics = Ctx.getFloatSemantics(E->getType()); if (!this->emitLoadFloat(E)) return false; APFloat F(TargetSemantics, 1); if (!this->emitFloat(F, E)) return false; if (!this->emitAddf(getFPOptions(E), E)) return false; if (!this->emitStoreFloat(E)) return false; } else { assert(isIntegralType(*T)); if (!this->emitPreInc(*T, E->canOverflow(), E)) return false; } return E->isGLValue() || this->emitLoadPop(*T, E); } case UO_PreDec: { // --x if (!Ctx.getLangOpts().CPlusPlus14) return this->emitInvalid(E); if (!T) return this->emitError(E); if (!this->visit(SubExpr)) return false; if (T == PT_Ptr) { if (!this->emitLoadPtr(E)) return false; if (!this->emitConstUint8(1, E)) return false; if (!this->emitSubOffsetUint8(E)) return false; return DiscardResult ? this->emitStorePopPtr(E) : this->emitStorePtr(E); } // Post-dec and pre-dec are the same if the value is to be discarded. if (DiscardResult) { if (T == PT_Float) return this->emitDecfPop(getFPOptions(E), E); return this->emitDecPop(*T, E->canOverflow(), E); } if (T == PT_Float) { const auto &TargetSemantics = Ctx.getFloatSemantics(E->getType()); if (!this->emitLoadFloat(E)) return false; APFloat F(TargetSemantics, 1); if (!this->emitFloat(F, E)) return false; if (!this->emitSubf(getFPOptions(E), E)) return false; if (!this->emitStoreFloat(E)) return false; } else { assert(isIntegralType(*T)); if (!this->emitPreDec(*T, E->canOverflow(), E)) return false; } return E->isGLValue() || this->emitLoadPop(*T, E); } case UO_LNot: // !x if (!T) return this->emitError(E); if (DiscardResult) return this->discard(SubExpr); if (!this->visitBool(SubExpr)) return false; if (!this->emitInv(E)) return false; if (PrimType ET = classifyPrim(E->getType()); ET != PT_Bool) return this->emitCast(PT_Bool, ET, E); return true; case UO_Minus: // -x if (!T) return this->emitError(E); if (!this->visit(SubExpr)) return false; return DiscardResult ? this->emitPop(*T, E) : this->emitNeg(*T, E); case UO_Plus: // +x if (!T) return this->emitError(E); if (!this->visit(SubExpr)) // noop return false; return DiscardResult ? this->emitPop(*T, E) : true; case UO_AddrOf: // &x if (E->getType()->isMemberPointerType()) { // C++11 [expr.unary.op]p3 has very strict rules on how the address of a // member can be formed. return this->emitGetMemberPtr(cast(SubExpr)->getDecl(), E); } // We should already have a pointer when we get here. return this->delegate(SubExpr); case UO_Deref: // *x if (DiscardResult) return this->discard(SubExpr); if (!this->visit(SubExpr)) return false; if (classifyPrim(SubExpr) == PT_Ptr) return this->emitNarrowPtr(E); return true; case UO_Not: // ~x if (!T) return this->emitError(E); if (!this->visit(SubExpr)) return false; return DiscardResult ? this->emitPop(*T, E) : this->emitComp(*T, E); case UO_Real: // __real x assert(T); return this->delegate(SubExpr); case UO_Imag: { // __imag x assert(T); if (!this->discard(SubExpr)) return false; return this->visitZeroInitializer(*T, SubExpr->getType(), SubExpr); } case UO_Extension: return this->delegate(SubExpr); case UO_Coawait: assert(false && "Unhandled opcode"); } return false; } template bool Compiler::VisitComplexUnaryOperator(const UnaryOperator *E) { const Expr *SubExpr = E->getSubExpr(); assert(SubExpr->getType()->isAnyComplexType()); if (DiscardResult) return this->discard(SubExpr); std::optional ResT = classify(E); auto prepareResult = [=]() -> bool { if (!ResT && !Initializing) { std::optional LocalIndex = allocateLocal(SubExpr); if (!LocalIndex) return false; return this->emitGetPtrLocal(*LocalIndex, E); } return true; }; // The offset of the temporary, if we created one. unsigned SubExprOffset = ~0u; auto createTemp = [=, &SubExprOffset]() -> bool { SubExprOffset = this->allocateLocalPrimitive(SubExpr, PT_Ptr, /*IsConst=*/true); if (!this->visit(SubExpr)) return false; return this->emitSetLocal(PT_Ptr, SubExprOffset, E); }; PrimType ElemT = classifyComplexElementType(SubExpr->getType()); auto getElem = [=](unsigned Offset, unsigned Index) -> bool { if (!this->emitGetLocal(PT_Ptr, Offset, E)) return false; return this->emitArrayElemPop(ElemT, Index, E); }; switch (E->getOpcode()) { case UO_Minus: if (!prepareResult()) return false; if (!createTemp()) return false; for (unsigned I = 0; I != 2; ++I) { if (!getElem(SubExprOffset, I)) return false; if (!this->emitNeg(ElemT, E)) return false; if (!this->emitInitElem(ElemT, I, E)) return false; } break; case UO_Plus: // +x case UO_AddrOf: // &x case UO_Deref: // *x return this->delegate(SubExpr); case UO_LNot: if (!this->visit(SubExpr)) return false; if (!this->emitComplexBoolCast(SubExpr)) return false; if (!this->emitInv(E)) return false; if (PrimType ET = classifyPrim(E->getType()); ET != PT_Bool) return this->emitCast(PT_Bool, ET, E); return true; case UO_Real: return this->emitComplexReal(SubExpr); case UO_Imag: if (!this->visit(SubExpr)) return false; if (SubExpr->isLValue()) { if (!this->emitConstUint8(1, E)) return false; return this->emitArrayElemPtrPopUint8(E); } // Since our _Complex implementation does not map to a primitive type, // we sometimes have to do the lvalue-to-rvalue conversion here manually. return this->emitArrayElemPop(classifyPrim(E->getType()), 1, E); case UO_Not: // ~x if (!this->visit(SubExpr)) return false; // Negate the imaginary component. if (!this->emitArrayElem(ElemT, 1, E)) return false; if (!this->emitNeg(ElemT, E)) return false; if (!this->emitInitElem(ElemT, 1, E)) return false; return DiscardResult ? this->emitPopPtr(E) : true; case UO_Extension: return this->delegate(SubExpr); default: return this->emitInvalid(E); } return true; } template bool Compiler::VisitVectorUnaryOperator(const UnaryOperator *E) { const Expr *SubExpr = E->getSubExpr(); assert(SubExpr->getType()->isVectorType()); if (DiscardResult) return this->discard(SubExpr); auto UnaryOp = E->getOpcode(); if (UnaryOp == UO_Extension) return this->delegate(SubExpr); if (UnaryOp != UO_Plus && UnaryOp != UO_Minus && UnaryOp != UO_LNot && UnaryOp != UO_Not && UnaryOp != UO_AddrOf) return this->emitInvalid(E); // Nothing to do here. if (UnaryOp == UO_Plus || UnaryOp == UO_AddrOf) return this->delegate(SubExpr); if (!Initializing) { std::optional LocalIndex = allocateLocal(SubExpr); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } // The offset of the temporary, if we created one. unsigned SubExprOffset = this->allocateLocalPrimitive(SubExpr, PT_Ptr, /*IsConst=*/true); if (!this->visit(SubExpr)) return false; if (!this->emitSetLocal(PT_Ptr, SubExprOffset, E)) return false; const auto *VecTy = SubExpr->getType()->getAs(); PrimType ElemT = classifyVectorElementType(SubExpr->getType()); auto getElem = [=](unsigned Offset, unsigned Index) -> bool { if (!this->emitGetLocal(PT_Ptr, Offset, E)) return false; return this->emitArrayElemPop(ElemT, Index, E); }; switch (UnaryOp) { case UO_Minus: for (unsigned I = 0; I != VecTy->getNumElements(); ++I) { if (!getElem(SubExprOffset, I)) return false; if (!this->emitNeg(ElemT, E)) return false; if (!this->emitInitElem(ElemT, I, E)) return false; } break; case UO_LNot: { // !x // In C++, the logic operators !, &&, || are available for vectors. !v is // equivalent to v == 0. // // The result of the comparison is a vector of the same width and number of // elements as the comparison operands with a signed integral element type. // // https://gcc.gnu.org/onlinedocs/gcc/Vector-Extensions.html QualType ResultVecTy = E->getType(); PrimType ResultVecElemT = classifyPrim(ResultVecTy->getAs()->getElementType()); for (unsigned I = 0; I != VecTy->getNumElements(); ++I) { if (!getElem(SubExprOffset, I)) return false; // operator ! on vectors returns -1 for 'truth', so negate it. if (!this->emitPrimCast(ElemT, PT_Bool, Ctx.getASTContext().BoolTy, E)) return false; if (!this->emitInv(E)) return false; if (!this->emitPrimCast(PT_Bool, ElemT, VecTy->getElementType(), E)) return false; if (!this->emitNeg(ElemT, E)) return false; if (ElemT != ResultVecElemT && !this->emitPrimCast(ElemT, ResultVecElemT, ResultVecTy, E)) return false; if (!this->emitInitElem(ResultVecElemT, I, E)) return false; } break; } case UO_Not: // ~x for (unsigned I = 0; I != VecTy->getNumElements(); ++I) { if (!getElem(SubExprOffset, I)) return false; if (ElemT == PT_Bool) { if (!this->emitInv(E)) return false; } else { if (!this->emitComp(ElemT, E)) return false; } if (!this->emitInitElem(ElemT, I, E)) return false; } break; default: llvm_unreachable("Unsupported unary operators should be handled up front"); } return true; } template bool Compiler::visitDeclRef(const ValueDecl *D, const Expr *E) { if (DiscardResult) return true; if (const auto *ECD = dyn_cast(D)) return this->emitConst(ECD->getInitVal(), E); if (const auto *FuncDecl = dyn_cast(D)) { const Function *F = getFunction(FuncDecl); return F && this->emitGetFnPtr(F, E); } if (const auto *TPOD = dyn_cast(D)) { if (std::optional Index = P.getOrCreateGlobal(D)) { if (!this->emitGetPtrGlobal(*Index, E)) return false; if (std::optional T = classify(E->getType())) { if (!this->visitAPValue(TPOD->getValue(), *T, E)) return false; return this->emitInitGlobal(*T, *Index, E); } return this->visitAPValueInitializer(TPOD->getValue(), E, TPOD->getType()); } return false; } // References are implemented via pointers, so when we see a DeclRefExpr // pointing to a reference, we need to get its value directly (i.e. the // pointer to the actual value) instead of a pointer to the pointer to the // value. bool IsReference = D->getType()->isReferenceType(); // Local variables. if (auto It = Locals.find(D); It != Locals.end()) { const unsigned Offset = It->second.Offset; if (IsReference) return this->emitGetLocal(classifyPrim(E), Offset, E); return this->emitGetPtrLocal(Offset, E); } // Global variables. if (auto GlobalIndex = P.getGlobal(D)) { if (IsReference) { if (!Ctx.getLangOpts().CPlusPlus11) return this->emitGetGlobal(classifyPrim(E), *GlobalIndex, E); return this->emitGetGlobalUnchecked(classifyPrim(E), *GlobalIndex, E); } return this->emitGetPtrGlobal(*GlobalIndex, E); } // Function parameters. if (const auto *PVD = dyn_cast(D)) { if (auto It = this->Params.find(PVD); It != this->Params.end()) { if (IsReference || !It->second.IsPtr) return this->emitGetParam(classifyPrim(E), It->second.Offset, E); return this->emitGetPtrParam(It->second.Offset, E); } } // In case we need to re-visit a declaration. auto revisit = [&](const VarDecl *VD) -> bool { if (!this->emitPushCC(VD->hasConstantInitialization(), E)) return false; auto VarState = this->visitDecl(VD, /*IsConstexprUnknown=*/true); if (!this->emitPopCC(E)) return false; if (VarState.notCreated()) return true; if (!VarState) return false; // Retry. return this->visitDeclRef(D, E); }; // Lambda captures. if (auto It = this->LambdaCaptures.find(D); It != this->LambdaCaptures.end()) { auto [Offset, IsPtr] = It->second; if (IsPtr) return this->emitGetThisFieldPtr(Offset, E); return this->emitGetPtrThisField(Offset, E); } if (const auto *DRE = dyn_cast(E); DRE && DRE->refersToEnclosingVariableOrCapture()) { if (const auto *VD = dyn_cast(D); VD && VD->isInitCapture()) return revisit(VD); } if (const auto *BD = dyn_cast(D)) return this->visit(BD->getBinding()); // Avoid infinite recursion. if (D == InitializingDecl) return this->emitDummyPtr(D, E); // Try to lazily visit (or emit dummy pointers for) declarations // we haven't seen yet. // For C. if (!Ctx.getLangOpts().CPlusPlus) { if (const auto *VD = dyn_cast(D); VD && VD->getAnyInitializer() && VD->getType().isConstant(Ctx.getASTContext()) && !VD->isWeak()) return revisit(VD); return this->emitDummyPtr(D, E); } // ... and C++. const auto *VD = dyn_cast(D); if (!VD) return this->emitDummyPtr(D, E); const auto typeShouldBeVisited = [&](QualType T) -> bool { if (T.isConstant(Ctx.getASTContext())) return true; return T->isReferenceType(); }; if ((VD->hasGlobalStorage() || VD->isStaticDataMember()) && typeShouldBeVisited(VD->getType())) { if (const Expr *Init = VD->getAnyInitializer(); Init && !Init->isValueDependent()) { // Whether or not the evaluation is successul doesn't really matter // here -- we will create a global variable in any case, and that // will have the state of initializer evaluation attached. APValue V; SmallVector Notes; (void)Init->EvaluateAsInitializer(V, Ctx.getASTContext(), VD, Notes, true); return this->visitDeclRef(D, E); } return revisit(VD); } // FIXME: The evaluateValue() check here is a little ridiculous, since // it will ultimately call into Context::evaluateAsInitializer(). In // other words, we're evaluating the initializer, just to know if we can // evaluate the initializer. if (VD->isLocalVarDecl() && typeShouldBeVisited(VD->getType()) && VD->getInit() && !VD->getInit()->isValueDependent()) { if (VD->evaluateValue()) return revisit(VD); if (!IsReference) return this->emitDummyPtr(D, E); return this->emitInvalidDeclRef(cast(E), /*InitializerFailed=*/true, E); } return this->emitDummyPtr(D, E); } template bool Compiler::VisitDeclRefExpr(const DeclRefExpr *E) { const auto *D = E->getDecl(); return this->visitDeclRef(D, E); } template void Compiler::emitCleanup() { for (VariableScope *C = VarScope; C; C = C->getParent()) C->emitDestruction(); } template unsigned Compiler::collectBaseOffset(const QualType BaseType, const QualType DerivedType) { const auto extractRecordDecl = [](QualType Ty) -> const CXXRecordDecl * { if (const auto *R = Ty->getPointeeCXXRecordDecl()) return R; return Ty->getAsCXXRecordDecl(); }; const CXXRecordDecl *BaseDecl = extractRecordDecl(BaseType); const CXXRecordDecl *DerivedDecl = extractRecordDecl(DerivedType); return Ctx.collectBaseOffset(BaseDecl, DerivedDecl); } /// Emit casts from a PrimType to another PrimType. template bool Compiler::emitPrimCast(PrimType FromT, PrimType ToT, QualType ToQT, const Expr *E) { if (FromT == PT_Float) { // Floating to floating. if (ToT == PT_Float) { const llvm::fltSemantics *ToSem = &Ctx.getFloatSemantics(ToQT); return this->emitCastFP(ToSem, getRoundingMode(E), E); } if (ToT == PT_IntAP) return this->emitCastFloatingIntegralAP(Ctx.getBitWidth(ToQT), getFPOptions(E), E); if (ToT == PT_IntAPS) return this->emitCastFloatingIntegralAPS(Ctx.getBitWidth(ToQT), getFPOptions(E), E); // Float to integral. if (isIntegralType(ToT) || ToT == PT_Bool) return this->emitCastFloatingIntegral(ToT, getFPOptions(E), E); } if (isIntegralType(FromT) || FromT == PT_Bool) { if (ToT == PT_IntAP) return this->emitCastAP(FromT, Ctx.getBitWidth(ToQT), E); if (ToT == PT_IntAPS) return this->emitCastAPS(FromT, Ctx.getBitWidth(ToQT), E); // Integral to integral. if (isIntegralType(ToT) || ToT == PT_Bool) return FromT != ToT ? this->emitCast(FromT, ToT, E) : true; if (ToT == PT_Float) { // Integral to floating. const llvm::fltSemantics *ToSem = &Ctx.getFloatSemantics(ToQT); return this->emitCastIntegralFloating(FromT, ToSem, getFPOptions(E), E); } } return false; } /// Emits __real(SubExpr) template bool Compiler::emitComplexReal(const Expr *SubExpr) { assert(SubExpr->getType()->isAnyComplexType()); if (DiscardResult) return this->discard(SubExpr); if (!this->visit(SubExpr)) return false; if (SubExpr->isLValue()) { if (!this->emitConstUint8(0, SubExpr)) return false; return this->emitArrayElemPtrPopUint8(SubExpr); } // Rvalue, load the actual element. return this->emitArrayElemPop(classifyComplexElementType(SubExpr->getType()), 0, SubExpr); } template bool Compiler::emitComplexBoolCast(const Expr *E) { assert(!DiscardResult); PrimType ElemT = classifyComplexElementType(E->getType()); // We emit the expression (__real(E) != 0 || __imag(E) != 0) // for us, that means (bool)E[0] || (bool)E[1] if (!this->emitArrayElem(ElemT, 0, E)) return false; if (ElemT == PT_Float) { if (!this->emitCastFloatingIntegral(PT_Bool, getFPOptions(E), E)) return false; } else { if (!this->emitCast(ElemT, PT_Bool, E)) return false; } // We now have the bool value of E[0] on the stack. LabelTy LabelTrue = this->getLabel(); if (!this->jumpTrue(LabelTrue)) return false; if (!this->emitArrayElemPop(ElemT, 1, E)) return false; if (ElemT == PT_Float) { if (!this->emitCastFloatingIntegral(PT_Bool, getFPOptions(E), E)) return false; } else { if (!this->emitCast(ElemT, PT_Bool, E)) return false; } // Leave the boolean value of E[1] on the stack. LabelTy EndLabel = this->getLabel(); this->jump(EndLabel); this->emitLabel(LabelTrue); if (!this->emitPopPtr(E)) return false; if (!this->emitConstBool(true, E)) return false; this->fallthrough(EndLabel); this->emitLabel(EndLabel); return true; } template bool Compiler::emitComplexComparison(const Expr *LHS, const Expr *RHS, const BinaryOperator *E) { assert(E->isComparisonOp()); assert(!Initializing); assert(!DiscardResult); PrimType ElemT; bool LHSIsComplex; unsigned LHSOffset; if (LHS->getType()->isAnyComplexType()) { LHSIsComplex = true; ElemT = classifyComplexElementType(LHS->getType()); LHSOffset = allocateLocalPrimitive(LHS, PT_Ptr, /*IsConst=*/true); if (!this->visit(LHS)) return false; if (!this->emitSetLocal(PT_Ptr, LHSOffset, E)) return false; } else { LHSIsComplex = false; PrimType LHST = classifyPrim(LHS->getType()); LHSOffset = this->allocateLocalPrimitive(LHS, LHST, /*IsConst=*/true); if (!this->visit(LHS)) return false; if (!this->emitSetLocal(LHST, LHSOffset, E)) return false; } bool RHSIsComplex; unsigned RHSOffset; if (RHS->getType()->isAnyComplexType()) { RHSIsComplex = true; ElemT = classifyComplexElementType(RHS->getType()); RHSOffset = allocateLocalPrimitive(RHS, PT_Ptr, /*IsConst=*/true); if (!this->visit(RHS)) return false; if (!this->emitSetLocal(PT_Ptr, RHSOffset, E)) return false; } else { RHSIsComplex = false; PrimType RHST = classifyPrim(RHS->getType()); RHSOffset = this->allocateLocalPrimitive(RHS, RHST, /*IsConst=*/true); if (!this->visit(RHS)) return false; if (!this->emitSetLocal(RHST, RHSOffset, E)) return false; } auto getElem = [&](unsigned LocalOffset, unsigned Index, bool IsComplex) -> bool { if (IsComplex) { if (!this->emitGetLocal(PT_Ptr, LocalOffset, E)) return false; return this->emitArrayElemPop(ElemT, Index, E); } return this->emitGetLocal(ElemT, LocalOffset, E); }; for (unsigned I = 0; I != 2; ++I) { // Get both values. if (!getElem(LHSOffset, I, LHSIsComplex)) return false; if (!getElem(RHSOffset, I, RHSIsComplex)) return false; // And compare them. if (!this->emitEQ(ElemT, E)) return false; if (!this->emitCastBoolUint8(E)) return false; } // We now have two bool values on the stack. Compare those. if (!this->emitAddUint8(E)) return false; if (!this->emitConstUint8(2, E)) return false; if (E->getOpcode() == BO_EQ) { if (!this->emitEQUint8(E)) return false; } else if (E->getOpcode() == BO_NE) { if (!this->emitNEUint8(E)) return false; } else return false; // In C, this returns an int. if (PrimType ResT = classifyPrim(E->getType()); ResT != PT_Bool) return this->emitCast(PT_Bool, ResT, E); return true; } /// When calling this, we have a pointer of the local-to-destroy /// on the stack. /// Emit destruction of record types (or arrays of record types). template bool Compiler::emitRecordDestruction(const Record *R, SourceInfo Loc) { assert(R); assert(!R->isAnonymousUnion()); const CXXDestructorDecl *Dtor = R->getDestructor(); if (!Dtor || Dtor->isTrivial()) return true; assert(Dtor); const Function *DtorFunc = getFunction(Dtor); if (!DtorFunc) return false; assert(DtorFunc->hasThisPointer()); assert(DtorFunc->getNumParams() == 1); if (!this->emitDupPtr(Loc)) return false; return this->emitCall(DtorFunc, 0, Loc); } /// When calling this, we have a pointer of the local-to-destroy /// on the stack. /// Emit destruction of record types (or arrays of record types). template bool Compiler::emitDestruction(const Descriptor *Desc, SourceInfo Loc) { assert(Desc); assert(!Desc->isPrimitive()); assert(!Desc->isPrimitiveArray()); // Can happen if the decl is invalid. if (Desc->isDummy()) return true; // Arrays. if (Desc->isArray()) { const Descriptor *ElemDesc = Desc->ElemDesc; assert(ElemDesc); // Don't need to do anything for these. if (ElemDesc->isPrimitiveArray()) return true; // If this is an array of record types, check if we need // to call the element destructors at all. If not, try // to save the work. if (const Record *ElemRecord = ElemDesc->ElemRecord) { if (const CXXDestructorDecl *Dtor = ElemRecord->getDestructor(); !Dtor || Dtor->isTrivial()) return true; } if (unsigned N = Desc->getNumElems()) { for (ssize_t I = N - 1; I >= 0; --I) { if (!this->emitConstUint64(I, Loc)) return false; if (!this->emitArrayElemPtrUint64(Loc)) return false; if (!this->emitDestruction(ElemDesc, Loc)) return false; if (!this->emitPopPtr(Loc)) return false; } } return true; } assert(Desc->ElemRecord); if (Desc->ElemRecord->isAnonymousUnion()) return true; return this->emitRecordDestruction(Desc->ElemRecord, Loc); } /// Create a dummy pointer for the given decl (or expr) and /// push a pointer to it on the stack. template bool Compiler::emitDummyPtr(const DeclTy &D, const Expr *E) { assert(!DiscardResult && "Should've been checked before"); unsigned DummyID = P.getOrCreateDummy(D); if (!this->emitGetPtrGlobal(DummyID, E)) return false; if (E->getType()->isVoidType()) return true; // Convert the dummy pointer to another pointer type if we have to. if (PrimType PT = classifyPrim(E); PT != PT_Ptr) { if (isPtrType(PT)) return this->emitDecayPtr(PT_Ptr, PT, E); return false; } return true; } template bool Compiler::emitFloat(const APFloat &F, const Expr *E) { assert(!DiscardResult && "Should've been checked before"); if (Floating::singleWord(F.getSemantics())) return this->emitConstFloat(Floating(F), E); APInt I = F.bitcastToAPInt(); return this->emitConstFloat( Floating(const_cast(I.getRawData()), llvm::APFloatBase::SemanticsToEnum(F.getSemantics())), E); } // This function is constexpr if and only if To, From, and the types of // all subobjects of To and From are types T such that... // (3.1) - is_union_v is false; // (3.2) - is_pointer_v is false; // (3.3) - is_member_pointer_v is false; // (3.4) - is_volatile_v is false; and // (3.5) - T has no non-static data members of reference type template bool Compiler::emitBuiltinBitCast(const CastExpr *E) { const Expr *SubExpr = E->getSubExpr(); QualType FromType = SubExpr->getType(); QualType ToType = E->getType(); std::optional ToT = classify(ToType); assert(!ToType->isReferenceType()); // Prepare storage for the result in case we discard. if (DiscardResult && !Initializing && !ToT) { std::optional LocalIndex = allocateLocal(E); if (!LocalIndex) return false; if (!this->emitGetPtrLocal(*LocalIndex, E)) return false; } // Get a pointer to the value-to-cast on the stack. // For CK_LValueToRValueBitCast, this is always an lvalue and // we later assume it to be one (i.e. a PT_Ptr). However, // we call this function for other utility methods where // a bitcast might be useful, so convert it to a PT_Ptr in that case. if (SubExpr->isGLValue() || FromType->isVectorType()) { if (!this->visit(SubExpr)) return false; } else if (std::optional FromT = classify(SubExpr)) { unsigned TempOffset = allocateLocalPrimitive(SubExpr, *FromT, /*IsConst=*/true); if (!this->visit(SubExpr)) return false; if (!this->emitSetLocal(*FromT, TempOffset, E)) return false; if (!this->emitGetPtrLocal(TempOffset, E)) return false; } else { return false; } if (!ToT) { if (!this->emitBitCast(E)) return false; return DiscardResult ? this->emitPopPtr(E) : true; } assert(ToT); const llvm::fltSemantics *TargetSemantics = nullptr; if (ToT == PT_Float) TargetSemantics = &Ctx.getFloatSemantics(ToType); // Conversion to a primitive type. FromType can be another // primitive type, or a record/array. bool ToTypeIsUChar = (ToType->isSpecificBuiltinType(BuiltinType::UChar) || ToType->isSpecificBuiltinType(BuiltinType::Char_U)); uint32_t ResultBitWidth = std::max(Ctx.getBitWidth(ToType), 8u); if (!this->emitBitCastPrim(*ToT, ToTypeIsUChar || ToType->isStdByteType(), ResultBitWidth, TargetSemantics, E)) return false; if (DiscardResult) return this->emitPop(*ToT, E); return true; } namespace clang { namespace interp { template class Compiler; template class Compiler; } // namespace interp } // namespace clang